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H. P. TALBOT, PH.D., Sc.D., CONSULTING EDITOR

PROTEINS AND THE THEORY OF
COLLOIDAL BEHAVIOR

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PROTEINS

AND THE THEORY OF

COLLOIDAL BEHAVIOE

BY

JACQUES LOEB

MEMBER OF THE ROCKEFELLER INSTITUTE FOR MEDICAL RESEARCH

FIRST EDITION

McGRAW-HILL BOOK COMPANY, INC,
NEW YORK: 370 SEVENTH AVENUE

LONDON: 6 & 8 BOUVERIE ST., E, C, 4
1922

C\ , . A, P

COPYRIGHT, 1922, BY THE
MCGRAW-HILL BOOK COMPANY, INC.

T H K BI A V I, W I> R K S S YORK PA

PREFACE

Colloid chemistry has been developed on the assumption that
the ultimate unit in colloidal solutions is not the isolated molecule
or ion but an aggregate of molecules or ions, the so-called micella
of Naegeli. Since it seemed improbable that such aggregates
could combine in stoichiometrical proportions with acids, alkalies,
or salts, the conclusion was drawn that electrolytes were adsorbed
on the surface of colloidal particles according to a purely empirical
formula, Freundlich's adsorption formula.

The writer's investigations have led to the result that this last
conclusion is based on a methodical error, as far as the proteins
are concerned ; namely, to the failure to measure the hydrogen ion
concentration of the protein solutions, which happens to be one of
the main variables. When the hydrogen ion concentrations are
duly measured and considered, it is found that proteins combine
with acids and alkalies according to the stoichiometrical laws of
classical chemistry and that the chemistry of proteins does not
differ from the chemistry of crystalloids.

As long as chemists continue to believe in the existence of a
special colloid chemistry differing from the chemistry of crystal-
loids, it will remain impossible to explain the physical behavior
of colloids in general and of proteins in particular. This state of
affairs is reflected in the concluding remarks of Burton's interest-
ing book on "The Physical Properties of Colloidal Solutions"
published in 1920,

"We may very well conclude with the words used by the pioneer
worker Zsigmondy, in closing his first account of the early work on
colloidal solutions:

'From the foregoing outline no general theory of colloids can be
given, for the study of colloids has become a great and extensive science,
in the development of which many must assist; only when the volu-
minous material supplied by much physico-chemical research has been
properly systematized, will the theory of colloidal solutions be raised
from mere consideration of the similarities in special cases to the standing
of an exact science.'"

vi PREFACE

Professor F. G. Donnan, of the University of London, an-
nounced in 1910 an ingenious theory of equilibria which are
established when two solutions of electrolytes are separated by a
membrane which is permeable to all except one ion. This theory
was successfully applied by Procter and Wilson to the explana-
tion of the influence of electrolytes on the swelling of gelatin. It
will be shown in this volume that Donnan's theory of membrane
equilibria furnishes a quantitative and mathematical explanation
not only of swelling but of the colloidal behavior of protein solu-
tions in general ; namely, electrical charges, osmotic pressure, vis-
cosity, and stability of suspensions. Such an application of
Donnan's theory would have been impossible without the stoichio-
metrical proof that proteins form true ionizable salts with acids
and alkalies. What was at first believed to be a new type of chem-
istry, namely colloid chemistry, with laws different from those of
general chemistry, now seems to have been only an unrecognized
equilibrium condition of classical chemistry; at least as far as
the proteins are concerned. This does not detract from the
importance of colloidal behavior for physiological and technical
problems, but it completely changes the theoretical treatment of
the subject.

Any rival theory which is intended to replace the Donnan theory
must be able to accomplish at least as much as the Donnan
theory, i.e., it must give a quantitative, mathematical, and
rationalistic explanation of the curves expressing the influence
of hydrogen ion concentration, valency of ions, and concentration
of electrolytes on colloidal behavior; and it must explain these
curves not for one property alone but for all the properties,
electrical charges, osmotic pressure, swelling, viscosity, and
stability of solution, since all these properties are affected by
electrolytes in a similar way.

The contents of the book are divided into two parts, one fur-
nishing the proof of the stoichiometrical character of the reactions
of proteins, the second developing a mathematical and quantita-
tive theory of colloidal behavior on the basis of Donnan's theory
of membrane equilibria.

The theory of colloidal behavior, as outlined in this book, can
only be considered as a first approximation. Finer methods of
experimentation will have to be introduced, many minor dis-

PREFACE vii

crepancies will have to be accounted for, and many additions
made. It was, however, thought advisable to publish the book
for the reason that the experimental facts are accumulating so
rapidly that it is difficult for anyone to gather the leading ideas
unless they are presented more systematically and with less
detail than in the original publications. It was also thought
advisable to avoid in this volume a discussion of the possible
applications of the new theory to physiological and technical
problems.

The writer wishes to express his appreciation to his technical
assistants, Mr. M. Kunitz, and Mr. N. Wuest, for the skill and
careshown in the measurementsre quired for the experimental
part of the work.

The writer's thanks are also due to Dr. John H. Northrop,
Dr. D. I. Hitchcock, and Dr. Anne Leonard Loeb, who have read
part or all of the manuscript and offered valuable suggestions;
and to Dr. J. A. Wilson, who kindly read and revised the first
part of the chapter on swelling and suggested to the writer the
mathematical proof on page 143 of the book.

The writer is indebted to Miss N. Kobelt for the reading of
the proof and for the index.

JACQUES LOEB.
THE ROCKEFELLER INSTITUTE FOR

MEDICAL RESEARCH,

66rn STREET AND AVENUE A;

NEW YORK, N. Y.

March, 1922

CONTENTS

PAGE
PREFACE ; . V

PART I
Proof of the Stoichiometrical Character of the Reactions of Proteins

CHAPTER I
HISTORICAL INTRODUCTION ; 1

1. The Alleged Difference Between the Chemistry of Colloids and

of Crystalloids . . ; 1

2. The Isoelectric Point of Proteins 6

3. The Adsorption Theory and the Precipitation of Proteins . . 10

4. The Hofmeister Ion Series 13

5. The Aggregation Hypothesis 15

6. Pauli's Hydration Theory 17

7. Donnan's Membrane Equilibrium 19

CHAPTER II

QUALITATIVE PROOF OF THE CORRECTNESS OF THE CHEMICAL VIEW-
POINT. PREPARATION OF PROTEINS FREE FROM IONOQENIC
IMPURITIES 27

CHAPTER III

METHODS OF DETERMINING THE ISOELECTRIC POINT OF PROTEIN

SOLUTIONS 37

CHAPTER IV

QUANTITATIVE PROOF OF THE CORRECTNESS OF THE CHEMICAL VIEW-
POINT 40

CHAPTER V

THE VALENCY RULE AND THE HOFMEISTER SERIES 65

A. Osmotic Pressure _. 65

B. Swelling 76

C. Viscosity 82

ix

X CONTENTS

CHAPTER VI

PAGE
THE ACTION OF NEUTRAL SALTS ON THE PHYSICAL PROPERTIES OF

PROTEINS 88

1. The Difference in the Effect of Acids, Alkalies, and Salts on

Proteins 88

2. Ion Series and the Action of Salts on Proteins 99

CHAPTER VII

THE INADEQUACY OF THE PRESENT THEORIES OF COLLOIDAL BEHA-
VIOR 112

PART II

Theory of Colloidal Behavior Based on Donnan's Theory of Membrane

Equilibria

CHAPTER VIII

MEMBRANE POTENTIALS 120

The Influence of the Hydrogen Ion Concentration of Gelatin

Solutions on the P.D 126

The Explanation of the P.D. Curve 127

The Valency Effect 132

Hydrogen Ion and Chlorine Ion Potentials 135

The P.D. of Na Gelatinate 137

The Influence of Neutral Salts on the P.D. of Gelatin Chloride

Solutions 139

The Influence of the Sign of Charge 144

The Influence of the Concentration of Protein on the P.D ... 145

The P.D. of Solutions of Crystalline Egg Albumin 145

CHAPTER IX

THE ORIGIN OF THE ELECTRICAL CHARGES OF MICELLES, AND OF

LIVING CELLS AND TISSUES 150

1. Stability of Suspensions, Electrical Charge of Micellae, and

Donnan Equilibrium 150

2. The Electrical Charge of Suspended Particles of Powdered

Gelatin 152

3. The Influence of pH on the Charge of Suspended Particles of

Powdered Gelatin 155

4. The Influence of Acid and Alkali on the Sign of Charge of

Micellae 155

5. The Influence of Salts on the Charge of Suspended Particles of

Gelatin . 157

6. The Origin of the Electrical Charges of Living Cells and Tis-

sues. . 166

CONTENTS xi

CHAPTER X

PAGE

OSMOTIC PRESSURE . . 169

1. Theoretical Statements 169

2. The Calculated Curves for the Influence of pH and Valency . 172

3. The Influence of the Addition of Salts 179

4. The Influence of the Concentration of a Protein Solution upon

the Osmotic Pressure 184

CHAPTER XI
SWELLING 189

CHAPTER XII

VISCOSITY 195

CHAPTER XIII

A RECIPROCAL RELATION BETWEEN THE OSMOTIC PRESSURE AND THE

VISCOSITY OF GELATIN SOLUTIONS 232

CHAPTER XIV

THE STABILITY OF PROTEIN SOLUTIONS 243

A. The Stability of Aqueous and Alcoholic Solutions of Gelatin . 243

CHAPTER XV

THE STABILITY OF PROTEIN SOLUTIONS (CONTINUED) 266

B. The Stability of Solutions of Casein in Water 266

CHAPTER XVI

COLLOIDAL SUBSTANCES, COLLOIDAL STATE, AND COLLOIDAL BEHA-
VIOR . .... 275

INDEX. 287

PROTEINS

AND

THE THEORY OF
COLLOIDAL BEHAVIOR

CHAPTER I
HISTORICAL INTRODUCTION

1. THE ALLEGED DIFFERENCE BETWEEN THE CHEMISTRY OF
COLLOIDS AND OF CRYSTALLOIDS

The distinction between crystalloids and colloids was proposed
by Graham in 1861, the crystalloids being characterized by a
tendency to form crystals when separating from a watery solu-
tion, and the colloids by a tendency to separate out in the form
of " gelatinous" (or amorphous) masses. Graham found that
these two groups of substances differ also in two other respects,
first, in their " diffusive mobility/' and second, in a peculiar
'" physical aggregation." The crystalloids diffuse readily through
different kinds of membranes (e.g., pig's bladder, parchment)
through which colloids can diffuse not at all or only very slowly.
The second peculiarity is the tendency of the colloids to form
aggregates when in solution while this property is lacking or less
pronounced in crystalloids. A brief quotation from a paper by
Graham will illustrate these definitions:

" Among the latter [i.e., the substances with low order of diffusibility]
are hydrated silicic acid, hydrated alumina, and other metallic peroxides
of the aluminous class, when they exist in the soluble form; and starch,
dextrin and the gums, caramel, tannin, albumen, gelatine, vegetable and
animal extractive matters. Low diffusibility is not the only property
which the bodies last enumerated possess in common. They are
distinguished by the gelatinous character of their hydrates. Although

1

2 THEORY OF COLLOIDAL BEHAVIOR

often largely soluble in water, they are held in solution by a most feeble
force. They appear singularly inert in the capacity of acids and bases,
and in all the ordinary chemical relations.1 But, on the other hand,
their peculiar physical aggregation with the chemical indifference
referred to, appears to be required in substances that can intervene in
the organic processes of life. The plastic elements of the animal body
are found in this class. As gelatine appears to be its type, it is proposed
to designate substances of the class as colloids, and to speak of their
peculiar form of aggregation as the colloidal condition of matter. Opposed
to the colloidal is the crystalline condition. Substances affecting the
latter form will be classed as crystalloids. The distinction is no doubt
one of intimate molecular constitution."2

It is therefore obvious that there are according to Graham at
least two essential differences between colloids and crystalloids,
the difference in diffusion through membranes, and the difference
in the tendency to form aggregates in solutions. We shall see
in this volume that the chief if not all the characteristics of
colloidal behavior can be explained mathematically from the
difference in diffusibility between colloids and crystalloids, while
the tendency of the protein molecules to form aggregates plays
only an indirect role, namely, by immobilizing one kind of ions
without interfering with the mobility of other ions.

In modern colloid chemistry it has, however, become custom-
ary to consider the tendency of colloids to form aggregates as
the fundamental property, for the reason that the precipitation
of colloids was the chief topic of research and discussion in
colloid chemistry, and precipitation is, of course, due to the
formation of aggregates. The colloidal state is defined by colloid
chemists as that state of matter in which the ultimate units in
solutions are no longer isolated molecules or ions, but aggregates
of molecules for which Naegeli had introduced the term micella
(small crumb). Thus Zsigmondy states,

"that the essential and characteristic constituents of colloidal solutions
are very small ultramicroscopic particles the dimensions of which lie
between molecular and microscopic size. . . . These ultramicroscopic

1 This is no longer correct, as we shall see.

2 GRAHAM, T., Phil Trans., pp. 183-224, 1861. Reprinted in "Chemical
and Physical Researches," p. 553, Edinburgh, 1876.

HISTORICAL INTRODUCTION 3

particles (ultramicrons) have the same significance for colloidal solutions
as the isolated molecules have for crystalloidal solutions."1

The idea that the ultimate unit of the colloidal solution is not
the molecule or ion of the solute but an aggregate induced colloid
chemists to propose a new type of chemistry in which the laws of
classical chemistry were replaced by laws peculiar to colloid
chemistry. It seemed improbable to them that the stoichio-
metrical laws of classical chemistry should hold for colloidal
solutions in which the ultimate units were larger aggregates of
molecules, since they argued that only the surface of such aggre-
gates should be capable of reacting with other substances. The
stoichiometrical relations valid in classical chemistry were as a
consequence replaced in colloid chemistry by an empirical
formula, Freundlich's so-called adsorption formula, which was
supposed to account for surface action.2 Recent investigations
by Langmuir3 have furnished the proof that Freundlich's adsorp-
tion formula does not hold for the reaction of gases with mica,
glass, and platinum possessing a smooth surface, and Langmuir
was able to show that the forces which act in these cases are the
purely chemical forces of primary or secondary valency. Like
most empirical formulas the adsorption formula may hold within
a limited range of observations, but not throughout the whole
range of variation, and Langmuir states that this was also true
for the adsorption formula in his experiments.

John A. Wilson and Wynnaretta H. Wilson4 have made a most
important contribution towards the question of the applicability
of the adsorption formula to colloidal problems, in which they
were also led to a rejection of the adsorption formula and to the
adoption of a purely chemical interpretation. Their discussion
is based on the experiments of Procter and Wilson on gelatin
and the facts to be given in this book fully support their skeptical
attitude towards the adsorption formula.

Even if we assume that the protein solutions contain no free
protein ions or molecules — which is contradicted by the experi-

1 ZSIGMONDY, R., "Kolloidchemie," 2nd ed., Leipsic, 1918.

2 FREUNDLICH, H., " Kapillarchemie," Leipsic, 1909.
'LANGMUIR, I., J. Am. Chem. Soc., vol. 40, p. 1361, 1918.

4 WILSON, J. A. and WILSON, W. H., J. Am. Chem. Soc., vol. 40, p. 886,
1918.

4 THEORY OF COLLOIDAL BEHAVIOR

ments on potential difference and osmotic pressure to be dis-
cussed later — such an assumption does not lead to the idea that
chemical reactions occur only at the surface of the micellae for
the simple reason that solid gels of proteins (e.g., of gelatin) are
easily permeable to acids, alkalies, and salts or to crystalloids in
general. Chemical reactions are, therefore, not restricted to the
surface of protein micellse.

While a number of authors, like Bugarszky and Liebermann,1
Osborne,2 Robertson,3 Pauli,4 and others assumed that the reac-
tions of proteins are purely chemical, this assumption could not
be proved conclusively until the modern methods of measuring
the hydrogen ion concentration of protein solutions were
developed by Friedenthal, S^rensen,5 Michaelis,6 Clark,7 and
their collaborators. On the basis of these methods it was easy
to demonstrate the purely stoichiometrical character of the
combination of proteins with acids and alkalies.

Thus it was proved that gelatin combines with acids only when
the hydrogen ion concentration of the solution is above a certain
critical point, namely greater than N/50,000 (or pH = 4.7).*
At hydrogen ion concentrations above N/50,000, H3PO4 dis-
sociates as a monobasic acid. Hence, if gelatin combines stoichio-
metrically with acids it should require three times as many
cubic centimeters of 0.1 N H3PO4 as it requires cubic centimeters
of 0.1 N HC1 or HNO3 to bring 1 gm. of gelatin in 100 cc. solution
from a hydrogen ion concentration of N/50,000 to that of, e.g.,
N/1,000. The strong acid H2SO4 dissociates, however, in this

1 BUGARSZKY, S. and LIEBERMANN, L., Arch. ges. PhysioL, vol. 72, p. 51,
1898.

2 OSBORNE, T. B., Die Pflanzenproteine : Ergeb. PhysioL, vol. 10, p. 47,
1910.

3 ROBERTSON, T. B. "The Physical Chemistry of the Proteins," New York,
London, Bombay, Calcutta, and Madras, 1918.

4 PAULI, W., Fortschr. naturwiss. Forschung, vol. 4, p. 223, 1912. "Kol-
loidchemie der Eiweisskorper," Dresden and Leipsic, 1920.

6 S0RENSEN, S. P. L., see Bibliography given in W. M. CLARK, "The
Determination of Hydrogen Ions," Baltimore, 1920.

6 MICHAELIS, L., "Die Wasserstoffionenkonzentration," Berlin, 1914.

7 CLARK, W. M., "The Determination of Hydrogen Ions," Baltimore,
1920.

8 LOEB, J., J. Gen. PhysioL, vol. 3, p. 85, 1920-21. Science, vol. 52, p. 449,
1920. J. chim. physique, vol. 18, p. 283, 1920.

HISTORICAL INTRODUCTION 5

range of hydrogen ion concentration as a dibasic acid and hence, it
should require as many cubic centimeters of 0.1 N H2SO4 as it
requires cubic centimeters of 0.1 N HC1 to bring the same 1 per
cent solution of gelatin from a hydrogen ion concentration of
N/50,000 to one of N/1,000. Titration experiments proved the
correctness of these and similar conclusions, not only in the case
of gelatin but also of other proteins, thus leaving no doubt that
proteins combine with acids or alkalies according to the stoichio-
metrical laws of general chemistry.1

It was merely an unfortunate historical accident that the
colloidal behavior of proteins was investigated before the con-
venient methods of measuring the hydrogen ion concentration
were developed; otherwise, we should probably never have heard
of the idea that the chemistry of colloids differs from the chemistry
of crystalloids, at least as far as the proteins are concerned. It
was this methodical error of not measuring the hydrogen ion
concentration of colloidal solutions and of gels which prevented
the development of an exact theory of colloidal behavior and
which gave rise to the statement of Zsigmondy quoted in the
preface.

The reason that measurements of the hydrogen ion concentra-
tion are paramount for the understanding of the chemical and
physical behavior of the proteins lies in the fact that proteins are
amphoteric electrolytes capable of forming ionizable salts with
acids as well as with alkalies, according to the hydrogen ion
concentration. When the hydrogen ion concentration exceeds a
certain critical value (which varies for different proteins) the
protein behaves as if it were a base, like NH3, capable of forming
salts with acids; while when the hydrogen ion concentration of
the solution is below this critical value the protein behaves as
if it were a fatty acid, e.g., CH3COOH, capable of forming salts
with bases. At the critical value of the hydrogen ion concentra-
tion the protein can practically combine neither with an acid nor
a base nor a neutral salt.2 This critical hydrogen ion concen-
tration is called the " isoelectric " point of the protein. More-
over, we shall see that the fraction of 1 gm. of originally isoelectric

1 LOEB, J., J. Gen. Physiol, vol. 3, pp. 85, 547, 1920-21.

2 LOEB, J., J. Gen. Physiol., vol. 1, pp. 39, 237, 1918-19. Science, vol. 52,
p. 449, 1920, /. chim. physique, vol. 18, p. 283, 1920.

6 THEORY OF COLLOIDAL BEHAVIOR

protein in 100 c.c. solution capable of combining with an acid or
alkali, is also a definite function of the hydrogen ion concentration.

2. THE ISOELECTRIC POINT OF PROTEINS

The conception of the "isoelectric point" of proteins was
introduced before its chemical meaning was recognized and it
attracted attention because it was connected with the precipita-
tion of colloids, a phenomenon on which the interest of a number
of investigators had been focussed. The conception of the
isoelectric point of proteins, which is due to W. B. Hardy,1
must be considered as the starting point for the physical chem-
istry of proteins. This author found in 1899 that white of egg
diluted with eight or nine times its volume of distilled water,
filtered, and boiled when put into an electrical field migrated
in an opposite direction according to whether the reaction of the
fluid was acid or alkaline. When the fluid had an alkaline
reaction, the particles moved in an electrical field from the
cathode to the anode; when the fluid was acid, the direction of the
motion of the particles was the reverse, namely, from the anode
to the cathode; when the fluid was neutral the movement of the
particles under the influence of a current was so slight that it was
difficult to detect.

"I have shown that the heat-modified proteid is remarkable in that its
direction of movement [in an electric field] is determined by the reaction
acid or alkaline, of the fluid in which it is suspended. An immeasurably
minute amount of free alkali causes the proteid particles to move against
the stream while in presence of an equally minute amount of free acid
the particles move with the stream. In the one case therefore the
particles are electro-negative, in the other they are electro-positive.
Since one can take a hydrosol in which the particles are electro-negative
and, by the addition of free acid, decrease their negativity, and ulti-
mately make them electro-positive it is clear that there exists some
point at which the particles and the fluid in which they are immersed
are isoelectric.

"The isoelectric point is found to be one of great importance. As it
is neared the stability of the hydrosol diminishes until, at the isoelectric
point, it vanishes, and coagulation or precipitation occurs, the one or the
other according to whether the concentration of the proteid is high or

1 HARDY, W. B., Proc. Roy. Soc., vol. 66, p. 110, 1900.

HISTORICAL INTRODUCTION 7

low, and whether the isoelectric point is reached slowly or quickly,
and without or with mechanical agitation."

In a preliminary note1 on his work on globulins published in
1903 Hardy gives an interpretation of the influence of H and OH
ions on the direction of migration of protein particles in an
electrical field which was destined to play an important role in
colloid chemistry, since it suggested to the later workers that the
H and OH ions produced their influence on the electrical charge of
the protein particles through a process of adsorption.

"The properties of globulins in solution seem to justify the following
view: They are not embraced by the theorem of definite and multiple
proportions. Therefore they are conditioned by purely chemical forces
only in a subsidiary way. A precipitate of globulin is to be conceived
not as composed of molecular aggregates but of particles of gel. I have
shown elsewhere that gelation and precipitation of colloidal solutions
are continuous processes. These particles of gel when suspended in a
fluid containing ions are penetrated by those ions. Let the fundamental
assumption be that the higher the specific velocity of an ion the more
readily it will become entangled within the colloidal particle. Then
as H and OH ions have by far the highest specific velocity the colloidal
particle will entangle an excess of H ions in acid and thereby acquire a
+ charge and of OH ions in alkali and thereby acquire a — charge.
These charges will decrease the surface energy of the particle and
thereby lead to changes in their average size."

Perrin adopted the idea that H and OH ions confer their
electrical charge to colloidal particles on account of their rela-
tively large velocity of migration, whereby they were readily
adsorbed by the colloidal particle. The hypothesis of a prefer-
ential adsorption of H and OH ions by colloidal particles has
since played a great role in colloid chemistry.

In 1904 the writer of this volume offered instead of this colloidal
a purely chemical view of the significance of the isoelectric
point and of the cause of the influence of acids and alkalies on
the direction of the migration of the colloidal particles.2

"It seems to the writer, however, that a different view of these
phenomena is possible whereby they appear in harmony with the view
of electrolytic origin of the charges of colloids. The proteids are known

1 HARDY, W. B., J. Physiol., vol. 29, p. 29, 1903.

2 LOEB, J., Univ. of Cal Publications, Physiology, vol. 1, p. 149, 1904.

8 THEORY OF COLLOIDAL BEHAVIOR

to be amphoteric in their reaction. If they be slightly dissociable they
will send H as well as OH ions into the solution. When the particles
send more H ions than OH ions into the solution they will have a
negative charge while they will have a positive charge when more OH
ions are given off than H ions. If acid is added to the solution in suffi-
cient concentration the amphoteric colloidal particle will send more OH
ions into the solution than H ions and hence, will assume a positive
charge. The reverse will be the case in an alkaline solution. It
harmonizes with this idea that, as Hardy found, neutral salts do not
influence the sign of the electrical charge of the globulins."

We shall see later on that this suggestion explains the source of
the electrical charge of isolated protein ions but explains only
indirectly the charge of larger aggregates.

In his famous paper on " Colloidal Solution" published in
1905, Hardy1 abandons the physical view which he expressed in
1903 and adopts "a frankly chemical standpoint."

" Globulin therefore is an amphoteric substance and its acid function
is much stronger than its basic function. As an acid it is strong enough
to form salts readily with bases so weak as aniline, glycocoll, and urea;
acting as a base it forms salts with weak acids, such as acetic, and boracic
acids, which are very unstable in presence of water."

While Hardy accepts the idea of an electrolytic origin of the
charges of proteins, he does not seem to be ready to concede that
the reactions of proteins with acids and alkalies are purely
stoichiometric, as the following quotations indicate.

" Though one may speak of the colloid particles as being ionic in
nature they are sharply distinct from true ions in the fact that they are
not of the same order of magnitude as are the molecules of the solvent,
the electric charge which they carry is not a definite multiple of a fixed
quantity and one cannot ascribe to them a valency, and their electrical
relations are those which underlie the phenomena of electrical endosmose.
To such ionic masses I would give the name 'pseudo-ions' and I propose
to treat globulin solutions from the standpoint of a hypothesis of
'pseudo-ions.'2

And in 1910 Wood and Hardy3 express the view that proteins

1 HARDY, W. B., J. Physiol., vol. 33, p. 251, 1905-06. See also,
HARDY, W. B., Proc. Roy. Soc., vol. 79, p. 413, 1907.

2 HARDY, W. B., J. Physiol., vol. 33, pp. 256-257, 1905-06.

3 WOOD, T. B. and HARDY, W, B., Proc, Roy. Soc., vol 81, p. 38, 1909,

HISTORICAL INTRODUCTION 9

"react with acids and alkalies to form salts, but the reactions are not
precise, an indefinite number of salts of the form (B)«BHA being formed
where the value of n is determined by conditions of temperature and
concentration, and of inertia due to electrification of internal surfaces
within the solution."

There are two elements in this view which should be separated.
The suggestion that the electrical charges of the micellae are not
"a definite multiple of a fixed quantity" harmonizes with the
results to be given later. The other suggestion, however, "that
the reactions are not precise" seems to be contradicted by the
stoichiometrical facts to be enumerated in the fourth chapter.

When the methods of measuring the hydrogen ion concentra-
tion had been developed by H. Friedenthal and by S^rensen it
became possible to determine the isoelectric point of genuine
proteins. This was first done by Michaelis and his collaborators
in 1910. Michaelis used the same method of migration of the
particles in an electrical field which had been used by Hardy.
The isoelectric point is, according to Michaelis, that hydrogen
ion concentration at which the particles migrate neither to the
anode nor to the cathode. The following figures give the
hydrogen ion concentrations defining the isoelectric points of
different proteins as determined by Michaelis.1

Genuine serum albumin 2 X 10~5N

Genuine serum globulin 4 X 10~6N

Oxyhemoglobin 1.8 X 10~7N

Gelatin 2 X 10~5N

Casein 2 X 10~6N

According to S^rensen the isoelectric point of crystalline egg
albumin is near that of serum albumin (namely, at a pH of 4.8). 2

We shall denote in this book the hydrogen ion concentration
by S^rensen's logarithmic symbol pH; e.g., the concentration
2 X 10~5N = 10~4-7N is written merely pH 4.7, the minus sign
being omitted.

If we assume that the ultimate units of a protein solution are
as a rule isolated protein molecules or ions which react stoichi-

1 MICHAELIS, L., "Die Wasserstoffionenkonzentration," p. 54 ff, Berlin,
1914.

2 S0RENSEN, S. P. L., Studies on proteins: Compt. rend. trav. Lab. Carls-
berg, vol. 12, Copenhagen, 1915-17.

10 THEORY OF COLLOIDAL BEHAVIOR

ometrically with acids and alkalies, forming highly dissociable
metal proteinates or protein-acid salts, we may define the iso-
electric point of a protein as that hydrogen ion concentration
in which the protein exists practically in a non-ionogenic (or non-
ionized) condition being able to form practically neither metal
proteinate nor protein-acid salt. We shall see that this theo-
retical result leads to a simple practical method of preparing
proteins entirely or practically free from ionogenic impurities.
The fact that solutions and suspensions of proteins are least
stable at the isoelectric point is then connected with the purely
chemical fact that proteins are amphoteric electrolytes which
exist at their isoelectric point in the form of practically non-
ionizable protein molecules.

3. THE ADSORPTION THEORY AND THE PRECIPITATION OF

PROTEINS

The interest of most investigators of colloidal phenomena was
centered on the precipitation of colloids, especially in those cases
where the precipitation required low concentrations of electro-
lytes. The explanation accepted by the majority of authors is
based on the assumption of an adsorption of ions by the colloid.

Hardy explained his discovery that proteins are most easily
flocculated from their solutions at the isoelectric point by the
fact that at that point the electrical charges of the protein particles
are a minimum, a conclusion derived from his observation that at
the isoelectric point proteins do not migrate in an electrical
field. He concluded from this that the stability of colloidal
solutions is due to the potential difference between each colloidal
particle and the surrounding liquid. In this state the charged
particles must repel each other with the result that they become
evenly distributed through the solvent. When the charge is
annihilated or sufficiently diminished "the adhesion or 'idio-
attraction' as Graham called it, of the colloid particles for each
other makes them cohere where they come together."1 He
originally assumed the positive charge of the particles in the
acid solution to be due to a preferential adsorption of H ions
and the negative charge in the presence of alkali to the adsorption

1 WOOD, T. B. and HARDY, W. B., Proc. Roy. Soc., vol. 81, p. 41, 1909.

HISTORICAL INTRODUCTION 11

of OH ions. Later he abandoned this view, which, however,
is still held by many chemists.

Another explanation of the coalescence of the particles which
have lost their electrical charge was given by Bredig on the basis
of surface tension changes. The surface tension at the boundary of
a micella and water is diminished when the particles are elec-
trically charged and reaches a maximum when the charge is
annihilated. Since at the isoelectric point the electrical charges
of the particles are nil the surface tension at the boundary of
particles and water must be a maximum and as a consequence
two isoelectric particles upon coming in contact are forced to
coalesce; while the particles will not coalesce when the surface
tension is low.1

It is, however, doubtful whether the coalescence of the non-
charged colloidal particles is due to surface tension effects.
Zsigmondy2 points out that Powis'3 observations on the precipi-
tation of droplets of oil emulsion by salts make it more probable
that the coalescence is due to forces of attraction between the
droplets, since in commencing flocculation the individual oil
globules only adhere to each other without coalescing into larger
droplets.

Colloids can, however, be flocculated by salts even if their solu-
tion is not at the isoelectric point. In this case Hardy assumes
that the addition of the salt lowers the potential difference
between the colloidal particle and the solvent. Schulze, Linder
and Picton, as well as Hardy4 had found that the ion which is
responsible for the flocculation has always the opposite sign of
charge to the colloidal particle, and moreover, that the coagulative
power of the ion increases rapidly with its valency.5 This rule
was considered to strengthen the adsorption theory.

It was assumed that the micellse possess an electrical charge

1 MICHAELIS, L., "Die Wasserstoffionenkonzentration," pp. 49-50, Berlin,
1914.

2 ZSIGMONDY, R., "Kolloidchemie," 2nd ed., p. 63, Leipsic, 1918.

3 Powis, F., Z. physik. Chem., vol. 89, pp. 91, 179, 186, 1915.

4 HARDY, W. B., Proc. Roy. Soc., vol. 66, p. 110, 1900, J. Physiol, vol.
33, p. 251, 1905-06.

6 For the details and the literature see BURTON, E. F., "The Physical
Properties of Colloidal Solutions," 2nd ed., London, New York, Bombay,
Calcutta, and Madras, 1921.

12 THEORY OF COLLOIDAL BEHAVIOR

which will cause them to " adsorb" most readily those ions of an
electrolyte which have the opposite sign of charge from the
colloidal particle. This adsorption is supposed to annihilate the
charge of the particles causing them to coalesce. The higher the
charge of the ion the more readily it is adsorbed; and this is
presumed to explain why the flocculating action of ions increases
with their valency.1

The hypothesis that the electrical charges of micellae of proteins
are diminished or annihilated by the preferential adsorption of
the ions of a salt rests on no measurements and the hypothesis
has never advanced beyond the stage of vague qualitative specu-
lation. Such speculations would never have been accepted or
considered if it were not for the fact that there existed no direct
measurements of the charges of suspended protein particles.
The writer found a method of directly measuring the P.D. between
protein particles and surrounding liquid, and was thus able to
follow minutely the influence of the hydrogen ion concentration
and of the addition of salts on the P.D.2 The quantitative data
thus gained made it possible to investigate the origin of the
P.D. and it was found that this P.D. is due to the fact that proteins
form ionizable salts with acids and bases. Whenever protein
ions are prevented from diffusing through membranes or gels
permeable to crystalloidal ions, peculiar equilibrium conditions
are established resulting in an unequal distribution of the
oppositely charged crystalloidal ions between colloidal particle
and surrounding liquid. This unequal distribution of oppositely
charged ions leads to the P.D. at the boundary of micellae and
surrounding liquid. It is possible to explain mathematically,
from Donnan's equation for such membrane equilibria, the influ-
ence of acids, alkalies, and neutral salts on the charges of the
micellae, and it can be shown that the observed P.D. agrees
quantitatively with that calculated from the equilibrium equation.
It thus turns out that the explanation of the annihilation of the

1 For a full presentation of the adsorption theory the reader is referred to
BANCROFT, W. D., " Applied Colloid Chemistry," New York, London, 1921,
in this series, and to LEWIS, W. C. McC., "A System of Physical Chemistry,"
2nd ed., vol. 1, p. 346, London, New York, Bombay, Calcutta, and Madras,
1920.

aLoEB, J., J. Gen. PhysioL, vol. 3, p. 667, 1920-21; vol. 4, p. 351, 1921-22.

HISTORICAL INTRODUCTION 13

charges of micellae by neutral salts depends on the fact that
proteins combine stoichiometrically with acids and alkalies
forming true ionizable salts. The agreement between calculated
and observed values is so close that there is neither any need nor
room for speculations on adsorption, unless it can be shown that
the adsorption hypothesis furnishes an equally good mathematical
and quantitative agreement between observed and calculated
P.D.

4. THE HOFMEISTER ION SERIES

Hofmeister1 was the first to investigate the effects of different
salts on the physical properties of proteins. He and his followers
observed that the relative effects of anions on the precipitation,
the swelling, and other properties of proteins seemed very definite
and that the anions could be arranged apparently in definite
series according to their relative efficiency, the order being
independent of the nature of the cation. Similar series were also
found for the cations, though these series seemed to be less
definite. These Hofmeister series were a puzzle to those who
accepted the chemical viewpoint of the behavior of proteins, inas-
much as it was impossible to discover in these series a relation to
the typical combining ratios of the ions.

To illustrate this we will quote the order which, according to
Pauli,2 represents the relative efficiency of different acids on the
viscosity of blood albumin,

HC1 > monochloracetic > oxalic > dichloracetic >
citric > acetic > sulphuric > trichloracetic acid,

where HC1 increased the viscosity most and trichloracetic or
sulphuric least. In this series the strong monobasic acid HC1 is
followed by the weak monochloracetic acid, this is followed by
the dibasic oxalic acid ; later follows the weak tribasic citric acid,
then the very weak monobasic acetic acid, then the strong dibasic
sulphuric acid, and finally again a monobasic acid, trichloracetic.
According to Hofmeister, gelatin swells more in chlorides,

1 HOFMEISTER, F., Arch. exp. Path. u. Pharm., vol. 24, p. 247, 1888;
vol. 25, p. 1, 188&-89; vol. 27, p. 395, 1890; vol. 28, p. 210, 1891.

2 PAULI, W., Fortschr. naturwiss. Forschung, vol. 4, p. 223, 1912.

14 THEORY OF COLLOIDAL BEHAVIOR

bromides, and nitrates than in water, while in acetates, tartrates,
citrates, or sugar it swells less than in water. R. S. Lillie1 arranges
ions according to their depressing effect on the osmotic pressure
of gelatin solution in the following way:

Cl>S04>N03>Br>I>CNS

These series2 again betray no relation to the stoichiometrical
properties of the ions. As long as these Hofmeister ion series
were believed to have a real existence it seemed futile to decide
for or against a purely chemical theory of the behavior of colloids
since even with a bias in favor of a chemical theory the Hof-
meister series remained a riddle.

The writer believes that he has removed these difficulties by
using protein solutions of equal hydrogen ion concentration as
the standard of comparison.

In this way it was found that a number of authors had errone-
ously attributed the effects of an alteration of the hydrogen ion
concentration upon the physical properties of a protein to a
difference in the specific action of the anion or cation added.
Thus it was always believed that acetates have almost as great a
"dehydrating" action as sulphates, but it was overlooked that
acetic acid is a weak acid, and that in the experiments referred to
the authors failed to compare the effects of SO4 and CH3COO at
the same hydrogen ion concentration. When this error is
avoided it can be shown that acetates influence the swelling,
osmotic pressure, and viscosity of protein solutions in the same
way as chlorides or nitrates, but not in the same way as sulphates;
in other words, anions of the same valency act alike.3

By taking into consideration the hydrogen ion concentration
it was possible to show that the assumption of specific differences
in the action of different ions of the same valency and sign of
charge was due to a methodical error; and that the Hofmeister
rule must be replaced by a simple valency rule, according to
which only the valency and sign of charge of an ion influence the
colloidal behavior of a protein but that the other properties of

1 LILLIE, R. S., Am. J. PhysioL, vol. 20, p. 127, 1907-08.

2 A fuller discussion of these series is found in HOBER, R., " Physikalische
Chemie der Zelle und der Gewebe," Leipsic and Berlin, 1914.

3LoEB, J., J. Gen. Physiol, vol. 3, p. 391, 1920-21.

HISTORICAL INTRODUCTION 15

the ion have no influence as long as no constitutional change in
the protein molecule occurs.

This fact established a complete harmony between the results
of the titration experiments and the influence of ions on the phys-
ical properties of gelatin. In the titration experiments it had
been found that at a hydrogen ion concentration of above 2 X
10~5N weak dibasic or tribasic acids generally combine with a
protein as if they were entirely or chiefly monobasic. Hence, the
anions of the protein salts formed with these weak dibasic or
tribasic acids, e.g., phosphoric, citric, tartaric, succinic, were
monovalent, and it was found that the osmotic pressure or
viscosity of solutions of protein phosphates were the same as
those of protein chlorides for the same hydrogen ion concentration
and the same concentration of originally isoelectric protein.

On the other hand, the titration experiments showed that the
anion of protein sulphate is dibasic and it was found that the os-
motic pressure and viscosity of protein sulphate is less than one-half
of that of protein chloride or phosphate or succinate, etc., at the
same hydrogen ion concentration and the same concentration
of originally isoelectric protein.1

In this way the influence of ions on the physical properties of
proteins, especially in the case of gelatin, turned out to be in
harmony with the results of titration experiments. In the case of
gelatin and apparently also crystalline egg albumin, only the
valency but not the nature of the ion in combination with the
protein influences its properties. The statements to the con-
trary were due to two errors, first and foremost, the failure to
measure the hydrogen ion concentration of the protein solutions,
and second, the confusion of phenomena of solubility with phe-
nomena of colloidal behavior.

5. THE AGGREGATION HYPOTHESIS

It was perhaps not very fortunate for the development of a
theory of colloids that the attention of investigators was focussed
especially on the phenomena of precipitation. Since precipita-
tion is due to an aggregation of particles it over-emphasized the
significance of aggregate formation. This led, as we have seen,
to the erroneous idea that proteins do not combine stoichiome-

1 LOEB, J., J. Gen. PhysioL, vol. 3, pp. 85, 247, 1920-21.

16 THEORY OF COLLOIDAL BEHAVIOR

trically with other compounds, since aggregates were assumed
to react only at their surface — an assumption which, as already
stated, is not warranted in the case of proteins, since protein gels
are freely permeable to crystalloids. It led, however, to another
equally fatal idea, that this aggregate formation would explain
all the colloidal phenomena. Thus when R. S. Lillie1 made the
important observation that neutral salts depress the osmotic
pressure of gelatin solutions, it seemed natural to explain this
fact from the precipitating action of salts, by assuming that the
addition of salt caused an aggregation of gelatin molecules or ions
into larger aggregates. This would lead to a diminution of the
number of particles in solution. But it was also found that the
addition of salts depresses the viscosity of protein solutions and
the swelling of solid proteins. We shall see later that the
formation of aggregates out of isolated protein molecules or ions
increases the viscosity of a gelatin solution.2 Hence, if the addi-
tion of a salt to a protein solution diminishes its osmotic pressure
by causing an increased formation of aggregates the same addi-
tion of salt should increase the viscosity of such a solution. The
reverse, however, happens, the viscosity of the solution being
decreased by the addition of salt.

There is nevertheless a connection between the phenomena of
precipitation and the depressing effect of salts on viscosity,
osmotic pressure, and swelling of proteins. Schulze, Linder and
Picton, and Hardy had observed that in the precipitation of
colloids that ion is active which has the opposite sign of charge
from the protein particle, and that the efficiency of the active
ion increased with its valency. The same rule applies to the
depressing action of salts on the osmotic pressure, viscosity, and
swelling of proteins. By trying to explain these latter effects
from the precipitating action of salts the colloid chemists put the
cart before the horse, and were led into a hopeless contradiction
wfth the facts. We shall see that by taking the reverse step,
namely, of explaining the precipitating action of salts from their
depressing action on osmotic pressure and P.D. of protein solu-
tions, everything becomes clear and consistent. But this step
could not be taken as long as the belief in the adsorption theory

MILLIE, R. S., Am. J. Physiol., vol. 20, p. 127, 1907-08.
2LoEB, J., J. Gen. Physiol., vol. 4, p. 97, 1921-22.

HISTORICAL INTRODUCTION 17

of colloids prevailed. The quantitative explanation of the col-
loidal behavior of proteins to be given in this book rests on the
proof that they form true ionizable salts with acids and alkalies.

6. PAULI'S HYDRATION THEORY

Laqueur and Sackur, l in studying the influence of the addition
of different quantities of NaOH to a given mass of casein,
assumed correctly that the two substances combined to form
sodium caseinate. The viscosity of the sodium caseinate solu-
tion was high and it varied in a peculiar way with the quantity of
NaOH added to the casein. When little NaOH was added, the
viscosity increased at first with an increase in the quantity of the
NaOH added until a maximum was reached, when the addition of
more NaOH diminished the viscosity again. This again is a
fundamental fact which has since been confirmed for the influ-
ence of acids and alkalies not only upon the viscosity but also
upon other properties of proteins and which holds not only for
casein but apparently for all proteins.

Laqueur and Sackur explained their results on the basis of
Reyher's2 experiments on the viscosity of solutions of fatty
acids. Reyher had found that the viscosity of solutions of salts
of the fatty acids is greater than that of solutions of fatty acids
themselves; and since the salts of the fatty acids undergo elec-
trolytic dissociation to a much greater extent than the acids it was
assumed that the increase in viscosity is determined chiefly by
the ionization. Laqueur and Sackur made the same assumption
for the casein solutions, attributing the high viscosity of casein
solutions to the casein ions, and they support their assumption
by the fact that the addition of little NaOH to casein at first
increases the viscosity until a maximum is reached and that the
addition of more NaOH diminishes the viscosity again. A dimi-
nution of viscosity could also be produced by the addition of
neutral salt to the solution of Na caseinate. Laqueur and Sackur
assume that this drop in the viscosity is caused by a lowering of
the degree of electrolytic dissociation of the Na caseinate by the
Na ion of the NaOH or NaCl added in excess.

1 LAQUEUR, E. and SACKUR, O., Beitr. chem. Physiol. u. PaihoL, vol. 3,
p. 193, 1903.

2 REYHER, R., Z. physik. Chem., vol. 2, p. 744, 1888.

18 THEORY OF COLLOIDAL BEHAVIOR

The idea that the viscosity of protein solution depends primarily
upon the protein ion was accepted by W. Pauli,1 who made the
additional hypothesis that each protein ion is hydrated; i.e.,
that each individual protein ion is surrounded by a considerable
shell of water. Pauli worked with blood albumin which had
been freed from salts by a dialysis continued for several weeks.
When he added acid to water-soluble albumin, the viscosity
increased first from 1.0623 for the pure albumin solution to
1.2937 when the concentration of HC1 added to the albumin
solution was 0.017 N. When the HC1 concentration was in-
creased to 0.05 N the viscosity was only 1.1667. The following
figures give the data according to Pauli:

Concentration of HC1 0.0 N 0.005 N 0.01 N 0.012 N 0.017 N 0.02 N 0.03 N 0.04 N 0.05 N
Viscosity 1.06231.2555 1.233 1.274 1.2937 1.27701.2241.18221.1667

Pauli assumed that the protein ions are surrounded by a jacket
of water, while the non-ionized molecules of protein he assumed
not to be hydrated. Addition of a little HC1 to isoelectric
albumin would cause the transformation of non-ionized albumin
into albumin chloride which is highly ionized and hence assumed
to be highly hydrated; the more acid is added the more albumin
chloride and the more hydrated albumin ions should be formed.
Hence, the viscosity should at first increase with the quantity
of acid added, until a point is reached where the addition of more
acid represses the degree of electrolytic dissociation of the albu-
min chloride on account of the high concentration of the Cl ion
common to both protein chloride and HC1.

If we intend to use these ideas for the explanation of the influ-
ence of the valency of ions on the physical properties of proteins
we are compelled to assume that the degree of electrolytic
dissociation of gelatin salts with bivalent ions is lower than that
of gelatin salts with monovalent ions. Since, e.g., the viscosity
of gelatin chloride solutions is considerably higher than thie
viscosity of gelatin sulphate solutions of the same hydrogen ion
concentration and the same concentration of originally iso-
electric gelatin, we should have to conclude that the degree of
electrolytic dissociation of gelatin sulphate is considerably less
than that of gelatin chloride.

1 PAULI, W., Fortschr. naturwiss. Forschung, vol. 4, p. 223, 1912; "Kol-
loidchemie der Eiweisskorper," Dresden and Leipsic, 1920.

HISTORICAL INTRODUCTION 19

The writer put this theory to a test by measuring the electrical
conductivity of solutions of different gelatin salts at different pH,
with the result that the parallelism between the concentration of
protein ions and the physical properties of proteins demanded
by Pauli's theory could not be demonstrated (see Chap. VII).
Lorenz,1 Born,2 and other authors have recently reached the
conclusion that the idea of a hydration of ions is not tenable in
the case of polyatomic ions.3

The increase in viscosity of certain protein solutions through
the addition of acid or alkali to isoelectric proteins is caused
by the ionization of proteins, but the connection is not the di-
rect one suggested by Laqueur and Sackur but an indirect one
due to the role of protein ions in the establishment of a Donnan
equilibrium.

7. DONNAN'S MEMBRANE EQUILIBRIUM

With the proof of the stoichiometrical character of the com-
bination of proteins with acids and alkalies the explanation of
colloidal behavior on the basis of the adsorption theory became
untenable and another theoretical basis had to be found. The
explanation offered in this volume is based on Donnan's theory
of membrane equilibria.

Donnan4 has shown that when a membrane separates two
solutions of electrolytes one of which contains one ion which
cannot diffuse through the membrane while all the other ions
can diffuse through the membrane, the result will be an unequal
distribution of the diffusible ions on the opposite sides of the
membrane. At equilibrium the products of the concentrations
of each pair of oppositely charged diffusible ions are the same on
the opposite sides of the membrane. This unequal concentration
of the crystalloidal ions must give rise to potential differences

1 LORENZ, R., Z. Elektrochem., vol. 26, p. 424, 1920.

2 BORN, M., Z. Elektrochem., vol. 26, p. 401, 1920.

3 The term "hydration" is often used in colloid chemistry in a vague
way to designate such phenomena as the swelling of proteins which is a
purely osmotic phenomenon. It is obvious that it can only lead to confusion
if the term hydration is used for osmotic pressure. In this volume the term
hydration is only used in the sense of Kohlrausch and Pauli.

4 DONNAN, F. G., Z. Elektrochem., vol. 17, p. 572, 1911.

20

THEORY OF COLLOIDAL BEHAVIOR

and osmotic forces, and we intend to show that these forces
furnish the explanation of colloidal behavior.

It may be best to quote Donnan's theory in his own words :

"We suppose that the membrane (indicated in the following diagram
by a vertical line) be impermeable for the anion R of a salt NaR (and
also for the non-dissociated part of the salt NaR), but permeable for all
the other ions and salts to be considered in this connection . . .

"Suppose that in the beginning we have a solution of NaR on one side
of the membrane (indicated by a vertical line) and of NaCl on the other
side

Na

R

(1)

Na
Cl

In this case NaCl will diffuse from (2) to (1). In the end the following
equilibrium will result:

Na

R

Cl

(1)

Na

Cl

(2)

"When this equilibrium is established the energy required to transport

+

reversibly and iso thermally 1 grammolecule Na from (2) to (1) equals
the energy which can be gained by the corresponding reversible and

isothermal transport of a grammolecule Cl. In other words, we con-
sider the following infinitely small isothermal and reversible change of
the system:

SnMolNa (2) -> (1)

UnMolCl (2) -» (1) J

"The energy which can be gained in this way (i.e., the diminution of
free energy) is zero, hence:

log

log --2 = 0

or

[Nak[Cl]2 = [Nh-lCl]!
where the brackets signify molar concentrations."

