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-
-<div style='text-align:center; font-size:1.2em; font-weight:bold'>The Project Gutenberg eBook of Life and death, by Albert Dastre</div>
-
-<div style='display:block; margin:1em 0'>
-This eBook is for the use of anyone anywhere in the United States and
-most other parts of the world at no cost and with almost no restrictions
-whatsoever. You may copy it, give it away or re-use it under the terms
-of the Project Gutenberg License included with this eBook or online
-at <a href="https://www.gutenberg.org">www.gutenberg.org</a>. If you
-are not located in the United States, you will have to check the laws of the
-country where you are located before using this eBook.
-</div>
-
-<p style='display:block; margin-top:1em; margin-bottom:1em; margin-left:2em; text-indent:-2em'>Title: Life and death</p>
-
-<div style='display:block; margin-top:1em; margin-bottom:1em; margin-left:2em; text-indent:-2em'>Author: Albert Dastre</div>
-
-<div style='display:block; margin-top:1em; margin-bottom:1em; margin-left:2em; text-indent:-2em'>Translator: William John Greenstreet</div>
-
-<div style='display:block; margin:1em 0'>Release Date: June 25, 2021 [eBook #65699]</div>
-
-<div style='display:block; margin:1em 0'>Language: English</div>
-
-<div style='display:block; margin:1em 0'>Character set encoding: UTF-8</div>
-
-<div style='display:block; margin-left:2em; text-indent:-2em'>Produced by: Turgut Dincer, Les Galloway and the Online Distributed Proofreading Team at https://www.pgdp.net</div>
-
-<div style='margin-top:2em; margin-bottom:4em'>*** START OF THE PROJECT GUTENBERG EBOOK LIFE AND DEATH ***</div>
-<div class="transnote">
-
-<h3>Transcriber’s Notes</h3>
-
-<p>Obvious typographical errors have been silently corrected. Variations
-in hyphenation and accents have been standardised but all other
-spelling and punctuation remains unchanged.</p>
-
-<p>In the section on The Instinct of Life, fifth paragraph “and <a href="#Flourens_has_reduced">Flourens
-has reduced</a> the ratio to that of 5:1, which would still give us 120
-years.” the 120 has been corrected to 100.</p>
-
-<p>In Book V, Chapter III, Chemical Changes, “and at the same time would
-transform an amido-group into an amido-group.” is as printed.</p>
-</div>
-
-<p class="half-title">LIFE AND DEATH.</p>
-<div class="chapter"></div>
-
-
-
-
-<h1>
-LIFE AND DEATH</h1>
-
-<p class="center spaced"><small>BY</small><br />
-
-A. DASTRE,<br />
-<span class="fs1">PROFESSOR OF PHYSIOLOGY AT THE SORBONNE.</span></p>
-
-<p class="center spaced"><small>TRANSLATED BY</small><br />
-W. J. GREENSTREET, M.A., F.R.A.S.</p>
-
-<p class="center spaced">
-THE WALTER SCOTT PUBLISHING CO., LTD.,<br />
-<small>PATERNOSTER SQUARE, LONDON, E.C.</small><br />
-CHARLES SCRIBNER’S SONS,<br />
-<small>153-157 FIFTH AVENUE, NEW YORK.<br />
-1911</small><br />
-</p>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak" id="PREFACE">PREFACE.</h2>
-</div>
-
-
-<p>The educated and inquiring public of the present
-day addresses to the experts who have specialized
-in every imaginable subject the question that was
-asked in olden times of Euclid by King Ptolemy
-Philadelphus, Protector of Letters. Recoiling in
-dismay from the difficulties presented by the study
-of mathematics and annoyed at his slow progress, he
-inquired of the celebrated geometer if there was
-not some royal road, could he not learn geometry
-more easily than by studying the Elements. The
-learned Greek replied, “There is no royal road.”
-These royal roads making every branch of science
-accessible to the cultivated mind did not exist in
-the days of Ptolemy and Euclid. But they do
-exist to-day. These roads form what we call
-Scientific Philosophy.</p>
-
-<p>Scientific philosophy opens a path through the
-hitherto inextricable medley of natural phenomena.
-It throws light on facts, it lays bare principles, it
-replaces contingent details by essential facts. And
-thus it makes science accessible and communicable.
-Intellectually it performs a very lofty function.</p>
-
-<p>There is virtually a philosophy of every science.<span class="pagenum" id="Page_vi">[Pg vi]</span>
-There is therefore a philosophy of the science which
-deals with the phenomena of life and death—<i>i.e.</i>, of
-physiology. I have endeavoured to give a summary
-of this philosophy in this volume. I have had in
-view two classes of readers. In the first place there
-are readers of general culture who are desirous of
-knowing something of the trend of ideas in biology.
-They already form quite a large section of the great
-public.</p>
-
-<p>These scholars and inquirers, with Bacon, believe
-that the only science is general science. What they
-want to know is not what instruments we use, our
-processes, our technique, and the thousand and one
-details of the experiments on which we spend our
-lives in the laboratory. What they are interested in
-are the general truths we have acquired, the problems
-we are trying to solve, the principles of
-our methods, the progress of our science in the
-past, its state in the present, its probable course in
-the future.</p>
-
-<p>But I venture to think that this book is also
-addressed to another class of readers, to those whose
-professional study is physiology. To them it is
-dedicated. They have been initiated into the
-mysteries of the science. They are learning it by
-practice. That is the right method. Practice makes
-perfect. Claude Bernard used to say that in order
-to be an expert in experimental science you must
-first be “a laboratory rat.” And among us there are
-many such “laboratory rats.” They are guided in<span class="pagenum" id="Page_vii">[Pg vii]</span>
-the daily task of investigation by a dim instinct
-of the path and of the direction of contemporary
-physiology. Perhaps it may be of assistance to
-them to find their more or less unconscious ideas
-here expressed in an explicit form.</p>
-
-<p class="psig">
-A. DASTRE.
-</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_ix">[Pg ix]</span></p>
-
-<h2 class="nobreak" id="CONTENTS">CONTENTS.</h2>
-</div>
-
-
-<table class="standard" summary="">
-<tr class="trbig">
-<td class="tdc" colspan="3"><a href="#BOOK_I">BOOK I</a>.</td>
-</tr>
-<tr>
-<td class="tdh" colspan="3"><span class="smcap">The Frontiers of Science. General Theories of
-Life and Death. Their Successive Transformations.</span></td>
-</tr>
-<tr>
-<td class="tdl"><span class="fs2">CHAP.</span></td>
-<td></td>
-<td class="tdr"><span class="fs2">PAGE</span></td>
-</tr>
-<tr>
-<td class="tdlt">I.</td>
-<td class="tdh"><span class="smcap">Early Theories</span></td>
-<td class="tdrb"><a href="#Page_1">1</a></td>
-</tr>
-<tr>
-<td class="tdlt">II.</td>
-<td class="tdh"><span class="smcap">Animism</span></td>
-<td class="tdrb"><a href="#Page_5">5</a></td>
-</tr>
-<tr>
-<td class="tdlt">III.</td>
-<td class="tdh"><span class="smcap">Vitalism</span></td>
-<td class="tdrb"><a href="#Page_15">15</a></td>
-</tr>
-<tr>
-<td class="tdlt">IV.</td>
-<td class="tdh"><span class="smcap">The Monistic Theory</span></td>
-<td class="tdrb"><a href="#Page_34">34</a></td>
-</tr>
-<tr>
-<td class="tdlt">V.</td>
-<td class="tdh"><span class="smcap">The Emancipation of Scientific Research from
-the Yoke of Philosophical Doctrine</span></td>
-<td class="tdrb"><a href="#Page_42">42</a></td>
-</tr>
-<tr class="trbig">
-<td class="tdc" colspan="3"><a href="#BOOK_II">BOOK II</a>.</td>
-</tr>
-<tr>
-<td class="tdh" colspan="3"><span class="smcap">The Doctrine of Energy and the Living World.
-General Ideas of Life. Alimentary Life.</span></td>
-</tr>
-<tr>
-<td class="tdlt">I.</td>
-<td class="tdh"><span class="smcap">Energy in General</span></td>
-<td class="tdrb"><a href="#Page_57">57</a></td>
-</tr>
-<tr>
-<td class="tdlt">II.</td>
-<td class="tdh"><span class="smcap">Energy in Biology</span></td>
-<td class="tdrb"><a href="#Page_97">97</a></td>
-</tr>
-<tr>
-<td class="tdlt">III.</td>
-<td class="tdh"><span class="smcap">Alimentary Energetics</span></td>
-<td class="tdrb"><a href="#Page_116">116</a></td>
-</tr>
-<tr>
-<td class="tdc" colspan="3"><a href="#BOOK_III">BOOK III</a>.</td>
-</tr>
-<tr>
-<td class="tdc" colspan="3"><span class="smcap">The Characters Common to Living Beings.</span></td>
-</tr>
-<tr>
-<td class="tdlt">I.</td>
-<td class="tdh"><span class="smcap">Doctrine of Vital Unity</span></td>
-<td class="tdrb"><a href="#Page_146">146</a></td>
-</tr>
-<tr>
-<td class="tdlt">II.</td>
-<td class="tdh"><span class="smcap">Morphological Unity of Living Beings</span></td>
-<td class="tdrb"><a href="#Page_157">157</a></td>
-</tr>
-<tr>
-<td class="tdlt">III.</td>
-<td class="tdh"><span class="smcap">Chemical Unity of Living Beings</span></td>
-<td class="tdrb"><a href="#Page_173">173</a></td>
-</tr>
-<tr>
-<td class="tdlt">IV.</td>
-<td class="tdh"><span class="smcap">Twofold Conditions of Vital Phenomena.
-Irritability</span></td>
-<td class="tdrb"><a href="#Page_188">188</a>
-<span class="pagenum" id="Page_x">[Pg x]</span></td>
-</tr>
-<tr>
-<td class="tdlt">V.</td>
-<td class="tdh"><span class="smcap">The Specific Form: its Acquisition, its Reparation</span></td>
-<td class="tdrb"><a href="#Page_199">199</a></td>
-</tr>
-<tr>
-<td class="tdlt">VI.</td>
-<td class="tdh"><span class="smcap">Nutrition. Functional Assimilation. Functional
-Distribution. Assimilating Synthesis</span></td>
-<td class="tdrb"><a href="#Page_209">209</a></td>
-</tr>
-<tr class="trbig">
-<td class="tdc" colspan="3"><a href="#BOOK_IV">BOOK IV</a>.</td>
-</tr>
-<tr>
-<td class="tdc" colspan="3"><span class="smcap">The Life of Matter.</span></td>
-</tr>
-<tr>
-<td class="tdlt">I.</td>
-<td class="tdh"><span class="smcap">Universal Life (Opinions of the Philosophers
-and Poets). Continuity between Brute Bodies and Living Bodies. Origin of the Principle of
-Continuity</span></td>
-<td class="tdrb"><a href="#Page_239">239</a></td>
-</tr>
-<tr>
-<td class="tdlt">II.</td>
-<td class="tdh"><span class="smcap">Origin of Living Matter in Brute Matter</span></td>
-<td class="tdrb"><a href="#Page_249">249</a></td>
-</tr>
-<tr>
-<td class="tdlt">III.</td>
-<td class="tdh"><span class="smcap">Organization and Chemical Composition of Living
-Matter and Brute Matter</span></td>
-<td class="tdrb"><a href="#Page_255">255</a></td>
-</tr>
-<tr>
-<td class="tdlt">IV.</td>
-<td class="tdh"><span class="smcap">Evolution and Mutability of Living Matter and
-Brute Matter</span></td>
-<td class="tdrb"><a href="#Page_259">259</a></td>
-</tr>
-<tr>
-<td class="tdlt">V.</td>
-<td class="tdh"><span class="smcap">The Composition of the Specific Form. Living
-Bodies and Crystals. Cicatrization</span></td>
-<td class="tdrb"><a href="#Page_281">281</a></td>
-</tr>
-<tr>
-<td class="tdlt">VI.</td>
-<td class="tdh"><span class="smcap">Nutrition in the Living Being and in the Crystal</span></td>
-<td class="tdrb"><a href="#Page_290">290</a></td>
-</tr>
-<tr>
-<td class="tdlt">VII.</td>
-<td class="tdh"><span class="smcap">Generation in Brute Bodies and Living Bodies.
-Spontaneous Generation</span></td>
-<td class="tdrb"><a href="#Page_294">294</a></td>
-</tr>
-<tr class="trbig">
-<td class="tdc" colspan="3"><a href="#BOOK_V">BOOK V</a>.</td>
-</tr>
-<tr>
-<td class="tdc" colspan="3"><span class="smcap">Senescence and Death.</span></td>
-</tr>
-<tr>
-<td class="tdlt">I.</td>
-<td class="tdh"><span class="smcap">The Different Points of View from which Death
-may be regarded</span></td>
-<td class="tdrb"><a href="#Page_307">307</a></td>
-</tr>
-<tr>
-<td class="tdlt">II.</td>
-<td class="tdh"><span class="smcap">Constitution of the Organisms. Partial Death.
-Collective Deaths</span></td>
-<td class="tdrb"><a href="#Page_312">312</a></td>
-</tr>
-<tr>
-<td class="tdlt">III.</td>
-<td class="tdh"><span class="smcap">Physical and Chemical Characteristics of
-Cellular Deaths. Necrobiosis</span></td>
-<td class="tdrb"><a href="#Page_321">321</a></td>
-</tr>
-<tr>
-<td class="tdlt">IV.</td>
-<td class="tdh"><span class="smcap">Apparent Perrennity of Complex Individuals</span></td>
-<td class="tdrb"><a href="#Page_330">330</a></td>
-</tr>
-<tr>
-<td class="tdlt">V.</td>
-<td class="tdh"><span class="smcap">Immortality of the Protozoa and of Slightly
-Differentiated Cells</span></td>
-<td class="tdrb"><a href="#Page_334">334</a></td>
-</tr>
-<tr>
-<td class="tdlt">VI.</td>
-<td class="tdh"><span class="smcap">Lethality of the Metazoa and of Differentiated
-Cells</span></td>
-<td class="tdrb"><a href="#Page_340">340</a></td>
-</tr>
-<tr>
-<td class="tdlt">VII.</td>
-<td class="tdh"><span class="smcap">Man. The Instinct of Life and the Instinct of
-Death</span></td>
-<td class="tdrb"><a href="#Page_345">345</a></td>
-</tr>
-<tr>
-<td></td>
-<td class="tdh"><span class="smcap"><a href="#INDEX_OF_AUTHORS">Index</a></span></td>
-<td class="tdrb"><a href="#Page_361">361</a></td>
-</tr>
-</table>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_1">[Pg 1]</span></p>
-
-<p class="half-title">LIFE AND DEATH.</p>
-
-
-<h2 class="nobreak" id="BOOK_I">BOOK I.<br />
-
-
-<span class="hang"><small>THE FRONTIERS OF SCIENCE—GENERAL THEORIES
-OF LIFE AND DEATH—THEIR SUCCESSIVE
-TRANSFORMATIONS.</small></span></h2>
-
-<p class="prel">Chapter I. Early Theories.—II. Animism.—III. Vitalism.—IV.
-Monism.—V. Emancipation of Scientific Research
-from the Yoke of Philosophy.</p>
-</div>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="CHAPTER_I">CHAPTER I.<br />
-
-<small>EARLY THEORIES</small>.</h3>
-</div>
-
-<p class="prel">Animism—Vitalism—The Physico-Chemical Theory—Their
-Survival and Transformations.</p>
-
-
-<p>The fundamental theories of science are but the expression
-of its most general results. What, then, is
-the most general result of the development of
-physiology or biology—that is to say, of that department
-of science which has life as its object? What
-glimpse do we get of the fruit of all our efforts? The
-answer is evidently the response to that essential
-question—What is Life?</p>
-
-<p>There are beings which we call living beings; there
-are bodies which have never been alive—inanimate
-bodies; and there are bodies which are no longer<span class="pagenum" id="Page_2">[Pg 2]</span>
-alive—dead bodies. The fact that we use these terms
-implies the idea of a common attribute, of a <i>quid proprium</i>,
-life, which exists in the first, has never existed
-in the second, and has ceased to exist in the last. Is
-this idea correct? Suppose for a moment that this
-is so, that this implicit supposition has a foundation,
-and that there really is something which corresponds
-to the word “<i>life</i>.” Must we then wait for the last
-days of physiology, and in a measure for its last
-word before we know what is hidden behind this
-word, “life”?</p>
-
-<p>Yes, no doubt positive science should be precluded
-from dealing with questions of this kind, which are
-far too general. It should be limited to the study of
-second causes. But, as a matter of fact, scientific
-men in no age have entirely conformed to this provisional
-or definitive antagonism. As the human
-mind cannot rest satisfied with indefinite attempts, or
-with ignorance pure and simple, it has always asked,
-and even now asks, from the spirit of system the
-solution which science refuses. It appeals to philosophical
-speculation. Now, philosophy, in order to
-explain life and death, offers us hypotheses. It offers
-us the hypotheses of thirty, of a hundred, or two
-thousand years ago. It offers us animism; vitalism
-in its two forms, unitary vitalism or the doctrine of
-vital force, and dismembered vitalism or the doctrine
-of vital properties; and finally, materialism, a
-mechanical theory, unicism or monism,—to give it
-all its names—<i>i.e.</i>, the physico-chemical doctrine of
-life. There are, therefore, at the present day, in
-biology, representatives of these three systems which
-have never agreed on the explanation of vital
-phenomena—namely, animists, vitalists, and monists.<span class="pagenum" id="Page_3">[Pg 3]</span>
-But it is pretty clear that there must have been
-some change between yesterday and to-day. Not
-in vain has general science and biology itself made
-the progress which we know has been made since
-the Renaissance, and especially during the course
-of the nineteenth century. The old theories have
-been compelled to take new shape, such parts as have
-become obsolete have been cut away, another
-language is spoken—in a word, the theories have
-become rejuvenated. The neo-animists of our day,
-Chauffard in 1878, von Bunge in 1889, and more
-recently Rindfleisch, do not hold exactly the same
-views as Aristotle, St. Thomas Aquinas, or Stahl.
-Contemporary neo-vitalists, physiologists like Heidenhain,
-chemists like Armand Gautier, or botanists like
-Reinke do not between 1880 and 1900 hold the same
-views as Paracelsus in the fifteenth century and Van
-Helmont in the seventeenth, as Barthez and Bordeu at
-the end of the eighteenth, or as Cuvier and Bichat at
-the beginning of the nineteenth century. Finally, the
-mechanicians themselves, whether they be disciples
-of Darwin and Haeckel, as most biologists of our
-own time, or disciples of Lavoisier, as most physiologists
-of the present day, have passed far beyond the
-ideas of Descartes. They would reject the coarse
-materialism of the celebrated philosopher. They
-would no longer consider the living organism as a
-machine, composed of nothing but wheels, springs,
-levers, presses, sieves, pipes, and valves; or again
-of matrasses, retorts, or alembics, as the iatro-mechanicians
-and would-be chemists of other days
-believed.</p>
-
-<p>All that is changed, at any rate in form. If we look
-back only thirty or forty years we see that the old<span class="pagenum" id="Page_4">[Pg 4]</span>
-doctrines have undergone more or less profound
-modifications. The changes of form, which have been
-made necessary by the acquisitions of contemporary
-science, enable us to appreciate its progress. They
-enable us to give an account of the progress of
-biology, and for this reason they deserve to be
-examined with some attention. It is into this
-examination that I ask my readers to accompany me.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_5">[Pg 5]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_II">CHAPTER II.<br />
-
-<small>ANIMISM.</small></h3>
-</div>
-
-
-<p class="prel">The Common Characteristic of Animism and Vitalism: the
-Human Statue—Primitive Animism—Stahl’s Animism—First
-Objection with Reference to the Relation between
-Soul and Body—Second Objection: the Unconscious
-Character of Vital Operations—Twofold Modality of the
-Soul—Continuity of the Soul and Life.</p>
-
-
-
-<p>Children are taught that there are three kingdoms
-in Nature—the mineral kingdom and the two living
-kingdoms, animal and vegetable. This is the whole
-of the sensible world. Then above all that is placed
-the world of the soul. School-boys therefore have
-no doubts on the doctrines that we discuss here.
-They have the solution. To them there are three
-distinct spheres, three separate worlds—matter, life,
-and thought.</p>
-
-<p>It is this preconceived idea that we are about to
-examine. Current opinion solves <i>a priori</i> the question
-of the fundamental homogeneity or lack of resemblance
-of these three orders of phenomena—the
-phenomena of inanimate nature, of living nature, and
-of the thinking soul. <i>Animism</i>, <i>vitalism</i>, and <i>monism</i>
-are, in reality, different ways of looking at them.
-They are the different answers to this question:—Are
-vital, psychic, and physico-chemical manifestations
-essentially distinct? Vitalists distinguish be<span class="pagenum" id="Page_6">[Pg 6]</span>tween
-life and thought, animists identify them. In
-the opposite camp mechanicians, materialists, or
-monists make the same mistake as the animists, but
-to that mistake they add another: they assimilate the
-forces at play in animals and plants to the general
-forces of the universe; they confuse all three—soul,
-life, inanimate nature.</p>
-
-<p>These problems belong on many sides to metaphysical
-speculation. They have been discussed by
-philosophers; they have been solved from time immemorial
-in different ways, for reasons and by arguments
-which it is not our purpose to examine here,
-and which, moreover, have not changed. But on
-some sides they belong to science, and must be tested
-in the light of its progress. Cuvier and Bichat, for
-example, considered that the forces in action in
-living beings were not only different from physico-mechanical
-forces, but were utterly opposed to them.
-We now know that this antagonism does not exist.</p>
-
-<p>The preceding doctrines, therefore, depend up to a
-certain point on experiment and observation. They
-are subject to the test of experiment and observation
-in proportion as the latter can give us information on
-the degree of difference or analogy presented by
-psychic, vital, and physico-chemical facts. Now,
-scientific investigations have thrown light on these
-points. There is no doubt that the analogies and
-the resemblances of these three orders of manifestations
-have appeared more and more numerous and
-striking as our knowledge has advanced. Hence it is
-that animism can count to-day but very few advocates
-in biological science. Vitalism in its different forms
-counts more supporters, but the great majority have
-adopted the physico-chemical theory.</p>
-
-<p><span class="pagenum" id="Page_7">[Pg 7]</span></p>
-
-<p>Both animism and vitalism separate from matter a
-directing principle which guides it. At bottom they
-are mythological theories somewhat similar to the
-paganism of old. The fable of Prometheus or the
-story of Pygmalion contains all that is essential.
-An immaterial principle, divine, stolen by the
-Titan from Jupiter, or obtained from Venus by the
-Cypriot sculptor, descends from Olympus and
-animates the form, till then inert, which has been
-carved in the marble or modelled in the clay. In a
-word, there is a human statue. It receives a breath
-of heavenly fire, a vital force, a divine spark, a soul,
-and behold! it is alive. But this breath can also
-leave it. An accident happens, a clot in a vein, a
-grain of lead in the brain—the life escapes, and all
-that is left is a corpse. A single instant has proved
-sufficient to destroy its fascination. This is how all
-men picture to their minds the scene of death. The
-breath escapes; something flies away, or flows away
-with the blood. The happy genius of the Greeks
-conceived a graceful image of this, for they represented
-the life or the soul in the form of a butterfly
-(Psyche) leaving the body, an ethereal butterfly,
-as it were, opening its sapphire wings.</p>
-
-<p>But what is this subtle and transient guest of the
-human statue, this passing stranger which makes of
-the living body an inhabited house? According to
-the animists it is the soul itself, in the sense in
-which the word is understood by philosophers; the
-immortal and reasoning soul. To the vitalists it is
-an inferior, subordinate soul; a soul, as it were, of
-secondary majesty, the vital force, or in a word, life.</p>
-
-<p><i>Primitive Animism.</i>—Animism is the oldest and
-most primitive of the conceptions presented to the<span class="pagenum" id="Page_8">[Pg 8]</span>
-human mind. But in so far as it is a co-ordinated
-doctrine, it is the most recent. In fact it only
-received its definitive expression in the eighteenth
-century, from Stahl, the philosopher-physician and
-chemist.</p>
-
-<p>According to Tylor, one of the first speculations of
-primitive man, of the savage, is as to the difference
-between the living body and the corpse. The former
-is an inhabited house, the latter is empty. To such
-rudimentary intellects the mysterious inhabitant is a
-kind of <i>double</i> or duplicate of the human form. It is
-only revealed by the shadow which follows the body
-when illuminated by the sun, by the image of its
-reflection in the water, by the echo which repeats the
-voice. It is only seen in a dream, and the figures
-which people and animate our dreams are nothing
-but these doubled, impalpable beings. Some savages
-believe that at the moment of death the double, or
-the soul, takes up its residence in another body.
-Sometimes each individual possesses, not one of these
-souls, but several. According to Maspero, the
-Egyptians counted at least five, of which the
-principle, the <i>ka</i> or <i>double</i>, would be the aeriform or
-vaporous image of the living form. Space is peopled
-by souls on their travels, which leave one set of bodies
-to occupy another set. After having been the cause
-of life in the bodies which they animated, they
-react from without on other beings, and are the
-cause of all sorts of unexpected events. They are
-benevolent or malevolent spirits.</p>
-
-<p>Analogy inevitably leads simple minds to extend
-the same ideas to animals and plants; in a word, to
-attribute souls to everything alive, souls more or less
-nomadic, wandering, or interchangeable, as is taught<span class="pagenum" id="Page_9">[Pg 9]</span>
-in the doctrine of metempsychosis. Mons. L. Errera
-points out that this primitive, co-ordinated, hierarchized
-doctrine—meet subject for the poet’s art—is
-the basis of all ancient mythologies.</p>
-
-<p><i>The Animism of Stahl.</i>—Modern animism was
-much more narrow in scope. It was a medical theory—<i>i.e.</i>
-almost exclusive to man. Stahl had adopted it
-in a kind of reaction against the exaggerations of the
-mechanical school of his time. According to him, the
-life of the body is due to the intelligent and reasoning
-soul. It governs the corporeal substance and
-directs it towards an assigned end. The organs are
-its instruments. It acts on them directly, without
-intermediaries. It makes the heart beat, the muscles
-contract, the glands secrete, and all the organs perform
-their functions. Nay more, it is itself the
-architectonic soul, which has constructed and which
-maintains the body which it rules. It is the <i>mens
-agitat molem</i> of Virgil.</p>
-
-<p>It is remarkable that these ideas, so excessively
-and exaggeratedly spiritualistic, should have been
-brought forward by a chemist and a physician, while
-ideas completely opposed to these were admitted by
-philosophers like Descartes and Leibniz, who were
-decided believers in the spirituality of the soul. Stahl
-had been Professor of Medicine at the University of
-Halle, physician to the Duke of Saxe-Weimar, and
-later to the King of Prussia. He left an important
-medical and chemical work, both theoretical and
-practical. He is the author of the celebrated theory
-of phlogiston, which held its ground in chemistry up
-to the time of Lavoisier. He died about 1734.</p>
-
-<p>Animism survived him for some time, maintained
-by the zeal of a few faithful disciples. But after the<span class="pagenum" id="Page_10">[Pg 10]</span>
-witty mockery of Bordeu,<a id="FNanchor_1" href="#Footnote_1" class="fnanchor">[1]</a>
-in 1742, it began to decay.
-We must, however, point out that an attempt to revive
-this theory was made in 1878 by a well-known doctor
-of the last generation, E. Chauffard. While preserving
-the essential features of the theory, this learned
-physician proposed to bring it into harmony with
-modern science, and to free it from all the reproaches
-which had been levelled at it.</p>
-
-<p><i>The Animism of E. Chauffard.</i>—These reproaches
-were numerous. The most serious is of a philosophic
-nature. It rises from the difficulty of conceiving a
-direct and immediate action of the soul, considered as
-a spiritual principle, upon the matter of the body.
-There is such an abyss—hewn by the philosophic
-mind itself—between soul and body, that it is impossible
-to imagine any relation between them. We
-can only get a glimpse of how the soul might become
-an instrument of action.</p>
-
-<p>This was the problem which sorely tried the genius
-of Leibniz. Descartes, in earlier days, attacked it
-vigorously, like an Alexander cutting the Gordian
-knot. He separated the soul from the body, and
-made of the latter a pure machine in the government
-of which the soul had no part. He attributed all the
-known manifestations of vital activity to inanimate
-forces. Leibniz, also, was compelled to reject all
-action, all contact, all direct relation, every real bond
-between soul and body, and to imagine between them
-<span class="pagenum" id="Page_11">[Pg 11]</span>a purely metaphysical relation—pre-established harmony:—“Soul
-and body agree in virtue of this
-harmony, the harmony pre-established since the
-creation, and in no way by a mutual, actual, physical
-influence. Everything that takes place in the soul
-takes place as if there were no body, and so everything
-takes place in the body as if there were no
-soul.” At this point we almost reach a scientific
-materialism. It is easy for the materialist to break
-this frail tie of pre-established harmony which so
-loosely unites body and soul, and to exhibit the
-organism as under the sole control of universal
-mechanics and physics.</p>
-
-<p>Thus the weak point of Stahl’s animism was the
-supposition of a direct action exercised on the organism
-by a distinct, heterogeneous, spiritual principle.</p>
-
-<p>Chauffard has endeavoured to avoid this pitfall. In
-conformity with modern ideas, he has brought together
-what the ancient philosophers and Stahl himself
-separated—the activity of matter and the activity of
-the soul. “Thought, action, function, are embraced
-in an indissoluble union.” This is the classical but
-not very lucid theory which has been so often reproduced—<i>Homo
-factus est anima vivens</i>—which
-Bossuet has expressed in the celebrated formula:
-“Soul and body form a natural whole.”</p>
-
-<p>A second objection raised against animism is that
-the soul acts consciously, with reflection, and with
-volition, and that its essential attributes are not found
-in most physiological phenomena, which, on the contrary
-are automatic, involuntary, and unconscious.
-The contradictory nature of these characteristics has
-obliged vitalists to conceive of a vital principle
-distinct from thought. Chauffard, agreeing here with<span class="pagenum" id="Page_12">[Pg 12]</span>
-Boullieu, Tissot, and Stahl himself, does not accept
-this distinction; he refuses to shatter the unity of the
-vivifying and thinking principle. He prefers to attribute
-to the soul two modes of action: the one
-which is exercised on the acts of thought, and hence
-it proceeds consciously, with reflection, and with
-volition; the other exercising control over the physiological
-phenomena which it governs, “by unconscious
-impressions, and by instinctive determinations, obeying
-primordial laws.” This soul is hardly in keeping with
-his definition of a conscious, reflecting, and voluntary
-principle; it is a new soul, a somatic soul, singularly
-akin to that <i>rachidian soul</i> which, according to
-Pflüger, a well-known German physiologist, resides
-in each segment of the spinal marrow, and is responsible
-for reflex movements.</p>
-
-<p><i>Twofold Modality of the Soul.</i>—This twofold
-modality of the soul, this duality admitted by Stahl
-and his disciples, was repugnant to many thinkers,
-and it is this repugnance that gave rise to the vitalistic
-school. It appeared to them to be a heresy tainted
-by materialism—and so it was. In this lay the
-strength and the weakness of animism. It admits
-of a unique animating principle for all the manifestations
-of the living being, for the higher facts in the
-realm of thought, and for the lower facts connected
-with the body. It throws down the barriers which
-separate them. It fills up the gap between the
-different forms of human activity, and assimilates
-them the one to the other.</p>
-
-<p>Now this is precisely what materialism does. It,
-too, reduces to a single order the psychical and physiological
-phenomena, between which it no longer
-recognizes anything but a difference of degree,<span class="pagenum" id="Page_13">[Pg 13]</span>
-thought being only a maximum of the vital movement,
-or life a minimum of thought. In truth, the
-aims of the two schools are diametrically opposed;
-the one claims to raise corporeal activity to the
-dignity of thinking activity, and to spiritualize the
-vital fact; the other lowers the former to the level of
-the latter and materializes the psychic fact. But,
-though the intentions are different, the result is
-identical. Spiritualistic monism inclines towards
-materialistic monism. One step more, and the soul,
-confused with life, will be confused with physical
-forces.</p>
-
-<p>On the other hand, twofold modality has this
-advantage, that it escapes the objection drawn from
-the existence of so many living beings to which a
-thinking soul cannot be attributed; an anencephalous
-fœtus, the young of the higher animals, the lower
-animals and plants, living without thought, or with a
-minimum of real, conscious thought. The advocate
-of animism replies that this physiological activity is
-still a soul, but one which is barely aware of its
-existence—a gleam of consciousness. In this theory,
-the knowledge of self, the consciousness, is of all
-degrees. On the other hand, in the eyes of the
-vitalist, it is an absolute fact which allows of no
-attenuation, of no middle course between the being
-and the non-being.</p>
-
-<p>It is this conception of the continuity of the soul and
-life, it is the affirmation of a possible lowering of the
-complete consciousness down to a mere gleam of knowledge,
-and finally down to unconscious vital activity,
-which saved animism from complete shipwreck. That
-is why this ancient doctrine finds, even in the present
-day, a few rare supporters. An able German scientist,<span class="pagenum" id="Page_14">[Pg 14]</span>
-G. von Bunge, well known for his researches in physiological
-chemistry, professes animistic views in a work
-which appeared in 1889. He attributes to organized
-beings a guiding principle, a kind of vital soul. A
-distinguished naturalist, Rindfleisch, of Lübeck, has
-likewise taken his place among the advocates of what
-we may call neo-animism.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_15">[Pg 15]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_III">CHAPTER III.<br />
-
-
-<small>VITALISM.</small></h3>
-</div>
-
-
-<p class="prel">Its Extreme Forms—Early Vitalism, and Modern Neo-vitalism—Advantage
-of distinguishing between Soul and Life—§
-1. <i>The Vitalism of Barthez</i>—Its Extension—The Seat of
-the Vital Principle—The Vital Knot—The Vital Tripod—Decentralisation
-of the Vital Principle—§ 2. <i>The Doctrine
-of Vital Properties</i>—Galen, Van Helmont, Xavier Bichat,
-and Cuvier—Vital and Physical Properties antagonistic—§
-3. <i>Scientific Neo-vitalism</i>—Heidenhain—§ 4. <i>Philosophical
-Neo-vitalism</i>—Reinke.</p>
-
-
-
-<p><i>Extreme Forms: Early Vitalism and Modern Neo-vitalism.</i>—Contemporary
-neo-vitalism has weakened
-primitive vitalism in some important points. The
-latter made of the vital fact something quite specific,
-irreducible either to the phenomena of general physics
-or to those of thought. It absolutely isolated life,
-separating it above from the soul, and below from inanimate
-matter. This sequestration is nowadays
-much less rigorous. On the psychical side the barrier
-remains, but it is lowered on the material side. The
-neo-vitalists of to-day recognize that the laws of
-physics and chemistry are observed within, as well as
-without, the living body; the same natural forces
-intervene in both, only they are “otherwise directed.”</p>
-
-<p>The vital principle of early times was a kind of
-anthromorphic, pagan divinity. To Aristotle, this
-force, the <i>anima</i>, <i>the Psyche</i>, worked, so to speak, with<span class="pagenum" id="Page_16">[Pg 16]</span>
-human hands. According to the well-known expression,
-its situation in the human body corresponds
-to that of a pilot on a vessel, or to that of a sculptor
-or his assistant before the marble or clay. And, in
-fact, we have no other clear image of a cause external
-to the object. We have no other representation of a
-force external to matter than that which is offered by
-the craftsman making an object, or in general by the
-human being with his activity, free, or supposed to be
-free, and directed towards an end to be realized.</p>
-
-<p>Personifications of this kind, the mythological
-entities, the imaginary beings, the ontological fictions,
-which ever filled the stage in the mind of our predecessors,
-have definitely disappeared; no longer have
-they a place in the scientific explanations of our time.
-The neo-vitalists replace them by <i>the idea of direction</i>,
-which is another form of the same idea of finality.
-The series of second causes in the living being seems
-to be regulated in conformity with a plan, and directed
-with a view to carrying it out. The tendency which
-exists in every being to carry out this plan,—that is to
-say, the tendency towards its end,—gives the impulse
-that is necessary to carry it out. Neo-vitalists claim
-that vital force directs the phenomena which it does not
-produce, and which are in reality carried out by the
-general forces of physics and chemistry.</p>
-
-<p>Thus, the directing impulse, <i>considered as really
-active</i>, is the last concession of modern vitalism. If
-we go further, and if we refuse to the directing idea
-executive power and efficient activity, the vital
-principle is weakened, and we abandon the doctrine.
-We can no longer invoke it. We cease to be vitalists
-if the part played by the vital principle is thus far
-restricted. At first it was both the author of the<span class="pagenum" id="Page_17">[Pg 17]</span>
-plan and the universal architect of the organic edifice;
-it is now only the architect directing his workmen,
-and they are physical and chemical agents. It is now
-reduced to the plan of the work, and even this plan
-has no objective existence; it is now only an <i>idea</i>.
-It has only a shadow of reality. To this it has been
-reduced by certain biologists. For this we may thank
-Claude Bernard; and he has thereby placed himself
-outside and beyond the weakest form of vitalism. He
-did not consider the <i>idea of direction</i> as a real
-principle. The connection of phenomena, their
-harmony, their conformity to a plan grasped by the
-intellect, their fitness for a purpose known to the
-intellect, are to him but a mental necessity, a metaphysical
-concept. The plan which is carried out has
-only a subjective existence; the directing force has no
-efficient virtue, no executive power; it does not
-emerge from the intellectual domain in which it took
-its rise, and does not “react on the phenomena which
-enabled the mind to create it.”</p>
-
-<p>It is between these two extreme incarnations of the
-vital principle, on the one hand an executive agent, on
-the other a simple directing plan, that the motley procession
-of vitalist doctrines passes on its way. At the
-point of departure we have a vital force, personified,
-acting, as we have stated, as if with human hands
-fashioning obedient matter; this is the pure and
-primitive form of the theory. At the other extreme we
-have a vital force which is now only a directing idea,
-without objective existence, and without an executive
-rôle; a mere concept by which the mind gathers
-together and conceives of a succession of physico-chemical
-phenomena. On this side we are brought
-into touch with monism.</p>
-
-<p><span class="pagenum" id="Page_18">[Pg 18]</span></p>
-
-<p><i>The Reasons given by the Vitalists for distinguishing
-Soul from Life.</i>—It is, in particular, on the opposite
-side, in the psychical world, that the early vitalists professed
-to entrench themselves. We have just seen that
-their doctrines were not so subtle as those of to-day;
-the vital principle to them was a real agent, and not an
-ideal plan in the process of being carried out. But
-they distinguished this spiritual principle from another
-co-existent with it in superior living beings—at any
-rate, in man: the thinking soul. They boldly distinguished
-between them, because the activity of the
-one is manifested by knowledge and volition, while
-on the contrary, the manifestations of the other for
-the most part escape both consciousness and volition.</p>
-
-<p>In fact, we know nothing of what goes on in the
-normal state of our organs. Their perfect performance
-of their functions is translated to us solely by an
-obscure feeling of comfort. We do not feel the beating
-of the heart, the periodic dilations of the arteries,
-the movements of the lungs or intestine, the glands at
-their work of secretion, or the thousand reflex manifestations
-of our nervous system. The soul, which is
-conscious of itself, is nevertheless ignorant of all this
-vital movement, and is therefore external to it.</p>
-
-<p>This is the view of all the philosophers of antiquity.
-Pythagoras distinguished the real soul, the thinking
-soul, the <i>Nous</i>, the intelligent and immortal principle,
-characterized by the attributes of consciousness and
-volition, from the vital principle, the <i>Psyche</i>, which
-gives breath and animation to the body, and which is
-a soul of secondary majesty, active, transient, and
-mortal. Aristotle did the same. On the one side he
-placed the soul properly so called, the <i>Nous</i> or
-intellect—that is to say, the understanding with its<span class="pagenum" id="Page_19">[Pg 19]</span>
-rational intelligence; on the other side was the
-directing principle of life, the irrational and vegetative
-Psyche.</p>
-
-<p>This distinction agrees with the fact of the diffusion
-of life. Life does not belong to the superior animals
-alone, and to the man in whom we can recognize a
-reasoning soul. It is extended to the vast multitude
-of humbler beings to which such lofty faculties cannot
-be attributed, the invertebrates, microscopic animals,
-and plants. The advantage is compensated for by
-the inconvenience of breaking down all continuity
-between the soul and life; a continuity which is the
-principle of the two other doctrines, animism and
-monism, and which is, we may say, the very aim and
-the unquestionable tendency of science.</p>
-
-<p>As for classical philosophy, it satisfies the necessity
-of establishing the unity of the living being,—<i>i.e.</i>, of
-bringing into harmony soul and body,—but in a
-manner which we need not here discuss. It attributes
-to the soul several modalities, several distinct
-powers: powers of the vegetative life, powers of the
-sensitive life, and powers of the intellectual life. And
-this other solution of the problem would be, in the
-opinion of M. Gardair, in complete agreement with
-the doctrines of St. Thomas Aquinas.</p>
-
-
-<h4>§ 1. <span class="smcap">The Vitalism of Barthez: its Extension.</span></h4>
-
-<p>Vitalism reached its most perfect expression in the
-second half of the eighteenth century in the hands of
-the representatives of the Montpellier school—Bordeu,
-Grimaud, and Barthez. The last, in particular,
-contributed to the prevalence of the doctrine in<span class="pagenum" id="Page_20">[Pg 20]</span>
-medical circles. A man of profound erudition, a
-collaborates with d’Alembert in the <i>Encyclopædia</i>,
-he exercised quite a preponderant influence on the
-medicine of his day. Stationed at Paris during part
-of his career, physician to the King and the Duke of
-Orleans, we may say that he supported his theories by
-every imaginable influence which might contribute to
-their success. In consequence of this, the medical
-schools taught that vital phenomena are the immediate
-effects of a force which has no analogues outside the
-living body. This conception reigned unchallenged
-up to the days of Bichat.</p>
-
-<p>After Bichat, the vitalism of Barthez, more or less
-modified by the ideas of the celebrated anatomist,
-continued to hold its own in all the schools of
-Europe until about the middle of the nineteenth
-century. Johannes Müller, the founder of physiology
-in Germany, admitted, about 1833, the existence of a
-unique vital force “aware of all the secrets of the
-forces of physics and chemistry, but continually in
-conflict with them, as the supreme cause and regulator
-of all phenomena.” When death came, this principle
-disappeared and left no trace behind. One of the
-founders of biological chemistry, Justus Liebig, who
-died in 1873, shared these ideas. The celebrated
-botanist, Candolle, who lived up to 1893, taught at
-the beginning of his career that the vital force was one
-of the four forces ruling in nature, the other three
-being—attraction, affinity, and intellectual force.
-Flourens, in France, made the vital principle one of
-the five properties of forces residing in the nervous
-system. Another contemporary, Dressel, in 1883,
-endeavoured to bring back into fashion this rather
-primitive, monistic, and efficient vitalism.</p>
-
-<p><span class="pagenum" id="Page_21">[Pg 21]</span></p>
-
-<p><i>The Seat of the Vital Principle.</i>—Meanwhile,
-another question was asked with reference to this
-vital principle. It was a question of ascertaining its
-seat: or, in other words, of finding its place in the
-organism. Is it spread throughout the organism, or is
-it situated in some particular spot from which it acts
-upon every part of the body? Van Helmont, a celebrated
-scientist at the end of the sixteenth century,
-who was both physician and alchemist, gave the first
-and rather quaint solution of this difficulty. The vital
-principle, according to him, was situated in the
-stomach, or rather in the opening of the pylorus. It
-was the <i>concierge</i>, so to speak, of the stomach. The
-Hebrew idea was more reasonable. The life was
-connected with the blood, and was circulated with it
-by means of all the veins of the organism. It escaped
-from a wound at the same time as the liquid blood.
-It is clear that in this belief we see why the Jews were
-forbidden to eat meat which had not been bled.</p>
-
-<p><i>The Vital Knot.</i>—In 1748 a doctor named Lorry
-found that a very small wound in a certain region of
-the spinal marrow brought on sudden death. The
-position of this remarkable point was ascertained in
-1812 by Legallois, and more accurately still by
-Flourens in 1827. It is situated in the rachidian
-bulb, at the level of the junction of the neck and the
-head; or more precisely, on the floor of the fourth
-ventricle, near the origin of the eighth pair of cranial
-nerves. This is what was called the <i>vital knot</i>.
-Upon the integrity of this spot, which is no bigger
-than the head of a pin, depends the life of the animal.
-Those who believed in a localisation of the vital
-principle thought that they had found the seat
-desired; but for that to be so the destruction of this<span class="pagenum" id="Page_22">[Pg 22]</span>
-spot must be irremediable, and must necessarily cause
-death. But if the <i>vital knot</i> be destroyed, and
-respiration be artificially induced by means of a
-bellows, the animal resists: it continues to live. It is
-only the nervous stimulating mechanism of the
-respiratory movements which has been attacked in
-one of its essential parts.</p>
-
-<p>Life, therefore, resides no more in this point than it
-does in the blood or in the stomach. Later experiment
-has shown that it resides everywhere, that each
-organ enjoys an independent life. Each part of the
-body is, to use Bordeu’s strong expression, “<i>an animal
-in an animal</i>”; or to adopt the phrase due to Bichat,
-“<i>a particular machine within the general machine</i>.”</p>
-
-<p><i>The Vital Tripod.</i>—What then is life, or, in other
-words, what is the biological activity of the individual,
-of the animal, of man? It is clearly the sum total, or
-rather, the harmony of these partial lives of the
-different organs. But in this harmony it seems that
-there are certain instruments which dominate and
-sustain the others. There are some whose integrity
-is more necessary to the preservation of existence and
-health, and of which any lesion makes death more
-inevitable. They are the lungs, the heart, and the
-brain. Death always ensues, said the early doctors, if
-any one of these three organs be injured. Life
-depends, therefore, on them, as if upon a three-legged
-support. Hence the idea of the <i>vital tripod</i>. It is no
-longer a single seat for the vital principle, but a kind
-of throne on three-supports. Life is decentralized.</p>
-
-<p>This was only the first step, very soon followed by
-many others, in the direction of vital decentralization.
-Experiment showed, in fact, that every organ separated
-from the body will continue to live if provided with<span class="pagenum" id="Page_23">[Pg 23]</span>
-the proper conditions. And here, it is not only a
-question of inferior beings; of plants that are propagated
-by slips; of the <i>hydra</i> which Trembley cut
-into pieces, each of which generated a complete hydra;
-of the <i>naïs</i> which C. Bonnet cut up into sections, each
-of which reconstituted a complete annelid. There is
-no exception to the rule.</p>
-
-<p><i>Decentralization of the Vital Principle.</i>—The result
-is the same in the higher vertebrates, only the experiment
-is much more difficult. At the Physiological
-Congress of Turin in 1901, Locke showed the heart of
-a hare, extracted from the body of the animal, and
-beating for hours as energetically and as regularly as
-if it were in its place. He suspended it in the air of
-a room at the normal temperature, the sole condition
-being that it was irrigated with a liquid composed of
-certain constituents. The animal had been dead some
-time. More recently Kuliabko has shown in the same
-way the heart of a man still beating, although the
-man had been dead some eighteen hours. The same
-experiment is repeated in any physiological laboratory,
-in a much easier manner, with the heart of a
-tortoise. This organ, extracted from the body, fitted
-up with rubber tubes to represent its arteries and
-veins, and filled with the defibrinated blood of a horse
-or an ox taken from the slaughter-house, works for
-hours and days pumping the liquid blood into its
-rubber aorta, just as if it were pumping it into the
-living aorta.</p>
-
-<p>But it is unnecessary to multiply examples. Every
-organ can be made to live for a longer or shorter
-period even though removed from its natural position;
-muscles, nerves, glands, and even the brain itself.
-Each organ, each tissue therefore enjoys an inde<span class="pagenum" id="Page_24">[Pg 24]</span>pendent
-existence; it lives and works for itself.
-No doubt it shares in the activity of the whole, but
-it may be separated therefrom without being thereby
-placed in the category of dead substances. For each
-aliquot part of the organism there is a partial life and
-a partial death.</p>
-
-<p>This decentralization of the vital activity is finally
-extended in complex beings from the organs to the
-tissues, and from the tissues to the anatomical
-elements—the cells. The idea of decentralization
-has given birth to the second form of vitalism, a
-softened down and weakened form—namely, pluri-vitalism,
-or the theory of vital properties.</p>
-
-
-<h4>§ 2. <span class="smcap">The Theory of Vital Properties.</span></h4>
-
-<p>The advocates of the theory of vital properties have
-cut up into fragments the monistic and indivisible
-guiding principle of Bordeu and Barthez. They have
-given it new currency—pluri-vitalism. This theory
-maintains the existence of spiritual powers of a lower
-order, which control phenomena more intimately than
-the vital principle did. These powers, less lofty in
-their dignity than the rational soul of the animists, or
-the soul of secondary majesty of the unitarian
-vitalists, are eventually incorporated in the living
-matter of which they will then be no longer more
-than the properties. Brought into closer connection
-therefore with the sensible world, they will be more
-in harmony with the spirit of research and with
-scientific progress.</p>
-
-<p>The defect of the earlier conceptions, their common
-illusion, rose from their seeking the cause outside the<span class="pagenum" id="Page_25">[Pg 25]</span>
-object, from their demanding an explanation of vital
-phenomena from a principle external to living,
-immaterial, and unsubstantial matter. Here this
-defect is less marked. The pluri-vitalists will in turn
-appeal to the vital properties as modes of activity,
-inherent in the living substance in which and by which
-they are manifested, and derived from the arrangement
-of the molecules of this substance—that is to say, from
-its organization. This is almost the conception of
-the present day.</p>
-
-<p>But this progress will only be realized at the end of
-the evolution of the pluri-vitalist theory. At the outset
-this theory seems an exaggeration of its predecessor,
-and a still more exaggerated form of the mythological
-paganism with which it was reproached. The archeus,
-the blas, the properties, the spirits—all have at first
-the effect of the genii or of the gods imagined by the
-ancients to preside over natural phenomena, of
-Neptune stirring up the waters of the sea, and of
-Eolus unchaining the winds. These divinities of the
-ancient world, the nymphs, the dryads, and the sylvan
-gods, seem to be transported to the Middle Ages, to
-that age of argument, that philosophical period of the
-history of humanity, and there metamorphosed into
-occult causes, immaterial powers, and personified
-forces.</p>
-
-<p><i>Galen.</i>—The first of the pluri-vitalists was Galen,
-the physician of Marcus Aurelius, the celebrated
-author of an Encyclopædia of which the greater part
-has been lost, and of which the one book preserved
-held its own as the anatomical oracle and breviary
-throughout the Middle Ages. According to Galen
-the human machine is guided by three kinds of
-spirits: <i>animal spirits</i>, presiding over the activity of<span class="pagenum" id="Page_26">[Pg 26]</span>
-the nervous system; <i>vital spirits</i> governing most of
-the other functions; and finally, <i>natural spirits</i>
-regulating the liver and susceptible of incorporation
-in the blood. In the sixteenth century, in the time of
-Paracelsus, Galen’s spirits became <i>Olympic spirits</i>.
-They still presided over the functional activity of the
-organs, the liver, heart, and brain, but they also
-existed in all the bodies of nature.</p>
-
-<p><i>Van Helmont.</i>—Finally, the theory was laid down
-by Van Helmont, physician, chemist, experimentalist,
-and philosopher, endowed with a rare and penetrating
-intellect. Here we find many profound truths combined
-with fantastic dreams. Refusing to admit the
-direct action of an immaterial agent, such as the soul,
-on inert matter, on the body, he filled up the abyss
-which separated them by creating a whole hierarchy
-of immaterial principles which played the part of
-mediators and executive agents. At the head of this
-hierarchy was placed the thinking and immortal soul;
-below was the sensitive and mortal soul, having for its
-minister the <i>principal archeus</i>, the <i>aura vitalis</i>, a kind
-of incorporeal agent, which is remarkably like the
-vital principle, and which had its seat at the orifice of
-the stomach. Below again were the subordinate
-agents, the <i>blas</i>, or <i>vulcans</i> placed in each organ, and
-intelligently directing its mechanism like skillful
-workmen.</p>
-
-<p>These chimerical ideas are not, however, so far
-astray as the theory of vital properties. When we
-see a muscle contract, we say that this phenomenon
-is due to a vital property—<i>i.e.</i>, a property without any
-analogue in the physical world, namely <i>contractility</i>,
-in the same way the nerve possesses two vital
-properties, <i>excitability</i> and <i>conductibility</i>, which Vulpian<span class="pagenum" id="Page_27">[Pg 27]</span>
-proposed to blend into one, calling it <i>neurility</i>. These
-are mere names, serving as a kind of shorthand; but
-to those who believe that there is something real in it,
-this something is not very far from the <i>blas</i> of Van
-Helmont. <i>Vulcans</i>, hidden in the muscle or the nerve,
-are here detected by attraction, there by the production
-and the propagation of the nervous influx;
-that is to say, by phenomena of which we as yet
-know no analogues in the physical world, but of
-which we cannot say that they do not exist.</p>
-
-<p><i>X. Bichat and G. Cuvier: Vital and Physical
-Properties Antagonistic.</i>—The archeus and the blas of
-Van Helmont were but a first rough outline of
-vital properties. Xavier Bichat, the founder of general
-anatomy, wearied of all these incorporeal entities, of
-these unsubstantial principles with which biology was
-encumbered, undertook to get rid of them by the
-methods of the physicist and the chemist. The physics
-and the chemistry of his day referred phenomenal
-manifestations to the properties of matter, gravity,
-capillarity, magnetism, etc. Bichat did the same.
-He referred vital manifestations to the properties of
-living tissues, if not, indeed, of living matter. Of
-these properties as yet but very few were known:
-the irritability described by Glisson, which is the
-excitability of current physiology; and the irritability
-of Haller, which is nothing but muscular contractility.
-Others had to be discovered.</p>
-
-<p>There is no need to recall the mistake made by
-Bichat and followed by most scientific men of his
-time, such as Cuvier in France, and J. Müller in
-Germany, for the story has been told by Claude
-Bernard. His mistake was in considering the vital
-properties not only as distinct from physical properties<span class="pagenum" id="Page_28">[Pg 28]</span>
-but even as opposed to them. The one preserve the
-body, the others tend to destroy it. They are always
-in conflict. Life is the victory of the one; death is
-the triumph of the other. Hence the celebrated
-definition given by Bichat: “Life is the sum total of
-functions which resist death,” or the definition of the
-Encyclopædia: “Life is the contrary of death.”</p>
-
-<p>Cuvier has illustrated this conception by a graphic
-picture. He represents a young woman in all the
-health and strength of youth suddenly stricken by
-death. The sculptural forms collapse and show the
-angularities of the bones; the eyes so lately sparkling
-become dull; the flesh tint gives place to a livid
-pallor; the graceful suppleness of the body is now
-rigidity, “and it will not be long before more horrible
-changes ensue; the flesh becomes blue, green, black,
-one part flows away in putrid poison, and another
-part evaporates in infectious emanations. Finally,
-nothing is left but saline or earthy mineral principles,
-all the rest has vanished.” Now, according to Cuvier,
-what has happened?</p>
-
-<p>These alterations are the effect of external agents,
-air, humidity, and heat. They have acted on the
-corpse just as they used to act on the living being;
-but before death their assault had no effect, because it
-was repelled by the vital properties. Now that life
-has disappeared the assault is successful. We know
-now that external agents are not the cause of these
-disorders. They are caused by the microbes of
-putrefaction. It is against <i>them</i> that the organs were
-struggling, and not against physical forces.</p>
-
-<p>The mistake made by Bichat and Cuvier was inexcusable,
-even in their day. They were wrong not
-to attach the importance they deserved to Lavoisier’s<span class="pagenum" id="Page_29">[Pg 29]</span>
-researches. He had asserted, apropos of animal heat
-and respiration, the identity of the action of physical
-agents in the living body and in the external world.
-On the other hand, Bichat, by a flash of genius, decentralized
-life, dispersing the vital properties in the
-tissues, or, as we should now say, in the living matter.
-It was from the comparison between the constitution
-and the properties of living matter and those of inanimate
-matter that light was to come.</p>
-
-
-<h4>§ 3. <span class="smcap">Scientific Neo-Vitalism.</span></h4>
-
-<p>We can now understand the nature of modern
-neo-vitalism. It borrows from its predecessor its
-fundamental principle—namely, the specificity of the
-<i>vital fact</i>. But this specificity is no longer <i>essential</i>,
-it is only <i>formal</i>. The difference between it and the
-physical fact grows less and almost vanishes. It consists
-of a diversity of mechanisms or executive agents.
-For example, digestion transforms the alimentary
-starch in the intestines into sugar; the chemist does
-the same in his laboratory, only he employs acids,
-while the organism employs special agents, ferments,
-in this case a diastase. It is a particular form of
-chemistry, but still it is a chemistry. That is how
-Claude Bernard looked at it. The vital fact was not
-fundamentally distinguished from the physico-chemical
-fact, but only in form.</p>
-
-<p>This expurgated and accommodated vitalism
-(Claude Bernard pushed his concessions so far as to
-call his doctrine “physico-chemical vitalism”) was revived
-a few years ago by Chr. Bohr and Heidenhain.</p>
-
-<p>Other biologists, instead of attributing the difference<span class="pagenum" id="Page_30">[Pg 30]</span>
-between the phenomena of the two orders to the
-manner of their occurrence, seem to admit the complete
-identity of the mechanisms. It is no longer
-then in itself, individually, that the vital act is
-particularized, but in the manner in which it is
-linked to others. The vital order is a series of
-physico-chemical acts realizing an ideal plan.</p>
-
-<p>Neo-vitalism has therefore assumed two forms,
-one the more scientific and the other the more
-philosophical.</p>
-
-<p><i>Chr. Bohr and Heidenhain.</i>—Its scientific form was
-given to it by Chr. Bohr, an able physiologist at
-Copenhagen, and by Heidenhain, a professor at
-Breslau, who was one of the lights of contemporary
-German physiology. The course of their researches
-led these two experimentalists, working independently,
-to submit to fresh investigation the ideas of
-Lavoisier and those of Bichat, on the relation of
-physico-chemical forces to the vital forces.</p>
-
-<p>It was by no means a question of a general
-inquiry, deliberately instituted with the object of discovering
-the part played respectively by physical and
-physiological factors in the performance of the various
-functions. Such an investigation would have taken
-several generations to complete. No; the question
-had only come up incidentally. Chr. Bohr had studied
-with the utmost care the gaseous exchanges which
-take place between the air and the blood in the lungs.
-The gaseous mixture and the liquid blood are face
-to face; they are separated by thin membrane formed
-of living cells. Will this membrane behave as an
-inert membrane deprived of vitality, and therefore
-obeying the physical laws of the diffusion of gases?
-Well! no. It does not so behave. The most careful<span class="pagenum" id="Page_31">[Pg 31]</span>
-measurements of pressures and of solubilities leave no
-doubt in this respect. The living elements of the
-pulmonary membrane must therefore intervene in
-order to disturb the physical phenomenon. Things
-happen as if the exchanged gases were subjected not
-to a simple diffusion, a physical fact obeying certain
-rules, but to a real secretion, a physiological or vital
-phenomenon, obeying laws which are also fixed, but
-different from the former.</p>
-
-<p>On the other hand, Heidenhain was led about the
-same time to analogous conclusions with respect
-to the liquid exchanges which take place within
-the tissues, between the liquids (lymphs) which
-bathe the blood-vessels externally and the blood
-which those vessels contain. The phenomenon is
-very important because it is the prologue of the
-actions of nutrition and assimilation. Here again,
-the two factors of exchange are brought into relation
-through a thin wall, the wall of the blood-vessel. The
-physical laws of diffusion, of osmosis, and of dialysis,
-enable us to foretell what would take place if the
-vitality of the elements of the wall did not intervene.
-Heidenhain thought he observed that things took
-place otherwise. The passage of the liquids is disturbed
-by the fact that the cellular elements are alive.
-It assumes the characteristics of a physiological act,
-and no longer those of a physical act. Let us add
-that the interpretation of these experiments is difficult,
-and it has given rise to controversies which still
-persist.</p>
-
-<p>These two examples, around which others might be
-grouped, have led certain physiologists to diminish the
-importance of the physical factors in the functional
-activity of the living being to the advantage of the<span class="pagenum" id="Page_32">[Pg 32]</span>
-physiological factors. It would therefore seem that
-the vital force, to use a rather questionable form
-of language, withdraws in a certain measure the
-organized being from the realm of physical forces—and
-this conclusion is one form of contemporary
-neo-vitalism.</p>
-
-
-<h4>§ 4. <span class="smcap">Philosophical Neo-Vitalism.</span></h4>
-
-<p>Contemporary neo-vitalism has assumed another
-form, more philosophical than scientific, by which it is
-brought closer to vitalism, properly so called. We
-should like to mention the experiment of Reinke,<a id="FNanchor_2" href="#Footnote_2" class="fnanchor">[2]</a>
-in Germany. Reinke is a botanist of distinction, who
-distinguishes the speculative from the positive domain
-of science, and cultivates both with success.</p>
-
-<p>His ideas are analogous to those of A. Gautier, of
-Chevreul, and of Claude Bernard himself. He thinks,
-with these masters, that the mystery of life is not to be
-found in the nature of the forces that it brings into
-play, but in the direction that it gives them. All these
-thinkers are struck by the order and the direction
-impressed upon the phenomena which take place
-in the living being, by their interconnection, by their
-apparent adaptation to an end, by the kind of impression
-that they give of a plan which is being
-carried out. All these reflections lead Reinke to
-attach great weight to the idea of a “directing
-force.”</p>
-
-<p>The physico-chemical energies are no doubt the
-only ones which are manifested in the organized
-being, but they are directed as a blind man is by his<span class="pagenum" id="Page_33">[Pg 33]</span>
-guide. It seems as if a <i>double</i> accompanies them like
-a shadow. This intelligent guide of blind, material
-force is what Reinke calls a <i>dominant</i>. Nothing
-could be more like the blas and the archeus of Van
-Helmont. Material energies would thus be paired
-off with their blas, their dominants, in the living
-organisms. In them there would therefore be two categories
-of force: “material forces,” or rather, material
-energies obeying the laws of universal energetics;
-and in the second place, intelligent “spiritual forces,”
-the dominants. When the sculptor is working his
-marble, in every blow which elicits a spark there is
-something more than the strong force of the hammer.
-There is thought, the volition of the artist, which is
-realizing a plan. In a machine there is more than
-machinery. Behind the wheels is the object which
-the author had in view when he adjusted them for a
-determined end. The energies spent in action are
-regulated by the adjustment—that is to say, by the
-dominants due to the intellect of the constructor.</p>
-
-<p>Thus it is in the living machine. The dominants
-in this case are the guardians of the plan, the agents
-of the aim in view. Some regulate the functional
-activity of the living body, and some regulate its
-development and its construction. Such is the second
-form, the philosophical form, extreme and teleological,
-of contemporary neo-vitalism.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_34">[Pg 34]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_IV">CHAPTER IV.<br />
-
-<small>THE MONISTIC THEORY.</small></h3></div>
-
-
-
-<p class="prel">Physico-chemical Theory of Life.—Iatro-mechanism.—Descartes,
-Borelli.—Iatro-chemistry.—Sylvius le Boë.—The
-Physico-chemical Theory of Life.—Matter and Energy.—Heterogeneity
-is merely the result of the arrangement or
-combination of homogeneous bodies.—Reservation relative
-to the world of thought.—The Kinetic Theory.</p>
-
-
-<p>The unicist or monistic doctrine gives us a third way
-of conceiving the functional activity of the living
-being, by levelling and blending its three forms of
-activity—spiritual, vital, and material. It was
-expressed in the seventeenth and eighteenth centuries
-in “iatro-mechanism” and “iatro-chemistry,” conceptions
-to which have more recently succeeded the
-physico-chemical doctrine of life, and finally “current
-materialism.”</p>
-
-<p>Materialism is not only a biological interpretation;
-it is a universal interpretation applicable to the whole
-of nature, because it is based on a determinate conception
-of matter. Here we find ourselves confronted
-by the eternal enigma discussed by philosophers
-relative to this fundamental problem of force and
-matter. We know what answers were given to
-the problem by the Ionic philosophers—Thales,
-Democritus, Heraclitus, and Anaxagoras, who discarded
-the agency of every spiritual power external<span class="pagenum" id="Page_35">[Pg 35]</span>
-to matter. The explanation of the world, the
-explanation of life, were reduced to the play of
-physical or mechanical forces. Epicurus, a little later,
-maintained that the knowledge of matter and its
-different forms accounts for all phenomena, and therefore
-for those of life.</p>
-
-<p>Descartes, sharply separating the metaphysical
-world—that is to say, the soul defined by its attribute,
-thought—from the physical or material world
-characterized by extension, practically came to the
-same conclusions as the materialists of antiquity. To
-him, as to them, the living body was a mere machine.</p>
-
-<p><i>Iatro-mechanism. Descartes. Borelli.</i>—This, then, is
-the theory of the iatro-mechanicians, of which we may
-consider Descartes the founder, instead of the Greek
-philosophers. These ideas held their own for two
-centuries, and were productive of such fruitful results
-in the hands of Borelli, Pitcairn, Hales, Bernoulli, and
-Boerhaave, as to justify the jest of Bacon that “the
-philosophy of Epicurus had done less harm to science
-than that of Plato.” The iatro-mechanic school tenaciously
-held its own until Bichat came upon the scene.</p>
-
-<p><i>Iatro-chemistry. Sylvius le Boë.</i>—It was from a
-reaction against their exaggerations that Stahl
-created animism, and the Montpellier school created
-vitalism. We gather some idea of the extravagant
-character of their explanations by reading Boerhaave.
-To this celebrated doctor the muscles were springs,
-the heart was a pump, the kidneys a sieve, and the
-secretions of the glandular juices were produced by
-pressure; the heat of the body was the result of the
-friction of the globules of blood against the walls of
-the blood-vessels; it was greater in the lungs because
-the vessels of the lungs were supposed to be narrower<span class="pagenum" id="Page_36">[Pg 36]</span>
-than those of other organs. The inadequacy of these
-explanations suggested the idea of completing them
-by the aid of the chemistry which was then springing
-into being. This chemistry, rudimentary as it was,
-longed for a share in the government of living bodies
-and in the explanation of their phenomena. Distillations,
-fermentations, and effervescences are now
-seen to play their rôle, a rôle which was premature
-and carried to excess. Iatro-chemistry from the
-general point of view is only an aspect of iatro-mechanics;
-but it is also an auxiliary. Sylvius le Boë
-and Willis were its most eminent representatives.
-This theory remained in the background until
-chemistry made its great advance—that is to say, in
-the days of Lavoisier. After that, its importance has
-gradually increased, particularly in the present day.
-Nowadays, the general tendency is to regard the
-organic functional activity, or even morphogeny—<i>i.e.</i>,
-whatever there is that is most peculiar to and characteristic
-of living beings—as a consequence of the
-chemical composition of their substance. This is a
-point of capital importance, and to it we must recur.</p>
-
-<p><i>The Physico-chemical Theory of Life.</i>—Contemporary
-biological schools have made many efforts to secure
-themselves from any slips on the philosophical side.
-They have avoided in most cases the psychological
-problem; they have deliberately refrained from
-penetrating into the world of the soul. Hence, <i>the
-physico-chemical theory</i> of life has been built up free
-from spiritualistic difficulties and objections. But
-this prudence did not exclude the tendency. And
-there is no doubt, as Armand Gautier said, that “real
-science can affirm nothing, but it also can deny
-nothing outside observable facts;” and again, that<span class="pagenum" id="Page_37">[Pg 37]</span>
-“only a science progressing backwards can venture to
-assert that matter alone exists, and that its laws alone
-govern the world.” It is none the less true that by
-establishing the continuity between inert matter and
-living matter, we thereby render probable the continuity
-between the world of life and the world of
-thought.</p>
-
-<p><i>Matter and Energy.</i>—Besides, and without any
-wish to enter into this burning controversy, it is
-only too evident that there is no agreement as to the
-terms that are used, and in particular as to “matter”
-and “laws of matter.” It is not necessary to repeat
-that the geometrical mould in which Descartes cast
-his philosophy has long since been broken. The
-celebrated philosopher, in defining matter by one
-attribute—extension, does not enable us to grasp its
-activity, an activity revealed by all natural facts; and
-in defining the soul by thought alone, prevents us
-from seeking in it the principle of this material activity.
-This purely passive matter, consisting of extension
-alone, this <i>bare matter</i> was to Leibniz a pure concept.
-A philosopher of our own time, M. Magy, has called it
-a sensorial illusion. The bodies of nature exhibit to
-us <i>matter clad</i> with energy, formed by the indissoluble
-union of extension with an inseparable dynamical
-principle. The Stoics declared that matter is mobile
-and not immobile, active and not inert. Leibniz also
-had this in his mind when he associated it indissolubly
-with an active principle, an “entelechy.” Others have
-said that matter is “an assemblage of forces,” or with
-P. Boscovitch, “a system of indivisible points without
-extension, centres of force, in fact.” Space would be
-the geometrical locus of these points.</p>
-
-<p>In this conception the materialistic school finds the<span class="pagenum" id="Page_38">[Pg 38]</span>
-explanation of all phenomenality. Physical properties,
-vital phenomena, psychical facts, all have their foundation
-in this immanent activity. Material activity is
-a minimum of soul or thought which, by continuous
-gradation and progressive complexity, without solution
-of continuity, without an abrupt transition from the
-homogeneous to the heterogeneous, rises through the
-series of living beings to the dignity of the human
-soul. The observation of the transitions, an imperfect
-tracing of the geometrical method of limits, thus
-enables us to pass from material to vital, and from
-thence to psychical activity.</p>
-
-<p><i>Apparent Heterogeneity is the Result of the Arrangement
-or the Combination of Homogeneous Bodies.</i>—In
-this system, material energy, life, soul would only be
-more and more complex combinations of the consubstantial
-activity with material atoms. Life appears
-distinct from physical force, and thought from life,
-because the analysis has not yet advanced far enough.
-Thus, glass would appear to the ancient Chaldeans
-distinct from the sand and salt of which they made it.
-In the same way, again, water, to modern eyes, is
-distinct from its constituents, oxygen and hydrogen.
-The whole difficulty is that of explaining what this
-“arrangement” of the elements can introduce that
-is new in the aspect of the compound. We must
-know what novelty and apparent homogeneity the
-variety of the combinations, which are only special
-arrangements of the elementary parts, may produce in
-the phenomena. But we do not know, and it is this
-ignorance which leads us to consider them as heterogeneous,
-irreducible, and distinct in principle. The
-vital phenomenon, the complexus of physico-chemical
-facts, thus appears to us essentially different from<span class="pagenum" id="Page_39">[Pg 39]</span>
-those facts, and that is why we picture to ourselves
-“dominants” and “directing forces” more or less
-analogous to the sidereal guiding principle of Kepler,
-which, before the discovery of universal attraction,
-regulated the harmony of the movements of the
-planets.</p>
-
-<p><i>A Reservation relative to the Psychical Order.</i>—The
-scientific mind has shown in every age a real
-predilection towards the mechanical or materialistic
-theory. Contemporary scientists as a whole have
-accepted it in so far as it blends the vital and the
-physical orders. Objections and contradictions are
-only offered in the realm of psychology. A. Gautier,
-for example, has contested with infinite originality
-and vigour the claims of the materialists who would
-reduce the phenomenon of thought to a material
-phenomenon. The most general characteristic of
-material phenomenality is—as we shall later see—that
-it may be considered as a mutation of energy—<i>i.e.</i>,
-it obeys the laws of energetics. Now thought,
-says A. Gautier, is not a form of material energy.
-Thought, comparison, volition, are not acts of material
-phenomenality; they are states. They are realities;
-they have no mass; they have no physical existence.
-They respond to adjustments, arrangements, and
-concerted groupings of material manifestations of
-chemical molecules. They escape the laws of
-energetics.</p>
-
-<p><i>Kinetic Theory.</i>—We shall lay aside for a moment
-this serious problem relative to the limits of the world
-of conscious thought and of the world of life. It is on
-the other side, on the frontiers of living and inanimate
-nature, that the mechanical view triumphs. It
-has furnished a universal conception agreeing with<span class="pagenum" id="Page_40">[Pg 40]</span>
-phenomena of every kind—viz., the kinetic theory,
-which ascribes everything in nature to the movements
-of particles, molecules, or atoms.</p>
-
-<p>The living and the physical orders are here reduced
-to one unique order, because all the phenomena of the
-sensible universe are themselves reduced to one and
-the same mechanics, and are represented by means of
-the atom and of motion. This conception of the
-world, which was that of the philosophers of the Ionic
-school in the remotest antiquity, which was modified
-later by Descartes and Leibniz, has passed into
-modern science under the name of the kinetic theory.
-The mechanics of atoms ponderable or imponderable,
-would contain the explanation of all phenomenality.
-If it were a question of physical properties or vital
-manifestations, the objective world in final analysis
-would offer us nothing but motion. Every phenomenon
-would be expressed by an atomistic integral,
-and that is the inner reason of the majestic unity
-which reigns in modern physics. The forces which
-are brought into play by Life are no longer to
-be distinguished in this ultimate analysis from
-other natural forces. All are blended in molecular
-mechanics.</p>
-
-<p>The philosophical value of this theory is undeniable.
-It has exercised on physical science an influence which
-is justified by the discoveries which it has suggested.
-But to biology, on the other hand, it has lent no aid.
-It is precisely because it descends too deeply into
-things, and analyzes them to the uttermost, that it
-ceases to throw any light upon them. The distance
-between the hypothetical atom and the apparent and
-concrete fact is too great for the one to be able to
-throw light on the other. The vital phenomenon<span class="pagenum" id="Page_41">[Pg 41]</span>
-vanishes with its individual aspect; its features can
-no longer be distinguished.</p>
-
-<p>Besides, a whole school of contemporary physicists
-(Ostwald of Leipzig, Mach of Vienna) is beginning to
-cast some doubt on the utility of the kinetic hypothesis
-in the future of physics itself, and is inclined to propose
-to substitute for it the theory of energetics. We
-shall see, in every case, that this other conception, as
-universal as the kinetic theory, <i>the theory of Energy</i>,
-causes a vivid light to penetrate into the depths of the
-most difficult problems in physiology.</p>
-
-<p>Such are, with their successive transformations, the
-three principal theories, the three great currents
-between which biology has been tossed to and fro.
-They are sufficiently indicative of the state of positive
-science in each age, but one is astonished that they
-are not more so; and this is due to the fact that these
-conceptions are too general. They soar too high above
-reality. More characteristic in this respect will be
-particular theories of the principal manifestations of
-living matter, of its perpetuity by generation, of the
-development by which it acquires its individual form,
-on heredity. It is here that it is of importance to
-grasp the progressive march of science—that is to say,
-the design and the plan of the building which is being
-erected, “blindly, so to speak,” by the efforts of an
-army of workers, an army becoming more numerous
-day by day.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_42">[Pg 42]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_V">CHAPTER V.<br />
-
-<small>THE EMANCIPATION OF SCIENTIFIC RESEARCH
-FROM THE YOKE OF PHILOSOPHICAL THEORIES.</small></h3></div>
-
-
-<p class="prel">The excessive use of Hypothetical Agents in Physiological
-Explanations—§ 1. <i>Vital Phenomena in Fully-constituted
-Organisms</i>—Provisory Exclusion of the Morphogenic
-idea—The Realm of the Morphogenic Idea as the
-Sanctuary of Vital Force—§ 2. <i>The Physiological Domain
-properly so called</i>—Harmony and Connection of Phenomena—Directive
-Forces—Claude Bernard’s Work—Exclusion
-of Vital Force, of Final Cause, of the “Caprice”
-of Living Nature—Determinism—The Comparative
-Method—Generality of Vital Phenomena—Views of
-Pasteur.</p>
-
-
-
-<p>The theories whose history we have just sketched
-in broad outline long dominated science and exercised
-their influence on its progress.</p>
-
-<p>This domination has ceased to exist. Physiology
-has emancipated itself from their sway, and this,
-perhaps, is the most important revolution in the whole
-history of biology. Animism, vitalism, materialism,
-have ceased to exercise their tyranny on scientific
-research. These conceptions have passed from the
-laboratory to the study; from being physiological,
-they have become philosophical.</p>
-
-<p>This result is the work of the physiologists of sixty
-years ago. It is also the consequence of the general
-march of science and of the progress of the scientific
-spirit, which shows a more and more marked tendency<span class="pagenum" id="Page_43">[Pg 43]</span>
-to separate completely the domain of facts from the
-domain of hypotheses.</p>
-
-<p><i>Excessive Use of Hypothetical Agents in Physiological
-Explanations.</i>—It may be said that in the
-early part of the nineteenth century, in spite of the
-efforts of a few real experimenters from Harvey to
-Spallanzani, Hales, Laplace, Lavoisier, and Magendie,
-the science of the phenomena of life had not followed
-the progress of the other natural sciences. It remained
-in the fog of scholasticism. Hypotheses were mingled
-with facts, and imaginary agents carried out real acts,
-in inexpressible confusion. The soul (<i>animism</i>), the
-vital force (<i>vitalism</i>), and the final cause (<i>finalism</i>,
-<i>teleology</i>) served to explain everything.</p>
-
-<p>In truth, it was also at this time that physical
-agents, electric and magnetic fluids, or, again, chemical
-affinity, played an analogous part in the science of
-inanimate nature. But there was at least this
-difference in favour of physicists and chemists, that
-when they had attributed some new property or
-aptitude to their hypothetical agents they respected
-what they attributed. The physiological physicians
-respected no law, they were subject to no restraint.
