SCIENCE REMAKING
THE WORLD

Brown Bros.

THE FIRST OIL WELL IN THE UNITED STATES

On Oil Creek in Pennsylvania. Col. E. L. Drake, shown in the picture
with the high hat, began work on this well May 20, 1859, and on August
27 of the same year struck oil at a depth of 695 feet. The well produced
thirty barrels a day for a year

OTIS W. CALDWELL

Ph. D* Director of the Lincoln School of Teachers College, and
Professor of Education, Columbia University

EDWIN E. SLOSSON

Ph. D., Editor, "Science Service19

SCIENCE

REMAKING

THE WORLD

GARDEN CITY PUBLISHING CO., INC.

GARDEN CITY, NEW YORK

CGPTRIGHT, 1922, 1923, BY DOUBLBDAr,
PAGE & COMPANY. ALL RIGHTS RESERVED.
PRINTED IN THE UNITED STATES AT THB
COUNTRY LIFE PRESS, GARDEN CITY, N. Y.

PREFACE

DURING the summer of 1922, nineteen men cooper-
ated in presenting a course of lectures in Teachers Col-
lege, Columbia University. The purpose of the course
was primarily to provide interesting and engaging in-
formation about the achievements of modern science.
It attempted to give students of all subjects an under-
standing of certain types of achievements of modern
science, to suggest the meaning of science in various
aspects of modern life and thought; to indicate the
place of science in modern, social, and industrial rela-
tions. Before half of the lectures had been presented,
hundreds of listeners had requested me, as organizer ot
the course, to assemble and publish part of the lectures
and if possible, to find means for wide distribution of
the resulting volume. In my desire that the volume,
when published, might benefit from the unusual style
and scientific clarity of Dr. E. E. Slosson, his assis-
tance was successfully importuned in the venture. Then,
a gracious and generous though anonymous benefactor
agreed to finance the placement of a limited number of
copies of the proposed volume in libraries of educational
institutions. Finally, the publishers cooperated by pro-
viding at bare cost of production the first lot of copies for
general distribution, depending upon later sales for their
profits from the publication. The authors and the

I

vi PREFACE

editors have contributed their services without personal
remuneration, and have done this as a welcome privilege
in helping to extend the achievements and underlying
truths of this most conspicuous field of modern thought.
Not all the lectures which were given in the course are
available; also changes which are advisable for publica-
tion have been made; and Dr. Kellogg and Dr. Williams
have kindly added chapters upon topics of wide interest
and importance.

Why give such a course of lectures, and why publish
such a volume? Because the citizen of our day uses
modern science at each turn of his day's work. If he
is a thinking citizen, he is ambitious to benefit by what
he understands as scientific procedure in using facts,
principles, and occurrences. A manufacturer wants
his operators to possess whatever knowledge of ma-
terials and processes science has produced for the
improvement of quality and quantity of output. A
lawyer or preacher desires factual illustrative material
from the working world of science with which to make
his case clear and convincing. If this citizen is a teacher
of any subject or grade he deals with the biggest science
need of all, for those whom he teaches belong to an age
which science has made unlike any of its predecesssors.
To men in industry, commerce, and the professions, it is
of increasing importance that progressive workers shall
have knowledge not only of accomplishments of science,
but of the methods by which discoveries are made.

Some thirty years ago Louis Pasteur said :

In our century science is the soul of the prosperity of nations and
the living source of all progress. Undoubtedly, the tiring daily

PREFACE vii

discussions of politics that seem to be our guide are empty appear-
ances. What really leads us forward are a few scientific discoveries
and their applications.

And the following is quoted from a recent statement
by President James R. Angell:

Nothing can be more certain than that the character and rapidity
of our national development in all matters which relate to industry,
agriculture, public health and the preservation of the physical
framework of our civilization will be dependent upon the quantity
and quality of sound research which is carried on. The truth of
this assertion becomes even more apparent when one recognizes the
fact that every modern nation stands in relation of industrial and
commercial competition with other nations, and, in the measure in
which this is true, to fall behind the others in scientific development
is to precipitate a trend of events which spells national depression
and disaster. In other words, the price of a sound, comprehensive
national life is, in these times, widespread and intelligent scientific
research.

Men need and desire a genuine interpretation of
modern science as it appears in the home, street, and
factory. They want to know its meaning in public
health, in industry, in social relations, and above all
in the adjustment of their philosophy to the scientific
truths of the modern world.

This volume is especially designed to assist the
teacher of courses in general science or the special
sciences by bringing textbooks up to date and suggest-
ing possible occupations to young people who really
need guidance in finding callings which appeal to them
as fields of opportunity and usefulness.

It is expected also that the public will find this volume
a convenient and engaging means of catching up with

viii PREFACE

the progress of modern science. Every intelligent
person, whatever his professional interests, has a nat-
ural curiosity to know something about the new things
in science, as well as in art, literature, drama, and world
events. But it is not so easy to keep in touch with the
advancement of science since comprehensible compen-
diums of recent researches are hard to find. At the end
of each chapter there has been appended a list of several
recent and reliable books and articles, both technical
and popular, for the convenience of readers who seek
further information.

The reader will notice that in almost every chapter
there is given, besides an explanation of recent discov-
eries and applications, some account of the efforts that
have led to them and of the personalities concerned
in them. This unusual feature is due to a theory of
the editors of the volume that more attention should
be paid to scientific history and biography. They be-
lieve that one of the reasons why science is commonly
regarded by the public as dry is that it has been too
completely divested of its human interest. It is im-
portant for the public to understand that scientific
progress is not a mere series of the lucky accidents and
happy inspirations of a few favoured individuals, but
a long and toilsome process of investigation, hypothe-
cation, and verification on the part of many workers
who often follow fallacious theories and turn into blind
alleys from which they have to find their way back to
the highway leading toward truth.

OTIS W. CALDWELL.

CONTENTS

ACHIEVEMENTS AND OBLIGATIONS OF MODERN rjuom

SCIENCE I

Otis W. Caldwell, Ph.D.

GASOLENE AS A WORLD POWER 12

Edwin E. Slosson, Ph.D.

THE INFLUENCE OF COAL-TAR ON CIVILIZATION 48
Edwin E. Slosson, Ph. D.

ELECTRONS AND How WE USE THEM ... 78
John Mills, M.A.

AN INVESTIGATION ON EPIDEMIC INFLUENZA . 99
Peter K. Olitsky, M.D., and Frederick L.
Gates, M.D.

OUR PRESENT KNOWLEDGE OF TUBERCULOSIS . 115
Linsly R. Williams, M.D.

Louis PASTEUR, AND LENGTHENED HUMAN LIFE

Otis W. Caldwell, Ph.D. 133

INTERNATIONAL PUBLIC HEALTH 150

George E. Vincent, Ph.D.

x CONTENTS

EDUCATIONAL VALUE OF MODERN BOTANICAL PAOB

GARDENS 102

George T. Moore, Ph.D.

THE MEANING OF EVOLUTION 167

John M. Coulter, Ph.D.

OUR FIGHT AGAINST INSECTS 19x5

L. O. Howard, Ph.D.

INSECT SOCIOLOGY 199

Vernon Kellogg, Ph.D.

How THE FORESTS FEED THE CLOUDS . . . 212
Raphael Zon, F.E.

THE MODERN POTATO PROBLEM 223

Charles O. Appleman, Ph.D.

CHEMISTRY AND ECONOMY OF FOOD .... 247
Henry C. Sherman, Ph.D.

OUR DAILY BREAD AND VITAMINS .... 265
Walter H. Eddy, Ph.D.

SCIENCE REMAKING
THE WORLD

SCIENCE REMAKING
THE WORLD

ACHIEVEMENTS AND OBLIGATIONS
OF MODERN SCIENCE

BY OTIS W. CALDWELL, PH.D.

Teachers College, Columbia University

A FEW years ago at a New York City luncheon, a
business acquaintance expressed a keen desire
to have a conference with a Chicago scientific
friend of one of the luncheon guests. He said: "Will
you not telephone him and see if he will meet me in
New York to-morrow ? " Thus, at 1 2 : oo noon, the tele-
phone connection with Chicago was made, a conversa-
tion held with the friend, and at 12:45 P-M- tne Chicago
scientist took his train. At 10 o'clock next day the
conference was held in New York, and at 2:45 P.M.
the man of science was on his return journey which
placed him in Chicago next morning, ready for his
regular day's work. What an age in which to live!
A science man, almost a thousand miles away, is needed
for a conference. The telephone permits a brief con-
versation with words so clear that the peculiarities of
friends' voices are heard almost as in the speaker's

2 SCIENCE REMAKING THE WORLD

presence. A modern train transports the passenger
while he eats, sleeps, and writes his plans for his meeting.
The necessary conference is held next morning, and the
following morning he is back at his regular post.

This ready and effective communication and dizzy
speed of travel have become ordinary and slow, as
modern science continues to work. By wireless we
speak not merely from New York to Chicago or to
'San Francisco, but over the oceans — around the earth
in a few relays. So rapidly is science improving com-
munication that we hesitate to write of "wireless,"
knowing full well that what we say will be out of date,
possibly, before the statements appear on the printed
page. And what of human transportation? The
Twentieth Century, the Broadway Limited, or the
Transcontinental Express, apparently creeps along as
the modern airplane above speeds on its way. A regu-
lar service route is proposed which will permit the pas-
senger to dine in New York or Chicago, go to a theatre,
then take his airplane sleeper, and breakfast in the
other city. Even the erstwhile astounding feat of a
non-stop flight in twenty-seven hours from New York
to San Diego has ceased to give us its early thrill, so
confident are we that modern science contains possi-
bilities surpassing our wildest expectations. "Twenty
thousand leagues under the sea" no longer seems
fanciful. "You can no more do that than you can fly,"
is now meaningless. "Voices passing through the air,"
is now so true that even we as speak to one another
there may be passing through the atmosphere about
you unseen messages pertaining to peace and war, love

MODERN SCIENCE 3

and hate, commerce, industry, government — every
topic which holds men's minds — all being transmitted
through a common medium, none necessarily interfering
with any other. Surely the imagery of the past seems
trivial when compared with the reality of to-day.

Science has successfully attacked many of the ills to
which men succumb. We need not now have smallpox
unless we prefer not to do the things which science has
shown will prevent this disease. Typhoid, far less
common than two decades ago, is so well understood
and its transmission so definitely associated with un-
cleanliness that we shall soon see the day when it will
be not only unfortunate but not respectable to have the
disease. It would now be more indecent to have
typhoid than it is to have the "itch," were each person
as fully in control of his own personal environment for
cne one disease as for the other. Yellow fever, the
awful plague of many countries, not only can be de-
stroyed, but has actually been destroyed in certain of
its worst centres. It is a picturesque campaign now
Deing waged, one with a vision of service to the human
race, to remove yellow fever from the earth. The most
dreaded disease of all, perhaps, tuberculosis, is slowly
but surely yielding. Though big tasks are ahead,
enough is now known and proved in practice with tu-
berculosis patients to give abundant hope to hundreds
of thousands of discouraged people who have this dis-
ease. It is but a brief time since a clear diagnosis of
tuberculosis was all but a death warrant. Surely sci-
ence is making the earth a better home for men.

In instruments of warfare science has produced an

4 SCIENCE REMAKING THE WORLD

antithesis not yet understood by men. In the World
War the airplane dropped bombs within the range over
which the airplane could fly. The dirigible balloon
could carry heavier bombs over a longer range, but the
gas which carried the dirigible aloft was highly inflam-
mable, and a gun shot through the gas bag meant con-
flagration and a terrible death to those who were in the
balloon. But a scientist studying the sun found
helium in the sun's chromosphere. Of what use to us
would the sun's helium be? Then helium was found
in a mineral in the earth. Helium, lighter than air,
was not inflammable, was not easily affected by electric
currents — thus an ideal gas for dirigible balloons.
Helium, supposedly very rare, could be secured only
at a cost of something like $1,500 per cubic foot, and a
large dirigible balloon requires a million or more cubic
feet of the gas. Then another scientist discovered that
helium may be secured from natural gas and the gas be
improved for domestic use when the helium is removed.
Later developments will permit men now to secure large
quantities of helium at a cost of a few cents per cubic
foot. Thus dirigible balloons may be floated on the
air by a non-inflammable, non-electrifiable gas at
heights and over distances hitherto thought impos-
sible.

During this development, new discoveries regarding
explosives have increased their efficiency, so that now
it is said that a single ton of the highest explosive will,
if advantageously placed, serve to destroy the largest
existing battleship. Or if the bomb is loaded with the
latest destructive gases, it will snuff out the life of all

MODERN SCIENCE 5

the occupants of a modern city. Helium gas for use in
balloons, other new substances for modern explosives
and killing gases — these are instruments of destruc-
tion which will completely change warfare in its meth-
ods. Even modern battleships are now said to be
obsolete, since none is protected against modern scien-
tific bombs. Helium carried dirigibles may go anywhere
and drop destructive gases hundreds, even thousands,
of miles from the base of operations.

The achievements of science are very great both in
their number and in the magnitude of their influences.
Tremendously powerful for good and for ill as are the
material advantages gained through modern science, it
is possible that still greater advantages may be gained
through certain attitudes of thinking, judging, and
acting which modern science is patiently teaching to a
slowly learning human race. It is but a little while,
in the comparative history of men, since those who dis-
agreed too loudly with generally accepted ideas were
put to death. This was done presumably to show
others the terrible results of permitting one's thinking
processes to lead him to unconventional conclusions.
If a daring honest mind led one to say that the earth
is round, not flat, this thinker's life had to be taken, lest
his heresy should be accepted by others. If a patriot
questioned the divine rights of the king, this patriot was
thought to be dangerous to the common good. If one
claimed the right and accepted the responsibility of
thinking through and acting according to his own
conclusions regarding spiritual problems, his life was
endangered because his thinking might undo the sys-

6 SCIENCE REMAKING THE WORLD

terns then in vogue. Even in a country to which our
ancestors came in order to think freely, they themselves
soon began to shackle, and occasionally destroy, those
whose alleged freedom in thinking led to conclusions
unacceptable to those in authority. In the present age
of science and renewed belief in the power of truth, we
see the old and inevitable strife between those who do
and those who do not believe in the progressive nature
of truth. Attempted legislation against truth merely
increases the caution and obligation of inquiring minds,
thus helps to refine the inquiry and make the results
more secure. Certainly an attack upon a progressive
thinker cannot kill progressive thought, but rather by
antithesis creates one more spiritual monument in the
name of truth seeking. Legislation against truthful,
progressive thinking helps to advertise the issues in-
volved, and to cause plastic minds to desire to know.1
Even if legislative walls could be erected, progressive
truth would leak through, filter beneath, fly above, or,
radium-like, would radiate by processes too elusive, too
intangible, and too fundamental to be denied its logical
advance. Did the persecution of Columbus keep the
earth from being round, even though many of the ideas
of Columbus's times have since been found to be faulty?
Did the persecution of Harvey stop the complete cir-
culation of human blood, even though later investiga-
tions have corrected many of Harvey 's ideas? Could
legislation stop biological development even though
thousands of research workers are earnestly endeavour-
ing to ascertain unknown truths about the processes
involved ?

MODERN SCIENCE 7

During the unprecedented scientific development of
the past half century, there have frequently arisen cer-
tain tendencies on the part of men of science which have
caused many non-scientific persons to misunderstand
the real nature of scientific truth. A scientific discov-
ery is usually much involved in scientific terminology
and is complicated by its intellectual associations with
a field of special facts and theories. The public usually
does not understand the terminology or the related
facts and theories as does the scientific worker. Hence
the public cannot fully comprehend the discovery or
new line of thought. It is extremely difficult for the
worker to explain, since his field and even his vocabu-
lary are not sufficiently sensed to provide a common
basis of understanding. So the worker in science too
often belittles the "common man's" ability to under-
stand and too often makes no effort to inform him.
He does, however, more or less inconsistently expect
the "common man" to accept his conclusions in so far
as these scientific conclusions touch the fields in which
this "common man" operates. The man who knows
sometimes becomes intolerant toward the man who
does not know, quite as the uninformed man becomes
intolerant of the man who knows. Most men, most of
the time at least, desire to do what is right, and will
oppose or support an idea because their conclusions, or
their prejudices which they think are their conclusions,
seem right to them. The intolerance of scientific men
toward a public which is more or less uninformed about
science may easily become quite as objectionable in-
tellectually, and perhaps as dangerous socially, as the

8 SCIENCE REMAKING THE WORLD

intolerance of a group which is uninformed regarding
scientific matters.

Further, there is no monopoly of uninformedness.
Those who do not know science often do know much
of human nature or practical affairs, or of government,
or of literature, art, and social relations; and some
of these are equally essential in accomplishing the
things which are really worth while. It usually helps
to get the point of view of the other man, and also
increases the light of vision and reduces the heat of
friction.

One of the heaviest obligations on modern science
requires that it shall organize and present many of its
results so that these results may be seen and understood
by intelligent but non-scientific persons. People will
eventually follow the truth, but they cannot follow it
unless they can amidst their confusion see its light at
least often enough and clearly enough to enable then?
to keep the general direction in which truth is moving.
In our day they cannot be expected to follow truth too
constantly merely by the admonitions of someone
whose evidences are known to him but unknown to
them.

In the rapid development of science another serious
social need has arisen among the science men them-
selves. The separate sectors or divisions of science have
been so compelling in their interest, so gigantic in their
possibilities, and so exacting upon the time and energy
of specialists, that many specialists have lost perspec-
tive of the whole field of science, not to speak of the
other necessary human interests mentioned above.

MODERN SCIENCE 9

The specialist, however, like other people, guides his
life by the stars which he sees, and his conclusions about
affairs and people outside of his field are sometimes
seriously and harmfully limited. One can and must, if
he is a productive student, dig deep into a special sub-
ject. But deep wells, while suggestive of depth and
height of vision, are not suggestive of broad and
comprehensive views. The figure would better be
changed to that of a "skyscraper mind," which rises to
great heights and consequently may have broad and
dependable views, since it stands upon foundations
which are secure and since its structural materials are
those which will endure under the seasonal and human
exigencies of its working environment.

One of the greatest functions of our organizations of
science men is the bringing together of scientists from
various sectors of science and compelling them to learn
enough of the elements, at least, of the other fields, to
gain some understanding of the purposes, ambitions,
and accomplishments of other science men. It would
not be bad for science, nor for the public, if special-
ists were required to teach other specialists enough
to enable all to take a reasonably elementary exami-
nation upon the special fields of one another.

There is another supremely important function to be
served by means of a better public understanding of
modern science and its uses. Science knowledge, scien-
tific processes and appliances, have reached the stage
where ignorance means danger, sometimes destruction.
Far more people are killed at street crossings than be-
fore the gas motor became common property. The air-

io SCIENCE REMAKING THE WORLD

plane which "won the war" has exacted the life of many
of those who persisted in flying. Gasolene, which also
"won the war," is just coming under reasonably safe
control. To live in a scientific age, an age of rapidly
accumulating knowledge, imposes heavy obligations
upon education and upon the resultant social and in-
dustrial controls. In the presence of modern science
those who do not know cannot long survive, else they
must seek the primitive places of the earth where the
more elemental practices may persist for a time. Even
in these primitive places, science will soon catch up and
there will again recur the old biological requirement to
learn, to move, or to cease to exist.

But the hardest question is yet to come. Has the
common appreciation of moral obligations developed
to a point where it is socially safe for all science knowl-
edge to become common property? Can the common
moral sense be trusted? Does knowledge of those*
chemicals which will readily destroy human life ever
result in an easier suicide or in the more ready destruc-
tion of one's human enemies ? Poison gases and other
war inventions are so terrible that it is not even safe
to allow all citizens to know what a few inquisitive and
trusted scientific men have discovered. If a bio-
chemico-physicist were to discover just how to change
electrical potentials over an area twenty miles square,
so that the electrons of human protoplasm would in-
stantly break down, it would not as yet be morally safe
for the different nations to have possession of this
secret. Since science deals with progressive truth, it
should not omit its obligation toward better common

MODERN SCIENCE n

knowledge of useful scientific truth. It dare not omit
its due share of the obligation to have modern society
develop in moral ideals and controls so that constructive
and not destructive use of science shall result.

It is surely a heavy burden that is imposed upon
modern education. Exact knowledge and faithful in-
terpretations of science in themselves provide large
obligations. But the still larger one — without which
modern science is dangerous — asks that intellectual and
moral ideals and controls shall develop in harmony with
growth in possession of scientific knowledge.

GASOLENE AS A WORLD POWER
BY EDWIN E. SLOSSON, PH.D.

Director of Science Service, Washington

THE work of the world is done by sun power.
Whether it be done by the muscular labour of
horses or human beings, by the whirling of wind-
mills or water wheels, by the burning of wood, coal, or
oil, or by the swift and silent electric current, the energy
comes directly or indirectly from the solar reservoir.
"Give us this day our daily bread" is the same as saying
"Give us this day our daily sunshine." But the sun
does not shine every day and it cannot shine on all
sides of the earth at once and it favours different zones
at different times of the year.

So man in order to avoid the darkness of night and
the cold of winter invented a way of using the sunshine
of the past for present needs. According to the Greeks
fire was a gift of that foresighted Titan Prometheus
who stole fire from heaven and brought it down to man
in a hollow reed. For this crime he was chained to the
Caucasus and from his torn liver flowed a stream of
black petroleum. The Greek mythologists differ as to
whether Prometheus was ever released from his chains
or not, and we cannot count Shelley as an authority, but
the streams of petroleum have continued to flow in the
Caucasus to this day. The Zoroastrians came to wor-

12

GASOLENE 13

ship the Fountain of Everlasting Fire, rightly regarding
it as somehow a gift from the sun, though how they could
not tell, any more than can the modern geologists just
how the energy of the solar rays came to be embodied in
the blazing oil. Marco Polo, who passed through
Baku on his way to Far Cathay, says that a hundred
ships might be filled at a time from the lake of oil, and
he notes, quite correctly, that it is not good to eat but
good to burn and to cure the sore backs of camels.

To-day this same Caucasian oil, which was to the
Persians the object of adoration and to the Greeks the
subject of a grotesque story, is to the modern world a
source of power and the desire of all nations. It is the
only liquid asset of the Bolsheviki and their efforts to
bargain it off to the highest bidder broke up the Genoa
Conference and are holding up The Hague. From 1898
to 1901 a ten-mile square of the Baku district supplied
nearly half the world's output of oil and it is still the
greatest source of the Old World.

FIRST USES OF AMERICAN OIL. — But the United
States has been favoured above all other nations in the
endowment of oil, and it was here that it first became an
important factor in civilization. It was from the
earliest time used in Pennsylvania, as Marco Polo saw
it used five hundred years before in the Caucasus, to
cure the sore backs of beasts of burden. The Indians
spread their blankets on the creeks that carried a film
of oil and wrung them out. The product was sold to
the Whites as "Seneca Oil" for man and beast at $2
a gallon. A little more than a century ago a well was
being drilled for brine in Kentucky when there burst

14 SCIENCE REMAKING THE WORLD

out instead of salt water a stream of black oil that
literally set the river on fire. The Kentuckians as-
cribed it to a different supernatural source from the
Zoroastrians and called it "The Devil's Tar." Now-
adays values are reversed and the driller who strikes
brine instead of oil is disappointed.

In 1859 Drake of Titusville, Pennsylvania, put down
a well and thereafter sold Rock Oil at the rate of thirty
barrels a day. The value of the new fuel was now be-
ginning to be perceived, and after the war the great oil
boom set in and millions were gained and lost on paper
while petroleum and its products found their varied
uses. The great fortunes that are peculiar to our time
had their origin in petroleum and it would be impossible
to overestimate their influence in all fields of modern
life.

Why petroleum is an unprecedented wealth producer
and how it can be so readily monopolized by individuals
or governments can be easily seen by reference to its
geology and chemistry. In the first place petroleum
comes in pockets and is therefore readily pocketable.
It forms pools under pressure, pushed up from below by
water and held down from above by a dome of impervious
rock. The first man who drills through the rock gets the
oil, not only the oil under his own claim but much of
what seeps in from his neighbours' claims. Hence the
race to get down the first well in a new field. But great
haste means great waste. It is estimated that half the
oil is lost through lack of system in drilling. Much of
it runs off or is burned up before the well is brought
under control. More of it is left in the ground through

GASOLENE 15

the competitive drilling. At the other end of the pro-
cess, the consumption, at least half of the product is
wasted, either through burning the oil to make steam
when it might be used in internal combustion engines,
or by the careless use of the gasolene in automobiles.
On the other hand the intermediate part of the process,
the refining and transporting, being under unified
management and chemical control is carried on with
comparative efficiency and economy. Yet we hear
little complaint over the irreparable loss of some three
fourths of the world's supply in the drilling and the
using while there is furious and incessant denunciation
of those who carry on the distribution and distillation
because they have made so much money out of it. We
do not seem to care how much wealth is wasted but we
care dreadfully if somebody gets more than we do.

Mineral oil therefore lends itself naturally to monop-
oly because it is found in but few places in the world
and there concentrated in small space; it is also irre-
placeable and indispensable. But why has petroleum
such a close connection with wealth ? Here the chemist
can give the answer. Wealth is produced by the ex-
penditure of energy, human, animal, or inanimate.
The unprecedented accumulation of wealth within the
last hundred and fifty years is due to the utilization of
external inanimate energy, chiefly the heat of combus-
tion of fossil fuel in the steam and gasolene engine. In
America the greatest use has been made of such sources
and therefore this country is the richest in the world.
If measured in the ancient way in terms of man-power
we would each of us on the average have a train of

i6 SCIENCE REMAKING THE WORLD

twenty able-bodied slaves waiting on us day and
night.

This increment of energy, that has given to all of
us comfort and conveniences beyond the power of
petentates in former times, comes mostly from two
simple and similar chemical reactions, the union of
hydrogen and of carbon with oxygen, or in common
language, burning. The first reaction, the uniting of
hydrogen with the oxygen to form water gives more
heat than any other combination of elements. Hydro-
gen would, therefore, be the best possible fuel but for
two reasons. In the first place it is too expensive. It
is not found free in nature, except in natural gas, and
this is rare and running out. To get the hydrogen out
of water would require as much expenditure of energy
as we should get out of it by burning it back again to
water. Secondly, hydrogen is a gas and therefore not
convenient to carry around. It would not be conveni-
ent to have a big gas bag hitched to your car like a cap-
tive balloon. It is true hydrogen can be liquefied but
it does not stay so and it is then exceedingly cold.

Carbon is tolerably abundant in many countries in
the form of coal. But carbon has less than one fourth
the heating power per pound that hydrogen has.
Carbon, being a solid, is handier to use than a gas like
hydrogen, but not so handy as a liquid would be. A
solid has to be shovelled. A liquid will flow. Coal
has to be mined and hoisted up from the ground.
Petroleum is so anxious to get out that it will blow off
the rigging when its rock prison is tapped.

What, then, would be the ideal fuel if we could have

GASOLENE 17

just what we wanted? It would be composed only of
hydrogen and carbon. It should give on complete
combustion only water and carbonic dioxide, innocuous
final products, already in the air. It should contain
no ash; leave no solid residue to foul the cylinder. It
should contain just as much hydrogen and as little car-
bon as possible. It should be a liquid at ordinary tem-
peratures but be easily converted to a gas for combus-
tion. It must not rot on keeping or freeze on cooling.
It should not contain water because that reduces the
heating power. Preferably it should look nice and
clear like water and not stain things. It must not have
a disgusting odour like carbon disulfide, though we will
not insist upon absolute odourlessness or a pleasant
perfume.

Now all these requirements are found in gasolene and
in that only. The compounds of carbon and hydrogen
are constructed like a chain. Each link is composed
of one carbon atom connected with two hydrogen atoms.
The first of the series and the simplest possible is me-
thane, CHU, but that is a gas. So is the next, but when
we get along to the fifth and sixth members of the
methane series we get to liquids of the gasolene group.

JUST WHAT Is GASOLENE ? — Gasolene is not a single
and uniform substance. You who use it know that it
varies in quality, especially in volatility. It is simply
the lightest part of petroleum, the part that comes over
at the lowest temperature when the distillation of
petroleum begins. Next comes kerosene, and then the
heavy lubricating oils, and later vaseline and paraffin,
le asphalt is left behind in the still. Formerly, when

18 SCIENCE REMAKING THE WORLD

there was no demand for gasolene, as much of it was run
into the next fraction, the kerosene, as it would stand
without blowing up in the lamps. Each state had to
have an oil inspector whose duty it was to see that no
kerosene was sold that had an ignition point below the
safety point of the lamps. There is now no difficulty
on that score because the temptation is all the other
way, to run the heavier kerosene fractions into the
gasolene until it becomes too heavy to burn and the
motor knocks. In the early days the gasolene, being in-
jurious to the illuminating oil and not being much
wanted anywhere, was allowed to run from the re-
fineries into the streams, where it sometimes took fire.
When the introduction of the automobile created a
demand for gasolene the refiners awoke to the fact that
they had been wasting one of the most valuable parts of
the petroleum. Then they began to save and sell their
lighter distillates which under ordinary conditions
amounted to about 1 1 per cent, of the crude oil.

But with the multiplication of motors this did not
suffice. It became necessary to break up the heavy
oils into light oils, which meant breaking up the big
molecules into little molecules. Nobody knows ex-
actly how petroleum was formed in the first place, nor
even what it was made out of. But presumably it was
made from masses of vegetable matter subjected to heat
and pressure. If, then, we could reproduce those con-
ditions we could shatter this sorry scheme of things and
remould it nearer to the heart's desire.

This was accomplished by W. W. Burton, president
of the Standard Oil Company of Indiana, who worked

GASOLENE 19

out a scheme of distillation under pressure which
cracked up the heavy oils into lighter fractions. To-day
the Standard Oil Company of Indiana has 800 pressure
stills which can produce 2,000,000 gallons of gasolene
a day. This makes possible the running of 2,000,000
motor cars. In recognition of this achievement the
American Chemical Society bestowed upon Mr. Burton
the medal that bears the name of Perkin, the discoverer
of the first coal-tar dye. The profits of this process are
so great that stock in the Standard of Indiana bought for
#100 in 1911 would be worth $37,200 ten years later.
Crude oil is now made to give on the average 28.5 per
cent, of gasolene by cracking and this amounts to 54.4
per cent, of the value of its products.

Another new source of motor fuel is the saving of the
gasolene vapours that are contained in natural gas.
These used to be lost but are now condensed by cooling
and provide about 8 per cent, of our present supply.

What the invention of the steam engine did for the
world we can read about in any modern history. What
the invention of the gasolene engine has done we can
see for ourselves if we only look about us. The signing
of the Declaration of Independence in 1776, which we
yearly celebrate by going on a picnic, was a much less
important event in the history of the world, even in
our own history, then the contemporary discovery of
the possibilities of steam power. Watt has had more
influence over the current of human affairs than Wash-
ington.

The Age of Steam lasted a hundred years. In 1876,
when we were celebrating our Centennial at Philadel-

20 SCIENCE REMAKING THE WORLD

phia, the rival and superior of the steam engine was
born. Doctor Otto of Cologne, Germany, in that year
made the first practicable engine run by the explosion
of a mixture of gas and air instead of by the expansive
force of steam. The steam engine was not thereby put
out of business. It will continue in the service of man-
kind so long as the coal holds out and perhaps longer.
But the internal-combustion engine is more powerful
and compact, simpler and more economical, and it has
already within the observation of all of us gone farther
and come into our lives more intimately than the steam
engine ever did. The agile auto climbs mountain
trails where the railroad cannot go, and reaches com-
munities that have never been awakened by the whistle
of a locomotive. It has made engineers out of our boys
and girls. No schools could teach mechanics as widely
and practically as the auto has. Gasolene has given to
man the wings he has always longed for but which he
had despaired of getting until he got to heaven. It hag
enabled men to go down to the sea in ships on their
more or less lawful occasions. It has multiplied the
magnitude of man by giving him the power to contract
all four of the dimensions within which his activities are
confined, the three dimensions of space and the fourth
dimension of time.

What is there about the gas engine that gives it this
manifold power and adaptability? Wherein does it
differ from the old steam engine? It is not merely in
using a different kind of fuel, as some seem still to sup-
pose. It is a different kind of motive power. In their
fundamental principles, however, the two are alike.

GASOLENE 21

What, to begin with, does man want of an engine? He
wants it usually to turn a wheel. And right here man
shows his superiority to all other animate beings, for
none of them makes use of a wheel. Man has no wheels
in his body, whatever he may have in his head. If he
wants, say, to turn a grindstone, he must do it by a to-
and-fro motion of his arm. But in the course of many
thousand years man got tired of this and then it oc-
curred to him to shift the work from his muscles to the
molecules. Man is naturally a shifter; therein lies the
secret of his progress. Where could man find a multi-
tude of molecules which would be so manageable that he
could make them work for him for nothing? He found
them where Lenin and Trotzky found their docile
Bolsheviki, in a state of anarchy. In any gas the mole-
cules have lost all sense of solidarity and reached a state
of complete freedom and independence such as man
fortunately has never been able to attain. It is self-
determination carried to the limit, for in any gas each
molecule is at liberty to do what it likes without regard
to what any other molecule may do. Every molecule
therefore goes straight ahead in its own way until it runs
up against some other molecule or a wall; then it gives
the obstacle a kick and goes off in some other direction.
The kick is light since the molecule is small, but if all
the kicks could be combined and turned in one direction
they would amount to something and could be used for
something. Force directed by intelligence produces
power, and power directed by intelligence produces prog-
ress. As soon as man acquired the intelligence he util-
ized the aimless force of the molecules knocking against

*2 SCIENCE REMAKING THE WORLD

the prison walls of the containing vessel as a motive
power for his own purposes. This was accomplished
by the simple expedient of making one of the partitions
movable. If a crowd of molecules are imprisoned in a
steel cylinder they bump incessantly against all the sides
equally as though trying to get out. If, now, one of
the ends is a piston head, slipping easily in the cylinder,
this gets shoved out by the constant pounding until
finally the exhausted molecules make their escape into
the open air.

WHAT HAPPENS IN AN ENGINE? — If the molecules
are crowded into a prison half the size by shoving in the
piston partition they naturally knock against it twice
as often. This observation is so obvious that you will
probably not appreciate it properly until you know that
it is called "Boyle's Law." Then again if you shove
in the piston head suddenly and crowd the molecules
into smaller space they naturally get hot about it and
do more knocking than ever. The hotter they get the
harder they pound against the prison walls. This also
is so easy to see that you will not get credit for it, even
from yourself, unless you dignify it by calling it the
"Law of Charles" and expressit in such words as: "The
pressure of a gas at constant volume is proportional to
the absolute temperature."

Having now in mind the two laws that all anarchic
molecules obey we can see how we can get the most work
out of a given number of them. Obviously this will be,
first, to confine them in the smallest space and force
them to fight their way out to the largest possible space.
Secondly, to get them as hot as possible and let them

GASOLENE 25

cool off as completely by exhaustion. Or in other words,
the efficiency of an engine depends upon getting the
longest possible range of pressure and temperature be-
tween the beginning and the end. The automobile is
run by two horses, heat and cold. The higher the
heat and the lower the cold, the greater the power.

We can use any gas we like for our engine, for all
gases behave about the same. Naturally steam was the
first gas used in the cylinder. But steam has to be
made separately in a boiler and then conducted into
the cylinder. And a boiler is a bulky thing and oc-
casionally blows up. To heat the boiler there must
be a furnace and to the furnace there must be attached
a tall chimney to create a draft. A pile of coal must
be at hand and a stoker to shovel it in. If the engine
is large and complicated there must be an engineer, duly
licensed and a member of the union. There is inevit-
ably tremendous waste of potential energy, for the steam
has at best a small fall of temperature while it is doing
its work in the cylinder. It is not nearly so hot as the
furnace gases which are lost up the chimney.

If in some way we could combine the furnace and
the boiler and burn the fuel in the cylinder itself, right
where we want to do the work, we could take ad-
vantage of the high temperature to get high pressure
and simplify the apparatus. This is just what is done
in the gasolene engine. The cylinder is made the fur-
nace. Fill it up, by a jerk of the piston rod, with air
mingled with a little vaporized gasolene, set it afire with
an electric spark. The carbon and the hydrogen of the
gasolene unite with the oxygen of the air, forming car-

24 SCIENCE REMAKING THE WORLD

bon dioxide and steam. The heat of combustion raises
both these gases to a high temperature and therefore to
a high pressure and the piston is pushed out and turns
the wheel, and there we are. We have done away with
the big boiler, the tall smokestack, the fiery furnace, the
pile of coal, the skilled engineer and the fireman. We
can have a range of temperature two or three times as
great in the gas engine as in the steam engine and so get
two or three times the efficiency. That is, more than
twice the percentage of the total energy in the fuel may
be got out in the form of usable energy by the gasolene
engine besides its advantages in compactness, clean-
liness and convenience. No wonder then that it has
transformed the conditions of modern life.

The steam engine and the gas engine passed from
peaceful competition to armed conflict in 1914 and the
newer motive power won the war. Senator Berenger
of France said that the Germans expected to win be-
cause they had the advantage over France in coal.
But the Allies won with the aid of oil. "It was a vic-
tory of the automobile over the railroad," he says.
This is confirmed by Lord Curzon, who said: "The
Allied cause was floated to victory on a wave of oil."

We first realized the possibilities of the new military
machine in September, 1914, when we read that the
taxicabs and omnibuses of Paris had been mobilized
to carry Gallieni's army out from the capital to attack
Von Kluck's invading forces in the rear and aid in
driving them back from the Marne.

From that time on both parties relied more and more
upon the mobility of the motor. Germany, having no

GASOLENE 25

oil fields of her own, was forced to seek a supply in
Poland and Roumania and so turned her attention
from France and Belgium to the eastern front.

Thanks to the supply of American petroleum the
steady line of camions was kept going into Verdun and
so the enemy did not pass the cornerstone of the French
frontier. But in December, 1917, the French petroleum
trust notified their government that their stock would
be exhausted by the following March and that they
could not supply the army in time to meet the German
spring attack. The monthly consumption of gasolene
was 30,000 tons and the stock had fallen to 28,000 and
soon would be reduced to nothing. Then Premier
Clemenceau sent an urgent cablegram to President
Wilson, personally requesting him to use his authority
to bring the 100,000 tons of tankers from the Pacific to
the Atlantic where they might replace those that the
Germans had sunk. M. Clemenceau closed his appeal
with the words: "If the Allies do not want to lose the
war it is necessary that fighting France, in the hour of
the supreme German shock, should possess the gasolene
which is as necessary as blood in to-morrow's battle/'

President Wilson complied, and the Petroleum War
Board supplied the ships used to bring the motor fuel
to France. Thanks to this prompt action Foch was able
to send an auto army to fill the gaps next spring when
the British gave way before the German drive toward
Amiens.

It is not necessary for me to speak of the gasolene-
driven submarines, for what they did and what they
nearly did is all too fresh in the memory of us all. But

26 SCIENCE REMAKING THE WORLD

we should recall that the swift motor boats that guarded
the coasts were also run by gasolene.

Nor can I stop to discuss what the new art of aviation
meant in the war. Leonardo da Vinci designed a fly-
ing machine but it had to wait for five hundred years
for a motor light and strong enough to carry it through
the air. But aviation as yet plays little part in our
everyday lives so let us turn to the automobile, whose
influence we can observe for and on ourselves.

In 1896 there were only four gasolene cars in the
United States. To-day there are 10,000,000. Of these
four pioneer automobiles, one was built by Elwood
Haynes of Kokomo, Indiana, one by Henry Ford of
Detroit, one by C. E. Duryea of Pennsylvania, and one
by Benz of Germany.

These early cars were called "horseless carriages"
and that is what they looked like, as though the horses
had been unhitched and the buggy left to run down hill
alone. Many inventions come in this negative way;
wireless telephones, fireless cookers, smokeless powder
and the like. Something left out makes something new.
This seems to be also nature's way, for biologists tell us
that valuable mutations in plants and animals often
arise from the omission of some single chromosome that
has accidentally got lost in the shuffle.

Gradually, however, the motor car ceased to look like
a mere mutilated vehicle and assumed a form and sym-
metry of its own. The horse, who had most reason to
view with alarm the advent of his fiery rival, soon
became oblivious to it. The machine, at first re-
fused admittance to the highways, came in the course,

GASOLENE 27

of time to dominate them. Up to 1896 automobiles
were prohibited from running on the English public
roads faster than four miles an hour and even then the
law required that a man should walk in front waving a
red flag. This had a tendency to hamper the develop-
ment of the automobile in England. Just so, a hun-
dred years before, Parliament had refused to allow a
thirty-mile railroad to be built on which Stephenson's
engine could run from Manchester to the sea. Thomas
Creevy, who was on the committee that killed the bill in
1825, writes in his diary:

Well — this devil of a railway is strangled at last . . . this infernal
nuisance — the loco-motive Monster, carrying eighty tons of goods,
and navigated by a tail of smoke and sulphur, coming through
every man's grounds between Manchester and Liverpool.

Now the situation is reversed and the auto has the
upper hand. It is already proposed to prohibit the use
of horses in New York City within a few years. Cer-
tainly anybody with a heart, who has seen the city in a
snowstorm when the poor horses slip and fall on the icy
pavement and have to be whipped to force them
through the drifts with a light load, will rejoice when
they have been displaced by the tireless and unfeeling
truck. Suppose there had never been horses and livery
stables in the city. What would happen to the man who
tried to introduce them ? The police, the health depart-
ment, the humane societies and the street cleaners would
unite to banish horses from the city, but they would
have to work quickly to get ahead of the mob. In any
innovation the majority of men see the disadvantages

28 SCIENCE REMAKING THE WORLD

before they see the advantages, while in regard to the
things to which they are accustomed they ignore the
faults and value the virtues.

THE GREATEST INVENTIONS. — Macaulay says: "Of
all inventions, the alphabet and printing press alone
excepted, those that have shortened distance have done
the most for humanity." Then gasolene, which has
given man a higher speed than he ever attained before,
must rank among the most beneficial of human in-
ventions. It has enabled man to travel in one hour 180
miles in an automobile and 220 miles in an airplane,
and to rise to a height of 41,000 feet in the air, 2,000
feet higher than Mount Everest, which British explorers
have been trying vainly to ascend.

Such records, though they may gratify man's am-
bition, do not benefit his life. The real advantages of
rapid transit are that it gives him greater power to
overcome the limitations of nature and lengthens his
life as measured by his activities. For practical pur-
poses distances are measured by the watch, not by the
map. "Twenty minutes from Times Square" means
something definite, if true. "Ten miles from Times
Square" means nothing, for it varies widely according
to direction.

The dimensions of cities, counties, states, and na-
tions depend upon the rapidity of communication.
The faster our vehicles the larger may be our political
divisions. The smallest territorial unit of our country
used to be the school district, which was measured by
the length of the legs of the littlest children. This vir-
tually ceases to have significance when the school 'bus

GASOLENE 29

can collect the children from a county and bring them
to a central school. The radius of a metropolitan area
is determined by the average time taken out of the day
in coming in to shop or office and going home again.
The extent of territory reached by a newspaper or a
store depends on the delay in delivery. Cutting the
time in half means multiplying the tributary territory
by four, for the area increases as the square of the
radius. One may almost say that the area increases
as the cube since we have by skyscrapers invaded the
third dimension and are building cubical habitations.

Any new scheme of speedier intercommunication
tends to expand the boundaries of political divisions.
But it does more than that. It weakens the boundaries
themselves. Statesmen may cut up continents into
countries but science knows no nationality. Ideas will
somehow leak through from one language to another.
Print and pictures will penetrate anywhere. The map
may be coloured like a crazy-quilt, but nobody can put
up partitions in the ether. The frontier may be lined
with soldiers, the radio will overreach them. The three-
mile limit of the high seas has ceased to have meaning.
The self-propelled projectile, the auto-airplane, carrying
death in its bombs, has no limit to its range. No wall,
trench, or barbed-wire fence can shut out the molecules
of poison gas. The airplane soars over custom houses.
The submarine dives under blockades. The automo-
bile runs across tariff walls.

Science erases the artificial barriers that the politician
erects. As the world comes under the sway of science
political divisions will be impossible to maintain.

30 SCIENCE REMAKING THE WORLD

Commerce, the child of science, is doing more to pro-
mote the unification of the world than all the politicians.
Politics is the art of managing men. It was therefore of
supreme importance in the days when war and work
were done by men. But as war and work come to be
done by machinery the importance of the politician
diminishes as the importance of the engineer increases.
The financial side of the automobile business is in-
teresting but puzzling. The best estimate of the an-
nual expenditure on motor cars in this country for 1921
makes the total out to be $7,783,000,000, distributed
as follows:

New Cars #1,448,000,000

Depreciation 1,800,000,000

Interest 295,000,000

Tires 450,000,000

Gasolene 823,000,000

Oil 175,000,000

Garage 552,000,000

Repairs and Supplies 1,000,000,000

Insurance 185,000,000

Taxes 275,000,000

Drivers' Salaries 600,000,000

Road Maintenance 180,000,000

$7,783,000,000

That is to say, we are spending approximately
eight billions of dollars a year on something that did
not exist twenty-five years ago.

Where does the money come from? I am not com-
plaining of extravagance. I am not saying that it is a
cent too much. But it would be interesting to find out,
if we could, from what sources this immense amount of

GASOLENE 3r

money has been derived. Here is a new channel of
expenditure into which an enormous flood of funds has
been suddenly turned. From what other channels has
it been diverted ? If we say it comes from the recent
general increment of wealth or the fictitious increment
due to inflation, then we can put the question in another
way: For what would this eight billions of dollars be
spent if there were no motor cars?

I do not know that the question can be answered
statistically but perhaps you get an answer from indi-
vidual observation or experience. When a man buys a
car and spends say a thousand dollars a year on it in
interest, depreciation and supplies, what does he
economize on? Does he take it out of his savings or
what he otherwise would have laid up for a rainy day?
But savings and investments have also increased during
this period. Does a family after it owns an auto spend
less on clothing or food or theatres or books or summer
resorts or golf? Or does it spend more? Is there a
saving on shoe leather by using rubber tires? But
more is spent on shoes and clothing than there used to
be. So of almost everything else. The only field in
which a definite falling off can be discerned and ascribed
to the introduction of the auto is in carriages, city sta-
bles and the like, but this is little compared with what is
spent on motor cars and motoring.

The building of railroad mileage has been virtually
at a standstill for a number of years, though the popu-
lation and business activity of the country have been
increasing. It may be said, then, that a large part of
the money spent for motor transportation would other-

32 SCIENCE REMAKING THE WORLD

wise have been put into spur-line railroads, electric
railways or else, which is more probable, there would
have been much less in the way of transportation facili-
ties available and consequently less wealth created. The
creation of rail lines covering the network of highways
over which motor cars travel, would probably be pro-
hibitive in cost.

A saving in the wages of farm workers has been an-
other source of income for automobile investment.
There has been a drift of farm population to the cities
without as yet a noticeable diminution of the volume
of farm products. The decrease in labour has been
taken care of by farm machinery, including motor
transportation, which has tremendously increased the
amount of time at the individual farmer's disposal as
compared with the horse-and-buggy days.