(1)

HISTORICAL INTRODUCTION 21

This last equation is the equilibrium equation which states
that the product of the concentrations of a pair of diffusible
cations and anions on one side of the membrane is equal to the
product of the concentrations of the same pair of diffusible anions
and cations on the other side. Since on the side of the non-
diffusible (protein) anion the concentration of cations Na is the
sum of the cations in combination with the non-diffusible anion
plus the cations in combination with the Cl, while on the other
side of the membrane the concentration of the Na ions is only that
of Na in combination with Cl and equal to the concentration of
Cl, it is obvious that Donnan's equation (1) can only be fulfilled
if

[Na]1>[Na]2
and

This inequality of concentration of the diffusible ions on the
opposite sides of the membrane accounts, as we shall see, for the
influence of electrolytes on all those properties which colloid
chemistry has vainly tried to explain on the basis of the disper-
sion and hydration hypotheses. The reader will notice that the
essential condition determining the equilibrium is the existence
of two phases separated by a membrane, one phase containing
an ion which cannot diffuse through a membrane which is easily
permeable for all the other ions.

This difference in the concentration of the diffusible ions on
opposite sides of the membrane must lead to potential differences
on opposite sides of the membrane and Donnan shows that this
difference must be (on the basis of Nernst's well-known formula)

RT, [Na]2 RT, [Cl]i
TI - 7T2 = log l— ^ = -=- log l-^-

[Na]x [Cl],

•prp

or since -^r = 58 millivolts (at room temperature) the potential
r

difference on opposite sides of the membrane should be in millivolts

Tl_T2=581og[4^ = 581og^
[Na], [Cl],

22 THEORY OF COLLOIDAL BEHAVIOR

The writer has tested this consequence of Donnan's theory
for solutions of protein salts separated from water by a collodion
membrane, with the result that the theory was completely
confirmed. Through these measurements of the membrane
potentials the correctness of Donnan's theory was proved beyond
doubt.

It may be pointed out that it is not necessary that the non-
diffusible ion be a colloid; it is only necessary that there be a
membrane which prevents one ion from diffusing; it is immaterial
whether or not this latter ion be a crystalloid or a colloid. If we
had a membrane impermeable for a SO4 ion but permeable for
Na and Cl ions, solutions of NaCl and Na2SO4 separated by the
membrane would give rise to the Donnan equilibrium, and the
Na2SO4 solution would probably resemble a solution of Na pro-
teinate in regard to certain features of colloidal behavior, e.g.,
osmotic pressure and P.D. against water.

Donnan and his collaborators proved the existence of the
inequality of the concentration of the diffusible ions of two salt
solutions on the opposite sides of a membrane when one of the
ions was not able to diffuse through the membrane. Thus
Donnan and Allmand investigated

"the distribution of potassium chloride between two compartments
separated by a copper ferrocyanide diaphragm, one compartment of
which contained potassium ferrocyanide (the membrane being imper-
meable to the Fe(CN)6 ion). The higher concentration of potassium
chloride on the side free from potassium ferrocyanide, and the relation
of this unequal distribution to the concentration of the chloride and
ferrocyanide, were experimentally established. The results obtained
agreed, in general, with the view of membrane equilibria proposed
by Donnan, but a discussion of the distribution data combined with
electromotive-force measurements appeared to show that, at all events
in the case of a copper ferrocyanide membrane and potassium ferrocy-
anide solutions, the phenomena are not so simple as supposed in the
theory."1

More recently Donnan and Garner2 investigated the equilib-
rium concentration of solutions of Na and K ferrocyanides and
of Na and Ca ferrocyanides across a copper ferrocyanide mem-

1 DONNAN, F. G. and ALLMAND, A. J., J. Chem. Soc., vol. 105, p. 1963,
1914.

2 DONNAN, F. G. and GARNER, W. E., J. Chem. Soc., vol. 115, p. 1313, 1919.

HISTORICAL INTRODUCTION 23

brane, and the results were in general agreement with Donnan's
theory. They also investigated a liquid membrane, namely, amyl
alcohol, and the electrolytes employed were KC1 and LiCl.

."So far as the preliminary experiments go, the equilibrium concentra-
tion of the Li and Cl ions and the undissociated part of the electrolyte
agree with Donnan's theory."

We shall see that Donnan's theory explains the influence of
electrolytes on the physical properties of proteins. He foresaw
the bearing which his theory was likely to have for colloid chem-
istry and physiology, as is shown by the following remarks.

"In this paper an attempt is made to describe ion equilibria which
are bound to occur when certain ions (or their corresponding non-
dissociated salt) cannot diffuse through a membrane. Such equilibria
possess a great importance for the theory of dialysis and of colloids
as well as for the mechanism of the cell and for general physiology."

As far as the writer is aware, Procter and J. A. Wilson were the
only authors who attempted the application of Donnan's theory
to colloidal problems.

Procter1 proposed in 1914 an ingenious theory of swelling
based on Donnan's membrane equilibrium. According to this
theory the force which causes the entrance of water into the gel
and thus determines the swelling is the osmotic pressure of the
excess of crystalloidal ions inside over that outside the gel, this
excess being caused by the Donnan equilibrium. The opposing
force which limits the swelling is the force of cohesion of the
colloidal particles.

According to Procter, the gelatin ion constituting a jelly of
gelatin chloride cannot diffuse and hence can exercise no osmotic
pressure, while the chlorine 'anions in 'combination with them are
retained in the jelly by the electrostatic attraction of the gelatin
ion, but exert osmotic pressure. This difference in the diffusi-
bility of the two opposite ions of gelatin chloride gives rise to the
establishment of Donnan's membrane equilibrium.

Procter put solid gelatin chloride into a watery solution of
HC1 and determined by titration the distribution of free HC1
inside tlie gel and outside at the time of equilibrium. In this
case there exists inside the gel free HC1 and gelatin chloride, out-

1 PROCTER, H. R., J. Chem. Soc., vol. 105, p. 313, 1914. PROCTER, H. R.
and WILSON, J, A., J, Chem, Soc., vol. 109, p. 307, 1916.

24 THEORY OF COLLOIDAL BEHAVIOR

side HC1. The relative concentration of free HC1 inside and out-
side at the time of equilibrium is determined by the equation for
the Donnan equilibrium

x2 = y (y + z) (1)

where x is the concentration of the H and Cl ions in the outside
solution, y the concentration of H and Cl ions of the free HC1
inside the gel, and z the concentration of Cl ions in combination
with the gelatin cation, x and y can be " determined experi-
mentally and z can be calculated with the aid of the equation.
In other words, the distribution of the H and Cl ions on the
opposite sides of a membrane is such that the product of the
concentrations of the pair of oppositely charged ions is equal in
both phases.

"The gelatin salt, like other salts, is highly ionised into the anion and
a colloid cation, which either from polymerisation or other causes
peculiar to the colloid state cannot diffuse and exerts no measurable
osmotic pressure, whilst its anion is retained in the jelly by electro-
chemical attraction of the colloid ion, but exerts osmotic pressure which,
on the one hand, causes the mass to swell with absorption of the external
solution, and, on the other, expels a portion of the acid, both anion
and hydrion, from this solution absorbed, the result in equilibrium being
that the jelly is poorer in hydrion and more concentrated in anion than
the external acid solution, the difference of concentration between
anion and hydrion in the jelly being, of course, equal to the ionised
anion of the gelatin salt, and electrically balanced by the positive
gelatin ions; whilst the hydrion concentration in the jelly is less than
that of the outer solution by the amount of acid expelled."1

By establishing a connection between the volume of the gel
and the observed values of x and y, Procter and Wilson were able
to calculate the effect of different concentrations of HC1 on the
swelling of gelatin, and they could show why little acid increased
the swelling until a maximum was reached and why the addition
of more acid depressed the swelling. They could further show why
the addition of neutral salt caused a depression of the swelling.

It is of interest to inquire why this theory of swelling was not
accepted and only rarely mentioned in the colloidal literature.

1 PROCTER, H, R. and WILSON, J. A., J, Chem. Soc., vol., 109, pp. 309-310,
1916.

HISTORICAL INTRODUCTION 25

In the first place, the application of Donnan's theory to the
behavior of proteins requires the proof that proteins form true
salts with acids and alkalies and that these salts dissociate
electrolytically into a protein ion and a crystalloidal cation or
anion. Such an assumption was in conflict with the adsorption
hypothesis accepted by the colloid chemists. Moreover, the
application of the Donnan theory to proteins tacitly implied
that only the valency and sign of charge should have an effect
on the proteins, while the nature of the ion should have no
effect; and this was in conflict with the belief in the Hofmeister
ion series. But even authors, like Robertson, who was a cham-
pion of the purely chemical conception of the behavior of proteins,
refused to accept Procter's theory of swelling.

" There should be a measurable potential difference between the
gelatin jelly and the external medium. This potential difference has
been sought for by Ehrenberg who was unable to detect any measurable
potential between the interior of a jelly and the external medium."1

This gap has been filled by the writer's experiments, which
have demonstrated the existence of this potential. The writer
has not only been able to furnish support for Procter's theory
of swelling but has also been able to show that the potential
differences across a membrane separating a solution of a protein
salt from pure water fully support Donnan's theory.2 When we
have a solution of a gelatin-acid salt with monovalent anion,
e.g., gelatin chloride (or gelatin phosphate) inside a collodion bag
which is dipped into pure water, the hydrogen ion concentration
as well as the anion concentration on the opposite sides of the
membrane are different when osmotic equilibrium is established.
The writer was able to show that the potential differences calcu-
lated from this difference of the concentration of ions on the
basis of Nernst's formula agree with the actually observed P.D.,
and that the calculated P.D. is the same whether based on a
measurement of the difference in the concentration of the hydro-
gen ions or of the difference in the concentration of the chlorine
ions on the opposite sides of the membrane. This latter fact

1 ROBERTSON, T. B., "The Physical Chemistry of the Proteins," p. 297,
New York, London, Bombay, Calcutta, and Madras, 1918.
2LoEB, J., J. Gen. Physiol, vol. 3, p. 667, 1920-21.

26 THEORY OF COLLOIDAL BEHAVIOR

seems a complete proof for the correctness of Donnan's theory of
membrane equilibrium, and also a further proof for the correctness
of the purely chemical conception of the combination of proteins
with acids and alkalies. For unless the proteins form true ioniz-
able salts with acids and alkalies they cannot fulfill the require-
ments of the Donnan equilibrium.

It was, however, possible to go a step further, inasmuch as
these membrane potentials showed the typical colloidal charac-
teristics noticed in connection with viscosity, swelling, and
osmotic pressure, namely, the potential difference across the mem-
brane was depressed by the addition of neutral salts, was increased
by the addition of little acid to isoelectric protein, and depressed
by the addition of more acid; the depressing effect was in both
cases due to the ion with the opposite sign of charge to that of the
protein ion, and finally the depressing influence increased rapidly
with the valency of the active ion — while the other characteristics
of the ion aside from sign and valency had no effect. In this
case there was not the slightest doubt that the effects were exclu-
sively the result of the Donnan equilibrium since they could be
mathematically predicted and calculated from the equilibrium
formula.

The writer was able to show, in addition, that the analogous
behavior of the osmotic pressure and viscosity of protein solutions
could be explained and calculated on the basis of Donnan's
theory.

It, therefore, turns out that two laws of classical chemistry
suffice to explain colloidal behavior quantitatively and mathe-
matically, and these two laws are the stoichiometrical law and
Donnan's theory of membrane equilibria. The proof for this
statement is the purpose of this volume.

CHAPTER II

QUALITATIVE PROOF OF THE CORRECTNESS OF
THE CHEMICAL VIEWPOINT

PREPARATION OF PROTEINS FREE FROM IONOGENIC IMPURITIES

The first problem confronting the chemist is to find a method
which permits him to settle definitely the problem whether only
one or both ions of a salt combine with a protein. This decision
was not possible with the old methods. Those who believe in
the adsorption theory assume that both ions of a salt are adsorbed
by colloids and Pauli holds that both ions of a salt are adsorbed by
the non-ionized molecules of protein.1

When a block of gelatin is put into a salt solution, the solution
enters into the interstices between the gelatin molecules constitut-
ing the block. When such a block of gelatin is melted, of course,
both ions of the salt are found, but nobody can tell whether the salt
found was only the salt contained in the interstices of the original
gel or whether it was in combination with the gelatin. This diffi-
culty can be circumvented by using solid gelatin in the form of a
very fine powder of grains approximately equal in size. When
such powdered gelatin is exposed to a salt solution for some time,
we can ascertain with certainty by a process of washing whether
one or both ions are in combination with the gelatin. After
a small mass of the powdered gelatin has been exposed to a
salt solution for about 1 hour, it is put on a filter and perfused,
with stirring, about six times or more with 25 c.c. of ice-cold
distilled water. The water must be cold since otherwise the
granules will coalesce, rendering the process of washing futile.
By this procedure it is possible to remove the salt solution
between the granules of gelatin, without removing the ions in
chemical combination with the gelatin — at least not by the six
washings. By using this method of washing we can ascertain

1 PAULI, W., Fortschr. naturwiss. Forschung, vol. 4, p. 223, 1912.

27

28 THEORY OF COLLOIDAL BEHAVIOR

whether both or only one of the two oppositely charged ions of a
salt enters into combination with gelatin.

Such experiments show that at a given hydrogen ion concentra-
tion either the cation or only the anion or neither ion can combine
with a protein; and that it depends solely on the hydrogen ion
concentration of the solution which of the three possibilities exists.1

Proteins are amphoteric electrolytes which exist in three states,
according to their hydrogen ion concentration, namely, (a) as
non-ionogenic or isoelectric protein; (6) metal proteinate (e.g.,
Na or Ca proteinate); and (c) protein-acid salts (e.g., protein
chloride, protein sulphate, etc.). We will use gelatin as an illus-
tration. At one definite hydrogen ion concentration, namely,
that of the isoelectric point, which in the case of gelatin lies at
10~4-7N (or in S^rensen's logarithmic symbol at pH = 4.7), gelatin
can combine practically with neither anion nor cation of an elec-
trolyte. At a pH>4.7, gelatin can combine only with cations
(forming metal gelatinate, e.g., Na gelatinate); at a pH<4.7,
gelatin combines with anions (forming gelatin chloride, etc.).
This was proved in the following way: Doses of 1 gm. of finely
powdered commercial gelatin (going through sieve 60 but not
through 80), which happened to have a pH of 7.0, were brought to
different hydrogen ion concentrations by putting them for 1 hour
at about 15°C. into 100 c.c. of HNO3 solutions varying in concen-
tration from M/8,192 to M/8. Owing to the Donnan equilib-
rium the hydrogen ion concentration inside a gelatin granule is
lower than that outside. After this, each dose of 1 gm. of gelatin
was put on a filter, the acid being allowed to drain off, and each
dose was washed once or twice with 25 c.c. of cold water (at 5°C.
or less) to remove the greater part of the acid between the
granules of the powdered gelatin. These different doses of
originally 1 gm. of gelatin, each of which now possessed a different
pH, were put for 1 hour each into a separate beaker containing
the same concentration, e.g., M/64, of silver nitrate at a temper-
ature of 15°C. Each dose of powdered gelatin was then put on a
filter and washed with stirring six or eight times each with 25 c.c.
of ice-cold water. This washing serves the purpose of removing
the AgNO3 held in solution between the granules, thus allowing

1 LOEB, J., J. Gen. PhysioL, vol. 1, pp. 39, 237, 1918-19. Science, vol.
52, p. 449, 1920. /. chim. physique, vol. 18, p. 283, 1920.

Is^ "I

S^^H.SS

•3*a.|&

C ^3

*§H

§,°3

J-s^iJii

T3 O g •** o -^

IMisi-a

c3^ -g "£ O o3
_§ 3 §^^ S^

^-^S § gjS o

fl C8 g ^^ 0-0

(3 T3 ti

o ® --1

t

*s s c

o § o

Oa)

e-|S

ll^l^l

l

y pL("®jd8"^'oa

x iafj|ij

•s;

CORRECTNESS OF THE CHEMICAL VIEWPOINT 29

us to ascertain where the Ag is in combination with gelatin and
where it is not in combination, since the Ag not in combination
with gelatin can be removed by the washing while the former can-
not, or at least only extremely slowly (by altering the pH).
After having removed the AgN03 not in combination with gelatin
by washing with cold water, the gelatin is melted by heating
to 40°C., enough distilled water is added to bring the volume of
each gelatin solution to 100 c.c., the pH of a sample of each solu-
tion is determined potentiometrically, and the solutions are
exposed in test-tubes to light, the previous manipulations having
been carried out in a dark room (with the exception of the deter-
mination of pH, for which only part of the gelatin solution was
used). In 20 minutes all the gelatin solutions with a pH>4.7,
i.e., from pH 4.8 and above, upon exposure to strong light become
opaque and then brown or black, while all the solutions of pH <
4.7, i.e., from 4.6 and below, remain transparent even when
exposed to light for months or years (Fig. 1). The solutions of
pH = 4.7 become opaque, but remain white, no matter how long
they may have been exposed to light. At this pH — the isoelectric
point — gelatin is not in combination with Ag, but it is sparingly
soluble. Hence, the cation Ag is only in chemical combination
with gelatin when the pH is >4.7. At pH 4.7 or below gelatin
is not able to combine with Ag ionogenically. This statement
was confirmed by volumetric analysis.

The same tests can be made for any other cation the presence
of which can be easily demonstrated. Thus, when powdered
gelatin of different pH is treated with NiCl2, and the NiCl2 not
in combination with gelatin be removed by washing with cold
water, the presence of Ni can be demonstrated in all gelatin
solutions with a pH >4.7 by using dimethylglyoxime as an indi-
cator. All gelatin solutions of pH of 4.8 or above assume a
crimson color upon the addition of dimethylglyoxime, while all
the others remain colorless. If we use copper instead of Ag or
Ni as a cation, treating gelatin with copper acetate, and washing
afterwards, the gelatin is blue and opaque when its pH is 4.8 or
above, but is colorless and clear for pH<4.7. Most striking are
the results with basic dyes, e.g., basic fuchsin or neutral red, after
sufficient washing with cold water; only those gelatin solutions
are red whose pH is above 4.7, while the others are colorless.

30 THEORY OF COLLOIDAL BEHAVIOR

On the acid side of the isoelectric point, i.e., at pH<4.7, the
gelatin is in combination with the anion of the salt used. This
can be demonstrated in the same way by bringing different doses
of powdered gelatin to different pH and treating them for 1 hour
with a dilute solution of a salt whose anion easily betrays itself,
e.g., M/128 K4Fe(CN)6. If after this treatment the powdered
gelatin is washed six times or oftener with cold water to remove
the Fe(CN)6 not in chemical combination with gelatin and if 1
per cent solutions of these different samples of gelatin are made,
it is found that when the pH is <4.7 the gelatin solution turns
blue after a few days (due to the formation of ferric salt), while
solutions of gelatin with a pH of 4.7 or above remain permanently
colorless (Fig. 2). Hence, gelatin enters into chemical combina-
tion with the anion Fe(CN)6 only when pH is <4.7. The same
fact can be demonstrated through the addition of ferric salt when
gelatin has been treated with NaCNS, the anion CNS being in
combination with gelatin only where the pH is <4.7. Acid dyes,
like acid fuchsin, combine with gelatin only when the pH is
<4.7.x

In this way it can be shown that when the pH is >4.7 gelatin
can combine only with cations; when the pH is <4.7 gelatin can
combine only with anions, while at pH 4.7 (the isoelectric point)
gelatin can combine with neither anion nor cation. The idea
that both ions are adsorbed or combine with a protein simultane-
ously is no longer tenable, since otherwise both ions of the salt
should have been discovered on both sides of the isoelectric point.

It follows also that a protein solution is not adequately defined
by its concentration of protein but that the hydrogen ion con-
centration must also be known, since each protein occurs in three
different forms — possibly isomers — according to its hydrogen
ion concentration.

Let us now return once more to the experiment in which doses
of powdered gelatin were brought to a different pH and subse-

1 In these experiments it may happen that a few individual granules do
not give off their stain at the isoelectric point or on the alkaline side of the
isoelectric point, due probably to experimental shortcomings. When the
gelatin is melted the solution may show an indication of red. The difference
between the gelatin on the alkaline and on the acid side is, however,
sufficiently striking even if this slight error interferes.

CORRECTNESS OF THE CHEMICAL VIEWPOINT 31

quently treated for 1 hour with the same concentration of AgNO3,
e.g., M/64 AgNO3, and then washed. In this case, the exposure
to light showed us that silver gelatinate existed only on the alka-
line side of the isoelectric point, since only on that side did the
gelatin turn black. When we now add enough alkali to the
gelatin solutions with a pH of 4.6 or less to bring their pH to 4.8
or above, they will not turn black when exposed to light. This
shows that the gelatin of pH below 4.6 did not contain any
demonstrable quantity of silver.1 It was conceivable that such
gelatin of pH below 4.6 contained Ag in a non-ionogenic form. If
this were the case, this fact should have betrayed itself in a
blackening upon the addition of enough alkali to bring the pH
above 4.7.

When we bring powdered gelatin of pH>4.7, which has been
treated with M/64 AgNO3 and washed, to a pH of 4.7, or below,
the silver which was in combination with the gelatin can be
removed by washing with cold water, and such gelatin will not
turn black when subsequently exposed to light, provided the
washing had been adequate.

When we include that part of the gelatin molecule which
cannot react with other electrolytes in brackets, while the part
of the molecule which is capable of reacting with other electro-
lytes is kept outside the brackets, we can symbolize our results
in the following way :

Isoelectric gelatin is entirely inside the brackets since at the
isoelectric point gelatin can combine neither with anions nor with
cations,

-NH2 1

— COOHj

On the alkaline side from the isoelectric point practically only
COOH groups of the molecule are capable of reacting with
other compounds and we represent the protein molecule on this
side in the following form:

1 This dogmatic presentation of our results is only approximately correct,
since a trace of anion should also combine, theoretically at least, on the
alkaline side of the isoelectric point; and a trace of cation on the acid side,
at least near the isoelectric point. As a matter of fact, however, this cannot
be demonstrated, though the theory of amphoteric electrolytes demands
that this should be so.

32 THEORY OF COLLOIDAL BEHAVIOR

[R

-NH;

— COOH

Such proteins behave as if they were simple (probably polybasic)
fatty acids, the rest of the molecule not participating in the reac-
tion. In the presence of a hydroxide, e.g., NaOH, sodium pro-
teinate is formed

— NH

.— COOH + NaOH " |_1X— COONa + H2O
and the sodium proteinate dissociates electrolytically into a
protein anion and a Na ion

- COONa L A "— COO + Na"

When other electrolytes are present they can of course exchange
their cation with the Na of the protein salt. Our symbol con-
siders only one COOH group, but it is probable that as a rule
more than one COOH group of a protein molecule combines
with alkali (Bugarszky and Liebermann, Sackur, Robertson,
S^rensen, Pauli, Northrop1).

On the acid side of the isoelectric point only the NH2 groups of
the molecule are capable of reacting with other compounds and
we represent the protein molecule on this side in the following
form:

[R

_NH2

COOH

In this form the proteins behave like NH3 which according to
Werner2 is capable of adding an acid, e.g., HC1, the H ion of the
acid being added directly to the N while the Cl remains outside

H

the ring of the 4H in the following way: HNHC1. It has been

H

1 NORTHROP, J. H., /. Gen. PhysioL, vol. 3, p. 715, 1920-21.

2 WERNER, A., " Neuere Anschauungen auf dem Gebiete der anorganischen
Chemie, 3rd ed., Braunschweig, 1913.

CORRECTNESS OF THE CHEMICAL VIEWPOINT 33

shown by W. Kossel1 and by Langmuir2 that this idea of Werner
is in perfect harmony with the electronic conception of molecular
compounds, and we shall give later in this book a direct
proof that it holds for proteins. We can, therefore, say that on
the acid side of its isoelectric point the protein particle is able
to add acid to its NH2 groups in the following form:

pr>__NH2HCl

+ HC1 = K
LiX-

— COOH I* v— COOH

which dissociates electrolytically into a protein cation and an
anion.

COOH A ^— COOH

While our symbol indicates only one NH2 group in the mole-
cule, it is probable that more than one NH2 or NH group is
capable of adding an acid molecule.

The simplification in the general chemistry of proteins implied
in these experiments is considerable. We only need to remember
that on the alkaline side of its isoelectric point the protein
behaves as if it were a fatty acid, only one or more COOH
groups existing in a chemically active form; while on the acid
side of its isoelectric point we may again disregard the enormous
protein molecule and go on the assumption that the protein
consists only of one or a number of NH2 groups, each capable of
adding the hydrogen ion of an acid.

It is possible though not proven that the difference in the
behavior of the proteins on the two opposite sides of the isoelectric
point is accompanied by an intramolecular change in the protein
molecule, and that the protein anion in a metal proteinate may
be considered an isomer of the protein cation in protein-acid salt.
Such a possibility is suggested by the behavior of indicators the
electrolytic dissociation of which is accompanied by an intra-
molecular change.

When we mix a metal gelatinate, e.g., sodium gelatinate, with
another salt, e.g., MgSO4, the Na of the metal gelatinate can be

1 KOSSEL, W., Ann. d. Physik, vol. 49, p. 229, 1916.

2 LANGMUIR, I., /. Am. Chem. Soc., vol. 41, p. 868, 1919,

3

34 THEORY OF COLLOIDAL BEHAVIOR

replaced by the Mg of the MgSO4 resulting in the formation of
magnesium gelatinate. The SO4, however, cannot affect the
properties of Na gelatinate since it cannot (or can practically not)
combine with the gelatin. When, however, we mix gelatin
chloride with MgSO4, only the SO4 can affect the properties of
the gelatin salt, since the SO4 can replace the Cl in the gelatin
chloride resulting in the formation of gelatin sulphate. The Mg,
however, cannot (or can practically not) enter into combination
with gelatin chloride and hence cannot affect its properties.

When we alter the pH of a gelatin-acid salt, e.g., gelatin
chloride, by adding alkali, e.g., NaOH, it will cease to be gelatin
chloride as soon as the pH is 4.7 because at this pH the Cl will be
given off by the gelatin and the latter will be transformed into the
chemically inert isoelectric or non-ionogenic gelatin and into
NaCl. The isoelectric gelatin can combine practically neither
with anions nor with cations. When we add more NaOH so that
the pH is >4.7, Na gelatinate will be formed. At no time can
metal gelatinate (e.g., Na gelatinate) and gelatin-acid salt (e.g.,
gelatin chloride) exist simultaneously (except in traces beyond
the limits of analytical demonstration). When we have Na
gelatinate and add acid, e.g., HC1, the gelatin salt will give off its
Na and become isoelectric gelatin as soon as pH = 4.7. This
isoelectric gelatin is chemically inert being practically unable to
combine with either anion or cation. When we add more HC1,
gelatin chloride will be formed.

These experiments show that proteins behave like amphoteric
electrolytes, forming definite salts with acids or bases, but that
they cannot combine simultaneously with the cation and the
anion of a neutral salt. The idea of the existence of adsorption
compounds between non-ionized molecules of proteins and mole-
cules of neutral salts is not in harmony with these experiments.

In 1918 the writer1 published a simple method of preparing
ash-free proteins based on the fact that at the isoelectric point
proteins can combine neither with anions nor with cations.
Hence, if we wish to prepare gelatin or casein free from ionogenic
impurities, we must bring these proteins in powdered form to the
isoelectric point and then wash them. This is of importance for
all industries using proteins as well as for scientific work. In the
, J., J. Gen. PhysioL, vol. 1, p. 237, 1918-19.

CORRECTNESS OF THE CHEMICAL VIEWPOINT 35

writer's work isoelectric protein was always used as the starting
point for experiments.

The procedure for preparing isoelectric protein is simple
enough. It is only necessary to determine the pH of a given
protein solution potentiometrically, and then to add very gradu-
ally as much acid or alkali as is required to bring it to the iso-
electric point.

The following method was used to prepare larger quantities
of approximately isoelectric gelatin: 50 gm. of commercial
powdered Cooper's gelatin, which happened to have a pH of
6.0 to 7.0, were put into 3,000 c.c. of M/128 acetic acid in ajar
at 10°C., and stirred frequently. After 30 minutes the super-
natant liquid was decanted and fresh M/128 acetic acid at 10°C.
was added to equal the original volume. The mass was fre-
quently stirred, and after 30 minutes the acid was again decanted
and replaced by an equal volume of distilled water at 5°C. The
gelatin was well stirred and then filtered by suction through
towel cloth in a Buchner funnel. It was then washed in the
funnel five times each with 1,000 c.c. of H2O at 5°C. After all
the water was drained off, the gelatin was transferred from the
Buchner funnel into a large beaker which was then heated in a
water bath to about 50°C. till the gelatin was melted. The
concentration of the gelatin was determined by evaporating
to dryness, using 10 c.c. of the melted gelatin in an electric oven
at 90 to 100°C. for 24 hours.

One hundred cubic centimeters of a 1 per cent gelatin solution
prepared in this way had no more than 1 mgm. of ash — appar-
ently Ca3(PO4)2, i-e.. the salt contained in the solution was
M/30,000. Salt in this concentration does not affect the physical
properties of proteins, such as osmotic pressure, viscosity, P.D.,
swelling or precipitability as will be shown in this volume. The
following is a result of an ash determination made by Dr. D. I.
Hitchcock on a sample of gelatin selected at random. The stock
solution contained 12.69 per cent gelatin.

SAMPLE No. 1 SAMPLE No. 2

Volume of solution 20 c.c. 10 c.c.

Weight of dry gelatin 2.535 gm. 1.269 gm.

Weight of ash 0.0024 gm. 0.0012 gm.

Obtained qualitative tests for Fe+4+, "Ca^, and PO^, negative tests for
Cl- and SOr.

36 THEORY OF COLLOIDAL BEHAVIOR

Miss Field1 has shown that by carrying the washing process a
step further the last traces of ash can be removed from the
powdered gelatin. In bringing powdered gelatin to the iso-
electric point and washing with water of the pH of the isoelectric
point we can quickly make the gelatin completely ash-free. If
the protein is soluble at this point (as is the case with crystalline
egg albumin) it is only necessary to carry out the dialysis at the
pH of the isoelectric point to obtain the protein free from iono-
genic impurities.2

This fact is a further support of our contention that at the
isoelectric point proteins can combine with neither anion nor
cation.

We may call attention to one interesting fact which is in
harmony with these results. It has always been known that
pepsin digestion occurs in nature in an acid medium. The
reason for this connection of an acid reaction with pepsin digestion
was cleared up by Northrop3 who found that the hydrogen ion
concentration at which pepsin commences to act on a protein
varies with the isoelectric point of the protein and that the action
always occurs on the acid side of the isoelectric point. It
seems to follow from the experiments of Pekelharing and Ringer4
that pepsin is an anion like Cl which can only combine with a
positive protein ion. This combination between pepsin and
positive protein ion seems to be the prerequisite for the falling
apart (or digestion) of the protein ion.

1 FIELD, A. M., J. Am. Chem. Soc., vol. 43, p. 667, 1921.

2 Miss Field's paper as well as the writer's paper referred to were over-
looked by C. R. SMITH (J. Am. Chem. Soc., vol. 43, p. 1350, 1921) who
also describes a method of preparing ash-free gelatin.

3 NORTHROP, J. H., J. Gen. Physiol., vol. 3, p. 211, 1920-21.

4 PEKELHARING, C. A. and RINGER, W. E., Z. physiol Chem., vol. 75,
p. 282, 1911.

CHAPTER III

METHODS OF DETERMINING THE ISOELECTRIC POINT
OF PROTEIN SOLUTIONS

The results of the preceding chapter make it clear that when-
ever work with amphoteric electrolytes is contemplated it
becomes necessary to ascertain first the isoelectric point of the
substance, since at the isoelectric point the material can be most
easily freed from ionogenic impurities. There can be no doubt
that many of the substances exhibiting colloidal behavior are
amphoteric electrolytes.

Hardy and Michaelis determined the isoelectric point by
observations on the migration of particles in the electrical field.
There are other methods available for this purpose, some of
which are often more convenient than Hardy's original method.
These methods are based on the fact that at the isoelectric point
the osmotic pressure, the viscosity, the amount of alcohol required
for precipitation, the conductivity, the swelling, the P.D. are all
a minimum. When the curves representing the values of these
properties are plotted as ordinates over the pH as abscissae, the
curves show a sharp drop at the isoelectric point. If, therefore,
a protein is brought to different pH by adding acid or alkali, and
if any of the properties mentioned is determined, the approximate
position of the isoelectric point can be inferred from the minimum
point of the property which is used as a test. The writer has
found it most convenient to use osmotic pressure experiments in
the case of proteins.

The following older experiment by the writer may serve as an
illustration.1 A number of doses each containing 1 gm. of finely
powdered Cooper's gelatin which had a pH of a little over 7.0
and consisted partly of Ca gelatinate were put for 30 minutes at
15°C. into beakers containing 100 c.c. of HBr of different con-
centrations, varying from M/8 to M/8,192; and as a control 1 gm.
of gelatin was put for 30 minutes at 15°C.into 100 c.c. of distilled

1 LOEB, J., J. Gen. PhysioL, vol. 1, p. 363, 1918-19.

37

38

THEORY OF COLLOIDAL BEHAVIOR

Rej

*ion of GelaTin-Br

Isoelectrjc
point Region of Gelatin

100
90
80
70
60
50
40
30
20
10
0
130
120
110
100
90
80
70
60
175
150
1Z5
100
75
50
IS
0
4
3
Z
1
0
3
Z
1
0

\

\

\

\

\

1

^^

To

al

we!

ing

^

/

\

\

\

\"

'\

\

,^

-^ — <

) —

Vis

cosi

y

Soc

^

P

1 3

3 0

3 3

6 L

0 4

43-4

4-4.5-4

7

1 5

5 5

8 t

0 €

1 6

\

\

s

\

\

\

^^

1 \

/

0.5

mot

c P

655

ire

\

\

\

N^

\

Cc

ndu

tivit

f

s>

^

>- — '

mu

Ohn

>s

/^

\

\

Cc

?•

0.0

N

5r i

\

s.

&

latin

I PC
50l

lion

Ns

HBr M M M M M — M:
cone. 8 16 32 64 »TZ5f

-M M M M M M f.
*& 1024 Z048 4096 mi 1638*

pH 41 4.1 42 42 444'5454J49 52 5.4 i5 56 S6 56

FIG. 3. — Showing that the physical properties of gelatin are a minimum at the

isoelectric point.

ISOELECTRIC POINT OF PROTEIN SOLUTIONS 39

water. The powdered gelatin was then put into a cylindrical
funnel and the acid allowed to drain off. The powdered gelatin
in the funnel was then perfused six or eight times, with constant
stirring, each time with 25 c.c. cold water — i.e., water not above
5°C. — to remove the excess of acid and the salts. The water
must be cold to prevent the powdered granules from coalescing
since otherwise the washing would be incomplete. After the
liquid was drained off from the filter, the volume (i.e., the rela-
tive swelling of the gelatin) was measured; then the gelatin was
melted by heating to 45°C. and enough water was added to bring
the volume in each case to 100 c.c. Then the conductivity,
osmotic pressure, and viscosity were measured in a way to be
described in a later chapter, and the pH was also determined,
either colorimetrically (which gives fairly accurate results with
gelatin but not with the other proteins) or preferably with the
hydrogen electrode. In the experiment represented in Fig. 3 the
pH was measured colorimetrically. A glance at the figure shows
that the ordinates of the curves representing the values for
osmotic pressure, conductivity, swelling, etc., drop very sharply
at pH 4.7, i.e., the isoelectric point of gelatin. By this method
the approximate location of the isoelectric point can be recognized
at a glance from the osmotic pressure measurements, the conduc-
tivity measurements, etc. The P.D. measurements would also
show a minimum at the isoelectric point.

The lowest curve in Fig. 3 represents titration for Br. Gelatin
should exist in the form of gelatin bromide only on the acid side of
the isoelectric point and titration for Br should be negative
when the pH is above 4.7. The curve shows that no Br was
found when pH was equal or greater than 4.7; while it was found
on the acid side increasing in quantity the lower the pH. On the
alkaline side of the isoelectric point the gelatin existed still in
the state of Ca gelatinate. In this experiment the mass of the
gelatin was diminished by solution and washing to 0.8 gm. or
possibly a little less.

We shall see later, that when powdered gelatin is put into an
acid solution, e.g., N/100 or N/1,000 HBr, the concentration of
the acid inside the gelatin granules is considerably lower than in
the outside solution. This is due to the establishment of a
Donnan equilibrium.

CHAPTER IV

QUANTITATIVE PROOF OF THE CORRECTNESS OF THE
CHEMICAL VIEWPOINT

1. The qualitative experiments of the second chapter did
not permit us to decide whether ions combine with proteins
stoichiometrically (i.e., by the purely chemical forces of primary
valency), or according to the empirical rule of adsorption, as is
assumed in colloid chemistry. A decision can be rendered by
titration experiments.1

The titrations required for this proof differ from those usually
performed in chemistry. In the usual chemical work titration
is carried to the point of neutrality, i.e., pH near 7.0. Proteins,
however, are amphoteric electrolytes, the isoelectric point of
which is generally different from neutrality. Gelatin and casein
act as bases for a pH below 4.7, and if we wish to ascertain how
much of a certain acid 1 gm. of isoelectric gelatin can bind we have
to titrate to a pH below 4.7. In doing this, we must also remem-
ber that at such a high hydrogen ion concentration only strong
dibasic acids, like H2SO4, continue to dissociate both H ions,
while weaker dibasic or tribasic acids, e.g., H3PO4, are only able
to split off one H ion, acting therefore like monobasic acids.

Our solutions contain generally 1 gm. of isoelectric protein in
100 c.c., and such solutions will be called 1 per cent protein
solutions. When 1 per cent solutions of albumin sulphate or 1 per
cent solutions of gelatin chloride are mentioned, this means that
1 gm. of originally isoelectric albumin or gelatin was in 100 c.c. of
the solution. The concentration of the stock solution of isoelec-
tric gelatin, albumin, or casein was determined by measuring the
dry weight of the solution.

When different quantities of 0.1 N acid, e.g., HC1, are added
to the same quantity of protein, e.g., I gm. of isoelectric gelatin
or crystalline egg albumin, bringing the volume of the solution

1LOEB, J., J.Gen. Physiol., vol. 1, p. 559, 1918-19; vol. 3, p. 85, 1920-21.

40

CORRECTNESS OF THE CHEMICAL VIEWPOINT 41

always to 100 c.c., it is found that the resulting hydrogen ion
concentration of the solution is different from the pH which is
found when the same amount of acid is added to the same quan-
tity of pure water. This is due to the fact that part of the acid
combines with the protein as originally suggested by Bugarszky
and Liebermann.1 On the basis of Werner's2 idea the HC1 should
combine with the NH2 groups of the protein molecule in the same
way as if it were added to NH3, thus forming a salt of the type
RNH3C1. This is intelligible on the basis of the recent theories
of G. N. Lewis,3 Kossel,4 and Langmuir.5 Gelatin chloride may
therefore be expected to dissociate electrolytically in the following
way:

Gelatin NH3O1 ^ gelatin NH3 + Cl

Hence, the concentration of the free Cl ions in a watery solution
of HC1 should remain the same if a small amount of isoelectric
gelatin is added, provided the electrolytic dissociation is complete.
This was tested by comparing the pCl of HC1 solutions with and
without gelatin (Table I). Both the pH and the pCl were
measured electrometrically. Table I shows that this pCl was
in solutions of HC1 without gelatin always identical with the
pH of the same solution. In a second set of experiments the
same HC1 solutions contained each 1 gm. of isoelectric gelatin in
100 c.c., and the pH and pCl in these 1 per cent solutions of
gelatin chloride were also determined after the reaction was com-
plete. The reader will notice from Table I that the values for
pCl of the watery solutions are within the limits of accuracy of
the determinations identical with those found in the gelatin
solutions containing the same amount of acid. The pH, however,
is different in the aqueous and in the 1 per cent gelatin solutions,

1 BUGARSZKY, S. and LIEBERMANN, L., Arch. ges. Physiol., vol. 72, p.
51, 1898.

2 WERNER, A., " Neuere Anschauungen auf dem Gebiete der anorganischen
Chemie," 3rd ed., Braunschweig, 1913.

3 LEWIS, G. N., J. Am. Chem. Soc., vol. 38, p. 762, 1916.

4 KOSSEL, W., Ann. Physik, vol. 49, p. 229, 1916.

5 LANGMUIR, I., J. Am. Chem. Soc., vol. 41, p. 868, 1919; vol. 42, p. 274,
1920.

42

THEORY OF COLLOIDAL BEHAVIOR

since, in the latter, part of the H ions of the free HC1 added

+

becomes part of the complex gelatin cation, gelatin-NH3. The
figures in Table I then prove that a strong acid, like HC1, com-
bines with the protein according to Werner's ideas.

TABLE I

Cubic centi-

Solution containing no

Solution containing 1 gm. of

meters of

gelatin

isoelectric gelatin in 100 c.c.

0.1 N HC1

in 100 c.c.

solution

pH

pCl

pH

pCl

2

2.72

2.72

4.2

2.68

3

2.52

2.54

4.0

2.53

4

2.41

2.39

5

2.31

2.29

3.60

2.33

6

2.24

2.26

3.41

2.25

7

2.16

2.18

3.23

2.18

8

2.11

2.12

3.07

2.11

10

2.01

2.01

2.78

2.025

15

1.85

1.85

2.30

1.845

20

1.72

1.76

2.06

1.76

30

1.55

1.59

1.78

1.60

40

1.43

1.47

1.61

1.47

It was found that whenever the same amount of acid was added
to the same amount, e.g., 1 gm., of originally isoelectric gelatin,
making up the volume to 100 c.c., the pH of the solution was
always the same ; so that we can say how much Cl is in combina-
tion with the protein if we know the pH of the gelatin chloride
solution. The lower the pH, the more chloride enters into com-
bination with the protein, until finally, all the protein is trans-
formed into protein chloride.

It seems that when an acid, e.g., HC1, is added to isoelectric
gelatin (or any other isoelectric protein), an equilibrium is
established between free HC1, protein chloride, and non-ionogenic
(or isoelectric) protein; when alkali is added to isoelectric gelatin,
an equilibrium is established between metal proteinate, non-
ionized protein, and free alkali (above pH 4.7). Similar results
had been obtained by S0rensen.1

1 S0RENSEN, S. P. L., Studies on proteins : Compt. rend. trav. Lab. Carlsberg,
vol. 12, Copenhagen, 1915-17.

CORRECTNESS OF THE CHEMICAL VIEWPOINT 43

It can be shown by titration experiments that acids and bases
combine with proteins in the same way as they combine with
crystalline compounds, namely, by the purely chemical forces
of primary valency. It is known that a weak dibasic or tribasic
acid gives off one hydrogen ion more readily than both or all
three, and that it depends on the hydrogen ion concentration of
the solution whether one or two or three H ions are dissociated
from a tribasic acid. Thus H3PO4 will give off only one H ion
as long as the pH is below 4.6. Oxalic acid, which is a stronger
acid, will act like a monobasic acid below a pH of about 3.0,1
while above this pH it acts more and more like a dibasic acid.
In a strong dibasic acid, like H2SO4, both H ions are held with so
small an electrostatic force that even at a pH of 3.0 or consider-
ably below the acid acts as a dibasic acid. If the forces which
determine the reaction between these acids and proteins are
purely chemical, it would follow that three times as many cubic
centimeters of 0.1 N H3PO4 should be required to bring 100 c.c.
of 1 per cent solution of isoelectric gelatin to a given pH below
4.6, e.g., 3.0, as are required in the case of HNO3 or HC1; while it
should require just as many cubic centimeters of 0.1 N H2SO4 as
of 0.1 N HC1. Twice as many cubic centimeters of 0.1 N oxalic
acid should be required to bring isoelectric gelatin to a pH of
3.0 or below, as are required in the case of HC1. It can be shown
that these predictions are true.2

2. Crystalline egg albumin was prepared according to S0rensen's
method,3 and crystallized three times. The only difference in
procedure was in the dialysis. Instead of putting the water
under negative pressure, as was done by S0rensen, pressure was
put on the egg albumin by attaching a long glass tube full of
water to the dialyzing bag so that the solution was under about
150 cm. water pressure during dialysis. This was necessary to
avoid too great an increase in volume. The same stock solution

1 HILDEBRAND, J. H., J. Am. Chem. Soc., vol. 35, p. 847, 1913. See
also MICHAELIS, L., "Die Wasserstoffionenkonzentration," Berlin, 1914;
CLARK, W. M., "The Determination of Hydrogen Ions," Baltimore, 1920.

2 The experiments to be described are from LOEB, J., J. Gen. Physiol.,
vol. 3, p. 85, 1920-21.

3 S^RENSEN, S. P. L., Studies on proteins: Compt. rend. trav.Lab. Carlsberg,
vol. 12, Copenhagen, 1915-17.

44

THEORY OF COLLOIDAL BEHAVIOR

of albumin served for all the experiments and was diluted before
the experiment to a 1 per cent solution. The concentration of

pH 2.0 22 2.4 26 2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2 4.4 4.6

FIG. 4. — The ordinates represent the number of c.c. of 0.1 N HC1, H2SO4,
oxalic, and phosphoric acids required to bring 1 gm. of isoelectric crystalline
egg albumin to the pH indicated on the axis of abscissae. Enough H2O was
added to bring the albumin and acid to a volume of 100 c.o. For the same pH
the ordinates for HC1, HzSC^, and phosphoric acid are approximately as 1:1:3.
The ratio of HC1 to oxalic acid is a little less than 1 : 2 when pH is > 3.0.

ammonium sulphate left in the solution was between M/ 1,000 and
M/2,000. The pH of the stock solution was about 5.20. By

CORRECTNESS OF THE CHEMICAL VIEWPOINT 45

adding about 1 c.c. 0.1 N HC1 to 100 c.c. of a 1 per cent solution
of this albumin the solution was brought to the isoelectric point
of the egg albumin, which is according to S0rensen at pH = 4.8.

The 1 per cent solutions were made up with different quantities
of acid (or alkali) and the pH of the albumin solution was
determined electrometrically. In Fig. 4 are plotted the titration
curves in which the pH are the abscissae while the ordinates are
the cubic centimeters of 0.1 N acid required to bring the 1 per
cent solutions of originally isoelectric crystalline egg albumin to
different pH. The curves represent these titration values for
four acids, HC1, H2SO4, H3PO4, and oxalic acid. Beginning
with the lowest curve, we notice that the curve is the same for
0.1 N HC1 and 0.1 N H2SO4, since both are strong acids; or, in
other words, H2SO4 combines in equivalent proportions with egg
albumin. The curve for H3PO4 is the highest curve and if we
compare the values for H3PO4 with those for HC1 (or H2SO4)
we notice that for each pH the ordinate for H3P04 is as nearly
three times as high as that for HC1 as the accuracy of our experi-
ments permits. This means that phosphoric acid combines
with albumin (inside of the range of pH of our experiment) in
molecular proportions and that the anion of albumin phosphate
is the monovalent anion H2PO4.

The values for oxalic acid are for pH below 3.2 almost but not
quite twice as high as those for HC1, indicating that for these
values of pH oxalic acid combines to a greater extent in molecular
and only to a small extent in equivalent proportions with
albumin.

These combining ratios of the four acids named with crystalline
egg albumin are, therefore, the same as those which would be
found if we substituted the crystalloidal base NH3 for the colloid
egg albumin, titrating in the same range of pH.

From the curves just discussed, the amount of acid in combi-
nation with 1 gm. of originally isoelectric crystalline egg albumin
in a 1 per cent solution of this protein at different pH can easily
be calculated. Let us assume the acid added to isoelectric
albumin to be HC1. If, e.g., at pH 3.0, 6 c.c. of 0.1 N HC1 are
contained in 100 c.c. of the 1 per cent solution of the originally
isoelectric albumin (as indicated in Fig. 4), part of the acid is in
combination with the albumin and part is free. How much is

46

THEORY OF COLLOIDAL BEHAVIOR

free is known from the pH of the albumin chloride solution,
namely, 1 c.c., since in the example selected the pH is 3.0 (Fig.
4). If 1 c.c. is deducted from 6 c.c. it is found that at pH 3.0

19
18
17
16
15
14
13
12

10
9
8

pH 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 40 4.2 44 4.6 4.8

FIG. 5.— Method of determining the amount of acid in combination with 1 gm.
of albumin from titration curve and pH curve.

5 c.c. of 0.1 N HC1 are in combination with 1 gm. of originally
isoelectric crystalline egg albumin in 100 c.c. solution (Fig. 5).
A curve is constructed in which the abscissa are the pH while ^he
ordinates are the cubic centimeters of 0.1 N HC1 contained in 100

CORRECTNESS OF THE CHEMICAL VIEWPOINT 47
c.c. of a watery solution, without protein. If the ordinatesof this

Z2
21
20
19
18
IT
16
15
14
13
12
11
10

8

[

\

1

\

\

4

\

\

:c. acid combined
rith 1 gm. of originally
soelectric egg albumi
in 100 cc. solution

\

(

^

•

n

\

L

I

\

\

\

\

A

\

\

\

V

\

\

\

9

\

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4

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V

&

j

&

n ,

s

°+,

J

Cc

>

1

2

Kf

V,

< vx

\^

v

X

ccJ

S

^

^

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1

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\

i

st

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5

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k

2

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i

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i;

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X

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k

^

Vv

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s

^

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pHl8 a.O 2.2 2.4 26 28 3.0 3.2 3.4 36 3.8 40 42 4.4 46

Fio. 6. — Proof of the stoichiometrical character of the combination of acids
with isoelectric albumin. The same mass of albumin com bines with three times
as many c.c. of 0.1 N H3PO4 as with HClor H 2SO 4 ; and with twice as many c.c.
of 0.1 N oxalic acid below pH 3.0.

latter curve are deducted from the ordinates of the titration

48 THEORY OF COLLOIDAL BEHAVIOR

curve in Fig. 4 containing 1 per cent of originally isoelectric
albumin chloride we get a curve whose ordinates give the number
of cubic centimeters of 0.1 N HC1 in actual combination with 1 gm.
of originally isoelectric albumin in 100 c.c. solution (middle curve
Fig. 5).