-Their vital force was capricious; its spontaneity made
-anticipation impossible; it acted arbitrarily in the
-healthy body; it acted more arbitrarily still in the
-diseased body. All the subtlety of medical genius
-was called into play to divine the fantastic behaviour
-of the spirit of disease. If we speak here of physiologists
-and doctors alone and do not quote biologists,
-it is because the latter had not yet made their
-appearance as authorities; their science had remained
-purely descriptive, and they had not yet begun to
-explain phenomena.</p>
-
-<p><span class="pagenum" id="Page_44">[Pg 44]</span></p>
-
-<p>Such was the state of things during the first years
-of the nineteenth century. It lasted, thanks to the
-founders of contemporary physiology—Claude Bernard
-in France, and Brücke, Dubois-Reymond, Helmholtz,
-and Ludwig in Germany—until a separation took
-place between biological research and philosophical
-theories. This delimitation operated in physiology
-properly so called—<i>i.e.</i> in a branch of the biological
-domain in which as yet joint tenancy had been the
-rule. An important revolution fixed the respective
-divisions of experimental science and philosophical
-interpretation. It was understood that the one ends
-where the other begins, that the one follows the other,
-that one may not cross the other’s path. There is
-between them only one doubtful region about which
-there is dispute, and this uncertain frontier is constantly
-being shifted and science daily gains what
-philosophy loses.</p>
-
-
-<h4>§ 1. <span class="smcap">Vital Phenomena in Constituted
-Organisms.</span></h4>
-
-<p>A displacement of this kind had taken place at the
-time of which we speak. It was agreed, that as far as
-concerns the phenomena which take place in <i>a constructed
-and constituted living organism</i>, it would no
-longer be permissible to allow to intervene in their
-explanation forces or energies other than those
-which are brought into play in inanimate nature.
-Just as when explaining the working of a clock,
-the physicist will not invoke the volition or the art
-of the maker, or the design that he had in view, but
-only the connection of causes and effects which he
-has utilized; so, for the living machine, whether the<span class="pagenum" id="Page_45">[Pg 45]</span>
-most complex, such as the human body, or the most
-elementary, such as the cell, we may not invoke a
-final cause, a vital force, external to that organism
-and acting on it from without, but only the connections
-and the fluctuations of effects which are the
-sole actual and efficient causes. In other words
-Ludwig, and Claude Bernard in particular, expelled
-from the domain of active phenomenality the three
-chimeras—Vital Force, Final Cause, and the “Caprice”
-of Living Nature.</p>
-
-<p>But the living being is not only a <i>completely constructed
-and completely constituted</i> organism. It is not
-a finished clock. It is a clock which is making itself,
-a mechanism which is constructing and perpetuating
-itself. Nothing of the kind is known to us in inanimate
-nature. Physiology has found—in what is
-called morphogeny—its temporary limit. It is beyond
-this limit, it is in the study of phenomena by which
-the organism is constructed and perpetuated, it is in
-the region of the functions of generation and development,
-that philosophical doctrines expand and flourish.
-This is the present frontier of these two powers,
-philosophy and science. We shall presently delimit
-them more precisely. W. Kühne, a well-known
-scientist whose death is deplored, not in Germany
-alone, amused himself by studying the division of
-biological doctrines among the members of learned
-societies and in the world of academies. He
-summed up this kind of statistical inquiry by
-saying in 1898 at the Cambridge Congress, that
-physiologists were nearly all advocates of the physico-chemical
-doctrine of life, and that the majority of
-naturalists were advocates of vital force, and of the
-theory of final causes.</p>
-
-<p><span class="pagenum" id="Page_46">[Pg 46]</span></p>
-
-<p><i>Domain of the Morphogenic Idea as the Last Sanctuary
-of Vital Force.</i>—We see the reason for this.
-Physiology, in fact, has taken up its position in
-the explanation of the functional activity of the
-constituted organism—<i>i.e.</i>, on a ground where
-intervene, as we shall show further on, no energies
-and no matter other than universal energies and
-matter. Naturalists, on the other hand, have more
-especially considered—and from the descriptive point
-of view alone, at least up to the times of Lamarck
-and Darwin—the functions, the generation, the
-development and the evolution of species. Now
-these functions are most refractory and inaccessible
-to physico-chemical explanations. So, when the
-time came to give an account of what they had done,
-the zoologists had substituted for executive agents
-nothing but vital force under its different names.
-To Aristotle it is the vital force itself which, as soon
-as it is introduced into the body of the child, moulds
-its flesh and fashions it in the human form. Contemporary
-naturalists, the Americans C. O. Whitman
-and C. Philpotts, for example, take the same line of
-argument. Others, such as Blumenbach and Needham,
-in the eighteenth century, invoked the same division
-under another name, that of the <i>nisus formativus</i>.
-Finally, others play with words; they talk of heredity,
-of adaptation, of atavism, as if these were real, active,
-and efficient beings; while they are only appellations,
-names applied to collections of facts.</p>
-
-<p>This region was therefore eminently favourable
-to the rapid increase of hypotheses, and so they
-abounded. There were the theories of Buffon, of
-Lamarck, of Darwin, of Herbert Spencer, of E.
-Haeckel, of His, of Weismann, of De Vries, and<span class="pagenum" id="Page_47">[Pg 47]</span>
-of W. Roux. Each biologist of any mark had his own,
-and the list is endless. But here already this domain
-of theoretical speculation is checked on various sides
-by experiment. J. Loeb, a pure physiologist, has
-recently given his researches a direction in which
-zoology believes may be found the explanation of the
-mysterious part played by the male element in
-fecundation. On the other hand, the first experiment
-of the artificial division of the living cell
-(<i>merotomy</i>), with its light upon the part played by
-the nucleus in the preservation and regeneration of
-the living form, is also the work of a physiological
-experimenter. It dates back to 1852, and is due to
-Augustus Waller. This experiment was made on the
-sensitive nervous cell of the spinal ganglions and on
-the motor cell of the anterior cornua of the spinal
-cord. The effects were correctly interpreted twelve
-or fifteen years later. All that zoologists have done
-is to repeat, perhaps unconsciously, this celebrated
-experiment and to confirm the result.</p>
-
-<p>Thus we see that the attack upon the vitalist
-sanctuary has commenced. But it would be a grave
-mistake to suppose that final cause and vital force are
-on the point of being dislodged from their entrenchments.
-Philosophical speculation has an ample field
-before it. Its frontiers may recede. For a long time
-yet there will be room for a more or less modernized
-vitalism.</p>
-
-
-<h4>§ 2. <span class="smcap">The Physiological Domain properly so
-called.</span></h4>
-
-<p>Vitalism is even found installed in the region of
-physiology, although for the moment this science
-limits its ambition to the consideration of the com<span class="pagenum" id="Page_48">[Pg 48]</span>pletely
-constructed organized being, perfected in its
-form. The explanation of the working of this constituted
-machine cannot be complete until we take
-into account the harmony and the adjustment of its
-parts.</p>
-
-<p><i>Harmony and Connection of Parts: Directive Forces.</i>—These
-constituent parts are the cells. We know
-that the progress of anatomy has resulted in the
-cellular doctrine—<i>i.e.</i>, in the two-fold affirmation
-that the most complicated organism is composed of
-microscopic elements, the cells, all similar, true
-stones of the living building, and that it derives its
-origin from a single cell, egg, or spore, the sexual cell,
-or cell of germination. The phenomena of life, looked
-at from the point of view of the formed individual,
-are therefore harmonized in space; just as, regarded
-from the point of view of the individual in formation
-and in the species, they are connected in time. This
-harmony and this connection are in the eyes of the
-majority of men of science the most characteristic properties
-of the living being. This is the domain of <i>vital
-specificity</i>, of the <i>directive forces</i> of Claude Bernard and
-A. Gautier, and of the <i>dominants</i> of Reinke. It is not
-certain, however, that this order of facts is more
-specific than the other. Generation and development
-have been considered by many physiologists, and
-quite recently by Le Dantec, as simple aspects or
-modalities of nutrition or assimilation, the common
-and fundamental property of every living cell.</p>
-
-<p><i>The Work of Claude Bernard. Exclusion of Vital
-Force, of Vital Cause, of the “Caprice” of Living Nature.</i>—It
-is not, however, a slight advance or inconsiderable
-advantage to have eliminated vitalistic hypotheses
-from almost the whole domain of present-day physi<span class="pagenum" id="Page_49">[Pg 49]</span>ology,
-and to have them, as it were, thrown back into
-its hinterland. This is the work of the scientific men
-of the first half of the nineteenth century, and particularly
-of Claude Bernard, who has thereby won
-the name of the founder or lawgiver of physiology.
-They found in the old medical school an obstinate
-adversary glorying in its sterile traditions. In vain
-was it proved that vital force cannot be an efficient
-cause; that it was a creation of the brain, an insubstantial
-phantom introduced into the anatomical
-marionette and moving it by strings at the will of
-any one—its adepts having only to confer upon it a
-new kind of activity to account for the new act. All
-that had been shown with the utmost clearness by
-Bonnet of Geneva, and by many others. It had also
-been said that the teleological explanation is equally
-futile, since it assigns to the present, which exists, an
-inaccessible, and evidently ultimately inadequate cause,
-which does not yet exist. These objections were in
-vain.</p>
-
-<p><i>Determinism.</i>—And so it was not by theoretical
-arguments that the celebrated physiologist dealt with
-his adversaries, but by a kind of lesson on things. In
-fact he was continually showing by examples that
-vitalism and the theory of final causes were idle errors
-which led astray experimental investigation; that
-they had prevented the progress of research and the
-discovery of the truth in every case and on every
-point in which they had been invoked. He laid down
-the principle of <i>biological determinism</i>, which is nothing
-but the negation of the “caprice” of living nature.
-This postulate, so evident that there was no need to
-enunciate it in the physical sciences, had to be shouted
-from the housetops for the benefit of supporters of<span class="pagenum" id="Page_50">[Pg 50]</span>
-vital spontaneity. It is the statement that, under
-determined circumstances materially identical, the
-same vital phenomena will be identically reproduced.</p>
-
-<p><i>Comparative Method.</i>—Claude Bernard completed
-this critical work by laying down the laws of experiment
-on living beings. He commended as the rational
-method of research the <i>comparative method</i>. This
-should be, and is in fact, the daily instrument of all
-those who work in physiology. It compels the
-investigator in every research bearing on organized
-beings to institute a series of tests, such that the
-conditions which are unknown and impossible to
-know may be regarded as identical from one test to
-another; and when we are certain that a single
-condition is variable, it compels him to discover the
-character of the condition we are dealing with, and
-to learn to appreciate, and to measure its influence.
-It is safe to say that the errors which are daily
-committed in biological work have their cause in
-some infraction of this golden rule. In physical
-science the obligation to follow the comparative
-method is much less felt. In most cases the <i>witness
-test</i><a id="FNanchor_3" href="#Footnote_3" class="fnanchor">[3]</a> is useless. In physiology the witness test is
-indispensable.</p>
-<p><span class="pagenum" id="Page_51">[Pg 51]</span></p>
-<p><i>Generality of Vital Phenomena.</i>—If we add that
-Claude Bernard opposed the narrow opinion, so dear
-to early medicine, which limited the consideration of
-vitality to man, and the contrary notion of the essential
-generality of the phenomena of life from man to the
-animal, and from the animal to the plant, we shall
-have given very briefly an idea of the kind of revolution
-which was accomplished about the year 1864, the
-date of the appearance of the celebrated <i>l’Introduction
-à la médecine expérimentale</i>.</p>
-
-<p>The ideas we have just recalled seem to be as
-evident as they are simple. These principles appear
-so well founded that in a measure they form an integral
-part of contemporary mentality. What scientist
-would nowadays deliberately venture to explain some
-biological fact by the intervention of the evidently
-inadequate vital force or final cause? And who, to<span class="pagenum" id="Page_52">[Pg 52]</span>
-account for the apparent inconsistency of the result,
-would bring forward the “caprice” of living nature?
-And who again would openly dispute the utility of
-the comparative method?</p>
-
-<p>What the physiologists of to-day, according to
-Claude Bernard, would no longer do, their predecessors
-would do, and not the least important of
-them. Longet, for example, at a full meeting of the
-Académie, apropos of recurrent sensibility, and Colin
-(of Alfort), communicating his statistical results on
-the temperature of two hearts, accepted more or
-less explicitly the indetermination of vital facts. And
-why confine our remarks to our predecessors? The
-scientists of to-day are much the same. So here
-again we see the reappearance of the phantom of
-the final cause in so-called scientific explanations.
-One fact is accounted for by the necessity of the
-self-defence of the organism; another by the necessity
-to a warm-blooded animal of keeping its temperature
-constant. Le Dantec has recently reproached zoologists
-for giving as an explanation of fecundation
-the advantage that an animal enjoys in having a
-double line of ancestors. We might as well say, as
-L. Errera has pointed out, that the inundations of the
-Nile occur in order to bring fertility to Egypt.</p>
-
-<p>We must not therefore depreciate the marvellous
-work which has emancipated modern physiology from
-the tutelage of early theories. The witnesses of this
-revolution appreciated its importance. One of them
-remarked as follows, on the appearance of <i>l’Introduction
-à la médecine expérimentale</i>, which contained,
-however, only a portion of the theory:—“Nothing
-more luminous, more complete, or more profound, has
-ever been written upon the true principles of an art so<span class="pagenum" id="Page_53">[Pg 53]</span>
-difficult as that of experiment. This book is scarcely
-known because it is on a level to which few people
-nowadays attain. The influence it will have on medical
-science, on its progress, and on its very language,
-will be enormous. I cannot now prove my assertion,
-but the reading of this book will leave so strong an
-impression that I cannot help thinking that a new
-spirit will at once inspire these splendid researches.”
-This was said by Pasteur in 1866. That is what he
-thought of the work of his senior and his rival, at the
-moment when he himself was about to inspire those
-“splendid researches” with the movement of reform,
-the importance and the consequences of which have
-no equivalent in the history of science. By their
-discoveries and their teaching, by their examples and
-their principles, Claude Bernard and Pasteur have
-succeeded in emancipating a portion of the domain of
-vital facts from the direct intervention of hypothetical
-agents and first causes. They were compelled, however,
-to leave to philosophical speculation, to directing
-forces, to animism, to vitalism, an immense provisory
-field, the field which corresponds to the functions of
-generation and of development, to the life of the
-species and to its variations. Here we find them
-again in various disguises.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_54">[Pg 54]</span></p>
-
-<h2 class="nobreak" id="BOOK_II">BOOK II.<br />
-
-
-<small>THE DOCTRINE OF ENERGY AND THE LIVING
-WORLD.</small></h2></div>
-
-
-<p class="prel">Summary: General Ideas of Life.—Elementary Life.—Chapter
-I. Energy in General.—Chapter II. Energy in Biology.—Chapter
-III. Alimentary Energetics.</p>
-
-
-<p class="center">GENERAL IDEAS OF LIFE. ELEMENTARY LIFE.</p>
-
-
-<p><i>Life is the Sum-total of the Phenomena Common
-to all Living Beings. Elementary Life.</i>—Living
-beings differ more in form and configuration than
-in their manner of being. They are distinguished
-more by their anatomy than by their physiology.
-There are, in fact, phenomena common to all, from
-the highest to the lowest. This is because there is
-that similar or identical foundation, that <i>quid commune</i>
-which has enabled us to apply to them the common
-name of “living beings.” Claude Bernard gave to
-this sum-total of manifestations common to all (nutrition,
-reproduction) the name of <i>elementary life</i>. To
-him <i>general physiology</i> was <i>the study of elementary
-life</i>; the two expressions were equivalent, and they
-were equivalent to a longer formula which the
-illustrious biologist has given as a title to one of
-his most celebrated works—<i>The Study of the
-Phenomena Common to all Living Beings, Animals,<span class="pagenum" id="Page_55">[Pg 55]</span>
-and Plants</i>. From this point of view each being is
-distinguished from another being as a given <i>individual</i>
-and as a particular <i>species</i>; but all are in some way
-alike and thus resemble one another: common life,
-elementary life, the essential phenomena of life; it is
-<i>life itself</i>.<a id="FNanchor_4" href="#Footnote_4" class="fnanchor">[4]</a></p>
-
-<p>The manifestations of life may therefore be regarded
-from the point of view of what is most general among
-them. As we go down the scale of anatomical organization,
-as we pass from apparatus (circulatory,
-digestive, respiratory, nervous) to the <i>organs</i> which
-compose them, from the organs to the <i>tissues</i>, and
-finally from the tissues to the <i>anatomical elements</i> or
-<i>cells</i> of which they are formed, we approach that
-common, physiological dynamism which is <i>elementary
-life</i>, but we do not actually reach it. The cell, the
-anatomical element, is still a complicated structure.
-The elementary fact is further from us and lower
-down. It is in the living matter, in the molecule of
-this matter, and there we must seek it.</p>
-
-<p>Galen gave in days gone by as the object of
-researches on life, the knowledge of the use of the
-different organs of the animal machine; “de usu
-partium.” Later, Bichat assigned to them as their
-end the determination of the <i>properties of tissues</i>.
-Modern anatomists and zoologists try to reach the
-constituent element of these tissue—the cell. Their
-dream is to construct a <i>cellular physiology</i>, a <i>physiological
-cytology</i>; but we must go further than that.</p>
-<p><span class="pagenum" id="Page_56">[Pg 56]</span></p>
-<p><i>General Physiology, Cellular Physiology, the
-Energetics of Living Beings.</i>—General physiology,
-as was taught by Pflüger and his school, claims
-to go deeper down than the apparatus, or the
-organ, or even the cell. As in the case of
-physics, general physiology endeavours to reach,
-and really does in many cases reach, as far as
-the molecule. It is not cellular, it is <i>molecular</i>.
-Already, in fact, the efforts of modern science have
-succeeded in penetrating into the most general phenomena
-of the living being—those attributable to living
-matter, or, to speak more clearly, those which result
-from the play of the universal laws of matter at work
-in this particular medium which is the organized
-being.</p>
-
-<p>Robert Mayer and Helmholtz have the honour of
-having set physiology in the right road. They
-founded <i>the energetics of living beings</i>—<i>i.e.</i>, they
-regarded the phenomena of life from the point of
-view of energy, which is the factor of all the phenomena
-of the universe.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_57">[Pg 57]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_I_2">CHAPTER I.<br />
-
-<small>ENERGY IN GENERAL.</small></h3></div>
-
-
-<p class="prel">Origin of the Idea of Energy.—The Phenomena of Nature bring
-into play only two Elements, Matter and Energy.—§ 1.
-Matter.—§ 2. Energy.—§ 3. Mechanical Energy.—§ 4.
-Thermal Energy.—§ 5. Chemical Energy.—§ 6. The Transformations
-of Energy.—§ 7. The Principles of Energetics.—The
-Principle of the Conservation of Energy.—§ 8. Carnot’s
-Principle.—The Degradation of Energy.</p>
-
-
-
-<p><i>Origin of the Idea of Energy.</i>—A new term, namely
-<i>energy</i>, has been for some years introduced into natural
-science, and has ever since assumed a more and more
-important place. It is owing to the English physicists,
-and especially to the English electrical engineers, that
-this expression has made its way into technology, an
-expression which is part and parcel of both languages,
-and which has the same meaning in both. The idea
-it expresses is, in fact, of infinite value in industrial
-applications, and that is why its use has gradually
-spread and become generalized. But it is not merely
-a practical idea. It is above all a theoretical idea of
-capital importance to pure theory. It has become
-the point of departure of a science, <i>energetics</i>, which,
-although born but yesterday, already claims to
-embrace, co-ordinate, and blend within itself all the
-other sciences of physical and living nature, which the
-imperfection of our knowledge alone had hitherto
-kept distinct and apart.</p>
-
-<p><span class="pagenum" id="Page_58">[Pg 58]</span></p>
-
-<p>On the threshold of this new science we find inscribed
-<i>the principle of the conservation of energy</i>,
-which has been presented to us by some as Nature’s
-supreme law, and which we may say dominates
-natural philosophy. Its discovery marked a new era
-and accomplished a profound revolution in our conception
-of the universe. It is due to a doctor, Robert
-Mayer, who practised in a little town in Wurtemberg,
-and who formulated the new principle in 1842, and
-afterwards developed its consequences in a series of
-publications between 1845 and 1851. They remained
-almost unknown until Helmholtz, in his celebrated
-memoir on the conservation of force, brought them to
-light and gave them the importance they deserved.
-From that time forward the name of the doctor of
-Heilbronn, until then obscure, has taken its place
-among the most honoured names in the history of
-science.<a id="FNanchor_5" href="#Footnote_5" class="fnanchor">[5]</a></p>
-<p><span class="pagenum" id="Page_59">[Pg 59]</span></p>
-<p>As for <i>energetics</i>, of which thermodynamics is only
-a section, it is agreed that even if it cannot forthwith
-absorb mechanics, astronomy, physics, chemistry, and
-physiology, and build up that general science which
-will be in the future the one and only science of
-nature, it furnishes a preparation for that ideal state,
-and is a first step in the ascent to definite progress.</p>
-
-<p>Here I propose to expound these new ideas, in so
-far as they contain anything universally accessible;
-and in the second place, I propose to show their
-application to physiology—that is to say, to point out
-their rôle and their influence in the phenomena of
-life.</p>
-
-<p><i>Postulate: the Phenomena of Nature bring into
-play only two Elements, Matter and Energy.</i>—If we
-try to account for the phenomena of the universe,
-we must admit with most physicists that they
-bring into play two elements, and two elements only;
-namely, <i>matter</i> and <i>energy</i>. All manifestations are
-exhibited in one or other of these two forms. This,
-we may say, is the postulate of experimental science.</p>
-
-<p>Just as gold, lead, oxygen, the metalloids, and the
-metals are different kinds of matter, so it has been
-recognized that sound, light, heat, and generally, the
-imponderable agents of the days of early physics, are<span class="pagenum" id="Page_60">[Pg 60]</span>
-different varieties of energy. The first of these ideas
-is older and more familiar to us, but it has not for that
-reason a more certain existence. Energy is objective
-reality for the same reason that matter is. The
-latter certainly appears more tangible and more easily
-grasped by the senses. But, upon reflection, we are
-assured that the best proof of their existence, in both
-cases, is given by the law of their conservation—that
-is to say, their persistence in subsisting.</p>
-
-<p>The objective existence of matter and that of
-energy will therefore be taken here as a postulate of
-physical science. Metaphysicians may discuss them.
-We have but little room for such a discussion.</p>
-
-
-<h4>§ I. <span class="smcap">Matter.</span></h4>
-
-<p>It is certainly difficult to give a definition of
-matter which will satisfy both physicists and metaphysicians.</p>
-
-<p><i>Mechanical Explanation of the Universe. Matter is
-Mass.</i>—Physicists have a tendency to consider all
-natural phenomena from the point of view of mechanics.
-They believe that there is a mechanical explanation
-of the universe. They are always on the look out for
-it, implicitly or explicitly. They endeavour to reduce
-each category of physical facts to the type of the facts
-of mechanics. They have made up their minds to see
-nowhere anything but the play of motion and force.
-Astronomy is celestial mechanics. Acoustics is the
-mechanics of the vibratory movements of the air or of
-sonorous bodies. Physical optics has become the
-mechanics of the undulations of the ether, after having
-been the mechanics of emission—a wonderful<span class="pagenum" id="Page_61">[Pg 61]</span>
-mechanics which represents exactly all the phenomena
-of light, and furnishes us with a perfect objective
-image of it. Heat, in its turn, has been reduced to a
-mode of motion, and thermodynamics claims to embrace
-all its manifestations. As early as 1812, Sir
-Humphry Davy wrote as follows:—“The immediate
-cause of heat is motion, and the laws of transmission
-are precisely the same as those of the transmission
-of motion.” From that time forth, this conception
-developed into what is really a science. The constitution
-of gases has been conceived by means of two
-elements—particles, and the motions of these particles,
-determined in the strictest detail. And finally, in spite
-of the difficulties of the representation of electrical and
-magnetic phenomena after Ampère and before Maxwell
-and Hertz, physicists have been able to announce in the
-second half of the nineteenth century the unity of the
-physical forces realized in and by mechanics. From
-that time forth, all phenomena have been conceived
-as motion or modes of motion, only differing essentially
-one from the other in so far as motions may
-differ—that is to say, in the masses of the moving
-particles, their velocities, and their trajectories. The
-external world has appeared essentially homogeneous;
-it has fallen a prize to mechanics. Above all, there
-is heterogeneity in ourselves. It is in the brain,
-which responds to the nervous influx engendered by
-the longitudinal vibration of the air, by the specific
-sensation of sound, which responds to the transverse
-vibration of the ether by a luminous sensation, and in
-general to each form of motion by an irreducible
-specific sensation.</p>
-
-<p>Forty years have passed since the mechanical explanation
-of the universe reached its definite and<span class="pagenum" id="Page_62">[Pg 62]</span>
-perfect form. It dominates physics under the name
-of the <i>theory of kinetic energy</i>. The minds of men in
-our own time are so strongly impregnated with this
-idea that most scientists of ordinary culture get no
-glimpse of the world of phenomena but by means of
-this conception. And yet it is only an hypothesis.
-But it is so simple, so intuitive, and appears to be so
-thoroughly verified by experiment, that we have
-ceased to recognize its arbitrary and unnecessarily
-contingent character. Many physicists from this
-standpoint consider the kinetic theory as an imperishable
-monument.</p>
-
-<p>However, as in the case of H. Poincaré, the most
-eminent physicists and mathematicians are not the
-dupes of this system; and without failing to recognize
-the immense services which it has rendered to science,
-they are perfectly well aware that it is only a system,
-and that there may be other systems. Certain among
-them, such as Ostwald, Mach, and Duhem, believe
-that the monument is showing signs of decay, and at
-present the theory is opposed by another theory—namely,
-the theory of <i>energy</i>.</p>
-
-<p>The theory of <i>energy</i> is usually considered and presented
-as a consequence of the kinetic theory; but it
-is perfectly independent of it, and it is, in fact, without
-relying on the kinetic theory, without assuming the
-unity of physical forces, which are combined in molecular
-mechanics, that we shall expound the general
-system.</p>
-
-<p>This is not the point at issue for the moment. It is
-not a question of deciding the reality or the merit of
-this or that mechanical explanation; it is a question
-of something more general, because upon it depends
-the <i>idea of matter</i>. It is a question of knowing if<span class="pagenum" id="Page_63">[Pg 63]</span>
-there are any explanations other than mechanical.
-The illustrious English physicist, Lord Kelvin, does
-not seem willing to admit this. “I am never satisfied,”
-he said, in his <i>Molecular Mechanics</i>, “until I have
-made a mechanical model of the object. If I can
-make this model, I understand; if I cannot, I do not
-understand.”</p>
-
-<p>This tendency of so vigorous a mind to be content
-only with mechanical explanations, has been
-that of the majority of scientific men up to the
-present day, and from it has arisen the scientific idea
-of matter.</p>
-
-<p>What is matter, in fact, to the student of mechanics?
-It is mass. All mechanics is constructed of masses
-and forces. Laplace said: “The mass of a body is the
-sum of its material points.” To Poisson, mass is the
-quantity of matter of which a body is composed.
-Matter is therefore confused with mass. Now, mass
-is the characteristic of the motion of a body under the
-action of a given force; it defines obedience or resistance
-to the causes of motion; it is the <i>mechanical
-parameter</i>; it is the co-efficient proper to every mobile
-body; it is the first <i>invariant</i> of which a conception
-has been established by science.</p>
-
-<p>In fact, the word matter appears to be used in
-other senses by physicists, but this is only apparently
-so. They have but broadened the idea of the
-mechanicians. They have characterized matter by
-the whole series of phenomenal manifestations which
-are <i>proportional to mass</i>, such as weight, volume,
-chemical properties—so that we may say that the
-notion of matter does not intervene scientifically with
-a different signification from that of mass.</p>
-
-<p><i>Two kinds of Matter. Ponderable and Imponder<span class="pagenum" id="Page_64">[Pg 64]</span>able.</i>—In
-physics we distinguish between two kinds
-of matter—ponderable, obeying the law of universal
-attraction or weight, and imponderable matter or
-ether, which we assume to exist and to escape the
-action of that force. Ether has no weight, or extremely
-little weight. It is material in so far as it
-has mass. It is its mass which confers existence on
-it from the mechanical point of view—a logical existence,
-inferred from the necessity of explaining the
-propagation of heat, light, or electricity.</p>
-
-<p>It may be observed that the use of mass really
-comes to bringing another element, force, to intervene,
-and we shall see that force is connected with energy;
-thus it comes to defining matter indirectly by energy.
-The two fundamental elements are not therefore
-irreducible; on the contrary, they should be one and
-the same thing.</p>
-
-<p><i>Energy is the only Objective Reality.</i>—This fusion
-into one will become more evident still when we
-examine the different kinds of energy, each of which
-exactly corresponds to one of the aspects of active
-matter. Shall we define matter by <i>extension</i>, by the
-portion of space it occupies, as certain philosophers
-do? The physicist will answer that space is only
-known to us by the expenditure of energy necessary
-to penetrate it (the activity of our different senses).
-And then what is weight? It is <i>energy of position</i>
-(universal attraction). And so with the other attributes.
-So that if matter were separated from the
-energetic phenomena by means of which it is revealed
-to us—weight or energy of position, impenetrability
-or energy of volume, chemical properties or chemical
-energies, mass or capacity for kinetic energy—the very
-idea of matter would vanish. And that comes to<span class="pagenum" id="Page_65">[Pg 65]</span>
-saying that fundamentally there is only one objective
-reality, <i>energy</i>.</p>
-
-<p><i>Philosophical Point of View.</i>—But from the philosophical
-point of view are there objective realities?
-That is a wider question which throws doubt upon
-matter itself, and which it is not our place to investigate
-here. A metaphysician may always discuss and
-deny the existence of the objective world. It may be
-maintained that man knows nothing beyond his
-sensations, and that he only objectivates them and
-projects them outside himself by a kind of hereditary
-illusion. We must avoid taking sides in all these
-difficulties. Physics for the moment ignores them—<i>i.e.</i>,
-postpones their consideration.</p>
-
-<p>In a first approximation we agree to consider
-ponderable matter only. Chemistry acquaints us
-with its different forms. They are the different
-simple bodies, metalloids, metals, and the compound
-bodies, mineral or organic. Hence we may say that
-chemistry is <i>the history of the transformations of
-matter</i>. From the time of Lavoisier this science has
-followed the transformations of matter, balance in
-hand, and ascertains that they are accomplished
-without change of weight.</p>
-
-<p><i>Law of the Conservation of Matter.</i>—Imagine a
-system of bodies enclosed in a closed vessel, and the
-vessel placed in the scale of a balance. All the
-chemical reactions capable of completely modifying
-the state of this system have no effect upon the scale
-of the balance. The total weight is the same before,
-during, and after. It is precisely this equality of
-weight which is expressed in all the equations with
-which treatises on chemistry are filled.</p>
-
-<p>From a higher point of view we recognize here, in<span class="pagenum" id="Page_66">[Pg 66]</span>
-this <i>law of Lavoisier</i> or of the <i>conservation of weight</i>,
-the verification of one of the great laws of nature
-which we extend to every kind of matter, ponderable
-or not. It is the <i>law of the conservation of matter</i>,
-or again, of the indestructibility of matter—“Nothing
-is lost, nothing is created, all is transformation.” This
-is exactly what Tait held, this impossibility of creating
-or destroying matter which at the same time is a
-proof of its objective existence. This indestructibility
-of ponderable matter is at the same time the fundamental
-basis of chemistry. Chemical analysis could
-not exist if the chemist were not sure that the contents
-of his vessel at the end of his operations ought to be
-quantitatively, that is to say by weight, the same as at
-the beginning, and during the whole course of the
-experiment.<a id="FNanchor_6" href="#Footnote_6" class="fnanchor">[6]</a></p>
-<p><span class="pagenum" id="Page_67">[Pg 67]</span></p>
-
-<h4>§ 2. <span class="smcap">Energy.</span></h4>
-
-<p><i>The Idea of Energy Derived from the Kinetic
-Theory.</i>—The notion of energy is not less clear than
-the notion of matter, it is only more novel to our
-minds. We are led to it by the mechanical conception
-which now dominates the whole of physics, <i>the kinetic
-conception</i>, according to which in the sensible universe
-there are no phenomena but those of motion. Heat,
-sound, light, with all their manifestations so complex
-and so varied, may, according to this theory, be
-explained by motion. But then, if outside the brain
-and the mind which has consciousness and which
-perceives, Nature really offers us only motion, it
-follows that all phenomena are essentially homogenous
-among one another, and that their apparent
-heterogeneity is only the result of the intervention of
-our sensorium. They differ only in so far as movements
-are capable of differing—that is to say, in
-velocity, mass, and trajectory. There is something
-fundamental which is common to them and this <i>quid
-commune</i> is <i>energy</i>. Thus the idea of energy may be
-derived from the kinetic conception, and this is the
-usual method of exposition.</p>
-
-<p>This method has the great inconvenience of causing
-an idea which lays claim to reality to depend upon an
-hypothesis. And besides that, it gives a view of it
-which may be false. It makes of the different forms
-of energy something more than varieties which are
-equivalent to one another. It makes of them <i>one and
-the same thing</i>. It blends into one the modalities of
-energy and mechanical energy. For the experimental
-idea of equivalence, the kinetic theory substitutes the
-arbitrary idea of the equality, the blending, and the
-fundamental homogeneity of phenomena. This no
-doubt is how the founders of energetics, Helmholtz,
-Clausius, and Lord Kelvin understood things. But a
-more attentive study and a more scrupulous determination
-not to go beyond the teaching of experiment
-should compel us to reform this manner of looking at
-it. And it is Ostwald’s merit that, after Hamilton, he
-insisted on this truth—that the various kinds of
-physical magnitudes furnished by the observation of
-phenomena are different and characteristic. In particular,
-we may distinguish among them those which
-belong to the order of <i>scalar</i> magnitudes and others
-which are of the order of <i>vector</i> magnitudes.</p>
-
-<p><i>The Idea of Energy derived from the Connection
-of Phenomena.</i>—The idea of energy is not absolutely<span class="pagenum" id="Page_68">[Pg 68]</span>
-connected with the kinetic theory, and it should not
-be exposed therefore to the vicissitudes experienced
-by that theory. It is of a higher order of truth. We
-can derive it from a less unsafe idea, namely that of
-the <i>connection of natural phenomena</i>. To conceive it
-we must get accustomed to this primordial truth, that
-there are no <i>phenomena isolated</i> in time and space.
-This statement contains the whole point of view of
-energetics.</p>
-
-<p>The physics of early days had only an incomplete
-view of things, for it considered phenomena independently
-the one of the other.</p>
-
-<p>Phenomena for purposes of analysis were classed in
-separate and distinct compartments: weight, heat,
-electricity, magnetism, light. Each phenomenon was
-studied without reference to that it succeeded or that
-which should follow. Nothing could be more artificial
-than such a method as this. In fact, there is a
-sequence in everything, everything is connected up,
-<i>everything precedes and succeeds in nature</i>—in nature
-there are only series. The isolated fact without
-antecedent or consequent is a myth. Each
-phenomenal manifestation is in solidarity with
-another. It is a metamorphosis of one state of
-things into another. It is transformation. It implies
-a state of things anterior to that which we are
-observing, a phenomenal form which has preceded
-the form of the present moment.</p>
-
-<p>Now there exists a link between the anterior state
-and the succeeding state—that is to say, between the
-new form which is appearing and the preceding form
-which is disappearing. The science of energy shows
-that something has passed from the first condition to
-the second, but covering itself as it were with a new<span class="pagenum" id="Page_69">[Pg 69]</span>
-garment; in a word, that something active and
-permanent subsists in the passage from one condition
-to another, and that what has changed is only the
-aspect, the appearance.</p>
-
-<p>This constant something which is perceived beneath
-the inconstancy and the variety of forms, and which
-circulates in a certain manner from the antecedent
-phenomenon to its successor, is energy.</p>
-
-<p>But still this is only a very vague view, and it may
-seem arbitrary. It may be made more exact by
-examples borrowed from the different categories of
-natural phenomena. There are energetic modalities
-in relation with the different phenomenal modalities.
-The different orders of phenomena which may be
-presented—mechanical, chemical, thermal, electrical—give
-rise to corresponding forms of energy.</p>
-
-<p>When to a mechanical phenomenon succeeds a
-mechanical, thermal, or electrical phenomenon, we
-say, embracing transformation in its totality, that
-there has been a transformation of mechanical energy
-into another form of energy, mechanical, thermal, or
-electrical, etc.</p>
-
-<p>This idea becomes more precise if we examine
-successively each of these cases and the laws which
-regulate them.</p>
-
-
-<h4>§ 3. <span class="smcap">Mechanical Energy.</span></h4>
-
-<p>Mechanical energy is the simplest and the oldest
-known.</p>
-
-<p><i>Mechanical Elements: Time, Space, Force, Work,
-Power.</i>—Mechanical phenomena may be considered
-under two fundamental conditions—<i>time</i> and <i>space</i>,<span class="pagenum" id="Page_70">[Pg 70]</span>
-which are, in a measure, logical elements, to which
-may be joined a third element, itself experimental,
-having its foundations in our sensations—namely,
-<i>force</i>, <i>work</i>, or <i>power</i>.</p>
-
-<p>The ideas of force, work, and power, are drawn from
-the experience man has of his muscular activity.
-Nevertheless the greatest mathematical minds from
-from Descartes to Leibniz have been obliged to define
-and explain them clearly.</p>
-
-<p><i>Force</i>.—The prototype of force is weight, universal
-attraction. Experiment shows us that every body
-falls as long as no obstacle opposes its fall. This is
-so universal a property of matter that it serves to
-define it. The <i>force</i>, weight, is therefore the name
-given to the cause of the fall of the bodies.</p>
-
-<p>Force in general is the <i>cause of motion</i>. Hence
-force exists only in so far as there is motion. There
-would be no force without action. This is Newton’s
-point of view. It did not prevail, and was not the
-point of view of his successors. The name of force
-has been given not only to the cause which produces
-or modifies motion, but to the cause which resists and
-prevents it. And then not only have <i>forces in action</i>
-been considered (dynamics), but <i>forces at rest</i> (statics).
-Now, to Newton there was no statics. Forces do not
-continue to exist when they produce no motion; they
-are not in equilibrium, they are destroyed.</p>
-
-<p>The idea of force therefore is a metaphysical idea
-which contains the idea of <i>cause</i>. But it becomes
-experimental immediately it is looked upon as resisting
-motion, according to the point of view of Newton’s
-opponents. Its foundations lie in the muscular
-activity of man.</p>
-
-<p>Man can support a burden without bending or<span class="pagenum" id="Page_71">[Pg 71]</span>
-moving. This burden is a weight—that is to say, a
-mass acted on by the force of weight. Man resists
-this force so as to prevent its effect. If it were not
-annihilated by man’s <i>effort</i>, this effect would be the
-motion or the fall of the heavy body. The <i>effort</i> and
-the force are thus in equilibrium, and the effort is
-equal and opposite to the force. It gives to the man
-who exercises it the conscious idea of <i>force</i>. Thus we
-know of force through effort. Every clear idea that
-we can have of <i>force</i> springs from the observation of
-our muscular effort.</p>
-
-<p>The notion of force is thus an anthropomorphic
-notion. When an effect is produced in nature outside
-human intervention, we say that it is by something
-analogous to what in man is effort, and we give to this
-something a name which is also analogous, namely
-<i>force</i>. To give a name to <i>effort</i> and to compare
-efforts in magnitude, we need not know all about
-them, nor need we know in what they essentially
-consist, of what series of physical, chemical, and
-physiological actions they are the consequence. And
-so it is with force. It is a resistance to motion or
-the cause of motion. This cause of motion may be
-an anterior motion (kinetic force). It may be an
-anterior physical energy (physical and chemical
-forces).</p>
-
-<p>Forces are measured in the C.G.S. system by comparing
-them with the unit called the Dyne.<a id="FNanchor_7" href="#Footnote_7" class="fnanchor">[7]</a> In
-practice they are compared with a much larger unit—the
-gramme, which is the weight, the force acting on
-a unit of mass of one centimetre of distilled water at
-a temperature of 4° C.</p>
-<p><span class="pagenum" id="Page_72">[Pg 72]</span></p>
-
-<p><i>Work.</i>—The muscular activity of man may be
-brought into play in yet another manner. When we
-employ workmen, as Carnot said in his <i>Essai sur
-l’équilibre et le mouvement</i>, it is not a question of
-“knowing the burdens that they can carry without
-moving from their position,” but rather the burdens
-that they can carry from one point to another. For
-instance, a workman may have to lift the water from
-the bottom of a well to a given height, and the case is
-the same for the animals we employ. “This is what
-we understand by force when we say that the force of
-a horse is equal to the force of seven men. We do
-not mean that if seven men were pulling in one
-direction and the horse in another that there would be
-equilibrium, but that in a piece of work the horse
-alone would lift, for example, as much water from the
-bottom of a well to a given height as the seven men
-together would do in the same time.”<a id="FNanchor_8" href="#Footnote_8" class="fnanchor">[8]</a></p>
-
-<p>Here, then, we have to do with the second form of
-muscular activity, which is called in mechanics, “work”—at
-least, if in the preceding quotation we attach no
-particular importance to the words “in the same
-time,” and retain the employment of muscular activity
-only “under constant conditions.” Mechanical work
-is compared with the elevation of a certain weight to a
-certain height. It is measured by the product of the
-force (understood in the sense in which it was used
-just now—that is to say, as causing or resisting motion)
-and the displacement due to this motion. The unit is
-the Kilogrammetre—that is to say, the work necessary
-to lift a weight of one kilogramme to the height of
-one metre.</p>
-<p><span class="pagenum" id="Page_73">[Pg 73]</span></p>
-<p>It will be remarked that the idea of time does not
-intervene in our estimation of work. The notion of
-work is independent of the ideas of velocity and
-time. “The greater or less time that we take to do
-a piece of work is of no more assistance in measuring
-its magnitude than the number of years that
-a man may have taken to grow rich or to ruin himself
-can help to estimate the present amount of his
-fortune.”</p>
-
-<p>Going back to Carnot’s comparison, an employer
-who employed his workmen only on piece-work,—that
-is to say, who would only care about the amount of
-work done, and would be indifferent to the time that
-they took over it,—would be at the same point of view
-as the advocates of the mechanical theory. M.
-Bouasse, whom we follow here, has remarked that this
-idea of mechanical work may be traced back to
-Descartes. His predecessors, and Galileo in particular,
-had quite a different idea of the way in which
-mechanical activity should be measured; and so,
-among the mathematicians of the eighteenth century,
-Leibniz and, later, John Bernoulli were almost alone
-in looking at it from this point of view.</p>
-
-<p><i>Energy.</i>—Work thus understood is <i>mechanical
-energy</i>. It represents the lasting and objective effect
-of the mechanical activity independent of all the circumstances
-under which it was carried out. The
-same work may be done under very different conditions
-of time, velocity, force, and displacement.
-It is therefore the permanent element in the variety of
-mechanical aspects. Work, for example, in the
-collision of bodies when the motion of a body appears
-to be destroyed on impact with another, reappears as
-indestructible <i>vis viva</i>. This, then, is exactly what<span class="pagenum" id="Page_74">[Pg 74]</span>
-we call <i>energy</i>; and if we agree to give it this name,
-we may say that the conservation of energy is
-invariable throughout all mechanical transformations.</p>
-
-<p><i>Distinction between Work and Force, and between
-Energy and Work.</i>—The history of mechanics shows
-us what trouble has been taken and what efforts have
-been made to distinguish work (now mechanical
-energy) from force.</p>
-
-<p>It is worth while insisting on this distinction. It
-could be easily shown that force has no objective existence.
-It has no duration, no permanence. It does
-not survive its effect, motion. There is no conservation
-of force. It passes instantly from infinity to
-zero. It is a <i>vectorial magnitude</i>—that is to say, it
-involves the idea of direction. Work, on the other
-hand, is the real element; it is a <i>scalar magnitude</i>
-involving the idea of opposite directions, indicated by
-the signs + and-. Work and force are heterogeneous
-magnitudes. Energy, and this is the only
-characteristic by which it is distinguished from work,
-is an <i>absolute magnitude</i> to which we may not even
-give opposite signs.</p>
-
-<p>An example may perhaps throw these characteristics
-into relief—namely, the hydraulic press. We have on
-the platform exactly the work which has been done
-on the other side. The machine has only made it
-change its form. On the contrary, the force has been
-infinitely multiplied. We may, in fact, consider an
-infinite number of surfaces equal to that of a small
-piston, placed and orientated at will within the liquid;
-each, according to Pascal’s principle, will support a
-pressure equal to that which is exercised. As soon as
-we cease to support it, this infinity falls at once to zero.<span class="pagenum" id="Page_75">[Pg 75]</span>
-Now what real thing could pass instantly from infinity
-to zero?</p>
-
-<p>That skilful and very able physiologist, M. Chauveau,
-has endeavoured to use the same term <i>energy of contraction</i>
-for the two phenomena of effort (force) and
-work. It seems, however, from the point of view of
-the expenditure imposed on the organism, that these
-two modes of activity, <i>static contraction</i> (effort), and
-<i>dynamical contraction</i> (work), may be, in fact, perfectly
-comparable. But although this manner of conceiving
-the phenomena may certainly be exact, and may be
-of great value, the idea of force must none the less
-remain distinct from that of work. The persistence
-of the author in violating established custom in this
-connection has prevented him from enabling mechanicians
-and even some physiologists to understand and
-accept very useful truths.</p>
-
-<p><i>Power.</i>—The idea of mechanical <i>power</i> differs from
-those of force and work. The idea of time must
-intervene. It is not sufficient, in fact, in order to
-characterize a mechanical operation, to point to the
-task accomplished. It may be necessary or useful to
-know how much time it required. This is true,
-especially when we are concerned with the circumstances
-as well as the results of the performance of
-the work; and this is the case when we wish to
-compare machines. We say that the machine which
-does the work in the shortest space of time is
-the most powerful. The unit of power is the Kilogrammetre-second—that
-is to say, the power of a
-machine which does a kilogrammetre in a second. In
-manufactures we generally employ a unit 75 times
-greater than this—a <i>horse-power</i>. This is the power of
-a machine which does 75 kilogrammetres a second.<span class="pagenum" id="Page_76">[Pg 76]</span>
-In the electrical industry we measure by <i>kilowatts</i>,
-which are equivalent to 1.36 horse power, or by a <i>watt</i>,
-a unit a thousand times smaller.</p>
-
-<p>Let us add that the power of a machine is not an
-absolute and permanent characteristic of the machine.
-It depends on the circumstances under which the
-work is carried out, and that is why, in particular, we
-cannot appreciate the power of the human machine in
-comparison with industrial machines. Experience
-has shown that the mechanical power of living beings
-depends upon the nature of the work they are doing.
-In this connection we may mention some very interesting
-experiments communicated to the Institute, in
-the year VI., by the celebrated physicist, Coulomb. A
-man of the average weight of 70 kilogrammes was
-made to climb the stairs of a house 20 metres high.
-He ascended at the rate of 14 metres a minute, and
-he performed this daily task for four effective hours.
-This work was equivalent to 235,000 kilogrammetres.
-But if, instead of climbing without a burden, the same
-man had had to carry a load, the result would have
-been quite different. Coulomb’s workman took up
-six loads of wood a day to a height of 12 metres
-in 66 journeys, corresponding to a maximum
-work of 109,000 instead of 235,000 kilogrammetres.
-The mechanical power of the human machine
-thus varied in the two cases in the ratio of 235
-to 109.</p>
-
-<p><i>The Two Aspects of Mechanical Energy: Kinetic
-and Potential.</i>—Energy, or mechanical work, may
-present itself in two forms—kinetic energy, corresponding
-to the mechanical phenomenon which has
-really taken place, and <i>potential energy</i>, or the energy
-of reserve.</p>
-
-<p><span class="pagenum" id="Page_77">[Pg 77]</span></p>
-
-<p>A body which has been raised to a certain
-height will, if it be let fall, perform work which
-can be exactly measured in kilogrammetres by the
-product of its weight into the height it falls. Such
-work may be utilized in many ways. In this way,
-for instance, public clocks are worked. Now, as long
-as the clock-weight is raised and not let go, and
-as long as it is motionless, the physics of early
-days would say that there is nothing to discuss;
-the phenomenon is the fall; it is going to take
-place, but at the present moment there has been
-no fall.</p>
-
-<p>In energetics we do not reason in this way. We
-say that the body possesses a <i>capacity for work</i> which
-will be manifested when the opportunity arises, a
-storage of energy, a virtual or <i>potential energy</i>, or
-again, an <i>energy of position</i>, which will be transformed
-into actual energy or real work as soon as the body
-falls.</p>
-
-<p>Let us ask whence this energy arises. It proceeds
-from the previous operation which has raised the
-weight from the surface of the soil to the position it
-occupies. For example, if it is a question of the
-weights of a public clock, which, by its fall, will develop
-in 15 days the work that is necessary to turn the
-wheels, to strike the bell, and to turn the hands,
-this work ought to bring to our minds the exactly equal
-and opposite work done by the clockmaker, who has
-to carry the clock-weight and to lift it up from the
-ground to its point of departure. The work of the
-fall is the faithful counterpart of the work of elevation.
-The phenomenon has therefore in reality two phases.
-We find in the second exactly what was put into the
-first, the same quantity of energy—<i>i.e.</i>, the same work.<span class="pagenum" id="Page_78">[Pg 78]</span>
-Between these phases comes the intermediary phase
-of which we say that it is a period of virtual <i>or potential
-energy</i>. This is a way of remembering in some
-measure the preceding phenomenon—<i>i.e.</i>, the work of
-lifting up, and of indicating the phenomena which will
-follow—<i>i.e.</i>, the work of the fall. And thus we connect
-by our thoughts the present situation with the antecedent
-and with the consequent position, and it is
-from this consideration of continuity alone that the
-conception of energy springs—that is to say, of something
-which is conserved and is found to be permanent
-in the succession of phenomena. This energy of
-which we lose no trace does not appear to us new
-when it is manifested. Our imagination eventually
-materializes the idea of it. We follow it as a real
-thing, having an objective existence, which is asleep
-during the latent potential period, and is revealed or
-manifested later.</p>
-
-<p>Among other examples, that of the coiled spring
-which is unwound is particularly suitable for showing
-this fundamental character of the idea of
-mechanical energy, an idea which is the clearest
-of all. Machines are only transformers and not
-creators of mechanical energy. They only change
-one form into another.</p>
-
-<p>In the same way, too, a stream of water or the
-torrent of a mountainous region may be utilized for
-setting in motion the wheels and the turbines of the
-factories situated in the valley. Its descent produces
-the mechanical work which would be a creation <i>ex
-nihilo</i> if we do not connect the phenomenon with its
-antecedents. We look on it as a simple restitution, if
-we think of the origin of this water which has been
-transported and lifted in some way to its level by the<span class="pagenum" id="Page_79">[Pg 79]</span>
-play of natural forces—evaporation under the action
-of the sun, the formation of clouds, transport by winds,
-etc. And we here again see that a complex energy
-has been transformed, in its first phenomenal condition,
-into <i>potential energy</i>, and that this potential
-energy is always expended in the second phase without
-loss or gain.</p>
-
-<p><i>The Different Kinds of Mechanical Energy; of
-Motion, of Position.</i>—There are as many forms of
-energy as there are distinct categories of phenomena
-or of varieties in these categories. Physicists distinguish
-between two kinds of mechanical energy—energy
-of motion and energy of position. The energy
-of position presents several variants—energy of distance,
-which corresponds to force: of this we have just
-spoken; energy of surface, which corresponds to particular
-phenomena of surface tension; and energy of
-volume which corresponds to the phenomena of pressure.
-Energy of motion, <i>kinetic energy</i>, is measured in two
-ways: as work (the product of force and displacement,
-W = <i>fs</i>) or as <i>vis viva</i> (half the product of the mass
-into the square of the velocity U = <i>mv<sup>2</sup></i>∕2.<a id="FNanchor_9" href="#Footnote_9" class="fnanchor">[9]</a></p>
-<p><span class="pagenum" id="Page_80">[Pg 80]</span></p>
-
-<h4>§ 4. <span class="smcap">Thermal Energy.</span></h4>
-
-<p>In the elements of physics it is nowadays taught
-that mechanical work may be transformed into heat,
-and reciprocally that heat may be transformed into
-mechanical work. Friction, impact, pressure, and
-expansion destroy or annihilate the mechanical energy
-communicated to a body or to the organs of a
-machine. With the disappearance of motion we
-note the appearance of heat. Examples abound.
-The tyre of a wheel is heated by the friction of the
-road. Portions of steel are warmed by the impact
-with stone, as in the old flint and steel. Two pieces
-of ice were melted by Davy, who rubbed them one
-against the other, the external temperature being
-below zero. The boiling of a mass of water caused
-by a drill was noticed by Rumford in 1790, during
-the manufacture of bronze cannon. Metal, beaten on
-an anvil, is heated. A leaden ball flattened against a
-resisting obstacle shows increase of temperature carried
-to the point of fusion. Finally, and symbolically, we
-have the origin of fire in the fable of Prometheus, by
-rubbing together the pieces of wood which the Hindoos
-called <i>pramantha</i>. Correlation is constant between
-the thermal and mechanical phenomena, a correlation
-that becomes evident as soon as observers have ceased
-to restrict themselves to the determination in isolation
-of the one fact or the other. There is never any real
-destruction of heat and motion in the true sense of the
-word; what disappears in one form appears again in
-another; just as if something indestructible were appearing
-in a series of successive disguises. This
-impression is translated into words when we speak<span class="pagenum" id="Page_81">[Pg 81]</span>
-of the metamorphosis of mechanical into thermal
-energy.</p>
-
-<p><i>The Mechanical Equivalent of Heat.</i>—The interpretation
-assumes a remarkable character of precision,
-which at once strikes the mind when physics applies
-to these transformations the almost absolute accuracy
-of its measurements. We then find that the rate of
-exchange is invariable. Transformations of heat into
-motion, and of motion into heat, take place according
-to a rigorous numerical law, which brings into exact
-correspondence the quantity of each. Mechanical
-effect is estimated, as we have seen, by work, that is in
-kilogrammetres. Heat is measured in calories, the
-calorie being the quantity of heat necessary to raise
-from 0°C to 1°C a kilogramme of water (Calorie) or
-one gramme of water (calorie). It is found that
-whatever may be the bodies and the phenomena
-which serve as intermediaries for carrying out this
-transformation, we must always expend 425 kilogrammetres
-to create a Calorie, or expend 0·00234
-Calories to create a kilogrammetre. The number 425
-is the mechanical equivalent of the Calorie, or, as is
-incorrectly stated, of the heat. It is this constant fact
-which constitutes <i>the principle of the equivalence of heat
-and of mechanical work</i>.</p>
-
-
-<h4>§ 5. <span class="smcap">Chemical Energy.</span></h4>
-
-<p>We cannot yet actually measure chemical activity
-directly, but we know that chemical action may give
-rise to all other phenomenal modalities. It is their
-most ordinary source, and it is to it that industries
-appeal to obtain heat, electricity, and mechanical<span class="pagenum" id="Page_82">[Pg 82]</span>
-action. In the steam engine, for instance, the work
-that is received arises from the combustion of carbon
-by the oxygen of the air. This gives rise to the heat
-which vaporizes the water, produces the tension of the
-steam, and ultimately produces the displacement of
-the piston. The theory of the steam engine might be
-reduced to these two propositions: chemical activity
-gives rise to heat, and heat gives rise to motion; or to
-use the language to which the reader by now will be
-accustomed, chemical energy is transformed into
-thermal energy, and that into mechanical energy. It
-is a series of phases and of instantaneous changes, and
-the exchange is always affected according to a fixed
-rate.</p>
-
-<p><i>The Measurement of Chemical Energy.</i>—Our knowledge
-of chemical energy is less advanced than that of
-the energies of heat and sensible motion. We have
-not yet reached the stage of numerical verifications.
-We can only therefore affirm the equivalence of
-chemical and thermal energies without the aid of
-numerical constants, because we do not yet, in the
-present state of science, know how to measure
-chemical energy directly. Other known energies are
-always the product of two factors: the mechanical
-energy of position, or work, is measured by the
-product of the force <i>f</i>, and the displacement <i>s</i>; work
-= <i>fs</i>; the mechanical energy of motion, U = 1∕2<i>mv<sup>2</sup></i>, is
-measured by the product of the mass into half the
-square of the velocity. Thermal energy is measured
-by the product of the temperature and the specific
-heat; electric energy by the product of the quantity
-of electricity (in coulombs) and of the electromotive
-force (in volts). As for chemical energy, we guess
-that it may be valued directly according to Berthollet’s<span class="pagenum" id="Page_83">[Pg 83]</span>
-system, adopted by the Norwegian chemists, Guldberg
-and Waage, by means of the product of the masses
-and of a force, or co-efficient of affinity, which depends
-on the nature of the substances which are brought together,
-on the temperature, and on the other physical
-circumstances of the reaction. On the other hand,
-the researches of M. Berthelot enable us in many
-cases to obtain an indirect valuation in terms of the
-equivalent heat.</p>
-
-<p><i>Its Two Forms.</i>—It is interesting to note that
-chemical energy may also be regarded from the two
-states of <i>potential</i> and <i>kinetic energy</i>. The coal-oxygen
-system, to burn in the furnace of the steam
-engine, must be primed by preliminary work (local
-ignition), just as the weight that is raised and left
-motionless at a certain height requires a small
-effort to be detached from its support. When this
-condition is fulfilled, energy is at once manifest.
-We must admit that it existed in the latent state, in
-the state of <i>chemical potential energy</i>. Under the
-impulse received, the carbon combines with the
-oxygen and forms carbonic acid, C + 2O becomes
-CO<sub>2</sub>; potential energy is changed into actual chemical
-energy, and immediately afterwards into thermal
-energy. We should have only a very incomplete and
-fragmentary view of the reality of things if we were
-to consider this phenomenon of combustion in isolation.
-We must consider it in connection with what has
-actually created the energy which it is about to
-dissipate. This antecedent fact is the action of the
-sun upon the green leaf. The carbon which burns in
-the furnace of the machine comes from the mine in
-which it was stored in the form of coal—that is to say,
-of a product which was vegetable in its primitive form,<span class="pagenum" id="Page_84">[Pg 84]</span>
-and which was formed at the expense of the carbonic
-acid of the air. The plant had separated, at the
-expense of the solar energy, the carbon from the
-oxygen to which it was united in the carbonic acid of
-the atmosphere. It had created the system C + 2O.
-So that the solar energy produces the chemical potential
-energy which was so long before it was utilized.
-Combustion expends this energy in making carbonic
-acid over again.</p>
-
-<p><i>Materialization of Energy.</i>—The fertility of the
-idea of energy is therefore, as we see from all
-these examples, due to the relations it establishes
-between the natural phenomena of which it exhibits
-the necessary relation, destroyed by the excessive
-analysis of early science. It shows us that in the
-world of phenomena there is nothing but transformations
-of energy. And we regard these transformations
-themselves as the circulation of a kind of
-indestructible agent which passes from one form of
-determination to another, as if it were simply putting
-on a fresh disguise. If our intellect requires images
-or symbols to embrace the facts and to grasp their
-relation, it may introduce them here. It will materialize
-energy, it will make of it a kind of imaginary being,
-and confer upon it an objective reality. And for the
-mind, as long as it does not become the dupe of the
-phantom which it itself has created, this is an
-eminently comprehensive artifice which enables us
-to grasp readily the relations between phenomena
-and their bond of affiliation.</p>
-
-<p>The world appears to us then, as we said at the
-outset, constructed with singular symmetry. It offers
-to us nothing but transformations of matter and
-transformations of energy; these two kinds of meta<span class="pagenum" id="Page_85">[Pg 85]</span>morphoses
-being governed by two laws equally
-inevitable, the conservation of matter and the conservation
-of energy. The first of these laws expresses
-the fact that matter is indestructible, and passes
-from one phenomenal determination to another at
-a rate of equivalence measured by weight; the
-second, that energy is indestructible, and that it
-passes from one phenomenal determination to another
-at a rate of equivalence fixed for each category by
-the discoveries of the physicists.</p>
-
-
-<h4>§ 6. <span class="smcap">Transformations of Energy.</span></h4>
-
-<p>The idea of energy has become the point of departure
-of a science, <i>Energetics</i>, to the establishment of which
-a large number of contemporary physicists, among
-whom are Ostwald, Le Châtelier, etc., have devoted
-their efforts. It is the study of phenomena, regarded
-from the point of view of <i>energy</i>. I have said that it
-claims to co-ordinate and to embrace all other sciences.</p>
-
-<p>The first object of energetics should be the consideration
-of the different forms of energy at present
-known, their definition and their measurement. This
-is what we have just done in broad outline.</p>
-
-<p>In the second place, each form of energy must be
-regarded with reference to the rest, so as to determine
-if the transformation of this into that is directly
-realizable, and by what means, and, finally, according
-to what rate of equivalence. This new chapter is a
-laborious task which would compel us to traverse the
-whole field of physics.</p>
-
-<p>Of this long examination we need only concern
-ourselves here with three or four results which will be<span class="pagenum" id="Page_86">[Pg 86]</span>
-more particularly important in the case of applications
-to living beings. They refer to mechanical energy, to
-the relations of thermal energy and chemical energy,
-to the complete rôle of thermal energy, and finally to
-the extreme adaptability of electrical energy.</p>
-
-<p>1. <i>Transformation of Mechanical Energy.</i>—Mechanical
-energy may change into every other form
-of energy, and all others can change into it, with but
-one exception, that of chemical energy. Mechanical
-effort does not produce chemical combination. What
-we know of the part played by pressure in the reactions
-of dissociation seems at first to contradict
-this assertion. But this is only in appearance. Pressure
-intervenes in these operations only as <i>preliminary
-work</i> or <i>priming</i>, the purpose of which is to bring the
-bodies into contact in the exact state in which they
-must be for the chemical affinities to be able to enter
-into play.</p>
-
-<p>2. <i>Transformation of Thermal Energy; Priming.</i>—Thermal
-(or luminous) energy does not change
-directly into chemical energy. In fact, heat and light
-favour and even determine a large number of chemical
-reactions; but if we go down to the foundation of
-things we are not long before we feel assured that
-heat and light only serve in some measure for
-<i>priming</i> for the phenomenon, for preparing the
-chemical action, for bringing the body into the
-physical state (liquid, steam) or to the degree of
-temperature (400° C. for instance, for the combination
-of oxygen and hydrogen) which are the preliminary
-indispensable conditions for the entry upon the scene
-of chemical affinities.</p>
-
-<p>On the contrary, chemical energy may really be
-transformed into thermal energy. We have an<span class="pagenum" id="Page_87">[Pg 87]</span>
-instance of this in the reactions which take place
-without the aid of external energy; and again, in
-those very numerous cases which, such as the combustion
-of hydrogen and carbon, or the decomposition
-of explosives, the reactions continue when once primed.
-I may make a further observation apropos of thermal
-and photic energy. These are not two really and
-essentially distinct forms, as was thought in the early
-days of physics. When we consider things objectively,
-there is absolutely no light without heat; light and
-heat are one and the same agent. According as it is
-at this or that degree of its scale of magnitude, it
-makes a stronger impression on the skin (sensation of
-heat) or on the retina (sensation of light) of man and
-animals. The difference may be put down to the
-diversity of the work and not to that of the agent.
-The kinetic theory shows us that the agent is
-qualitatively identical. The words heat and light
-only express the chance of the meeting of the radiant
-agent with a skin and a retina. At the lowest degree
-of activity this agent exerts no action on the terminations
-of the thermal cutaneous nerves, nor on the
-optic nerve-terminations. As this degree is raised
-the former of these nerves are affected (cold, heat) and
-are so to the exclusion of the nerves of vision. Then
-they are both affected (sensation of heat and light),
-and finally, beyond that, sight alone is affected. The
-transformation of one energy into the other is therefore
-here reduced to the possibility of increasing or
-decreasing the intensity of the action of this common
-agent in the exact proportions suitable for passing
-from one of the conditions to the other; and this is
-easy when it is a question of going up the scale in the
-case of light, and, on the contrary, it is not realizable<span class="pagenum" id="Page_88">[Pg 88]</span>
-directly, that is to say without external assistance,
-when it is a question of going down the scale again, in
-the case of heat.</p>
-
-<p>3. <i>Heat a Degraded Form of Energy.</i>—We have
-seen that thermal energy is not directly transformed
-into chemical energy. There is yet another restriction
-in the case of this thermal energy if we study the laws
-which govern the circulation and the transformations
-of thermal energy; and the most important comes from
-the impossibility of transporting it from a body at
-a lower temperature to a body at a higher temperature.
-On the whole, and because of these restrictions,
-thermal energy is an imperfect variety of universal
-energy, or, as the English physicists call it, a degraded
-form.</p>
-
-<p>4. <i>Simple Transformations of Electrical Energy. Its
-Intermediary Rôle.</i>—On the other hand, electrical energy
-represents a perfected and infinitely advantageous form
-of this same universal energy, and this explains the vast
-development of its industrial applications within less
-than a century. It is not that it is better known than
-the others in its nature and in the secret of its action.
-On the contrary, there is more dispute than ever as to
-its nature. To some, electricity, which is transported
-and propagated with the speed of light, is a real flux
-of the ether as was taught by Father Secchi, who
-compared it to a current of water in a pipe. It would
-do its work, just as the water of the mill does its
-work by flowing over a wheel or through a turbine.
-Electricity, like water in this case, would not be
-an energy in itself, but a means of transporting
-energy.</p>
-
-<p>To others, such as Clausius, Hertz, and Maxwell, it
-is not so; the electric current is not a transport of<span class="pagenum" id="Page_89">[Pg 89]</span>
-energy. It is a state of the ether of a peculiar,
-specific kind, periodically produced (electric oscillation),
-and propagated with a speed of the order of
-that of light.</p>
-
-<p>However that may be, what constitutes the essential
-peculiarity of electrical energy, and what causes its
-value, is that it is an incomparable agent of transformation.
-Every known form of energy may be
-converted into it, and inversely, electrical energy may
-be changed with the utmost facility into all other
-energies. This extreme adaptability assigns to it
-the part of an intermediary between the other less
-tractable agents. Mechanical energy, for instance,
-lends itself with difficulty to the production of light,
-that is to say, to a metamorphosis into photic energy
-(a variety of thermal energy). A fall of water cannot
-be directly utilized for lighting purposes. The
-mechanical work of this fall, which cannot be
-exploited in its present form, serves to set in
-motion in industrial lighting the installations, the
-electric machines, and the dynamos which feed the
-incandescent lamps. Mechanical work is changed
-into electrical energy, and it, in its turn, into thermal
-or photic energy. Electricity has here played the part
-of a useful intermediary.</p>
-
-<p>The last part of energetics must be consecrated to
-the study of the general principles of this science.
-These principles are two in number, the principle of
-the <i>conservation of energy</i>, or Mayer’s principle, and
-the principle of the transformation of energy, or
-Carnot’s principle. The doctrine of energy thus
-reduces to two fundamental laws the multitude of
-laws, often known as “general,” to which natural
-science is subject.</p>
-
-<p><span class="pagenum" id="Page_90">[Pg 90]</span></p>
-
-
-<h4>§ 7. <span class="smcap">The Principle of the Conservation
-of Energy.</span></h4>
-
-<p>In all that precedes, the principle of conservation has
-intervened at every step. In fact, the very idea of
-energy is connected with the existence of this principle.
-We first discover the idea in the work of the philosophical
-mathematicians who established the foundations
-of mechanics:—Newton, Leibniz, d’Alembert,
-and Helmholtz; or of inductive physicists such as
-Lord Kelvin. Its experimental proof, sketched by
-Marc Seguin and R. Mayer, is due to Colding and
-Joule.</p>
-
-<p><i>It is Independent of the Kinetic Theory.</i>—Mayer’s
-law states that energy is indestructible; that all
-phenomenality is nothing but a transformation of
-energy from one form to another, and that this
-transformation takes place either at equal values,
-or rather, at a certain rate of equivalence. This is
-what takes place when thermal energy is transformed
-into mechanical energy (equivalent 425). This rate
-of equivalence is fixed by the researches of physicists
-for each category of energy.</p>
-
-<p>It will be noticed that this law and this theory of
-energy, which is always presented by authors of
-elementary books as a consequence of the kinetic
-theory, is quite independent of it. In the preceding
-lines we have not even mentioned its name. We
-have not assumed that all phenomena are movements
-or transformations of movements, whether sensible or
-vibratory; we have not affirmed that what was
-passing from one phenomenal determination to
-another was the <i>vis viva</i> of the motion, as is the case<span class="pagenum" id="Page_91">[Pg 91]</span>
-in the impact of elastic bodies. No doubt the kinetic
-theory affords us a very striking image of these truths
-which are independent of it; but it may be false: and
-the theory of energy which assumes the minimum of
-possible hypotheses would yet be true.</p>
-
-<p><i>It contains a great many other Principles.</i>—The
-principle of the conservation of energy contains
-a large number of the most general principles of
-science. It may be shown without much difficulty
-that, for example, it contains the principle of the
-inertia of matter, laid down by Galileo and Descartes;
-that of the equality of action and reaction, due to
-Newton; and even that of the conservation of matter,
-or rather of mass, due to Lavoisier. And finally, it
-contains the experimental law of equivalence connected
-with the name of the English physicist Joule,
-from which may be derived the Law of Hess and the
-principle of the initial and final states which we owe
-to Berthelot.</p>
-
-<p><i>It involves the Law of Equivalence.</i>—Here we may
-be content with noticing that the law of the conservation
-of energy involves the existence of relations of
-equivalence between the different varieties. A certain
-quantity of a given energy, measured, as we have
-seen, by the product of two factors, is equivalent to a
-certain fixed quantity of quite a different form of
-energy into which it may be converted. The laws
-which govern energetic transformations therefore contain,
-from both the qualitative and the quantitative
-points of view, all the connections of the phenomena
-of the universe. To study these laws in their detail is
-the task that physics must take upon itself.</p>
-
-<p>The conversion one into the other of the different
-forms of energy by means of equivalents is only a<span class="pagenum" id="Page_92">[Pg 92]</span>
-possibility. It is subject, in fact, to all sorts of
-restrictions, of which the most important are due to
-the second principle.</p>
-
-
-<h4>§ 8. <span class="smcap">Carnot’s Principle. Its Generality.</span></h4>
-
-<p>The second fundamental principle is that of the
-transformations of equilibrium, or of the conditions
-of reversibility, or again, Carnot’s principle. This
-principle, which first assumed a concrete form in
-thermodynamics, has been very widely extended. It
-has reached a degree of generality such that contemporary
-theoretical physicists such as Lord Kelvin, Le
-Châtelier, etc., consider it the universal law of
-physical, mechanical, and chemical equilibrium.</p>
-
-<p>Carnot’s principle contains, as was shown by G.
-Robin, d’Alembert’s principle of virtual velocities,
-and according to physicists of to-day, as we have just
-remarked, it contains the laws peculiar to physico-chemical
-equilibrium. The application of this principle
-gives us the differential equations from which
-are derived numerical relations between the different
-energies, or the different modalities of universal
-energy.</p>
-
-<p><i>Its Character.</i>—It is very remarkable that we cannot
-give a general enunciation of this principle which
-by its revealing power has changed the face of
-physics. This is because it is less a law, properly so
-called, than a method or manner of interpreting the
-relations of the different forms of energy, and particularly
-the relations of heat and mechanical energy.</p>
-
-<p><i>Conversion of Work into Heat and Vice-versâ.</i>—The
-conversion of work into heat is accomplished without
-difficulty. For example, the hammering of a piece of<span class="pagenum" id="Page_93">[Pg 93]</span>
-iron on an anvil may bring it to a red heat. A shell
-which passes through an armour plate is heated, and
-melts and volatilizes the metal all round the hole it
-has made. By utilizing mechanical action under the
-form of friction all energy can be converted into heat.</p>
-
-<p>The inverse transformation of heat into work, on
-the contrary, cannot be complete. The best motor
-that we can think of, and <i>à fortiori</i> the best we can
-realize, can only transform a third or a fourth of the
-heat with which it is supplied.</p>
-
-<p>This is an extremely important fact. It is of incalculable
-importance to natural philosophy, and may
-be ranked among the greatest discoveries.</p>
-
-<p><i>Higher and Degraded Forms of Energy.</i>—Of these
-we may give an account by distinguishing among the
-forms of universal energy <i>higher forms</i>, and <i>lower</i> or
-<i>degraded forms</i>. Here we have the principle of the
-<i>degradation of energy</i> on its trial, and it may be
-regarded as a particular aspect of the second principle
-of energetics, or Carnot’s principle. Mechanical
-energy is a higher form. Thermal energy is a lower
-form, a degraded form, and one which has degrees in
-its degradation. Higher energy, in general, may be
-completely converted into lower energy; for example,
-work into heat: the slope is easy to descend, but it is
-difficult to retrace our steps; lower energy can be
-only partially transformed into higher energy, and the
-fraction thus utilizable depends upon certain conditions
-on which Carnot’s principle has thrown considerable
-light.</p>
-
-<p>Thus, although in theory the thermal energy of a
-body may have its equivalent in mechanical energy,
-the complete transformation is only realizable from
-the latter to the former, and not from the former to<span class="pagenum" id="Page_94">[Pg 94]</span>
-the latter. This is due to a condition of thermal
-energy which is called <i>temperature</i>. The same
-quantity of thermal energy, of heat, may be stored
-in the same thermal body at different temperatures.
-If this quantity of thermal energy is in a very hot
-body we can utilize a large portion of it; if it is in a
-relatively cold body we can only convert a small
-portion of it into mechanical work. Thus the value
-of energy,—<i>i.e.</i>, its capacity of being converted into
-a higher and more useful form,—depends on temperature.</p>
-
-<p><i>The Capacity of Conversion depends on Temperature.</i>—The
-conversion of heat into work assumes two
-bodies of different temperatures, the one warm and
-the other cold; a boiler and a condenser. Every
-thermal machine conveys a certain amount of heat
-from the boiler to the condenser, and what is not thus
-carried is changed into work. This residue is only a
-small fraction, a quarter, or at most a third of the
-heat employed, and that, too, in the theoretically
-perfect machine, in the ideal machine.</p>
-
-<p>This output, this utilizable fraction depends on the
-fall of temperature from the higher to the lower level,
-just as the work of a turbine depends on the height
-of the waterfall which passes through it. But it also
-depends on the conditions of this fall, on the
-accessory losses from radiation and conduction.
-However, Carnot has shown that the output is the
-same, and a maximum for the same fall of temperature,
-whatever be the working agent (steam, hot air, etc.),
-and whatever be the machine—provided that this
-agent, this substance which works is not exposed to
-accessory losses, that it is never in contact with a
-body having temperature different to its own—or<span class="pagenum" id="Page_95">[Pg 95]</span>
-again, that it is connected only with bodies impermeable
-to heat.</p>
-
-<p>This is Carnot’s principle in one of its concrete
-forms.</p>
-
-<p>A machine which realizes this condition, that the
-agent (steam, alcohol, ether) is in relation, at all
-phases of its function, with bodies which can neither
-take heat from it nor give heat to it, is a <i>reversible
-machine</i>. Such a machine is perfect. The fraction
-of heat that it transforms into motion is constant; it
-is a maximum; it is independent of the motor, of its
-organs, of the agent: it accurately expresses the
-transformability of the heat agent into a mechanical
-agent under the given conditions.</p>
-
-<p><i>The Degradation and Restoration of Energy.</i>—The
-fraction not utilized, that which is carried to the
-condenser at a lower temperature, is <i>degraded</i>. It
-can only be used by a new agent, in a new machine
-in which the boiler has exactly the same temperature
-as the condenser in the first machine, and the new
-condenser has a lower temperature, and so on. The
-proportion of utilizable energy thus goes on diminishing.
-Its utilization requires conditions more and
-more difficult to realize. The thermal energy loses its
-potential and its value, and is further and further degraded
-as its temperature approaches that of the
-surrounding medium.</p>
-
-<p>The degraded energy, theoretically, has kept its
-equivalent value but, practically, it is incapable of
-conversion. However, it is shown in physics that it
-can be raised and re-established at its initial level.
-But for that purpose another energy must be utilized
-and degraded for its benefit.</p>
-
-<p><i>The End of the Universe.</i>—What we have just<span class="pagenum" id="Page_96">[Pg 96]</span>
-seen with respect to heat and motion is to some
-degree true of all other forms of energy, as Lord
-Kelvin has shown. The principle of the degradation
-of energy is very general. Every manifestation of
-nature is an energetic transformation. In each of
-these transformations there is a degradation of energy—<i>i.e.</i>,
-a certain fraction is lowered and becomes less
-easily transformable. So that the energy of the
-universe is more and more degraded; the higher
-forms are lowered to the thermal form, the latter
-increasing at temperatures which become more and
-more uniform. The end of the universe, from this
-point of view, would then be unity of (thermal) energy
-in uniformity of temperature.</p>
-
-<p><i>Importance of the Idea of Energy in Physiology.</i>—I
-have said that the application of Carnot’s principle
-furnished numerical relations between the different
-energetic transformations.</p>
-
-<p>The science of living beings has not yet reached
-that point of development at which it is possible for
-us to obtain its numerical relations. However, the
-consideration of energy and the principle of conservation
-has altered the outlook of physiology on many
-questions which are of the highest importance.</p>
-
-<p>The determination of the sources from which plants
-and animals draw their vital energies; the mediate
-transformation of chemical energy into animal heat in
-nutrition, or into motion in muscular contraction; the
-chemical evolution of foods; the study of soluble
-ferments—all these questions are of considerable
-importance when we wish to understand the
-mechanisms of life. They are therefore departments
-of physiological energetics in which great
-advances have already been made.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_97">[Pg 97]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_II_2">CHAPTER II.<br />
-
-<small>ENERGY IN BIOLOGY.</small></h3></div>
-
-
-<p class="prel">§ 1. Energy in Living Beings.—§ 2. The First Law of Biological
-Energetics:—All Vital Phenomena are Energetic Transformations.—§ 3. Second
-Law:—The Origin of Vital
-Energy is in Chemical Energy. Functional Activity and
-Destruction.—§ 4. Third Law:—The Final Form of
-Energetic Transformation in the Animal is Thermal
-Energy. Heat is an Excretum.</p>
-
-
-<p>The theory of energy was thought of and utilized in
-physiology before it was introduced into physics, in
-which it has exercised such an extraordinary influence.