Another source of possible saving is in city rents by
removal to the suburbs and country, which would leave
the difference in rent available for motor transportation.
But city rents have not perceptibly fallen and there is
also the extension of city deliveries into the vicinity to
balance this economy.

Besides the question of money expenditure there is
the question of time expenditure, equally important
and equally unanswerable. Leaving out of considera-
tion the commercial use of motor cars there is an enor-
mous amount of time spent in pleasure riding, in taking
care of the machine and talking about it and in sitting
around waiting for a new tire to be put on. How was
this time spent formerly or how would it be spent now
if there were no automobiles ? Here we are not both-

GASOLENE 33

cred by a change in the standard of measurement. The
length of the day is one of the few things that the war
has not altered. Has there been a decline in sleeping,
reading, seeing motion pictures, playing cards, going to
church or what? Unfortunately we have no census
figures on how we spend our spare time although many
less important queries are asked us by the Census
Bureau.

I used to ask such questions as these of my students in
the School of Journalism at Columbia and while the
answers were not always valuable I am sure the ques-
tions were. The important thing is to get a realization
of the innumerable and various ways in which any such
invention affects all our lives. The same question
would often bring opposite answers but I was not under
the painful necessity of marking either one of them
wrong. Take, for instance, this question of the effect
of the automobile on church attendance. Some of my
students would report that the congregations had fallen
off, for the people went riding on sunny days while on
rainy days they could not be expected to go to church.
But students from other sections would say that church
attendance had increased because the people could
come from many miles around and it took less time.
There would seem to be something in this because the
churches have grown in membership during the auto-
mobile era and why should people join a church if they
do not go to its meetings ?

Another question bringing different answers was the
effect of the automobile on the spirit of democracy.
Students from New York City were apt to say that it

34 SCIENCE REMAKING THE WORLD

had intensified the tension between social classes be«
cause the poor pedestrian resented having to turn out
of the road at the honk of the plutocrat and receive a
whiff of scorched gasolene in return. On the other hand
students from the West reported that the automobile
was an agency for democracy for it had wiped out the
distinction between classes. Formerly when the few
had buggies and the rest had to ride to town in lumber
wagons the former set looked down on the other but
now that all had automobiles they were substantially on
a level. This must be the case in such states as Cali-
fornia, Iowa, South Dakota and Nebraska, which have
one motor vehicle for each five and a fraction persons,
that is, one for every family.

Once I asked my class to "specify the influence of the
automobile in political, commercial, social, and martial
affairs." I got unexpected answers, for some students
seemed to have difficulty in reading my writing on the
blackboard and mistook the "martial" for "marital."
But I was glad of the misunderstanding for the answers
were interesting. Some said that automobiles pro-
moted marriages by providing courting parlours but
others said they dissolved marriages for similar reasons.
Here, as usually, the truth lies not in the mean but at
the extremes. Two opposites may both be true but if
we average them we may get nothing, or a falsehood.
Many a fallacy has come into sociology through dealing
with an average man who does not exist.

It was commonly assumed that the automobile
would relieve the congestion of our cities and check
what was called their " abnormal growth." The mental

GASOLENE 35

conservatism of the masses of mankind leads them to
call anything "abnormal" that is merely unprecedented.
The expectation that there would be an exodus from the
cities if opportunity were offered was based upon the
unconscious assumption that people were more anxious
to get out of the city than to get in. But it seems on
the contrary that the pressure of population is from the
rarer to the more densely inhabited districts: the re-
verse of the law of gases, for men do not always behave
like molecules. Our cities continue to grow and the
bigger they are the faster they grow. Autos are more
used to bring countrymen into the town than towns-
men out to the country. However the balance lies the
net result is to bring about a greater mixing of rural
and urban population. God made the country. Man
made the city. Gasolene made the suburb.

CHANGES IN THE COUNTRY. — The roadside inn has
been revived. Front rooms of farmhouses, formerly
only opened for weddings and funerals, have been turned
into tea houses. Apples and berries, sweet corn and
melons, are set out on a box by the roadside in charge of
a child as salesman and the passing autos take their pick
of the produce as though it were a cafeteria. This
brings the grower and eater directly together and omits
the middle man or men. That the city dweller is led by
a love of nature into the country is evidenced by his
effort to bring the country back with him by filling his
car with other people's flowering trees and bundles of
flowers. But all men kill the thing they love. Before
the end of the season there are few flowers left within
the radius of the afternoon ride and next season there

36 SCIENCE REMAKING THE WORLD

may be none, unless some means may be found for add-
ing brains to enthusiasm. A sylvan solitude loses its
chief attraction when it becomes densely thronged.

The motor furniture van has facilitated the fondness
of Americans for moving. All the contents of a seven-
room flat in New York City may be stowed, without
crating, in a van and set up in a house in Washington
next day without breakage, loss, or delay. Already the
motor truck is a close rival to the railroad car in ton-
nage carried. (In 1921, tonnage carried by truck,
1,430,000,000; by railroads, 1,641,000,000). In the
number of passengers and the number of miles they
were carried the motor cars have gone far beyond the
trains. (In 1921, passengers carried in motor cars,
7,000,000; in railroad cars, 1,000,000. Passenger mile-
age: motor cars 71,000,000, railroads 37,000,000).

The spread of the automobile created a demand for
new materials in large quantities, for something that
would give a stouter skeleton and a softer tread.
Metals like vanadium and molybdenum, names so
unfamiliar to the people that they had to be taught in
advertisements how to spell and pronounce them before
they could ask for them, were needed to give steel a
greater elasticity and strength, and these "rare ele-
ments" had to be provided by the thousands of tons.
During the automobile races of 1905 in Florida a French
machine went to smash. There happened to be hang-
ing about, a man with an abnormal curiosity, Henry
Ford. He picked up a fragment of the wrecked racer,
a valve stem, and found it lighter and stronger than
anything he could make. He had it analyzed and

GASOLENE 37

found that it contained vanadium, a metal that Ameri-
can steel makers did not know how to use. Special
furnaces had to be made for it since vanadium melts at
3,000 degrees Fahrenheit and the ordinary steel furnace
could not run above 2,700 degrees. But vanadium steel
is two and a half times as strong for equal weight as
common steel and was therefore peculiarly fitted for a
car that was to be light and tough, as well as cheap and
simple.

THE BEGINNINGS OF RUBBER. — The boom in rubber
had begun before, in the Bicycle Age, when an Irish
horse doctor named Dunlop tied a rubber tube around
the rim of his boy's velocipede, and blew it full of air.
Brazilian forests could not supply the caoutchouc
needed for pneumatic tires and electrical apparatus, so
attention was turned to the Congo, where a reporter for
the New York Herald named Stanley had established
a Free State under the patronage of the leading Euro-
pean nations and the United States. The protecting
powers, anxious to make the natives safe and happy and
fearing that they might be exploited if put under one of
the greater powers, picked out a benevolent looking old
king with a long white beard and gave him a man-
date for the Congo. King Leopold of Belgium was a
high liver and a free spender in the promotion of the
fine arts, especially drama and dancing, and was not
content with the 300 to 800 per cent, income on the capi-
tal invested. So the Belgian officials in the Congo, to
get their tale of rubber, drove the negroes deeper into
the jungle. Men were murdered, women were flogged,
children had their hands cut off. Finally the Congo

38 SCIENCE REMAKING THE WORLD

atrocities aroused the moral sense of the world and the
Free State was rescued from the hands of Leopold.

In 1910 the price of Para rubber had risen to $2.00 or
$3.00 a pound and the forests were being depleted of the
trees. Then science came to the rescue and showed
how an unlimited supply of the precious gum could be
obtained without robbing the natives or ruining the trees.
This was by cultivating the rubber tree. The fore-
sighted British and Dutch set out rubber plantations
and produced a better product than thewild rubber for 25
cents a pound or less. The United States consumes
some 75 per cent, of the world's rubber but it is all
foreign grown. Akron, Ohio, alone manufactures over
a third of the world's rubber. We found what it meant
to have neglected to cultivate our own garden when the
war broke out and threatened to ruin the third largest
of our industries by taking off our tires. We had to pay
whatever the British and the Dutch cared to charge us,
and they reaped a rich harvest from their providence,
but in 1920, when the automobile business took a sud-
den slump, the price of rubber fell from 55 cents a
pound to 13. Three per cent, of the rubber plantations
of the world are now owned by American companies but
none of them have been placed in our own tropical
possessions. Dutch and British dependencies are
evidently considered more dependable than ours. So
we see that development of a new motive power affects
international relations everywhere. The same thing
may bring ruin to the Congo and prosperity to the
Malay Peninsula. Recently the British have put an
export tax on their rubber and we are beginning to

GASOLENE 39

wake up to the desirability of having a few rubber trees
in our own yard. So Congress has consented to ap-
propriate $500,000 to see if we cannot grow rubber
under the American flag in the Philippines or elsewhere.

Hardly had the automobile been born before it began
to complain about the roads, especially in America.
In Europe the roads were better than ours, thanks to
the Romans who, whenever they conquered a country,
made a good road through it leading straight to Rome
and so solid that it lasts to this day. The French cars
that we first imported groaned dreadfully over our
rough roads, sometimes indeed balked at travelling in
the dirt. So we resolved to mend our ways and have
done wonders in a few years. In the period 1910-1921
over two and a half billion dollars were spent in road
construction in the United States. The Federal
Government has come to the aid of the states and at the
end of 1921 there had been completed 12,900 miles of
good roads, costing about $221,000,000, of which the
Federal Government had contributed 46 per cent.

Although the improvement of highways is chiefly due
to the demands of the motor car they ease the labour of
the surviving horses. The automobiles wear out the
roads more than horse-drawn vehicles but on the other
hand they contribute heavily to the government rev-
enues. New York City alone takes in $6,000,000 a
in motor fees — not counting fines. In 1921 the
states received in registration and license fees and gas-
olene tax more than $132,000,000. Altogether it is esti-
mated that motor vehicles paid into the treasuries, state,
national and municipal, $341,300,000 in 1921.

40 SCIENCE REMAKING THE WORLD

Taking the locomotive off the rail and putting it on
the road is in itself a revolution of wide-reaching in-
fluence. With a network of good roads covering the
country and with vehicles that require no other track,
our population has acquired a flexibility of movement
that has amazing consequences. The jitney can shift its
routes from day to day according to where the people
want to go, while the tramcar must stick to its trolley
and track regardless of traffic. A touring car can
change its mind in a moment's caprice while the rail-
road train must follow the time-table. In England
the rural districts are getting disturbed by the inva-
sions of cockneys in the char-a-banc or motor lorry.

The transformation of the farm by motor fuel, strik-
ing as it seems, is only beginning. Agriculture has so
far been comparatively little affected by the industrial
revolution. This is because the revolutionary agent,
the steam engine, has not found a place upon the farm
as it has in the factory. Farm work is too varied and
scattered to be run by a central power plant. Look
into one of our big steel plants or machine shops and
you will be struck by the scarcity of men. The building
seems deserted when it is really most active. Here and
there is a man moving about looking after things.
Groups of three or four may be standing by a process
and occasionally intervening. If you find a bunch of a
dozen straining their muscles in lifting or pulling you
may be sure that something has gone wrong with the
machinery and they are fixing it up.

The human muscular labour that has been so largely
eliminated from the factory is still the mainstay of

GASOLENE 41

the farm. The horse aids man but does not supplant
him. The gasolene motor may 'do for the farmer
what the steam engine could not. The motor is
small, light, portable, cheap and easily managed. The
tractor is capable of doing the work of two or three
teams of horses although it seems that the farmer must
still keep a team or two. For the road haul and
running to town the motor vehicle is rapidly displacing
the old lumber wagon and buggy. There are about
three million motor vehicles used on American farms.
Of these 150,000 are trucks. The states having most
cars on farms are Iowa, Illinois, and Ohio. The states
having most trucks on farms are Pennsylvania, New
York, and Iowa. In many places gasolene has knocked
the picturesque milkmaid off her three-legged stool.
A motor will milk a dozen cows at a time and never
complain of the chores, and the mechanical milkmaid
is more sanitary. The day of the open pail is passing.
We may hope to see the man with the hoe supplanted
by the man with the Ford. His brow will not slant so
much, for the farmer of the future will have to be a
high-brow to manage power machinery.

Where will the fuel come from to run all these new
machines? The world's oil-tank is running dry and we
are not yet in sight of a new supply. The United
States, that was the best endowed, has been most ex-
travagant. We have wasted the greater part of our oil
and have sold to everybody that would buy. Now, like
the foolish virgins, we must ask others for oil and are
likely to get the same reply.

Nobody knows how much petroleum there is left in

42 SCIENCE REMAKING THE WORLD

the ground in various parts of the world, but it is evi*
dent that it is not enough to go around.

According to the estimate of the United States Geo-
logical Survey there is still underground in the United
States some six billion barrels of oil. This seems like
a lot, but we are burning over half a billion a year. Half
a billion goes into six billion twelve times which would
put the date of the practical exhaustion of American
oil fields in 1934 at the present rate. But the rate of
consumption is increasing. Between 1910 and 1921 the
consumption of crude oil in the United States arose 68
per cent., while the domestic production increased only
56 per cent. Therefore our importations increased 600
per cent, for the same period. Last year we had to im-
port more than 125,000,00x3 barrels of petroleum and we
will have to import more and more every year hereafter
— if we can get it.

What can take the place of gasolene for the motor?
There are two present possibilities: shale oil and alcohol.
Either will be more expensive and less satisfactory,
so the transition will bring about a new sociological
transformation.

I have shown how naturally the distribution and dis-
tillation of petroleum led to the concentration of
great wealth in the hands of a few individuals. Many
of those who "struck it rich" in the early days spent
their money about as quickly as they got it on reckless
personal extravagance. This had only a temporary
effect on society and that altogether bad. But greater
wealth has come into the hands of some who have
spent it in carefully contrived means for public welfare.

GASOLENE 43

Mr. Rockefeller's donations to education and welfare
organizations amount to more than half a billion dol-
lars. From this source about $10,000,000 a year is
dispensed, largely for medical education and public
sanitation. Last year two millions were promised to
Harvard for a school of health, a million to Columbia,
three and one half millions for rebuilding the medical
schools of Brussels. A complete modern medical school
has been established in Peking and twenty-five other
.medical centres in China have been helped. Consider
what it means for the four hundred million people of
China to have scientific research established there at
this critical period in their history. Nineteen coun-
tries besides our southern states have been helped in
unhooking the hookworm. Campaigns against yellow
fever and malaria have been instigated the world over.
How much does that mean for the increase of human
health and energy? Notice that these donations, large
as they are, do not compare with what the communities
concerned will themselves spend in the work thus
started. Who can estimate the influence of the Univer-
sity of Chicago and of the other universities which its
founding has effected? Here are profound and far-
reaching sociological effects resulting from the almost
accidental accumulation of this wealth in the hands of
one particular man. Any other man or group of men
would have spent it differently, worse or more wisely,
as you choose to think.

How HAS GASOLENE AFFECTED Us? — I must not
close without mention of the psychological effects of the
introduction of gasolene, its influence on the mind of

44 SCIENCE REMAKING THE WORLD

man. The horseman realizes that he is dealing with an
intelligent or a wilful, capricious, and perhaps vicious
animal, whose conduct will be affected by his own tem-
per. The chauffeur knows that he is handling a ma-
chine which cannot be punished or coaxed. Anger has
no effect on an auto-engine. To display or even to feel
any emotion toward it is simply silly. In Wells's Freu-
dian novel, "The Secret Places of the Heart," the man
who in a fit of fury smashes up his wife's dainty sedan
betrays thereby his subconscious animosity toward the
owner. The substitution of machinery for all slave and
animal power and even in large part for personal service
must in the long run have very profound effects on
human character.

A professor of psychiatry tells me that he prescribes
automobile driving for certain types of nervous patients,
especially such as suffer from inability to concentrate
their minds on anything outside of themselves or who
are deficient in quick decision. The chauffeur who
hesitates is lost. The automobile obviously cultivates
celerity of decision on the part of the pedestrian as well
as of the driver. When the automobile first came into use
it was said that it was dividing the population into two
classes: the quick and the dead. This has ceased to be
a joke. More than twelve thousand persons are killed
each year in the United States by automobiles. How
many persons do you suppose were killed in Great Bri-
tain during the late war by all the shells and bombs
from German ships and airplanes and zeppelins? Six
hundred forty-two, or about I per cent, of our death
rate from motor cars.

GASOLENE 45

The acquisition of external energy, as in employment
of gasolene, means an augmentation of the individual.
The management of a machine gives one a sense of
personal power, much like that of the consciousness of
controlling other human beings but less harmful in its
reflex effect on the possessor of the power. This sense
of power is doubtless one of the chief reasons for the
fondness for fast driving. The best expression of this
feeling that I have found in literature is the following
passage in Maurice Maeterlinck's essay on the automo-
bile in "The Double Garden":

The pace grows faster and faster, the delirious wheels cry aloud in
their gladness. And at first the road comes moving towards me,
like a bride waving palms, rhythmically keeping time to some joy-
ous melody. But soon it grows frantic, springs forward, and throws
itself madly upon me, rushing under the car like a furious torrent,
whose foam lashes my face; it drowns me beneath its waves, it
blinds me with its breath! . . . Now the road drops sheer into
the abyss, and the magical carriage rushes ahead of it. The trees,
that for so many slow-moving years have serenely dwelt on its
borders, shrink back in dread of disaster. They seem to be hasten-
ing one to the other to approach their green heads, and in startled
groups to debate how to bar the way of the strange apparition.
But as this rushes onward, they take panic, and scatter and fly,
each one seeking its own habitual place; and as I pass they bend
tumultuously forward, and their myriad leaves, quick to the mad
joy of the force that is chanting its hymn, murmur in my ears the
voluble psalm of Space, acclaiming and greeting the enemy that
hitherto has always been conquered but now at last triumphs:
Speed. . . . Space and Time, its invisible brother, are perhaps
the two great enemies of mankind. Could we conquer these, we
should be as the gods.

When I told M. Maeterlinck how much I admired it
he laughed heartily and said that the inspiration of the
rhapsody was one of the primitive five-horse-power

46 SCIENCE REMAKING THE WORLD

machines of twenty years ago that got out of breath
when it climbed a hill and occasionally broke down on a
level. But I do not think he can write any better now
that he has a modern racer.

The French seem to be quicker than we in perceiving
the poetry in modern inventions. Maeterlinck's prose
poem on the first automobile may be matched by Ed
mond Rostand's sonnet on the first airplane:

J'avais sur la montagne un grand jardin secret

Mais, ce soir, se levant du fond de la campagne,

Le long biplan que Toeil des bergers accompagne

Vint a ma solitude infliger un soufflet.

Car, doublant mon toit basque ou, presque, il s'eraflait,

Le monstre pour lequel il n'est plus de montagne

Passa sur mon jardin comme le vent d'Espagne,

Et mon sable cut son ombre, et mon lac son reflet!

J'aurais du t'en vouloir, 0 beau monstre de toile,

Moi qui n'ayant cherche que 1'aigle et que 1'etoile

Suis venu sur ce mont, loin du plaisir humain,

Pour avoir a moi seul un ciel qui se deploie!

Mais j'ai crie d'orgueil et j'ai pleure de joie

Lorsque j'ai vu mon ciel devenir un chemin!1

'For the benefit of those who do not read French my wife has put thi
poem into English verse:

A high and secret garden was my own.
This evening, rising from the low champaign,
While shepherds stood astare, the long biplane
Above my sheltered seat was swiftly blown,
And buzzed about my Basque roof with its drone!
The linen monster mountains bar in vain,
Passed o'er my garden like the wind from Spain;
A moment's shadow on my lake was thrown.
Fair monster! Should I not have wished you far;
I, who to seek the eagle and the star,
To claim a space of heaven for my abode,
Had climbed the height to human joy denied?
I wept with joy and shouted out with pride
To see this heaven of mine become a road!

GASOLENE 47

GUIDE TO FURTHER READING

"Discoveries and Inventions of the Twentieth Century," by
Edward Cressy. (Dutton and Company.) Contains chapters on
petroleum and gas engines.

"Chemical Discovery and Invention in the Twentieth Century,"
by Sir W. A. Tilden. (Dutton and Company.) 1916. Contains
chapters on petroleum and rubber.

"America's Power Resources," by C. G. Gilbert and J. E. Pogue.
(Century Company.) 1921. Shows the economic significance of
coal, oil and water-power. See also the same authors' "Energy
Resources of the United States," Bulletin 102, Smithsonian Insti-
tution, Washington.

"Gasoline and Other Motor Fuels," by Carleton Ellis and Joseph
V. Meigs. (Van Nostrand Company.) 1922. Comprehensive
volume on the manufacture of gasolene.

Reports of the United States Bureau of Mines for statistics of
production of petroleum products.

Yearbook of the National Automobile Chamber of Commerce
(N. Y.)t and current motor magazines for figures on the development
of the industry.

For the sociological effects of the introduction of the gasolene
motor the reader will have to rely upon his own powers of observa-
tion and reasoning.

THE INFLUENCE OF COAL-TAR ON
CIVILIZATION

BY EDWIN E. SLOSSON

WHAT were the most precious things in the
ancient world? What would a king bring to
a great king whose favour he sought? What
would the great king offer to his god? When a daring
trader had reached the Far East after untold hardships
by land and sea for many months, what commodities
would he pick out to purchase and take back, knowing
that he must make his fortune out of what he could
carry on a camel's back, or perhaps his own, through the
torrid desert, beset by robbers, and over the icy
mountains ? You know what he could buy to take back
if you know your Bible, or even if you know your
Arabian Nights. You could inventory that cargo from
such fragments of ancient verse or prose as linger in
your memory. You know that when his pack of rare
and precious goods was opened it would be found to be
filled largely with what are now called coal-tar com-
pounds. Not much else, except gold and gems. There
would be dyes and drugs, perfumes, and preservatives;
whatever amorous youth would choose to enhance the
beauty of his lady love, and whatever pious youth
would use to embalm the body of his father; whatever

48

COAL-TAR 49

would colour the curtains of the palace of the king or of
the temple of the deity; whatever would serve to scent
the banquet hall or ascend to heaven as incense from
the altar.

Now these that were the gifts of kings, the prerogative
of royalty, the acme of luxury, all these have, by the
bounty of science, been put within the reach of all. To
be born to the purple is no longer a distinction. It is
the natural heritage of any American babe. King
Solomon in all his glory was not arrayed like a lady who
has all the aniline dyes at her disposal. The shop girl
may rival the Queen of Sheba in her employment of
perfume — and she often does.

But notice this — that perfumes and similar luxuries
are not used so lavishly now when they are cheap as int
the days when they were rarities. They are not abused
by the many as they were by the privileged few. We
may think that nowadays some people put too much
scented unguent on their person, but we never see any
one with so much of it as was used in the case of Aaron,
where it soaked his head, ran down to the tip of his
beard and went on to grease his garments to the skirt
and doubtless formed a puddle on the floor. If we
should see and smell anything like that to-day, there
would indeed be reason for outcry against the growing
extravagance of the age.

All of the comforts and conveniences of our ordinary
life were on their introduction denounced by moralists
as extravagant and demoralizing luxuries. Juvenal de-
clared that Rome was in decadence because the rich
used ice and white bread at their banquets. But now-

So SCIENCE REMAKING THE WORLD

adays to live on white bread and iced water is not re-
garded as wicked indulgence. Nobody objects to it ex-
cept those who think that brown bread and tepid water
are better for the health.

This does not prove that Juvenal and such satirists
were wrong. On the contrary they were doubtless
right, for the aristocrat who ate white bread and drank
cold drinks when nobody else in the city could afford
them, did feel a selfish satisfaction at his superiority
and so it was demoralizing to him. But when the roller
mill and the refrigerating machine brought these table
delicacies to the level of common life they became quite
harmless.

The way to make a luxury innocuous is to make
enough of it to go around. When it becomes cheap it
ceases to be extravagant, and when it becomes common
it ceases to be exclusive, and therefore it is no longer a
menace to morality. Isaiah was doubtless justified in
denouncing the daughters of Zion for their "changeable
suits of apparel," but I do not think he would say the
same now when a package of dye soap can be bought
for ten cents. For the ladies who change the colour of
their apparel by the use of such coal-tar products do not>
I am sure, feel sinfully set up about it.

The coal-tar products form a new factor in our civili-
zation. Not long ago, chemists celebrated the fiftieth
anniversary of the day when a London schoolboy, wash-
ing up his glassware after an experiment that had failed,
found that the black sticky stuff in his beaker kept
colouring the wash water purplish. Like Columbus
and Saul, young Perkin had failed to find what he was

COAL-TAR 51

looking for, but had hit upon something greater. He
was after quinine, but he had accidentally entered the
unknown field of aniline dyes and drugs, many of which
are more valuable to the world than the knowledge of
how to make quinine without the aid of Peruvian bark.
He was working in a laboratory that he had fitted up
for himself at home because the Royal College of
Science was not open enough hours to satisfy him, and
he was using impure chemicals. This was fortunate,
for if his aniline had been pure he would have missed
mauve.

The first coal-tar dye, mauve, was discovered in the
Easter vacation of 1856. Note the date, I mean the
time of year. It is significant. Not because it was
Easter, although you may have a childhood association
of aniline dyes with Easter eggs. But it was in vaca-
tion. It was made by a boy who played hooky from
Vacation, by a boy who had rather work than eat, so he
spent his noon hour fussing with chemical apparatus.
There are such boys even now in spite of the fact that
they are persecuted by their classmates as grinds and
are not always encouraged by their teacher. I don't
know how William Henry was treated by his school-
mates, but he was encouraged by his teacher in the
most effective fashion by being set at a discouraging
task, in fact an impossible task to him, one that has not
yet been accomplished — the synthesis of artificial
quinine.

The English and the French at first entered with
enthusiasm upon the preparation of new coal-tar com-
pounds, but were ultimately distanced by the Germans,

52 SCIENCE REMAKING THE WORLD

who made the research laboratory a part of the factory
and by thus putting their industries under scientific
guidance had, before the war, obtained practically a
world monopoly of the manufacture of synthetic organic
chemicals.

The 1914 edition of Schultz and Julius Dyestuff
Tables listed 925 coal-tar dyes as used in the trade,
but the chemist knows of thousands of others that he
might make if needed. We already have dyes for all
kinds of material and for any desired colour and shade.
Some are fast and some are fugitive. Some are glaring
and some are dull. Some are cheap and some are dear.
Some are poisonous and some are harmless. It is ab-
surd to condemn or commend the coal-tar colours as a
whole, because they differ in every possible respect.

That is, the dyer of to-day has a thousand pigments
on his palette not counting shades and combinations.
Before the discovery of mauve in 1856 — you will re-
member that date if I repeat it often enough — there
were barely a score of dyestuffs in general use, mostly
barks and roots of uncertain composition. It is hard
for us to realize what a different-looking world we are
living in, thanks to coal-tar compounds, and still harder
to express in words the difference in aesthetic effect.

Coal-tar has brought more colour into our dull lives,
not only through our clothing but also through our
food. Food and drink, appropriately tinted, become
more attractive, and being more attractive become more
appetizing, and being more appetizing become more di-
gestible, and being more digestible become more nutri-
tious, and being more nutritious become more strength-

COAL-TAR 53

ening. Each step in this Aristotelian sorites has, I be-
lieve, been experimentally demonstrated, so it seems to
lead logically to the conclusion that the increasing
use of aniline dyes in food products has added to the
energy of the nation. I do not put entire faith in
Aristotle's logic until it is confirmed by the calori-
meter, so I will not press this argument, but content
myself with the safe observation that the coal-tar
colours add to popular pleasure, whether or not they
increase the public efficiency That they are at least
harmless is assured by the United States Department
of Agriculture, which analyzes every batch of dyes used
in edible products to see that they are not in themselves
poisonous and do not contain accidental arsenic. No
new dye is added to the allowed list until it has been put
through a long series of tests, first on animals, then on
man, to see that it is not injurious, even in much larger
amounts than are to be used in edibles.

The use of artificial colours in foodstuffs is increasing
rapidly. About 500,000 pounds of dyes are used every
year in the United States for colouring foods and drinks.
This is some four times greater than the quantity used
a few years ago. The favourite colours in this field are
the same as those which periodical publishers have as-
certained to have the greatest selling value on the cover
of a magazine, red and yellow. I leave it to the psychol-
ogist to explain this popular preference for the longer
wavelengths of the spectrum. The red dyes go largely
into frankfurters and the yellow into butter and rival
spreads, while all the colours of the rainbow are in de-
mand for cake and candy icings and ice cream, and for

54 SCIENCE REMAKING THE WORLD

the wide variety of soft drinks that are gi adually weaning
the American people away from hard liquor. Four
billion pints of bottled soda are consumed annually in
the United States, not counting what is sold from foun-
tains.

Another indication of the popular trend toward a
gayer taste is the use of chemical compounds with intent
to increase the attractiveness of the naturally more at-
tractive sex. The people of the United States are now
spending about one hundred million dollars a year-on
perfumes and cosmetics. We are importing four times
as much of these, measured by cost, as we were before
the war and we are exporting ten times as much.

I will not attempt to apply here the syllogistic chain
used above, for experimental evidence is almost alto-
gether lacking. Since odours are known to have a
profound influence upon the emotions, the effects of the
wider use of perfumes and the introduction of new scents
cannot be negligible, although they may be indetermin-
able.

In the manufacture of fine odours the chemist is rapid-
ly catching up with the flowers; in fact has already sur-
passed them in some lines. Let not the reader stick
up his nose at synthetic perfumes. We could not get
along without them. In fact we are altogether de-
pendent upon them for certain popular forms of per-
fumery, for many flowers do not give up their scent
satisfactorily and so the perfumer has to imitate it as
best he can. For instance, the perfumes sold under the
names of arbutus, sweet peas, mayflower, cyclamen,
magnolia, phlox, honeysuckle, lilac, and lily of the valley

COAL-TAR 55

are not produced from the flowers, but are put together
by the perfumer from chemical compounds or other
floral essences.

In the field of perfumes and flavours the benzene de-
rivatives, natural or artificial, play a prominent part.
This world would lose a large part of its delight if the
"aromatics" should be deprived of the power of titillat-
ing our two chemical senses, taste and smell. These six-
membered carbon rings enter into all sorts of combina-
tions and serve us in various ways. For instance,
anthranilic acid in divers forms gives us the odour of
jasmine and orange blossoms, the flavour of the grape,
and the colour of indigo.

Salicylic acid cures our corns and relieves our rheu-
nnatJsm and in combination with the deadly "wood
alcohol" (now rechristened "methanol" to keep people
from drinking it) gives us the wintergreen flavour for
which we Americans inherit a taste from our New
England ancestors. Saccharin, a coal-tar product, is
several hundred times sweeter than sugar. It is alto-
gether lacking in nutritive value, but a dietary experi-
ment on the largest conceivable scale, namely its daily
use by many millions of Europeans for several years
during the sugar shortage in the late war, should remove
the popular impression acquired during the pure food
campaign, that it is injurious to health. This has been
recently confirmed by M. Bonjean of the Superior
Council of French Public Hygiene who made a ser-
ies of physiological experiments of long duration with
men and dogs in all doses practically possible and
found no derangement of health or digestion.

56 SCIENCE REMAKING THE WORLD

The familiar phrase for anything particularly expen-
sive or extravagant, "It costs like smoke," implies
doubtless an unconscious realization of the fact that
oxidation is the reversal of the synthetic reaction, the un-
doing of the constructive activity of animate nature.
The plant builds. Man utilizes. Fire destroys. Now
one of the most wasteful forms of smoke was that which
poured uninterruptedly during the great part of the last
century from the open tops of the beehive coke ovens.
In fact one can yet see these prodigal flares on the Penn-
sylvania mountains as he looks out of his Pullman win-
dow in the night. This is not merely a waste of fossil
fuel, which we already begin to realize will not last for
ever, but there is also a loss of a variety of compounds
that can be made very useful if properly worked up.
If a ton of bituminous coal is heated in a closed retort
instead of the open beehive, we may get besides the gas
and the coke, a dozen pounds of ammonium sulfate and
a dozen gallons of tar. The ammonium sulfate is valu-
able as a fertilizer, since it will feed nitrogen to the
crops, and the tar on redistillation will yield a dozen
products out of which some 200,000 distinct organic com-
pounds may be made, some of which are extremely useful
to mankind.

There is no use crying over lost coal-tar, but the time
is coming when we must be more economical. I do not
want to use language instigating violence, because that
is against the law, so I will merely quote Admiral
Dumas, Secretary of the British Royal Commission
on Oil Fuel, who said not long ago:

"I would like to see a government official hanged on

COM TAR 57

every lamp-post where gas is burned, because benzol
goes up with the flame." He had in mind particularly
the impending shortage of gasolene, for which benzol, or
benzene as we call it, is a suitable substitute as motor
fuel.

Before the war the British were glad- to sell their sur-
plus tar at low price to the Germans who made out of it
all sorts of dyes and drugs which they sold back to the
British at high prices. The Germans also found the
stuff useful for the manufacture of high explosives which
however, they were not so anxious to sell abroad but
preferred to keep at home for purposes best known to
themselves.

We Americans, too, were neglectful of the explosive
possibilities of the coal-tar products. Indeed, there
was then a prevalent feeling that war was an anachron-
ism and would gradually sink into innocuous desuetude.
We Americans have a curious belief that anachronisms
die out spontaneously if let alone, whereas history shows
that they are very long-lived creatures and rarely die of
old age but usually have to be killed off. In 1914 there
were only enough by-product coke-ovens in the United
States to turn out 700,000 pounds of toluene a month.
Toluene is used in wartime for making trinitrotoluene,
familiarly known as TNT, but there was not much de-
mand for it then, so most of the coke makers let it burn.
When America entered the war our Government per-
suaded them, more or less imperatively, to put in by-
product coke-ovens, and by 1918 they could turn out
12,000,000 pounds of toluene a month.

The Great War differed from all former wars in the

S8 SCIENCE REMAKING THE WORLD

use made of high explosives; that is, compounds that
can be kept and carried with comparative safety but
which explode with terrific violence on being set off by a
percussion cap of the right sort. The Germans with
the chemical factories and nitrate plants were better
prepared with these new weapons of warfare and that is
why they burst through the border with such alarming
speed. The steel and concrete cupolas of the Belgian
and French fortresses were shattered to pieces by single
shells from the 42 centimetre guns. The British trooptf
had to fall back rapidly before Von Kluck's army and
even then narrowly escaped destruction. Lord Kitch-
ener and the British general staff were slow to realize
that the old means of defence and offence were useless
against the coal-tar munitions, but finally word was got
to the British people that the army in France must
have high explosives or perish. They got them in
time to make a stand after the first German drive had
spent its initial force and so coal-tar products "won the

war."

In considering coal-tar explosives we must not think
that their usefulness is confined to settling the relative
strength of nations in war. Explosives are simply com-
pact packages of potential chemical energy put up in a
form ready for quick release, and as such they are
valuable in various ways. In 1921 the United States
produced and used for industrial purposes 538,000,000
pounds of explosives. This does not include exports,
but includes explosives not made from coal-tar, such as
gunpowder and nitroglycerin.

Carbolic acid, which the chemist calls "phenol,"

COAL-TAR 59

comes directly from coal tar. If this is acted upon by
nitric acid, picric acid is formed, which is a dye, a drug,
and an explosive. Treat picric acid with chlorine and
we get chlorpicrin, one of the poison gases first used in
the late war. The mother substance of this group of
aromatic compounds is benzene, a colourless liquid.
Treated with nitric acid this becomes nitrobenzene, and
this reduced by hydrogen gives aniline, from which the
innumerable and variously coloured aniline dyes are
made. Acting on aniline dye with acetic acid, the acid
of vinegar, gives us acetanilid, a headache remedy, or,
rather, relief. Toluene, the next member of the series
to benzene, can be converted by similar treatment into
dyes and drugs, explosives and sedatives, perfumes and
poison gas. The benzene family is remarkably versatile.
What is made for one purpose often serves for another.
During the war the women munition workers in England
were found to be using trinitrotoluene for dyeing their
hair an auburn shade, and had to be warned against
the dangerous practice by an official of the Explosives
Department.

When we were children and played the "game of
twenty questions" we always used to begin by asking
"Is it animal, mineral, or vegetable?" We thought by
that to corner the unknown object in one of the three
kingdoms of nature, for it did not occur to us that any
material thing could belong to more than one or lie
outside of all three. But there are no lines in nature.
What seem to us such are but merely the boundaries of
our own ignorance. The synthetic products of chemical
art, since they are built up from the primary elements

6o SCIENCE REMAKING THE WORLD

themselves, do not properly belong to any one of the
traditional three kingdoms for they may be made from
material found in any of them and the product is the
same whatever the source. So with the substances that
we are considering. They are commonly called coal-
tar products because that is the ordinary source of the
raw material, for tar is a by-product of the gas and coke
industry, formerly thrown away and even yet often
wasted. But it is necessary to understand that there is
nothing exclusive or peculiar about coal-tar. It does
not contain the various valuable things that are made
from it. These are mostly composed of four elements,
the commonest in the world : carbon, hydrogen, oxygen,
and nitrogen. These four make up air and water, and
out of air and water these compounds could be made,
although it would be a difficult and expensive process. ;

In the chemistry books they are known either as the
"aromatic compounds," because a good many of them
have an aromatic odour, or the " benzene series " from
the light colourless oil known as benzene which distils off
when tar is heated, and which serves as the basic sub-
stance of those compounds. This benzene is composed
of molecules consisting of six carbon atoms hooked up
into a ring. But the benzene ring and similar structures
are commonly found in vegetable and animal sub-
stances.

The reason why I call your attention to this is that
there is a prevalent impression that the coal-tar prod-
ucts are some new invention of the chemists, perhaps
instigated by the devil with whom chemists have always
been accused of being too familiar. Many of the things

COAL-TAR 61

that are now made from coal-tar were formerly ex-*
tracted from plants.

Indigo, for instance, has been prepared from the most
ancient time out of the juice of a plant grown in India.
The preparation of the dye was a toilsome process. The
natives cut the plant by hand, squatting on the ground,
and then beat it up in vats with paddles, standing up to
their waists in the blue liquid. In 1896 there were
more than a million and a half acres devoted to its
culture in that country. Shortly after that the Ger-
mans invented a way of making artificial indigo —
no, let us say more correctly, of making indigo artifi-
cially— from coal-tar, and then the land and natives of
India were released for better employment. Since the
war America makes her own indigo and has enough
surplus to export. In 1920 there was produced in the
United States more than 18,000,000 pounds of indigo,
which is more than twice what we imported before the
war.

Next to indigo the most popular of the old vegetable
dyes was madder. This has been used for more than
two thousand years. It is the ground root of an Asian
plant and is known as "Turkey Red." Extensive
fields were given over to its culture in France and the
Netherlands until 1869 when two German chemists,
Graebe and Liebermann, discovered how to make the
pure dyestuff, alizarin, from a waste product of coal-
tar, anthracene. The artificial alizarin is better and
cheaper, and this early triumph of synthetic chemistry
was, at the end of the first decade of its manufacture,
saving the world $20,000,000 a year, and is now saving

62 SCIENCE REMAKING THE WORLD

much more than that. As Professor W. A. Noyes
recently put it:

"It is scarcely an exaggeration to say that enough
has been saved from this to pay for all the university
laboratories in the world."

Let us consider another famous dye, the royal purple.
You may recall what Browning says of it in the poem
"Popularity."

Who has not heard how Tyrian shells
Enclosed the blue, that dye of dyes

Whereof one drop worked miracles,
And colored like Astarte's eyes

Raw silk the merchant sells?

Now this same royal purple that used to be extracted
drop by drop from the Mediterranean mollusc may be
made by the ton from coal-tar. Why is it not? Be-
cause it is not good enough to satisfy modern taste.
Some of the new aniline dyes are superior to it.

This idea that the coal-tar products are artificial and
unnatural sometimes leads to amusing consequences.
In the days when the newspapers were publishing scare
stories about the poisonousness of benzoic acid, an
over-zealous food inspector tried to confiscate a earful
of cranberries because he found benzoic acid in them.
But when he attempted to get at the person responsible
for putting in the forbidden preservative so that He
could be properly 'punished, He was found to be too
high up and powerful for the police to reach, being no
less a personage than the Creator of Heaven and Earth
and all that in them is. He puts benzoic acid into cran-

COAL-TAR 63

berries whenever He makes them, whatever may be the
law of the land.

A similar instance occurred recently. The leading
manufacturer of grape juice was accused of adding an-
other coal-tar preservative, namely anthranilic acid, to
his bottled product. But this also turned out to be a
case of "natural adulteration," so to speak, for all
grapes of this species contain anthranilic acid; in fact,
that is what gives them their pleasant flavour.

We could not rule the coal-tar products, these ben-
zene compounds, out of our life if we wanted to, and
we certainly do not want to, for they furnish a large part
of the beauty and pleasure of the world, of the flavours
of its fruits, the perfumes of its flowers, the colours of
its plants. Yet you will now hear some foolish crafts-
man say that we ought to do away with aniline dyes and
go back to such good old vegetable colouring matters as
indigo and madder. But we can beat nature at making
these same things, as well as make others even more
beautiful that nature cannot make.

In the incessant warfare between man and microbe
the human side received a powerful ally when coal-tar
came to its aid, because then for the first time man
could see his insidious foes. For thousands of years
man had seen men and children, the strongest of the
warriors and wisest of the elders, struck down by in-
visibles enemies against whom he had no weapons, for
he did not know what they were nor whence they came.
No wonder he thought such deaths were due to the un-
seen arrows of evil spirits. But by 1880 the bandage
was lifted from the eyes of man, for about that time

64 SCIENCE REMAKING THE WORLD

Robert Koch and others began to use aniline dyes to
stain the microscopic disease germs and to catch their
pictures on the photographic plate, developed by coal-
tar chemicals. From that time on, as he said, dis-
coveries fell into the lap of the investigator like ripe
fruit. In 1882 he discovered the bacillus of tuberculosis
and in the following year the bacillus of Asiatic cholera.

The bacillus of typhoid fever was discovered in 1880
and in 1896 a serum was prepared to prevent it. What
this has meant for public health we are all vaguely
aware, but a few figures may fix our ideas. In our war
with Spain where we had 107,973 men in encampments,
20,738 of them were taken down with typhoid and
1,580 of them died of it. But in 1912, when we had
12,801 men under similar conditions stationed on the
Mexican border, only two cases developed, while in the
Great War there were only 227 deaths from fever in all
the American armies during two years. This microbe
that had been the most formidable foe in previous wars
has been finally conquered because we know where it
lives and how it is carried and can even prepare the body
in advance to resist it, if in spite of our precautions it
gains entrace.

It is not a matter of chance that certain dyes have
been found valuable as drugs. The same thing that
makes them good dyes makes them good medicines;
that is, their ability to attach themselves to some par-
ticular kind of animal or vegetable substance. Many of
our most dangerous diseases are, as we now know, due
to minute vegetable or animal parasites, bacteria or
protozoa, that flourish in the blood and at our expense.

COAL-TAR 65

But these are hard to see on a microscope slide where
they are mixed up with all sorts of similar cells and
tissues and may be quite invisible. It was fortunately
found that the aniline dyes were useful in bringing out
the various substances, for some would be stained with a
particular colour while other things on the slide were
unaffected. Those of you who have tried home dyeing
will have found that in a piece of cloth composed of
mixed cotton and wool, the dye is apt to attach itself
to one kind of thread and leave the other untinted.

One day Dr. Koch was being shown through the
Breslau laboratories, and as he passed a table where a
young student was busily engaged in staining micro-
scope slides, he was told: "This is our little Ehrlich.
He is a first-class stainer of tissues, but he will never
pass his examinations." In fact, he never did, but his
"staining of tissues" led to the new science of chemo-
therapy which has given remedies for diseases hitherto
incurable. He found first that fuchsine, a familiar red
dye, would stain the tubercle bacilli so that they could
be seen on a miscroscope slide. Later he found that these
stains would act even in the living cell. He discovered
that methylene blue, a common colouring matter,
\vould seek out and destroy the parasite that causes the
quartan type of malarial fever. With this as a clue he
set about making molecules that would not only search
out and attach themselves to the pernicious parasite,
but carry along a dose of poison. For instance salvar-
san, otherwise known as "606," or as it has been re-
christened in America since the war, arsphenamine, con-
sists of two aniline rings with arsenic atoms attached.

66 SCIENCE REMAKING THE WORLD

The number shows the difficulty of this research, for it
means that 605 failures preceded this success.

The only way to get a realizing sense of the influence
of the introduction of these coal-tar compounds is to
pick out one of them and consider what pleasure or pain
it has brought into the world, how much suffering it
has caused or cured.

For instance, did you ever have a headache that you
relieved by aspirin or any of the other coal-tar re-
medies? If so, multiply your headache by as many
million times as you think other people have been so
relieved and by as many years as you think people will
continue to have headaches.

Did you ever have a tooth pulled without, and an-
other one with, the use of a local anesthetic? If so,
you are in position to estimate in some degree the
amount of human misery that has been eliminated by
the invention of procaine (novocain) and similar pain-
killers.

Did you ever see an epileptic fit? Then imagine
that seizure and thousands like it prevented by the use
of luminal.

Did you ever lose a friend from diphtheria? Then
you can realize what it meant to the world that the
bacterium of the disease was made visible by staining
with methylene blue, so that physicians could identify
it in any suspected case and administer an anti-toxic
serum.

Statistics are meaningless to us unless we can trans-
late them into concrete terms.

Who can estimate the increase in industrial efficiency

COAL-TAR 67

and individual happiness caused by the abolition of
malarial mosquitoes in a community whose inhabitants
have shaken for generations with "fever and ague?"

In many warm countries the energy of 80 per
cent, of the population is being continually sapped
by the hookworms which they carry about with them
but which may be expelled by thymol, one of the ben-
zene compounds. I quote a single minor incident in
the anti-hookworm campaign from the 1921 Report of
the Rockefeller Foundation:

Three estates in Sumatra which, in spite of all recommendations,
refused to adopt hookworm control measures, had in the course of
two and one half years 4,657 admissions to the hospital. Three
other estates with a laboring force of the same size which did adopt
these measures had only 1,034 admissions — a difference of 78 per
cent. One hospital admission represented on the average twenty-
two days of treatment, which, reckoned at fifty cents a day, meant
an aggregate loss of no less than 40,000 guilders during a period of
only two and one half years.