Figure 6 contains the curves whose ordinates give the amount
of cubic centimeters of 0.1 N HC1, H2S04, H2C204, and H3PO4
in combination with 1 gm. of originally isoelectric egg albumin at
different pH. It appears again that the curves for HC1 and H2SO4
practically coincide as the purely chemical theory demands, that
the oxalic acid curve is higher, and that the phosphoric acid
curve is still higher. What is of greater importance is that for
the same pH the ordinates of the H3P04 curve are always approxi-
mately three times as high as the ordinates of the curves for HC1
and H2SO4.

The results in Table II show the actual numbers of cubic
centimeters of each of the four acids in combination with 1 gm.
of originally isoelectric crystalline egg albumin in 100 c.c. solution.
The values for HC1 and H2S04 are identical. Those for H3PO4
are within the limits of accuracy always three times as large as
those for HC1. Thus at pH 4.0, 1.7 c.c. of 0.1 N HC1 or H2SO4
are combined with 1 gm. of albumin, while 5.3 c.c. of 0.1 N H3PO4
are in combination; at 3.4, 3.5 c.c. of 0.1 N HC1 or H2SC>4 and
10.6 c.c. of 0.1 N H3PO4.

In the case of oxalic acid, we notice that at pH above 3.6 the
number of cubic centimeters of 0.1 N oxalic acid in combination
with 1 gm. of albumin is less than twice that of HC1 and that the
difference is the greater the higher the pH. At pH = 3.2 and
below practically twice as many cubic centimeters of oxalic acid
are at the same pH in combination with 1 gm. of originally
isoelectric albumin as are of HC1. Thus at pH 2.6, 6.7 c.c. of 0.1
N HC1 and 13.3 c.c. of 0.1 N oxalic acid are in combination with
1 gm. of albumin; at pH 3.0, 5.0 c.c. of 0.1 N HC1 and 9.5 c.c. of
0.1 N oxalic acid. These figures correspond to the results to be
expected on the basis of Hildebrand's titration experiments
against inorganic bases. These titration experiments then leave
no doubt that these acids combine with proteins in the same
stoichiometric way as they combine with crystalloids. That
these simple facts had not been discovered earlier is the con-

CORRECTNESS OF THE CHEMICAL VIEWPOINT

49

TABLE II. — CUBIC CENTIMETERS OF 0.1 N ACID IN COMBINATION WITH

1 GM. OF ORIGINALLY ISOELECTRIC CRYSTALLINE EGG ALBUMIN IN

100 c.c. SOLUTION

PH

HC1,
cubic
centimeters

H2S04,
cubic
centimeters

Oxalic acid,
cubic
centimeters

H3P04,

cubic
centimeters

4.2

1.15

1.15

1.8

3.8

4.0

1.7

1.7

2.6

5.3

3.8

2.3

2.3

3.7

6.8

3.6

2.9

2.9

5.0

8.6

3.4

3.5

3.5

6.3

10.6

3.2

4.2

4.3

8.0

13.1

3.0

5.0

5.1

9.5

16.1

2.8

5.8

5.9

11.1

19.3

2.6

6.7

6.5

13.3

22.9

2.4

7.6

7.0

16.0

sequence of the failure of the workers to consider the hydrogen
ion concentration of their solutions. Had this been done, nobody
would have thought of suggesting that acids combine with pro-
teins according to the adsorption formula.

These titration experiments are of especial value for the reason
that crystalline egg albumin is for the present probably the
purest protein available.

The same proof can be furnished in the case of other proteins,
e.g., gelatin. A stock solution of isoelectric gelatin was used for
the experiment. The isoelectric gelatin was prepared by putting
the powdered gelatin of pH 7.0 into M/128 acetic acid (100 c.c. of
11/128 acid for 1 gm. of gelatin) for 1 hour at 15°C., and then
washing four or five times with cold water (5°C.). An 8 per cent
stock solution was prepared ; the concentration of the gelatin was
ascertained by a determination of the dry weight. To 50 c.c. of a
2 per cent solution of isoelectric gelatin were added different
quantities of acid and the volume made up to 100 c.c. by adding
enough H20, usually of a pH of about 5.6. It was ascertained
how many cubic centimeters of 0.1 N different acids were required
to bring 1 gm. of isoelectric gelatin in a 1 per cent solution to the
same pH.

4

50

THEORY OF COLLOIDAL BEHAVIOR

In Fig. 7 the abscissae are the pH while the ordinates are the
number of cubic centimeters of 0.1 N HC1, H2SO4, H2 oxalate,

pHlfi 2.0 2.2 2.4 2.6 ZQ 3.0 3.2 3.4 3.6 3.8 4.0 42 44 46

FIG. 7. — Titration curve for 1 per cent solution of originally isoelectric gelatin,
proving the stoichiometrical character of combination of acids with gelatin
(see legend under Fig. 6).

and H3PO4 contained in 100 c.c. solution of originally isoelectric
gelatin to the same pH,

CORRECTNESS OF THE CHEMICAL VIEWPOINT 51

It is again obvious that the curves for HC1 and H2SO4 are
practically identical while the ordinates of the curve for H3PO4

20
19
18
17
16
15
14
13
12
11
10

\

4

I

\

\

)c. acid combined -
rith Ifim. of originallyi
.5oelectric gelatin
n lOOcc. solution -

\

V

V

\

\

•]

.

N

\

J

\

V

\l

v

•>

•x

\

\

J

%

\

;o.
'0

V

j~r

^

4

V

VI

•

(

LC

^

ft?

\]

%

^

^ t

^x

S

&

Y

G^

r\ 1 ,

c.

WA

^

§

fcsw

-

s

\

I

^v

\

v

1

\

\

b

\

1

\

k>

\

N

\

i

>SA

^

\

\

s

s

\

V

2.0 22 £.4 2.6 2.8 3.0 3.Z 3.4 3.6 3.6 4.0 4.2 44 4.6

FIG. 8. — Combination curve of acids with gelatin, confirming the stoichio-
metrical character of the combination.

are approximately three and those for oxalic acid about twice as
high as those for HC1 or H2SO4 for the same pH, as long as the
pH is below 3.2; while above 3.2 the curve for oxalic acid deviates

52

THEORY OF COLLOIDAL BEHAVIOR

the more from that ratio the higher the pH, as the theory
demands.

The curves in Fig. 8 represent the values for the cubic centi-
meters of 0.1 N acid found in combination with 1 gm. of originally
isoelectric gelatin in 100 c.c. solution at different pH. The
results are tabulated in Table III. The table shows that
within the limits of accuracy of the experiments, at the same pH
approximately equal numbers of cubic centimeters of 0.1 N HC1
and 0.1 N H2S04 are in combination with 1 gm. of originally
isoelectric gelatin in 100 c.c. solution, while about three times as
many cubic centimeters of 0.1 N H3PO4 are in combination. The
number of cubic centimeters of 0.1 N oxalic acid in combination
with 1 gm. of gelatin is less than twice that of HC1 as long as the
pH is above 3.0, while below 3.0 the combining ratio of the two
acids is approximately as 1:2, as the theory demands.

TABLE III. — CUBIC CENTIMETERS OF 0.1 N ACID IN COMBINATION WITH
1 GM. OF ORIGINALLY ISOELECTRIC GELATIN IN 100 c.c. SOLUTION

HC1,

H2S04,

Oxalic acid,

H3P04,

pH

cubic

cubic

cubic

cubic

centimeters

centimeters

centimeters

centimeters

4.0

2.7

3.9

6.95

3.8

3.9

3.75

5.5

9.4

3.6

4.8

4.8

7.3

12.3

3.4

5.6

5.75

9.1

15.2

3.2

6.4

6.75

11.0

18.0

3.0

7.2

7.5

13.15

20.7

2.8

7.9

8.25

15.3

23.6

2.6

8.35

8.8

17.1

26.2

2.4

8.5

9.3

18.0

These experiments corroborate our conclusion that acids
combine stoichiometrically with proteins if the hydrogen ion
concentration is properly taken into consideration.

Similar experiments were made with casein prepared after the
method of L. L. Van Slyke and J. C. Baker,1 who described in

1 VAN SLYKE, L. L. and BAKER, J. C., J. Biol Chem., vol. 35, p. 127,
1918.

CORRECTNESS OF THE CHEMICAL VIEWPOINT 53

1918 a method for preparing "pure casein" from skimmed milk,
which consisted

"in the gradual addition of acid and its immediate distribution through
the mass of milk without causing coagulation of casein at the point
where the acid first comes into contact with a portion of the milk.
This result can be accomplished by introducing the acid below the
surface of the milk with high-speed mechanical stirring. After stand-
ing under gentle stirring for 3 hours with acidity just below the point of
casein coagulation, addition of acid is continued slowly, accompanied
as before by rapid stirring in order to obtain the particles of casein
coagulum in the finest possible state of division."

The coagulated casein is then centrifuged and after repeated
washings is found free from Ca and inorganic P. As Van Slyke
and Baker point out, the pH of this casein coagulum is about
4.5 to 4.6, i.e., it is slightly below the isoelectric point. The
essential feature of Van Slyke and Baker's method therefore
consists in slowly bringing the milk or casein solution approxi-
mately to the pH of the isoelectric point of casein. The writer
has shown that gelatin gives off all ionogenic impurities at the
isoelectric point and Van Slyke and Baker's experiments show
that the same method works also with casein. The casein
prepared after Van Slyke and Baker's method is also free from
albumin since this latter protein is soluble at pH 4.5 or 4.7,
and is, hence, removed from the insoluble isoelectric casein by
washing.

In our experiments1 we used casein prepared after Van Slyke
and Baker's method from skimmed milk and in addition from a
"pure casein" of the market. Both preparations gave practi-
cally the same result. In order to remove traces of fat from the
casein the latter was washed in acetone.

It is not possible to prepare 1 per cent casein solutions, except
with a few acids, on account of the low solubility of the casein
salts with acids. It is, however, possible to compare casein
chloride and casein phosphate in 1 per cent solutions. One gram
of isoelectric casein, prepared after Van Slyke and Baker, was put
into 100 c.c. of watery solution containing 1, 2, 3, etc., c.c. of
0.1 N HC1 or 0.1 N H3PO4. The pH of the casein solution was
, J., J. Gen. PhysioL, vol. 3, 547, 1920-21.

54

THEORY OF COLLOIDAL BEHAVIOR

ascertained potentiometrically and the number of cubic centi-
meters of 0.1 N acid required to bring the 1 per cent casein solu-

C
'3

a

o

i

.3

o

CO

o
u
o
o

B

u

40
38
36
34
32
30
28
26
24
22
20
18
16
14
12
10
8
6
4
2

\

\

\

pH 1.4 1.6 1.8 2.0 2.2 24 2.6 2.8 3.0 3.2 34 3.6 3.8

FIG. 9. — Ordinates represent the c.c. of 0.1 N HC1 or H3PO4 in 100 c.c. of 1
per cent casein solution. The abscissa are the pH of the solution. Approxi-
mately three times as many c.c. of 0.1 N HsPC^ as of 0.1 N HC1 are required to
bring 1 gm. of casein to the same pH.

tion to the same pH were plotted over the final pH of the casein
solution as abscissae. The casein chloride or casein phosphate is
not completely soluble in a 1 per cent solution until the pH is

CORRECTNESS OF THE CHEMICAL VIEWPOINT 55

about 3.0 or a trifle below. When too much acid is added, i.e.,
when the pH is 1.6 or possibly a little above, casein precipitates
out again from a 1 per cent solution.

Figure 9 gives the titration curves for HC1 and H3PO4, drawn
out within those limits of pH within which the casein salts are
soluble in a 1 per cent solution. The curves show that- about
three times as many cubic centimeters of 0.1 N H3PO4 as of
0.1 N HC1 are required to bring 1 gm. of originally isoelectric
casein in a 1 per cent solution to the same pH; or in other words,
H3PO4 combines with casein in molecular proportions, as should
be expected if casein phosphate is a true chemical compound.

It was not possible to plot the corresponding curves for casein
sulphate and casein oxalate since these salts are too sparingly
soluble. This is true also for casein salts with other acids, e.g.,
trichloracetic acid.

From all these experiments we draw the conclusion that acids
combine with crystalline egg albumin, gelatin, and casein (and
probably proteins in general) by the same forces of- primary
valency by which the same acids combine also with crystalloidal
substances, e.g., NH3 or NaOH.

3. In the preceding experiments we started with isoelectric
protein and determined the number of cubic centimeters of
0.1 N acid required to bring the protein solution to a definite
pH. It seemed of interest to confirm our results by the reverse
titration; namely, by starting with a protein-acid salt of a
definite pH and determining how many cubic centimeters of
0.1 N NaOH are required to bring a solution of a protein-acid salt
to a definite pH, e.g., 7.0. This method requires, however, cer-
tain corrections which will become clear from the following con-
siderations. The experiments were made with gelatin solutions
containing about 0.8 gm. of originally isoelectric gelatin in 100 c.c.
solution. When we add different quantities of 0.1 N acid, e.g.,
HBr, to 0.8 gm. of isoelectric gelatin, melt, and make a 0.8 per
cent solution by adding enough water to bring the volume to
100 c.c., there is in solution a mixture of two substances, namely,
free hydrobromic acid and gelatin bromide. The total amount
of Br contained in 10 c.c. solution can be determined by titrating
for Br; part of this Br is in combination with protein and part is
in combination in the free HBr, The latter part can be

56 THEORY OF COLLOIDAL BEHAVIOR

ascertained from the pH of the gelatin bromide solution by
preparing a solution of HBr of the same pH in water, without
gelatin, and determining the amount of Br in this solution free
from gelatin. By deducting this value from the total Br it can
be found how much HBr is combined with the gelatin. Table
IV gives the results of such an experiment.1 Row 1 gives the
number of cubic centimeters of 0.01 N free hydrobromic acid
originally contained in 100 c.c. of the 0.8 per cent solution of orig-
inally isoelectric gelatin. Row 2 gives the pH of each gelatin-
bromide solution after equilibrium is established ; Row 3 the total
amount of 0.01 N Br found in 10 c.c. of the solution; and Row

4 gives the amount of Br actually in combination with gelatin
after deducting the amount of Br in the free HBr (not in com-
bination with gelatin) from the total amount of Br found.

There is a second method of ascertaining the amount of HBr in
combination with a given mass of gelatin, namely by titrating for
acid with NaOH.1 In this case the number of cubic centimeters
0.01 N NaOH required to bring 10 c.c. of the gelatin-bromide
solution to a pH of 7.0 must be determined. This gives the
total acid, from which the value for free acid not in combination
with gelatin is to be deducted. This value is obtained by titrat-
ing a solution of HBr (free from gelatin) of the same pH as the
gelatin-bromide solution with NaOH. A second correction,
however, must be made ; namely, the quantity of NaOH required
to bring 10 c.c. of an 0.8 per cent solution of isoelectric gelatin to a
pH of 7.0 must be ascertained. This value was found to be about
1.8 c.c. 0.01 NaOH for lOc.c. of a 0.8 per cent solution of isoelectric
gelatin. This value must also be deducted, and if these two
deductions are made, approximately the same figures are reached
as by direct titration for Br. This is shown by Table IV. Row

5 gives the number of cubic centimeters 0.01 N NaOH required to
bring 10 c.c. of gelatin solution to pH of 7.0. Row 6 gives the
corrected NaOH values, i.e., after the two deductions just
mentioned are made from the values in Row 5. A comparison
of the values of Row 6 with those of Row 4 shows that they are
identical within the limits of the accuracy of our methods.

This method of titrating with NaOH allows us, therefore, to

1 LOEB, J., J. Gen. PhysioL, vol. 1, p. 559, 1918-19.

CORRECTNESS OF THE CHEMICAL VIEWPOINT 57

o

iO t- ^H O O5 O

d ^ d 6 -< d

*|

B

1C 1C

O*O N i-H IH CO

'o a

9

FH Tf 00 <N 0

Sj

>

o

iO CO S S t^ 00
<N TJH' 00 NO

PH -**

11

1

0 - « 3 * S

10 -^ r-< ^ CO i-l

2

li

U

00 00
10 0 •* <N <N (N

t>.' CO C4 <N "*' (N

-3 -g

i g

S2 2

q
w

O t» O 00 t^ Is-

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la

d
o

1C K5

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e<J co' co co "5 co

2 O

5*

a "°

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1C CO •*' CO 1C CO

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d co •*' •* co Tji

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>C CO •* O> O t-

<N CO lO •* t- **
<N

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'o S °

BO

ON t- »H CO OS

in

J °

1C CO >C »0 t- •*
(N

3&f

£ 5
o g

0 2 Tf CO 0 ^

d co co' "5 06 >o

CO

a««

5 . 1

i i

O 1-1 00 00 •* CO

1C CO CO 1C 00 «C
CO

5 =3 §

MI •- a

C .S T3

^ §

00 CO ^H M <N

3- §

§§

d co t-^ co d cd

11,3

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8jl

R^ ^

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1

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M

S

00

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j>

S

1

1. Cubic centimeters 0.01 N HBr added
2. pH of gelatin solution
3. Cubic centimeters 0.01 N Br found in 10 c.c. of
gelatin solution
4. Corrected values of Br
5. Cubic centimeters 0.01 N NaOH required to
bring 10 c.c. of gelatin solution to pH 7.0 ..
6. Corrected NaOH value

(In this experiment the collodion bag
same concentration as that added to
solution so that at equilibrium the latte

58

THEORY OF COLLOIDAL BEHAVIOR

find out the amount of any acid in combination with a given mass
of gelatin of a certain pH.

With the new method we can also confirm the statement that
weaker dibasic or tribasic acids, like oxalic or phosphoric, com-
bine with gelatin in molecular proportions. Table V gives the
equivalents of HNO3, oxalic, and phosphoric acids in combination
with gelatin at different pH in 10 c.c. of 0.8 per cent solution of
originally isoelectric gelatin.

The values found for HNO3 in Table V are slightly less than
those found for HBr in Table IV and HC1, due to the fact that
the concentration of gelatin was slightly less in the experiments
recorded in Table V than in Table IV.1 A comparison of the
figures for NaOH values for HNO3, and for the PO4 values (Table
V, Rows 1 and 3), found by direct titration for PO4 with the uranyl-
acetate method, shows for the two values practically the ratio of
1 : 3 at the same pH; i.e., three times as much H3P04 as HNO3 is in
combination with the same mass of gelatin. The figures for
HNO3 and oxalic acid (Rows 1 and 2, Table IV) give the ratio of
approximately 1:2 for pH 3.5 or below. Hence, oxalic and phos-
phoric acids combine in molecular proportions with gelatin. In
the same way it was shown that H2S04 combines in equivalent
proportions with gelatin,

These measurements confirm the conclusions at which we
arrived by the other method.

TABLE V.— CUBIC CENTIMETERS OF 0.01 N ACID IN COMBINATION WITH

GELATIN IN 10 c.c. OF AN 0.8 PER CENT GELATIN SOLUTION AT

DIFFERENT pH

pH

3.1

3.2

3.3

3.4

3.5

3.7

3.9

4.1

4.2

4.3

1. HNO3

4.35
9.6

4.1
8.75
12.4

3.6
7.6
10.4

3.2
6.7

9.8

2.85
6.00
9.00

2.45
4.3

7.4

1.9
3.0

5.8

1.45
4.5

1.65
2.6

0.75
2.1

2. Oxalic acid

3. H3PO4

1 In these earlier experiments 1 gm. of powdered gelatin was brought to
the isoelectric point. This entailed some loss, especially during the wash-
ing, which varied slightly in different experiments. In later experiments
this source of error was avoided by using a stock solution of about 8 per
cent isoelectric gelatin and ascertaining the concentration of isoelectric
gelatin by dry-weight determinations.

CORRECTNESS OF THE CHEMICAL VIEWPOINT

59

It was found in these experiments that all strong monobasic
acids, like HBr or HNO3, gave the same titration curve as HC1.
This, however, was, of course, no longer the case for weak acids.
The weaker the acid the more is required to bring the protein
solution to the same pH. This is illustrated in Fig. 10, which
gives the titration curves for 0.1 N acetic, mono-, di-, and tri-

3

22

£6 28 3.0 32 3.4 3.6 3.8 40 42 44 46 48

FIG. 10. — The ordinates represent the number of c.c. of 0.1 N acetic, mono-,
di-, and trichloracetic acids required to bring about 0.8 gm. of isoelectric gelatin
to the pH indicated by the abscissae. Enough HoO was added to bring the
gelatin-acid solution to a volume of 100 c.c.

chloracetic acids with the same mass of isoelectric gelatin (about
0.8 gm.) in 100 c.c. solution. It is obvious that the weaker the
acid the more is required to bring the same mass of isoelectric
gelatin to the same pH.

On account of the enormous quantities required in the case of
weak acids, it is not well possible to plot the quantity of acid in
combination with a given mass of protein in the same way as done
in the case of HC1 ; but it will be shown in the next chapter by an
indirect method that the amount of anion combined with a given

60

THEORY OF COLLOIDAL BEHAVIOR

m^- ,x protein in the same volume of solution is the same for a
given pH no matter whether the acid is strong or weak.

4. If the numbers of cubic centimeters of 0.1 N KOH, NaOH,
Ca(OH)2, and Ba(OH)2 are measured which must be contained

10

11

FIG. 11. — Curves representing the number of c.c. of 0.1 N NH4OH, NaOH,
and Ca(OH)2 required to bring 1 gm. of isoelectric, crystalline egg albumin in
100 c.c. solution to different pH. The curves for NaOH and Ca(OH)2 are
identical.

in 100 c.c. of a 1 per cent solution of originally isoelectric crystalline
egg albumin to bring the solution to the same pH, it is found that
these numbers are identical and that the values for the four bases
lie in one curve. This means that Ca (OH) 2 and Ba (OH) 2 combine

CORRECTNESS OF THE CHEMICAL VIEWPOINT

61

in equivalent proportions with crystalline egg albumin; i.e.,
combine with crystalline egg albumin in the same stoichiome-

40
38
36

52 32

<D

u 30

o~ 28

0 26

22

u

CD

u
0

20
18
16

14
12

10

8
6

4

Na

Cd

-Kr

Ba

casemate

71

pH 6

8

10

11

12

FIG. 12.— Ordinates are the c.c. of 0.1 N NaOH, KOH, Ca(OH)2, and Ba(OH)2
in 100 c.c. of 1 per cent solution of casein. Abscissae are the pH of the solution.
The curves for the four alkalies are identical, proving that Ba and Ca combine
with casein in equivalent proportion.

trical way in which they combine with crystalloidal acids.
This is equally true for the combination of these bases with
isoelectric albumin (Fig. 11), with casein (Fig. 12), and with

62

THEORY OF COLLOIDAL BEHAVIOR

gelatin (Fig. 13). In this latter case the solution contained only
about 0.8 gm. of originally isoelectric gelatin in 100 cc. solution.1

q

e

<&-

1

8
^

8

0.1N

0.1N

o.iNBaio:

Nate

KOH

and

01N

:a(ort)

/

67 72 7.7 82 87 92 97 10.2 107 112 11.7

3 DH47 5.2 5.7 62

8

FIG. 13.— Curves for the number of c.c. of 0.1 N NaOH, KOH, Ba(OH)2,
and Ca(OH)2 required to bring the same mass of about 0.8 gm. of isoelectric
gelatin in 100 c.c. solution to different pH. All four curves are identical.

The question may be finally raised, How many molecules of
acid or alkali can combine with one molecule of protein? The
smoothness of the titration curves of isoelectric proteins with
acids indicates that either only one or many molecules of a
monobasic acid, e.g., HC1, combine with one molecule of protein,
since otherwise, the curves could not be smooth. It is not
probable that only one molecule of acid combines with one mole-
cule of protein.

Procter and Wilson, have reached the conclusion that the
equivalent weight of gelatin is 768 (see Chap. XI), and Wintgen
and Kruger2 give the value as 839. According to the recent

, J., J. Gen. PhysioL, vol. 3, p. 85, 1920-21.
2 WINTGEN, R., and KRUGER, K., Kolloid-Z., vol. 28, p. 81, 1921.

CORRECTNESS OF THE CHEMICAL VIEWPOINT 63

analyses by Dakin,1 gelatin contains 1.4 per cent phenylalanme,
which would give as the minimal molecular weight of gelatin
11,800. Procter and Wilson's value leads to the result that
about 15, or a multiple of 15, molecules of a monobasic acid
combine with one molecule of gelatin.

It can be stated, as the result of all these titration experiments,
that the ratios in which acids and bases combine with proteins
are identical with the ratios in which acids and bases combine
with crystalloids. Or, in other words, the forces by which
gelatin, egg albumin, and casein (and probably proteins in
general) combine with acids or alkalies are the purely chemical
forces of primary valency.

The question may be raised, How can the fact that proteins
combine stoichiometrically be reconciled with the statement that
their solutions frequently contain aggregates of molecules?
This latter fact led to the assumption of adsorption at the surface
of each micella, but without cogent reason. The protein micellae
which may exist in a solution of gelatin in water are not compar-
able with metallic spheres or oil globules in water, where the two
phases are separated by a continuous boundary. When a 1 per
cent gelatin solution sets to a gel, the equal distribution of the
molecules of the gel in the water remains the same. The random
orientation of the gelatin molecules in the solution may change to
a more definite orientation in the gel, but the average distance
between the protein molecules will probably not change. The
interstices between the molecules remain the same, and the
protein molecules and protein ions remain as accessible to alkali
or acid in the gel as are molecules or ions in true solution. The
micellae of gelatin in solution are submicroscopic particles of jelly
and there is no reason why the reactions between gelatin and
electrolytes should not be stoichiometrical even if the protein
were entirely in the gel state.

The titration experiments given in this chapter show also why
it is necessary to compare the relative efficiency of two kinds of
ions of the same sign not only for the same concentration of the
originally isoelectric protein but also for the same pH. As the
combination curves Figs. 6 and 8 show, at each pH only part of
the mass of the protein present exists in the form of a salt, the

1 DAKIN, H. D., J. BioL Chem., vol. 44, p. 499, 1920.

64 THEORY OF COLLOIDAL BEHAVIOR

rest exists as non-ionogenic protein. Only if enough acid (or
alkali) is added, is all the protein transformed into a salt. The
combination curves show that at the same pH the same fraction
of the protein present exists in the form of a protein salt. If it is
desired to compare the relative efficiency of different ions in
combination with a protein, one must be sure that the concen-
tration of originally isoelectric protein is the same in both solu-
tions and that the fraction of protein which has combined with
the two ions is the same. This is only true when the solutions of
the protein salts to be compared have not only the same concen-
tration of originally isoelectric protein but also the same pH.

There existed no reason for comparing the effects of different
ions at the same pH as long as the titration curves given in this
chapter were not known. But the knowledge of these curves
forces the experimenter to change his methods and to base all the
comparisons of the influence of ions on the physical prop-
erties of proteins on protein solutions of equal hydrogen ion
concentrations.

CHAPTER V
THE VALENCY RULE AND THE HOFMEISTER SERIES

(A) OSMOTIC PRESSURE

In this chapter it will be shown that the combining ratios of
acids and alkalies with proteins furnish the key for the under-
standing of the influence of ions on the physical properties of
proteins, inasmuch as only the sign of charge and the valency
but not the other properties of an ion influence such physical
qualities of proteins as osmotic pressure, viscosity, and, in the
case of gelatin, swelling. In this discussion only the monovalent
and bivalent ions will be considered.

The fact to be proved is contrary to the statements current in
colloid chemistry according to which the chemical nature of the
ion is of as much importance as the valency. As already stated
in the first chapter, the ions have been arranged in series,
the so-called Hofmeister series, according to their relative in-
fluence on swelling, viscosity, and osmotic pressure of proteins.
It is perfectly true that the different ions of the same valency,
e.g., Li, Na, K, Rb, Cs, or Cl, Br, and I, have different chemical
properties according to their position in the periodic table, and
monovalent anions, such as NO3, CH3COO, also have definite
chemical characteristics different from those of I or Br or Cl.
These differences manifest themselves in many phenomena,
e.g., in solubility, but they are obviously of minor importance
in their influence on the physical properties of proteins alluded
to, for a reason which will become clear in the second part of the
book. For the present it will only be shown that the Hofmeister
ion series are largely the result of the same methodical error
which had prevented the recognition of the fact that acids and
alkalies combine with proteins stoichiometrically, namely, the
failure to measure the hydrogen ion concentration of the protein
solutions. If we wish to compare the relative efficiency of two
5 65

66 THEORY OF COLLOIDAL BEHAVIOR

ions, e.g., Cl and CH3COO, on the osmotic pressure or viscosity
of protein solutions, it is absolutely necessary to do so at the
same pH and the same concentration of originally isoelectric
protein. If this is done, it will be found that the Hofmeister
series have practically no real significance and that essentially
only the valency, not the specific nature of the ion in combination
with the protein, influences its physical properties.

In the preceding chapter it was seen that at the same pH three
times as many cubic centimeters of 0.1 N H3PO4 as of HNOsare in
combination with 1 gm. of originally isoelectric gelatin in 100 c.c.
of solution. From this it follows that the anion of gelatin phos-
phate is the monovalent ion H2PO4 and not the trivalent anion
P04. It follows likewise from the combining ratios discussed in
Chap. IV that the anion of oxalic acid in combination with
protein below pH = 3.0 is the monovalent anion HC2O4, while at
pH above 3.0 the oxalic acid dissociates to an increasing degree as
a dibasic acid, forming a divalent anion C2O4 with protein. The
same must be true, mutatis mutandis, for all weak dibasic or
tribasic acids, e.g., citric, tartaric, or succinic acids, namely, that
at pH below 4.7 they form protein salts with chiefly monovalent
anions. It follows also from the combining ratios, that the salt
of a protein with a strong dibasic acid, as H2SO4, must have a
divalent anion, e.g., SO4. On the basis of our valency rule, we
should, therefore, expect that the osmotic pressure of 1 per cent
solutions of originally isoelectric gelatin with different acids of
the same pH should be identical for all gelatin salts with monova-
lent anion; in other words, 1 per cent solutions of gelatin chloride,
bromide, nitrate, tartrate, succinate, citrate, or phosphate should
all have about the same osmotic pressure and the same viscosity
at the same pH; and the same should be true for swelling; while
gelatin sulphate, which has a bivalent anion, should have a much
lower osmotic pressure, viscosity, or swelling. We will show
first that this is true for the osmotic pressure of protein solutions.

The simple method of R. S. Lillie1 was employed for the measure-
ment of the osmotic pressure of gelatin solutions. Collodion
bags of a volume of about 50 c.c. were cast in Erlenmeyer flasks
assuming the shape of the latter. These were prepared in a
uniform way, as follows: Collodion (Merck, 275 grains of ether

1 LILLIE, R. S., Am. J. PhysioL, vol. 20, p. 127, 1907-08.

THE VALENCY RULE AND THE HOFMEISTER SERIES 67

per ounce; 27 per cent alcohol, U. S. P. IX) was used. Erlen-
meyer flasks of a volume of about 50 c.c. were rinsed with 95 per
cent alcohol and then filled to the neck with the collodion solution.
After the flask was filled with collodion, the latter was allowed to
pour out slowly from the flask which was rotated slowly by hand
during this process. The process of rotating the flask and pour-
ing out the collodion was timed to occupy exactly 2 minutes.
Then the Erlenmeyer flask, which was now empty except for a
film of collodion adhering to the inside of the glass wall, was
allowed to dry for exactly 2 minutes at room temperature. It
was then put under the faucet and tap water was allowed to run
in in a gentle stream for 5 minutes. The collodion film formed
inside the flask could be pulled out being an exact cast of the flask.
These collodion bags were closed, with the aid of rubber bands,
by a conical rubber stopper which was perforated to allow a glass
tube to be pushed through. The collodion bag was filled with the
solution of protein with the aid of a small funnel, all air bubbles
were removed and the glass tube was pushed into the bag to serve as
a manometer. The bag was then put into a beaker usually con-
taining 350 c.c. of water, having the same pH as the protein solu-
tion. The surface of the stopper was so adjusted that it lay in the
surface of the water in the beaker and the glass tube (or manometer)
was pushed a little deeper into the bag so that at the beginning the
level of the protein solution was about from 20 to 30 mm. above
that of the water in the outside beaker.

The water diffused from the outside beaker into the protein
solution and the column of liquid in the manometer rose to a
maximum which was usually reached in about 6 hours or possibly
less. It must be taken into consideration that two changes in
pH will occur in these experiments which affect the osmotic
equilibrium. The one change is due to the Donnan equilibrium
which was referred to in the introduction. The other change is
due to the influence of the CO2 of the air in the outside solution
and this influence is especially disturbing when alkaline 'solutions
are used. It must also be borne in mind that in these experi-
ments the protein solution is also usually diluted through the
entrance of water into the collodion bag. In later chapters
measures will be mentioned by which these sources of error
can be avoided or diminished.

68

THEORY OF COLLOIDAL BEHAVIOR

One per cent solutions of originally isoelectric protein were
made, each solution containing a certain amount of an acid or of
alkali to give it a definite pH. In each case the collodion bag

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FIG. 14. — Influence of pH and valency of anion on osmotic pressure of solu-
tions of different gelatin-acid salts. The osmotic pressure is a minimum at the
isoelectric point, pH 4.7, rises with the addition of acid until pH is 3.4, and
then drops .upon the addition of more acid. The curves for gelatin chloride and
gelatin phosphate are identical.

containing the gelatin solution was dipped, as described, into a
beaker containing 350 c.c. of water of originally the same pH as
that of the protein solution used. On account of the Donnan
equilibrium this equality of pH in the inside and outside solu-

THE VALENCY RULE AND THE HOFMEISTER SERIES 69

tions was not retained, the pH rising higher inside than outside in
the case of solutions of gelatin-acid salts. The observations
lasted usually for 1 day but the level of liquid in each manometer
was recorded at first every 20 or 30 minutes and the values
recorded the next day were used to plot the curves in Fig. 14.
The osmotic equilibrium was usually established in about 6
hours. The experiments were carried on in a thermostat at a
temperature of 24°C.

Figure 14 gives the curves of the osmotic pressure for solutions
of originally 1 per cent isoelectric gelatin with four different
acids, HC1, H2S04, oxalic, and phosphoric acids.1 The abscissae
are the pH of the gelatin solutions after osmotic equilibrium was
established, i.e., at the end of the experiment. The pH was
always determined potentiometrically. The reader will notice
that the four curves have a number of characteristic features in
common. The osmotic pressure is, in all cases, a minimum at
the isoelectric point, namely, at pH = 4.7; it rises with increasing
hydrogen ion concentration (or diminishing pH) , and the curves
all reach a maximum at about pH = 3.4. When the hydrogen
ion concentration rises still further (or with a further drop in pH)
the curves for the osmotic pressure of the solutions of the four
gelatin salts diminish almost as steeply as they rose on the other
side of the maximum. It may be noticed in passing, that Pauli2
and Manabe and Matula3 speak of a maximum in the viscosity
curves of albumin at a pH of about 2.1. It will be observed that
the maximum for osmotic pressure lies at a much higher pH,
namely at about pH 3.4, and that at pH 2.1 the curves are at a low
level again, not much above that of the isoelectric point. This
form of the curves of osmotic pressure when plotted as a func-
tion of pH of the protein solutions is very characteristic and
invariable.

The main point, however, which interests us in this connection
is the proof of the valency rule. The titration curves show that
in the case of gelatin phosphate as well as of gelatin chloride the
anion is monovalent, H2P04 and Cl. The valency rule demands

1 LOEB, J., J. Gen. PhysioL, vol. 3, p. 691, 1920-21.

2 PAULI, W., " Kolloidchemie der Eiweisskorper," Dresden and Leipsic,
1920.

3 MANABE, K., and MATULA, J., Biochem. Z., vol. 52, p. 369, 1913.

70 THEORY OF COLLOIDAL BEHAVIOR

that the osmotic pressures of the two salts should be identical
and a glance at Fig. 14 shows that this is the case. The anion
of gelatin oxalate should also be essentially monovalent for pH
below 3.0 and we see that the descending branch of the oxalate
curve, from pH 3.0 and below, practically coincides with the
descending branch of the curve for gelatin chloride and phos-
phate. For pH above 3.0 the curve for the osmotic pressures of
gelatin oxalate is slightly lower than the curve for gelatin phos-
phate and gelatin chloride, as the theory of electrolytic dissocia-
tion demands, since for pH above 3.0 oxalic acid dissociates
electrolytically more and more like a dibasic acid the higher
the pH. Hence, at about pH 3.4 the majority of the anions of
gelatin oxalate is monovalent, but a certain small percentage is
divalent. For this reason the curve for gelatin oxalate is at
pH 3.4 or for higher pH not quite as high as that for gelatin
chloride or phosphate. This is in strict agreement with the
titration curves in Fig. 7.

The titration curves in Fig. 7 show also that H2S04 forms a
divalent anion in combining with gelatin and we notice that the
maximum of the osmotic pressure curve at pH 3.4 is less than
one-half that of the osmotic pressure curve for gelatin chloride
or gelatin phosphate at the same pH.

These results are then in full agreement with the titration
experiments if we assume that only (or chiefly) the sign and the
valency of the ion with which the protein is in solution determine
the osmotic pressure of the protein salt formed, while the nature
of the ion has either no effect or if it has any effect the latter must
be so small that it escapes detection.

If the Hofmeister series were correct, we should have expected
that the curve for the osmotic pressure of gelatin phosphate
should have been of the order of that of gelatin sulphate or even
lower instead of being equal to that of gelatin chloride; and the
same should have been true for the curve for gelatin oxalate.

I have repeated these experiments so often that there can be
no doubt about the correctness of the result.

The experiments with 1 per cent solutions of originally isoelec-
tric crystalline egg albumin confirm the valency rule also for
this salt.1 The abscissae are again the pH determined at the
, J., J. Gen. PhysioL, vol. 3, p. 85, 1920-21.

THE VALENCY RULE AND THE HOFMEISTER SERIES 71

beginning of the experiment, the ordinates the osmotic pressure
after equilibrium was reached. The acids used were HC1, H2SO4,
oxalic acid, and H3PO4 (Fig. 15). The reader notices again that
the osmotic pressures are a minimum at the isoelectric point,
that they reach a maximum at pH a little above pH 3.2, and
that they then drop again.

FIG. 15. — Osmotic pressure of different albumin-acid salts. The ordinates
indicate the osmotic pressure (in mm. of 1 per cent albumin solution); the
abscissae are the pH. All solutions are 1 per cent in regard to isoelectric albumin.
The curves for albumin chloride and albumin phosphate are identical.

The four curves confirm the valency rule. The curves for
albumin chloride and albumin phosphate are practically identical,
that for albumin sulphate is almost but not quite half as high as
that of phosphate, and the curve for oxalate is at the maximum
a little lower than that for chloride.

The valency rule holds also for casein-acid salts.1 Since
casein oxalate and sulphate are too sparingly soluble we can only
compare the osmotic pressures of casein phosphate and casein
chloride. The curves for the osmotic pressures of these two
J., J, Gen. Physiol, vol. 3, p. 547, 1920-21,

72

THEORY OF COLLOIDAL BEHAVIOR

salts are alike if plotted over the pH, as Fig. 16 shows. The
maximal osmotic pressure lies at pH of about 3.0.

There is then no doubt that the curves for the osmotic pressures
of the three proteins, gelatin, crystalline egg albumin, and
casein obey the valency rule, and show no appreciable influence
of the nature of the ion except that of the sign of charge and
valency.

FIG. 16. — Osmotic pressure of 1 per cent solutions of casein chloride and casein
phosphate as function of pH. The two curves are almost identical.

In the older experiments in which the hydrogen ion concentra-
tions were not measured, the action of weak acids led the investi-
gators into error. In the Hofmeister series it is generally
contended that acetic acid acts like sulphuric acid and not like
hydrochloric or nitric acids. This is due to the fact that the
investigators compared the effects of different acids at equal
molecular concentrations instead of comparing the effects of
different acids at the same pH. If this is done it is found that
acetic acid .acts like HC1 and not like H2SO4. Figure 17 gives
the curves for the osmotic pressure of about 0.8 per cent solutions

THE VALENCY RULE AND THE HOFMEISTER SERIES 73

of originally isoelectric gelatin with six different acids, HC1,
H2SO4, acetic, monochloracetic, dichloracetic, and trichloracetic
acids plotted over pH as abscissae.1 Since the concentration of

340
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FIG. 17. — Osmotic pressure (in mm. BUG) of about 0.8 per cent solutions of
gelatin chloride, gelatin acetate, monochloracetate, dichloracetate, and tri-
chloracetate. The curves are practically identical.

the originally isoelectric gelatin in these solutions was lower than
in the experiments represented in Fig. 14 (about 0.8 per cent
instead of 1 per cent) , the osmotic pressures are also all lower, but
the results are relatively the same. Thus the maximal osmotic
1LOEB, J., J. Gen. PhysioL, vol. 3, p. 85, 1920-21.

74 THEORY OF COLLOIDAL BEHAVIOR

pressure of gelatin sulphate is in Fig. 17 also a little less than one-
half of the maximal osmotic pressure of gelatin chloride and the
maximum lies again at pH of about 3.4. The four acetic acids
have their maximum also at the same pH and this maximum is
equal to that of HC1.1 The slight variations in the height of the
curves for the five monobasic acids are merely accidental and
probably chiefly due to slight differences in the concentration of
the isoelectric gelatin. In these experiments each gram of
powdered gelatin was brought independently to the isoelectric
point and in this procedure about 20 per cent of gelatin were
lost, but the loss varied slightly in the different experiments.
In the experiments represented in Fig. 14 a large quantity
of powdered gelatin was brought to the isoelectric point and
doses of 1 gm. of isoelectric gelatin were used. In this latter
case the quantity of originally isoelectric gelatin was always
the same.

It was also found that the osmotic pressure of 0.8 per cent
solutions of gelatin tartrate and gelatin citrate is approxi-
mately the same as that of gelatin chloride of the same pH.

The writer has also shown that the curves for the osmotic
pressure of 1 per cent solutions of originally isoelectric crystal-
line egg albumin are identical for albumin chloride, albumin
acetate, and albumin dichloracetate, when plotted over the pH
as abscissae.1

These experiments on gelatin and albumin leave no doubt that
the acetates behave like chlorides and not like the sulphates.
Pauli claimed that trichloracetic acid acted like sulphuric acid but
this is certainly not the case as far as the osmotic pressure of
gelatin solutions is concerned.

The idea that the valency of the ion in combination with a
protein is the chief if not the only factor which influences its
osmotic pressure is corroborated by measurements of the osmotic
pressure of metal gelatinates. We had shown in Chap. IV that
Ca(OH)2 and Ba(OH)2 combine with gelatin in equivalent pro-
portions and that hence, the ion in combination with gelatin
in these cases is the bivalent cation Ca or Ba. The experiments
showed that Li, Na, K, and NH4 gelatinate have about the same
, J., J. Gen. Physiol., vol. 3, p. 85, 1920-21.

THE VALENCY RULE AND THE HOFMEISTER SERIES 75

osmotic pressure at the same pH and the same concentration of
originally isoelectric gelatin; while under the same conditions Ba
and Ca gelatinate have an osmotic pressure less than one-half of
that of the metal gelatinates with monovalent cation.1 The same

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FIG. 18. — Curves of the osmotic pressure of NEU, Na, and Ca albuminate
at different pH. The curves for NEU and Na albuminate are practically
identical.

is true in the case of the metal salts of crystalline egg albumin.
Figure 18 shows that the curves for the osmotic pressure of NH4
and Na albuminate are about the same for the same pH while
that for Ca albuminate is about half as high.
1 LOEB, J., J. Gen. Physiol., vol. 3, p. 85; 547, 1920-21.

76 THEORY OF COLLOIDAL BEHAVIOR

Similar results were obtained in the case of the osmotic pressure
of metal caseinates.

All experiments agree that only the sign and the valency of
the ion with which a protein is in combination determine its
osmotic pressure while the specific nature of the ion seems to
have no influence. This fact is of the greatest significance since
it was to be expected if colloidal behavior is due to the Donnan
equilibrium. The writer may state that this valency rule was
found before he was aware of the fact that the influence of
electrolytes on the osmotic pressure of protein solutions could be
derived from the Donnan equilibrium.

(B) SWELLING

It is generally stated in colloidal literature that solid blocks
of gelatin swell more in chlorides, bromides, or nitrates than in
water and that they swell less in citrates, acetates, tartrates,
phosphates, and sulphates than in water. The author of this
statement is Hofmeister1 who was a pioneer and who cannot
be blamed for not considering the hydrogen ion concentration
of his solutions about which nothing was known at the time of
his experiments. In Hofmeister's experiments gelatin blocks
were put into salt solutions of a high concentration, and the
differences in the effects observed in different solutions were slight.

He even states that sugar solutions have a dehydrating effect,
like certain salts, and this fact alone should have warned chemists
that his experiments could not be used for conclusions concerning
the specific effects of ions on the physical properties of colloids.
As far as the writer knows the discrimination between "hydrat-
ing" and " dehydrating" ions originated from these experiments.

It is often asserted that Hofmeister's ion series for swelling
have been confirmed by other authors. Thus on page 373 of
Zsigmondy's book " Kolloidchemie " (2nd edition), the following
statements are made in support of this impression.

"Wo. Ostwald who compared the efficiency of different acids found
that swelling diminishes in the acids in the following order, HC1 >
HNOs > acetic acid > sulphuric acid > boric acid. Fischer has shown
that the acid and alkali swelling of gelatin as well as that of fibrin is

1 HOFMEISTER, F., Arch. exp. Path. u. Pharm., vol. 28, p. 210, 1891.

THE VALENCY RULE AND THE HOFMEISTER SERIES 77

diminished by the addition of salt, and that chlorides, bromides, and
nitrates have a less dehydrating action than acetates, sulphates, or
citrates. We have here a similar series as in the case of the precipita-
tion of proteins by alkali salts, although the order does not agree
entirely."

The writer is inclined to interpret Ostwald's and Fischer 's
experiments differently from Zsigmondy, since both authors
ignored the hydrogen ion concentration of their solutions. Our
experiments have shown that it is necessary to base conclusions
concerning the relative efficiency of ions on experiments with
equal hydrogen ion concentration. By ignoring this postulate
Ostwald only proved that acetic and boric are weaker acids than
nitric but not that the acetate and borate anions have a greater
depressing effect on the swelling of gelatin than NO3; and Fischer
only proved that citrates and acetates are buffer salts which
when added to a solution of a strong acid diminish its hydrogen
ion concentration, but not that the acetate and citrate anions have
a greater depressing effect on the swelling of gelatin than Cl or
NO3. Both authors erroneously ascribed the effects of variation
of pH to an effect of the nature of the anion. The Hofmeister
series of ion effects on swelling has, in reality, never been
confirmed.

If we wish to study the specific effects of ions on the swelling
of gelatin we must proceed from isoelectric gelatin, bringing it
to different pH by different acids or alkalies and then compare
the swelling at the same pH for these different acids or alkalies.
If this is done it is found that when gelatin is in combination
with the anion of a weak dibasic or tribasic acid, e.g., tartaric,
citric, phosphoric, its degree of swelling is the same as when it is in
combination with Cl or NO3; since in all these cases the anion of
the gelatin salts is monovalent, and that only in the case of gela-
tin sulphate is the swelling considerably less, because H2SO4 com-
bines with gelatin in equivalent and not in molecular proportions
as does the weak dibasic or tribasic acid, e.g., phosphoric.1

The following simple and quick volumetric method for measur-
ing the swelling was adopted.

Dry powdered gelatin was sifted and the grains no longer
going through sieve 50 but going through sieve 40 or 30 were
, J., J. Gen. Physiol, vol. 3, p. 247, 1920-21.

78 THEORY OF COLLOIDAL BEHAVIOR

selected for the experiment. Doses of 1 gm. each were weighed
out and each was put for an hour into 100 c.c. M/128 acetic
acid at 10°C. to bring the gelatin to the isoelectric point. The
powdered mass was then put on a filter and washed five times
with 25 c.c. of distilled water of 5°C. In the acetic acid solution
and during the washing on the filter the powdered gelatin is
stirred constantly. In this washing about 20 per cent of the
gelatin were lost, so that the mass of gelatin in the following
experiments was only about 0.8 gm. each.

Each dose of originally 1 gm. of dry powder which had mean-
while absorbed a certain quantity of liquid (which was about the
same for each dose of isoelectric powder) was then put for 1 hour
at about 20° into 100 c.c. of different concentrations of the acid
or base whose influence on swelling was to be tested, and the
mass was frequently agitated. To measure the relative amount
of swelling in different acids or alkalies and at different pH the
mass was poured into graduated cylinders of 100 c.c. in which the
granules settled very rapidly to the bottom. The cylinders were
kept in a water bath at 20° for about 10 to 15 minutes and the
volume occupied by the gelatin granules, after settling, was then
read. This volume included a certain amount of solution between
the granules and, therefore, the real volume of the gelatin was
smaller than that read. While therefore, the method cannot be
used to measure the absolute amount of swelling it allowed us to
determine the relative influence of different acids or bases on the
swelling for the same pH.

The pH inside the gelatin granules and the surrounding
solution are quite different, owing to the Donnan equilibrium.
It is, therefore, not correct to assume that the pH of the granules
of gelatin is that of the supernatant liquid. The pH of the
granules of gelatin was determined after the gelatin had been
poured on a filter and the acid in the interstices of the granules
of gelatin had been allowed to drain off. Traces of this outside
acid remained undoubtedly at the surface of the granules. • The
gelatin was then melted and its volume brought to 100 c.c. by
adding enough distilled water of pH 5.6. The pH was determined
potentiometrically. This pH was probably a trifle too low on
account of some of the acid adhering.