-Robert Mayer was a physicist and a doctor. Helmholtz
-was equally at home in physiology and in physics.
-From the outset both had seen in this new idea a
-powerful instrument of physiological research. The
-volume in which Robert Mayer expounded, in 1845,
-his remarkable views on organic movement in relation
-to nutrition, and Helmholtz’ commentary leave us in
-no doubt in this respect. The essay on the mechanical
-equivalent of heat, of a more particularly physical
-character, is six years later than the earlier work.</p>
-
-<p><i>The Relations between Energetics and Biology.</i>—The
-theory of energy is therefore only returning to
-its cradle; and to that cradle it returns with all the
-sanction of physical proof, as the most general theory<span class="pagenum" id="Page_98">[Pg 98]</span>
-ever proposed in natural philosophy, and the theory
-least encumbered with hypotheses. It reduces all
-particular laws to two fundamental principles—that
-of the conservation of energy, which contains the
-principles of Galileo and Descartes, of Newton, of
-Lavoisier, Joule’s law, Hess’s law, and Berthelot’s
-principle of the initial and final states; and also
-Carnot’s principle, from which are deduced the laws
-of physico-chemical and chemical equilibrium. These
-two principles therefore sum up the whole of natural
-science. They express the necessary relation of all
-the phenomena of the universe, their uninterrupted
-gentic connection, and their continuity.</p>
-
-<p><i>A priori</i> there would be little likelihood that a
-doctrine, so universal and so thoroughly verified in
-the physical world, could be restricted, and thus
-be useless to the living world. Such a supposition
-would be contrary to the scientific method, which
-always tends to the generalization and the explanation
-of elementary laws. The human mind has always
-proceeded thus: it has applied to the unknown
-order of living phenomena the most general laws of
-contemporary physics.</p>
-
-<p>This application has been found legitimate, and has
-been justified by experiment whenever it has been a
-question of the laws or of the really fundamental or
-elementary conditions of phenomena. It has, on the
-other hand, however, been unfortunate when it has
-stopped short of secondary characteristics. When we
-now concede the subjection of living beings to these
-general laws of energetics, we are following a
-traditional method. There is no doubt that this
-application is legitimate, and that experiment will
-justify it <i>a posteriori</i>.</p>
-
-<p><span class="pagenum" id="Page_99">[Pg 99]</span></p>
-
-<p>I will therefore grant, as a provisional <i>postulate</i>,
-the consequences of which will have to be ultimately
-justified, that the living and inanimate world alike
-show us nothing but <i>transformations of matter</i> and
-<i>transformations of energy</i>. The word phenomenon
-will have no other signification, whatever be the
-circumstances under which the phenomenon occurs.
-The varied manifestations which translate the activity
-of living beings thus correspond to transformations of
-energy, to conversions of one form into another, in
-conformity with the rules of equivalence laid down by
-the physicists. This conception may be formulated
-in the following manner:—<i>The phenomena of life have
-the same claim to be energetic metamorphoses as the
-other phenomena of nature</i>.</p>
-
-<p>This postulate is the foundation of biological
-energetics. It may be useful to give some explanation
-relative to the signification, the origin, and
-the scope of this statement.</p>
-
-<p>Biological energetics is nothing but general physiology
-reduced to the principles that are common to all
-the physical sciences. Robert Mayer and Helmholtz
-gave the best description of this science, and laid
-down its limits by defining it as “the study of the
-phenomena of life regarded from the point of view
-of energy.”</p>
-
-
-<h4>§ 1. <span class="smcap">Energy at play in Living Beings.
-Common or Physical Energies. Vital
-Energies.</span></h4>
-
-
-<p>Our first object will be to define and to enumerate the
-energies at play in living beings; to determine their
-more or less easy transformations from one to another,<span class="pagenum" id="Page_100">[Pg 100]</span>
-to bring to light the general laws which govern those
-transformations, and finally to apply them to the
-detailed study of phenomena. This programme may
-be divided into four parts.</p>
-
-<p>In the physical world the specific forms of energy
-are not numerous. When we have mentioned
-mechanical, chemical, radiant (thermal and photic)
-energies, electrical energy, with which is blended
-magnetic energy, we have exhausted the catalogue of
-natural agents.</p>
-
-<p>But is this list for ever closed? Are vital energies
-comprised in this list? These are the first questions
-which we must ask ourselves.</p>
-
-<p>The iatro-mechanical school, on <i>a priori</i> grounds
-give an affirmative answer. No doubt there are in the
-living organism many manifestations which are pure
-physical manifestations of known energies, mechanical,
-chemical, thermal, etc. But are all the manifestations
-of the living being of this order? Are they all, henceforth,
-reducible to the categories and varieties of energy
-which are investigated in physics? This is the claim
-of the mechanical school. But the claim is rash. Our
-fundamental postulate affirms, in principle, that universal
-energy is manifested in living beings; but, as a
-matter of fact, there is no reason for the assertion that
-it does not assume particular forms, according to the
-circumstances peculiar to the conditions under which
-they are produced.</p>
-
-<p>These <i>special forms of energy</i> manifested in the conditions
-suitable to living beings would swell the list
-drawn up by the physicists. And it would not be the
-first instance of an extension of this kind. The
-history of science records many remarkable cases.
-Scarcely a century has passed since we first heard of<span class="pagenum" id="Page_101">[Pg 101]</span>
-electrical energy. This discovery in the world of
-energy, which took place, so to speak, before our
-very eyes, of an agent which plays so large a part
-in nature, clearly leaves the door open to other
-surprises.</p>
-
-<p>We shall therefore concede that there may be
-other forms of energy at work in living beings than
-those we already know in the physical world. This
-reservation would enable us to discover at once the
-essential characteristics by which vital phenomena
-are henceforth reduced to universal physics, and
-the purely formal differences still distinguishing
-them.</p>
-
-<p>If there are really special energies in living beings,
-our monistic postulate leads us to assert that these
-energies are homogeneous with the others, and that
-they do not differ from them more than they differ
-among themselves. It is probable that some day
-they will be discovered external to living bodies, if
-the material conditions (which it is always possible to
-imagine) are realized externally to them. And if we
-must admit that the peculiarity of the medium is
-such that these forms must remain indefinitely
-peculiar to living beings, we may assert with every
-confidence that these special energies do not obey
-special laws. They are subject to the two fundamental
-principles of Robert Mayer and Carnot.
-They are exchanged according to fixed laws with
-the other physical forms of energies at present
-known.</p>
-
-<p>To sum up, then, we must establish three categories
-in the forms of energy which express the phenomena
-of vitality.</p>
-
-<p>In the first place, most of these energies are those<span class="pagenum" id="Page_102">[Pg 102]</span>
-which have already been studied and recognized in
-general physics. They are the same energies:
-chemical, thermal, mechanical, with their characteristics
-of mutability, their lists of equivalents,
-and their actual and potential stales.</p>
-
-<p>In the second place, it may happen, and it probably
-will happen, as it happened in the last century
-in the case of electricity, that some new form of
-energy will be discovered belonging to the universal
-order as to the living order. This will be a conquest
-of general physics as well as of biology.</p>
-
-<p>And finally we may rigorously and provisionally
-admit a last category of <i>vital energies properly so
-called</i>.</p>
-
-<p>It is difficult to give much precision to the idea of
-<i>vital energies properly so called</i>.</p>
-
-<p>It will be easier to measure them by means of
-equivalents than to indicate their nature. Besides,
-this is the ordinary rule in the case of physical agents.
-We can measure them, although we know not what
-they are.</p>
-
-<p><i>Characteristics of Vital Energies.</i>—We see why we
-cannot exhibit with precision, <i>a priori</i>, the nature of
-vital energies. In the first place, they are expressed
-by what takes place in the tissues in activity, and
-this cannot at present be identified with the known
-types of physical, chemical, and mechanical phenomena.
-This is a first, intrinsic reason for not being
-able to distinguish them readily, since what takes
-place is not distinguished by the phenomenal appearances
-to which we are accustomed.</p>
-
-<p>There is a second, intrinsic reason. These vital
-phenomena are intermediary, as we shall see, between
-manifestations of known energies. They lie between<span class="pagenum" id="Page_103">[Pg 103]</span>
-a chemical phenomenon which always precedes them,
-and a thermal phenomenon which always follows
-them. They are lost sight of, as it were, between
-manifestations which strike our attention. Generally
-speaking, intermediary energies often escape us
-even in physics. Only the extreme manifestations
-are clearly seen. In the presence of the organism
-we are, as it were, in electric lighting works which
-are run by a fall of water, and at first we only
-see the mechanical energy of the falling water,
-of the turbine and dynamo at work, and the
-photic energy of the lamps which give the light.
-Electrical energy, an intermediary, which has only
-a transient existence, does not impose itself on our
-attention.</p>
-
-<p>And so <i>vital energies</i> for this twofold reason, intrinsic
-and extrinsic, are not readily apparent. To
-reveal them, the careful analysis of the physiologists
-is required. They are acts, in most cases silent and
-invisible, which we should scarcely recognize but by
-their effects, after they have terminated in familiar,
-phenomenal forms. This is, for example, what goes
-on in the muscle in process of shortening, in the nerve
-carrying the nervous influx, in the secreting gland.
-And this is what constitutes the different forms of
-energy which we call <i>vital properties</i>. M. Chauveau
-and M. Laulanié use the phrase <i>physiological work</i>
-to distinguish them. <i>Vital energy</i> would be preferable.
-It better expresses the analogy of this special
-form with the other forms of universal energy; it
-helps us better to understand that we must henceforth
-consider it as exchangeable by means of
-equivalents with the energies of the physical world
-just as they are exchangeable one with another.</p>
-
-<p><span class="pagenum" id="Page_104">[Pg 104]</span></p>
-
-
-<h4>§ 2. <span class="smcap">First Law of Biological Energetics.</span></h4>
-
-
-<p>It is easy to understand, after these remarks, the
-significance and the scope of this assertion which
-contains the first principle of biological energetics—namely,
-that the phenomena of life have the same
-claim to be called energetic metamorphoses as the
-other phenomena of nature.</p>
-
-<p><i>Irreversibility of Vital Energies.</i>—However, there
-is one characteristic of vital energies which deserves
-the closest attention. Their transformations have a
-direction which is in some measure inevitable. They
-descend a slope which they never re-ascend. They
-appear to be irreversible. Ostwald has rightly insisted
-on this fundamental characteristic, which no
-doubt is not that of all the phenomena of the living
-being without exception, but which is certainly that of
-the most essential phenomena. There are reversible
-phenomena in organisms; there are energetic transformations
-which may take place from one form of
-energy to another, or <i>vice versâ</i>. But the most
-characteristic phenomena of vitality do not act in
-this way. We shall presently see that most functional
-physiological acts begin with chemical and end with
-thermal action. The series of energetic transformations
-takes place in an inevitable direction, from
-chemical to thermal energy. The order of succession
-of ordinary energies is thus determined in the machine
-of the organism, and therefore by the conditions of
-the machine. The order of transformation of vital
-energies is still more rigorously regulated, and the
-phenomena of life evolve from childhood to ripened
-years, and thence to old age, without a possible
-return.</p>
-
-<p><span class="pagenum" id="Page_105">[Pg 105]</span></p>
-
-<p>The laws of biological energetics are three in number.
-First of all, there is the fundamental principle
-which we have just developed, and which is, so to
-speak, laid down <i>a priori</i>; and there are two other
-principles, those established by experiment and
-summing-up, as it were, the multitude of known
-physiological effects. Of these two experimental
-laws, one refers to the <i>origin</i> and the other to the
-<i>termination of the energies developed in living beings</i>.</p>
-
-
-<h4>§ 3. <span class="smcap">Second Law of Biological Energetics.</span></h4>
-
-
-<p><i>The Origin of Vital Energy.</i>—Vital energies have
-their origin in one of the <i>external or common energies</i>—not
-in any one we choose, as might be supposed,
-but in one only: chemical energy. The third principle
-will show us that they terminate in another energy or
-a few others, also completely fixed.</p>
-
-<p>It follows that the phenomena of life must appear
-to us to be a circulation of energy which, starting from
-one fixed point in the physical world, returns to that
-world by a few points, also fixed, after a transient
-passage through the animal organism.</p>
-
-<p>Or more precisely, it is a transposition from the
-realm of matter into the world of energy, of the idea
-of the <i>vital vortex</i> of Cuvier and the biologists.
-They defined life by its most constant property—nutrition.
-Nutrition was exactly this current of
-matter which the organism obtains from without by
-alimentation, and which it throws out again by excretion;
-and the even momentary interruption of
-which, if complete, would be the signal of death.
-The cycle of energy is the exact counterpart of
-this cycle of matter.</p>
-
-<p><span class="pagenum" id="Page_106">[Pg 106]</span></p>
-
-<p>The second truth taught us by general physiology,
-a truth which physiology learned from experiment, is
-enunciated as follows:—<i>The maintenance of life consumes
-none of its energy. It borrows from the external
-world all the energy which it expends, and borrows it in
-the form of potential chemical energy.</i> This is a translation
-into the language of energetics of the results
-acquired in animal physiology during the last fifty years.
-No comment is needed to exhibit the importance of
-such a truth. It reveals the origin of animal activity.
-It reveals the source from which proceeds that energy
-which at some moment of its transformations in the
-animal organism will be a <i>vital energy</i>.</p>
-
-<p>The <i>primum movens</i> of vital activity is, therefore,
-according to this law, the chemical energy stored up
-in the immediate principles of the organism.</p>
-
-<p>Let us try to follow, for a moment, this energy
-through the organism and to specify the circumstances
-of its transformations.</p>
-
-<p><i>Organic Functional Activity, and the Destruction of
-Reserve-stuff.</i>—Let us suppose then, for this purpose,
-that our attention is directed to a given limited part
-of this organism, to a certain tissue. Let us seize
-it, so to speak, by observation at a given moment,
-and let us make an examination of the functional
-activity starting from this conventional moment.
-This functional activity, like all other vital phenomena,
-will be the result, as we have just explained, of
-a transformation of the potential chemical energy
-contained in the materials held in reserve in the
-tissue. This is our first perceptible fact. This
-energy, when disengaged, will furnish to the vital
-action the means by which it may be prolonged.</p>
-
-<p>There is, then, a <i>functional destruction</i>. There is, at<span class="pagenum" id="Page_107">[Pg 107]</span>
-the beginning of the functional process, and by a
-necessary effect of that very process, a liberation of
-chemical energy; and that can only take place by a
-decomposition of the immediate principles of the
-tissue, or, as we may say, by a destruction of organic
-material. Claude Bernard insisted on this consideration,
-that the vital function is accompanied by a
-destruction of organic material. “When a movement
-is produced, when a muscle is contracted, when
-volition and sensibility are manifested, when thought
-is exercised, when a gland secretes, then the substance
-of the muscles, of the nerves, of the brain, of the
-glandular tissue, is disorganized, is destroyed, and is
-consumed.” Energetics enables us to grasp the
-deeply-seated reason of this coincidence between
-chemical destruction and the functional activity, the
-existence of which Claude Bernard intuitively suspected.
-A portion of organic material is decomposed,
-is chemically simplified, becomes less complex, and
-loses in this kind of descent the chemical energy
-which it contained in its potential state. It is this
-energy which becomes the very texture of the vital
-phenomenon.</p>
-
-<p>It is clear that the reserve of energy thus expended
-must be replaced, because the organism remains in
-equilibrium. Alimentation provides for this.</p>
-
-<p>How does it provide for it? This is a question
-which deserves detailed examination. We cannot
-incidentally treat it in full; we can only indicate its
-main features.</p>
-
-<p><i>How the supply of Reserve Stuff is kept up.</i>—We
-know that food does not directly replace the reserve
-of energy consumed by the functional activity. It is
-not its potential chemical energy which replaces,<span class="pagenum" id="Page_108">[Pg 108]</span>
-purely and simply, the energy brought into play,
-consumed, or, better still, transformed in the active
-organ, or tissue. Food as it is introduced, inert food,
-does not, in fact, take up its place <i>as it is</i>, without
-undergoing changes in that organ and that tissue, in
-order to restore the <i>status quo ante</i>.</p>
-
-<p>Before building up the tissue it will have undergone
-various modifications in the digestive apparatus. It
-will have also undergone changes in the circulatory
-apparatus, in the liver, and in the very organ we are
-considering. It is after all these changes that assimilation
-takes place. It will find its place and will have
-then passed into the state of <i>reserve</i>.</p>
-
-<p>The food digested, modified, and finally incorporated
-as an integral part in the tissue in which it will be expended,
-is therefore in a new state, differing more or
-less from its state when it was ingested. It is a part
-of the living tissue in the state of constitutive reserve.
-Its potential chemical energy is not the same as that
-of the food introduced. It may differ from it very
-remarkably in consequence of sudden alterations.</p>
-
-<p>We do not know for certain at the expense of what
-category of foods this or that given organ builds up
-its reserve stuff. There is a belief, for instance,
-according to M. Chauveau, that the muscle does its
-work at the expense of the reserve of glycogen which
-it contains. The potential chemical energy of this
-substance would be a source of muscular mechanical
-energy. But we do not know exactly at the expense
-of what foods, albumenoids, fats, or carbohydrates
-the muscle builds up the reserve of <i>glycogen</i> expended
-during its contraction. It is probable that it builds it
-up at the expense of each of the three categories after
-the various more or less simple alterations undergone<span class="pagenum" id="Page_109">[Pg 109]</span>
-by the materials in the digestive tube, the blood, the
-liver, or other organs.</p>
-
-<p>This building up of reserve stuff, the complement
-and counterpart of <i>functional destruction</i>, is not chemical
-synthesis. It is, on the contrary, generally, and
-on the whole, a simplification of the food that has
-been introduced. This is true, at least as far as the
-muscle is concerned. However, to this operation,
-Claude Bernard has given the name of <i>organizing
-synthesis</i>, but the phrase is not a happy one. But
-in no case was the eminent physiologist deceived
-as to the character of the operation. “The organizing
-synthesis,” says he, “remains internal, silent,
-hidden in its phenomenal expression, gathering
-together noiselessly the materials which will be
-expended.”</p>
-
-<p>These considerations enable us to understand the
-existence of the two great categories into which the
-eminent physiologist divides the phenomena of animal
-life: the phenomena of the <i>destruction of reserve-stuff</i>
-corresponding to <i>functional facts</i>—that is to say
-expenditures of energy; and the <i>plastic phenomena</i> of
-the <i>building-up of reserves</i> of organic regeneration, corresponding
-to <i>functional repose</i>—<i>i.e.</i>, to the supply of
-food to the tissues.</p>
-
-<p><i>Distinction between Active Protoplasm and Reserve-stuff.</i>—If
-it is not exactly in these terms that Claude
-Bernard formulated this fruitful idea, it is at any
-rate in this way that it is to be interpreted. This
-can be done by giving it a little more precision.
-We apply more rigorously than that great physiologist
-the distinction drawn by himself between <i>really
-active and living protoplasm</i> and the <i>reserve-stuff</i>
-which it prepares. To the latter is restricted the<span class="pagenum" id="Page_110">[Pg 110]</span>
-destruction by the functional activity and the building
-up by repose.</p>
-
-<p>The classification of Claude Bernard is strictly true
-for reserve-stuff. It is easy to criticize the wavering
-and, as it were, dimly groping expressions in
-which the celebrated physiologist has shrouded his
-ideas. The old adage will excuse him: <i>Obscuritate
-rerum verba obscurantur</i>. In the depths of his ignorance
-he had a flash of genius; perhaps he did not find
-the definitive and, as it were, clearly-cut formula defining
-what was in his mind. But, in this respect, he
-has left his successors an easy task.</p>
-
-<p><i>The Law of Functional Assimilation.</i>—The progress
-of physiological knowledge compels us therefore to
-distinguish in the constitution of anatomical elements
-two parts—the materials of <i>reserve-stuff</i> and the <i>really
-active</i> and <i>living protoplasm</i>. We have just seen how
-the reserve-stuff behaves, alternately destroyed by
-functional activity, and built up afterwards by the
-ingestion of food, followed by the operations of digestion,
-elaboration, and assimilation. It remains to
-ask how this really living and protoplasmic matter
-behaves. Does it follow the same law? Is it destroyed
-during the functional activity, and is it afterwards
-replaced? As to this we can express no
-opinion. M. le Dantec fills a gap in our knowledge,
-in this respect, by an hypothesis. He assumes that
-this essentially active matter grows during functional
-activity, and is destroyed during repose. This is what
-he calls the <i>law of functional assimilation</i>. The
-protoplasm would therefore behave in an exactly
-contrary manner to the reserve-stuff. It will be its
-counterpart. But this is only an hypothesis which,
-in the present state of our knowledge, cannot be<span class="pagenum" id="Page_111">[Pg 111]</span>
-verified by experiment We are at liberty to
-assert either that the protoplasm increases by
-functional activity or that it is destroyed. Neither
-the arguments nor the objections pro or con have any
-decisive value. The facts alleged on either side are
-capable of too many interpretations.<a id="FNanchor_10" href="#Footnote_10" class="fnanchor">[10]</a></p>
-
-<p>The only favourable argument (not demonstrative)
-is furnished by energetics. It is this. The <i>re-building
-of the protoplasm</i> is not like the <i>organisation of reserve-stuff</i>,
-a slightly complicated or even simplified phenomenon,
-as happens in the case of the reserve of
-muscular glycogen. The glycogen, in fact, is built up
-at the expense of foods chemically more complex.
-It is, on the contrary, a clearly synthetic phenomenon,
-certainly of chemical complexity, since it ends
-in building up the active protoplasm which is, in some
-measure, of the highest scale of complexity. Its formation
-at the expense of the simplest alimentary
-materials requires, therefore, an appreciable quantity
-of energy.</p>
-<p><span class="pagenum" id="Page_112">[Pg 112]</span></p>
-<p>The assimilation which organizes the active protoplasm
-therefore requires energy for its realization.
-Now, at the moment of functional activity, and by a
-necessary consequence thereof, the chemical destruction
-or simplification of the substance of reserve takes
-place. Here is something that meets the case, and
-we may note the coincidence. It does not mean that
-the disposable energy is really used to increase the
-protoplasm, nor that the protoplasm itself is thereby
-increased. It merely signifies that the wherewithal
-exists to provide for that increase if it takes place.</p>
-
-<p>It is therefore <i>possible</i> that the active protoplasm
-follows the law of functional assimilation; but it is
-<i>certain</i> that the reserve-stuff follows the law laid down
-by Claude Bernard.</p>
-
-<p>All these considerations definitely result in the
-confirmation of this second law of general physiology,
-according to which all vital energies are borrowed
-from the potential chemical energy of the reserve-stuff
-of alimentary origin.</p>
-
-
-<h4>§ 4. <span class="smcap">The Third Law of Biological Energetics.</span></h4>
-
-
-<p>The third law of biological energetics is also drawn
-from experiment. It relates no longer to the point of
-departure of the cycle of animal energy, but to its
-final position. <i>The energetic transformations of the
-animal end in thermal energy.</i></p>
-
-<p>This is the most novel part of the theory, and, if we
-may say so, that least understood by physiologists
-themselves. The energy resulting from the chemical
-potential of food, having passed through the organism
-(or simply through the organ which we are considering
-in action), and having given rise to phenomenal appearances
-more or less diversified, more or less dim or
-clear, obscure or obvious, which are the characteristic
-or still irreducible manifestations of vitality, finally<span class="pagenum" id="Page_113">[Pg 113]</span>
-returns to the physical world. This return takes
-place (with certain exceptions which will be presently
-indicated) under the ultimate form of thermal energy.
-This we are taught by experiment. The phenomena
-of functional activity are exothermal.</p>
-
-<p>Real vital phenomena thus lie between the chemical
-energy which gives rise to them, and the thermal
-phenomena to which they in their turn give rise. The
-place of the vital fact in the cycle of universal energy
-is therefore completely determined. This conclusion
-is of the utmost importance to biology. It may be
-expressed in a concise formula which sums up in a
-few words all that natural philosophy can teach as to
-energetics applied to living beings. “Vital energy is
-a transformation of chemical energy into thermal
-energy.”</p>
-
-<p><i>Exceptions.</i>—There are some exceptions to the
-rigour of this statement, but they are not many in
-number. We must first of all remark that it applies
-to <i>animal life</i> alone.</p>
-
-<p>In the case of vegetables, looked at as a whole, the
-law must be modified. Their vital energy has another
-origin, and another final form. Instead of being the
-destroyers of chemical potential energy, they are its
-creators. They build up by means of the inert and
-simple materials afforded them by the atmosphere
-and the soil, the immediate principles by which their
-cells are filled. Their vital functional activity forms by
-synthesis of the reserves, carbo-hydrates (sugars and
-starches), fats, albuminoid nitrogenous materials—that
-is to say, the same three principal categories of foods
-as those used by animals.</p>
-
-<p>And to return to the latter, it should be observed
-that thermal energy is not the only final form of vital<span class="pagenum" id="Page_114">[Pg 114]</span>
-energy, as this dogmatic statement would have it
-supposed. It is only the principle of the final forms.
-The cycle of energy occasionally terminates in
-mechanical energy (phenomena of motion) and in
-a less degree in other energies; such as, for example,
-the electrical energy produced by the functional activity
-of the nerves and muscles in all animals, or in the
-functional activity of special organs in rays, torpedo-fish,
-and the malapterurus electricus, or finally, in the
-photic energy of phosphorescent animals. But these
-are secondary facts.</p>
-
-<p><i>Heat is an Excretum.</i>-The third principle of biological
-energetics may be therefore thus enunciated:—<i>Vital
-energy in its final form becomes thermal energy.</i>
-This principle teaches us that if chemical energy is
-the primitive generating form of vital energies,
-thermal energy is the form of waste, of emunctory,
-the degraded form as the physicists would say. Heat
-is in the dynamical order an excretion of animal
-life, as urea, carbonic acid and water, are excreta in
-the substantial order. By a false interpretation of
-the principle of the mechanical equivalence of heat, or
-through ignorance of Carnot’s principle, certain
-physiologists have fallen into error when they still
-speak of the transformation of heat into motion or into
-into electricity in the animal organism. Heat is transformed
-into nothing in the animal organism. It is dissipated.
-Its utility arises not from its energetic value,
-but from the part it plays as a primer in the chemical
-reactions, as has been explained with reference to the
-general characteristics of chemical energy.</p>
-
-<p><i>The Effect of Energetics on our Knowledge of the
-Relations of the Universe.</i>—The consequences of these
-principles of energetic physiology, which give us so<span class="pagenum" id="Page_115">[Pg 115]</span>
-much and which are so clear, are of the greatest
-importance from the practical as well as from the
-theoretical point of view.</p>
-
-<p>In the first place, they show us the position and the
-rank of the phenomena of life in the universe as a
-whole. They throw fresh light on the noble harmony
-of the animal and vegetable kingdoms which Priestley,
-Ingenhousz, Senebier, and the chemical school of the
-beginning of the nineteenth century discovered, and
-which was expounded by Dumas with incomparable
-lucidity and brilliance. Energetics is expressed in a
-line. “The animal world expends the energy accumulated
-by the vegetable world.” It extends these
-views beyond the living kingdoms. It shows how the
-vegetable world itself draws its activity from the
-energy radiated by the sun, and how animals restore
-it again, in dissipated heat, to the cosmic medium.
-It extends the harmony of the two kingdoms to the
-whole of nature. The new science makes of the
-whole universe one connected system.</p>
-
-<p>From a more limited point of view, and so that we
-may not restrict ourselves to a consideration of the
-domain of animal physiology, the laws of energetics
-sum up and explain a multitude of facts and of
-experimental laws—for example, the law of the intermittence
-of physiological activity, the facts of fatigue,
-the rôle and the general principles of alimentation,
-and the conditions of muscular contraction.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_116">[Pg 116]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_III_2">CHAPTER III.<br />
-
-<small>ALIMENTARY ENERGETICS.</small></h3></div>
-
-
-<p class="prel">Various Problems of Alimentation. § 1. <i>Food the source of
-Energy and Matter.</i> The two forms of Energy afforded by
-Food—Vital Energy, Thermal Energy. Food the source
-of Heat. The rôle of Heat.—§ 2. <i>Measure of the output of
-Energy</i>—by the Calometric Method—by the Chemical
-Method.—§ 3. The regular type of Food, Biothermogenic,
-and the irregular type, Thermogenic.—§ 4. Food considered
-as the source of Heat. The Law of Surfaces. The limits
-of Isodynamics.—§ 5. Plastic rôle of Food. Preponderance
-of Nitrogenous Foods.</p>
-
-
-
-<p>Among the problems on which energetics has
-thrown a vivid light we have mentioned alimentation,
-muscular contraction, and, more general still, the
-intermittence of vital functional activity. We shall
-begin with the study of alimentation.</p>
-
-<p><i>The Different Problems of Alimentation.</i>—What is a
-food? In what does alimentation consist? The
-dictionary of the <i>Académie</i> will give us our first
-answer. It tells us that the word food is applied to
-“every kind of matter, whatever may be its nature,
-which habitually serves or may serve for nutrition.”
-This is very well put, but here again we must know
-what nutrition is, and that is not a simple matter; in
-fact, it practically means whatever is usually placed
-on the table in a civilized and polished society. But<span class="pagenum" id="Page_117">[Pg 117]</span>
-it is just the profound reasons for this traditional
-practice that we are trying to discover.</p>
-
-<p>The problem of alimentation may be looked at in a
-thousand ways. It is culinary, no doubt, and gastronomic;
-but it is also economical and social,
-agricultural, fiscal, hygienic, medical, and even moral.
-But first and foremost, it is physiological. It comprises
-and assumes the knowledge of the general
-composition of foods, of their transformations in the
-digestive apparatus, and their comparative utility in
-the maintenance and the sound functional activity
-of the organism. To this first group of subjects for
-our discussion are attached others relating to the
-effects of inanition, of insufficient alimentation, and of
-over-feeding. And in order to throw light on all
-these aspects of the problem of alimentation, we have
-to lay bare the most intimate and delicate reactions by
-which the organism is maintained and recruited, and,
-in the words of a celebrated physiologist, “to penetrate
-into the kitchen of vital phenomena.” And here
-neither Apicius, nor Brillat-Savarin, nor Berchoux,
-nor the moralists, nor the economists are of any use
-to us as guides. We must appeal to the scientists,
-who, following the example of Lavoisier, Berzelius,
-Regnault, and Liebig, have applied to the study of
-living beings the resources of general science, and
-have thus founded <i>chemical biology</i>.</p>
-
-<p>This branch of science developed considerably in
-the second half of the nineteenth century. It has now
-its methods, its technique, its chairs at the universities,
-its laboratories, and its literature. It has particularly
-applied itself to the study of the “material changes”
-or the <i>metabolism</i> of living beings, and with that
-object in view it has done two things. In the first<span class="pagenum" id="Page_118">[Pg 118]</span>
-place, it has determined the composition of the
-constituent materials of the organism; then analyzing
-qualitatively and quantitatively all that penetrates into
-that organism in a given time—that is to say, all the
-alimentary or respiratory ingesta, and all that issues
-from the organism, <i>i.e.</i>, all the excreta, all the <i>egesta</i>,—it
-has drawn up <i>nutritive balance sheets</i>, corresponding
-to the various conditions of life, whether
-naturally or artificially created. And thus we can
-determine the alimentary régimes which give too
-much, and which give too little, and which finally
-restore equilibrium.</p>
-
-<p>We do not propose to give a detailed account of
-this scientific movement. This may be done in monographs.
-All we wish to indicate here is the most
-general result of these laborious researches—that is
-to say, the laws and the doctrines which are derived
-from them, and the theories to which they have given
-birth. It is by this alone that they are brought into
-relation with general science, and may therefore
-interest the reader. The facts of detail are never
-lacking to the historian; it is more profitable to show
-the movement of ideas. The theories of alimentation
-bring into conflict very different conceptions of
-the vital functional activity. And here we find a
-confused medley of opinions on which it is not without
-interest to endeavour to throw some light.</p>
-
-
-<h4>§ 1. <span class="smcap">Food, a Source of Energy and Matter.</span></h4>
-
-
-<p><i>Definitions of Food.</i>—Before the introduction into
-physiology of the notion of energy, no one had
-succeeded in giving an exact idea and a precise
-definition of food and alimentation. Every physio<span class="pagenum" id="Page_119">[Pg 119]</span>logist
-and medical man who attempted it had failed,
-and this for various reasons.</p>
-
-<p>The general cause of this failure was that most definitions,
-popular or technical, interposed the condition
-that the food must be introduced into the digestive
-apparatus. “It is,” said they, “a substance which
-when introduced into the digestive tube undergoes,
-etc., etc.” But plants draw food from the soil, and
-they possess no digestive apparatus; many animals
-have no intestinal tube; and in the case of certain
-rotifera, the females possess a digestive apparatus,
-while the males have none. Nevertheless all animals
-feed.</p>
-
-<p>On the other hand, there are other substances than
-those which use the digestive tract for the purpose of
-entering the organism, and which are eminently useful
-or necessary to the maintenance of life. In particular
-we may mention oxygen.</p>
-
-<p>The distinctive feature of food is its <i>utility</i>—when
-conveniently introduced or employed—to the living
-being. Claude Bernard’s definition is this:—A substance
-taken in the external medium “necessary for the
-maintenance of the phenomena of the healthy organism
-and for the reparation of the losses it constantly
-suffers.” “A substance which supplies an element
-necessary for the constitution of the organism, or
-which <i>diminishes its disintegration</i>” (stored-up food);
-this is the definition of C. Voit, the German physiologist.
-M. Duclaux says, in his turn, but in far too
-general terms, that it is a substance which contributes
-to assure the sound functional activity of any of the
-organs of the living being. None of these ways of
-describing food gives a complete idea.</p>
-
-<p><i>Food, the Source of Energy and Matter.</i>—The inter<span class="pagenum" id="Page_120">[Pg 120]</span>vention
-of the notion of energy enables us more
-completely to understand the true nature of food.
-We must, in fact, have recourse to the energetic conception
-if we desire to take into account all that the
-organism requires from food. It not only requires
-<i>matter</i>, but also, and most important of all, energy.</p>
-
-<p>Investigators so far concentrated their thoughts exclusively
-on the necessity of a supply of matter—that
-is to say, they only looked upon one side of the
-problem. The living body presents, at each of its
-points, an uninterrupted series of disintegrations and
-reconstitutions, the materials being supplied from
-without by alimentation, and rejected by excretion.
-Cuvier gave to this unceasing circulation of ambient
-matter throughout the vital world the name of <i>vital
-vortex</i>, and he rightly saw in it the characteristic of
-nutrition, and the distinctive feature of life.</p>
-
-<p>This idea of the <i>cycle of matter</i> has been completed
-in our own time by that of the <i>cycle of
-energy</i>. All the phenomena of the universe, and
-therefore those of life, are conceived of as energetic
-transformations. We now look at them in their relationship
-instead of considering them individually as of old.
-Each has an antecedent and a consequent unity with
-which it is connected in magnitude by the law of
-equivalents taught us by contemporary physics. And
-thus we may conceive of their succession as the
-cycle of a kind of indestructible agent, which changes
-only apparently, or assumes another form as it passes
-from one to the other, but its magnitude remains
-unaltered. This is energy. Thus, in the living being
-there is not only a circulation of matter, but also a
-circulation of energy.</p>
-
-<p>The most general result of research in physiological<span class="pagenum" id="Page_121">[Pg 121]</span>
-chemistry from the time of Lavoisier down to our own
-day has been to teach us that <i>the antecedent of the
-vital phenomenon is always a chemical phenomenon</i>.
-The vital energies are derived from the potential
-chemical energy accumulated in the immediate constituent
-principles of the organism. In the same way
-<i>the consequent phenomenon of the vital phenomenon is in
-general a thermal phenomenon</i>. The final form of
-vital energy is thermal energy. These three assertions
-as to the nature, the origin, and the final form of vital
-phenomena constitute the three fundamental principles,
-the three laws, of biological energetics.</p>
-
-<p><i>Food, a Source of Heat. It is not quâ source of heat
-that food is the source of vital energy.</i>—The place of
-vital energy in the cycle of universal energy is completely
-determined. It lies between the chemical
-energy which is its generating form and the thermal
-energy which is its form of disappearance, of breakdown,
-the “degraded form,” as the physicists say.
-Hence we have a result which can be immediately
-applied in the theory of food—namely, that heat is in
-the dynamical order an excretum of the animal life
-rejected by the living being, just as in the substantial
-order, urea, carbonic acid and water, are the materials
-used up and again rejected by it. We therefore must
-not think of the transformation in the animal organism
-of heat into vital energy, as certain physiologists
-always do. Nor must we think, with Béclard, of its
-transformation into muscular movement; or, as others
-have maintained, into animal electricity. This is not
-only an error of doctrine but an error of fact. It
-proceeds from a false interpretation of the principle of
-the mechanical equivalent of heat and a misunderstanding
-of Carnot’s principle. Thermal energy does<span class="pagenum" id="Page_122">[Pg 122]</span>
-not repeat the course of the energetic flux in the
-animal organism. The heat is not transformed into
-anything. It is simply dissipated.</p>
-
-<p><i>The Part played by Animal Heat as a Condition of
-Physiological Manifestations.</i>—Does this mean that
-heat is useless to life in the very beings in which it is
-most abundantly produced—<i>i.e.</i>, in man and in the
-warm-blooded vertebrates? So far from this being so,
-it is necessary to life. But its utility has a peculiar
-character which must neither be misunderstood nor
-exaggerated. It is not transformed into chemical
-or vital reactions, but merely creates for them a
-favourable condition.</p>
-
-<p>According to the first principle of energetics, for
-the vital fact to be derived from the thermal fact, the
-heat must be preliminarily transformed into chemical
-energy, since chemical energy is necessarily an antecedent
-and generating form of vital energy. Now
-this regressive transformation is impossible according
-to the current theories of general physics. The part
-played by heat in the act of chemical combination is
-that of a primer to the reaction. It consists in placing
-the reacting bodies, by changing their state or by
-modifying their temperature, in the condition in which
-they ought to be for the chemical forces to come into
-play. For example, in the combination of hydrogen
-and oxygen by setting light to an explosive mixture,
-heat only acts as a primer to the phenomenon, because
-the two gases which are passive at ordinary temperatures,
-require to be raised to 400° C. before chemical
-affinity comes into play. And so it is with the
-reactions which go on in the organism. They have
-a maximum temperature, and the part played by
-animal heat is to furnish them with it.</p>
-
-<p><span class="pagenum" id="Page_123">[Pg 123]</span></p>
-
-<p>It follows that heat intervenes in animal life in two
-capacities—first and foremost as <i>excretum</i>, or end of
-the vital phenomenon, of <i>physiological work</i>; and on
-the other hand, as a <i>condition</i> or <i>primer</i> of the chemical
-reactions of the organism; and generally, as a favourable
-condition for the appearance of the physiological
-manifestations of living matter. Thus, it is not
-dissipated in sheer waste.</p>
-
-<p>I was led to adopt these views some years ago
-from certain experiments on the rôle played in food by
-alcohol. I did not then know that they had already
-been expressed by one of the masters of contemporary
-physiology, M. A. Chauveau, and that they were
-related in his mind to a series of conceptions and of
-researches of great interest, in the development of
-which I have since then taken a share.</p>
-
-<p><i>Two Forms of Energy supplied to Animals by Food.</i>—To
-say that food is simultaneously a supply of
-energy and a supply of matter, is really to express in
-a single sentence the fundamental conception of
-biology, in virtue of which life brings into play no
-substratum or characteristic dynamism. According
-to this, the living being appears to us as the
-seat of an incessant circulation of matter and energy,
-starting from the external world and returning
-to it. All food is nothing but this matter and this
-energy. All its characteristics, our views as to its
-rôle, its evolution, all the rules of alimentation are
-simple consequences of this principle, interpreted by
-the light of energetics.</p>
-
-<p>And first of all, let us ask what forms of energy are
-afforded by food? It is easy to see that there are
-two—food is essentially a source of chemical energy;
-and secondarily and accessorily, it is a source of heat.<span class="pagenum" id="Page_124">[Pg 124]</span>
-Chemical energy is the only energy, according to the
-second law of energetics, which may be transformed
-into vital energy. It is true at any rate for animals;
-for in plants it is otherwise. There the vital cycle has
-neither the same point of departure nor the same final
-position. The circulation of energy does not take
-place in the same manner.</p>
-
-<p>On the other hand, and this we are taught by the
-third law, energy brought into play in vital phenomena
-is finally liberated and restored to the physical
-world in the form of heat. We have just said that
-this release of heat is employed in raising the temperature
-of the living being. It is animal heat.</p>
-
-<p>Thus there are two forms of energy supplied by
-food, chemical and thermal.</p>
-
-<p>It must be added that these are not the only forms,
-but the principal, and by far the most important. It is
-not absolutely true that heat is the only outcome of the
-vital cycle. It is only so in the subject in repose, contented
-to live idly without doing external mechanical
-work, without lifting a tool or a weight, even that of its
-own body. And again, speaking in this way, we neglect
-all the movements and all the mechanical work which
-is done without exercise of the volition, by the beating
-of the heart and of the arteries, the movements of
-respiration, and the contractions of the digestive tube.</p>
-
-<p>Mechanical work is, in fact, another possible termination
-of the cycle of energy. But there is no
-longer anything necessary or inevitable in this, since
-motion and the use of force are in a certain measure
-subordinated to the capricious volition of the animal.<a id="FNanchor_11" href="#Footnote_11" class="fnanchor">[11]</a></p>
-<p><span class="pagenum" id="Page_125">[Pg 125]</span></p>
-<p>At other times, again, it is an electrical phenomenon
-which terminates the vital cycle, and it is, in fact, in
-this way that things happen in the functional activity
-of the nerves and muscles in all animals, and in the
-functional activity of the electrical organ in fish,
-such as the ray and the torpedo. Finally, the termination
-may be a photic phenomenon, and this is
-what happens in phosphorescent animals.</p>
-
-<p>It is idle to diminish the power of these principles
-by proceeding to enumerate the whole of the exceptions
-to their validity. We know perfectly well
-that there are no absolute principles in nature. Let
-us say, then, that the energy which temporarily
-animates the living being is furnished to it by the
-external world under the exclusive form of potential
-chemical energy; but that, if there is only one door of
-entry, there are two exits. It may return to the external
-world in the principal form of thermal energy
-and in the accessory form of mechanical energy.</p>
-
-
-<h4><span class="smcap">§ 2. Measurement of the Supply Of
-Alimentary Energy.</span></h4>
-
-<p><i>Calorimetric Method.</i>—From what has preceded it
-is clear that if the energetic <i>flux</i> which circulates
-through the animal emerges, <i>in toto</i>, in the state of
-heat, the measurement of this heat becomes the<span class="pagenum" id="Page_126">[Pg 126]</span>
-measurement of the vital energy itself, for the origin
-of which we must go back to the food. If the flux is
-divided into two currents, mechanical and thermal,
-they must both be measured and the sum of their
-values taken. If the animal does not produce mechanical
-work, and all ends in heat, we have only to
-capture, by means of a calorimeter, this energetic flux
-as it emerges, and thus measure in magnitude and
-numerically the energy in motion in the living being.
-Physiologists use for this purpose various types of
-apparatus. Lavoisier and Laplace used an ice calorimeter—that
-is to say, a block of ice in which they
-shut up a small animal, such as a guinea-pig; they
-then measured its thermal production by the quantity
-of ice it caused to melt. In one of their experiments,
-for instance, they found that a guinea-pig had melted
-341 grammes of ice in the space of ten hours, and had
-therefore set free 27 Calories.</p>
-
-<p>But since those days more perfect instruments have
-been invented. M. d’Arsonval employed an air calorimeter,
-which is nothing but a differential thermometer
-very ingeniously arranged, and giving an automatic
-record. Messrs. Rosenthal, Richet, Hirn and Kaufmann,
-and Lefèvre have used more or less simplified
-or complicated air calorimeters. Others, following
-the example of Dulong and Despretz, have used
-calorimeters of air and mercury, or with Liebermester,
-Winternitz, and J. Lefèvre (of Havre), have had
-recourse to baths. Here, then, there is a considerable
-movement of research which has led to the discovery
-of very interesting facts.</p>
-
-<p><i>Measurement of the Supply of Alimentary Energy
-by the Chemical Method.</i>—We may again reach our
-result in another way. Instead of surprising the cur<span class="pagenum" id="Page_127">[Pg 127]</span>rent
-of energy as it emerges and in the form of
-heat, we may try and capture it at its entry in the
-form of potential chemical energy.</p>
-
-<p>The evaluation of potential chemical energy may
-be effected with the same unit of measurement as the
-preceding—that is to say, the Calorie. If we consider
-man and mammals, for example, we know that there
-is only apparently an infinite variety in their foods.
-We may say that they feed on only three substances.
-It is a very remarkable fact that all the complexity
-and multiplicity of foods, fruits, grains, leaves, animal
-tissues, and vegetable products of which use is made,
-reduce to so great a simplicity and uniformity, that all
-these substances are of three types only: albuminoids,
-such as albumen or white of egg—foods of animal
-origin or varieties of albumen; carbo-hydrates, which
-are more or less disguised varieties of sugar; and
-finally, fats.</p>
-
-<p>Here, then, from the chemical point of view, leaving
-out certain mineral substances, are the principal
-categories of alimentary substances. Here, with the
-oxygen that is brought in by respiration, is everything
-that penetrates the organism.</p>
-
-<p>And now, what comes out of the organism? Three
-things only, water, carbonic acid, and urea. But the
-former are the products of the combustion of the
-latter. If we consider an adult organism in perfect
-equilibrium, which varies throughout the experiment
-neither in weight nor in composition, we may say that
-the receipts balance the expenditure. Albumen, sugar,
-fat, plus the oxygen brought in, balance quantitatively
-the water, carbonic acid, and urea expelled. Things
-happen, in fact, as if the foods of the three categories
-were burned up more or less completely by the oxygen.</p>
-
-<p><span class="pagenum" id="Page_128">[Pg 128]</span></p>
-
-<p>It is this combustion that we have known since the
-days of Lavoisier to be the source of animal heat.
-We can easily determine the quantity of heat left by
-albumen passing into the state of urea, and by the
-starch, the sugars, and the fats reduced to the state of
-water and carbonic acid. This quantity of heat does
-not depend on the variety of the unknown intermediary
-products which have been formed in the
-organism. Berthelot has shown that this quantity of
-heat which measures the chemical energy liberated by
-these substances is identical with the quantity obtained
-by burning the sugar and the fats in a chemical
-apparatus, in a calorimetric bomb, until we get carbonic
-acid and water, and by burning albumen till we get
-urea. This result is a consequence of Berthelot’s
-<i>principle of initial and final states</i>. The liberated
-heat only depends on the initial and final states, and
-not on the intermediary states. The heat left in the
-economy by the food being the same as that left in
-the calorimetric bomb, it is easy for the chemist to
-determine it. It has thus been discovered that one
-gramme of albumen produces 4.8 Calories, one gramme
-of sugar 4.2 Calories, and one gramme of fat 9.4
-Calories. We thus gather what a given ration—a mixture
-in certain proportions of these different kinds of
-foods—supplies to the organism and what energy
-it gives it, measured in Calories.</p>
-
-<p>The calculation may be carried out to a high degree
-of accuracy if, instead of confining ourselves to the
-broad features of the problem, we enter into rigorous
-detail. It is only, in fact, approximately that we have
-reduced all foods to albumen, sugar, and fat, and all
-excreta to water, carbonic acid, and urea.</p>
-
-<p>The reality is a little more complicated. There<span class="pagenum" id="Page_129">[Pg 129]</span>
-are varieties of albumen, carbo-hydrates, and fatty
-bodies, the heats of combustion of which in the
-organism oscillate in the neighbourhood of the numbers
-4.8, 4.2, and 9.4. Each of these bodies has been
-individually examined, and numerical tables have
-been drawn up by Berthelot, Rubner, Stohmann, Van
-Noorden, etc. The tables exhibit the thermal value
-or energetic value of very different kinds of foods.</p>
-
-<p>In our climate, the adult average man, doing no
-laborious work, daily consumes a maintenance ration
-composed, as a rule, of 100 grammes of albuminoids,
-49 grammes of fats, and 403 grammes of carbo-hydrates.
-This ration has an energetic value of 2,600
-Calories.</p>
-
-<p>It is therefore, thanks to the victories won in the
-field of thermo-chemistry, and to the principles laid
-down since 1864 by M. Berthelot, that this second
-method of attack on nutritive dynamism has been
-rendered possible. Physiologists, by the aid of these
-methods, have drawn up <i>balance-sheets of energy</i> for
-living beings just as they had previously established
-<i>balance-sheets of matter</i>.</p>
-
-<p>Now, it is precisely researches of this kind that we
-have indicated here as a consequence of biological
-energetics, which in reality have helped to build up
-that principle. These researches have shown us that,
-in conformity with the <i>principles of thermodynamics</i>,
-there was not, in fact, in the organism, any transformation
-of heat into mechanical work, as the
-physiologists for a short time supposed, on the
-authority of Berthelot. With the help of our theory
-this mistake is no longer possible. The doctrine of
-energetics shows us in fact the current of energy
-dividing itself, as it issues from the living being, into<span class="pagenum" id="Page_130">[Pg 130]</span>
-two divergent branches, the one thermal and the
-other mechanical, external the one to the other
-although both issuing from the same common trunk,
-and having between them no relation but this, that
-the sum of their discharges represents the total of the
-energy in motion. Let us now translate these very
-simple notions into the more or less barbarous jargon
-in use in physiology. We shall be convinced as we
-go on of the truth of the saying of Buffon, that “the
-language of science is more difficult to learn than the
-science itself.” We shall say, then, that chemical
-energy, that the unit of weight of the food which may
-be placed in the organism, constitutes the alimentary
-<i>potential</i>, the <i>energetic value</i> of this substance, its
-<i>dynamogenic power</i>. It is measured in units of heat,
-in Calories, which the substance may leave in the
-organism. The evaluation is made according to the
-principles of thermo-chemistry, by means of the
-numerical tables of Berthelot, Rubner, and Stohmann.
-The same number also expresses the <i>thermogenic
-power</i>, virtual or theoretical, of the alimentary substance.
-This energy being destined to be transformed
-into <i>vital energies</i> (Chauveau’s <i>physiological work</i>,
-<i>physiological energy</i>), the dynamogenic or thermogenic
-value of the food is at the same time its biogenetic
-value. Two weights of different foods which supply
-the organism with the same number of Calories,—<i>i.e.</i>
-for which these numerical values are the same,—will be
-called <i>isodynamic</i> or <i>isodynamogenic</i>, <i>isobiogenetic</i>, <i>isoenergetic</i>
-weights. They will be equivalent from the
-point of view of their alimentary value. And finally,
-if, as is usually the case, the cycle of energy ends in
-the production of heat, the food which has been
-utilized for this purpose has a real <i>thermogenic value</i>,<span class="pagenum" id="Page_131">[Pg 131]</span>
-identical with its theoretical thermogenic value. In
-this case it might be determined experimentally by
-direct calorimetry, measuring the heat produced by
-the animal supposed absolutely unchanged and identical
-before and after the consumption of the food.</p>
-
-
-<h4>§ 3. <span class="smcap">Different Types of Foods. The Regular,
-Biothermogenic Type and the Irregular,
-Thermogenic Type.</span></h4>
-
-
-<p>Food is a source of thermal energy for the organism
-because it is decomposed within it, and undergoes
-within it a chemical degradation. Physiological
-chemistry tells us that whatever be the manner in
-which it is broken up, it always results in the same
-body and always sets free the same quantity of heat.
-But if the point of departure and the point of arrival
-are the same, it is possible that the path pursued is
-not constantly identical. For example, one gramme
-of fat will always give the same quantity of heat,
-9.4 Calories, and will always come to its final state
-of carbonic acid and water; but from the fat to
-the mixture of carbonic acid gas and water there
-are many different intermediaries. In a word we
-get the conception of varied cycles of alimentary
-evolutions.</p>
-
-<p>From the point of view of the heat produced it has
-just been said that these cycles are equivalent. But
-are they equivalent from the vital point of view?
-This is an essential question.</p>
-
-<p>Let us imagine the most ordinary alternative.
-Food passes from the natural to the final state after
-being incorporated with the elements of the tissues,<span class="pagenum" id="Page_132">[Pg 132]</span>
-and after having taken part in the vital operations.
-The chemical potential only passes into thermal
-energy after having passed through a certain intermediary
-phase of vital energy. This is the normal
-case, <i>the regular type of alimentary evolution</i>. It may
-be said in this case that the food has fulfilled the
-whole of its function, it has served for the vital
-functional activity before producing heat. It has
-been <i>biothermogenic</i>.</p>
-
-<p><i>The irregular or pure thermogenic type.</i>—And now
-let us conceive of the most simple <i>irregular or
-aberrant type</i>. Food passes from the initial to the
-final state without incorporation in the living cells of
-the organism, and without taking part in the vital
-functional activity. It remains confined in the blood
-and the circulating liquids, but it undergoes in the
-end, however, the same molecular disintegration as
-before, and sets free the same quantity of heat
-Its chemical energy changes at once into thermal
-energy. Food is a <i>pure thermogen</i>. It has fulfilled
-only one part of its work. It has been of slight
-vital utility.</p>
-
-<p>Does this ever occur in reality? Are there foods
-which would be only <i>pure thermogens</i>—that is to
-say, which would not in reality be incorporated with
-the living anatomical elements, which would form no
-part of them either in a state of provisory constituents
-of the living protoplasm, or in the state of reserve-stuff;
-which would remain in the internal medium, in
-the blood and the lymph, and would there undergo
-their chemical evolution? Or again, if the whole of
-the food does not escape assimilation, would it be
-possible for part to escape it? Would it be possible
-for one part of the same alimentary substance to be<span class="pagenum" id="Page_133">[Pg 133]</span>
-incorporated, and for the rest to be kept in the blood
-or the lymph, in the circulating liquids <i>ad limina
-corporis</i>, so to speak? In other words, can the same
-food be according to circumstances a <i>biothermogen</i> or
-a <i>pure thermogen</i>? Some physiologists—Fick of
-Wurzburg, for instance—have claimed that this is
-really the case for most nitrogenous elements, carbohydrates,
-and fats; all would be capable of evolving
-according to the two types. On the other hand, Zuntz
-and von Mering have absolutely denied the existence
-of the aberrant or pure thermogenic type. No substances
-would be directly decomposed in the organic
-liquids apart from the functional intervention of the
-histological elements. Finally, other authors teach
-that there is a small number of alimentary substances
-which thus undergoes direct combustion, and among
-them is alcohol.</p>
-
-<p><i>Liebig’s Superfluous Consumption.</i>—Liebig’s <i>theory
-of superfluous consumption</i> and Voit’s <i>theory of the
-circulating albumen</i> assert that the proteid foods
-undergo partial direct combustion in the blood vessels.
-The organism only incorporates what is necessary
-for physiological requirements. As for the surplus
-of the food that is offered it, it accepts it, and, so
-to speak, squanders it; it burns it directly; and
-we have a “sumptuary” consumption, consumption
-<i>de luxe</i>.</p>
-
-<p>In this connection arose a celebrated discussion
-which still divides physiologists. If we disengage
-the essential body of the discussion from all
-that envelops it, we see that it is fundamentally a
-question of deciding whether a food always follows the
-same evolution whatever the circumstances may be,
-and particularly when it is introduced in great excess.<span class="pagenum" id="Page_134">[Pg 134]</span>
-Liebig thought that the superabundant part, escaping
-the ordinary process, was destroyed by direct combustion.
-He affirmed, for instance, that nitrogenous
-substances in excess were directly burned in the blood
-instead of passing through their usual cycle of vital
-operations. We might express the same idea by
-saying that they then undergo an accelerated
-evolution. Instead of passing through the blood in
-the anatomical element, to return in the dismembered
-form from the anatomical element to the blood,
-their breaking up takes place in the blood itself.
-They save a displacement, and therefore in reality
-remain external to the construction of the living
-edifice. Their energy, crossing the intermediary vital
-stage, passes with a leap from the chemical to the
-thermal form. Liebig’s doctrine reduced to this
-fundamental idea deserved to survive, but mistakes
-in minor details involved its ruin.</p>
-
-<p><i>Voit’s Circulating Albumen.</i>—A few years later
-C. Voit, a celebrated physiological chemist of Munich,
-revived it in a more extravagant form. He held
-that almost the whole of the albuminoid element
-is burned directly in the blood. He interpreted
-certain experiments on the utilization of nitrogenous
-foods by imagining that these substances
-when introduced into the blood were divided as a
-result of digestion into two parts: the one very small,
-which was incorporated with the living elements, and
-passed into the stage of <i>organized albumen</i>, the other,
-corresponding to the greater part of the alimentary
-albumen, remained mingled with the blood and
-lymph, and was subjected in this medium to direct
-combustion. This was <i>circulating albumen</i>. In this
-theory the tissues are almost stable; the organic<span class="pagenum" id="Page_135">[Pg 135]</span>
-liquids alone are subjected to oxydizing transformations,
-to nutritive metabolism. The accelerated
-evolution, which Liebig considered as an exceptional
-case, was to C. Voit the rule.</p>
-
-<p><i>Current Ideas as to the Rôle of Foods.</i>—The ideas
-of to-day are not those of Voit; but they do not,
-however, differ from them essentially. We no longer
-admit that the greater part of the ingested and
-digested albumen remains confined in the circulating
-medium external to the anatomical elements. It is
-held, with Pflüger and the school of Bonn, that it
-penetrates the anatomical element and is incorporated
-in it; but in agreement with Voit it is believed
-that a very small part is assimilated to the really
-living matter, to the protoplasm properly so called;
-the greater part is deposited in the cellular element
-as reserve-stuff. The material, properly so called, of
-the living machine does not undergo destruction and
-reparation as extensively as our predecessors supposed.
-There is no need for great reparation. On the contrary,
-the physiological activity consumes to a great
-extent the reserve-stuff. And the greater part of
-the food, after having undergone suitable elaboration,
-serves to replace the reserve-stuff destroyed
-in each anatomical element by the vital functional
-activity.</p>
-
-<p><i>Experimental Facts.</i>—Among the facts which
-brought physiologists of the school of Voit to believe
-that most foods do not get beyond the internal
-medium, there is one which may well be mentioned
-here. It has been observed that the consumption of
-oxygen in respiration increases notably (about a fifth
-of its value) immediately after a meal. What does
-this mean? The interval is too short for the digested<span class="pagenum" id="Page_136">[Pg 136]</span>
-alimentary substances to have been elaborated and
-incorporated in the living cells. It is supposed that
-an appreciable time is required for this complete
-assimilation. The products of alimentary digestion
-are therefore in all probability still in the blood, and
-in the interstitial liquids in communication with it.
-The increase of oxygen consumed would show that a
-considerable portion of these nutritive substances
-absorbed and passed into the blood would be oxydized
-and then and there destroyed. But this
-interpretation, however probable it may be, does not
-really fit in with the facts in such a way that we may
-consider it as proved. Certain experiments by Zuntz
-and Mering are opposed to the idea that combustion
-in the blood is easy. These physiologists injected
-certain oxydizable substances into the vessels without
-being able to detect any instantaneous oxidation.
-It is only fair to add that against these fruitless
-attempts other more fortunate experiments may be
-quoted.</p>
-
-<p><i>Category of Purely Thermogenic Foods, with Accelerated
-Evolution. Alcohol. Acids of Fruits.</i>—The
-accelerated evolution of foods—an evolution
-which takes place in the blood, that is to say outside
-the really living elements—remains, therefore, very
-uncertain as far as ordinary food is concerned. It
-has been thought that it was a little less uncertain
-as far as the special category of alcohol, acids of
-fruits, and glycerine is concerned.</p>
-
-<p>Some authors consider these bodies as pure
-thermogens. When alcohol is ingested in moderate
-doses, they say that about a tenth of the
-quantity absorbed becomes fixed in the living tissues;
-the rest is “circulating alcohol.” It is oxidized<span class="pagenum" id="Page_137">[Pg 137]</span>
-directly in the blood and in the lymph, without intervening
-in the vital functions other than by the heat
-it produces. From the point of view of the energetic
-theory these are not real foods, because their potential
-energy is not transformed into any kind of vital
-energy, but passes at once to the thermal form. On
-the other hand, other physiologists look upon alcohol
-as really a food. According to them everything is
-called a food which is transformed in the organism
-with the production of heat; and they measure the
-nutritive value of a substance by the number of
-Calories it can give up to the organism. So that
-alcohol would be a better food than carbohydrated
-and nitrogenous substances. A definite quantity of
-alcohol, a gramme for instance, is equivalent from
-the thermal point of view to 1.66 grammes of sugar,
-1.44 of albumen, or 0.73 of fat. These quantities
-would be <i>isodynamic</i>.</p>
-
-<p>Experiment has not entirely decided for or against
-this theory. However, the first tests have not been
-very favourable to it. The researches of C. von
-Noorden and his pupils, Stammreich and Miura, have
-clearly and directly established that alcohol cannot
-be substituted in a maintenance ration for an exactly
-isodynamic quantity of carbohydrates. If the substitution
-is effected, a ration only just capable of
-maintaining the organism in equilibrium becomes insufficient.
-The animal decreases in weight. It loses
-more nitrogenous matter than it can recover from
-its diet, and this situation cannot be sustained for
-long. On the other hand, the celebrated researches
-of the American physiologist, Atwater, would plead,
-on the contrary, in favour of almost isodynamic substitution.
-Finally, Duclaux has shown that alcohol<span class="pagenum" id="Page_138">[Pg 138]</span>
-is a real food, biothermogenic for certain vegetable
-organisms. But urea is also a food for <i>micrococcus
-ureæ</i>. It does not follow that it is a food for mammals.
-We have not reached the solution yet—<i>adhuc
-sub judice</i>.</p>
-
-<p><i>Conclusion: The Energetic Character of Food.</i>—To
-sum up we have confined ourselves, in what has been
-said, to the consideration of a single character of
-food, and really the most essential, its energetic
-character. Food must furnish energy to the organism,
-and for that purpose it is decomposed and broken up
-within it, and issues from it simplified. It is thus,
-for instance, that the fats, which from the chemical
-point of view are complicated molecular edifices,
-escape in the form of carbonic acid and water. And
-so it is with carbo-hydrates, starchy and sugary
-substances. This is because these compounds
-descend to a lower degree of complexity during their
-passage through the organism, and by this drop, as it
-were, they get rid of the chemical energy which they
-contained in the potential state. Thermo-chemistry
-enables us to deduce from the comparison of the
-initial and final states the value of the energy
-absorbed by the living being. This energetic, dynamogenic
-or thermogenic value, thus gives a measure of
-the alimentary capacity of the substance. A gramme
-of fat, for instance, gives to the organism a quantity
-of energy equivalent to 9.4 Calories; the thermogenic
-value of the albumenoids is 4.8 Calories.
-The thermogenic or thermal value of carbohydrates
-is less than 4.7 calories. This being so, we understand
-why the animal is nourished by foods which
-are products very high in the scale of chemical
-complexity.</p>
-
-<p><span class="pagenum" id="Page_139">[Pg 139]</span></p>
-
-
-<h4>§ 4. <span class="smcap">Food considered exclusivelyy as
-Source of Heat.</span></h4>
-
-
-<p>We have seen that food is, in the first place, a
-source of <i>chemical energy</i>; and, in the second place,
-a source of <i>vital energy</i>—finally, and consequently, a
-source of thermal energy. It is this last point of
-view which has exclusively struck the attention of
-certain physiologists, and hence has arisen a peculiar
-manner of conceiving the rôle of food. It consists in
-looking on food as a source of thermal energy.</p>
-
-<p>This conception is easily applied to warm-blooded
-animals, but to them exclusively—and this is where
-it first fails. The animal is warmer than the environment
-in general. It is constantly giving out heat to
-it. To repair this loss of heat it takes in food in
-exact proportion to the loss it sustains. When it is a
-question of cold-blooded vertebrates, which live in
-water and in most cases have an internal temperature
-which is not distinguishable from that of
-the environment, we see less clearly the thermal rôle
-of food. It seems then that the production of heat
-is an episodic phenomenon, not existing for itself.</p>
-
-<p>However that may be, food is in the second place
-a source of thermal energy for the organism. Can it
-be said, inversely, that every substance which we introduce
-into the economy, and which is there broken
-up and gives off heat, is a food? This is a moot
-point. We dealt just now with purely thermogenic
-foods. However, most physiologists are inclined to
-give a positive answer. In their eyes the idea of food
-cannot be considered apart from the fact of the production
-of heat. They take the effect for the<span class="pagenum" id="Page_140">[Pg 140]</span>
-cause. To these physiologists everything ingested is
-called food, if it gives off heat within the body.</p>
-
-<p>To be heated by food is, indeed, an imperious
-necessity for the higher animals. If this need be not
-satisfied the functional activities become enervated;
-the animal falls into a state of torpor; and if it is
-capable of attenuated, of more or less latent, life it
-sleeps in a state of hibernation; but if it is not
-capable of this, it dies. The warm-blooded animal
-with a fixed temperature is so organized that this
-constancy of temperature is necessary to the exercise
-and to the conservation of life. To maintain this
-indispensable temperature there must be a continual
-supply of thermal energy. According to this, the
-necessity of alimentation is confused with the
-necessity of a supply of heat to cover the deficit
-which is due to the inevitable cooling of the organism.
-This is the point of view taken up by theorists, and
-we cannot say that they have no right to do so. We
-can only protest against the exaggeration of this
-principle, and the subordination of the other rôles of
-food to this single role as a thermogen. It is the
-magnitude of the thermal losses which, according to
-these physiologists, determines the need for food, and
-regulates the total value of the maintenance ration.
-From the quantitative view it is approximately true.
-From the qualitative point of view it is false.</p>
-
-<p>Such is the theory opposed to the theory of
-chemical and vital energy. It has on its side a large
-number of experts, among whom are Rubner,
-Stohmann, and von Noorden. It has been defended in an
-article in the <i>Dictionnaire de Physiologie</i> by Ch.
-Richet and Lapicque. They hold that thermogenesis
-absolutely dominates the play of nutritive exchanges;<span class="pagenum" id="Page_141">[Pg 141]</span>
-and it is the need for the production of heat that
-regulates the total demand for Calories which every
-organism requires from its ration. It is not because
-it produces too much heat that the organism gets rid
-of it peripherally: it is rather because it inevitably
-disperses it that it is adapted to produce it.</p>
-
-<p><i>Rubner’s Experiments.</i>—This conception of the rôle
-of alimentation is based on two arguments. The first
-is furnished by Rubner’s last experiment (1893). A
-dog in a calorimeter is kept alive for a rather long
-period (two to twelve days); the quantity of heat
-produced in this lapse of time is measured, and it is
-compared with the heat afforded by the food. In all
-cases the agreement is remarkable. But is it possible
-that there should be no such agreement? Clearly no,
-because there is a well-known regulating mechanism
-which always exactly proportions the losses and the
-gains of heat to the necessity of maintaining the fixed
-internal temperature. This first argument is, therefore,
-not conclusive.</p>
-
-<p>The second argument is drawn from what has been
-called the <i>law of surfaces</i>, clearly perceived by Regnault
-and Reiset in their celebrated memoir in 1849,
-formulated by Rubner in 1884, and beautifully
-demonstrated by Ch. Richet. In comparing the
-maintenance rations for subjects of very different
-weights, placed under very different conditions, it is
-found that the food always introduces the same number
-of Calories for the same extent of skin—<i>i.e.</i>, for
-the same cooling surface. The numerical data
-collected by E. Voit show that, under identical conditions,
-warm-blooded animals daily expend the same
-quantity of heat per unit of surface—namely, 1.036
-Calories per square yard. The average ration intro<span class="pagenum" id="Page_142">[Pg 142]</span>duces
-exactly the amount of food which gives off
-sensibly this number of Calories. Now, this is an
-interesting fact, but, like the preceding, it has no
-demonstrative force.</p>
-
-<p><i>Objections. The Limits of Isodynamism.</i>—On the
-contrary, there are serious objections. The thermal
-value of the nutritive principles only represents one
-feature of their physiological rôle. In fact, animals
-and man are capable of extracting the same profit
-and the same results from rations in which one of the
-foods is replaced by an <i>isodynamic</i> proportion of the
-other two—that is to say, a proportion developing the
-same quantity of heat. But this substitution has very
-narrow limits. Isodynamism—that is to say, the
-faculty that food has of supplying <i>pro ratâ</i> its thermal
-values—is limited all round by exceptions. In the
-first place, there are a few nitrogenous foods that no
-other nutritive principle can supply; and besides, beyond
-this minimum, when the supply takes place, it is
-not perfect. Lying between the albuminoids and the
-carbohydrates relatively to the fats, it is not between
-these two categories relatively to nitrogenous substances
-if the thermal power of food were the only
-thing that had to be considered in it, the isodynamic
-supply would not fail in a whole category of principles
-such as alcohol, glycerin, and the fatty acids. Finally,
-if the thermal power of a food is the sole measure of
-its physiological utility, we are compelled to ask why
-a dose of food may not be replaced by a dose of heat.
-External warming might take the place of the internal
-warming given by food. We might be ambitious
-enough to substitute for rations of sugar and fat an
-isodynamic quantity of heat-giving coal, and so
-nourish the man by suitably warming his room. In<span class="pagenum" id="Page_143">[Pg 143]</span>
-reality, food has many other offices to fulfill than
-that of warming the body and of giving it energy—that
-is to say, of providing for the functional activity
-of the living machine. It must also serve to provide
-for wear and tear. The organism needs a suitable
-quantity of certain fixed principles, organic and
-mineral. These substances are evidently intended to
-replace those which have been involved in the cycle
-of matter, and to reconstitute the organic material.
-To these materials we may give the name of <i>histogenetic</i>
-foods (repairing the tissues), or of <i>plastic</i>
-foods.</p>
-
-
-<h4>§ 5. <span class="smcap">The Plastic Rôle of Food.</span></h4>
-
-
-<p><i>Opinions of the Early Physiologists.</i>—It is from this
-point of view that the ancients regarded the rôle of
-alimentation. Hippocrates, Aristotle, and Galen
-believed in the existence of a unique nutritive substance,
-existing in all the infinitely different bodies
-that man and the animals utilize for their nourishment.
-It was Lavoisier who first had the idea of a
-dynamogenic or thermal rôle of foods. Finally, the
-general view of these two species of attributes and
-their marked distinction is due to J. Liebig, who
-called them <i>plastic</i> and <i>dynamogenic</i> foods. In addition
-he thought that the same substance should accumulate
-the same attributes, and that this was the case with
-the albuminoid foods, which were at once <i>plastic</i> and
-<i>dynamogenic</i>.</p>
-
-<p><i>Preponderance of Nitrogenous Foods.</i>—Magendie, in
-1836, was the pioneer who introduced in this interminable
-list of foods the first simple division. He
-divided them into proteid substances, still called<span class="pagenum" id="Page_144">[Pg 144]</span>
-albuminoids, nitrogenous, quaternary, and <i>ternary
-substances</i>. Proteid substances are capable of maintaining
-life. Hence the preponderant importance
-given by the eminent physiologist to this order of
-foods. These results have since been verified. Pflüger,
-of Bonn, gave a very convincing proof of this a few
-years ago. He fed a dog, made it work, and finally
-fattened it, by giving it nothing at all to eat but meat
-from which had been extracted, as thoroughly as
-possible, every other substance.<a id="FNanchor_12" href="#Footnote_12" class="fnanchor">[12]</a> The same experiment
-showed that the organism can manufacture fats and
-carbo-hydrates at the expense of the nitrogenous food,
-when it does not find them ready formed in the ration.
-The albumen will suffice for all the needs of energy and
-and matter. To sum up, there is no necessary fat, no
-carbohydrate is necessary; albuminoids alone are indispensable.
-Theoretically, the animal and man alike
-could maintain life by the exclusive use of proteid
-food; but, practically, this is not possible for man,
-because of the enormous amount of meat which
-would have to be used (3 kilogrammes a day).</p>
-
-<p>Ordinary alimentation comprises a mixture of
-three orders of substances, and to this mixture
-albumen brings the plastic element materially necessary
-for the reparation of the organism; it also is
-the source of energy. The two other varieties only
-bring energy. In this mixed regimen the quantity
-of albumen must never descend below a certain
-minimum. The efforts of physiologists of late years
-have tended to fix with precision this minimum
-ration of albuminoids—or as we may briefly put it,<span class="pagenum" id="Page_145">[Pg 145]</span>
-of <i>albumen</i>—below which the organism would perish.
-Voit had found 118 grammes of albumen necessary
-for the average adult man weighing 70 kilos. This
-figure is certainly too high. The Japanese doctors,
-Mori, Tsuboï, and Murato, have shown that a considerable
-portion of the population of Japan is
-content with a diet much poorer in nitrogen, and
-suffers no inconvenience. The Abyssinians, according
-to Lapicque, ingest, on the average, only 67
-grammes of albumen per day. A Scandinavian physiologist,
-Siven, experimenting on himself, found that
-he could reduce the ration of albumen necessary to
-the maintenance and equilibrium of the organism to
-the lowest figures which have been yet reached—namely,
-from 35 to 46 grammes a day. These
-experiments, however, must be confirmed and interpreted.
-Besides, it is important to point out that the
-most advantageous ration of albumen requires to be
-a good deal above the strictly sufficient quantity.</p>
-
-<p>It only remains to refer to several other recent
-researches. The most important of many are those
-published by M. Chauveau, on the reciprocal transformation
-of the immediate principles in the organism
-according to the conditions of its functioning and
-the circumstances of its activity. To deal with
-these researches with as much detail as they deserve,
-we must study the physiology of muscular contraction
-and of movement—that is to say, of muscular
-energetics.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_146">[Pg 146]</span></p>
-
-<h2 class="nobreak" id="BOOK_III">BOOK III.</h2>
-
-
-<p class="center">THE CHARACTERS COMMON TO LIVING BEINGS.</p>
-
-
-<p class="prel">Chapter I. Summary: The doctrine of vital unity.—Chapter II.
-The morphological unity of living beings.—Chapter III.
-The chemical unity of living beings.—Chapter IV. The
-mutability of living beings.—Chapter V. The specific
-form, its acquisition, and reparation.—Chapter VI. Nutrition.</p>
-</div>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="CHAPTER_I_3">CHAPTER I.<br />
-
-<small>THE DOCTRINE OF VITAL UNITY.</small></h3></div>
-
-
-<p class="prel">Phenomena common to all living beings—Theory of vital
-duality—Unity in the formation of immediate principles—Unity
-in the digestive acts—The common vital fund.</p>
-
-
-<p>When we ask the various philosophical schools what
-life is, some show us a chemical retort, and others
-show us a soul. Whether vitalists or of the mechanical
-school, these are the adversaries who since philosophy
-began have vainly contested the possession of the
-secret of life. We need not concern ourselves with this
-eternal quarrel. We need not ask Pythagoras, Plato,
-Aristotle, Hippocrates, Paracelsus, Van Helmont,
-and Stahl what idea they formed of the vital
-principle; nor need we probe to the depths the
-ideas of living nature held by Epicurus, Democritus,<span class="pagenum" id="Page_147">[Pg 147]</span>
-Boerhaave, Willis, and Lamettrie; nor need we
-apply to the iatromechanicians nor to the chemists.
-We may do better than that. We may ask nature
-itself.</p>
-
-<p><i>Phenomena Common to Living Beings.</i>—Nature
-shows us an infinite number of beings, animal or
-vegetable, described in ordinary language as <i>living
-beings</i>. This language implicitly assumes something
-common to them all, a universal manner of being
-which belongs to them without distinction, without
-regard to differences of species, types, or kingdoms.
-On the other hand, anatomical analysis teaches us
-that animated beings and plants may be divided into
-parts ever decreasing in complexity, of which the
-last and the simplest is the <i>anatomical element</i>, the
-<i>cell</i>, the microscopic organic unit which, too, is alive.
-Common opinion suspects that all these beings,
-whether entire as in the case of animal and vegetable
-individuals, or fragmentary as in the case of
-cellular elements, have the same manner of being,
-and present the same body of common characteristics
-which rightly gives them this unmistakable title of
-living beings. Life then essentially would be this
-manner of being, common to animals, vegetables, and
-their elements. To seize in isolation these common,
-necessary, and permanent features, and then to
-synthetize them into a whole, will be the really
-scientific method of defining life, and of explaining
-its nature.</p>
-
-<p>And here then immediately arises a fundamental
-question which gives one pause, a question of fact
-which must be solved before we can go further.