A striking illustration of the possible importance of a
coal-tar compound comes to hand as I am writing this.
The Germans are talking of trading off Bayer 205 for
their lost African colonies. Bayer 205 is a secret
synthetic medicine, presumably a coal-tar derivative
like the previously known remedies of the sort, which is
supposed to be a sure cure for the sleeping sickness. It
is said to be fatal to the trypanosomes, the minute
creatures with whip-like tail and spiral movement, that
invade the blood of men and cattle in tropical Africa
and bring them to a stupor that ends in death. These
microbes are conveyed and injected by the tsetse fly, as
fevers are by mosquitoes. The opening up of trade

68 SCIENCE REMAKING THE WORLD

routes through Africa has carried the fly and the para-
site into the heart of the dark continent and almost de-
populated large areas. The white man has found his
dearly bought possessions valueless because neither
man nor beast could live there except under constant
danger of the "pestilence that flieth by night." Vari-
ous coal-tar products have been found effective against
the trypanosomes. Ehrlich used trypan rose, an aniline
dye, and Koch used atoxyl, an arsenic compound, but
none proved a complete and permanent cure once the
vicious little animals were in the blood.

We may question the right of the Germans to with-
hold knowledge of such a boon to humanity until they
get their price for it, although the price demanded is
hardly greater than the total profit that has been de-
rived from other remedies and not by Germans alone.
We may surmise, too, that the Germans could not keep
the secret of Bayer 205 very long anyway, for if the drug
comes into general use somebody will analyze it, what-
ever the promises under which it may be supplied. Or
the pharmacologists of other countries would in time
work out the formula for themselves since they already
can give a shrewd guess at what sort of a substance it is.

But assuming that Bayer 205 is all that is claimed for
it and will rid Africa of its plague and that Germans
have a monopoly of it, then the British, French, and
Belgians could well afford to trade off to Germany a
large part of the immense territories they won by the
war, for the value of the remainder would be immeasur-
ably enhanced. It is not at all likely that such a bar-
gain will be struck, but the mere fact that it has been

COAL-TAR 69

suggested shows that a single coal-tar compound might
have a value that would make it a factor of importance
in international relations.

It is unnecessary to expand upon their war-time im-
portance, but I must call attention to two revolutionary
changes that chemical warfare has made in the balance
of power. First, it has already increased the superiority
of the civilized man over the savage and of the scientific
and industrial nation over the ignorant and primitive.
There is no longer any danger that civilized nations will
be overwhelmed by barbarians, as has often happened
in the past, unless indeed we hatch our own barbarians
in our midst. In ancient times, when martial prowess
meant merely the muscular ability to wield a sword or
spear and a fondness for fighting, the barbarian was
likely to be more than a match for the civilian. But
with the introduction of chemical warfare by the
use of gunpowder in the I4th century, the balance
turned in favour of the scientist against the savage,
and the odds have increased ever since. Second,
the recent development of chemical warfare in the way
of high explosives and toxic gases has given the defence
an advantage against the offensive and has made num-
bers less important than intelligence.

I picked out coal-tar as a topic because it is such un-
promising material; black, smelly, sticky stuff, neither
liquid nor solid but variably between, depending on the
temperature, hard to handle because it could be neither
poured like oil nor picked up like coal, combustible but
not convenient for fuel, poisonous to fish if run into the
water and offensive to folks if left on the land. It was

70 SCIENCE REMAKING THE WORLD

worse than a waste product: it was a nuisance. It
clogged up the gas works in the old days and could
hardly be given away.

When the chemist took this disagreeable stuff in
hand he extracted from it, or rather prepared out of it,
useful and beautiful things innumerable. Out of the
strong came forth sweetness. The most dainty per-
fumes, the most brilliant colours, the most potent
drugs, the most violent explosives, the means of de-
stroying life and extending life, and making life more en-
joyable. A good chemist, like a good cook, is one who
can make best use of left-overs.

Yet coal-tar is not peculiar in its ability to contribute
to man's needs. There are dozens of other forms of
waste that might be made as valuable lying around
loose. As I look out of the window for lack of an il-
lustration, I see the ground covered with autumn leaves
and dried weeds standing thick by the roadside. I
wonder how many million tons of such vegetable matter
containing all sorts of carbon compounds go to waste in
the woods and wilds of the world every year without
serving any other purpose than to refresh the humus
of the soil. And then there is sawdust, and peanut
shucks, oathulls, corncobs, straw, and the refuse from
sugar factories, oil mills, and wood-pulp works; any of
these and their like might well be worked up into all
sorts of desirable commodities.

The production of coal-tar compounds is an import-
ant industry, and I have not tried to conceal its im-
portance in these pages. But it is not a big business.
It is one of the minor chemical industries as measured

COAL-TAR 71

by financial income or avoirdupois output. It does not
compare in these respects with such chemical industries
as steel-making, glass-making, sugar-making, or cement-
making. The coal-tar dyes manufactured in the
United States in 1921 were valued at $32,40x3,000, but
the chewing gum manufactured was worth — or was
sold for — much more ($51,240,000 in 1919).

But 1921 was an off year all around. Let us rather
consider the famous year of 1920 when the United States
manufactured 88,000,000 pounds of dyes valued at
$95,000,000. This is nearly as much as we imported,
chiefly from Germany, in 1914 when we did not have
any dye industry to speak of. We exported American-
made dyes in 1920 to the value of $30,000,000, which is
a big advance over 1914 when we exported only $400,000
worth, and considerably higher than 1921, when we ex-
ported $6,270,000 worth. Still our home industry is
not yet sufficient to satisfy our needs for all kinds of
dyes, so in 1921 we imported about 4,000,000 pounds of
dyes valued at $5,000,000, about nine tenths of which
came from Germany and Switzerland. Besides dyes,
the United States manufactured in 1920 coal-tar
medicinals to the amount of 5,000,000 pounds and the
value of $5,700,000, and perfumes and flavours to the
amount of 100,000 pounds and the value of $300,000.
Whether this infant industry will thrive or decline under
the new tariff law remains to be seen and does not con-
ct rn us here since we are considering only the influence
of these products on the world at large. The figures
and facts given are sufficient to show how rapidly a new
industry, created out of a waste product, can assume in-

72 SCIENCE REMAKING THE WORLD

ternational importance and affect in various ways the
lives of all of us.

The aesthetic and emotional effects of such new
factors in our civilization are doubtless more important
than the material but they are more apt to be under-
estimated because they cannot be figured in pounds or
dollars. What, for instance, is the psychological in*
fluence of the varied tints that our chemists have re-
cently introduced ? On this point we should consult the
sex that takes most delight in colour, or at least makes
most use of it. So I quote without permission from a
private letter I recently received from a professor of
chemistry in one of the leading colleges for women:

Our colours are so much more beautiful than those which we had
formerly. I remember the first aniline dyes which were introduced
when I was a little girl. "Crushed strawberry" and "raspberry"
were fashionable. The colours improved greatly, but they have
never since then been so beautiful as they are getting to be now.
There is a whole range of colours developed by our chemists which
are entirely new, all the shades of henna, of jade, Russian green, the
rose colours, to mention only a few. They are much more suited
to our climate, to our taste and to our fabrics than the German dyes
which so often looked " dowdy." If a colour is pleasing, our chemists
can introduce more varieties in it, just as has happened with henna.
At first there was only one shade, now there are many more, delicate
ones suited to summer skies and deeper ones for winter.

The psychological effect of colour is beginning to be understood
very much better now than formerly. The colours which oui
chemists have introduced are so much more refining and stimulating
than the old ones. A lovely colour gives an aesthetic pleasure, often-
times surpassing that of music, and sometimes makes the possessor
of it aspire to something higher and finer. It brings freedom with it.

Coal-tar has also played a part in the development
of our other aesthetic sense, the sense for sound.

COAL-TAR 73

Carbolic acid, or phenol, is most familiar to us as an
antiseptic for it destroys those microscopic enemies of
ours that are always hanging around ready to enter
any breach in the wall of our bodily citadel. But there
is another use of it, not less important but much less
familiar: its use in making artificial resins. Phenol
unites with formaldehyde, another well-known anti-
septic, and by the union of the liquid and the gas there
is produced a hard solid insoluble substance, looking
like amber or jet. This is called by the various manu-
facturers "bakelite," "redmanol," and "condensite,"
and is extensively used, together with hard rubber, for
the insulating parts of electrical apparatus, therefore
contributing to electric light and power and to tele-
phone and radio. It also is a factor in the phonograph.

Various kinds of tar, asphalts, and pitch are also em-
ployed in the manufacture of phonograph records; each
manufacturing house has its own secret recipe. In the
Edison record a thin coating of condensite on both sides
of the disk receives the imprint of the spiral groove that
carries the music. No synthetic phenol was made in
this country before the war, and when we entered the
conflict there came a sudden demand for an immense
amount of it for making picric acid to be used in shells.
Of course munitions came before music and the phono-
graph was robbed to make explosives. The price of
phenol jumped from nine cents a pound to $1.50.
Edison with his accustomed energy set up a factory for
making phenol artificially and had it running within a
month. Others followed suit and before the war was
over there was plenty. In 1918, 106,800,000 pounds

74 SCIENCE REMAKING THE WORLD

of .synthetic phenol was made in America. But it was,
if you remember, some time before phonograph disks
recovered their former reliability. We knew the world
was out of tune because our records were.

In one of the numerous notebooks, in which Thomas
A. Edison has recorded the ideas that flash through his
fertile brain, is sketched under date of July 18, 1877,
a crude cylinder with a handle and a trumpet, and this
note written beneath:

Just tried an experiment with diaphragm having an embossing
point and held against paraffined paper moving rapidly. The speak-
ing vibrations are indented nicely and there's no doubt that I shall
be able to store up and reproduce automatically, at any future time,
the human voice perfectly.

This was a momentous day in the history of the
human race, for it was the first time that inanimate
nature had answered, although man had been talking
for more than a hundred thousand years. But when
Mr. Edison said "Hello, hello!" back came the friendly
hail "Hello, hello!" from the paraffined paper. It was
the first time that a man had heard his own voice, except
as an echoed syllable. It was the beginning of an era
of preserved speech.

The invention naturally created a sensation and there
war much speculation as to what would come of it.
Edward Bellamy of "Looking Backward" was among
the prophets and he, like most of them, saw in the
phonograph the supplanter of print. It was commonly
expected that our newspapers and books would be re-
placed by talking machines and that we should use our
*ars instead of our eyes in getting the news and perusing

COAL-TAR 75

novels. Not so much was said about the phonograph
as a musical instrument. I asked Mr. Edison, when he
showed me that page in his notebook, if he foresaw its
musical possibilities at the beginning, and he said that
he did not, that he thought of it as a dictating machine,
but now, he said, "I am hoping to hear Beethoven's
Ninth Symphony with an orchestra of seventy-five
pieces perfectly reproduced before I die."

The so-called "talking machine" has had little talk-
ing to do except in office work. There is little call for
the canned speeches of our statesmen and little demand
for recitations except certain comic monologues. The
phonograph newspaper and novel have yet to appear.
We shall have to substitute some sort of continuous
strip for the dinner plate to allow of sufficient length.
The radio with aid of coal-tar compounds has now en-
tered this field and has converted the continent into one
vast auditorium.

In the field of music the phonograph has gone be-
yond the wildest anticipations of its early days. It
is the mocking-bird of musical instruments. It can
imitate all of them, some with such exactness as to defy
detection, some inadequately and imperfectly but suffi-
ciently well to recall to our minds the original music as
we may have heard it and so to give us a pleasure that
is partly memory, as a monochrome sketch will recall
a beautiful painting. It is only in trying to record a
chorus or large orchestra that the diaphragm gets rat-
tled and makes a failure.

Whatever the defects and deficiencies of the phono-
graph as it is, it has served as a test of taste on a nation-

76 SCIENCE REMAKING THE WORLD

wide scale and a trainer of taste as well. It used
to be said that only the few could appreciate the best
music but we know that this is not true. For the great-
est of composers are represented by some disks in the
poorest collection. They may have been bought in
the beginning for the looks of the thing and may at
first be brought out only for high-brow visitors, but
some of the family are likely in time to like them better
than the flashy trashy tinkling tunes that first caught
their fancy. This is the first time that good music has
had an even chance in competition with poor music for
popular appreciation. To rural communities, where for-
merly the only music to be heard was that of a painfully
played cabinet organ or of a self-taught fiddler, the pho-
nograph has brought at least a hint of the possibilities
of all instruments and of the characteristics of various
compositions and of the peculiarities of varied players.
With the phonograph has come into vogue its comple-
ment, the motion picture, and soon the two are likely
to be made one. As the telescope brings to us happen-
ings distant in space, so the phonograph and the motion
picture bring to us happenings distant in time. The
motion picture film is produced with coal-tar developers
so this too as well as all photography might be included
among the beneficiaries of benzene. In short there is
no end to the ramifications of the influence of coal-tar
compounds on our daily life.

GUIDE TO FURTHER READING

"Chemical Discovery and Invention in the Twentieth Century,"
by Sir William A. Tilden. (Dutton.) Chapters XXI and XXIL

COAL-TAR 77

"Creative Chemistry," by Edwin E. Slosson. (Century.)
Chapters IV and VII.

"Application of Dyestuffs," by J. Merritt Matthews. (Wiley.)

"Dyes Classified by Intermediates," by R. Norris Shreve.
(Chemical Catalogue Co.)

"Dyes and Dyeing," by C. W. Pellew. (McBride.) Nontech-
nical.

"Manufacture of Dyes," by J. C. Cain. (Macmillan.)

" Dyes and Their Application to Textile Fabrics/'" by A. J. Hall.
(Pitman.)

"The Story of Drugs," by H. C. Fuller. (Century.)

"The Future Independence and Progress of American Medicine
in the Age of Chemistry." (American Chemical Society.)

"Origin and History of All the Pharmacopoeial Vegetable Drugs,
Chemicals, and Preparations," by J. U. Lloyd. (American Drug
Manufacturers' Association.)

Reports of the United States Department of Commerce and of the
United States Tariff Commission.

ELECTRONS AND HOW WE USE THEM
BY JOHN MILLS, M.A.

Educational Director, Western Electric Company

WHAT is the electron? It is to-day's ultimate
element. What to-morrow's may be no one
can say. In terms of it the scientist of to-day
envisages all matter, all the stuff of which our universe
is composed. The constant change and motion of
matter, which appear as chemical or electrical or gravi-
tational phenomena, are ascribed to another entity,
called energy, which is the hidden motive power. A
third entity is sometimes postulated to fill the broad
spaces in which our tangible and ponderable matter
forms mere specks. A vast ether is then assumed
through which energy may be transmitted from one
body to another, whether as light and heat from solar
bodies or as so-called ether waves from a broadcasting
radio station to the household receiving set.

Matter energy, and a universal medium are the three
entities in terms of which our present-day science is
finding its explanations and extending its applications
to human welfare. Of these the ether is the most de-
batable assumption. Perhaps energy is not trans-
mitted in waves through a continuous ethereal medium
but hurtles through empty space like a bullet. For this

78

ELECTRONS 79

there is much evidence — too much in fact for exposition
within the limits of a single chapter.

Energy, the second unknown of modern science, is
accepted by the physicist, not only because it is a
necessary assumption in the eternal sequence of changes
which occur within us and about us, but also because
there is an unknown something which correlates exactly
with all these changes and seems to be conserved
throughout them. Whenever changes occur in the
form,' chemical composition, or location of bodies of mat-
ter the magnitude of the change is always definitely to be
predetermined upon the assumption that this mysteri-
ous energy will be constant and unchanged in amount.

Its existence is an inference from the motions in-
volved in the change. Only in this kinetic form is it to
be detected and measured; and then, of course, only by
the motions of ponderable matter. Between such occa-
sions it masks its potentialities and appears as harmless
as the explosive shell, the high-tension electric wires,
or the reservoir of still water in the hills above the hydro-
electric plant. But when released, the magnitude of
the changes which occur shows that it has not been
altered by quiescence.

In a science where the ether is a convenient postulate,
and energy a formless unknown, the electron stands
out in stark reality as a definite ponderable particle,
the tiny material element of the universe.

Its identification in 1897 by Professor J. J. Thomson
followed close upon the discoveries of radium and
X-rays to which it now furnishes the mechanism for a
valid explanation. The quarter of a century since his

8o SCIENCE REMAKING THE WORLD

definite experiments has been enriched by thousands of
delicate researches and the verification of ingenious
theories.

In the first place there has been proved the existence
of a counterpart to the electron, a complementary par-
ticle, conveniently known to-day as the "proton." In
the original literature the proton is called a positive
electron, the term deriving from the earlier and arbi-
trary classification of electricity as positive or negative.

Of protons and electrons all known kinds of matter
are composed. More than that, these elementary
particles are the positive and negative electricities which
were earlier assumed to explain electrical phenomena.
So now we say that matter is granular in structure and
electrical in nature, although we might equally well say
that electricity is granular and material.

These positive and negative specks follow the well-
known electrical laws: like particles repelling each other
and unlike attracting. Their actions (manifestations
of energy), appear as if they were the result of two urges
for both of which a common satisfaction is only rarely
attained. One is toward the assembling in any region
of equal numbers of protons and electrons, that is, a
tendency toward an unelectrified condition. Protons
are attracted toward regions where there are more
electrons than protons, and vice versa. Bodies com-
posed of more protons than electrons are called posi-
tively charged; and similarly an excess of electrons is
the state of a negatively charged body. The uncharged,
or neutral, condition with equal numbers is the stable
condition.

ELECTRONS 81

The other urge, instead of depending as does the first
upon the mutual attraction of protons and electrons,
depends upon the mutual repulsions which occur be-
tween two or more protons or between two or more
electrons. In any grouping of several protons and
electrons there are some amenities in the way of proper
separations between mutually repellent members. Cer-
tain configurations, or arrangements of the particles in
space, seem to be more stable than others and toward
such configurations this second urge is effective.

One of the most stable groups comprises four protons
and four electrons, satisfying thereby the more funda-
mental urge of equal numbers. All of these, except two
electrons, are closely grouped into a tiny particle, known
as an "alpha particle." Why and how four protons
and two electrons should group so closely no one as yet
knows. (Perhaps, at such infinitely small and sub-
atomic distances, it has been suggested, the laws of
attraction and repulsion do not follow the same mathe-
matical relationship as they do for the larger distances
at which they were determined.) The two remaining
electrons disport themselves at some distance and
presumably on opposite sides of the alpha particle, which
attracts them because it has an excess of protons.

The entire group is known as an atom of helium, that
inert gas which has been recommended for airships.
In this grouping both urges find complete satisfaction.
No greater satisfaction could be obtained by any ar-
rangement; so there is no residual tendency to join with
other protons and electrons to form a larger but more
stable group.

82 SCIENCE REMAKING THE WORLD

In the helium atom we have the characteristic struc-
ture of all atomic systems. At the centre there is a
nuclear particle composed of a close arrangement of
protons and electrons but including more protons than
electrons. In the region beyond there are electrons.
The whole constitutes a miniature celestial system in
which the nucleus is the central mass and the remaining
electrons planetary satellites.

Atomic structure is more completely illustrated by
the familar nitrogen of which we daily breathe about
four times as much as we do of oxygen. Its nucleus
contains seven more protons than electrons; in fact
fourteen protons and seven electrons. About this
nucleus are seven planetary electrons. Two of these
apparently occupy positions on opposite sides like the
satellites in the helium atom; and the remaining five,
at a greater distance from the nucleus, are disposed as
if on an imaginary sphere about the nuclear centre.

How much of this well-ordered picture is speculation?
Relatively little. Admitting that the evidence is not
direct but circumstantial and that the positions of the
planetary electrons are not exactly known, the state-
ment stands as made. The evidence, however, may
well wait the presentation of further facts and some
ideas as to the magnitudes involved.

Imagine this atom of nitrogen which consists of seven
specks in space enclosing imperfectly a central speck,
for the atom is mostly hole — imagine it magnified about
one hundred thousand times. The specks would then
be about as large as the unmagnified atom. Two such
atoms of nitrogen, associated much like partners in

*>,

£lectro Ntgaffr*

From "Within the Atom," by John Mills. Published by D. Van Nostrand Company

Atomic systems at the periodic table. Place numbers correspond to
atomic numbers. Systems similarly situated, as indicated by radial
lines, have similar chemical properties

83

84 SCIENCE REMAKING THE WORLD

polite dancing, form a molecule of nitrogen. Of such mol-
ecules you inhale with each breath a few score billion,
to say nothing about one fourth as many oxygen mole-
cules each formed of two atoms. In the air around
you all these molecules are moving at about one thou-
sand miles an hour, in a haphazard way, for on the aver-
age each can travel less than one thousandth of an inch
before it must dodge another. That means a change
of front about fifty million times a second, and estab-
lishes a world's record in expediency.

Now imagine a cube of this air about three eighths of
an inch on a side, a cubic centimeter. Let the cube and
its contents grow until its edge would reach from New
York to Cleveland. Then about every foot along the
way there would be a molecule; but you could not ex-
pect to see one because it would be only a few tiny
specks, each speck about one hundred thousandth of an
inch.

Nitrogen has an excess of seven protons in each
atomic nucleus. Helium has two. So far as concerns
an excess of protons in the nucleus there are just ninety-
two possible conditions, extending from a nucleus of one
proton and no electrons to the condition of ninety-two
more protons in the nucleus. Whether or not there
ever were any nuclei with an excess of more than ninety-
two no one knows. If there were in the early geologic
ages, they have now disappeared, for nuclei with more
than eighty-two excess protons spontaneously disinte-
grate. This is the secret of the radioactive elements of
which radium is the widest known, but uranium and
thorium are the unrelated parents.

ELECTRONS 85

Uranium, a chemical element of which the atomic
nucleus has an excess of ninety-two protons, has a most
unstable internal situation. Every little while some
atom of uranium will yield to the strain and expel from
its nucleus a whole group of protons and electrons,

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From "Letter, of a Radio-

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Harcourt, Brace and Com-

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closely associated and forming the so-called alpha par-
ticle. When it has done so the nucleus contains four
less protons and two less electrons, making a net excess
of ninety. During the process the number of planetary
electrons is reduced from ninety-two to ninety, to cor-

86 SCIENCE REMAKING THE WORLD

respond to the reduced attraction of the nucleus. The
result is the formation of an atom of an entirely different
chemical element with different chemical properties.

This process has continued for ages, gradually de-
creasing the supply of uranium. In its place are its
disintegration products, uranium X», so-called, and
helium because the emitted alpha particle soon finds
two electrons to act as its planets and with them settles
down to the uncompanionable existence of a helium
atom.

The expulsion of an alpha particle from a uranium
atom fails, however, to cure its internal troubles. Two
electrons are therefore successively expelled from the
nucleus of the newly formed uranium X,. The excess
of protons in the nucleus is increased from ninety to
ninety-one and then to ninety-two. The expelled
electrons shoot into space with enormous velocity, but
their independent careers are not our present concern.

With their leaving, the nucleus returns to a condition
of ninety-two excess protons. Thereafter it is a spend-
thrift, losing one alpha particle after another until it
finally becomes identical with the nucleus of the lead
atom, which has an excess of eighty-two. During its
downward progress it serves for a time as the nucleus
of the well-advertised radium atom.

The radioactive elements are responsible for much
of our present-day knowledge of electronic physics.
They gave away the inner secrets of a large group of
atoms to such ingenious and persistent investigators as
Professors Rutherford and Soddy. It was the former,
for example, who proved that the alpha particle is really

ELECTRONS 87

the kernel of the helium atom. He used a glass tube
with a deep dimple in one side. First he tested the
atmosphere within the tube for the presence of helium
and found none. Then in the dimple he placed a radio-
active substance. Again he tested; and helium was
then present. The enormous velocities of the alpha
particles had carried them through the glass wall into
the enclosed space, where they showed in the spectro-
scope the lines which are characteristic of helium.

More recently Professor Rutherford has let these
alpha particles shoot through nitrogen gas. Imagine,
if you care to, some enormously solid comet plunging
into our solar system so rapidly as not to perturb our
planet until the fatal moment when it collides with the
sun. The violent impacts of alpha particles and nuclei
of nitrogen were relatively infrequent since both are
very tiny; but when they occurred the nitrogen atom
was disrupted and some of the protons knocked out of
its nucleus.

There is dove-tailing evidence enough on all these
matters to require several graduate courses in physics
for its exposition, so the reader whose time is limited
must accept it on faith. He might justly ask, however,
how these protons were recognized? By the distance
they were knocked ! And the reason is this : Alpha par-
ticles rushing from their former nuclear homes will
penetrate a fairly definite distance in air before they are
so slowed down that they will not produce little scin-
tillations when they strike a properly prepared screen.
If instead of air they rush through an atmosphere of
hydrogen gas the effect is the same except that occa-

88 SCIENCE REMAKING THE WORLD

sional scintillations may be observed at a much greater
distance from the radioactive material. Now, hydro-
gen has long been known to be an atom with a single
proton for a nucleus and, of course, one planetary elec-
tron. These scintillations are due to these protons
which, being lighter than the alpha particles, are thrown
farther by the collision. When pure nitrogen is used
there are occasional scintillations at that greater dis-
tance which corresponds to a single proton being pro-
jected forward by the collision.

In the radioactive atoms the nucleus is most expres-
sive but in all atoms it is the real determining influence.
Upon it depends the number of planetary electrons,
for their number is normally equal to the excess of pro-
tons in the nucleus. Upon this number depends the
configuration and that determines the chemical behav-
iour of the atom. In final analysis the nuclear content
makes the atom what it is. For that reason it is con-
venient to classify on a purely numerical basis by the
"atomic number" which states the excess of protons in
the nucleus.

For purposes of visualizing the chemical behaviour
of atoms it is simplest to deal with those of atomic
numbers n and 17 which are sodium and chlorine,
respectively. Now it happens that the atom of atomic
number 10 is that of neon, an inert gas, much like helium
except heavier, which is completely satisfied. The
atomic number 18 denotes another satisfied structure,
that of argon. Sodium and chlorine, however, were
created without the complete satisfaction of both the
urges which were mentioned earlier. Sodium has one

ELECTRONS 89

planetary electron too many for a really satisfactory
configuration such as is represented by the planetary
electrons in the neon atom. Chlorine on the other hand
lacks one electron of the eighteen which would assume
the stable arrangement of the argon atom.

A sodium atom is like a human being wrought upon
by two conflicting emotions. If it should lose a planet-
ary electron its remaining satellites would have a satis-
fied configuration, but the urge for an equal number of
protons and electrons would then be effective and the
atom would merely have changed the kind of its dis-
content. On the other hand, the chlorine atom would
be better off with an additional electron in its planetary
spheres, if it were not that, for it also, the urge of equal-
ity and electrical neutrality would then be dominant.
One has an electron to lose : the other, one to gain. They
meet apparently on the same plane of mutual profit
as do buyer and seller in the ideal case of business trans-
actions. An electron is transferred. But neither
buyer nor seller dares balance his books thereafter.
The only solution is to remain together so that for pur-
poses of accountancy the transaction may be considered
incomplete and yet both may have the satisfaction
which is the profit. This seems to be the basis of the
existence in combination of a sodium and a chlorine
atom as a molecule of sodium chloride, the common salt
of the table. In fact, in a crystal of salt the various
atoms are arranged in orderly rows in such a manner as
to make the accountancy surprisingly satisfactory to
each atom. Above and below, in front and behind,' to
right and left of each sodium atom there is one of

90 SCIENCE REMAKING THE WORLD

chlorine; and the converse is true of each chlorine atom.

In the confusion, however, which occurs when salt is
dissolved in water the necessity of balancing accounts is
momentarily forgotten. The chlorine nucleus moves
out into free space between the water molecules, taking
with it as an extra satellite an electron from the sodium.
The sodium nucleus starts off on its wanderings with
one too few electrons. From that time on each is an
"ion," an electrically charged particle, seeking a means
of balancing its electronic accounts. In its wanderings
it may meet with another and oppositely charged ion
but the association and consequent satisfaction are only
transient because the fluid milieu in which they find
themselves encourages incompatibility. (Of course, if
there is too little water crystallization occurs.)

If molecules of some other substance, which also dis-
sociates into ions, have been dissolved in the same
water these ions may afford satisfaction to the ions
formed from the salt. A positive ion, that is one which
has lost an electron, will always welcome a meeting with
a negative ion for the latter has too many electrons.

Combinations into molecules occur between atomic
systems, that is atoms or ions, either under the urge of
attaining greater satisfaction of configuration for the
planetary electrons or under the urge of becoming elec-
trically neutral. (In the non-chemical phenomena of
electricity it is the second urge which is responsible.)
The un satisfactions which lead to activities may involve
more than one electron for each atom, instead of just
one as in the simple case of sodium and chlorine. Com-
plicated molecular unions may, therefore, be formed

ELECTRONS 91

comprised of many atoms, which as individuals may
have had urges of different degrees of intensity.

The chlorine atom which serves for visualizing chem-
ical activity will also illustrate one fact which remains
to be expressed before the picture is complete. Chlor-
ine is a substance well known to the chemist. In our
modern terms it is the element of atomic number 17,
that is, it contains in its nucleus seventeen more protons
than electrons. Its atomic number states a difference;
but what about the actual content of the nucleus?

In the first place we know the masses of the proton
and electron. The proton is about eighteen hundred
and fifty times greater in mass than the electron. It is,
therefore, responsibile for the weight of discrete atoms
and of their aggregations in such masses as we weigh on
chemists' balances or coal-scales. The weight of a
helium atom which contains four protons in its nucleus
should then be practically four times that of the hydro-
gen atom which has a single proton for its nucleus.
Oxygen, which is known to contain sixteen protons, is
approximately sixteen times as heavy as the hydrogen
atom.

The masses of various atoms have been found by an
electrical method by Professor J. J. Thomson and more
recently by Dr. F. W. Aston. The method involved
ionizing the atoms, that is removing from them one or
more electrons. Due to the resulting electrified condi-
tion the atom will respond to electrical attractions and
repulsions. The amount of its motion may then be
used as a measure of its mass just as you might measure
masses by observing what motions you could give to

92 SCIENCE REMAKING THE WORLD

them with a definite muscular force. As to knocking
electrons off from atoms, and thus ionizing, there are
many ways but they are not our present concern.

The important point is that because of the electrical
nature of the tiny particles which compose atoms it
becomes possible not only to determine the masses of
the atoms but also to separate atoms by weight.

The chemist has always separated atoms on the cri-
terion of chemical behaviour, that is, unconsciously un-
til recently, on the basis of atomic number. For atoms
so separated there have long been available very accurate
determinations of the relative weights of the atoms of
different chemical elements. The results of the elec-
tronic physicist agree with these in those cases where
the chemist had found for the atomic weight a whole
number, when compared to the weight of the oxygen
atom assumed as sixteen. The weights should be re-
lated as integers since the nucleus should contain whole
numbers of protons.

The chemical method determined the average atomic
weight of a large number of atoms of a chemically pure
element. The physical method could be applied to a
mixture of elements and would separate the atoms
according to their weight. The chemical method
applied to chlorine obtained an atomic weight of 35.45
on a scale where the oxygen atom was 16.00. The
physical method applied to chlorine indicated a mixture
of two distinct types of atoms, one with a weight of
35 and the other with a weight of 37. There were ap-
parently in any sample of chemically pure chlorine
about three times as many atoms with weights of 35

ELECTRONS 93

as there were with weights of 37. On the average such
a mixture would then have the weight indicated by the
chemical method.

Two kinds of atoms, differing in the total number of
protons, were thus found to possess the characteristic
behaviour of chlorine. They are called "isotopes" of
each other because they occupy in the chemical tables
the same position. The term was introduced by Pro-
fessor Soddy who has met a similar phenomenon in his
study of the chemistry of the radioactive elements.
The case of uranium which was cited earlier will illus-
trate it. Uranium loses from its nucleus successively
an alpha particle and two electrons. Thereby it has
reduced its nuclear content by four protons and four
electrons. The atomic number of the new element,
uranium II, is the same as uranium; the chemical
behaviour is the same although, of course, the radio-
activity is different; but the atomic weight is reduced
by four units. The new element is an isotope of the
old, chemically identical, but with a lower atomic
weight.

Such is a brief outline of the present ideas as to the
matter of which our universe is composed. It is gran-
ular in structure and electrical in nature, being com-
posed of definite specks. Upon the number and
arrangement of these specks, protons and electrons,
depend all the physical and chemical characteristics of
matter.

Instead of classifying matter inexactly by the average
behaviour of a number of atoms it is now possible to
extend a rigorous and numerical classification to individ-

94 SCIENCE REMAKING THE WORLD

ual atoms. The key to the atom is its nuclear composi-
tion. Its weight depends upon the number of protons
in its nucleus. Its normal possibilities of combination
into molecular form, that is, its chemical properties,
depend upon the excess of protons in the nucleus. That

From "Letters of a Radio-Engineer to His Son," by John
Mills. Published by Harcourt, Brace and Company, IDC.

The Thermionic Vacuum Tube. Electrons emitted by a heated fila-
ment, F, are drawn across a highly evacuated space to a plate, P. The
stream is very sensitive to changes in the electrical potential of the
grid, G. The device is widely used in the Bell System as an amplifier of
telephone currents

determines what is its normal complement of planetary
electrons and their configuration.

In terms of excess protons in the nucleus, that is, the
so-called atomic number, there are ninety-two classes,
of which eighty-seven are known chemical elements.
In each class, however, there may be required a further
subdivision on the basis of total number of protons in
the nucleus. In addition, although the point has not
previously been developed, there may be a difference
in nuclear history which predisposes a nucleus to one

ELECTRONS 95

course of degradation rather than another. This is
true of certain of the radioactive elements, where atoms
of the same atomic weight as well as of the same atomic
number may follow different sequences of radioactive
changes.

Whenever the number of planetary electrons about
a nucleus does not correspond to the atomic number,
then the atomic system is electrically charged, that is,
"ionized/* Its further activities are due to that charge
and the atom is under the urge of restoring a state of
electrical equilibrium. Of such activities there are too
many for present mention. They accompany any de-
rangement of the planetary electrons and to them are
due many of the phenomena of light and X-rays.

A current of electricity exists whenever there is a
stream of electrons from one point to another. In con-
duction through gases the gas must be ionized before it
becomes conducting. Its molecules must be split apart
in some manner which will result in the formation of
ions, that is, atomic or molecular systems which have
more or less than the normal number of electrons. Such
ionization may be accomplished in a number of ways,
by the action of ultra-violet light, by exposure of the
gas to X-rays, by impacts with swiftly moving electrons
or alpha particles from radioactive substances, or by
collision with swiftly moving free electrons or ions how-
ever obtained. Under these conditions some of the
gaseous molecules lose by impact planetary electrons
and thus become positive ions. The freed electrons
immediately take up their way toward the positive elec-
trode and the positive ions take the opposite way

96 SCIENCE REMAKING THE WORLD

toward the negative electrode. Both may produce
further ions from the normal molecules of gas with
which they collide if the impacts are sufficiently violent.

Such, in general, is the phenomenon of conduction
through gases. In solid bodies, like wires, conduction
occurs by the motion of free electrons which wander this
way and that through the intermolecular or interatomic
spaces. The metals, the best conductors, are electro-
positive, that is, their atoms are systems with incon-
venient electrons in excess of the simplest configura-
tional requirement but not in excess of the number of
protons in the atoms. It is these loosely held electrons,
most probably, which serve to conduct electricity
through solid conductors. Their haphazard wander-
ings are superseded by a definite drift when the ter-
minals of the solid are connected to a battery.

This phenomenon of electron streams in wires con-
ducting electricity is made to furnish the electrons
which form the stream through the vacuum of an
audion. The audion consists of an evacuated vessel
with a filament through which a current of electricity
may be passed. There is also a metal plate and be-
tween the plate and the filament a fine wire-grid.

A strong current of electricity through the filament is
manifested by its rise in temperature and its lumines-
cence. Both the heat and the light are due to the dis-
turbances created among the atoms of the wire by the
stream of electrons which constitutes the current. The
individual electrons of the stream, which is being forced
through the filament by an external battery, must dodge
or jostle their way past the more fixed atomic systems

ELECTRONS 97

and the stay-at-home electrons. They move with
considerable velocities and from time to time one is
diverted from the straight path of the conductor and
flies beyond the restricting influence of its protons to
the free space surrounding the filament. The number
that thus escape is very large, increasingly so at high
temperatures of the filament.

Another battery is connected to the audion in such a
manner as to make the plate positive with respect to
the filament. The free electrons are then drawn across
the vacuum from filament to plate. On the way, how-
ever, they pass through the meshes of the grid. The
latter is strategically placed nearer the filament than
the plate. Feeble electrical changes in the condition
of the grid, therefore, produce pronounced changes in
the stream of electrons which flows from filament to
plate. Changes produced in this manner will be evi-
dent in the external portion of the electrical circuit
which is formed by the second battery, the filament, the
plate, and the intervening vacuum. The small inertia
of these individual electrons and the delicacy with
which the strategically placed grid controls their actions
have resulted in the marvellous application of the audion
to the electrical communication of speech by wire and
by radio.

GUIDE TO FURTHER READING

" Matter and Energy," by Frederick Soddy. (Henry Holt.) 1912.
' nee and Life," by Frederick Soddy. (John Murray.) 1920.
"Within the Atom," by John Mills. (D. Van Nostrand and
Co.) 1922.

98 SCIENCE REMAKING THE WORLD

"Letters of a Radio-Engineer to His Son," by John Mills. (Har-
court, Brace & Co.) 1922.

"Molecular Physics," by James A. Crowther. (P. Blakiston's
Son & Co., Phila.) 1919.

"Chemistry and Its Borderland," by Alfred W. Stewart. (Long-
mans Green & Co.) 1914.

"The Electron," by Robert A. Millikan. (Univ. of Chicago
Press.) 1917.

"Electrons, Electric Waves and Wireless Telephony," by J. A.
Fleming. (Wireless Press.) 1922.

"The Radio Pathfinder," by Richard Ranger. (Doubleday, Page
&Co.) 1922.

AN INVESTIGATION ON EPIDEMIC
INFLUENZA

BY PETER K. OLITSKY, M.D. AND
FREDERICK L. GATES, M.D.

The Rockefeller Institute for Medical Research

EPIDEMICS of influenza have occurred at Intervals
for centuries, and may be recognised from con^
temporary descriptions though they were known
under different names in different places and different
times. The disease has had a wide or more restricted
distribution according to various circumstances of the
time, especially the rapidity and extent of the move-
ments of men. Thus in earlier centuries human trans-
port carried the pestilence slowly and over limited
areas; in modern times, in a world knit closely together
with frequent and rapid means of migration, the disease
passes quickly from country to country and from con-
tinent to continent. During the World War it quickly
exacted a death toll from the warring countries surpass-
ing their losses under arms.

The place or places of origin of the epidemics are still
under investigation, and it remains for future study to
determine whether the spread takes place from a single
source or from many. History traces the outbreaks
of many epidemics to regions of eastern Russia and
Turkestan; but indications are not wanting that in-

99

xoo SCIENCE REMAKING THE WORLT5

fluenza lurked in many centers preceding the pandemic
of 1918. Which ever of these divergent places of origin
proves to be the true one, certain essential conditions
(as yet undiscovered) must be regarded as combining
to convert smouldering inactivity into epidemic spread.

THE EPIDEMIC OF 1918. — The emergency created by
the epidemic outburst of 1918, which was of unparalleled
severity, coincided with the exigencies of the Great War
so that the full weight and force of modern methods
of clinical and bacteriological study could not quickly
be brought to bear upon the disease. In many instances
investigators were further handicapped through failure
to distinguish influenza as a primary infection from the
frequent pneumonias of common bacterial origin which
were secondary to it; or were prejudiced in their views
by the general acceptance of Pfeiffer's bacillus as the
bacterial cause of influenza. This bacillus had been
discovered by Richard PfeifFer during the epidemic of
1889.

Early in the course of the epidemic, however, discor*
dant findings cast doubt on the part played by Pfeiffer's
bacillus as the cause of the disease and in many labor-
atories the search was started de novo for some hitherto
unknown microbe whose distribution and character
would more nearly fit the requirements of the case.
The results of such an investigation at the Rockefeller
Institute for Medical Research are described in this
chapter.

DEFINITION OF EPIDEMIC INFLUENZA. — Epidemic in-
fluenza free from complications is usually a mild affec-
tion. On the fringes of an epidemic it is not always

EPIDEMIC INFLUENZA 101

easy to distinguish it from other indefinite ailments of
the upper respiratory tract. In the midst of an epi-
demic, however, when many similar cases may be seen,
its manifestations are more obvious and uniform. The
attack is usually sudden with a chill, or chilly sensations*
and fever. Headache, frontal or general, develops,
with pains in the back, joints, and extremities. In the
severer cases the prostration that accompanies these
symptoms forces the patient to bed. The eyes become
inflamed and painfully sensitive to light. The face is.
flushed; the throat swollen and raw, a thin irritating
secretion flows from the nose, and the progress of the
infection is denoted by hoarseness and a dry and dis-
tressing bronchial cough. Examination of the chest,.
however, reveals no certain signs of lung involvement.
Other organs are not usually obviously affected. Pulse
and respiration are only slightly accelerated. The
temperature remains fairly constant, between 101.5
and 103° F. for two to four days and, then after a pro-
fuse perspiration, it falls rapidly to normal (about
98.5° F.) with the beginning of convalescence.

The duration of uncomplicated influenza is usually
one to three days; in the severer cases four to six days.
When symptoms persist beyond this period a secondary
pneumonia or seme other sequel is to be suspected.

Peculiar features of the disease are an early drop in
the circulating white blood cells, a lowering of the resis-
tance of the lungs to secondary infection by common
bacteria, resulting in a high incidence of severe and
ffctal secondary pneumonias, and the persistence of a
profound physical and mental depression during con-

102 SCIENCE REMAKING THE WORLD

valescence. Characteristic of an epidemic is the rapid
spread, coupled with a high incidence of infection, so
that more than half a population may be attacked in
the first wave, and the recurrence of successive waves
of diminishing extent and severity until, in the course
of three or four years, the epidemic dies out.

EXPERIMENTAL INOCULATIONS. — In September, 1918,
when it was decided to undertake a search for the in-
fectious agent of epidemic influenza in the laboratories
of the Rockefeller Institute for Medical Research,
methods of transmitting the infection to animals were
first considered, because an experimental infection in
animals offers facilities for study not obtainable in
human cases. For example, the transmission of a
transient disease such as influenza through animals
insures its indefinite propagation and affords material
for study after human sources fail. An infection in
laboratory animals can be interrupted at any time for
necessary examinations of its progress and offers many
avenues of approach which are closed to the investigator
if he must depend wholly upon human cases for study.

Uncomplicated influenza, however, is a relatively
mild disease in man and some of its prominent manifes-
tations such as chills, headache, sore throat, and de-
pression cannot be observed in animals. It was ex-i
pected that the experimental disease, if successfully
established in animals, would be mild as well, and
might be missed unless some definite, measurable cri-
teria could be employed to indicate the development of
abnormal conditions similar to those observed in human
<:ases. It was thought that among the characteristic

EPIDEMIC INFLUENZA 103

signs of the human infection, the typical changes in the
blood might be used as an indication of successful trans-
mission and it appeared probable that some local injury
might be found in the lungs of the animals which would
account for the characteristic defect in the resistance of
the lungs following human influenza.

Influenza is transmitted from person to person by the
secretions of the respiratory tract, so the first experi-
ments were undertaken with washings from the noses
and throats of human patients in the early hours of the
disease. These washings of course contained many
varieties of bacteria, but it was expected that in favour-
able instances the ordinary bacteria of the nose and
throat would be suppressed through the natural resis-
tance of the animal and that the specific effects of an
extraordinary microbe might thereby be revealed.

In a short series of experiments monkeys were found
to be unsuitable for use in the study of influenza both
because of their scarcity and because of the frequent
presence of pulmonary tuberculosis in the available
monkeys. These preliminary experiments, however,
gave a clue to a method of injecting the nasal washings
which promised definite results. Injections of the
washings into the nose and throat, the eyes, the blood,
and under the skin produced no distinctive effects.
But when the injections were made into the trachea,
so that the material ran down into the lungs, the mon-
keys showed a decrease in the white cells of the blood,
such as is characteristic of human influenza. This
suggestive sign could not be correlated with local dam-
age to the lungs, however, because of the frequency

io4 SCIENCE REMAKING THE WORLD

of diseased conditions due to other causes. The rabbit
was then chosen for further experiments.

The results of the first injections of nasal washings
from human influenza patients into the lungs of rabbits
showed that something in the washings was producing
definite and characteristic effects. On the first or
second day after injection the rabbits appeared ill, with
ruffled fur, inflamed eyes and usually a degree or two of
fever. The constant feature of their illness was a
sudden drop in certain of the white cells of the blood
which fell to half or a quarter of their normal number.
These effects were transitory, and after two or three
days the animals recovered. If the animals were killed
for examination at the height of the attack, their lungs
showed evidences of a definite type of injury and dis-
organization unlike that found in ordinary pneumonia
but similar in many respects to the influenzal damage
found in persons dying early in the disease. Usually
no ordinary bacteria could be recovered from the in-
jured rabbits' lungs and it appeared that the effects pro-
duced by the human nasal washings were independent
of the presence of commonly recognized microbes.

By injecting into the lungs a suspension of ground
lung tissue from a previously affected rabbit the typical
effects just described could be induced successively in
a series of animals. In one instance fifteen successive
transmissions were obtained before the experiment was
discontinued. The persistence of these characteristic
results, in spite of the repeated dilution of the original
material between transmissions, indicated the presence
of a self-perpetuating agent; a living organism or virus.

EPIDEMIC INFLUENZA 105

The next step was to define the living agent more
exactly and to attempt its cultivation in the laboratory.
It was soon found to be so minute that it readily passed
through earthenware filters impervious to ordinary
bacteria. In this way it could be separated from other
microbes in the human nasal washings or in affected
rabbits' lungs. Filtered nasal washings from influenza
patients and filtered lung suspensions produced the
typical train of effects in rabbits and thus proved that
ordinary bacteria were not involved in the process. The
specific microbe, which as yet had not been seen but
whose presence was clearly indicated by the animal
experiments, was a "filter-passer." Now although very
few filter-passing microbes have been identified, the
group, in general, has certain well-known characteristics
which this virus was found to share. For example,
although it was readily killed by heat at 133-140° F.,
temperatures often used in pasteurization, it was resis-
tant to drying or freezing and could withstand the
action of 50 per cent, glycerine for periods up to nine
months. When animal tissues containing it were con-
taminated by moulds or bacteria, the virus still survived.

Another noteworthy effect of this active agent early
claimed attention. When unfiltered nasal washings
from influenza patients were injected into rabbits* lungs,
other microbic residents of the nose and throat were
likewise deposited. Ordinarily such bacteria do not
do any damage under these conditions but are over-
powered by the active protective mechanisms of the
body. But in the presence of the primary injury caused
by the influenzal agent these bacteria were sometimes

io6 SCIENCE REMAKING THE WORLD

able to multiply and cause severe pneumonias. The
similarity of these accidental infections in the experi-
mental animals to the secondary pneumonias in man
led to a series of experiments to put this significant train
of events to further test.

These experiments proved that a decrease in the re-
sistance of the lungs to common bacteria was a charac-
teristic result of infection with the filterable virus.
After the lungs had been damaged by the influenzal
agent the other organisms were injected into the trachea
or into the blood stream, and from both sources the
common bacteria invaded the injured lungs and there
induced a typical pneumonia. To the normal lungs of
healthy or "control" animals the same doses of these
microbes were harmless.