Figures 19 and 20 give the results of the measurements of swell-

THE VALENCY RULE AND THE HOFMEISTER SERIES 79

ing in acid. The abscissae are the pH found in the gelatin after
equilibrium was established. The ordinates represent the figures
for the volume of the granules of about 0.8 gm. of gelatin in
different acids. It is obvious that in all cases the volume (or
swelling) is a minimum at the isoelectric point pH = 4.7, that it
rises with diminishing pH until the maximum is reached at a pH
of about 3.2 or a little less, and that the curve drops steeply with

6

FIG. 19.— Influence of HC1, HNO3, H3P04, H2SO4, trichloracetic, and oxalic
acids on the swelling of gelatin. Abscissae are the pH, ordinates the volume of
gelatin. The curves for all the acids are practically identical except that for
HaSCh which is about one-half as high as the curves for the other acids.

a further diminution of pH (i.e., a further increase of hydrogen
ion concentration) . The main fact is, however, that the curves
for the influence of HC1, HNO3, trichloracecic, oxalic, phos-
phoric, citric, and tartaric acids are practically identical, proving
that only the valency and not the nature of the anion of the
acid used influences the swelling of gelatin; since the anion of
weak dibasic or tribasic organic acids combining with the gelatin
is always monovalent.

80

THEORY OF COLLOIDAL BEHAVIOR

The curve for the swelling of gelatin sulphate, where the anion
combining with gelatin is bivalent, is only about half as high as
the curve for the salts of gelatin with the anion of weak dibasic
acids (Figs. 19 and 20).

FIG. 20. — Influence of citric, tartaric, and acetic acids on swelling of gelatin.
The curves for citric and tartaric acids are practically identical with those for
HC1 and HNO3 in Fig. 19. That for acetic acid is a little higher owing possibly
to some specific and secondary effect of this acid on the cohesion of the jelly.

Acetic acid gives an increasing amount of swelling, but it must
be remembered that 1 M acetic acid had to be used to bring the
pH of the gelatin to 3.0, and it is not impossible that in this case
the high concentration of undissociated acid caused a secondary

THE VALENCY RULE AND THE HOFMEISTER SERIES 81

physical modification of the gelatin (e.g., diminution of cohesion
between the particles of gelatin).

Figure 21 gives the curves for the action of alkalies on swelling.
The curves for Li, Na, K, and NH4 gelatinate of the same pH
are practically the same, except that the values for NH4OH are
irregular for pH above 8.5, possibly on account of the fact that
the concentration of NH4OH required to bring gelatin to such pH

5 6 7 8 9 10 11 12

FIG. 21. — Curves for the effect of different bases on swelling. Those for
LiOH, NaOH, KOH, and NH4OH are practically identical and about twice as
high as those for Ca(OH)2 and Ba(OH)2.

is rather high. The main fact is that the ratio of the maximal
swelling of gelatin salts with bivalent cation, like Ca or Ba, is
considerably less than that of gelatin salts with monovalent
cation, like Na, K, or NEU.1 This agrees with the results of the
titration experiments which show that Ca(OH)2 and Ba(OH)2
combine with gelatin in equivalent proportions and that, hence,
the cation in combination with the gelatin is, in this case, bivalent.

It should be pointed out that the maximal swelling of gelatin
in alkalies was less than that in acids. This was not observed in
the osmotic pressure curves. It is probably due to differences of
cohesion of the ions of the gel in the two cases.

The results show clearly that the Hofmeister series is not the
correct expression of the relative effect of ions on the swelling of

1 LOEB, J., /. Gen. PhysioL, vol. 3, p. 247, 1920-21.

82 THEORY OF COLLOIDAL BEHAVIOR

gelatin, and that it is not true that chlorides, bromides, and
nitrates have "hydrating" and acetates, tartrates, citrates, and
phosphates " dehydrating " effects. If the pH of the gelatin is
taken into consideration, it is found that for the same pH the
effect on swelling is the same for Cl, NO3, trichloracetate, tartrate,
succinate, oxalate, citrate, and phosphate, while the swelling is
considerably less for S(>4. This is exactly what we should expect
according to the valency rule on the basis of the combining
ratios of different acids with gelatin, since the weak dibasic and
tribasic acids combine with gelatin in molecular proportions
while the strong dibasic acid H2SO4 combines with gelatin in
equivalent proportions. In the case of the weak dibasic acids
the anion in combination with gelatin is monovalent and in
the case of the strong H2SO4 it is bivalent. Hence, it is only
the valency and not the nature of the ion in combination with
gelatin which affects the degree of swelling.

(C) VISCOSITY

The valency rule which permits us to predict the relative
osmotic pressure of solutions of protein holds also in the case
of viscosity of gelatin and casein solutions.

We will begin with experiments on the influence of gelatin
on the viscosity of water.1 A 4 per cent stock solution of
isoelectric gelatin was prepared, and some of the stock solution
was heated to 45° and made up to a 1.6 per cent solution in
quantity sufficient for a day's experiments. This 1.6 per cent
solution was kept during the day at 24°C. To 50 c.c. of this
solution was added the desired acid or alkali in sufficient quantity
and then the volume raised to 100 c.c. by the addition of enough
distilled water. The 0.8 per cent solution was then rapidly
brought to a temperature of 45°, kept there for 1 minute and was
then rapidly cooled to 24°C. The solution was stirred constantly
during the heating and cooling. The viscosity was measured
immediately after the solution was cooled to 24°C. The measure-
ments were all made at 24°C. by using the time of outflow
through a viscometer. The time of outflow of distilled water
through the Ostwald viscometer used was exactly 1 minute at

1 LOEB, J., J. Gen. Physiol, vol. 3, p. 85, 1920-21.

THE VALENCY RULE AND THE HOFMEISTER SERIES 83

24°C. Each measurement of viscosity was repeated with the
same gelatin solution and the beginning and the end of a series

FIG. 22. — Curves representing relative viscosity of 0.8 per cent solution of
originally isoelectric gelatin brought to different pH. The curves for relative
viscosity of gelatin chloride, phosphate, and oxalate are practically identical.
Relative viscosity is given as time of outflow of gelatin solution divided by time
of outflow of water through viscometer at 24°C.

consisted in the measurement of viscosity of isoelectric gelatin.
These latter measurements agreed in all experiments within 1

84

THEORY OF COLLOIDAL BEHAVIOR

second varying only between 80 and 81 seconds, thus guarantee-
ing the reproducible character of the experiment.

FIG. 23. — Curves representing relative viscosity of gelatin succinate, tartrate,
and citrate. The curves are practically identical with those for the viscosity of
gelatin chloride and phosphate.

The results can be given briefly. Figure 22 gives the curves
for the relative viscosity of 0.8 per cent solutions of gelatin chloride,

THE VALENCY RULE AND THE HOFMEISTER SERIES 85

sulphate, oxalate, and phosphate. The abscissae are the pH of
the gelatin solutions, the ordinates the ratio of the time of outflow
of the gelatin solutions divided by the time of outflow of pure

6

1 2 3 4 47 5

FIG. 24. — Curves representing relative viscosity of gelatin acetate, mono-, di-,
and trichloracetate. Curves identical with those for gelatin chloride and
phosphate.

water. For the sake of brevity this quotient will be called
the relative viscosity of the gelatin solution. The curves for the
four acids all rise steeply from the isoelectric point with increasing

86 THEORY OF COLLOIDAL BEHAVIOR

hydrogen ion concentration until they reach a maximum at pH
about 3.0 or slightly above. The curves then drop again. The
curves for the three salts, gelatin chloride, oxalate, and phosphate
are practically identical while the curve for gelatin sulphate is
considerably lower.

Figure 23 gives the curves for the viscosity of gelatin citrate,
tartrate, and succinate. The three curves are practically
identical and also identical with the curves for gelatin chloride
and gelatin phosphate in Fig. 22.

Figure 24 gives the curves for the viscosity of 0.8 per cent solu-
tions of originally isoelectric gelatin to which acetic and mono-,
di-, and trichloracetic acids have been added. The curves are
again identical with those for gelatin chloride, phosphate, etc.

The titration curves with alkalies have shown that Ca and Ba
combine with proteins in equivalent proportions and we should
hence expect that the viscosity curves for Ba and Ca proteinates
would be lower than those for Li, Na, K, and NH4 proteinates.
This was found to be correct.

In experiments on the viscosity of casein solutions the limited
degree of solubility of the salts of casein has to be considered. In
the region from 4.7 to 3.0 or even a trifle below neither casein
chloride nor casein phosphate is sufficiently soluble to permit
the preparation of a 1 per cent solution, and in this region the in-
fluence of casein on the viscosity of water is, therefore, negligible.
The curve representing the relative viscosity of 1 per cent casein
chloride and phosphate solutions (as compared with that of pure
water) rises sharply at pH 3.0. With a further increase of the
hydrogen ion concentration the curve falls steadily as it did in
the case of the curve for gelatin. This indicates that the maxi-
mum for the influence of casein chloride on viscosity lies at pH
equal to or greater than 3.0. The curve for the influence of
casein phosphate on viscosity coincides with the curve for
casein chloride.

The difference between the viscosity curve of Na caseinate
and Ba caseinate (Fig. 25) is also similar to that of the
corresponding gelatin salts.

In the influence of monovalent or bivalent ions on those physi-
cal properties of proteins which are characteristic for colloidal be-
havior only the valency and the sign of charge of the ion play a role,

THE VALENCY RULE AND THE HOFMEISTER SERIES 87

while ions of the same sign of charge and valency have similar
effects. In the second part of the book it will be shown that this
is due to the fact that the colloidal behavior is the expression of
the forces set up by the Donnan equilibrium and in the equation

pH 6

10

11

12

FIG. 25. — Curves representing relative viscosity of Na and Ba caseinate for

different pH.

for this equilibrium only the sign of charge and valency appear.
It is also obvious that it would have been impossible to arrive at
this valency rule without the proof of the stoichiometrical
character of the combination of proteins with acids or bases,
especially the proof that weak dibasic and tribasic acids combine
in the range of pH concerned in molecular proportions.

CHAPTER VI

THE ACTION OF NEUTRAL SALTS ON THE PHYSICAL
PROPERTIES OF PROTEINS

1. THE DIFFERENCE IN THE EFFECT OF ACIDS, ALKALIES,
AND SALTS ON PROTEINS

The most striking proof for the alleged existence of specific
ion effects on proteins (aside from those due to valency of the
ion), seemed to have been furnished by experiments on the
influence of neutral salts on the osmotic pressure, swelling, and the
viscosity of protein solutions.

It has been noticed by a number of authors that the influence
of neutral salts on the physical properties of proteins differs from
that of acids and bases, and various attempts have been made to
find an accurate expression for this difference. Some hold that
neutral salts form "adsorption compounds" with " electrically
neutral," i.e., non-ionized, protein molecules, in which both ions
of the salt were believed to be simultaneously adsorbed by the
"neutral" protein molecule.1 This idea is no longer tenable for
salt solutions of low concentration since the experiments with
powdered gelatin discussed in Chapter II have shown that only
one (or practically only one) of the two ions of a neutral salt can
combine at one time with a protein. At the isoelectric point,
i.e., at pH 4.7, gelatin can combine with neither ion of a neutral
salt; at a pH > 4.7 only the metal ion of the neutral salt can com-
bine with the gelatin, forming metal gelatinate ; at a pH < 4.7 only
the anion of the neutral salt is capable of combining with the
protein, forming gelatin-acid salts.

R. S. Lillie has made the statement that while acids and alkalies
increase, salts depress the osmotic pressure of gelatin.2 This
statement, while it was the expression of facts actually observed

1 PAULI, W., Fortschr. naturwiss. Forschung, vol. 4, p. 223, 1912.

2 LILLIE, R. S., Am. J. Physiol.,vol. 20, p. 127, 1907-08.

88

THE ACTION OF NEUTRAL SALTS 89

by Lillie, is not entirely correct owing to the fact that the influence
of the hydrogen ion concentration of the gelatin solution was not
taken into consideration. It was shown in the preceding chapter
that if acid is added to a gelatin-acid solution of a pH of 3.0 or
below, the effect is practically the same as when we add a neutral
salt, namely, a diminution of the osmotic pressure of the solution;
and that when alkali, e.g., KOH, is added to a solution of a metal
gelatinate of pH 11.0 or above, the effect is also a similar depres-
sion of the osmotic pressure to that caused by the addition of
KC1. A depression is also noticed when some acid is added to a
solution of metal gelatinate or when some alkali is added to
gelatin-acid salts ; since in both cases the gelatin is brought nearer
to the isoelectric point.

It is also incorrect to speak of an antagonism between the
effects of acids and salts, since the facts mentioned show that
there is also an antagonism between little and much acid; thus,
if the pH of a gelatin-acid salt is 3.0, a further addition of the
same acid depresses the osmotic pressure or viscosity. The
question then arises, What is the correct expression of the facts
in the case?

The answer seems to be as follows: Suppose the pH is below
but near that of the isoelectric point of a protein and HC1 be
added. In this case the more acid is added the more non-
ionogenic protein is transformed into salt. This salt formation
raises the osmotic pressure, swelling, and viscosity of the protein.
This agrees with the views of Laqueur and Sackur, and of Pauli.
At the same time the anion of the acid has an opposite, namely
a depressing effect. The addition of acid has, therefore, two
opposite effects on the osmotic pressure, viscosity, and swelling
of protein, namely, first, an augmenting effect due to increasing
protein-salt formation with increasing hydrogen ion concentration,
and second, a depressing effect due to the anion, in our example
Cl. At first, the augmenting effect increases more rapidly than
the depressing effect. When, however, the pH of the protein
solution approaches the value 3.0 the augmenting influence due
to the formation of new gelatin chloride grows less rapidly with
a further decrease in pfi than does the depressing effect of the
anion, and hence, when the amount of acid added increases
still further, the depressing effect of the Cl ion prevails over the

90 THEORY OF COLLOIDAL BEHAVIOR

augmenting effect of the H ion. The true reason for this will
appear in Chap. VIII.

When an alkali, e.g., NaOH, is added to a protein, e.g., gelatin,
with a pH slightly above 4.7, at first more of the non-ionogenic
protein is transformed into metal proteinate, e.g., Na gelatinate;
and this raises the osmotic pressure, viscosity, and swelling
rapidly by causing an increase in the concentration of ionized
protein for a reason which will be given later. The cation of the
alkali, the Na ion, has a depressing effect on these properties,
and this depressing effect begins to be visible when the pH
exceeds a certain value. After this, with a further addition of
alkali, the depressing action of the cation (e.g., of Na) increases
more rapidly than the augmenting action of the OH ion.

The addition of neutral salts of a concentration below N/16
to isoelectric gelatin has no effect on osmotic pressure, viscosity,
or swelling of the gelatin solution. When neutral salt is added
to a gelatin solution on either side of its isoelectric point only a
depressing action of that ion which has the opposite sign of
charge to the protein ion is observed. No augmenting action of
the ion with the same sign of charge as the protein is noticeable.
Thus, if CaC^or Na2SO4 is added to a solution of gelatin chloride
or gelatin nitrate only a depressing effect of the Cl or SO4 ion
is observed but no augmenting effect of the Ca or Na ion; while
when these salts are added to a solution of a metal gelatinate only
a depressing effect of the Ca or Na ion is apparent but no aug-
menting effect of the anion.1 The theoretical reason for these
effects will be given in Chap. VIII.

An approximately 1.6 per cent solution of isoelectric gelatin
was prepared and brought to a pH of 4.0. The solution was made
0.8 per cent in regard to the originally isoelectric gelatin by adding
to 50 c.c. of the 1.6 per cent solution either 50 c.c. of H2O or of a
salt solution, e.g., NaCl, of different molecular concentration,
from M/8,192 to 1 M, taking care that the hydrogen ion concen-
tration remained the same. The time of outflow through a
viscometer was determined in the way described in Chap. V,
and the ratios of the time of outflow to that of water were plotted
as ordinates over the pH as abscissae (lower curve, Fig. 26). We

1 The contents of this chapter are based on LOEB, J., J. Gen. Physiol.,
vol. 3, p. 391, 1920-21.

THE ACTION OF NEUTRAL SALTS

91

will designate this value as relative viscosity. The addition
of the NaCl causes only a drop, and no rise in the curve.

LO

nMlLN-KKKKN N N N
U 8192409620481024512 256 128 64 32 16 8

Concentration

FIG. 26.— Difference in the effect of different concentrations of NaCl and of
HC1 on the relative viscosity of an 0.8 per cent solution of gelatin chloride of
pH 4.0. In the case of NaCl we observe only the depressing effect of the Cl ion;
in the case of HC1 we notice an augmenting effect of the H ion and a depressing
effect of the Cl ion, the latter prevailing as soon as the concentration of acid
added is > N/256.

If, however, the 1.6 per cent gelatin solution of pH 4.0 is mixed
with various concentrations of HC1 (upper curve, Fig. 26) instead

92

THEORY OF COLLOIDAL BEHAVIOR

of with NaCl, at first a rise occurs which is followed by a drop
when the concentration of the Cl ion is a little above N/ 1,000.
In Fig. 26 the drop appears at a concentration of about N/256 HC1,
but the reader must remember that on account of the fact that

\

\

'\

Xk

28
2.7
26
25
24
23
2.2

Z1
20

1.9

">

1-7

1.6

15
1.4
1.3
12
1.1

Concentotion

FIG. 27. — The relative viscosity of 0.8 per cent solution of gelatin chloride
of pH 3.0 is depressed almost equally by the Cl ion of HC1 as of NaCl. The
augmenting effect of the H ion in the case of HC1 is no longer noticeable.

part of the acid combined with the gelatin the pH of the solution
was about 3.0. In other words, while the addition of H ions
increases the viscosity of a solution of gelatin chloride of pH 4.0,
the addition of Na ions does not have such an effect, but the Cl
ion depresses the viscosity in both cases, no matter whether
NaCl or HC1 is added to the gelatin solution; and the depressing
action of the Cl ion increases with its concentration. Moreover,

THE ACTION OF NEUTRAL SALTS

93

the increase of the viscosity by the H ions stops as soon as the
pH of the solution reaches about 3.0 for the reason stated.

When the same experiment is repeated with a gelatin solution
of pH 3.0, the addition of NaCl immediately causes a drop also

8

I

£4
2.3
2.2
2.1
20
1.9
1.8
1.7
1.6
1.5
1.4

1.2
1.1
1.0

Concentration

FIG. 28.— When the gelatin solution has a pH of 2.5, HC1 and NaCl depress the
relative viscosity of the gelatin solution to the same degree.

(Fig. 27) while the addition of HC1 no longer causes a rise but
the drop commences a little later than in the case of NaCl.

When, however, the same experiment is made with a gelatin
solution of pH 2.5 (Fig. 28), an immediate drop is noticed upon
the addition of HC1 as well as in the case of the addition of NaCl,

M

94

THEORY OF COLLOIDAL BEHAVIOR

and the curve for HC1 coincides practically with that for NaCl,
as our theory demands.

That the depression of the viscosity of gelatin chloride due to
the presence of a salt is exclusively determined by the anion of

Concentration

FIG. 29. — The depressing effect of equal molecular concentrations of NaCl,
CaCh, and LaCU on the relative viscosity of 0.8 per cent gelatin chloride solution
of pH 3.0 is roughly in proportion to the concentration of the Cl ions in the
solutions; i.e., as 1:2:3.

the salt and that the cation has no augmenting effect is shown
in Fig. 29, where the influence of NaCl, CaCl2, and LaCl3 upon
the viscosity of gelatin of pH 3.0 is represented. Fifty cubic centi-
meters of a 1.6 per cent solution of gelatin chloride of pH 3.0 were
added to 50 c.c. of a solution of different concentrations of each
salt as described, the pH being kept at 3.0. It is obvious from

THE ACTION OF NEUTRAL SALTS

95

Fig. 29 that the molecular concentrations of NaCl, CaCU, and
LaCl3, which depress the viscosity to the same level are approxi-
mately in the ratio of 3:2:1. Thus, when the effect of NaCl and

2.8
2.7
£6
25

2.4
2.3
£2
2.1
20
1.9
1.8
1.7
1.6
1.5
L4
1.3
1.2
1.1
1.0

:\

\

Nv

^r4

0 SI92 4096

512 256 128 64 32 16 8

| IN

Concentration of Cl

FIG. 30. — Showing that NaCl and CaCh have the same depressing'effect on the
viscosity of gelatin chloride of pH = 3.0 when the concentration of Cl ions is
the same.

CaCl2 is plotted over the same concentration of the Cl ions the
curves for the salts become nearly identical (Fig. 30), and the same
would be practically true for the LaCl3 curve. From this it follows

96

THEORY OF COLLOIDAL BEHAVIOR

that the depressing effect of these three salts on gelatin chloride
is practically exclusively a function of the concentration of the

4096 2048 1021 512 256 128 64 32 1

Concentration

FIG. 31. — The relative depressing effect of equal molecular concentrations
of NaCl, Na2SO4, and Na4Fe(CN)e on the relative viscosity of a gelatin chloride
solution of pH 3.0 is approximately as 1:4: 16.

Cl ion, while no augmenting effect of the cation is noticeable.
This observation disposes of vague hints found in the literature

THE ACTION OF NEUTRAL SALTS 97

of colloids that the opposite ions of a neutral salt affect the prop-
erties of a protein in an opposite direction. We made sure
that in all these cases the pH of the gelatin solution was not
altered by the addition of the salt.

When 0.8 per cent solutions of gelatin chloride of pH 3.0 are
prepared in solutions of Na salts with the anion of a weaker
acid, e.g., Na2 oxalate, Na4Fe(CN)6, the pH is increased and
there exists the danger of erroneously attributing a depressing
effect to the anion which in reality is caused by the increase in
pH. In Fig. 31 the effects of the addition of equal concentrations
of Nad, Na2SO4, and Na4Fe(CN)6 on gelatin chloride of pH =
3.0 are plotted. In the case of Na4Fe(CN)6 only the lowest
concentrations, from M/8,192 to M/ 1,024, could be used, since
in these only did the pH of the protein solution remain = 3.0.
Figure 31 shows that the depressing effect of these salts increases
rapidly with the valency of the anion. When the concentration
of the salt was only M/ 1,024 a drop in the viscosity was already
noticeable. This drop was small in the case of NaCl (from 2.8
to 2.6), was greater in the case of Na2S04 (from 2.8 to 2.35),
and considerably greater in the case of Na4Fe(CN)6 (from 2.8
to 1.5). The objection might be raised that since Na2SO4 has
twice as many cations as NaCl of the same concentration and
Na4Fe(CN)6 has four times as many cations, it was the difference
in the concentration of the cations which caused the difference
in the drop. This is refuted by the fact that Na2SO4 causes a
drop in the specific viscosity to 1.8 at a concentration of M/256
while NaCl causes the same drop at a concentration of above
M/64 which is about four times as high. If the concentration
of the cation were responsible for the drop the two concentrations
should be more nearly as 1 : 2. Na4Fe(CN) 6 causes the same drop
of the viscosity to 1.8 at a concentration less than M/ 1,024.
Hence, the concentration of Na4Fe(CN)6 required to cause the
same diminution of the specific viscosity as that caused by M/64
NaCl is less than one-sixteenth of the latter, while it should be
only one-fourth if the cation were responsible for the drop.

Experiments on osmotic pressure and on swelling lead to the
same formulation of the difference in the effect of acids and salts
as the viscosity experiments.

What has been shown for the effect of acids on the physical

7

98

THEORY OF COLLOIDAL BEHAVIOR

properties of proteins can also be shown for the influence of
alkalies. Thus, the addition of KOH to Na gelatinate of pH 12.0
depresses the viscosity in the same way as the addition of KC1
(Fig. 32) ; while the addition of little KOH to Na gelatinate of
pH 4.8 to 8.0 increases the viscosity, and the addition of KC1 to
Na gelatinate always depresses the viscosity. The depressing
effect of salts on the viscosity of solutions of metal gelatinate is

1

2.0
1.9

1.8
1.7
1.6
1.5
1.4
1.3
1.2
1.1
1 n

KOI

?[•.

ft5

~^1 f.

I I

S*

c

^

k

c

\,
c

N^

i(
<

>v/

1

ft.JdL 1L JtLliJl JHL 11 M ^^

u 6192409620451024512 256 1Z8 64 32 16

Concentration

FIG. 32. — The depressing effect of KOH and KC1 on Na gelatinate of pH 12.0
is practically the same.

due to the cation of the salt added, that of bivalent cations
being greater than that of monovalent cations, while the valency
of the anion has no effect.

We have already stated that the addition of neutral salt to
isoelectric gelatin leaves the viscosity and osmotic pressure of the
solution practically unchanged. This fact is of great importance
for the theory of colloids.

The depressing effect of neutral salts on the physical prop-
erties of proteins is, therefore, the same phenomenon as the
drop in the curves of these properties when too much acid or too
much alkali has been added. It is due to the fact that in all

THE ACTION OF NEUTRAL SALTS 99

cases that ion which has the opposite sign of charge to that of
the protein ion depresses the osmotic pressure, swelling, and
viscosity of proteins.

2. ION SERIES AND THE ACTION OF SALTS ON PROTEINS

From what has been said, it is clear that only one of the ions of
a neutral salt influences the physical properties of a protein,
namely that ion which has the opposite sign of charge to the
protein ion; and this influence is of a depressing character. We
will now show that this effect depends only upon the valency of
the depressing ion and that different ions of the same valency
have the same depressing effect. It is necessary to compare the
relative depressing action of low but equal concentrations of
different salts upon the physical properties of a gelatin salt, for
example, gelatin chloride of a definite pH; e.g., 3.0. As can be
easily surmised, the addition of a salt will in many cases alter the
pH of the solution and this alteration will be larger in the case of
certain salts, e.g., Na acetate, than in the case of others, e.g.,
NaCl. Unless we take into consideration these variations in the
pH caused by the addition of salts there will be danger of
erroneously ascribing the influence of a variation in the hydrogen
ion concentration to an influence of the nature of the anion.
The Hofmeister ion series, as far as they refer to proteins, are
largely due to this error.

The method of our experiments was as follows: 50 c.c. of a 1.6
per cent solution of originally isoelectric gelatin contained enough
HC1 to make the pH = 3.0. To this were added 50 c.c. of H2O
or of a salt solution of different molecular concentration, and the
viscosity of this mixture was measured using those precautions
which were described in the preceding chapter.

Figure 33 gives the curves representing the depression of the
relative viscosity of a gelatin chloride solution of pH 3.0 by dif-
ferent concentrations of salts with monovalent anion; namely,
NaCl, NaH2PO4, NaCNS, NaH tartrate, NaH2 citrate, and Na
acetate. The curve for Na2SO4 is added for comparison. The
monosodium salts of weak dibasic and tribasic acids dissociate
electrolytically into a Na ion and a monovalent anion, H2PO4, H
tartrate, H2 citrate, etc. All the salts mentioned in Fig. 33 are
therefore salts with monovalent anion with the exception of

100 THEORY OF COLLOIDAL BEHAVIOR

. Our valency rule demands that the relative depressing

M

ft ft ft fe f 9 : 9

Concentration.

FIG. 33. — The depressing effect of different salts with monovalent anion
(NaCl, NaH2PO4, NaCNS, NaH tartrate, and NaH2 citrate) on the relative
viscosity of 0.8 per cent solution of gelatin chloride of pH 3.0. The effects of
NaCl and NaHzPCh are identical since the pH is not altered by the addition of
these salts. The depression in the values for the relative viscosity is greater in
the case of Na acetate than in the case of NaCl for the reason that the Na acetate
raises the pH of the gelatin chloride solution.

effect of these salts (with the exception of Na2SO4) should be

THE ACTION OF NEUTRAL SALTS

101

nearly the same and that deviations from this rule should find
their explanation in corresponding deviations of the pH due to the
influence of certain of the salts. We will first consider this latter
influence as given in Table VI, which shows the results of the

TABLE VI. — CHANGES IN pH OF 0.8 PEE CENT GELATIN CHLORIDE OF
pH = 3.0 UPON ADDITION OF VARIOUS CONCENTRATIONS OF SALTS

Molecular concentrations of salts used

0

i-H

ocf

3

1

00

1

^

i— r

—

§

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|

CO

^

s
1st

oo
^

1

NaCl...

3 0

3.0
3.0
3.0
3.0
3.0
3.0
3.0

3.0
3.0
3.0
3.0
3.0
3.0
3.0

3.0
3.0
3.0
3.0
3.0
3.0
3.05

3.0
3.0
3.0
3.0
3.0
3.0
3.1

3.0
3.0
3.0
3.0
3.0
3.1
3.3

3.0
3.0
3.0
3.1
3.1
3.2
3.7

3.0
3.0
3.1
3.2
3.3
3.4
4.3

3.0
3.05
3.2
3.3
3.45
3.6
4.6

3.0
3.1
3.3
3.6
3.5
3.7

3.0
3.2
3.4
3.9
3.55
3.75

3.0
3.3

3.45
4.2

3.0
3.35
3.5
4.4

Na2SO4

3.0
3.0
3.0
3.0
3.0
3.0

NaH2PO4
NaCNS

NaH tartrate
NaH2 citrate
Na acetate

measurements of pH in these different gelatin solutions after
the addition of salts. The original gelatin chloride solution had
a pH of about 3.0 and the pH was not altered by the addition of
NaCl and only slightly by the addition of NaH2PO4 in con-
centrations below M/16. According to the valency rule the
curves for the depressing effect of NaCl and NaH2P04 should be
almost identical and Fig. 33 shows that this is the case.

Table VI shows that NaCNS, monosodium tartrate, and mono-
sodium citrate raise the pH of the solution as soon as the con-
centration reaches M/128 or more. If we consider this effect,
we must expect to find that the drop in the curves for NaCNS,
monosodium citrate, and monosodium tartrate is a little steeper
in concentrations of M/128 and above than the curve for the
depressing effect of NaCl. Figure 33 shows that the curves for
the depressing effect of these three salts are slightly lower than
the curve for NaCl or NaH2PO4. The greatest apparent
deviation from the valency rule occurs in the curve for Na acetate
whose depressing effect is of the order of that of Na2SO4.

In the colloidal literature it is always stated that Na acetate
acts like Na2SO4 and this is interpreted to mean that the acetate

102

THEORY OF COLLOIDAL BEHAVIOR

anion acts like the bivalent SO4 anion and not like the monovalent
Cl or NO3 anion. Table VI shows that Na acetate also depresses
the hydrogen ion concentration more than NaCl or NaH2PO4;

2.8
2.7
2.6
2.5
2.4
2.3
& 22

8 2.1
to
> 2.0

1 L9
33 1-8
& 1.7
1.6
1.5
1.4
L3
1.2
1.1
i r»

t —

—

^i

5

k^

\

ft

<

^ V^

\

1

,^

a

\

\

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\

Aj

>

i

\ j

\

\

N

»

PH

= 3..

j

M M M

M M. H M M M M
512 256 128 64 32 16

Concentration

FIG. 34. — When the pH is kept equal the depressing effect of equal concentra-
tions of NaCl and Na acetate on the relative viscosity of an 0.8 per cent gelatin
chloride or gelatin acetate solution of pH 3.3 is the same.

M/64 Na acetate brings the gelatin solution practically to the
isoelectric point, and at the isoelectric point the viscosity of
gelatin solution is a minimum. This lowering of the hydrogen ion

THE ACTION OF NEUTRAL SALTS 103

concentration (and not the alleged influence of the acetate anion)
explains the excessive depressing effect of Na acetate. That
this interpretation is correct can be proved in the following way:
0.8 per cent solutions of gelatin acetate of pH 3.3 and gelatin
chloride also of pH 3.3 were prepared. The relative viscosity
of these two solutions was practically the same (both were 0.8
per cent solutions in regard to originally isoelectric gelatin).
The solution of gelatin acetate of pH 3.3 was made up in various
concentrations of Na acetate of pH 3.3. The Na acetate solu-
tion of pH 3.3 was obtained by dissolving M/16 Na acetate in
IJ^J M acetic acid and the various degrees of dilution of this
M/16 Na acetate solution of pH 3.3 were brought about by
dilution with pure acetic acid of pH 3.3. The non-dissociated
molecules of acetic acid have no more depressing influence on
the physical properties of proteins than have the molecules of
any non-electrolyte. Figure 34 gives the curve representing the
depressing effect of Na acetate on gelatin acetate of pH 3.3, when
the pH is kept constant.

The gelatin chloride solution of pH 3.3 was made up in different
concentrations of NaCl and the depressing effect of NaCl on the
viscosity of gelatin chloride is also plotted in Fig. 34. It is
obvious from Fig. 34 that the depressing effects of Na acetate
and NaCl are identical when the pH is kept constant and identical
in both cases.

The same fact was confirmed in a somewhat different way.
A 1.6 per cent solution of gelatin chloride of pH 3.0 was made up
in various concentrations of Na acetate also of pH 3.0. In
order to prepare Na acetate solutions of pH 3.0, M/4 Na acetate
was dissolved in M/4 HC1 and the various dilutions required for
the experiment were obtained by diluting the mixture of equal
parts of M/4 HC1 and M/4 Na acetate with M/1,000 HC1.

The 1.6 per cent gelatin chloride solution of pH 3.0 was diluted
with 50 c.c. of this mixture so that the resulting 0.8 per cent
gelatin chloride solution of pH 3.0 contained various concentra-
tions of Na acetate (or more correctly of NaCl and Na acetate).
The curve representing the depressing effect of this salt is given
in Fig. 35, and is shown to be identical with the curve representing
the depressing effect of the addition of NaCl to gelatin chloride
of pH 3.0.

104

THEORY OF COLLOIDAL BEHAVIOR

We can, therefore, state that sodium acetate has the same effect
on the viscosity of gelatin chloride as the addition of any other
salt with monovalent anion, and that the anomalous effect

2.8
2.7
2.6
2.5
2.4
2.3

f »

£ 21

> 2.0
1 «

1 »

^ 1.7
1.6
1.5
1.4
1.3
1.2

1.1
1 n

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^

>

v._

^

\

i(

c

K,

i

\

<

^

J

\

ic^

X

\

1 ^^

c

V

9^,

\

^

i

^

\

X

1

\

1

r N

I

X,

pH

= 3.C

ft M M M M M M M M M M

U 8192409620481024512 256 128 64 32 16

Concentration

Fio. 35. — vSee legend of Fig. 34, except that the pH of gelatin solution is 3.0.

ascribed to the acetate anion in the colloidal literature is in
reality due to the depression of the hydrogen ion concentration
of the gelatin solution by the Na acetate, which is a buffer salt,

THE ACTION OF NEUTRAL SALTS

105

The failure to recognize the buffer character of salts, like the
acetates, citrates, and tartrates, has led to the error of the Hof-
meister ion series. In reality we find our valency rule confirmed
whereby all salts with an anion of the same valency have about
the same relative depressing effect on the viscosity of a gelatin
chloride solution if the pH of the solution is kept constant.

B ^

<& 55
CP 50
32 45
2_ 40

d 35
J? 30

^" 25

§

S 20

.ZJ

1 15
*> 10
S 5
f£ 0

i

"1

^

tl

x

N

2

r

•
K

\

V

px \

\

k <^

/».

•^

*^* <

M

B

M

p

j->

A

1

•

•\

a

* 5

; j

\

i

k

i

\
4

k

A

N

|

^

k

NBP

4

3

^s

^

:

°Na

ma

^n\

fp,

N

k

—

*Na

Hpd

trat

i

0 8192 4096 Z048 1024 512 256 128 64 32 16 ^

Concentration

FIG. 36. — Showing that the depressing effect of salts with monovalent anion
on the swelling of gelatin chloride of pH 3.3 is similar to that on the relative
viscosity. All salts with monovalent anion depress the swelling of gelatin chlor-
ide to the same extent, the seeming deviation from this rule being due to variation
in the pH of the gelatin solution caused by buffer salts.

What has been demonstrated for the effect of these salts on the
viscosity of gelatin solutions holds also for their effect on the
swelling of gelatin. The same volumetric method for measuring
the swelling effect was used which was described in the preceding
chapter. Figure 36 gives the relative depressing effect of NaCl,
NaH2P04, NaCNS, monosodium tartrate, monosodium citrate,

106

THEORY OF COLLOIDAL BEHAVIOR

and Na acetate on the swelling of gelatin chloride of pH 3.3
(the curve for Na2S04 is added for comparison), and Table VII
gives the variation of the pH of the gelatin caused by the addition
of these salts. Our theory demands that all these salts (except
Na2SO4) should depress the swelling of gelatin chloride of pH
3.3 to the same amount, and that deviations from this rule

TABLE VII. — CHANGES IN pH OF 0.8 PER CENT GELATIN CHLORIDE OF
pH = 3.3 UPON ADDITION OF VARIOUS CONCENTRATIONS OF SALTS

Molecular concentrations of salts used

o

O5
l-H

GO"

1

M/2,048

1
i— 1

a

i— i

1

§

CO

5

CO

CO

GO

NaCl

3.3
3.3
3.3
3.3
3.3
3.3
3.3

3.3
3.3
3.3
3.3
3.3
3.3
3.3

3.3
3.3
3.3
3.3
3.3
3.3
3.3

3.3
3.3
3.3
3.3
3.3
3.3
3.4

3.3
3.3
3.3
3.3
3.3
3.3
3.45

3.3
3.3
3.3
3.3
3.4
3.4
3.5

3.3
3.3
3.3
3.3
3.5
3.5
3.8

3.3
3.3
3.3
3.3
3.5
3.6
4.3

3.3
3.35
3.4
3.3
3.6
3.8
4.8

3.3
3.4
3.5
%3.3
3.7
3.85
5.2

3.3
3.5
3.6
3.35
3.7
3.9
5.4

3.3
3.6
3.7
3.4
3.7
3.9
5.5

Na2SO4

NaH2PO4

NaCNS

NaH tartrate
NaH2 citrate
Na acetate

must find their explanation in variations of pH caused by the
addition of salt. Table VII shows that the variations in pH are
small for NaCl, NaCNS, and NaH2PO4 and hence, the curves
for the depressing effect of these three salts upon the swelling of
gelatin are almost identical, as the valency rule demands. Mono-
sodium citrate and tartrate have a greater depressing effect on
the hydrogen ion concentration and Na acetate has a still greater
depressing effect than these two salts. This explains the appar-
ent deviation of the curves for these three salts from the valency
rule.

A. D. Hirschfelder1 has published a paper on the effects of
different salts on the swelling of fibrin in HC1 in which he showed
that the effect of citrates, acetates, and phosphates on swelling
was the same as that of chlorides, bromides, and nitrates if the
hydrogen ion concentration was kept constant; only the sulphates
had a greater depressing effect. The influence of salts on the

1 Hirschfelder, A. D., J. Am. Med. Ass., vol. 67, p. 1891, 1916.

THE ACTION OF NEUTRAL SALTS

107

swelling of fibrin is, therefore, identical with the influence of
salts on the swelling of gelatin.

The osmotic pressure, viscosity, and swelling of Na gelatinate
should be depressed by the cation of a salt and the more so the
higher the valency of the cation. Figure 37 shows that this is
true for the swelling of Na gelatinate of pH about 9.3. The
molecular concentration in which the swelling is depressed by the

'2048 1C

Concentration

FIG. 37. — The depressing effect of neutral salts on the swelling of Na gelatinate
of pH about 9.3 is due to the cation of the salt, the depressing effect of NaCl being
half as great as that of NasSC^ of equal molecular concentration of Na2SO4 while
that of CaCh is considerably greater owing to the fact that Ca is bivalent.

same amount is about half as great for Na2S04 as for NaCl
(for molecular concentrations from M/256 to M/32), while it is
about eight times as high for NaCl as for CaCl2, roughly proving
that the cation is responsible for the depression. The pH of
the gelatin was practically the same in all solutions.

All these data confirm our valency rule, whereby ions of the
same valency and the same sign of charge have, in the same
concentration, nearly the same depressing effect on osmotic
pressure, swelling, and viscosity of proteins; while the depressing
effect increases rapidly with the valency. The Hofmeister ion

108 THEORY OF COLLOIDAL BEHAVIOR

series are chiefly due to the failure to measure the influence
of the salts on the hydrogen ion concentration of the gelatin
solutions. This neglect has given rise to the statement that
salts like sodium acetate have the same depressing effect on
the physical properties of proteins as the sulphates.

Neutral salts, when added in low concentrations — i.e., below
M/16 — affect the physical properties of proteins in two different
ways: first, by an exchange of one of the ions of the salt for the
ion with which the protein is in combination. Thus by adding
K2SC>4 to a solution of gelatin chloride, gelatin sulphate is formed
resulting in a diminution of osmotic pressure, viscosity, etc., of the
protein solution; or if KC1 is added to gelatin sulphate the reverse
chemical and physical changes take place. If the protein is on
the alkaline side of its isoelectric point, e.g., in the case of Na
gelatinate, the addition of a salt with bivalent cation, e.g.,
MgCl2 or CaCl2, etc., results in the formation of Mg or Ca
gelatinate with the consequence that the osmotic pressure, vis-
cosity, and swelling of the gelatin is diminished. By mixing
two different salts, e.g., NaCl and MgCh, the antagonistic effects
so well known in biology can be imitated.

The second effect of the addition of a neutral salt to a solution
of a protein is a general depressing effect on the physical proper-
ties of a solution of a protein salt and this depression is caused
by that ion of the salt which has the opposite sign of charge to
that of the protein ion. Thus all anions regardless of valency
depress the osmotic pressure, viscosity, and swelling of gelatin
chloride and the depressing effect increases with the concentra-
tion and valency of the anion of the salt added. All cations
depress the viscosity, swelling, and osmotic pressure of Na gela-
tinate and the more so the higher the concentration and valency
of the cations added.

This effect is similar to the depression of electrolytic dissocia-
tion of one electrolyte caused by the addition of a second electro-
lyte with a common ion, but, nevertheless, the salt effects just
mentioned are not (or only to a negligible degree) due to a depres-
sion of the degree of electrolytic dissociation of the protein salt,
but are due to Donnan's membrane equilibrium.

Previous authors had already observed that only electrolytes
have a depressing effect on the physical properties of protein

THE ACTION OF NEUTRAL SALTS

109

solutions, such as osmotic pressure, viscosity, etc., while non-
electrolytes, like cane sugar, have no such effect. Since in these
older experiments the pH was not considered and since this fact
is of paramount importance, it seemed desirable to repeat them.
It was found that non-electrolytes, like cane sugar, have no
depressing effect on the osmotic pressure or the viscosity of gelatin
solutions. Solutions of gelatin chloride of pH 3.4 containing 1 gm.
of originally isoelectric gelatin in 100 cc. solution were made up in
various concentrations of cane sugar, were rapidly heated to 45°
and rapidly cooled to 24°. The time of outflow of the gelatin
solutions through a viscometer was measured immediately. In
addition the time of outflow of the pure sugar solution was also
determined at 24°C. The ratio of the time of outflow of the
gelatin-cane sugar solution divided by the time of outflow of the
pure cane sugar solution was thus determined. The results given
in Table IX show that the ratio of viscosity of gelatin solution to
viscosity of cane sugar solution is not diminished by the addition
of cane sugar; in fact it seems, if anything, slightly increased if
the cane sugar concentration is above M/8.

TABLE IX. — INFLUENCE OF THE ADDITION OF CANE SUGAR ON THE VISCOSITY

AND OSMOTIC PRESSURE OF 1 PER CENT SOLUTIONS OF GELATIN

CHLORIDE OF pH 3.4

Concentration of cane sugar

N

<N

CO

GO

r-T

iO

3

eo

co

oo

TH

<N

0

s

s

%

s

s

S

s

s

s

s

Viscosity ratio

2.33

2.31

2.33

2.35

2.30

2.31

2.31

2.30

2.39

2.44

2.57

Osmotic pressure

after 21 hours at

24°C. in milli-

meters H«O ....

434

390

380

405

408

400

407

432

397

401

395

Similar results were obtained in regard to osmotic pressure as
Table IX shows.

This fact is one of the prerequisites for the validity of the
theory of membrane equilibrium, since only ions contribute to
the equilibrium conditions on opposite sides of the membrane.

A second prerequisite is, that the addition of salts should have

110 THEORY OF COLLOIDAL BEHAVIOR

no influence on the viscosity, osmotic pressure, or P.D. of protein
solutions at the isoelectric point. This prerequisite of the
Donnan theory was also fulfilled.

In his book on "Applied Colloid Chemistry" Bancroft makes
the following comment on the writer's experiments on the Hof-
meister series.

"Under the conditions of the experiments Loeb found that on the acid
side of the isoelectric point only anions of neutral salts are taken up and on
the alkaline side of the isoelectric point only cations. Since the Hofmeister
series calls for an effect due to both ions of a neutral salt on the swelling of
gelatine, Loeb concludes that the Hofmeister series is a delusion and a snare.
This does not follow at all. Loeb is working at such extreme dilutions that
the specific effects of all ions but hydrogen and hydroxyl ions are practically
negligible. In acid solutions only anions are taken up and in alkaline
solutions only cations. Loeb recognizes the specific effect of iodine ions over
chlorine ions in causing the liquefaction of gelatine; but he considers that
liquefaction stands in no necessary relation to swelling, an assumption which
will be shared by few. With higher salt concentrations Loeb will undoubt-
edly get entirely different results."1

The answer to this comment is that when Bancroft wrote it he
had not read the writer's later papers dealing with the Hof-
meister series. A glance at Figs. 27, 29, 30, 31, 33, 35, 46, and 60
will show that salt solutions up to grammolecular concentration
were used without any indication of the validity of the Hof-
meister series being found. Bancroft will surely not maintain
that solutions of neutral salts up to molecular concentration are
so dilute that the effects of all ions except the hydrogen and
hydroxyl ions are practically negligible.

The writer's statement that the liquefaction of solid gelatin
stands in no necessary relation to swelling is correct, since higher
concentrations of acids or of salts like CaCl2 diminish the swelling
of gelatin while they increase its solubility (see Chap. XIV).
This is due to the fact that swelling and solution of solid gelatin
in the presence of acid are functions of different variables, swell-
ing in acid depending on the Donnan equilibrium, while the solu-
tion of gelatin depends on the same forces which are responsible
for the solution of ordinary crystalloids in water (probably
secondary valency forces).

The belief in the validity of the Hofmeister series has given rise

1 BANCROFT, W. D., "Applied Colloid Chemistry," New York and London,
1921, pp. 255-256.

THE ACTION OF NEUTRAL SALTS 111

to a flood of speculations concerning the nature of physiological
and pathological processes. These speculations were, unfortu-
nately, rarely supported by adequate experimntes and when experi-
ments • were made the hydrogen ion concentrations were ignored,
so that the basis of these speculations is always uncertain if not
positively wrong. Thus it has been suggested that muscular
contraction is due to swelling caused by acid formation. This
may or may not turn out to be correct, but the production of
acid in the muscle can only lead to increased swelling if the pH
inside the muscle is lower (but not much lower) than that of the
isoelectric point of the proteins responsible for the alleged swell-
ing; since otherwise the acid formation could only diminish the
swelling already existing in the resting muscle. It is obvious
that we must know the isoelectric points of the proteins in the
muscle, as well as the pH in the resting and the active muscle,
before a discussion of the hypothesis becomes profitable.

It has been stated that edema is due to the swelling of proteins
inside the cells caused by acid formation. Not only have none
of the measurements of the hydrogen ion concentrations required
for such a hypothesis been made but all critical experiments and
clinical observations indicate that edema is a phenomenon
dependent on increased filtration of liquid from the capillaries
into the spaces between tissues or cells; while there is no indica-
tion that edema is connected with colloidal swelling.1

It has been suggested that the absorption of water by the
striped muscle (and by other cells) in hypotonic solutions is due
to a colloidal swelling caused by acid formation inside the cells,
but it can be shown that if the solution is rendered isotonic by
the addition of a sugar, the living muscle no longer absorbs
water.2 This proves that the absorption of water by living
muscles (and other living cells) in hypotonic solution is due to
the fact that these tissues or cells are surrounded by semiper-
meable membranes and that the absorption of water by living
striped muscles or cells in hypotonic solutions has no connection
with colloidal swelling.

1 See HIRSCHFELDER, A. D., Trans. Section Pharmacol. and Therapeutics,
Am. Med. Assoc., p. 182, 1917; and MOORE, A. R., Am. J. Physiol, vol. 37,
p. 220, 1915.

2 HOBER, R., " Physikalische Chemie der Zelle und der Gewebe," p. 386,
Leipsic and Berlin, 1914. LOEB, J., Science, vol. 37, p. 427, 1913.

CHAPTER VII

THE INADEQUACY OF THE PRESENT THEORIES OF
COLLOIDAL BEHAVIOR

We have given a survey of the influence of electrolytes on the
behavior of proteins and we may now single out those character-
istics which are specifically colloidal, i.e., which do not seem to
occur in crystalloids. These characteristics are:

1. The addition of little acid (or alkali) to an isoelectric protein
(crystalline egg albumin, gelatin, and casein) increases, and the
addition of more acid (or alkali) diminishes the osmotic pressure,
the viscosity (and also, as will be seen, the potential differences) of
solutions of these proteins; and the same is true for the swelling
of gelatin.

2. This effect of acids and alkalies depends only on the sign
and the valency of the ions in combination with the proteins;
ions of the same sign and valency, e.g., Cl, NO3, CH3COO,
H2PO4 HC2O4 etc., influence the properties in the same way,
provided that th,e properties of the protein solutions are com-
pared for the same pH and the same concentration of originally
isoelectric protein, and provided that no constitutional changes
occur in the protein molecule or ion.

3. When the ion in combination with a protein is bivalent
(e.g., 864, Ca, Ba) the osmotic pressure, viscosity, and swelling
of the protein are considerably less than when the ion is monova-
lent (e.g., Cl, Br, NO3, H2PO4, HC2O4, Na, K, etc.).

4. The addition of a neutral salt to a protein solution (which is
not at the isoelectric point) depresses the osmotic pressure,
viscosity (and P.D.) of the solutions and the degree of swelling
of gels, and this effect increases with the valency of that ion of
the salt which has the opposite sign of charge to that of the
protein ion.

Any theory which claims to be able to explain colloidal behavior
must account quantitatively for these four results. As a matter

112

THEORIES OF COLLOIDAL BEHAVIOR 113

of fact the explanations offered in the colloidal literature do not
even suffice as qualitative explanations since they are in contra-
diction with the facts.