-Is there really a common manner of being in all
-these things? Are <i>animal life, vegetable life</i>, and the<span class="pagenum" id="Page_148">[Pg 148]</span>
-life of the elements or <i>elementary life</i>, all the same?
-Is there a sum total of characteristics which may
-define life in general?</p>
-
-<p>The physiologists, following in the steps of Claude
-Bernard, respond in the affirmative. They accept as
-valid and convincing the proof given of this vital
-community by the illustrious experimentalist. However
-there are some rare exceptions to this universal
-assent. In this concert of approval there is at least
-one discordant voice, that of M. F. Le Dantec.<a id="FNanchor_13" href="#Footnote_13" class="fnanchor">[13]</a></p>
-<p><span class="pagenum" id="Page_149">[Pg 149]</span></p>
-<p><i>The Doctrine of the Vital Duality of Animals and
-Plants.</i>—There are, therefore, biologists who, in the
-domain of theory and in virtue of more or less well-founded
-conceptions or interpretations, separate
-<i>elementary life</i> from other vital forms, and thus break
-the bond of vital unity proclaimed by Claude Bernard.
-This monistic doctrine at the outset met with other
-opponents, and that, too, in the domain of facts.
-But it triumphed over them and became established.
-We have to deal with scientists like J. B. Dumas and
-Boussingault, who drew a dividing line between
-<i>animal life</i> and <i>vegetable life</i>.</p>
-
-<p>But let us in a few words recall to the reader this
-victorious struggle of the monistic doctrine against
-the dualism of the two kingdoms. If we consider an
-animal in action, said the champions of vital dualism,
-we agree that it feels, moves, breathes, digests, and
-finally, that it destroys by a real operation of chemical
-analysis the materials afforded to it by its ambient
-world. It is in these phenomena that are manifested
-its activity, its life. Now, added the dualists, plants
-do not feel, do not move, do not breathe, and do not
-digest. They build up from immediate principles,
-by an operation of chemical synthesis, the materials
-they borrow from the soil which bears them, or from
-the atmosphere which surrounds them. There is,
-therefore, nothing in common between the representatives
-of the two kingdoms if we confine ourselves
-to the examination of the actual phenomena which
-take place in them. To find a resemblance between
-the animal and the vegetable, said the dualists, we
-must set aside what they <i>do</i>, for they do different, or
-even contrary things. We must consider whence
-they come and what they <i>become</i>. Both originate<span class="pagenum" id="Page_150">[Pg 150]</span>
-in organisms similar to themselves. They grow,
-evolve, and generate as they themselves were
-generated. In other words, while their acts separate
-plants from animals, their mode of origin and
-evolution alone bring them together. Such analogies
-are of no slight importance; but they were neutralized
-by their dissimilarities, which were exaggerated by
-the dualistic school.</p>
-
-<p>It is clear that the word <i>life</i> would lose all actual
-significance to those who would reduce it to the
-faculty of evolution, and who would separate all its
-real manifestations in animated beings and in plants.
-If there are two lives, the one animal and the other
-vegetable, there are no more; or, what comes to the
-same thing, there is an infinite number of lives which
-have nothing in common but the name, or at most,
-the possession of some secondary characteristics.
-There are as many of them as there are different
-beings, for each has its own particular evolution.
-Here the specific is the negation of the general and
-it destroys it instead of being subordinate to it. The
-principle of life becomes for each being something as
-individual as its own evolution. And this, if we
-think it out, is how the philosophers look at life, and
-it is the real reason of their disagreement with the
-physiological school.</p>
-
-<p><i>Proof of the Monistic Theory.</i>—On the other hand,
-under the disguise of living forms, the physiologist
-recognizes the existence of an identical basis. His
-trained ear marks amid the overcharged instrumentation
-of the vital work the recognizable
-undertones of a constant theme. It was the work of
-Claude Bernard to bring this common basis to
-light. He shows that plants live as animals do,<span class="pagenum" id="Page_151">[Pg 151]</span>
-that they breathe, digest, have sensory reactions,
-move essentially like animals, destroy and build up
-in the same manner the immediate chemical principles.
-For that purpose it was necessary to pass in
-review, examining them from their foundation and
-distinguishing the essential from the secondary, the
-different vital manifestations—digestion, respiration,
-sensibility, motility, and nutrition. This is what
-Claude Bernard did in his work <i>Sur les Phénomènes
-de la vie communs aux animaux et aux plantes</i>. We
-need only to sketch in broad outline the characteristic
-features of his lengthy demonstration.</p>
-
-<p><i>Unity in the Formation of Immediate Chemical
-Principles.</i>—The first and most important of the
-differences pointed out between the life of animals
-and that of plants was relative to the formation of
-immediate principles. On this ground, indeed, vital
-dualism raised its fortress. The animal kingdom
-was considered in its totality as the parasite of the
-vegetable kingdom. To J. B. Dumas, animals,
-whatever they may be, make neither fat nor any
-elementary organic matter; they borrow all their
-foods, whether they be sugars or starches, fats or
-nitrogenous substances, from the vegetable kingdom.
-About the year 1843 the researches of the chemists,
-and of Payen in particular, succeeded in proving the
-presence, almost constant, of fatty matters in vegetables;
-and, further, these matters existed there in
-proportions more than sufficient to explain how
-the beast which fed upon them was fattened. The
-chemists attributed to nature as much practical sense
-as they themselves possessed; and since the hay and
-the grass of the ration brought fat ready made to the
-horse, the cow, and the sheep, they declared that the<span class="pagenum" id="Page_152">[Pg 152]</span>
-animal organism had nothing whatever to do but to
-put this food into the tissues, or to arrange for it to
-pass into the milk. But nature is not so wise and
-economical as was supposed at the Académie des
-Sciences. After a memorable debate, in which
-Dumas, Boussingault, Payen, Liebig, Persoz, Chossat,
-Milne-Edwards, and Flourens took part, and, later on,
-Berthelot and Claude Bernard, it was agreed that
-the animal does not grow fat from the fatty food
-which is supplied it, and that it makes its own fat
-just as the vegetable does, but in another manner.
-In the same way sugar, the normal constituent substance
-necessary for the nutrition of animals and
-plants, instead of being a vegetable product passing
-by alimentation from the herbivorous animals and
-thence to the carnivorous, is manufactured by the
-animal itself. Generally speaking, immediate principles
-have an equal claim to existence in the two
-kingdoms. Both form and destroy the substances
-indispensable to life.</p>
-
-<p>Here, then, one of the barriers between animal life
-and vegetable life is overthrown and destroyed.</p>
-
-<p><i>Unity of Digestive Acts in Animals and Plants.</i>—Similarly,
-another barrier falls if we show that
-digestion, long considered the exclusive function of
-animals, and, in particular, of the higher animals, is
-in reality universal.</p>
-
-<p>Cuvier pointed out the absence of a digestive
-apparatus as a very general and distinctive characteristic
-of plants. But the absence of a digestive
-apparatus does not necessarily imply the absence of
-digestion. The essential act of digestion is independent
-of the infinite variety of the organs, just as a
-reaction is independent of the form of the vessel in<span class="pagenum" id="Page_153">[Pg 153]</span>
-which it takes place. It is, in fact, a chemical
-transformation of an alimentary substance. This
-transformation may be realized outside the organism,
-<i>in vitro</i>, just as it can in the living being without
-masticating organs, without an intestinal apparatus,
-without glands, in a vessel placed in a stove, simply
-by means of a few soluble ferments—pepsine, trypsine,
-amylolytic diastases.</p>
-
-<p>All alimentary substances, whether taken from
-without or borrowed from the reserves accumulated
-in the internal stores of the organism, must undergo
-preparation. This preparation is digestion. Digestion
-is the prologue of nutrition. It is over when the
-reparative substance, whether food or reserve-stuff,
-is brought into a state enabling it to pass into the
-blood, and to be utilized by the organism.</p>
-
-<p><i>The Identity of Categories of Foods in the Two
-Kingdoms.</i>—Now the alimentary substances are the
-same in the two kingdoms, and so is their digestive
-preparation. Alimentary materials are of four
-kinds: albuminoid, starchy, fatty, and sugary substances.
-The animal takes them from without
-(food properly so-called), or from within (reserve-stuff).
-Man obtains starch, for instance, from different
-farinaceous dishes. It may, however, equally well
-be borrowed from the reserve of flour that we carry
-within us in our liver, which is a veritable granary,
-full of floury substance, glycogen. And so it is with
-vegetables. The potato has its store of flour in its
-tuber just as the animal has in its liver. The grain
-which is about to germinate has it in reserve-stuff in
-its cotyledons, or in its albumen. The bud which is
-about to develop into a tree or a flower carries it at
-its base.</p>
-
-<p><span class="pagenum" id="Page_154">[Pg 154]</span></p>
-
-<p>The same conclusions are true for another class
-of substances, the sugars. They may be a food taken
-from without, or a reserve deposited in the tissues.
-The animal takes from without, in fruits for instance,
-the ordinary sugar which pleases its taste. Beetroot,
-when flowering and fructifying, draws this substance
-from its roots in which stores have been amassed.
-The sugar cane when running to seed takes the
-sugar from the stores which it possesses in its cane.
-Brewer’s yeast, the <i>saccharomyces cerevisiæ</i>, the agent
-of alcoholic fermentation, finds this same substance in
-the sugary juices favourable to its development.</p>
-
-<p>In the same way, identically fatty substances,
-either in the form of food or of reserve-stuff, serve
-for nutrition to animals and vegetables; and that is
-again true of the substances of the fourth class,
-albuminoids, identical in the two kingdoms, foods or
-reserve-stuff, equally utilizable in both after digestion.</p>
-
-<p><i>Identity of the Digestive Agents and Mechanisms in
-Plants and Animals.</i>—Now, the results of contemporary
-research have been to establish a surprising
-resemblance in the modifications experienced by these
-foods, or reserve stuffs, in animals and plants; and
-even resemblances in the agents which realize them,
-and in the mechanisms by which they are performed.
-There is a real unity. The flour accumulated in the
-tuber of the potato is liquefied and digested on the
-appearance of the buds or of the flower, just as the
-starch of the liver or the alimentary flour is digested
-by the animal. The fatty matter which is stored up
-in the oleaginous grain is digested at the moment of
-germination, just as the fat during a meal is digested
-in the animal’s intestine. As the beetroot begins to
-run to seed, the root gives up part of its store of<span class="pagenum" id="Page_155">[Pg 155]</span>
-sugar, and this reserve stuff is distributed throughout
-the stalk after having been digested, exactly as would
-have been the case in the digestive canal of man.</p>
-
-<p>Vegetables, then, really digest. The four classes of
-substances mentioned above are really digested in
-order to pass from their actual form, a form unsuitable
-for interstitial exchanges, to another form suitable for
-nutrition. As there are four kinds of foods, so there
-are four kinds of digestions, four kinds of ferment-producing
-agents—amylolytic,<a id="FNanchor_14" href="#Footnote_14" class="fnanchor">[14]</a> proteolytic,<a id="FNanchor_15" href="#Footnote_15" class="fnanchor">[15]</a> saccharine,
-and lipasic<a id="FNanchor_16" href="#Footnote_16" class="fnanchor">[16]</a> diastases, identical in the animal
-and the plant. Identity of ferments implies identity
-of digestions. Going down to the very basis of
-things, the digestive act is nothing but the action of
-this ferment. This is the crux of the whole question.
-All else is only difference in scene, varying in the
-means of execution and in the accessories. The
-difference arises from the stage on which it takes
-place, but the piece which is being played is the
-same, and the actors are the same, and so is the
-action of the play.</p>
-
-<p>This identity between animal and vegetable life is
-found in the phenomena of respiration and of motility.
-The limits of this book do not allow of our entering
-into the details of facts. Besides, the facts are well
-known, and may be found in any treatise on general
-physiology. This science, therefore, enables us to
-perceive the imposing unity of life in its essential
-manifestations.</p>
-
-<p><span class="pagenum" id="Page_156">[Pg 156]</span></p>
-
-<p>The community of the phenomena of vitality in
-animals and plants being thus placed beyond a doubt,
-we must now discover the reason why. This reason
-is to be found in their anatomical and in their
-chemical unity. The fundamental phenomena are
-common because the composition is common, and
-because the universal anatomical basis, the cell,
-possesses in all cases a sum total of identical
-properties.</p>
-
-<p>If we appeal to physiology for the characteristics
-common to living beings, it will generally give us the
-following:—A structure or organization; a certain
-chemical composition which is that of <i>living matter</i>;
-a specific form; an evolution which in the earliest
-stage occasions the being to grow and develop until
-it is divided, and which in the highest stage includes
-one or more evolutive cycles with growth, the adult
-stage, senility, and death; a property of increase or
-nutrition, with its consequence—namely, a relation of
-material exchanges with the ambient medium;—and
-finally, a property of reproduction. It is important
-to pass them rapidly in review.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_157">[Pg 157]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_II_3">CHAPTER II.<br />
-
-<small>MORPHOLOGICAL UNITY OF LIVING BEINGS.</small></h3></div>
-
-
-<p class="prel">§ 1. The cellular theory. First period: division of the organism—§
-2. Second period: division of the cell—Cytoplasm—The
-nucleus—§ 3. Physical constitution of living matter—The
-micellar theory—§ 4. Individuality of complex beings—The
-law of the constitution of organisms.</p>
-
-
-
-<p>The first characteristic of the living beings is
-<i>organization</i>. By that we mean that they have a
-structure; that they are complex bodies formed of
-smaller aliquot parts and grouped according to a
-certain disposition. The most simple elementary
-being is not yet homogeneous. It is heterogeneous.
-It is organized. The least complex protoplasms,
-those of bacteria, for example, still possess a
-physical structure; Kunstler distinguishes in them
-two non-miscible substances, presenting an alveolar
-organization. Thus animals and plants present an
-organization, and it is sensibly constant from one end
-to the other of the scale of beings. There is a
-<i>morphological unity</i>.</p>
-
-
-<h4>§ 1. <span class="smcap">The Cellular Theory. First Period:
-Division of the Organism into Cells.</span></h4>
-
-
-<p><i>Cellular Theory. First Period.</i>—Morphological
-unity results from the existence of a universal<span class="pagenum" id="Page_158">[Pg 158]</span>
-anatomical basis, the <i>cell</i>. The cellular theory sums
-up the teaching of general anatomy or histology.</p>
-
-<p>At the beginning of the nineteenth century anatomy
-was following a routine dating from ancient times.
-It divided animal and vegetable machines into units
-in descending order, first into different forms of
-apparatus (circulatory, respiratory, digestive, etc.);
-then the apparatus into organs examined one by one,
-figuring and describing each of them from every
-point of view with scrupulous accuracy and untiring
-patience. If we think of the duration of these
-researches—the <i>Iliad</i>, as Malgaigne says, already
-containing the elements of a very fine regional
-anatomy—and especially of the powerful impulse
-they received in the seventeenth and eighteenth
-centuries, we shall understand the illusion of those
-who, in the days of X. Bichat, could fancy that the
-task of anatomy was almost ended.</p>
-
-<p>As a matter of fact this task was barely begun, for
-nothing was known of the intimate structure of the
-organs. X. Bichat accomplished a revolution when
-he decomposed the living body into tissues. His
-successors, advancing a step in the analysis, dissociated
-the tissues into elements. These elements,
-which one would have thought were infinitely varied,
-were reduced in their turn to one common <i>prototype</i>,
-the cell.</p>
-
-<p>The living body, disaggregated by the histologist,
-resolves under the microscope into a dust, every grain
-of which is a cell. A cell is an anatomical element
-the constitution of which is the same from one part
-to the other of the same being, and from one being to
-another; and its dimensions, which are sensibly
-constant throughout the whole of the living world,<span class="pagenum" id="Page_159">[Pg 159]</span>
-have an average diameter of several thousandths of
-a millimetre—<i>i.e.</i>, of several <i>microns</i>. This element,
-the cell, is a real organ. It is smaller, no doubt, than
-those described by the ancient anatomists, but it is not
-less complex. Its complexity is only revealed later.
-It is an organic unit. Its form varies from one
-element to another. Its substance is a semi-fluid
-mass, a mixture of different albuminoids. In the
-mean value of its dimensions, so carefully measured—<i>exceptis
-excipiendis</i>—we have a condition the significance
-of which has not yet been discovered, but
-which may be of great value in the explanation of its
-peculiar activities.</p>
-
-<p>Such is the result to which have converged the researches
-of the biologists who have examined plants
-or the lower animals, as well as of the anatomists who
-have been more especially occupied with the vertebrates
-and with man. All their researches have
-brought them to the same conclusion—the cellular
-theory. Either living beings are composed of a single
-cell—as is the case with the microscopic animals called
-<i>protozoa</i>, and the microscopic vegetables called <i>protophytes</i>—or,
-they are cellular complexes, <i>metazoa</i> or
-<i>metaphytes</i>—that is to say, associations of these
-microscopic organic units which are called cells.</p>
-
-<p><i>The Law of the Composition of Organisms.</i>—The
-law of the composition of organisms was discovered
-in 1838 by Schleiden and Schwann. From that time
-up to 1875 it may be said that micrographers have
-spent their time in examining every organ and every
-tissue, muscular, glandular, conjunctive, nervous, etc.,
-and in showing that in spite of their varieties of
-aspect and form, of the complexity of structures due
-to cohesion and fusion, they all resolve into the com<span class="pagenum" id="Page_160">[Pg 160]</span>mon
-element, the cell. Contemporary anatomists,
-Koelliker, Max Schultze, and Ranvier, have thus
-established the generality of the cellular constitution,
-while zoologists and botanists confirm the same law
-for all animals and vegetables, and exhibit them all
-as either unicellular or multicellular.</p>
-
-<p><i>The Cellular Origin of Complex Beings.</i>—At the
-same time embryogenic researches showed that all
-beings spring from a corpuscle of the same type.
-Going back in the history of their development to the
-most remote period, we find a cell of very constant
-constitution—namely, the <i>ovule</i>. This truth may be
-expressed by changing a word in Harvey’s celebrated
-aphorism—<i>omne vivum ex ovo</i>; we now say omne
-<i>vivum e cellula</i>. The myriads of differentiated anatomical
-elements whose association forms complex
-beings are the posterity of a cell, of the <i>primordial
-ovule</i>, unless they are the posterity of another equivalent
-cell. The second task of histology in the latter
-half of the nineteenth century consisted in following
-up the filiation of each anatomical element from the
-cell-egg to its state of complete development.</p>
-
-<p>The whole cellular theory is contained in the
-two following statements, which establish the morphological
-unity of living beings:—<i>Everything is a
-cell, everything comes from an initial cell</i>; the cell
-being defined as a mass of substance, protoplasm or
-protoplasms, of an average diameter of a few microns.</p>
-
-<h4>§ 2. <span class="smcap">The Second Period: the Division Of
-the Cell.</span></h4>
-
-<p><i>Second Period: Constitution of the Cell.</i>—This was,
-however, only the first phase in the analytical study<span class="pagenum" id="Page_161">[Pg 161]</span>
-of the living being. A second period began in
-1873 with the researches of Strassburger, Bütschli,
-Flemming, Kuppfer, Fromann, Heitzmann, Balbiani,
-Guignard, Kunstler, etc. These observers in their
-turn submitted this anatomical, this infinitely small
-cellular microcosm, to the same penetrating dissection
-their predecessors had applied to the whole organism.
-They brought us down one degree lower into
-the abyss of the infinitely small. And as Pascal,
-losing himself in these wonders of the imperceptible,
-saw in the body of the mite which is only a point,
-“parts incomparably smaller, legs with joints, veins in
-the legs, blood in the veins, humours in the blood,
-drops in the humours, vapours in these drops,” so
-contemporary biologists have shown in the epitome
-of organism called a cell, an edifice which itself is
-marvellously complex.</p>
-
-<p><i>The Cytoplasm.</i>—The observers named above revealed
-to us the extreme complexity of this organic
-unit. Their researches have shown us the structure
-of the two parts of which it is composed—the cellular
-protoplasm and the nucleus. They have determined
-the part played by each in genetic multiplication.
-They have shown that the protoplasm which forms the
-body of the cell is not homogeneous, as was at first
-supposed. The idea which was mooted later, that
-this protoplasm was formed, to use Sachs’ words, of a
-kind of “protoplasmic mud,”—<i>i.e.</i>, of a dust consisting
-of grains and granules connected by a liquid,—is no
-longer accurate. There is a much simpler view of the
-case. According to Leydig and his pupils, we must
-compare the protoplasm to a sponge in the meshes of
-which is lodged a fluid, transparent, hyaline substance,
-a kind of cellular juice, hyaloplasm. From the<span class="pagenum" id="Page_162">[Pg 162]</span>
-chemical point of view this cellular juice is a mixture
-of very different materials, albumens, globulins, carbohydrates,
-and fats, elaborated by the cell itself. It is
-a product of vital activity; it is not yet the seat of
-this activity. The living matter has taken refuge in
-the spongy tissue itself, in the <i>spongioplasm</i>.</p>
-
-<p>According to other histologists, the comparison of
-protoplasm to a spongy mass does not give the
-most exact idea, and, in particular, it does not furnish
-the most general idea. It would be far better to say
-that the protoplasm possesses the structure of foam
-or lather. As was seen by Kunstler in 1880, a comparison
-with some familiar objects gives the best idea.
-Nothing could be more like protoplasm physically
-than the culinary preparation known as <i>sauce mayonnaise</i>,
-made with the aid of oil and a liquid with
-which oil does not mix. Emulsions of this kind were
-made artificially by Bütschli. He noted that these
-preparations mimicked all the aspects of cellular
-protoplasm. Thus, in the living cell there is a
-mixture of two liquids, non-miscible and of unequal
-fluidity. This mixture gives rise to the formation of
-little cells. The more consistent substance forms
-their supporting framework (Leydig’s spongioplasm),
-while the other, which is more fluid, fills its interior
-(hyaloplasm).</p>
-
-<p>However that may be, whether the primitive
-organization of the cellular protoplasm be that of a
-sponge, as is asserted by Leydig, or that of a <i>sauce
-mayonnaise</i>, as is claimed by Bütschli and Kunstler,
-the complexity does not rest there. Further recourse
-must be made to analysis. Just as the tissue of a
-sponge, when torn, shows the fibres which constitute
-it, so the spongioplasm, the parietal substance, is<span class="pagenum" id="Page_163">[Pg 163]</span>
-exhibited as formed of a tangle of fibrils, or better
-still, of filaments or ribbons (in Greek, <i>mitome</i>), which
-are called <i>chromatic filaments</i>, because they are deeply
-stained when the cell is plunged into aniline dye. In
-each of these filaments, the substance of which is
-called chromatin, the devices of microscopic examination
-enable us to discover a series of granulations like
-beads on a string, the <i>microsomes</i> or bioblasts, connected
-one with the other by a sort of cement,
-Schwartz’s <i>linin</i>, which is a kind of nuclein.</p>
-
-<p>And let us add, to complete this summary of the
-constitution of cellular protoplasm, that it presents, at
-any rate at a certain moment, a remarkable organ,
-the <i>centrosome</i>, which plays an important part in
-cellular division. Its pre-existence is not certain.
-Some writers make it issue from the nucleus. At the
-moment of cellular division it appears like a compressed
-mass of granulations, which may be deeply
-stained. Around it is seen a clear unstainable zone,
-called the attraction-sphere; and finally, beyond this
-is a crown of striæ, which diverge like the rays of a
-halo—<i>i.e.</i>, the <i>aster</i>. In conclusion, there are yet in
-the cellular body three kinds of non-essential bodies:
-the vacuoles, the leucites, and various inclusions. The
-<i>vacuoles</i> are cavities, some inert, some contractile; the
-<i>leucites</i> are organs for the manufacture of particular
-substances; the <i>inclusions</i> are the manufactured products,
-or wastes.</p>
-
-<p><i>The Nucleus</i>.—Every cell capable of living,
-growing, and multiplying, possesses a <i>nucleus</i> of
-constitution very analogous to the cellular mass
-which surrounds it. The anatomical elements in
-which no nucleus is found, such as the red globules
-of blood in adult mammals, are bodies which are<span class="pagenum" id="Page_164">[Pg 164]</span>
-certain, sooner or later, to disappear. There is therefore
-no real cell without a nucleus, any more than
-there is a nucleus without a cell. The exceptions to
-this law are only apparent. Histologists have
-examined them one by one, and have shown their
-purely specious character. We may therefore lay
-aside, subject to possible appeal from this decision,
-organisms such as Haeckel’s <i>monera</i> and the problem
-of finding out if bacteria really have a nucleus. The
-very great, if not the absolute generality of the
-nuclear body, must be admitted.</p>
-
-<p>It hence follows that there is a nuclear protoplasm
-and a nuclear juice, just as we have seen that there is a
-protoplasm and a cellular juice. What was just said of
-the one may now be repeated of the other, and perhaps
-with even more emphasis. The nuclear protoplasm
-is a filamentary mass sometimes formed of a single
-mitome or cord, folded over on itself and capable of
-being unrolled. The mitome in its turn is a string
-of microsomes united by the cement of the linin.
-These are the same constituent elements as before,
-and the language of science distinguishes them one
-from the other by a prefix to their name of the words
-<i>cyto</i> or <i>karyo</i>, which in Greek signify cell and nucleus,
-according as they belong to one or the other of these
-organs. These are mere matters of nomenclature,
-but we know that in the descriptive sciences such
-matters are not of minor importance.</p>
-
-<p>We have just indicated that in a state of repose,—that
-is to say, under ordinary conditions,—the structure
-of a nucleus reproduces clearly the structure of the
-cellular protoplasm which surrounds it. The nuclear
-essence is best separated from the spongioplasm.
-It takes more clearly the form of a filamentary<span class="pagenum" id="Page_165">[Pg 165]</span>
-thread, and the filaments themselves (mitome) show
-very thick chromatic granulations, or microsomes,
-connected by the linin.</p>
-
-<p>At the moment of reproduction of the cell these
-granulations blend into a stainable sheath which
-surrounds the filaments, and the latter dispose themselves
-so as to form a single thread. This chromatic
-filament, which has now become a single thread, is
-shortened as it thickens (<i>spireme</i>); it is then cut into
-segments, twelve or twenty-four in the case of animals
-and a larger number in the case of plants. These
-are <i>chromosomes</i>, or <i>nuclear segments</i>, or <i>chromatic</i>
-loops. Their part is a very important one. They
-are constant in number and permanent during the
-whole of the life of the cell. Let us add that the
-nucleus still contains accessory elements (nucleoli).</p>
-
-<p><i>The Rôle of the Nucleus</i>.—Experiment has shown
-that the nucleus presides over the nutrition, the
-growth, and the conservation of the cell. If, following
-the example of Balbiani, Gruber, Nussbaum, and
-W. Roux of Leipzig, we cut into two a cell without
-injuring the nucleus, the fragment which is denuded
-of the nucleus continues to perform its functions for
-some time in the ordinary manner, and in some
-measure in virtue of its former impulse. It then
-declines and dies. On the contrary, the fragment
-provided with the nucleus repairs its wound, is
-reconstituted and continues to live. Thus the nucleus
-takes a very remarkable part in the reproduction of
-the cell, but it is still a matter of uncertainty whether
-its rôle is here subordinated to that of the cellular
-body, or if it is pre-eminent. However that may be,
-it follows from this experiment that the nucleus
-presents all the characteristics of a vigorous vitality,<span class="pagenum" id="Page_166">[Pg 166]</span>
-and that it is in its protoplasm that the chemists
-should be able to find the compounds, the special
-albuminoids, which, <i>par excellence</i>, form living matter.</p>
-
-
-<h4>§ 3. <span class="smcap">The Physical Constitution of Living
-Matter. The Micellar Theory.</span></h4>
-
-<p><i>Physical Constitution of Living Matter</i>.—Microscopic
-examination does not take us much farther.
-The microscope, with the strongest magnification
-of which it is capable at present, shows us nothing
-beyond these links of aligned microsomes forming
-the species of protoplasmic thread or mitome, whose
-cellular body is a confused tangle or a very tangled
-ball. It is not probable that direct sight can penetrate
-much farther than this. No doubt the microscope,
-which has been so vastly improved, is capable
-of still further improvement. But these improvements
-are not indefinite. We have already reached
-a linear magnification of 2000, and theory tells us
-that a magnification of 4000 is the limit which cannot
-be passed. The penetrating power of the instrument
-is therefore near its culminating point. It has already
-given almost all that we have a right to expect
-from it.</p>
-
-<p>We must, however, penetrate beyond this microscopic
-structure at which the sense of sight has been
-arrested. How is this to be done? When observation
-is arrested, hypothesis takes its place. Here
-there are two kinds of hypotheses, the one purely
-anatomical, the other physical. Anatomically, beyond
-the visible microsomes there have been imagined
-invisible hyper-microscopic corpuscles, the plastidules<span class="pagenum" id="Page_167">[Pg 167]</span>
-of Haeckel, the idioblasts of Hertwig, the pangenes of
-de Vries, the plasomes of Wiesner, the gemmules of
-Darwin, and the biophores of Weismann.</p>
-
-<p>Biologists who have not got all that they hoped
-from microscopic structure are therefore thrown back
-on hyper-microscopic structure.</p>
-
-<p>It is very remarkable that all this profound knowledge
-of structure has been so sterile from the point
-of view of the knowledge of cellular functional activity.
-All that is known of the life of the cell has been
-revealed by experiment. Nothing has resulted from
-microscopic observation but ideas as to configuration.
-When it is a question of giving or imagining an
-explanation of vital facts, of heredity, etc., biologists
-unable to supply anything beyond the details of
-structure revealed by anatomy have had recourse to
-hypothetical elements, gemmules, pangenes, biophores,
-and different kinds of determinants.</p>
-
-<p>Anatomy never has explained and never will explain
-anything. “Happy physicists!” wrote Loeb,
-“in never having known the method of research by
-sections and stainings! What would have happened
-if by chance a steam engine had fallen into the hands
-of a histological physicist? How many thousands of
-sections differently stained and unstained, how many
-drawings, how many figures, would have been produced
-before they knew for certain that the machine
-is an engine, and that it is used for transforming
-heat into motion!”</p>
-
-<p>The study of physical properties, continued on
-rational hypotheses, has also thrown some light
-on the possible constitution of living matter. The
-gap between microscopical structure and molecular or
-chemical structure has thus been filled.</p>
-
-<p><span class="pagenum" id="Page_168">[Pg 168]</span></p>
-
-<p>The consideration of the properties of <i>turgescence</i>
-and of <i>swelling</i>, which very generally belong to
-organized tissues, and therefore to the organic
-substance of protoplasm, has enabled us to obtain
-some idea of its ultra-microscopic constitution. If
-we wet a piece of sugar or a morsel of salt, before
-they are dissolved they absorb and imbibe the water
-without sensibly increasing their volume. It is quite
-otherwise with a tissue (<i>i.e.</i>, with a protoplasm)
-when weakened in water as a preliminary. The
-tissue, plunged into the liquid, absorbs it, swells, and
-often grows considerably. And this water does not
-lodge in the gaps, in pre-existing lacunar spaces, for
-organic matter presents no gaps of this kind. It
-does not resemble a porous mass with capillary
-canals, such as sandstone, tempered mortar, clay, or
-refined sugar. The molecules of water interpose
-between and separate the organic molecules, thus
-increasing by a sort of intussusception the intervals
-separating the one from the other—molecular intervals
-escaping the senses, as do the molecules themselves
-because they are of the same order of magnitude.</p>
-
-<p><i>Micellar Theory.</i>—While pondering over this
-phenomenon, an eminent physiologist, Nägeli, was
-led in 1877 to propose his <i>micellar theory</i>. Micellæ
-are groups of molecules in the sense in which
-physicists and chemists use the word. They are
-molecular structures with a configuration. They
-rapidly absorb water and are capable of fixing a
-more or less thick and adherent layer of it to their
-surface. In a word, they are aggregates of organic
-matter and water.</p>
-
-<p>There is therefore every reason for believing that
-the <i>microsomes</i> of spongy protoplasm, the physical<span class="pagenum" id="Page_169">[Pg 169]</span>
-support or basis of cellular life, are <i>groups of micellæ</i>
-formed of albuminoid substances and water. These
-clustered forms, these micellæ, are not absolutely
-peculiar to organized matter. Pfeffer, the learned
-botanist, has pointed them out under another name,
-<i>tagmata</i>, in the membranes of chemical precipitates.</p>
-
-<p>Beyond this limit analysis finds nothing but the
-chemical molecule and the atom. So that if we
-wish to reconstruct the hierarchy of the materials of
-constitution of the protoplasm in order of ascending
-complexity, we shall find at the foundation the atom or
-atoms of simple bodies. They are principally carbon,
-hydrogen, oxygen, nitrogen, the elements of all
-organic compounds, to which may be added sulphur
-and phosphorus. At the head we have the albuminoid
-molecule, or the albuminoid molecules,
-aggregates of the preceding atoms. In the third
-stage the micellæ or tagmata, aggregates of albuminoids
-and water, are still too small to be observed
-by the senses. They unite in their turn to form the
-microsomes, the first elements visible to the microscope.
-The microsomes, cemented by linin, form the
-filaments or links which are called mitomes. The
-living protoplasm is therefore nothing but a chain, or
-tangled skein, or a spongy skeleton formed by its
-filaments.</p>
-
-<p>Such is the typical constitution of living matter
-according to microscopic observation, supplemented by
-a perfectly reasonable hypothesis, which is, so to speak,
-only a translation of one of its most evident physical
-properties. This relatively simple scheme has become
-a complex scheme in the hands of later biologists.
-On the micellar hypothesis, which seems almost
-inevitable in its character, new hypotheses have been<span class="pagenum" id="Page_170">[Pg 170]</span>
-grafted, merely for the sake of convenience. Hence,
-we are led farther and farther from the real truth,
-and this is why, in order to explain the phenomena
-of heredity, we find ourselves compelled to intercalate
-hypothetical elements between micellæ and
-the microsome in the higher hierarchy quoted above—gemmules,
-pangenes, plasomes, which are only mental
-pictures or simple images to represent them.</p>
-
-
-<h4>§ 4. <span class="smcap">The Individuality of Complex Beings.
-Law of the Constitution of Organisms.</span></h4>
-
-
-<p><i>Individuality of Complex Beings.</i>—From the cellular
-doctrine follows a remarkably suggestive conception
-of living beings. The metazoa and the metaphytes—that
-is to say, the multicellular living beings which
-may be seen with the eyes and do not require the
-microscope to reveal them—are an assemblage of
-anatomical elements and the posterity of a cell.
-The animal or the plant, instead of being an
-individual unity, is a “multitude,” a term which is
-used by Goëthe himself when pondering, in 1807, over
-the doctrine taught by Bichat; or, according to the
-equally correct expression of Hegel, it is a “nation”;
-it springs from a common cellular ancestor, just as
-the Jewish people sprang from the loins of Abraham.</p>
-
-<p>We now picture to ourselves the complex living
-being, animal or plant, with its configuration which
-distinguishes it from every other being, just as a
-populous city is distinguished by a thousand
-characteristics from its neighbour. The elements
-of this city are independent and autonomous for the
-same reason as the anatomical elements of the<span class="pagenum" id="Page_171">[Pg 171]</span>
-organism. Both have in themselves the means of
-life, which they neither borrow nor take from their
-neighbours nor from the whole. All these inhabitants
-live in the same way, are nourished and breathe in
-the same manner, all possessing the same general
-faculties, those of man; but each has besides, his
-profession, his trade, his aptitudes, his talents, by
-which he contributes to social life, and by which in
-his turn he depends on it. Professional men, the
-mason, the baker, the butcher, the manufacturer, the
-artist, carry out different tasks and furnish different
-products, the more varied, the more numerous and
-the more differentiated, in proportion as the social
-state has reached a higher degree of perfection. The
-living being, animal or plant, is a city of this kind.</p>
-
-<p><i>Law of the Constitution of Organisms.</i>—Such is
-the complex animal. It is organized like the city.
-But the higher law of this city is that the conditions
-of the elementary or individual life of all the anatomical
-citizens are respected, the conditions being
-the same for all. Food, air, and light must be
-brought everywhere to each sedentary element; the
-waste must be carried off in discharges which will
-free the whole from the inconvenience or the danger
-of such debris; and that is why we have the different
-forms of apparatus in the circulatory, respiratory,
-and excretory economy. The organization of the
-whole is therefore dominated by the necessities of
-cellular life. This is expressed in <i>the law of the constitution
-of organisms</i> formulated by Claude Bernard.
-The organic edifice is made up of apparatus and
-organs, which furnish to each anatomical element
-the necessary conditions and materials for the maintenance
-of life and the exercise of its activity. We<span class="pagenum" id="Page_172">[Pg 172]</span>
-now understand what is the life, and at the same
-time what is the death, of a complex being. The
-life of the complex animal, of the metazoon, is of two
-degrees; at the foundation, the activity proper to
-each cell, <i>elementary life</i>, cellular life; above, the
-forms of activity resulting from the association of the
-cells, <i>the life of the whole</i>, the sum or rather the
-complex of elementary partial lives. There is a
-solidarity between them produced by the nervous
-system, by the community of the general circulatory,
-respiratory apparatus, etc., and by the free communication
-and mixture of the liquids which constitute
-the media of culture for each cell. We shall
-have an opportunity of recurring to current ideas as
-to the morphological constitution of organisms.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_173">[Pg 173]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_III_3">CHAPTER III.<br />
-
-<small>THE CHEMICAL UNITY OF LIVING BEINGS.</small></h3></div>
-
-
-<p class="prel">The varieties and essential unity of the protoplasm—Its
-affinity for oxygen—The chemical composition of protoplasm—Its
-characteristic substances.—§ 1. The different
-categories of albuminoid substances—Nucleo-proteids—Albumins
-and histones—Nucleins.—§ 2. Constitution of
-nucleins.—§ 3. Constitution of histones and albumins—Schultzenberger’s
-analysis of albumin—Kossol’s analysis—The
-hexonic nucleus.</p>
-
-
-<p>The chemical unity of living beings corresponds to
-their morphological unity.</p>
-
-<p><i>The Varieties and Essential Unity of the Protoplasm.</i>—One
-essential feature of the living being is
-that it is composed of matter peculiar to it, which is
-called <i>living matter</i>, or <i>protoplasm</i>. But this is a
-somewhat incorrect way of expressing the facts.
-There is no unique living matter, no single protoplasm;
-their number is infinite, there are as many as
-there are distinct individuals. However like one
-man may be to another, we are compelled to admit
-that they differ according to the substance of which
-they are constituted. That of the first offers a certain
-characteristic personal to the first, and found in all
-his anatomical elements; similarly for the second.
-With Le Dantec we shall say that the chemical
-substance of Primus is not only of the substance of
-man, but in all parts of his body and in all his con<span class="pagenum" id="Page_174">[Pg 174]</span>stituent
-cells it is the exclusive substance of Primus;
-and, in the same way, the living matter of another
-individual Secundus will carry everywhere his personal
-impress, which differs from that of Primus.</p>
-
-<p>But it is none the less true that this absolute
-specificity is based with certainty only on differences
-which from the chemical point of view are exceedingly
-slight. All these protoplasms have a very analogous
-composition. And, if we regard as negligible the
-smallest individual, specific, generic, or ordinal variations
-we may then speak in a general manner of
-<i>protoplasm</i> or <i>living matter</i>.</p>
-
-<p>Experiment shows us, in fact, that the real living
-substance—apart from the products it manufactures
-and can retain or reject—is in every cell tolerably
-similar to itself. The fundamental chemical resemblance
-of all protoplasms is certain, and thus
-we may speak of their typical composition. We
-may sum up the work of physiological chemistry for
-the last three quarters of a century by affirming that
-it has established the chemical unity of all living
-beings—that is to say, a very notable analogy in the
-composition of their protoplasm.</p>
-
-<p>This living matter is essentially a mixture of the
-proteid or albuminoid substances, to which may be
-added other categories of immediate principles, such
-as carbohydrates and fatty matters. But the latter
-are of secondary importance. The essential element
-is the proteid substance. The most skilful chemists
-have tried for more than half a century to discover
-its composition. Only during the last few years—thanks
-to the researches of Kossel, the German
-chemist, following on those of Schultzenberger and
-Miescher—we are beginning to know the outer walls<span class="pagenum" id="Page_175">[Pg 175]</span>
-or the framework of the albuminoid molecule; in
-other words, its chemical nucleus.</p>
-
-<p><i>Physical Characters of Protoplasm.</i>—About 1860
-Ch. Robin thought that he had defined living matter
-sufficiently—or, at least, as perfectly as could be
-expected at that time—by attributing to it three
-physical characteristics. They were:—Absence of
-homogeneity, molecular symmetry, and the association
-of three orders of immediate principles—albuminoids,
-carbohydrates and fats. These characteristics assist,
-but do not suffice, to define the organization.</p>
-
-<p>No doubt the characteristics must be completed by
-the addition of a certain number of more subtle
-physical features.</p>
-
-<p>One of them refers to the structure of protoplasm
-as revealed by the microscope. Throughout the
-whole of the living kingdom, from the bacteria studied
-by Kunstler and Busquet to the most complicated
-protozoa, protoplasmic matter presents the same
-constitution, and in consequence, this structure of
-the protoplasm must be considered as one of its
-distinctive characters. It is not homogeneous; it
-is not the last term of the visible organization: it is
-itself organized. Experiment shows that it does not
-resist breaking up or crushing. Mutilations cause
-it to lose its properties. As for the kind of structure
-that it presents, it may be expressed by saying that it
-is that of a foamy emulsion.</p>
-
-<p>We saw above that our knowledge as to the physical
-condition of protoplasm has been completed by the
-theories of Bütschli’s micellæ or Pfeffer’s tagmata.</p>
-
-<p><i>Properties of the Protoplasm. Its Affinity for
-Oxygen.</i>—From the chemical point of view, living
-matter presents a very remarkable property—namely,<span class="pagenum" id="Page_176">[Pg 176]</span>
-a great affinity for oxygen. It absorbs it so greedily
-that the gas cannot remain in a free state in its
-neighbourhood. Living protoplasm, therefore, exercises
-a reducing power. But it does not absorb
-oxygen in this way for its own advantage; oxygen
-is not absorbed, as was supposed thirty years ago, to
-supply fuel wherewith to burn the protoplasm. The
-products are not those of its oxidation, of its own
-disintegration. They are the products of combustion
-of the reserve-stuff which is incorporated in it.
-These substances have been supplied to it from
-without, like the oxygen itself, with the blood. This
-was proved by G. Pflüger in 1872 to 1876. The
-protoplasm is only the focus, the scene, or the
-factor of combustion. It is not its victim, it does
-not itself furnish the fuel. It works like the chemist,
-who obtains a reaction with the substances that are
-given to him.</p>
-
-<p>As for the reducing power of protoplasm, A.
-Gautier in 1881 and Ehrlich in 1890 have given fresh
-proofs. A. Gautier in particular has insisted that the
-phenomena of combustion take place, so to speak,
-outside the cell, and at the expense of the products
-which surround it; while on the contrary the really
-active and living parts of the nucleus and of the
-cellular body, work protected by the oxygen, as in the
-case of anaerobic microbes.</p>
-
-<p>This result is of great importance. Burdon Sanderson,
-the late learned professor of physiology at the
-University of Oxford, has not hesitated to compare
-it to the discovery of respiratory combustion by
-Lavoisier. There is no doubt some exaggeration in
-the comparison; but there is, on the other hand, no
-less exaggeration in supposing that it is not of great<span class="pagenum" id="Page_177">[Pg 177]</span>
-importance. We may no longer in these days speak
-without reservation of the vital vortex of Cuvier, and
-of the incessant twofold movement of assimilation
-and dissimilation which is ever destroying living
-matter and building it up again. In reality, the
-living protoplasm varies very little; it only undergoes
-oscillations of very slight extent; it is the
-materials, the reserve stuff on which it operates, which
-are subject to continual transformations.</p>
-
-<p><i>Chemical Composition of Protoplasm.</i>—One of the
-the three characters attributed by Ch. Robin to living
-matter was its chemical composition, of which little
-was known in his time. He insisted on the constant
-presence in the living elements of three orders of
-immediate principles—proteid substances, carbohydrates,
-and fatty bodies. In reality the proteid
-substances, or albuminoids, alone are characteristic.
-The two other groups, carbohydrates and fatty bodies,
-are rather the signs and the products of the vital
-activity, than constituents of the matter on which it is
-exercised.</p>
-
-<p>It is therefore on the knowledge of the proteid
-substances that all the sagacity of biological chemists
-has been exercised. Their efforts for thirty years,
-and particularly in the last few years, have not been
-barren; they enable us to give a first rough sketch of
-the constitution of these substances.</p>
-
-
-<h4>§ 1. <span class="smcap">The Characteristic Substances of the
-Protoplasm. The Nucleo-Proteids.</span></h4>
-
-
-<p><i>The Different Categories of Albuminoid Substances.</i>—Albuminoid
-or proteid substances are extremely
-complex compounds, much more so than any of those<span class="pagenum" id="Page_178">[Pg 178]</span>
-which are being constantly studied by the chemist.
-They also are to be found in great variety. It has
-been difficult to separate them one from the other, to
-characterize them rigorously, or, in other words, to
-classify them. However, it has been done now, and
-we distinguish three classes which are differentiated
-at once from the physiological and from the chemical
-points of view. The first comprises the complete or
-typical albuminoids. They are the <i>proteids</i> or <i>nucleo-albuminoids</i>.
-They are to be found in the most active
-and most living parts of the protoplasm, and therefore
-in the spongioplasm of the cell and around the
-nucleus. The second group is formed of <i>albumins</i>
-and <i>globulins</i>, compounds already simpler, fragments
-derived from the destruction of the preceding, into
-which they enter as constituent elements. In the
-isolated state they do not belong to the really living
-protoplasm; they exist in the cellular juice, in the
-interstitial and circulating liquids in the blood and in
-the lymph. The third category comprises real but
-incomplete albuminoids. They are to be found in
-the portions of the economy which have a specialized
-or attenuated life, and are destined to serve as a
-support to the more active elements—<i>i.e.</i>, they contribute
-to the building up of the bony, cartilaginous,
-conjunctive, elastic tissues. They are called <i>albumoids</i>.
-It is naturally the first group, that of the
-proteids—<i>i.e.</i>, of the complete and characteristic compounds
-of the living substance—upon which the
-attention of the physiologists must be fixed. It is
-only quite recently that the clear definition of these
-substances has been given, and proteid compounds
-detected in the confused mass.</p>
-
-<p><i>The Nucleo-proteids.</i>—This progress in the char<span class="pagenum" id="Page_179">[Pg 179]</span>acterization
-and specification of the proteids required
-in the first place a knowledge of two particular compounds,
-the <i>nucleins</i> and the <i>histones</i>. This did not
-become possible until after the researches of Miescher
-and Kossel on the nucleins, which went on from 1874
-to 1892, and those of Lilienfeld and d’Yvor Bang on
-the histones, from 1893 to 1899. The complete
-albuminoids are constituted by the combination of
-two kinds of substances—albumins or histones on the
-one hand, and nucleins on the other. By combining
-solutions of albumins or histones with solutions of
-nuclein, the synthesis of the proteid is effected. The
-study of the properties and characteristics of these
-nucleo-albumins and nucleo-histones is going on at
-the present moment. It is being carried out with
-much method and with wonderful patience by the
-German school.</p>
-
-<p>All the proteids contain phosphorus in addition to
-the five chemical elements, carbon, oxygen, hydrogen,
-nitrogen, and sulphur, which are common to the
-other albuminoids. Another interesting feature in
-their history is that the action of the gastric juice
-divides them into their two constituents:—the nuclein,
-which is deposited and resists the destructive action
-of the digestive liquid, and the albumin or histone,
-which on the contrary experiences this action with
-the usual consequences. Thus the gastric juice
-furnishes a process which is very simple and very
-convenient in the analysis of the proteids.</p>
-
-<p><i>Localization of the Nucleo-Proteids.</i>—What we said
-before as to the important physiological rôle of the
-cellular nucleus may arouse the expectation that in it
-will be found the living matter which is chemically
-the most differentiated, the albuminoids of highest<span class="pagenum" id="Page_180">[Pg 180]</span>
-rank—<i>i.e.</i>, the nucleo-proteids and their constituents.
-Not that they would not be found in the protoplasm
-of the rest of the cell, but there is certainly a risk
-that they would be less concentrated there and more
-blended with accessory products; they are there connected
-with much more secondary vital functions.
-This conclusion inspired the early researches of Professor
-Miescher, of Basle, in 1874, and, twenty years
-later, those of Professor Kossel, one of the most
-eminent physiological chemists in Germany.</p>
-
-<p>In fact, these compounds have been found in all
-tissues which are rich in cellular elements with well-developed
-nuclei. The white globules of the blood
-furnished to Lilienfeld the first nucleo-histone ever
-isolated. The red globules themselves, when they
-possess a nucleus, which is the case in birds and
-reptiles as well as in the embryo of mammals, contain
-a nucleo-proteid which was easily isolated by Plosz and
-Kossel. Hammarsten, the Swedish chemist, who has
-acquired a great reputation from his researches in
-other domains of biological chemistry, prepared the
-nucleo-proteids of the pancreas in 1893. They have
-been obtained from the liver, from the thyroid
-gland (Ostwald), from brewers’ yeast (Kossel), from
-mushrooms, and from barley (Petit). They have
-been detected in starchy bodies and in bacteria
-(Galeotti).</p>
-
-
-<h4>§ 2. <span class="smcap">Constitution of Nucleins.</span></h4>
-
-
-<p><i>Constitution of Nucleins.</i>—Our path is already
-marked out if we wish to penetrate farther into the
-constitution of these proteids, which are the imme<span class="pagenum" id="Page_181">[Pg 181]</span>diate
-principles highest in complexity among those
-which form the living protoplasm. We must analyze
-the two components, the albumins and the histones on
-the one hand, and the nucleins on the other. As for
-the nucleins, this has already been done, or very
-nearly so.</p>
-
-<p>Kossel, in fact, decomposed the nuclein by a series
-of very carefully arranged operations, and has reduced
-it step by step to its crystallizable organic radicals.
-At each stage that we descend in the scale of
-simplification a body appears which is more acid and
-more rich in phosphorus. At the third stage we
-come to phosphoric acid itself. The first operation
-divides the nuclein into two substances: the new
-albumin and nucleinic acid. After separating these
-elements they can be reunited: a solution of albumin
-with a solution of nucleinic acid reconstitutes the
-nuclein. A second operation separates the nucleinic
-acid in its turn into three parts. One is a body of
-the nature of the sugars—<i>i.e.</i>, a carbohydrate. The
-appearance of a sugar in this portion of the molecule
-of nucleinic acid is an interesting fact and fertile in
-results. The second part is constituted by a mixture
-of nitrogenous bodies, well known in organic chemistry
-under the name of <i>xanthic bases</i> (xanthin, hypoxanthin,
-guanin, and adenin). The third part is a
-very acid body and full of phosphorus—thymic acid.
-If in a third and last operation the thymic acid is
-analyzed, it is finally separated into phosphoric acid
-and into thymene, a crystallizable base, and thus we
-are brought back to the physical world, for all these
-bodies incontestably belong to it.</p>
-
-<p><span class="pagenum" id="Page_182">[Pg 182]</span></p>
-
-
-<h4>§ 3. <span class="smcap">The Constitution of Histones and
-Albumins.</span></h4>
-
-
-<p><i>Constitution of Histones.</i>—But we are only half-way
-through our task. We are acquainted in its origin
-with one of the genealogical branches of the proteid,
-the nucleinic branch. We must also learn something
-of the other branch, the albumin or histone branch.
-But on this side the problem assumes a character of
-difficulty and complexity which is admirably adapted
-to discourage the most untiring patience.</p>
-
-<p>The analysis of albumin for a long time baulked
-the chemist “Here,” said Danilewsky, “we come to
-a closed door which resists all our efforts.” We know
-how vastly interesting what is taking place on the
-other side must be, but we cannot get there. We get
-a mere glimpse through the cracks or chinks which
-we have been able to make.</p>
-
-<p>This analysis of albuminous matter at first requires
-great precautions. The chemist finds himself in the
-presence of architecture of a very subtle kind. The
-molecule of albumin is a complex edifice which has
-used up several thousand atoms. To perceive the
-plan and structure, it must be dismantled and
-separated into parts which are neither too large nor
-too small. Such careful demolition is difficult.
-Processes too rough or too violent will reduce the
-whole to the tiniest of fragments. It is a statue
-which may be reduced to dust, instead of being
-separated into recognizable fragments, easily fitted in
-place along their fractured faces.</p>
-
-<p><i>Analysis of Albumin by Schützenberger.</i>—Schützenberger,
-a chemist of great merit, attempted (about<span class="pagenum" id="Page_183">[Pg 183]</span>
-1875) this thankless task. Others before him had
-experimented in various ways. Two Austrian
-scientists, Hlasitwetz and Habermann, in 1873, and
-a little later Drechsel in 1892, had used concentrated
-hydrochloric acid to break down albumin.
-They also employed bromine for the same purpose.
-More recently Fuerth had used nitric acid with a
-similar object. Schützenberger tried another way.
-The battering ram which he used against the edifice
-of albumin was a concentrated alkali, baryta. He
-warmed the white of an egg with barium hydrate
-in a closed vessel at a temperature of 200°. The
-albumin of egg then divides into a certain number of
-simpler groups. The difficulty is to isolate and to
-recognize each part in this mass of the materials of
-demolition. That can be done by the aid of the
-processes of direct analysis. By mentally combining
-these different fragments, the original building is
-reconstructed. This method of demolition is certainly
-too rough and violent. Schützenberger’s operation
-gives us very fine fragments—small molecules of free
-hydrogen, of ammonia, of carbonic, acetic, and oxalic,
-acids which reveal extreme pulverization. These
-products represent about a quarter of the total mass.
-The other three-quarters are formed of larger fragments,
-the examination of which is most instructive.
-They belong to four groups. The first comprises five
-or six bodies, amido-acids or <i>leucins</i>. It proves the
-existence in the molecule of albumin of compounds of
-the series of fats—<i>i.e.</i>, arranged in an open chain.
-The second group is formed by tyrosin and kindred
-products—<i>i.e.</i>, by the bodies of the aromatic series,
-which force us to acknowledge the presence in the
-molecule of albumin of a benzene nucleus. The third<span class="pagenum" id="Page_184">[Pg 184]</span>
-group forms around the nucleus known to chemists
-under the name of pyrrol. The fourth comprises
-bodies such as the glucoproteins, connected with the
-sugars, or carbohydrates.</p>
-
-<p>Does the fact that the molecule of albumin is
-destroyed in producing these compounds raise the
-question as to whether it implies the idea that in
-reality they pre-exist in it? Chemists are rather
-inclined to admit this. However, the conclusion does
-not appear to be permissible. Duclaux considers it
-doubtful. It is not certain that all these fragmentary
-bodies pre-exist in reality, and it is no more certain
-that a simple bringing of them together represents
-the primitive edifice. Materials of demolition from a
-house that has been pulled down give no idea of its
-natural architectural character. There is only one
-way of justifying the hypothesis, and that is to reconstitute
-the original molecule of albumin by bringing
-the fragments together. We have not got to that
-stage yet. The era of syntheses of such complexity
-is more or less near, but it has certainly not yet
-begun.</p>
-
-<p>Moreover, it is not correct to say that the simple
-juxtaposition of the surfaces of fracture will reproduce
-the initial body. The fragments, so far as analysis
-has obtained them, are not absolutely what they might
-have been in the original structure. There they
-adhered the one to the other, not only by the mere
-contact of their surfaces of fracture, as is supposed,
-but in a slightly more complex manner. The fragments
-of the molecule are joined by bonds. We can
-picture them to ourselves by supposing these bonds
-to be like hooks. The hooks, which could only be
-broken by violence, are called by the chemists<span class="pagenum" id="Page_185">[Pg 185]</span>
-<i>satisfied atomicities</i>. These atomicities, set free by
-the breaking up, cannot remain in this condition;
-they must be satisfied anew. The hook tries to attach
-itself. In Schützenberger’s experiment the addition
-of water provides for this necessity. A molecule of
-water (H<sub>2</sub>O) splits into two, the hydrogen (H) on the
-one side and the hydroxyl (OH) on the other. These
-two elements cling to the liberated bonds of the
-fragments of the molecule of albumin, and thus
-the bodies were found complete. Schützenberger’s
-experiment was too violent, too radical, and it gave
-too large a number of fragments, with their free hooks
-and atomicities unsatisfied, for rather a large proportion
-of the water added disappeared during the
-experiment. In one case this quantity was as much
-as 17 grammes per 100 grammes of albumin. The
-molecules of this water were employed in the
-reparation of the incomplete fragmentary molecules
-of the albumin.</p>
-
-<p>It follows that Schützenberger’s experiment gave
-too large a number of very small pieces corresponding
-to far too great a pulverization. The very small fragments
-are the molecules of acids such as acetic acid,
-oxalic acid, carbonic acid, molecules of ammonia,
-and even of hydrogen, which we know we are setting
-free.</p>
-
-<p>But, apart from these products which represent a
-quarter of the molecule of albumin submitted to
-analysis, the other three quarters represent larger
-fragments which may be considered as the real
-constituents of the building. Thus we find four
-kinds of groups which may be accepted as natural.
-The first of these groups is that of the leucins or
-amido-acids. It proves the existence in the molecule<span class="pagenum" id="Page_186">[Pg 186]</span>
-of albumin of compounds of the fatty series. There
-is also an aromatic group—a pyridine group—and a
-group belonging to the category of sugars. Imagine
-a certain grouping of these four series. This would
-be the nucleus of the molecule of albumin. If we
-graft on to this nucleus, on to this framework as it
-were, so many annexes, or lateral chains, the building
-will be loaded with embellishments; it will have
-been made unstable and <i>ipso facto</i> appropriate for the
-part that it plays in the incessant transformations
-of the organism.</p>
-
-<p><i>Kossel’s Analysis. Hexonic Nucleus.</i>—Kossel has
-approached the problem in another fashion. He
-did not attempt to attack the albumin of the egg.
-This body is, in fact, a heterogeneous mixture as
-complex as the needs of the embryo of which it forms
-the food. Kossel tried a physiologically simpler
-albuminoid. He got it from an anatomical element
-having no nutritive rôle, of a very elementary
-organization and physiological functional activity,
-and yet one of energetic vitality—the male generating
-cell. Instead of the hen’s egg he therefore analyzed
-the milt of fish, and, in the first place, of salmon. As
-was to be expected from what has been said of the
-proteids, this living matter gives a combination of
-the nuclein, already known, with an albumin. The
-latter is abundant, forming a quarter of the total
-mass. Its reaction is strongly alkaline, which is the
-general characteristic of the variety of albumin known
-by the name of histones. Miescher, the learned
-chemist of Basle, who had noticed this basic albumin
-when working on the Rhine salmon, gave it the name
-of protamin. This is the substance submitted by
-Kossel to analysis in preference to the albumin of<span class="pagenum" id="Page_187">[Pg 187]</span>
-egg, so dear to the chemists who had preceded him.
-The disintegration of this molecule, instead of giving
-the series of bodies obtained by Schützenberger,
-gave but one, a real chemical base, <i>arginin</i>. At the
-first trial the albumin examined was reduced to a
-simple crystallizable element. The conclusion was
-obvious. The protamin of salmon is the simplest of
-albumins. To form this elementary proteid substance
-a hexonic base with water is all that is required.</p>
-
-<p>Continuing on these lines other male generating
-cells were examined and a series of protamines constructed
-on the same type was found, and these
-albuminous bodies proved to be formed of a base or
-mixture of analogous hexonic bases: arginin, histidin,
-and lysin—all bodies closely akin in their properties
-and entirely belonging to the physical world.</p>
-
-<p>Once aware of the existence of this fundamental
-nucleus, chemists found it in the more complex
-albumins where it had been missed. It was found in
-the albumin of egg hidden under the mass of other
-groups. It was recognized in all animal or vegetable
-albumins. The nuclei of Schützenberger may be
-missing. Hexonic bases are the constant and
-universal element of all varieties of albumins. They
-prevail in the chemical nucleus of the albuminous
-molecule, and perhaps as is suggested by Kossel,
-they may form it exclusively. All the other elements
-are superadded and accessory. The essential type of
-this molecular edifice, sought for so long, is known at
-last.</p>
-
-<p><i>Conclusion.</i>—To sum up, the chemical unity of
-living beings is expressed by saying that living
-matter, protoplasm, is a mixture or a complex of
-proteid substances with an hexonic nucleus.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_188">[Pg 188]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_IV_3">CHAPTER IV.<br />
-
-<small>THE TWOFOLD CONDITIONING OF VITAL
-PHENOMENA. IRRITABILITY.</small></h3></div>
-
-
-<p class="prel">Appearance of internal activity of the living being—Vital
-phenomena regarded as a reaction of the ambient world.—§
-1. Extrinsic conditions—The optimum law.—§ 2. Intrinsic
-conditions—The structure of organs and apparatus—How
-experiment attacks the phenomena of life. Generalization
-of the law of inertia—Irritability.</p>
-
-
-<p><i>Instability. Mutability. The Appearance of Internal
-Activity of the Living Being.</i>—One of the most
-remarkable characteristics of the living being is its
-instability. It is in a state of continual change. The
-simplest of the elementary beings, the plastid, grows
-and goes on growing and becoming more complex,
-until it reaches a stage at which it divides, and thus
-rejuvenated it commences the upward march which
-leads it once again to the same segmentation. Its
-evolution is thus betrayed by its growth, by the
-variations of form which correspond to it, and by
-its division.</p>
-
-<p>If it be a question of beings higher in organization
-than the cellular element the evolutionary
-character of this mutability becomes more obvious.
-The being is formed, it grows; then in most cases,
-after having passed through the stages of youth and
-adult age, it grows old, declines and dies, and is<span class="pagenum" id="Page_189">[Pg 189]</span>
-disorganized after having gone through what we may
-call an ideal trajectory. This march in a fixed
-direction with its points of departure, its degrees, and
-its termination, is a repetition of the path that the
-ancestors of the living being have already followed.</p>
-
-<p>Here, then, is a characteristic fact of vitality, or
-rather there are two facts. The one consists in this
-morphological and organic evolution, the negation of
-immutability, the negation of the indefinite maintenance
-of a permanent state or form which is
-regarded, on the contrary, as the condition of inert,
-fixed stable bodies, eternally at rest. The other
-consists in the repetition, realized by this evolution,
-of the similar evolution of its ancestors; this is a
-fact of heredity. Finally, evolution is always in a
-cycle—that is to say, that it comes to an end which
-brings the course of things to their point of departure.</p>
-
-<p>This kind of internal activity of the living being
-is so striking, that not only does it serve us to
-differentiate the living being from the inert body,
-but it gives rise to the illusion of a kind of internal
-demon, vital force, manifested by the more or less
-apparent acts of the life of relation, of the motricity,
-of the displacement, or by the less obvious acts of
-vegetative life.</p>
-
-<p><i>Vital Phenomena regarded as a Reaction of the
-Ambient World. Their Twofold Conditioning.</i>—In
-reality, as the doctrine of energetics teaches us, the
-phenomena of vitality are not the effect of a purely
-internal activity. They are a reaction of the environment.
-“The idea of life,” says Auguste Comte,
-“constantly assumes the necessary correlation of two
-indispensable elements:—an appropriate organism
-and a suitable environment. It is from the reciprocal<span class="pagenum" id="Page_190">[Pg 190]</span>
-action of these two elements that all vital phenomena
-inevitably result.” The environment furnishes the
-living being with three things:—its matter, its
-energy, and the exciting forces of its vitality. All
-vital manifestation results from the conflict of two
-factors: the extrinsic factor which provokes its
-appearance; the intrinsic factor, the very organization
-of the living body, which determines its form.
-Bichat and Cuvier saw in the phenomena of life the
-exclusive intervention of a principle of action entirely
-internal, checked rather than aided by the universal
-forces of nature. The exact opposite is true. The
-protozoan finds the stimuli of its vitality in the
-aquatic medium which is its habitat. The really
-living particles of the metazoan—that is to say, its
-cells, its anatomical elements—meet these stimuli in
-the lymph, in the interstitial liquids which bathe
-them and which form their real external environment.</p>
-
-<p>Auguste Comte thoroughly understood this truth,
-and has clearly expressed it in the passage we have
-just quoted. Claude Bernard has fully developed it
-and given it its classical form.</p>
-
-<p>In order to manifest the phenomena of vitality,
-the elementary being, the protoplasmic being, requires
-from the external world certain favourable
-conditions; these it finds there, and they may be
-called the stimuli, or extrinsic conditions of vitality.
-This being possesses no initiative or spontaneity in
-itself, it has only a faculty of entering into action
-when an external stimulus provokes it. This subjection
-of the living matter is called <i>irritability</i>.
-The term expresses that life is not solely an internal
-attribute, but an internal principle of action.</p>
-
-<p><span class="pagenum" id="Page_191">[Pg 191]</span></p>
-
-
-<h4>§ 1. <span class="smcap">Extrinsic Conditions.</span></h4>
-
-<p><i>Extrinsic Conditions.</i>—By showing that every vital
-manifestation results from the conflict of two factors:
-the extrinsic or physico-chemical conditions which
-determine its appearance, and the intrinsic or organic
-conditions which regulate its form, Claude Bernard
-dealt a mortal blow at the old vitalist theories. For
-he has not only asserted the close dependence of the
-two kinds of factors, but he has shown them in action
-in most physiological phenomena. The study of the
-extrinsic or physico-chemical conditions necessary to
-vital manifestations teaches us our first truth—namely,
-that they are not infinitely varied as might
-be supposed. They present, on the contrary, a
-remarkable uniformity in their essential qualities.
-The fundamental conditions are the same for the
-animal or vegetable cells of every species. They are
-four in number:—<i>moisture</i>, the air, or rather <i>oxygen</i>,
-<i>heat</i>, and a certain <i>chemical constitution</i> of the medium,
-and the last condition, the enunciation of which
-seems vague, becomes more precise if we look at it
-a little closer. The chemical constitution of media
-favourable to life, the media of culture, obeys three
-general laws. It is the knowledge of these laws
-which formerly enabled Pasteur, Raulin, Cohn, and
-Balbiani to provide the media appropriate to the
-existence of certain relatively simple organisms, and
-thus to create an infinitely valuable method for
-the study of nutrition, etc.,—namely, the <i>method of
-artificial cultures</i>, numerous developments of which
-have been shown us by microbiology and physiology.</p>
-
-<p><i>The Optimum Law.</i>—It has been said, and it is
-more than a play on words, that the conditions of<span class="pagenum" id="Page_192">[Pg 192]</span>
-the vital medium were the conditions of the <i>juste
-milieu</i>. Water is wanted, there must not be too
-much or too little. Oxygen is necessary, and also in
-certain proportions. Heat is required, and for that,
-too, there is an optimum degree. Certain chemical
-compounds are needed and, in this respect too, there
-must also be <i>optima</i> proportions.</p>
-
-<p>Water is a constituent element of the organisms.
-They contain fixed proportions for the same tissue,
-proportions varying from one tissue to another
-(between 2∕3 and 9∕10). The cell of a living tissue requires
-around it an aqueous atmosphere, formed by
-the different juices of the organism, the interstitial
-liquids, the blood, and the lymph. We are deceived
-by appearances when we distinguish between aerial,
-aquatic, and land-dwelling animals, and when we
-speak of the air, the water, and the land as their
-natural environment. If we go to the bottom of
-things, and fix our attention on the real living
-unities, on the cells of which the organism is composed,
-we shall find around them the juices, rich in water,
-which are their real environment. If these juices are
-diluted or concentrated the least in the world, life
-stops. The cell, the whole animal, falls into a state
-of latent life, or dies. “All living beings are aquatic,”
-said Claude Bernard. “Beings that live in the air are
-in reality wandering aquariums,” said another physiologist.
-“No moisture, no life,” wrote Preyer. The
-environment must contain water, but it must contain
-it in certain proportions. In the higher animals
-there is a mechanism which works automatically to
-keep at a constant level the quantity of water in the
-blood. Researches on the lavage of the blood (A.
-Dastre and Loye) have clearly shown this.</p>
-
-<p><span class="pagenum" id="Page_193">[Pg 193]</span></p>
-
-<p>Oxygen is also necessary to life. It is the <i>pabulum
-vitæ</i>. But the discovery of the beings called by
-Pasteur <i>anaerobia</i> appears to contradict this statement.
-Pfeffer, the illustrious botanist, was certain,
-in 1897, that the dogma of the necessity of oxygen
-no longer held good. This is no longer tenable.
-In 1898 Beijerinck carried out most careful researches
-on anaerobia said to have been cultivated
-in a vacuum, such as the <i>bacteria of tetanus</i> and the
-<i>septic vibrion</i>; or on those to which oxygen seems to
-be a poison, such as the <i>butyric</i> and the <i>butylic
-ferments</i>, the anaerobia of putrefaction, the reducing
-spirilla of the sulphates. All use free oxygen. They
-consume very little it is true; they are micro-aerobia.
-The other organisms, on the contrary, need more.
-They are macro-aerobia or simply <i>aerobia</i>. Besides,
-if the so-called anaerobia take little or no free
-oxygen, it matters little. They take the oxygen
-in combination. It may be said with L. Errera
-that they have an affinity for oxygen, for they
-extract it from its combinations, and that “they
-are so well adapted to this mode of existence that
-life in the open air being too easy no longer suits
-them.” There are for the different animal species
-different optima of oxygen.</p>
-
-<p>Living beings require a certain amount of heat.
-Life, which could not have existed on the globe when
-it was incandescent, will not be able to exist when it
-is frozen. For each organism and each function
-there is a maximum and a minimum of temperature
-compatible with activity. There is also an optimum.
-For instance, the optimum is 29° C for the germination
-of corn.</p>
-
-<p>The condition of the optimum exists in the same<span class="pagenum" id="Page_194">[Pg 194]</span>
-way for the chemical composition of the vital medium—and
-for the other ambient physical conditions, such
-as atmospheric pressure.</p>
-
-<p>It is therefore a law of <i>universal</i> scope, a regulating
-law, as it were, of life. Life is a function of extrinsic
-variables, water, air, heat, the chemical composition of
-the medium, and pressure. “Every vital phenomenon
-begins to be produced, starting from a certain stage
-of the variable (minimum), becomes more and more
-vigorous as it increases up to a determinate value
-(optimum), weakens if the variable continues to increase,
-and disappears when it has reached a certain
-limiting value (maximum).” This law, proved by
-Sachs, the German botanist, in 1860, apropos of the
-action of temperature on the germination of plants,
-by Paul Bert in 1875, apropos of the action of oxygen
-and of atmospheric pressure on animals, and already
-formulated at that time by Claude Bernard, was
-illustrated by Leo Errera in 1895. It is a law of
-moderation. It expresses La Fontaine’s “<i>rien de
-trop</i>” Terence’s “<i>ne quid nimis</i>,” the μηδὲν ἄγαν of
-Theognis, and the biblical phrase “<i>omnia in mensura
-et numero et pondere</i>.” L. Errera sees the profound
-cause of this optimum law in the properties of the
-living protoplasm, which are mean properties. It
-is semi-liquid. It is composed of albuminoid substances,
-which can stand no extremes either from the
-physical or from the chemical points of view.</p>
-
-
-<h4>§ 2. <span class="smcap">Intrinsic Conditions. The Law of the
-Constitution of Organs and Apparatus.</span></h4>
-
-
-<p><i>Law of the Constitution of Organs and Apparatus.</i>—If
-we consider more highly organized beings, the<span class="pagenum" id="Page_195">[Pg 195]</span>
-influence of the intrinsic conditions appears quite
-as clearly. As we have seen, this is so that the
-requisite fundamental materials may be spent by
-each element in suitable proportions,—water, chemical
-compounds, air, and heat,—that organs may be added
-to organs, and that apparatus may be set to work in
-complex structures. Why a digestive apparatus?
-To prepare and introduce into the internal medium
-liquid materials which are necessary to life. Why a
-respiratory apparatus? To impart the vital gas
-necessary to the cells, and to expel the gaseous
-excrement, the carbonic acid which they reject.
-Why a circulatory apparatus? To transport and
-renew this medium throughout. The apparatus, the
-functional wheels, the vessels, the digestive and
-respiratory mechanisms do not exist for themselves,
-like the random sketches of an artistic nature. They
-exist for the innumerable anatomical elements which
-people the economy. They are arranged to assist
-and more rigorously to regulate cellular life with
-respect to the extrinsic conditions which it demands.
-They are, in the living body, as in civilized society,
-the manufactories and the workshops which provide
-for the different members of society dress, warmth,
-and food. In a word, the <i>law of the construction of
-organisms</i> or of the <i>bringing to perfection of an
-organism</i> is the same as the law of cellular life. It
-is otherwise suggestive as the law of <i>division of
-physiological labour</i> formerly enunciated by Henry
-Milne-Edwards; and in every case it has a more
-concrete significance. Finally, it brings the organic
-functional activity into relation with the conditions of
-the ambient medium.</p>
-
-<p><i>How Experiment acts on the Phenomena of Life.</i>—<span class="pagenum" id="Page_196">[Pg 196]</span>
-The two orders of conditions, the one provided by the
-being itself, the other by external agents, are equally
-indispensable—and therefore of equal importance or
-dignity. But they are not equally accessible to the
-experimentalist. It is not easy to exercise on the
-organization direct and measurable actions. On the
-contrary, the physical conditions are in the hands
-and at the discretion of the experimenter. By them
-he may reach the vital manifestations as they appear,
-stimulate or check them, defer or precipitate them.
-Thus, for instance, the physiologist suspends or re-establishes
-at his will full vital activity in a multitude
-of reviviscent or hibernating beings, such as grains,
-the infusoria capable of <i>encystment</i>, the vibrio, the
-tardigrade, the cold-blooded animals, and perennial
-plants.</p>
-
-<p>The ambient world therefore furnishes to the animal
-and to the vegetable, whole or fragmentary, those
-materials of its organization which are at the same
-time the stimuli of its vitality. That is to say, the
-vital mechanism would be a dormant and inert
-mechanism if nothing in the surrounding medium
-could provoke it to action or give it a check. It
-would be a kind of steam engine without coal and fire.</p>
-
-<p>Living matter, in other words, does not possess real
-spontaneity. As I have shown elsewhere, the law of
-inertia which it is supposed it obeys with inert bodies
-is not special to them. It is applied to the living
-bodies whose apparent spontaneity is only an illusion
-contradicted by physiology as a whole. All the vital
-manifestations are responses to a stimulus of acts
-provoked, and not of spontaneous acts.</p>
-
-<p><i>Generalization of the Law of Inertia in Living
-Bodies. Irritability.</i>—In fact, vulgar prejudice opposes<span class="pagenum" id="Page_197">[Pg 197]</span>
-this view. The opinion of the average man distrusts
-it. It applies the law of inertia only to inert matter.
-This is because the vital response does not always
-immediately succeed the external stimulus, and is not
-always proportional to it. But it is sufficient to have
-seen the flywheel of a steam engine to understand
-that the restitution of a mechanical force cannot be
-instantaneous. It is sufficient to have had a finger
-on the trigger of a firearm to know that there is no
-necessary proportion between the intensity of the
-stimulus and the magnitude of the force produced.
-Things happen in the living just as in the inert
-machine.</p>
-
-<p>The faculty of entering into action when provoked
-by an external stimulus has received, as we have said,
-the name of <i>irritability</i>. The word is not used of
-inert matter. However, the condition of the latter is
-the same. But there is no need to affirm its irritability,
-because no one denies it. We know perfectly
-well that brute matter is inert, that all the manifestations
-of activity of which it is the theatre are provoked.
-Inertia is for it the equivalent of irritability in living
-matter. But while it is not necessary to introduce
-this idea into the physical sciences, where it has
-reigned since the days of Galileo, it was, on the
-contrary, necessary to affirm it in biology, precisely
-because it was in biology that the opposing doctrine
-of vital spontaneity ruled supreme.</p>
-
-<p>Such was the view held by Claude Bernard. He
-never varied on this point. <i>Irritability</i>, said he, is the
-property possessed “by every anatomical element
-(that is to say, the protoplasm which enters into its
-constitution) of being stimulated into activity and of
-reacting in a certain manner under the influence of<span class="pagenum" id="Page_198">[Pg 198]</span>
-the external stimuli.” He could not claim that this
-was a distinguishing characteristic between living
-bodies and brute bodies, and that all the less because
-he always tried to efface on this point the distinctions
-which were current in his time, and which were
-established by Bichat and Cuvier. And so also Le
-Dantec does not seem to have thoroughly grasped
-the ideas of the celebrated physiologist on this point
-when he asserts, as if he were thereby contradicting
-the opinion of Claude Bernard and his school, that
-irritability is not something peculiar to living bodies.<a id="FNanchor_17" href="#Footnote_17" class="fnanchor">[17]</a></p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_199">[Pg 199]</span></p>
-<h3 class="nobreak" id="CHAPTER_V_3">CHAPTER V.<br />
-
-<small>THE SPECIFIC FORM. ITS ACQUISITION.
-ITS REPARATION.</small></h3></div>
-
-
-<p class="prel">§ 1. Specific form not special to living beings—Connected with
-the whole of the material conditions of the body and the
-medium—Is it a property of chemical substance?—§ 2.