The first object of the investigation had now been
accomplished. An infectious agent, present only in the
nasal washings of influenza patients in the early hours
of the disease, had been transmitted to laboratory
animals and could now be studied under experimental
conditions. The presence of this virus induced changes
in the blood that are typical of the blood changes in
human influenza. And the lungs of the infected rabbits
were found to be the site of typical injuries, which pre-
disposed them to severe and fatal pneumonias.

ARTIFICIAL CULTIVATION. — From the beginning of
the investigation, while the first animal transmission
experiments were in progress, attempts were made to
isolate the active agent in artificial cultures outside the
body. For this purpose the usual methods of cultiva-
tion were discarded in favour of the particular methods

EPIDEMIC INFLUENZA 107

developed by Doctor Noguchi, based on the early ex-
periments of Doctor Theobald Smith. The Smith-
Noguchi culture medium, which had proved successful
in the cultivation of certain highly parasitic microbes,
consists of dilute blood serum or tissue fluid with a
small fragment of fresh sterile tissue — usually rabbit
kidney — and is thus very different from the artificial
broths and jellies commonly employed in bacteriology.
Besides furnishing nutritive substances the tissue frag-
ment creates an environment favourable to those pe-
culiar "anaerobic" microorganisms which can live only
in the absence of air. The choice of this medium for
the cultivation of the active agent of the animal trans-
mission experiments proved to be a fortunate one.

In November, 1918, certain extremely minute but
characteristic spindle-shaped bodies were observed in
strictly anaerobic cultures of the filtered nasal washings
of an influenza patient in the early hours of the disease.
In size they approached the limit of vision with the high-
est powers of the microscope so that the sparse growths
in the early cultures were identified with the greatest
difficulty. Soon, however, other cultures were ob-
tained, both from the filtered nasal washings of other
influenza patients and from the whole or filtered lung-
tissue specimens of rabbits which had been typically
affected by these secretions, as has been described.

As these minute microorganisms were carried through
successive generations of culture, they became better
adapted to artificial cultivation and multiplied more
luxuriantly, so that the cultures could be used in animal
experiments with unequivocal results. These experi-

io8 SCIENCE REMAKING THE WORLD

ments proved beyond question the identity of the
active agent obtained from influenza cases and the
bodies obtained in culture. Both were derived from
the same sources. Both were filterable. Both pro-
duced identical effects in rabbits, and from the pulmon*
ary lesions produced by either, further animal passages,
or cultures, could be obtained. Both, protected by
bits of affected lung tissues, withstood 50 per cent,
glycerine for periods of months. Both had that curious
property of damaging the lung in such a way as to lower
its resistance to secondary invasion with ordinary bac-
teria. It was from this character that the microbe,
objectively, received its name. It was called Bacterium
pneumosintes — a bacterium that injures the lung.
Finally, conclusive evidence of the identity of Bacterium
pneumosintes and the virus from the human nasal
washings was furnished by a series of experiments which
showed that a previous infection with either one of these
pathogenic agents rendered an animal immune to attack
by the other.

IMMUNITY. — In many infectious diseases, the im-
munity conferred by an attack is associated with the
appearance in the blood of specific principles, or "anti-
bodies," which can be demonstrated by serum tests.
Efforts were therefore directed toward the observation
of antibodies in the blood of experimentally infected
rabbits, and of influenza patients, from which the
strains of Bacterium pneumosintes ultimately had been
derived. But it was found that cultures of Bacterium
pneumosintes in the Smith-Noguchi medium were un-
suitable for such experiments. The sparse growth of

EPIDEMIC INFLUENZA 109

the earlier generations was mixed with protein precipi-
tate that interfered with the reactions and had proper-
ties that precluded its use. It was therefore necessary
to devise special methods of cultivation, and before
these methods became available the first opportunity
was lost to test for antibodies in the blood of influenza
patients and of affected rabbits.

It was found later that if the Smith-Noguchi medium
was enclosed in a collodion sac, surrounded by distilled
water or physiological salt solution, anaerobic conditions
were shortly established throughout the system and
the nutritive and growth-promoting substances of the
medium diffused through the membrane in sufficient
quantities to support a luxuriant growth in the surround-
ing liquid. The protein precipitate that collected
around the tissue fragment was retained within the sac.

When it was possible to cultivate Bacterium pneumo-
sintes by this method in quantities sufficient for use,
rabbits were repeatedly injected with small doses of
live cultures, or of heat-killed organisms. After a suit-
able interval, their blood serum was found to possess
specific antibodies against Bacterium pneumosintes.

A significant feature of the immunity experiments
and also of these serum tests was the fact that all the
strains tested had similar properties and reacted iden-
tically with the specific antibodies produced by any
one of them. This is what would be expected if they
were all derived from a common source.

The experiments described above based on the
epidemic of 1918-1919 and the recurrence of 1920, had
extended over three years and the facts had been care-

no SCIENCE REMAKING THE WORLD

fully controlled, and checked by repetition. They
could not be further extended, however, without fresh
material from influenza cases and for some time it was
not possible to determine whether the blood of influenza
patients contained specific protective substances against
Bacterium pneumosintes, or whether protection might
be afforded by subcutaneous injections of the killed
organism — a method of prevention that has proved so
efficacious against typhoid fever. An opportunity for
further study was finally provided by a recurrence of
epidemic influenza in New York City in January and
'February, 1922.

With material obtained from a number of early cases
of influenza in this outbreak, all the essential steps in
the former investigation were repeated so that this
series of experiments served to check and confirm the
results of the earlier work. Especially significant was
the fact that the new and old strains reacted identically
in specific serum tests and that rabbits immunized
against the old strains were subsequently resistant to
the new ones, thus proving the identity of the micro-
organisms.

With the 1922 strains of Bacterium pneumosintes the
experiments on the blood of recovered patients and on
the protection afforded by vaccination with killed cul-
tures could now be carried out. In the blood tests
specimens of serum were studied from nineteen persons
who had recovered from influenza from ten days to five
months previously, and from twenty-two other persons
who gave no history of influenza since 1920. The sera of
the twenty-two controls were uniformly negative in the

EPIDEMIC INFLUENZA in

tests. On the other hand, the serum specimens from
seventeen of the nineteen persons who had influenza
during the recurrence of 1922 reacted positively and
thus afforded presumptive eivdence that they had
recently been infected with Bacterium pneumosintes.
One of the persons chosen as a control subsequently had
influenza. It was interesting to find that his blood
serum, previously negative, reacted positively with
Bacterium pneumosintes when tested on the tenth and
eighty-ninth days after recovery. In other instances
demonstrable antibodies persisted in the blood for at
least five months following an attack of influenza.

The second series of experiments that were made possi-
ble by the acquisition of new and pathogenic strains of
Bacterium pneumosintes deak with the immunizing
effects in rabbits of subcutaneous injections of appro-
priate doses of the heat-killed organisms. When a
number of rabbits had been prepared by three injections
of the killed bacteria the protective effects of the vac-
cination were demonstrated in two ways. By examina-
tion of the blood serum it was found that eleven among
fifteen vaccinated animals had developed specific
antibodies against Bacterium pneumosintes. Their re-
sistance was then tested to doses of the living organisms
which were pathogenic for normal, unvaccinated ani-
mals. In all but two instances the protection was com-
plete. Not only did the vaccinated rabbits fail to show
the characteristic signs of infection with Bacterium
pneumosintes but, with the two exceptions noted above,
they were normally resistant to secondary infection
with ordinary bacteria. Incidentally, it was observed

ii2 SCIENCE REMAKING THE WORLD

that the doses of vaccine were well borne and did not
even temporarily reduce the rabbits' resistance to other
infections. These experiments therefore pointed the
way to a similar series of observations in man.

On the basis of these results the vaccine has been of-
fered to several groups of men in the United States
Army. A very wide and extended experience will be
necessary, however, to determine its value, and at
present nothing definite can be said as to its efficacy in
the prevention of influenza.

CONCLUSIONS. — As the result of this investigation
at the Rockefeller Institute a hitherto undiscovered
organism, Bacterium pneumosintes, has been isolated
from the nose and throat secretions of influenza pa-
tients in the early hours of the epidemic disease. It is
filterable, anaerobic, resistant, and pathogenic for rab-
bits, in which it induces a typical infection seemingly
identical with epidemic influenza in man. The signifi-
cant features of this experimental infection are the
changes in the blood cells and the production of a
characteristic injury to the lungs associated with a de-
fect in their resistance to secondary invasion with
common pathogenic bacteria.

All the strains of Bacterium pneumosintes have similar
properties, indicating a common source. Animals
subjected to a primary infection, or injected with living
or killed organisms, are immune to subsequent injec-
tion. The killed bacteria induce specific antibody for-
mation even when injected subcutaneously in doses well
tolerated by man. The blood serum of recovered in-
fluenza patients contains antibodies for Bacterium

EPIDEMIC INFLUENZA 113

pneumosintes, whereas that of normal persons does not.
These experimental observations, reported elsewhere
in greater detail, especially in view of the source of the
cultures, their effects in rabbits, their identity, and the
presence of specific antibodies in the blood serum of re-
cently recovered influenza patients, point to Bacterium
pneumosintes as the bacterial incitant of epidemic in-
fluenza. Moreover, many of the essential facts brought
out in this study have been confirmed by Loewe and
Zeman, and by Baehr and Loewe in New York, by Gor-
don in England, and by Lister in South Africa. The
significance of similar observations from such widely
separated localities is obvious. But medical science is
apparently at the threshold of knowledge of a group or
class of minute microorganisms which the anaerobic
Smith-Noguchi technique and more recently developed
methods of cultivation have thrown open to exploit-
ation. This new field of bacteriology invites further in-
vestigation. It has seemed wise merely to report the
experimental facts so far obtained and to defer the final
decision on the precise relation which Bacterium pneu-
mosintes bears to epidemic influenza until further ex-
perience is obtained.

GUIDE TO FURTHER READING

"Twenty-five Years of Bacteriology. A Fragment of Medical
Research," by Simon Flexner. Science, 1920, vol. lii, page 615.

" Parasitism as a Factor in Disease," by Theobald Smith. Science,
1921, vol. liv, page 99.

"Epidemiology and Recent Epidemics," by Simon Flexner.
Science, 1919, vol. 1, page 317; Jour. Jmer. Mtd. Assn., 1919, voL
kxiii, page 949.

ii4 SCIENCE REMAKING THE WORLD

"Influenza, an Epidemiologic Study," by Warren T. Vaughan.
Baltimore. 1921. (Published by American Journal of Hygiene.}

Influenza. Encyclopedia Britannica, I2th Edition, 1922, new
vol. 31, page 488.

"Influenza Studies," by R. Pearl. U. S. Public Health Reports,
1919, vol. 34, page 1743.

"The Epidemiology of Influenza," by W. H. Frost. U. S. Public
Health Reports, 1919, vol. 34, page 1823. ,

OUR PRESENT KNOWLEDGE OF
TUBERCULOSIS

BY LINSLY R. WILLIAMS, M.D.

Managing Director, The National Tuberculosis Association, New York City

DURING the lyth and i8th centuries the words
"consumption" and "phthisis" were com-
monly used to designate various wasting dis-
eases now known to be of many varied types. In the
medical literature of this period there appears frequently
the word "tubercle," but what the authors meant by this
word was apparently nothing more than small nodules
the size of a small pea or smaller which were found from
time to time in bodies that were examined. Tubercle
was first described definitely by Baillie in England in
1793, who, relying on naked-eye observations, differ-
entiated tubercle from other tumors and commented
upon its constant appearance in autopsies of persons
dying of consumption. In 1810 Bayle in Paris at-
tempted to classify the different types of these tuber-
cles. A few years later (1819) Laennec, the inventor of
the stethoscope, showed that in autopsies made of
persons dying of consumption there were found in the
lungs small tubercles, agglomerations of many tuber-
cles. Also he found some tubercles which had under-
gone a partial degeneration; and found cavities in the
walls of which small tubercles appeared. By means of

"S

rt\

23
I-

116

TUBERCULOSIS 117

such studies of degeneration of lung tissue Laennec'thus
showed that consumption and tubercle were nothing
more than parts of the same situation.

COMMUNICABILITY OF TUBERCULOSIS. — No one ap-
parently believed in the possibility of tuberculosis being
a communicable disease until the epoch-making studies
of Villemin, who in 1862 demonstrated by carefully con-
trolled animal experimentation that tuberculosis could
be communicated from one animal to another, thus for
the first time refuting the existing theory that tubercu-
losis was a hereditary disease.

THE TUBERCLE BACILLUS. — The causative agent of
tuberculosis was not known until in 1882 Koch of Berlin
described the tubercle bacillus. Not until 1884 did he
fully describe the nature of this parasite and show that
the tubercle bacillus was found in tuberculosis of the
lungs; in " white swellings" which some authorities be-
lieved to be tuberculosis; in Pott's Disease; in diseases
of the hip; and in lupus (tuberculosis of the skin). He
showed also that this organism, which was always pres-
ent in these various conditions, could be grown arti-
ficially in various media in pure culture; that the pure
culture would show no parasitic life other than the
tubercle bacillus; that when these tubercle bacilli were
introduced into animals they reproduced a disease
identical in its lesions to the disease known as tubercu-
losis; and finally that these same tubercle bacilli could
be recovered from the organs of the animal which had
been given the disease.

How Do THE BACILLI ENTER THE BODY? — As soon
as Koch's epoch-making discoveries were made known

ii8 SCIENCE REMAKING THE WORLD

to the scientific world, numerous observers began to ex-
periment in order to learn how the tubercle bacillus
entered the body. There were those who believed that
it entered the body through the respiratory passages;
others who thought that it entered the body through the

TUBERCULOSIS DEATH RATE OF U 5 REGISTRATION AREA

PULMONARY AND OTHtR FORMS

• 300 TO 1921 irvc

ku.rw.KJ 10. >»4

digestive tract; others by way of the skin; and a few
who still believed that the disease was hereditary and
that the tubercle bacilli were transmitted directly from
mother to infant. The researches of Cornet and others
showed that in experimenting upon animals tuberculosis
could readily be induced by permitting them to inhale
moist air which was impregnated with tubercle bacilli.
For a considerable time nearly all the methods for the

TUBERCULOSIS 119

prevention of tuberculosis were based on the assump-
tion that tuberculosis was caused by inhaling tubercle
bacilli. Later researches, however, showed that experi-
mental tuberculosis could also be produced in animals
by means of the ingestion of food impregnated with
tuberculous material or tubercle bacilli. When these
animals were autopsied they showed not only tubercu-
losis of the intestinal tract, but also tuberculosis of the
lungs. Also tubercles could commonly be found in the
lymphatic ducts passing from the intestinal tract to the
lymph glands of the lung. Von Behring in 1903 made
a great contribution to our knowledge when similar ex-
periments performed by him with very young animals
showed that when the tubercle bacilli were ingested
they might induce tuberculosis of the mesentary nodes
or of the bronchial lymph nodes without causing any
lesion in the intestinal tract. He stated as a hypothesis
that tuberculous infection in man would commonly
take place during childhood through the digestive tract
and that the tubercle baccili would lie dormant in the
bronchial lymph nodes for an indefinite period of time.
Skin infection was also proved to be possible though
rare.

INFLUENCE OF THE BACILLI ON THE BODY. — The
effect of the tubercle bacilli on the body, once having
entered it, depends upon a number of factors. These
factors are the initial number of tubercle bacilli, the
virulence of the bacilli, and the capacity of the body to
manufacture products which tend to wall off the bacilli
or to kill them. If the number of bacilli be relatively
small and the resistance of the individual good, the

120 SCIENCE REMAKING THE WORLD

bacilli will do little harm. This is true even if they are
lodged in a number of places, for a reaction is induced
which causes the growth of epithelial and interstitial
cells which soon form a globular mass and completely
surround the tubercle bacilli. The bacilli may remain
alive and virulent but are walled off from the rest of the
body. These small pin-head size masses of walled-off
bacilli are not always readily detected. They are
known as miliary tubercles.

If, however, the conditions are favourable for the
growth of the tubercle bacilli and they find satisfactory
conditions for their nourishment within the body, the
tissues adjacent to the bacilli are injured and although
new cells are formed, these new cells in turn are killed
.and the area of dead tissue enlarges, so that we soon
have an ulcerating sore in some part of the body. On
the other hand, a series of small tubercles may be near
together and may combine into one larger tubercle as
big as a pea or larger. The tubercle bacilli encased
within the wall or cells may not kill the cells which sur-
round them, but may gradually cause the degeneration
of these cells so that this larger globular tubercle be-
comes a soft granular mass. When these conditions
develop, a variety of symptoms occur and the individual
is then said to have tuberculosis.

In the vast majority of instances, when infection
takes place the number of bacilli is limited and the
process of walling them off from the rest of the body
does not cause any disturbance. If, however, a con-
siderable number of tubercles are being formed at the
same time, the growth of the tubercle bacilli and the

TUBERCULOSIS 121

effort of the body to wall off these bacilli produce a
reaction as a result of the dissemination throughout the
body of the products of the tubercle bacilli. This re-
action is expressed in terms of symptoms which make
the individual realize that something is wrong. In a
comparatively small number of instances this tubercu-
lous process becomes chronic, the tubercle bacilli con-
tinue to grow, the infected areas become larger and
larger, and more and more of the organ in which they
are seated becomes destroyed. More and more symp-
toms are produced and the efficiency of the body is
reduced by the influence of the poisons distributed
throughout the body in the circulating blood and by the
destruction of part of some organ of the body. In rare
instances a tubercle may grow in the wall at a small vein
or in a small artery and eventually rupture into the
vein, and the contents of the tubercle with many tuber-
cle bacilli are thus discharged into the blood stream.
When this takes place there is a rapid dissemination of
bacilli throughout the body, causing a marked increase
in the number of tubercles growing in the body. In
such a case the condition known as miliary tubercu-
losis is produced.

HEREDITY. — As has been stated, until the time of
Villemin the generally accepted theory was that tuber-
culosis was hereditary. It is now known that fetal
infection may occur but that when such infection oc-
curs, the mother is in the advanced stages of tuberculosis
and tubercle bacilli are circulating in the blood which
passes through the placenta into the fetus. This is a
occurrence and in only a few instances have reports

122 SCIENCE REMAKING THE WORLD

been made of the presence of tuberculosis in a newly
born child. The tubercle bacilli are rarely found in the
circulating blood, and individuals or animals which are
promptly removed from tuberculous parents do not

DEATH RATE FROM TUBERCULOSIS, ALL FORM5

I9IO AND I92O

COMPARISON FOR CERTAIN AGE CROUPS

necessarily become diseased. It is also known that
tuberculosis is extremely rare in foundling asylums
and that in thousands of children autopsied during the
first year of their life tuberculosis is hardly ever found

TUBERCULOSIS 123

unless the child had been constantly exposed to an in-
dividual affected with advanced tuberculosis. It has
been noted also amongst the thousands of infaHts
placed out to board by the municipality of Paris that
tuberculosis is rarely responsible for death during the
first years of their life.

EVIDENCE OF THE PRESENCE OF TUBERCLE BACILLI
IN HEALTHY INDIVIDUALS. — Naegeli in 1900 reported
that he had autopsied over 500 adults dying of all types
of disease and found upon careful examination that
tubercle was found in 97 per cent, of these autopsies.
Many observations were made in the latter part of the
I9th century on the autopsies of children which con-
troverted the findings of Naegeli in adults. Loomis in
New York in 1890 reported the autopsies of a large
number of adults who had died as a result of traumatism
and found in practically every instance that tubercles
were present although the individual did not have the
disease known as tuberculosis. Loomis removed the
tubercles from the dead bodies of these healthy adults
and injected them into rabbits and this injection almost
invariably caused tuberculosis. So that prior to the
discovery of tuberculin by Koch, it had been surmised
if not generally accepted that the tubercle bacilli were
pretty generally present amongst all adults and that it
was extremely rare to find any evidence of the presence
of tubercle bacilli in infants.

TUBERCULIN. — Tuberculin, a product of the tubercle
bacilli, was discovered by Koch in 1894 and thought by
him to have great curative value. Tuberculin when
administered subcutaneously produces local, systemic,

124 SCIENCE REMAKING THE WORLD

v

and" focal reactions. A local inflammation is produced
at the site of injection, a general reaction characterized
by headache, backache, and fever, and a renewed or
increased activity at the site of injection. This latter
can readily be seen in lupus. Tuberculin was advocated
by Koch as a curative agent, but it has been proven
almost valueless and when not properly administered
does more harm than good. Koch announced that the
general reaction did not take place except in tubercu-
losis, but many observers soon found that healthy in-
idividuals reacted when larger doses were given. It
was found that sometimes 50 per cent, of adults reacted,
/and even 90 per cent, at times, depending on the size
of the dose. Its diagnostic value was therefore minim-
ized. Calmette and Wolff-Eisner found that tuber-
'culin dropped in the eye would produce a reaction.
Moro rubbed it into the skin and finally Pirquet in 1907
found that if a very slight abrasion were made in the
skin and a drop of tuberculin placed on the abrasion,
a local reaction would take place in tuberculous per-
sons, but without systemic or focal reaction. At first
this test was thought to be of great diagnostic value, but
as in the subcutaneous test it seemed that nearly every
one healthy or tuberculous reacted, with the exception
of very young children. Here was a phenomenon which
was difficult at first to accept; but Naegeli had shown
that 97 per cent, of adults autopsied showed an old
tuberculous process and many others had shown that
tuberculous lesions were rare in infants, but that as the
child grew older the lesions were more frequently found.
It is evident then that there was a marked difference

TUBERCULOSIS 125

between tuberculous infection and tuberculous disease.
Almost every child in civilized communities is exposed
to tubercle bacilli and infection takes place either
through the respiratory or digestive tract, so that by
fifteen years of age, nearly every child has become in-
fected. It is true that nearly all adults harbour tu-
bercle bacilli in their bodies, but only when for some
special reason these bacilli begin to grow or when
additional large numbers of bacilli enter the body does
the individual become affected with the disease tubercu-
losis.

TUBERCULOSIS IN MAN AND ANIMALS. — The natural
habitat of the tubercle bacilli is the bodies of men and
domestic animals. In the aboriginal Negro, tubercu-
losis is rarely found unless he is brought in contact with
civilization. Occasionally tuberculosis is found in wild
animals but usually when they have become domesti-
:ated. Three special types of tubercle bacilli are
known: the human, bovine, and avian. The human
strain is most virulent to man, the bovine less virulent
and the avian bacilli are a negligible factor in human
tuberculosis. We have already seen that tubercle in-
fection is almost ubiquitous among civilized people of
the human race. This is also true of the bovine races,
but in other animals it is far less common. The ba-
rilli, however, will live for months outside of the body
but are killed by sunlight. The disease tuberculosis,
although occurring in but a small proportion of those in-
fected, is one of the most serious of diseases.

During the past century one seventh of all deaths
the result of tuberculosis. During the year 1921

126 SCIENCE REMAKING THE WORLD

100,000 persons died of tuberculosis in the United States
and from 86 per cent, to 90 per cent, of them died of
pulmonary tuberculosis. Further, we know that for
each person dead of tuberculosis, there are at least
three seriously ill of tuberculosis and at least seven
more who have symptoms from time to time. This

DEATH RATE FROM TUBERCULOSIS IN NEW YORK CITY

PER EACH 100.000 INHABITANTS, SINCE 1898

100.

236 239 Z37 229 2OT\2R 2B 212 2* 209 I9« KJ7 181 180 173 171 I7J 169 159 164 160 132 109
47 47 43.33 36 34 M 2fl 30 29 29 Z7 29 30 2$ *8 27 27 23 Z4 24 20 n
283 296 280 264 Z43 246 250 240 246 236 227 U4 2JO 210 201 «9 200 ISA 182 IM 184 152 126

means that at least a million persons in the United
States will be either seriously ill or have symptoms of
tuberculosis this year. A similar situation exists
among all civilized races.

These enormous numbers of deaths and illnesses
occur most frequently during early adult life and chiefly
among tvhe wage-earner group. When standards of

TUBERCULOSIS 127

living are low or overcrowding or under-nourishment
exists, the death rates are higher, and conversely among
the wealthier class the amount of disease and death is
low.

IMMUNITY FROM TUBERCULOSIS. — Practically no one
is immune to infection, but many are immune to the
disease. The exact reason for this immunity is not
known. Immunity is racial, family, or individual.
The Jews and the Italians are relatively immune while
the Irish and the Negroes have very little immunity.
Family immunity exists, for in many families no evidence
of tuberculosis may exist for generations. Then some-
times one individual in a family may remain well when
all other members become diseased even though ap-
parently exposed to the same dangers. Individual
immunity varies also, for the immunity is lowered by
acute illness, pregnancy, childbirth, long hours of
laborious work, and constant undernourishment.

DANGERS OF INFECTION AND DISEASE. — The dangers
are twofold. First, the risk of receiving at one time
large quantities of tubercle bacilli from a case of ad-
vanced pulmonary tuberculosis or from the milk of a
cow with tuberculosis of the udder. Second, having
one's resistance lowered as a result of ill health or a poor
standard of living. In many instances both factors
play a part, as when a healthy woman cares for her
tuberculous husband, the family income is lowered, the
woman's work becomes more arduous and she is con-
stantly exposed to infection. There is no considerable
danger, however, from the brief exposure of healthy
individuals to those affected with tuberculosis which

128 SCIENCE REMAKING THE WORLD

may occur daily in our crowded cities. Nurses,
physicians, or employees in hospitals and sanatoria for
tuberculosis are not thought to be in any considerable
danger. In the latter case the patients are trained in
the employment of sanitary precautions and tubercu-
losis is more rare in this class of hospital employees than
in the same class outside of institutions. Consequently
the presence of such an institution in a community is
of no danger to its population. Milk from cows not
proven to be free from tuberculosis is undoubtedly a
source of danger, especially to young children whose
intestinal wall will not always prevent the tubercle
bacillus from entering the lymphatic system. Proper
methods of pasteurization remove this danger.

SYMPTOMS OF PULMONARY TUBERCULOSIS. — The
symptoms of pulmonary tuberculosis at the onset are
cough with or without expectoration, loss of weight and
strength, slight rise of temperature, and the spitting
of blood. Any one or any group of these symptoms
should arouse suspicion, and the patient merits a phys-
ical examination and an examination of the sputum,
if there is any, for tubercle bacilli. If they are present
it is a positive diagnosis. The examinations should be
repeated if symptoms persist and an X-ray examination
should be made also. The disease may be active, how-
ever, and detected by medical examination even when
no symptoms exist. Fortunately this condition is re-
latively rare. Persistent cough and unexplained fever
are danger signals and a pulmonary hemorrhage or
hemoptysis is almost positively diagnostic. If the
disease progresses, cough and expectoration, fever,

TUBERCULOSIS

129

emaciation and night sweats are the prominent symp-
toms. Hemorrhages may occur and complications may
arise in various parts of the body.

NON-PULMONARY TUBERCULOSIS. — If tuberculous

disease develops elsewhere than in the lungs, it develops

NEW YORK CITY

DEATHS FROM TUBERCULOSIS

SINCE 1898 _

«» •«" MB trn TMS <*4

a train of symptoms depending primarily on its location.
If the meninges be affected, symptoms of meningitis; if
the pleura or peritoneum, symptoms of pleurisy or
peritonitis; if the intestines, symptoms of inflammation
of the bowels; if glands, symptoms of inflammation re-
sulting in a cold abscess; if bone or joint, symptoms of
osteitis or arthritis.

TREATMENT OF TUBERCULOSIS. — Any chronic disease
to be successfully treated requires two important fac-

130 SCIENCE REMAKING THE WORLD

tors — a skilled physician and a patient with character
and an earnest desire to get well, come what may.
There is no specific cure for tuberculosis though many
cures have been heralded. Reliance must be placed
upon rest, nourishment, and fresh air under the guid-
ance of the physician. Sanatorium treatment is
extremely valuable in training the patient to follow
closely rules of conduct as to food, air, and rest, and the
more skilled physicians are usually found in sanatoria
or in resorts near them. Climate is a relatively unim-
portant factor, for recoveries take place in our crowded
cities and in all climates. The disease was once sup-
posed to be incurable. Not only are most cases cur-
able, but thousands of persons who have been cured
gladly give this testimony.

THE PREVENTION OF TUBERCULOSIS. — Preventive
measures are primarily those which will prevent the
bacilli from entering a healthy body by killing the bacilli
as soon as they leave an infected body. If all bacilli
coming from tuberculous individuals in the sputum or
other discharges could be destroyed and all milk coming
from tuberculous cows could be pasteurized, tubercu-
losis would soon disappear. Unfortunately, large
masses of people do not know this and many persons
have tuberculosis who do not know it, or even after they
know it they endanger the lives of their families by care-
less habits. It is necessary, therefore, to educate the
public in so far as is possible; to provide sanatoria for
the care and cure of tuberculosis; to provide hospitals or
special pavilions for the isolating of the more dangerous
advanced cases; dispensaries to care for ambulatory or

TUBERCULOSIS 131

moderately advanced cases, to supervise the chronic
milder cases and to ascertain what facilities are avail-
able for institutional care; and finally public health or
tuberculosis nurses to educate the other members of
the patient's family and others to take the precautions
necessary to prevent the disease.

Other general measures which improve the public
health or the individual health are useful. Public
health measures which provide pure water, sewage
disposal, clean streets, sanitary housing, and measures
which prevent other communicable diseases; general
measures which improve the individual health by means
of education of the care of the body; the Modern Health
Crusade which not only teaches children the principles
of health, but also trains them to acquire healthy habits;
the playground, the summer camp, the fresh-air home,
outdoor sports, proper habits of exercise and diet, rest
and play and all measures which improve body health
help in the prevention of tuberculosis.

RESULTS OF PREVENTION. — The death rate in the
United States from tuberculosis has fallen from 201 to
99 per 100,000 during the past twenty years, which
caused a saving of 100,000 lives in 1921. The value of
these lives is almost beyond compute, as is also the cost
of caring for such an army of sick persons. Suffering,
death, and sorrows have diminished, but there still
remains much to be done.

WORK STILL TO BE DONE. — More scientific research
to determine many unknown factors on infection and
immunity and the final perfection of a cure for tubercu-
losis which would be as effective as quinine is for malaria,

132 SCIENCE REMAKING THE WORLD

or a preventive as effective as vaccination for smallpox.
Failing these, there is great need for increased education
of the public, more health education for school children,
better training for physicians and nurses from the
scientific and social aspect. Most persons need not
have tuberculosis unless they choose to do so by de-
clining to do the things necessary for its prevention.

GUIDE TO FURTHER READING

"Pulmonary Tuberculosis," by Otis. (Leonard.) 1920.

"Early Pulmonary Tuberculosis," by Hawes. (Wood.) 1913.

" Rules for Recovery from Pulmonary Tuberculosis," by Brown.
(Lea and Febinger, 4th edition, revised and enlarged.) 1923.

"Rest and Other Things," by Krause. (Williams & Wilkins.)
1923.

"Environment and Resistance in Tuberculosis," by Krause.
(Williams & Wilkins.) 1923.

"The Causes of Tuberculosis," by Cobbett. (Cambridge Univer-
sity Press.) 1917.

Bulstrode lecture, Lancet, 1903, vol. 2, page 1199.

"Congenital Tuberculosis," by Warthin and Couie. Journal of
Infectious Diseases, vol. 1, page 140.

"Relation of Human and Bovine Tuberculosis." Report of
?"itish Royal Commission, 1905.

"What You Should Know About Tuberculosis." Pamphlet 106,
.National Tuberculosis Association.

" Sitting and Sleeping in the Open Air." Pamphlet 101, National
Tuberculosis Association.

LOUIS PASTEUR, AND LENGTHENED HUMAN

LIFE

BY OTIS W. CALDWELL, PH.D.

Teachers College, Columbia University

WHEN Louis Pasteur was sixteen years old his
father, anxious about his education, decided
to send him from the home town of Arbois
to Paris. The boy was to have the advantage of instruc-
tion in the ficole Normale, a school in which the father
thought there would be an exceptionally good oppor-
tunity for his boy since the Ecole Normale had been es-
tablished to train men for college positions. This was in
1838, when schools were not generally as good in France
as they are to-day. The elder Pasteur did not have
the privilege of much schooling but had gained a fair
education for his time by personal industry and efforts.
Like many a father of recent times, or to-day for that
matter, Louis' hardworking father decided that poverty
should not deprive his son of a good education, and thus
planned family sacrifices in the name of the boy's
education. That parental sacrifice does not guarantee
an education was as true of Louis Pasteur as it has
proved to be of many another boy or girl. No sooner
did the boy find himself at the school in Paris than an
old and honourable malady befell the boy — homesick-
ness. It is honourable and eminently respectable to

U3

134 SCIENCE REMAKING THE WORLD

be homesick, even almost disgraceful not to be so on
occasion; but succumbing to this worthy emotional
illness is not so respectable.

Louis Pasteur's father was a tanner of hides, as had
been his grandfather and great-grandfather. His
home was near the malodorous tannery yard, and his
childhood home street in Dole before his family moved
to Arbois, was known as the "street of the tanners."
From his birth in 1822 until he was almost sixteen years
of age, his life had been more or less associated with the
tannery. And now, as a lonesome boy in a distant
school, in a great city one hundred leagues from home,
he longed so earnestly "for a whiff of the old tannery"
that genuine illness would have been welcome if it
could have secured his return to his home. Hours were
days to the boy, and he soon decided he could stand it no
longer. His work was poor, he was miserable, and so
wrote to his father. The father, with much depression,
went to Paris and took the boy back to his Arbois home.

The halo over the home and playground is some-
times more easily seen one hundred leagues away than
close at hand. It was so with young Pasteur, for the
halo evanesced and certain stern realities appeared.
He soon announced his readiness to return to Paris, but
the wise father replied that the schools of Arbois would
suffice for the present. The boy became an outstanding
pupil in drawing, so recognized by all. At night he
went over all of his day's lessons with his father, not
the lessons of the next day, as is so commonly done now-
adays to make sure that pupils know their lessons; but
the lessons of the preceding morning and afternoon, as

LOUIS PASTEUR 135

the father desired to learn those things with which the
son was dealing, and Louis became truly his father's
teacher. Two years in the schools of Arbois, then two
years in the college at Besancon not far from Arbois,
brought to Louis recognition as a successful student and
as a tutor of his fellows. Then, at twenty years of age,
in 1842, he returned to Paris as a student in the Ecole
Normale, soon to be widely recognized as a young man
of industry, intellectual integrity, and earnest devotion
to his studies.

In addition to other studies, Pasteur attended lec-
tures at the Sorbonne and devoted much time to the
study of the structure of crystals. He became widely
known and highly respected as a student of chemistry,
and on January 15, 1849, began an eight-year period of
useful service as professor of chemistry at the University
of Strassburg. A characteristic Pasteurism occurred
in the early part of his stay at Strassburg. The rector
of the University was most cordial to the newly arrived
professor of chemistry and took him to his home, where
Pasteur was introduced to the rector's wife and daughter.
In two weeks Louis addressed a lengthy letter to the
rector, serving notice that the elder Pasteur, according
to the customs of the times, would soon appear and
propose marriage between Louis and the daughter. In
this letter Louis informed the rector that, "as to the
future, unless my tastes should completely change, I
shall give myself up entirely to chemical research."
The father came, the proposal was made and duly ac-
cepted, the marriage occurred in three months.

At the close of 1854 Pasteur left Strassburg for a pro-

i36 SCIENCE REMAKING THE WORLD

fessorship at the University of Lille, where he served
for two years. Then he went back to Paris, which
was the central location of his work for the rest of
his life.

When Pasteur went to Lille he fully expected to con-
tinue his studies in chemical and physical problems
relative to crystals. The brewers and wine makers
about Lille were having great difficulty since they could
not be certain to secure the kinds of fermentation speci-
fically needed in different cases, in order to produce the
different specific results they desired. The wine and
beer "went wrong," fermentation could not be con-
trolled, and the industry was suffering great financial
losses, said to exceed #20,000,000 yearly in certain
years. Pasteur was known as a chemist, and as a mani-
pulator of the crude microscopes of that day. The
manufacturers appealed to him to solve their problems,
and he reluctantly agreed to the temporary diversion
from his chosen studies, for he saw in this study great
possibilities of new knowledge. Through the studies of
famous German students, much had recently been
learned about the yeasts which produce fermentation
and about certain bacteria, but application of these
studies had not been made in the brewing industries.
There was still extended belief that the living organisms
of fermentation came into existence spontaneously
(spontaneous generation of life, as it was called), and
that such organisms spring into existence in the wine
and beer because of "a vital force of nature," and thus
injure it. Pasteur, and others even more than Pasteur,
proved that if nutritive liquids are sterilized and con-

LOUIS PASTEUR 137

stantly kept from contact with air and other unsterile
substances, no organisms will develop within this nutri-
tive liquid no matter how lung the experiment is con-
tinued. There was recently exhibited in the United
States (1922), a flask of beef broth which it is claimed,
correctly no doubt, that Pasteur prepared over fifty
years ago. The beef broth is still fresh-looking and
clear, never having had the stopper removed from the
glass flask in which the broth has been constantly kept.
Small living things, like the larger ones which we readily
see, come only from other living things of their own
kind. The process of treating wines as recommended
by Pasteur, known as pasteurization, has since been
applied to milk in all civilized countries.

With previously gained facts in mind, Pasteur pro-
ceeded to separate single living yeast plants under his
microscope, and then to grow pure cultures from these
organisms thus separated. He not only found that
they grew as pure culture, but that each kind of small
organism produced its own peculiar kind of fermenta-
tive products in the nutritive liquids. He thus taught
the brewers and wine manufacturers how to separate,
grow, and use the particular kinds of living microscopic
organisms which produce the kinds of wine and beer
that they desired.

We are not keenly interested in the fact that such dis-
coveries taught people how to save the alcoholic in-
dustries of France and Germany. What interests us
most is that he isolated the microscopic organisms,
grew them in pure cultures, and proved that micro-
scopic living things, like the larger ones we readily see,

138 SCIENCE REMAKING THE WORLD

each produces its own peculiar results as product of its
life and growth.

We need to recall that when Pasteur was studying
fermentation the human race did not know the causes of
human diseases. Causes had been suspected, but not
proved. What we know to-day as the science of public
health did not exist. The bacterial origin of diseases
was merely suspected, and the idea generally ridiculed.
If a person had been bold enough to assert as true even
a small part of what we now know to be true, such a
person would have been thought insane or foolish. It
was then not uncommon to think that persons who be-
came ill had been guilty of some gross wrong-doing, and
that illness was sent upon them as punishment for their
sins. Or it was sometimes said that the "humours of
the body," of which the blood and the bile were two, in
some way got into wrong proportions or became de«-
ranged and thus caused illness. It is now generally
known that most, if not all, common diseases are caused
by living microscopic organisms, either bacteria or
small animal parasites. Though this knowledge is but
a few decades old, it is so common that it is difficult to
put ourselves back to the recent date when the human
race did not possess this knowledge. It is of such un-
told importance that Louis Pasteur lived and accom-
plished what he did, that, as we read this chapter, we
must imagine ourselves for a time moved back a little
more than forty years in the history of man's desire
and efforts to have better health. Then, as now, most
people wished to live instead of to die, and while living
wished to have the best possibk health. Then, as now,

LOUIS PASTEUR

there were some benighted people who would not do
the things necessary to produce good health, even if
knowledge of how to do them were available.

When Pasteur's yeast and spontaneous generation
studies were almost completed, he was urged to go to
southern France to try to discover why the silk worms
were sick. He tried to decline saying: "I have never
touched a silk worm in my life." Why did people urge
Pasteur to do this ? Why didn't they call a bacteriolo-
gist or a student of insect diseases? At that time there
were no bacteriologists because there was no bacteriol-
ogy. Of course there were bacteria, but since no one
then knew the laws of bacteria, there was no bac-
teriology. Likewise there was no science of insect
diseases, or science of diseases of men as we now under-
stand those terms.

For many years the silk industry of France had suf-
fered. Often the worms became sick and died, or if
they lived, they produced poor cocoons. Poor cocoons,
or no cocoons, mean reduction or loss of the desired
silk, which means poorer food for the people, poorer
education for their children, and all the poorer things
which accompany reduction or loss of a fundamental in-
dustry. So important was the silk industry in southern
France, and so great the anxiety about the health of the
silkworms, that one writer says the workers when meet-
ing would salute one another by saying: "Good morn-
ing! How are the silkworms this morning?" What
they desired was good healthy adult silk moths which
laid good moth eggs; that these eggs should hatch into
worms which might feed and grow healthily upon their

140 SCIENCE REMAKING THE WORLD

food, the mulberry leaves; that the full-grown worms
might spin good cocoons from which the workers could
unravel the desired silk; that enough good cocoons
should be left to produce adult moths to continue pro-
duction of new supplies of healthy eggs.
1 Pasteur began this study in 1865. He studied the
eggs and found within some of them certain small
bodies resembling the smallest animal cells. He called
these bodies corpuscles, simply meaning "small bodies."
He notecf that when eggs which contained the cor-
puscles hatched, the worms were sickly and usually
died. Using his crude microscope, he separated the
eggs which contained no corpuscles and caused them to
natch. The worms thus produced seemed to be healthy,
and after careful work, Pasteur announced that people
'could produce healthy worms and good cocoons by se-
lecting eggs which contained no corpuscles. When this
was tried and failed, Pasteur patiently returned to his
microscopic studies and found another small organism,
a bacterium, and immediately concluded that the silk-
worms had two diseases instead of one. One, pebrine,
was caused by the animal corpuscles; and the other,
flacherie, caused by bacteria. Through long and care-
ful experiments he discovered that eggs selected so as
to be free from corpuscles and bacteria would produce
healthy worms; that such worms when grown upon
fresh mulberry leaves would mature and produce good
silk cocoons; but that even healthy worms when grown
were likely to sicken and die. He thus concluded that the
corpuscles and bacteria produce the diseases, and that
.diseases from sick wTorms may be transmitted to healthy

LOUIS PASTEUR 141

worms by contact with the food in which sick worms
have fed. It is not so important that Pasteur taught
France how to save her silk industry as it is that he
proved that the small organisms produce the diseases;
that transmission of the organisms may transmit the
Disease; and that prevention of transmission prevents
disease. We are not likely to over-estimate the im-
portance of these discoveries to modern public and
individual health.

. Meantime the cattle and sheep industry of France
and of other countries was suffering from a disease
known as anthrax. So deadly was anthrax to human
beings that when once it was clear that a person had
the disease, it was regarded almost as a death warrant.
Fortunately and for reasons then unknown, the disease
did not often attack human beings. Its destruction of
cattle and sheep was enormous.

Other students had discovered the nature of the
bacterium which causes anthrax and had definitely
proved the causal relation of the organism. But since
no preventive or cure had been discovered, people
appealed publicly to Pasteur to attack the problem.
No less than 3600 public officers and prominent citizens
signed petitions to Pasteur to undertake to find a means
of preventing the ravages of this dreaded disease."* He
responded and began the study. It is interesting and
important to know that the so-called anthrax bacteria
cause the disease anthrax; but if they cannot be kept
from causing the disease what does the knowledge profit
us? If cattle and sheep and men must die, there
really isn't large comfort in mere knowledge of what

142 SCIENCE REMAKING THE WORLD

caused this wholesale death. That knowledge was es
sential for the beginning of Pasteur's study, but was
merely the beginning.

After many efforts, too many and too intensive to be
related in this connection, Pasteur recalled an impor-
tant discovery made by the Englishman, Jenner, in
J798. Jenner, working in England, noted that persons
who milked cows which were ill with cowpox contracted
a disease resembling human smallpox, and that there-
after such persons would not contract smallpox from
human beings ill with that disease. Jenner devised
means, now improved and known to everyone, for
giving human beings generally the infection or vacci-
nation which protects against smallpox. In recalling
this situation, Pasteur argued that smallpox was caused
by a living organism; that the organism when it lived
in cattle did not flourish, and that this organism when
introduced from cattle into human beings was not vig-
orous enough to produce a bad case of smallpox; that the
case produced was bad enough, however, to leave some
kind of protection or immunity against an attack from
organisms from persons who have a vigorous case of
smallpox. This line of thought is most interesting
when we recall that we do not yet possess satisfactory
evidence as to just what kind of an organism causes
smallpox.

Meantime Pasteur had been carrying on experiments
with chicken cholera. He left cultures of chicken chol-
era germs in his laboratory, and went away for a short
vacation. Upon his return he found that these old cul-
tures would no longer produce chicken cholera when

LOUIS PASTEUR 143

some of the cultures were injected into fowls. Most
important of all, he found that after the fowls had been
treated with these old cultures they would not take
chicken cholera even when injected with fresh and viru-
lent germs. Therefore partly by chance came the dis-
covery of the process of vaccinating poultry against
cholera by use of depleted cholera germs or possibly
by use of the dead products remaining in old cultures of
these germs.

Thus Pasteur began his efforts to reduce the vigour of
anthrax germs so that perchance they might not pro-
duce anthrax of usual destructiveness. Many highly
illuminating experiments were performed. Finally, by
growing anthrax bacteria in beef broth at high tempera-
tures, it was found that they flourished for a time, then
slowly died out. By using some of these cultures when
the bacteria were much depleted, it was found that sheep
could be given mild attacks of anthrax from which they
recovered. After their recovery they were given fully
active anthrax germs, from which the sheep promptly
developed bad cases of anthrax and died. Pasteur
then tried a first vaccination of depleted bacteria, and
when the sheep had recovered, gave a second mild at-
tack by use of bacteria much less depleted than those
first used, but far from normal vigour. The sheep and
cattle upon which this experiment was tried took suc-
cessive mild attacks of anthrax. Thereafter, fully
virulent anthrax bacteria failed to produce the disease,
and Pasteur announced his triumph in producing pro-
gressive vaccination with successful results.

So important was this discovery that Pasteur was

144 SCIENCE REMAKING THE WORLD

challenged to make a public demonstration of his claims.
The Agriculture Society at Melun, France, offered to
provide sheep and cattle for the demonstration. Dele-
gates were invited and came from many interested
organizations and countries. Pasteur penned ten
sheep to serve as controls to determine whether anthrax
was in the food, air, or water given to them and to the
other sheep and cattle. Twenty-five sheep and six
cows were to be vaccinated, and twenty-three sheep,
two goats, and four cows were not to be vaccinated but
were to receive fully virulent anthrax bacteria at the
same time as the vaccinated sheep and cattle. On
May 5, 1881, the first vaccination was given to the
twenty-five sheep and six cows. On May 17, 1881, the
second vaccination was given to the same animals. On
May 31, 1 88 1, fully virulent anthrax germs were given
to all vaccinated sheep and cows, to the four remaining
cows, and to the twenty-three sheep and the goats.
Pasteur told the delegates to return on June 2. This
direction was unnecessary as most of them did not leave,
so keenly did they appreciate the momentous impor-
tance of what was going on. Many were disbelievers and
expected Pasteur's downfall. The results were trium-
phant. On the morning of June 2, all of the non-
vaccinated sheep and cows and the goats were dead,
dying, or severely ill. Not a vaccinated sheep or cow or a
control sheep died as a result of the treatment they had
received. Since that day the human race has known
how to avoid anthrax, if only it will do what is known as
good to do. More than this, the idea of successive
vaccination was proved, and this has been the founda-

LOUIS PASTEUR 145

tion of many subsequent advances in prevention of
diseases of several types.