We have seen in the introduction how the original definition
of colloids by Graham, based on the non-diffusion of colloids
(through membranes), has of late been abandoned by colloid
chemists in favor of the micella or aggregation theory of colloids,
according to which the ultimate unit of colloidal matter in
solution or suspension is not the isolated molecule or ion, but
an aggregate of the latter — the micella of Naegeli. Such aggre-
gations occur and they play a role in gel formation, precipitation,
and to some extent in the viscosity of protein solutions, but they
cannot explain the influence of electrolytes on the properties of
proteins mentioned, since they have only an indirect connection
with colloidal behavior. It will be shown that the aggregates
act like membranes blocking the diffusion of the ions constituting
the aggregate and this prevention of diffusion is a source of
colloidal behavior.

The depressing effect of the addition of salts to protein solu-
tions cannot be harmonized with the aggregation theory. Zsig-
mondy suggests that the depressing effect of a neutral salt on the
osmotic pressure of a solution of a gelatin salt might find its
explanation in the assumption that the addition of salt increases
the degree of aggregation and hence diminishes the number
of the particles in solution, the diminution in the number of
particles leading to the lowering of osmotic pressure.1 It is
undoubtedly true that salts precipitate proteins and that pre-
cipitation is due to an increase in aggregation, but the salting
out of gelatin from its watery solution is not determined by the
ion with the opposite sign of charge to that of the protein ion,
while we have seen that the depressing effect of a salt on the
osmotic pressure of gelatin solutions is determined by the ion
with the opposite sign of charge to that of the protein ion. In
other words, the salting out of gelatin from its watery solution
is a process of an entirely different character from the lowering
of the osmotic pressure of a protein solution by a neutral salt.
It is, therefore, impossible to explain the latter process by the
former.

1 ZSIQMONDY, R., "Kolloidchemie," 2nd ed,, p. 342, Leipsic, 1918,
8

114 THEORY OF COLLOIDAL BEHAVIOR

Moreover, the attempt to explain the depressing effect of the
addition of salts on the basis of the micella theory fails com-
pletely in the case of the other properties of protein solutions
which are equally depressed by them as the osmotic pressure,
namely, the viscosity and the P.D.

We shall see in Chap. XIII that if the state of aggregation
increases in a gelatin solution — i.e., if isolated protein molecules
or ions unite to form a larger aggregate — the viscosity of the
solution is thereby increased, for the reason that these aggregates
occlude comparatively large quantities of water whereby the
relative volume occupied by the gelatin in the solution is increased.
This increase in the volume of the micellae at the expense of
water leads, as will be seen, to an increase in viscosity. Hence,
if we assume that the addition of a salt increases the degree of
aggregation in protein solution, it would follow that this should
result in an increase of viscosity; while the addition of salt
depresses the viscosity. The attempt to explain the depressing
influence of salts on the osmotic pressure and viscosity of protein
solutions on the basis of the aggregation theory leads therefore
to conclusions which are in contradiction with the actual facts.

An attempt to account for the colloidal behavior of protein
solutions was made by Pauli in his theory of hydration of protein
ions.

Kohlrausch had tried to account for the differences in the
mobility of different ions by the assumption that each ion is
surrounded by a shell of water and that the velocity of migration
of ions is greatest where this shell of water is a minimum. Pauli
assumes that the protein ion is surrounded by an enormous
shell of water while no such jacket of water surrounds the
non-ionized protein.1 The shell of water might prevent the coa-
lescence of the protein ions and, hence, might cause a higher
degree of dispersion. On the basis of the hydration theory we
can find a qualitative explanation of the peculiar pH curves in the
following way : At the isoelectric point protein is in a non-ionized
condition and no hydration occurs. Hence, the degree of disper-
sion of particles and the osmotic pressure are a minimum at this
point and the viscosity and swelling should also be a minimum,

1 PAULI, W., Fortschr. naturwiss. Forschung, vol. 4, p. 223, 1912, "Kol-
loidchemie der Eiweisskorper," Dresden and Leipsic, 1920,

THEORIES OF COLLOIDAL BEHAVIOR

115

since swelling might be directly due to the existence of this water
jacket, and viscosity should also increase with the mass of water
surrounding each particle. If an acid, e.g., HC1, is added to
isoelectric gelatin, the latter will be transformed into gelatin
chloride which, being a salt, is strongly dissociated. The more
acid is added the more gelatin is transformed into gelatin chloride.
We have shown in Chap. V that the curves for osmotic pres-
sure, swelling, and viscosity reach a maximum at a pH varying
between 3.5 and 2.8, and that they then drop. Pauli assumes
that the drop is due to a repression of the degree of electrolytic
dissociation of the gelatin chloride (or any protein-acid salt)
through the addition of more acid on account of the common
anion. It should, however, be mentioned that Pauli1 and
Manabe and Matula2 state that the maximum of the curves
occurs not at pH between 3.5 or pH 2.8, but at pH 2.1 or 2.0.
Table X shows that the pH for the maximal values of the
physical properties of gelatin, crystalline egg albumin, and
casein solutions is considerably higher than 2.1. In fact at a
pH of 2.1 the osmotic pressure of gelatin chloride and albumin
chloride solutions is half way down between that at the maxi-
mum (pH 3.4) and at the minimum (the isoelectric point,
pH 4.7).

TABLE X

1 per cent protein chloride
solution

pH where the maximal values are
observed for

Osmotic pressure

Swelling

Viscosity

Gelatin

3.4
3.4
3.0

3.2

2.9
3.0

Crystalline egg albumin

Casein

The assumption that the maximum lies at pH 2.1, therefore,
does not agree with the observations made on the physical
behavior of the three proteins mentioned in Table X. It might
be true for the viscosity of solutions of blood albumin, on which

1 PAULI, W., " Kolloidchemie der Eiweisskorper," Dresden and Leipsic,
1920.

2 MANABE, K. and MATULA, J., Biochem. Z., vol. 53, p. 369, 1913.

116 THEORY OF COLLOIDAL BEHAVIOR

Pauli has done most of his work, but Michaelis and Mostynski1
have pointed out that there is no maximum of viscosity in the case
of serum albumin. There is also no maximum in viscosity
followed by a drop in the case of egg albumin when the pH varies.

The hydration hypothesis can be put to a direct test by deter-
mining the specific conductivity of solutions of protein salts, e.g.,
gelatin chloride, albumin chloride, etc. Since according to the
hydration hypothesis only the protein ion undergoes hydration,
the variation in the osmotic pressure, swelling, and viscosity
should be accompanied by a corresponding variation in the
concentration of protein ions in solution. If, therefore, the
specific conductivity of gelatin chloride is measured at varying
pH but equal concentrations of originally isoelectric gelatin, the
curves representing the values found for conductivity of the
protein should run parallel with the curves for the osmotic
pressure, swelling, and viscosity; moreover, the curve for the
conductivity of gelatin sulphate should be only about half as high
as the curve for the specific conductivity of gelatin chloride;
while the curve for the specific conductivity of gelatin oxalate
should be almost but not quite as high as that for gelatin chloride.
The experiments show that this is not the case.

The concentration of ionized gelatin in solution can be deter-
mined with the aid of conductivity measurements of the solution
of a gelatin salt, e.g., gelatin chloride, by deducting the conduc-
tivity of the free HC1 in the solution from the total conductivity
of the gelatin solution, since the gelatin chloride solution prepared
by the writer's method from washed powdered isoelectric gelatin
contains practically no other electrolyte except the free HC1 and
the gelatin chloride. This was proved by ash determinations
and by the fact that a solution of isoelectric gelatin prepared
according to our method of washing has practically a con-
ductivity of zero. The method of procedure was as follows:

Solutions of different gelatin-acid salts were prepared in two
different concentrations of originally isoelectric gelatin, 0.8 per
cent and 2.4 per cent. The specific conductivities of these gelatin-
acid salts were determined at different pH. The conductivities
of pure aqueous solutions of the same acids at different pH were
also measured. In both cases the conductivities were plotted

1 MICHAELIS, L. and MOSTYNSKI, B., Biochem. Z., vol. 25, p. 401, 1910.

THEORIES OF COLLOIDAL BEHAVIOR

117

as ordinates over the pH as abscissae. By deducting the values for
the specific conductivity of the pure aqueous solution of an acid
from the values for the total specific conductivity of the gelatin-
acid solution of the same pH the curve for the specific conduc-
tivity of the gelatin-acid salt for that pH is obtained.1

Figure 38 shows that the curves representing the percentage
of ionized gelatin in gelatin chloride resemble the combination

2.0 22 2A 26 2£> 3.0 32 3.4 3.6 3.8 4.0 42 4.4 4.6

FIG. 38. — Curves for the specific conductivity of 2A per cent solutions of
gelatin chloride, sulphate, and oxalate, showing the entirely different character of
these curves from that of the osmotic pressure curves in Figs. 14 and 15.

curves in Fig. 8, since in both cases there is a gradual rise in the
concentration of ionizable protein at a pH below that of the
isoelectric point, but no maximum followed by a drop at pH 3.4 or
3.0. But otherwise the curves for combination and for con-
ductivity differ; the curve representing the percentage of ionized
gelatin is almost the same for gelatin chloride and gelatin sulphate,
while for gelatin oxalate the curve is a little lower. If we attempt
1 LOEB, J., J. Gen. Physiol, vol. 3, p. 247, 1920-21.

118

THEORY OF COLLOIDAL BEHAVIOR

to account for the low osmotic pressure of gelatin sulphate solutions
by the hydration hypothesis, the specific conductivity of gelatin
sulphate should be half or less than half of that of gelatin chloride,
while the curve for gelatin oxalate should be almost as high as
that for gelatin chloride. Figure 38 shows that neither expec-
tation is fulfilled.

\

50

PH 20 22 Z4 26 2.6 3.0 3.2 3.4 3.6 3.8 4.0 42 4.4 4.6 46 5.Q
FIG. 39. — Comparison of conductivity curve and osmotic, pressure curve for
albumin chloride, showing the entirely different character of the two curves.

Figure 39 shows that the same disagreement exists between the
conductivity curve and the osmotic pressure curve for solutions
of the chloride of crystalline egg albumin. These curves, then,
do not support the hydration hypothesis.

Pauli's hydration theory rests, as stated above, on an assump-
tion made by Kohlrausch that the difference in the mobility of ions
is due to molecules of water being dragged along with the migrat-
ing ion. Lorenz,1 Born,2 and others have come to the conclusion
that while Kohlrausch's idea is probably correct for monatomic
ions it cannot be correct for large polyatomic ions. This would

1 LORENZ, R., Z. Elektrochem., vol. 26, p. 424, 1920.

2 BORN, M., Z. Elektrochem., vol. 26, p. 401, 1920.

THEORIES OF COLLOIDAL BEHAVIOR 119

exclude the assumption of a high degree of hydration of protein
ions.

The theory of adsorption is used to explain the precipitation of
colloids by low concentrations of salts. The experiments de-
scribed in the second, third, and fourth chapters of this book flatly
contradict the assumption of such an adsorption when the con-
centration of salts is low.

The adsorption theory, the aggregate theory, and the hydration
theory cannot explain the features of colloidal behavior enu-
merated at the beginning of this chapter.

As long as chemists continue to believe in the applicability
of the adsorption formula to the behavior of proteins, no scientific
theory of colloidal behavior will be possible. We intend to show
in the second part of the book that such a theory can be given on
the basis of the stoichiometrical proof that proteins form true
salts with acids and alkalies, and that these salts lead to the
formation of protein ions. Colloidal behavior is due to the fact
that these protein ions cannot diffuse through many membranes
which are permeable to the majority of crystalloidal ions, or that
protein ions form solid gels in which cohesive forces prevent their
diffusion, while such gels are permeable to crystalloidal ions. The
theory of the equilibrium conditions resulting from this difference
in the diffusibility of the two opposite ions of an electrolyte was
developed by Donnan. These equilibrium conditions give rise
to forces, such as P.D., osmotic pressure, etc., which are the only
cause of colloidal behavior. It will be shown that Donnan's
theory gives not only a qualitative but a quantitative and
mathematical explanation of colloidal behavior.

CHAPTER VIII
MEMBRANE POTENTIALS1

We have seen that electrolytes influence the osmotic pressure,
swelling, and viscosity of protein solutions in a similar way, so
that we must think of the possibility that the cause of this influ-
ence is the same for all these properties.

When a solution of a protein salt, e.g., I per cent gelatin
chloride, is separated from distilled water by a collodion mem-
brane, a potential difference exists across the membrane between
the gelatin chloride solution and the outside solution with which
it is in equilibrium. If this P.D. is measured with the aid of a
Compton electrometer with saturated KC1 calomel electrodes,
it is found that the P.D. is influenced in the same way by
electrolytes as the osmotic pressure, swelling, and viscosity (see
Fig. 41 in this chapter). This in itself would only mean the
addition of another property varying in the same characteristic
way as osmotic pressure, or swelling, or viscosity of proteins
under the influence of electrolytes, if it were not for the fact that
we can correlate the variations of the new property with the
Donnan equilibrium, and that we can calculate the P.D. with a
fair degree of accuracy on the basis of this equilibrium. This
then gives us a rational, quantitative theory of the influence of
the pH, the valency of ions, and of the concentration of neutral
salts on a colloidal property of proteins.

It is necessary to. give a brief description of the method of
measuring the P.D. Suppose that the protein in solution is
gelatin chloride containing 1 gm. of originally isoelectric gelatin
in 100 c.c. solution. Such solutions of gelatin chloride are put
into collodion bags closed with rubber stoppers which are per-
forated with glass tubes serving as manometers, as described in
the osmotic pressure experiments. These collodion bags filled

1 This chapter is based on LOEB, J., J. Gen. Physiol, vol. 3, pp. 557, 667,
1920-21; vol. 4, pp, 351, 463, 1921-22.

120

MEMBRANE POTENTIALS

121

with the gelatin chloride solution are dipped into beakers con-
taining 350 c.c. of aqueous HC1 solution of originally the same
pH as that of the gelatin chloride solution, but free from gelatin.
The experiments last 20 hours or more at 24°C. to allow the
establishment of osmotic equilibrium between the two solutions
(which requires only about 6 hours under the conditions of the
experiments). After 20 hours or more the P.D. between the
gelatin solution (which we call the inside solution) and the aqueous

FIG. 40. — Method of measuring the P.D. between gelatin chloride solution in a
collodion bag and the outside HC1 solution in beaker.

solution (which we call the outside solution) is measured with the
aid of a Compton electrometer, giving a deviation of about 2
mm. on the scale for 1 millivolt at a distance of about 2 m. The
two electrodes leading to the electrometer are identical (Fig. 40).
They are calomel electrodes filled with saturated KC1 solution.
One electrode dips through a capillary glass tube into the gelatin
solution, the other also through a capillary glass tube into the
outside solution. In order to allow the electrode to dip into the
gelatin solution, the glass tube serving as a manometer is replaced
by a funnel, as shown in the figure. In the figure the upper level

122

THEORY OF COLLOIDAL BEHAVIOR

of the gelatin solution is in the funnel. This is not really neces-
sary but it is convenient and is accomplished by allowing the
collodion bag to press against the glass wall of the beaker con-

1.8 2.0 22 24 26 28 3.0 3.2 3.4 3.6 3.8 40 42 4.4 46 4.8

Fia. 41. — Influence of pH and valency of anion on P.D. of solutions of different
gelatin-acid salts. The curves in Fig. 41 are similar to (but not identical with)
those in Fig. 14.

taining the outside solution. As a minor but convenient acces-
sory each electrode is connected with a reservoir of saturated
KC1 solution which makes it possible to let the KC1 solution in
the capillary flow out after each measurement, so that the
electrode is always clean for each new measurement. What was

MEMBRANE POTENTIALS

123

measured in this way was, therefore, the electromotive force
of the following cell,

calomel
electrode

saturated
KC1

outside
solution
HC1

collodion
mem-
brane

inside
solution
gelatin
chloride

saturated
KC1

calomel
electrode

It is found that in this cell the gelatin solution has a positive
charge and the outside solution a negative charge and that the
P.D. varies with the pH of the gelatin chloride solution, as indi-
cated in Fig. 41. It is also found that the P.D. of gelatin phos-
phate solutions is practically identical with the P.D. of gelatin
chloride solutions of the same pH and that both are considerably
higher (about 50 per cent higher, as we shall see) than the P.D. of
gelatin sulphate solutions. We shall also see that the addition
of a neutral salt to the gelatin chloride solution depresses the
P.D. In other words, electrolytes influence the P.D. between
gelatin chloride solution and outside solution in a way similar
to that in which they influence the osmotic pressure and the
viscosity of the same solution. It becomes, therefore, of con-
siderable importance to find out the origin of this P.D. We
intend to show that the P.D. is due to the establishment of a
Donnan equilibrium between the gelatin chloride solution and the
outside aqueous solution (free from gelatin).

We have already given a brief outline of Donnan 's membrane
theory in the first chapter. In our experiment a collodion bag
filled with a 1 per cent solution of gelatin chloride is dipped into
a beaker containing a solution of HC1 (without gelatin) of origin-
ally the same pH as that of the gelatin solution. In this case we
have free HC1 inside as well as outside, but in addition we have
inside the collodion bag a gelatin chloride solution which ionizes
into Cl and a positive gelatin ion. The gelatin ion is unable to
diffuse through the collodion membrane but the H ions and Cl
ions can diffuse freely through the membrane. Donnan has
shown that in this case an equilibrium condition is established
in which the product of the concentrations of the H and Cl ions
in the outside solution equals the product of the concentrations
of the H and Cl ions inside. This equilibrium is expressed by

124 THEORY OF COLLOIDAL BEHAVIOR

the following equation, which was used by Procter and Wilson
for the distribution of free HC1 between a jelly of solid gelatin
chloride and surrounding water, but which holds also for the
case where the gelatin chloride is in solution and separated from
the outside solution by a collodion membrane impermeable for
gelatin ions,

x2 = y(y + z) (1)

where x is the concentration of H and Cl ions in the outside
solution, y the concentration of the H and Cl ions of the free
acid inside the gelatin solution, and .z the concentration of the
Cl ions in combination with the gelatin. (For the sake of
simplification complete electrolytic dissociation of HC1 and
gelatin chloride is assumed.) Since all the quantities in Equa-
tion (1) are positive, the concentration x of the hydrogen ions
in the outside solution must be greater than the concentration y
of the hydrogen ions in the inside solution; and the total con-
centration of the chlorine ions in the inside solution, y + z,
must be greater than the concentration of the Cl ions in the out-
side solution, x. This difference in the distribution of the
crystalloidal ions on the opposite sides of the membrane is
caused by the fact that one type of ions (the protein ions) cannot
diffuse through the membrane.

We now come to the most important point for the foundation
of the theory of colloidal behavior. If it is true that the Donnan
equilibrium is the cause of the P.D. between a gelatin chloride
solution and the outside solution, the Donnan equilibrium is
likely to be also the cause of the influence of the mysterious
influence of electrolytes on the other properties of proteins, since
the curves for P.D. are similar to the curves of osmotic pressure,
viscosity, and swelling. In order to prove that the P.D. is due
to the Donnan equilibrium, we must be able to show that the
unequal distribution of the H and Cl ions on the opposite sides
of the collodion membrane allows us to account quantitatively
for the P.D. on the basis of Nernst's well known logarithmic
formula for concentration cells.

We have seen in Chap. IV that we can determine the con-
centration of the Cl ions of the gelatin chloride solution by titra-
tion; and we can, of course, also determine the Cl of the outside
watery solution by titration. Let x be the concentration of Cl

MEMBRANE POTENTIALS 125

ions in the outside solution and y + z the concentration of Cl in
the gelatin solution (as found by titration) and let us assume that
this difference of concentration determines the P.D. observed
between the gelatin chloride solution and the outside solution,
then we should expect that at 24°C. the observed P.D. = .059

loS ly~+~z volts-

We shall see later in this chapter that the observed P.D. in
millivolts is actually equal to 59 log — ^— millivolts, and this

makes it very probable that the P.D. between a gelatin chloride
solution and the outside watery solution across a collodion
membrane is caused exclusively by the Donnan equilibrium.

We have a second check since it follows also that we must be
able to calculate our observed P.D. on the basis of the difference
in the concentration of hydrogen ions on the opposite sides of the.
membrane with the aid of Nernst's formula. Donnan's equilib-
rium equation

z2 = y(y + z)
can be written in the form

y = x

x y + z

where y is the concentration of the hydrogen ions inside the
gelatin solution and x the concentration of the hydrogen ions
in the outside solution. Hence, if the Donnan equilibrium is
responsible for the observed P.D. between the gelatin chloride
solution and the watery solution, it must also be possible to
show that

Observed P.D. = 59 log | millivolts

We intend to show that this is actually the case. Instead of
measuring the concentration of the hydrogen ions inside (i.e.,
in the gelatin solution) and outside (i.e., in the aqueous solution)
by titration, we measure these concentrations with the hydrogen
electrode. Since log y is the value pH inside and log x the value
pH outside, the value 59 (pH inside minus pH outside) millivolts
must (within the limits of accuracy of measurement) be equal to

126 THEORY OF COLLOIDAL BEHAVIOR

the observed P.D. if the Donnan equilibrium is the exclusive
cause for the P.D. between a gelatin chloride solution and the
outside watery solution; neglecting the sign.1

Although the value pH inside minus pH outside is an observed
value, e.g., observed with the hydrogen electrode, we will call the
value 59 (pH inside minus pH outside) the calculated P.D. to
distinguish it from the P.D. observed with the indifferent
electrodes.

THE INFLUENCE OF THE HYDROGEN ION CONCENTRATION OF GELATIN
SOLUTIONS ON THE P.D.

Collodion bags of a volume of about 50 c.c. were filled with 1 per
cent solutions of gelatin chloride of different pH. The bags were
put into beakers containing each 350 c.c. of distilled water. To
hasten the establishment of equilibrium between gelatin chloride
solution and outside water some HC1 was added to the latter
—in fact the pH of the gelatin and the outside solutions was
generally made equal at the beginning of the experiment. The
collodion flasks containing the gelatin solution were closed with
rubber stoppers which were perforated by glass tubes serving as
manometers to allow the measurement of the osmotic pressure of
the solution. After about 6 hours osmotic equilibrium was com-
plete but we waited, as a rule, about 18 hours before measuring
the P.D. across the membrane. Figure 41 shows that the pH
influences the P.D. in a similar way as it influences the osmotic
pressure, swelling, etc. Similar experiments were made with 1
per cent solutions of gelatin phosphate, -gelatin oxalate, and
gelatin sulphate, and the curves are also given in Fig. 41. To
demonstrate the similarity between the curves for osmotic

1 The sign of the observed P.D. was apparently, but not in reality, the
reverse of the sign of the calculated P.D. In the "observed" P.D. the
membrane (acting as a hydrogen electrode) was between the concentrated
and dilute HC1, while in the "calculated" values the P.D. was obtained,
from the potentiometric determinations of the pH. In this latter case two
hydrogen electrodes were separated by a concentrated and a dilute solu-
tion. The "observed" P.D. was hence between two solutions of different
concentrations while in the "calculated" values we measured the P.D.
between two electrodes. In our tables the apparent (but not real) reversal
of sign is corrected.

MEMBRANE POTENTIALS 127

pressure and P.D., the osmotic pressures were observed in all the
experiments used for measuring the influence of pH on the P.D.,
and Fig. 14 gives the osmotic pressures. A comparison of the two
figures for P.D. (Fig. 41) and for osmotic pressure (Fig. 14) shows
the following similarities: Both sets of curves rise from the
isoelectric point with a lowering of the pH until they reach a
maximum; this maximum is, however, not identical in the two
cases. For the P.D. it varies between 3.6 and 4.0, while for os-
motic pressure it lies near 3.5. With a further fall in pH both
sets of curves show approximately the same steep drop.

The second point of similarity is the influence of valency. The
curves for the P.D. (Fig. 41) are practically the same for gelatin
chloride and gelatin phosphate, and are but slightly lower in the
case of gelatin oxalate, while the curve for the P.D. is considerably
lower in the case of gelatin sulphate. The same is true for the
osmotic pressure curves (Fig. 14).

If these characteristic curves are exclusively determined by
Donnan's membrane equilibrium it should be possible to show
that the variation of the observed P.D. with pH is accompanied
by a parallel variation of the value pH inside minus pH outside
and that the agreement between these two sets of values is as
perfect as the accuracy of the measurements permits. Tables
XI, XII, and XIII show that this is true. The upper two hori-
zontal rows give the pH inside and outside, the third horizontal
row gives the difference, pH inside minus pH outside, and the
fourth row gives the P.D. calculated in millivolts by multiplying
the values pH inside minus pH outside by 59. The last hori-
zontal row gives the observed P.D. in millivolts. The agree-
ment between observed and calculated P.D. is sufficiently close
to permit us to say that the characteristic curves representing the
influence of the pH on the P.D. are a consequence of the Donnan
equilibrium.

THE EXPLANATION OF THE P.D. CURVE

Figure 41 shows that the P.D. of gelatin-acid salts is a minimum
at the isoelectric point, that it rises rapidly with the increase in
the hydrogen ion concentration until reaching a maximum at pH
about 4.0 to 3.8, and then drops again with a further increase of

128

THEORY OF COLLOIDAL BEHAVIOR

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130 THEORY OF COLLOIDAL BEHAVIOR

the hydrogen ion concentration. This is the characteristic pH
effect already discussed in connection with viscosity, osmotic
pressure, etc. Pauli explained this behavior of the viscosity
curves on the basis of ionization and hy drat ion. The hydration
can have no connection with the P.D., but the ionization un-
questionably has. Pauli assumes that the viscosity rises with
increasing ionization of a protein salt and explains the maximum
and drop by the repression of ionization of the protein salt by the
anion of the acid added. This latter explanation is plainly
inadequate in our case, since it would mean that the electrolytic
dissociation of gelatin chloride is markedly diminished by a
N/10,000 HC1 solution. We can show that the Donnan theory
accounts mathematically for the influence of pH on the P.D. of
gelatin chloride solutions as expressed in Fig. 41.

Donnan had arrived at his equilibrium equation on the basis
of thermodynamical considerations, but Proctor and Wilson
have pointed out1 that it can be derived more simply from the
ordinary laws of ionization,

"since the nonionized portion of hydrochloric acid which, although small,
must exist takes no direct part in the equilibrium and must be equal in
both places. "

Hence when a solution of gelatin chloride is separated by a
collodion membrane from a solution of HC1 (without gelatin),
if x is the concentration of H and Cl ions in the outside solu-
tion and [HC1] the concentration of non-ionized HC1,

x2 = K [HC1]

If y is the concentration of hydrogen ions inside the solution,
y is the corresponding concentration of Cl ions; and if z is the
concentration of Cl ions in combination with gelatin

y(y + z) = K [HC1]
hence

z2 = y(y + z) (1)

x = V y(y + z)

PROCTER, H. R., and WILSON, J. A., J. Chem. Soc., vol. 109, p. 309, 1916.

MEMBRANE POTENTIALS

131

Substituting \/y(y + z) for x in the term - we get

Vy(y

%••&!

Hence at 18°C. the P.D. should be = y log (l + -) millivolts.

We will now show that from the term \n + - the influence of

y

pH on the P.D. as expressed in the curves of Fig. 41 can be derived.

When we add little HC1 to isoelectric gelatin, we increase the

amount of gelatin chloride formed and hence the value of z.

Hence, the P.D. should increase since it depends on log (l + -j.
We also increase the value of y, but z and y will not increase at

the same rate, z can be calculated from the equation - = - —

y x

z = x2 - y2 = (x + y)(x - y)

y y

When little acid is added to isoelectric gelatin the value of z
rises more rapidly than the value of y, while when more acid is
added the reverse happens. This is obvious from Table XIV
comparing the variations of z and y upon the addition of increas-
ing quantities of HC1 to isoelectric gelatin.

TABLE XIV

Cubic

centimeters

pHof

0.1 N acid
in 100 c.c. 1
per cent

gelatin
solution
at

Cone, y
X105 N

Cone, z

X10« N

z
V

*"<'+;)

P.D. cal-
culated from

29 log (l+^-)

P.D.
observed,
milli-

originally

equi-

\ y /

millivolts

volts

isoelectric

librium

gelatin

1.0

4.56

2.7

16.5

6.1

0.8513

24.7

24.0

2.0

4.31

4.9

51.4

10.5

1.0607

30.7

32.0

4.0

4.03

9.3

132.5

14.3

1. 1847

34.4

33.0

6.0

3.85

14.1

200.0

14.2

1. 1818

34.3

32.5

8.0

3.33

46.8

343.0

7.3

0.9191

26.1

26.0

10.0

3.25

56.2

372.0

6.6

0.8808

25.5

24.5

12.5

2.85

141.0

477.0

3.4

0. 6435

18.7

16.5

15.0

2.52

302.0

608.0

2.0

0.4771

13.8

11.2

20.0

2.13

741.0

609.0

0.82

0.2601

7.5

6.4

132 THEORY OF COLLOIDAL BEHAVIOR

The fifth vertical column of the table shows that at first the
value - increases with increasing addition of acid until pH = 4.03,

\j

and that with the addition of more acid the value - diminishes

again. A comparison of the last and second last vertical columns
shows that the observed and calculated P.D. agree.

The Donnan equilibrium thus explains mathematically why
the P.D. rises at first when HC1 is added to isoelectric gelatin
until the pH is 4.03, and why the P.D. drops when the pH falls
below 3.8. No other colloidal theory is able to explain the
curves in Fig. 41.

THE VALENCY EFFECT

Figure 41 shows that the P.D. curves for gelatin chloride and
phosphate are considerably higher than the curve for gelatin
sulphate. The same valency effect was observed for the osmotic
pressure curves, the viscosity curves, and the curves for swelling.
It can be shown that the Donnan theory demands that for the
same pH and the same concentration of originally isoelectric
gelatin the P.D. of gelatin chloride and gelatin sulphate should
stand in the exact ratio of 3 : 2, and it is one of the most convincing
proofs of the correctness of the theory that the calculated values
for the P.D. of these two gelatin salts agree with this postulate.
By calculated values we mean the value 59 (pH inside minus
pH outside).

The proof that the values for pH inside minus pH outside and,
hence, the P.D. of the solutions of the two gelatin salts must
show the ratio of 3 : 2 is as follows :

The equilibrium equation for gelatin chloride is of the second
degree, namely,

x _ y + z
y~ x
and we have just seen that by proper substitution the

P. D. =^ log ( 1-f -) millivolts.
z \ y/

The equilibrium equation which is of the second degree when the
anion is monovalent becomes of the third degree when the anion

MEMBRANE POTENTIALS 133

is bivalent, e.g., S04, in the case of gelatin sulphate. Let x be the
concentration of hydrogen ions in the outside solution, y

the hydrogen ion concentration in the inside solution; then |

is the concentration of the SO4 ions in the outside, and | the

concentration of the SO4 ions of the free H2SO4 in the inside
(gelatin) solution. The concentration of SO4 ions in combination

with gelatin becomes ~- Then the following two dissociation
equations must hold :

x2^ = K I H2SO4J undissociated (outside)

y2 (! + !)= K[H2SO4] undissociated (inside)

Since the undissociated H2SO4 must be distributed equally on
both sides of the membrane, x3 = y2(y + 2); x = [y2(y -f 2)]*.

x
The value which interests us is -, i.e., the ratio of the hydrogen ion

concentrations.

Substituting \yz(y + 2)]* for x in - we get

The P.D. is, therefore, in the case of gelatin sulphate,
P.D. = y log (l + p millr

millivolts

while in the case of gelatin chloride it was

CO f -V

P.D. = 7f loglH--J millivolts
z \ y/

Hence, the P.D. of gelatin sulphate solutions should be only
two-thirds of the value of a gelatin chloride solution of the
same pH and the same concentration of originally isoelectric
gelatin.

This theoretical deduction is actually fulfilled, as the Tables
XI, XII, and XIII show. Thus in Table XII we find that for

134

THEORY OF COLLOIDAL BEHAVIOR

°§

Tf CO — 1

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IN ...

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CO (N CO

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gelatin phosphate of pH 3.98 the
calculated P.D. was 34.0 and from
Table XIII we notice that for gela-
tin sulphate of pH 3.98 the calcu-
lated P.D. was 22.2 millivolts. This
is (within the limits of accuracy
of the observations) the ratio 3:2,
which the theory demands. For
pH 4.31 the P.D. is 31 in the case
of gelatin chloride and phosphate
and for pH 4.34 it was 20.5 for
gelatin sulphate, again the ratio of
3:2. The strict confirmation of
the valency ratio came out clearly
in the following experiment which
was undertaken for another pur-
pose— on account of • its analogy
with antagonistic salt action — but
which shows that for the same pH
the values of the calculated P.D.
for gelatin chloride and sulphate
are in the ratio of 3:2.

Solutions of 1 gm. of isoelectric
gelatin were prepared in 100 c.c. of
water containing 5 c.c. of a mixture
of 0.1 N HC1 and 0.1 N H2SO4 in
various proportions. The solu-
tions were put into collodion bags
of about 50 c.c. volume and the lat-
ter were put into 350 c.c. of H2O
containing mixtures of N/1,000 HC1
and N/1,000 H2SO4 in the same
proportions as inside. The arrange-
ment was that described for os-
motic pressure measurements, and
the osmotic pressure, P.D., and pH
inside minus pH outside, were
measured after 24 hours at 24°C.
The upper rows of Table XV give

MEMBRANE POTENTIALS 135

the ratio of cubic centimeters of 0.1 N HC1 and 0.1 N H2SO4
in 100 c.c. of liquid. The rest of the table requires no further
explanation. As in all gelatin-acid salt experiments, the agree-
ment between observed and calculated P.D. is good.

Both P.D. and osmotic pressure are depressed the more the
more HC1 is replaced by H2S04, but the depressing effect is
greater in the case of osmotic pressure than in the case of P.D.
The result of interest to us is the following: The value of pH inside
minus pH outside was, for gelatin chloride of pH 3.64, = 0.49, and
for gelatin sulphate of pH 3.64, = 0.31. The ratio of the two
values is as nearly 3:2 as the accuracy of the measurements
permits us to expect. The values for the observed P.D. agree
with the values of the calculated P.D. within the limits of ac-
curacy of the measurements.

This quantitative agreement between the observed P.D. and
the P.D. calculated on the basis of the Donnan theory leaves
little doubt that the observed P.D. is exclusively determined by
the Donnan equilibrium.

HYDROGEN ION AND CHLORINE ION POTENTIALS
If we write the equation for the equilibrium condition between
gelatin chloride solution and water in the form

y _ x
x y +z

where x is the concentration of H and Cl ions in the outside
solution, y the concentration of the H and Cl ions of the free HC1
inside the gelatin chloride solution, and z the concentration of

the Cl ions in combination with the gelatin, - is the ratio of

x

hydrogen ion concentration inside to the hydrogen ion concen-

/>•

tration outside; and - - the ratio of the concentre

y -f a

chlorine ion outside to the chlorine ion inside. Since,
and

tration outside; and — ^r— the ratio of the concentration of the
>

log = pH inside minus pH outside
x

log — j— = pCl outside minus pCl inside

it follows that

pH inside minus pH outside = pCl outside minus pCl inside (2)

136

THEORY OF COLLOIDAL BEHAVIOR

If Donnan's membrane equilibrium is the cause of the influence
of pH on the P.D. (and on the other physical properties) of
protein solutions, we must be able to show that equation (2) is
actually fulfilled.

This consequence of Donnan's theory was put to a test and
some of the experiments described in the preceding part of this
chapter were selected for this purpose. Inside the collodion
bags were 1 per cent solutions of gelatin chloride of different
pH; outside, water. After 18 hours equilibrium was established
between inside and outside solutions and the pCl as well as the
pH was ascertained. The pCl was determined in two different
ways in the two experiments; in one experiment it was deter-
mined with the calomel electrode, in the other it was determined
in the gelatin chloride solution by titration with NaOH according
to the method described in the fourth chapter. Both methods of
determining the pCl led to the result that the value pCl outside
minus pCl inside was for the same solution at the point of equilib-
rium equal to the value pH inside minus pH outside (within
the limits of accuracy of the experiments) . The pCl outside was
identical with the pH outside since the outside solution contained
only free HC1. The values of pH were all determined potentio-
metrically (Table XVI).

TABLE XVI
Experiment 1. pCl determined by titration

pH of gelatin chloride

solution at equilibrium

4.13

3.69

3.30

3.10

2.92

2.78

2.46

2.26

2.01

1.76

pH inside minus pH

outside

0.56

0.58

0.50

0.49

0.44

0.44

0.33

0.23

0.15

0.10

pCl outside minus pCl

inside

0 48

0 51

0 59

0 44

0 44

0 38

0 35

0 22

0 15

0 11

Experiment 2. pCl determined electrometrically

pH of gelatin chloride

solution at equilibrium

4.04

3.92

3.78

3.61

3.46

3.16

2.73

2.36

2.04

1.73

pH inside minus pH

outside

0.60

0.62

0.66

0.55

0.50

0.43

0.300.20

0.12

0.07

pCl outside minus pCl

inside. .

0.55

0.60

0.57

0.50

0.53

0.38

0.32

0.17

0.12

0.07

MEMBRANE POTENTIALS 137

Nernst's formula leads therefore to the same theoretical P. D.
regardless of whether we calculate the P.D. on the basis of
the difference pH inside minus pH outside or on the basis of
the difference pCl outside minus pCl inside. It is also obvious
that both assumptions lead to the same sign of charge of the
gelatin chloride solution. If we assume that the P.D. is deter-
mined by differences in the hydrogen ion concentration, the
outside solution is concentrated and the inside solution dilute;
if the P.D. is determined by differences in the concentration of
the Cl ions, the inside solution is concentrated and the outside
solution dilute. Since the common ion is positive in the former
and negative in the latter case, the gelatin solution becomes
positive in both cases.

OUTSIDE SOLUTION INSIDE SOLUTION

H+ dilute +

— H+ concentrated

~, ,., , membrane

— Cl- dilute

Cl~ concentrated

The facts contained in this section of this chapter prove that
the equation x2 = y(y + z) is the correct expression for the
Donnan membrane equilibrium between acid-salts of proteins
with monovalent anion and water, and that the Donnan equilib-
rium accounts for the P.D. observed. We wish to point out
that we get the same result whether we determine pCl by titra-
tion or potentiometrically. The agreement with the theory is
the same in both cases though the accuracy of the determination
of pCl is less than that of pH.

THE P.D. OF Na GELATINATE

The Donnan theory demands that when a solution of Na
gelatinate contained in a collodion bag is in equilibrium with a
watery solution free from gelatin, free NaOH should be forced
from the inside gelatin solution through the membrane into the
outside watery solution free from gelatin. As a result the pH
inside will now be less than pH outside, and the value pH
inside minus pH outside will be negative for Na gelatinate while
it was positive for gelatin chloride. If the Donnan equilibrium
determines the P.D. (as it does) the sign of charge of Na gela-
tinate must be the reverse from what it was for gelatin chloride.

138

THEORY OF COLLOIDAL BEHAVIOR

This is indeed the case and the
turning point lies, as was ex-
pected, at the isoelectric point.

The experiments with Na
gelatinate demand more rigid
precautions than those with
gelatin chloride. It is neces-
sary to prevent the CO2 of
the air from diffusing into
the alkaline solutions and
therefore the outside solution
was put into stoppered bot-
tles connected with the outside
air by glass tubes filled with
soda lime. On account of the
CO2 error the pH measure-
ments near the isoelectric point
are unreliable and only when
the pH is above 7.0 is it pos-
sible to get reliable results.
The main facts demanded by
the theory can, however, be
demonstrated. The first fact
is the proof that the sign of
charge of the Na gelatinate
solution is the reverse of that
of a gelatin chloride solution.

Collodion bags of a vol-
ume of about 50 c.c. were
filled with solutions of Na
gelatinate containing 1 gm.
of originally isoelectric gelatin
and varying amounts of 0.1 N
NaOH in 100 c.c. solution.
The collodion bags were dip-
ped into flasks containing 500
c.c. of aqueous solutions of
NaOH of various concentra-
tions and free from gelatin.

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MEMBRANE POTENTIALS 139

The flasks were sealed, communicating with the air only through
tubes filled with soda lime, as stated. The collodion bags con-
taining the gelatin were closed by a rubber stopper perforated
by a glass tube which served as a manometer. The experiment
lasted 6 hours at a temperature of 24° C. The results of the
experiments are given in Table XVII. The upper horizontal
row gives the number of cubic centimeters of 0.1 N NaOH
originally in 100 c.c. of the gelatin solution; the second row
gives the original concentration of NaOH in the outside aqueous
solution free from gelatin ; the third row gives the osmotic pressure
in mm. H2O after 6 hours. The next row gives the pH inside
and the following row the pH outside after the experiment was
finished (i.e., after 20 hours), and the sixth row gives the differ-
ence pH inside minus pH outside. The reader will notice that
this difference is always negative with one exception, which is
obviously an error. The last two rows give the P.D. calculated
from pH inside minus pH outside, and the P.D. observed.

It is obvious that there is no quantitative agreement between
observed and calculated P.D. near the isoelectric point. As soon
as the pH is above 7.0 the agreement between observed and
calculated P.D. becomes better, so that we are entitled to say
that the difference of potential between a Na gelatinate solution
and an outside solution at or near equilibrium is due to the
Donnan equilibrium which forces the expulsion of NaOH from
the inside into the outside solution. As a consequence the pH
inside becomes lower than the pH outside.

THE INFLUENCE OF NEUTRAL SALTS ON THE P.D. OF GELATIN
CHLORIDE SOLUTIONS

It was shown in Chapter VI that the addition of neutral salts
to solutions of protein salts depresses the osmotic pressure or
viscosity of these solutions, and that the addition of neutral
salts to a gel depresses the swelling of the latter (except when the
solutions and gels are at the isoelectric point). It was of interest
to find out whether or not the addition of a salt to a protein
solution depresses also the P.D. across a collodion membrane,
and whether this is also due to a depression of the value of pH

140 THEORY OF COLLOIDAL BEHAVIOR

inside minus pH outside. It was possible to show that this is
true.

Gelatin chloride solutions containing 1 gm. of originally iso-
electric gelatin in 100 c.c. solution and having a pH of 3.5 were
made up in different concentrations of NaNO3 in water, the
concentration of NaNO3 varying from M/4?096 to M/32 NaNO3,
and all possessing a pH of 3.5. These mixtures were put into col-
lodion bags and the bags were put into HC1 solutions of pH 3.0
made up in different concentrations of NaNO3, also of pH 3.0.
These outside solutions contained no gelatin. The collodion bags
were put into these outside solutions free from gelatin in such a
way that the concentration of the NaNO3 solution inside the
collodion bag was always the same as outside.

When the P.D. across the collodion membrane was measured
after 18 hours (after equilibrium was established) it was found
that it was diminished upon the addition of neutral salt and the
more the higher the concentration of the salt. This shows that
the addition of neutral salt to a protein solution has a similar
depressing effect on the P.D. as on the osmotic pressure, swelling,
and viscosity of the protein solutions.

The next fact of interest was that the values of pH inside
minus pH outside diminish in a parallel way with the diminution
of the P.D. and that the values of 59 (pH inside minus pH outside)
agree remarkably well with the observed P.D. (Table XVIII).

We have seen in Chapter VI that the addition of a salt with
bivalent anion, e.g., Na2SO4, to a gelatin chloride solution has a
much greater depressing effect on the osmotic pressure, viscosity,
etc., of the solution than the addition of a salt with monovalent
anion, namely, NaNO3. It can be shown that the addition of
Na2SO4 also has a greater depressing effect on the P.D. of a
gelatin chloride solution than has a NaNO3 solution of the same
molecular concentration (Table XIX).

We will consider as a third case the influence of CaCl2 on the
P.D. of a gelatin chloride solution. It has been shown that the
depressing effect of CaCl2 on the osmotic pressure of a gelatin
chloride solution is about twice as great as that of an equimolec-
ular concentration of NaCl. Table XX shows that the depress-
ing influence of CaCU on the P.D. is about twice as great as
that of NaNOs. The agreement between the observed P.D. and

MEMBRANE POTENTIALS

141

5

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142

THEORY OF COLLOIDAL BEHAVIOR

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PH PH'

MEMBRANE POTENTIALS 143

the value 59 (pH inside minus pH outside), i.e., the calculated
P.D., is excellent.

It is of importance that the depressing effect of salts on the P.D.
can be derived from the Donnan theory. To show this we must
remember that the P.D. is expressed by the following term:

P.D. == Y log (l + -) millivolts

When we add NaCl to a gelatin chloride solution we increase the
concentration of the chlorine ions not in combination with gela-
tin, i.e., y, while the concentration z of the Cl ions in combination
with the gelatin remains the same, provided the pH remains the
same (neglecting the diminution of ionization of gelatin chloride).
Hence, the P.D. must become the smaller the greater y, and with

steadily increasing y and constant z the value of 1 H — must

approach 1; i.e., the addition of enough salt must depress the
P.D. to zero, which is actually the case.

This is also true when we add another salt, e.g., NaNO3, to a
gelatin chloride solution. In this case we may assume that
gelatin nitrate is formed.

The depressing effect of the addition of NaCl to gelatin chloride
solution on the P.D. can be derived from the values of pH
inside minus pH outside. The question arises, Why is it correct
to neglect the influence of the Na ion? The writer did not give
any reason for this but Dr. J. A. Wilson was kind enough to point
out in a letter the mathematical proof justifying the writer's
procedure in the following way:

"The true expression of the P.D. of a gelatin chloride solution
the presence of NaCl is

p RT . [HJ outside + [NaJ outside

F r +1 r +1

LH J inside + |_NaJ inside

Let the system contain the positive ions A, B, C, etc., and the
negative ions M, N, 0, etc., whose concentration in the outside
solution are, a, b, c, m, n, o, etc., and in the inside solution,
a', br, etc. From the published work of Procter and Wilson it is
evident that the product of concentration of any pair of op-
positely charged ions is equal in both phases. The following
equations are evident,

144 THEORY OF COLLOIDAL BEHAVIOR

a X m = a' X in'
b x m = b' X m'

(a + b + c + . . . )m = (a' + 6' + c' + . . . X
(a + 6 + c + . . )(w + n + o + . . . ) =

(a' + 6' + c' + ... )(ro' + n' + o' + . . . )
whence

a b _c a + 6 + c + . . . "
a7 == 6' ~? == a' + 6' + c' + . . .

It is, therefore, immaterial which ion is singled out for the
calculation of the P.D. on the basis of the Donnan effect. For
the sake of the accuracy of measurement the hydrogen ion was
selected.

It is perhaps worth while to point out that the agreement
between calculated and observed P.D. is better in the experi-
ments with salts than in the experiments without salts, especially
near the isoelectric point. It seems almost as if the presence of
too low a concentration of electrolyte increased the error of the
measurements .

THE INFLUENCE OF THE SIGN OF CHARGE

The fact that the P.D. of a protein-acid salt solution is a

function of the term log (1 + -), where z is the concentration of

y

the anion in combination with the protein ions and y the con-
centration of the anion of the free acid, explains a phenomenon
which is fundamental in colloidal behavior, namely, that when-
ever a salt depresses any physical property of a protein (or a
colloidal solution in general) this action is due to that ion of the
salt which has the opposite sign of charge to that of the protein
ion. That this is true for the influence of salts on viscosity,
osmotic pressure, and swelling has been discussed in Chap. VI,
and we shall see that it is true also for the precipitation of certain
protein solutions. In the latter case it is known as Hardy's rule
of the precipitating action of salt. In all these cases the effi-
ciency of the salt increases with the valency of the efficient
ion of the salt. These rules are a consequence of the Donnan

MEMBRANE POTENTIALS 145

equilibrium. The term derived from the equilibrium equation,
log (1 -\ — ) makes the P.D. a function of z and y, i.e., that ion
which has the opposite sign of charge to the protein ion.
THE INFLUENCE OF THE CONCENTRATION OF PROTEIN ON THE P.D.

While the addition of neutral salt depresses the P.D. of protein
solutions across a membrane (as it depresses all the other prop-
erties) the addition of protein has the opposite effect, increasing
the P.D. (as it increases also the other properties). This influ-
ence of the concentration of the protein follows mathematically

from the equilibrium equation. Since P.D. = -=- log (1 + -)

* y

millivolts, it is obvious that if y remains constant (i.e., if no salt
is present and the pH remains the same) while z increases as a
consequence of the increase of the concentration of protein, the
P.D. must rise with the concentration, and this was found to be
the case.

Collodion bags, connected with glass manometers in the way
described, containing 50 c.c. of different concentrations of origi-
nally isoelectric gelatin varying from 0.125 per cent to 2 per cent
and containing enough H3PO4 to bring the gelatin solution to a
pH of 3.5 were put into beakers containing 350 c.c. H3PO4
solution of pH 3.5. In order to prevent dilution of the protein
solution through osmosis, the glass manometers were filled at
the beginning of the experiment with the same gelatin phosphate
solution as that contained in the collodion bag, to that height
which the osmotic pressure measured in preceding experiments
amounted to. After about 20 hours the pH in the inside and the
outside solutions and the P.D. across the membrane were meas-
sured. Some of the experiments were made in duplicate (Table
XXI).

It is obvious, first, that the P.D. increases with the concentra-
tion of gelatin, and second, that the increase of P.D. observed
agrees quantitatively with the increase calculated on the assump-
tion of the validity of Donnan's theory.

THE P.D. OF SOLUTIONS OF CRYSTALLINE EGG ALBUMIN

The experiments mentioned thus far had all been done on

gelatin. It was of importance to determine whether or not
10

146

THEORY OF COLLOIDAL BEHAVIOR

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MEMBRANE POTENTIALS 147

these results could be confirmed with crystalline egg albumin.
This was found to be the case, and the experiments on the
membrane potentials of the solutions of the chloride of crystalline
egg albumin showed a perfect quantitative agreement with the
theory.