-Acquisition and re-establishment of the specific form—Normal
-regeneration—Accidental regeneration in the protozoa
-and the plastids—In the metazoa.</p>
-
-
-<h4>§ 1. <span class="smcap">The Specific Form.</span></h4>
-
-<p><i>The Specific Form is not Peculiar to Living Beings.</i>—The
-position of a <i>specific form</i>—the acquisition of
-this typical form progressively realized—the re-establishment
-when some accident has altered it—these
-are the features which we consider distinctive of living
-beings, from the protophytes and the lowest protozoa
-to the highest animals. Nothing gives a better idea
-of the unity and the individuality of the living being
-than the existence of this typical form. We do not
-mean, however, that this characteristic belongs to the
-living being alone, and is by itself capable of defining
-it. We repeat that this is not a case with any
-characteristic. In particular the <i>typical form</i> belongs
-to crystal as well as to living beings.</p>
-
-<p><i>The Specific Form depends on the sum of Material
-Conditions of the Body and the Medium.</i>—The consideration
-of mineral bodies shows us form dependent<span class="pagenum" id="Page_200">[Pg 200]</span>
-on the physico-chemical conditions of the body and
-the medium. The form depends mainly on physical
-conditions in the cases of a drop of water falling from
-a tap, of the liquid meniscus in a narrow tube, of a
-small navel-shaped mass of mercury on a marble
-slab, of a drop of oil “emulsioned” in a solution, and
-of the metal which is hardened by hammering or
-annealed. In the case of crystals the form depends
-more on chemical conditions. It is crystallization
-which has introduced into physics the idea that has
-now become a kind of postulate—namely, that the
-specific form is connected with the chemical composition.
-However, it is sufficient to instance the dimorphism
-of a simple body, such as sulphur, sometimes
-prismatic, sometimes octahedric, to realize that substance
-is only one of the factors of form, and that the
-physical conditions of the body and of the medium
-are other factors quite as influential.</p>
-
-<p><i>Is the Specific Form a Property of the Chemical
-Substance?</i>—How much truer this restriction would
-be if we consider, instead of a given chemical compound,
-an astonishingly complex mixture, such as
-protoplasm or living matter, or the more complex
-organism still—the cell, the plastid.</p>
-
-<p>Are there not great differences between the substance
-of the cellular protoplasm, or cytoplasmic
-substance, and that of the nucleus? Should we not
-distinguish in the former the hyaloplasmic substance;
-the microsomic in the microsomes; the linin between
-its granulations; the centrosomic in the centrosome;
-the archoplasmic in the attraction sphere; not to
-mention the different leucins, the vacuolar juice, and
-the various inclusions? And in the nucleus must we
-not consider the nuclear juice, the substance of the<span class="pagenum" id="Page_201">[Pg 201]</span>
-chromosomes, and that of the nucleoles? And is not
-each of these probably a very complex mixture?</p>
-
-<p>However, it is to this mixture that we attribute the
-possession of a form, in virtue of and by extension of
-the principles of crystallization, which definitely teach
-us that these mixtures cannot have form; that form
-is the attribute of pure bodies, and is only obtained
-by the separation of the blended parts—<i>i.e.</i>, by a
-return to homogeneity. There are therefore very
-good reasons for hesitating before we transfer the
-absolute principle of the dependence between
-chemical form and composition, as some philosophical
-biologists have done, from the physical
-sciences—where it is already subject to serious
-restrictions—to the biological sciences.</p>
-
-<p>Le Dantec, however, has made this principle the
-basis of his biological system. He therefore finds in
-the crystal the model of the living being. He thus
-gives a physical basis to life.</p>
-
-<p>Is it a question in this system of explaining this
-incomprehensible, this unfathomable mystery, which
-shows the egg cell attracting to itself materials from
-without and progressively building up that amazing
-structure which is the body of the animal, the body of
-a man, of any given man, of Primus, for example?
-It is said that the substance of Primus is specific.
-His living substance is his own, special to him; and
-that, too, from the beginning of the egg to the end of
-its metamorphosis. It only remains to apply to this
-substance the postulate, borrowed from crystallography,
-of the absolute dependence of the nature of
-substance on the form it assumes. The form of the
-body of the animal, of the man, of Primus, is the
-crystalline form of their living substance. It is the<span class="pagenum" id="Page_202">[Pg 202]</span>
-only form of equilibrium that this substance can
-assume under the given conditions, just as the cube is
-the crystallized form of sea salt, the only state of
-equilibrium of chloride of sodium in slowly evaporated
-sea water. Thus the problem of the living form is
-reduced to the problem of the living substance, which
-seems easier; and at the same time the biological
-mystery is reduced to a physical mystery. It is clear
-that this way of looking at things simplifies prodigiously—and,
-we must add, simplifies far too much—the
-obscure problem of the relation of form to
-substance, simultaneously in the two orders of science.
-This may be summed up in a single sentence:
-There is an established relation between the specific
-form and the chemical composition: the chemical
-composition <i>directs</i> and implies the specific form.</p>
-
-<p>We need not now examine the basis of this opinion.
-If it is nothing but a verbal simplification, a unification
-of the language applied to the two orders of
-phenomena, it implies an assimilation of the mechanisms
-which realize them. To the organogenic forces
-which direct the building up of the living organisms
-it brings into correspondence the crystallogenic forces
-which group, adjust, equilibrate, and harmonize the
-materials of the crystal.</p>
-
-<p>When it is a question of the application of a
-principle such as this, in order to test its legitimacy
-we must always return to the experimental foundations.
-Let us imagine, for example, a simple body,
-such as sulphur, heated and brought to a state of
-fusion—that is to say, homogeneous, isotropic, in an
-undisturbed medium the only change in which will
-be a very gradual cooling down. These are the
-typical crystallogenic conditions. The body would<span class="pagenum" id="Page_203">[Pg 203]</span>
-take a given crystalline form. It is from experiments
-such as this that we derive the idea of <i>a specific form
-connected with a chemical constitution</i>.</p>
-
-<p>But in drawing this conclusion our logic is at fault.
-The real interpretation suitable to this case, as in all
-others, is that the specific form is suitable to the
-substance, and also to the physical, chemical, and
-mechanical conditions in which it is placed. And
-the proof is that this same substance, sulphur, which
-takes the prismatic form immediately after fusion,
-will not retain that form, but will pass on to the
-quite different octahedral form.</p>
-
-<p>It is so with the specific form of the living being—that
-is to say, with the assemblage of its constituent
-materials co-ordinated in a given system—in a word,
-with its organization. This is suitable to its substance,
-and to all the material, physical, chemical,
-and mechanical conditions in which it is placed. This
-form is the condition of material equilibrium corresponding
-to a very complex situation, to a sum of
-given conditions. The chemical condition is only
-one of these. And further, it is hardly proper to
-speak of a “chemical substance” when we refer to an
-astonishingly complex mixture which is in addition
-variable from one point to the other of the living
-body. When we thus reduce phenomena to their
-original signification, false analogies disappear. To
-say with Le Dantec that the form of the greyhound
-is the condition of equilibrium of the “greyhound
-chemical substance” is saying much; and too much,
-if it means that the body of the greyhound has a
-substance which behaves in the same way as homogeneous,
-isotropic masses like melted sulphur and
-dissolved salt. It were better to say much less, if it<span class="pagenum" id="Page_204">[Pg 204]</span>
-means, as it will in the minds of the physiologists,
-that the body of the greyhound is the condition of
-equilibrium of a heterogeneous, anisotropic, material
-system, subjected to an infinite number of physical
-and chemical conditions.</p>
-
-<p>The idea of connecting form, and by that we mean
-organization, with chemical composition did not arise
-in the minds of chemists or physiologists. Both have
-expressed themselves very clearly on this point.</p>
-
-<p>“We must distinguish,” said Berthelot, “between
-the formation of the chemical substances, the assemblage
-of which constitutes organized beings, and the
-formation of the organs themselves. This last problem
-does not come into the domain of chemistry. No
-chemist will ever claim to have formed in his laboratory
-a leaf, a fruit, a muscle, or an organ.... But chemistry
-has a right to claim that it forms direct principles—that
-is to say, the chemical materials which constitute
-the organs.” And Claude Bernard in the same way
-writes:—“In a word, the chemist in his laboratory,
-and the living organism in its apparatus, work in the
-same way, but each with its own tools. The chemist
-can make the products of the living being, but he
-will never make the tools, because they are the result
-of organic morphology.”</p>
-
-
-<h4>§ 2. <span class="smcap">The Acquisition and Re-establishment
-of the Specific Form.</span></h4>
-
-
-<p><i>Acquisition of the Typical Form.</i>—The acquisition
-of the typical form in the living being is the result of
-ontogenic work which cannot be examined here. In
-the elementary being, the plastid, this work is blended<span class="pagenum" id="Page_205">[Pg 205]</span>
-with the work of nutrition. It is <i>directed nutrition</i>.
-It consists of a simple increase from the moment the
-element is born by the division of an anterior element,
-and of a necessarily restricted differentiation. It is a
-rudimentary embryogeny. In the complex being,
-metazoan or metaphyte, the organism is constituted,
-starting from the egg, by the growth, by the bipartition
-of the elements, and their differentiation, accomplished
-in a certain direction and in conformity with
-a given plan. This, again, is directed nutrition, but
-here the embryogeny is complex. The directing plan
-of operations is no doubt the consequence of the
-material conditions realized each moment in the
-organism.</p>
-
-<p><i>Normal Regeneration.</i>—Not only do living beings
-themselves construct their typical architecture, but
-they re-establish it and continually reconstitute it,
-according as accidents, or even ordinary circumstances,
-tend to destroy it; in a word, they become rejuvenescent.
-This regeneration consists in the reformation
-of the parts that are altered or carried away in the
-normal play of life, or by the accidents which disturb
-its course.</p>
-
-<p>Thus there is a <i>normal physiological regeneration</i>,
-which is, so to speak, the prolongation of the ontogenesis—<i>i.e.</i>,
-of the work of formation of the individual.
-We have examples in the reconstitution of the skin
-of mammals—in the throwing off of the epidermic
-products constantly used up in their superficial and
-distal parts and regenerated in their deeply-seated
-parts; in the loss and the renewal of teeth at the
-first dentition and in certain fish in the fact of
-successive dentitions; in the periodical renewal of
-the integument in the larvæ of insects, and in the<span class="pagenum" id="Page_206">[Pg 206]</span>
-crustaceæ; and finally in the destruction and the
-neo-formation of the globules of the blood of vertebrates,
-of the glandular cells, and of the epithelial
-cells of the intestine.</p>
-
-<p><i>Accidental Regeneration in Protozoa and Plastids.</i>—There
-is also an <i>accidental regeneration</i> which more or
-less perfectly renews the parts that are lost. This
-regeneration has its degrees, from the simple cicatrization
-of a wound to the complete reproduction of the
-part cut off. It is very unequally developed in
-zoological groups even when they are connected.
-In the elementary monocellular beings—<i>i.e.</i>, in the
-anatomical elements and in the protozoa,—the experiments
-in merotomy, <i>i.e.</i>, in <i>partial section</i>, enable us
-to appreciate the extent of this faculty of regeneration.
-These experiments, inaugurated by the researches
-of Augustus Waller in 1851, were repeated
-by Gruber in 1885, continued by Nussbaum in 1886,
-Balbiani in 1889, Verworn in 1891, and have been
-reproduced by a large number of observers. They
-have shown that the two fragments cicatrize, and are
-repaired, building up an organism externally similar
-to the primitive organism, but smaller. The two new
-organic units do not, however, behave in the same
-way. That which retains the nucleus possesses the
-faculty of regeneration, and of living as the primitive
-being lived. The protoplasmic fragment, which does
-not contain the nucleus, cannot rebuild this absent
-organ; and though it has functional activity in most
-respects, just as the nucleated fragment, yet it is
-distinguished from it in others of great importance.
-The anucleated fragment of an infusorian behaves as
-the nucleated, and as the whole animal so far as the
-movements of the body, the cilia, prehension of food,<span class="pagenum" id="Page_207">[Pg 207]</span>
-evacuation of fæces, and the rhythmical contraction
-of the pulsatile vesicules are concerned. But
-Balbiani’s researches in 1892 have shown us that
-secretion, complete regeneration, and the faculty of
-reproduction by fission can take place only in the
-nucleated fragment—<i>i.e.</i>, in the nucleus.</p>
-
-<p><i>Accidental Reproduction in the Metazoa.</i>—Among
-multicellular beings the faculty of reproduction is met
-with in the highest degree in plants, where we find it
-in the process of propagation by slips. In animals it
-is the most marked in Cœlenterata. Trembley’s
-experiments are a striking instance. We know that
-when the hydra is cut into tiny pieces it reproduces
-exactly as many complete beings. Among the
-worms, Planaria afford a similar example. Every
-fragment, provided its volume is not less than a tenth
-of that of the whole, can reproduce a complete, entire
-being. The snail can produce a large part of its head,
-including the tentacles and the mouth. Among the
-Tritons and the Salamanders the faculty of regeneration
-reproduces the limbs, the tail, and the eye. In
-the Frog family, on the contrary, the work of regeneration
-does not go beyond cicatrization, and it is
-the same with Birds and Insects.</p>
-
-<p>It is really startling to see in a vertebrate like the
-Triton the stump of an arm with its fragment of
-humerus reproducing the forearm and the hand in all
-their complexity, with their skeleton, blood vessels,
-nerves, and teguments. We say that the limb has
-<i>budded</i>, as if there were a germ of it which develops
-like the seed of a plant, or as if each transverse portion
-of the limb, each slice, so to speak, could re-form the
-slice that follows.</p>
-
-<p>The mechanism of generation and that of regenera<span class="pagenum" id="Page_208">[Pg 208]</span>tion
-alike raise problems of the highest importance.
-Does the part become regenerated just as it was
-formed at first? Does the regeneration repeat the
-ontogeny? Is it true that a lost organ is never regenerated
-(the kidney for instance)? Does the
-symmetrical organ enjoy a compensating and hypertrophic
-development, as Ribbert has asserted? And
-further, if the organ be removed and transplanted to
-another position, can it be grafted there, as Y. Delage
-maintains? These are very important questions; but
-if we dwell upon them, we shall be diverted from our
-immediate object. Our task is to look at these facts
-from the point of view of their significant and characteristic
-meaning in vitality. Flourens invoked on
-their behalf the intervention of vital forces, <i>plastic</i>
-and <i>morphoplastic</i>. But, as we shall see later, these
-phenomena of cicatrization, of reparation, of regeneration,
-these more or less complete efforts for
-the re-establishment of the specific form, although
-they are found in all living beings in different degrees,
-are not exclusively confined to them. We find them
-again in some representatives of the mineral world—in
-crystals, for instance.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_209">[Pg 209]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_VI_3">CHAPTER VI.<br />
-
-<small>NUTRITION.</small></h3></div>
-
-
-<p class="prel">FUNCTIONAL ASSIMILATION. FUNCTIONAL DESTRUCTION.
-ORGANIC DESTRUCTION. ASSIMILATING
-SYNTHESIS.</p>
-
-
-<p class="prel">The extreme importance of nutrition—§ 1. Effect of vital
-activity—Destruction or growth—Distinction between the
-living substance and the reserve-stuff mingled with it—Organic
-destruction—Destruction of reserve-stuff—Destruction
-of living matter—Growth of living matter—§
-2. The two categories of vital phenomena—Foundations
-of the idea of functional destruction—The two kinds of
-phenomena of vitality—Criticism of Claude Bernard—Current
-views—Criticism of Le Dantec’s new theory of
-life.—§ 3. Correlation of the two kinds of vital facts—Law
-of connection—Contradictions in the new theory.—§ 4. The
-characteristics of nutrition—Its definition—Its permanence—Erroneous
-idea of the vital vortex—Formative assimilation
-of reserve-stuff—Formative assimilation of protoplasm—Death,
-real and apparent.</p>
-
-
-<p><i>The Immense Importance of Nutrition.</i>—We now
-come to the important feature of vitality. All other
-characteristics of living matter, its unstable equilibrium,
-its chemical and anatomical organization, the acquisition
-and the maintenance of a typical form, are only
-secondary properties, so to speak, subordinate with
-reference to <i>nutrition</i>. Generation itself is only a
-mode. <i>Nutrition</i> is the essential attribute of life. It
-is life itself.</p>
-
-<p><span class="pagenum" id="Page_210">[Pg 210]</span></p>
-
-<p>Before we define it a few preliminary explanations
-are necessary.</p>
-
-<p>The most striking thing in living matter is its
-<i>growth</i>. An animal, a vegetable, is something which
-is first more or less minute, and which grows. Its
-characteristic is to expand—from the spore, the seed,
-the slip, the egg—it grows.</p>
-
-<p>Whether we are dealing with a cellular element, a
-plastid, or a complex being, their condition is the
-same in this respect. No doubt when the animal or
-plant has reached a certain stage of development its
-growth is stopped, and for a more or less lengthy
-period it remains in the adult stage, in what seems to be
-equilibrium. But even then there is no check in the
-manufacture of living matter; there is only a compensation
-between its production and its destruction.</p>
-
-<p>It is important to reduce to order the ideas on this
-important subject, which at present are confused,
-inconsistent, and contradictory. In biology grievous
-confusion reigns.</p>
-
-
-<h4>§ 1. <span class="smcap">Effect of the Vital Activity.
-Destruction or Growth?</span></h4>
-
-<p><i>Distinction between the Living Substance and the
-Reserve-stuff mingled with it.</i>—The physiology of
-nutrition has given rise to a vast body of research
-during the last half-century. Physiological schools,
-masters and pupils, such as the school at Munich
-under Voit and Pettenkofer, Pflüger’s at Bonn,
-Rubner’s, and those of Zuntz and von Noorden at
-Berlin, and a large number of zootechnical and agricultural
-laboratories through the whole world have for<span class="pagenum" id="Page_211">[Pg 211]</span>
-years past been engaged in analyzing ingesta and
-egesta, in drawing up schedules of nutrition, in order
-to determine the course of decomposition and reconstitution
-of the living material.</p>
-
-<p>If I were asked what, in my opinion, is the most
-general result of all this labour, I would reply that it
-has affirmed and corroborated the important distinction
-which must be drawn between <i>living substance,
-properly so called</i>, and <i>reserve-stuff</i>. The latter, the
-<i>reserve-stuff</i> of albuminoids, carbohydrates, and fats,
-are so intimately intermingled with the living substance
-that they are in most cases very difficult to
-distinguish from it.</p>
-
-<p><i>Organic Destruction.</i>—A second point, which is
-placed equally beyond doubt, is that the vital functional
-activity is accompanied by a destruction of the
-immediate principles of the organism, in the direction
-of their simplification. This functional destruction
-cannot be doubted in the case of differentiated organs
-in which the functional activity is evident, intermittent,
-and in some measure distinct from the other
-vital phenomena which take place in them. For
-example, in the case of contracting muscles the
-respiratory carbonic acid and urinary carbon are the
-irrefutable proofs of this destruction: weak in repose,
-abundant during activity, and in proportion to it.
-There can be no doubt on this point. The truth
-laid down by Claude Bernard under the name of
-the <i>law of functional destruction</i> has been doubly
-consecrated by experiment and theory. According
-to the energetic theory, in fact, mechanical and
-thermal energies manifested in the vital functional
-activity can only have their source in the chemical
-energy set free by the destruction of the immediate<span class="pagenum" id="Page_212">[Pg 212]</span>
-principles of the organism, reduced to a lower degree
-of complexity.</p>
-
-<p><i>Destruction of Reserve-stuff.</i>—But now the disagreement
-begins. What are these decomposed, destroyed
-principles? Do they belong to the cellular reserve-stuff
-or to the living matter properly so called?
-There is no doubt that most of them belong to the
-reserve-stuff. For example, this is especially true of
-glycogen, which is consumed in muscular contraction
-just as coal is consumed in the furnace of the locomotive;
-and glycogen is a reserve-stuff of muscle.
-These reserve-stuffs destroyed in the functional
-activity can be built up again only during repose.</p>
-
-<p>But it is not yet certain whether the living
-matter itself, the active protoplasm, the muscular
-protoplasm, takes part in this destruction, whether it
-provides it with elements. Experiments have proved
-contradictory. Experimenters have isolated the nitrogenous
-wastes (urea) after muscular labour, and they
-have compared them with the wastes of the period of
-repose. These nitrogenous wastes bear witness to the
-destruction of albuminoid substances, and the latter
-are the constituent principles of living matter. If—under
-conditions of sufficient alimentation—the muscular
-functional activity involves more nitrogenous
-waste, <i>i.e.</i>, a greater destruction of albuminoids, it
-might be supposed that the living material properly
-so called has been used up and destroyed for its
-own purposes. (And here again there might be a
-reserve-stuff of albuminoids, distinct from the living
-protoplasm itself, and more or less incorporated
-with it.)</p>
-
-<p>But experiment so far has not given decisive results.
-The latest experimental researches, such as those of<span class="pagenum" id="Page_213">[Pg 213]</span>
-Igo Kaup, of Vienna, which date from 1902, tell us as
-uncertain a tale as their predecessors. The increase
-in the destruction of albumen has not been constant;
-the conditions of the observations do not justify our
-making an assertion either <i>pro</i> or <i>con</i>.</p>
-
-<p><i>Destruction of Living Matter.</i>—As no certain
-answer is supplied by experiment, theory intervenes
-and gives two conflicting answers. The majority of
-physiologists are inclined to believe in <i>the destruction
-of the living substance as the result of its own functional
-activity</i>. The functional activity would therefore
-destroy not only the reserve-stuff, but also the
-protoplasmic material. This is the current view.
-Only this opinion is strongly challenged by the
-positive teaching of science. It is certain that this
-material, in the muscle, is but little attacked, if it
-is attacked at all. We have seen above that the
-physiologists, with Pflüger and Chauveau, are agreed
-on this point. The vital functional activity in particular
-is destructive to the reserve-stuffs. It does
-not destroy them much; it destroys the organic
-material still less. Both would be repaired in functional
-repose.</p>
-
-<p><i>Growth of Living Matter.</i>—The second assertion is
-diametrically opposed to this. Not only, says Le
-Dantec, is the muscle not destroyed in the functional
-activity, but it grows. Contrary to universal opinion,
-the protoplasmic material increases by activity, and it
-is destroyed in repose. There would thus be a
-general law—<i>the law of functional assimilation</i>. “A
-cell of brewers’ yeast when introduced into a sugared
-must makes this must ferment, and at the same time,
-so far from destroying it, it increases it. Now, the
-fermentation of the must is exactly the same as the<span class="pagenum" id="Page_214">[Pg 214]</span>
-functional activity of the yeast.” It is, says the same
-author, a mistake to believe that the phenomena of
-functional activity, of <i>vital activity</i>, only takes place
-at the price of organic destruction. Here, then, are
-these two competing views. They are not so very far
-apart as a matter of fact, since the question at issue is
-one of deciding between a slight destruction and a
-slight growth, but theoretically they are strongly
-opposed. Moreover, they are arbitrary, and <i>experiment</i>
-has not decided between them.</p>
-
-
-<h4>§ 2. THE TWO CATEGORIES OF VITAL PHENOMENA.</h4>
-
-<p><i>Foundation of the Idea of Functional Destruction.
-Claude Bernard.</i>—The doctrine of functional destruction
-has been laid down with remarkable power
-by Claude Bernard. But the terms in which he has
-expressed it in a measure betray the thoughts of the
-great physiologist, or, at any rate, overstep the
-immediate fact he had in view. “The phenomena
-of destruction are very obvious. When movement is
-produced, when the muscle contracts, when volition
-and sensibility are manifested, when thought is
-exercised, when the gland secretes, then the substance
-of the muscles, of the nerves, of the brain, of
-the glandular tissue, becomes disorganized, destroyed,
-and consumed. So that every manifestation of a
-phenomenon in the living being is necessarily connected
-with an organic destruction.” To Claude
-Bernard organic destruction is a truth. To Le Dantec
-it is an error. Which is right? Clearly Claude
-Bernard. He bases his conviction on the analyses
-of the materials excreted in the process of physio<span class="pagenum" id="Page_215">[Pg 215]</span>logical
-work. The excreta bear witness to a certain
-organic demolition. Generalizing this teaching of
-experiment the illustrious biologist divined the
-fundamental law of energetics before the idea of
-energetics had made much way in France. Every
-act which expends energy, which produces heat or
-motion, any manifestation whatever that may be
-looked upon as an energetic transformation, necessarily
-expends energy, and that energy is borrowed
-from the substance of the organism. These substances
-are simplified, broken up, and destroyed.
-Now the functional activity of the muscle produces
-heat and movement in warm-blooded as well as in
-cold-blooded animals. The functional activity of
-the glands produces heat, as has been shown by the
-celebrated experiments of C. Ludwig on the salivary
-secretion, and as is also shown by the study of thermal
-topography in the vertebrates. The functional activity
-of the nerves and the brain produces a slight quantity
-of electricity and heat, as most observers have agreed.
-The functional activity of the electrical and of the
-photic apparatus also expends energy. Finally, the
-eye which receives the photic impression destroys the
-purple matter of the retina, and that purple matter,
-as we well know, is recuperated in the dark during
-the repose of the organ. Everything that is expressed
-objectively, everything that is a phenomenon in the
-living being—with the exception of growth and
-formation, which are generally slow phenomena, and
-of which we can only get an idea by the comparison
-of successive states—all these energetic manifestations
-suppose a destruction of organic matter, a chemical
-simplification, the source of the energy manifested.
-And that is why material destruction does not merely<span class="pagenum" id="Page_216">[Pg 216]</span>
-coincide with functional activity, but is its measure
-and expression.</p>
-
-<p><i>The Two Kinds of Phenomena of Vitality.</i>—Another
-point on which Claude Bernard is right and his
-opponent is wrong is not less fundamental. What
-are we to understand by functional phenomena?
-This is the very point at issue. Now, in the mind of
-physiologists, this expression has a perfectly definite
-meaning. It is not so with Le Dantec. Physiologists
-who have studied animals rather high in organization—in
-which the differentiation of phenomena enables
-us to grasp the fundamental distinction—have readily
-recognized that the phenomena of living beings are
-divided into two categories. There are some which
-are intermittent, alternative, which take place, or grow
-stronger at certain moments, but which cannot be
-continuous—they are the <i>functional acts</i>; there are
-others in which this characteristic of explosives,
-energetic expenditure and intermittence, do not
-appear—they are, in general, the <i>nutritive acts</i>. The
-muscle which contracts shows functional activity. It
-has an activity and a repose. During this apparent
-repose we must not say that it is dead; it has a life,
-but that life is obscure as far as the salient fact of
-functional movement is concerned. The salivary
-gland which throws up waves of saliva when the food
-is introduced and masticated in the mouth, or when
-the chord of the tympanum is at work, is in a state of
-functional activity; this is the salient phenomenon.
-But before, though nothing, absolutely nothing, was
-flowing through the glandular canal, yet the gland
-was not reduced to the condition of a dead organ: it
-was living a more obscure, a less evident life. The
-microscopical researches of Kühne, Lea, and Langley,<span class="pagenum" id="Page_217">[Pg 217]</span>
-now universally verified, show us that during this
-time of apparent repose the cells were loading up
-their granulations and getting ready the materials of
-secretion, as just now the muscle at rest was accumulating
-glycogen and the reserve-stuff which are to be
-expended and destroyed in contraction. Similarly,
-with regard to the functional activity of the other
-glands, of the brain, etc. Claude Bernard was, therefore,
-perfectly right, when he took as his model the
-chemists who distinguished between exothermic and
-endothermic reactions, and who classed the phenomena
-of life into two great divisions: those of
-functional activity, and those of functional repose.</p>
-
-<p>1st. <i>The phenomena of functional activity</i> “are
-those which ‘leap to the eyes,’ and by which we
-are inclined to characterize life. They are conditioned
-by the effects of wear and tear, of chemical
-simplication, and of the organic destruction which
-liberates energy.” And it must be so, because these
-functional manifestations expend energy. These
-phenomena, which are the most obvious, are also the
-least specific phenomena of vitality. They form
-part of the general phenomenality.</p>
-
-<p>2nd. The <i>phenomena</i> which accompany <i>functional
-repose</i> correspond to the building up of the reserve-stuff
-destroyed in the preceding period, to the organizing
-synthesis. The latter remains “internal, silent,
-concealed in its phenomenal expression, noiselessly
-gathering together the materials which will be expended.
-We do not see these phenomena of
-organization directly. The histologist and the
-embryogenist alone, following the development of
-the element or of the living being, sees the changes
-and the phases which reveal this silent effort. Here<span class="pagenum" id="Page_218">[Pg 218]</span>
-is a store of substance; there, the formation of
-an envelope or a nucleus; there, a division or
-multiplication, a renewal.” This type of phenomena
-is the only type which has no direct analogues:
-it is peculiar, special to the living being: what
-is really vital is this evolutive synthesis. Life is
-creation.</p>
-
-<p><i>Criticism of Claude Bernard.</i>—All this is perfectly
-true. Thirty years of the most intensive scientific
-development have run by since these lines were
-written, and have not essentially changed the ideas
-therein expressed. His work in its broad lines
-remains intact. Does that imply, however, that
-everything is perfect in detail and expression, and
-that there is no reason for making it more precise or
-for giving it fresh form? No doubt this is not so.
-Although Claude Bernard contributed to establish
-the essential distinction between the real living
-protoplasm and the materials of reserve-stuff which
-it contains, he has not drawn a sufficiently clear
-distinction between what belongs to each of the
-categories. He has not specified, in relation to
-organic destruction, what bearing it has on the
-organic materials of reserve-stuff. Sometimes he uses
-the term “organic destruction,” which is correct, and
-sometimes “vital destruction,” which is of doubtful
-import. Further, he employs an obscure and
-paradoxical formula to characterize the obvious but
-nevertheless not specific phenomena of organic
-destruction, and he says: “life is death.”</p>
-
-<p><i>Current Views.</i>—Nowadays, if I may express a
-personal opinion on this important distinction between
-functional activity and functional repose, I
-should say that after having distinguished between<span class="pagenum" id="Page_219">[Pg 219]</span>
-the two categories of phenomena we must try to
-correlate them. We must try to discover, for
-instance, what there is in common between the
-muscle in repose and the muscle in contraction, and
-to perceive in the <i>muscular tonus</i> a kind of bridge
-thrown between these two conditions. The functional
-activity would be uninterrupted, but it would have its
-degrees of activity. The muscular tonus would be
-the permanent condition of an activity which is capable
-only of being considerably raised or lowered.
-Similarly for the glandular functional activity; the
-periods of charge must be connected with the periods
-of discharge. In a word, following the constant path
-of the human mind in scientific knowledge, after
-having drawn the distinctions that are necessary to
-our understanding of things, we must obliterate them.
-After having dug our ditches we must fill them up
-again. After having analyzed we must synthesize.
-The distinction between the phenomena of <i>functional
-activity</i> and the phenomena of <i>functional repose</i> or
-<i>purely vegetative</i> and nutritive <i>activity</i>, though only
-valid in the case of a provisional and approximate
-truth, none the less throws light on the obscure
-regions of biology.</p>
-
-<p>The succession of energy and repose, of sleep and
-awakening, is a universal law, or at least a very
-general law, connected with the laws of energetics.
-The heart, the lungs, the muscles, the glands, the
-brain obey in the most obvious manner this obligation
-of rhythmical activity. The reason is clear. It is
-because the functional activity involves what is
-generally a sudden expenditure of energy, and this
-has to be replaced by what is generally a slow
-process of reparation. Functional activity is an<span class="pagenum" id="Page_220">[Pg 220]</span>
-explosive destruction of a chemical reserve which is
-built up again more or less slowly.</p>
-
-<p><i>Criticism of Le Dantec’s “New Theory of Life.”</i>—Let
-us now examine the antithesis of Claude
-Bernard’s views. There are evidently rudimentary
-organisms in which the differentiation of the two
-categories of phenomena is but little marked; in
-which, apart from the movement, it is impossible to
-recognize intermittent, functional activities clearly
-distinct from morphogenic activity. It is not in this
-domain of the indistinct that we must seek the
-touchstone of physiological distinctions. Clearly, we
-must not choose these elementary plastids to test
-the doctrine of functional assimilation and functional
-destruction. But is not this exactly what Le Dantec
-did when he began his researches on brewers’ yeast?
-When we try to examine things, we must choose the
-conditions under which they are differentiated, and
-not those in which they are confused. And this is
-why, in the significant words of Auguste Comte, “the
-more complex living beings are, the better known
-they are to us.” The philosopher goes still farther
-in this direction, and adds “directly it is a question
-of the characteristics of animality we must start from
-the man, and see how those characteristics are little
-by little degraded, rather than start from the sponge
-and endeavour to discover how these characteristics
-are developed. The animal life of the man assists
-us to understand the life of the sponge, but the
-converse is not true.”</p>
-
-<p>When, moreover, we consider a vegetable organism
-such as yeast, which derives its energy, not from
-itself, not from the potential chemical energy of its
-reserve-stuff, but directly from the medium—that is<span class="pagenum" id="Page_221">[Pg 221]</span>
-to say, from the potential chemical energy of the
-compounds which form its medium of culture,—we
-then find ourselves in the worst possible situation for
-the recognition of organic destruction. Further, it is
-doubly wrong to assert that in so ill-chosen a type
-the functional phenomena do not result from an
-organic destruction—for at first there are no very
-distinct functional phenomena here—and, in the second
-place, there certainly is organic destruction. The
-phenomena of the morphogenic vitality detected in
-the yeast are the exact concomitants, or the results,
-of the destruction of an organic compound, which in
-this case is sugar. The yeast destroys an immediate
-principle, and this is the point of departure of its vital
-manifestations; only, it has not, as a preliminary,
-clearly incorporated and assimilated this principle.
-When, therefore, the functional phenomena are
-effaced and disappear, we none the less find phenomena
-of destruction of organic compounds which are
-in a measure, a preface to the phenomena of growth.
-This is what happens in the case of brewers’ yeast:
-and here, again, the two categories of facts exist.
-Once more, we find, in the first place, the phenomena
-of destruction (destruction of sugar, reduced by
-simplification to alcohol and carbonic acid)—phenomena
-which this time no longer respond to obvious
-functional manifestations; and, in the second place,
-the phenomena of chemical and organogenic synthesis,
-corresponding to the growth of the yeast and the
-multiplication of its protoplasm. The former are no
-longer detected, as we have just said, by striking
-manifestations. However, it is not true that everything
-which is visible and which may be isolated
-outside the activity of the yeast is part of those<span class="pagenum" id="Page_222">[Pg 222]</span>
-phenomena. The boiling of the juice or the mash,
-the heat given off by the copper, all this phenomenal
-apparatus is but the consequence of the production of
-the carbonic acid and of its liberations—<i>i.e.</i>, the
-consequence of the act of destruction of the sugar.
-Here is organic destruction with its energetic
-manifestations!</p>
-
-<p>This example of the life of brewers’ yeast, of the
-saccharomyces, specially chosen by Le Dantec as
-being absolutely clear and giving the best illustration
-of his argument, contradicts him at every point. The
-general thesis of this vigorous thinker is that we
-cannot distinguish between the two parts of the vital
-act, organic destruction, and assimilating synthesis;
-that these two acts are not successive; that they give
-rise to phenomenal manifestations equally evident,
-apparent, or striking. Now, in the case of yeast, the
-phenomenon of destruction is clearly distinct from
-that of the assimilating synthesis which multiplies
-the substance of the saccharomyces. In fact, the
-action is realized by means of an alcoholic diastase
-manufactured by the cell; and Büchner succeeded in
-isolating this alcoholic ferment which splits up the
-sugar into alcohol and carbonic acid, and also <i>in vitro</i>
-and <i>in vivo</i>, makes the vat boil and heats the liquid.
-All the yeast is at work at once, says M. Dantec.
-No, and this is the proof.</p>
-
-<p>And, further, Pasteur himself, who had shown the
-relation of the decomposition of the sugar to the fact
-of the growth of the yeast and of the production
-of accessory substances such as succinic acid and
-glycerine, always referred to <i>correlation</i> between these
-phenomena. The destruction of the sugar is the
-<i>correlative</i> of the life of the yeast. This was his<span class="pagenum" id="Page_223">[Pg 223]</span>
-favourite formula. It never entered his head that
-there could be a confusion instead of a correlation,
-and that there might be only one and the same act,
-the phases of which would be indistinguishable.
-This unfortunate idea, which was fated to be so
-rapidly contradicted, is due to Le Dantec. Far
-from it being the case, Pasteur had distinguished
-the <i>ferment function</i> from the life of the yeast.
-According to him, the yeast may exist sometimes as
-a ferment and sometimes otherwise.</p>
-
-
-<h4>§ 3. <span class="smcap">Correlation of Two Orders of
-Vital Facts.</span></h4>
-
-<p>It is this correlation between acts <i>distinct in themselves</i>
-but <i>usually connected</i> that was announced by
-Claude Bernard. And, <i>mirabile dictu</i>—and this is the
-natural outcome of the perfect sanity of mind of this
-great physiologist—it happens that not only Pasteur’s
-researches, but the development of a new science,
-Energetics, and Büchner’s discovery lend support to
-his views, and that, too, in a field where one would
-have thought they had no application. Le Dantec is
-wrong when he declares that these ideas only apply to
-vertebrates. “It is clear,” he says on several occasions,
-“that the author has in view the metazoa and
-even the vertebrates.” Well! no. All that is general,
-universally applicable, and universally true. So that
-there are two orders of distinct phenomena energetically
-opposed and certainly connected. We need
-only repeat Claude Bernard’s own words quoted by
-Le Dantec in order to confute them.</p>
-
-<p><i>Law of Connection of Two Orders of Vital Facts.</i>—“These
-phenomena [of organic destruction and of<span class="pagenum" id="Page_224">[Pg 224]</span>
-assimilating synthesis] are simultaneously produced
-in every living being, in a connection which cannot
-be broken. The disorganization or dissimilation uses
-up living matter [by this we must understand the
-reserve-stuff, as will be seen later on in the quotation]
-in the organs <i>in function</i>: the assimilating synthesis
-regenerates the tissues; it gathers together the reserve-stuff
-which the vital activity must expend.
-These two operations of destruction and renovation,
-inverse the one to the other, are absolutely connected
-and inseparable, in this sense at any rate, that destruction
-is the necessary condition of renovation.
-The phenomena of functional destruction are themselves
-the precursors and the instigators of material
-regeneration, of the formative process which is silently
-going on in the intimacy of the tissues. The losses
-are repaired as they take place; and equilibrium being
-re-established as soon as it tends to be broken, the
-body is maintained in its composition.”</p>
-
-<p>It is perfectly right and wise to say with Claude
-Bernard that the two orders of facts are successive,
-and that one is normally the inciting condition of the
-other. The possibility of the development of the
-yeast when fermentation fails, and the weakness of
-this development on the other hand under these conditions,
-are an excellent proof of this. The one proves
-the essential independence of the two orders of facts,
-the other the inciting and provoking virtue of the first
-relatively to the second. The experimental truth is
-thus expressed with a minimum of uncertainty. We
-know the facts which led Le Dantec to formulate his
-law of functional assimilation—namely, that the
-functional activity is useful or indispensable to the
-growth of the organ; that the organs which are<span class="pagenum" id="Page_225">[Pg 225]</span>
-functionally active grow, and those which do not act
-become atrophied. We are only expressing the facts
-when we say that the organic destructions that go on in
-the living being (whether at the expense of its reserve-stuff
-or at the expense of its medium, or whether it be
-even slightly at the expense of the plastic substance
-itself) are the antecedent, the inciting agent or the
-normal condition of the chemical and organogenic
-syntheses which create the new protoplasm.</p>
-
-<p>On the other hand, we are wrong if we hold with
-Le Dantec that instead of two chemical operations
-there is only one, that which creates the new protoplasm.
-The obvious destruction is neglected; it is
-deliberately passed over. He does not see that it is
-necessary to liberate the energy employed in the
-construction, by complication, of this highly complex
-substance which is the new protoplasm. He really
-seems to have made up his mind not to analyze the
-phenomenon. If we decline to admit that to the first
-act of functional destruction succeeds a second,
-assimilation or organogenic synthesis, we are looking
-at elementary beings, in which the succession
-cannot be grasped, as we look on brewers’ yeast.
-We not only mean that the morphogenic assimilation
-results from the functional activity; we mean that it
-results from it directly, immediately, that it is the
-functional activity itself. Experiment tells us nothing
-of all this. It shows us the real facts, the facts of the
-destruction of an organic immediate principle, the
-sugar, and the fact that an assimilating synthesis is
-the correlative of this destruction. Besides, if it is
-impossible in examples of this kind to exhibit the
-succession, it is perfectly easy in beings of a higher
-order. It is, then, clearly seen that the preliminary<span class="pagenum" id="Page_226">[Pg 226]</span>
-destruction of a reserve-stuff (and perhaps of a small
-quantity of the living substance) precedes and conditions
-the formation of a greater quantity of this
-living matter—in other words, the growth of the
-protoplasm of the organ.</p>
-
-<p><i>Contradictions in the New Theory.</i>—Moreover, these
-mistakes involve those who make them in a series of
-inextricable contradictions. Here, for example, is
-life; it is found, they say, in three forms:—Life
-manifested, or condition 1º; latent life, or condition
-3º. So far this is the classical theory; but they add
-a condition 2º, which is what might be called <i>pathological
-or incomplete life</i>. This is defined by the
-following characteristic:—That its functional phenomena
-are identical with those in the first form, but
-that they are not accompanied by assimilation and by
-protoplasmic growth, But since, they say, growth is
-the chemical consequence of the functional activity,
-since it is so to speak its metabolic aspect, since it is
-confused with it, and inseparable from it, by the
-argument—then it is contradictory and logically
-absurd to speak of condition 2º. It would be acknowledging
-in the case of the anucleated merozoite,
-for example, a functional activity unaccompanied by
-assimilation, yet identical with the functional activity
-which is accompanied by assimilation in the nucleated
-merozoite. The general movement, that of the cilia,
-the taking of food, the evacuation of the fæces, the
-contraction of the pulsatile vacuoles, are the same.
-And this fact is the best proof that this vital functional
-activity (with the organic destruction which is
-its energetic source) must be distinguished from the
-assimilation which usually follows it, and which in
-exceptional cases may not follow it.</p>
-
-<p><span class="pagenum" id="Page_227">[Pg 227]</span></p>
-
-<p>We shall carry this discussion no farther. We have
-examined at some length Le Dantec’s views, and we
-have contrasted them with the doctrine which has
-been current in general physiology since the time of
-Claude Bernard, and this comparison does not turn
-out quite to their advantage. It was inevitable that
-the experimental and realistic spirit which inspired
-the doctrine of the celebrated physiologist made his
-work really too systematic. His formula, “life is
-death,” and the form he gave his ideas, are not always
-irreproachably correct. They lend themselves at
-times to criticism. Sometimes they require commentary.
-These are errors of detail which Le Dantec
-has summarized somewhat roughly. There is no
-necessity to do this in his own case. We pay our
-tribute to the clearness of his language, although we
-believe the foundations of his system are false and
-ill-founded. Their rigour is purely verbal. Their
-external qualities, their careful arrangement are well
-adapted to the seduction of the systematic mind
-prepared by mathematical teaching. This new theory
-of life is presented with pedagogic talent of the
-highest order. We think we have shown that the
-foundations are entirely fallacious, in particular the
-following:—Vital condition No. 2º; the confusion between
-functional activity and assimilating synthesis;
-the so-called absolute connection between morphogeny
-and chemical composition; the fundamental
-distinction between elementary life and individual life.</p>
-
-
-<h4>§ 4. <span class="smcap">Characteristics of Nutrition.</span></h4>
-
-<p><i>Definition of Nutrition.</i>—As we have just seen, the
-organism is the scene of chemical reactions of two<span class="pagenum" id="Page_228">[Pg 228]</span>
-kinds, the one destructive and simplifying, the other
-synthetic, constructive, or assimilating. This totality
-of reactions constitutes nutrition. Hence the two
-phases that it is convenient to consider in this function—<i>assimilation</i>
-and <i>disassimilation</i>. This twofold
-chemical movement or <i>metabolism</i> corresponding to
-the two categories of vital phenomena, of destruction
-(catabolism) and of synthesis (anabolism) is therefore
-the chemical sign of vitality in all its forms. But it
-is clear that disassimilation or organic destruction,
-which is destined to furnish energy to the organism
-for its different operations, reappears in the plan of
-the general phenomena of nature. It is not specifically
-vital in its principle. Assimilation, on the other
-hand, is in this respect much more characteristic.</p>
-
-<p>To some physiologists nutrition is only assimilation.
-Of the two aspects of metabolism they consider
-only one, the most typical, <i>Ad-similare</i>, to assimilate,
-to restore the substance borrowed from the ambient
-medium, the alimentary substances, <i>similar</i> to living
-matter, to make living matter of them, to increase
-active protoplasm—this is indeed the most striking
-phenomenon of vitality. To grow, to increase, to
-expand, to invade, is the law of living matter.
-Assimilation, nutrition in its essentials, is, according
-to the definition of Ch. Robin, “the production by the
-living being of a substance identical with its own.”
-It is the act by which the living matter, the protoplasm
-of a given being, is created.</p>
-
-<p><i>Permanence in Nutrition.</i>—Nutrition presents one
-quite remarkable character—permanence. It is a vital
-manifestation, a property if we look at it in the cell,
-in the living substance, a function if we consider it in
-the animal or in the plant as a whole, which is never<span class="pagenum" id="Page_229">[Pg 229]</span>
-arrested. Its suspension involves <i>ipso facto</i> the suspension
-of life itself. It is, in the words of Claude
-Bernard, that property of nutrition “which, as long as
-it exists in an element, compels us to believe that this
-element is alive, and which, when it is absent, compels
-us to believe that it is dead. It dominates all others
-by its generality and its importance. In a word, it is
-the absolute test of vitality.”</p>
-
-<p><i>Biological Energetics shows the Importance of
-Nutrition.</i>—We have indicated in advance the reason
-of its importance, showing that its two phases, disassimilation
-and assimilation, are the energetic
-condition of the two kinds of vital phenomena
-which we can distinguish.</p>
-
-<p>Nutrition is a manufacture of protoplasm at the
-expense of the materials of the cellular ambient
-medium, which are assimilated—<i>i.e.</i>, made chemically
-and physically similar to living matter and to the
-reserves it stores up. This operation, which is
-peculiarly chemical, is therefore indicated by the
-borrowing of materials from the external world, a
-borrowing which is always going on, because the
-operation is permanent, and, let me add, because of
-the continual rejection of the waste products of
-this manufacture. Our formula is:—Nutrition is a
-chemistry which persists.</p>
-
-<p><i>The Idea of the Vital Vortex is Erroneous.</i>—Here
-the effect has hidden the cause from the eyes
-of the biologists. They have been struck by the
-incessant entry and exit, by the never-ceasing passage,
-by the <i>cycle</i> of matter through the living being
-without guessing its why and wherefore; and they
-have taken as a picture of the living being a vortex
-in which the essential form is maintained while the<span class="pagenum" id="Page_230">[Pg 230]</span>
-matter, which is accessory, flows on without a check.
-This is Cuvier’s <i>vital vortex</i>. But for what purpose
-is this circulating matter used? They thought that
-it was employed entirely for the reconstitution of
-the living substance, continually and inevitably destroyed
-by the vital Minotaur.</p>
-
-<p><i>Destruction of Reserve-stuff</i>.—Here again there is
-a mistake. Really living substance is but little
-destroyed, and consequently requires very little
-renewal by the functional activity of the animal
-machine. Its metabolism—destruction and renewal—is
-in every case infinitely less than is supposed in
-the classical image of the vital vortex. It is the
-merit of physiologists, and particularly of Pflüger and
-Chauveau, to have worked for nearly forty years
-to establish this truth. They have proved it, at
-least as far as the muscular tissue is concerned.
-Protoplasm, properly so-called, is only destroyed
-as the organs of a steam engine are destroyed—its
-tubes, its boiler, its furnace. And it matters little.
-We know that such an engine uses much coal, and we
-know very little of its machinery and its metallic
-frame. And so it is with the cell, the living machine.
-A very small portion of the food introduced will be
-assimilated in the living substance. By far the
-greater part of it is destined to be worked up by the
-protoplasm and placed in reserve under the form of
-glycogen, albumen, and fat, etc.—<i>i.e.</i>, compounds
-which are not the really living substance, the hereditary
-protoplasm, but the products of its industry, just as
-they are or may be the products of the industry of
-the chemist working in his laboratory. They will be
-expended for the purpose of furnishing the necessary
-energy to the vital functional activity, muscular<span class="pagenum" id="Page_231">[Pg 231]</span>
-contraction, secretion, heat, etc., just as coal is
-expended to set the steam engine going. The proof
-as far as the muscle is concerned does not stand
-alone. There are other examples. In particular,
-micrographic physiologists who have studied nervous
-phenomena say that the anatomical elements of the
-brain last indefinitely, and that they continue as they
-are, without renewal from birth to death. The
-permanence of the consciousness, be it said in
-passing, is connected by them with the permanence
-of the cerebral element (Marinesco).</p>
-
-<p>Thus destruction is very restricted. There is only
-a very slight disassimilation of the living matter,
-properly so-called, in the course of the vital functional
-activity. We may even go farther than this experimental
-fact. This is what Le Dantec has done
-when he claims that there is even an assimilation, an
-increase of the protoplasm. Strictly speaking, this
-is possible, but there is no certain proof of it; and in
-any case we cannot agree with him when he affirms
-that the increase is the <i>direct result</i> of the functional
-activity and blends with it in one single, unique
-operation. We must, on the contrary, agree with
-Claude Bernard that it is only a <i>consequence</i> of it,
-that it is produced in consequence of the existence of
-a bond of correlation between organic destruction and
-assimilating synthesis.</p>
-
-<p>Why is there this bond? That is easily understood
-if we reflect that the assimilating synthesis, an
-operation of endothermic, chemical complexity, naturally
-requires an exothermic counterpart, the organic
-destruction which will set free this necessary energy.</p>
-
-<p><i>Formative Assimilation of Reserve-stuff. Formative
-Assimilation of Protoplasm.</i>—It follows that<span class="pagenum" id="Page_232">[Pg 232]</span>
-there are in nutritive assimilation itself two distinct
-acts. The one consisting of the manufacture of
-reserve-stuff is the more obvious but the less
-specific; the other, really essential, is assimilation
-properly so-called, the reconstitution of the protoplasm.
-The former is indispensable to the production
-of the most prominent acts of vitality—movement,
-secretion, production of heat. If it is
-suspended, functional activity is arrested. We get
-<i>apparent death</i>, or <i>latent life</i>. But if the real assimilation
-is arrested, we have <i>real death</i>.</p>
-
-<p>According to this there would be a fundamental
-distinction between real and apparent death. The
-former would be characterized by an <i>arrest of the
-protoplasmic assimilation</i> which is externally indicated
-by no sign. On the other hand, apparent death
-would be characterized by <i>the arrest of the formation
-and destruction of reserve-stuff</i>. It would be externally
-manifested by two signs:—The suppression
-of material exchanges with the medium (respiration,
-alimentation) and the suppression of the functional
-acts (production of movement, of heat, of electricity,
-of glandular excretion).</p>
-
-<p>Such would be the most expedient test for apparent
-or real death. The question occurs in the case of
-grains of corn in Egyptian tombs, and also of
-hibernating animals and reviviscent beings, and, in
-general, in the case of what has been called the state
-of <i>latent life</i>. But from the practical point of view
-it is extremely difficult to apply this test and to
-decide if the phenomena which are arrested in the
-grain at maturity, in Leeuwenhoek’s tardigrada,<a id="FNanchor_18" href="#Footnote_18" class="fnanchor">[18]</a><span class="pagenum" id="Page_233">[Pg 233]</span>
-and in the dried-up Anguillulidæ<a id="FNanchor_19" href="#Footnote_19" class="fnanchor">[19]</a> of Baker and
-Spallanzani, in the encysted colpoda<a id="FNanchor_20" href="#Footnote_20" class="fnanchor">[20]</a> that a drop of
-warm water will revive, in the animals exposed by
-E. Yung and Pictet to a cold of more than a
-100° C. below zero, are due to the general arrest of
-the two forms of assimilation, or to the arrest of the
-manufacture and utilization of reserve-stuff alone, or
-finally, to the arrest of protoplasmic assimilation
-alone. The latter, which is already very restricted
-in beings in a normal condition whose growth is
-terminated, may fall to the lowest degree in the
-being which, having no functional activity, is assimilating
-nothing. So that, to cut the question short,
-the experimenter who measures the value of the
-exchanges between the being and the medium has
-seldom to do more than decide between little and
-nothing. Hence his perplexity. But if experiment
-hesitates, theory affirms: it admits <i>a priori</i> that the
-movement of protoplasmic assimilation, an essential
-sign of vitality, is neither checked nor renewed, but
-proceeds continuously.</p>
-
-<p><i>Is Nutrition, the Assimilating Synthesis, interrupted?</i>—Nevertheless,
-there are many reasons for
-suspending all judgment as to this interpretation.
-It is questioned by most biologists. According to
-A. Gautier, the preserved grain of corn and the dried
-up rotifera are not really alive; they are like clocks
-in working order, ready to tell the time, but awaiting
-in absolute repose the first vibration which will set
-them going. As for the grain, it is the air, heat, and<span class="pagenum" id="Page_234">[Pg 234]</span>
-moisture which supply the first impulse. In other
-words, the organization proper to the manifestation of
-life remains, but there is no life. The so-called
-arrested life is not a life.</p>
-
-<p>It must be said, however, that the majority of
-physiologists refuse to accept this interpretation.
-They believe in an attenuation of the nutritive
-synthesis and not in its complete destruction. They
-think that this total suppression would be contrary
-to current ideas relative to the perpetuity of the
-protoplasm and the limited duration of the living
-element. The natural medium is variable, and even
-the mineral cannot remain eternally fixed. Still less
-is perennity a property of the living being. If
-ordinary life is for each individual of limited duration,
-the arrested life must also be of limited duration.
-We cannot believe that after an indefinitely prolonged
-sleep the grain of corn, or the paste-eel, or the
-colpoda, emerging from their torpor can resume their
-existence, like the Sleeping Beauty, at the point at
-which it was interrupted, and thus pass with a bound,
-as it were, through the centuries.</p>
-
-<p>In fact the maintenance of the vitality of grains
-of corn from the Egyptian tombs and their aptitude
-to germinate after thousands of years are only fables
-or the result of imposture. Maspero, in a letter
-addressed to M. E. Griffon on the 15th July 1901,
-has clearly summed up the situation by saying that
-the grains of corn bought from the fellahs almost
-always germinate, but that this is never the case with
-those that the experimenter himself takes from the
-tombs.</p>
-
-<p>To sum up, we must use the same language of
-nutrition and of life, of their uninterrupted progress,<span class="pagenum" id="Page_235">[Pg 235]</span>
-of their continuity, of their permanence, of their
-activity, and of their slackening. Living matter is
-always growing, much or little, slowly or quickly,
-in its reserve-stuff or in its protoplasm, for expenditure
-or accumulation. This inevitability of growth defines
-it, characterizes it, and sums up its activity. Development
-and the evolution of growth are consequences or
-aspects of nutrition.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_236">[Pg 236]</span></p>
-
-<h2 class="nobreak" id="BOOK_IV">BOOK IV.<br />
-
-
-<small>THE LIFE OF MATTER.</small></h2></div>
-
-
-<p class="prel">Summary: Chap. I. Universal life—Opinions of philosophers
-and poets—Continuity between brute and living bodies—Origin
-of this principle.—Chap. II. Origin of brute matter
-in living matter.—Chap. III. Organization and chemical
-composition of brute and living bodies.—Chap. IV. Evolution
-and transformation of brute and living bodies.—Chap.
-V. Possession of a specific form—Living bodies and
-crystals—Cicatrization.—Chap. VI. Nutrition in the living
-body and in the crystal.—Chap. VII. Generation in brute
-and in living bodies—Spontaneous generation.</p>
-
-
-
-<p><i>Apparent Differences between Living and Brute
-Bodies. The Two Kingdoms.</i>—It seems at first
-impossible that there should be any essential
-similarity between an inanimate object and a living
-being. What resemblance can be discovered between
-a stone, a lion, and an oak? A comparison of the
-inert and immovable pebble with the leaping animal,
-and with the plant extending its foliage gives an
-impression of vivid contrast. Between the organic
-and the inorganic worlds there seems to be an abyss.
-The first impressions we receive confirm this view;
-superficial investigation furnishes arguments for it.
-There is thus aroused in the mind of the child, and
-later in that of the man, a sharply marked distinction
-between the natural objects of the mineral kingdom
-on the one hand, and those of the two kingdoms of
-living beings on the other.</p>
-
-<p><span class="pagenum" id="Page_237">[Pg 237]</span></p>
-
-<p>But a more intimate knowledge daily tends to
-throw doubt upon the rigour or the absolute character
-of such a distinction. It shows that brute matter can
-no longer be placed on one side and living beings on
-the other. Scientists deliberately speak of “the life
-of matter,” which seems to the average man a contradiction
-in terms. They discover in certain classes
-of mineral bodies almost all the attributes of life.
-They find in others fainter, but still recognizable
-indications of an undeniable relationship.</p>
-
-<p>We propose to pass in review these analogies and
-resemblances, as has already been done in a fairly
-complete manner by Leo Errera, C. E. Guillaume,
-L. Bourdeau, Ed. Griffon, and others. We will consider
-the fine researches of Rauber, of Ostwald,
-and of Tammann upon crystals and crystalline germs—researches
-which are merely a continuation of those
-of Pasteur and of Gernez. These show that crystalline
-bodies are endowed with the principal attributes
-of living beings—<i>i.e.</i>, a rigorously defined form; an
-aptitude for acquiring it, and for re-establishing it by
-repairing any mutilations that may be inflicted upon
-it; nutritive growth at the expense of the mother
-liquor which constitutes its culture medium; and,
-finally—a still more incredible property—all the
-characteristics of reproduction by generation. Other
-curious facts observed by skilful physicists—W.
-Roberts-Austen, W. Spring, Stead, Osmond, Guillemin,
-Charpy, C. E. Guillaume—show that the immutability
-even of bodies supposed to be the most rigid
-of all, such as glass, the metals, steel, and brass, is
-apparent rather than real. Beneath the surface of the
-metal that seems to us inert there is a swarming
-population of molecules, displacing each other, moving<span class="pagenum" id="Page_238">[Pg 238]</span>
-about, and arranging themselves so as to form definite
-figures, and assuming forms adapted to the conditions
-of the environment. Sometimes it is years before
-they arrive at the state of ultimate and final equilibrium—which
-is that of eternal rest.</p>
-
-<p>However, in order to understand these facts and
-their interpretations, it is necessary to pass in review
-the fundamental characteristics of living beings. It
-will be shown that these very characteristics are found
-in inanimate matter.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_239">[Pg 239]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_I_4">CHAPTER I.<br />
-
-<small>UNIVERSAL LIFE. OPINIONS OF PHILOSOPHERS
-AND POETS.</small></h3></div>
-
-
-<p class="prel">§ 1. Primitive beliefs; the ideas of poets.—§ 2. Opinions of
-philosophers—Transition from brute to living bodies—The
-principle of continuity: continuity by transition: continuity
-by summation—Ideas of philosophers as to sensibility and
-consciousness in brute bodies—The general principle of
-homogeneity—The principle of continuity as a consequence
-of the principle of homogeneity.</p>
-
-
-<h4>§ 1. <span class="smcap">Primitive Beliefs. Ideas of the Poets.</span></h4>
-
-<p>The teaching of science as to the analogies between
-brute bodies and living bodies accords with the conceptions
-of the philosophers and the fancies of the
-poets. The ancients held that all bodies in nature
-were the constituent parts of a universal organism,
-the macrocosm, which they compared to the human
-microcosm. They attributed to it a principle of
-action, the <i>psyche</i>, analogous to the vital principle,
-and this psyche directed phenomena; and also an
-intelligent principle, the <i>nous</i>, analogous to the soul,
-and the <i>nous</i> served for the comprehension of phenomena.
-This universal life and this universal soul
-played an important part in their metaphysical
-systems.</p>
-
-<p><span class="pagenum" id="Page_240">[Pg 240]</span></p>
-
-<p>It was the same with the poets. Their tendency
-has always been to attribute life to Nature, so as to
-bring her into harmony with our thoughts and feelings.
-They seek to discover the life or soul hidden
-in the background of things.</p>
-
-<div class="poetry-container">
-<div class="poetry">
- <div class="stanza">
- <div class="verse indent0">“Hark to the voices. Nothing is silent.</div>
- </div>
- <div class="stanza">
- <div class="verse indent0">Winds, waves, and flames, trees, reeds, and rocks</div>
- <div class="verse indent0">All live; all are instinct with soul.”</div>
- </div>
-</div>
-</div>
-
-<p>After making proper allowance for emotional
-exaggeration, ought we to consider these ideas as the
-prophetic divination of a truth which science is only
-just beginning to dimly perceive? By no means. As
-Renan has said, this universal animism, instead of
-being a product of refined reflection, is merely a
-legacy from the most primitive of mental processes,
-a residue of conceptions belonging to the childhood
-of humanity. It recalls the time when men conceived
-of external things only in terms of themselves; when
-they pictured each object of nature as a living being.
-Thus, they personified the sky, the earth, the sea, the
-mountains, the rivers, the fountains, and the fields.
-They likened to animate voices the murmur of the
-forest:—</p>
-
-<div class="poetry-container">
-<div class="poetry">
- <div class="stanza">
- <div class="verse indent0">“ ... The oak chides and the birch</div>
- <div class="verse indent0">Is whispering....</div>
- <div class="verse indent0">And the beech murmurs....</div>
- <div class="verse indent0">The willow’s shiver, soft and faint, sounds like a word.</div>
- <div class="verse indent0">The pine-tree utters mysterious moans.”</div>
- </div>
-</div>
-</div>
-
-<p>For primitive man, as for the poet of all times,
-everything is alive, and every sound is due to a being
-with feelings similar to our own. The sighing of the
-breeze, the moan of the wave upon the shore, the<span class="pagenum" id="Page_241">[Pg 241]</span>
-babbling of the brook, the roaring of the sea, and the
-pealing of the thunder are nothing less than sad,
-joyous, or angry living voices.</p>
-
-<p>These impressions were embodied in ancient
-mythology, the graceful beauty of which does not
-conceal its inadequacy. Then they passed into
-philosophy and approached the realm of science.
-Thales believed that all bodies in nature were
-animate and living. Origen considered the stars as
-actual beings. Even Kepler himself attributed to the
-celestial bodies an internal principle of action, which,
-it may be said in passing, is contrary to the law of
-the inertia of matter, which has been wrongly ascribed
-to him instead of to Galileo. The terrestrial globe
-was, according to him, a huge animal, sensitive to
-astral influences, frightened at the approach of the
-other planets, and manifesting its terror by tempests,
-hurricanes, and earthquakes. The wonderful flux and
-reflux of the ocean was its breathing. The earth had
-its blood, its perspiration, its excretions; it also had
-its foods, among which was the sea water which it
-absorbs by numerous channels. It is only fair to add
-that at the end of his life Kepler retracted these vague
-dreams, ascribing them to the influence of J. C.
-Scaliger. He explained that by the soul of the
-celestial bodies he meant nothing more than their
-motive force.</p>
-
-
-<h4>§ 2. <span class="smcap">Opinion of the Philosophers.</span></h4>
-
-<p><i>Transition from Brute to Living Bodies.</i>—The
-lowering of the barrier between brute bodies and
-living bodies began with those philosophers who<span class="pagenum" id="Page_242">[Pg 242]</span>
-introduced into the world the great principles of
-continuity and evolution.</p>
-
-<p><i>The Principle of Continuity.</i>—First and foremost
-we must mention Leibniz. According to the teaching
-of that illustrious philosopher, as interpreted by M.
-Fouillée, “there is no inorganic kingdom, only a great
-organic kingdom, of which mineral, vegetable, and
-animal forms are the various developments....
-Continuity exists everywhere throughout the world;
-everywhere is life and organization. Nothing is
-dead; life is universal.” It follows that there is no
-interruption or break in the succession of natural
-phenomena; that everything is gradually developed;
-and finally, that the origin of the organic being must
-be sought in the inorganic. Life, properly so called,
-has not, in fact, always existed on the surface of the
-globe. It appeared at a certain geological epoch, in
-a purely inorganic medium, by reason of favourable
-conditions. The doctrine of continuity compels us,
-however, to admit that it pre-existed on the globe
-under some rudimentary form.</p>
-
-<p>The modern philosophers who are imbued with
-these principles, MM. Fouillée, L. Bourdeau, and A.
-Sabatier, express themselves in similar language.
-“Dead matter and living matter are not two absolutely
-different entities, but represent two forms of
-the same matter, differing only in degree, sometimes
-but slightly.” When it is only a matter of degree, it
-cannot be held that these views are opposed. Inequalities
-must not be interpreted as contrary attributes,
-as when the untrained mind considers heat
-and cold as objective states, qualitatively opposed
-to each other.</p>
-
-<p><i>Continuity by Transition.</i>—The argument which<span class="pagenum" id="Page_243">[Pg 243]</span>
-leads us to remove the barrier between the two kingdoms,
-and to consider minerals as endowed with a
-sort of rudimentary life, is the same as that which
-compels us to admit that there is no fundamental
-difference between natural phenomena. There are
-transitions between what lives and what does not,
-between the animate being and the brute body. And
-in the same way there are transitions between what
-thinks and what does not think, between what is
-thought and what is not thought, between the conscious
-and the unconscious. This idea of insensible
-transition, of a continuous path between apparent
-antitheses, at first arouses an insuperable opposition
-in minds not prepared for it by a long comparison of
-facts. It is slowly realized, and finally is accepted by
-those who, in the world of things, follow the infinity
-of gradations presented by natural phenomena. The
-principle of continuity comes at last to constitute, as
-one may say, a mental habit. Thus the man of science
-may be led, like the philosopher, to entertain the
-idea of a rudimentary form of life animating matter.
-He may, like the philosopher, be guided by this idea;
-he may attribute <i>a priori</i> to brute matter all the really
-essential qualities of living beings. But this must
-be on the condition that, assuming these properties to
-be common, he must afterwards demonstrate them by
-means of observation and experiment. He must show
-that molecules and atoms, far from being inert and
-dead masses, are in reality active elements, endowed
-with a kind of inferior life, which is manifested by all
-the transformations observed in brute matter, by
-attractions and repulsions, by movements in response
-to external stimuli, by variations of state and of
-equilibrium; and finally, by the systematic methods<span class="pagenum" id="Page_244">[Pg 244]</span>
-according to which these elements group themselves,
-conforming to those definite types of structure by
-means of which they produce different species of
-chemical compounds.</p>
-
-<p><i>Continuity by Summation.</i>—The idea of summation
-leads by another path to the same result. It is
-another form of the principle of continuity. A sum
-total of effects, obscure and indistinct in themselves,
-produces a phenomenon appreciable, perceptible, and
-distinct, apparently, but not really, heterogeneous in
-its components. The manifestations of atomic or
-molecular activity thus become manifestations of vital
-activity.</p>
-
-<p>This is another consequence of the teaching of
-Leibniz. For, according to his philosophical theory,
-individual consciousness, like individual life, is the
-collective expression of a multitude of elementary
-lives or consciousnesses. These elements are inappreciable
-because of their low degree, and the real
-phenomenon is found in the sum, or rather the
-<i>integral</i>, of all these insensible effects. The elementary
-consciousnesses are harmonized, unified,
-integrated into a result that becomes manifest, just
-as “the sounds of the waves, not one of which would
-be heard if by itself, yet, when united together and
-perceived at the same instant, become the resounding
-voice of the ocean.”</p>
-
-<p><i>Ideas of the Philosophers as to Sensibility and Consciousness
-in Brute Bodies.</i>—The philosophers have
-gone still further in the way of analogies, and have
-recognized in the play of the forces of brute matter,
-particularly in the play of chemical forces, a mere
-rudiment of the appetitions and tendencies that regulate,
-as they believe, the functional activity of living<span class="pagenum" id="Page_245">[Pg 245]</span>
-beings—a trace, as it were, of their sensibility. To
-them reactions of matter indicate the existence of a
-kind of <i>hedonic consciousness</i>—<i>i.e.</i>, a consciousness
-reduced simply to a distinction between comfort and
-discomfort, a desire for good and repulsion from evil,
-which they suppose to be the universal principle of all
-activity. This was the view held by Empedocles in
-antiquity; it was that of Diderot, of Cabanis, and, in
-general, of the modern materialistic school, eager to
-find, even in the lowest representatives of the
-inorganic world, the first traces of the vitality and
-intellectual life which blossom out at the top of the
-scale in the living world.</p>
-
-<p>Similar ideas are clearly seen in the early history of
-all natural sciences. It was this same principle of
-appetition, or of love and of repulsion or hate that,
-under the names of affinity, selection, and incompatibility,
-was thought to direct the transformations of
-bodies when chemistry first began; when Boerhaave,
-for example, compared chemical combinations to
-voluntary and conscious alliances, in which the
-respective elements, drawn together by sympathy,
-contracted appropriate marriages.</p>
-
-<p><i>General Principle of the Homogeneity of the Complex
-and its Components.</i>—The assimilation of brute bodies
-to living bodies, and of the inorganic kingdom to the
-organic, was, in the mind of these philosophers, the
-natural consequence of positing <i>a priori</i> the principles
-of continuity and evolution. There is, however, a
-principle underlying these principles. This principle
-is not expressed explicitly by the philosophers; it is
-not formulated in precise terms, but is more or less
-unconsciously implied; it is everywhere applied. It,
-however, may be clearly seen behind the apparatus of<span class="pagenum" id="Page_246">[Pg 246]</span>
-philosophical argument It is the assertion that no
-arrangement or combination of elements can put
-forth any new activity essentially different from the
-activities of the elements of which it is composed.
-Man is living clay, say Diderot and Cabanis; and,
-on the other hand, he is a thinking being. <i>As it is
-impossible to produce that which thinks from that which
-does not think</i>, the clay must possess a rudiment of
-thought. But is there not another alternative? May
-not the new phenomenon, thought, be the effect of
-the arrangement of this clay? If we exclude this
-alternative, we must then consider arrangement and
-organization as incapable of producing in arranged
-and organized matter a new property different from
-that which it presented before such arrangement.
-Living protoplasm, says another, is merely an
-assemblage of brute elements; “these brute elements
-must therefore possess a rudiment of life.” This is
-the same implied supposition which we have just
-considered; if life is not the basis of each element, it
-cannot result from their simple assemblage.</p>
-
-<p>Man and animals are combinations of atoms, says
-M. le Dantec. It is more natural to admit that
-human consciousness is the result of the elementary
-consciousness of the constituent atoms than to consider
-it as resulting from construction by means
-of elements with no consciousness. “Life,” says
-Haeckel, “is universal; we could not conceive of its
-existence in certain aggregates of matter if it did not
-belong to their constituent elements.” Here the
-postulate is almost expressed.</p>
-
-<p>The argument is always the same; even the same
-words are used: the fundamental hypothesis is the
-same; only it remains more or less unexpressed,<span class="pagenum" id="Page_247">[Pg 247]</span>
-more or less unperceived. It may be stated as
-follows:—Arrangement, assemblage, construction, and
-aggregation are powerless to bring to light in the
-complex anything new and essentially heterogeneous
-to what already exists in the elements. Reciprocally,
-grouping reveals in a complex a property and
-character which is the gradual development of an
-analogous property and character in the elements.
-It is in this sense that there exists a collective soul in
-crowds, the psychology of which has been discussed
-by M. G. Le Bon. In the same way, many sociologists,
-adopting the views advanced by P. de Lilienfeld
-in 1865, attribute to nations a formal individuality,
-after the type of that possessed by each of their
-constituent members. M. Izolet considers society
-as an organism, which he calls a “hyperzoan.”
-Herbert Spencer has developed the comparison of
-the collective organism with the individual organism,
-insisting on their resemblances and differences. Th.
-Ribot has dwelt, in particular, on the resemblances.</p>
-
-<p>The postulate that we have clearly stated here is
-accepted by many as an axiom. But it is not an
-axiom. When we say that there is nothing in the
-complex that cannot be found in the parts, we think
-we are expressing a self-evident truth; but we are,
-in fact, merely stating an hypothesis. It is assumed
-that arrangement, aggregation, and complicated and
-skilful grouping of elements can produce nothing
-really new in the order of phenomena. And this is
-an assertion that requires verification in each particular
-case.</p>
-
-<p><i>The Principle of Continuity, a Consequence of the
-Preceding.</i>—Let us apply this principle to the beings
-in nature. All beings in nature are, according to<span class="pagenum" id="Page_248">[Pg 248]</span>
-current ideas, arrangements, aggregates, or groupings
-of the same universal matter, that is to say, of the
-same simple chemical bodies. It results from the
-preceding postulate that their activities can only differ
-in degree and form, and not fundamentally. There
-is no essential difference of nature between the
-activities of various categories of beings, no heterogeneity,
-no discontinuity. We may pass from one to
-another without coming to an hiatus or impassable
-gulf. The law of continuity thus appears as a simple
-consequence of the fundamental postulate. And so
-it is with the law of evolution, for evolution is merely
-continuity of action.</p>
-
-<p>Such are the origins of the philosophical doctrine
-which universalizes life and extends it to all bodies
-in nature.</p>
-
-<p>It may be remarked that this doctrine is not
-confined to any particular school or sect. Leibniz
-was by no means a materialist, and he endowed his
-mundane elements, his <i>monads</i>, not only with a sort
-of life, but even with a sort of soul. Father Boscovitch,
-Jesuit as he was, and professor in the college of
-Rome, did not deny to his <i>indivisible points</i> a kind of
-inferior vitality. St. Thomas, too, the angelical
-doctor, attributed, according to M. Gardair, to
-inanimate substances a certain kind of activity,
-inborn inclinations, and a real appetition towards
-certain acts.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_249">[Pg 249]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_II_4">CHAPTER II.<br />
-
-<small>ORIGIN OF BRUTE MATTER IN LIVING MATTER.</small></h3></div>
-
-
-<p class="prel">Spontaneous generation: an episode in the history of the
-globe—Verification of the identity between brute and
-living matter—Slow identification—Rapid identification—Contrary
-opinion—Hypothesis of cosmozoa; cosmic
-panspermia—Hypothesis of pyrozoa.</p>
-
-
-<p>There should be two ways of testing the doctrine of
-the essential identity of brute and living matter—one
-slow and more laborious, the other more rapid
-and decisive.</p>
-
-<p><i>Identification of the Two Matters, Brute and
-Living.</i>—The laborious method, which we will be
-obliged to follow, consists in the attentive examination
-of the various activities by which life is
-manifested, and in finding more or less crude
-equivalents for them in all brute beings, or in certain
-of them.</p>
-
-<p><i>Rapid Verification. Spontaneous Generation.</i>—The
-rapid and decisive method, which, unhappily, is
-beyond our resources, would consist in showing unquestionable,
-clearly marked life, the superior life,
-arising from the kind of inferior life that is attributed
-to matter in general. It would be necessary completely
-to construct in all its parts, by a suitable
-combination of inorganic materials, a single living
-being, even the humblest plant or the most rudi<span class="pagenum" id="Page_250">[Pg 250]</span>mentary
-animal. This would indeed be an irrefutable
-proof that the germs of all vital activity are contained
-in the molecular activity of brute bodies, and that
-there is nothing essential to the latter that is not
-found in the former.</p>
-
-<p>Unhappily this demonstration cannot be given.
-Science furnishes no example of it, and we are forced
-to have recourse to the slow method.</p>
-
-<p>The question here involved is that of spontaneous
-generation. It is well known that the ancients
-believed in spontaneous generation, even for animals
-high in the scale of organization. According to
-Van Helmont, mice could be born by some incomprehensible
-fermentation in dirty linen mixed with
-wheat. Diodorus speaks of animal forms which were
-seen to emerge, partly developed, from the mud of
-the Nile. Aristotle believed in the spontaneous birth
-of certain fishes. This belief, though rejected as to
-the higher forms, was for a long time held with
-regard to the lower forms of animals, and to insects—such
-as the bees which the shepherd of Virgil saw
-coming out from the flanks of the dead bullock—flies
-engendered in putrefying meat, fruit worms and
-intestinal worms; finally, with regard to infusoria
-and the most rudimentary vegetables. The hypothesis
-of the spontaneous generation of the living
-being at the expense of the materials of the ambient
-medium has been successively driven from one
-classificatory group to another. The history of the
-sciences of observation is also a history of the confutation
-of this theory. Pasteur gave it the finishing
-stroke, when he showed that the simplest microorganisms
-obeyed the general law which declares
-that the living being is formed only by <i>filiation</i>—that<span class="pagenum" id="Page_251">[Pg 251]</span>
-is to say, by the intervention of a pre-existing living
-organism.</p>
-
-<p><i>Spontaneous Generation an Episode in the History
-of the Globe.</i>—Though we have been unable to effect
-spontaneous generation up to the present, it has been
-referred by Haeckel to a more or less distant past, to
-the time when the cooling of the globe, the solidification
-of its crust, and the condensation of aqueous
-vapour upon its surface created conditions compatible
-with the existence of living beings similar to those
-with which we are acquainted. Lord Kelvin has
-fixed these geological events as occurring from twenty
-to forty million years ago. Then circumstances
-became propitious for the appearance of the first
-organisms, whence were successively derived those
-which now people the earth and the waters.</p>
-
-<p>Circumstances favourable to the appearance of the
-first beings apparently occurred only in a far distant
-past; but most physiologists admit that if we knew
-exactly these circumstances, and could reproduce
-them, we might also expect to produce their effect—namely,
-the creation of a living being, formed in all
-its parts, developed from the inorganic kingdom.
-To all those who held this view the impotence of
-experiment at the present time is purely temporary.