Did Pasteur then retire from active labour, one man's
gigantic work having been done? Did he remind his
co-workers that since 1868 half-paralysis had made his
work very difficult? No! Rather he reminded his
closest friends that his part-paralysis which he suffered
in 1868 enabled him to make more cautious and effective
use of those parts of his body not affected by his mal-
ady— a malady for which the answer is not yet at hand.
Instead he turned now to his last and most spectacular
achievement. For many years the sympathies of this
great founder of the science of bacteriology had been
sorely tried because of the ravages of the awful disease
rabies or hydrophobia. It is doubtless true that the
cry of "mad dog" has created human panic since the
times of primitive men. No sane person who has wit-
nessed death from hydrophobia will willingly do so a
second time, unless he is needed in ministrations of
assistance or mercy. For years Pasteur had studied
the dreaded disease and performed experiments with
rabbits and other animals in efforts to locate the causal
organism and to find a preventive or cure. It almost
belittles this gigantic task to go directly to results,
omitting description of many fruitless efforts, false
hopes roused in the man whose heart as well as mind
was now devoted to his supreme task. However, one
day, after many failures to locate any guiding arrow,
Pasteur used for inoculation in a rabbit a piece of old
and dry spinal-cord tissue previously taken from a rabbit
that had died of rabies. He had previously oftentimes

146 SCIENCE REMAKING THE WORLD

transmitted the disease by use of nerve tissue, but the
diseases thus produced were violent and death-
producing. This time, however, the desiccated nerve
tissue produced a mild attack from which the rabbit
recovered. Following this lead, a series of less and less
dry nerve tissues were used to produce a cumulative
series of mild attacks, after which the bite of a rabid
animal failed to produce hydrophobia.

At this juncture one of the most striking events of
all science occurred. Frau Meister, of Alsace, had a
boy, Joseph, who two days before had been bitten by a
rabid dog. Such an attack as that shown by the four-
teen bites upon the unfortunate boy had been previously
regarded as meaning almost certain death. The mother
had heard of Pasteur, and at once started to Paris with
her boy. The treatment had not been given to any
human being; it was not known whether results would
be similar to those obtained in lower animals; it was not
known what series or gradation of treatments would be
necessary for human beings; it had been proved that
the treatment could be applied to animals after a rabid
bite, and that protection could be secured. Frau
Meister was obdurately insistent. Pasteur's advisers
intimated that the boy's death would be upon Pasteur if
he refused to treat him and the mother absolved him
from responsibility if the treatment were given. Against
advice from his friends, Pasteur began the experiment
upon the boy, shortening the periods between treat-
ments in efforts to secure cumulative protective results.
The ignorant but beautiful confidence of the mother
and boy permitted them to sleep and rest between^

LOUIS PASTEUR 147

treatments; but the highly intelligent understanding
and tremendous responsibility and hope of Pasteur
made sleep and rest almost impossible for him until the
crisis had passed, and he felt sure that the boy's life
had been saved.

Soon Pasteur institutes appeared in available centres
throughout the civilized world, and to-day it is very
rarely that a human being need die from hydrophobia.
Superstitious and ignorant fear of hydrophobia has
given place to the intelligent guidance of modern
science.

On Pasteur's seventieth birthday (1892, three years
before his death) delegates from the scientific societies
and public bodies of the civilized world met in France,
in the great theatre room of the Sorbonne. The band
of the Republican Guard of France played the triumphal
march. The President of the Republic was the escort
as down the aisle came one of the greatest heroes and
benefactors in human history. Gounod directed a
choir which sang his Ave Maria. Coquelin recited
verses written by him especially for this occasion. The
Minister of Public Instruction among other things said:

Who can now say how much human life owes to you and how much
more it will owe you in the future? The day will come when an-
other Lucretius will sing, in a new poem on Nature, the immortal
Master whose genius engendered such benefits.

Joseph Lister, when called upon said:

Your researches upon fermentations have thrown a powerful light
which has illuminated the baleful darkness of surgery and has
changed the treatment of wounds from an uncertain and too often

i48 SCIENCE REMAKING THE WORLD

disastrous empirical affair into a sure beneficent scientific art.
Thanks to you, surgery has undergone a complete revolution which
has robbed it of its terrors, and has enlarged almost without limit
its efficacious power. Medicine owes not less than surgery to your
profound and philosophical studies. You have lifted the veil which
had covered infectious diseases during the centuries; you have dis*
covered and demonstrated their microbial nature. Thanks to your
initiative and, in many cases, to your own special work, there are
already a large number of these pernicious maladies of which we
now know the causes.

Then Pasteur rose and spoke quietly and feelingly of
his hope that science would save men from their bodily
ills; that men will be more useful when free from dis-
ease. Then turning to the delegates he said:

And you, delegates from other nations, bring me the deepest joy
that can be felt by a man whose invincible belief is that Science and
Peace will triumph over Ignorance and War, that nations will
unite, not to destroy, but to build, and that the future will belong
to those who will have done most for suffering humanity.

The foundations of the science which may remove
from man all his bodily ills if only he will turn his mind
to them long enough, with sufficient patience and un-
selfishness— that is the achievement of Louis Pasteur.
Human life is now much lengthened because of the work
of Pasteur, by the few others of hi s time, and by the many
others since who have been stimulated and whose work
has been made possible by him. Those who know and
do what modern health science teaches are the ones
whose lives are lengthened. It is they who are of most
worth to the world. A man at forty has just learned
how to work. To add ten or fifteen or twenty years to
his life saves to the world a man who is equipped and
ready. His added years may double his service to the

LOUIS PASTEUR 149

world. Surely in an age when great warriors are still
extolled, it is supremely important for our young people
to appreciate that true heroes help men to live and
serve rather than teach them to vanquish and destroy
their fellows.

GUIDE TO FURTHER READING

"The Life of Pasteur," by R. Vallery Radot. Translated from
the French by Mr. R. L. Devonshire. Doubleday, Page & Co.,
Garden City, N. Y. 484 pages, 1908.

"The Influence of Pasteur on Medicinal Science." Dodd,
Mead & Company, New York. 77 pages, 1904.

" Pasteur, The History of a Mind," by Duclaux. Translated by
Erwin F. Smith. W. B. Saunders Company, Philadelphia. 363
pages, 19*0.

INTERNATIONAL PUBLIC HEALTH
BY GEORGE E. VINCENT, PH.D.

President of the Rockefeller Foundation, New York City

IF THE hygienic control of the world were put in the
hands of some superman with scientific knowledge
and authoritative powers it is possible to imagine
the way in which he would organize his forces and carry
out his task. First of all he would not rest content
with the scientific resources in his possession, but would
provide for continuous investigation in order to re-
examine constantly the knowledge already acquired
and to add new information. He would fit up well-
equipped and competently manned centres for investi-
gation. These institutions he would place in strategic
positions throughout the world in such a way as to
bring the widest variety of diseases under constant
scrutiny. He would further see to it that the staffs of
these research centres were in constant communication
so that duplication of effort would be avoided and the
results secured in one place put quickly at the disposal
of workers in all the other institutions. In this way he
would organize medical research as a world activity,
constantly recruiting his groups of investigators and
producing steadily new knowledge about the nature,
cure, and especially the prevention of the maladies
which afflict mankind.

150

INTERNATIONAL PUBLIC HEALTH 151

In the second place, this hygienic force would effect
an administrative health organization throughout the
World. Each country would be subdivided into sani-
tary districts, while the nations themselves would be
brought into a unified administrative system under
central control. Thus stationed throughout the world
would be health officers with their technical experts and
subordinates all organized into a hierarchy under single
authoritative control. Under such a military regime
sanitation, control of epidemics, regulation of individual
conduct in the interests of health would be in force with
all the efficiency which characterized the success of pre-
ventive measures in Cuba and the Panama Canal Zone.

In the third place, through such an organization as
toas been described, there would be centralization of
vital statistics — accurate and trustworthy conclusions
based upon the reports of competent diagnosticians per-
forming their duties in an objective way uninfluenced
by economic and social considerations. These statistics
constantly gathered and interpreted by experts, would
guide the organization and conduct of health campaigns
in various parts of the world to meet situations as they
were revealed by the statistical data. The appearance
of an epidemic would be instantly reported to head-
quarters and orders would issue at once to apply meas-
ures which would insure the prompt control of the
threatened outbreak. Outposts and barriers against
epidemics would be established and held in readiness for
emergencies. Gradually the foci of diseases would be
circumscribed until finally these sources of danger
would be eliminated.

1 52 SCIENCE REMAKING THE WORLD

In the fourth place, the guardian of the world's health
would not rest content with the negative control of
disease. He would regard sanitation and epidemiology
as only the first steps toward a positive campaign to be
carried out through control of the diet, housing, exer-
cise, and recreation of the world's population. This
benevolent autocrat would see to it that children'were
well born and nourished and from their earliest days
trained to hygienic habits. In this way he would,
through the perfect obedience of millions to the dic-
tation of wisdom and benevolence, produce a vigorous
and healthy race.

Of course, as fundamental to this entire programme
the commanding officer would establish medical schools
and training centres in which the officers and privates
of his army of hygiene would be recruited and trained
for their important tasks. Under his guidance medical
schools would transfer their chief interest from the cure
to the prevention of diseases. The stress would be
laid upon early diagnosis and upon preventive treat-
ment, upon frequent medical examinations, upon sound
habits of living, upon the importance of mental serenity
and a stimulating social life. From such schools of
medicine and hygiene would go out men and women
apostles of the doctrine of prevention determined to
keep people well and regarding the occurrence of
disease among those under their charge as a serious
reflection upon the vigilance and resourcefulness of the
members of the profession.

The description of an arbitrary control of this kind
is in itself sufficient to show how impossible and in-

INTERNATIONAL PUBLIC HEALTH 153

tolerable such a regime would be. Local autonomy,
nationalistic feeling, the absence of supermen, and
human nature's resentment of control imposed from
without are a few of the many obstacles which would
make it utterly impossible to bring about the hygienic
solidarity of the world. But the outlining of an imagin-
ary unified system of control at least serves as a back-
ground against which to observe influences which have
been going on for a long time in the world, but which of
late have gained greatly in definiteness of organization.
In some sense, every one of the things which have been
suggested as a part of an imaginary world organization
is being to a degree accomplished.

Thus there are more than 445 medical schools scat-
tered throughout the world. They represent the in-
fluence of three systems of medicine: the British, the
Latin, and the German. These systems have been dis-
tributed in accordance with well-organized principles of
national influence. The British system has prestige
throughout the Empire, subject to modification espe-
cially in Canada. French medicine prevails in the Latin
countries of Europe and in Central and South America;
while the German plan is largely followed in Scandi-
navia, Austria, eastern Europe, in the Balkan regions,
and in Japan. In the United States a combination of
British and German methods has been gradually devel-
oped with certain features which are not found in either
of the two European systems. The three national types
are yielding to internal influences which may be counted
upon to produce, not uniformity, but a more cosmo-
politan ideal than at present exists anywhere in the

154 SCIENCE REMAKING THE WORLD

world. In short, forces of intercourse and cooperation
are approximating a world system more successfully
than anything but the control by a superman could
bring about.

Moreover, institutes for medical research are found in
many parts of the world. Of these the best known are
the Pasteur Institute of Paris, the Rockefeller Institute
of New York, the London and Liverpool Schools of
Tropical Medicine, the Hongkong School of Tropical
Medicine. Many other centres exist throughout the
world. These centres, through publications, migra-
tions, and international congresses are kept in close com-
munication so that knowledge of each other's work is
quickly disseminated. In a very true sense there is an
informal and effective world organization for prosecu-
tion of medical research. Many of the medical schools
are an integral part of this system, making impor-
tant contributions to what is a genuine international
product.

In the collection of vital statistics definite prog*
ress toward world organization has been made.
Through the Office International cTHygiene in Paris,
forty nations are regularly exchanging information
with respect to vital statistics. Uniform methods of
reporting deaths have been agreed upon and are to a
considerable degree being successfully carried out.
The areas from which trustworthy and acceptable re-
ports aretnade in various countries are being gradually
extended. It is true that only a beginning has been
made but these beginnings have sketched a programme
of international cooperation in the gathering and dis-

INTERNATIONAL PUBLIC HEALTH 155

tribution of vital statistics which will inevitably be
steadily elaborated during succeeding decades.

Growth of health organizations in different countries
is constantly recorded. The leading nations of the
world are giving increasing attention to health adminis-
tration; administrative areas are being organized and
trained sanitarians put in charge. Not only is this
national organization going forward, but the nations
are drawing closer together in their cooperation for
world health. The first European conference to con-
sider health problems was held in 1851. Twelve nations
were represented. Concerted measures against cholera,
plague, and yellow fever were adopted. Thereafter at
intervals of a few years other congresses were called to
insure better team-work in conformity with rapidly ad-
vancing knowledge of preventive medicine. In 1902
an International Sanitary Bureau was established in
Washington by the Pan-American Union. Finally, in
1908, a permanent International Office of Hygiene,
which has already been mentioned, was established in
Paris.

The most significant development in this world
movement is the recent creation under the League of
Nations of a Health Organization which has the direct
support of fifty-two nations and the sympathetic co-
operation of the United States. The programme of
the League's Health Organization includes the gather-
ing of vital statistics, prompt notification of epidemics,
a standardizing of vaccines and sera, international con-
ferences and exchanges of health officers, securing of
better health conditions for sailors on shipboard and in

156 SCIENCE REMAKING THE WORLD

ports, cooperation with League mandatories, with the
Commission on Opium, and with the Labour Office.

The fact that great epidemic diseases disregard na-
tional boundaries forces upon nations the adoption of
cooperative measures against the ravages of these
diseases. The first congress in 1851 was called to con-
sider ways of dealing with cholera, plague, and yellow
fever. The most striking illustration of national
cooperation was afforded in 1920 and 1921 by the special
commission against typhus in eastern Europe. This
campaign was organized under the auspices of the
League of Nations and had the direct financial support
of fourteen governments. A sanitary barrier was
erected in eastern Europe and the march of the disease
was halted. There is every reason to expect that co-
operation of this sort will become more frequent and
that diseases which heretofore have flourished because
they encountered only unorganized resistance will now
face the united front of a world sanitary army.

After public-health officers have done all that they
can in the way of sanitation and control of contagious
diseases, there remains a majority of diseases with which
only the individual can deal. A large part of the prob-
lem of public health resolves itself into the question of
personal hygiene. Only by changing the health habits
of millions can the level of national and world efficiency
be raised. In attempting this task certain traits of
human nature must be reckoned with. All the re-
sources of modern education, publicity, and suggestion
must be employed. Especially must the habits of
children be formed while they are still in a plastic stage.

INTERNATIONAL PUBLIC HEALTH

Thus attempts in popular education in personal hygiene
are being made in many countries and by various
methods. The movement is still in the stage of experi-
ment and demonstration. There are some signs of
definite accomplishment in this field, but much re-
mains to be done in the way of testing the material and
methods of instruction before the campaign can be
pushed with complete conviction and hope of perma-
nent success. But this is inevitable unless control from
without is to be substituted for mere self-direction. No
one advocates the course of compulsion except with
respect to well-established conditions of contagious dis-
ease which call for the exercise of the police power of
the community in the interests of all.

The essential task of training health officers and the
various technical experts who form the staff of a modern
health organization is being put upon a professional
basis. The School of Hygiene and Public Health of
Johns Hopkins University, the new School of Public
Health of Harvard University, the School for Nurses of
Yale University, the training centres at the University
of Toronto and at London, Ontario, the new School of
Hygiene which is being established in London under the
auspices of the British Government, the Institutes of
Hygiene at Prague and Warsaw, and many other in-
stitutions of a similar sort are equipped to give a
thorough professional training, both in the fundamental
sciences which underlie modern hygiene and in the prac-
tical application of scientific knowledge to the problems
of control and administration in the field. Through a
system of interchange of health officers being carried

158 SCIENCE REMAKING THE WORLD

on by the Health Organization of the League of Nations,
a spirit of international cooperation is being created in
this individual and personal way; the knowledge of
health procedures in one country is being put at the
disposal of other nations.

The direct cooperation of governments is having an
important bearing upon the growth of international
hygiene. The leading governments furnish health
officers in the ports of other countries so that valuable
means of contact and cooperation are established.
What amounts to the appointment of attaches of
hygiene is being brought about so that it is possible to
look forward to a time in the early future when every
country will have its sanitary representatives in other
lands. Such a system cannot fail to increase in many
ways the effectiveness of organization and activity in
behalf of world health.

Non-governmental health agencies are playing a
significant part in the new hygienic movement. The
international Red Cross has for many years concerned
itself with the health conditions of prisoners of war.
With the organization of the League of Red Cross
Societies in 1919, a new international voluntary agency
was set up. A programme of this society includes as
an important feature the promotion of public health
measures in the different countries where the Red
Cross Society has been established. The Rockefeller
Foundation, through its subsidiaries, the International
Health Board, the China Medical Board, and the Divi-
sion of Medical Education, is carrying on work which,
during recent years, has included items of cooperation

INTERNATIONAL PUBLIC HEALTH 159

and service in sixty of the governmental areas of the
world. It has demonstrated on a large scale the possi-
bilities of the control of hookworm disease and the use
of such control measures as a means of educating whole
populations in the matter of public health work. The
International Health Board of the Foundation has also
conducted a successful campaign which aims at the
complete eradication of yellow fever. This has called
for the cooperation of Mexico, Central America, and
several South American countries. The outcome is a
striking proof of what can be accomplished when
nations work together with complete confidence and
good-will.

Thus as we try to get a picture of what is going on to-
day in the world in the interests of the health of all the
nations, we see that there is something like an approxi-
mation to the ideal system which a superman might
conceivably try to set up. As compared with what re-
mains to be accomplished, only an insignificant start
has been made, but looked at from the standpoint of a
century ago, really striking progress has already been
achieved. In the last half century the scientific re-
sources of modern medicine have been enormously
enriched. The causes of a great number of devastating
diseases have been discovered; the methods of con-
trolling them have been worked out; medical education
has been put upon a higher level; a beginning has been
made in the training of expert sanitarians and an entire
hygienic personnel. Organization of health administra-
tion has been greatly increased in efficiency. The death
rates in all the leading countries of the world have fallen

160 SCIENCE REMAKING THE WORLD

in a most gratifying fashion. Beginnings have been
made in the education of the public in the laws of per-
sonal hygiene. International understandings and good-
will have been promoted. He would be hopeful indeed
who should at the present time see anything like a
millennium of human brotherhood; but at any rate it is
obvious that the tendencies now to be seen in the world
toward cooperation for health cannot fail to draw
scientific men everywhere into closer comradeship.
So much is clear gain. There is reason to hope that for
a time at least the resources of science will be turned
from the destruction of human life to the healing of the
nations.

GUIDE TO FURTHER READING

American Public Health Association: "Half Century of Public
Health; Jubilee Historical Volume," edited by Mazyck P. Ravwiel.
N. Y. Auth., 1921, 461 pages.

"China and Modern Medicine. A Study in Medical Missionary
Development," by Harold Balme. London, 1921, 224 pages.

"Progress of Public Health Work," by Dr. J. H. Beard. 152 p.
Reprint from Scient. Month., N. Y., Feb., 1922.

"International Organization and Public Health," by G. S.
Buchanan. Lancet, Feb. 26, 1921, vol. I, pages 415-520.

"The International Mind in Medicine," by Kendall Emerson.
Boston Med. and Surgical Jour., June 15, 1922, pages 795-799.

"Medical Education in the United States and Canada," by
A. Flexner. Carnegie Foundation for the Advancement of Teach-
ing. Bull. No. 4, 1910. 346 pages.

"Medical Education in Europe." Carnegie Foundation for the
Advancement of Teaching. Bull. No. 6, 1912. 357 pages.

"The New Public Health," by Dr. H. W. Hill. (Macmillan,
N. Y.) 1918. 206 pages.

"The Future of Medicine," by Sir James Mackenzie. (Henry
Frowdc, Hodder and Stoughton, London.) 1919. 238 pages.

INTERNATIONAL PUBLIC HEALTH 161

"The New Chivalry — Health." Southern Sociological Congress,
Houston, Texas. May 8-n, 1916, 555 pages.

"Medical Research and Education," by Drs. Richard M. Pearce,
Wm. H. Welch and others. Edited by J. McKeen Cattell. (The
Science Press, N. Y.) 1913. 536 pages. (Science and Education,
vol. 2.)

"The Health Officer," by Frank Overton and Willard J. Denno.
(W. B. Saunders Co.) 1919. 512 pages.

The Red Cross and International Public Health. League of
Red Cross Societies, Second Meeting of the General Council, Geneva,
March 28-31, 1922, by Rocco Santoliquido. Documents, vol. 2,
pages 115-125.

The Worlds Health. A monthly review published by the League
of Red Cross Societies. 7 Rue Quentin Rouchart, Paris VIII,
France.

EDUCATIONAL VALUE OF MODERN
BOTANICAL GARDENS

BY GEORGE T. MOORE, PH. D.

Director of the Missouri Botanical Garden, St. Louis, Mo.

THE cultivation of plants for their healing quali-
ties by the monks of the middle ages appears tc
have been the beginning of the modern botanical
garden, although these medieval gardens doubtless
took their origin from others of greater antiquity.

A most ingenious theory concerning the origin of
botanical gardens was put forward by a Frenchman
who claimed that during the i6th century designers of
embroidery and lace in France sought inspiration from
blooming plants. To meet this demand an enter-
prising horticulturist opened a garden with conserva-
tories in which he cultivated many strange and little-
known varieties. Later this garden became crown
property and medical students were admitted on condi-
tion that they would not interfere with the designers
of textiles and laces. Although the aesthetic study of
plants must have appealed to those who visited public
gardens, and even at the present day designers and
makers of artificial flowers get many ideas from study-
ing nature, it seems quite certain that botanical gardens
were primarily created for the students of maUria
medica.

162

MODERN BOTANICAL GARDENS 163

The educational value of a botanical garden did not
develop much, if at all, prior to the middle of the
1 7th century, when those at Bologna, Montpelier,
Leyden, Pans, and Upsala became more or less note-
worthy as aids to scientific teaching. The taste for
ornamental and decorative plants had meanwhile
been slowly growing and persons of wealth and influ-
ence, desiring to cultivate rare and unusual species,
began to employ men skilled in botanical knowledge to
take charge of their gardens. The world was searched
for new and rare plants which were brought back for
cultivation in the botanical gardens of Europe, and
many handsomely illustrated volumes describing these
plants were pubHshed by the rich patrons of botany.
These older gardens were essentially private institu-
tions, but gradually a few of the existing establishments
and a number of new ones were opened more or less to
the public.

Modern botanical gardens, therefore, have a number
of functions which have not appeared simultaneously
but have been a matter of gradual development. Be-
ginning with the utilitarian idea, there have been added
to this the aesthetic, the scientific, and the educational.
Naturally these elements have been given different de-
grees of prominence depending upon local conditions;
but whether a garden be essentially scientific or mainly
utilitarian, or combine all of the essential functions of
a garden, it is clear that the educational features are
receiving more and more emphasis. Formerly a public
garden was a mere museum of living plants; at best a
place for recreation and pleasure. Nowadays the at-

164 SCIENCE REMAKING THE WORLD

tempt is to have collections which, while appealing to
the sense of the beautiful, will give definite information
and instruction to the amateur as well as to the specialist.
The modern botanical garden fails to serve the com-
munity as it should if the school pupil as well as the
advanced student is unable to learn much from it. Mod-
ern educators who are seeking to find improved methods
of teaching are beginning to recognize the fact that
gardens furnish some most important and unique op-
portunities for imparting knowledge. Formerly books
and travel were the chief sources of information to the
general public; in these days of the phonograph, the
radio, and the moving picture, visual education is taking
a larger and larger place. Exhibits of plants native to
countries being studied in geography may give a better,
idea of conditions in that country than anything short
of an actual visit could accomplish. The growing of
tropical fruits, spice and perfume plants, rice, cotton,
sugar cane, coffee, tobacco, peanuts, and other economic
plants, particularly if their peculiarities are pointed
out by one familiar with their various characteristics,
forms a most helpful adjunct to modern educational
practices. Nowhere can fundamental facts concerning
heredity, selection, and breeding be so well demon-
strated as in a garden; and an insight into physiology,
morphology, and pathology may be easily gained when
presented through the life of a plant. Most children
are interested in gardens of one sort or another and
through their desire to learn what to grow and how to
grow it, as well as the kind of care which must be exer-
cised in order to make a success, many important bits

MODERN BOTANICAL GARDENS 165

of real knowledge, as well as much general information
may be imparted. For this reason a botanical garden
as an educational institution may be a much more
helpful feature in a community than a zoological park
or a museum, since it comes so close to everyday
life.

It is impossible to treat in detail the various kinds of
exhibits and demonstrations prepared to impart knowl-
edge to young persons. The ease with which this may
be done coupled with its recreational and pleasure-
giving qualities, makes it desirable for many communi-
ties to include in their educational systems a botanical
garden of some kind. Not only should the rare
"vegetable curiosities," consisting of a sort of botanical
circus, be featured, but common things such as wild
flowers, weeds, and farm crops must also be instruc-
tively displayed. Accurate labels giving the most im-
portan* information about plants are a necessity, and
by using different colours to indicate the country from
which plants come or the uses to which they are put,
definite facts and geographic interpretations are ab-
sorbed almost unconsciously. When to the educational
function is added the great humanizing power of a gar-
den, and the recreational service which it is able to ren-
der to the business man, the student and the plant lover,
it becomes clear why so many thousands of citizens
regularly visit gardens in cities which possess them.

GUIDE TO FURTHER READING

"Botanical Gardens," by N. L. Britton. Bull. Ton. Bot. CL
1896-

166 SCIENCE REMAKING THE WORLD

"History and Functions of Botanical Gardens," by Arthur W.
Hill. Ann. Mo. Dot. Card. 2:185-223. 1915.

"The Missouri Botanical Garden," by W. Trelease. Pop. Sci.
Monthly , 62:193-221. 1903.

Various articles relating to specific problems in botanical gardens,
by George T. Moore, and others. Missouri Botanical Garden
Bulletin, 1913-1923.

THE MEANING OF EVOLUTION
BY JOHN M. COULTER, PH.D.

Professor of Botany, University of Chicago

THE meaning of evolution is probably more mis-
understood than any doctrine of science. The
reason for it is that it has been discussed very
freely by those who are not informed, and in this way
much misinformation has been propagated. The evolu-
tion of the material world, called inorganic evolution,
aroused wonder but not apprehension; but when or-
ganic evolution came into prominence hostility was
aroused, because such evolution seemed to involve man.
<The general meaning of organic evolution is that the
plant and animal kingdoms have developed in a con-
tinuous, orderly way, under the guidance of natural
laws, just as the solar system has evolved in obedience
to natural laws. There are at least three important
reasons why an understanding of the doctrine of evolu-
tion should be regarded as a necessary part of college
training:

I. It has revolutionized modern thought. Every
subject to-day is being attacked on the basis of its
evolution. Not only are inorganic and organic evolu-
tion being considered, but also the evolution of language,
of literature, of society, of government, of religion. In
other words, it is a point of view which represents the
atmosphere of modern investigation in every field.

167

168 SCIENCE REMAKING THE WORLD

2. It is persistently misunderstood. From the press,
the lecture platform, and even the pulpit, one frequently
receives amazing statements in reference to organic
evolution. If it were made an essential feature of stu-
dent training, there would be developed a propaganda
of information instead of misinformation.

3. It has revolutionized agriculture. The practical
handling of plants and animals in the way of improving
old forms and securing new ones, was made possible
and definite when the laws of inheritance began to be
uncovered through experimental work in evolution.

j In brief, the purpose of a course in organic evolution
should be to give some appreciation of its meaning and
methods, to furnish a check on rash and unfounded
statements in reference to it, and to show how the study
of evolution has led to enormously practical results.

PERIODS IN THE HISTORY OF EVOLUTION

/ There have been three distinct periods in the history
of evolution, based upon the method of attack. These
three methods may be spoken of in general as specu-
lation, observation and inference, and experimentation.
I. SPECULATION. — The idea of organic evolution is
as old as our record of men's thoughts, for all the old
mythologies are full of it. No modern man, therefore,
is responsible for the idea, although it is a common
misconception to load this responsibility upon certain
distinguished modern students of evolution. For ex*
ample, the name of Darwin is so conspicuous in connec-
tion with evolution that many seem to think that
Darwinism and evolution are synonymous. Until 1790,

EVOLUTION 169

however, organic evolution was a pure speculation, with
no basis of scientific work. In other words, it was based
upon meditation rather than investigation, and was to
be regarded as a philosophy rather than a science. It
should be emphasized that the idea of evolution has
always been in the mind of men.

During the latter part of this period certain facts be-
gan to be observed that made some thinking men con-
clude that evolution might be a fact, and not merely a
speculation. It will be helpful to note briefly, in his-
torical succession, the kinds of facts that set these men
to thinking, and that resulted in the second period in
the history of evolution, when it became a science.

In classifying plants and animals, which was the
initial phase of biology, men rigidly defined the differ-
ent species, the thought being that the different kinds
had descended in unbroken succession "from the be-
ginning," whenever that may have been. When more
extensive observations were made in the field, numer-
ous intergrades began to be found. The species, as
defined, seemed to intergrade freely. In other words,
the pigeon-hole arrangement, with rigid partitions, did
not express the facts. It became evident that species
had been defined by man rather than by nature. Some
were distinct enough, but many intergraded. It ought
to be realized that a species is the conception of man,
and fluctuates just as do human opinions. Biologists
learned, therefore, that species are human inventions,
and intergrading suggested that one species might come
from another, the intergrades marking the trail.

The next observations suggesting that evolution

170 SCIENCE REMAKING THE WORLD

might be a fact had to do with what was called the
"power of adaptation," which we now call "responses.'*
It was observed that plants and animals respond to
changes in environment, often in a striking way. I
have seen what were regarded as two good species
changed into one another by changing from a moist
habitat to a dry one, or the reverse. This ability to
respond to changing conditions seemed to indicate that
species are not so rigid and invariable as had been
supposed.

As technique developed, and the internal structures
of plants and animals became known, it often happened
that rudimentary structures were found, which never
developed to a functioning stage, but which occurred
fully developed in related forms. For example, it was
found that in the developing parrot a set of embryo
teeth begins, but never matures. The inference was
natural that these structures had been functional in the
ancestors, but had been abandoned by some of their
descendants. In these days, it has become the habit to
call these rudimentary structures "vestiges." Plants
and animals are full of these vestiges. One illustration
in the human body is the vermiform appendix. It
seems safe to say that we are walking museums of
antiquity. As technique developed still further, the
embryology of plants and animals began to be studied
in detail, the whole progress from egg to adult being
observed. In very many cases, during this progress,
glimpses of fleeting structures and resemblances were ob-
tained, which had disappeared when the adult stage was
reached, but which related the form to other species.

EVOLUTION 171

After this succession of facts, there came a revelation
which convinced more men that evolution is a fact
than any evidence which had preceded. The geologists
had begun to uncover that wonderful succession of
plants and animals from the earliest geological periods
to the present time. They saw in the oldest periods
forms unlike any now existing; they saw gradual changes
with each succeeding horizon; they saw a steady ap-
proach to forms like those of to-day, until by insensible
gradations the present flora and fauna were ushered in.
This geological record, becoming continuously more
detailed in its interpretation, set men to thinking
seriously.

Finally, after all this evidence was in, men began to
look around them and to realize what they had been
doing for centuries in domesticating animals and plants.
They had been bringing them from the wild state and
changing them so much by the methods of culture that
in many cases the wild originals could not be recognized.
Most of our cultivated plants, if found in nature as-
sociating with their wild originals, would be regarded!
as extremely distinct species.

In the presence of such an array of facts, is it to be
wondered at that certain men began the serious, scienti-
fic study of evolution ? As a result, the second period
in the history of evolution was ushered in, and evolution
became a science.

2. OBSERVATION AND INFERENCE. — In time this
period extends from 1790 to 1900. It is characterized
by the appearance of a succession of explanations of
evolution. It is important to remember that the men

172 SCIENCE REMAKING THE WORLD

who offered these explanations are not responsible for
the idea of evolution, but merely attempted to explain
the fact of evolution. They were explainers rather
than authors. It is also important to realize the
method used. It may be called the method of compari-
son and inference. Plant and animal forms were ob-
served, and resemblances were assumed to indicate re-
lationship through descent. It was not demonstration,
but inference based on observation. Darwin carried
the method to the limit of its possibilities, observing not
a small range of forms, but observing through several
years a world-wide range of forms, in connection with
the famous voyage of the Beagle. His caution is also
indicated by the fact that his observations were under
consideration for some twenty years before his con-
clusions were published. His facts were so undoubted,
and his case so well put, that his explanation of evolu-
tion attracted immediate attention and really fought the
battle of evolution. This is what made his explanation
an epoch in the history of biological science.

This period in the history of evolution, which may be
thought of as the mediaeval period, is marked by the
appearance of three conspicuous explanations. There
is no need to define these explanations in detail. The
explanation which ushered in the period was proposed
simultaneously and independently by Goethe of Ger-
many, St. Hilaire of France, and Erasmus Darwin of
England, in 1790. Observations of responses to
changed environment, led to the conclusion that en-
vironment is the direct cause of change, actually mould-
ing forms. This evolutionary factor, therefore, is

EVOLUTION 173

entirely external to animal or plant. It was a natural
first explanation, but it was too superficial, and en-
vironment as a direct cause of evolution soon passed
into the historical background.

In 1801, Lamarck, in a series of lectures, announced
his explanation, calling it the theory of "appetency."
This was really the first explanation with a body of
doctrine, and hence Lamarck has often been called
the "founder of organic evolution." The term "appe-
tency," however, has been abandoned, and its real mean-
ing expressed by the "effect of use and disuse." With
Lamarck, environment is not the direct cause of the
change, but the occasion for the change. The cause is
the striving, the effort to do something that had become
necessary. Thus organs would become developed as a
consequence of some change in environment calling;
them into use; and conversely, organs would become
gradually aborted as a consequence of some change in
environment that eliminated their use. This explana-
tion rests absolutely upon the inheritance of acquired
characters, meaning characters not inherited by the
possessor, but acquired during the lifetime of the in-
dividual.

In 1858 the epoch-making explanation by Charles
Darwin was announced, an explanation which was dom-
minant for about fifty years. It is too familiar to need
explanation, but I wish to call attention to the steps by
which it developed in Darwin's mind. These steps have
been spoken of as five facts and one inference, and the in-
ference appeared so natural that there was no escaping
it. The five facts in their logical sequence are the ratio

174 SCIENCE REMAKING THE WORLD

of increase, the equilibrium of species, variation, and
artificial selection, from which natural selection was the
inevitable inference. In brief, it claims that nature
selects among variations, that the method of selection
is competition, that the result is the destruction of the
relatively unfit, or as Spencer put it, the "survival of
the fittest." In brief, the theory is really an explana-
tion of what is called adaptation.

As facts multiplied, the current explanations of
evolution were found to be inadequate to explain some
of them. This led to a general misunderstanding of
the situation by the uninformed public. For example,
more intensive study developed the fact that Darwin's
explanation does not always explain. His name is so
identified with evolution in public thought, that this
criticism of the universal application of his conclusions
by certain scientific men was taken to mean that the
theory of evolution was being abandoned. The real
situation is that every proposed explanation may prove
inadequate, and yet the fact of evolution remains to be
explained.

All of the explanations offered are partial explanations
which simply means that no one of them applies to all
the facts. We need them all and more besides. So far
from being abandoned, evolution is the basis of all bio-
logical work to-day.

The method of comparison and inference continued
until the beginning of the present century. Then came
a new epoch in the history of evolution.

3. EXPERIMENTATION. — This may be called the
modern period, in contrast with the mediaeval and

EVOLUTION 175

ancient periods. It was ushered in by the work of
DeVries, who introduced the experimental study of
evolution, and announced his explanation of evolution
by means of mutation. The problem was to discover
whether one species actually produces another one. It
had been inferred that it does, but inference is not
demonstration. By means of carefully controlled pedi-
gree cultures, DeVries discovered a plant in the actual
performance of producing occasionally a new form
among its numerous progeny. This form bred true and
preserved its distinctive characters; in other words, it
was a new species, or at least a different species from
its parent. Many such species have now been ob-
served originating in this way, both in plants and
animals. That one species can produce another one is
no longer inferred, but demonstrated, and demonstrated
repeatedly. There is no longer any doubt, therefore,
that evolution is a fact. It is quite a different question
whether the proposed explanations are adequate.

This outline of methods and results in one phase of
one science is illustrative of all scientific investigation.
It is uncovering facts by experimental demonstration,
and is taking less account of inferences. In the field
of evolution, when inferences were the only results, it
was natural to extend inference to the evolution of the
plant and animal kingdoms, and this involved the origin
of man. In these days, there is no such attempt, for
experimental demonstration of the evolution of the
whole series of organic forms, culminating in man, is
clearly impossible. Biologists, therefore, are no longer
concerned with the whole story of evolution, but only

176 SCIENCE REMAKING THE WORLD

in discovering experimentally how one species may
produce another one. The fact of evolution is estab-
lished, but the whole story of evolution must remain an
inference.

PRESENT STATUS OF EVOLUTION. — Only a very
general statement is possible, since a full statement
would involve an extensive discussion. The experi-
mental study of evolution has led to the development
of the field of genetics, a subject which has grown with
remarkable rapidity. It is genetics which must un-
cover the machinery of evolution, which of course is
fundamentally a matter of inheritance. The facts
thus far uncovered indicate complexities which were
not realized before, but which should have been anti-
cipated, for inheritance with its resulting evolution
represents the most complex biological situation imag-
inable.

The present status of evolution as a body of doctrine
may be said to be in a state of flux, out of which the
truth will emerge eventually. Any meeting of biolo-
gists at which evolution is discussed will disclose con-
siderable diversity of opinion. It is evident, of course,
that whatever produces variation furnishes a basis for
evolution. But what produces variation? Environ-
ment is one factor, direct or indirect; sex is another
factor, especially when strains are crossed; and still
other factors might be cited. Any factor claimed to in-
duce variation must stand the test of genetics, with
its cytological background. Variations, however pro-
duced, are of two general kinds, as indicated by be-
havior,, namely, the so-called continuous variation of

EVOLUTION 177

Darwin's explanation, and the so-called discontinuous
variations of De Vries's explanation. The differences
of opinion have to do with the method of variation pro-
duction, that is, variation that may result in a new
species.

After variation is secured, there is no question as to
the function of selection. It is merely a statement of
fact to say that some variations persist and some are
eliminated. It is a very different matter to claim that
only the "fit" persist. In some way the selection is
made, and the selection factors may be quite variable.
In general, it may be said that there is no serious differ-
ence of opinion that evolution is based on variation and
subsequent selection. It is only a matter of detail to
determine the exact factors.

There is a much more serious problem of evolution,
however, which is still baffling. The variations ob-
served, which result in new species, as tested by genetics,
and for which the cytological machinery has been ob-
served, produce species either laterally or retrogres-
sively; that is, species of the same phylogenetic level,
or of declining rank. There is as yet no adequate ex-
planation of progressive evolution, the advance from
one great phylum to another. Progressive evolution is
a very evident fact, as shown by many an impressive
series disclosed by the geological records, and also by
our inferred lines of phylogeny. The theory of ortho-
genesis is often cited as an attempt to explain progres-
sive evolution. Orthogenesis is not an explanation, but
a statement of the fact of progressive evolution, which
still awaits explanation. The multiplication of species

178 SCIENCE REMAKING THE WORLD

is within the reach of experimental study as to causes
and methods, and the results are leading to conclusions
that may vary with the investigator, but which will be
checked up by further investigation. The phylogenetic
advance of species, however, is still within the region of
inference. It is something like the difference between
the tracks in a switchyard and the main line. We
have succeeded in investigating the switching, but the
through trains are still baffling.

PRACTICAL RESULTS

The experimental study of evolution, leading to the
development of the science of genetics, resulting in in-
^creasing knowledge of the laws of inheritance, has led to
practical results which the public in general do not ap-
preciate. I wish to refer to two of these by way of
illustration.

i. THE REVOLUTION IN AGRICULTURE. — It seems a
far cry from speculations concerning evolution to a
revolution in agriculture, but the continuity is un-
broken. Speculation led to observation; observation
led to experimentation; experimentation resulted in
discovering the laws of inheritance; and the application
of these laws has enabled us to handle plants and ani-
mals in a way that was never dreamed of before. It is
a good illustration of the fact that there is no sharp
dividing line between what is called pure science and
applied science, for pure science may prove to be enor-
mously practical.

A brief statement will illustrate the agricultural re-
sults in the application of our knowledge of inheritance.

EVOLUTION 179

It had become evident, for example, that for various
reasons the ratio of increase in population was much
greater than the ratio of increase in food production.
The statement was made that during the ten years
preceding the great war our population had increased
20 per cent, and our food production about I per
cent. I cannot vouch for the accuracy of this state-
ment, but it illustrates the situation. It was certainly
an alarming outlook. Under these circumstances,
plant crops began to be studied from the standpoint
of genetics, and plant breeding became a science.

The lack of crop production arose chiefly from three
causes, namely, lack of adaptation of crops to environ-
ment, destruction by drought, and destruction by
disease. The same races were being cultivated every-
where, and only in certain places was the maximum re-
sult obtained. A study of races of crop plants through-
out the world, and of the environment necessary for
maximum yield, resulted in such an adjustment of
crops to conditions that total food production was enor-
mously increased. The problem of drought is being
rapidly solved by the discovery or development of
drought resistant races, not only insuring against loss
from this cause, but also enormously increasing the
possible area of cultivation. The problem of disease
has been attacked in the same way, and disease resistant
races of most of the important crops have been devel-
oped, insuring against this loss. As a result, food pro-
duction is now beginning to overtake population, and
we may thank the persistent study of evolution for the
result.

i8o SCIENCE REMAKING THE WORLD

2. THE DEVELOPMENT OF THE SCIENTIFIC SPIRIT.-^
This is a result of such fundamental importance that it
must be considered, for it is revolutionizing the mental
attitude of the human race. Its relation to the study
of evolution may not be clear, but it was the study of
evolution that revolutionized science and put it upon
its present basis. The scientific spirit means a certain
attitude of mind, which may be described best by speak-
ing of some of its characteristics.

(i) It is the spirit of inquiry. — In our experience we
encounter a vast body of established belief in reference
to all important subjects, such as society, government,
education, religion, etc. It is well if our encounter be
only objective, for it is generally true, and a more dan-
gerous fact, that we find ourselves cherishing a large'
body of belief, often called hereditary, but really the re-
sult of early association. Nothing seems more evident
than that all this established belief which we encounter
belongs to two categories: (i) the priceless result of
generations of experience, and (2) heirloom rubbish.
Unfortunately, the discovery of the latter has often
resulted in weakening the hold of the former. The
young inquirer, or the non-logical inquirer, is in danger
of condemning all the conclusions of the past when one
is found wanting.

Toward this whole body of established belief the
scientific attitude of mind is one of unprejudiced inquiry.
It is not the spirit of iconoclasm, as some would be-
lieve; but an examination of the foundations of belief.
The spirit which resents inquiry into any belief, how-
ever cherished, is the narrow spirit of dogmatism; and

EVOLUTION 181

is as far removed from the true scientific attitude as the
shallow-minded rejection of all established beliefs. The
childhood of the race accumulated much which its
manhood is compelled to lay aside, and the world needs
a thorough going over of its stock in trade. Such work
cannot be done all at once, or once for all, for it must be
a gradual sloughing off as the spirit of inquiry becomes
more generally diffused.

It must be evident that this spirit is diametrically op-
posed to intolerance, and that it can find no common
ground with those who confidently affirm that the pres-
ent organization of society is as good as it can be; that
the present republics of the wrorld represent the highest
possible expression of man in reference to government;
that the past has discovered all that is best in education;
that the mission of religion is to conserve the past
rather than to grow into the future. This is not the
spirit of unrest, of discomfort, but the evidence of a
mind whose every avenue is open to the approach of
truth from every direction. Like the tree, it is rooted
and grounded in all the eternal truths that the past has
revealed, but is stretching out its branches and ever-
renewed foliage to the air and sunshine, and taking into
its life the forces of to-day.

In his essay on Intellect, Emerson says:

Gv»d offers to every mind its choice between truth and repose.
Take which you please, you can never have both. Between these
as a pendulum, man oscillates. He in whom the love of repose
predominates will accept the first creed, the first philosophy, the
first political party he meets, most likely his father's. He pets
rest, commodity, and reputation; but he shuts the door of truth.
He in whom the love of truth predominates will keep himself aloof

182 SCIENCE REMAKING THE WORLD

from all moorings, and afloat. He will abstain from dogmatism, and
recognize all the opposite negations between which, as walls, his
being is swung. He submits to the inconvenience of suspense and
imperfect opinion, but he is a candidate for truth, as the other is not,
and respects the highest law of his being.

Dogmatism still finds many victims, for education
has not yet touched the majority; but every day the
possible victims are becoming fewer in number, and
those who seek to lead opinion must presently abandon
the method of bare assertion. The factors in this
general intellectual progress are perhaps too subtle and
interwoven to analyze with certainty, but conspicuous
among them is certainly the development of scientific
training. For fear of being misunderstood, I hasten
to say that this beneficent result of scientific training
does not come to all those who cultivate it, any more
than is the Christ-like character developed in all those
who profess Christianity. I regret to say that even
some who bear great names in science have been as
dogmatic as the most rampant theologian. But the
dogmatic scientist and theologian are not to be taken
as examples of the "peaceable fruits of righteousness,"
for the general ameliorating influence of religion and of
science is none the less apparent.

(2) The scientific spirit demands a real connection be-
tween an effect and its claimed cause. — It is in the labora-
tory that one first really appreciates how many factors
must be taken into the count in considering any result,
and what an element of uncertainty an unknown factor
introduces. In the very simplest cases, where we have
approximated certainty in the manipulation of factors

EVOLUTION 185

to produce results, there is still lurking an element of
chance, which simply means an unknown and hence
uncontrolled factor. Even when the factors are well in
hand and we can combine them with reasonable cer-
tainty that the result will appear, we may be entirely
wrong in our conclusion as to what in the combination
has produced the result.

For example, we have been changing the forms of
certain plants at will by supplying in their nutrition
varying combinations of certain substances. By manip-
ulating the proportions of these substances we pro-
duce the expected result. It was perhaps natural to
conclude that the chemical nature of these particular
substances produce the result, and our prescription was
narrowed down to certain substances. Now, however,
it is discovered that the results are not due to the chemi-
cal nature of these substances, but to a particular physi-
cal condition which is developed by their combination,
a condition which may be developed by the combination
of other substances as well; so that our prescription is
much enlarged. In this operation we are thus freed
from slavery to particular substances, and must look
only to the development of a particular physical con-
dition.