Collodion bags of about 50 c.c. volume were filled with a solu-
tion of 1 per cent crystalline egg albumin containing varying
amounts of 0.1 N HC1, and the bags were put, as usual, into
beakers containing 350 c.c. of HC1 solutions of different concen-
tration but free from albumin. The first two horizontal rows
of Table XXII give the amount of 0.1 N HC1 in each solution.
The experiments were carried out at a temperature of 24°C.,
and after 22 hours the osmotic pressure, P.D., and pH of inside
(albumin) solution and pH of the outside solution were measured.
The albumin used was not isoelectric, but since it had been
prepared after S0rensen's method it was probably partly am-
monium albuminate, with a pH of near 6.0. The table shows that
the calculated and observed P.D. agree beautifully (especially on
the acid side of the isoelectric point) ; that the P.D. is a minimum
near pH 4.70 of the albumin (i.e., near the isoelectric point, which
is at pH 4.8), and that the albumin is positively charged on the
acid and negatively charged on the alkaline side of the isoelectric
point. This is again in harmony with what we should expect
on the basis of the Donnan equilibrium.

The next problem was to determine the influence of the addi-
tion of a neutral salt to a solution of the chloride of crystalline
egg albumin. A 1 per cent solution of crystalline egg albumin
containing 7 c.c. of 0.1 N HC1 in 100 c.c. was made up in various
concentrations of NaCl. The collodion bags containing these
albumin chloride-NaCl mixtures were dipped into beakers con-
taining 350 c.c. of the same concentration of NaCl as that of the
albumin solution, and all made up in N/1,000 HC1. The experi-
ment was carried out at 24°C. and the measurements were made
after 22 hours.

Table XXIII gives the results, which show again a beautiful
agreement between calculated and observed P.D.

We may, therefore, conclude that the P.D. of both gelatin
solutions and solutions of crystalline egg albumin separated by a
collodion membrane from a watery solution free from protein is

148

THEORY OF COLLOIDAL BEHAVIOR

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MEMBRANE POTENTIALS 149

exclusively determined by the Donnan equilibrium, since
otherwise the quantitative agreement between the observed
P.D. and the values calculated from Donnan's equation would
be impossible.

It may be stated, finally, that since P.D. = 29 log (l + |)

millivolts, it follows that the addition of a non-electrolyte to a
gelatin chloride solution cannot influence the P.D. since the

addition of a non-electrolyte cannot affect the value of -•

The expression for P.D. also explains why the P.D. is zero
at the isoelectric point of a protein, since z becomes zero at that
point. Moreover, it is obvious that the addition of a neutral
salt to a solution of isoelectric gelatin cannot further depress
the P.D. or cause a reversal in the sign of the charge.

Donnan's theory of membrane equilibrium therefore explains
mathematically and quantitatively the P.D. observed at equi-
librium between a protein solution and a watery solution free
from protein, separated by a membrane. It does not happen
very often that every postulate of a theory is fulfilled by the
observation as it is in this case.

The bearing of this fact upon the theories of colloidal behavior
is as follows: The P.D. is influenced by the hydrogen ion con-
centration, by the valency of the ion, by the addition of neutral
salt in the same way as are the other properties of protein, such
as osmotic pressure, viscosity, and swelling. Since the Donnan
theory explains this influence of pH, valency, and salt effect on
P.D. with mathematical accuracy, it seems at least highly
probable that it may also explain the other colloidal properties
of proteins in the same way, with this difference only, that the
experimental error is much greater in the measurements of the
other properties than in the measurements of P.D.

CHAPTER IX

THE ORIGIN OF THE ELECTRICAL CHARGES OF MICEL-
LAE, AND OF LIVING CELLS AND TISSUES

1. STABILITY or SUSPENSIONS, ELECTRICAL CHARGES OF
MICELLAE, AND DONNAN EQUILIBRIUM

The stability of suspensions is, perhaps, the chief problem of a
theory of colloidal behavior. Hardy1 has shown that this prob-
lem is linked with the problem of the origin of the electrical
charges of the particles in suspension, since such particles are
forced by mutual electrostatic repulsion to remain in suspension.
By his experiments on the migration of suspended particles of
coagulated white of egg in an electrical field he proved that they
have a positive charge in the presence of acid, a negative charge
in the presence of alkali, and no charge at an intermediate point
which he termed the isoelectric point of the particles. He was
able to demonstrate that the stability of colloidal suspensions is
a minimum at the isoelectric point.

He and others found, moreover, that low concentrations of
neutral salts diminish the stability of colloidal suspensions in
the presence of acids or alkalies and that the efficient ion of the
salt has the opposite sign of charge to that of the colloidal
particle, since the precipitating efficiency of a salt increases
rapidly with the valency of that ion of the salt which has the
opposite sign of charge to that of the colloidal particles. It
seemed natural to infer that the precipitation of colloidal sus-
pensions by low concentrations of a salt was caused by an
annihilation of the charge of the colloidal particle. The problem
of the stability of the colloidal suspension then developed into
the problem of accounting for this peculiar behavior of the
electrical charges of colloidal particles.

Hardy's original idea was that the H ions of the acid or OH

1 HARDY, W. B., Proc. Roy. Soc., vol. 66, p. 110, 1900.

150

THE ELECTRICAL CHARGES OF MICELLA 151

ions of the alkali were adsorbed by the colloidal particle in pref-
erence to the other ions on account of their greater rapidity of
migration;1 and this idea was also accepted by Perrin2 in his
experiments on electrical endosmose, where it was necessary
to account for the fact that certain membranes become posi-
tively charged in the presence of acid and negatively in the
presence of alkali. Those who accept the adsorption hypothesis
explain the fact that the electrical charges of the particles are
apparently diminished or destroyed by the addition of a salt on
the assumption of a preferential adsorption of one of the ions of
the salt by the micellae; yet such an assumption is incompatible
with the purely stoichiometrical behavior of proteins. It is
also difficult to account on the basis of the adsorption hypothesis
for the fact that the addition of little acid increases while the
addition of more acid depresses the electrical charge of micellae.

A second possibility was pointed out by the writer in 1904, 3
namely, that Hardy's migration experiments might be explained
in the case of proteins by the fact that proteins are amphoteric
electrolytes which in the presence of alkali dissociate electro-
lytically by giving rise to a protein anion and in the presence of
acid giving rise to a protein cation; while at the isoelectric point
no protein ion would be formed. This idea could, however, not
explain why the addition of a salt in low concentration should
diminish the charge of aggregates of ions, i.e., the micellae, except
by assuming that in this case the electrolytic dissociation of the
protein salts should be repressed. The concentration of salts
required for the precipitation of colloidal suspensions is, however,
much too small to make such a suggestion acceptable. The
idea is, however, correct if applied to the migration of isolated
protein ions in the electrical field.

In 1916 J. A. Wilson4 suggested that these electrical charges of
micellae were caused by the establishment of a Donnan equilib-
rium between the colloidal particle and the surrounding solution.
There were, however, no measurements of membrane potentials

1 HARDY, W. B., J. physiol, vol. 29, p. xxvi, 1903.

2 PERRIN, J., J. chim. physique, vol. 2, p. 601, 1904; vol. 3, p. 50, 1905.
Notice sur les titres et travaux scientifiques de M. JEAN PERRIN, Paris,
1918.

3 LOEB, J., Univ. Cat. Pub., Physiology, vol. 1, p. 149, 1904.

4 WILSON, J. A., J. Am. Chem. Soc., vol. 38, p. 1982, 1916.

152 THEORY OF COLLOIDAL BEHAVIOR

available at that time and this was probably the reason that his
suggestion was not accepted.

We may consider a protein solution inside a collodion bag and
surrounded by a watery solution as a model of a protein micella
suspended in a watery solution. In that case it can be shown
that the electrical charge of such a model varies in exactly the
same way as the charges of colloidal particles in suspension,
e.g., coagulated egg albumin.

1. The electrical charge of the micella model (i.e., gelatin solu-
tion in a collodion bag) is zero at the isoelectric point.

2. The charge of the model is positive on the acid side and
negative on the alkaline side of the isoelectric point of gelatin and
of crystalline egg albumin.

3. The charge of the model increases with the addition of little
acid and diminishes with the addition of more acid to isoelectric
particles.

4. The charge of the model is diminished by the addition of low
concentrations of neutral salts, and the depressing action of the
salt increases rapidly with the valency of that ion of the neutral
salt which has the opposite sign of charge to that of the micella.

It has been shown in the preceding chapter that these facts
can be explained not only qualitatively but quantitatively from
the theory of Donnan's membrane equilibrium. This quantita-
tive agreement leaves no doubt that the electrical charge of this
micella model is caused exclusively by the Donnan equilibrium.

2. THE ELECTRICAL CHARGE OF SUSPENDED PARTICLES OF
POWDERED GELATIN

We may ask whether it is justifiable to consider a gelatin solu-
tion enclosed in a collodion bag and surrounded by an aqueous
solution as a model of a micella. This is theoretically correct
since the colloidal behavior of both a true micella as well as the
protein solution in a collodion bag is due to the same condition,
namely, that the protein ion is prevented from diffusing into the
outside aqueous solution while no such block exists for the diffu-
sion of the crystalloidal ions. The block which prevents the
diffusion of the protein ions in the model is the collodion mem-
brane, while in the case of the micella (or a solid jelly) it is the

THE ELECTRICAL CHARGES OF MICELLA 153

cohesion between the protein ions themselves. The formation of
a micella depends upon these cohesive forces between the protein
ions (or parts of these ions) becoming stronger than the attractive
forces between the protein molecules and the molecules of water.
The nondiffusibility of the protein ions of the micella must give
rise to the establishment of a Donnan equilibrium between the
micella and the surrounding liquid, and this equilibrium must
give rise to the electrical charge of the micella. The only ques-
tion is how far the agreement between Donnan's theory and the
observed charge goes in the case of true micellae. To test this we
used suspensions of particles of powdered gelatin in water. If it
can be shown, first, that these particles assume electrical charges
when suspended in water, second, that these charges vary in the
usual way with pH and the presence of salts, and third, that these
charges can be derived from the Donnan equilibrium, the theory
of these charges as well as the theory of the stability of colloidal
suspensions can be put on an exact scientific basis.

The method of these experiments was as follows: Powdered
particles of isoelectric gelatin were put into a solution of acid or
alkali at a temperature of 20°C. and allowed to remain there for a
number of hours to allow a complete or approximate equilibrium
to be established between the inside of the micellae and the outside
solution.1 The temperature must not be above 20°, since other-
wise the granules of gelatin will dissolve too rapidly. After a
number of hours the suspended particles were separated from
the outside solution by filtration, the gelatin was melted and put
into vessels with two bent tubes (see Fig. 42). After the gelatin
had set to a gel (by cooling) the P.D. between the solid gel and
the outside solution (filtrate) was determined with the electro-
meter. The P.D. was that of the following cell:

calomel
electrode

saturated
KC1

outside
watery
solution

solid gel

saturated
KC1

calomel
electrode

Everything else being symmetrical the P.D. measured was that
between the suspended particles of gelatin (solid gel) and the
outside solution with which the gelatin micellae had been in
complete or approximate equilibrium.

1 LOEB, J., J. Gen. Physiol, vol. 4, p. 351, 1921-22.

154

THEORY OF COLLOIDAL BEHAVIOR

It can be shown that the P.D. between the micellae and the
surrounding solution is influenced in the same way by pH,
valency, and salts as is the P.D. between a protein solution and a
watery solution separated from each other by a collodion mem-
brane. It was then necessary to ascertain whether this P.D.
was due to Donnan equilibrium, and for this purpose the pH

Fia. 42. — Method of measuring P.D. between gel and surrounding solution.

inside of the (melted) gelatin micellae and the pH of the outside
solution were measured with the hydrogen electrode and the
potentiometer. It was found that the value 58 (pH inside the
micellae minus pH outside) agreed as closely with the P.D.
observed with the Compton electrometer as the accuracy of the
measurements permitted. This makes it highly probable that
the electrical charge of the micellae is determined by the Donnan
equilibrium. We will again call the value 58 (pH inside micellae
minus pH outside) the calculated P.D. though it was in reality
also observed. The accuracy of the P.D. measurements is not as
great as in the case of the experiments of the preceding chapter,
for reasons which we have not yet been able to ascertain.

THE ELECTRICAL CHARGES OF MICELLAE 155

3. THE INFLUENCE OF pH ON THE CHARGE OF SUSPENDED

PARTICLES OF POWDERED GELATIN

One-gram samples of powdered isoelectric gelatin going through
mesh 30 but not through mesh 60 were put into 350 c.c. of water
containing various quantities of HC1 (see first horizontal row of
Table XXIV), and left in these solutions for 24 hours at 20°C.
The mixtures were occasionally stirred. After 24 hours the
relative volume of the particles was measured and they were put
on a filter to allow the acid to drain off. The gelatin was then
melted by heating to 45°C. and poured into glass cylinders which
at their lower end had two glass side tubes attached (Fig. 42).
The mass was then allowed to solidify by cooling and the P.D.
between gelatin and watery solution was ascertained. One of the
two glass tubes dipped into a beaker containing the outside HC1
solution (the filtrate) with which the gelatin had been in equilib-
rium, and the other dipped into a beaker containing a saturated
solution of KC1. Each beaker was connected with a calomel
electrode (filled with saturated KC1) leading to a Compton
electrometer. The last row in Table XXIV gives the observed
P.D. in millivolts.

The pH of the melted gelatin was determined potentiometri-
cally. This is called pH inside in Table XXIV. The pH of the
outside solutions (filtrate) was also determined.

While the agreement between the observed P.D. and the value
of 59 (pH inside micellae minus pH outside) is not as good as in the
experiments with collodion bags, it is at least sufficient to leave
no doubt that the charge is caused by the Donnan equilibrium in
the way discussed in the preceding chapter.

4. THE INFLUENCE OF ACID AND ALKALI ON THE SIGN OF CHARGE

OF MICELLAE

In Hardy's experiment with white of egg the particles were
positively charged on the acid side of the isoelectric point and
negatively charged on the alkaline side. It can be shown that
this is also true for the charges of the suspended particles of
powdered gelatin, and that this change of sign of charge of these
particles by going from the acid to the alkaline side of the iso-

156

THEORY OF COLLOIDAL BEHAVIOR

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THE ELECTRICAL CHARGES OF MICELLA 157

electric point is accompanied by a change in the sign of the value
(pH inside micellae minus pH outside).

One gram of powdered gelatin of grain size between mesh 30
and 60, rendered isoelectric, was put into each of a series of
closed flasks containing 350 c.c. of distilled water with varying
quantities of 0.1 N HC1 or NaOH per 100 c.c. (see Table XXV).
The temperature was 20°C. After 4 hours the powdered gelatin
was separated from its supernatant liquid by filtration, the gela-
tin was melted and the pH of the melted gelatin and of the outside
solution (filtrate) were measured. The gelatin was then solidi-
fied and the P.D. between the solid gelatin and the filtrate (out-
side solution) determined, as described. The results of the
experiments are given in Table XXV. The first row gives the
number of cubic centimeters of 0.1 N HC1 or NaOH contained
originally in 100 c.c. outside solution. The next row gives the
relative volume of the solid mass of gelatin, i.e., the degree of
swelling. The rest of the table needs no explanation. It is
obvious that pH inside minus pH outside is positive as long as the
pH of the gelatin is on the acid side of the isoelectric point, while
it is negative when the gelatin is on the alkaline side of the iso-
electric point. The turning point is approximately at the iso-
electric point, but the measurements near the isoelectric point
are obviously vitiated by experimental errors and possibly by
some other factor, so that we cannot demonstrate more by the
experiment than that suspended particles of solid metal gelatinate
have the opposite sign of charge to that of the micellae of gelatin
chloride, and that this difference is accompanied by a reversal of
the sign of the value of pH inside minus pH outside, which is
positive in the case of gelatin chloride and negative in the case
of Na gelatinate. It may also be pointed out that the minimum
of swelling (volume) coincides with the minimum of P.D.

5. THE INFLUENCE OF SALTS ON THE CHARGE OF SUSPENDED
PARTICLES OF GELATIN

The most important fact which a theory of the electrical charge
of colloidal micellse is expected to explain is the annihilation of
these charges by neutral salts. Those who believe in the adsorp-
tion theory assume that both ions of a neutral salt are adsorbed

158 THEORY OF COLLOIDAL BEHAVIOR

by the colloidal particles, and that the salt ion with the opposite
sign of charge to that of the colloidal particle diminishes the
charge of the latter, while the salt ion with the same sign of charge
as the colloidal particle increases the charge of the latter, and the
more the higher the valency of the ion of the salt. The idea that
such an adsorption occurs is definitely refuted by the experiments
discussed in Chap. II (see Figs. 1 and 2). It might, however,
be possible that the ion with the same sign of charge as the
colloidal particle might increase the charge of the colloidal
particle in some other way than through adsorption, and it was
necessary to test this possibility, which has found acceptance on
the part of some chemists. The writer's experiments on anomal-
ous osmosis have shown that when a dilute solution of a salt is
separated from pure water by a collodion membrane coated
with gelatin, if the salt solution and the water are brought to the
same pH by adding an acid, e.g., HNO3, the potential difference
on the two opposite sides of the membrane increases with the
valency of the cation of the salt used, i.e., in the order

Ce>Ca>Na

This influence was found to be due to a diffusion potential.1
Nevertheless it seemed necessary to determine whether or not
these cations influenced the charge of suspended particles of
gelatin chloride in the same way. If this were true, the depress-
ing effect of CeCl3 on the charge of the micellae should be less
than the depressing effect of CaCl2, and the depressing effect of
CaCl2 should be less than the depressing effect of Nad, provided
the pH is on the acid side of the isoelectric point.

If, on the other hand, the Donnan effect alone determines the
depressing effect of the salt on the charge of the suspended
particles of gelatin, this depressing effect should be exclusively
due to the anion of the salt on the acid side of the isoelectric
point of the gelatin, while the cation of the salt should have no
effect. This follows from the discussion in the preceding chapter
according to which the P.D. between gelatin chloride solution

and water is determined by the value of log (1 + -), where z

y
and y are the anions. The cations do not enter into the term on

1 LOEB, J., J. Gen. Physiol., vol. 4, pp. 213, 463, 1921-22.

THE ELECTRICAL CHARGES OF MICELLA 159

the acid side of the isoelectric point. We shall see that the meas-
urements of the P.D. between micellae and surrounding solution
are sufficiently accurate to leave no doubt that the Donnan equi-
librium alone determines the charge of the micellae and that the
cation of the salt does not increase the charge of the micellae of
gelatin chloride.

In order to get accurate measurements it was necessary to use
micellae of gelatin chloride of a pH sufficiently far from the iso-
electric point to avoid the errors of the measurements which
occur near that point. We weighed out doses of 1 gm. of
powdered gelatin of a pH of near 7.0 and made them isoelectric by
treatment with M/128 acetic acid and subsequent washing as
described in Chap. II. In this process some gelatin was dis-
solved and lost (probably about 25 per cent). The isoelectric
powdered gelatin was put into 200 c.c. of H20 or a solution of
different concentrations of a salt — NaCl, CaCl2, BaCl2, CeCl3,
or Na2SO4 — and containing 16 c.c. of 0.1 N HC1. This brought
the pH of the micellae down to 2.8 or less, as Tables XXVI to
XXX show. The powdered gelatin was left in these acid-salt
solutions for two hours at 20°C., with frequent stirring. Then
the supernatant liquid was separated from the powdered particles
of gelatin by filtration and the P.D. between the micellae and the
surrounding liquid (filtrate) measured with the Compton electro-
meter using the electrodes described in Fig. 42. After this the
value (pH inside — pH outside) was obtained with the aid of the
hydrogen electrode at 24°C. and this value multiplied by 59 is
called the calculated P.D. Tables XXVI to XXX give the
results. The uppermost row gives the nature and concentration
of the salt. The next row gives the relative volume of the gel
of gelatin, and the depressing influence of the salt on the swelling;
then follow the values for pH inside and outside measured with
the hydrogen electrode and then the values pH inside minus
pH outside. The last two columns give the calculated P.D. , i.e.,
the value 59 (pH inside minus pH outside), and the P.D. observed
with the Compton electrometer and the indifferent electrodes
described in Fig. 42.

The fact in common to all the experiments is the satisfactory
agreement between the observed and calculated P.D. except that
the calculated P.D. is on the average about 3 millivolts higher

160

THEORY OF COLLOIDAL BEHAVIOR

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than the observed P.D. and the
cause for this difference is un-
known at present. It is, how-
ever, a constant difference and
has therefore no relation to the
nature of the salt used. When
we use as a standard for com-
parison of the relative depressing
effect of a salt the concentration
required to depress the observed
P.D. to about 10 millivolts, we
find that the following concen-
trations of the five salts are
required for this purpose.

NaCl about M/64
CaCl2 slightly above M/128
BaCl2 slightly above M/128
CeCl3 between M/256 and M/128
Na2SO4 about M/256

The main fact is that the de-
pressing effect of the four salts
NaCl, CaCl2, BaCl2, and CeCl3
is determined by the chlorine ion
concentration, and that the val-
ency of the cation has no influ-
ence. This leaves no doubt that
the charge of the micellae is an
unequivocal function of the,
Donnan equilibrium.

The depressing action of Na2-
SO4 is about four times as great
as that of NaCl.

If the precipitating effect of a
salt on the stability of colloidal
suspensions is due exclusively to
the depressing effect of the salt
on the P.D. between micellae and
surrounding liquid, only that ion

THE ELECTRICAL CHARGES OF MICELLA 163

should have an effect on the precipitation which has the opposite
charge to that of the micellae; and this precipitating effect should
increase with the valency of the active ion. The Hardy-Schulze
and Linder-Picton rule of precipitation is, therefore, only the
consequence of the Donnan equilibrium.

It is necessary to correct in this place an error which occurs
frequently in the colloidal literature, namely, the statement that
in the precipitation of colloidal suspensions by neutral salts the
colloidal particles are brought to the isoelectric point by the
salt. What happens is that by the addition of neutral salts the
P.D. between suspended particles and liquid is diminished, and
if enough salt is added completely annihiliated. This is due to
the fact that as a consequence of the addition of the salt the value

y in the term log ( 1 + -j , upon which the P.D. depends, increases.

When, however, the gelatin granules are brought to the iso-
electric point of gelatin, i.e., to pH 4.7, through a change in the
hydrogen ion concentration, the P.D. between particles and
surrounding liquid becomes also zero, but for a different reason,
namely, because the gelatin is now no longer ionized at this point.
In this case the P.D. becomes zero because z in the term log

4- -) becomes zero.

If the theory of the Donnan equilibrium is applied to these
phenomena it becomes therefore obvious that the P.D. between
colloidal particles and surrounding liquid can become zero in two

different ways : first, by making the value of z in the term 1 + -

equal to zero, and this is only possible by bringing the hydrogen
ion concentration of the solution to that of the isoelectric point
of the protein (which in the case of gelatin is at pH 4.7); and

second, by making y in the term 1 + - very large, i.e., by increas-
ing the concentration of the ions having the opposite sign of
charge to that of the colloidal particles, and this can be done at
any pH by adding a neutral salt.

It is therefore entirely wrong to say that the salt causes the
precipitation of the suspended particles by bringing them to the
isoelectric point or that the isoelectric point of a protein is shifted

164 THEORY OF COLLOIDAL BEHAVIOR

by the addition of a salt. The isoelectric point of a protein is a
constitutional property of the protein which need not be and
probably, as a rule, is not affected by the addition of a neutral
salt, since it is that hydrogen ion concentration at which a protein
dissociates equally as an acid and as a base.

Electrical endosmose, anomalous osmosis, and kindred phen-
omena are due to the fact that there is a P.D. between the liquid
and the walls of the membrane through which the liquid diffuses.
It is often assumed that this P.D. is due to the adsorption of ions
by the membrane whereby the charge of the adsorbed ion is
transferred to the membrane. The writer tested this idea by
experiments with membranes which had received a coating of a
protein. He found that at the isoelectric point of the protein
which forms the coating no electrical transport of water occurs
either in electrical endosmose or in anomalous osmosis.1 This
agrees with the idea that the charge of the liquid inside the pores
of the membrane is due to the Donnan equilibrium between
membrane and liquid.

Experiments on anomalous osmosis were made to test the idea
whether or not salts can transfer an electrical charge to solid
particles of gelatin as acids or alkalies can. In order to test this
idea these experiments were made with liquids of pH 4.7, i.e., at
the isoelectric point of gelatin. In this case the gelatin is not
charged through acid or alkali and no electrical transport of water
occurs at this point in either electrical endosmose or in anomalous
osmosis. If now a salt, like CaCl2 or Na2SO4, were able to trans-
fer a charge to the gelatin, this should betray itself by an electrical
transport of water through the gelatin membrane at pH 4.7 in
experiments on anomalous osmosis. It was found that salts, like
LiCl, NaCl, KC1, MgCl2, CaCl2, BaCl2, Na2S04, and others, at
pH 4.7, leave the isoelectric gelatin uncharged, and that no
electrical transport of liquid occurs at pH 4.7 in the presence of
these salts. When, however, solutions of salts with trivalent
cations, such as LaCl3 or CeCl3, or with tetravalent anion, like
Na4Fe(CN)6, (all of pH 4.7) were used, the film of isoelectric
gelatin assumed a charge; this charge was positive in the case of
CeCl3 or LaCl3 and negative in the case of Na4Fe(CN)6. It was

^OEB, J., J. Gen. PhysioL, vol. 2, p. 557, 1919-20; and in unpublished
experiments.

THE ELECTRICAL CHARGES OF MICELLAE 165

apparently not due to a change in the pH since it occurred also
when the salt solution was buffered by the addition of a mixture
of Na acetate and acetic acid.1 Perrin had noticed in his experi-
ments on electrical endosmose2 that salts with trivalent cations
reversed the sign of charge of negatively charged membranes and
that tetravalent anions reversed the sign of charge of positively
charged membranes.

As a possible explanation the writer suggested a loose combina-
tion between isoelectric gelatin and the salts with trivalent cations
or tetravalent anions, resulting in the formation of complex and
positively charged gelatin-Ce or gelatin-La ions or negatively
charged gelatin-Fe(CN)6 ions. In other words, salts with
trivalent (and tetravalent?) cations would react with isoelectric
gelatin somewhat like acids, and salts with tetravalent anions
would react somewhat like alkalies, the former causing the forma-
tion of positively charged complex protein ions, the latter
causing the formation of negatively charged complex protein
ions, — with this difference, that the protein-acid salts and metal
proteinates are much more stable than the complex salts formed
with trivalent cations and tetravalent anions. The result would
in both cases be the ionization of the protein salt, resulting in a
Donnan equilibrium and P.D. between solid protein and water.

It should be added that the experiments in Chap. II show
that the Ce or Fe(CN)6 ions can be washed away very easily, so
that their compounds with gelatin differ in this respect from the
compounds of gelatin with acid or alkali.

The tendency of proteins to form durable films when in contact
with solid bodies probably explains the phenomenon that the
addition of a little gelatin keeps coarser particles in suspension
which without the gelatin would rapidly settle. If in this case
the gelatin forms a solid film on the surface of the particle the
latter will assume an electrical charge as long as the liquid has a
pH different from 4.7; since as long as the pH is either less or more
than 4.7 the P.D. between water and the gelatin-coated particles
will keep the latter from settling. When, however, the pH is
4.7, this protective influence of the gelatin must disappear.

iLoEB, J., J. Gen. Physiol, vol. 4, p. 463, 1921-22.
2 PERRIN, J., /. chim. physique, vol. 2, p. 601, 1904; vol. 3, p. 50, 1905.
Notice sur les titres et travaux scientifiques de M. Jean Perrin, Paris, 1918.

166 THEORY OF COLLOIDAL BEHAVIOR

It is very interesting that this film formation of gelatin on
collodion membranes occurs regardless of the pH of the solution.
It is, therefore, not necessary that the gelatin (or protein) be
ionized to form a film on collodion membranes.

Aside from the electrical charges, the osmotic pressure of the
solution seems also to have an effect on the stability of the col-
loidal solution. We shall see that the Donnan effect demands also
that the osmotic pressure be influenced in a similar way by the pH,
the valency, and the presence of salt as is the P.D. The depress-
ing effect of the salt on the difference of osmotic pressure inside
and outside the micellae may possibly be of more importance in
the precipitation of colloidal suspensions than the depressing
effect of the salt on the electrical charge of the micellae. This is
indicated by the fact that the difference in the depressing effect
of NaCl and Na2SO4 is greater for osmotic pressure than for P. D.

6. THE ORIGIN OF THE ELECTRICAL CHARGES OF LIVING CELLS

AND TISSUES

In his first paper on the theory of membrane equilibria Donnan
suggested that the membrane potentials postulated by his theory
might contribute towards an explanation of the action of nerves
and even of electrical fish. In 1911 the writer suggested to Dr.
Beutner that he investigate the P.D. between such organs as
apples, or leaves of the rubber plant, and water, instead of the P.D.
of muscles or nerves, which had usually been used by physiologists
for this purpose. In these experiments Dr. Beutner made the
important observation that the P.D. between the surface of an
apple or a leaf was a maximum when the bounding liquid was pure
water, while the P.D. was depressed when a salt was added to
the water, the depressing effect on the P.D. increasing with the
concentration of the salt.1 MacDonald2 had observed a similar
phenomenon, namely, the increase in P.D. between nerve and
surrounding salt solution with increasing dilution. Donnan's
theory was not known to us and we were not able to give an
explanation of the depressing effect of salt on the P.D.

A search was made for those substances in the cortex of an
apple or leaf which might be responsible for these peculiar con-

, J. and BEUTNER, R., Biochem.-Z., vol. 41, p. 1, 1912.
2 MACDONALD, J. S., Proc. Roy. Soc., vol. 67, p. 310, 1900.

THE ELECTRICAL CHARGES OF MICELLA 167

centration effects on the P.D. When the P.D. between solid
gels of gelatin and of coagulated egg albumin and water was
investigated, no potential differences were observed, to the great
surprise and disappointment of the writer, who had hoped that
the investigations of the P.D. might lead to an explanation of the
antagonistic ion effects in which he was then interested. It is
possible that the negative results with protein were due to the
fact that the measurements were accidentally made near the
isoelectric point. On the other hand, it was found that there
existed a P.D. at the boundary of lipoids (lecithin dissolved in
guaiacol) which was depressed by the addition of salts and the
more the higher the concentration of the salt.1

This analogy between lipoids and living cells gave us the im-
pression that the proteins had no share in the potential differ-
ences observed between living tissues or living cells and watery
solutions. The experiments recorded in this chapter leave no
doubt that this conclusion was wrong; any ion in a cell or on its
surface which cannot diffuse into the surrounding watery solu-
tion (no matter whether the ion is a protein or a fatty acid or some
complicated lipoid or a complicated carbohydrate or even a
crystalloid) can or must give rise to a P.D. which is depressed
when a diffusible salt is added to the surrounding watery solution.

The idea that lipoids are the substances responsible for the
P.D. of tissues led Beutner to an extensive and most interesting
investigation of the P.D. at the boundary of water-immiscible
substances and water.2 He found always a depressing effect
of the addition of salt. Beutner tried to explain this on the
basis of differences in the electrolytic dissociation in the watery
and the water-immiscible (oily) phase. Such an explanation
cannot be applied to the experiments with protein solutions and
yet these latter solutions also show the depressing effect of the
addition of salt on the P.D. in a most striking way. In this
latter case the depressing effect of the salt on the P.D. is due to
the Donnan equilibrium, and there is no reason why the theory
of membrane equilibria should not apply to the P.D. between

, J. and BEUTNER, R., Biochem.-Z., vol. 51, p. 288, 1913; vol. 59,
p. 195, 1914.

2 BEUTNER, R., "Die Entstehung elektrischer Strome in lebenden Gewe-
ben," Stuttgart, 1920.

168 THEORY OF COLLOIDAL BEHAVIOR

oily and watery phases, since this theory only demands that one
ion of the oily phase should be prevented from migrating into
the watery phase. Any lipoid ion would fulfill this postulate
of the theory. The peculiarities of electrolytic dissociation
found by Beutner in non-aqueous solutions must, however, influ-
ence the Donnan equilibrium in a secondary way, since this
equilibrium depends upon ionization.

CHAPTER X

OSMOTIC PRESSURE1

1. THEORETICAL STATEMENTS

The characteristic features of colloidal behavior appear also in
the case of the osmotic pressure of solutions of protein salts.
If the Donnan equilibrium is actually the cause of this behavior,
as the experiments on membrane potentials suggest, it must be
possible to derive these features of the osmotic pressure quanti-
tatively and mathematically from Donnan's equilibrium formula.
It is the purpose of this chapter to show that this is possible on
the basis of van't Hoff's theory of osmotic pressure. The
methods of measuring the osmotic pressure have been described
in Chap. V. Collodion bags, of a volume of about 50 c.c., are
filled with a protein solution, while the outside solution is 350 c.c.
of water into which diffuses some of the free acid of the protein-
acid salt solution or some of the free alkali of the metal proteinate
solution. In order to hasten the establishment of equilibrium
between inside and outside, the pH of the outside solution
was usually at the beginning of the experiment brought to the
same pH as that of the protein solution by adding the same acid
or the same base as that of the protein solution. Equilibrium
was established after about 6 hours but the measurements were
usually taken after about 20 hours. The solutions were kept at
a constant temperature of 24°C. throughout the experiment.

A gelatin chloride solution contains free hydrochloric acid,
gelatin chloride (which dissociates electrolytically like any other
salt in watery solution), and non-ionogenic protein molecules.
A 1 per cent gelatin chloride solution of about pH 3.5 is in equi-
librium with a HC1 solution (free from protein) of a pH of about
3.0, the solutions being separated by a collodion membrane.

The terms for the calculation of the osmotic pressure of
gelatin solutions are the same as those used by Procter (1914)
, J., J. Gen. Physiol, vol. 3, p. 691, 1920-21.
169

170 THEORY OF COLLOIDAL BEHAVIOR

and by Procter and Wilson (1916) l for the calculation of the
swelling (see Chap. XI). Since, however, the application of
the theory is simpler in the case of osmotic pressure than in the
case of swelling, it may be well to discuss osmotic pressure
experiments first.2

Let y be the concentration of the H and Cl ions of the free HC1
inside a gelatin chloride solution (containing 1 gm. of originally
isoelectric gelatin in 100 c.c.), z the concentration of the Cl ions
held by the gelatin ions, and a the sum of the concentrations of
the gelatin ions and non-ionized molecules of gelatin. For the
sake of simplification we assume complete electrolytic dissociation
of the gelatin chloride and of the HC1. In this case the osmotic
pressure of the inside solution is determined by

2y + z + a

Since, however, the outside solution is at equilibrium not H2O
but HC1 solution — in the example selected a HC1 solution of
about pH 3.0 — the observed osmotic pressure is the difference
between the osmotic pressure of the inside solution and the
osmotic counterpressure of the outside -solution.

Let x be the concentration of the H ions in the outside solution,
then the osmotic counterpressure of the outside solution is
determined by 2x.

Hence the observed osmotic pressure of the gelatin chloride
solution is determined by

2y + z + a - 2x

The osmotic pressure is observed experimentally, y can be
calculated from the pH inside, and x from the pH outside.
z can be calculated from Donnan's equilibrium equation

x2 = y(y + z} (1)

(x + y)(x -y)

y

where x, y, and z have the significance stated above. The z
thus calculated differs, however, from the z obtained from the

1 PROCTER, H. R., J. Chem. Soc., vol. 105, p. 313, 1914. PROCTER, H. R.
and WILSON, J. A., J. Chem. Soc., vol. 109, p. 307, 1916.
2LoEB, J., J. Gen. Physiol, vol. 3, p. 691, 1920-21.

OSMOTIC PRESSURE 171

titration values, and this is probably the cause of a slight dis-
crepancy between observed and calculated osmotic pressures.
For the present we calculate z from equation (1).

a is unknown, and we therefore can only calculate for the
present the values of

2y + z - 2x

If we express the theoretical osmotic pressure of a grammolecu-
lar solution in terms of millimeter pressure of a column of H2O we
get (with correction for a temperature of 24°C.)

22.4 X 760 X 13.6 X = 2.5 X 105 mm.

In other words, a theoretical pressure of 2.5 mm. H^O cor-
responds to a concentration of 10~5 N. In the following tables
all concentrations are expressed in terms of 10~5 N and hence we
only need to multiply the values for 2y + z — 2x given in our
tables by 2.5 to obtain the calculated osmotic pressure of the
gelatin solution in mm. H2O (neglecting the osmotic pressure of
the gelatin ions and molecules).

Equation (1) holds in the case of solutions of all gelatin-acid
salts with monovalent anion; i.e., gelatin chloride, acetate,
phosphate, tartrate, citrate, etc. When, however, the anion of
a gelatin-acid salt is divalent, as in the case of gelatin sulphate,
the equilibrium equation becomes one of the third degree, as
has been stated in Chap. VIII. If x is the hydrogen ion con-
centration of the outside solution, the concentration of the SO4

ions in the outside solution becomes ~- If y is the concentration

of the H ions of the free sulphuric acid in the inside solution, |

is the concentration of the SO4 ions of the free acid inside the
gelatin sulphate solution. In the case of gelatin chloride z repre-
sented the concentration of chlorine ions in combination with

the gelatin; hence ~ will represent the concentration of 864 ions
in combination with the same number of gelatin ions.

172 THEORY OF COLLOIDAL BEHAVIOR

The equilibrium equation, therefore, assumes in the case of
gelatin sulphate the following form:

From equation (2) it follows that

9 — x ~ y
~¥~

The osmotic pressure of the gelatin sulphate solution should
therefore be calculated from the following values (omitting the
share of the osmotic pressure due to the gelatin molecules and
ions).

3 , z 3

2. THE CALCULATED CURVES FOR THE INFLUENCE OF pH AND

VALENCY

Solutions containing 1 gm. of originally isoelectric gelatin in
100 c.c. and containing different quantities of acid were prepared.
Collodion bags cast in the form of Erlenmeyer flasks of 50 c.c.
volume were filled with the 1 per cent solutions of a gelatin-acid
salt and put into beakers containing 350 c.c. of H2O. In order
to accelerate the establishment of the equilibrium between inside
and outside solutions a certain amount of acid was added to the
outside water (e.g., HC1 in the experiments with gelatin chloride,
H3PO4, in the experiments with gelatin phosphate, etc.). Each
Erlenmeyer flask was closed with a rubber stopper perforated
by a glass tube serving as a manometer. All this was described
in more detail in Chap. V.

In Fig. 43 are plotted the values of the osmotic pressures of 1
per cent solutions of gelatin chloride, gelatin phosphate, and
gelatin sulphate, calculated on the basis of equations (1) and (2);
and Tables XXXI, XXXII, and XXXIII give the data on the
basis of which the calculations are made. The abscissae in
Fig. 43 are the pH in the inside solution at the point of equilib-
rium, the ordinates are the values for osmotic pressure calcu-
lated from the equations referred to. Figure 44 gives the
actually observed osmotic pressures in the same experiments
which furnished the data for the calculated curves in Fig. 43.
The reader will notice that the three curves plotted in Fig. 43

OSMOTIC PRESSURE

173

show not only the same qualitative characteristics as the curves
for the observed osmotic pressures in Fig. 44, but show them
almost quantitatively; except that a correction for the value of
osmotic pressure due to the gelatin particles themselves has to be
added, a point which will be discussed later. What is of im-

pH 1.4 1.6 IS 20 22 2.4 2.6 2.8 3.0 32 3.4 a6 3.8 4.0 42 44 4.6 4fi

FIG. 43. — Calculated curves of osmotic pressure taken from the data of the
experiments represented in Fig. 44. The calculation is made on the basis of the
validity of Donnan's theory of membrane equilibrium. The calculations lead to
curves resembling the curves in Fig. 44 in all essential points, in regard to valency
effect of the anion, as well as in regard to influence of pH (see legend under
Fig. 44).

portance here is the following : The curves for osmotic pressure
calculated on the basis of the Donnan equation and plotted in
Fig. 43 resemble the curves for the osmotic pressure observed in
the same experiments represented in Fig. 44 in the following
essential points.

174

THEORY OF COLLOIDAL BEHAVIOR

(a) The curve for the calculated osmotic pressure of gelatin
chloride is identical with the curve for the calculated osmotic
pressure of gelatin phosphate, and the same is true for the two
corresponding curves representing the observed osmotic pressures
(Figs. 43 and 44).

450
425
400
375
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pH 1.4 1.6 IB 2.0 22 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 40 42 4.4 46 45

FIG. 44. — Observed curves representing the influence of pH and valency of
anion on osmotic pressure of solutions in gelatin-acid salts containing 1 gm. of
originally isoelectric gelatin in 100 c.c. solution. The curves for gelatin chloride
and gelatin phosphate are identical since the anions, Cl and HzPC^, of these two
gelatin salts are monovalent. The curve for gelatin sulphate is less than half as
high as the curve for the two other salts because the anion of gelatin sulphate is
bivalent. Both curves rise from the isoelectric point at 4.7 to a maximum at pH
about 3.4 or 3.5, and then drop rapidly again.

(6) The curve for the calculated osmotic pressure of gelatin
sulphate is a little less than half as high as the curves for the calcu-
lated osmotic pressures of gelatin chloride and gelatin phosphate;
and the same is true for the curves representing the observed
osmotic pressures of gelatin sulphate and gelatin chloride.

OSMOTIC PRESSURE

175

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176

THEORY OF COLLOIDAL BEHAVIOR

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(c) All the curves in Figs.
43 and 44 rise from a minimum
at pH 4.7, reach a maximum
(which lies at pH 3.4 or 3.5
for the observed, and at 3.0
for the calculated curves), and
then drop again as steeply as
they rose on the other side.
Moreover, the absolute values
of observed and calculated
osmotic pressures are almost
equally high, a fact which will
be discussed more fully a little
further on.

It may be added that the
curve for the calculated val-
ues of the osmotic pressure
of gelatin oxalate solutions
agrees also with the curve for
the observed values of the
osmotic pressure of solutions
of the same gelatin salt,
both being slightly lower
than the curves for gelatin
chloride.

In comparing the observed
with the calculated values for
osmotic pressure, the reader
must keep in mind that the
differences are exaggerated on
account of the fact that the
pressures are expressed in
millimeters of a column of
water instead of mercury.
If we had expressed all the
figures in terms of pressure of
mercury, as is customary, the
agreement would have ap-
peared more complete.

OSMOTIC PRESSURE

177

We can, therefore, say that (with the exception of two minor
discrepancies to be discussed further on) the Donnan equilibrium
accounts not only qualitatively but almost quantitatively for
(a) the valency effect of the anion with which the gelatin is in com-
bination; (b) for the effect of the pH.

s

450
425
400
375
350
325
300
275
250

£ 225

a 200

t/2

O 175

150

.125

100

75

50

25

t-

smoti

7o(>ektin

: presi

chl

OP(

)rice

\

\

pH 1.6 IB 20 2.2 2.4 26 2.8 3.0 3.2 34 3.6 3.8 4.0 4.2 4.4 4.6

FIG. 45. — Showing agreement and minor discrepancies between the curves
of observed and calculated osmotic pressures of 1 per cent gelatin chloride
solutions.

A glance at the formulae will show us that this influence of
the pH on osmotic pressure te a mathematical consequence of
12

178 THEORY OF COLLOIDAL BEHAVIOR

the theory. From the equilibrium equation, x2 — y(y + z), it
follows that

s = Vy(y + 2)

If we substitute this value in the term for osmotic pressure 2y
-\-z-2x, we get

2y + z - 2Vy(y+ z)

When z is zero (at the isoelectric point), the whole term becomes
zero. At the isoelectric point we observe therefore the osmotic
pressure of the protein solution free from the disturbing effects
of the Donnan equilibrium. When we add acid to isoelectric
gelatin, z increases and so does y, but, as we have shown in
Table XIV of Chap. VIII, z increases at first more rapidly
than y and later more slowly. Hence, the value of 2y + z —

+ «), i.e.j the osmotic pressure, increases at first the more
acid we add to isoelectric gelatin until a maximum is reached.
When.?/ grows more rapidly than z, z becomes more and more
negligible in comparison to y and the value of the term 2y + z —
2-\/y(y -J- z) diminishes again with increasing y, finally approach-
ing zero again as a limit.

The curves representing the values for calculated osmotic
pressures differ in one or two respects from the curves represent-
ing the values for the observed osmotic pressures (Fig. 45). As
a rule, the calculated values are lower than the observed values
(though this is only partly true for Fig. 45). This is to be ex-
pected since the calculated curves do not include that part of the
osmotic pressure which is due to the protein particles and the
calculated curves must therefore be too low, though this is
(perhaps accidentally) not true for the descending part of the
curve (for lower pH) in Fig. 45. The slight discrepancies be-
tween observed and calculated values may be due to an uncer-
tainty in our calculations or to a simplification in our assumption
which is not justified. We assume, e.g., complete electrolytic
dissociation of all compounds, which may not be entirely correct.

The discrepancies may also be due to an error in calculating z.

f7/* r I 77 ji'y* -^ 77)

We calculated z from — — where x and y were

y

the hydrogen ion concentrations determined electrgmetricaily.

OSMOTIC PRESSURE

179

There is a second way of measuring z, namely, by determining
the concentration of Cl inside a 1 per cent gelatin chloride solu-
tion by titration. The Cl inside is partly in combination with H
(free HC1) and partly combined with gelatin. By titrating with
NaOH to pH 7.0 and making the correction for isoelectric
gelatin (as described in Chap. IV) we determine the value
z -f- y. y is known from the pH and by deducting y, we get z.
We made such determinations at the end of an osmotic experi-

f y)(x-y)

ment and calculated z also from

y

in the same

experiment. Table XXXIV gives a comparison of the values
of z obtained in identical solutions by the two different methods.

TABLE XXXIV.— CONCENTRATIONS OF z X 105 N

pH of gelatin solu-
tion . . .

4 51

4 26

3 96

3 61

3 53

3 32

3 23

2 86

2 32

2 16

1 93

z calculated from

(x + y} (x — y)

30

90

166

223

252

316

387

493

570

687

687

y

z found by titra-
tion

17

84 5

170

275

291

342

401

532

548

838

885

There is no wide divergence between the two sets of values,
yet enough to suggest that the calculated values of z may be
chiefly responsible for the discrepancy between calculated and
observed curves. The reader must remember that the value of
z is multiplied by 2.5 in the calculations of the osmotic pressure
(and, therefore, any error in the calculated osmotic pressure is
multiplied in the same way).

3. THE INFLUENCE OF THE ADDITION OF SALTS

It was first pointed out by R. S. Lillie that the addition of salt
to a gelatin solution depresses its osmotic pressure. It should,
however, be stated that this depressing effect does not occur at
the isoelectric point. When we add different salts to a gelatin
chloride solution of an initial pH 3.5 containing 1 gm. originally
isoelectric gelatin in 100 c.c. solution, the depressing effect of the
salt on osmotic pressure should according to the Donnan equa-

180

THEORY OF COLLOIDAL BEHAVIOR

tion be due to the anion; and this is the case, as Fig. 46 shows.
The gelatin chloride solutions were made up in different concen-
trations of the salts, NaCl, NaNO3, CaCl2, and Na2SO4. The
pH of the mixtures was always 3.5. Collodion bags of a volume

M.
8

M. _M M. M

128 64 3Z 16 8 4

Concentration of salts

FIG. 46. — Depressing effect of neutral salts on the osmotic pressure of a 1 per cent
solution of gelatin chloride of pH 3.5.

of about 50 c.c. were filled with the gelatin chloride-salt mixtures.
These bags were dipped into beakers containing 350 c.c. of a
solution of the same inorganic salt of the same concentration
as that contained in the gelatin solutions, but these outside
solutions contained no gelatin. The pH of the outside solutions

OSMOTIC PRESSURE 181

was made at the beginning 3.0 to accelerate the establishment
of the equilibrium. The osmotic pressure was read after about
20 hours. The temperature was (as always in these cases)
24°C.

In Fig. 46 the abscissae are the initial concentrations of the salt
solutions while the ordinates are the osmotic pressures. The Don-
nan equilibrium caused a change of pH as well as of the dis-
tribution of the neutral salts on the opposite sides of the
membrane. The change of pH in this experiment has already
been discussed in Tables XVIII, XIX, and XX of Chapter
VIII. Figure 46 shows that the depressing effect of NaCl and
NaN03 is practically the same, that the depressing effect of an
equimolecular concentration of CaCl2 is not very far from twice
as great as that of NaCl, but that the effect of Na2SO4 — where
the anion is bivalent — is about eight times as great as that of a
NaCl solution of the same molecular concentration. This leaves
no doubt that the depressing effect is due to the anion and that
the cation is seemingly without any influence (it has certainly
not any influence in the opposite direction from that of the
anion). This depressing influence of the anion of a neutral salt
on the osmotic pressure of protein-acid salts can be derived from
the Donnan equilibrium equation.

Omitting that share of the osmotic pressure of the solution
which is due to the protein molecules and ions, the share due to the
Donnan equilibrium is expressed by the term

2y + z - 2Vy(y + z) (1)

Suppose the gelatin be gelatin chloride and the salt added NaCl.
Then z is the concentration of Cl in combination with gelatin,
while y is the sum of the concentration of the Cl ions combined
with the H ions of the free HC1 present in the gelatin solution
and the Cl ions of the NaCl contained in the gelatin solution at
equilibrium. We can ascertain the total concentration of Cl
ions inside the gelatin solution, i.e., the value of y + z in term
(1) by tit ration. This term 2y -\- z — 2\/y(y + z) will become
the smaller, the more closely

approaches the value 1.

182 THEORY OF COLLOIDAL BEHAVIOR

It is obvious that if z is small and constant, while y increases
more and more (through the addition of NaCl), z becomes a
negligible quantity and the term

a 2y

approaches /— = 1

0 7-7
2Vy(y

We can measure the term \/y(y + z) directly by titrating the
outside solution for Cl. We cannot determine 2y -f z directly
but we can determine y + z by titrating the inside solution for
Cl. If both tit rations are made after equilibrium is established
we get the value of

2)

and the variations of this value with increasing concentration of
NaCl are contained in Table XXXV. It is seen that this value
is almost 1 when the NaCl solution is M/32.