-It is comparable to that of primitive men before the
-time of Prometheus; they, not knowing how to
-produce fire, could only get it by transmitting it
-from one to another. It is due to the inadequacy
-of our knowledge and the weakness of our means; it
-does not contradict the possibility of the fact.</p>
-
-<p><i>Contrary Opinion. Life did not Originate on our
-Globe.</i>—But all biologists do not share this opinion.
-Some, and not the least eminent, hold it to be an<span class="pagenum" id="Page_252">[Pg 252]</span>
-established fact that it is impossible for life to arise
-from a concurrence of inorganic materials and forces.
-This was the opinion of Ferdinand Cohn, the great
-botanist; of H. Richter, the Saxon physician, and of
-W. Preyer, a physiologist well known from his
-remarkable researches in biological chemistry.
-According to these scientists, life on the surface of
-the globe cannot have appeared as a result of the
-reactions of brute matter and the forces that continue
-to control it.</p>
-
-<p>According to F. Cohn and PI. Richter, life had no
-beginning on our planet. It was transported to the
-earth from another world, from the cosmic medium,
-under the form of cosmic germs, or <i>cosmozoa</i>, more
-or less comparable to the living cells with which we
-are acquainted. They may have made the journey
-either enclosed in meteorites, or floating in space in
-the form of cosmic dust. The theory in question
-has been presented in two forms:—<i>The Hypothesis of
-Meteoric Cosmozoa</i>, by a French writer, the Count
-de Salles-Guyon; and that of <i>cosmic panspermia</i>
-brought forward in 1865 and 1872 by F. Cohn and
-H. Richter.</p>
-
-<p><i>Hypothesis of the Cosmozoa.</i>—The hypothesis of
-the cosmozoa, living particles, protoplasmic germs
-emanating from other worlds and reaching the earth
-by means of aerolites, is not so destitute of probability
-as one might at first suppose. Lord Kelvin and
-Helmholtz gave it the support of their high authority.
-Spectrum analysis shows in cometary nebulæ the
-four or five lines characteristic of hydro-carbons.
-Cosmic matter, therefore, contains compounds of
-carbon, substances that are especially typical of
-organic chemistry. Besides, carbon and a sort of<span class="pagenum" id="Page_253">[Pg 253]</span>
-humus have been found in several meteorites. To
-the objection that these aerolites are heated while
-passing through our atmosphere, Helmholtz replies
-that this elevation of temperature may be quite
-superficial and may allow micro-organisms to subsist
-in their interior. But other objections retain their
-force:—First, that of M. Verworn, who considers the
-hypothesis of cosmic germs as inconsistent with the
-laws of evolution; and that of L. Errera, who denies
-that the conditions necessary for life exist in interplanetary
-bodies.</p>
-
-<p><i>Hypothesis of Cosmic Panspermia.</i>—Du Bois-Reymond
-has given the name of <i>cosmic panspermia</i>
-to a theory very similar to the preceding, formulated
-by F. Cohn in 1872. The first living germs arrived
-on our globe mingled with the cosmic dust that
-floats in space and falls slowly to the surface of the
-earth. L. Errera observes that if they escape by
-this gentle fall the dangerous heating of meteorites,
-they still remain exposed to the action of the photic
-rays, which is generally destructive to germs.</p>
-
-<p><i>Hypothesis of Pyrozoa.</i>—W. Preyer declined to
-accept this cosmic transmigration of the simplest
-living beings, nor would he allow the intervention of
-other worlds into the history of our own. Life,
-according to him, must have existed from all time,
-even when the globe was an incandescent mass.
-But it was not the same life as at present. Vitality
-must have undergone many profound changes in the
-course of ages. The <i>pyrozoa</i>, the first living beings,
-vulcanians, were very different from the beings of
-the present day that are destroyed by a slight
-elevation of temperature. No doubt this theory of
-pyrozoa, proposed by W. Preyer in 1872, seems<span class="pagenum" id="Page_254">[Pg 254]</span>
-quite chimerical, and akin to Kepler’s dreamy visions.
-But in a certain way it accords with contemporary
-ideas concerning the life of <i>matter</i>. It is related to
-them by the evolution which it implies in the materials
-of the terrestrial globe.</p>
-
-<p>According to Preyer, primitive life existed in fire.
-Being igneous masses in fusion, the pyrozoa lived
-after their own manner; their vitality, slowly modified,
-assumed the form which it presents to-day. Yet, in
-this profound transformation their number has not
-varied, and the total quantity of life in the universe
-has remained unchanged.</p>
-
-<p>Here we recognize the ideas of Buffon. These
-cosmozoa, these pyrozoa, have a singular resemblance
-to the <i>organic molecules</i> of “live matter” of the
-illustrious naturalist—distributed everywhere, indestructible,
-and forming living structures by their
-concentration.</p>
-
-<p>But we must leave these scientific or philosophical
-theories, and come to arguments based upon facts.</p>
-
-<p>It is in a spirit quite different from that of the
-poets, the metaphysicians, and the more or less
-philosophical scientists that the science of our days
-looks at the more or less obscure vitality of inanimate
-bodies. It claims that we may recognize in them,
-in a more or less rudimentary state, the action
-of the factors which intervene in the case of living
-beings, the manifestation of the same fundamental
-properties.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_255">[Pg 255]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_III_4">CHAPTER III.<br />
-
-<small>ORGANIZATION AND CHEMICAL COMPOSITION OF
-LIVING AND BRUTE MATTER.</small></h3></div>
-
-
-<p class="prel">Laws of the organization and of the chemical composition of
-living beings—Relative value of these laws; vital phenomena
-in crushed protoplasm—Vital phenomena in brute
-bodies.</p>
-
-
-<p><i>Enumeration of the Principal Characters of Living
-Beings.</i>—The programme which we have just sketched
-compels us to look in the brute being for the properties
-of living beings. What, then, are, in fact, the
-characteristics of an authentic, complete, living being?
-What are its fundamental properties? We have
-enumerated them above as follows:—A certain
-chemical composition, which is that of living matter;
-a structure or organization; a specific form; an
-evolution which has a duration, that of life, and an
-end, death; a property of growth or nutrition; a
-property of reproduction. Which of these characters
-counts for most in the definition of life? Are they
-all equally necessary? If some of them were wanting,
-would that justify the transference of a being, who
-might possess the rest, from the animate world to
-that of minerals? This is precisely the question that
-is under consideration.</p>
-
-<p><i>Organization and Chemical Composition of Living
-Beings.</i>—All that we know concerning the constitution<span class="pagenum" id="Page_256">[Pg 256]</span>
-of living matter and its organization is summed up in
-the laws of the <i>chemical unity</i> and the <i>morphological
-unity of living beings</i> (v. Book III.). These laws seem
-to be a legitimate generalization from all the facts
-observed. The first states that the phenomena of
-life are manifested only in and through living matter,
-protoplasm—<i>i.e.</i>, in and through a substance which
-has a certain chemical and physical composition.
-Chemically it is a proteid complexus with a hexonic
-nucleus. Physically it shows a frothy structure
-analogous to that resulting from the mixture of two
-granular, immiscible liquids, of different viscosities.
-The second law states that the phenomena of life
-can only be maintained in a protoplasm which has
-the organization of the complete cell, with its cellular
-body and nucleus.</p>
-
-<p><i>Relative Value of these Laws. Exceptions.</i>—What
-is the signification of these laws of the chemical
-composition and organization of living beings?
-Evidently that life in all its plenitude can only exist
-and be perpetuated under their protection. If these
-laws were absolute, if it were true that no life were
-possible but in and through albuminous protoplasm,
-but in and through the cell, the problem of “the life
-of matter” would be decided in the negative.</p>
-
-<p>May it not happen, however, that fragmentary and
-incomplete vital manifestations, progressive traces
-of a true life, may occur under different conditions;
-for example, in matter which is not protoplasm, and
-in a body which has a structure differing from that
-of a cell—that is to say, in a being which would be
-neither animal nor plant? We must seek the answer
-to this question by an appeal to experiment.</p>
-
-<p>Without leaving the animal and vegetable king<span class="pagenum" id="Page_257">[Pg 257]</span>doms—<i>i.e.</i>,
-real living beings—we already see less
-rigour in the laws governing chemical constitution
-and cellular organization.</p>
-
-<p>Experiments in merotomy—<i>i.e.</i>, in amputation—carried
-out on the nervous element by Waller, on
-infusoria by Brandt, Gruber, Balbiani, Nussbaum,
-and Verworn, show us the necessity of the presence
-of the cellular body and the nucleus—<i>i.e.</i>, of the integrity
-of the cell. But they also teach us that when
-that integrity no longer exists death does not immediately
-follow. A part of the vital functions continues
-to be performed in denucleated protoplasm, in a cell
-which is mutilated and incomplete.</p>
-
-<p><i>Vital Phenomena in Crushed Protoplasm.</i>—It is
-true also that grinding and crushing suppress the
-greater part of the functions of the cell. But tests
-with pulps of various organs and with those of certain
-yeasts also show that protoplasm, even though ground
-and disorganized, cannot be considered as inert, and
-that it still exhibits many of its characteristic phenomena;
-for example, the production of diastases, the
-specific agents of vital chemistry. Finally, while we
-do not know enough about the actions of which the
-secondary elements of protoplasm—its granulations,
-its filaments—are capable, which this or that method
-of destruction may bring to light, at least we know
-that actions of this kind exist.</p>
-
-<p>To sum up, we are far from being able to deny that
-rudimentary, isolated vital acts may be produced by
-the various bodies that result from the dismemberment
-of protoplasm. The integrity of the cellular
-organization, even the integrity of protoplasm itself,
-are therefore not indispensable for these partial
-manifestations of vitality.</p>
-
-<p><span class="pagenum" id="Page_258">[Pg 258]</span></p>
-
-<p>Besides, biologists admit that there exist within
-the protoplasm aliquot parts, elements of an
-inferior order, which possess special activities.
-These secondary elements must have the principle
-of their activity within themselves. Such are the
-<i>biophors</i> to which Weismann attributes the vital
-functions of the cell, nutrition, growth, and multiplication.
-If there are biophors within the cell, we
-may imagine them outside the cell, and since they
-carry within themselves the principle of their activity
-they may exercise it in an independent manner.
-Unhappily the biophors, and other constituent elements
-of that kind, are purely hypothetical. They
-are like Darwin’s gemmules, Altmann’s bioblasts, and
-the pangens of De Vries. They have no relation to
-facts of observation and to real existence.</p>
-
-<p><i>Vital Phenomena in Brute Bodies.</i>—There is no
-doubt that certain phenomena of vitality may occur
-outside of the cellular atmosphere. And carrying
-this further, we may admit that they may be produced
-in certain slightly organized bodies (crushed
-cells), and then in certain unorganized bodies in
-certain brute beings. In every case it is certain that
-effects are produced at any rate similar to those which
-are characteristic of living matter. It is for observation
-and experiment to decide as to the degree of similarity,
-and their verdict is that the similarity is complete.
-The crystals and the crystalline germs studied by
-Ostwald and Tammann are the seat of phenomena
-which are quite comparable to those of vitality.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_259">[Pg 259]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_IV_4">CHAPTER IV.<br />
-
-<small>EVOLUTION AND MUTABILITY OF LIVING MATTER
-AND BRUTE MATTER.</small></h3></div>
-
-
-<p class="prel">Supposed immobility of brute bodies—Mobility and mutability
-of the sidereal world.—§ 1. The movement of particles and
-molecules in brute bodies—The internal movements of
-brute bodies—Kinetic conception of molecular motion—Reality
-of the motion of particles—Comparison of the
-activity of particles with vital activity.—§ 2. Brownian
-movement—Its existence—Its character—Its independence
-of the nature of the bodies and of the nature of the environment—Its
-indefinite duration—Its independence of external
-conditions—The Brownian movement must be the first
-stage of molecular motion.—§ 3. Motion of particles—Migration
-of material particles—Migration under the
-action of weight; of diffusion; of electrolysis; of mechanical
-pressure.—§ 4. Internal activity of alloys—Their structure—Changes
-produced by deforming agencies—Slow return to
-equilibrium—Residual effect—Effect of annealing; effect
-of stretching—Nickel steel—Colour photography—Conclusion—Relations
-of the environment to the living or brute
-matter.</p>
-
-
-<p>One of the most remarkable characteristics of a living
-being is its evolution. It undergoes a continuous
-change. It starts from something very small; it
-assumes a configuration and grows; in most cases
-it declines and disappears, having followed a course
-which may be predicted—a sort of ideal trajectory.</p>
-
-<p><i>Supposed Immobility of Brute Bodies.</i>—It may be
-asked whether this evolution, this directed mobility,<span class="pagenum" id="Page_260">[Pg 260]</span>
-is so exclusively a feature of the living being as it
-appears, and if many brute bodies do not present
-something analogous to it. We may answer in no
-uncertain tones.</p>
-
-<p>Bichat was wrong when he contrasted in this
-respect brute bodies with living bodies. Vital
-properties, he said, are temporary; it is their nature
-to be exhausted; in time they are used up in the
-same body. Physical properties, on the contrary, are
-eternal. Brute bodies have neither a beginning nor
-an inevitable end, neither age, nor evolution; they
-remain as immutable as death, of which they are the
-image.</p>
-
-<p><i>Mobility and Mutability of the Sidereal World.</i>—This
-is not true, in the first place, of the sidereal
-bodies. The ancients held the sidereal world to be
-immutable and incorruptible. The doctrine of the
-incorruptibility of the heavens prevailed up to the
-seventeenth century. The observers who at that
-epoch directed towards the heavens the first telescope,
-which Galileo had just invented, were struck with
-astonishment at discovering a change in that celestial
-firmament which they had hitherto believed incorruptible,
-and at perceiving a new star that appeared
-in the constellation Ophiuchus. Such changes no
-longer surprise us. The cosmogonic system of
-Laplace has become familiar to all cultivated minds,
-and every one is accustomed to the idea of the continual
-mobility and evolution of the celestial world.
-“The stars have not always existed,” writes M. Faye;
-“they have had a period of formation; they will
-likewise have a period of decline, followed by final
-extinction.”</p>
-
-<p>Thus all the bodies of inanimate nature are not<span class="pagenum" id="Page_261">[Pg 261]</span>
-eternal and immutable; the celestial bodies are
-eminently susceptible of evolution, slow indeed with
-that we observe on the surface of our globe; but this
-disproportion, corresponding to the immensity of
-time and of cosmic spaces as compared with terrestrial
-measurements, should not mislead us as to the
-fundamental analogy of the phenomena.</p>
-
-
-<h4>§ 1. <span class="smcap">The Movement of Particles and Molecules
-in Brute Bodies.</span></h4>
-
-<p>It is not only in celestial spaces that we must
-search for that mobility of brute matter which imitates
-the mobility of living matter. In order to find it we
-have only to look about us, or to inquire from
-physicists and chemists.</p>
-
-<p>As far as geologists are concerned, M. le Dantec
-tells us somewhere of one who divided minerals into
-<i>living rocks</i>—rocks capable of change of structure, of
-evolution under the influence of atmospheric causes;
-and <i>dead rocks</i>—rocks which, like clay, have found at
-the end of all their changes a final state of repose.
-Jerome Cardan, a celebrated scientist of the sixteenth
-century, at once mathematician, naturalist, and
-physician, declared not only that stones live, but
-that they suffer from disease, grow old, and die.
-The jewellers of the present day use similar language
-of certain precious stones; the torquoise, for example.</p>
-
-<p>The alchemists carried these ideas to an extreme.
-It is not necessary here to recall the past, to evoke
-the hermetic beliefs and the dreams of the alchemists,
-who held that the different kinds of matter lived,
-developed, and were transmuted into each other.</p>
-
-<p><span class="pagenum" id="Page_262">[Pg 262]</span></p>
-
-<p>I refer to precise and recent data, established by
-the most expert investigators, and related by one of
-them, Charles Edward Guillaume, some years ago,
-before the <i>Société helvétique des Sciences naturelles</i>.
-These data show that determinate forms of matter
-may live and die, in the sense that they may be
-slowly and continuously modified, always in the same
-direction, until they have attained an ultimate and
-definitive state of eternal repose.</p>
-
-<p><i>The Internal Movements of Bodies.</i>—Swift’s reply to
-an idle fellow who spoke slightingly of work is well
-known. “In England,” said the author of <i>Gulliver’s
-Travels</i>, “men work, women work, horses work,
-oxen work, water works, fire works, and beer works;
-it is only the pig who does nothing at all; he must,
-therefore, be the only gentleman in England.” We
-know very well that English gentlemen also work.
-Indeed, everybody and everything works. And the
-great wit was nearer right than he supposed in comparing
-men and things in this respect. Everything
-is at work; everything in nature strives and toils, at
-every stage, in every degree. Immobility and repose
-in the case of natural things are usually deceptive;
-the seeming quietude of matter is caused by our
-inability to appreciate its internal movements. Because
-of their minuteness we do not perceive the
-swarming particles that compose it, and which, under
-the impassible surface of the bodies, oscillate, displace
-each other, move to and fro, and group themselves
-into forms and positions adapted to the conditions
-of the environment. In comparison with these
-microscopic elements we are like Swift’s giant among
-the Lilliputians; and this is far from being a sufficiently
-forcible comparison.</p>
-
-<p><span class="pagenum" id="Page_263">[Pg 263]</span></p>
-
-<p><i>Kinetic Conception of Molecular Motion.</i>—The idea
-of this peculiar form of motion is by no means new to
-us. We were familiarized with it in scientific theories
-during our school days. The atomic theory teaches
-us that matter behaves, from a chemical point of
-view, as if it were divided into molecules and atoms.
-The kinetic theory explains the constitution of gases
-and the effects of heat by supposing that these
-particles are endowed with movements of rotation
-and displacement. The wave theory explains photic
-phenomena by supposing peculiar vibratory movements
-in a special medium—the ether. But these
-are merely hypotheses which are not at all necessary;
-they are the images of things, not the things themselves.</p>
-
-<p><i>Reality of the Motion of Particles.</i>—Here there is
-no question of hypotheses. This internal agitation,
-this interior labour, this incessant activity of matter
-are positive facts, an objective reality. It is true that
-when the chemical or mechanical equilibrium of
-bodies is disturbed it is only restored more or less
-slowly. Sometimes days and years are required
-before it is regained. Scarcely do they attain this
-relative repose when they are again disturbed, for the
-environment itself is not fixed; it experiences variations
-which react in their turn upon the body under
-consideration; and it is only at the end of these
-variations, at the end of their respective periods, that
-they will attain together, in a universal uniformity, an
-eternal repose.</p>
-
-<p>We shall see that metallic alloys undergo continual
-physical and chemical changes. They are
-always seeking a more or less elusive equilibrium.
-Physicists in modern times have given their attention<span class="pagenum" id="Page_264">[Pg 264]</span>
-to this internal activity of material bodies, to the
-pursuit of stability. Wiedemann, Warburg, Tomlinson,
-MM. Duguet, Brillouin, Duhem, and Bouasse
-have revived the old experimental researches of
-Coulomb and Wertheim on the elasticity of bodies,
-the effects of pressures and thrusts, the hammering,
-tempering, and annealing of metals.</p>
-
-<p>The internal activity manifested under these circumstances
-presents quite remarkable characteristics
-which cannot but be compared to the analogous
-phenomena presented by living bodies. Thus have
-arisen even in physics, a figurative terminology, and
-metaphorical expressions borrowed from biology.</p>
-
-<p><i>Comparison of the Activity of Particles with Vital
-Activity.</i>—Since Lord Kelvin first spoke of the <i>fatigue</i>
-of metals, or the <i>fatigue</i> of elasticity, Bose has
-shown in these same bodies the fatigue of electrical
-contact. The term <i>accommodation</i> has been employed
-in the study of torsion, and according to Tomlinson
-for the very phenomena which are the inverse of
-those of fatigue. The phenomena presented by glass
-when acted on by an external force which slowly
-bends it, have been called facts of adaptation. The
-manner in which a bar of steel resists wire-drawing
-has been compared to <i>defensive</i> processes against
-threatened rupture. And M. C. E. Guillaume speaks
-somewhere of “the heroic resistance of the bar of
-nickel-steel.” The term “defence” has also been
-applied to the behaviour of chloride or iodide of
-silver when exposed to light.</p>
-
-<p>There has been no hesitation in using the term
-“memory” concurrently with that of hysteresis to
-designate the behaviour of bodies acted on by
-magnetism or by certain mechanical forces. It is<span class="pagenum" id="Page_265">[Pg 265]</span>
-true that M. H. Bouasse protests in the name of the
-physico-mathematicians against the employment of
-these figurative expressions. But has he not himself
-written “a twisted wire is a wound-up watch,” and
-elsewhere, “the properties of bodies depend at every
-moment upon all anterior modifications”? Does not
-this imply that they retain in some manner the
-impression of their past evolution? Powerful deformative
-agencies leave a trace of their action; they
-modify the body’s condition of molecular aggregation,
-and some physicists go so far as to say that they even
-modify its chemical constitution. With the exception
-of M. Duhem, the disciples of the mechanical school
-who have studied elasticity admit that the effect of an
-external force upon a body depends upon the forces
-which have been previously acting on it, and not
-merely upon those which are acting on it at the
-present moment. Its present state cannot be anticipated,
-it is the recapitulation of preceding states.
-The effect of a torsional force upon a new wire will
-be different from that of the same force upon a wire
-previously subjected to torsions and detorsions. It
-was with reference to actions of this kind that
-Boltzmann, in 1876, declared that “a wire that has
-been twisted or drawn out remembers for a certain
-time the deformations which it has undergone.”
-This memory is obliterated and disappears after a
-certain definite period. Here then, in a problem of
-static equilibrium, we find introduced an unexpected
-factor—time.</p>
-
-<p>To sum up, it is the physicists themselves who
-have indicated the correspondence between the condition
-of existence in many brute bodies and that in
-many living bodies. It cannot be expected that<span class="pagenum" id="Page_266">[Pg 266]</span>
-these analogies will in any way serve as explanations.
-We should rather seek to derive the vital from the
-physical phenomenon. This is the sole ambition of
-the physiologist. To derive the physical from the
-vital phenomenon would be unreasonable. We do
-not attempt to do this here. It is nevertheless true
-that analogies are of service, were it only to shake the
-support which, from the time of Aristotle, has been
-accorded to the division of the bodies of nature into
-<i>psuchia</i> and <i>apsuchia</i>—<i>i.e.</i>, into living and brute
-bodies.</p>
-
-
-<h4>§ 2. <span class="smcap">The Brownian Movement</span>.</h4>
-
-<p><i>The Existence of the Brownian Movement.</i>—The
-simplest way of judging of the working activity of
-matter is to observe it when the liberty of the
-particles is not interfered with by the action of the
-neighbouring particles. We approximate to this
-condition when we watch, through the microscope,
-grains of dust suspended in a liquid, or globules of
-oil suspended in water. Now what we see is well
-known to all microscopists. If the granulations are
-sufficiently small, they seem to be never at rest.
-They are animated by a kind of incessant tremor;
-we see the phenomena called the “Brownian movement.”
-This movement has struck all observers since
-the invention of the magnifying glass or simple
-microscope. But the English botanist, Brown, in
-1827, made it the object of special research and gave
-it his name. The exact explanation of it remained
-for a long time obscure. It was given in 1894 by
-M. Gouy, the learned physicist of the Faculty of
-Lyons.</p>
-
-<p><span class="pagenum" id="Page_267">[Pg 267]</span></p>
-
-<p>The observer who for the first time looks through
-the microscope at a drop of water from the river, from
-the sea, or from any ordinary source—that is to say,
-water not specially purified—is struck with surprise
-and admiration at the motion revealed to him.
-Infusoria, microscopic articulata, and various micro-organisms
-people the microscopic field, and animate
-it by their movements; but at the same time all sorts
-of particles are also agitated, particles which cannot
-be considered as living beings, and which are, in fact,
-nothing but organic detritus, mineral dust, and debris
-of every description. Very often the singular movements
-of these granulations, which simulate up to a
-certain point those of living beings, have perplexed
-the observer or led him to erroneous conclusions, and
-the bodies have been taken for animalcules or for
-bacteria.</p>
-
-<p><i>Characters of this Movement.</i>—But it is as a rule
-quite easy to avoid this confusion. The Brownian
-movement is a kind of oscillation, a stationary,
-dancing to-and-fro movement. It is a Saint Vitus’s
-dance on one and the same spot, and is thus distinguished
-from the movements of displacement
-customary with animate beings. Each particle has
-its own special dance. Each one acts on its own
-account, independently of its neighbour. There is,
-however, in the execution of these individual oscillations
-a kind of common and regular character which
-arises from the fact that their amplitudes differ
-little from each other. The largest particles are
-the slowest; when above four thousandths of a
-millimetre in diameter, they almost cease to be
-mobile. The smallest are the most active. When so
-small as to be barely visible in the microscope, the<span class="pagenum" id="Page_268">[Pg 268]</span>
-movement is extremely rapid, and can only occasionally
-be perceived. It is probable that it would be
-still more accelerated in smaller objects; but the latter
-will always escape our observation.</p>
-
-<p><i>Its Independence of the Nature of the Bodies and of the
-Environment.</i>—M. Gouy remarked that the movement
-depends neither on the nature nor on the form
-of the particles. Even the nature of the liquid has
-but little effect. Its degree of viscosity alone comes
-into play. The movements are, indeed, more lively
-in alcohol or ether, which are very mobile liquids;
-they are slow in sulphuric acid and in glycerine. In
-water, a grain one two-thousandth of a millimetre in
-diameter traverses, in a second, ten or twelve times its
-own length.</p>
-
-<p>The fact that the Brownian movement is seen in
-liquors which have been boiled, in acids and in
-concentrated alkalies, in toxic solutions of all degrees
-of temperature, shows conclusively that the phenomenon
-has no vital significance; that it is in no way
-connected with vital activity so called.</p>
-
-<p><i>Its Indefinite Duration.</i>—The most remarkable character
-of this phenomenon is its permanence, its
-indefinite duration. The movement never ceases,
-the particles never attain repose and equilibrium.
-Granitic rocks contain quartz crystals which, at the
-moment of their formation, include within a closed
-cavity a drop of water containing a bubble of gas.
-These bubbles, contemporary with the Plutonian age
-of the globe, have never since their formation ceased
-to manifest the Brownian movement.</p>
-
-<p><i>Its Independence of External Conditions.</i>—What is
-the cause of this eternal oscillation? Is it a tremor
-of the earth? No! M. Gouy saw the Brownian<span class="pagenum" id="Page_269">[Pg 269]</span>
-movement far away from cities, where the mercurial
-mirror of a seismoscope showed no subterranean
-vibration. It does not increase when the vibrations
-occur and become quite appreciable. Neither is it
-changed by variation in light, magnetism, or electric
-influences; in a word, by any external occurrences.
-The result of observation is to place before us the
-paradox of a phenomenon which is kept up and
-indefinitely perpetuated in the interior of a body
-without known external cause.</p>
-
-<p><i>The Brownian Movement must be the First Stage of
-Molecular Motion.</i>—When we take in our hands a
-sheet of quartz containing a gaseous inclusion, we
-seem to be holding a perfectly inert object. When
-we have placed it upon the stage of the microscope,
-and have seen the agitation of the bubble, we are
-convinced that this seeming inertia is merely an
-illusion.</p>
-
-<p>Repose exists only because of our limited vision.
-We see the objects as we see from afar a crowd of
-people. We perceive them only as a whole, without
-being able to discern the individuals or their movements.
-A visible object is, in the same way, a mass
-of particles. It is a molecular crowd. It gives us
-the impression of an indivisible mass, of a block in
-repose.</p>
-
-<p>But as soon as the lens brings us near to this
-crowd, as soon as the microscope enlarges for us the
-minute elements of the brute body, then they appear
-to us, and we perceive the continual agitation of those
-elements which are less than four thousandths of a
-millimetre in diameter. The smaller the particles
-under consideration, the more lively are their movements.
-From this we infer that if we could perceive<span class="pagenum" id="Page_270">[Pg 270]</span>
-molecules, whose probable dimensions are about one
-thousand times less, their probable velocity would be,
-as required by the kinetic theory, some hundreds of
-metres per second. In the case of objects we can
-only just see, the Brownian velocity is only a few
-thousandths of a millimetre per second. No doubt,
-concludes M. Gouy, the particles that show this
-velocity are really enormous when compared with
-true molecules. From this point of view the
-Brownian movement is but the first degree, and a
-magnified picture of the molecular vibrations assumed
-in the kinetic theory.</p>
-
-
-<h4>§ 3. <span class="smcap">The Internal Activity of Bodies.</span></h4>
-
-<p><i>Migration of Material Particles.</i>—In the Brownian
-movement we take into account only very small,
-isolated masses, small free fragments—<i>i.e.</i>, material
-particles which are not hampered by their relations to
-neighbouring particles. Any one but a physicist
-might believe that in true solids endowed with
-cohesion and tenacity, in which the molecules were
-bound one to the other, in which form and volume
-are fixed, there could be no longer movements or
-changes. This is a mistake. Physics teaches us the
-contrary, and, in late years especially, has furnished
-us characteristic examples. There are real migrations
-of material particles throughout solid bodies—migrations
-of considerable extent. They are accomplished
-through the agency of diverse forces acting externally—pressures,
-thrusts, torsions; sometimes under the
-action of light, sometimes under the action of electricity,
-sometimes under the influence of forces of<span class="pagenum" id="Page_271">[Pg 271]</span>
-diffusion. The microscopic observation of alloys by
-H. and A. Lechatelier, J. Hopkinson, Osmond, Charpy,
-J. R. Benoit; researches into their physical and
-chemical properties by Calvert, Matthiessen, Riche,
-Roberts Austen, Lodge, Laurie, and C. E. Guillaume;
-experiments on the electrolysis of glass, and the
-curious results of Bose upon electrical contact of
-metals, show in a striking manner the chemical and
-kinetic evolutions which occur in the interior of
-bodies.</p>
-
-<p><i>Migration under the Action of Weight.</i>—An experiment
-by Obermeyer, dating from 1877, furnishes
-a good example of the motions of solid bodies
-through a hardened viscid mass, taking place under
-the influence of weight. The black wax that
-shoemakers and boatbuilders use, is a kind of resin
-extracted from the pine and other resinous trees,
-melted in water, and separated from the more fluid
-part which rises from it. Its colour is due to the
-lampblack produced by the combustion of straw and
-fragments of bark. At an ordinary temperature it is
-a mass so hard that it cannot always be easily
-scratched by the finger-nail; but if it is left to itself
-in a receptacle, it finally yields, spreads out as if it
-were a liquid, and conforms to the shape of the vessel.
-Suppose we place within a cavity hollowed out of a
-piece of wood a portion of this substance, and keep it
-there by means of a few pebbles, having previously
-placed at the bottom of the cavity a few fragments of
-some light substance, such as cork. The piece of wax
-is thus between a light body below and a heavy body
-above. If we wait a few days, this order is reversed—the
-wax has filled the cavity by conforming to it;
-the cork has passed through the wax and appears on<span class="pagenum" id="Page_272">[Pg 272]</span>
-the surface, while the stones are at the bottom. We
-have here the celebrated experiment of the flask with
-the three elements, in which are seen the liquids
-mercury, oil, and water superposed in the order of
-their density, but in this case demonstrated with
-solid bodies.</p>
-
-<p><i>Influence of Diffusion.</i>—Diffusion, which disseminates
-liquids throughout each other, may also cause
-solids to pass through other solids. Of this W.
-Roberts Austen gave a convincing proof. This ingenious
-physicist placed a little cylinder of lead upon
-a disc of gold, and kept the whole at the temperature
-of boiling water. At this temperature both metals
-are perfectly solid, for the melting point of gold is
-1,200° C., and of lead is 330°. Still, after this contact
-has been prolonged for a month and a half, analysis
-shows that the gold has become diffused through the
-top of the cylinder of lead.</p>
-
-<p><i>Influence of Electrolysis.</i>—Electrolysis offers another
-no less remarkable means of transportation. By its
-means we may force metals, such as sodium or lithium,
-through glass walls. The experiment may be performed
-as indicated by M. Charles Guillaume. A
-glass bulb containing mercury is placed in a bath of
-sodium amalgam, and a current is then made to pass
-from within outward. After some time it can be
-shown that the metal has penetrated the wall of the
-bulb, and has become dissolved within it.</p>
-
-<p><i>Influence of Mechanical Pressure.</i>—Mechanical pressure
-is also capable of causing one metal to pass into
-another. We need not recall the well-known experiment
-of Cailletet, who, by employing considerable
-pressure, caused mercury to sweat through a block of
-iron. In a more simple manner W. Spring showed<span class="pagenum" id="Page_273">[Pg 273]</span>
-that a disc of copper could be welded to a disc of tin
-by pressing them strongly one against the other. Up
-to a certain distance from the surfaces of contact
-a real alloy is formed; a layer of bronze of a certain
-thickness unites the two metals, and this could not
-take place did not the particles of both metals
-mutually interpenetrate.</p>
-
-
-<h4>§ 4. <span class="smcap">Internal Activity of Alloys.</span></h4>
-
-<p><i>Structure of Alloys.</i>—Metallic alloys have a remarkable
-structure, which is essentially mobile, and
-which we have only now begun to understand by the
-aid of the microscope. Microscopical examination
-justifies to a certain degree Coulomb’s conjecture.
-That illustrious physicist explained the physical properties
-of metals by imagining them to be formed of
-two kinds of elements—integral particles, to which the
-metal owes its elastic properties, and a <i>cement</i> which
-binds the particles, and to which it owes its coherence.
-M. Brillouin has also taken up this hypothesis of
-duality of structure. The metal is supposed to be
-formed of very small, isolated, crystalline grains,
-embedded in an almost continuous network of viscous
-matter. A more or less compact mass surrounding
-more or less distinct crystals is the conception which
-may be formed of an alloy.</p>
-
-<p><i>Changes of Structure produced by Deforming
-Agencies.</i>—It has been shown that profound changes
-of crystalline structure can be produced by various
-mechanical means, such as hammering, and the
-stretching of metallic bars carried to the point of
-rupture. Some of these changes are very slow, and
-it is only after months and years that they are com<span class="pagenum" id="Page_274">[Pg 274]</span>pleted,
-and the metal attains the definite equilibrium
-corresponding to the conditions to which it is exposed.
-Though there may be discussions concerning the
-extent of the transformations to which it is subjected,
-though some believe they affect the chemical condition
-of the alloy, while others limit its power to
-physical effects, it is nevertheless true—and this
-brings us back to our subject—that the mass of these
-metals is at work, and that it only slowly attains the
-phase of complete repose.</p>
-
-<p><i>The Slow Re-establishment of Equilibrium. Residual
-Effect.</i>—These operations by which the physical
-characters of metals are changed, and by which they
-are adapted to a variety of industrial needs—compression,
-hammering, rolling, stretching, and torsion—have
-an immediate, very apparent effect; but they
-have also a consecutive effect, slowly produced, much
-less marked and less evident. This is the “residual
-effect,” or “Nachwirkung” of the Germans. It is not
-without importance, even in practical applications.</p>
-
-<p>Heat also creates a kind of <i>forced equilibrium</i>.
-This becomes but slowly modified, so that a body
-may remain for a long time in a state which is, however,
-not the most stable for the conditions under
-which it is considered. The number of these bodies
-<i>not in equilibrium</i> is as great as that of the substances
-which have been exposed to fusion. All the Plutonic
-rocks are in this condition. Glass presents a condition
-of the same kind. Thermometers placed in
-melting ice do not always mark the zero Centigrade.
-This displacement of the zero point falsifies all
-records if care is not taken to correct it. The
-correction usually requires prolonged observation.
-The theory of the displacement of the thermometric<span class="pagenum" id="Page_275">[Pg 275]</span>
-zero is not entirely established; but we may suppose,
-with the author of the <i>Traité de Thermométrie</i>, that in
-glass, as in alloys, are to be found compounds which
-vary according to the temperature. At each temperature
-glass tends to assume a determinate composition
-and a corresponding state of equilibrium;
-but the previous temperature to which it has been
-subjected clearly has an influence on the rapidity
-with which it attains its state of repose. The effect
-of variation is more marked when we observe glass of
-more complicated composition. We can understand
-that those which contain comparable quantities of the
-two alkalies, soda and potash, may be more subject
-to these modifications than those having a more
-simple composition based on a single alkali.</p>
-
-<p><i>Effects of Annealing.</i>—A piece of brass wire that
-has been drawn and then heated is the scene of
-certain very remarkable internal changes, and these
-have been only recently recognized. The violent
-treatment of the metallic thread in forcing it through
-the hole in the die has crushed the crystalline
-particles; the interior state of the wire is that of
-broken crystals embedded in a granular mass.
-Heating changes all that. The crystals separate,
-repair themselves, and are built up again; they are
-then hard, geometrical bodies, in an amorphous,
-relatively soft and plastic mass; their number keeps
-on increasing; equilibrium is not established until the
-entire mass is crystallized. We may imagine how
-many displacements, enormous when compared with
-their dimensions, the molecules have to undergo when
-passing through the resisting mass, and arranging
-themselves in definite places in the crystalline
-structures.</p>
-
-<p><span class="pagenum" id="Page_276">[Pg 276]</span></p>
-
-<p>In the same way, too, in the manufacture of steel,
-the particles of coal at first applied to the surface
-pass through the iron.</p>
-
-<p>This <i>faculty of molecular displacement</i> enables the
-metal in some cases to modify its state at one point
-or another. The use made of this faculty under
-certain circumstances is very curious, greatly resembling
-the adaptation of an animal to its environment,
-or the methods of defence against agents that
-might destroy it.</p>
-
-<p><i>Effect of Stretching. Hartmann’s Experiment.</i>—When
-a cylindrical rod of metal, held firmly at either
-end—a test-piece, as it is called in metallurgy—is
-pulled sufficiently hard, it often elongates considerably,
-part of the elongation disappearing as soon as
-the strain ceases, and the other part remaining. The
-total elongation is thus the sum of an “elastic
-elongation,” which is temporary, and a “permanent
-elongation.” If we continue the stretching, there
-appears at some point of the rod a local extension
-with contraction of sectional area. It is here that the
-rod will break.</p>
-
-<p>But in place of continuing the stretching, Mr.
-Hartmann suspends it. He stops, as if to give the
-“metal-being” time to rally. During this delay it
-would seem that the molecules hasten to the menaced
-point to reinforce and harden the weak part. In
-fact the metal, which was soft at other points, at
-this spot looks like tempered metal. It is no longer
-extensible.</p>
-
-<p>When the experimenter begins the stretching again
-after this rest, and after the narrowed bar has been
-rolled and become cylindrical again, the local extension
-and sectional contraction is forced to occur at<span class="pagenum" id="Page_277">[Pg 277]</span>
-another point. If another rest is given at this point
-the metal will also become hardened.</p>
-
-<p>If we repeat the experiment a sufficient number of
-times, we shall find a total transformation of the rod,
-which becomes hardened throughout its entire extent.
-It will break rather than elongate if the stretching is
-sufficiently severe.</p>
-
-<p><i>Nickel Steels—their “Heroic” Resistance.</i>—Nickel
-steels present this phenomena in an exaggerated
-degree. The alternation of operations which we
-have just described, bringing the various parts of an
-ordinary steel rod into a tempered state, is not
-necessary with nickel steel. The effect is produced
-in the course of a single trial. As soon as there is
-any tendency to contraction the alloy hardens at that
-precise place; the contraction is hardly noticeable;
-the movement is stopped at this point to attack
-another weak point, stops there again and attacks a
-third, and so on; and, finally, the paradoxical fact
-appears that a rod of metal which was in a soft state
-and could be considerably elongated has now become
-throughout its whole extent as hard, brittle, and
-inextensible as tempered steel. It is in connection
-with this point that M. C. E. Guillaume spoke of
-“heroic resistance to rupture.” It would seem, in
-fact, as if the ferro-nickel bar had reinforced each
-weak point as it was threatened. It is only at the
-end of these efforts that the inevitable catastrophe
-occurs.</p>
-
-<p><i>Effect of Temperature.</i>—When the temperature
-changes, it is seen that these ferro-nickel bars elongate
-or retract, modifying at the same time their chemical
-constitution. But these effects, like those which occur
-in the glass bulb of a thermometer, do not occur<span class="pagenum" id="Page_278">[Pg 278]</span>
-at once. They are produced rapidly for one part, and
-more slowly for a small remaining portion. Bars of
-ferro-nickel which have been kept at the same
-temperature change gradually in length in the course
-of a year. Can we find a better proof of internal
-activity occurring in a substance differing so greatly
-from living matter?</p>
-
-<p><i>Nature of the Activity of Particles.</i>—These are
-examples of the internal activity that occurs in brute
-bodies. Besides, these facts that we are quoting
-merely to refute Bichat’s assertion relative to the
-immutability of brute bodies, and to show us their
-activity, also afford us another proof. They show
-that this activity, like that of animals, wards off
-foreign intervention, and that this parrying of the
-attack, again like that of animals, is adapted for the
-defence and preservation of the brute mass. So that
-if we consider of special importance the adaptative,
-teleological characteristic of vital phenomena, a
-characteristic which is so easily made too much of
-in biological interpretations, we may also find it
-again in the inanimate world. To this end we may
-add to the preceding examples one more which is
-no less remarkable. This is the famous case of
-Becquerel’s process for colour-photography.</p>
-
-<p><i>Colour-Photography.</i>—A greyish plate, treated with
-chloride or iodide of silver and exposed to a red light,
-rapidly becomes red. It is then exposed to green
-light, and after passing through dull and obscure
-tints it becomes green. To explain this remarkable
-phenomenon, we cannot improve on the following
-statement:—The silver salt protects itself against
-the light that threatens its existence; that light
-causes it to pass through all kinds of stages of<span class="pagenum" id="Page_279">[Pg 279]</span>
-coloration before reducing it; the salt stops at the
-stage which protects it best. It stops at red, if it is
-red light that assails it, because in becoming red by
-reflection it best repels that light—<i>i.e.</i>, it absorbs it
-the least.</p>
-
-<p>It may then be advantageous, for the comprehension
-of natural phenomena, to regard the transformation
-of inanimate matter as manifestations of a
-kind of internal life.</p>
-
-<p><i>Conclusion. Relations of the Surrounding Medium
-to the Living Being and the Brute Body.</i>—Brute
-bodies, then, are not immutable any more than are
-living bodies. Both depend on the medium that
-surrounds them, and they depend upon it in the
-same way. Life brings together, brings into conflict,
-an appropriate organism and a suitable environment.
-Auguste Comte and Claude Bernard have taught
-us that vital phenomena result from the reciprocal
-action of these two factors which are in close correlation.
-It is also from the reciprocal action of the
-environment and the brute body that inevitably
-result the phenomena which that body presents.
-The living body is sometimes more sensitive to
-variations of the ambient medium than is the brute
-body, but at other times the reverse is the case.
-For example, there is no living organism as impressionable
-to any kind of stimulus whatever as the
-bolometer is to the slightest variations of temperature.</p>
-
-<p>There can only be, then, one chemically immutable
-body—namely, the atom of a simple body, since, by
-its very definition, it remains unaltered and intangible
-in combinations. This notion of an unalterable atom
-has, however, itself been attacked by the doctrine of
-the ionization of particles due to Sir J. J. Thomson;<span class="pagenum" id="Page_280">[Pg 280]</span>
-and besides, with very few exceptions—those of
-cadmium, mercury, and the gases of the argon series—the
-atoms of simple bodies cannot exist in a free
-state.</p>
-
-<p>Thus, as in the vital struggle, the ambient medium
-by means of alimentation furnishes to the living being,
-whether whole or fragmentary, the materials of its
-organization and the energies which it brings into play.
-It also furnishes to brute bodies their materials and
-their energies.</p>
-
-<p>It is also said that the ambient medium furnishes
-to the living being a third class of things, the
-<i>stimuli</i> of its activities—<i>i.e.</i>, its “provocation to action.”
-The protozoon finds in the aquatic environment
-which is its habitat the stimuli which provoke it to
-move and to absorb its food. The cells of the
-metazoon encounter in the same way in the lymph,
-the blood, and the interstitial liquids which bathe
-them, the shock, the stimulus which brings their
-energies into play. They do not derive from themselves,
-by a mysterious spontaneity without parallel
-in the rest of nature, the capricious principle which
-sets them in motion.</p>
-
-<p>Vital spontaneity, so readily accepted by persons
-ignorant of biology, is disproved by the whole history
-of the science. Every vital manifestation is a response
-to a stimulus, a provoked phenomenon. It is unnecessary
-to say this is also the case with brute
-bodies, since that is precisely the foundation of the
-great principle of the inertia of matter. It is plain
-that it is also as applicable to living as to inanimate
-matter.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_281">[Pg 281]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_V_4">CHAPTER V.<br />
-
-
-<small><span class="smcap">Specific Form. Living Bodies and Crystals.</span></small></h3>
-</div>
-
-<p class="prel">§ 1. Specific form and chemical constitution—The wide distribution
-of crystalline forms—Organization of crystals—Law
-of relation between specific form and chemical
-constitution—Value of form as a characteristic of brute
-and living beings—Parentage, living beings and mineral
-parentage—Iso-morphism and the faculty of cross-breeding—Other
-analogies. § 2. Acquisition and re-establishment
-of the specific form—Mutilation and regeneration of crystals—Mechanism
-of reparation.</p>
-
-
-
-<p>§ 1. <i>Specific Form and Chemical Constitution.</i>—In
-the enumeration which we have made of the essential
-features of vitality there are three that are, so to
-speak, of the highest value. They are, in the order of
-their importance:—The possession of a specific form;
-the faculty of growth or nutrition; and finally, the
-faculty of reproduction by generation. By restricting
-our comparison between brute bodies and living
-bodies to these truly fundamental characters we
-sensibly restrict the field, but we shall see that it
-does not disappear.</p>
-
-<p><i>Wide Distribution of Crystalline Forms.</i>—The
-consideration of specific forms shows us that in
-the mineral world we need only consider crystallized
-bodies, as they are almost the only ones that possess
-definite form. In restricting ourselves to this category
-we do not limit our field as much as might be sup<span class="pagenum" id="Page_282">[Pg 282]</span>posed.
-Crystalline forms are very widely distributed.
-They are, in a measure, universal. Matter has a
-decided tendency to assume these forms whenever the
-physical forces which it obeys act with order and
-regularity, and when their action is undisturbed by
-accidental occurrences. In the same way, too, living
-forms are only possible in regulated environments,
-under normal conditions, protected from cataclysms
-and convulsions of nature.</p>
-
-<p>The possession of a specific form is the most
-significant feature of an organized being. Its
-tendency, from the time it begins to develop from
-the germ, is toward the acquirement of that form.
-The progressive manner in which it seeks to realize
-its architectural plan in spite of the obstacles and
-difficulties that arise—healing its wounds, repairing
-its mutilations—all this, in the eyes of the philosophical
-biologist, forms what is perhaps the most
-striking characteristic of a living being, that which
-best shows its unity and its individuality. This
-property of organogenesis seems pre-eminently the
-vital property. It is not so, however, for crystalline
-bodies possess it in an almost equal degree.</p>
-
-<p>The parallel between the crystal and a living being
-has been often drawn. I will not reproduce it here
-in detail. My sole desire, after sketching its principal
-features, is to call attention to the new information
-that has been brought out by recent investigations.</p>
-
-<p><i>Organization of Crystals. Views of Haüy, Delafosse,
-Bravais, and of Wallerant.</i>—In botany, zoology,
-and crystallography we understand by form an
-assemblage of material constituents co-ordinated in
-a definite system—<i>i.e.</i>, the organization itself. The
-body of man, for example, is an edifice in which sixty<span class="pagenum" id="Page_283">[Pg 283]</span>
-trillion cells ought each to find its own predetermined
-place.</p>
-
-<p>In crystallography also we understand by form the
-organization which crystals present. The grouping
-of the elements of crystals is, perhaps, more simple.
-They are none the less organized, in the same sense
-that living bodies are.</p>
-
-<p>Their organization, while more uniform than that
-of living bodies, still shows a considerable amount of
-variation. It should not be assumed that the area of
-a crystal is completely filled, with contiguous parts
-applied one to the other by plane faces, as might be
-supposed from the phenomenon of cleavage which
-dissociates the parts of the crystalline body into
-solids of this kind. In reality, the constituent parts
-are separated from each other by spaces. They are
-arranged in a quincunx, as Haüy put it, or along the
-lines of a network, to use the terms of Delafosse and
-Bravais. The intervals left between them are incomparably
-larger than their diameters. So that in the
-organization of a crystal it is necessary to take into
-account two quite different things:—An element, the
-crystalline particle, which is a certain aggregate of
-chemical molecules having a determinate geometrical
-form; and a more or less regular, parallelopipedic network,
-along the edges of which are arranged in a constant
-and definite manner the aforesaid particles. The
-external form of the crystal indicates the existence
-of the network. Its optical properties depend upon
-the action of the particles, as Wallerant has shown:
-Thus we must distinguish in a crystal between two
-kinds of geometrical figures—that of the network
-and that of the particle—and their characters of
-symmetry may be either concordant or discordant.</p>
-
-<p><span class="pagenum" id="Page_284">[Pg 284]</span></p>
-
-<p>The crystalline particle, the element of the crystal,
-is therefore a certain molecular complex that repeats
-itself identically and is identically placed at the
-nodes of the parallelopipedic network. It has been
-given different names well calculated to produce
-confusion-the crystallographic molecule of Mallard,
-the complex particle of other authors. Some have
-separated this element into subordinate elements
-(the fundamental particles of Wallerant and of
-Lapparent).</p>
-
-<p>These very general outlines will suffice to show
-how complex and adjustable is the organization of
-the crystalline individual, which in spite of its
-geometric regularity and its rigidity, may be compared
-with the still more flexible organization of the
-living element. The mineral individual is more
-stable, more labile—<i>i.e.</i>, less prone to undergo change
-than is the living individual. We may say with
-M. Lapparent that “crystallized matter presents the
-most perfect and stable orderly arrangement of
-which the particles of bodies are susceptible.”</p>
-
-<p><i>Law of Relation of Specific Form to Chemical
-Constitution.</i>—Crystallization is a method of acquiring
-specific form. The geometrical architecture of the
-mineral individual is but little less wonderful or
-characteristic than that of the living individual. Its
-form is the result of the mutual reactions of its
-substances and of the medium in which it is produced;
-it is the condition of material equilibrium
-corresponding to a given situation. This idea of a
-specific form belonging to a given substance under
-given conditions must be borne in mind. We may
-consider it as a kind of principle of nature, an
-elementary law, which may serve as a point of<span class="pagenum" id="Page_285">[Pg 285]</span>
-departure for the explanation of phenomena. A
-particular substance under identical conditions of
-environment, must always assume a certain form.</p>
-
-<p>This close linking of substance and form, admitted
-as a postulate in physical sciences, has been carried
-into biology by some philosophical naturalists, by
-M. Le Dantec, for instance.</p>
-
-<p>Let us imitate them for a moment. Let us cease
-to seek in the living being for the prototype of the
-crystal; let us, on the contrary, seek in the crystal the
-prototype of the living being. If we succeed in this,
-we shall then have found the physical basis of life.</p>
-
-<p>Let us say, then, with the biologists we have
-mentioned, that the substance of each living being is
-peculiar to it; that it is specific, and that its form—that
-is to say its organization—follows from it. The
-morpholpgy of any being whatever, of an animal—of
-a setter, for example—or even of a determinate
-being—of Peter, of Paul—is the “crystalline form of
-their living matter.” It is the only form of equilibrium
-that can be assumed under the given conditions
-by the substance of the setter, of Peter, or of Paul,
-just as the cube is the crystalline form of sea-salt.
-In this manner these biologists have supposed that
-they could carry back the problem of living form
-to the problem of living substance, and at the same
-time reduce the biological mystery to the physical
-mystery. I have shown above (Chap. V. pp. 199-204)
-how far this idea is legitimate, and how far and with
-what restrictions it may be welcomed and adopted.</p>
-
-<p><i>Value of Form as a Characteristic of Living and
-Brute Beings.</i>—However this may be, we may say,
-without fear of exaggeration, that the crystalline form
-characterizes the mineral with no less precision than<span class="pagenum" id="Page_286">[Pg 286]</span>
-the anatomical form characterizes the animal and the
-plant. In both cases, form—regarded as a method
-of distribution of the parts—indicates the individual
-and allows us to diagnose it with more or less facility.</p>
-
-<p><i>Parentage of Living Beings and Mineral Parentage.</i>—Still
-another analogy has been noted. In
-animals and plants similarity in form indicates
-similarity in descent, community of origin, and
-proximity in any scheme of classification. In the
-same way identity of crystalline form indicates
-mineral relationship. Substances chemically analogous
-show identical, geometrically superposable
-forms, and are thus arranged in family or generic
-groups recognizable at a glance.</p>
-
-<p><i>Isomorphism and the Faculty of Cross-breeding.</i>—And
-further, the possibility in the case of isomorphous
-bodies, of their replacing each other in the same crystal
-during the process of formation and of thus mingling,
-so to speak, their congenital elements, may be
-compared with the possibility of inter-breeding with
-living beings of the same species. Isomorphism is
-thus a kind of faculty of crossing. And as the
-impossibility of crossing is the touchstone of taxonomic
-relationship, testing it, and separating stocks
-that ought to be separated, so the operation of
-crystallization is also a means of separating from an
-accidental mixture of mineral species the pure forms
-which are blended therein. Crystallization is the
-touchstone of the specific purity of minerals; it is the
-great process in chemical purification.</p>
-
-<p><i>Other Analogies.</i>—The analogies between crystalline
-and living forms have been pushed still further
-even to the verge of exaggeration.</p>
-
-<p>The internal and external symmetry of animals<span class="pagenum" id="Page_287">[Pg 287]</span>
-and plants has been compared to that of crystals.
-Transitions or intergradations have been sought
-between the rigid and faceted architecture of the
-latter and the flexible structure and curved surface of
-the former; the utricular form of flowers of sulphur
-on the one hand, and the geometrical structure of the
-shells of radiolarians on the other, have shown an
-exchange of typical forms between the two systems.
-An effort has even been made to draw a parallel
-between six of the principal types of the animal
-kingdom and the six crystalline systems. If carried
-as far as this, our thesis becomes puerile. Real
-analogies will suffice. Among these the curious facts
-of crystalline renewal come first.</p>
-
-
-<h4>§ 2. <span class="smcap">Cicatrization in Living Beings and in
-Crystals.</span></h4>
-
-<p>We know that living beings not only possess a
-typical architecture which they have themselves
-constructed, but that they defend it against destructive
-agencies, and that if need arise they repair
-it. The living organism cicatrizes its wounds, repairs
-losses of substance, regenerates more or less perfectly
-the parts that have been removed; in other terms,
-when it has been mutilated it tends to reconstruct
-itself according to the laws of its own morphology.
-This phenomenon of reconstitution or reintegration,
-these more or less successful efforts to re-establish its
-form and its integrity, at first appear to be a characteristic
-feature of living beings. This is not the
-case.</p>
-
-<p><i>Mutilation and Re-integration of Crystals.</i>—Crystals—let
-us say crystalline individuals—show a<span class="pagenum" id="Page_288">[Pg 288]</span>
-similar aptitude for repairing their mutilations.
-Pasteur, in an early work, discussed these curious
-facts. Other experimenters, Gernez a little later and
-Rauber more recently, took up the same subject, but
-could do no more than extend and confirm his
-observations. Crystals are formed from a primitive
-nucleus, as the animal is formed from an egg; their
-integral particles are disposed according to efficient
-geometrical laws, so as to produce the typical form
-by a constructive process that may be compared to
-the embryogenic process which builds up the body of
-an animal. Now this operation may be disturbed by
-accidents in the surrounding medium or by the
-deliberate intervention of the experimenter. The
-crystal is then mutilated. Pasteur saw that these
-mutilations repaired themselves. “When,” said he,
-“a crystal from which a piece has been broken off is
-replaced in the mother liquor, we see that while it
-increases in every direction by a deposit of crystalline
-particles, activity occurs at the place where it was
-broken off or deformed; and in a few hours this
-suffices not only to build up the regular amount
-required for the increase of all parts of the crystal,
-but to re-establish regularity of form in the mutilated
-part.” In other words, the work of formation of the
-crystal is carried on much more actively at the point
-of lesion than it would have been had there been no
-lesion. The same thing would have occurred with a
-living being.</p>
-
-<p><i>Mechanism of Reparation.</i>—Gernez some years later
-made known the mechanism of this reparation, or, at
-least, its immediate cause. He showed that on the
-injured surface the crystal becomes less soluble than
-on the other facets. This is not, however, an ex<span class="pagenum" id="Page_289">[Pg 289]</span>ceptional
-phenomenon. It is, on the contrary, quite
-frequently observed that the different faces of a
-crystal show marked differences in solubility. This
-is what happens in every case for the mutilated face
-in comparison with the others; the matter is less
-soluble there. The consequence of this is clear; the
-growth must preponderate on that face, since there
-the mother liquor will become super-saturated before
-being super-saturated for the others. We may
-explain this result in another way. Each face of the
-crystal in contact with the mother liquor is exposed
-to two antagonistic actions: The matter deposited
-upon a surface may be taken away and redissolved if,
-for any reason whatever, such matter becomes more
-soluble than that of the liquid stratum in contact
-with it; in the second place, the matter of this liquid
-stratum may, under contrary conditions, be deposited,
-and thus increase the body of the crystal. There is,
-then, for each point of the crystalline facet, a positive
-operation of deposit which results in a gain, and a
-negative operation of redissolution which results in a
-loss. One or the other effect predominates according
-as the relative solubility is greater or less for the
-matter of the facet under consideration. On the
-mutilated surface it is diminished, deposition then
-prevails.</p>
-
-<p>But this is only the immediate cause of the
-phenomenon; and if we wish to know why the
-solubility has diminished on the mutilated surface
-Ostwald explains it to us by showing that crystallization
-tends to form a polyhedron in which the
-surface energy is a relative minimum.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_290">[Pg 290]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_VI_4">CHAPTER VI.<br />
-
-<small>NUTRITION IN THE LIVING BEING AND IN THE
-CRYSTAL.</small></h3></div>
-
-
-<p class="prel">Assimilation and growth in the crystal.—Methods of growth
-in the crystal and in the living being; intussusception;
-apposition.—Secondary and unimportant character of the
-process of intussusception.</p>
-
-
-<p>I have already stated (Chap. VI. p. 209) that nutrition
-may be considered as the most characteristic and
-essential property of living beings. Such beings are
-in a state of continual exchange with the surrounding
-medium. They assimilate and dissimilate. By assimilation
-the substance of their being increases at
-the expense of the surrounding alimentary material,
-which is rendered similar to that of the being itself.</p>
-
-<p><i>Assimilation and Growth in the Crystal.</i>—There
-exists in the crystal a property analogous to nutrition,
-a kind of nutrility, which is the rudiment of this
-fundamental property of living beings. The development
-of a crystal starts from a primitive nucleus, the
-germ of the crystalline individual that we will
-presently compare to the ovum or embryo of a plant
-or an animal. Placed in a suitable culture-medium—<i>i.e.</i>,
-in a solution of the substance—this germ
-develops. It assimilates the matter in solution,
-incorporates the particles of it, and increases, preserving
-at the same time its form, reproducing its<span class="pagenum" id="Page_291">[Pg 291]</span>
-specific type or a variety of it. Its growth proceeds
-without interruption. The crystalline individual may
-attain quite a large size if we know how to nourish it
-properly—we might say, to fatten it. Very frequently,
-at a given time, a new particle of the crystal
-serves in its turn as a primitive nucleus, and becomes
-the point of departure for a new crystal engrafted
-upon the first.</p>
-
-<p>Taken from its mother liquor, placed where it
-cannot be nourished, the crystal, arrested in its
-growth, falls into a condition of rest not without
-analogy to that of a seed or of a reviviscent animal.
-Its evolution is resumed with the return of favourable
-conditions—the bath of soluble matter.</p>
-
-<p>The crystal is in a relation of continual exchange
-with the surrounding medium which feeds it. These
-exchanges are regulated by the state of this medium,
-or, more exactly, by the state of the liquid stratum
-which is in immediate contact with the crystals. It
-loses or it gains in substance if, for example, this
-layer becomes heated or cooled more rapidly than the
-crystal. In a general way, it assimilates or dissimilates
-according as its immediate environment is saturated
-or diluted. Here, then, we have a kind of mobile
-equilibrium, comparable, in some measure, to that of
-the living being.</p>
-
-<p><i>Methods of Growth of the Crystal and of the Living
-Being. Intussusception. Apposition.</i>—In truth, there
-seems to be a complete opposition between the crystal
-and the living being as regards their manner of
-nutrition and growth. In the one case the method is
-intussusception; in the other it is apposition. The
-crystalline individual is all surface. Its mass is impenetrable
-to the nutritive materials. Since only the<span class="pagenum" id="Page_292">[Pg 292]</span>
-surface is accessible, the incorporation of similar
-particles is possible only by external juxtaposition,
-and the edifice increases only because a new layer of
-stones has been added to those which were there
-before. On the contrary, the body of an animal is a
-mass essentially penetrable. The cellular elements
-that compose it have more or less rounded and
-flexible forms. Their contact is by no means perfect.
-They have neither the stiffness nor the precision
-of adjustment that the crystalline particles have.
-Liquids and gases can insinuate themselves from
-without and circulate within the meshes of this loose
-construction. Assimilation can therefore take place
-throughout its whole depth, and the edifice increases
-because each stone is itself increasing.</p>
-
-<p><i>The Secondary and Commonplace Character of the
-Process of Intussusception.</i>—The apparent opposition
-of these two processes is doubtless diminished if we
-compare the simple mineral individual with the
-elementary living unit, the crystalline particle with
-the protoplasmic mass of a cell. Without carrying
-analysis so far as this, it is yet easy to see that apposition
-and intussusception are mechanical means
-that living beings employ at one and the same time
-and combine according to their necessities. The hard
-parts of the internal and external skeleton increase
-both by interposition and superposition, at once. It
-is by the last method that bones increase in diameter,
-and the shells of molluscs, the scales of reptiles and
-fishes, and the testae of many radiate animals are
-formed. In these organs, as in crystals, life and
-nutrition occur at the surface.</p>
-
-<p>Apposition and intussusception are then secondary,
-mechanical arrangements having relation to the<span class="pagenum" id="Page_293">[Pg 293]</span>
-physical characters of the body—solidity in the
-crystal, semi-fluidity in the cellular protoplasm. If
-we compare the inorganic liquid matter with the
-semi-fluid organized matter, we recognize that the
-addition of substance takes place in the same manner
-in each—<i>i.e.</i>, by interposition. If we add a soluble
-salt to a fluid, the molecules of the salt separate
-themselves and interpose themselves between those
-of the fluid. There is, therefore, nothing especially
-mysterious or particularly vital about the process of
-intussusception. Applied to fluid protoplasm, it is
-merely the diffusion that ordinarily occurs in mixed
-liquids.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_294">[Pg 294]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_VII_4">CHAPTER VII.<br />
-
-<small>GENERATION IN BRUTE BODIES AND LIVING
-BODIES. SPONTANEOUS GENERATION.</small></h3></div>
-
-
-<p class="prel">Protoplasm a substance which continues—Case of the crystal—Characteristics
-of generation in the living being—Property
-of growth—Supposed to be confined to the living being—Fertilization
-of micro-organisms—Fertilization of crystals—Sterilization
-of crystalline and living media—Spontaneous
-generation of crystals—Metastable and labile zones—Glycerine
-crystals—Possible extinction of a crystalline
-species—Conclusion.</p>
-
-
-<p>We have not yet exhausted the analogies between a
-crystal and the living being. The possession of a
-specific form, the tendency to re-establish it by redisintegration
-and the existence of a kind of nutrition
-are not sufficient to constitute complete similarity.
-It still lacks a fundamental character, that of generation.
-Chauffard some time ago, in an attack which
-he made upon the physiological ideas of his day,
-aptly exhibited this weak point. “Let us disregard,”
-he said, “those interesting facts relative to the acquisition
-of a typical form—facts that are common to the
-mineral world as well as to living beings. It is none
-the less true that the crystalline type is in no way
-derived from other pre-existing types, and that
-nothing in crystallization recalls the actions of
-ascendants and the laws of heredity.”</p>
-
-<p>This gap has since been filled. The work of<span class="pagenum" id="Page_295">[Pg 295]</span>
-Gernez, of Violette, of Lecoq de Boisbaudran, the experiments
-of Ostwald and of Tammann, the observations
-of Crookes and of Armstrong—all this series of
-researches, so lucidly summarized by M. Leo Errera
-in his essays in botanical philosophy, had for their
-result the establishment of an unsuspected relation
-between the processes of crystallization and those of
-generation in animals and plants.</p>
-
-<p><i>Protoplasm is a Substance which Continues. The
-Case of the Crystal.</i>—Under present conditions a living
-being of any kind springs from another living being
-similar to itself.</p>
-
-<p>Its protoplasm is always a continuation of the
-protoplasm of an ancestor. It is an atavic substance
-of which we do not see the beginning; we only see it
-continue. The anatomical element comes from a
-preceding anatomical element, and the higher animal
-itself comes from a pre-existing cell of the material
-organism, the ovum. The ladder of filiation reaches
-back indefinitely into the past.</p>
-
-<p>We shall see that there is something analogous to
-this in certain crystals. They are born of a preceding
-individual; they may be considered as the posterity
-of the antecedent crystal. If we speak of the matter
-of a crystal as the matter of a living being is spoken
-of, in cases of this kind we would say that the
-crystalline substance is an atavic substance of which
-we see only the continuation, as in the case of
-protoplasm.</p>
-
-<p><i>Characters of Generation in the Living Being.</i>—Growth
-of the living substance, and consequently of
-the being itself, is the fundamental law of vitality.
-Generation is the necessary consequence of growth
-(p. 210).</p>
-
-<p><span class="pagenum" id="Page_296">[Pg 296]</span></p>
-
-<p>Living elements or cells cannot subsist indefinitely
-without increasing and multiplying. The time must
-come when the cell divides, either directly or indirectly;
-and then, instead of one cell, there are two.
-This is the method of generation for the anatomical
-element. In a complex individual it is a more or less
-restricted part of the organism, usually a simple
-sexual cell, that takes on the formation of the new
-being, and assures the perpetuity of the protoplasm,
-and therefore of the species.</p>
-
-<p><i>Property of Growth. Its Supposed Restriction to
-Living Beings.</i>—At first it would appear that nothing
-like this occurs in inanimate nature. The physical
-machine, if we furnish it matter and energy, could go
-on working indefinitely, without being compelled to
-increase and reproduce. Here, then, there is an
-entirely new condition peculiar to the organized
-being, a property well adapted, it would seem—and
-this time without any possible doubt—for separating
-living matter from brute matter. It is not so.</p>
-
-<p>It would not be impossible to imagine a system
-of chemical bodies organized like the animal or
-vegetable economy, so that a destruction would be
-compensated for by a growth. The only thing impossible
-is to suppose, with M. le Dantec, a destruction
-that would at the same time be an analysis. And an
-additional perplexity occurs when he supposes that
-in the successive acts exchanges of material may
-occur.</p>
-
-<p>There is no necessity for making this impossible
-chemistry a characteristic of the living being. The
-chemistry of the living being is general chemistry.
-Lavoisier and Berthelot enforced this view. We
-should not lose sight of the teachings of the masters.</p>
-
-<p><span class="pagenum" id="Page_297">[Pg 297]</span></p>
-
-<p>Let us return to generation, properly so called, and
-find in it the characteristics of brute bodies and of
-crystals.</p>
-
-<p><i>The Sowing of Micro-organisms.</i>—When a microbiologist
-wishes to propagate a species of micro-organisms,
-he places in a culture medium a few
-individuals (one is all that is actually necessary), and
-soon observes their rapid multiplication. Usually, if
-only the ordinary microbes in atmospheric dust are
-wanted, the operator need not trouble to charge the
-culture; if the culture tube remains open and the
-medium is suitably chosen, some germ of a common
-species will fall in and the liquid will become
-colonized. This has the appearance of spontaneous
-generation.</p>
-
-<p><i>The Sowing of Crystals.</i>—Concentrated solutions of
-various substances, supersaturated solutions of sodium
-magnesium sulphate, and sodium chlorate are also
-wonderful culture media for certain mineral organic
-units—certain crystalline germs. Ch. Dufour, experimenting
-with water cooled below 0° C., its point
-of solidification; Ostwald, with salol kept below 39°.5,
-its point of fusion; Tammann, with betol, which
-melts at 96°; and, before them, Gernez, with melted
-phosphorus and sulphur—all these physicists have
-shown that liquids in superfusion are also media
-specially appropriate for the culture and propagation
-of certain kinds of crystalline individuals.</p>
-
-<p>Some of these facts have become classic. Lowitz
-showed in 1785 that a solution of sodium sulphate
-could be concentrated by evaporation so as to contain
-more salt than was conformable with the temperature,
-without, however, depositing the excess. But if a
-solid fragment, a crystal of salt, is thrown into the<span class="pagenum" id="Page_298">[Pg 298]</span>
-liquor, the whole of the excess immediately passes
-into the state of a crystallized mass. The first
-crystal has engendered a second similar to itself;
-the latter has engendered a third, and so on from one
-to the other. If we compare this phenomenon with
-that of the rapid multiplication of a species of
-microbes in a suitable culture medium, no difference
-will be perceived. Or perhaps we may note one
-unimportant difference—the rapidity of the propagation
-of the crystalline germs as opposed to the relative
-slowness of the generation of the micro-organisms.</p>
-
-<p>Again, the propagation of crystallization in a supersaturated
-or superfused liquid may be delayed by
-appropriate devices. The crystalline individual gives
-birth, then, to another individual that conforms to its
-own type, or even to varieties of that type when such
-exist. Into the right branch of a U tube filled with
-sulphur in a state of superfusion Gernez dropped
-octahedric crystals of sulphur, and into the left branch
-prismatic crystals. On either side were produced
-new crystals conforming to the type that had been
-sown.</p>
-
-<p><i>Sterilization of Crystalline Media and Living Media.</i>—Ostwald
-varied these experiments by using salol.
-He melted the substance by heating it above 39∙5°C.;
-then, protecting it from crystals of any kind, he let
-the solution stand in a closed tube. The salol remained
-liquid indefinitely—until it was touched with
-a platinum wire that had been in contact with solid
-salol—<i>i.e.</i>, until a crystalline germ was introduced.
-But if the platinum wire has been previously sterilized
-by passing it, as the bacteriologists do, through a
-flame, it can then be introduced into the liquor with
-impunity.</p>
-
-<p><span class="pagenum" id="Page_299">[Pg 299]</span></p>
-
-<p><i>The Dimensions of Crystalline Germs Comparable
-to those of Microbes.</i>—We may dilute the solid
-salol with inert powder—lactin, for example—dilute
-the first mixture with a second, the second with a
-third, and so on; then, throwing into the solution of
-surfused salol a tenth of a milligram from one of
-these various mixtures, we find that the production of
-crystals will not take place if the fragment thrown in
-weighs less than a millionth of a milligram, or
-measures less than ten thousandths of a millimetre
-in length. It would seem, then, that these are the
-dimensions of the crystalline particle or crystallographic
-molecule of salol. In the same way Ostwald
-satisfied himself that the crystalline germ of hyposulphite
-of soda weighs about a thousand-millionth of
-a milligram, and measures a thousandth of a millimetre;
-that of chlorate of soda weighs a ten-millionth
-of a milligram. These dimensions are entirely comparable
-with those of microbes.</p>
-
-<p>All these phenomena have been studied with a
-detail into which it is impossible to enter here, and
-which clearly shows more and more intimate analogies
-between the formation of crystals and the generation
-of micro-organisms.</p>
-
-<p><i>Extension and Propagation of Crystallization.
-Optimum Temperature of Incubation.</i>—Crystallization
-which has commenced around a germ is propagated
-more or less rapidly, and ends by invading the whole
-of the liquor.</p>
-
-<p>The rapidity of this movement of extension depends
-upon the conditions of the medium, especially upon
-its temperature. This is shown very well by
-Tammann’s experiments with betol. This body,
-the salicylic ester of naphthol, fuses at 96° C. If it<span class="pagenum" id="Page_300">[Pg 300]</span>
-is melted in tubes sealed at a temperature of 100° C.,
-it may be cooled to lower and lower temperatures—to
-+ 70°, to + 25°, to + 10°, to-5° without solidifying.
-Let us suppose that by some combination of circumstances
-a few centres of crystallization—that is to
-say, of crystalline germs—have appeared in the
-solution. Solidification will extend slowly at the
-ordinary temperature, at 20° to 25° and thereabouts.
-On the other hand, it will be propagated with great
-rapidity if the liquor is kept at about 70°. This
-point—70°—is the thermal optimum for the propagation
-of germs. It is the most favourable
-temperature for what may be called their incubation.
-As soon as the germs find themselves in a liquor at
-70° they increase, multiply, and show that they are in
-the best conditions for growth.</p>
-
-<p><i>Spontaneous Generation of Crystals. Optimum
-Temperature for the Appearance of Germs.</i>—If we
-consider various supersaturated solutions or liquids
-in superfusion, we shall soon discover that they can
-be arranged in two categories. Some remain indefinitely
-liquid under given conditions unless a
-crystalline germ is introduced into them. Others
-solidify spontaneously without artificial intervention,
-and such crystallization may even be propagated very
-rapidly under determinate conditions. This implies
-that these are conditions favouring the spontaneous
-appearance of germs.</p>
-
-<p>This distinction between substances of crystalline
-generation by filiation and substances of spontaneous
-crystalline generation is not specific. The same
-substance may present the two methods of generation
-according to the conditions in which it is placed.
-Betol furnishes a good example of this. Liquefy it at<span class="pagenum" id="Page_301">[Pg 301]</span>
-100° in a sealed tube and keep it by means of a stove
-above 30°, and it will remain liquid almost indefinitely.
-On the other hand, lower its temperature and leave it
-for one or two minutes at 10°, and germs will appear
-in the liquor; prolong the exposure to this degree of
-heat and the number of these spontaneously appearing
-germs, appearing in isolation, will rapidly increase.
-On the other hand, you will observe that propagation
-by filiation—that is to say, by extension from one
-to another—is almost absent. The temperature of
-10° is not favourable to that method of generation;
-and we have just seen, in fact, that it is at a temperature
-of about 70° that extension of crystallization
-from one to another is best accomplished. The
-temperature of 70° was the optimum for propagation
-by filiation. Inversely, the temperature of 10° is the
-optimum for spontaneous generation. Above and
-below this optimum the action is slower. We may
-count the centres of crystallization, which slowly
-extend further and further, as in a microbic
-culture one counts the colonies corresponding to
-the germs primitively formed. To sum up, if
-there is an optimum for the formation of
-crystals, there is a different optimum for their rapid
-extension.</p>
-
-<p><i>The Metastable and Labile Zones.</i>—This phenomena
-is general. There is for each substance a set of
-conditions (temperature, degree of concentration,
-volume of the solution) in which the crystalline
-individuals can be produced only by germs or by
-filiation. This is what occurs for betol above the
-temperature of 30°. The body is then in what
-Ostwald has called a <i>metastable</i> zone. There is,
-however, for the same body another set of circum<span class="pagenum" id="Page_302">[Pg 302]</span>stances
-more or less complete, in which its gems
-appear simultaneously. This is what happens for
-betol at about the temperature of 10°. These circumstances
-are those of the <i>labile zone</i> or zone of
-spontaneous generation.</p>
-
-<p><i>Crystals of Glycerine.</i>—We may go a step further.
-Let us suppose, with L. Errera, that we have a liquid
-in a state of metastable equilibrium, whose labile
-equilibrium is as yet unknown. This is what actually
-occurs for a very widely known body, glycerine.
-We do not know under what conditions glycerine
-crystallizes spontaneously. If we cool it, it becomes
-viscous; we cannot obtain its crystals in that way.
-It was not found in crystals until 1867. In that
-year, in a cask sent from Vienna to London during
-winter, crystallised glycerine was found, and Crookes
-showed these crystals to the Chemical Society of
-London. What circumstances had determined their
-formation? We knew not then, and we know not
-now. It may be observed that this case of spontaneous
-generation of the crystals of glycerine has
-not remained the solitary instance. M. Henninger
-has noted the accidental formation of glycerine
-crystals in a manufactory in St. Denis.</p>
-
-<p>It may be remarked that this crystalline species
-appeared, as living species may have done, at a given
-moment in an environment in which a favourable
-chance combined the necessary conditions for its
-production. It is also quite comparable to the
-creation of a living species; for having once appeared
-we have been able to perpetuate it. The crystalline
-individuals of 1867 have had a posterity. They
-have been sown in glycerine in a state of superfusion,
-and there they reproduced themselves. These<span class="pagenum" id="Page_303">[Pg 303]</span>
-generations have been sufficiently numerous to
-spread the species throughout a great part of
-Europe. M. Hoogewerf showed a great flask full
-to the Dutch biologists who met at Utrecht in
-1891. M. L. Errera presented others in June 1899,
-to the Society of Medical and Natural Sciences at
-Brussels. To-day the great manufactory of Sarg &amp;
-Co., of Vienna, is engaged in their production on a
-large scale for industrial purposes.</p>
-
-<p>Thus we are able to study this crystalline species
-of glycerine and to determine with precision the
-conditions of its continued existence. It has been
-shown that it does not resist a temperature of 18°, so
-that if precautions were not taken to preserve it,
-a single summer would suffice to annihilate all the
-crystalline individuals existing on the surface of the
-globe, and thus the species would be extinguished.</p>
-
-<p><i>Possible Extinction of a Crystalline Species.</i>—As
-these crystals melt at 18°, this temperature represents
-the point of fusion of solid glycerine or the point of
-solidification of liquid glycerine. But the liquor
-does not solidify at all if its temperature falls below
-18° C., as we well know, for it is at that temperature
-we use it. Nor does it solidify at zero, nor even at
-18° below zero; at 20°, for instance, it merely thickens
-and becomes pasty. We only know glycerine, then, in
-a state of superfusion, a fact which chemists have not
-learned without amazement. Under these conditions,
-so analogous to the appearance of a living species, to
-its unlimited propagation and to its extinction, the
-mineral world offers a quite faithful counterpart to
-the animal world. The living body illustrates here
-the history of the brute body and facilitates its
-exposition. Inversely, the brute body in its turn<span class="pagenum" id="Page_304">[Pg 304]</span>
-throws remarkable light on the subject of the living
-body, and on one of the most serious problems
-relative to its origin, that of spontaneous generation.</p>
-
-<p><i>Conclusion.</i>—These facts lead to one conclusion.