It seems to me that there is a broad application
here. In education, we are in danger of slavery to
subjects. Having observed that certain ones may be
used to produce certain results, we prescribe them as
essential to the process, without taking into account
the possibility that other subjects may produce similar
results.

184 SCIENCE REMAKING THE WORLD

In religion, we are in danger of formulating some
specific line of conduct as essential to the result, and of
condemning those who do not adhere to it. This is the
essence of formalism. That there may be many lines of
approach to a given result, if that result be a general
condition, is a hard lesson for mankind to learn.

If it is so difficult to get at the real factors of a simple
result in the laboratory, and still more difficult to inter-
pret the significance of factors when found, in what
condition must we be in reference to the immensely
more difficult and subtle problems which confront us in
social^ organization, government, education, and reli-
gion; especially when it is added that the vast majority
of those who have offered answers to these problems
have had no conception of the difficulties involved in
reaching absolute truth. It is evident that in the vast
problems which concern human welfare in general, we
are but groping our way, and that our answers as yet
are largely empirical. The proper effect of such
knowledge is not despair, but a receptive mind. In my
judgment, therefore, the diffusion of the scientific
spirit will make it more and more difficult for any one
with a nostrum to get a hearing.

The prevailing belief among the untrained is that any
result may be explained by some single factor operating
as a cause. They seem to have no conception of the
fact that the cause of every result is made up of a com-
bination of interacting factors, often in numbers and
combinations that are absolutely bewildering to con-
template. An enthusiast discovers some one thing
which he regards, and which perhaps all unprejudiced

EVOLUTION 185

and right-thinking people regard as an evil in society or
in government, and straightway this explains for him
the whole of our present unhappy condition. This
particular tare must be rooted up, and rooted up im-
mediately without any thought as to the possible
destruction of the plants we must cultivate. The ab^
normal tissue must be destroyed without reference to
the fact that the method of destruction may debilitate
the normal tissue.

This habit of considering only one factor, when per-
haps scores are involved, indicates a very primitive and
untrained condition of mind. In the youth of science
it often threw its votaries into hostile camps, each
proclaiming rival factors, when the problem really
demanded all the factors they had and many more
besides.

It is fortunate when the leaders of public sentiment
have gotten hold of one real factor. They may overdo
it, and work damage by insisting upon some special
form of action on account of it, but so far as it goes it is
the truth. It is more apt to be the case, however, that
the factor claimed holds no relation whatever to the
result. This is where political demagoguery gets in its
most unrighteous work, and preys upon the gullibility
of the untrained; and is the soil in which the noxious
weeds of destructive radicalism, charlatanism, and re-
ligious cant flourish.

It is to such blindness that scientific training is
bringing a little glimmer of light, and when the world
one day really opens its eyes, and it is well if it open
them gradually, the old things will have passed away.

186 SCIENCE REMAKING THE WORLD

(3) The scientific spirit keeps one close to the facts. —
One of the hardest things in my teaching experience
has been to check the tendency of many students to use
one fact as a starting point for a flight of fancy that
is simply prodigious. Such a tendency is corrected, of
course, when the facts accumulate somewhat, and flight
in one direction is checked by a pull in some other di-
rection; but most of us have this tendency, and the
majority are so unhampered by facts that flight is free.
This exercise is beautiful and invigorating if it is recog-
nized to be what it really is, a flight of fancy; but if
it results in a system of belief it is a deception.

There seems to be abroad a notion that one may start
with a single, well-attested fact, and by some logical
machinery construct an elaborate system and reach an
authentic conclusion; much as the world has imagined
for more than a century that Cuvier could do if a single
bone were furnished him. The result is bad, even
though the fact have an unclouded title; but it too often
happens that great superstructures have been reared on
a fact which is claimed rather than demonstrated.

We are not called upon to construct a theory of the
universe upon every well-attested fact, and the sooner
this is learned the more time will be saved and the
more functional will the observing powers remain.
Facts are like stepping stones; so long as one can get a
reasonably close series of them, he can make progress in
a given direction; but when he steps beyond them he
flounders. As one travels away from a fact, its signi-
ficance in any conclusion becomes more and more at-
tenuated, until presently the vanishing point is reached,

EVOLUTION 187

like the rays of light from a candle. A fact is really
influential only in its own immediate vicinity; but
the whole structure of many a system lies in the region
beyond the vanishing point.

Such "vain imaginings" are delightfully seductive
to many people, whose life and conduct are even shaped
by them. I have been amazed at the large develop-
ment of this phase of emotional insanity, commonly
masquerading under the name of "subtle thinking."
Perhaps the name is expressive enough, if it means
thinking without any material for thought. One of
the great dangers of our educational system is in laying
special stress on training. There is danger of setting
to work a mental machine without giving it suitable
material upon which it may operate, and it reacts upon
itself, resulting in a sort of mental chaos. An active
mind turned in upon itself, without any valuable ob-
jective material, can never reach any very valuable
results.

It may not be that science is the only agency, apart
from common sense, which is correcting this tendency;
but it certainly teaches most impressively, by object
lessons which are concrete and hence easiest to grasp,
that it is dangerous to stray very far from the facts, and
that the farther one strays away the more dangerous it
becomes, and almost inevitably leads to self-deception.

In conclusion, it may be said that the attitude of
mind represented by the scientific spirit must bring in*
dependence in observation and conclusion, some idea
as to what an exact statement is, and some conception
of what constitutes proof.

188 SCIENCE REMAKING THE WORLD

Any field, whether religion or science, is to be esti-
mated by its ideals, even though its occasional per-
formance may be open to criticism. The ideals of
science are (i) to understand nature, that the boun-
daries of human knowledge may be extended, and man
may live in an ever-widening perspective; (2) to apply
this knowledge to the service of man, that his life may
be fuller of opportunity; and (3) to use the method of
science in training man, so that he may solve his prob-
lems and not be their victim.

I find nothing more helpful to the student and leader
of men than a clear appreciation of the working of
evolution as exemplified in plants and animals. Evo-
lution teaches that progress is gradual; that a better is
progress toward the best; that sudden radical changes
are not to be expected; that the future has its roots in the
present. It teaches that revolutions may be very slow.
It forbids unreasonable demands upon the individual
or upon society, and discountenances the usual type
of reformer. It shows that there have been no universal
catastrophes and new creations, but that the present has
gradually evolved from the past, and that the future
will appear in the same gradual way. Furthermore, it
shows that advance in a certain direction may not be
uniform, for there are periods of apparent recession, as
well as those of more rapid advance. The results are
only apparent in the large view over long periods of
time, when the tossing back and forth of surface waves
disappears, and the steady advance of the slow-moving
current becomes apparent.

Perhaps most important of all, it teaches that man

EVOLUTION 189

is a poor interpreter of individual events, and has no
means of deciding whether they contribute to advance
or not. Hence it must lead to cautious and charitable
judgments; but at the same time it supplies a strong
ground of confidence that there must be eventual
progress. Some of the minor details of evolution may
be useful to the pessimist, but its whole sweep justifies
the broadest optimism.

GUIDE TO FURTHER READING

"Variation, Heredity, and Evolution," by R. H. Lock.

"Heredity and Environment," by E. G. Conklin. (Princeton
Univ. Press.) 1916.

"Genetics," by H. E. Walter. (Macmillan.) 1913-

" Fundamentals of Plant Breeding," by J. M. Coulter. (Apple-
ton.) 1914.

"Readings in Evolution, Genetics, and Eugenics," by H. H.
Newman. (University of Chicago Press.)

OUR FIGHT AGAINST INSECTS
BY L. O. HOWARD, PH.D.

Chief of the Bureau of Entomology,
U. S. Department of Agriculture

THE civilized part of the human race is just
awakening to the fact that the future welfare and
happiness of humanity depends to a considerable
extent upon its success in the fight against the insects.
They possess characteristics which permit them to live
under all sorts of conditions and their work as a class
brings them into direct conflict with the interests of
humanity in multitudes of ways, many of which are
entirely unsuspected by people in general and many
others are still undoubtedly undiscovered. Their small
size has often obscured their destructive powers, but in
their very insignificance in size lies much of the danger.
Insects damage practically all of the farmer's crops,
but it is not generally known that year after year at
least a tenth part of all that is artificially grown is con-
sumed by them. Not only do they eat the crops, but
they eat clothing in city and country and they damage
stored foods of all kinds; they burrow into the timbers
of our buildings, they eat books, and wooden and leather
implements. They accommodate themselves to new
conditions as they arise. Telegraph lines, compara-
tively new in the history of human civilization hav*

190

OUR FIGHT AGAINST INSECTS 191

come into the insects' view, and they eat the poles and
even burrow into the insulating lead of the wire coils.
A still later step in man's advance, the airplane, also in-
volves a fight against the insects, for the wood which is
used in their propellers is also damaged by certain
species.

Most domestic animals suffer greatly from their at-
tacks. Almost every kind of animal that is domesti-
cated and used by human beings has its serious insect
enemies, and man himself is far from immune. Aside
from the species that sting him and annoy him, there
are other forms that carry disease. The house fly
carries at least thirty different kinds of disease and
parasites. Mosquitoes of different kinds are responsible
for distribution of malaria and yellow fever, dengue
/ever, and filariasis. The tsetse fly carries the sleeping
sickness which has decimated large areas in Africa, the
tick carries the germs of Rocky Mountain fever, and
there are many other insects that carry various dis-
eases, some doubtless unknown.

A few years ago we should have said that this was a
fairly comprehensive summary of the possibilities of in-
sect damage, but it has recently been discovered that
they are responsible for the carriage of many of the most
fatal diseases of cultivated plants just as they carry
the diseases of animals and man. They are carriers of
fatal diseases to many of the most important crops and
to fight the diseases we must fight the insect carriers and
control them.

Country after country has organized its entomo-
logical service, following the lead of the United States*

192 SCIENCE REMAKING THE WORLD

which was the first country to begin to study insects in
a really competent way from the economic point of view.
This action on the part of our own country is not in the
least surprising, since as agriculture spread intensively
over its hitherto uncultivated territory and the so-
called balance of nature was upset in a rapid and most
imperative manner, many native species took readily to
the new food planted for them in enormous fields and
multiplied to an incredible extent.

And in this development, with the bringing over of
products of different kinds, including plants from the
old countries, their insect enemies were brought with
them, and finding themselves in a region where the
summers or breeding seasons were longer arid where the
cultivation was upon a tremendous scale, the insects
took cheerfully to the new environment and multiplied
to an extent which had not been possible in the small
fields and shorter summers of Europe.

Beginning in a small way and really not until after
the completion of the Civil War, the good results
reached by the labours of a few entomologists, notably
Walsh and Le Baron in Illinois and Riley in Missouri,
gained public attention. With the establishment of
the state agricultural experiment stations in the late
'eighties, activity in the work against insects was multi-
plied in this country. From that time to the present
the increases in the state and government appropria-
tions have been rapid. Capable young men have
studied in the universities and colleges of agriculture in
increasing numbers until at the present time the Bureau
of Entomology of the Department of Agriculture at

OUR FIGHT AGAINST INSECTS 193

Washington has an annual budget amounting to more
than a million and a half dollars and employs a small
army of trained workers. Each state also has its corps
of entomologists. In California there is a competent
entomologist for each county of the State.

Other countries have followed, and France and Italy
particularly have shown themselves to be keenly alive
to the importance of this work. Although the entomo-
logical problems of the British Isles are comparatively
less exacting than in the United States, Great Britain is
developing many competent workers in her vast colo-
nial possessions in many of which conditions are much
like those in the United States. In London there is an
Imperial Bureau of Entomology which is in constant
touch with the official entomologists of the different
dominions and colonies and assists them in many im-
portant ways.

While it must seem to many people that insects are
more abundant and more injurious now than ever be-
fore, a large part of this opinion is due to our better
appreciation of conditions and to the fact that as the
population increases and the competition for existence
grows keener the losses brought about by the insects
are sooner noticed and more grievously realized. The
entomologist, when attacking an insect problem, first
attempts to learn all he can about the intimate life
history of the destructive species which engages his
attention. This is usually slow work and is usually
prosecuted while the entomologist at the same time is
learning the efficacy of spraying. Indeed, spraying is
practical both with and without knowledge of its effects.

194 SCIENCE REMAKING THE WORLD

In other cases the cultural practices are changed in
efforts to affect the life of injurious insects. Or, as in
the case of the California white scale and the Australian
ladybird, the entomologist attempts to use the natural
enemies of insects in his warfare.

The importation of the Australian ladybird into
California in the late 'eighties to kill off the white scale
which threatened the extinction of the orange and lemon
growing industries was a great accomplishment in itself
and saved the country many millions of dollars. It is
of especial significance, however, in that it pointed out
the possibility of the utilization of the natural enemies
of destructive insects, particularly those accidentally
imported from one country into another, in such a way
that it has been followed with other successes in this
country and elsewhere.

We need only refer to the gipsy moth and the brown*
tail moth to realize the importance of these kinds of
investigation cited above. It has been possible to re-
tard the spread of the gipsy moth for many years and
practically to confine it to New England largely by the
development of spraying methods which render possible
the spraying of large forested areas. During a number
of years parasites of different kinds were imported from
all parts of Europe and from Japan. Several species
of these parasites have become established in this coun-
try, and it is due largely to their work that the brown-
tail moth has become greatly reduced in number and
that the area over which it had spread has become
greatly restricted. And it is also due to these parasites,
at least in part, that in the Boston metropolitan dis-

OUR FIGHT AGAINST INSECTS 195

trict and in other New England towns the gipsy moth
has been so reduced in numbers that it is rather rarely
to be seen. Moreover, the long and careful study of
the gipsy moth has shown that with a certain kind of
forest management its destructive work can largely
be avoided; that is, by the gradual elimination of its
preferred food plants, such as oak, from the mixed
forests.

With the cotton boll-weevil, a species which is at the
present time much in the public eye, the parasite
method of control has been unsuccessful. Where the
weevil has occupied a territory for some years, some
of the native parasites of allied weevils have attacked it
but never in competent numbers. The early studies of
the life history and habits of the weevil which were made
in Texas in the early part of the century soon indicated
means by which the damage could be greatly lessened
by certain farming methods, notably early planting,
pushing the crop, picking it early, and destroying the old
plants at as early a date as possible. These recommen-
dations were repeatedly made, but the southern planters
as a rule did not adopt them, and the weevil spread year
after year until now practically the whole cotton belt
is infested. In the meantime, however, a method of
control has been found, in the way of dusting with
calcium arsenate, which can be used with profit on good
land, and another method has recently been announced
by the Florida State Plant Board by which cotton can
profitably be grown on poor land in that State, the
Florida method being cheaper than the one just men-
tioned. The dusting process will be made simpler and

196 SCIENCE REMAKING THE WORLD

cheaper as time goes on, and there is a good chance that
the airplane may be used in community dusting to great
advantage.

The ravages of the pine bark-beetles in the far north-
western forests in past years have caused enormous
loss. Some people have said that this loss has been as
great as that from forest fires. These beetles have been
carefully studied from all points of view by Dr. A. D.
Hopkins and his associates, and it has resulted that
when an epidemic of these beetles has gained a start it
is now possible, by felling only a certain percentage of
the infested trees, to arrest the plague, while the ex-
pense of the operation is largely borne by the value of
the felled trees. This, however, has to be done at a
certain time of the year, namely in the month of April,
and the trees must be marked by trained scouts who
explore the forests during the previous autumn and
winter. A clean-up of this kind has just been made in
southern Oregon and northern California by coopera-
tive work of the Interior Department, the Forest Ser-
vice, the Bureau of Entomology, and private owners,
the operations being directed by a trained entomolo-
gist.

At the present time more than 140 distinct projects
are being investigated by the federal bureau, and these
projects involve possibly five hundred of the species of
insects most injurious to crops, domestic animals,
stored foods, forest products, shade trees, and ornamen-
tal plants. It is safe to say that some form of remedial
treatment has been found for almost every markedly
injurious insect in the United States; but continued

OUR FIGHT AGAINST INSECTS 197

efforts are being made to find something more effective,
or cheaper or simpler.

In addition to the large projects mentioned in pre-
ceding paragraphs, many striking things have been ac-
complished. The pear thrips, which at one time threat-
ened the extinction of the fruit industry on the Pacific
coast, is no longer feared; two serious pests of the clover
seed crop can now be handled by slight variations in
the cropping methods; sprays and spraying machinery
have been developed which can be used successfully
against practically all leaf-feeding species; the fumiga-
tion of nursery stock and of warehouses has been per-
fected; such injurious species as the onion thrips, the
grape-berry moth, the alfalfa weevil, the tobacco horn
worm, and many others of recent prominence can now
be controlled.

The two outstanding problems at present before the
country are the control of the European corn-borer,
which at present exists in portions of New England,
New York, and Ohio, and of the Japanese beetle which
is at present confined to an area in New Jersey and
Pennsylvania. Both of these insects bid fair to extend
their range greatly and to damage the corn crop and,
in the case of the Japanese beetle, to damage the or-
chards to an extent which cannot be predicted but
which promises enormous loss. Pending the develop-
ment of more satisfactory means of control, efforts are
being made to prevent these insects from rapid spread.

The fight calls for many more trained entomologists
and the expenditure of much larger sums than are at
present available.

198 SCIENCE REMAKING THE WORLD

GUIDE TO FURTHER READING

"Agricultural Entomology," by Herbert Osborn. Lea & Febiger.
Philadelphia, 1916.

"Entomology with Special Reference to its Ecological Aspects,**
by J. W. Folsom. Third revised edition. P. Blakiston's Son & Co.
Philadelphia, 1922.

"Injurious Insects," by W. C. O*Kane. The Macmillan Co.
New York, 1912.

"Insect Pests of Farm, Garden, and Orchard," by E. D. Sander-
son. Second edition, revised and enlarged. John Wiley & Sons.
New York, 1921.

"Practical Information on the Scolytid Beetles of North American
Forests. I. Barkbeetles of the Genus Dendroctonus," by A. D.
Hopkins. U. S. Department of Agriculture Bureau of Entomology
Bulletin No. 83, Part I. Washington, Government Printing Office,
1909.

"The Importation into the United States of the Parasites of the
Gipsy Moth and the Brown-Tail Moth; A Report of Progress,
with some Consideration of Previous and Concurrent Efforts of
This Kind," by L. O. Howard and W. F. Fiske. U. S. Department
of Agriculture Bureau of Entomology Bulletin No. 91. Washington,
Government Printing Office, 1911.

"The Plum Curculio," by A. L. Quaintance and E. L. Jenne.
U. S. Department of Agriculture Bureau of Entomology Bulletin
No. 103. Washington, Government Printing Office, 1912.

"Mexican Cotton-Boll Weevil," by W. D. Hunter and W. D.
Pierce. Senate Document No. 305, 62d Congress, 2d Session.
Washington, Government Printing Office, 1912.

"Life History of the Codling Moth in the Grand Valley of
Colorado," by E. H. Siegler and H. K. Plank, in cooperation with
the Colorado Agricultural Experiment Station. U. S. Department
of Agriculture Bulletin No. 932. Washington, Government Print-
ing Office, 1921.

"Information for Fruit Growers about Insecticides, Spraying
Apparatus, and Important Insect Pests," by A. L. Quaintance and
E. H. Siegler. U. S. Department of Agriculture Farmers' Bulletin
No. 908. Revised reprint. Washington, Government Printing
Office, 1920.

INSECT SOCIOLOGY
BY VERNON KELLOGG, PH.D.

Secretary of National Research Council, Washington, D. C.

WHAT may be called our personal relations to
each other, resulting in various degrees and
types of social organization, constitute a sub-
ject of particular interest to the students of man and
his life. If insects could see each other as we see our-
selves— maybe they can — the students among them
would also have a lively interest in their own personal
relationships. These insect relationships may even
have some special interest to us, because they attain
a peculiarly high degree of specialization, perhaps be-
cause there are so many more kinds of insects than
there are of any other kind of animals — indeed, than
there are of all other kinds of animals put together.

Because of these many insect kinds there is an espe-
cially keen competition and struggle for existence among
them, and all kinds of adaptations and shifts for a living
are carried to extremes. Social organization is but an
adaptation for successful living. So the study of insect
sociology is but a study of a biological phenomenon.
Thar is also true, fundamentally, of human sociology.

I here are individualists among insect kinds, insects
that set up no special relations with other kinds except
those of general competition for food and a place in the

100

200 SCIENCE REMAKING THE WORLD

sun, and whose individuals have no special social re-«
lations with other individuals of the same kind. The
butterflies are good examples of these individualistic
insects. Their specialized associations are more with
the flowers than with other insects even of their same
kind. However, there are a few species of gregarious
butterflies whose individuals come together occasionally
in large swarms for some reason not well understood.
The familiar large reddish-brown monarch or milkweed
butterfly (anosia archippus) is such a gregarious butter-
fly. I have seen tall Monterey Pine trees on Point
Pinos near Monterey, California, simply covered by
thousands of these conspicuous butterflies, hanging to
the branches and to each other in long festoons. This
butterfly species has, too, the habit of migrating
occasionally in immense swarms.

SOCIAL BEES. — Such gregariousness is exhibited also
by certain mining bees which sometimes make their
nest-burrows, a single burrow for each mother bee, in
large numbers close together in some clay bank. Other
kinds of mining bees carry this nesting association a
step farther, in that several mother bees will combine to
dig a common vertical burrow and then each will build
a short side tunnel branching oflF from the common en-
trance tunnel for its own eggs and the stored food for
the larva which are to hatch from them later.

The next step in this progress of the bees toward a
jsocial life, at least a family social life, is shown by the
bumble-bees. With all the bumble-bee species a few
fertilized fertile females or "queens," produced in the
autumn, go over the winter in concealment under

INSECT SOCIOLOGY 201

stones or in other convenient hiding places, and come
out in the spring, each to found then a family colony or
community. Finding a deserted field-mouse's nest or
some natural small hole or crevice in the ground, the
queen brings to it a small mass of flower pollen and
nectar and lays a few eggs on this food mass. As the
eggs hatch the issuing grubs (larvae) begin eating the
stored food and do this in such a way as to form for each
a little irregular cell, in which, when finished with their
feeding, they pupate and from which they finally issue
as full-fledged worker (infertile female) bumble-bees.

These workers now bring more mixed pollen and
nectar, the queen lays more eggs from which new
workers are produced, and this process continues
through the summer until there is a large colony (or
family) of bees. In the autumn some males and fe-
males are produced, which fly out and find mates, the
old queen and workers die, and the mated females
(now "queens") hide themselves to pass over the
winter and come out in the next spring to found new
family communities.

This is the way also in which the social wasps, the
hornets and yellowjackets, found their family communi-
which live in large wood-pulp paper nests in the
ground or hanging from branches or the eaves of houses
and out-buildings. Each queen wasp, coming out
from her winter hiding place, makes a little paper
"queen nest," composed of a few interior cells enclosed
in one or two layers of wood-pulp paper which she makes
by biting off and chewing up bits of old wood. In the
ceils of this queen nest eggs are laid by the queen from

202 SCIENCE REMAKING THE WORLD

which soon hatch wasp grubs that are fed by her with
chewed-up insects until the grubs pupate. After a few
days they issue as worker wasps (infertile females),
which immediately enlarge the nest, and make more
cells in which the queen lays more eggs. The grubs
hatching from these eggs are fed by the workers, and by
repeating this performance the family grows by the end
of the summer into a community of many hundreds of
active wasps. But in the autumn, after males and
females have been produced to mate and provide fertil-
ized females (queens) to start new families in the next
spring, the old queen and workers die and the com-
munity breaks up.

The honey-bees take a great step forward, for their
communities do not regularly break up each year, but
go on continuously for an indefinite period occasionally
budding off new communities ("swarming")- Each
community, too, may, and in the course of time al-
ways does, contain individuals produced by different
queens, for whenever new queens are produced, which
happens each year, it is sometimes the old queen that
goes out with the swarm, leaving the new queen to
produce new individuals in the hive.

There is, too, in the honey-bee community much more
differentiation as regards the work done in the com-
munal home than in the social wasp and bumble-bee
communities, and this work is much more varied in
character. At any given time in the honey-bee com-
munity some workers will be acting as nurses for the
larval bees, some as pollen and nectar gatherers, some
as wax-makers and comb-builders, some as cleaners,

INSECT SOCIOLOGY 203

some as ventilators, and some as guards at the en-
trance of the hive. The queen, on the other hand, never
does any work at all except to lay eggs. The drones
simply act as consorts for the queens. The founding
of a new community by the swarming away of a new
(or the old) queen with several thousand workers is very
different from the establishing of new wasp or bumble-
bee communities, in which an unaided queen does all
the work necessary to get the community started,
making a beginning nest herself and caring for the first
brood of young.

There are two other kinds of communal insects,
namely the termites, or "white ants/* with a number of
different species mostly limited to the tropics and semi-
tropics, and the true ants, with a great many species,
occurring abundantly all over the world. The true ants
have often been called the most successful and, because
of their high structural and economic specialization,
the "highest" insects. Both the termites and the ants
have more different "castes," or kinds of individuals,
belonging to a species than the social wasps and bees,
which have only three castes, that is, males (drones)
fertile females (queens) and infertile females (workers).

The termites have usually two and sometimes three
kinds of workers, namely, minim and major woikers
and soldiers, and they have, besides, both "comple-
mentary" or reserve males and females in addition to
the regular males and queens. These complementary
forms can replace the regular males and queens in cases
of emergency.

The true ants also have varying numbers of castes and

204 SCIENCE REMAKING THE WORLD

exhibit an extraordinary degree of variety and special-
ization in economic organization. Some kinds are
agriculturalists, and collect and store up seeds, some
are hunters and marauders and travel about in large
armies, some make slaves of other ants, some care for
plant lice and scale-insects, which secrete honey dew —
a favourite food of the ants — not only to the extent of
protecting these helpless "ant cattle" from predaceous
insect enemies but even to the extent of taking care of
their eggs and putting the newly hatched young on
proper plants for their nourishment.

There is a well-known little brown ant common in
the cornfields of the Mississippi Valley which collects
the eggs of the corn-root plant-louse, laid in the autumn
in the soil, carries them into its nests and protects
them through the winter. In the spring these plant-
louse eggs hatch before the corn has been planted and
there are no corn roots yet for the plant-lice to feed on,
so the ants place the delicate little plant-louse babies
on the roots of an early weed, called pigeon grass, that
grows in the cornfields. Then when the corn is planted
and the corn roots are developed the ants carry the
plant-lice from the pigeon-grass roots to the corn
roots.

Why this interest on the part of the ants in the plant-
lice? Because the plant-lice secrete, while they are
sucking sap from the corn roots, a plentiful supply of
that honey dew which is so favourite a food of the ants.
Thus through this interesting social relation between
the ants and the plant-lice, these latter get protected
and cared for and the former get a welcome supply of

INSECT SOCIOLOGY 205

food. This is an excellent example of what the natural-
ists call helpful symbiosis, meaning the living together
of two different kinds of animals (or plants, or of animals
and plants) to the mutual advantage of both kinds.

There are many examples of this symbiotic associa-
tion that are well-known tomaturalists. Various species
of hermit crabs always have a growth of hydroid
polyps on the front upper part of the shell which serves
them as a movable house. If these polyp colonies are
removed the crabs do not rest until they have found
other colonies which they dislodge from the rocks to
which they are attached and plant on their shells. By
this arrangement the polyps, ordinarily fixed in one
place, are carried about by the crabs and in this way
are aided in finding food. They probably get some of
this food by seizing loose bits of the small animals
seized and torn up by the crabs in their own feeding.
The crabs, for their part, gain a certain protection from
enemies by the presence of the polyps which have
stinging tentacles that dangle down over the head of the
crab, that make things uncomfortable for any moving
sea animals looking for crab-meat.

Among the coral reefs of the South Seas there lives
an enormous kind of sea anemone or polyp. Indivi-
duals of this great polyp measure two feet across the
d*sk when fully expanded. In the interior, or stomach
cavity, which communicates freely with the outside by
means of the large mouth opening at the free end of the
polyp, there may often be found a small fish (Amphi-
prion percula). That this fish is purposely in the gas-
tral cavity of the polyp is proved by the fact that when

206 SCIENCE REMAKING THE WORLD

it is dislodged it invariably returns to its singular
lodging place. The fish is brightly coloured, being of
a brilliant vermilion hue with three broad white cross-
bands. The discoverer of this pe-
culiar habit suggests that there
are mutual benefits to fish and
polyp from this habit. The fish,
being conspicuous, is liable to at-
tacks, which it escapes by a rapid
retreat into the sea anemone; its
enemies in hot pursuit blunder
against the outspread tentacles of
the anemone and are at once nar-
cotized by the "thread cells" shot
out in innumerable
showers from the ten-
tacles, and afterward
drawn into the stom-
ach of the anemone
and digested.

There are more
than one thousand
species of insects, in-
cluding various cock-
roaches, beetles, flies,
etc., that live in
ants' nests in various kinds and degrees of symbiotic
association with their ant hosts. In some cases this
symbiosis takes on a very highly specialized form.
For example Wheeler (the foremost student of ants and
an entirely reliable observer) has worked out the follow

Underground nest of the
bumblebee

INSECT SOCIOLOGY 207

ing extraordinary symbiotic relation between the red-
brown ant, Myrmica brevinodes, and the smaller Lepto-
thorax emersoni. The little Leptothorax ants live in the
Myrmica nests, building one or more chambers with en-
trances from the Myrmica galleries, so narrow that the
large Myrmicas cannot get through them. When need-
ing food the Leptothorax workers come into the Myr-
mica galleries and chambers and, climbing on the backs
of the Myrmica workers, proceed to lick the face and
the back of the head of each host. A Myrmica thus
treated, says Wheeler,

paused, as if spellbound by this shampooing and occasionally folded
its antennae as if in sensuous enjoyment. The Lfptothorax after
licking the Myrmica s pate, moved its head round to the side and
began to lick the cheeks, mandibles, and labium of the Myrmica.
Such ardent osculation was not bestowed in vain, for a minute drop
of liquid — evidently some of the recently imbibed sugar-water —
appeared on the Myrmica s lower lip and was promptly lapped up
by the Leptothorax. The latter then dismounted, ran to another
Myrmica, climbed on its back, and repeated the very same perform-
ance. Again it took toll and passed on to still another Myrmica.
On looking about in the nest I observed that nearly all the Lepto-
thorax workers were similarly employed.

Wheeler believes that the Leptothorax get food only in
this way. They feed their queen and larvae by regurgi-
tation. The Myrmicas seem not to resent at all the
presence of their Leptothorax guests, and indeed may
derive some benefit from the constant cleansing licking
of their bodies by the shampooers. But the Lfpto-
thorax workers are careful to keep their queen and young
in a separate chamber, not accessible to their hosts.
This is probably the part of wisdom, as the thoughtless

208 SCIENCE REMAKING THE WORLD

habit of eating any conveniently accessible pupae of
another species is widespread among ants.

Finally there is another widespread type of social re-
lationship in the life of insects, and that is the relation-
ship of parasite to host, or parasitism. Thousands of
insect kinds live exclusively as parasites on other in-
sects, and in many cases a very high degree of specializa-
tion in this relation has been developed. One of the
most familiar forms of this relation is shown by the
many various ichneumon flies which lay their eggs on
or in the bodies of the caterpillars (larvae) of various
moths and butterflies. When the ichneumon grubs
hatch from these eggs they burrow about in the body
of the caterpillar, feeding on its tissues but avoiding
till the last the tissues and organs especially necessary
for the life of the caterpillar. So the caterpillar moves
about, feeding on the leaves of its food plant, while the
ichneumon grubs grow and develop inside of it. By
the time these grubs are full grown the caterpillar dies
or may just be able to change into a chrysalid, from
which issues, however, not a butterfly or moth but a
number of ichneumon flies.

It is undoubtedly true that the most effective checks
against the too terrible increase in numbers of various
serious insect pests of our orchard and field crops are
their natural insect parasites. A considerable number
of our worst insect pests have come to this country by
one means or another from other countries, and in many
of these cases they have come unaccompanied by their
parasites. Under these circumstances the insect pest
has been able to increase so rapidly in this country as

INSECT SOCIOLOGY

209

to threaten to wipe out some important American wild
or domesticated food plant or flower. In several such
cases entomologists have visited the native country of
the insect pest, found its natural parasites and brought
them to this country, where they have been released
among their hosts and have soon increased to such
numbers as to be a remedy for the pest.

Thus we find among insects brilliant examples of a
number of phases of social relationships which are

Honey-ants about three times natural size, taken from ground about the
roots of pine trees

familiar to us in human life. These relationships are
accompanied, in the insects, by a good deal of struc-
tural modification of individuals for the sake of accom-
plishing special functions which is a phenomenon that
occurs in but slight degree among human beings.
We devise and use different tools and machines to equip
different individuals for different kinds of work. But
the results are similar in the two groups.

Some of the phases of insect sociology have been
developed and specialized far beyond the condition
attained in human life. The communal life of the

210 SCIENCE REMAKING THE WORLD

honey-bee, for example, goes to an extreme hardly
dreamed of yet by man as possible to him. If he did
dream of it, it would be a bad dream. The worker
honey-bees literally kill themselves working for the
community. The summer foragers fly back and forth
between hive and the flowers from which they bring
pollen and nectar until they can fly no more. They
often fall dead with their loads at the very entrance to
the hive. They have no children of their own; the
royal mother produces all the children; they take care
of them. The males do nothing but act as royal con-
sorts in the summer and then they die or are killed by
the workers, as useless individuals, when winter comes
on. The queen never works. She simply lays eggs.
And so on. Not a kind of social organization we want,
but a successful one, biologically.

The insects go in strongly for parasitism, also a bio-
logically successful way of making a living. But we try
to discourage it in human society. Some of the ants
do nothing but fight and rob. They have even given
up caring for their own young. They enslave other
ants to act as nurses and to collect food for the whole
community. Other ants convert some of their com-
munity members into living honey-jars, which stuff
themselves with honey until their stomachs are so full
and their bodies so swollen that they can hardly move
and simply lie in a gallery or room in the ant nest ready
to give up some of their honey by regurgitation to the
active workers who come and tap them with their
antennae.

Insect sociology is interesting, but most of its teach-

INSECT SOCIOLOGY 211

ing to us is that, however successful biologically it may
be for insects, it is not the kind of sociology we want for
ourselves. Differentiation of labour and specialization
of social relationships may be advisable for us up to a
certain point; beyond that they are highly inadvisable.
Let us not too literally follow the familiar injunction
which instructs us to learn from the ant. To imitate
his industry cannot lead us wrong; to imitate his ex-
treme communism would be to make depersonalized
and de-individualized automatons out of us.

GUIDE TO FURTHER READING

"American Insects," by Vernon Kellogg. (Henry Holt & Co.)
Second edition 1908. A comprehensive account of the insects of
North America with classification, structure, general habits, and
special adaptations.

"Ants, Their Structure, Development, and Behaviour," by
William Morton Wheeler. (Lemcke.) 1910. The best book yet
published about ants.

"The Life of the Bee," by Maurice Maeterlinck. (Dodd, Mead
& Co., New York.) 1902. A poetical but fairly accurate account
of the life of honey-bees.

" Social Life in he Insect World," by J. H. Fabre. (Century Co.,
New York.) 1912. This, together with other books by Fabre about
insect life, are full of interesting observations and are delightfully
written.

"The Psychic Life of Insects," by E. L. Bouvier (trans, by L. O.
Howard). (Century Co.) 1922. A keenly analytk account of in-
•ect instincts.

HOW THE FORESTS FEED THE CLOUDS
BY RAPHAEL ZON, F. E.

Forest Economist, United States Forest Service

KR a long time it has been accepted without any
icstion that all the vapour that is condensed
... the form of rain or snow over the land surface
is furnished by the evaporation of water from the
oceans. The part which vapour from the ocean plays
in the precipitation over the land has been greatly exag-
gerated. A noted European meteorologist, Professor
Bruckner, has computed the amount of water evapo-
rated from the ocean surface and the land surface, and
the amount of water which is returned to the ocean and
the land in the form of precipitation. The balance
sheet of the circulation of water on the earth's surface
is shown in the accompanying illustration. The regions
tributary to oceans are capable of supplying seven
ninths of the precipitation by evaporation from their
own areas. The moisture which is carried by the winds
into the interior of vast continents, coming thousands of
miles from the oceans, is almost exclusively due to con-
tinental vapours and not to evaporation from the ocean.
Bruckner's figures for the entire earth's surface are
corroborated also by study of specific drainage areas.
The most interesting study in this direction is that by
Professors Francis N. Nipher and George A. Lindsay on

212

HOW FORESTS FEED CLOUDS 213

the rainfall of the State of Missouri and the discharge
of the Mississippi River at St. Louis, Mo., and Car-
rollton, La.*

FOREST THE GREATEST EVAPORATOR OF WATER. —
What are the sources from which the evaporation on
land is the greatest? The evaporation from a moist
bare soil is on the whole greater than from a water sur-
face, especially during the warm season of the year when
the surface of the soil is heated. A soil with a living
vegetative cover loses moisture, both through direct
evaporation and through absorption by its vegetation,
much faster than bare, moist soil and still more than
free water surface. The more developed the vegetative
cover, the faster is moisture extracted from the soil and
given off into the air. The forest in this respect is the
greatest desiccator of water in the ground. Numerous
experiments in Europe in the level and slightly hilly
forest regions have shown that the forest, on account
of its excessive transpiration, consumes more moisture,
all other conditions being equal, than a similar area
bare of vegetation or covered with some herbaceous
vegetation. The amount of water consumed by forests
is nearly equal to the total annual precipitation. In
cold and humid regions it is somewhat below this
amount and in warm and dry regions it is above it.
The ground water table under forests was found in-
variably to be lower than in the adjoining open fields.

*Francis E. Nipher: "Report on Missouri Rainfall, with Averages for
Ten Years ending December, 1887." Transactions of the Academy of Science
of St. Louis, Vol. V, p. 383. Geo. A. Lindsay: "The Annual Rainfall and
Temperature of the United States." Transactions of the Academy of Scienct
oj St. Louis, June, 1912.

214 SCIENCE REMAKING THE WORLD

This enormous amount of moisture given off into the
air by the forest, which may be compared to clouds of
exhaust steam thrown into the atmosphere, must play
an important part in the economy of nature and de-
servedly earns for the forests the name of the "oceans
of the continent."

WIND PERIODICITY AND PRECIPITATION. — In the
eastern part of the North American continent east of
the looth meridian the winds during the winter and
partly in the fall and in the early spring come from the
west and northwest. These prevailing winds bring
cold and comparatively dry air from the interior of the
continent. In summer the prevailing winds are from
the southeast in Texas, and farther north and east they
come from the south and southwest. There is a most
intimate relation between the prevailing southerly
winds and precipitation in the eastern half of the
United States. It is during the summer period, when
the entire eastern half of the United States is under
the influence of the southerly winds, that most of the
precipitation falls over it. On the plains east of the
Rocky Mountains the summer rainfall forms from three
fourths to four fifths of that of the entire year. In
winter, with the change in the direction of the wind,
there is a radical change in precipitation.

The periodicity of the wind direction and its relation
to precipitation over the eastern half of the United
States is well illustrated on the two maps. The arrows
indicate the direction of the prevailing winds, and the
lines and figures show the mean precipitation for the
months of July and January. The map for the month

HOW FORESTS FEED CLOUDS 215

of July is typical for the summer period and the one for
the month of January is typical for the winter period.
The data represent more than twenty years of continu-
ous records.

THE SIGNIFICANCE OF THE FACTS. — The three facts
just discussed, namely, that vegetation from land con-
tributes more to the precipitation over land than
evaporation from the ocean, that forests evaporate
more water than free water surface or any other vege-
tation, and that transpiration of the eastern half of the
United States is intimately connected with the pre-
vailing south wind, throw an entirely new light on the
relationship between the forests of the coastal plain and
the Southern Appalachians and the humidity of the
central states and the prairie region.

The central portion of the United States is distinctly
a continental region, particularly the prairie region,
which suffers from lack of precipitation. On the other
hand, large areas in the south and southeast because
of large swamps, suffer from too much humidity, which
is caused not only by excessive precipitation but
also by deficient evaporation. We have, therefore,
two extremes in the eastern half of the United States:
(i) in the states adjoining the Atlantic Ocean and the
Gulf of Mexico, there is an excess of moisture on the
ground, both on account of excessive precipitation and
slight evaporation; (2) in the vast interior of the Central
United States, on the other hand, there is a deficiency
of moisture both on account of scant precipitation and
of the intense evaporation. Is there not some con-
nection between these two extremes? Is it not possible

216 SCIENCE REMAKING THE WORLD

that changes which take place in one part of this vast
region may exert some influence on the condition of the
other? We have seen that in the central states in
summer the prevailing westerly and northwesterly
winds give way to southerly and southeasterly winds.
In other words, in the summer the central states are
under the influence of moist winds just at the time when

PRECIPITATION SHOWN BY
-LINL5AND riGURE15
WIND SHOWN BY ARROWS

- WIND DIRECTION AND MCAN PRE.CIPJTATION FOR THE MONTH OF JANUARY

the evaporation is the greatest and the forest vegetation
is especially active. It seems, therefore, that the
amount of moisture evaporated within the more moist
region of the United States can influence the conditions
of humidity, not only in the states close to the ocean,
but also in the region into which the prevailing moist
winds flow. The more moisture there is evaporated
from the ground in the southern and southeastern

HOW FORESTS FEED CLOUDS

217

portions of the United States, the moister must be the
air in the central states and the more precipitation
must fall there.

The central interior region of the United States is
the battleground of two titanic forces, of which one is
harmful and the other beneficial. The beneficial force
takes its origin in the Gulf of Mexico and the adjoining

PRECIPITATION SHOWN BY

LINES AND riGURW
WIND StlOWN 6Y ARROWS

WIND DIRECTION AND MEAN PRECIPITATION TOR THE MONTH OFJULY

ocean, the harmful in the interior of the contintent and
the Rocky Mountain region. The central states and
the prairie region are geographically at the point where
the battle between the two forces is fiercest and the
victory is now on the one side and now on the other,
being dependent on the cold and humid and the warm
and dry climatic cycles as well as upon the seasons of the
year. When the humid southerly winds extend their

218 SCIENCE REMAKING THE WORLD

influence far into the interior of the country and over*
power the dry continental winds, the central states
and prairie region, the granary of the United States,
produce large crops. When the dry winds overpower
the humid southerly winds there are drouths and crop
failures.

The southerly winds on their way from the Gulf of
Mexico do not meet any mechanical obstacles. Since
the Appalachian Mountains, running in a northeasterly
and southwesterly direction, do not hamper their pas-
sage, they are capable of penetrating far into the in-
terior of the country and, therefore, determine the
amount of precipitation even in such states as Min-
nesota, Nebraska, North Dakota, and South Dakota.
The moisture-laden winds from the Gulf, as soon as
they reach the land and encounter irregularities, are
cooled and begin to lose part of their moisture in the
form of precipitation. As long as the air currents are
saturated with moisture the slightest cooling or ir-
regularity of the land that causes them to rise will cause
precipitation. But as they move inland and become
drier, the remaining moisture is given off with difficulty
and precipitation decreases. The sooner the humid
air currents in the passage over land are drained of the
moisture, the shorter is the distance from the ocean
over which abundant precipitation falls; the longer the
moisture is retained in the air currents, the farther into
the interior will it be carried and the larger will be the
area over which precipitation will be distributed.

If precipitation over land depended only on the
amount of water directly brought by the prevailing

HOW FORESTS FEED CLOUDS 219

humid winds from the ocean, the land would be pretty
arid and the rainfall would be confined to only a narrow
belt close to the ocean. Fortunately, not all the water
that is precipitated is lost from the air currents; a part
runs off into the rivers or percolates into the ground,
but a large part of it is again evaporated into the
atmosphere. The moisture-laden currents, therefore,

gggjiwr CIRCULATION OF WATER ON EARTH'S SURFACE

"MMFAa CUBIC MILES OF WATER

PRECIPITATION OVER OCEAN*

86.000

EVAPORATION FROM LAND DRAINING TOWARD OCEANS

2/000 (++.0/S.+OO SQ.M/LfS)

BIBI^7E£:iptTATION OVER LAND DRAIN ING TOWARD OCEANS
27OOO

I EVAPORATION FROM CLOSED BASINS

(//.583.000 SQ.

/3o\ PRECIPITATION OVER CLOSED BASINS

upon entering land, at first lose the moisture which they
obtain directly from the ocean, but in their farther
movement into the interior they absorb the evaporation
from the land. Hence, the farther from the ocean, the
greater is the part of the air moisture contributed by
evaporation from the land. At a certain distance from
the ocean practically all of the moisture of the air must
consist of moisture obtained by evaporation from the
land. At least it must form a larger part than the water
which was obtained directly by evaporation from the
oceans.

220 SCIENCE REMAKING THE WORLD

The vapour brought by the prevailing winds from the
ocean is many times turned over or reinvested before it
is returned again to the ocean through the rivers. If
we could reduce the surface run-off, and at its expense
increase the evaporation from the land, we would
thereby increase the moisture in the passing air currents
and in this way contribute to the precipitation of that
region into which the prevailing winds blow. This
conclusion is almost axiomatic.

If the southerly and southeasterly winds in their
passage toward the north, northwest, and northeast, in
the spring and summer, did not encounter the vast
forest areas bordering the shores of the Gulf of Mexico
and the Atlantic Coast and those of the Southern
Appalachian region and, therefore, were not enriched
with enormous quantities of moisture given off by
them, the precipitation in the central states and the
prairie region would undoubtedly be much smaller
than it is now.

If the present area occupied by forest in the Atlantic
plain and the Appalachian region were instead occupied
by a large body of water, no meteorologist would hesi-
tate for a moment to admit that this water surface
would have a perceptible influence upon the humidity
of the central states and prairie region. Should not,
therefore, the forests which give off into the atmosphere
much larger quantities of moisture than free water sur-
face have at least a similar influence upon the regions
into which the prevailing air currents flow?

Direct proof of this climatic influence quantitatively
expressed is still lacking. It will take many decades

HOW FORESTS FEED CLOUDS 221

before direct observations of such a character will be
secured. If, however, the premises upon which the
discussion rests — namely, that precipitation of the
eastern half of the United States is intimately connected
with the prevailing south winds, that evaporation from
land contributes more to the precipitation over land
than evaporation from the ocean, that forests evaporate
more water than free water surface or any other vege-
tation— are correct, then forests in the path of pre-
vailing winds must necessarily act as the distributors of
precipitation over wide continents.

The moisture given off by the forests into the air is
formed into clouds. These are carried by the prevailing
southerly winds in the summer far into the interior of
the country. There they settle as rain and enrich with
moisture the fertile-agricultural lands. The central
and prairie region — the granary of the United States
• — depends to a large extent for its rains on the moisture
supplied by the forests of the southern and south-
eastern States.