Now the value of — / ' = does not differ much from the

Vy(y+*)

value - — / ; as long as y is large in comparison with 2, and

we can say that with z small and constant and y large and increas-
ing rapidly, the two values

y + z 2y + z

approach the value 1 almost (but not quite) at an equal rate.
Hence, it follows from Table XXXV that if the concentration of
NaCl becomes M/32 the value 2y + z — 2VtKi + 2) must be
nearly zero. In this case the osmotic pressure of the 1 per cent
gelatin chloride solution must be almost but not quite down to
that of the pure gelatin solution as it is at the isoelectric point.
The actual observations plotted in Fig. 46 show that for M/32
NaCl or M/32 NaNO3 a 1 per cent solution of gelatin chloride
of pH about 3.5 has an osmotic pressure not far from that of

y -\- z

isoelectric gelatin. If the values of / == are plotted as

V y(y + z)

OSMOTIC PRESSURE

183

ordinates over the values of the concentration of NaCl it is
noticed that the two curves are approximately parallel (Fig. 47).

400
375
350
325
300

d 250

S 225
^-200

?..»

100
75
50
25
0

2.8
2.6
2.4
2.2
2.0
1.8
1.6
1.4
1.2
1.0

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KM MMMUMM
2018 1524 512 256 128 64 32 IF

Concentration of NaCl

Fia. 47. — Parallelism between depressing action of NaCl in the osmotic
pressure of a gelatin chloride solution and the curve representing the value

This shows that the Donnan equation actually accounts for the
depressing effect of neutral salts on the osmotic pressure of a
gelatin chloride solution,

184

THEORY OF COLLOIDAL BEHAVIOR

TABLE XXXV. — INFLUENCE OF NaCl ON OSMOTIC PRESSURE OF 1 PER
CENT GELATIN CHLORIDE SOLUTION

Concentration
of NaCl

Inside

y + z

Outside

Vy(y +z]

y + 2

Vy(y + z)

M/2,048

566

200

2.83

M/1,024

633

267

2.37

M/512

(800

300

2.66)

M/256

966

534

1.81

M/128

1,370

1,000

1.37

M/32

3,800

3,340

1.14

M/16

6,930

6,540

1.06

4. THE INFLUENCE OF THE CONCENTRATION OF A PROTEIN
SOLUTION UPON THE OSMOTIC PRESSURE

An increase in the concentration of a protein solution at the
same pH and in the absence of neutral salts should have a
double effect on the osmotic pressure. It should, first, raise the
osmotic pressure of the solution on account of the increase in the
number of protein particles in the solution; and it should, second,
lead to a further increase in osmotic pressure due to an increase
in the value of 2y + z — 2x or 2y + z — 2\/y(y + z), for it is
obvious that as long as y is constant, i.e., at constant pH of the
gelatin solution, the value of the term 2y -f z — 2\/y(y -f z)
will increase with increasing z. The two effects can be separated
by subtracting the value of the term 2y + z — 2x from the
observed osmotic pressure. The difference between the two
values should (within the limits of the accuracy of the experi-
ments) increase with the concentration of the protein. Both
expectations are fulfilled.

Different concentrations of gelatin phosphate from 2 per cent to
0.5 per cent were prepared, all having a pH of 3.5. The gelatin
phosphate solutions were put into encollodion flasks of 50 c.c.
volume, each connected with a glass tube serving as a manometer
as described, and these flasks were put into beakers containing
350 c.c. of H2O, the pH of which was brought at the beginning of
the experiment to 3.5 through the addition of H3PO4. When the
bags containing gelatin phosphate solutions are put into water

OSMOTIC PRESSURE . 185

the latter diffuses rapidly into the gelatin solution thereby
lowering the concentration of the gelatin solution. To avoid
this error so much gelatin phosphate solution was poured into
each bag and glass tube that at the beginning of the experiment
the liquid reached already to about that level which from pre-
ceding experiments we knew the gelatin solution would reach
in the manometer at the point of osmotic equilibrium. All
experiments were made in duplicate. In addition to the osmotic
pressure we measured the pH inside and outside after equilibrium
was reached. From these latter data the osmotic pressure due
to the H and H2PO4 ions could be calculated, being equal to

(2y + z - 2x) X 2.5 mm. H2O

By deducting this value from the observed osmotic pressure in
each case it was hoped to obtain a rational value for the share
of the protein particles in the observed osmotic pressure. Table
XXXVI gives the results.

The reader's attention is called to the last two rows of figures
(Table XXXVI) giving the difference between the observed and
the calculated osmotic pressures, since if this difference actually
represents the osmotic pressure due to the gelatin particles, the
figures should be in direct proportion to the concentration of the
gelatin. The experiments were all made in duplicate to give
some idea of the magnitude of error, and it is obvious that the
error may be considerable, 25 per cent or more, because the
errors in the observed and the calculated values are additive.
Thus the " difference" is for 0.75 per cent solution in one case 92,
in the other 61, a variation of 50 per cent! If we take this into
consideration we may conclude that the differences between
the observed and the calculated osmotic pressures are compatible
with the idea that the difference is the value for the osmotic
pressure due to the gelatin particles in solution.

This would lead us to the conclusion that the osmotic pressure
due to the gelatin particles in a 1 per cent solution (of originally
isoelectric gelatin) of gelatin phosphate of pH 3.60 is about 100
mm. H2O. Since the osmotic pressure of one grammolecule is
about 250,000 mm. H2O and since 1 liter of a 1 per cent solution
of gelatin contains 10 gm. of gelatin, the molecular weight of
gelatin should be expected to be in the neighborhood of 25,000.

186

THEORY OF COLLOIDAL BEHAVIOR

E OF

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1

OSMOTIC PRESSURE

187

The experiment just described for gelatin phosphate was repeated
for gelatin chloride, with similar results.

According to DakhYs1 recent analyses gelatin contains 1.4
per cent phenylalanine. Since one molecule of gelatin cannot
contain less than one molecule of phenylalanine and since the
molecular weight of this amino-acid is 165 the lowest possible
weight of gelatin is 11,800. If a molecule of gelatin contains
two molecules of phenylalanine, the molecular weight should be
about 23,600. This would be approximately the figure we might
expect from the data of Table XXXVI on the assumption that
the differences in the last two rows may be considered to be the
values of the osmotic pressure of the protein particles.

TABLE XXXVII. — INFLUENCE OF CONCENTRATION OF ALBUMIN CHLORIDE
OF pH OF ABOUT 3.4 on THE OSMOTIC PRESSURE

Concentration of egg albumin in per cent

4

3

2

1

X

K

pH inside at equilibrium
pH outside at equilibrium

3.34
2.98

45.7
104.7
194.0

76.0

3.32
2.97

47.9
107.2
192.0

74.0

3.38
3.07

41.7
85.1
132.0

45.0

3.40
3.14

39.8
72.4
92.0

27.0

3.40
3.19

39.8
64.5
64.6

15.0

3.40
3.24

39.8
57.5
43.3

8.0

y — CH inside X 10*

* — CH outside X 10s

(x + y)(x - y)

z =

y

2y + z — 2x

Observed osmotic pressure

776.0
190.0
586.0

555.0 +
185.0
370.0 +

375.0
113.0

262.0

163.0
67.0
96.0

75.0
39.0
36.0

36.0
20.0
16.0

Calculated osmotic pressure (ignoring al-
bumin)

Difference (osmotic pressure due to albumin)

A similar experiment was made with different concentrations of
solutions of the chloride of crystalline egg albumin. The original
pH of the albumin chloride solution was 3.5 and that of the outside
solution 3.0. After equilibrium was established the pH both
inside and outside was slightly changed as is shown in Table
XXXVII. The osmotic pressures for 0.25 to 4 per cent solutions

1 DAKIN, H. D., J. Biol. Chem., vol. 44, p. 499, 1920.

188 THEORY OF COLLOIDAL BEHAVIOR

of albumin chloride were measured and calculated for 2y -\- z — 2x.
The difference, which should be the osmotic pressure of the albu-
min particles in solution, is found in the last row. It is almost
identical with the difference found for gelatin chloride for the
same concentration of gelatin.

We therefore come to the conclusion that the Donnan equilib-
rium theory allows us to explain and to derive mathematically
the influence of pH, of valency of ions, of concentration of neutral
salt, and of concentration of protein on the osmotic pressure;
and that the values calculated for the osmotic pressure on the
basis of this theory agree within the limits of the accuracy of the
experiments with those actually observed, though the accuracy
of the experiments is considerably less than in the case of the
P.D. measurements.

CHAPTER XI

SWELLING

Procter (1914) and Procter and Wilson (1916) applied
Donnan's equilibrium theory to the explanation of the swelling
of gelatin in acid. According to these authors, the force which
causes the entrance of water and hence the increase of volume in
a solid block of gelatin in acid is osmotic, and the opposing force
which limits the swelling is the force of cohesion between the
gelatin molecules or ions constituting the framework inside of
which the water is occluded. These cohesive forces thereby play
the same role in the swelling equilibrium as does the hydrostatic
pressure on the membrane in the experiments on osmotic pressure.

The protein ions constituting a jelly of gelatin chloride cannot
diffuse and hence, according to Procter and Wilson, can exercise
no measurable osmotic pressure, while the chlorine anions in
combination with them are retained in the jelly by the electro-
static attraction of the gelatin ion but exert osmotic pressure.
This difference in the diffusibility of the two opposite ions of the
gelatin chloride gives rise to the condition leading to the establish-
ment of Donnan's membrane equilibrium. It is immaterial
for this equilibrium whether the diffusion of dissolved protein
ions is prevented by a collodion membrane, or whether it is pre-
vented by the forces of cohesion between the gelatin ions of a
solid gel. If x be the concentration of the H and Cl ions in the
outside solution, y the concentration of the free H and Cl ions in
the solid gel, and z the concentration of Cl ions in combination
with gelatin, the Donnan equilibrium is expressed by the equation

x2 = y(y + z)
and the osmotic force e for the absorption of water by the gel is

e = 2y + z - 2x

The reader will notice that this is the formula applied later by
the writer to osmotic pressure.

189

190 THEORY OF COLLOIDAL BEHAVIOR

J. A. and W. H. Wilson1 developed Procter's line of reasoning
further and derived the following formula by purely mathe-
matical reasoning from the assumption that gelatin combines
chemically with hydrochloric acid to form a highly ionizable
gelatin chloride:

V(K + y)(CV + 2VCYy) - y = 0

where V is the increase in volume in cubic centimeters of one
milliequivalent weight of gelatin, C is the constant corresponding
to the modulus of elasticity of the gelatin, and K is a constant
defined by the equation

[gelatin] [H+] = ^[gelatin ion]

Given the constants, it is obviously possible to calculate all the
variables of the equilibrium.

Procter and Wilson found the value K = 0.00015 by means
of the hydrogen electrode on gelatin solutions and the value C
= 0.0003 at 18°C. from experiments on the swelling of gelatin
jellies. From Procter's data on gelatin, Wilson2 calculated 768
as its equivalent weight. Using these constants, Wilson and
Wilson calculated the variables V, y, and z for comparison with
the data obtained experimentally by Procter. The calculated
and observed results are shown in Table XXXVIII and it will
be seen that the agreement is absolute, within the limits of
Procter's experimental error. This is shown even more strik-
ingly when the values are plotted. Procter and Wilson regard
this as establishing their theory quantitatively.

The relation of V to e is governed by Hooke's law, ut tensio
sic vis, and since e represents a pressure equal in all directions,
the result is a pull upon the jelly equal in each dimension. The
quantitative expression is

e = CV

where the constant C is determined by the bulk modulus of the
gelatin.

1 WILSON, J. A., and WILSON, W. H., J. Am. Chem. Soc., vol. 40, p. 886,
1918.

2 WILSON, J. A., J. Am. Leather Chem. Assn., vol. 12, p. 108, 1917.

SWELLING
TABLE XXXVIII1

191

X

V

y

z

Calculated

Observed

Calculated

Observed

Calculated

Observed

0.0032

43.2

41.2

0.0005

0.0005

0.018

0.017

0.0073

40.8

44.5

0.002

0.002

0.022

0.018

0.0077

40.2

40.1

0.002

0.002

0.023

0.020

0.0120

37.5

39.9

0.005

0.006

0.026

0.021

0.0122

37.3

39.7

0.005

0.006

0.026

0.021

0.0170

34.5

31.1

0.008

0.009

0.028

0.028

0.0172

34.3

37.0

0.008

0.009

0.028

0.022

0.0406

26.7

28.0

0.026

0.030

0.037

0.031

0. 0420

26.4

23.4

0.027

0.030

0.038

0.038

0.0576

24.0

26.1

0.041

0.043

0.041

0.036

0. 0666

23.0

21.4

0.049

0.050

0.043

0.045

0. 0680

22.8

22.4

0.050

0.053

0.044

0.039

0. 0930

20.7

17.7

0.072

0.072

0.049

0.054

0.0944

20.5

20.3

0.073

0.072

0.049

0.049

0. 1052

19.8

22.9

0.083

0.085

0.051

0.043

0.1180

18.9

18.7

0.095

0.090

0.053

0.058

0. 1434

17.9

18.4

0.118

0.118

0.056

0.055

0. 1435

17.9

18.6

0.118

0. 118

0.056

0.054

0. 1685

17.1

18.0

0.141

0.138

0.059

0.062

0. 1925

16.3

15.8

0.164

0.161

0.061

0.068

0. 1940

16.2

17.4

0.166

0.165

0.061

0.060

0. 1945

16.2

17.0

0.167

0.164

0.061

0.062

1 Observed values are taken from PROCTER, H. R., J. Chem. Soc., vol. 105, p. 313, 1914.
The observed value for V given in this table is the increase in volume in cubic centimeters
of 0.768 gm. of gelatin. Values for x, y, and z are given in moles per liter.

Procter and Wilson then explain on the basis of theDonnan
equation why the value of e, and therefore also V, should follow
a curve of the particular type it does. By proper substitution
from the thermodynamic and osmotic equations it follows that:

e = -2x + \/4x2 + z2

"As the concentration of acid is increased from zero to some small, but
finite, value, z must necessarily increase at a very much greater rate than
x. This is shown very markedly in the most dilute solutions, where
almost all the acid added combines with the gelatin : but z has a limiting
value, which is determined by the total concentration of gelatin with
which we started. Now z must either approach this limiting value or
diminish, which it would do if the ionization of the gelatin chloride were
sufficiently repressed. In either case:
limit

192 THEORY OF COLLOIDAL BEHAVIOR

from which it follows that:

X = co

It is clear from this that, as x increases from zero, e must increase to a
maximum and then decrease, approaching zero asymptotically, regard-
less of whether or not the ionization of the gelatin salt is appreciably
repressed."1

As far as the depressing action of salt on swelling is concerned,
Procter and Wilson do not accept the idea that it is due to the
repression of ionization.

" Whilst the salt undoubtedly represses the ionisation of the gelatin
chloride to some extent, it would scarcely be sufficient to account
for the fact that salt reduces the volume of jelly almost to that of dry
gelatin. The chief action is probably that the addition of salt corre-
sponds with an increase in the value of #, and that this increase in x
must, according to the equation just discussed, produce a decrease in
the value of e, with a corresponding diminution of the volume of the
jelly."1

There can be little doubt that the osmotic theory of Procter
and Wilson accounts quantitatively for the process of swelling;
no other theory has thus far been offered which can claim the
same result.

The force which opposes and limits the swelling is the cohesion
between the molecules or ions constituting the gel. When this
force is diminished the swelling should increase. Procter and
Wilson have pointed out that this is the case since the swelling
of gelatin increases when the gel is heated.2

The forces of cohesion depend not only on temperature but
also on chemical constitution. They are forces of the same kind
as the forces determining solution; and it is well known that, e.g.,
the substitution of Na for H in oleic acid increases the solubility
of the substance in water, and that the substitution of K for Na
increases the solubility still more. We might a priori expect that
the forces of cohesion in a solid jelly of gelatin would also change
considerably with the nature of the ion in combination with

1 PROCTER, H. R., and WILSON, J. A., /. Chem. Soc., vol. 109, p. 317, 1916.

2 PROCTER, H. R., and WILSON, J. A., J. Chem. Soc., vol. 109, p. 315, 1916.

SWELLING 193

the gelatin. This is, however, as a rule, not the case. Only
the valency but not the nature of the ion in combination with
gelatin influences the swelling of gelatin. Thus, at the same
temperature, at the same pH, and the same concentration
of originally isoelectric gelatin, the swelling of gelatin chloride,
nitrate, trichloracetate, oxalate, tartrate, phosphate, citrate,
etc., is approximately the same, while that of gelatin sulphate is
considerably lower. The swelling of Li, Na, K, and NH4
gelatinate is also practically the same at the same pH and the
same concentration of originally isoelectric gelatin, but the
swelling of Mg, Ca, and Ba gelatinate is considerably less (see
Chap. V).

It was shown in Chap. V that the same valency effect which
exists in regard to osmotic pressure exists also in regard to swell-
ing, and the theoretical discussion given in the preceding
chapter for this valency effect in the case of osmotic pressure
covers also the similar effect in the case of swelling.

In the case of casein-acid salts, which are less soluble than
gelatin-acid salts, the nature of the anion is not without influence
on the cohesive forces. Thus casein trichloracetate is practically
as insoluble as casein sulphate, and neither of the two salts is
capable of swelling; while the more soluble casein chloride and
casein phosphate are capable of swelling. In the latter case the
valency rule also holds since the degree of swelling is practically
the same for casein phosphate and casein chloride, at the same
pH temperature and concentration of originally isoelectric
casein.1 The valency rule holds wherever colloidal behavior is
concerned, since colloidal behavior is only the consequence of the
Donnan equilibrium and the equilibrium equation is only con-
cerned with the sign and valency of the ion. The problems of
solubility and of cohesion have only an indirect connection with
colloidal behavior, and the fact that solubility and cohesion depend
upon the specific nature of the ion (in addition to its sign of charge
and valency) is not in conflict with the other fact that in the truly
colloidal phenomena only the sign of charge and valency of an
ion are concerned.

At the isoelectric point gelatin is practically not ionized and
there can therefore be no Donnan equilibrium. Yet when dry

1 LOEB, J., and LOEB, R, F., J, Gen. Physiol., vol. 4, p. 187, 1921-22.
13

194 THEORY OF COLLOIDAL BEHAVIOR

grains of isolectric gelatin are put into water of pH 4.7, a consid-
erable swelling occurs. The swelling must be determined by
forces different from those set up by the Donnan equilibrium.
In the first place, there are those forces of chemical attraction
between the molecules of water and certain of the groups of the
gelatin molecule which cause the solution of gelatin in water when
the forces of cohesion between the gelatin molecules forming the
gel can be overcome. The absorption of water by dry grains of
isoelectric gelatin at pH 4.7 is, therefore, primarily but in all
probability not exclusively due to the residual valency forces, and
the swelling of solid isoelectric gelatin granules is primarily a
phenomenon of solid solution.

CHAPTER XII

VISCOSITY1

1. We have seen in Chaps. V and VI that the influence of
electrolytes on the viscosity of the solutions of certain proteins,
e.g., gelatin or casein, is similar to the influence of electrolytes
on osmotic pressure, swelling, and potential differences. The
explanation given for the influence of electrolytes on the last
named properties was based on the theory of Donnan's membrane
equilibirum. This theory can only be applied where the diffusion
of one type of ions is prevented, while no such block exists for
other ions. In the experiments on osmotic pressure or P.D. of
protein solutions the collodion membrane permits the diffusion of
crystalloidal ions while preventing the diffusion of the protein
ions ; and in the case of the solid gel the protein ions are prevented
by the forces of cohesion from diffusing into the surrounding solu-
tion free from protein. But this raises the problem of how the
Donnan equilibrium can be applied to the viscosity of protein
solutions. We intend to show that the answer lies in the fact that
although protein solutions may be and probably are as a rule true
solutions, consisting of isolated protein ions and molecules dis-
tributed equally through the water, they contain under certain
conditions submicroscopic solid particles of protein. We shall see
that the viscosity of protein solutions is only influenced in the
same way by electrolytes as is the osmotic pressure, when such
solid protein particles are present in considerable numbers. If
they are absent, or if they are scarce, electrolytes will not influ-
ence the viscosity of protein solutions in the same way as electro-
lytes influence the osmotic pressure or the P.D. of protein solu-
tions. In the following discussion we shall measure the viscosity
of protein solutions by the time of outflow through a capillary
tube, as described by Ostwald, and the quotient of this time over
the time of outflow of pure water through the same viscometer at

^OEB, J., J. Gen. Physiol., vol. 3, p. 827, 1920-21; vol. 4, pp. 73, 97,
1921-22. LOEB, J., and LOEB, R. F., /. Gen. Physiol., vol. 4, p. 187, 1921-22.

195

196 THEORY OF COLLOIDAL BEHAVIOR

the same temperature will be referred to as the relative viscosity
or as the viscosity ratio of the protein solution. This method of
measuring the relative viscosity will require improvement but it
suffices for an approximate test of the validity of the theory.

Einstein1 has developed a theory of the viscosity of solutions
which makes the viscosity a linear function of the relative volume
occupied by the solute in the solution

7? = Wl + 2.5<rf (1)

where rjo is the viscosity of the water at the temperature of the
experiment, rj the viscosity of the solution, and <p the fraction of
the volume occupied by the solute in the volume of the solution.
As Einstein points out, this formula can only be used when <p is
very small and when the particles of the solute are spherical and
large in comparison with the molecules of the solvent. This
condition is no longer fulfilled in protein solutions when the
relative volume occupied by the protein in the solution becomes
too large.

Several authors have tried to modify Einstein's formula in
order to make it applicable to higher concentrations of protein
solutions. Hatschek2 proposed to replace the constant 2.5 of
Einstein's formula by the constant 4.5, but his deductions have
been criticised both by Smoluchowski3 and by Arrhenius.4
Arrhenius has shown that a logarithmic formula, which he derives
very ingeniously from Einstein's formula, fits the actual observa-
tions in a satisfactory way, this formula being

log ri - log TJO = <V (2)

where <p is again the fraction of volume occupied by the protein
in solution, $ a constant, while rj and 170 have the same significance
as in Einstein's equation. We shall make use of Arrhenius's
equation (2) when we are dealing with higher viscosities.

Both the formulae of Einstein and of Arrhenius make the
viscosity a function of the relative volume occupied by the solute

1 EINSTEIN, A., Ann. Physik, vol. 19, p. 289, 1906; vol. 34, p. 591, 1911.

2 HATSCHEK, E., Kolloid-Z., vol. 11, p. 280, 1912.

3 SMOLUCHOWSKI, M., Kolloid-Z., vol. 18, p. 190, 1916.

4 ARRHENIUS, S., Meddelanden K. Vetenskapsakademiens Nobelinstitut,
vol. 3, No. 21, 1917.

VISCOSITY 197

in the solution, and it must be our task to correlate the influence
of electrolytes on viscosity with corresponding variations of the
volume of the protein in solution.

The question then arises, How can the same mass of protein
particles in solution change its relative volume under the influ-
ence of electrolytes? This is only possible if the relative volume
occupied by the protein in the solution is increased by water
shifting from solvent to solute. We, therefore, have to find out
whether or not a shifting of water from the solvent to the solute
is possible, so that the volume of the solvent is diminished and
that of the solute increased. It is generally assumed that the
mechanism for such a transfer of water from solvent to solute is
explained by Pauli's hydration theory which has been repeatedly
referred to in this volume. Pauli suggested that the ionized
molecule of protein is surrounded by a shell of water which is
lacking in the non-ionized molecule. When protein is ionized,
i.e., by the addition of acid or alkali to isoelectric protein, a shell
of water is formed around each individual protein ion. On this
basis we can understand why the viscosity of a solution of iso-
electric protein should increase with the addition of acid or
alkali. The work of Lorenz, Born, and others, however, casts a
doubt on the assumption of a general hydration of polyatomic
ions. There are still other facts which show that the mere
ionization and consequent hydration of the individual protein ions
cannot well be the cause of the influence of the pH on the relative
viscosity of gelatin solutions.

Gelatin solutions show the characteristic influence of the pH
on their viscosity, as is demonstrated in Fig. 48. The viscosity
of gelatin solutions behaves qualitatively as we might expect on
the basis of Pauli's hydration theory. Yet, if hydration of the
individual protein ions were the cause of the variation of the
viscosity of gelatin solutions, a variation of the hydrogen ion
concentration should have a similar influence on the viscosity
of solutions of simple amino-acids, like glycocoll and alanine, to
that which it has on the viscosity of gelatin solutions. Five
per cent solutions of glycocoll and alanine were brought to differ-
ent pH, from 5.0 to 2.0 and below, by the addition of HC1.
Miss Brakeley found, in the writer's laboratory, that the variation
of the pH of 5 per cent solutions of these two amino-acids between

198

THEORY OF COLLOIDAL BEHAVIOR

the limits of 5.0 and 1.16 had no measurable influence on the
viscosity of the solution. G. Hedestrand1 found in Euler's
laboratory a slight variation in the viscosity of 2 N glycocoll
solutions upon the addition of acid or alkali; the minimum was
found at pH 6.4 where the viscosity was about 1.36, while at

"5 3.5
•B 3.0

2.5

8

2.0

1.5

1.0

gelatin

pH 1.4 1.6 15 2.0 2.2 2.4 26 28 3.0 3.2 3.4 3.6 3.8 40 4.2 4.4 4.6

FIG. 48. — Influence of pH on viscosity of freshly prepared gelatin chloride

solutions.

pH 3.0 it was 1.38. This is an influence of pH of a much lower
order of magnitude than the one found in the case of gelatin solu-
tions or casein solutions. These results cast a serious doubt on
the assumption that the variations in the curve of the viscosity
of gelatin, as expressed in Fig. 48, were caused by variations in
the hydration of the individual gelatin ions.

This doubt was increased by experiments on the influence of pH
on the viscosity of crystalline egg albumin which indicated only a
slight, almost negligible influence of the pH on the viscosity. Fig-
ure 49 gives such an experiment with 3 per cent originally iso-
electric albumin brought to different pH through the addition
of HC1. The ordinates are the viscosity ratios of albumin solu-
tion over water, drawn on a larger scale than those in Fig. 48, and
the abscissae are the pH of the solution. It is obvious that if com-
pared with the gelatin curves the pH has only a very slight

1 HEDESTRAND G., Arkiv Kemi, Min. och Geol., vol. 8, p. 1, 1921.

VISCOSITY

199

influence on the viscosity of solutions of crystalline egg albumin
between pH 4.6 and pH 1.0. With a further lowering of pH the
viscosity suddenly rises, a fact to which we shall return later.

The method of the experiments was as follows: 50-c.c. samples
of a 6 per cent solution of isoelectric crystalline egg albumin were
mixed with 50 c.c. of HC1 solutions of different concentrations
and the pH measured. The solutions were rapidly brought to a
temperature of 24°C. and the viscosity was measured immediately
at that temperature.

1.5
1.4
13
12
11
m

•

24'

C.

^,

37o

alb

urn

in <

:Mc

rifl

£.

V

» —

-

— —

,*—

•—

— •-

— »

— •-

——4

•

-^-

— •

— •-

— •

pH 0.8 1.0 .12 1.4 16 l& 2.0 23. 24 26 28 3.0 3.2 3.4 36 3.8 4.0 42 44

FIG. 49. — Showing that solutions of crystalline egg albumin have a low vis-
cosity in comparison with gelatin solutions, and that the pH has little influence
on the viscosity of solutions of crystalline egg albumin at pH over 1.0 and at
ordinary temperature.

The question then arises, Why do amino-acids and at least one
protein, namely crystalline egg albumin, behave so differently
from gelatin in regard to the influence of the pH on the viscosity
of their solutions? As long as we assume that the influence of
the hydrogen ion concentration on the viscosity of gelatin-acid
salt solution is due to the hydration of the individual protein
ions this difference is incomprehensible, since the amino-acids
as well as crystalline egg albumin should in this case show the
same influence of ionization on viscosity as the gelatin.

The puzzle becomes still greater if we take into consideration
the fact that the osmotic pressure of solutions of crystalline egg
albumin is affected in the same way by the hydrogen ion con-
centration as is the osmotic pressure of gelatin solutions (Chap.
V). Why then do these two proteins behave so differently as
regards the influence of the pH on their viscosity?

We get an answer to this question by comparing the order of
magnitude of the viscosity of solutions of crystalline egg albumin
and of gelatin. The viscosity of solutions of crystalline egg

200

THEORY OF COLLOIDAL BEHAVIOR

albumin has a comparatively low order of magnitude if
compared with the viscosity of solutions of gelatin of the same
concentration of protein and the same pH. The viscosity of
solutions of crystalline egg albumin of pH 5.1, (i.e., near the
isoelectric point) of concentrations from 1 to 14 per cent, was
measured at 15°C. (Fig. 50). The viscosity is not only low but is
also practically a linear function of the concentration. Figure 51
gives the viscosity of different concentrations of solutions of

1.0

0.5

Vis

cos

py

of.

SOki

tior

IS C

>f

«&

al

bur

am

P]

1=5

lat

15'

C.

r —

^~*

>- — •

__-<

,

1- — ^

—^

0 1 2 3 4 5 6 7 8 9 10 11 12 13 14

Concentration of albumin in per cent

FIG. 50. — Viscosity ratio of solutions of crystalline egg albumin near the
isoelectric point. Inside the concentrations used, the viscosity ratio is nearly a
linear function of the concentration.

isoelectric gelatin at different temperatures. The solutions
were prepared from the same stock solution of isoelectric gelatin
and were rapidly heated to 45°C. and rapidly cooled to the desired
temperature and then the time of outflow in an Ostwald visco-
meter was measured. This was done to avoid the increase in
viscosity which occurs on standing and which is especially notice-
able in the case of solutions of isoelectric gelatin. For the sake of
conformity the same procedure was followed in the case of solu-
tions of crystalline egg albumin. It is obvious that where the pH
influences the viscosity in the same sense as the osmotic pressure,
e.g., in the case of gelatin solutions, the viscosity is of a much
higher order of magnitude than where the pH has no such influ-
ence on viscosity as is the case in solutions of crystalline egg
albumin.

It now remains to show that this difference in the order of
magnitude of the viscosity of the two solutions is connected with
the relative volume occupied by the protein in solution. The
low order of magnitude of the viscosity of solutions of crystalline

VISCOSITY

201

egg albumin suggests a small relative volume; and if this be true
the viscosity of solutions of crystalline egg albumin should obey
the Einstein formula; while the high order of magnitude of
viscosity of the solutions of gelatin suggests that a larger volume is

0 0.25 0.5 1.0 15 20 £5 3.0

Concentration of gelatin in per cent

4.0

FIG. 51. — Influence of concentration on the viscosity of solutions of isoelectric

gelatin.

occupied by the gelatin particles in solution and hence the con-
stant 2.5 of Einstein's formula should be found too small; in other
words, the Einstein formula should be replaced by some other
formula, e.g., that of Arrhenius.

Einstein's formula is — = 1 + 2.5<p, where <p is the relative

*?o

volume occupied by the protein in the solution, and - is the

202

THEORY OF COLLOIDAL BEHAVIOR

viscosity ratio, i.e., time of outflow of solution over time of
outflow of water. The volume occupied by the protein in 100
c.c. of solution is

(•n A 100

<p=(^~

2.5

By dividing the weight of albumin in solution by its volume we
should obtain the density of albumin. Determinations of the
density of albumin, by direct methods, give the value of 1.36
(Arrhenius). Table XXXIX shows that if we calculate the

TABLE XXXIX

Concentration
of crystalline
egg albumin,
per cent

?.-'

Calculated
volume of
albumin, cubic
centimeters

Calculated
density of
albumin

14

0.290

11.6

1.20

12

0.240

9.6

1.25

10

0.185

7.4

.35

8

0.132

5.3

.51

6

0.100

4.0

.50

4

0.074

2.96

.36

2

0.042

1.7

.17

density of albumin on the basis of Einstein's formula, we obtain
values which differ only inside the limits of accuracy from the
value 1.36 obtained by direct determination. The time of
outflow of water through the viscometer was in this case 227
seconds at 15°C. These measurements show that the low order
of magnitude of the viscosity of solutions of crystalline egg
albumin is accompanied by a volume of albumin sufficiently low
to permit the application of Einstein's formula, with the constant
2.5.

When we try to apply Einstein's formula in the same way to
the viscosity measurements of isoelectric gelatin solutions we find
that the relative volume of gelatin in the solution and its density
calculated on the basis of the constant 2.5 lead to impossible
results. Thus the density of gelatin is probably not very differ-

VISCOSITY

203

ent from that of egg albumin, i.e., in the neighborhood of 1.4.
The values calculated in Table XL with Einstein's viscosity con-
stant 2.5 are from 20 to 40 times too low. Hence, the relative

TABLE XL

Concentration

Calculated

Calculated

of isoelectric

- 1

volume of

density of

gelatin,

*?o

gelatin, cubic

gelatin

per cent

at 35°

centimeters

0.5

0.170

6.8

0.077

1.0

0.405

16.2

0.06

1.5

0.725

29.0

0.05

2.0

1.020

40.8

0.05

2.5

1.405

56.2

0.045

3.0

2.042

81.7

0.037

3.5

2.560

102.4

0.034

volume of gelatin in these solutions is far beyond the limit inside
which the formula of Einstein is applicable. The formula of
Arrhenius (2) leads to a fair agreement. According to this
formula the logarithms of the viscosity ratio when plotted
over the concentration of the gelatin should give a straight line.
The agreement of the values for 45 and 35° with this theory is
satisfactory (considering the limits of accuracy of the measure-
ments) the logarithms of the viscosity increasing practically in
direct proportion with the concentration (i.e., the relative
volume) of the gelatin in the solution (Table XLI). At 60°
the agreement is not quite so good but still recognizable. At
25°C., however, it is satisfactory only at the lowest concentra-
tions, but at the higher concentrations the viscosity grows more
rapidly than the concentration. The reason for this is, however,
obvious, since at this temperature the gelatin solution solidifies
so rapidly that the viscosity measurements were no longer
possible for a concentration of 3.5 per cent gelatin solution, and
for this reason the value of the viscosity of a 3 or a 2 per cent
solution is already too high on account of the mechanical hin-
drance of the flow of the solution through the viscometer owing to
partial solidification.

204

THEORY OF COLLOIDAL BEHAVIOR
TABLE XLI

Concentration of

i-_ "n

log —

solution of iso-

•no

electric gelatin,

per cent

60°

45°

35°

25°

0.25

0.0236

0.0306

0.0269

0.0374

0.5

0.0504

0.0682

0.0682

0.0792

1.0

0.0930

0.1350

0.1475

0.1685

1.5

0.1656

0.2135

0.2367

0.2765

2.0

0.2350

0.2796

0.3057

0.3701

2.5

0.2953

0.3512

0.3811

0.4691

3.0

0.3094

0.4409

0.4832

0.6941

3.5

0.4321

0.5051

0.5514 solidifies

4.0

0.5214

0.5660

0.6043

These experiments lead to the following two conclusions.

(a) Since the viscosity measurements of solutions of crystalline
egg albumin and of gelatin agree fairly well with Einstein's and
Arrhenius's formula respectively, it seems that the viscosity of
the solutions of proteins is primarily a function of the relative
volume occupied by the protein in solution.

(6) Since the measurements were made at (or near) the iso-
electric point of the two proteins the difference in the viscosity
of solutions of gelatin and of crystalline egg albumin cannot be
ascribed to differences in the degree of hydration of the individual
protein ions, since at the isoelectric point the protein is not
ionized.

It follows from these results, that the difference in the order
of magnitude of the viscosity of the two proteins must be due to
the fact that gelatin possesses a mechanism for increasing its
relative volume in solution which is lacking in the case of egg
albumin (in not too high a concentration, at not too high a tem-
perature a*nd a pH above 1.0), and this mechanism seems to be
connected, in the case of gelatin solutions, with their tendency
to set to a gel.

Zsigmondy (p. 98) states that Smoluchowski has explained
the increase in the viscosity of a solution of aluminium oxide
upon coagulation by the assumption of an occlusion of liquid
between the particles. Smoluchowski calculates from the

VISCOSITY 205

increase of viscosity during coagulation of aluminium oxide that
the coagulating particles occupy a volume 400 to 500 times as
great as that occupied by the dry material itself.1 This apparent
increase of volume he explains through the aggregation of needle-
shaped particles, water being occluded between these particles.
Smoluchowski apparently did not associate this occlusion of
water with the Donnan equilibrium.

If we adopt this idea for the explanation of the high order of
viscosity of gelatin solutions as compared with solutions of egg
albumin we reach, the conclusion that the gelatin solutions contain
submicroscopic particles of solid jelly , i.e., micellae which occlude
relatively large quantities of water, whereby the relative volume
occupied by the gelatin in solution is increased, and that such par-
ticles are lacking or scarce in the case of solutions of egg albumin.
These particles of solid jelly are the precursors of the continuous
jelly to which the gelatin solution has a tendency to set. The fact
that these particles are lacking or scarce in the case of solutions of
egg albumin is connected with the fact that the latter solutions
have no tendency to set to a jelly at ordinary temperature and a
pH above 1.0. When the pH is below 1.0 and the temperature
higher the solutions of crystalline egg albumin set to a jelly and
in that case their viscosity becomes of the same high order of
magnitude as that of gelatin solutions.

This assumption would also explain why the pH causes a
similar variation in the viscosity of gelatin solutions as in their
osmotic pressure, while the viscosity of solutions of crystalline
egg albumin shows no such influence of the pH. There must
arise a Donnan equilibrium between these submicroscopic
particles of solid jelly and the surrounding solution, and this
Donnan equilibrium must regulate the amount of water occluded
by the submicroscopic particles of solid jelly, floating in the
gelatin solution. Since the low order of magnitude of the vis-
cosity of albumin solutions excludes the existence of a consider-
able number of such submicroscopic solid particles in the solution,
it becomes obvious that the Donnan equilibrium cannot manifest
itself to any large extent in the viscosity of solutions of this

1 Quoted from ZSIGMONDY. The paper of SMOLUCHOWSKI is inaccessible
to the writer since the number of the journal in which it appeared failed
to reach the Institute during and since the war.

206 THEORY OF COLLOIDAL BEHAVIOR

protein at not too high a concentration, at low temperatures, and
at pH above 1.0.

2. If this assumption is correct, it would follow that a suspen-
sion of powdered gelatin in water should have a greater viscosity
at a given temperature than if the same mass of gelatin is dis-
solved in water, since in the latter case part of the gelatin at
least is in true solution (as we shall see later) and this latter is
incapable of increasing its volume by occluding water. It would
follow, furthermore, that the influence of electrolytes on the
viscosity of suspensions of powdered gelatin would be the same
as the influence of electrolytes on the osmotic pressure of gelatin
solutions. It can be shown that both expectations are fulfilled.

Doses of 0.5 gm. of powdered gelatin were put into 100 c.c. of
water containing 0, 1, 2, 3, 4, 5, 6, 7, 8, 10, 12.5, 15 and 20 c.c. of
0.1 N HC1 to bring the gelatin to different pH. The suspensions
were allowed to stand 1 hour at 20° to bring about the swelling
of the particles, and the viscosity of the suspensions was measured
in a straight viscometer at 20°C. The time of outflow of water
through the viscometer at 20° was 48.5 seconds. The upper
curve in Fig. 52 gives the ratio of viscosity of suspensions to
that of water at 20°C. (When the viscosity is high, the values
obtained are a little too great owing to a gravity effect which
causes the solid particles to collect above the upper opening of
the capillary tube during a part of the time of the experiment
thus increasing temporarily the density of the suspension.)
After the viscosity of a suspension was measured the suspension
was transformed into a solution by heating the suspension to 45°C.
for 10 minutes; after that the solution was rapidly cooled to 20°C.
and the viscosity of the gelatin solution was immediately meas-
ured with the same viscometer at 20°C. The lower curve in
Fig. 52 shows that the viscosity was now considerably diminished.
The abscissae are the pH of the gelatin solutions.

If we measure the volume of the suspended particles we find
that it varies in a similar way as the viscosity. Samples of 0.5
gm. of Cooper's powdered commercial gelatin of a pH of about 6.0
were added to 100-c.c. portions of water containing varying
amounts of HC1. The particles had uniform size (going through
sieve 100 but not through sieve 120), but their shape was ex-
tremely irregular. They were left in the solution several hours

VISCOSITY

207

at 20°C., and then their time of outflow through a capillary
tube was ascertained at 20°C. The time of outflow of water
through the viscometer at this temperature was 24 seconds. It
was essential to stir the suspension thoroughly before sucking it
into the viscometer since the gelatin particles sink rapidly to the
bottom of the dish.

4.0

3.5

3.0
fi

J> 2.0

1.5
1.0

lulion

Vis

OS

itv

\

at 2

o°c.

pH 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 40 42

FIG. 52. — Difference in the viscosity of a suspension of 0.5 gm. of powdered
gelatin in 100 c.c. and of the solution of the suspension in the same liquid; both
viscosities were measured at 20°C.

After the viscosity measurements were taken, the suspension
was put on a filter of cotton wool and the supernatant water
allowed to drain off. By measuring the volume of the filtrate
and deducting this from the original volume of the suspension
(which was in all cases 100 c.c.), the volume of the gelatin was ob-
tained (with a considerable error). Then the gelatin was melted
and the pH of the melted mass of gelatin as well as of the filtrate
was determined potentiometrically. Figure 53 gives the result
of such an experiment. The lower curve shows the influence of

208

THEORY OF COLLOIDAL BEHAVIOR

the pH (of the gelatin) on the viscosity, and the upper curve the
influence of the pH on the volume of the gelatin. The two curves
are similar.

The valency of the anion of the acid influences the viscosity of
suspensions of protein in a similar way as it does the viscosity
of solutions. This proof is furnished in Fig. 54. Doses of 0.5
gm. of finely powdered gelatin (going through a sieve of mesh

3.0

2.5

2.0

1.5

1.0

O.I

&

LpC

we

er<=

d

^

^S

tele

tin

in

X

«>s

/

\

iLLS

pei:

£101

I

<$

^

^o

o

\

/>

^

^

» —

>>v

\

0

s

'.

•(

•^

V

V

\.

/

/]

%

\

•

\

t
\

*

•$

X

s

X

^

L

25

20

"I

.*

pH 1.8 2JO 22 2.4 26 Z8 ao a2 3.4 a6 a8 40 42 4.4

FIG. 53. — Showing that the influence of pH on viscosity of 0.5 per cent sus-
pensions of powdered gelatin in water is similar to the influence of pH on vis-
cosity of gelatin solutions, and that the volume occupied by the particles in the
suspension varies in a similar way as the viscosity. Temperature 20°C.

size 100 but not through sieve of mesh size 120) of pH 7.0 were put
into a series of beakers containing each 100 c.c. of HC1 of different
pH and kept in the solution over night at a temperature of 20°C.
Simultaneously a similar series of beakers containing each 100 c.c.
of H3PO4 and H2SO4 of different pH (instead of HO) were pre-
pared, each receiving also 0.5 gm. of powdered gelatin. After
19 hours the viscosities of all these series of suspensions were
determined at 20°C. Figure 54 gives the result, the ordinates
being the values for the viscosity ratios, gelatin suspension:
water, and the abscissae are the pH of the gelatin particles
at equilibrium. The curves show that the viscosity of suspen-
sions of gelatin sulphate is a little less than half that of suspensions
of gelatin chloride and phosphate of the same pH. The curves
for the suspensions of gelatin chloride and gelatin phosphate are
alike, with the exception of part of the descending branch.

VISCOSITY

209

Experiments on the influence of these three acids on swelling
(Fig. 19, Chap. V) show that the curves for the relative volume of
powdered gelatin in solutions of these three acids are similar to the
viscosity curves in Fig. 54 since the relative volume of gelatin
sulphate was found to be not far from one-half of that of gelatin
chloride or gelatin phosphate of the same pH.

4.5

4.0

3.5

2.5

2.0

1.5

1.0

*.u

7

Viscosity of suspen-
sions of 05 gm. of
powdered gelatin in
100 cc. of acid solution

\

pH 16 16 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2 44 46

FIG. 54. — Viscosity of suspensions of 0.5 gm. of powdered gelatin of grain
size 100 to 120. Abscissae are the pH, the ordinates the ratio of time of outflow
of suspension to time of outflow of water. The influence of HC1 and HsPC^ is
practically identical for the same pH while H2SO4 depresses the viscosity of the
suspensions to a little less than one-half of that for HC1.

We have seen that the viscosity of a gelatin chloride solution,
e.g., of pH 3.0, is lowered when neutral salts are added and the pH
kept constant (Fig. 29, Chap. VI). The same is true for the
viscosity of suspensions of powdered gelatin. Doses of 0.5
gm. of powdered gelatin of pH 6.0, going through sieve 100 but
not through sieve 120, were put each into 100 c.c. of water con-
taining 6 c.c. of 0.1 N HC1, and different quantities of NaNO3, so
that the concentration of the salt varied in the different solutions
from M/8 to M/2,048. One solution contained no salt. The

14

210

THEORY OF COLLOIDAL BEHAVIOR

pH of the gelatin varied in the neighborhood of 3.0; the. tempera-
ture was 20°C. After 2J£ hours, when the Donnan equilibrium
between the particles and the surrounding solution was supposed
to be established, the viscosity of each suspension was measured
at 20°C. and the volume occupied by the suspended particles of
gelatin was ascertained in the manner described. It was found

3.5
o 3.0

!

£»M
1

!fl 2.0
1.5
1 n

O.J

> gn

i.p<

wd

er€

d

25
20
15
10
5
n

i

^__ <

g<

slat

In (

:hK

)ric

Le

^

^s<

1

n i

(IS

pei

li>iU

Ll •

X

^

-

i
\

(

S

i

\

i

\

<

—

•«^^>.

&

>

1

C

^

s

s,

S

s

r^

S
Id

0 2048 1024 512 256 128 64 32 16

Concentration ofNaN03

FIG. 55. — Showing depressing influence of neutral salts on viscosity of sus-
pensions of powdered gelatin in water and on the volume occupied by the gelatin
particles in the suspension.

that the addition of salt diminished the relative volume of the
gelatin particles and the viscosity (Fig. 55) . Where the volume
of the gelatin was great it no longer varied parallel with the
viscosity, as was to be expected from the fact that Einstein's
formula no longer holds in this case.

The measurements of the pH of the gelatin solution and the
outside solution showed that the addition of salt diminished the
difference between the two, as Donnan's theory demands (Table
XLII).

VISCOSITY
TABLE XLII

211

Concentration of NaNOs

0

oo
o

<N~

s

T-H

s

<N

»0

s

s

<N

5"

00
<N

S,

1

<N

^

CO
rH

S

pH of gelatin particles
pH of supernatant liquid ....

3.04
2.74

3.04
2.76

3.03
2.76

3.02
2.76

3.00

2.77

3.02
2.80

2.97

2.78

2.94

2.77

2.85
2.70

Difference, pH inside minus
r)H outside

0.30

0.28

0.27

0.26

0.23

0.22

0.19

0.17

0.15

This demonstration completes the proof that the viscosity of
suspensions of powdered gelatin in water of different pH is
influenced in the same way by electrolytes as is the viscosity of
solutions of the same gelatin salts, and that this influence is due,
in the case of suspensions, to the influence of the Donnan equilib-
rium upon the swelling of the particles.

The volume V of gelatin occupied in 100 c.c. of the suspension
was determined by filtering and deducting the volume of the
filtrate from the total volume of the suspension. Knowing
the viscosity we can calculate Einstein's constant c according to
the formula

.. - c

l V

c should be 2.5 if V is sufficiently small.

TABLE XLIII

V,
cubic centimeters

.2.

1/0

c

12.0

1.292

2.5

17.0

1.480

2.8

18.0

1.792

4.4

20.5

2.064

5.1

20.5

2.020

4.9

20.0

1.855

4.2

18.0

1.625

3.5

16.5

1.542

3.3

212 THEORY OF COLLOIDAL BEHAVIOR

The values in Table XLIII show that Einstein's formula gives
the correct values for viscosity when the volume of the gelatin
is small, since in that case c is equal or nearly equal to 2.5, as his
formula demands.

When, however, the volume is larger, the value for c exceeds
2.5. The fact that the value for c exceeds 2.5 when the relative
volume occupied by the particles in the solution is large, was
found also by Hatschek, Smoluchowski, and Arrhenius. Hat-
schek replaced the value 2.5 in Einstein's formula by a larger one,
namely 4.5. This, however, meets in our case with the difficulty
that the value c shows a drift reaching a maximum when the
volume of the gelatin particles is a maximum. This difficulty
is largely avoided in Arrhenius's formula and we have to change
from Einstein's formula to that of Arrhenius whenever the
relative volume of the particles in solution or suspension exceeds
the limits of the applicability of Einstein's formula, as we shall
see in the next chapter.

The experiments on the viscosity of suspensions of powdered
gelatin in water have, therefore, led to the result, first, that the
influence of pH, of the valency of ions, and of the concentration
of neutral salts on the viscosity of suspensions of finely powdered
gelatin in water is similar to the influence of these three agencies
on the viscosity of gelatin solutions; second, that the influence of
electrolytes on the viscosity of the suspensions is due to the
variation of the swelling (or relative volume) of the suspended
particles; and third, that this latter fact explains why the Donnan
equilibrium determines also the variation of viscosity of these
suspensions. If it could be shown that a solution of gelatin
contains also some (submicroscopic) particles of solid jelly
(capable of swelling), we should understand at once why electro-
lytes influence the viscosity of gelatin solutions as they influence
the swelling, osmotic pressure, or the P.D. of these solutions.