-Until the concourse of propitious circumstances
-favourable to their spontaneous generation was
-brought about, crystals were obtained only by
-filiation. Until the discovery of electro-magnetism,
-magnets were made only by filiation, by means of
-the simple or double application of a pre-existing
-magnet. Before the discovery which fable attributes
-to Prometheus, every new fire was produced only by
-means of a spark from a pre-existing fire. We are
-at the same historical stage as regards the living
-world, and that is why, up to the present, there has
-never been formed a single particle of living matter
-except by filiation, except by the intervention of a
-pre-existing living organism.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_305">[Pg 305]</span></p>
-
-<h2 class="nobreak" id="BOOK_V">BOOK V.<br />
-
-
-<small>SENESCENCE AND DEATH.</small></h2></div>
-
-
-<p class="prel">Chap. I. The different points of view from which death may be
-regarded.—Chap. II. Constitution of the organisms—Partial
-death—Collective death.—Chap. III. Physical
-and chemical characteristics of cellular death—Necrobiosis.—
-Chap. IV. Apparent perennity of complex individuals.—Chap. V.
-Immortality of the protozoa and of slightly
-differentiated cells.</p>
-
-
-
-<p>We grow old and we die. We see the beings
-which surround us grow old and disappear. At first
-we see no exceptions to this inexorable law, and we
-consider it as a universal and inevitable law of
-nature. But is this generalization well founded?
-Is it true that no being can escape the cruel fate of
-old age and death, to which we and all the representatives
-of the higher animality are exposed? Or,
-on the other hand, are any beings immortal? Biology
-answers that, in fact, some beings are immortal.
-There are beings to whose life no law assigns a
-limit, and they are the simplest, the least differentiated
-and the least perfect. Death thus appears to be a
-singular privilege attached to organic superiority, the
-ransom paid for a masterly complexity. Above these
-elementary, monocellular, undifferentiated beings,
-which are protected from mortality, we find others,
-higher in their organization, which are exposed to<span class="pagenum" id="Page_306">[Pg 306]</span>
-it, but with whom death seems but an accident,
-avoidable in principle if not in fact. The anatomical
-elements of this higher animal are a case in point.
-Flourens once tried to persuade us that the threshold
-of old age might be made to recede considerably, and
-there are biologists in the present day who give us
-some glimpse of a kind of vague immortality. We
-may, therefore, ask our readers to follow us in our
-examination of these re-opened if not novel questions,
-and we shall explain the views of contemporary
-physiology as to the nature of death, its causes, its
-mechanisms, and its signs.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_307">[Pg 307]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_I_5">CHAPTER I.<br />
-
-<small>VARIOUS WAYS OF REGARDING DEATH.</small></h3></div>
-
-
-<p class="prel">Different meanings of the word death—Physiological distinction
-between elementary and general death—Non-scientific
-opinions—The ordinary point of view—Medical point of
-view.—The signs of death are prognostic signs.</p>
-
-
-<p><i>Different Meanings of the Word Death.</i>—An English
-philosopher has asserted that the word we translate
-by “cause” has no less than sixty-four different meanings
-in Plato and forty-eight in Aristotle. The word
-“death” has not so many meanings in modern
-languages, but still it has many. Sometimes it
-indicates an action which is taking place, the action
-of dying, and sometimes a state, the state which
-succeeds the action of dying. The phenomena it
-connotes are in the eyes of many biologists quite
-different, according as we watch them in an animal
-of complex organization, or on the other hand, in
-monocellular beings, protozoa and protophytes.</p>
-
-<p><i>Physiological Distinction between Elementary Death
-and General Death.</i>—We distinguish the death of the
-anatomical elements, <i>elementary death</i>, from the
-death of the individual regarded as a whole, <i>general
-death</i>. Hence we recognize an <i>apparent death</i>, which
-is an incomplete and temporary suspension of the
-phenomena of vitality, and a <i>real death</i>, which is a
-final and total arrest of these phenomena. When<span class="pagenum" id="Page_308">[Pg 308]</span>
-we consider it in its essential nature (assumed, but
-not known) we look on it as the <i>contrary of life</i>, as
-did the Encyclopædia, Cuvier, and Bichat; or we
-regard it with others either as the consequence of
-life, or simply as the end of life.</p>
-
-<p><i>Non-scientific Opinions.</i>—What is death to those
-outside the realm of science? First of all we find the
-consoling solution given by those who believe death
-to be the commencement of another life. We next
-find ourselves involved in a confused medley, an
-infinite diversity of philosophical doubt and superstition.
-“A leap into the unknown,” says one.
-“Dreamless and unconscious night,” says another.
-And again, “A sleep which knows no waking.”
-Or, with Horace, “the eternal exile,” or with
-Seneca, annihilation. <i>Post mortem nihil; ipsaque
-mors nihil.</i></p>
-
-<p>The idea which is constantly supervening in the
-midst of this conflict of opinion is that of the
-<i>breaking up</i> of the elements, the union of which
-forms the living being. It has, as we shall see, a
-real foundation which may perhaps receive the
-support of science. We shall not find that the best
-way of defining death is to say that it consists of the
-“dissolution of the society formed by the anatomical
-elements, or again, in the dissolution of the consciousness
-that the individual possesses of himself—<i>i.e.</i>, of
-the existence of this society.” It is the rupture of
-the social bond. The old idea of dispersion is a
-variant of the same notion. But the ancients
-evidently could not understand, as we do, the nature
-of these elements which are associated to form the
-living being, and which are liberated or dispersed
-by death. We, as biologists, can see microscopical<span class="pagenum" id="Page_309">[Pg 309]</span>
-organic unity with a real objective existence. The
-ancients were thinking of spiritual elements, of
-principles, of entities. To the Romans, who may be
-said to have held that there are three souls, death
-was produced by their separation from the body.
-The first, the breath, the <i>spiritus</i>, mounting towards
-celestial regions (<i>astra petit</i>); the second, the <i>shade</i>,
-regaining on the surface of the earth and wandering
-around the tombs; the third, the <i>manes</i>, descending
-to the lower regions. The belief of the Hindoos was
-slightly different. The body returned to the earth,
-the breath to the winds, the fire of the glance to the
-sun, and the ethereal soul to the world of the pure.
-Such were the ideas of mortal dispersion formed by
-ancient humanity.</p>
-
-<p>Modern science takes a more objective point of
-view. It asks by what facts, by what observable
-events death is indicated. Generally speaking, we
-may say that these facts interrupt an interior state
-of things which was life and to which they put an
-end. Thus death is defined by life. It is the
-cessation of the events and of the phenomena which
-characterize life. We must, therefore, know what
-life is to understand the meaning of death. How
-wise was Confucius when he said to his disciple,
-Li-Kou:—“If we do not know life, how can we
-know death?” According to biology there are two
-kinds of death because there are two kinds of life;
-elementary life and death correspond just as general
-life and death do, and this is where scientific opinion
-diverges from commonly received opinion.</p>
-
-<p>What cares the man who reasons as most human
-beings do, about this life of the anatomical elements
-of his body, the existence and the silent activity of<span class="pagenum" id="Page_310">[Pg 310]</span>
-which are in no way revealed to him. What does
-their death matter to him? To him there is but one
-poignant question, that of being separated or not
-being separated from the society of his fellows.
-Death is no longer to feel, no longer to think; it is
-the assurance that one will never feel, one will never
-think again. Sleep, dreamless sleep, is already in our
-eyes a kind of transient death; but, when we fall asleep
-we are sure of waking again. There is no awaking
-from the sleep of death. But that is not all. Man
-knows that death, this dreamless sleep that knows no
-waking, will be followed by the dissolution of his
-body. And what a dissolution will there be for the
-body, the object of his continual care! Remember
-the description of Cuvier—the flesh that passes from
-green to blue and from blue to black, the part which
-flows away in putrid venom, the other part which
-evaporates in foul emanations, and finally, the few
-ashes that remain, the tiny pinch of minerals, saline
-or earthy, which are all that is left of that once
-animated masterpiece.</p>
-
-<p><i>The Popular View.</i>—To the man afraid of death
-it seems, in the presence of so great a catastrophe,
-that the patient analysis of the physiologist scrupulously
-noting the succession of phenomena and explaining
-their sequence is uninteresting. He will
-only attach the slightest importance to knowing that
-vestiges of vitality remain in this or that part of his
-body, if they do not re-establish in every part the
-<i>status quo ante</i>. He cares not to hear that a certain
-time after the formal declaration of his death his
-nails and his hair will continue to grow, that his
-muscles will still have the useless faculty of contraction,
-that every organ, every tissue, every element,<span class="pagenum" id="Page_311">[Pg 311]</span>
-will oppose a more or less prolonged resistance to the
-invasion of death.</p>
-
-<p><i>Medical View.</i>—It is, however, these very facts and
-details, this why and wherefore, which interest the
-physiologist. The state of mind of the doctor in this
-respect, again, is different. When, for instance, the
-doctor declares that such and such a person is dead,
-he is really making not so much a statement of fact
-as a prediction. How many elements are still living
-and will be capable of new birth in this corpse that
-he has before his eyes? That is not what he asks
-himself, nor is it what we should ask of him. He
-knows, besides, that all these partial survivals will be
-extinguished and will never find the conditions
-necessary to reviviscence, and that the organization
-will never be restored to its primal activity; and this
-is what he affirms. The fear of premature burial
-which haunts so many imaginations is the fear of an
-error in the prediction. It is to avoid this that
-practical medicine has devoted so much of its
-attention to the discovery of a <i>certain</i>—and early—sign
-of death. By this we understand the discovery
-of a <i>certain prognostic sign of general death</i>. We
-want a prognostic sign enabling us to assert that the
-life of the brain is now extinguished and will never
-be reanimated. And yet there are in that organism
-many elements which are still alive. Many others
-even may be born anew if we could give them
-suitable conditions which they no longer meet with
-in the animal machine now thrown out of gear.
-What finer example could we give than the experiment
-of Kuliabko, the Russian physiologist, who
-kept a man’s heart working and beating for eighteen
-hours after the official verification of his death.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_312">[Pg 312]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_II_5">CHAPTER II.<br />
-
-<small>THE PROCESS OF DEATH.</small></h3></div>
-
-
-<p class="prel">Constitution of organisms.—Partial lives.—Collective life.—The
-rôle of apparatus.—Death by lesion of the major apparatus.—The
-vital tripod.—Solidarity of the anatomical
-elements.—Humoral solidarity.—Nervous solidarity.—Independence
-and subordination of the anatomical elements.</p>
-
-
-<p><i>Partial Lives.</i> <i>Collective Life.</i>—With the exception
-of the physiologist, no one, neither he who is ignorant
-nor he who is intellectual, nor even the doctor,
-troubles his head about the life or the death of the
-element, although this is the basis, the real foundation,
-of the activity manifested by the social body
-and by its different organs. The life of the individual,
-of the animal, depends on these elementary
-partial lives just as the existence of the State depends
-upon that of its citizens. To the physiologist, the
-organism is a federation of cellular elements unified
-by close association. Goethe compared them to a
-“multitude”; Kant to a “nation”; and others have
-likened them to a populous city the anatomical
-elements of which are the citizens, and which possesses
-an individuality of its own. So that the
-activity of the federated organism may be discussed
-in each of its parts, and then it is <i>elementary life</i>, or
-in its totality, and then it is <i>general life</i>. Paracelsus
-and Bordeu had a glimpse of this truth when they
-considered a life appropriate to each part (<i>vita propria</i>)<span class="pagenum" id="Page_313">[Pg 313]</span>
-and a collective life, the life of the whole (<i>vita
-communis</i>). In the same way we must distinguish
-the <i>elementary death</i>, which is the cessation of the
-vital phenomena in the isolated cell, from the <i>general
-death</i>, which is the disappearance of the phenomena
-which characterised the collectivity, the totality, the
-federation, the nation, the city, the whole in so far as
-it is a unit.</p>
-
-<p>These comparisons enable us to understand how
-general life depends on the partial lives of each
-anatomical citizen. If all die, the nation, the federation,
-the total being clearly ceases to exist. This
-city has an enormous population—there are thirty
-trillion cellules in the body of man; it is peopled
-with absolutely sedentary citizens, each of which has
-its fixed place, which it never leaves, and in which it
-lives and dies. It must possess a system of more or
-less perfect arrangements to secure the material life
-of each inhabitant. All have analogous requirements:
-they feed very much the same; they breathe
-in the same way; each in fact has its profession,
-industry, talents, and aptitudes by which it contributes
-to social life, and on which, in its turn, it
-depends. But the process of alimentation is the
-same for all. They must have water, nitrogenous
-materials and analogous ternaries; the same mineral
-substances, and the same vital gas, oxygen. It is no
-less necessary that the wastes and the egesta, very
-much alike in every respect, should be carried off and
-borne away in discharges arranged so as to free the
-whole system from the inconvenience, the unhealthiness,
-and the danger of these residues.</p>
-
-<p><i>Secondary Organization in Organs.</i>—That is why,
-as we said above, the secondary organizations of the<span class="pagenum" id="Page_314">[Pg 314]</span>
-economy exist:—the digestive apparatus which prepares
-the food and enables it to pass into the blood,
-into the lymph, and finally into the liquid medium
-which bathes each cell and constitutes its real
-medium; the respiratory apparatus which imports
-the oxygen and exports the gaseous excrement,
-carbonic acid; the heart and the circulatory system
-which distributes through the system the internal
-medium, suitably purified and recuperated. The
-organization is dominated by the necessities of
-cellular life. This is the law of the city, to which
-Claude Bernard has given the name of the <i>law of the
-constitution of organisms</i>.</p>
-
-<p><i>Death by Lesion of the Major Organs. Vital
-Tripod.</i>—Thus we understand what life is, and at the
-same time what is the death of a complex living
-being. The city perishes if its more or less complicated
-mechanisms which look after its revictualling
-and its discharge are seriously affected at any point.
-The different groups may survive for a more or less
-lengthy period, but progressively deprived of the
-means of food or of discharge, they are finally
-involved in the general ruin. If the heart stops,
-there is a universal famine; if the lungs are seriously
-injured, we are asphyxiated; if the principal organ
-of discharge, the kidney, ceases to perform its allotted
-task, there is a general poisoning by the used-up and
-toxic materials retained in the blood.</p>
-
-<p>We understand how the integrity of the major
-organs,—the heart, the lungs, the kidney,—is indispensable
-to the maintenance of existence. We
-understand that their lesion, by a series of successive
-repercussions, involves universal death. We always
-die, said the doctors of old, because of the failure of<span class="pagenum" id="Page_315">[Pg 315]</span>
-one of these three organs, the heart, the lungs, or the
-brain. Life, they said in their inaccurate language,
-depends upon these as upon three supports. Hence
-the idea of the <i>vital tripod</i>. But it is not only this
-trio of organs which maintain the organism; the
-kidney and the liver are no less important. In
-different degrees each part exercises its action on the
-rest. Life is based in reality on the immense
-multitude of living cells associated for the formation
-of the body; on the thirty trillion anatomical elements,
-each part is more or less necessary to all the
-rest, according as the bond of solidarity is drawn more
-or less closely in the organism under consideration.</p>
-
-<p><i>Death and the Brain.</i>—There are indeed more noble
-elements charged with higher functions than the rest.
-These are the nervous elements. Those of the brain
-preside over the higher functions of animality, sensibility,
-voluntary movement, and the exercise of the
-intellect. The rest of the nervous system forms an
-instrument of centralization which establishes the
-relations of the parts one with the other and secures
-their solidarity. When the brain is stricken and its
-functions cease, man has lost the consciousness of his
-existence. Life seems to have disappeared. We say
-of a man in this plight that he no longer lives, thus
-confusing general life with the cerebral life which is
-its highest manifestation. But the man or the
-animal without a brain lives what may be called a
-vegetative life. The human anencephalic foetus lives
-for some time, just as the foetus which is properly
-formed. Observation always shows that this existence
-of the other parts of the body cannot be sustained
-indefinitely in the absence of that of the brain.
-By a series of impulses due to the solidarity of the<span class="pagenum" id="Page_316">[Pg 316]</span>
-grouping of the parts, the injury received by the
-brain affects by repercussion the other organs, and
-leads in the long run to the arrest of elementary life
-in all the anatomical elements. The death of the
-whole is then complete.</p>
-
-<p>Doctors have therefore a two-fold reason for saying
-that the brain may cause death. The death of the
-brain suppresses the highest manifestation of life, and,
-in the second place, by a more or less remote counter
-stroke, it suppresses life in all the rest of the system.</p>
-
-<p><i>Death is a Process.</i>—Besides, the fact is general.
-The death of one part always involves the death of
-the rest—<i>i.e.</i>, universal death. A living organism
-cannot be at the same time alive and a cemetery. The
-corpses cannot exist side by side with the living
-elements. The dead contaminates the living, or in
-some other way involves it in its ruin. Death is
-propagated; it is a progressive phenomenon which
-begins at one point and gradually is extended to the
-whole. It has a beginning and a duration. In other
-words, the death of a complex organism is a process.
-And further, the end of a simple organism, of a
-protozoan, of a cell, is itself a process infinitely
-more shortened.</p>
-
-<p>The very perfection of the organism is therefore the
-cause of its fragility. It is the degree of solidarity of
-the parts one with another which involves the one set
-in the catastrophe of the rest, just as in a delicate
-piece of mechanism the derangement of a wheel brings
-nearer and nearer the total breakdown. The important
-parts, the lungs, the heart, the brain, suffer no
-serious alteration without the reflex being felt throughout.
-But there are also wheels less evident, the
-integrity of which is scarcely less necessary.</p>
-
-<p><span class="pagenum" id="Page_317">[Pg 317]</span></p>
-
-<p><i>The Solidarity of the Anatomical Elements.</i>—The
-cause of the mortal process—<i>i.e.</i>, of the extension and
-the propagation of an initial destruction—is therefore
-to be found in the solidarity of the parts of the
-organism. The closer it is the greater do the chances
-of destruction become, for the accident which has
-happened to one will by repercussions affect the
-others.</p>
-
-<p>Now the solidarity of the parts of the organism
-may be carried out in two ways; there is a <i>humoral
-solidarity</i> and a <i>nervous solidarity</i>.</p>
-
-<p><i>Humoral Solidarity.</i>—Humoral solidarity is realized
-by the mixture of humours. All the liquids of the
-organism which have lodged in the interstices of the
-elements and which soak the tissues, are in contact
-and in relation of exchange one with another, and
-through the permeable wall of the small vessels they
-are in relation with the blood and the lymph.</p>
-
-<p>All the liquid atmospheres which surround the
-cells and form their ambient medium have intercommunication.
-A change having taken place in one
-cellular group, and therefore in the corresponding
-liquid, modifies the medium of the further or nearer
-groups, and therefore these groups themselves.</p>
-
-<p><i>Nervous Solidarity.</i>—But the real instrument of the
-solidarity of the part is the nervous system. Thanks
-to it in the living machine the component activities of
-the cellular multitude restrain and control one another.
-Nervous solidarity makes of the complex being not a
-mob of cells, but a connected system, an individual in
-which the parts are subordinated to the whole and the
-whole to the parts; in which the social organism has
-its rights just as the individual has his rights. The
-whole secret of the vital functional activity of the<span class="pagenum" id="Page_318">[Pg 318]</span>
-complex being is contained in these two factors:—the
-independence and the subordination of the elementary
-lives. General life is the harmony of the elementary
-lives, their symphony.</p>
-
-<p><i>Independence and Subordination of the Anatomical
-Elements.</i>—The independence of the anatomical elements
-results from the fact that they are the real
-depositaries of the vital properties, the really active
-components. On the other hand the subordination of
-the parts to the whole is the very condition of the
-preservation of form in animals and plants. The
-architecture which is characteristic of them, the
-morphological plan which they realize in their
-evolutive development which they are ever preserving
-and repairing, form a striking proof of this. This
-dependence in no way contradicts the autonomy of
-the elements. For when with Claude Bernard and
-Virchow we study the circumstances we see that
-the element accommodates itself to the organic
-plan without violence to its nature. It behaves
-in its natural place as it would behave elsewhere,
-if elsewhere it were to meet around it the
-same liquid medium which at once is a stimulant
-and a food. This at least is the conclusion we
-may draw from experiments on transplanting, or
-on animal and vegetable grafting. Neither the
-neighbouring elements, nor the whole system act on it
-at a distance by a kind of mysterious induction,
-according to the ideas of the vitalists, in order to
-regulate the activity of the element. They contribute
-solely to the composition of the liquid atmosphere
-which bathes it. They intervene in order to provide
-it with a certain environment whose very characteristic
-physical and chemical constitution regulates its<span class="pagenum" id="Page_319">[Pg 319]</span>
-activity. This constitution may be some day imitated
-by the devices of experiment. When that result is
-achieved the anatomical element will live in isolation
-exactly as it lives in the organic association, and the
-mysterious bond which causes its solidarity with the
-rest of the economy will become intelligible. In fact,
-we may defer more or less the maturity of this
-prophecy, but there is no doubt that we are daily
-nearing its fulfilment.</p>
-
-<p>The general life of the complex being is therefore
-the more or less perfect synergy, the <i>ordered process</i> of
-elementary lives. General death is the destruction of
-these partial lives. The nervous system, the instrument
-of this harmony of the parts, represents the
-social bond. It keeps most of the partial elements
-under its sway, and is thus the intermediary of their
-relations. The closer this dependence, the higher the
-development of the nervous apparatus, and the better,
-also, is assured the universal solidarity and therefore
-the unity of the organism. Cellular federation
-assumes the characteristic of a unique individuality
-in proportion to the development of this nervous
-centralization. With an ideal perfect nervous system
-the correlation of the parts would also attain perfection.
-As Cuvier said: “None could experience
-change without a change in the rest.”</p>
-
-<p>But no animal possesses this extreme solidarity of
-the parts of the living economy. It is a philosopher’s
-dream. It is the dream of Kant, to whom the perfect
-organism would be “a teleological system,” a system
-of reciprocal ends and means, a sum total of parts
-each existing for and by the rest, for and by the
-whole. An organism so completely connected would
-be unlikely to live. In fact, living organisms show a<span class="pagenum" id="Page_320">[Pg 320]</span>
-little more freedom in the interplay of their parts.
-Their nervous apparatus fortunately does not attain
-this imaginary perfection; their unity is not so
-rigorous. The idea of individuality, of individual
-existence, is therefore not absolute but relative.
-There are all degrees of it according to the development
-of the nervous system. What the man in the
-street and the doctor himself understand by death is
-the situation created by the stopping of the general
-wheels, the brain, the heart, and the lungs. If the
-breath leaves no trace on the glass held to the mouth,
-if the beating of the heart is no longer perceptible by
-the hand which touches or the ear which listens, if the
-movement and the reaction of sensitiveness have
-ceased to be manifest, these signs make us conclude
-that it is death. But this conclusion, as we have said
-before, is a prognostic rather than a judgment of fact.
-It expresses the belief that the subject will certainly
-die, and not that it is from this moment dead. To
-the physiologist the subject is only on the way to die.
-The process has started. The only real death is
-when the universal death of all the elements has been
-consummated.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_321">[Pg 321]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_III_5">CHAPTER III.<br />
-
-<small>PHYSICAL AND CHEMICAL CHARACTERS OF CELLULAR
-DEATH. NECROBIOSIS. GROWING OLD.</small></h3></div>
-
-
-<p class="prel">Characteristic of elementary life—Changes produced by death
-in the composition and the death of the cell—Schlemm;
-Loew; Bokorny; Pflüger; A. Gautier; Duclaux—The
-processive character of death—Accidental death—Necrobiosis—Atrophy—Degeneration—So-called
-natural death—Senescence—Metchnikoff’s
-theory of senescence—Objections.</p>
-
-
-<p>Elementary death is nothing but the suppression
-in the anatomical elements of all the phenomena of
-vitality.</p>
-
-<p><i>Characteristics of Elementary Life.</i>—The characteristic
-features of elementary life have been
-sufficiently fixed by science. First of all, there is
-<i>morphological unity</i>. All the living elements have an
-identical morphological composition. That is to say
-that life is only accomplished and sustained in all its
-fulness in organic units possessing the anatomical
-constitution of the cell, with its cytoplasm and its
-nucleus, constituted on the classical type. In the
-second place, there is <i>chemical unity</i>. The constituent
-matter, the matter of which the cell is built up, diverges
-but little from a chemical type—a proteid complex,
-with a hexonic nucleus, and from a physical model
-which is an emulsion of granulous, immiscible liquids,
-of different viscosities. The third character consists in<span class="pagenum" id="Page_322">[Pg 322]</span>
-the possession of a <i>specific form</i> acquired, preserved,
-and repaired by the element. The fourth character,
-and perhaps the most essential of all, is <i>the property
-of growth</i> or <i>nutrition</i> with its consequence, namely, a
-relation of exchanges with the external medium,
-exchanges in which oxygen plays considerable part.
-Finally, there is a last property, that of <i>reproduction</i>,
-which in a certain measure is a necessary consequence
-of the preceding,—<i>i.e.</i>, of growth.</p>
-
-<p>These five vital characters of the elements are most
-in evidence in cells living in isolation, in microscopical
-beings formed of a single cell, protophytes and
-protozoa. But we find them also in the associations
-formed by the cells among one another—<i>i.e.</i>, in
-ordinary plants and animals, multicellular complexes,
-called for this reason metaphytes and metazoa. Free
-or associated, the anatomical elements behave in the
-same way—feed, grow, breathe, digest in the same
-manner. As a matter of fact, the grouping of the
-cells, the relations, proximity and contiguity, which
-they assume, introduce some variants into the expression
-of the common phenomena; but these slight
-differences cannot disguise the essential community
-of the vital processes.</p>
-
-<p>The majority of physiologists, following Claude
-Bernard, admit as valent and convincing the proof that
-the illustrious experimenter furnished of this unity
-of the vital processes. There are, however, a few
-voices crying in the wilderness. M. Le Dantec is one.
-In his new theory of life he amplifies and exalts the
-differences which exist between the elementary life of
-the proteids and the associated life of the metazoa.
-In them he can see nothing but contrasts and
-deviations.</p>
-
-<p><span class="pagenum" id="Page_323">[Pg 323]</span></p>
-
-<p>If this is elementary life, let us ask what is
-<i>elementary death</i>—<i>i.e.</i>, the death of the cell. And in
-this connection let us ask the questions which we have
-to examine in the case of animals high in organization,
-and of man himself. What are the characteristics
-of elementary death? When the cell dies, is its death
-preceded by a growing old or senescence? What are
-the preliminary signs and the acknowledged symptoms?</p>
-
-<p><i>Changes Produced by Death.</i>—The state of death is
-only truly realized when the fundamental properties
-of living matter enumerated above have entirely
-disappeared. We must follow step by step this disappearance
-in all the anatomical elements of the
-metazoan.</p>
-
-<p>Now the properties of the cell are connected with
-the physical and chemical organization of living
-matter. For them to disappear entirely, this organization
-must be destroyed as far as all that is essential
-in it is concerned. We cannot admit with the
-vitalists that there is any material difference between
-the dead and the living, and that only an immaterial
-principle which has escaped into the air distinguishes
-the corpse from the animated being. In fact, the
-external configuration may be almost preserved, and
-the corpse may bear the aspect and the forms of the
-preceding state. But this appearance is deceptive.
-Something in reality has changed. The structure,
-the chemical composition of the living substance,
-have undergone essential changes. What are these
-changes?</p>
-
-<p><i>Physical Changes.</i>—Certain physiologists have
-endeavoured to determine them. Klemm, a botanist,
-pointed out in 1895 the physical changes which
-characterize the death of vegetable cells—loss of<span class="pagenum" id="Page_324">[Pg 324]</span>
-turgescence, fragmentation of the protoplasm, the
-formation of granules, and the appearance of vacuoles.</p>
-
-<p><i>Chemical Changes.</i>—O. Loew and Bokorny laid
-great stress in 1886 and 1896 on the chemical changes.
-The living protoplasm according to them is an
-unstable proteid compound. A slight change would
-detach from the albuminoid molecule a nucleus with
-the function of aldehyde, and at the same time would
-transform an amido-group into an amido-group. This
-would suffice for the transition of the protoplasm from
-the living to the dead state. This theory is based on
-the fact that the compounds which exercise a toxic
-action on the living cell, without acting chemically on
-the dead albumin, are easily fixed by the aldehydes;
-and on the fact that many of them, which attack
-simultaneously the living albuminoids and the dead
-albumin, easily combine with the amido-group.</p>
-
-<p>E. Pflüger, a celebrated German scientist, has
-considered living matter as an albumin spontaneously
-decomposable, the essential nucleus of which is formed
-by cyanogen. Its active instability would be due to
-the penetration into the molecule of the oxygen which
-fixes on the carbon and separates it from the nitrogen.
-Armand Gautier has not confirmed this view.
-Duclaux (1898) has stated that the difference between
-the living and the dead albumin would be of a stereochemical
-order.</p>
-
-<p><i>Progressive Character of Death. Accidental Death.</i>—We
-have seen that in general the disappearance of
-the characteristics of vitality is not instantaneous, at
-least in the natural course of things, in complex organisms.
-It is the end of a more or less rapid process. But
-death is not instantaneous in the isolated anatomical
-element any more than it is in the protozoan or<span class="pagenum" id="Page_325">[Pg 325]</span>
-protophyte. We must have recourse to very violent
-devices of destruction to kill the cell at a blow, to
-leave absolutely nothing of its organization existing.
-The protoplasm of yeast when violently crushed by
-Büchner still possessed the power of secreting soluble
-ferments. A powerful action, a very high temperature,
-is necessary to obtain the result. <i>A fortiori</i>,
-the difficulty increases in the case of complex organisms,
-all of whose living elements cannot be attacked
-at the same moment by the destructive cause. A
-mechanical action, capable of destroying at one blow
-all the living parts of a complex being, of an animal,
-of a plant, must be of almost inconceivable power.
-The blow of a Nasmyth hammer would not be strong
-enough.</p>
-
-<p>The chemical alteration produced by a very toxic
-substance distributed throughout the blood, and thus
-brought into contact with each element, would produce
-a disorganization which, however rapid it were, could
-not be called instantaneous. And the same holds
-good of physical agents.</p>
-
-<p>But these are not the processes of nature under
-normal circumstances. They are accidents or devices.
-We shall leave on one side their consideration and
-we shall only deal here with the natural processes of
-the organism.</p>
-
-<p>Imagine it placed in a medium appropriate to its
-needs and following out without intervening complications
-the evolution assigned to it by its
-constitution. Experiment tells us that this natural
-evolution in every case known to us ends in death.
-Death supervenes sooner or later. For beings higher
-in organization, which we can bring into closer and
-closer resemblance to man, we find that they die of<span class="pagenum" id="Page_326">[Pg 326]</span>
-disease, by accident, or of old age. And as disease
-is an accident, we may naturally ask if what we call
-old age is not also a disease.</p>
-
-<p>However that may be, the mortal process, being
-never instantaneous, has a duration, a beginning, a
-development, an end—in a word, a history. It
-constitutes an intermediary phase between perfect
-life and certain death.</p>
-
-<p><i>Necrobiosis.</i> <i>Atrophy.</i> <i>Degeneration.</i>—The process
-according to the circumstances may be shortened or
-prolonged. When death is the result of violence
-events are precipitated. The physical and chemical
-transformations of the living matter constitute a kind
-of acute alteration called by Schultze and Virchow
-<i>necrobiosis</i>. According to the pathologists, there are
-two kinds of <i>necrobiosis</i>:—that by <i>destruction</i>, by
-<i>simple atrophy</i>, which causes the anatomical elements
-to disappear gradually without undergoing appreciable
-modifications; and <i>necrobiosis by degeneration</i>,
-which transforms the protoplasm into fatty matter
-into calcareous matter, into granulations (fatty degeneration,
-calcification, granulous degeneration).
-There is no disagreement as to the causes of this
-necrobiosis. They are always accidental; they
-originate in external circumstances:—the insufficiency
-of the alimentary materials, of water, of oxygen; the
-presence in the medium of real poisons destroying
-the organized matter; the violent intervention of
-physical agents, heat, electricity; the reflex on the
-composition of the cellular atmosphere of a violent
-attack on some essential organ, the heart, the lungs,
-the kidneys.</p>
-
-<p><i>Senescence.</i> <i>Old Age.</i>—In a second category we
-must place the mortal processes, slow in their move<span class="pagenum" id="Page_327">[Pg 327]</span>ment,
-in which we cannot see the intervention of
-clearly accidental and abnormal disturbing agents.
-Death appears to be the termination of a breaking-up
-proceeding by insensible degrees in consequence of the
-progressive accumulation of very small inappreciable
-perturbations. This slow breaking up is adequately
-expressed by the term—growing old, or senescence.
-The alterations by which it is betrayed in the cell are
-especially <i>atrophic</i>, but they are also accompanied,
-however, by different forms of degeneration. An
-extremely important question arises on this subject,
-and that is whether the phenomena of senility have
-their cause in the cell itself, if they are inevitably
-found in its organization, and therefore if old age and
-death are natural and necessary phenomena. Or, on
-the other hand, should we consider them as due to a
-progressive alteration of the medium, the character of
-which would be accidental although frequent or
-habitual? This, in a word, is the problem which has
-so often engaged the attention of philosophical
-biologists. Are old age and death natural and
-inevitable phenomena?</p>
-
-<p>The recent experiments of Loeb and Calkins, and
-all similar observations, tend to attribute to the
-phenomenon of growing old the character of a
-remediable accident. But the remedy has not been
-found, and the animal finally succumbs to these slow
-transformations of its anatomical elements. We then
-say that it <i>dies of old age</i>.</p>
-
-<p><i>Metchnikoff’s Theory of Senescence. Objections.</i>—Metchnikoff
-has proposed a theory of the mechanism
-of this general senescence. The elements of the
-conjunctive tissue, phagocytes, macrophages, which
-exist everywhere around the specialized and higher<span class="pagenum" id="Page_328">[Pg 328]</span>
-anatomical elements would destroy and devour them
-as soon as their vitality diminishes, and would take
-their place. In the brain, for example, it would be
-the phagocytes which, attacking the nervous cellules,
-would disorganize the higher elements, incapable of
-defending themselves. This substitution of the conjunctive
-tissue, which only possesses vegetative properties
-of a low order, for the nervous tissues, which
-possesses very high vegetative properties, results in
-an evident breaking-up. The gross element of
-violent and energetic vitality stifles the refined and
-higher element.</p>
-
-<p>This expulsion is a very real fact. It constitutes
-what is called senile sclerosis. But the active <i>rôle</i>
-attributed to it by Metchnikoff in the process of
-degeneration is not so certain. An expert observer
-in the microscopic study of the nervous system, M.
-Marinesco, does not accept this interpretation as far
-as the senescence of the elements of the brain is concerned.
-Diminution of the cell, the decrease in the
-number of its stainable granulations, chromatolysis,
-the formation of inert, pigmented substances—all
-these phenomena which characterize the breaking-up
-of the cerebral cells would be accomplished, according
-to this observer, without the intervention of the
-conjunctive elements, the phagocytes.</p>
-
-<p>The characteristic of extensive and progressive
-process presented by death necessitates in a complex
-organism, which is a prey to it, the existence
-side by side of living and dead cells. Similarly, in
-the organism which is growing old, there are young
-elements and elements of every age side by side with
-senile elements. As long as the disorganization of
-the last has not gone too far, they may be rejuvenated.<span class="pagenum" id="Page_329">[Pg 329]</span>
-All we have to do is to restore to them an appropriate
-ambient medium. The whole question is one of
-knowing and being able to realize, for this or that
-part which we wish to reanimate and to rejuvenate,
-the very special or very delicate conditions that this
-medium must fulfil. As we have said, success is
-attained in this respect as far as the heart is concerned,
-and this is why we are able to reanimate and
-to revive the heart of a dead man. It is hoped that
-ideas along these lines will extend with the progress
-of physiology.</p>
-
-<p>After this sketch of the conditions and of the
-varieties of cellular death we must return to the
-essential problem which is engaging the curiosity of
-biologists and philosophers. Is death unavoidable,
-inevitable? Is it the necessary consequence of life
-itself, the inevitable issue, the inevitable end?</p>
-
-<p>There are two ways of endeavouring to solve this
-question of the inevitability of death. The first is to
-examine popular observation, practised, so to speak,
-unintelligently and without special precautions. The
-second is to analyze everything we know relative to
-the conditions of elementary life.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_330">[Pg 330]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_IV_5">CHAPTER IV.<br />
-
-<small>THE APPARENT PERENNITY OF COMPLEX
-INDIVIDUALS.</small></h3></div>
-
-
-<p class="prel">Millenary trees—Plants with a definite rhizome—Vegetables
-reproduced by cuttings—Animal colonies—Destruction due
-to extrinsic causes—Difficulty of interpretation.</p>
-
-
-<p>Popular opinion teaches us that living beings have
-only a transient existence, and as a poet has said:
-“Life is but a flash between two dark nights.” But,
-on the other hand, simple observation shows us, or
-appears to show us, beings whose duration of existence
-is far longer, and practically illimitable.</p>
-
-<p><i>Millenary Trees.</i>—We know of trees of venerable
-antiquity. Among these patriarchs of the vegetable
-world there is a chestnut tree on Mount Etna which
-is ten centuries old, and an ivy in Scotland which is
-said to be thirty centuries old. Trees of 5000 years
-old are not absolutely unknown. We may mention
-among those of that age the famous dragon tree<a id="FNanchor_21" href="#Footnote_21" class="fnanchor">[21]</a> at
-Orotava, in the island of Teneriffe. Two other
-examples are known in California—the pseudo-cedar,
-or <i>Tascodium</i>, at Sacramento, and a <i>Sequoïa gigantea</i>.
-We know that the olive tree may live 700 years.
-There are cedars 800 years old and oaks of the age of
-1,500 years.</p>
-
-<p><i>Plants with a Rhizome.</i>—Vegetable species of<span class="pagenum" id="Page_331">[Pg 331]</span>
-almost unlimited duration of life are known to
-botanists. Such, for instance, are plants with a
-definite rhizome, such as colchicum. Autumnal
-colchicum has a subterranean root, the bulb of
-which pushes out every year fresh axes for a new
-bloom; and as each of these new axes stretches out
-an almost constant length, a botanist once set himself
-the singular problem of discovering how long it would
-take such a foot, if suitably directed, to travel round
-the world.</p>
-
-<p><i>Vegetables Reproduced by Cuttings.</i>—Vegetables reproduced
-by slips furnish another example of living
-beings of indefinite duration. The weeping willows
-which adorn the banks of sheets of water in the parks
-and gardens throughout the whole of Europe have
-sprung, directly or indirectly, from slips of the first
-<i>Salix Babylonica</i> introduced to the West. May it not
-be said that they are the permanent fragments of that
-one and the same willow?</p>
-
-<p><i>Animal Colonies.</i>—These examples, as well as those
-furnished to zoologists by the consideration of the
-polypi which have produced by their slow growth the
-reefs, or <i>atolls</i>, of the Polynesian seas, do not, however,
-prove the perennity of living beings. The
-argument is valueless, for it is founded upon a confusion.
-It turns on the difficulty that biologists
-experience in defining the individual. The oak and
-the polypus are not simple individuals, but associations
-of individuals, or, to use Hegel’s expression,
-the nations of which we see the successive generations.
-We give to this succession of generations a
-unique existence, and our reasoning comes to this,
-that we confer on each present citizen of this social
-body the antiquity which belongs to the whole.</p>
-
-<p><span class="pagenum" id="Page_332">[Pg 332]</span></p>
-
-<p><i>Destruction of the Social Individual due to Extrinsic
-Causes.</i>—As for the destruction, the death of this
-social individual, of this hundred-year-old tree, it
-seems indeed that there is no ground for considering
-it a natural necessity. We find the sufficient reason
-of its usual end in the repercussion on the individual
-of external and contingent circumstances. The cause
-of the death of a tree, of an oak many centuries old,
-is to be found in the ambient conditions, and not in
-some internal condition. Cold and heat, damp and
-dryness, the weight of the snow, the mechanical
-action of the rain, of hail, of winds unchained, of
-lightning; the ravages of insects and parasites—these
-are what really work its ruin. And further,
-the new branches, appearing every year and increasing
-the load the trunk has to bear, increase the
-pressure of the parts, and make more difficult the
-motion of the sap. But for these obstacles, external,
-so to speak, to the vegetable being itself, it would
-continue indefinitely to bloom, to fructify, and as
-each spring returned to show fresh buds.</p>
-
-<p><i>Difficulty of Interpretation.</i>—In this as in all other
-examples we must know the nature of the beings that
-we see lasting on and braving the centuries. Is it the
-individual? Is it the species? Is it a living being,
-properly so called, having its unity and its individuality,
-or is it a series of generations succeeding
-one another in time and extending in space? In a
-word, the question is one of knowing if we have to do
-with a real tree or with a genealogical tree. We are
-just as uncertain when we deal with animals. What
-is the being that lasts on—a series of generations or
-an individual? This doubt forbids us to draw any
-conclusion from the observation of complex beings.<span class="pagenum" id="Page_333">[Pg 333]</span>
-We must therefore return from them to the <i>elementary
-being</i>; and we must examine it from the point of view
-of perennity or of vital decay. Let us then ask the
-questions that we have already examined with reference
-to animals high in organization and to man
-himself. Is the death of the cell an inevitable characteristic?
-Are there any cells, protophytes, protozoa,
-which are immortal?</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_334">[Pg 334]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_V_5">CHAPTER V.<br />
-
-<small>THE IMMORTALITY OF THE PROTOZOA.</small></h3></div>
-
-
-<p class="prel">Impossibility of life without evolution—Law of increase and
-division—Immortality of the protozoa—Death, a phenomenon
-of adaptation which has appeared in the course of
-the ages—The infusoria—The death of the infusoria—Two
-kinds of reproduction—The caryogamic rejuvenescence of
-Maupas—Calkins on rejuvenescence—Causes of senescence—Impossibility
-of life without evolution.</p>
-
-
-<p>We take into account, <i>a priori</i>, the conditions that
-must be fulfilled by the monocellular being in order
-to escape the inevitability of evolution, of the succession
-of ages, of old age, and of death. It must be
-able indefinitely to maintain itself in a normal régime,
-without changing, without increasing, maintaining its
-constant morphological and chemical composition, in
-an environment vast enough for it to be unaltered by
-the borrowings or the spendings resulting from its
-nutrition—<i>i.e.</i>, it must remain constant in the presence
-of the constant being. We might conceive of a
-nutrition perfect enough, of exchanges exact enough,
-and regular enough, for the state of things to be
-indefinitely maintained. This would be absolute
-permanence realized in the vital mobility.</p>
-
-<p><i>The Law of Growth and Division.</i>—This model of
-a perfect and invariable machine does not exist in
-nature. Life is incompatible with the absolute per<span class="pagenum" id="Page_335">[Pg 335]</span>manence
-of the dimensions and the forms of the living
-organism.</p>
-
-<p>In a word, it is a rigorous law of living nature that
-the cell can neither live indefinitely without growth,
-nor grow indefinitely without division.</p>
-
-<p>Why is this so? Why is there this impossibility
-of a regular régime in which the cell would be maintained
-in magnitude without diminution or increase?
-Why has nutrition as a necessary consequence the
-growth of the element? This is what we do not
-positively know.</p>
-
-<p>Things are so. It is an irreducible fact, peculiar to
-the protoplasm, a characteristic of the living matter
-of the cell. It is the fundamental basis of the property
-of generation. That is all we can say about it.
-Real living beings have therefore inevitably an evolution.
-They are not unchangeable. In its simple form
-this evolution consists in the fact that the cell grows,
-divides, and diminishes by this division, begins the
-upward march which ends in a new division. And
-so on.</p>
-
-<p><i>Immortality of the Protozoa.</i>—It may happen, and
-it does happen in fact, that this series of acts is
-repeated indefinitely at any rate unless an accidental
-cause should interrupt it. The animal thus describes
-an indefinite curve, constituted by a series of indentations,
-the highest point of which corresponds to the
-maximum of size, and the lowest point to the
-diminution which succeeds the division. This state of
-things has no inevitable end if the medium does not
-change. The being is immortal.</p>
-
-<p>In fact, the compound beings of a single cell, protophytes
-and protozoa, the algae and the unicellular
-mushrooms, at the minimum stage of differentiation,<span class="pagenum" id="Page_336">[Pg 336]</span>
-escape the necessity of death. They have not, as
-Weismann remarks, the real immortality of the gods
-of mythology, who were invulnerable. On the contrary,
-they are infinitely vulnerable, fragile, and
-perishable; myriads die every moment. But their
-death is not inevitable. They succumb to accidents,
-never to old age.</p>
-
-<p>Imagine one of these beings placed in a culture
-medium favourable to the full exercise of its activities,
-and, moreover, wide enough in its extent to be unaffected
-by the infinitely small quantities of material
-which the animal may take from it or expel into it.
-Suppose, for example, it is an infusorian in an ocean.
-In this invariable medium the being lives, increases,
-and grows continually. When it has reached the
-limits of a size fixed by its specific law, it divides into
-two parts, which are indistinguishable the one from
-the other. It leaves one of its halves to colonize in its
-neighbourhood, and it begins its evolution as before.
-There is no reason why the fact should not be repeated
-indefinitely, since nothing is changed, either
-in the medium or in the animal.</p>
-
-<p>To sum up. The phenomena which take place in
-the cell of the protozoan do not behave as a cause of
-check. The medium allows the organism to revictual
-and to discharge itself in such a way and with such
-perfection that the animal is always living in a regular
-régime, and, with the exception of its growth and
-later on of its division, there is nothing changed
-in it.</p>
-
-<p><i>Death a Phenomenon of Adaptation—It appeared in
-the Course of the Ages.</i>—This immortality belongs in
-principle to all the protista which are reproduced by
-simple and equal division. If it be remarked that<span class="pagenum" id="Page_337">[Pg 337]</span>
-these rudimentary organisms endowed with perennity
-are the first living forms which have shown themselves
-on the surface of the globe, and that they have
-no doubt preceded many others—the multicellular,
-for instance, which are liable, on the contrary, to
-decay—the conclusion is obvious:—Life has long
-existed without death. Death has been a phenomenon
-of adaptation which has appeared in the
-course of the ages in consequence of the evolution of
-species.</p>
-
-<p><i>The Death of Infusoria.</i>—We may ask ourselves at
-what moment in the history of the globe, at what
-period of the evolution of its fauna, this novelty,
-death, made its appearance. The celebrated experiments
-of Maupas on the senescence of the infusoria
-seem to authorize us to give a precise answer to this
-question. By means of these experiments we are
-led to believe that death must have appeared
-at the same time as sexual reproduction. Death
-became possible when this process of generation
-was established, not in all its plenitude, but in its
-humblest beginnings, under the rudimentary forms
-of unequal division and of conjugation. This
-happened when the infusoria began to people the
-waters.</p>
-
-<p><i>The Two Modes of Multiplication.</i>—Infusoria are, in
-fact, capable of multiplication by simple division.
-It is true to say that in addition to this resource, the
-only one which interests us here, because it is the
-only one which confers immortality, they possess
-another. They present and exercise under certain
-circumstances a second mode of reproduction, caryogamic
-conjugation. It is a rather complicated
-process in its detail, but it is definitively summed up<span class="pagenum" id="Page_338">[Pg 338]</span>
-as the temporary pairing of two individuals, which
-are otherwise very much alike, and which cannot be
-distinguished as male and female. They become
-closely united on one of their faces; they reciprocally
-exchange a semi-nucleus which passes into the conjoint
-individual; and then they separate. But
-infusoria can be prevented from this conjunction by
-regularly isolating them immediately after their birth.
-Then they grow, and are constrained after a lapse of
-time to divide according to the first method.</p>
-
-<p>Maupas has shown that the infusoria could not
-accommodate themselves to this régime indefinitely;
-they could not go on dividing for ever. After a
-certain number of divisions they show signs of
-degeneration and of evident decay. The size
-diminishes, the nuclear organs become atrophied,
-all the activities fail, and the infusorian perishes.
-It succumbs to this kind of senile atrophy unless it
-is given an opportunity of conjugation with another
-infusorian in the same plight. In this act it then
-derives new strength, it grows larger, attains its
-proper size, and builds up its organs once more.
-Conjugation gives it life, youth, and immortality.</p>
-
-<p><i>Alimentary Rejuvenescence.</i>—Recent observations
-due to Mr. G. N. Calkins, an American biologist,
-and confirmed by other investigators, have shown
-that this method of rejuvenescence is not the only
-one, and is not even the most efficacious. Conjugation
-has no mysterious, specific virtue. The
-infusoria need not be married in order to be
-rejuvenated. It is sufficient to improve their food.
-In the case of the “tailed” paramecium we may
-substitute beef broth and phosphates for conjugation.
-Calkins observed 665 consecutive generations<span class="pagenum" id="Page_339">[Pg 339]</span>
-without blemish, without exhaustion, and without
-any sign of old age. Plenty of food and simple
-drugs have successfully resisted senility and the
-train of atrophic degenerations which it involves.</p>
-
-<p><i>Causes of Senescence.</i>—As for the causes of senescence
-which have been remedied with such success,
-they are not exactly known. Calkins thinks that
-senescence results from the progressive losses to the
-organism of some substance essential to life. Conjugation
-or intensive alimentation would act by building
-up again this necessary compound. G. Loisel
-believes on the contrary that it is a matter of the
-progressive accumulation of toxic products due to a
-kind of alimentary auto-intoxication.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_340">[Pg 340]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_VI_5">CHAPTER VI.<br />
-
-<small>LETHALITY OF THE METAZOA AND OF
-DIFFERENTIATED CELLS.</small></h3></div>
-
-
-<p class="prel">Evolution and death of metazoa.—Possible rejuvenescence of
-the differentiated cells by the conditions of the medium.—Conditions
-of the medium for immortal cells.—The
-immortal elements of metazoa.—The element in accidental
-and remediable death.—Somatic cells and sexual cells.</p>
-
-
-<p><i>Evolution and Death of Metazoa.</i>—We have seen
-that the infusoria are no longer animals in which
-material exchanges take place with sufficient perfection,
-and in which cellular division, the consequence
-of growth, is produced with sufficient precision and
-equality for life to be carried on indefinitely in
-a perfect equilibrium in the appropriate medium
-without alteration or check. <i>A fortiori</i> we no
-longer find the perfect regularity of nutritive
-exchange in the classes above them. In a word,
-starting from this inferior group, there are no
-animated beings in the state of existence which
-Le Dantec calls “condition <span class="allsmcap">Iº</span> of manifested life?”
-Living matter, instead of being continually kept
-identical in conditions of identical media, is modified
-in the course of existence. It becomes dependent on
-time. It describes a declining trajectory; it experiences
-evolution, decay, and death. Thus the<span class="pagenum" id="Page_341">[Pg 341]</span>
-fundamental condition of invariable youth and
-of immortality fails in all metazoa. The vital
-wastes accumulate in all through the insufficiency
-or the imperfection of nutritive absorption or of
-excretion. Life decays; the organism progressively
-alters, and thus is constituted that state of decrepitude
-by atrophy or chemical modification
-which we call senescence, and which ends in death.
-To sum up, old age and death may be attributed to
-cellular differentiation.</p>
-
-<p><i>Possible Alimentary Rejuvenescence of the Differentiated
-Cells—Conditions of Medium.</i>—We must add,
-however—as the teaching of experiments in general
-and in particular as the teaching of the experiments
-of Loeb and of Calkins—that a slight change of the
-environment, made at the right time, is capable of
-re-establishing equilibrium and of completely rejuvenating
-the infusorian. Senescence has not in
-this case a definitive any more than an intrinsic
-character; a modification in the composition of the
-alimentary medium will successfully resist it. If we
-are allowed to generalize this result, it may be said
-that senescence, the declining trajectory, the evolution
-step by step down to death, are not for the
-cells considered in isolation an inevitable and essentially
-inherent in the organism, and a rigorous consequence
-of life itself. They preserve an accidental
-character. In senescence and death there is no
-really natural, internal cause, inexorable, and irremediable,
-as was claimed in the past by J. Müller,
-and more recently by Cohnheim in Germany and
-Sedgwick Minot in America.</p>
-
-<p><i>Conditions of the Medium for Immortal Cells.</i>—As
-for the cells which are less differentiated, the proto<span class="pagenum" id="Page_342">[Pg 342]</span>phytes
-and the protozoa situated one degree lower in
-the scale than the infusoria, we must admit the
-possibility of that perfect and continuous equilibrium
-which would save them from senile decrepitude.
-And it is quite understood that this privilege remains
-subordinated to the perfect constancy of the
-appropriate medium. If the latter changes, the
-equilibrium is broken, the small insensible perturbations
-of nutrition accumulate, vital activity
-decays, and in sole consequence of the imperfection
-of the extrinsic conditions or of the medium, the
-living being finds itself once more dragged down to
-decay and to death.</p>
-
-<p><i>Immortal Elements of the Metazoa.</i>—All the preceding
-facts and considerations refer to isolated cells,
-to monocellular beings. But, and this is what makes
-these truths so interesting, they may be extended to
-all cells grouped in collectivity—i.e., to all the
-animals and living beings that we know. In the
-complicated edifice of the organism, the anatomical
-elements, at any rate the least differentiated, would
-have a continual brevet of immortality. Generally
-speaking, this would be the case for the egg, for the
-sexual elements, and perhaps, too, for the white
-globules of the blood, the leucocytes. And, further,
-around each of these elements must be realized the
-invariably perfect medium which is the necessary
-condition. This does not take place.</p>
-
-<p><i>Elements in Accidental and Remediable Death.</i>—As
-for the other elements, they are like the infusoria,
-but without the resource of conjugation. The
-ambient medium becomes exhausted and intoxicated
-around each cell, in consequence of the accidents
-which happen to the other cells. Each therefore<span class="pagenum" id="Page_343">[Pg 343]</span>
-undergoes progressive decay, and finally they
-perish—the decay and destruction being perhaps
-in principle accidental, but, in fact, they are the
-rule.</p>
-
-<p>The different anatomical elements of the organism
-are more or less sensitive to those perturbations which
-cause senescence, necrobiosis, and death. There are
-some more fragile and more exposed. Some are
-more resisting, and finally, there are some which
-are really immortal. We have just said that the
-sexual cell, the ovum, is one. It follows that the
-metazoan, man for instance, cannot entirely die.
-Let us consider one of these beings. Its ancestors,
-so to speak, have not entirely disappeared; each has
-left the fertile egg, the surviving element from which
-has issued the being of which we speak; and when
-it in its turn has developed, part of that ovum has
-been placed in reserve for a new generation. The
-death of the elements is not therefore universal.
-The metazoan is divided from the beginning into
-two parts. On the one hand are the cells destined
-to form the body, <i>somatic</i> cells. They will die. On
-the other hand are the <i>reproductive</i>, or <i>germinal</i>, or
-<i>sexual</i> cells, capable of living indefinitely.</p>
-
-<p><i>Somatic and Sexual Cells.</i>—In this sense we may
-say with Weismann that there are two things in
-the animal and in man—the one mortal, the <i>soma</i>
-the body, the other immortal, the <i>germen</i>. These
-germinal cells, as in the case of the protozoa we
-mentioned above, possess a conditional immortality.
-They are imperishable, but on the contrary, are
-fragile and vulnerable. Millions of ova are destroyed
-and are disappearing every moment. They may die
-by accident, but never of old age.</p>
-
-<p><span class="pagenum" id="Page_344">[Pg 344]</span></p>
-
-<p>We now understand that if the protistae are
-immortal, it is because these living beings, reduced
-to a single cell, accumulate in it the compound
-characters of the somatic cell and germinal cell,
-and enjoy the privilege which is attached to the
-latter.</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_345">[Pg 345]</span></p>
-
-<h3 class="nobreak" id="CHAPTER_VII_5">CHAPTER VII.<br />
-
-<small>MAN. THE INSTINCT OF LIFE AND THE INSTINCT
-OF DEATH.</small></h3></div>
-
-
-<p class="prel">The miseries of humanity: 1. Disease; 2. Old age.—Old age
-considered as a chronic disease.—Its occasional cause.—3.
-The disharmonies of human nature; 4. The instinct of life
-and the instinct of death.</p>
-
-
-<p>Man’s unhappy plight is the constant theme of
-philosophies and religions. Without referring to its
-moral basis, it has a physical basis due to four
-causes—the physical imperfection or disharmony of
-nature, disease, old age, and death—or rather of
-three, for what we call old age is perhaps a simple
-disease. These are the great sorrows of man, the
-sources of all his woes. Disease attacks him, old age
-awaits him, and death must tear him from all the
-ties which he has formed. All his pleasures are
-poisoned by the certain knowledge that they last
-but for a moment, that they are as precarious as his
-health, his youth, and his life itself.</p>
-
-
-<h4>§ 1. <span class="smcap">Disease.</span></h4>
-
-<p>Disease, frequent, constant, and inevitable as it is,
-is, however, nothing but a fact outside the natural
-order. Its character is clearly accidental, and it
-interrupts the normal cycle of evolution. Medical<span class="pagenum" id="Page_346">[Pg 346]</span>
-observation teaches us, on the other hand, that the
-health of the body reacts on that of the mind; and
-therefore man as a whole, moral and physical, is
-affected by disease. Bacon described a diseased
-body as a jailer to the soul, and the healthy body as
-a host. Pascal recognized in diseases a principle of
-error. “They spoil our judgment and our senses.”</p>
-
-<p>I am not expressing a chimerical hope when I
-predict that science will conquer disease. Medicine
-has at last issued from the contemplative attitude
-of so many centuries; it has engaged in the
-struggle, and signs of victory are already appearing.
-Disease is no longer the mysterious power which it
-was impossible to escape. Pasteur gave to it a body.
-The microbe can be caught. In the words of
-Schopenhauer, an alteration of the atmosphere so
-slight that it is impossible to detect it by chemical
-analysis may bring on cholera, yellow fever, the
-black plague, diseases which carry off thousands of
-men; and a slightly greater alteration might endanger
-all life. The at once mysterious and terrifying spectacle
-of the cholera at Berlin in 1831 had such an
-effect on the philosopher that he fled in terror to
-Frankfort. It has been said that this was the origin
-of his pessimism, and that but for this he would have
-continued to teach idealistic philosophy in some
-Prussian university. L. Hartmann, another celebrated
-leader of contemporary pessimism, has also
-said that disease will always be beyond the resources
-of medicine. Facts have given the lie to these
-sombre prognostics. The microbic origin of most infectious
-diseases has been recognized. The discovery
-of attenuated poisons and serums has diminished
-their gravity. An exact knowledge of methods of<span class="pagenum" id="Page_347">[Pg 347]</span>
-contagion has enabled us to erect against them impregnable
-barriers. Cholera, yellow fever, the plague
-knock in vain at our doors. Diphtheria, dreaded by
-every mother, has partially lost its deadly character.
-Puerperal fever and blindness of the new-born child
-are tending to disappear. Legend tells us that
-Buddha in his youth, frightened at the sight of a
-sick man, expressed in his father’s presence the wish
-to be always in perfect health and sheltered from
-disease. The King answered: “My son! you are
-asking the impossible.” But it is towards the
-realization of this impossibility that we are on our
-way. Science is repelling the attacks of disease.</p>
-
-
-<h4>§ 2. <span class="smcap">Old Age.</span></h4>
-
-<p>Old age is another sorrow of humanity. The
-stage of existence in which the strength grows less
-and never grows greater, and in which a thousand
-infirmities appear, is not, however, a stage universal
-in animals. Most of them die without our perceiving
-in them any apparent signs of senile weakness. On
-the other hand, some vegetables exhibit these signs.
-Some trees are old; but it is in birds and mammals
-that this decay, with the train of evils which accompanies
-it, becomes a very marked phase of existence.
-In man to debility is added a bodily shrinkage, grey
-hairs, withered skin, and the wearing out and loss of
-teeth. The exhausted and atrophied organism offers
-a favourable field to all intercurrent diseases and to
-every cause of destruction. It is this discrepitude
-which makes old age so hateful. All desire to be
-old, said Cicero; and when they are old, they say
-that old age has come quicker than they expected.<span class="pagenum" id="Page_348">[Pg 348]</span>
-La Bruyère expresses it in an apothegm, “We want
-to grow old, and we fear old age.” One would like
-longevity without old age.</p>
-
-<p>But can life be prolonged without senility diminishing
-its value? Metchnikoff thinks it can. He
-more or less clearly catches a glimpse of a normal
-evolution of existence which would make it longer
-and nevertheless exempt from senile decay.</p>
-
-<p>It is remarkable that we have so few scientific data
-on the old age of man, and we have still fewer on
-that of animals. The biologist knows no more than
-the layman. The old age of the dog is betrayed by
-its gait. Its coat loses its lustre, just as in disease.
-The hair whitens around the forehead and the
-muzzle. The teeth grow blunt and drop out. The
-character loses its gaiety and becomes gloomy; the
-animal becomes indifferent. He ceases to bark, and
-often becomes blind and deaf.</p>
-
-<p>It is admitted that senile degeneration is due to an
-alteration affecting most of the tissues. The cells,
-the special anatomical elements of the liver, the
-kidney, and the brain are reduced by atrophy and
-degeneration. At the same time, the conjunctive
-woof which serves them as a support develops, on
-the contrary, at the expense in a measure of the
-higher elements. For this reason the tissues harden.
-We know that the flesh of old animals is tough. We
-know in pathology that this is happening to the
-tissues. It is due to growth, to injury to the
-active and important elements, to the elements of
-support of the organs. They form a tissue sometimes
-called packed tissue, to show its secondary rôle
-with reference to the elements which are deposited
-in it. This kind of degeneration of the organs is<span class="pagenum" id="Page_349">[Pg 349]</span>
-known as sclerosis. It constitutes the characteristic
-lesion of a certain number of chronic diseases; and
-these diseases are serious, for the stifling of the
-characteristic elements by the less important elements
-of the conjunctive or packed tissue results in
-the more or less complete reduction or suppression
-of the function.</p>
-
-<p>The blood vessels also undergo this transformation,
-and what we may call universal trouble and danger
-ensue. This sclerosis of the arteries, this arterio-sclerosis,
-not only deprives the walls of the blood
-vessels of the suppleness and elasticity which are
-necessary for the proper irrigation of the organs, but
-it makes them more fragile. Thus it becomes a
-cause of hemorrhage, which is a very serious matter
-as far as the brain and lungs are concerned.</p>
-
-<p>It is remarkable that the alteration of the tissues
-during old age should be exactly similar to this.
-This is inferred from the few researches that have
-been made on the subject—from those of Demange
-in 1886, of Merkel in 1891, and finally from the
-researches of Metchnikoff himself. It is a generalized
-sclerosis. As its consequence we have the lowering
-of the proper activity of the organs and the danger
-of cerebral hemorrhage created by arterio-sclerosis.
-The transformations of the tissues in old men are
-therefore summed up in the atrophy of the important
-and specific elements of the tissues, and their replacement
-by the hypertrophied conjunctive tissue. This
-sclerosis is comparable to that of chronic diseases;
-it is a pathological condition. Thus old age, as we
-understand it, is a chronic disease and not a normal
-phase of the vital cycle.</p>
-
-<p>On the other hand, if we ask ourselves what is the<span class="pagenum" id="Page_350">[Pg 350]</span>
-origin of the scleroses which engender chronic
-diseases, we find that they are due to the action of
-various poisons, among which syphilitic poison and
-the immoderate use of alcohol take the first place.
-These are also the usual causes of senile degeneration.
-But there must be some other, some very
-general cause to explain the universality of the
-process of senescence. Metchnikoff thinks that he
-has found this cause in the microbes which swarm in
-man’s digestive tube, particularly in the large intestine.
-Their number is enormous. Strassburger
-has given an approximate calculation, but words fail
-to express it. We have to imagine a figure followed
-by fifteen zeros. This microbic flora is composed of
-“bacilli” and of “cocci,” and comprises a third of
-the rejected matter. It produces slow poisons,
-which, being at once reabsorbed, pass into the blood
-and provoke the constant irritation from which
-results arterio-sclerosis and the universal sclerosis
-of old age. Instead of enjoying a healthy and
-normal old age, in which the faculties of ripening
-years are preserved, we drag out a diminished life,
-a kind of chronic disease, which is ordinary old age.
-This is due, according to Metchnikoff, to the parasitism
-and the symbiosis of microbic flora, lodged in
-a part of the economy in which it finds all the conditions
-favourable to its prolific expansion. Such is
-the specious theory, held to the verge of intrepidity,
-by which this investigator explains the misery of our
-old age, and which inspires him with the idea of a
-remedy. For his observations conclude with a
-régime, a series of prescriptions by which the author
-fancies that life may be lengthened and the evils of
-old age swept from our path. The dangerous flora<span class="pagenum" id="Page_351">[Pg 351]</span>
-must be transformed into a cultivated and selected
-flora. Although the organ in question may be of
-doubtful utility, and although its existence, the
-legacy of atavic heredity, must be considered as a
-disharmony of human nature, Metchnikoff does not
-go so far as to propose that it should be cut away,
-and that we should call in surgery to assist in making
-mankind perfect! But the rational means he proposes
-will be endorsed by the most judicious students
-of hygiene; and their effect, if it is not as wonderful
-as one hopes for, cannot fail to ameliorate the
-conditions of old age and make it more vigorous.</p>
-
-
-<h4>§ 3. <span class="smcap">Disharmonies in Human Nature.</span></h4>
-
-<p>Another misery in the condition of man is due to
-the dissidencies of his nature—that is to say, to his
-physical imperfections and the discordancies which
-exist between the physiological functions and the
-instincts which should regulate them.</p>
-
-<p>This discordance reigns throughout the physical
-organism. The body of man is not the perfect
-masterpiece it was once supposed to be. It is
-encumbered with annoying inutilities, with rudimentary
-organs that have neither rôle nor function,
-unfinished sketches which nature has left in the
-different parts of his body. Such are the lachrymal
-caruncle, a vestige of the third eyebrow in mammals;
-the extrinsic muscles of the ear; the pineal gland of
-the brain, which is only the rudiment of an ancestral
-organ; the third eye, or the Cyclopean eye of the
-saurians. The list is interminable. Wiedersheim has
-counted in man 107 of these abortive hereditary
-organs, the useless vestiges of organs useful to our<span class="pagenum" id="Page_352">[Pg 352]</span>
-remote animal ancestors, atrophied in the course of
-ages in consequence of modifications that have taken
-place in the external medium.</p>
-
-<p>These rudimentary organs are not only useless;
-they are often positively harmful.</p>
-
-<p>But the most serious discordance is that which
-exists between the physiological functions and the
-instincts which regulate them. In a well-regulated
-organism slowly developed by adaptation the instincts
-and the organs alike should be in relation with the
-functions. All really natural acts are solicited by
-an instinct, the satisfaction of which is at once a
-need and a pleasure. The maternal instinct is
-awakened at the proper moment in animals, and it
-disappears as soon as the offspring requires no more
-assistance. A craving for milk is shown in all newborn
-children, and often disappears at an early age.</p>
-
-<p>Nature has endowed man as well as the other
-animals with peculiar instincts, destined to preside
-over the different functions and to ensure their
-accomplishment. And, at the same time, it has
-enabled him in a measure to deceive those instincts
-and to satisfy them by other means than the execution
-of the physiological acts with a view to which
-they exist. Love and the instinct of reproduction
-exist in man before the age of puberty. Canova felt
-the spur of love at the age of five. Dante was in
-love with Beatrice at nine; and Byron, then scarcely
-seven, was already in love with Maria Duff. On the
-other hand, puberty has no necessary relation to the
-general maturity of the organism.</p>
-
-<p>The family instinct is subject to the same aberrations.
-Man limits the number of his children. The<span class="pagenum" id="Page_353">[Pg 353]</span>
-Turks of to-day follow the ancient Greeks in the
-practice of abortion. Plato approved of the custom,
-and Aristotle sanctioned its general prevalence. In
-the province of Canton the Chinese of the agricultural
-classes kill two-thirds of their girl children,
-and the same is done at Tahiti. All these customs
-co-exist with the perfect love and tender care of the
-living children.</p>
-
-<p>Because of these different discordancies the physical
-life of man is insufficiently regulated by nature.
-Neither the physiological instinct, nor the family
-instinct, nor the social instinct is, in general, sufficiently
-imperative and precise. Hence, since the
-internal impulse has not sufficient power, the necessity
-arises for a rule of conduct exercising its influence
-from without. Philosophies, religions, and legislation
-have provided for this. They have regulated man’s
-hygiene and the carrying out of his different physiological
-functions. Their control has, moreover, had
-its hygienic side. The scientific hygiene of to-day
-has inherited their rôle.</p>
-
-<p>The idea of the fundamental perversity of human
-nature is born of our cognizance of its discordancies,
-unduly amplified and exaggerated. Soul and body
-have been considered as distinctly discordant and
-hostile elements. The body, the shroud of the soul,
-the temporary host, the prison, the present source of
-miseries, has been subjected to every kind of mortification.
-Asceticism has treated the body and all the
-innate instincts as our mortal foes.</p>
-
-<p>This suspicion, this depreciation of human nature
-was the great error of the mystics. This view was
-as fatal as the inverse view of pagan antiquity.
-The model of the perfect life according to Greek<span class="pagenum" id="Page_354">[Pg 354]</span>
-philosophy is a life in conformity with nature. To
-aim at the harmonious development of man was the
-precept of the ancient Academy, formulated by Plato.
-The Stoics and the Epicureans had adopted the same
-principle. Physical nature is considered as good.
-It gives us the type, the rule, and the measure. The
-moral rule itself is exactly appropriate to the physical
-nature. We may say that pagan morality was
-hygiene, the hygiene of the soul and the body alike;
-the <i>mens sana in corpore sano</i> gave individual and
-social direction. The Rationalists, the philosophers
-of the eighteenth century, such as Baron d’Holbach
-and later W. Von Humboldt, Darwin, and Herbert
-Spencer, have adopted analogous views. If these
-views have been contested, it is because of the imperfections
-or aberrations of the natural instincts of
-man. Also, if we wish to base individual family or
-social morality on the natural instincts of man, it
-must be specified that these instincts are to be
-regularized. We must necessarily appeal from the
-imperfect instincts of the present to the perfected
-instincts of the future. Their perfection, moreover,
-will only be a more exact approximation to the real
-nature of man, and he, having avoided by the aid of
-science the accidents which cause disease and senile
-decrepitude, will enjoy a healthy youth and an ideal
-old age.</p>
-
-<p>The reason of the discrepancies between instinct
-and function in man is given by the natural history
-of his development. We know that man has within
-him original sin—his long atavism. He has sprung,
-according to the transformists, from a simian stock.
-He is a cousin, the successful relation, of a type
-of antinomorphic monkeys, the chimpanzees. He<span class="pagenum" id="Page_355">[Pg 355]</span>
-has “arrived,” they have remained undeveloped.
-Probably he had a common ancestor with them,
-some dryopithecan of an extinct species. From that
-type sprang a new type already on the way to
-progress, the <i>Pithecanthropus erectus</i>. Finally, the
-anthropoid ancestor became one fine day the father
-of a scion, clearly superior to himself, a miraculously
-gifted being, man. Here, then, is no sign of the slow
-evolution and gradual progress, which is the doctrine
-held at present by Transformists. The Dutch
-botanist De Vries has shown us, in fact, that nature
-does leap: <i>natura facit saltus</i>. There would thus be
-crises, as it were, in the life of species. At certain
-critical epochs considerable differences of a specific
-value appear in their offspring. It is at one of these
-critical periods in the simian life that man has
-appeared as the phenomenal child of an anthropoid.
-He was born with a brain and an intellect superior
-to those of his humble parents; and on the other
-hand, he has inherited from them an organization
-which is only inadequately adapted to the new conditions
-of existence created by the development of
-his sensitiveness and his brain power. This intellect
-is not proportioned to his organization, which has
-not developed at the same rate; it protests against
-the discordances which adaptation has not yet had
-time to efface. But it will efface them in the future.</p>
-
-
-<h4>§ 4. <span class="smcap">The Instinct of Life and the Instinct
-of Death.</span></h4>
-
-<p>The greatest discrepancy of this kind is the
-knowledge of inevitable death without the instinct
-which makes it longed for.<span class="pagenum" id="Page_356">[Pg 356]</span></p>
-
-<p>There are immortal animals. Man is not of the
-number. He belongs, like all highly organized
-beings, to the class of beings which have an end.
-They die from accident or from disease. They
-perish in the struggle with other animals, or with
-microbes, or with external conditions. There are
-certainly very few, if there are any, which die a
-really natural death. And so it is with man. We
-see old men gradually declining who appear to
-doze gently off into the last sleep, and become
-extinguished without disease, like a lamp whose oil
-is exhausted. But this is in most cases only
-apparently so. Besides the fact that the old age to
-which they seemed to succumb is really a disease,
-a generalized sclerosis, autopsy always reveals some
-lesion more or less directly responsible for the fatal
-issue.</p>
-
-<p>Man, like all the higher animals, is therefore
-subject to the law of lethality. But while animals
-have no idea of death and are not tormented by the
-sentiment of their inevitable end, man knows and
-understands this destiny. He has with the animals
-the instinct of self-preservation, the instinct of life,
-and at the same time the knowledge and the fear of
-death. This contradiction, this discordance, is one
-of the sources of his woes.</p>
-
-<p>Whether it be an accident or the regular term of
-the normal cycle, death always comes too soon. It
-surprises the man at a time when he has not yet
-completed his physiological evolution; hence the
-aversion and the terror it inspires. “We cannot
-fix our eyes on the sun or on death,” said La Rochefoucauld.
-The old man does not regard death with
-less aversion than the young man. “He who is<span class="pagenum" id="Page_357">[Pg 357]</span>
-most like the dead dies with most regret.” Man
-knows that he is not getting his full measure.</p>
-
-<p>Further, all the really natural acts are solicited
-by an instinct, the satisfaction of which is a need
-and a joy. The need of death should therefore
-appear at the end of life, just as the need of sleep
-appears at the end of the day. It would appear, no
-doubt, if the normal cycle of existence were fulfilled,
-and if the harmonious evolution were not always
-interrupted by accident. Death would then be
-welcomed and longed for. It would lose its horror.
-The instinct of death would replace at the wished
-for moment the instinct of life. Man would pass
-from the banquet of life with no other desire. He
-would die without regret, “being old and full of
-days,” according to the expression used in the Bible
-in the case of Abraham, Isaac, and Jacob. No
-doubt there are some analogies to this in the insects
-which only assume the perfect form for the purpose
-of procreation and immediately perish in their full
-perfection. In these animals the approach of death
-is blended with the intoxication of hymen. Thus
-we see some of them, the ephemerae, lose at that
-moment the instinct of life and the instinct of
-self-preservation. They allow themselves to be
-approached, taken, and seized, and make no effort
-at flight.</p>
-
-<p>But what is this full measure of life which is
-imparted to us? Metchnikoff holds that the ages
-attributed to several persons in the Bible are very
-probable. Abraham lived 175 years, Ishmael 137,
-Joseph 110, Moses 120. Buffon believed in the
-existence of a ratio between the longevity of animals
-and the duration of their growth. He fixed it at<span class="pagenum" id="Page_358">[Pg 358]</span>
-7:1. The animal whose development lasts two years
-would thus have 14 years of life. This law would
-give us 140 years, but the figure is too high, and
-<a id="Flourens_has_reduced"></a>Flourens has reduced the ratio to that of 5:1, which
-would still give us 100 years. Plato died in the act
-of conversation at 81; Isocrates wrote his <i>Panathenaïcus</i>
-at 94; Gorgias died in the full possession
-of his intellect at 107.</p>
-
-<p>To reach the end of the promised longevity we
-must neither count on the elixir of life nor on the
-potable gold of the alchemists, nor on the stone of
-immortality which did not prevent its inventor,
-Paracelsus, from dying at the age of 58, nor on
-transfusion, nor on Graham’s celestial bed, nor on
-King David’s gerocomy, nor on any nostrum or
-remedy. <i>Contra vim mortis non est medicamen in
-hortis</i>, said the Salernian school. What Feuchtersleben
-said is most true, “The art of prolonging life
-consists in not cutting it short,” and it is a hygiene,
-but a brilliant hygiene, such as that of which
-Metchnikoff traces us the future lines, which will
-realize the desires of nature.</p>
-
-<p>And now shall we find that physiology has solved
-the enigma proposed by the Sphinx, and that it has
-answered these poignant questions:—Whence do
-we come? whither do we go? what is the end of
-life? The end of life is, to the physiologist as well
-as to Herbert Spencer, the tendency towards an
-existence as full and as long as possible, towards a
-life in conformity with real nature freed from the
-discordancies which still remain; it is the accomplishment
-of the harmonious cycle of our normal
-evolution. This ideal human nature, without discordancies,
-no longer vitiated as it is at present but<span class="pagenum" id="Page_359">[Pg 359]</span>
-improved, will be the work of time and science.