GUIDE TO FURTHER READING

"Forests and Water in the Light of Scientific Investigation," by
Raphael Zon. Appendix V of the Final Report of the National
Waterways Commission, Senate Document 469, Sixty-second
Congress, Second Session. A non-technical summary of the en-
tire subject of the relation of forests and waters.

"What the National Forests Mean to the Water User," by S. T.
Dana, U. S. Department of Agriculture. A popular presentation of
the dependence of the water supply in the West on the National
Forests.

"Primer of Forestry." Farmers' Bulletins 173 and 358, U. S.
Department of Agriculture. A popular discussion of the entire

222 SCIENCE REMAKING THE WORLD

field of forestry. The statistical material is somewhat out of date.

"Timber — Mine, or Crop?" 1922 Yearbook article. A compre-
hensive, non-technical presentation of the importance of growing
timber as a crop treated from a national economic standpoint.

"Forests and Forestry in the United States." Report prepared
by the U. S. Forest Service for the Brazilian Exposition Commission,
1923, Forest Service, Washington, D. C. A popular statement of
the progress of forestry in the United States, with special reference
ftO the National Forests.

THE MODERN POTATO PROBLEM
BY CHARLES O. APPLEMAN, PH. D.

Dean of the Graduate School and Professor of Plant Physiology.
University of Maryland

THE potato crop ranks next to the cereals as a
food crop in the United States. It ranks third
in the number of calories that can be grown on
an acre of land, corn ranking first and sweet potatoes
second. The average per capita annual consumption
of potatoes for the past several years is 3.5 to 4 bushels.
The 1922 acreage was more than 4,000,000 and the
production nearly 400,000,000 bushels, or an average of
about loo bushels per acre. These are still far below
the possibilities and are greatly exceeded in some other
countries. Much scientific effort and education have
been necessary to maintain even our present production
and quality. The purpose of modern study of the
potato is not only a greater average production per
acre, but also a product of higher grade and quality
that can be kept in good condition for consumption
through the greater part of the year. Many years of
investigation on some of the older and simpler problems
have yielded such conclusive results that they are now
simply awaiting more general application in practice.
New potato problems are constantly arising. They
are v«ry diverse in character and their study is demand-

224 SCIENCE REMAKING THE WORLD

ing the combined efforts of many scientific specialists.
What are a few of these problems and how are they
being studied ?

THE REST PERIOD. — In order to insure the con-
tinued vegetative propagation of the potato plant as a
permanent inhabitant of the earth, nature has en-
dowed the tubers with a rest or dormant period, so that
the young plants will not immediately start to grow and
then be killed by the coming winter cold. This is fine
for the wild plant, but since man has tamed it and
brought it under cultivation, the operation of the rest
period does not always suit his requirements. Usually
the potato tubers will not sprout for several weeks after
they are harvested. The length of the rest period varies
with different varieties, but is fairly constant for a given
variety grown for a long time at the same place. The
cause and control of this rest period is a subject of im-
portance. Any practical means of eliminating or even
abbreviating the rest period would be very valuable in
growing a second crop in our southern states. It is
also of equal importance to know how to extend the rest
period of potatoes during storage. So far scientists
have not been able fully to unravel nature's secret of
dormancy in potatoes, but some clues have been ob-
tained. By carefully removing the skins from the
tubers and supplying them with plenty of moisture,
air, and a certain amount of warmth, the young sprouts
will start to grow in a comparatively short time. This
seems to indicate that the skins keep out something
necessary for growth or prevent the escape from the in-
side of the tuber of something holding growth back*

THE MODERN POTATO PROBLEM 225

The former may be oxygen of the air and the latter the
carbon dioxide produced by the tuber's respiration.
Other methods that have been found effective in short-
ening the rest period, such as treating the tubers with
certain gases, probably do so by rendering the skins
more permeable to oxygen or carbon dioxide. However,
this does not explain how the tubers finally come out of
their rest period without help. Nature does not remove
their jackets.

DEGENERATION OF POTATOES. — When we start with
a potato plant grown from a seed and use the tubers for
its propagation, each succeeding crop really represents
an annual growth of our original plant. This may be
made clearer by comparing the seedling potato plant
with a young apple tree. Every summer the tree
produces a large number of buds which remain dormant
until the following spring, when they give rise to a new
crop of shoots. The potato plant likewise produces
dormant buds on the tubers, which are large fleshy
underground shoots, or stems. By the annual death
of the vines the tubers are separated from the parent
plant whose life is perpetuated by the tubers. If we
imagine each succeeding crop of tubers, like the apple
shoots, becoming a permanent part of the parent plant,
we would have a giant potato plant often many years
old. Are these giant potato plants, known as varieties,
immortal, or are they subjected to old age and final
death the same as animals? At first thought this
mi^ht seem an easy question to answer, but scientists
still hold divergent views about it.

Degeneration of potatoes is a well-established fact.

226 SCIENCE REMAKING THE WORLD

Varieties are known to have progressively lost their
vigour and entirely run out in certain regions. We
know now that many cases of degeneracy are due to
slow diseases and not to old age. Symptoms that were
once attributed to senility are now recognized as
typical symptoms of "Mosaic" and other virus diseases.
An extreme view holds that a given variety would re-
main vigorous and live indefinitely if grown continu-
ously under favourable conditions. According to this
view any degeneracy of a variety not due to apparent
disease simple means that it is unable to cope with the
adversities of its environment. This is undoubtedly
often the case because varieties have been grown for
many years in some places without loss of vigour, but
gradually degenerate in another region. Potatoes for the
spring planting in the southern states are usually im-
ported from the north, as these varieties degenerate
when the seed stock is home-grown. Even in the
more northern states it is often necessary to obtain the
seed tubers of some varieties from other regions in
order to maintain the normal vigour of the crop and
certain desired characters of the tubers. Lack of
adaptation to environment can be argued against any
claims for an inherent tendency to old age in potato
varieties, so we may still ask the question, does our
giant potato plant naturally grow old ?

SEED STOCK. — Modern potato research is showing a
very decided trend toward studies of the factors in-
fluencing the vitality of the seed stock and of practical
methods for maintaining the normal vigour of the
variety. The potato plant is grown from a specialized

THE MODERN POTATO PROBLEM 227

vegetative portion of the parent plant, namely, the
tuber. Therefore, if the daughter plant is to maintain
full vigour the parent tuber, or fraction thereof, must
possess and maintain this normal vegetative vigour
until it is planted. The growing appreciation of the
importance of good vigorous seed stock true to name is
one of the most promising developments in modern
potato culture. Many factors are now known to in-
fluence in varying degrees the vitality of seed tubers,
as storage conditions, maturity, repeated sprouting,
methods of preparation of tubers for planting, physio-
logical and virus diseases, climatic conditions, where and
when seed is grown, etc. Important researches con-
cerning the vitality of seed stock have yielded infor-
mation of great value to potato culture, but there is
still need of much careful research.

The practice of seed inspection and certification is
contributing greatly toward the improvement of seed
stock. The growers of seed potatoes apply to state
officials for inspection of their crop. The inspections
are made two or three times while the crop is growing
and once after harvest. If the crop comes up to certain
standards in respect to freedom from diseases and weak
plants, as well as true to type, it is certified. The
grower pays a small fee for this service and commands a
higher price for the certified product. The grower can
afford to pay a higher price for he can then grow more
and better potatoes.

If the tubers have begun to sprout before they are
planted, as is frequently the case, the character of the
sprout growth is a rough index of seed vitality in many

228 SCIENCE REMAKING THE WORLD

varieties. Good normal tubers, as a rule, will sprout
first from the eyes on the terminal or seed end of the
tuber. These sprouts, if not destroyed, or too much
impeded in growth, will inhibit the growth of sprouts
from the basal eyes. If the first sprouts lack the nor-
mal vigour of the variety they will not prevent the
growth of sprouts from the more basal eyes, but sprouts
will be scattered over the entire tuber. This lack of
apical dominance in the first crop of sprouts is a sign of
low tuber vitality, or in other words, its inability to pro-
duce vigorous plants with the proper number of stalks.
Extreme cases of low vitality are manifested in the
spindliness of the sprouts, but in many cases the sprouts
are much below normal in growth vigour without show-
ing the characteristic spindliness. It is in the latter
case that lack of apical dominance is of service as a
guide.

A great deal of the older potato research was con-
cerned with methods of cutting the seed tubers and
with the most profitable amount of seed to plant per
acre. In regard to certain phases of this problem the
results have been so uniform and conclusive that it is
now largely a matter of education to get them more
generally adopted in practice. It is generally conceded
that no conditions will justify planting seed pieces
weighing less than 1.5 to 2 ounces. With high fertility
and cheap seed it is sometimes profitable in some locali-
ties to plant seed pieces weighing even more than 2
ounces. More recent research has shown that the
low yields from small seed pieces is traceable to weak
sprouts produced by the small pieces. After a mini-

THE MODERN POTATO PROBLEM < 229

mum size of seed piece is reached, the vigour of the
sprouts becomes progressively less as the size of the
seed piece is further reduced. This minimum size for
many varieties has been found to be about 1.5 ounces.
The cause of the weak growth of sprouts on pieces of
tuber below a minimum size is not definitely known.
There are some indications that the potato tuber con-
tains a limited amount of an accessory growth-
promoting material. This may or may not be analo-
gous to the vitamine so essential to growth in animals.
Experiments have shown that seed pieces large enough
to contain an abundance of the usual nutrients for
sprout growth still produce weak sprouts. These seed
pieces lack something in sufficient amount to start
growth off normally. The plants from these weak
sprouts are correspondingly weak and the best of cul-
tural conditions will not revive their normal vigour.
During the recent war a prominent newspaper recom-
mended the planting of peelings and saving the rest of
the tuber for consumption. Valuable land and labour
werewasted by this practice.

VARIETAL NOMENCLATURE. — The ever increasing
number of so-called varieties has made the subject of
nomenclature for potato varieties an important potato
problem. More than five hundred names are reported
for varieties that are supposed to be still grown in the
United States. Much of the present confusion in
varietal nomenclature has resulted from the propensity
of seedmen to rename old varieties and to introduce
new varieties indistinguishable from existing ones.
This chaotic condition has been greatly improved by

230 SCIENCE REMAKING THE WORLD

arranging these names into typical groups, a very im-
portant but difficult task. The public and the potato
industry should be protected by certain restrictions
governing the introduction of new potato varieties.
Encouraging efforts are being made in this direction.

POTATO IMPROVEMENT. — Variety testing has long
been a favourite type of potato investigation. The re-
sults of this enormous amount of work have been of
great local importance in discovering standard varieties
best suited to particular climate and soil conditions, but
they have been of very limited general application.
Recent years have shown a marked decrease in the
number of such investigations. Much of this effort
is now being replaced by attempts to improve our
standard varieties and to develop new varieties better
suited to local condition.

The potato can be improved by application of modern
knowledge of breeding and selection. The former
method consists in the actual crossing of two varieties
by artificially applying the pollen of one parent to the
stigma of the other. This is the only means by which
desirable characters of two parents can be combined
in the offspring. It is frequently desirable to combine,
in the offspring, immunity to disease of one parent
with high yield or better cooking quality of the other
parent, or high yield with more desirable tuber charac-
ters, as size, shape, shallow eyes, etc. Most of our
present varieties have originated as seedlings, either
by chance or artificial breeding. Unfortunately potato
breeding is fraught with many difficulties. On account
of long continued reproduction by tubers or for othe$

THE MODERN POTATO PROBLEM 231

reasons, sterility in the flowers of potatoes is the rule
rather than the exception — that is, potato seeds are
rarely produced. The cause of this phenomena is being
investigated with the view of bringing it under control
in breeding work. Another difficulty is the fact that
most varieties of potatoes are already hybrids possess-
ing latent characteristics of their wild ancestors. These
undesirable characters are liable to crop out and be-
come dominant in the seedlings, so it is necessary to
grow a large number of plants from which to select the
ones desired. The increasing prevalence of diseases is
also adding greatly to the almost insurmountable diffi-
-culties of the potato breeder. On account of difficulties
involved and the expert technique required, to say noth-
ing of the expense, potato breeding cannot be generally
practised as a method of potato improvement. How-
ever, important improvements of potato varieties have
been made by this method and the outlook is very prom-
ising for further improvements. Some attempts are
being made to breed strains that will propagate them-
selves just as well by seeds as by tubers. If this can
be accomplished, it will result in great saving in the price
of seed and in the elimination of diseases that are carried
in and on infected tubers.

. The second method intended to improve existing
varieties is by selection. The procedure is to propa-
gate from a single tuber, or from desirable hills selected
in the field. Selection methods have been extensively
used and are still practised, although it has not been
definitely proved that our existing varieties can be
much improved by these methods. The chief benefits

232 SCIENCE REMAKING THE WORLD

derived from selection methods may be due entirely to
the elimination from the seed stock of tubers produced
by degenerate or diseased plants. From this viewpoint,
hill selection must be an annual task. Bud sports
or "mutants," do occasionally appear in the tubers.
New varieties have arisen in this way, most of them
differing from the parent variety merely in a modifica-
tion of the colour of the skin or tissue and in the period
of ripening. Bud sports are not usually considered of
much importance in selection work on account of their
infrequent occurrence.

At the present time great emphasis is being placed
upon the importance of discovering strains of our
standard commercial varieties that are more vigorous
and productive than others.

SALT NUTRITION. — Different crops have different re-
quirements regarding the nutrients supplied to the
roots. All of them demand a group of essential ele-
ments, but these are utilized in different proportions by
different crops. If the soil does not already contain
these necessary elements in the proper amounts, they
must be supplied in fertilizers. The importance of
fertilizing the crop rather than the soil has led to ex-
tensive and carefully controlled experiments to dis-
cover the salt requirements peculiar to different crops.
This applies not only to the proper proportions of the
salts, but also to the kind of salts carrying the fertilizer
elements. Modern methods of salt nutrition studies
applied to the potato crop are now supplementing the
older empirical fertilizer tests and the outlook indicates
a more rational and economic fertilizer practice.

FHE MODERN POTATO PROBLEM 233

DISEASES. — Potatoes, like human beings, are subject
to serious and destructive diseases. Some of these
diseases frequently become epidemic in certain sec-
tions of the country, causing almost total loss of the
crop. The potato plant may become afflicted with
purely physiological troubles but the most destructive
diseases are parasitic in origin. As in the case of
animals, these pathogenic organisms are of several
different types. Although fungous diseases are rare
in animals they cause the largest group of potato dis-
eases. Early blight (Alternaria solani) and late blight
(Phytophthora infestans) especially the latter, head the
list of destructive fungous diseases. Both are diseases
of the foliage and stems but late blight also attacks the
tubers, causing them to rot either in the field or under
improper storage conditions. Fortunately, science has
found a specific preventive for these parasites. Spray-
ing the plants with Bordeaux mixture will check the
ravages of both diseases. In 1885 Millardet, then
professor at the University of Bordeaux, published the
first directions for preparing Bordeaux mixture, which
consisted of certain proportions of water, copper sul-
fate, and lime. This mixture has proved of inesti-
mable value in the control of some of the most destruc-
tive diseases of our food crops.

The thread-like hyphae of the fungi causing the
Fusarium and Verticillium wilts grow in the conducting
vessels of the stems and thereby prevent the passage of
water through the stems to the leaves. Wilting of the
foliage and death of the plant follow. Although the
do not cause as much damage as the unchecked

234 SCIENCE REMAKING THE WORLD

blights, they are more difficult to control. Certain
helpful measures have been found effective in check-
ing these diseases, but absolute control is yet un-
known.

One of the most dangerous of the European fungous
diseases of the white potato is the potato wart. It is a
disease of the tubers and from the standpoint of its
seriousness and some of its characteristic manifestations
it may be thought of as potato cancer, although it is
unlike true animal cancer in that it is very infectious.
In advanced stages the warty growths on the tubers may
be as large as the tuber itself. In severe cases the fun-
gous consumes nearly all of the stored food material in
the tuber, reducing it to a soft mass. Realizing the
possibility of this dread disease being introduced into
the United States, an embargo went into effect in 1912
against potatoes from countries known to harbour wart.
This legislation evidently came a little too late, for in
1918 the disease was discovered in gardens at Highland,
Pa., a hamlet in the heart of the anthracite coal dis-
trict. The alarming discovery of this malady in the
United States at once led federal and state officials to
launch an extensive campaign to discover the extent
of its occurrence in this country. So far it has been
found only in gardens, chiefly in restricted areas of the
mining districts, in Pennsylvania, West Virginia, and
Maryland. Strict quarantine has been placed on these
districts and every effort is being made to prevent its
spread. This virulent and dangerous disease has rather
suddenly become one of the modern potato problems in
this country. Immunity to disease in plants is beauti-

THE MODERN POTATO PROBLEM 235

fully demonstrated in the case of potato wart. Experi-
ments have shown that the susceptibility of the varie-
ties tested varies within wide limits. A number of
varieties were found to be absolutely immune. In-
cluded in this group are some of our leading commercial
varieties, as the Irish Cobbler and Green Mountain.
On the other hand it is unfortunate that some of our
other leading varieties are so susceptible that they
are practically destroyed when attacked by the wart
disease. The growing of immune varieties has been
found to be the only practical method of controlling
this disease in several European countries.

There is a group of filamentous micro-organisms
Occupying an intermediate position between the moulds
and the bacteria. To this group of parasites belong the
Actinomyces. Certain species of this parasite cause
serious suppurative affections in animals. Another
species is the cause of one of the most common diseases
of the potato tuber, the common scab. It is recognized
by the rough pitting of the tubers, rendering them un-
sightly and greatly depreciating their market value.
This disease is no longer a serious problem in potato
culture aside from the expense and labour involved in
its control. By careful selection and disinfection of
the seed tubers, this source of the infection may be
controlled. The most effective, as well as the cheapest,
means of controlling the organisms in the soil are still
problems that are being studied. This organism thrives
best in soils of an alkaline reaction. The addition of
sulphur to certain types of soil has recently been recom-
mended as a means of controlling scab. The oxidation

236 SCIENCE REMAKING THE WORLD

of the sulphur produces the necessary acid reaction in
the soil to check the growth of the scab organism.

Several years ago Dr. Erwin F. Smith ventured the
statement that "there are in all probability as many
bacterial diseases of plants as of animals." Time has
more than borne out this statement. However, bac-
terial diseases of the potato crop are not at the present
time a serious problem. The disease known as black-
leg (Bacillus phytophthorus, Appel) which attacks both
the vines and tubers, may, under certain climatic con-
ditions, cause considerable damage. There seems to be
no evidence that the causal organism can live over win-
ter in the soil or in diseased tubers that may remain in
the soil. Careful selection and disinfection of the seed
tubers would appear then to be adequate prophylactic
measures to control this bacterial disease of potatoes.

The two diseases known as "Leaf-roll" and "Mosaic"
belong to the same category as measles and scarlet
fever, being infectious diseases of unknown causation.
Potato leaf-roll has been recognized only in recent years
in this country. Mosaic is an old disease formerly
known as leaf-curl or curly dwarf and thought to be
associated with degeneration or senility of the variety.
On account of the increasing prevalence of these dis-
eases and the difficulties involved in their control they
have become the chief potato disease problem in some
sections of the country. Quanjer, a Dutch scientist,
has shown by grafting diseased branches on healthy
stocks that both diseases are contagious and that the
virus is carried in the juice of the plant and tu«
ber. He also showed that the virus from diseased

THE MODERN POTATO PROBLEM 237

plants may pass through the soil to healthy plants as
far as two or three yards away. More recently the
transmission of leaf-roll from one plant to another by
aphids, or plant-lice, has been demonstrated. Other
means of transmission are yet unknown. Healthy
growing plants that become infected with the virus of
either of these diseases respond rather slowly to the in-
fection, making it difficult to recognize the symptoms
in the first crop. Since the virus is carried in the tuber
these diseases are truly hereditary, and they become
progressively more severe with each succeeding genera-
tion. The impossibility of reaching the virus by seed
treatments coupled with the difficulty of recognizing
the symptoms in their incipient stages, greatly add to
the seriousness of the increasing prevalence of both the
leaf-roll and mosaic diseases.

Of the physiological diseases of the potato, the so-
called spindling sprout disease is probably the most
important. However, to speak of a spindling sprout
disease is misleading, since the weak spindling sprouts
are merely a symptom which may have a variety of
causes. The true spindling sprout diseases referred to
here appears to be a response to unusually hot and
possibly dry mid-summer conditions when the tubers
are forming. The only reliable visible symptom of the
disease in the tuber is the spindliness of the sprouts and
the frequent appearance, in severe cases, of small tubers
at the base of these sprouts. Studies on this disease
have revealed some characteristic physiological and
chemical conditions of the spindling sprout tubers, but
it is impossible yet to say whether any one of these con-

238 SCIENCE REMAKING THE WORLD

ditions is the cause or result of the trouble. There arc
some indications that suggest a lack on these tubers of
a sufficient amount of an accessory growth-promoting
substance. It is possible by repeated sprouting to
cause normal tubers to produce typical spindling sprouts
even to the point when small tubers appear at the base
of the sprouts, a characteristic of severe cases of the
spindling sprout disease. Chemical analysis of the
mother tubers showed that very small amounts of the
usual food materials had been removed from the tubers
when the sprouts began to show decided spindliness
of growth. However, the tubers were exhausted of a
substance necessary for normal growth.

In cool climates the spindling disease is rare, but it is
very prevalent in our southern states. Experimenta-
tion in recent years has proved conclusively the supe^
riority of northern seed over home-grown seed for the
early crop in the more southern latitudes. The true
character of this place-effect in the production of seed
potatoes is certainly not definitely known, but it is be-
lieved that the spindling sprout disease is an important
contributing factor.

During certain seasons the potato crop suffers much
damage by the premature death of the tips and margins
of the leaves, without evident parasitic causation. This
condition, known as tip-burn, has usually been attrib-
uted to the loss of water from the leaves by transpira-
tion at a more rapid rate than it can be supplied by the
roots under the prevailing climatic conditions. This
simple explanation of tip-burn has been recently con-
tested, and its true cause has truly become a real mod-

THE MODERN POTATO PROBLEM 239

ern potato problem. Entomologists have recently dem-
onstrated an apparent close association of the insects
known as leaf-hoppers with tip-burn and they have been
inclined to carry this condition over into their domain
and have renamed it hopper-burn. It has also been
claimed that the secret of tip-burn on the potato foliage
is to be found in the water pores, or hydathodes, which
are grouped around the margin of the leaf on the upper
side and masked toward its tip end. The death of the
marginal vein is due to the loss of water from these
pores which lie over it. This is followed by a browning
of the entire region. Attention is particularly called
to the fact that the plant can control the opening and
closing of the stomata but that the hydathodes remain
open permanently.

Modern potato disease research in common with re-
search on plant diseases in general has assumed a much
broader scope than formerly. In the past the pathol-
ogists devoted most of their studies to the parasite.
This type of research is now being supplemented by
physiological studies. The influence of environment on
disease is being emphasized. Investigations are yield-
ing results of tremendous practical importance. They
are explaining the variability in the occurrence of cer-
tain diseases both in general and local areas. The
factors influencing the susceptibility of the plant to
various diseases and the physiological responses of the
plant to the invading organisms are problems awaiting
further research.

POTATO STORAGE. — The storage and transportation
of plant food products is becoming a national problem,

240 SCIENCE REMAKING THE WORLD

ranking in importance with their production. The con-
centration of our population in the cities makes it neces-
sary to draw on stored products in ever greater quantity
and for longer periods of time. Great quantities of
potatoes for future consumption and for seed are stored
both at places of production and in terminal warehouses.
The present losses due to unfavourable storage condi-
tions are enormous. To store potatoes like household
furniture, a method still practised, especially in ter-
minal warehouses, is a costly procedure.

First of all we must bear in mind the fact that the
potato is a living, breathing creature and must be
treated as such. It is not endowed with natural long
life, but is intended to perpetuate the life of the variety
by giving rise to new plants. The practical problem of
potato storage is to prolong the life of the tubers with-
out impairment of their culinary or seed value. They
must also be protected against decay caused by micro-
organisms. Their tissues form an ideal medium for the
growth of fungi and bacteria.

The necessity of specialized storage for potatoes is
now generally recognized, but there is still much
difference of opinion regarding the most favourable
storage conditions. This situation is due in part to a
lack of sufficient and accurate scientific information on
the physiology of the potato tuber during the different
periods of its storage life. Storage conditions that are
most favourable or allowable for one period in the stor-
age life of the potato may not be the best or even toler-
ated in a previous or succeeding period. Although the
complete story of the physiology of the potato during

THE MODERN POTATO PROBLEM 241

its storage life is yet to be written, sufficient information
is now available to characterize certain fairly definite
periods of importance in practical storage. During
the early dormant period chemical changes due to ripen-
ing may continue, if the tubers have not fully ripened
in the ground. These chemical changes consist mainly
in the building up of complex food and structural ma-
terials from simpler substances. For example, nearly
all of the sugar in unripe potatoes is converted into
starch. Cork formation in the skins may continue for
some time. Shrinkage of the tubers due to loss of water
is unusually high during this period.

The latter part of the dormant period may be spoken
of as the late dormant period. By this time the skins
are well corked and the loss of water from the tubers
by evaporation is very low unless the storage air is
unusually dry. The building up and breaking down
processes in the tubers now tend to equalize each other
and at temperatures between 40° and 70° F. there is very
little change in the percentage composition of the tubers.
The potatoes are much less effected by storage condition
than during any other period in their storage life.

The period that elapses between the time when
potatoes come out of their rest period and will sprout
under growing conditions, and the time when sprouting
actually begins, may be thought of as the post-dormant
period and is the critical period in the storage of po-
tatoes. The breaking-down processes, or hydrolysis,
tend to predominate, probably due to weakening with
age of the constructive or synthetic processes. The
tubers are liable to soften rapidly with unfavourable

242 SCIENCE REMAKING THE WORLD

storage conditions. The market demands a firm potato
as it has better cooking qualities. The sprouting period
is characterized by high destructive metabolism, result-
ing in loss from the tubers of starch and other solids.
Loss of water through the sprouts may also be high.
The final result of these processes is the extreme wilting
of the tubers.

External conditions have a profound influence on the
physiology of potatoes in storage. Undesirable changes
in the tubers may be controlled or checked and their
storage life prolonged by a proper combination of stor-
age temperature, humidity, and ventilation. The most
favourable combinations of these factors for the differ-
ent periods in the storage life of the potato can be de-
termined only when we possess accurate and controlled
data on the individual effects of these storage factors.

When human beings are well the temperature of their
bodies is practically constant regardless of the external
temperature. Plants are not so fortunate, as the tem-
perature in their tissues changes with that around them.
This explains why temperature is so important in shap-
ing the life activities of plants and in controlling their
destiny.

The researches of Muller-Thurgau clearly demon-
strated the relationship between storage temperature
and the accumulation of sugar in the tubers. Po-
tatoes attain their maximum sweetness after a few
weeks' storage at a temperature of 32° F. and not as a
result of freezing, which does not occur until the tem«
perature falls to 28° or 26° F. Potatoes will accumulate
a small amount of sugar at 42° F. but practically none

THE MODERN POTATO PROBLEM 243

above this temperature. The maximum sugar content
found in potatoes after storage at a given low tempera-
ture varies with time of year and with individual tubers,
young tubers accumulating less sugar than older ones.
Muller-Thurgau found that the sugar in potatoes after
a period of storage at low temperature is changed again
into starch when the tubers are exposed for from eight to
ten days at ordinary room temperature. This dis-
covery has been confirmed by other workers on a large
number of different varieties and is a practical means of
removing from potatoes their undesirable sweetness.
More recent work has shown that the room temperature
must not be too high because potatoes which have be-
come sweet will not lose their sugar at temperatures as
high as 80° to 85° F., but may continue for a time to ac-
cumulate more sugar.

Respiration is a vital process common to all living
things. Breathing is just as essential to the life of a
potato as it is to the life of man, although this fact is
not generally appreciated. The intensity of respiration
in potatoes varies with the storage temperature, the
higher the temperature up to a maximum of about
1 10° F. the greater the respiratory rate. In the process
of respiration, oxygen and carbohydrates, as sugar and
starch, are consumed and carbon dioxide, water and
heat are produced. The accumulation of these pro-
ducts in storage is injurious to potatoes, therefore ven-
tilation is just as essential to the health of a potato as it
is to the health of animals. In extreme cases of high
temperature and poor ventilation, death of the inter-
nal tissues of potatoes by suffocation may occur, giving

244 SCIENCE REMAKING THE WORLD

rise to the condition known as "Black Heart." Dead
tissue of a vegetable or fruit will decompose and spoil
very quickly at ordinary temperature.

One of the most important discoveries in connection
with respiration of potatoes is the fact that when they
have been stored for a period at low temperature and
then transferred to higher temperature their respiration
for a few days is very high but gradually falls to the
normal rate for the given temperature. This initial
period of abnormally high respiration may, under cer-
tain conditions, become an important factor in the keep-
ing qualities of cold-storage potatoes during their
transportation and marketing. These potatoes must be
supplied with very good ventilation, especially for the
first week or two after they are taken from cold storage.
For the same reason potatoes in late common storage
must be well ventilated. Experiments are now in prog-
ress to discover, if possible, storage conditions that are
generally satisfactory but that will not impose upon
the tubers the initial abnormal rate of respiration when
they are exposed to higher temperatures.

Storage temperature is the most important factor in
controlling the growth of decay organisms as well as the
growth of sprouts in late storage. At temperatures
below 46° F. the damage due to rot organisms is very
slight.

When all of the temperature effects are considered,
the selection of the best storage temperature will be a
compromise and will probably vary somewhat with
the storage period. Temperatures ranging from 36° to
42° F. are now recommended for potatoes to be used

THE MODERN POTATO PROBLEM 245

for food. Seed potatoes may be stored at temperatures
as low as 33° F. without impairment of seed value if the
storage period is not too long. It is probable that the
age and condition of the tubers, when placed in storage,
are important factors in determining the possible period
of cold storage before they are damaged for seed.

Besides supplying oxygen to the potatoes and dissi-
pating the products of respiration, ventilation is also a
means of removing excessive moisture trom the storage
air and of controlling the temperature of common stor^
age. The necessary amount of ventilation depends
upon the temperature and the season of the year. It is
quite generally agreed that the humidity in the storage
air should not permit condensation of water on the
tubers, but it should be high enough to prevent undue
shrinkage and wilting of the tubers by evaporation
of their water. The relative humidity would vary
with the temperature; at 40° F. it would be about 80
per cent.

This discussion has included just a few of the impor-
tant modern potato problems. Many others of equal
importance are confronting the potato grower and the
potato industry in general — such as the physiology of
tuberization, immunity to disease, various cultural
problems, marketing, utilization of culls and surplus
crops, chemical composition, and cooking qualities of
the tubers as effected by different conditions.

Many of the modern potato problems are typical of
other food crops and rank with the most important
problems confronting modern science as they are con-
cerned with the world's food supply.

246 SCIENCE REMAKING THE WORLD

' GUIDE TO FURTHER READING

"Study of the Rest Periods in Potato Tubers," by C. O. Apple-
man. Maryland Agricultural Experiment Station, Bull. No. 183,
1914.

" Physiological Basis for the Preparation of Potatoes for Seed,"
by C. O. Appleman. Maryland Agricultural Experiment Station,
Bull. No. 212, 1918.

"Anatomy of the Potato Plant, with Special Reference to the
Outogeny of the Vascular System," by Ernest F. Artschwager, 1918.

" Potato Diseases/' by C. R. Orton. Agricultural Experimental
Station, Penn. State College, Bull. No. 140, 1916.

" Potato Tuber Diseases," by W. A. Orton. United States De-
partment of Agriculture, Farmers* Bull. No. 544.

"Lessons for American Potato Growers from German Ex-
periences," by W. R. Orton. United States Department of Agri-
culture, Bull. No. 47, 1913.

Proceedings of the Eighth Annual Meeting of the Potato Associa-
tion of America, 1921.

"The Mosaic Disease of the Solanaceae, etc." by H. M. Quanjer.
Phytopathology, 10: 35-47, 1920.

"Degeneration of Potatoes," by Redcliffe N. Salaman. Royal
Horticultural Society, International Potato Conference.

"Leaf-roll, Net-Necrosis, and Spindling-Sprout of the Irish Po-
tato," by E. S. Schultz and Donald Folsom. Journal Agricultural
Research, 21: 47-68, 1921.

"Group Classification and Varietal Descriptions of Some Ameri-
can Potatoes," by William Stuart. United States Department of
Agriculture, Bull. No. 176, 1915.

"Potato Breeding and Selection," by William Stuart. United
States Department of Agriculturej Bull. No. 195.

CHEMISTRY AND ECONOMY OF FOOD
BY HENRY C. SHERMAN, PH.D.

Professor of Food Chemistry and Executive Officer oj ike
Department of Chemistry, Columbia University

HALF of the struggle of life is a struggle for food"
in the sense that a majority of the world's
people must spend as much of their time or
their earnings in providing themselves with adequate
food as with all other necessities combined.

THE COST AND THE FUNCTIONS OF FOOD. — A family
in comfortable circumstances may spend as much for
rent, sometimes (too often perhaps) as much for cloth-
ing, as for food. The food is more nearly a fixed re-
quirement than are the other items of the cost of living.
When we consider the larger numbers of families who
must live on smaller incomes we find that while the ex-
penditures for food average somewhat less than in well-
to-do families of the same size, yet in general it is not
feasible to diminish the expenditure for food in the same
proportion that the income is diminished. Thus the
smaller the income the larger the proportion of it that
goes for food. In the typical family of a labouring man
or minor clerk half of the entire income is often spent
for food and must be if the health and efficiency of the
family are to be maintained. Or as one writer puts it:

247

248 SCIENCE REMAKING THE WORLD

"The less the worker gains the more he must invest in
food, renouncing of necessity all other .desires/'
j Why? What makes it necessary for the majority to
renounce so much of what they rightly desire in other
directions and spend such large fractions of their slender
incomes upon food?

It is because the functions performed by our food are
so urgently and fundamentally necessary not only to
our comfort, efficiency, and health, but even to life it-
self. Very briefly stated the functions of food are:
(i) to yield energy for carrying on the activities of
the body; (2) to furnish the materials necessary for the
growth and repair or upkeep of the body tissues; (3) to
regulate conditions and processes in the body. The
most prominent function of food, and the one in which
nearly all articles of food take part, is to burn in the
body and so yield the energy for the work which is al-
ways going on in every living organism even when it is,
as we ordinarily speak, at rest. For every act and sign
of life involves warmth, movement, or some other form
of energy expenditure.

Fundamental as is the energy requirement or need for
calories, yet food requirements cannot be met in terms
of calories alone. Our wheat and corn crops alone
would furnish each year enough calories for four times
our population. But we could not thrive long on grains
alone, for they are not entirely satisfactory in the fulfill-
ment of the second and third functions of food. While
we in America have an unparalleled food resource in
our grain crops, we need other food crops also to make
our food supply adequate as well as abundant.

CHEMISTRY AND FOOD 249

FOOD CHEMISTRY. — Chemistry has already made and
will surely continue to make many important contri-
butions to the problems of food supply. Soil problems;
fertilizer problems, including the fixation of atmospheric
nitrogen and the utilization of the potash which would
otherwise be lost in the cement industry or remain un-
claimed in the desert lakes or in the sea; the problems of
properly handling and preserving the food crops; the
inrention, development, and control of manufacturing
operations in the food industries; as well as the inspec-
tion of their products in the interest of the consuming
public — all these are problems largely for the chemist to
solve and fields of work in which chemistry has already
shown noteworthy achievements and must continue to
play a leading part.

Perhaps the most important of all the services of food
chemistry lies in the formulation of the requirements of
human nutrition in explicit, scientific, and practical
terms, and in determining the relative values of different
foods in nutrition and the ways in which they supple-
ment each other so that we may know how best to use
our food supplies to the end that all people may be as
well nourished as possible. For good nutrition is an
even larger factor in health, happiness, and efficiency
than we have previously supposed.

Until recently the application of chemistry to food
problems, which has been uppermost in the public
mind, has been in the use of chemical analysis to detect
adulterations in food. There was justification for the
charge sometimes brought against the food chemist that
he ''spends his time finding out what we shouldn't eat

250 SCIENCE REMAKING THE WORLD

instead of what we should." In those days, too, at-
tempts to describe a good diet in purely chemical terms
were hampered by the embarrassing fact that all efforts
to raise animals upon mixtures of carefully purified food
substances containing all the chemical compounds then
known as essential to foods, had ended in failure; in fact,
the purer the chemical substances making up the food
mixture, the more certainly did it fail to support normal
nutrition. Whether nutritive failure resulted from the
need of other substances in addition to those then known
as essential, or from faulty selection or combination of
the nutrients entering into the artificial food mixture,
remained obscure until about ten years ago when the
work of Hopkins in England, and of Osborne and Men-
del and McCollum and Davis in this country, made it
clear that an adequate food supply must furnish cer-
tain substances which are absolutely essential but whose
existence was previously unknown, and which we now
know as the vitamins.

Although the vitamins have not yet been isolated in
pure form, nor their chemical nature determined, yet
we now know enough of their occurrence in foods and
their functions in nutrition to include them in our
study and discussion of food values, and we can now
describe adequate food supply in chemical terms with
confidence that we are taking account of all essential
factors. Such a description requires the use of a small
number of terms which a few years ago were regarded as
technical but which have now become household words
through the war-time discussions of food values and
food conservation. An adequate food supply may be

CHEMISTRY AND FOOD 251

described from the chemical point of view as one which
furnishes: (i) sufficient amounts of digestible material to
yield when burned in the body the necessary number of
calories of energy; (2) enough protein of suitable sorts;
(3) adequate amounts and suitable proportions of a
number of mineral or inorganic elements (the ash con-
stituents of the food); (4) enough of each of at least
three kinds of vitamins.

If a mechanical analogy helps, one may compare the
body and its food to a gasolene engine and its require-
ments. The digestible organic foodstuffs such as fats,
sugars, and starches correspond to the fuel for the engine;
the proteins and some of the mineral matters to the
materials of which the motor is made; other mineral
matters to the lubricant; and the vitamins to the igni-
tion sparks whose own energy is insignificant but with-
out which the engine cannot run, however fine the ma-
terials of which it is built or however abundant and
appropriate the supplies of fuel and of lubricant.

The efficiency with which economy in the use of food
can be combined with entire adequacy of nutrition is
chiefly dependent upon the extent to which we can state
the various esssentials of an adequate diet in quantita-
tive terms. Here in the most practical manner imagin-
able the exact science of the research laboratory in food
chemistry comes directly into the service of human nu^
trition. How best to spend a dollar in the purchase of
food for a family, or how best to divide the money which
is to be spent for food — is a problem more often met
than faced and one which may well serve to put into
practical use whatever knowledge of food values and

252 SCIENCE REMAKING THE WORLD

food needs has been gained from the simplest food
study of the elementary school or from the most ad-
vanced university course in the chemistry of food and
nutrition.

FUEL OR ENERGY VALUES OF FOOD — THE TOTAL
FOOD REQUIREMENT. — The exact quantitative deter-
mination of human food requirements is chiefly the out-
growth of the nutrition investigations begun by means
of a small appropriation made by Congress to the
United States Department of Agriculture and expended
under the direction of Dr. W. O. Atwater, late Professor
of Chemistry in Wesleyan University. Professors At-
water, Rosa, and Benedict constructed in the basement
of the chemical laboratory of Wesleyan University at
Middletown, Connecticut, the first practically success-
ful apparatus for the measurement of the energy ex-
changes in, and the energy needs of, the human body, i

The outstanding achievement of Professor Atwater's
work in this field was the development of a respiration
calorimeter suited to direct experiments with men at
rest and at work, and the perfection of this apparatus
until it became truly an instrument of precision. This
respiration calorimeter provided a copper room seven
feet long, four feet wide, six and one-half feet high in
which a man may live as many days as the particular
experiment may require, and fitted with means for
measuring accurately the amounts of energy used by
the man under various conditions of activity and occu-
pation. Figure I shows a general view of this appara-
tus as it was developed and used in the Atwater labora-
tory; Figures 2 and 3 show inside views of the living

CHEMISTRY AND FOOD 253

chamber. For explanation of the various parts refer-
ence must be made to fuller descriptions of the appara-
tus, e. g.y Bulletin 175 of the Office of Experiment Sta-
tions, United States Department of Agriculture, and
Publication 123 of the Carnegie Institution of Wash-
ington.

When the experiments made by means of this original
respiration calorimeter had given sufficient knowledge
of the relative expenditures of energy at different times
of the day and night and under different conditions of
work and rest, it became possible to study particular
problems by means of apparatus of smaller size and of
particular design according to the nature of the problem
to be investigated. Examples of such apparatus are
the chair calorimeter and bed calorimeter (Figures 4
and 5) which are but two of the many improved calori-
meters devised by Dr. F. G. Benedict, the Director of
the Nutrition Laboratory of the Carnegie Institution
of Washington and the leading experimenter in this
field. Another important contribution made by Doctor
Benedict to the methods of research upon energy re-
quirements is the perfection of respiration apparatus
by means of which the amount of oxidation taking
place and of energy being used in the human body can
be accurately determined by means of measurements of
the oxygen consumed and the respiratory products
given off, which measurements are now accomplished
without necessitating the confinement of the man in the
respiration calorimeter.

So fruitful did this line of study prove that notwith-
standing the considerable expense involved in making

254 SCIENCE REMAKING THE WORLD

the experiments and the difficulty of securing funds for
such work — since its more practical bearings could not
be brought out in convincing fashion until the results
of years of research could be brought together — it has
been carried forward by the United States Department
of Agriculture first under Professor Atwater and then
under Dr. C. F. Langworthy, and also by the Carnegie
Institution of Washington in its nutrition laboratory
under Doctor Benedict, until now the energy require-
ments of the normal human body for different ages,
sizes, and conditions of work and rest are fairly ac-
curately known. The number of calories expended
per hour by an average-sized man under various con-
ditions of daily living, industrial occupation, and ath-
letic exercise is shown in Table i, taken from the
author's "Chemistry of Food and Nutrition, Second
Edition, " in which may be found a fuller discussion of
the achievements here sketched in bare outline.

TABLE I

Hourly expenditure of energy by average-sized man (70 kilograms
or 154 pounds without clothing) under different conditions of ac-
tivity. (Approximate averages only.)

CALORIES

Sleeping 6070

Awake, lying still 70-85

Sitting at rest 100

Standing at rest 115

Tailoring 135

Typewriting rapidly 140

Bookbinding 170

"Light exercise" (bicycle ergometer) 170

Shoemaking 180

Walking slowly (about 2§ miles per hour) .... 200

CHEMISTRY AND FOOD 255

CALORIES

Carpentry 240

Metal working 240

Industrial painting 240

"Active exercise" (bicycle ergometer) 290

Walking actively (about 3f miles per hour) .... 300

Stoneworking 400

"Severe exercise" (bicycle ergometer) 450

Sawing wood 480

Running (about 5^ miles per hour) 500

"Very severe exercise" (bicycle ergometer) .... 600

This exact quantitative knowledge of the energy
values of foods and energy requirements in nutrition
now forms the basis of all sound practical work in food
chemistry and human nutrition — whether it be a prob-
lem of an individual or a family, a nation or a whole
group of nations. During the World War the food
crops and the food needs of America and the Allies were
pooled and apportioned on the basis of calories; and
every individual who wishes to purchase food economic-
ally begins his or her planning by deciding first upon
the level of expenditure which is best expressed in terms
of the number of calories which must be bought with
a cent, or the number of cents which may be spent per
1000 calories of total food obtained.

THE NUTRITIVE EFFICIENCIES OF FOOD PROTEINS.—
Protein has long occupied a prominent place in studies
of food and nutrition and during the past decade much
new interest has been attracted to this factor in food
value by the discovery that the different proteins found
in foods may, when taken separately, show very differ-
ent efficiencies in nutrition.

Dr. Thomas B. Osborne of the Connecticut Agricul-

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CHEMISTRY AND FOOD 257

tural Experiment Station and Professor Lafayette B.
Mendel of Yale are the leaders in this field of science
and their successful correlation of the chemical differ-
ences among proteins with their nutritive functions and
efficiencies is one of the great achievements of modern
science. Only a hint of it can be given here. When
only one protein was fed at a time, along with
mixtures of other foodstuffs known to be adequate to
all other nutritive requirements, it was found that some
proteins are adequate to support normal growth, others
support maintenance but little if any growth, while still
others always fail even to permit the animal to maintain
his weight. A photograph of a rat whose growth had
been practically suspended by feeding with a diet good
in all other respects but containing gliadin as sole pro-
tein is shown in Figure 6 along with photographs, taken
at the same focal distance, of normal rats, one of the
same age, and another of the same weight, as the rat
which had been thus stunted.

At first thought, therefore, it may seem surprising
that the Inter-Allied Scientific Food Commission while
setting standards for food needs in terms of calories
declared it unnecessary to set standards for protein on
the ground that a food supply of any ordinary character
and sufficiently abundant to meet the calorie (energy)
requirement can be trusted to furnish adequate protein
without special planning. The justification for this
view is found in two facts: (i) the quantities of protein
actually required for healthy nutrition have been found
by much careful research to be considerably smaller
than formerly supposed; (2) the differences in nutritive

258 SCIENCE REMAKING THE WORLD

efficiency shown by certain individual proteins taken
singly do not imply any great danger that the daily food
will furnish inefficient protein, because the articles of
food which we actually use contain many kinds of pro-
tein and these different proteins supplement each other.
To explain this fully would require too long a discussion
of the individual amino acids of which the proteins are
composed.

THE MINERAL ELEMENTS AND VITAMINS OF FOODS. —
Besides the five chemical elements of which simple pn>
teins are composed, about a dozen more are now known
to be essential to human nutrition; and besides the
chemically known organic foodstuffs at least three other
organic substances, vitamins A, B, and C, are also nec-
essary. Space does not permit the discussion here of
even the more important of our recent advances in the
study of the mineral elements of food, and the vitamins
need not be further discussed in this chapter since they
are treated elsewhere in this volume by Doctor Eddy.
It must, however, be emphasized that the recently
developed knowledge of the nutritive importance of
the mineral elements and vitamins and of the very un-
even distribution of these dietary essentials among the
different articles and types of foods has greatly clarified
our ideas of food values. For progress in this line of
study we are greatly indebted to McCollum and Sim-
monds, formerly of the University of Wisconsin and
now of the Johns Hopkins University. It was for-
merly customary to speak as though dietaries could be
"balanced" by a consideration of protein, fat, and car-
bohydrate, whereas we now see clearly that the mineral

CHEMISTRY AND FOOD 259

elements and vitamins are at least equally important in
this connection.

Taking account of energy values, protein content,
mineral elements, and vitamins, we now group the chief
articles and types of food according to their outstanding
nutritional characteristics as follows:

1. Grain products — economical sources of energy and
protein but not satisfactory in their mineral and vitamin
content.

2. Sugars and fats — chiefly important from the nutri-
tional standpoint as supplementary sources of energy,
although some fats are also important as sources of the
fat-soluble vitamin.