-Realized at last it will serve as a solid basis for
-individual, family, and social morality. Healthy
-youth fit for action; prolonged, adult age, the
-symbol of strength; normal old age, wise in council,
-these would have their natural places in harmonious
-society. “Great actions,” said one of old, “are not
-achieved by exertions of strength, or speed, or agility,
-but rather by the prudence, the authority, and the
-judgment which are found in a higher degree in old
-age.” The old age of which Cicero here speaks is
-the ideal old age, regular and normal, and not the
-premature, deformed, incapable and egoistic old age
-which results from a pathological condition. At the
-end of this full life, the old man being full of days,
-will crave for the eternal sleep and will resign
-himself to it with joy....</p>
-
-<p>Death, then, “the last enemy that shall be
-destroyed,” to use the expression of St. Paul, will
-yield to the power of science. Instead of being
-“the king of terrors,” it will become after a long
-and healthy life, after a life exempt from morbid
-accidents, a natural and longed for event, a satisfied
-need. Then will be realized the wish of the
-fabulist:—</p>
-
-<div class="blockquot">
-
-<p>“<i>I should like to leave life at this age, just as one
-leaves a banquet, thanking the host, and departing.</i>”</p>
-</div>
-
-<p>Has this physiological solution of the problem of
-death the virtue attributed to it by Metchnikoff?
-Is it as optimistic as he thinks it is? The instinct
-of death supervening at the end of a normal and
-well-filled cycle will no doubt facilitate to the aged
-their departure on the great voyage. The wrench<span class="pagenum" id="Page_360">[Pg 360]</span>
-will no longer exist for the dead. Will it not exist
-for those who are left behind? And since the
-instinct of death can only exist about the time at
-which death is expected, will the young man and
-the man of ripened years look with less horror than
-to-day at the law which cannot be escaped, when
-they are in full possession of the instinct of life,
-but warned of the inevitability of death?</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_361">[Pg 361]</span></p>
-
-<h3 class="nobreak" id="INDEX_OF_AUTHORS">INDEX OF AUTHORS.</h3>
-</div>
-
-<ul class="index">
-<li class="ifrst">Altmann, <a href="#Page_258">258</a></li>
-
-<li class="indx">Anaxagoras, <a href="#Page_34">34</a></li>
-
-<li class="indx">Aquinas, St. Thomas, <a href="#Page_3">3</a>, <a href="#Page_19">19</a>, <a href="#Page_248">248</a></li>
-
-<li class="indx">Aristotle, <a href="#Page_3">3</a>, <a href="#Page_15">15</a>, <a href="#Page_18">18</a>, <a href="#Page_143">143</a>, <a href="#Page_146">146</a>, <a href="#Page_307">307</a></li>
-
-<li class="indx">Armstrong, <a href="#Page_295">295</a></li>
-
-<li class="indx">Atwater, <a href="#Page_137">137</a></li>
-
-
-<li class="ifrst">Bacon, vi., <a href="#Page_35">35</a>, <a href="#Page_346">346</a></li>
-
-<li class="indx">Baker, <a href="#Page_233">233</a></li>
-
-<li class="indx">Balbiani, <a href="#Page_161">161</a>, <a href="#Page_165">165</a>, <a href="#Page_191">191</a>, <a href="#Page_206">206</a>-7, <a href="#Page_257">257</a></li>
-
-<li class="indx">Bang, d’Yvor, <a href="#Page_179">179</a></li>
-
-<li class="indx">Barthez, <a href="#Page_3">3</a>, <a href="#Page_19">19</a>, <a href="#Page_24">24</a></li>
-
-<li class="indx">Beclard, <a href="#Page_121">121</a></li>
-
-<li class="indx">Becquerel, <a href="#Page_278">278</a></li>
-
-<li class="indx">Beijerinck, <a href="#Page_193">193</a></li>
-
-<li class="indx">Benoit, <a href="#Page_271">271</a></li>
-
-<li class="indx">Bernard, Claude, vi., <a href="#Page_17">17</a>, <a href="#Page_27">27</a>, <a href="#Page_29">29</a>, <a href="#Page_32">32</a>,
- <a href="#Page_48">48</a>, <a href="#Page_50">50</a>-4, <a href="#Page_107">107</a>, <a href="#Page_109">109</a>, <a href="#Page_112">112</a>, <a href="#Page_119">119</a>, <a href="#Page_148">148</a>, <a href="#Page_150">150</a>-1, <a href="#Page_171">171</a>, <a href="#Page_190">190</a>-2, <a href="#Page_194">194</a>, <a href="#Page_197">197</a>, <a href="#Page_204">204</a>, <a href="#Page_210">210</a>, <a href="#Page_214">214</a>-218, <a href="#Page_220">220</a> <i>et seq.</i>, <a href="#Page_310">310</a>, <a href="#Page_318">318</a></li>
-
-<li class="indx">Bernoulli, John, <a href="#Page_35">35</a>, <a href="#Page_73">73</a></li>
-
-<li class="indx">Bert, Paul, <a href="#Page_194">194</a></li>
-
-<li class="indx">Berthelot, <a href="#Page_91">91</a>, <a href="#Page_98">98</a>, <a href="#Page_128">128</a>-130, <a href="#Page_152">152</a>, <a href="#Page_204">204</a>, <a href="#Page_296">296</a></li>
-
-<li class="indx">Berthollet, <a href="#Page_82">82</a></li>
-
-<li class="indx">Berzelius, <a href="#Page_117">117</a></li>
-
-<li class="indx">Bichat, <a href="#Page_3">3</a>, <a href="#Page_6">6</a>, <a href="#Page_20">20</a>, <a href="#Page_22">22</a>, <a href="#Page_27">27</a>-30, <a href="#Page_35">35</a>, <a href="#Page_55">55</a>, <a href="#Page_158">158</a>, <a href="#Page_170">170</a>, <a href="#Page_198">198</a>, <a href="#Page_308">308</a></li>
-
-<li class="indx">Blumenbach, <a href="#Page_46">46</a></li>
-
-<li class="indx">Boë, Sylvius Le, <a href="#Page_35">35</a>-6</li>
-
-<li class="indx">Boerhaave, <a href="#Page_35">35</a>, <a href="#Page_147">147</a>, <a href="#Page_245">245</a></li>
-
-<li class="indx">Bohr, <a href="#Page_29">29</a>-30</li>
-
-<li class="indx">Bokorny, <a href="#Page_324">324</a></li>
-
-<li class="indx">Boltzmann, <a href="#Page_265">265</a></li>
-
-<li class="indx">Bonnet, <a href="#Page_23">23</a>, <a href="#Page_49">49</a></li>
-
-<li class="indx">Bordeu, <a href="#Page_3">3</a>, <a href="#Page_10">10</a>, <a href="#Page_19">19</a>, <a href="#Page_22">22</a>, <a href="#Page_24">24</a>, <a href="#Page_312">312</a></li>
-
-<li class="indx">Borelli, <a href="#Page_35">35</a></li>
-
-<li class="indx">Boscovitch, <a href="#Page_37">37</a>, <a href="#Page_248">248</a></li>
-
-<li class="indx">Bose, <a href="#Page_264">264</a></li>
-
-<li class="indx">Bossuet, <a href="#Page_11">11</a></li>
-
-<li class="indx">Bouasse, <a href="#Page_73">73</a>, <a href="#Page_264">264</a>-5</li>
-
-<li class="indx">Boullier, <a href="#Page_12">12</a></li>
-
-<li class="indx">Bourdeau, <a href="#Page_237">237</a>, <a href="#Page_242">242</a></li>
-
-<li class="indx">Boussingault, <a href="#Page_149">149</a></li>
-
-<li class="indx">Brandt, <a href="#Page_257">257</a></li>
-
-<li class="indx">Bravais, <a href="#Page_282">282</a></li>
-
-<li class="indx">Brillouin, <a href="#Page_264">264</a>, <a href="#Page_273">273</a></li>
-
-<li class="indx">Brown, <a href="#Page_266">266</a> <i>et seq.</i></li>
-
-<li class="indx">Brücke, <a href="#Page_44">44</a></li>
-
-<li class="indx">Büchner, <a href="#Page_325">325</a></li>
-
-<li class="indx">Buffon, <a href="#Page_46">46</a>, <a href="#Page_254">254</a>, <a href="#Page_357">357</a></li>
-
-<li class="indx">Bunge, von, <a href="#Page_3">3</a>, <a href="#Page_14">14</a></li>
-
-<li class="indx">Burdon, Sanderson, <a href="#Page_176">176</a></li>
-
-<li class="indx">Busquet, <a href="#Page_175">175</a></li>
-
-<li class="indx">Bütschli, <a href="#Page_161">161</a>-2, <a href="#Page_175">175</a></li>
-
-
-<li class="ifrst">Cabanis, <a href="#Page_245">245</a>, <a href="#Page_246">246</a></li>
-
-<li class="indx">Cailletet, <a href="#Page_272">272</a></li>
-
-<li class="indx">Calkins, <a href="#Page_327">327</a>, <a href="#Page_338">338</a></li>
-
-<li class="indx">Calvert, <a href="#Page_271">271</a></li>
-
-<li class="indx">Candolle, <a href="#Page_20">20</a></li>
-
-<li class="indx">Cardan, <a href="#Page_261">261</a></li>
-
-<li class="indx">Carnot, <a href="#Page_72">72</a>-3, <a href="#Page_89">89</a>, <a href="#Page_92">92</a> <i>et seq.</i>, <a href="#Page_101">101</a>, <a href="#Page_114">114</a>, <a href="#Page_121">121</a></li>
-
-<li class="indx">Charpy, <a href="#Page_237">237</a>, <a href="#Page_271">271</a></li>
-
-
-<li class="indx">Chauffard, <a href="#Page_3">3</a>, <a href="#Page_10">10</a>, <a href="#Page_11">11</a>, <a href="#Page_294">294</a></li>
-
-<li class="indx">Chauveau, <a href="#Page_75">75</a>, <a href="#Page_103">103</a>, <a href="#Page_108">108</a>, <a href="#Page_123">123</a>, <a href="#Page_130">130</a>, <a href="#Page_145">145</a>, <a href="#Page_213">213</a></li>
-
-<li class="indx">Chevreul, <a href="#Page_32">32</a></li>
-
-<li class="indx">Chossat, <a href="#Page_152">152</a></li>
-
-<li class="indx">Cicero, <a href="#Page_347">347</a>, <a href="#Page_359">359</a></li>
-
-<li class="indx">Clausius, <a href="#Page_67">67</a>, <a href="#Page_88">88</a></li>
-
-<li class="indx">Cohn, <a href="#Page_191">191</a>, <a href="#Page_252">252</a></li>
-
-<li class="indx">Cohnheim, <a href="#Page_341">341</a></li>
-
-<li class="indx">Colding, <a href="#Page_58">58</a> <i><a href="#Footnote_4">note</a></i>, <a href="#Page_90">90</a></li>
-
-<li class="indx">Colin, <a href="#Page_52">52</a></li>
-
-<li class="indx">Comte, <a href="#Page_189">189</a>-190, <a href="#Page_310">310</a></li>
-
-<li class="indx">Confucius, <a href="#Page_309">309</a></li>
-
-<li class="indx">Coulomb, <a href="#Page_76">76</a>, <a href="#Page_264">264</a>, <a href="#Page_273">273</a></li>
-
-<li class="indx">Crookes, <a href="#Page_295">295</a>, <a href="#Page_302">302</a></li>
-
-<li class="indx">Cuvier, <a href="#Page_3">3</a>, <a href="#Page_6">6</a>, <a href="#Page_27">27</a>-8, <a href="#Page_105">105</a>, <a href="#Page_120">120</a>, <a href="#Page_152">152</a>, <a href="#Page_190">190</a>, <a href="#Page_198">198</a>, <a href="#Page_308">308</a>, <a href="#Page_310">310</a>, <a href="#Page_319">319</a>
-<span class="pagenum" id="Page_362">[Pg 362]</span></li>
-
-
-<li class="indx">D’Alembert, <a href="#Page_20">20</a>, <a href="#Page_59">59</a> <i><a href="#Footnote_4">note</a></i>, <a href="#Page_90">90</a>, <a href="#Page_92">92</a></li>
-
-<li class="indx">Dantec, Le, <a href="#Page_48">48</a>, <a href="#Page_52">52</a>, <a href="#Page_55">55</a> <i><a href="#Footnote_3">note</a></i>, <a href="#Page_110">110</a>, <a href="#Page_148">148</a>, <a href="#Page_173">173</a>, <a href="#Page_198">198</a>,
- <a href="#Page_201">201</a>, <a href="#Page_203">203</a>, <a href="#Page_213">213</a>, <a href="#Page_216">216</a>, <a href="#Page_220">220</a>, <a href="#Page_223">223</a> <i>et seq.</i>, <a href="#Page_231">231</a>, <a href="#Page_246">246</a>, <a href="#Page_261">261</a>, <a href="#Page_285">285</a>, <a href="#Page_296">296</a>, <a href="#Page_340">340</a></li>
-
-<li class="indx">D’Arsonval, <a href="#Page_126">126</a></li>
-
-<li class="indx">Darwin, <a href="#Page_3">3</a>, <a href="#Page_46">46</a>, <a href="#Page_167">167</a>, <a href="#Page_258">258</a>, <a href="#Page_354">354</a></li>
-
-<li class="indx">Dastre, A., <a href="#Page_192">192</a>, <a href="#Page_198">198</a> <i><a href="#Footnote_16">note</a></i></li>
-
-<li class="indx">Davy, Sir Humphry, <a href="#Page_61">61</a>, <a href="#Page_80">80</a></li>
-
-<li class="indx">Delafosse, <a href="#Page_282">282</a></li>
-
-<li class="indx">Delage, <a href="#Page_208">208</a></li>
-
-<li class="indx">Demange, <a href="#Page_349">349</a></li>
-
-<li class="indx">Democritus, <a href="#Page_34">34</a>, <a href="#Page_146">146</a></li>
-
-<li class="indx">Descartes, <a href="#Page_3">3</a>, <a href="#Page_9">9</a>, <a href="#Page_35">35</a>, <a href="#Page_37">37</a>, <a href="#Page_40">40</a>, <a href="#Page_73">73</a>, <a href="#Page_91">91</a>, <a href="#Page_98">98</a></li>
-
-<li class="indx">Despretz, <a href="#Page_126">126</a></li>
-
-<li class="indx">Diderot, <a href="#Page_245">245</a>, <a href="#Page_246">246</a></li>
-
-<li class="indx">Drechsel, <a href="#Page_183">183</a></li>
-
-<li class="indx">Dressel, <a href="#Page_20">20</a></li>
-
-<li class="indx">Dubois-Reymond, <a href="#Page_44">44</a>, <a href="#Page_58">58</a> <i><a href="#Footnote_5">note</a></i>, <a href="#Page_253">253</a></li>
-
-<li class="indx">Duclaux, <a href="#Page_119">119</a>, <a href="#Page_137">137</a>, <a href="#Page_184">184</a>, <a href="#Page_324">324</a></li>
-
-<li class="indx">Dufour, <a href="#Page_297">297</a></li>
-
-<li class="indx">Duguet, <a href="#Page_264">264</a></li>
-
-<li class="indx">Duhem, <a href="#Page_62">62</a>, <a href="#Page_264">264</a>, <a href="#Page_265">265</a></li>
-
-<li class="indx">Dulong, <a href="#Page_126">126</a></li>
-
-<li class="indx">Dumas, <a href="#Page_115">115</a>, <a href="#Page_149">149</a>, <a href="#Page_151">151</a>-2</li>
-
-
-<li class="ifrst">Epicurus, <a href="#Page_35">35</a>, <a href="#Page_146">146</a></li>
-
-<li class="indx">Ehrlich, <a href="#Page_176">176</a></li>
-
-<li class="indx">Errera, <a href="#Page_52">52</a>, <a href="#Page_193">193</a>-4, <a href="#Page_237">237</a>, <a href="#Page_153">153</a>, <a href="#Page_295">295</a>, <a href="#Page_302">302</a> <i>et seq.</i></li>
-
-<li class="indx">Euclid, v.</li>
-
-
-<li class="ifrst">Faye, <a href="#Page_260">260</a></li>
-
-<li class="indx">Feuchterslehen, <a href="#Page_358">358</a></li>
-
-<li class="indx">Flemming, <a href="#Page_161">161</a></li>
-
-<li class="indx">Flourens, <a href="#Page_20">20</a>-1, <a href="#Page_152">152</a>, <a href="#Page_208">208</a>, <a href="#Page_306">306</a>, <a href="#Page_358">358</a></li>
-
-<li class="indx">Fouillée, <a href="#Page_242">242</a></li>
-
-<li class="indx">Fromann, <a href="#Page_161">161</a></li>
-
-<li class="indx">Fuerth, <a href="#Page_183">183</a></li>
-
-
-<li class="ifrst">Galen, <a href="#Page_25">25</a>, <a href="#Page_55">55</a>, <a href="#Page_143">143</a></li>
-
-<li class="indx">Galeotti, <a href="#Page_180">180</a></li>
-
-<li class="indx">Galileo, <a href="#Page_73">73</a>, <a href="#Page_91">91</a>, <a href="#Page_98">98</a>, <a href="#Page_197">197</a>, <a href="#Page_241">241</a>, <a href="#Page_260">260</a></li>
-
-<li class="indx">Gardair, <a href="#Page_19">19</a>, <a href="#Page_248">248</a></li>
-
-<li class="indx">Gautier, A., <a href="#Page_3">3</a>, <a href="#Page_32">32</a>, <a href="#Page_36">36</a>, <a href="#Page_39">39</a>, <a href="#Page_176">176</a>, <a href="#Page_233">233</a>, <a href="#Page_324">324</a></li>
-
-<li class="indx">Gernez, <a href="#Page_237">237</a>, <a href="#Page_288">288</a>, <a href="#Page_295">295</a> <i>et seq.</i></li>
-
-<li class="indx">Glisson, <a href="#Page_27">27</a></li>
-
-<li class="indx">Goethe, <a href="#Page_170">170</a>, <a href="#Page_312">312</a></li>
-
-<li class="indx">Gouy, <a href="#Page_266">266</a>, <a href="#Page_268">268</a></li>
-
-<li class="indx">Grimaud, <a href="#Page_19">19</a></li>
-
-<li class="indx">Gruber, <a href="#Page_165">165</a>, <a href="#Page_206">206</a>, <a href="#Page_257">257</a></li>
-
-<li class="indx">Guignard, <a href="#Page_161">161</a></li>
-
-<li class="indx">Guillaume, <a href="#Page_237">237</a>, <a href="#Page_262">262</a>, <a href="#Page_264">264</a>, <a href="#Page_271">271</a>, <a href="#Page_277">277</a></li>
-
-<li class="indx">Guillemin, <a href="#Page_237">237</a></li>
-
-<li class="indx">Guldberg, <a href="#Page_83">83</a></li>
-
-
-<li class="ifrst">Harbermann, <a href="#Page_183">183</a></li>
-
-<li class="indx">Haeckel, <a href="#Page_3">3</a>, <a href="#Page_46">46</a>, <a href="#Page_164">164</a>, <a href="#Page_167">167</a>, <a href="#Page_246">246</a>, <a href="#Page_251">251</a></li>
-
-<li class="indx">Hales, <a href="#Page_43">43</a></li>
-
-<li class="indx">Haller, <a href="#Page_27">27</a></li>
-
-<li class="indx">Hamilton, Sir W. Rowan, <a href="#Page_67">67</a></li>
-
-<li class="indx">Hammarsten, <a href="#Page_180">180</a></li>
-
-<li class="indx">Hartmann, <a href="#Page_276">276</a>, <a href="#Page_346">346</a></li>
-
-<li class="indx">Harvey, <a href="#Page_43">43</a>, <a href="#Page_160">160</a></li>
-
-<li class="indx">Haüy, <a href="#Page_282">282</a></li>
-
-<li class="indx">Hegel, <a href="#Page_170">170</a>, <a href="#Page_331">331</a></li>
-
-<li class="indx">Heidenhain, <a href="#Page_3">3</a>, <a href="#Page_29">29</a>, <a href="#Page_30">30</a>-1</li>
-
-<li class="indx">Heitzmann, <a href="#Page_161">161</a></li>
-
-<li class="indx">Helmholtz, <a href="#Page_44">44</a>, <a href="#Page_56">56</a>, <a href="#Page_58">58</a>, <a href="#Page_67">67</a>, <a href="#Page_90">90</a>, <a href="#Page_97">97</a>, <a href="#Page_99">99</a>, <a href="#Page_252">252</a></li>
-
-<li class="indx">Helmont, van, <a href="#Page_3">3</a>, <a href="#Page_21">21</a>, <a href="#Page_26">26</a>, <a href="#Page_33">33</a>, <a href="#Page_146">146</a>, <a href="#Page_250">250</a></li>
-
-<li class="indx">Henninger, <a href="#Page_302">302</a></li>
-
-<li class="indx">Heraclitus, <a href="#Page_34">34</a></li>
-
-<li class="indx">Hertwig, <a href="#Page_167">167</a></li>
-
-<li class="indx">Hertz, <a href="#Page_88">88</a></li>
-
-<li class="indx">Hess, <a href="#Page_91">91</a>, <a href="#Page_98">98</a></li>
-
-<li class="indx">Hippocrates, <a href="#Page_146">146</a></li>
-
-<li class="indx">Hirn, <a href="#Page_126">126</a></li>
-
-<li class="indx">His, <a href="#Page_46">46</a></li>
-
-<li class="indx">Hlasitwetz, <a href="#Page_183">183</a></li>
-
-<li class="indx">Holbach, d’, <a href="#Page_354">354</a></li>
-
-<li class="indx">Hoogewerf, <a href="#Page_303">303</a></li>
-
-<li class="indx">Hopkinson, <a href="#Page_271">271</a></li>
-
-<li class="indx">Humboldt, W. von, <a href="#Page_354">354</a></li>
-
-
-<li class="ifrst">Ingenhousz, <a href="#Page_115">115</a></li>
-
-<li class="indx">Izolet, <a href="#Page_247">247</a></li>
-
-
-<li class="ifrst">Joule, <a href="#Page_53">53</a> <i>note</i>, <a href="#Page_90">90</a>-1, <a href="#Page_93">93</a>, <a href="#Page_133">133</a> <i>et seq.</i>, <a href="#Page_143">143</a>, <a href="#Page_152">152</a></li>
-
-
-<li class="ifrst">Kant, <a href="#Page_312">312</a>, <a href="#Page_319">319</a></li>
-
-<li class="indx">Kaup, <a href="#Page_213">213</a></li>
-
-<li class="indx">Kaufmann, <a href="#Page_126">126</a></li>
-
-<li class="indx">Kelvin, Lord, <a href="#Page_63">63</a>, <a href="#Page_67">67</a>, <a href="#Page_90">90</a>, <a href="#Page_92">92</a>, <a href="#Page_251">251</a>-2, <a href="#Page_264">264</a>;</li>
-<li class="isub1">and the idea of energy, <a href="#Page_66">66</a></li>
-
-<li class="indx">Kepler, <a href="#Page_29">29</a>, <a href="#Page_241">241</a></li>
-
-<li class="indx">Klemm, <a href="#Page_323">323</a></li>
-
-<li class="indx">Koelliker, <a href="#Page_160">160</a>
-<span class="pagenum" id="Page_363">[Pg 363]</span></li>
-
-<li class="indx">Kossel, <a href="#Page_174">174</a>, <a href="#Page_179">179</a>, <a href="#Page_130">130</a>-1, <a href="#Page_136">136</a> <i>et seq.</i></li>
-
-<li class="indx">Kuhne, <a href="#Page_45">45</a></li>
-
-<li class="indx">Kuhm, <a href="#Page_216">216</a></li>
-
-<li class="indx">Kuliabko, <a href="#Page_23">23</a>, <a href="#Page_311">311</a></li>
-
-<li class="indx">Kunstler, <a href="#Page_157">157</a>, <a href="#Page_161">161</a>-2, <a href="#Page_175">175</a></li>
-
-<li class="indx">Kuppfer, <a href="#Page_161">161</a></li>
-
-
-<li class="ifrst">Lammettrie, <a href="#Page_147">147</a></li>
-
-<li class="indx">Lamarck, <a href="#Page_46">46</a></li>
-
-<li class="indx">Lapparent, <a href="#Page_284">284</a></li>
-
-<li class="indx">Lapicque, <a href="#Page_140">140</a>, <a href="#Page_145">145</a></li>
-
-<li class="indx">Langley, <a href="#Page_216">216</a></li>
-
-<li class="indx">Laplace, <a href="#Page_43">43</a>, <a href="#Page_63">63</a>, <a href="#Page_126">126</a>, <a href="#Page_260">260</a></li>
-
-<li class="indx">Laulanié, <a href="#Page_103">103</a></li>
-
-<li class="indx">Laurie, <a href="#Page_271">271</a></li>
-
-<li class="indx">La Rochefoucauld, <a href="#Page_356">356</a></li>
-
-<li class="indx">Lavoisier, <a href="#Page_3">3</a>, <a href="#Page_28">28</a>, <a href="#Page_30">30</a>, <a href="#Page_36">36</a>, <a href="#Page_43">43</a>, <a href="#Page_65">65</a>, <a href="#Page_117">117</a>, <a href="#Page_121">121</a>, <a href="#Page_126">126</a>, <a href="#Page_128">128</a>, <a href="#Page_143">143</a>, <a href="#Page_176">176</a>, <a href="#Page_296">296</a></li>
-
-<li class="indx">Lea, <a href="#Page_216">216</a></li>
-
-<li class="indx">Le Châtelier, <a href="#Page_85">85</a>, <a href="#Page_92">92</a></li>
-
-<li class="indx">Lechatelier, H. and A., <a href="#Page_271">271</a></li>
-
-<li class="indx">Lecocq de Boisbaudran, <a href="#Page_295">295</a></li>
-
-<li class="indx">Leeuwenhoek, <a href="#Page_232">232</a></li>
-
-<li class="indx">Lefèvre, <a href="#Page_126">126</a></li>
-
-<li class="indx">Legallois, <a href="#Page_21">21</a></li>
-
-<li class="indx">Leydig, <a href="#Page_161">161</a>-2</li>
-
-<li class="indx">Liebermeister, <a href="#Page_136">136</a></li>
-
-<li class="indx">Liebig, <a href="#Page_26">26</a>, <a href="#Page_53">53</a> <i>note</i>, <a href="#Page_117">117</a></li>
-
-<li class="indx">Lilienfeld, <a href="#Page_179">179</a>, <a href="#Page_247">247</a></li>
-
-<li class="indx">Locke, <a href="#Page_23">23</a></li>
-
-<li class="indx">Lodge, <a href="#Page_271">271</a></li>
-
-<li class="indx">Loeb, <a href="#Page_43">43</a>, <a href="#Page_167">167</a>, <a href="#Page_327">327</a>, <a href="#Page_341">341</a></li>
-
-<li class="indx">Loew, <a href="#Page_324">324</a></li>
-
-<li class="indx">Loisel, <a href="#Page_339">339</a>, <a href="#Page_341">341</a></li>
-
-<li class="indx">Lorry, <a href="#Page_21">21</a></li>
-
-<li class="indx">Longet, <a href="#Page_52">52</a></li>
-
-<li class="indx">Lowitz, <a href="#Page_297">297</a></li>
-
-<li class="indx">Loye, <a href="#Page_192">192</a></li>
-
-<li class="indx">Ludwig, <a href="#Page_44">44</a>, <a href="#Page_215">215</a></li>
-
-
-<li class="ifrst">Mach, <a href="#Page_41">41</a>, <a href="#Page_62">62</a></li>
-
-<li class="indx">Magendie, <a href="#Page_43">43</a>, <a href="#Page_143">143</a></li>
-
-<li class="indx">Magy, <a href="#Page_37">37</a></li>
-
-<li class="indx">Malgaigne, <a href="#Page_153">153</a></li>
-
-<li class="indx">Mallard, <a href="#Page_284">284</a></li>
-
-<li class="indx">Marinesco, <a href="#Page_231">231</a>, <a href="#Page_328">328</a></li>
-
-<li class="indx">Markel, <a href="#Page_349">349</a></li>
-
-<li class="indx">Maspero, <a href="#Page_3">3</a>, <a href="#Page_234">234</a></li>
-
-<li class="indx">Matthiesson, <a href="#Page_271">271</a></li>
-
-<li class="indx">Maupas, <a href="#Page_337">337</a></li>
-
-<li class="indx">Maxwell, <a href="#Page_88">88</a></li>
-
-<li class="indx">Mayer, R., <a href="#Page_56">56</a>, <a href="#Page_58">58</a>, <a href="#Page_89">89</a>, <a href="#Page_90">90</a>, <a href="#Page_97">97</a>, <a href="#Page_99">99</a>, <a href="#Page_101">101</a></li>
-
-<li class="indx">Mering, von, <a href="#Page_133">133</a>, <a href="#Page_136">136</a></li>
-
-<li class="indx">Metchnikoff, <a href="#Page_327">327</a> <i>et seq.</i></li>
-
-<li class="indx">Miescher, <a href="#Page_174">174</a>, <a href="#Page_179">179</a></li>
-
-<li class="indx">Milne-Edwards, <a href="#Page_152">152</a>, <a href="#Page_195">195</a></li>
-
-<li class="indx">Minot, <a href="#Page_341">341</a></li>
-
-<li class="indx">Miura, <a href="#Page_137">137</a></li>
-
-<li class="indx">Mori, <a href="#Page_145">145</a></li>
-
-<li class="indx">Müller, <a href="#Page_20">20</a>, <a href="#Page_27">27</a>, <a href="#Page_341">341</a></li>
-
-<li class="indx">Murato, <a href="#Page_45">45</a></li>
-
-
-<li class="ifrst">Naegeli, <a href="#Page_168">168</a></li>
-
-<li class="indx">Needham, <a href="#Page_46">46</a></li>
-
-<li class="indx">Newton, <a href="#Page_58">58</a> <i><a href="#Footnote_4">note</a></i>, <a href="#Page_70">70</a>, <a href="#Page_90">90</a>-1, <a href="#Page_93">93</a></li>
-
-<li class="indx">Noorden, van, <a href="#Page_129">129</a>, <a href="#Page_137">137</a>, <a href="#Page_140">140</a>, <a href="#Page_210">210</a></li>
-
-<li class="indx">Nussbaum, <a href="#Page_165">165</a>, <a href="#Page_206">206</a>, <a href="#Page_215">215</a>, <a href="#Page_217">217</a></li>
-
-
-<li class="ifrst">Obermeyer, <a href="#Page_271">271</a></li>
-
-<li class="indx">Osmond, <a href="#Page_237">237</a>, <a href="#Page_271">271</a></li>
-
-<li class="indx">Ostwald, <a href="#Page_41">41</a>, <a href="#Page_62">62</a>, <a href="#Page_67">67</a>, <a href="#Page_85">85</a>, <a href="#Page_104">104</a>, <a href="#Page_237">237</a>, <a href="#Page_258">258</a>, <a href="#Page_289">289</a>, <a href="#Page_295">295</a> <i>et seq.</i></li>
-
-
-<li class="ifrst">Paracelsus, <a href="#Page_26">26</a>, <a href="#Page_146">146</a>, <a href="#Page_312">312</a></li>
-
-<li class="indx">Pascal, <a href="#Page_74">74</a>, <a href="#Page_161">161</a></li>
-
-<li class="indx">Pasteur, <a href="#Page_53">53</a>, <a href="#Page_191">191</a>, <a href="#Page_222">222</a> <i>et seq.</i>, <a href="#Page_237">237</a>, <a href="#Page_250">250</a>, <a href="#Page_288">288</a>, <a href="#Page_346">346</a></li>
-
-<li class="indx">Payen, <a href="#Page_151">151</a></li>
-
-<li class="indx">Persoz, <a href="#Page_152">152</a></li>
-
-<li class="indx">Petit, <a href="#Page_180">180</a></li>
-
-<li class="indx">Pettenkofer, <a href="#Page_210">210</a></li>
-
-<li class="indx">Pfeffer, <a href="#Page_175">175</a>, <a href="#Page_193">193</a></li>
-
-<li class="indx">Pflüger, <a href="#Page_12">12</a>, <a href="#Page_56">56</a>, <a href="#Page_135">135</a>, <a href="#Page_144">144</a>, <a href="#Page_176">176</a>, <a href="#Page_210">210</a>, <a href="#Page_213">213</a></li>
-
-<li class="indx">Philpotts, <a href="#Page_46">46</a></li>
-
-<li class="indx">Pictet, <a href="#Page_233">233</a></li>
-
-<li class="indx">Pitcairn, <a href="#Page_35">35</a></li>
-
-<li class="indx">Plato, <a href="#Page_35">35</a>, <a href="#Page_307">307</a></li>
-
-<li class="indx">Plosz, <a href="#Page_180">180</a></li>
-
-<li class="indx">Poincaré, <a href="#Page_62">62</a></li>
-
-<li class="indx">Poisson, <a href="#Page_63">63</a></li>
-
-<li class="indx">Preyer, <a href="#Page_192">192</a>, <a href="#Page_252">252</a> <i>et seq.</i></li>
-
-<li class="indx">Priestley, <a href="#Page_115">115</a></li>
-
-<li class="indx">Ptolemy, v.</li>
-
-<li class="indx">Pythagoras, <a href="#Page_18">18</a></li>
-
-
-<li class="ifrst">Rauber, <a href="#Page_237">237</a>, <a href="#Page_288">288</a></li>
-
-<li class="indx">Raulin, <a href="#Page_191">191</a></li>
-
-<li class="indx">Regnault, <a href="#Page_117">117</a></li>
-
-<li class="indx">Reinke, <a href="#Page_3">3</a>, <a href="#Page_32">32</a></li>
-
-<li class="indx">Renan, <a href="#Page_240">240</a></li>
-
-<li class="indx">Ribbert, <a href="#Page_208">208</a>
-<span class="pagenum" id="Page_364">[Pg 364]</span></li>
-
-<li class="indx">Ribot, <a href="#Page_247">247</a></li>
-
-<li class="indx">Riche, <a href="#Page_271">271</a></li>
-
-<li class="indx">Richet, <a href="#Page_50">50</a>, <a href="#Page_126">126</a>, <a href="#Page_140">140</a></li>
-
-<li class="indx">Richter, <a href="#Page_252">252</a></li>
-
-<li class="indx">Rindfleisch, <a href="#Page_4">4</a></li>
-
-<li class="indx">Roberts-Austen, <a href="#Page_237">237</a>, <a href="#Page_271">271</a>-2</li>
-
-<li class="indx">Robin, <a href="#Page_62">62</a>, <a href="#Page_177">177</a></li>
-
-<li class="indx">Rosenthal, <a href="#Page_126">126</a></li>
-
-<li class="indx">Rouvier, <a href="#Page_160">160</a></li>
-
-<li class="indx">Roux, <a href="#Page_46">46</a>, <a href="#Page_165">165</a></li>
-
-<li class="indx">Rubner, <a href="#Page_129">129</a>, <a href="#Page_130">130</a>, <a href="#Page_140">140</a> <i>et seq.</i>, <a href="#Page_210">210</a></li>
-
-<li class="indx">Rumford, <a href="#Page_80">80</a></li>
-
-
-<li class="ifrst">Sabatier, <a href="#Page_242">242</a></li>
-
-<li class="indx">Sachs, <a href="#Page_161">161</a>, <a href="#Page_194">194</a></li>
-
-<li class="indx">Salles-Guyon, <a href="#Page_252">252</a></li>
-
-<li class="indx">Sanderson, Burdon, <a href="#Page_176">176</a></li>
-
-<li class="indx">Scaliger, <a href="#Page_241">241</a></li>
-
-<li class="indx">Schleiden, <a href="#Page_159">159</a></li>
-
-<li class="indx">Schopenhauer, <a href="#Page_346">346</a></li>
-
-<li class="indx">Schwartz, <a href="#Page_162">162</a></li>
-
-<li class="indx">Schultze, <a href="#Page_160">160</a>, <a href="#Page_326">326</a></li>
-
-<li class="indx">Schultzenberger, <a href="#Page_174">174</a>, <a href="#Page_162">162</a> <i>et seq.</i></li>
-
-<li class="indx">Secchi, <a href="#Page_88">88</a></li>
-
-<li class="indx">Seguin, <a href="#Page_58">58</a> <i><a href="#Footnote_4">note</a></i>, <a href="#Page_90">90</a></li>
-
-<li class="indx">Senebier, <a href="#Page_115">115</a></li>
-
-<li class="indx">Siven, <a href="#Page_145">145</a></li>
-
-<li class="indx">Spallanzani, <a href="#Page_43">43</a>, <a href="#Page_233">233</a></li>
-
-<li class="indx">Spencer, Herbert, <a href="#Page_46">46</a>, <a href="#Page_247">247</a>, <a href="#Page_354">354</a>, <a href="#Page_358">358</a></li>
-
-<li class="indx">Spring, <a href="#Page_272">272</a></li>
-
-<li class="indx">Stahl, <a href="#Page_3">3</a>, <a href="#Page_9">9</a>, <a href="#Page_12">12</a>, <a href="#Page_35">35</a>, <a href="#Page_146">146</a></li>
-
-<li class="indx">Stammreich, <a href="#Page_137">137</a></li>
-
-<li class="indx">Stead, <a href="#Page_237">237</a></li>
-
-<li class="indx">Stohmann, <a href="#Page_129">129</a>, <a href="#Page_130">130</a>, <a href="#Page_140">140</a></li>
-
-<li class="indx">Strassburger, <a href="#Page_161">161</a>, <a href="#Page_350">350</a></li>
-
-<li class="indx">Swann, <a href="#Page_159">159</a></li>
-
-<li class="indx">Swift, <a href="#Page_262">262</a></li>
-
-
-<li class="ifrst">Tait, <a href="#Page_53">53</a> <i>note</i>, <a href="#Page_66">66</a></li>
-
-<li class="indx">Tammann, <a href="#Page_237">237</a>, <a href="#Page_253">253</a>, <a href="#Page_295">295</a> <i>et seq.</i></li>
-
-<li class="indx">Thales, <a href="#Page_34">34</a></li>
-
-<li class="indx">Thomson, Sir J. J., <a href="#Page_279">279</a></li>
-
-<li class="indx">Tissot, <a href="#Page_12">12</a></li>
-
-<li class="indx">Tomlinson, <a href="#Page_264">264</a></li>
-
-<li class="indx">Trembley, <a href="#Page_22">22</a>, <a href="#Page_206">206</a></li>
-
-<li class="indx">Tsuboï, <a href="#Page_145">145</a></li>
-
-<li class="indx">Tylor, <a href="#Page_8">8</a></li>
-
-
-<li class="ifrst">Verworn, <a href="#Page_206">206</a>, <a href="#Page_252">252</a>, <a href="#Page_257">257</a></li>
-
-<li class="indx">Violette, <a href="#Page_295">295</a></li>
-
-<li class="indx">Virchow, <a href="#Page_318">318</a>, <a href="#Page_326">326</a></li>
-
-<li class="indx">Voit, <a href="#Page_119">119</a>, <a href="#Page_133">133</a> <i>et seq.</i>, <a href="#Page_210">210</a></li>
-
-<li class="indx">Vries, de, <a href="#Page_46">46</a>, <a href="#Page_258">258</a>, <a href="#Page_355">355</a></li>
-
-<li class="indx">Vulpian, <a href="#Page_24">24</a></li>
-
-
-<li class="ifrst">Waage, <a href="#Page_83">83</a></li>
-
-<li class="indx">Waller, <a href="#Page_47">47</a>, <a href="#Page_206">206</a></li>
-
-<li class="indx">Wallerant, <a href="#Page_282">282</a>-3</li>
-
-<li class="indx">Warburg, <a href="#Page_264">264</a></li>
-
-<li class="indx">Watt, <a href="#Page_76">76</a></li>
-
-<li class="indx">Weismann, <a href="#Page_46">46</a>, <a href="#Page_167">167</a>, <a href="#Page_336">336</a>, <a href="#Page_343">343</a></li>
-
-<li class="indx">Wertheim, <a href="#Page_264">264</a></li>
-
-<li class="indx">Whitman, <a href="#Page_46">46</a></li>
-
-<li class="indx">Widersheim, <a href="#Page_351">351</a></li>
-
-<li class="indx">Wiedermann, <a href="#Page_264">264</a></li>
-
-<li class="indx">Wiesner, <a href="#Page_167">167</a></li>
-
-<li class="indx">Willis, <a href="#Page_36">36</a>, <a href="#Page_147">147</a></li>
-
-<li class="indx">Winternitz, <a href="#Page_126">126</a></li>
-
-
-<li class="ifrst">Yung, <a href="#Page_233">233</a></li>
-
-
-<li class="ifrst">Zuntz, <a href="#Page_133">133</a>, <a href="#Page_136">136</a>, <a href="#Page_210">210</a></li>
-
-</ul>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_365">[Pg 365]</span></p>
-
-<h2 class="nobreak" id="INDEX_OF_SUBJECTS">INDEX OF SUBJECTS.</h2>
-</div>
-
-
-
-<ul class="index">
-<li class="ifrst">Activity, functional and vital, <a href="#Page_106">106</a> <i>et seq.</i>, <a href="#Page_217">217</a> <i>et seq.</i></li>
-
-<li class="indx">Aerobia, <a href="#Page_193">193</a></li>
-
-<li class="indx">Age, old, Book v.</li>
-
-<li class="indx">Albumin, <a href="#Page_178">178</a></li>
-
-<li class="indx">Albuminoids, <a href="#Page_178">178</a></li>
-
-<li class="indx">Alcohol, <a href="#Page_136">136</a></li>
-
-<li class="indx">Alimentation, <a href="#Page_116">116</a> <i>et seq.</i></li>
-
-<li class="indx">Alloys, structure of, <a href="#Page_273">273</a></li>
-
-<li class="indx">Anærobia, <a href="#Page_193">193</a></li>
-
-<li class="indx">Animism, <a href="#Page_6">6</a>, <a href="#Page_7">7</a>, Chap. ii., <i>passim</i></li>
-
-<li class="indx">Annealing, <a href="#Page_275">275</a></li>
-
-<li class="indx">Apposition, <a href="#Page_291">291</a></li>
-
-<li class="indx">Archeus, the, <a href="#Page_25">25</a>, <a href="#Page_26">26</a>, <a href="#Page_33">33</a></li>
-
-<li class="indx">Arginin, <a href="#Page_187">187</a></li>
-
-<li class="indx">Assimilation, law of functional, <a href="#Page_110">110</a>, <a href="#Page_213">213</a></li>
-
-<li class="indx">Atomicities, satisfied, <a href="#Page_185">185</a></li>
-
-<li class="indx">Atrophy, <a href="#Page_326">326</a></li>
-
-<li class="indx">Attraction, energy of position, <a href="#Page_64">64</a></li>
-
-
-<li class="ifrst">Balance, sheet, nutritive, <a href="#Page_118">118</a></li>
-
-<li class="indx">Beliefs, primitive, <a href="#Page_239">239</a></li>
-
-<li class="indx">Bioblasts, <a href="#Page_253">253</a></li>
-
-<li class="indx">Biophors, <a href="#Page_167">167</a></li>
-
-<li class="indx">Blas, the, <a href="#Page_25">25</a>, <a href="#Page_33">33</a></li>
-
-<li class="indx">Blood, lavage of, <a href="#Page_192">192</a></li>
-
-<li class="indx">Brain, and death, <a href="#Page_315">315</a></li>
-
-<li class="indx">Butylic ferments, <a href="#Page_193">193</a></li>
-
-<li class="indx">Butyric ferments, <a href="#Page_193">193</a></li>
-
-
-<li class="ifrst">Calorie, <a href="#Page_125">125</a> <i><a href="#Footnote_10">note</a></i></li>
-
-<li class="indx">Calorimeter, ice, <a href="#Page_126">126</a>;</li>
-<li class="isub1">bomb, <a href="#Page_128">128</a></li>
-
-<li class="indx">Caprice, of Nature, <a href="#Page_45">45</a></li>
-
-<li class="indx">Cause, final, <a href="#Page_45">45</a></li>
-
-<li class="indx">Cells, <a href="#Page_48">48</a>, <a href="#Page_147">147</a>;</li>
-<li class="isub1">somatic and sexual, <a href="#Page_343">343</a></li>
-
-<li class="indx">Cellular theory, <a href="#Page_158">158</a> <i>et seq.</i></li>
-
-<li class="indx">Centrosome, <a href="#Page_163">163</a></li>
-
-<li class="indx">Chromosome, <a href="#Page_165">165</a></li>
-
-<li class="indx">Cicatrization, <a href="#Page_287">287</a></li>
-
-<li class="indx">Complex, homogeneity of the, <a href="#Page_245">245</a></li>
-
-<li class="indx">Conductibility, <a href="#Page_26">26</a></li>
-
-<li class="indx">Consciousness, in brute bodies, <a href="#Page_244">244</a> <i>et seq.</i></li>
-
-<li class="indx">Continuity, principle of, <a href="#Page_242">242</a>, <a href="#Page_247">247</a></li>
-
-<li class="indx">Contractility, <a href="#Page_26">26</a></li>
-
-<li class="indx">Contraction, energy of static and dynamic, <a href="#Page_75">75</a></li>
-
-<li class="indx">Conservation, of energy, <a href="#Page_58">58</a>;</li>
-<li class="isub1">of force, <a href="#Page_58">58</a></li>
-
-<li class="indx">Crystals, <a href="#Page_200">200</a> <i>et seq.</i>, <a href="#Page_237">237</a> <i>et seq.</i>, <a href="#Page_281">281</a> <i>et seq.</i></li>
-
-<li class="indx">Cytoplasm, <a href="#Page_161">161</a> <i>et seq.</i></li>
-
-
-<li class="ifrst">Death, apparent, <a href="#Page_232">232</a>;</li>
-<li class="isub1">senescence of, <a href="#Page_305">305</a> <i>et seq.</i>;</li>
-<li class="isub1">cellular, <a href="#Page_321">321</a> <i>et seq.</i></li>
-
-<li class="indx">Decentralization, <a href="#Page_24">24</a></li>
-
-<li class="indx">Degeneration, <a href="#Page_326">326</a></li>
-
-<li class="indx">Destruction, functional, <a href="#Page_106">106</a>;</li>
-<li class="isub1">organic, <a href="#Page_211">211</a>;</li>
-<li class="isub1">of living matter, <a href="#Page_213">213</a></li>
-
-<li class="indx">Determinism, <a href="#Page_49">49</a></li>
-
-<li class="indx">Digestion, of plants and animals, <a href="#Page_152">152</a> <i>et seq.</i></li>
-
-<li class="indx">Direction, idea of, <a href="#Page_16">16</a></li>
-
-<li class="indx">Dominants, <a href="#Page_33">33</a>, <a href="#Page_39">39</a>, <a href="#Page_45">45</a></li>
-
-<li class="indx">Dyne, the, <a href="#Page_71">71</a></li>
-
-
-<li class="ifrst">Effort, of force, <a href="#Page_71">71</a></li>
-
-<li class="indx">Electrolysis, <a href="#Page_272">272</a></li>
-
-<li class="indx">Energetics, <a href="#Page_39">39</a>, <a href="#Page_56">56</a>;</li>
-<li class="isub1">laws of biological, <a href="#Page_105">105</a> <i>et seq.</i>, <a href="#Page_229">229</a>;</li>
-<li class="isub1">alimentary, <a href="#Page_116">116</a> <i>et seq.</i></li>
-<li class="indx"><span class="pagenum" id="Page_366">[Pg 366]</span></li>
-<li class="indx">Energy, <a href="#Page_37">37</a>, Book ii., <i>passim</i>;</li>
-<li class="isub1">origin of idea of, <a href="#Page_57">57</a>;</li>
-<li class="isub1">theory of, <a href="#Page_62">62</a>;</li>
-<li class="isub1">the only objective reality, <a href="#Page_64">64</a>-5;</li>
-<li class="isub1">and kinetic conception, <a href="#Page_67">67</a>;</li>
-<li class="isub1">mechanical, <a href="#Page_69">69</a>, <a href="#Page_73">73</a>;</li>
-<li class="isub1">of contraction, <a href="#Page_75">75</a>;</li>
-<li class="isub1">kinetic, <a href="#Page_76">76</a>, <a href="#Page_83">83</a>;</li>
-<li class="isub1">potential, <a href="#Page_76">76</a>, <a href="#Page_83">83</a>;</li>
-<li class="isub1">virtual, <a href="#Page_77">77</a>;</li>
-<li class="isub1">of motion and position, <a href="#Page_79">79</a>;</li>
-<li class="isub1">thermal, and its measurements, <a href="#Page_80">80</a>-2;</li>
-<li class="isub1">chemical, and its measurements, <a href="#Page_81">81</a>-2;</li>
-<li class="isub1">chemical and potential, <a href="#Page_83">83</a>;</li>
-<li class="isub1">materialization of, <a href="#Page_84">84</a>;</li>
-<li class="isub1">transformations of, <a href="#Page_85">85</a> <i>et seq.</i>;</li>
-<li class="isub1">luminous, <a href="#Page_86">86</a> <i>et seq.</i>;</li>
-<li class="isub1">conservation of, <a href="#Page_90">90</a> <i>et seq.</i>;</li>
-<li class="isub1">capacity of conversion of, <a href="#Page_93">93</a>;</li>
-<li class="isub1">in biology, <a href="#Page_97">97</a>;</li>
-<li class="isub1">in living beings, <a href="#Page_99">99</a> <i>et seq.</i>;</li>
-<li class="isub1">physical, <a href="#Page_99">99</a> <i>et seq.</i>;</li>
-<li class="isub1">vital, <a href="#Page_99">99</a> <i>et seq.</i></li>
-
-<li class="indx">Ether, <a href="#Page_89">89</a></li>
-
-<li class="indx">Equivalence, law of, <a href="#Page_91">91</a></li>
-
-<li class="indx">Excitability, <a href="#Page_26">26</a>-7</li>
-
-
-<li class="ifrst">Fatigue, of metals, <a href="#Page_264">264</a></li>
-
-<li class="indx">Ferments, butylic and butyric, <a href="#Page_193">193</a></li>
-
-<li class="indx">Filiation, <a href="#Page_250">250</a></li>
-
-<li class="indx">Finalism, <a href="#Page_43">43</a></li>
-
-<li class="indx">Food, a source of energy, <a href="#Page_118">118</a> <i>et seq.</i>;</li>
-<li class="isub1">thermogenic and biothermogenic types of, <a href="#Page_131">131</a> <i>et seq.</i>;</li>
-<li class="isub1">dynamogenic type of, <a href="#Page_143">143</a>;</li>
-<li class="isub1">nitrogenous, <a href="#Page_143">143</a>;</li>
-<li class="isub1">of animals and plants, <a href="#Page_153">153</a> <i>et seq.</i></li>
-
-<li class="indx">Force, directive, <a href="#Page_16">16</a> <i>et seq.</i>, <a href="#Page_32">32</a>, <a href="#Page_39">39</a>, <a href="#Page_48">48</a>;</li>
-<li class="isub1">vital, <a href="#Page_45">45</a>;</li>
-<li class="isub1">an anthromorphic notion, <a href="#Page_71">71</a>;</li>
-<li class="isub1">and work, <a href="#Page_74">74</a>;</li>
-<li class="isub1">measurement of, <a href="#Page_71">71</a>;</li>
-<li class="isub1">plastic, <a href="#Page_143">143</a>;</li>
-<li class="isub1">plastic and morphoplastic forces, <a href="#Page_208">208</a></li>
-
-<li class="indx">Form, specific, <a href="#Page_199">199</a> <i>et seq.</i>, <a href="#Page_281">281</a></li>
-
-<li class="indx">Fruits, acids of, <a href="#Page_136">136</a></li>
-
-
-<li class="ifrst">Gemmules, <a href="#Page_167">167</a>, <a href="#Page_258">258</a></li>
-
-<li class="indx">Generation, spontaneous, <a href="#Page_249">249</a> <i>et seq.</i>, <a href="#Page_294">294</a> <i>et seq.</i></li>
-
-<li class="indx">Globulin, <a href="#Page_178">178</a></li>
-
-<li class="indx">Glycerine, crystals of, <a href="#Page_302">302</a></li>
-
-<li class="indx">Glycogen, <a href="#Page_108">108</a>, <a href="#Page_153">153</a> <i>et seq.</i></li>
-
-<li class="indx">Gramme, <a href="#Page_71">71</a></li>
-
-
-<li class="ifrst">Heat, a mode of motion, <a href="#Page_61">61</a>;</li>
-<li class="isub1">rôle of animal heat, <a href="#Page_122">122</a>;</li>
-<li class="isub1">mechanical equivalent of, <a href="#Page_81">81</a>;</li>
-<li class="isub1">an excretum, <a href="#Page_114">114</a>;</li>
-<li class="isub1">a degraded form of energy, <a href="#Page_88">88</a>;</li>
-<li class="isub1">converted into work, <a href="#Page_92">92</a></li>
-
-<li class="indx">Heterogeneity, <a href="#Page_38">38</a>, <a href="#Page_61">61</a></li>
-
-<li class="indx">Histones, <a href="#Page_179">179</a>, <a href="#Page_182">182</a> <i>et seq.</i></li>
-
-<li class="indx">Horse-power, <a href="#Page_75">75</a></li>
-
-<li class="indx">Hyaloplasm, <a href="#Page_161">161</a></li>
-
-
-<li class="ifrst">Iatro-chemistry and mechanics, <a href="#Page_34">34</a>-5</li>
-
-<li class="indx">Idioblasts, <a href="#Page_167">167</a></li>
-
-<li class="indx">Infusoria, death of, <a href="#Page_337">337</a></li>
-
-<li class="indx">Instability, <a href="#Page_188">188</a> <i>et seq.</i></li>
-
-<li class="indx">Instinct, of life and death, <a href="#Page_345">345</a> <i>et seq.</i></li>
-
-<li class="indx">Intussusception, <a href="#Page_291">291</a></li>
-
-<li class="indx">Invariant, mass the first, <a href="#Page_63">63</a></li>
-
-<li class="indx">Irreversibility, of vital energies, <a href="#Page_104">104</a></li>
-
-<li class="indx">Irritability, <a href="#Page_27">27</a>, <a href="#Page_196">196</a> <i>et seq.</i></li>
-
-<li class="indx">Isodynamism, <a href="#Page_142">142</a></li>
-
-<li class="indx">Isomorphism, <a href="#Page_286">286</a></li>
-
-
-<li class="ifrst">Ka, the, <a href="#Page_8">8</a></li>
-
-<li class="indx">Kilogrammetre, <a href="#Page_72">72</a>, <a href="#Page_75">75</a>;</li>
-<li class="isub1">per second, <a href="#Page_75">75</a></li>
-
-<li class="indx">Kilowatt, <a href="#Page_76">76</a></li>
-
-<li class="indx">Kinetic theory, <a href="#Page_39">39</a>, <a href="#Page_62">62</a></li>
-
-<li class="indx">Knot, the vital, <a href="#Page_21">21</a></li>
-
-
-<li class="ifrst">Leucines, <a href="#Page_183">183</a></li>
-
-<li class="indx">Leucites, <a href="#Page_163">163</a></li>
-
-<li class="indx">Life, defined, <a href="#Page_28">28</a>;</li>
-<li class="isub1">latent, <a href="#Page_233">233</a>;</li>
-<li class="isub1">physico-chemical theory of, <a href="#Page_36">36</a>;</li>
-<li class="isub1">elementary, <a href="#Page_321">321</a></li>
-
-<li class="indx">Linin, <a href="#Page_163">163</a></li>
-
-
-<li class="ifrst">Mass, and matter, <a href="#Page_63">63</a></li>
-
-<li class="indx">Materialism, <a href="#Page_34">34</a></li>
-
-<li class="indx">Matter, <a href="#Page_37">37</a>, <a href="#Page_60">60</a>, <a href="#Page_62">62</a>;</li>
-<li class="isub1">and mass, <a href="#Page_63">63</a>;</li>
-<li class="isub1">two kinds of, <a href="#Page_63">63</a>;</li>
-<li class="isub1">life of, <a href="#Page_236">236</a> <i>et seq.</i>;</li>
-<li class="isub1">brute and living, <a href="#Page_249">249</a> <i>et seq.</i>;</li>
-<li class="isub1">organization and constitution of, <a href="#Page_255">255</a> <i>et seq.</i>;</li>
-<li class="isub1">defined as extension, <a href="#Page_64">64</a>;</li>
-<li class="isub1">conservation of, <a href="#Page_65">65</a>
-<span class="pagenum" id="Page_367">[Pg 367]</span></li>
-<li class="indx">“Memory,” of metals, etc., <a href="#Page_265">265</a></li>
-
-<li class="indx">Merotomy, <a href="#Page_47">47</a></li>
-
-<li class="indx">Metabolism, <a href="#Page_117">117</a></li>
-
-<li class="indx">Metazoa, evolution and death of, <a href="#Page_340">340</a> <i>et seq.</i></li>
-
-<li class="indx">Meteoric cosmozoa, <a href="#Page_252">252</a></li>
-
-<li class="indx">Micellar theory, <a href="#Page_166">166</a> <i>et seq.</i></li>
-
-<li class="indx">Microcosms, <a href="#Page_163">163</a></li>
-
-<li class="indx">Micro-organisms, culture of, <a href="#Page_297">297</a></li>
-
-<li class="indx">Mitomes, <a href="#Page_169">169</a></li>
-
-<li class="indx">Mobility of stars, <a href="#Page_260">260</a></li>
-
-<li class="indx">Modality, twofold, of soul, <a href="#Page_12">12</a></li>
-
-<li class="indx">Molecules, organic, <a href="#Page_254">254</a></li>
-
-<li class="indx">Monism, <a href="#Page_34">34</a>, Chap. iv. <i>passim</i>, <a href="#Page_63">63</a></li>
-
-<li class="indx">Montpellier, the school of, <a href="#Page_35">35</a></li>
-
-<li class="indx">Motion, cause of, <a href="#Page_71">71</a>;</li>
-<li class="isub1">kinetic conception of molecular, <a href="#Page_263">263</a></li>
-
-<li class="indx">Morphogenesis, idea of, <a href="#Page_46">46</a></li>
-
-<li class="indx">Movements, internal of bodies, <a href="#Page_262">262</a>;</li>
-<li class="isub1">Brownian, <a href="#Page_266">266</a> <i>et seq.</i></li>
-
-<li class="indx">Mutability, <a href="#Page_80">80</a>, <a href="#Page_188">188</a> <i>et seq.</i>;</li>
-<li class="isub1">of living matter, <a href="#Page_259">259</a> <i>et seq.</i>;</li>
-<li class="isub1">of brute bodies, <a href="#Page_259">259</a> <i>et seq.</i></li>
-
-
-<li class="ifrst">Necrobiosis, <a href="#Page_326">326</a></li>
-
-<li class="indx">Neo-vitalism, <a href="#Page_15">15</a>, <a href="#Page_29">29</a>, <a href="#Page_32">32</a></li>
-
-<li class="indx">Neurility, <a href="#Page_27">27</a></li>
-
-<li class="indx">Nickel, steels, <a href="#Page_277">277</a></li>
-
-<li class="indx">Nisus <i>formativus</i>, <a href="#Page_46">46</a></li>
-
-<li class="indx">Nous, the, <a href="#Page_18">18</a>, <a href="#Page_239">239</a></li>
-
-<li class="indx">Nucleins, <a href="#Page_179">179</a>, <a href="#Page_180">180</a> <i>et seq.</i></li>
-
-<li class="indx">Nucleo-albuminoids, <a href="#Page_178">178</a>;</li>
-<li class="isub1">-proteids, <a href="#Page_177">177</a> <i>et seq.</i></li>
-
-<li class="indx">Nucleus, <a href="#Page_163">163</a> <i>et seq.</i>;</li>
-<li class="isub1">hexonic, <a href="#Page_186">186</a></li>
-
-<li class="indx">Nutrition, directed, <a href="#Page_205">205</a>, <a href="#Page_209">209</a> <i>et seq.</i>, <a href="#Page_227">227</a> <i>et seq.</i>, <a href="#Page_290">290</a> <i>et seq.</i></li>
-
-
-<li class="ifrst">Organogenesis, <a href="#Page_282">282</a></li>
-
-<li class="indx">Organs, organization of, <a href="#Page_314">314</a>;</li>
-<li class="isub1">death of, <a href="#Page_315">315</a>;</li>
-<li class="isub1">perfect, <a href="#Page_319">319</a></li>
-
-
-<li class="ifrst">Pangenes, <a href="#Page_167">167</a></li>
-
-<li class="indx">Panspermia, <a href="#Page_252">252</a></li>
-
-<li class="indx">Parameter, mass the mechanical, <a href="#Page_63">63</a></li>
-
-<li class="indx">Phenomena, vital, <a href="#Page_44">44</a>, <a href="#Page_51">51</a>, <a href="#Page_189">189</a>;</li>
-<li class="isub1">modes of motion, <a href="#Page_61">61</a></li>
-
-<li class="indx">Photography, colour, <a href="#Page_277">277</a></li>
-
-<li class="indx">Physiology, general, <a href="#Page_56">56</a>;</li>
-<li class="isub1">cellular, <a href="#Page_56">56</a></li>
-
-<li class="indx">Plants, and immortality, <a href="#Page_330">330</a></li>
-
-<li class="indx">Plasomes, <a href="#Page_167">167</a></li>
-
-<li class="indx">Plurivitalism, <a href="#Page_25">25</a></li>
-
-<li class="indx">Power, <a href="#Page_70">70</a>, <a href="#Page_75">75</a></li>
-
-<li class="indx">Principle, vital, <a href="#Page_15">15</a> <i>et seq.</i></li>
-
-<li class="indx">Properties, vital, <a href="#Page_25">25</a>, <a href="#Page_103">103</a></li>
-
-<li class="indx">Proteids, <a href="#Page_178">178</a></li>
-
-<li class="indx">Protoplasm, <a href="#Page_109">109</a> <i>et seq.</i>, <a href="#Page_175">175</a> <i>et seq.</i>, <a href="#Page_231">231</a> <i>et seq.</i>;</li>
-<li class="isub1">life in crushed, <a href="#Page_257">257</a> <i>et seq.</i></li>
-
-<li class="indx">Protozoa, immortality of, <a href="#Page_352">352</a> <i>et seq.</i></li>
-
-<li class="indx">Psyche, <a href="#Page_239">239</a></li>
-
-<li class="indx">Pyrozoa, <a href="#Page_253">253</a></li>
-
-
-<li class="ifrst">Regeneration, normal, <a href="#Page_205">205</a>;</li>
-<li class="isub1">accidental, <a href="#Page_206">206</a></li>
-
-<li class="indx">Reparation, mechanism of, <a href="#Page_288">288</a></li>
-
-<li class="indx">Repose, functional, <a href="#Page_109">109</a>, <a href="#Page_217">217</a> <i>et seq.</i></li>
-
-<li class="indx">Reserve stuff, <a href="#Page_106">106</a> <i>et seq.</i>, <a href="#Page_212">212</a>, <a href="#Page_230">230</a> <i>et seq.</i></li>
-
-<li class="indx">Rachidian, soul, <a href="#Page_12">12</a></li>
-
-
-<li class="ifrst">Senescence, <a href="#Page_305">305</a> <i>et seq.</i></li>
-
-<li class="indx">Sensibility, in brute bodies, <a href="#Page_244">244</a></li>
-
-<li class="indx">Solidarity, of anatomical elements, humoral and nervous, <a href="#Page_317">317</a></li>
-
-<li class="indx">Soul, the, <a href="#Page_7">7</a> <i>et seq.</i></li>
-
-<li class="indx">Space, <a href="#Page_69">69</a></li>
-
-<li class="indx">Specificity, vital, <a href="#Page_48">48</a></li>
-
-<li class="indx">Spireme, <a href="#Page_165">165</a></li>
-
-<li class="indx">Spongioplasm, <a href="#Page_162">162</a></li>
-
-<li class="indx">States, initial and final, <a href="#Page_128">128</a></li>
-
-<li class="indx">Swelling, <a href="#Page_167">167</a></li>
-
-<li class="indx">Synthesis, organizing, <a href="#Page_109">109</a></li>
-
-
-<li class="ifrst">Tagmata, <a href="#Page_169">169</a>, <a href="#Page_175">175</a></li>
-
-<li class="indx">Teleology, <a href="#Page_43">43</a></li>
-
-<li class="indx">Tetanus, bacteria of, <a href="#Page_193">193</a></li>
-
-<li class="indx">Thermogenesis, <a href="#Page_140">140</a></li>
-
-<li class="indx">Time, <a href="#Page_69">69</a></li>
-
-<li class="indx">Tonus, muscular, <a href="#Page_119">119</a></li>
-
-<li class="indx">Trees, and immortality, <a href="#Page_330">330</a> <i>et seq.</i></li>
-
-<li class="indx">Tripod, vital, <a href="#Page_2">2</a>, <a href="#Page_314">314</a></li>
-
-<li class="indx">Turgescence, <a href="#Page_168">168</a></li>
-
-
-<li class="ifrst">Universe, the, mechanical explanation of, <a href="#Page_60">60</a>;</li>
-<li class="isub1">the end of the, <a href="#Page_95">95</a></li>
-
-<li class="indx">Unity, chemical, of living beings, <a href="#Page_173">173</a> <i>et seq.</i>, <a href="#Page_321">321</a>;</li>
-<li class="isub1">morphological, <a href="#Page_321">321</a>
-<span class="pagenum" id="Page_368">[Pg 368]</span></li>
-
-<li class="ifrst">Vacuoles, <a href="#Page_113">113</a></li>
-
-<li class="indx">Vibrion, septic, <a href="#Page_193">193</a></li>
-
-<li class="indx">Vis viva, <a href="#Page_73">73</a></li>
-
-<li class="indx">Vital properties, theory of, <a href="#Page_29">29</a> <i>et seq.</i></li>
-
-<li class="indx">Vitalism, <a href="#Page_6">6</a>, <a href="#Page_7">7</a>, Chap. iii. <i>passim</i>;</li>
-<li class="isub1">physico-chemical, <a href="#Page_29">29</a></li>
-
-<li class="indx">Vitality, phenomena of, <a href="#Page_216">216</a></li>
-
-<li class="indx">Vortex, vital, <a href="#Page_105">105</a>, <a href="#Page_120">120</a>, <a href="#Page_229">229</a> <i>et seq.</i></li>
-
-<li class="indx">Vulcans, <a href="#Page_26">26</a>-7</li>
-
-
-<li class="ifrst">Weight, energy of position, <a href="#Page_64">64</a>;</li>
-<li class="isub1">conservation of, <a href="#Page_65">65</a>;</li>
-<li class="isub1">movement under action of, <a href="#Page_271">271</a> <i>et seq.</i></li>
-
-<li class="indx">Work, <a href="#Page_70">70</a>, <a href="#Page_72">72</a>;</li>
-<li class="isub1">and force, <a href="#Page_74">74</a>, <a href="#Page_77">77</a>;</li>
-<li class="isub1">converted into heat, <a href="#Page_92">92</a>;</li>
-<li class="isub1">physiological, <a href="#Page_103">103</a></li>
-
-
-<li class="ifrst">Xanthic bases, <a href="#Page_180">180</a></li>
-
-
-<li class="ifrst">Zones, metastable and labile, <a href="#Page_301">301</a></li>
-</ul>
-
-
-
-
-<p class="center spaced"><span class="fs2">THE WALTER SCOTT PUBLISHING COMPANY, LTD., FELLING-ON-TYNE.</span></p>
-
-
-<div class="footnotes"><h2>FOOTNOTES:</h2>
-
-<div class="footnote">
-
-<p><a id="Footnote_1" href="#FNanchor_1" class="label">[1]</a> In a
-thesis presented in 1742 at Montpellier, Bordeu, then only twenty years
-of age, made game of the tasks imposed by animists on the Soul, “which
-has to moisten the lips when required;” or, “whose anger produces the
-symptoms of certain diseases;” or again, “which is prevented by the
-consequences of original sin from guiding and directing the body.”</p>
-</div>
-
-
-<div class="footnote">
-
-<p><a id="Footnote_2" href="#FNanchor_2" class="label">[2]</a> Reinke, <i>Die Welt als That</i>; Berlin, 1899.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_3" href="#FNanchor_3" class="label">[3]</a> In an article on the experimental method recently published
-in the <i>Dictionnaire de Physiologie</i>, M. Ch. Richet writes as
-follows:—“We must therefore never cease to carry out comparative
-experiments. I do not hesitate to say that this
-comparison is the basis of the experimental method.” It is in
-fact what was taught by Claude Bernard in maxim and by
-example. It is no exaggeration to assert that nine-tenths of the
-errors which take place in research work are imputable to some
-breach of this method. When an investigator makes a mistake,
-save in the case of material error, it is almost certainly due to the
-fact that he has neglected to carry out one of the comparative
-tests required in the problem before him. The following is
-an instance which happened since the above pages were
-written:—Several years ago a chemist announced the existence
-in the blood serum of a ferment, lipase, capable of
-saponifying fats—that is to say, of extracting from them the fatty
-acid. From this he deduced many consequences relative to the
-mechanism of fermentations. But on the other hand, it has
-been since shown (April 1902) that this lipase of the serum
-does not exist. How did the error arise? The author in
-question had mixed normally obtained serum with oil, and he
-had noted the acidification of the mixture; he assured himself
-of the fact by adding carbonate of soda. He saw the alkalinity
-of the mixture, serum + oil + carbonate of soda, diminish, and he
-drew the conclusion that the acid came from the saponified oil.
-He did not make the comparative test, serum + carbonate of
-soda. If he had done so, he would have ascertained that it also
-succeeded, and that therefore as the acid did not come from
-the saponification of the oil, since there was none, its production
-could not prove the existence of a lipase.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_4" href="#FNanchor_4" class="label">[4]</a> Le Dantec has objected to this conception of phenomena
-common to different living beings. He insists that all
-phenomena which take place in a given living being are
-proper to him, and differ, however slightly, from those of
-another individual. The objection is more specious than real.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_5" href="#FNanchor_5" class="label">[5]</a> Mayer’s claim to fame has been disputed. A Scotch physicist,
-P. G. Tait, has investigated the history of the law of the conservation
-of energy, which is the history of the idea of energy.
-The conception has taken time to penetrate the human mind,
-but its experimental proof is of recent date. P. G. Tait finds an
-almost complete expression of the law of the conservation of
-energy in Newton’s third law of motion—namely, “the law of the
-equality of action and reaction,” or rather, in the second explanation
-which Newton gave of that law. In fact, it was from
-this law that Helmholtz deduced it in 1847. He showed that
-the law of the equality of action and reaction, considered as a
-law of nature, involved the impossibility of perpetual motion,
-and the impossibility of perpetual motion is, in another form, the
-conservation of energy.</p>
-
-<p>At a meeting of the Academy of Science, at Berlin, 28th
-March 1878, Du Bois-Reymond violently attacked Tait’s contention.
-The honour of having been the first to conceive of the
-idea of energy and conservation was awarded to Leibniz.
-Newton had no right to it, for he appealed to divine intervention
-to set the planetary system on its path when disturbed by accumulated
-perturbations. On the other hand, Colding claims to
-have drawn his knowledge of the law of conservation from
-d’Alembert’s principle. Whatever may be the theoretical
-foundations of this law, we are here dealing with its experimental
-proof. According to Tait, the proof can no more be
-attributed to R. Mayer than to Seguin. The real modern
-authors of the principle of the conservation of energy, who gave
-an experimental proof of it, are Colding, of Copenhagen, and
-Joule, of Manchester.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_6" href="#FNanchor_6" class="label">[6]</a> It must be added that the absolute rigour of this law has
-been called in question in recent researches. It would only
-have an approximate value.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_7" href="#FNanchor_7" class="label">[7]</a> The dyne is the force which applied to the unit of mass
-produces a unit of acceleration.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_8" href="#FNanchor_8" class="label">[8]</a> These words spoil the statement, for time has nothing to
-do with it.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_9" href="#FNanchor_9" class="label">[9]</a> We therefore notice that the measures of force and work
-bring in mass, space, and time. The typical force, weight, is
-given by w = mg. On the other hand, we have by the laws of
-falling bodies <i>v</i> = <i>gt</i>; <i>s</i> = 1∕2<i>gt<sup>2</sup></i>;
-whence <i>g</i> = 2<i>s</i>∕<i>t<sup>2</sup></i>; <i>w</i> = <i>m</i>(2<i>s</i>∕ <i>t<sup>2</sup></i>); or, if
-F be the force, M the mass, L the space described, and T the
-time, we have F = MLT<sup>-2</sup>, which expresses what are called the
-dimensions of the force—that is to say, the magnitudes with their
-degree, which enter into its expression. We may thus easily
-obtain the dimensions of work:—</p>
-
-<p>
-<i>Work</i> = <i>f</i> × <i>s</i> = <i>mv<sup>2</sup></i>∕2 = ML<sup>2</sup>T<sup>-2</sup>.<br />
-</p>
-
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_10" href="#FNanchor_10" class="label">[10]</a> The reason is to be found in the large number of indeterminates
-in the problem we have to solve. It will be sufficient
-to enumerate them: the two substances which exist in the
-anatomical element, protoplasm and reserve-stuff, to which
-are attributed contrary roles; the two conditions attributable
-to the protoplasm, of manifested or latent activity; the faculty
-possessed by both of being prolonged for an indeterminate
-period, and of encroaching each on its protagonist when its
-existence is at stake. Here are more elements than are necessary
-to explain the positive or negative results of all the
-experiments in the world.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_11" href="#FNanchor_11" class="label">[11]</a> There is another reason why the rôle of mechanical energy,
-compared with that of thermal energy, is reduced, in the partition
-of afferent, alimentary energy—at least, in animals which have not
-to do excessive work. The unit of heat, the Calorie, is equivalent
-to 425 units of work—<i>i.e.</i>, to 425 kilogrammetres. In the animal
-at rest, the number of kilogrammetres representing the different
-quantities of work done is small, the number of corresponding
-Calories is 425 times smaller. It becomes almost negligeable in
-comparison with the considerable number of Calories dissipated
-in the form of heat.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_12" href="#FNanchor_12" class="label">[12]</a> It is not certain, however, that all the precautions taken
-have the desired result. You cannot entirely deprive meat of its
-carbohydrates.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_13" href="#FNanchor_13" class="label">[13]</a> M. Le Dantec, of whose philosophical and rigorously
-systematic mind I have the highest opinion, has laid down a
-new conception of life, the essential basis of which is this very
-distinction between elementary life and ordinary life; between
-the life of the elements or of the beings formed from a single
-cell, protophytes and protozoa, and the life of ordinary animals
-and plants, which are multicellular complexes, and for that
-reason called <i>metazoa</i> and <i>metaphytes</i>.</p>
-
-<p>Further, in the <i>elementary life</i> peculiar to monocellular
-beings (protozoa and cellular elements), M. Le Dantec distinguishes
-three manners of being:—The first condition, which
-is elementary life manifested in all its perfection, cellular
-health; the second condition is deteriorated elementary life,
-<i>cellular disease</i>; and the third condition, which is <i>latent life</i>.
-I should say at once that in so far as the fundamental distinction
-of the phenomena of <i>elementary life</i> and those of the
-general life of animals and ordinary plants, metazoa or metaphytes
-is concerned, we find it neither justified nor useful.
-And further, <i>manifested elementary life</i>, as M. Le Dantec
-understands it, would only belong to a small number of
-<i>elementary beings</i>—for the protozoa, starting with the infusoria,
-are not among the number—and to a still smaller number of
-<i>anatomical elements</i>, since among the vertebrates we recognize
-as almost the only elements satisfying it, the ovule, and perhaps
-the leucocyte. Physiologists, therefore, do not agree with
-M. Le Dantec as to the utility of adding one condition more to
-those we all admit—namely, manifested animal life and latent
-life.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_14" href="#FNanchor_14" class="label">[14]</a> Amylolytic ferments change starch and glycogen (<i>amyloses</i>)
-into sugar.—<span class="smcap">Tr.</span></p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_15" href="#FNanchor_15" class="label">[15]</a> Proteolytic ferments change proteids into peptones and
-proteoses.—<span class="smcap">Tr.</span></p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_16" href="#FNanchor_16" class="label">[16]</a> The enzyme known as lipase splits the fat or oil in germinating
-seeds into a fatty acid and glycerine.—<span class="smcap">Tr.</span></p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_17" href="#FNanchor_17" class="label">[17]</a> These ideas are clearly brought to light in a series of
-articles in the <i>Revue Philosophique</i>, published in 1879 under
-the title of “La problème physiologique de la vie,” and endorsed
-by A. Dastre in his commentary on the <i>Phénomènes communs
-aux animaux et aux plantes</i>.</p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_18" href="#FNanchor_18" class="label">[18]</a> Bear-animalcules, Sloth-animalcules. An order of Arachnida.—<span class="smcap">Tr.</span></p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_19" href="#FNanchor_19" class="label">[19]</a> Minute thread worms, known as paste-eels and vinegar-eels.—<span class="smcap">Tr.</span></p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_20" href="#FNanchor_20" class="label">[20]</a> Genus of Infusoria. Colpodea cucullus is found in infusions
-of hay.—<span class="smcap">Tr.</span></p>
-
-</div>
-
-<div class="footnote">
-
-<p><a id="Footnote_21" href="#FNanchor_21" class="label">[21]</a> Lately destroyed in a storm. [Tr.]</p>
-
-</div>
-</div>
-
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