3. Meats, including fish and poultry — rich in protein
or fat or both, but showing, in general, the same mineral
and vitamin deficiencies as do the grains.

4. Fruits and vegetables — varying greatly in their
protein and energy values but very important as sources
of mineral elements and vitamins.

5. Milk — important as source of energy, protein,
mineral elements, and vitamins; the most efficient of all
foods in making good the deficiencies of the grains and
in ensuring the all-round adequacy of the diet. (See
Fig. 6.)

Fruits, vegetables, and milk are now seen to have
much higher food values than were hitherto known, be-
cause they serve (as meats, sweets, and most fats do not)
to make good the mineral and vitamin deficiencies of the
breadstuff's and other grain products.

What we now call the newer knowledge of nutrition
has been acquired within much less than a generation

26o SCIENCE REMAKING THE WORLD

and as yet its practical application has but barely begun.
The economic and hygienic benefits which we may rea-
sonably anticipate are incalculable. We must remem-
ber that the food crops produced by a country are not
determined by nature (though writers often seem to
imply this) but by the relative demands for the different
things which any given farm can produce. The farmer
in the long run will employ his land and labour and dis-
pose of his crops in whatever way he finds most profit-
able and this in turn will depend upon what the con-
sumer demands in the market and the relative prices
which he (or she) is willing to pay. As fast as consum-
ers come to understand that fruits and vegetables and
milk are worth more and that meats and sweets are*
worth less than has been hitherto supposed, and show
this knowledge by shifting the emphasis of their de-
mands from meats and sweets to fruits, vegetables, and
milk, just so fast will more fruits, vegetables, and milk
be produced because they will thus become the crops
that pay the farmer best.

For instance, when a normal American corn crop has
been harvested and all the demands of human consump-
tion, of industry, of seed for the next crop, and of feed
for the farmers* draft animals have been met, there re-
main in the hands of the farmers of the United States
over a billion bushels of grain to be turned into extra
meat or into extra milk according to which "the mar-
ket," that is, the consumer, makes it more profitable
for the farmer to produce. Increase in the milk supply
need not be entirely at the expense of a decreased meat
production, but even if this were true the production of

CHEMISTRY AND FOOD 261

milk could be doubled by decreasing the meat supply
only one third. Two thirds of our present meat supply
would give us a larger per-capita meat consumption
than any European country, even Great Britain, has
ever enjoyed in modern times — in all probability quite
as much as is good for us; while to double the milk
supply of the United States would undoubtedly mean a
tremendous gain in the well-being of the people.

Even if our present milk supply be regarded as ade-
quate, we now have evidence that a more liberal supply
would be better.

ADEQUATE VERSUS OPTIMUM FOOD SUPPLY. — The
space assigned for this paper being nearly exhausted,
let us conclude it with a brief account of a current in-
vestigation demonstrating the fact that through our
present knowledge of food chemistry, a food supply al-
ready adequate may still be capable of improvement
with corresponding gain in health and vigour.

In developing and applying the newer knowledge of
food chemistry in our work at Columbia University, we
have not been satisfied to stop with adequacy of nutri-
tion. We have sought to find and to show how a food
supply which is already adequate may be made still
better so that it will support a higher degree of health.

The Century Dictionary defines health as: "Sound-
ness of body; that condition of a living organism and
of its various parts and functions which conduces to
efficient and prolonged life. . . . Health implies
also, physiologically, the ability to produce offspring
fitted to live long and perform efficiently the ordinary
functions of their species."

262 SCIENCE REMAKING THE WORLD

We are somewhat accustomed to quantitative ratings
of soundness and efficiency and much more so to data
of growth rates, birth rates, and statistics of duration of
life. In human experience so many factors may enter
to influence health in the course of a lifetime that it is
hard to separate and measure the effects of food alone.
But this can be done with laboratory animals of rapid
growth and early maturity like the rat, and in such ex-
periments it is possible to determine under conditions
uniform in all other respects the influence of food upon
the various factors of health comprised in the definition
just quoted.

Among the recent findings of nutrition experiments
carried through successive generations of such labora-
tory animals the results of which are, I believe, directly
and fully applicable to the problem of the attainment
of the highest degree of human health, is the fact that
starting with a diet already adequate we may by im-
provement of the diet induce a higher degree of health
and vigour. This has been rather strikingly shown in
experiments with rats in which different families from
the same stock have been kept for successive genera-
tions upon two uniform food supplies : the first diet
adequate as shown by the fact that it has supported
healthy growth, development, and reproduction in
some families for no less than six generations; the
second diet differing from the first merely in that it
contains a higher proportion of milk. These experi-
ments are still in progress but certain results are already
clear.

Among the evidences of a higher degree of health

CHEMISTRY AND FOOD 263

which we find to result from increasing the proportion
of milk in a diet already adequate are the following:

1. More rapid growth.

2. More efficient growth, i. e. a greater gain in weight
for each 1000 calories of food consumed.

3. Somewhat larger average size at all ages, though
the difference in size is not striking and probably
not of great importance.

4. Greater vigour as indicated by earlier maturity,
larger capacity for reproduction, and greater
success in rearing the young.

5. The period of full vigour was prolonged and the
proportion of families dying without issue was
greatly reduced.

6. The weight of the mother was better maintained
while suckling her young and the young grew and
developed better during the suckling period.

7. Both infant mortality and the death rate after
infancy were reduced, and this notwithstanding
the fact that the females had borne and suckled
more young.

There is no reason to doubt that all these findings,
as thus stated in qualitative terms, will apply equally in
human experience and that a higher degree of health
will follow an improvement in the dietary of the in-
dividual or in the food supply of the community, such
as an increase in the proportion of milk, even where the
original dietary was already adequate according to all
current standards.

264 SCIENCE REMAKING THE WORLD

This does not mean, as the sensationally minded
would have it, that by the use of a "super-diet" we can
produce a "super-race." It does mean that by the right
use of our present knowledge and of our food supplies
we can in future bring to a much larger percentage of
our peonle that full measure of health and efficiency
which only the more fortunate now enjoy.

May not such results of scientific investigation func-
tion somewhere in the curriculum of every school?

GUIDE TO FURTHER READING

"Economics of the Household", by B.R. Andrews. (Macmillan,
New York.) 1923.

"The Nutrition of Man," by R. H. Chittenden. (Stokes, New
York.) 1907.

"The Science of Nutrition," by G. Lusk. New Third Edition.
(Saunders, Philadelphia.) 1920.

"The Cost of Living," by E. H. Richards. Third Edition.
(Wiley, New York.) 1905.

•" Feeding the Family," by M. S. Rose. (Macmillan, New York.)
1916.

'"Laboratory Handbook for Dietetics," by M. S. Rose. Second
Edition. (Macmillan, New York.) 1921.

"Chemistry of Food and Nutrition," by H. C. Sherman. Second
Edition. (Macmillan, New York.) 1918.

" Food Products," by H. C. Sherman. (Macmillan, New York.)
1914.

"The Vitamins," by H. C. Sherman and S. L. Smith. (Chemical
Catalogue Company, New York.) 1922.

"Elementary Household Chemistry," by J. F. Snell. (Macmillan,
New York.) 1914.

"Dietetics for High Schools," by Florence Willard and L. H.
Gillett. (Macmillan, New York.) 1920.

OUR DAILY BREAD AND VITAMINS
BY WALTER H. EDDY, PH.D.

Professor of Physiological Chemistry, Columbia University

ONE of the outstanding events in nutrition of the
past decade has been the evolution of the
vitamin hypothesis. Unfortunately the appli-
cation of this hypothesis to the needs of the layman has
provided the food and nostrum purveyors with material
for advertising and exaggeration, and it is now essen-
tial that the cold facts in the case be presented to the
public if we are to avoid the evils that have arisen from
this quackery. In this chapter I wish to outline briefly
the significant steps that have led to our knowledge of
vitamins, the relation of this knowledge to our previous
conceptions of right feeding, the methods which are used
to evaluate the vitamin content of foodstuffs, and some
simple rules for guidance in food selection in view of the
new discovery.

Previous to 1906 the study of nutrition by laboratory
methods has provided important basal principles for
guidance in food selection. These principles are as
fundamental and basic to-day as they were then, and
the first fact to emphasize is that the vitamin discover-
ies have merely provided knowledge with which to
supplement these facts, not to supersede or overthrow
them.

266 SCIENCE REMAKING THE WORLD

The basal principles to which I refer may be sum-
marized rather briefly.

First, food is fuel. Like coal the amount of energy
that a given food will produce can be measured in heat
units and that is all there is to the calorie evaluation
idea. The calorie is simply a unit to measure with, like
the inch or the centimetre. Thanks to accurate instru-
ments and chemical analyses, it is now easily possible to
determine on the one hand just how many calories of
energy you or I need to run our human machine for
twenty-four hours, and on the other hand just how much
of the various kinds of foods we must consume to pro-
duce these calories.

But even though a foodstuff measures up to our
calorie needs the body requires other qualities. To
produce energy alone we can use starches, sugars, or
fats, but to rebuild the living cellular matter (proto-
plasm) we require not only these foods but also others
rich in nitrogen. The chemist calls starches and sugars,
"carbohydrates." He calls the fatty substances,
"lipins," and to the nitrogenous foodstuffs he has ap-
plied the term "protein." For all of these collectively
he uses the term "organic nutrients." Chemical analy-
ses easily give the proportions of carbohydrates, fats,
and proteins in any foodstuff and this information is
now available to the public in the form of tables issued
by the Government and to be found in the many
standardized texts on dietetics. If the ordinary in-
dividual will so select his foodstuffs as to provide fifty
grams (about two ounces) of protein per day and to
meet the calorie needs, he has satisfied most of what we

VITAMINS 267

call the per diem nutrient needs of the human machine.

Aside from the organic nutrients present in a food,
however, it has been found that the body also requires
certain mineral salts. The manufacture of bone, for
example, is a matter of lime deposition and we are learn-
ing that to deposit this lime as bone the body requires,
not only lime salts, but a certain amount of phosphorus.
Again the prevention of various bad conditions lumped
collectively under the name of acidosis requires that our
blood be kept nearly neutral in reaction and the carbo-
nates and phosphates play an important part in this regu-
lation. Mineral salts, then, constitute a fourth nutrient.

We are accustomed, then, to say that the second
principle for guidance in food selection is to make sure
that the foodstuffs contain the proper kinds and
amounts of nutrients, including under this term car-
bohydrates, fats, proteins, and mineral salts.

The next discovery was the demonstration that pro-
teins differ in nutritive value and that not only must
the body have its fifty grams of protein per day, but it
is extremely fussy as to the kind of protein it demands.
As a result of the studies of many chemists working in
this field we know that proteins are to be thought of as
mosaics made up of separate chemical pieces and that
there are some eighteen of these pieces, nearly all of
which are absolutely necessary to make a body-
satisfying protein. These pieces are known chemically
as amino acids, but the principle involved is covered if
we say that not only must we be sure of the amount of
protein, but we must also assure ourselves as to its
quality or make-up.

268 SCIENCE REMAKING THE WORLD

There are also foods which were originally despised
because of their poor showing in the respects referred to
above, which are now valued for another cause. The
normal activity of our digestion demands a certain
bulk to our food mixture, even though that bulk is se-
cured by materials which are classed as indigestible.
It is of course obvious that no matter how rich a food
may be in the qualities outlined above, the nutrients
must be of such a nature that the digestive juices can
act upon them and so change them that they will pass
freely from the digestive organs to the blood. If not
they will fail to reach the muscle, nerve, skin, bone, and
other structures they are intended to nourish. This
property, then, demands that our foods be digestible,
but if we attempted to feed a man on completely digesti-
ble mixtures his stomach and intestines would in time
become atrophied. In other words we must have pres-
ent a certain amount of indigestible matter to provide
bulk and stimulation to the lining of the digestive tract.
The cellulose which forms the coating of starch grains,
the connective tissue that forms the indigestible portions
of meats, etc., are examples of such substances. We
speak of them as roughage and they are mechanical
necessities of our food mixtures which must not be
neglected if we are to avoid constipation and like ills.
In general, then, while our foods must contain digestible
nutrients they should also carry a certain amount of
indigestible roughage.

Finally the form of the food offered is important.
Eating is to a high extent a psychological affair. If
the food is presented in an unpalatable form the body

VITAMINS 269

can utilize it, but in time the mental antipathy reacts
physiologically and the individual becomes badly
affected thereby. It is worth-while always to pay at-
tention to palatability.

Osborne's and Mendel's studies on the significance of
protein quality were conducted between 1908 and 1911
and actually published in 1911. At that time the
principles mentioned above were supposed to have
completely expressed the basis for guidance in food se-
lection. To illustrate these principles let us consider
for a moment the composition of a foodstuff which is
universally recognized as a perfect type of food, milk.
In the following table are listed the chemical facts which
are necessary to establish the standing of this foodstuff
in the light of the knowledge of 1906-1911.

THE VALUE OF MILK AS A FOODSTUFF

g

(a) One quart of milk will produce about 700 calories of energy.
If a baby's need were 700 calories per day one quart of milk would
therefore meet this need without resource to other food. A man
requiring 3,000 calories per day would, of course, need to consume
a very large amount of liquid if he lived on milk alone and hence
usually prefers to supplement milk with other less watery prod-
ucts.

(b) The nutrient content of ordinary cow's milk is as follows:

Protein of good quality 3-3%

Lipins 4.0%

Carbohydrates 5.0%

Mineral salts «-7%

Water 87.0%

Wt. of one quart 34.4 oz. or 2.15 Ibs.

Amino acid content — All the essential ones

It is also digestible and palatable.

270 SCIENCE REMAKING THE WORLD

Such tabulation as the above is perhaps sufficient index
of how to test out any foodstuffs concerning which we
have similar data.

In our introduction we called attention to one view-
point which we wish to reemphasize here. The vi-
tamin hypothesis has not changed any of the basal
principles by which we judge food value but merely re-
quires us to supplement that knowledge by an additional
criterion. How has this supplementary material been
derived ? What led to the vitamin hypothesis ?

Briefly, two lines of investigation that at first may
seem to have no relationship. First, the prevalence in
certain parts of the world of a disease whose cause was
unknown and whose toll of human lives justified scientific
study. Second, the attempt of the nutrition students
to prove that if we ate foods which met all the require-
ments cited above we would get normal growth, and the
failure of the experiments to demonstrate this.

Since the word vitamin itself was coined as a result of
pursuit of the first line of investigation we will consider
that side of the story first. In the Orient, especially
in East Asia, where the diet consisted largely of fish and
white or polished rice, a peculiar disease often mani-
fested itself to which was given the name beri-beri.
This disease has been known for hundreds of years.
Outside of the Orient the second greatest area was Brazil
and the disease was also known, though less extensively,
in many other districts of the world. The idea that this
disease was of dietary origin seems to have first sug-
gested itself about 1878-1880. In 1882 Takaki pro-

VITAMINS

posed to change the diet of the Japanese Navy from
rice diet and to add meat, bread, fruit, and vegetables.
The result was an immediate reduction in cases of beri-
beri. Rice then was early indicated as one of the
offending articles of diet in the production of this dis-
ease. It would take too long to follow out all the in-
vestigations that were developed after the idea that
beri-beri was due to a certain dietary deficiency first
appeared. We will mention only a few of the most
important. Of these, the investigations directed or
personally conducted by Eijkman, a Dutch investi-
gator in Java, deserve special attention. To him we
owe two very important contributions. The following
table collected by Vordermann at Eijkman's suggestion
from Javanese prison cases shows how rice was first
convicted of being a casual agent.

KINDS OF RICE IN
DIETS

NO. OF
PRISONERS
FED THESE
DIETS

NO. OF
BERI-BERI
CASES

RATIO OF
BERI-BERI
CASES

White rice

I 5O.266

j.,201

I "?O

Rice with partial silver skin
Unpolished rice ....

35,082
96,530

85

9

1:416

1:10725

"A glance at this data shows how attention was fo-
cused not only on rice but on the polishing of rice, or
"silver skin," as the carrier of protection against the
disease. In 1896 Eijkman made a very important ac-
cidental discovery. He found that chickens fed upon
the remains of foods used in a hospital for beri-beri died

272 SCIENCE REMAKING THE WORLD

of a disease which he called "polyneuritis gallinarum"
and recognized as similar to human beri-beri. With
chickens as experimental animals he was then able to
supplement his medical investigations and to demon-
strate that beri-beri was brought about in the Java
cases by long-continued consumption of white rice and
that the act of polishing removes an important con-
stituent of the rice. The Dutch investigators, how-
ever, failed to see the full significance of their findings.
Eijkman himself believed that the starch of the rice
grain gave rise to toxins or poisons which acted on the
nervous system and that this toxic action was prevented
by material in the silver skin or, as he later showed, in
the pericarp of the grain. The foundations laid by
Eijkman stimulated many other workers to follow up
his lead and his greatest contribution was in providing
a test animal in which could be induced the disease and
with which diets could be tested quantitatively.

The search for the preventive substance to which rice
polishings owed their beri-beri protecting power, how-
ever, began actively with Eijkman's contribution in
1897. Other foodstuffs were studied and Grijns found
certain beans to carry this protective substance.'
Schaumann extended the list of curative substances to
include yeast. Other workers then sought to determine
the value of the curative material itself. It was thought
at one time that phosphorus compounds were the re-
sponsible factors. In his book, "The Vitamines,"
Casimir Funk, the author of the term vitamin, sum-
marizes the situation up to the time of introduction ot
the vitamin theory (1911) as follows:

VITAMINS 273

To summarize our knowledge of the chemical nature of the active
principle prior to the introduction of the vitamin theory (till 1911)
the following may be set down with certainty:

1. The substance is soluble in water, alcohol, and acidified
alcohol.

2. The substance is dialysable.

3. The substance is destroyed at 130° c.

When we took up the question in 1911 it was not known whether
the active substance was organic or inorganic, in nature, whether or
not it was a constituent of proteins, nucleins, or phosphatides. It
was not certain that we were not dealing with a ferment, nor was it
known if the substance belonged to some chemical group already
described, or to some new unknown class of substances.

Casimir Funk began his researches in this field
shortly prior to 191 1. He set himself the task of isolat-
ing the anti-beri-beri substance from its sources and the
establishment of its chemical identity. In combina-
tion with Cooper, Funk had shown that when pressed
yeast was boiled with 20 per cent, sulfuric acid for
'twenty-four hours and the sulfuric acid completely
removed with baryta, the evaporated filtrate still ex-
hibited marked anti-beri-beri qualities. This stability
in the presence of an acid led him to believe that the
substance must be an organic base. With this assump-
tion he began a systematic investigation of large
amounts of rice polishings, the results of which he pub-
lished in 1911. In testing his fractions he made use of
pigeons which had been shown, like chickens, to be
particularly susceptible to this disease when fed on pol-
ished rice. By careful fractioning Funk was able to
isolate from 100 pounds of rice polishings less than
2-iooths of an ounce of needle-shaped crystals which
melted sharply at 233° F. and were highly curative.

274 SCIENCE REMAKING THE WORLD

Analysis of these crystals showed the presence of nitro-'
gen. Hence, in a later publication Funk christened these
crystals the anti-beri-beri vita-amine or "vitamine."
Amine has long designated to chemists a substance
basic in action and with a nitrogen content. Since the
crystals prevented loss of life it was natural to call them
the life (vita) amine. It is no discredit to Funk that
later, largely through his own studies and partly
through the work of others, the crystals which he be-
lieved to be pure vitamin were found to consist mainly
of something else. To-day we have not yet succeeded in
isolating the pure substance but Funk's researches laid
a basis upon which all fractioning attempts have been
based. The later discovery of other types of these sub-
stances developed a controversy in which he was criti-
cised for his selection of a name but none of the substi-
tutes proved more acceptable and his term is now in
universal use. Drummond suggested recently that since
the presence of nitrogen had not been demonstrated in
what we now know as vitamin A and C, we drop the
final e in the word and call them vitamins. Funk him-
self rather deprecates this change but the suggestion has
been generally accepted by workers in this field.

Had the vitamin theory concerned solely this oriental
disease and its prevention, we would not have had the
extended public interest that exists in the subject to-
day. To see how this has come about we must turn to
the second line of investigations in 1906. Hopkins and
his pupils in England had arrived at an interesting re-
sult in connection with their attempts to prove the ade-
quacy of the food evaluation principles which we have.

VITAMINS 275

listed. As a result of feeding mice on food mixtures
composed of purified nutrients and meeting all the views
expressed in our qualifications for a perfect food, the
animals failed to grow. Hopkins expressed his views at
the time as follows :

But further, no animal can live upon a mixture of pure protein,
fat, and carbohydrate, and even when the necessary inorganic ma-
terial is carefully supplied, the animal still cannot flourish. . . .
The field is almost unexplored, only it is certain that there are many
minor factors in all diets of which the body takes account.

In 1912, Hopkins first published the evidence on
which he based these prophetic utterances. In this
paper he demonstrated that a small quantity of milk
contains something other than purified nutrient sub-
stances of suitable quality, which is necessary to rat
growth. He suggested the name "accessory factor"
for this substance.

In 1911 appeared the classical work of Osborne and
Mendel in demonstration of the significance of the
amino acids for maintenance and growth. They also
used rat-feeding experiments and, like Hopkins, soon
found that rats fed on purified substances alone would
not grow. They believed that they had found an ac-
cessory factor in milk, and by removing the protein
from the milk obtained a factor which they called
"Protein-free milk," and which, when added to their
otherwise adequate food mixtures, actually promoted
growth. They thought at first that the mineral con-
tent of the milk was the answer, but when they care-
fully analyzed their milk and substituted for natural

276 SCIENCE REMAKING THE WORLD

protein-free milk an artificial mixture built of the salts
in the proportions indicated in the analysis, it failed to
produce the same effect.

Stepp, a worker in Germany, had been attracted to
the problem by the researches in protein quality and
on the hypothesis that fats also might differ in quality
experimented along this line with rats. He first demon-
strated that bread and milk constitute a growth-
producing diet for rats. He then extracted his bread-
and-milk mixture with ether and found the residue
inadequate for growth. This result seemed confirmatory
of his viewpoint. But when he added to the residue
purified fat which he assumed was what had been re-
moved by the ether extraction, no growth resulted.
On the other hand, the residue obtained by evaporation
of his ether extract when mingled with the other residue
produced normal growth. Stepp failed to grasp the
entire significance of these experiments at the time, but
he did provide additional evidence that milk contains
something that is neither protein nor fat and which is
essential to growth.

In 1906 an experiment was begun at the Wisconsin
Experiment Station which was planned by S. M. Bab-
cock and carried out by Hart and Humphrey. In the
later stages of this experiment McCollum and Steenbock
cooperated. The object of this experiment was to
determine whether rations for cattle, so made up as to
be alike so far as chemical analysis would show, but
derived each from a single plant, would prove to be of
equal nutritive value for growth and the maintenance
of vigour. The plants selected were wheat, corn, and

VITAMINS 277

oats and a control group of a ration of the same chemical
composition, but blended of corn, oats, and wheat.
Young heifer calves were used, weighing 350 pounds
and as near alike as possible. They were given all the
salt they cared for, and allowed to exercise in an open lot
free of vegetation, but the diet was absolutely restricted
aside from salt (NaCl) to the particular ration. Dif-
ferences failed to develop until after a year or more
of time had elapsed. At that time the corn-fed animals
were in much superior condition to all the others, even
the control group. The wheat-fed ones were in the
worst condition of all. Body condition, milk produc*
tion, and the bearing of young paralleled one another in
demonstrating the distinction between the diets.

This experiment marked the entrance of McCollum
into a field which was to make him one of the important
contributors to the vitamin hypothesis. He began
the study of the cause of the failure of animals to grow
on mixtures of purified foodstuffs in 1907 and employed
the domestic rat as the experimental animal. In 1909,
McCollum introduced a new feature by seeking to in-
crease the variety of foodstuffs in the diet as far as
possible, but every organic component of the diet was
required to be pure and free from phosphorus in any
form, practically the only source of phosphorus in the
diet being finely ground tricalcium phosphate. The
paper in which the results were published is important,
for it reported the first successful growth experiments
with a food supply which was at the time considered to
be composed only of foodstuffs which could be named.
It seemed to demonstrate the adequacy of the views

278 SCIENCE REMAKING THE WORLD

set forth in our basal principles for food selection and
that the failure of animals fed upon purified food mix-
tures such as those used by Hopkins and Osborne and
Mendel is due to lack of palatability and consequent
failure of the animals to eat enough. McCollum's food
mixture was made up of the proteins edestin from hemp
seed and zein from corn. With these were given corn-
starch, wheat starch, milk sugar, glucose, cane sugar,
butter fat, bacon fat, and cholesterol and a salt mixture.
The striking result was normal growth. In 1909,
Osborne and Mendel began their work to evaluate the
importance of the protein components of the diet. In-
stead of duplicating the diet of McCollum they substi-
tuted a simple mixture consisting of milk-casein, starch,
lard, and a salt mixture recommended by Rohmann.
These animals, unlike McCollum's, failed to grow and
by carefully measuring the food intake it was proved
that this failure was not due to lack of appetite. At
that time no one was able to see any important chemical
difference between the two diets. But by substituting
for 28 per cent, of the diet the milk residue which they
called protein-free milk, they obtained growth.

It would take too long to follow out all the lines of
this experimentation. Out of it came the important
information which has brought us recognition of the
differences in protein quality. But from the vitamin
viewpoint it was still more important. As a result of
McCollum's study of his own diet he finally demon-
strated the presence of a hitherto unsuspected factor in
his butter fat that is absent in lard. He also found that
egg yolk contained this substance. At the time of thia

VITAMINS 279

discovery he believed that this was the key to the differ-
ence between his diets and those of Osborne and Mendel
and he christened this new substance "unidentified
dietary factor fat-soluble A."

But there was another factor in the mixtures en-
tirely unsuspected by either McCollum or Osborne and
Mendel at the time. This factor was present in the
protein-free milk and also in McCollum's lactose. The
publication of Funk's work and his vitamin suggestions
set the investigators on a new trail. McCollum ob-
jected to the idea that his fat factor was Funk's vitamin.
Funk tried to show that the factor in butter fat was his
vitamin substance. The literature of 1912-1915 is full
of data bearing on this phase of the subject. Osborne
and Mendel were able to confirm the presence of a stim-
ulatory factor in certain fats as McCollum contended,
but still believed that their protein-free milk supplied
something else equally important. All the world
knows to-day that the truth was that two vitamins were
present. McCollum's butter fat did contain one, and
we now call it vitamin A, or fat-soluble A. The one
in his lactose and in the milk was proven to be appar-
ently the anti-beri-beri type, and to reconcile the no-
menclature it was listed as Funk's vitamin or "uniden-
tified dietary factory water-soluble B."

By the time this tangle was ordered, the field of in-
vestigators had increased enormously and universal
recognition was now given to the idea that in addition to
nutrients of proper kind and quality, animals require
for their growth and maintenance at least two other
chemical substances hitherto unsuspected. It really

280 SCIENCE REMAKING THE WORLD

didn't matter much what these were called. We might
have adopted Hopkins' term, "accessory food factors,"
or McCollum's phrases, "unidentified dietary factors
fat-soluble A and water-soluble B," but Funk's term at
least provided brevity and by common consent these
factors have become vitamins A and B.

It now became fashionable to suspect diseases of
hitherto unknown cause to be matters of vitamin de-
ficiency. Scurvy had been known for years and its
prevention by the use of lime juice had earned a name
for the British mercantile navy of "lime juicers." Two
workers in Europe, Hoist and Frohlich, published in
the years 1907-1912 a series of brilliant studies which
appeared to demonstrate this disease to be due to the
absence of a specific vitamin, unlike the anti-beri-beri
type and carried in abundance by substances such as
lemon and orange juice. McCollum, however, re-
ported in 1918 certain observations on experimental
scurvy in guinea pigs which seemed to him to prove that
this disease was explicable as a result of the absorption
of toxic products from the intestines of the animals. A
new controversy arose. Partisans of the two views
arose also, but in time the truth confirmed the view-
point of Hoist and Frohlich and vitamin C was added
to the list. This matter was barely settled when a new
controversy began, this time over the causes of rickets.
Mellanby in England, working for the British Medical
Research Committee, arrived at a viewpoint which the
Committee published and to which they gave their
support. This view was in brief that vitamin A, in
which cod-liver oil is especially rich, is not only a growth

VITAMINS 281

factor and a preventive of eye disease as was already
demonstrated, but was also the factor which determined
the proper deposition of lime salts in bone formation.
Mellanby believed it to be entitled to the term anti-
rachitic vitamin. The whole problem of rickets and its
prevention was then reopened. Much valuable new
data developed. It was found possible to cure rickets
by regulation of the phosphorus in the diet, by using
the ultra-violet ray or direct sunlight and by the use ot
cod-liver oil in the diet. The vitamin interest, how-
ever, centred about the use of the oil. Butter fat,
known to be rich in A vitamin, was shown to be value-
less as a preventive. On the other hand cod-liver oil
was shown to be many times richer in A than butter
fat and it was felt that perhaps Mellanby was right and
that the distinction was a matter of quantity in the
dosage. In August, 1922, however, McCollum pub-
lished a series of studies which seem to leave no other
conclusion than that cod-liver oil owes its antirachitic
power to a new vitamin, that the antirachitic vitamin
is not vitamin A. For this McCollum suggests the
term D unless it shall be shown conclusively that vita-
min B is actually composed of at least two factors.
Funk has already offered evidence that the B concen-
trates contain a factor which is essential to the cure of
beri-beri and another factor that seems to have a
specific power in stimulating yeast growth. For the
latter he had already suggested the term vitamin D.
McCollum raises the question as to whether we should
include in the vitamin series other factors than those
proved of significance in mammalian nutrition. This

282 SCIENCE REMAKING THE WORLD

matter is purely a question of nomenclature and we
have at least satisfactory evidence to-day of five sub-
stances which were hitherto unrecognized in dietary
demands and which we consider entitled to names.
The list is probably still far from complete. Very re-
cently Evans and Bishop have shown that when rats
are fed on diets adequate in every known way and in-
cluding vitamins A, B, and C, they are often infertile.
The addition of lettuce to the diet prevents this sterility.
While the distribution of this fertility factor is still to be
worked out it is certain that they are dealing with a
hitherto unrecognized factor, perhaps the sixth vitamin.
These new substances so far as present knowledge is
concerned are all alike in being potent in very small
amounts and in defying chemical separation or identi-
fication except by physiological effects. It may well be
that when isolated in free form they will show similar
structure, but at present we have no data on which to
base even a reasonable guess in this direction.

The review preceding is essential to make clear ex-
actly the relation of the vitamin discovery to proper
food evaluation. Enough experimentation has been
carried out to date to show that these factors are wide-
spread in nature. The following table from the
author's Vitamin Manual will give a little idea of thii
widespread distribution:

VITAMINS

283

SOURCE OF VITAMINS

FOODSTUFF

Meats:

Beef heart . . .

Brains ....

Codfish

Fish roe

Herring ....

Kidney

Lean muscle

Liver ....

Pancreas . . .

Pig heart . . .
Vegetables:

Beet root . . .

Cabbage, fresh

Carrots

Cauliflower . .

Celery ....

Chard ....

Lettuce ....

Onions ....

Parsnips

Peas (fresh) . .

Potatoes . . .

Potatoes (sweet) .

Spinach
Cereals:

Barley . . . .

Bread (white^

Bread (whole meal)

Maize . . .

Oats . . .
Rice polished .
Rice (wbole grain)
Rye . .

Corn embryo .

+ In yellow
o In

284 SCIENCE REMAKING THE WORLD

FOODSTUFF

"A"

"B"

«c"

Cereals — Continued:

Corn (see maize) .

Malt extract

O

O

O

Wheat bran . .

O

+

0

Wheat embryo

+ +

+ + +

0

Wheat kernel . .

+

+H~f

O

Other seeds:

Beans, navy

+++

O

Cotton seed

+ +

+++

Peanuts

+

++

Peas (dry) . . .

•H

++

O

Fruits:

Apples ....

++

++

Bananas . . .

?

+

++

Grapefruit . . .

+++

+++

Grape juice . .

+

-f-

Grapes ....

O

+

+

Lemons ....

+++

++++

Limes ....

++

++

Oranges

+++

++++

Pears ....

++

++

Raisins ....

+

+

Tomatoes .

•f-r-

+++

4-+++

Oils and fats:

Beef fat . . .

+

0

0

Butter ....

+ + + +

0

0

Cocoanut oil

0

0

0

Cod-liver oil

+ +++

0

0

Corn oil ...

0

0

0

Cotton seed oil

0?

0

0

Egg yolk fat . .

++++

0

0

Fish oils . . .

++

0

0

Lard ....

0?

0

0

Oleo, animal

+

0

O

Oleo, vegetable

0

0

O

Olive oil ...

0

0

O

Pork fat . . .

0?

0

Tallow ....

O

0

0

VITAMINS

285

FOODSTUFP

"A"

"B"

"c"

Nuts:

Almonds

+

+ + +

Chestnut . .

+ + +

Cocoanut .

++

+ + +

English walnuts

+ + +

Hickory

+

+

+

Dairy products: .

Butter . . .

++++

0

0

Cheese .

++

+

?

Condensed milk

++

+

0

Cream . . .

-H-+

+

?

Eggs . • -,

++++

4~f

0

Milk powder (skim)

+

+++

+?

Milk powder (whole)

+++

+++

4-1

Milk whole . . .

+++

+4-4-

•H*

Miscellaneous:

Alfalfa . . a

+++

+++

?

Clover . .

+++

++++

?

Honey . ' .

++

0

Timothy

+4-

+++

Yeast cakes - .

o

4-f

o

It will also serve to point an important viewpoint
which needs special emphasis. When we select our
daily diet now we must of course include our quota of
vitamins. But in view of the small amounts essential,
bear in mind that this selection can be made without
going outside the usual list of foodstuffs. We need no
pills or nostrums. The slogan of a quart of milk a day
for the growing child is still good advice in more than its
original sense. In milk, vitamins A, B, C, and per-
haps D, are present in abundance. Green vegetables
and fruits supply the A and C lacking in a purely meat

286 SCIENCE REMAKING THE WORLD

and cereal diet. Look to your green stuffs. But let
us learn to pick our vitamins out of the food market and
there will be no need to go to the druggist.

A final word is perhaps desirable to explain the com-
pilation of a table such as shown above. How is such
information obtained ? No other discover}' emphasizes
more strikingly the value of animal experimentation
as a means of furthering human knowledge. Until
Eijkman discovered that beri-beri could be induced in
fowls, no tool was available for measuring quantita-
tively the amounts of the anti-beri-beri vitamin in
foodstuffs. The white rat has provided all the data
for distribution figures in regard to vitamin A and much
for B. To the guinea pig the race is indebted for the
proof of presence and quantity distribution of vitamin
C. If we can find an animal in which we can induce
pellagra, that controversy may be cleared up. In
brief, then, several methods of experimentation are
now in universal use in the study of vitamin nature or
distribution, but all are alike in principle. They all
consist in either feeding to the experimental animal a
diet lacking in a given factor and then attempting
cure by addition of the foodstuff under investigation,
or incorporating the foodstuff in the original diet in
varying amounts and noting the prevention or lack of
prevention of symptoms that follow. In all these diets
the principles laid down in our original list are utilized
and are essential if we are to be sure the results measure
vitamin deficiency.

We end then, as we began, with reiterating that the
vitamin hypothesis has not destroyed old ideas about

VITAMINS 287

food selection, but merely extended our bases for se-
lection. We continue to require calories, nutrients,
proper protein quality, but to these we must now add
vitamin content. Someone has compared vitamins
to the spark in the gasolene engine. It does not replace
the gas but makes it work. So in the animal mechanism
the fuel is food, but the food fails to function properly
without its controlling vitamins.

GUIDE TO FURTHER READING

"The Vitamine Manual," by Walter H. Eddy. (Williams & Wil-
kins, Baltimore, Md.)

"The Vitamines," by Casimir Funk. (Williams & Wilkins, Bal-
timore, Md.)

"The Vitamins," by H. C. Sherman and S. L. Smith. (Chemi-
cal Catalogue Co., New York City.)

"The Newer Knowledge of Nutrition," by E. V. McCollum.
(Macmillan, New York City.)

"Vital Factors of Foods," by C. Ellis and A. L. McLeod. (D. Van
Nostrand Co., New York City.)

"Vitamins," by Benj. Harrow. (E. P. Dutton, New York City.)

"Scurvy Past and Present," by A. F. Hess. (Lippincott's, Phila-
delphia, Pa.)

"Deficiency Diseases," by R. C. McCarrison. (Oxford Univ.
Press.)

Some Comprehensive Reviews:

"The Vitamins," by H. C. Sherman. Physiol. Reviews, 1921, i,
page 598.

Report on the Present State of Knowledge Concerning Acces-
sory Food Factors, British Medical Research Committee, pub. by H.
M. Stationery Office, London.

"The Vitamine, Bibliographic Review," by W. H. Eddy. Ab-
stracts Bacteriology, 1919? i"> page 313.

"Vitamins," by J. F. Lyman. Bull., vol. xviii, no. 3, of the
Ohio State University Agricultural Extension Service.

288 SCIENCE REMAKING THE WORLD

"Newer Aspects of Some Nutritional Disorders," by A. F. Hess.
/. Am. Med. Assn., vol. 76, page 693.

"The Etiology of Rickets," by E. A. Park. Physiol. Reviews,
1923, iii, page 106.

"Vitamins in Canned Foods," by E. F. Kohman. Nat'l Can-
ners' Asso. Bull. No. 19 L (1922).

"The Present Status of Vitamins," by K. Blunt. Journ. Home
Economics, 1921, xiii, page 97.

THE END

INDEX

Achievements and Obligations of

Modern Science, I
Alcohol, 42
Alfalfa Weevil, 197
Alizarin. 61
Alpha Particle, 81, 86
American Chemical Society, 19
American-Made Dyes, 71
Angell, James R., VII
Aniline Dyes, 51, 65
Anthrax, 141, 143
Ants, 203, 206
Appleman, Charles 0., 223
Argon, 89

Aromatic Compounds, 60
Arsphenamine, 65
Artificial Colours in Foodstuffs, 53
Aspirin, 66
Aston, F. W., 91
Atomic Weight, 92
Atomic Structure, 82
Atoms, 88
Atwater, W. O., 252
Australian Ladybird, 194
Automobile, 30, 36
Autumn Leaves, 70

Bacterial Origin of Diseases, 64, 103,

106,136,138

Bacterium Pneumosintes, 108
Bailie, 115
Bakelite, 73
" Bayer 105, "67
Bees, 200

Benedict, F. G., 252, 253
Benzene, 55, 60

Beri-Beri, 270, 280
Black Heart, 244
Blackleg, 236

Bonjean, 55

Botanical Gardens, 162

Boyle's Law, 22

Browning, 62

Browntail Moth, 194

Bureau of Entomology, 192, 106

Burton, W. W., 18

Butterflies, 200

By- Product Coke-Ovens, 57

Caldwell, Otis W., viii, 133

California White Scale, 194

Calories, 248, 255, 266

Carbohydrates, 266

Carbolic Acid, 58, 73

Carnegie Institution of Washington,

253

Cellulose, 268
Charles's Law, 22
Chemical Elements, 92
Chemical Warfare, 69
Chemistry and Economy of Food, 247
Chemotherapy, 65
China Medical Board, 158
China, Medical Schools in, 43
Chlorine, 91
Cholera, 64
Clemenceau, 25
Coal-Tar, 48, 69
Coal-Tar Compounds, 70
Coal-Tar Dye, 51, 52
Cod-Liver Oil, 280
Coke Ovens, 56
Columbia University, 33, 247, 261,

Conduction, 96

Congo, 37

Connecticut Agricultural Expcr*

imental Station, 257
Corn- Borer, 197

289

290 INDEX

Cotton Boll-Weevil, 195
Coulter, John M., 167
Creevy, 27
Curzon, 24

Darwin, Charles, 168, 173

Darwin, Erasmus, 172

Davis, 250

Degeneration of Potatoes, 225

Department of Agriculture, 192

DeVries, 175

Diphtheria, 66

Dirigible Balloons, 4

Disease Germs, 64, 103, 136

Drake, 14

Dunlop, 37

Eddy, Walter H., 258, 265
Educational Value of Modern Bo-
tanical Gardens, 162
Ehrlich, 65, 68
Eijkman, 271, 272, 286
Electricity, 80, 95
Electrons, 80

Electrons and How We Use Them, 78
Embryology, 170
Emerson, 181
Energy, 79

Energy Values of Food, 252
Epidemic Influenza, 99
Epidemics, 151
Evolution, 167

Expenditure on Motor Cars, 30
Experimental Study of Evolution,

*7S
Explosives, 4, 57, 58

Fats, 259
Fermentation, 136
Food, 247

Food Chemistry, 249
Food Production, 179
Food Supply, 261
Ford, Henry, 26, 36
Forest, 213, 220
Formaldehyde, 73
Fruits, 259, 285
runk, Casimir, 273

Gallieni, 24

Gas Engine, 24, 41

Gasolene as a World Power, 12, 17
Gates, Frederic L., 99
Giant Potato Plants, 225
Gipsy Moth, 194
Gliadin, 257
Goethe, 172

Helium, 4, 82, 84
Hermit Crabs, 205
History of Evolution, 168, 171
Honey-Bees, 202, 210
Hongkong School of Tropical Medi-
cine, 154

Hookworms, 67, 159
Hopkins, 250
House Fly, 190

How the Forests Feed the Clouds, 212
Howard, L. O., 190
Human Nutrition, 249
Humidity, 220
Hydrogen, 87
Hydrophobia, 145

Ichneumon, 208

Ideals of Science, 188

Immunity from Tuberculosis, 127

Indigo, 61

Industrial Revolution, 40

Influence of Coal-Tar on Civiliza-
tion, 48

Influenza, 99

Ions, 90

Insect Enemies, 192

Insect Sociology, 199, 210

Insects, 190

International Office of Hygiene, 155

International Public Health, 150,
159

International Sanitary Bureau, 15?

International Health Board, 159

Inventions, The Greatest, 28

Isotopes, 93

apanese Beetles, 197
enner, 142

ohns Hopkins University, 258
uvenal, 49

Kellogg, Vernon, 199
Kerosene, 18

INDEX

291

Kitchener, Lord, 58

Koch, Robert, 64, 68, 117, 123

Lamarck, 173
Leaf-Roll, 237
League of Nations, 155
Legislation Against Thinking, 6
Leopold of Belgium, 37
Lettuce, 282
Lime Juice, 280
Li pins, 266
Lister, 145

Louis Pasteur, and Lengthened Hu-
man Life, 133
Lurainal, 66

Macaulay, 28

Madder, 61

Maeterlinck, Maurice, 45

Malarial Fever, 65, 191

Marco Polo, 13

McCollum, 250, 276, 279

Meaning of Evolution, 167

Meat Consumption, 261

Meats, 259

Mendel, G., 250, 260, 275, 279

Mendel, Lafayette B., 257

Methanol, 5?

Methylene Blue, 66

Microbes, War Against, 63

Mills, John, 78

Milk, 259, 263, 269, 279, 285

Mineral Salts, 267

Modern Potato Problem, 223

Molecules, 84

Moore, George T., 162

Mosaic Disease, 236

Myrmica, 207

Naegeli, 123, 124

National Tuberculosis Association,

US

Nitrogen, 82, 84
Noguchi, 107
Novocain, 66

Nucleus of Atoms, 84, 85, 88
Nutrition Experiment*, 262

Oil, 42
Orthogenesis, 177

Osborne, Thomas B., 250, 255, 269

275, 279

Otto Gas Engine, 20
Our Daily Bread and Vitamins, 265
Our Fight Against Insects, 190
Our Present Knowledge of Tubercii"

losis, 115
Oxygen, 92

Pan American Union, 155
Parasites, 208, 235
Pasteur Institute, 154
Pasteur, Louis, vi, 133
Pasteurization, 137
Pear Thrips, 197
Perfumes, 54, 71
Perkin, W. H., 50
Petroleum, 41, 12
Pfeiffer's Bacillus, 100
Picric Acid, 73
Pine Bark-Beetles, 196
Phenol, 58, 73
Phonograph, 73, 75
Plant Lice, 204, 237
Potato Crop, 223
Potato Diseases, 233
Potato Improvement, 230
Potato Scab, 235
Potato Storage, 239
Potato Varieties, 229
Potato Wart, 235
Pott's Disease, 117
Precipitation, 221
Procaine, 66

Proton, 80, 259, 266, 267
Public Health, 151
Pulmonary Tuberculosis, 130

Rabies, 145

Radioactive Elements, 86, 95

Religion, 184, 188

Rice, 270

Rickets, 281

Road Construction, 39

Rockefeller Foundation. 158, 150

Rockefeller Institution for Medical

Research, 99, 102, 154
Rosa, 2C2

ul, Edmond, 46
Royal Purple, 62

292 INDEX

Rubber, 37

Rubber Plantations, 38

Rutherford, 86

Saccharin, 55

Salicylic Acid, 55

Salvarsan, 65

School of Tropical Medicine, 154

Scientific Spirit, 180

Scurvy, 280

Sea Anemone, 205

Seed Inspection, 227

Seneca Oil, 13

Shale Oil, 42

Sherman, Henry C., 247

Silkworms, 139

Sleeping Sickness, 67

Slosson, Edwin E., v, 12, 48

Smallpox, 142

Smith, Erwin S., 236

Smith-Noguchi Medium, 109

Smith, Theobald, 107

Social Wasps, 201

Soddy, 86, 93

Sodium, 89

Soft Drinks, 54

Spindling Disease, 238

Spontaneous Generation of Life, 136,

„ '39.

Spraying, 193

Standard Oil Company of Indiana, 19

Steam Engine, 19, 40

Stephenson, 27

Stepp, 276

St. Hilaire, 172

Sugar, 259

Symbiosis, 205

Synthetic Perfumes, 54, 71

Termites, 203
Thomson, J. J., 79, 91
Trinitrotoluene, 57

Trucks, 41

Trypanosomes, 67

Tsetse Fly, 191

Tubercle Bacilli, 65, 119, 125

Tuberculin, 123

Tuberculosis, 64, 115, 117

Typhoid, 3, 64

United States Department of Agri-
culture, 252, 253

United States Forest Service, 212
University of Maryland, 223
Uranium, 85, 93

Vaccination, 142

Vanadium, 37

Vegetables, 259, 285

Vestiges, 170

Vincent, George E., 150

Vinci, Leonardo da, 26

Vitamins, 229, 250, 258, 259, 265,

267, 270, 283
Von Behring, no
Von Kluck, 24, 58

Watt, 19

Wealth, 15

Wesleyan University, 252

Williams, Linsly R., 115

Wilson, 25

Wind Periodicity and Precipitation,

214

Winds, 216
Wintergreen, 55
Wheeler, 207

X-Rays, 95

Yellow Fever, 3, 191

Zon, Raphael, 112
Zoroastrians, 12