3. We have only indirect means of testing the occlusion theory
for gelatin solutions but these tests give an unequivocal answer.
When a 0.5 per cent solution of isoelectric gelatin is heated rapidly
to 45°, cooled rapidly to a lower temperature, e.g., 20°C., and
kept at this temperature, the solution will ultimately set to a
continuous gel but will steadily increase its viscosity before this
stage is reached. It is natural to assume that the formation

VISCOSITY

213

of a continuous jelly is preceded by the formation of submicro-
scopic pieces of jelly, which increase in number and size, forming
finally a continuous jelly. Hence, the longer a solution of
isoelectric gelatin stands at 20°C. the greater the number of
submicroscopic solid pieces of jelly formed in the solution. The
submicroscopic pieces of jelly, surrounded by a true solution of

pHl.6 18 2.0 22 24 2.6 25 3.0 3.2 3.4 3.6 3.8 40 42 44

FIG. 56. — Increase in viscosity when acid is added to solutions of isoelectric gela-
tin after they had been standing for 3 and 17 hours respectively.

isolated molecules of gelatin in water, are compelled to regulate
the amount of water they occlude by the Donnan equilibrium.
Hence, when we add some HC1 to a 0.5 per cent solution of iso-
electric gelatin after the solution has been standing for some
hours at 20° we should expect to find a higher viscosity than when
we add the same amount of acid to the gelatin solution immedi-
ately after it has been rapidly heated to 45° and rapidly cooled
to 20°C.

This experiment turns out as expected, as is shown in Fig. 56.

214 THEORY OF COLLOIDAL BEHAVIOR

When a 0.5 per cent solution of isoelectric gelatin is rapidly
heated to 45°C., cooled rapidly to 20°C., and brought immediately
to a different pH by the addition of HC1, at 20°C. a viscosity
curve like the lowest in Fig. 56 is obtained. When, however,
the 0.5 per cent isoelectric gelatin solution is allowed to stand for
3 hours at 20°C. before the acid is added, a parallel viscosity curve
is formed at 20°C. but higher than the first one (middle curve,
Fig. 56), for the reason that during the 3 hours an additional
number of solid jelly particles capable of swelling has beenformed.
If the solution of isoelectric gelatin stands for 17 hours at 20°C.,
before the HC1 is added, the curve is still higher though practically
parallel with the first curve (upper curve, Fig. 56), except at the
summit. It is probable that on standing not only the number
but the size of individual particles also increases, and the writer
has observed that for the size of granules used in his experiments
the greater the size the greater the viscosity, since the viscosity
is chiefly but not exclusively a function of the relative volume of
the particles.

Since jelly formation of gelatin is a reversible process we should
expect that two opposite processes always take place simultane-
ously in a gelatin solution on standing, namely, first, the forma-
tion of solid particles of jelly through the aggregation of previously
isolated gelatin molecules and ions, and second, the dissolution
of such aggregates (micellae) back into isolated molecules and
ions. It is easy to show that powdered gelatin of a given pH
dissolves the more rapidly the higher the temperature. If,
therefore, our assumption is correct that in a solution of gelatin
two opposite processes go on constantly, the rate of melting of
the micellae should increase if the temperature rises. Hence,
at very low temperature the viscosity of a gelatin solution should
increase rapidly on standing since the formation of new micellae
takes place constantly, while practically no melting of micellae
occurs. When, however, the temperature is raised beyond a
certain point, the rate of melting of micellae increases more
rapidly than the rate of formation of new micellae. Hence, at
such a temperature the viscosity of a gelatin solution should not
increase but decrease on standing.

This conclusion was tested experimentally and found to be
correct. A 2 per cent solution of gelatin chloride of pH 2.7 was

VISCOSITY

215

rapidly heated to a temperature of 45° and then rapidly brought
to the temperature at which the change of viscosity of the solution
with time was to be observed. At definite intervals the viscosity
of the solution was measured. Figure 57 gives the result. At

11.0
10.0
9.0
8.0

to

'53 6.0

I

*> 5.0

4.0

ao

2.0

OS

tv

chloride

of

oluLiorso

5 10 15 20 25 30 35 40 45 50 55 60

Time in minutes

FIG. 57. — Influence of temperature on the variation of viscosity of gelatin
solutions on standing. Below 35°C. the viscosity of a 2 per cent gelatin chloride
solution of pH 2.7 no longer increases but diminishes on standing.

15° the viscosity increased rapidly on standing; at 25° it increased
on standing but less rapidly; at 35° or above it diminished on
standing, the more rapidly the higher the temperature. The

216

THEORY OF COLLOIDAL BEHAVIOR

temperature at which the two opposite processes — the formation
and the melting of micellae — occur equally rapidly in a 2 per cent
solution of gelatin chloride of pH 2.7 lies between 25 and 35°C.

2.0

5 10 15 20 25 30 35 40 45 50 55 60

Time in minutes

FIG. 58. — Increase of viscosity of gelatin sulphate solution of different pH on
standing. The increase is most rapid at the isoclectric point, thus proving that
the acid retards or prevents the formation of submicroscopic solid particles of
jelly on standing.

When acid is added to powdered isoelectric gelatin the time
required to dissolve the particles diminishes at a given tempera-
ture with increasing hydrogen ion concentration of the solution and
this tendency of the particles to dissolve with increasing hydrogen

VISCOSITY

217

ion concentration shows no maximum as does the swelling. Hence
we should expect that the more acid is added to a 0.5 per cent

CQ

o
o

CO

3.3
3.2
3.1
3.0
2.9
2.8
27
2.6
2.5
2.4
2.3
2.2
2.1
2.0
1.9
1.8
1.7
1.6
1.5
1.4

FIG. 59.-
an increase
at 20°C.

1 I I L

J L

Influence ^

the rise in viscosity of
1% gelatin chloride
solution of pH 3.4 on
standing at 20 ° C.

0 5 10 15 20 25 30 35 40 45 50 55 60

Time in minutes

-Showing that concentrations of Na2SO4 of M/32 and above cause
in the viscosity of gelatin chloride solution of pH 3.4 on standing

solution of isoelectric gelatin the less the viscosity will increase
on standing at a given temperature, e.g., 20°C., since the more
acid is added to isoelectric gelatin the greater the tendency of

218 THEORY OF COLLOIDAL BEHAVIOR

the solid jelly particles already existing to dissolve; while the
tendency of the isolated gelatin molecules or ions to adhere to
each other is not increased. It should follow that on standing the
viscosity of a 0.5 per cent solution of gelatin chloride or gelatin
sulphate will increase the less at 20° the lower the pH of the solu-
tion. Figure 58 shows that this is the case.

In Chap. XIV we shall see that the rate of solution of
powdered gelatin in water is influenced in a different way by
different salts. Na2SO4 diminishes the rate of solution of
powdered gelatin chloride when the concentration of Na2SO4
exceeds M/64; and the diminution is the greater the higher the
concentration; while CaCl-2 accelerates the rate of solution of
powdered gelatin chloride when the concentration of CaC^
exceeds M/4.

Gelatin chloride solutions of pH 3.4, containing 1 gm. of
originally isoelectric gelatin in 100 c.c. solution, were made up in
various concentrations of Na2SO4 and CaCl2. The solutions
were rapidly heated to 45° and rapidly cooled to 20°C. and kept
at this temperature for 1 hour. The time of outflow of the
solution through a viscometer was measured immediately and
in intervals of 5 or 10 minutes. The time of outflow of water
through the viscometer at 20° was 61 seconds.

The viscosity of a gelatin chloride solution of pH 3.4 rises
gradually but very slowly (uppermost curve in Fig. 59) and the
rate of increase of viscosity on standing is not materially altered
in M/512 Na2SO4 and only little in M/128 Na2SO4. In M/32
Na2SO4 the viscosity increases more rapidly on standing, in
M/8 Na2SO4 still more rapidly, and in M/2 Na2SO4 very sharply.
This is exactly what we should expect, since the Na2SO4 causes a
diminution of the rate of solution of gelatin chloride as soon as
the concentration of Na2SO4 is above M/64. In such solutions
the rate of solution of micellae will be less and less, and since
new micellae are constantly formed at 20°C. the viscosity will
rise more rapidly on standing when the solution contains Na2SO4
in concentrations above M/64 than when the solution contains
less Na2SO4 or none at all.

Figure 60 shows that CaCl2 in concentrations up to M/8 does
not alter the increase in viscosity of gelatin chloride solution on
standing, but that the viscosity of gelatin chloride of pH 3.4 no

VISCOSITY

219

longer increases on standing when the concentration of CaCU is
M/2 or 1 M. In this concentration CaCl2 causes a slight increase
in the rate of solution of gelatin chloride.

NaCl causes no change in the rate of solution of gelatin chloride
as long as the concentration of NaCl does not exceed 1 M.
Above this concentration it causes coagulation and the viscosity

Influence of CaCl2 on
the rise in viscosity of
1% gelatin chloride
solution of pH 3.4 on
standing at 20 °C.

2.7

2.6

2.5

2.4

2.3

S 2.2
^ 2.1
8 2.0

.2 L9

^ 1.8
1.7
1.6
1.5

1.4

5 10 15 20 25 30 35 40 45 50 55 60

Time in minutes

FIG. 60. — Showing that concentrations of CaCh or M/2 or above prevent
the increase in viscosity of gelatin chloride solution of pH 3.4 on standing
at 20°C.

can no longer be measured. Hence NaCl in concentrations up
to 1 M should not alter the rate of increase of viscosity of gelatin
chloride solutions on standing. Figure 61 shows that this is
correct.

The simplest method of melting solid particles of jelly is by
heating to 45°C. If, therefore, the striking increase in viscosity
which occurs when a 0.5 per cent solution of isoelectric gelatin is

220

THEORY OF COLLOIDAL BEHAVIOR

kept standing for a day at a temperature of, e.g., 10°C., is due to
the formation of particles of solid jelly, then if this solution is
heated to 45°C. and cooled rapidly to 20°C. the majority of these
solid particles should have melted and dissolved into isolated

I

2.7
2.6
2.5
2.4
2.3

zz

o 1>9

> I1?

.1.6

1.5
1.4
1.3
1.2
1.1

i i r

i i i

Influence of NaCl on
the rise in viscosity of
17o gelatin chloride
solution of pH 3.4 on
standing at 20° C

0 5

10 15 20 25 30 35 40 45 50 55 60

Time in minutes

FIG. 61. — Showing that NaCl solutions up to a concentration of 1M have no
effect on the increase in viscosity of gelatin chloride solution of pH 3.4 on stand-
ing at 20°C.

ions or molecules. Hence such a solution when cooled rapidly
to 20° should show at this temperature a considerably lower
viscosity than the same solution shows at 20° when it is brought
to this temperature directly from 10°C. without previous heating
to 45°C. The experiment represented in Fig. 62 shows that this is
the case.

VISCOSITY

221

These experiments then support the conclusion that the high
viscosity of gelatin solutions and the influence of electrolytes on
this viscosity is due to the fact that these solutions contain sub-
microscopic particles of solid jelly (micellae) capable of occluding
large amounts of water the quantity of which is regulated by the
Donnan equilibrium.

4. The pH influences the viscosity of casein chloride solutions
in a similar way to that in which it influences gelatin chloride

3.5
o 3.0

^ 2'5
8
| 2'°

1.5
1.0

.

sCe'

JKX

l£h

?r|/

r^^

^P

^

^^^%

Vx

?

/

/

^

^

Vi

sec

sit-

/" C

f

\

^

0*

>7o^

HO'

elal
citic

in c
>n 8

hlo

rid

T,

s

\

i

/

'

\

«r

\

-£

t?e\

iou

?iy

ke

^>M

f

n1

»

i

0^

<ru

— u~

u^t

•o —

Lfl

r u

0

• ••

!__ -^

>-^*"

pH 1.8 2.0 22 2.4 2.6 2.8 3.0 32 34 3.6 3.8 4.0 42 4.4 4.6

FIG. 62. — Showing that previous heating diminishes the viscosity of 0.5 per cent
solutions of gelatin chloride.

solutions; and the depressing effect of neutral salts on the vis-
cosity of casein chloride solutions is similar to that of the addition
of salts on the osmotic pressure of gelatin chloride. Casein
chloride solutions have no tendency to set to a jelly, but they
have one feature in common with gelatin solutions, namely, the
existence of particles capable of occluding water, the amount of
which is regulated by the Donnan equilibrium. As a conse-
quence, casein chloride solutions have a comparatively high
viscosity which is influenced by electrolytes in the way charac-
teristic for the Donnan equilibrium. The existence of such

222

THEORY OF COLLOIDAL BEHAVIOR

particles in the casein chloride solution is indicated by the
opacity of the solution.

The material used in our experiments was a fine dry powder of
nearly isoelectric casein prepared after Van Slyke and Baker.
Particles of equal size of grain (between mesh 100 and 120) were
sifted out and 1 gm. of such powder was put into 100 c.c. each
of solutions of HC1 of different concentration to bring the casein
to varying pH. A microscopic examination of the granules

22

8 E0

S 18

.»->

g 16

.9 14

1

I

10
8
6
4

Volune ofscdimen

incc.

pH 1.4 1.6 1.6 20 2.2 2.4 2.6 28 3.0 32 3.4 3.6 3.8 4.0 4.2

FIG. 63. — Swelling and solution of casein chloride in 1 and 22 hours at 20°C.

showed that they underwent a swelling which was a minimum
at the isoelectric point, which increased with increasing hydrogen
ion concentration until it reached a maximum, and which then
diminished again with a further increase in the hydrogen ion
concentration (see Chap. XV). Hence, the volume of the
casein particles suspended in the HC1 varied in a similar way
with the pH as the volume of suspended particles of gelatin.

This swelling could also be observed when the suspension was
put into 100 c.c. graduates and the suspended particles were
allowed to settle. . The volume of the sediment was a minimum
at the isoelectric point increasing with increasing hydrogen ion

VISCOSITY

223

concentration of the solution and finally decreasing again. But
the curves of swelling and of volume of sediment were only
parallel at the beginning of the experiment, since the swelling
(which occurred at once) was followed by some of the casein
going into solution or into suspension. The longer the experi-
ment lasted the smaller the volume of the sediment became and
the larger the mass which went into the supernatant solution.
This is expressed in Fig. 63. The upper curve represents the
volume of the sediment after 1 hour. The suspension of 1 gm. of

Dry weight of sediment in £m

i>* to to •£> bt b> ^ b»
ooooooooo

&

x^

k

&

f

N>

L

$

7

$1

\

\

^

/

£

TT

s^

s

v^

X

ty

;

\

<&

vv

/

Dr

y v

/•eif

htc

)fsc

5dir

ien

*\

J>

7

in j

|m.

"O*-o

pH 1.4 L6 16 2.0 22 2.4 2.6 2.8 3.0 3.2 3.4 3.6 "3.8 4.0 4.2

FIG. 64. — Dry weight of sediment of casein chloride solutions after 1 and 22

hours.

casein in 100 c.c. of HC1 of different concentration had been kept
for 1 hour at 20°, had been shaken repeatedly but not frequently,
and the suspension was then passed into 100 c.c. graduates and
allowed to settle at 20°C. After 2 hours the volume of the sedi-
ment was measured and the volumes are the ordinates of the
curve marked " after 1 hour" in Fig. 63. A similar experiment
was made in which the suspension of casein was kept for 22
hours at 20°C. and was allowed to settle during 6 hours also at
20°C. The volumes are the ordinates of the second curve in
Fig. 63, marked " after 22 hours." The abscissae are the pH
of the total solution and suspension.

The curve " after 1 hour" is clear, since it is chiefly the expres-

224 THEORY OF COLLOIDAL BEHAVIOR

sion of the variation of the degree of swelling of the casein
particles, not as much having gone into solution as after 22
hours. We notice that the volume occupied by the solid particles
in the 1-hour curve is a minimum at the isoelectric point, that it
rises steeply after pH 3.1, that it drops at 2.2, and that a second
drop commences at pH 1.8. The two drops have a different
cause. The drop at pH 1.8 is due to a diminution of the degree
of swelling of the sediment, while the drop at 2.2 in the 1-hour
curve is due to the fact that at pH 2.2, where the solubility of
casein chloride is a maximum, some of the casein chloride has gone
into solution. This conclusion is supported by the fact that the
drop at 2.2 increases in time and is very considerable after 22
hours (see Fig. 63), while otherwise the 1-hour and the 22-hour
curves show only minor differences.

The proof that this interpretation in the volume curves of Fig.
63 is correct is furnished by Fig. 64, where the ordinates are the
dry weights of the sediments, the volumes of which are given in
Fig. 63. One gram of powdered casein had when dried for 24
hours at between 90 and 100°C. a dry weight of 0.87 gm.

That part of the casein chloride which goes into the supernatant
liquid (i.e., which is not contained in the sediment) consists of
two constituents, namely, first, solid submicroscopic particles in
suspension which in due time would have settled, and second,
isolated casein ions and molecules. The solid particles in the
supernatant liquid (unless they are below the limit required to
occlude water) undergo the same swelling under the influence of
the Donnan equilibrium as the particles of the sediment. In
addition, however, we have individual casein ions in solution (the
molecules being probably insoluble since isoelectric casein is
practically insoluble) but these ions cannot undergo any swelling
and hence do not add materially to the volume and the viscosity.
As a consequence, the more solid particles of casein chloride are
dissolved into isolated casein ions or particles too small to occlude
water, the more the relative volume occupied by the casein in
the solution should be diminished, and this should be accompanied
by a diminution in viscosity. If our theory of the origin of the
viscosity of the gelatin solutions is correct, it should be possible
to prove that where the solubility of the casein chloride solution
is a maximum the viscosity curve shows a drop.

VISCOSITY

225

The correctness of this inference is supported by the viscosity
curves in Fig. 65, which represent the viscosity after 1 hour and
after 22 hours. The experiments are the same as those referred
to in Figs. 63 and 64. The viscosity of the total suspension and
solution was measured in a straight viscosimeter with a time of
outflow for water of 48.4 seconds at 20°C. The curve for the
viscosities after 1 hour is the expression chiefly of the swelling,
since casein chloride goes only slowly into solution at 20°C.
The curve is almost continuous and has its maximum in the
region between pH 2.1 and 2.4, where also the swelling is a

1.7

.2 L6
b

W 1-3

1 12
? 1.1

1.0
pHl

FIG. 65.—

/

* *

r~^»
#

s*

^v?

\

Vi

sec

sit^

rof

1%

&-

-cr-c

x^,

^\

S

ca

sei:

A

1 C

(• p/

hloi

?id€

*y

V*

K

s

t

\

jr

3

4 1.6 1.8 2.0 22 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 40 4.2

Viscosity of 1 per cent casein chloride solutions after 1 and 22 hour
at 20°C.

maximum. There is, however, a slight depression at pH 2.2,
where the solubility of the casein is a maximum.

The curve for the viscosities, Fig. 65, after 22 hours shows, how-
ever, a distinct saddle at pH 2.2 where the solubility of casein
chloride is a maximum. This agrees with the assumption that
the high viscosity is due to swollen particles of casein, a certain
quantity of which had been dissolved at or near pH 2.2. This
solution of the particles capable of swelling beneath that size
where they no longer can occlude water must diminish the rela-
tive volume of the casein and cause a diminution of the viscosity.
Below a pH of 1.8, where the solubility of the casein is consider-
ably diminished, the 1-hour and the 22-hours viscosity curves
(Fig. 65) no longer differ materially. As a consequence of the

15

226

THEORY OF COLLOIDAL BEHAVIOR

saddle the maximum of the viscosity curve after 22 hours now
lies at pH 2.6.

Since the point at issue, namely, the diminution of the viscosity
when solid submicroscopic particles, capable of swelling, are
dissolved into particles so small that they no longer can occlude
water, is so fundamental for the theories of viscosity and of
colloidal behavior in general, it seemed necessary to look for a
more striking proof than that given in the experiment quoted.
For this purpose measurements were made on 1 per cent casein
chloride solutions prepared from very finely powdered casein
particles sifted through a 200-mesh sieve. In order to get a

1.0

pHl4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2

FIG.

66. — Diminution of viscosity through solution of solid particles of casein

chloride.

more rapid solution of the particles the experiment was carried
out at 40°C. The time of outflow of water through the visco-
meter at 40° was 35.5 seconds. Figure 66 gives the results.
The viscosity measurements were made at four different times,
namely: first, immediately after the powdered casein was put
into the HC1; then after 1J^, 3, and 6 hours. During this time
the casein chloride solutions were kept at 40°C. The viscosity
curve taken immediately after the suspensions were prepared is
continuous and is the expression of the swelling which occurred
in the few minutes which elapsed in the preparation of the suspen-
sions and during which the casein was at 40°C. The maximum
swelling occurred at about pH 2.3. At this time the amount of

VISCOSITY

227

casein dissolved into separate casein ions, was negligible. The
curve resembles the 1-hour curve in Fig. 65. After 1^ hours the
second measurements of viscosity were taken, and the reader will
notice from Fig. 66 that the viscosity had dropped considerably
in the neighborhood of pH 2.2 where the solubility of casein chlo-
ride is the greatest, and the maximum depression is at pH 2.1
where also the solubility is a maximum. With a further lower-
ing of the pH the viscosity rises again. The maximal viscosity
in the IJ^-hours series is now at pH of about 2.7 or 2.8 where it

«QJD

20
18
16

14

5

10

8

e^—

4

50
40
30
20
10
0

/

7 *

N

V

•

J/

d

\

\

J

^S

s\

{

5

\

X

f

\\

?

V

6
4

2

0
pHi

^

l\0

§

y

oCt

sei

n c

ilor

ide

U

^

kp

*

4 1.6 1.8 2/3 22 24 2.6 26 3.0 3.2 3.4

FIG. 67. — Similarity of curves for log — and for relative volume of casein chloride

770
in solutions.

was also in the 22-hours series in Fig. 65. The later viscosity
measurements, after 3 and 6 hours (Fig. 66) confirm these conclu-
sions.

5. It is of interest to see whether or not Arrhenius's formula
can account for the influence of electrolytes on the viscosity of
casein suspensions. If this were the case, the curves represent-
ing log - should run parallel to curves representing the relative
770

volume occupied by the casein in the solution. We get the
values of log — from our observations of the relative viscosity

228 THEORY OF COLLOIDAL BEHAVIOR

which give us — , aird we can calculate the volume from the

'no

measured volume of the sediment plus the calculated volume of
the casein in the supernatant liquid. The latter value is obtained
by deducting the dry weight of the sediment from the (known)
dry weight of the whole mass of casein put into the water (1 gm.
powdered casein, dry weight = 0.87 gm.); assuming that the
casein in the supernatant liquid consists exclusively of suspended
particles. This is partly correct for a 1-hour experiment at 20°.
The ordinates in Fig. 67 represent the values for volume thus

corrected and the values for log — while the abscissae are the pH

"no

of the suspensions. The two curves are almost parallel.

It should be stated that these corrected volumes of casein
include a certain amount of water between the granules. We
are, however, in this case not concerned with the absolute but
only the relative volume occupied by the casein.

When NaCl is added in different concentrations to a casein
chloride solution it is noticed that the viscosity is diminished
as it is in the case of solutions of gelatin chloride. We shall see
in Chap. XV that this diminution of viscosity is accompanied by
a diminution in the degree of swelling of the individual particles
of casein which is parallel to the depression of the viscosity.

One gram of powdered casein was put into 100 c.c. of H2O
containing 12.5 c.c. of 0.1 N HC1, and NaCl in concentrations
varying from 0 to M/4. The mixture was shaken occasionally
and kept for 16 hours at 20°. Then the viscosity, volume of
sediment (after settling for 24 hours), dry weight of sediment
(after deduction of the free NaCl contained in the sediment)
were determined. When the volume and the values for log

— are plotted as ordinates over the concentrations as abscissae,

7°

it is found that the two curves agree fairly well (Fig. 68) except

where no or little salt was added and where therefore some casein
particles had been completely dissolved. In this solution the
calculated volume was too high and our curves express the fact.
From these experiments we may conclude that the influence of
electrolytes on the viscosity of casein solutions or suspensions is
due to the swelling of particles of casein suspended in the solu-

VISCOSITY

229

tion of casein and that the volume of these particles is regulated
by the Donnan equilibrium.

6. These experiments leave little doubt that the high viscosity
of certain protein solutions, such as gelatin or casein, is due to the
existence of solid particles occluding large quantities of water,
the amount of which is regulated by the Donnan equilibrium,
while the isolated ions of proteins in solution or the particles too
small to occlude water have no share in the causation of high
viscosities.

22
20
18
16
14
"1^ 12

2° l°
8

6
4
2
0

50
40 ^

E!

o

30 ^

0)

8
3

ZO 'o
10
0

*• ~
<

— —

^

^^

X

^

01 *

1

1

t

^

\

\

1

a

\\

V

I

I.

17o(

:as<

iin

:hlc

>rid

g

^

N

^

P1

1=2

.18

K;

WrTMMMMMMMM
2048 1624 5l2 256 128 64 32 T5 "5" 4

Concentration of NaCl

in solutions.

The quantities of water which can be occluded in a solid jelly
of gelatin are enormous. If we assume the molecular weight
of gelatin to be of the order of magnitude of about 12,000, a
solid gel of 1 per cent originally isoelectric gelatin contains over
60,000 molecules of water to 1 molecule of gelatin. It is out of
the question that such masses of water could be held by the
secondary valency forces of the gelatin and water molecules.
Casein particles occlude much less water and for this reason the

230 THEORY OF COLLOIDAL BEHAVIOR

viscosity of casein chloride solutions never becomes as high as
that of gelatin solutions containing equal masses of protein per
100 c.c. of solution.

All the experiments described agree with the occlusion theory
but not with the hydration theory. Thus the fact that the
viscosity of a 0.5 per cent solution of isoelectric gelatin increases
rapidly at a temperature of 20°C. or below cannot possibly be
explained on the basis of the hydration theory since isoelectric
gelatin is not ionized. It might be explained on the basis of
another suggestion which attributes to the gelatin solution a
similar structure to that possessed by the solid jelly of gelatin.
This idea would lead us to the assumption that in addition to the
source of viscosity due to the relative volume of the protein
solution there exists a second type peculiar to protein solutions
which has no connection with the volume.

"Bearing in mind the possibility that protein solutions may contain a
preformed molecular structure analogous to that of the jellies or coagula
which they can form, we are strongly impelled towards the belief that the
type of viscosity which solutions of proteins exhibit may in some manner
owe its existence to this structure, and not to the type of internal friction
which hinders molecular and ionic motion. Thus a netlike structure,
such as a tennis net, will offer no hindrance to the passage through it of a
quickly moving body which is smaller than its meshes, other than that
which is due to the fact that the material which composes the net occu-
pies a small fraction of the area which the body must traverse, but to
any force which involves deformation of the structure, for instance, a
force which seeks to drag it through a small tube, it will offer a very
considerable resistance."1

This theory becomes untenable in the case of suspensions of
powdered gelatin and of casein chloride which have no tendency
to set to a jelly. It fails, moreover, to account for the fact that
the influence of pH on the viscosity resembles that on the osmotic
pressure of gelatin solutions. The assumption of a second
type of viscosity independent of the relative volume occupied
by the solute becomes unnecessary, since the theories of Einstein
and of Arrhenius respectively, which derive the viscosity from the
relative volume, suffice to account for all the phenomena observed.

1 ROBERTSON, T. B., "The Physical Chemistry of Proteins," pp. 324-25,
New York, London, Bombay, Calcutta, and Madras, 1918.

VISCOSITY 231

We therefore arrive at the conclusion that where the hydrogen
ion concentration, the valency of ions, and the concentration of
salts influence the viscosity of protein solutions in a similar way
to that in which they influence the osmotic pressure, this influence
on viscosity is in reality an influence of electrolytes on the swelling
of solid submicroscopic protein particles contained in the solution.

CHAPTER XIII

A RECIPROCAL RELATION BETWEEN THE OSMOTIC

PRESSURE AND THE VISCOSITY OF GELATIN

SOLUTIONS1

1. The experiments in the preceding chapter have led to the
conclusion that proteins form true solutions consisting of isolated
protein ions and molecules which may or may not contain in
addition to the isolated ions and molecules submicroscopic
particles capable of occluding water and giving rise to a Donnan
equilibrium. Only when a protein solution contains particles of
this latter type do we notice a comparatively high viscosity and a
similar influence of electrolytes on viscosity as on osmotic pres-
sure. Solutions of crystalline egg albumin of not too high a con-
centration have a comparatively low viscosity which is not
affected in the typical way by electrolytes and this leads to the
conclusion that these solutions consist chiefly of isolated ions and
molecules or of particles too small to occlude water. If this con-
clusion is justified, we are forced to the further conclusion that the
influence of electrolytes on the osmotic pressure of protein solu-
tions is determined by the isolated ions of a protein solution and
not by the submicroscopic particles capable of occluding water,
i.e., the micellae, since solutions of crystalline egg albumin show
the influence of electrolytes on their osmotic pressure in a striking
way. It would further follow that in case of a gelatin solution
where both isolated ions and submicroscopic micellae are sup-
posed to exist the isolated ions are responsible for the influence of
electrolytes on the osmotic pressure of the solution while the sub-
microscopic particles of solid jelly capable of occluding water are
responsible for the influence of electrolytes on the viscosity of
gelatin solutions. In other words, wherever there exists a rever-
sible aggregate formation from isolated protein ions in solution

1 LOEB, J., J. Gen. Physiol, vol. 4, p. 97, 1921-22,

232

OSMOTIC PRESSURE AND VISCOSITY 233

there should exist a reciprocal relation between the viscosity and
the osmotic pressure of the solution since, the transformation of
the submicroscopic particles of solid jelly should lower the vis-
cosity and raise the osmotic pressure of a gelatin solution and
vice versa. It can be shown that this conclusion is supported by
observations on gelatin solutions.

It was noticed in the preceding chapter that the viscosity of
solutions of gelatin chloride does not always increase on standing
but that it diminishes when the temperature exceeds a certain
limit. This was shown for a 2 per cent solution of gelatin chloride
of pH 2.7 in Fig. 57. The viscosity of such a solution increases
very rapidly on standing at 15°C., much less rapidly at 25°C.,
but diminishes when kept at a temperature above 35°C., and the
more rapidly the higher the temperature. This we assume tobe
due to the fact that at a temperature above 35°C. the rate of
melting of submicroscopic particles of solid jelly exceeds the rate
of their formation from isolated ions or molecules.

Several liters of a 0.55 per cent solution of isoelectric gelatin
were kept at about 10°C. for 48 hours and at 20°C. for the next
24 hours. Then the stock solution was divided into two parts.
The one part was subdivided into doses of 90 c.c. each, and each
was brought to a different pH by adding 10 c.c. containing
different quantities of HC1. In this way the concentration of
originally isoelectric gelatin was, therefore, in every case 0.5
per cent. The second portion was treated in the same way
except that before adding the acid the gelatin was kept for 1
hour at 45°C. This was done to melt part of the submicroscopic
pieces of jelly assumed to exist in the solution, and thus to
increase the concentration of the isolated ions and molecules and
to diminish the relative quantity of solid submicroscopic particles
responsible for the high viscosity characteristic of gelatin solu-
tions. After this second portion of the stock solution of iso-
electric gelatin had been kept for 1 hour at 45°C. it was rapidly
cooled to 20°C., the HC1 was added in the way described for the
first portion and the solutions were put into collodion bags to
measure the osmotic pressure. Each collodion bag contained
about 50 c.c. of gelatin solution. The temperature now remained
constant at 20°C. for both sets of experiments. It was noticeable
from the first that the osmotic pressure of the gelatin solution

234

THEORY OF COLLOIDAL BEHAVIOR

which had been kept for 1 hour at 45° and which was therefore
supposed to have melted into smaller particles was higher than
that of the gelatin solution not previously heated. Figure 69
shows the result after 22 hours. The maximum osmotic pressure
was for the gelatin solution that had been previously heated 200
mm. H2O, while it was only 170 mm. for the other gelatin solution
not previously heated to 45°C.

220

1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 Z.Q 3.6 4.0 4.2 4.4 4.6

FIG. 69. — Showing that the osmotic pressure of a solution of gelatin chloride
which has been previously heated to 45°C. for 1 hour and then rapidly cooled
to 20°C. is higher than the osmotic pressure of the same solution of gelatin
chloride not previously heated.

Then the viscosities were determined at 20° and they gave the
opposite result (Fig. 62 of the preceding chapter), the viscosities
being considerably higher in the solutions not previously heated
to 45° than in the solutions previously heated. This experiment
then confirms our expectation that there exists a reciprocal
relation between the viscosity of protein solutions and their
osmotic pressure, inasmuch as a transformation of solid sub-
microscopic particles of jelly into isolated protein ions and mole-
cules diminishes the viscosity but increases the osmotic pressure.

As far as the quantitative relations are concerned, the differ-

OSMOTIC PRESSURE AND VISCOSITY 235

ence in viscosity (Fig. 62) is more striking than the difference in
osmotic pressure (Fig. 69). This is possibly connected with the
fact that the lowering in viscosity due to heating to 45°C. was
measured immediately after the temperature had reached 20°C.
again, while the osmotic pressure of the same solutions was
measured after the solutions had been standing for 22 hours at
20°C. During this time a considerable formation of sub-
microscopic particles of solid jelly had probably occurred in the
solutions previously heated to 45°C.

It was expected that when we put a collodion bag filled with a
1 per cent solution of gelatin of e.g., pH 3.5, which had been kept
for 1 hour at 45° and cooled to 20° into a beaker containing a 1
per cent solution of the identical gelatin chloride solution of pH
3.5, but which had not been heated to 45°C. before being brought
to 20°C., water would diffuse from the latter into the former
solution. This experiment was carried out with a positive result.

These experiments support the idea expressed in the preceding
chapter that protein solutions are true solutions which may or
may not contain solid particles of protein capable of swelling.
In the case of gelatin solutions the formation of submicroscopic
particles of solid jelly from isolated molecules or ions is a reversi-
ble process, and this leads in this case to a reciprocal variation of
osmotic pressure and viscosity of such solutions.

This probably explains a phenomenon which has puzzled the
writer for a long time, namely that the osmotic pressures of
gelatin solutions of the same pH and concentration of originally
isoelectric gelatin showed occasionally variations for which he
could not account. It now becomes probable that this was due
to a factor which was not taken into consideration, namely,
that on standing at room temperature a gradual transformation
of isolated molecules or ions into larger aggregates takes place,
which must diminish the osmotic pressure but increase the
viscosity. This source of variation was eliminated in the viscos-
ity experiments in which the gelatin solution was always heated
first to 45°C. and then as soon as this temperature was reached
the solution was cooled to the temperature desired for the viscos-
ity measurements. It is probable that the same uniformity of
treatment is also required for the osmotic pressure experiments.

This reciprocal relation between osmotic pressure and viscosity

236 THEORY OF COLLOIDAL BEHAVIOR

exists probably also in the case of solutions of casein salts.
Solutions of Na caseinate are less opaque than those of casein
chloride (of the same concentration of originally isoelectric
casein) which indicates that the Na caseinate solution contains
more isolated casein ions and fewer submicroscopic solid particles
than the solution of casein chloride.

The writer had already shown in a preceding chapter that the
maximal viscosity of a 1 per cent solution of casein chloride is
higher than the viscosity of solutions of Na caseinate of equal
concentration of originally isoelectric casein, while the osmotic
pressures of solutions of the two salts show exactly the reverse
relation, the maximal osmotic pressure of a 1 per cent solution
of Na caseinate being almost 700 mm. H^O while the maximal
osmotic pressure of a 1 per cent solution of casein chloride is
only about 200 mm.

The solutions of crystalline egg albumin seem to consist (at
ordinary temperature and at not too high a concentration of
albumin and of the hydrogen ions) exclusively or almost exclu-
sively of isolated molecules or ions. Since the latter cannot
diffuse through a collodion membrane they give rise to a Donnan
equilibrium across the membrane and hence only the osmotic
pressure of solutions of salts of crystalline egg albumin is influ-
enced by electrolytes in the way demanded, while the viscosity
shows such an influence only to a negligible degree.

2. It should be possible to give a more striking confirmation
of the reciprocal relation between the viscosity and the osmotic
pressure if we replace in a gelatin solution part of the dissolved
gelatin by equal weight of powdered gelatin. Such a substitu-
tion should increase the viscosity and diminish the osmotic
pressure of the solution.

Figure 70 shows that the osmotic pressure of a 1 per cent solu-
tion of originally isoelectric gelatin diminishes the more the more
we replace the dissolved gelatin by small granules of powdered
gelatin. The ordinates of the upper curve represent the values
of the osmotic pressure of a 1 per cent solution of originally
isoelectric gelatin at different pH, the pH serving as abscissae of
the curves. The acid used was HC1, and the curve is the usual
one. At the beginning of the experiment the gelatin solution was
rapidly heated to a temperature of 45°C. and rapidly cooled to

OSMOTIC PRESSURE AND VISCOSITY

237

20°C. and then kept at that temperature throughout the entire
experiment. The pH is that of the gelatin solution at the end of
the experiment.

The middle curve represents an experiment in which 0.5 gm.
of the isoelectric gelatin in solution was replaced by 0.5 gm. of

500
475
450
425
400
375
350
g 325

| soo

£275

P-

0250

§225

§ 200
o
175

150
125

Osr ioti

2

/

>£

sf,

Y

pH 1.6 16 2.0 2.2 24 26 25 3.0 3.2 3.4 3.6 3.8 40 42 4.4 4.6

FIG. 70. — A suspension of 1 gm. of a fine powder of gelatin in 100 c.c. of
water has practically no osmotic pressure (lowest curve), while a solution of
1 gm. of the same gelatin has a maximal osmotic pressure of over 500 mm.
(uppermost curve). A mixture of 0.5 gm. of powdered and 0.5 gm. of liquid
gelatin in 100 c.c. water has practically the osmotic pressure of the 0.5 per cent
liquid gelatin in 100 c.c. of water (middle curve).

isoelectric powdered gelatin. The latter did not contribute to
the osmotic pressure, the observed osmotic pressure being due to
the isolated ions of the 0.5 per cent gelatin in solution which
determined the Donnan effect, and in addition to the gas pres-

238 THEORY OF COLLOIDAL BEHAVIOR

sure of the isolated gelatin ions and the isolated gelatin molecules.
Theoretically, of course, the coarse particles of gelatin also
participate in the osmotic pressure but this effect is negligible on
account of the small number of such particles. (The gelatin
particles used were of grain size slightly above %o of an inch
diameter.) At the beginning of the experiment the 0.5 per
cent solution of gelatin was rapidly heated to 45°C. and rapidly
cooled to 20°C., and then the powdered gelatin was added. The
pH is that of the 0.5 per cent gelatin solution at the end of the
experiment.

The lowest curve represents the osmotic pressure of 1 gm. of
powdered isoelectric particles in 100 c.c. of HC1 of different pH.
The slight osmotic pressure observed is probably due to the fact
that a little of the gelatin went gradually into solution. This
apparently happened to a less extent in a repetition of this experi-
ment and the osmotic pressures observed were still lower than in
the lowest curve in Fig. 70. All these osmotic pressure experi-
ments were made in a thermostat at 20°C.

The viscosity is affected in exactly the opposite sense from the
osmotic pressure if part of the dissolved gelatin is replaced by
solid particles of gelatin. The more dissolved gelatin is replaced
by solid particles of gelatin the higher the viscosity, a result
to be expected from the experiments and conclusions already
stated.

Solutions of 0.5, 0.625, 0.750, 0.875, and 1.0 gm. of isoelectric
gelatin were heated quickly to 45°C. and cooled quickly to 20°C.,
and so much powdered gelatin of pH 7.0 was added as to bring
the total gelatin in 100 c.c. to 1 gm.;z.e., to a 0.5 per cent solution
of gelatin was added 0.5 gm. of powdered gelatin (between mesh
sizes 100 and 120), and to a 0.875 per cent solution of liquid
gelatin was added 0.125 gm. of powdered gelatin, while no
powdered gelatin was added to the 1 per cent solution of liquid
gelatin. The different mixtures were brought to different pH
through the addition of different quantities of HC1 and the solu-
tions were allowed to stand for 1 hour before the viscosities were
measured in order to give the powdered gelatin a chance to swell.
The results of the measurements are represented in Fig. 71.
The reader will see that within the range of the pH between 3.6
and 1.4 the viscosity is the greater, the more liquid gelatin is

OSMOTIC PRESSURE AND VISCOSITY

239

replaced by powdered gelatin. This supports the idea that
the influence of electrolytes on the viscosity of gelatin solutions
is due to the influence of the electrolytes on the swelling of solid
submicroscopic particles of gel in the solution.

The nature of the curves in Fig. 71 between pH 4.6 and 3.8
requires an explanation. The curves are here the lower the

pH 1.4 1.6 1.8 ED 2.2 E4 £6 2.6 3.0 3.2 3.4 3.6 3.8 4.0 42 4.4 4.6

FIG. 71. — The influence of replacing liquid by powdered gelatin on viscosity
is exactly the reverse as on osmotic pressure. The more the powdered particles
replace the liquid gelatin the higher the viscosity.

more liquid gelatin is replaced by solid gelatin. This is due to
the fact that it was necessary to let the suspensions stand for at
least 1 hour to allow the particles of powdered gelatin to swell
before the viscosity measurements were made. During this
time the liquid gelatin at or near the isoelectric point increases

240

THEORY OF COLLOIDAL BEHAVIOR

rapidly in viscosity while this increase in viscosity is suppressed
where the hydrogen ion concentration is higher. This is proved
by Fig. 72 which gives the viscosity of the supernatant solutions
of gelatin (without the suspended particles) which had been stand-
ing for 1 hour. Inside the range of pH 4.4 and 4.6 the viscosity
had risen more rapidly on standing than at the lower pH ; which
means that at or near the isoelectric point new submicroscopic
particles of solid jelly are constantly formed from the molecules
while this process is the slower the higher the hydrogen ion
concentration. While thus the addition of acid to a solution of
isoelectric gelatin retards the rate of formation of new submicro-

0.8'

5%

0.62 5 2

V1£CO£

pH 1.4 16 Ifl 20 2.2 2.4 2.6 26 3.0 32 3.4 3.6 38 40 42 4.4 4.6

FIG. 72. — Viscosity of gelatin solutions after standing for 1 hour at 20°C.
Notice minimum at pH 4.4, indicating that the viscosity has risen more near the
isoelectric point on account of the formation of submicroscopic particles of gel.

scopic particles of jelly, it increases the swelling of those already
present when the acid is added. On the other hand, powdered
particles of isoelectric gelatin in water of pH 4.7 do not increase
their volume on standing.

The fact that the addition of acid to a solution of isoelectric
gelatin inhibits or retards the formation of new solid particles
on standing was discussed in the preceding chapter.

If we now return to .the discussion of the curves in Fig. 71 we
may say that the results in that part of the curves which belongs
to the abscissae of pH above 3.8 is the expression of the fact that
that part of the viscosity which is due to the gelatin in solution

OSMOTIC PRESSURE AND VISCOSITY

241

had undergone an increase during the hour the solution had been
standing at 20°C. after having been heated to 45°C.; and that the
increase caused in the viscosity of the liquid gelatin was a maxi-
mum at the isoelectric point, being almost zero at a pH below 3.4;
while the addition of acid had the opposite effect on the solid
granules of gelatin, since their volume was increased according
to the rules of the Donnan equilibrium.

It is necessary that we convince ourselves that a Donnan equi-
librium exists when particles of solid gelatin are suspended in a
solution of gelatin. That this is actually true was shown in the
following way: 0.5-gm. doses of powdered gelatin were added to
100 c.c. of 0.5 per cent gelatin chloride solutions of different pH.
The different beakers containing these mixtures were kept for 3^
hours at 20°C. The mass was then filtered through cotton wool
and the pH of the filtrate (0.5 per cent gelatin solution) and of the
solid gelatin granules were determined, that of the latter after
they had been melted. It was found that the pH of the gelatin
granules was higher than that of the solution and that the differ-
ence followed the Donnan equilibrium equation (Table XLIV),
though the result was slightly irregular owing to the fact that it
is impossible to free the suspended particles of gelatin completely
from the supernatant liquid. When we separate a gelatin solu-
tion from water by a collodion membrane we have two equilib-
ria, one across the membrane caused by the protein ions on one
side of the membrane; and a second one inside the protein solu-
tion caused by the solid particles of jelly.

TABLE XLIV

pH of gelatin in

suspension

5.12

4.60

4.49

4.18

4.07

3.73

3.45

3.93

2.68

2.34

2.09

1.86

1.77

1.53

pH of gelatin in

solution

4.98

4.35

4.12

3.91

3.69

3.50

3.14

2.78

2.50

2.28

1.97

1.86

1.72

1.57

The reciprocal relation between viscosity and osmotic pressure
of protein solutions disposes of the attempt to explain the influ-
ence of electrolytes on the physical properties of protein solu-
tions on the basis of the micella or aggregate theory. We have
seen that both the osmotic pressure of a gelatin chloride solution
as well as its viscosity are depressed when a neutral salt is added

16

242 THEORY OF COLLOIDAL BEHAVIOR

to the solution. The micella theory would explain this by assum-
ing that the addition of a salt increases the degree of aggregation
in the solution and hence diminishes the number of isolated par-
ticles and therefore the osmotic pressure of the solution. This
assumption cannot be put to a quantitative test since we have no
direct method of determining the number of aggregates in solu-
tion. We have shown, however, in this chapter that if we in-
crease the number of aggregates at the expense of isolated protein
ions or molecules, the viscosity rises. Hence, if we assume that
the number of aggregates in the gelatin chloride solution is
increased through the addition of salt, the viscosity of such a
solution should increase for the same reason; whereas in reality
we have seen that the addition of salt depresses both the osmotic
pressure and the viscosity of the gelatin solution. This fact
eliminates the aggregation or micella theory as a possible source
of explanation of the colloidal behavior. We need not deplore the
loss, since the application of the aggregate theory to the explana-
tion of colloidal phenomena has never risen beyond the stage of
vague speculations.

CHAPTER XIV
THE STABILITY OF PROTEIN SOLUTIONS1

A. THE STABILITY OF WATERY AND AQUEOUS SOLUTIONS OF

GELATIN

1. It is difficult to discuss the problem of the stability of
colloidal solutions satisfactorily as long as we do not possess a
complete theory of the solution of crystalloids. In a general way
we can say that there seem to exist two different kinds of forces
by which substances can be kept in solution, first, the general
forces active in all solutions and which are supposed to be the
forces of attraction between solvent and solute; and second, the
special forces such as the mutual repulsion of the particles due to
electrical charges. These latter special forces are supposed to
become of significance only when the general forces of attraction
between solute and solvent are comparatively feeble.

It was noticed long ago that colloids in general and proteins in
particular behave very differently in regard to the concentration
of salt required for precipitation, some requiring very high con-
centrations of salt for this purpose and others comparatively low
concentrations.2 There is apparently no transition between the
two extremes. It was formerly believed that these differences
in the concentration of salts required could be used for the classi-
fication of colloids, and some authors divide the proteins or
colloids in general into two groups, those which exist in the form
of suspensions ("suspensoids," "lyophobic" or " hydrophobic "
colloids), and those which exist in the form of solutions ("emul-
soids," "lyophilic" or " hydrophilic " colloids). The former are
precipitated by low concentrations, the latter only by high con-
centrations of salt. It is of more interest to know the reason
why the precipitation of one type requires high and of the other

1LoEB, J., and LOEB, R. F., J. Gen. PhysioL, vol. 4, p. 187, 1921-22.
2 HARDY, W. B., J. PhysioL, vol. 33, p. 251, 1905-06.

243

244 THEORY OF COLLOIDAL BEHAVIOR

low concentrations of salts than to invent names for the two
cases.

We intend to show that where low concentrations of electro-
lytes are required for precipitation, the precipitating influence
of the salt has the earmarks of the Donnan effect, inasmuch as
the effective ion of the salt has the opposite sign of charge to that
of the protein particles, while where high concentrations of salts
are required no such relation exists; and we conclude from this
that where low concentrations of salts suffice for precipitation,
the precipitation is due to the diminution of the value (pH inside
the colloidal particles minus pH of the outside solution), as shown
in the chapter on the charge of colloidal particles, while where high
concentrations of salts are required the precipitating influence is
due to some other cause, possibly the weakening of the forces of
attraction between protein molecules and the molecules of the
solvent, e.g., water, through the presence of the salt. This latter
conclusion, of course, would imply that the proteins can exist in
true crystalloidal solution, the ultimate units being protein
molecules or ions. There is no proof against the permissibility
of such an assumption in the case of aqueous solutions of crystal-
line egg albumin (at the proper temperature, pH, and concentra-
tion) or of gelatin. This opinion is shared by S0rensen, who has
not hesitated to determine the molecular weight of crystalline
egg albumin from the osmotic pressure of its solution.1

2. Solutions of gelatin in water require enormous concentra-
tions of salts for precipitation, and this process of salting out has
no connection with the Donnan equilibrium, since solutions of
gelatin are more readily salted out by sulphates than by chlorides
regardless of the pH of the protein solution. The same is true
for solutions of crystalline egg albumin of pH 4.7 or above; when,
however, the pH of the crystalline egg albumin becomes too low
(e.g., 2.0 or less), lower concentrations of salts will cause precipita-
tion. The reason for this influence of the pH is mentioned at
the end of this chapter.

Eight-tenths per cent solutions of gelatin were prepared at
three different pH, namely 4.7 (isoelectric gelatin), 3.8 (gelatin
chloride), and 6.4 to 7.0 (Na gelatinate). The purpose was to

1 S0RENSEN, S. P. L., Studies on proteins; Compt. rend. trav. Lab. Carlsberg,
vol. 12, Copenhagen, 1915-17.

THE STABILITY OF PROTEIN SOLUTIONS

245

find the molecular concentration of different salts — namely,
(NH4)2SO4, Na2SO4, MgSO4, KC1, and MgCl2— required for pre-
cipitation. Table XLV shows that regardless of the pH the
sulphates are better precipitants than the chlorides. Wherever
we are dealing with colloidal phenomena, i.e., phenomena regu-
lated by the Donnan equilibrium, we must expect that sulphates
will have a more depressing effect than chlorides when the protein
is on the acid side of the isoelectric point but no when it is on the
alkaline side or at the isoelectric point. But this is not true for
the influence of ions on the salting out of gelatin in aqueous
solution.

TABLE XLV. — MINIMAL MOLAR CONCENTRATIONS REQUIRED TO PRE-
CIPITATE 0.8 PER CENT SOLUTIONS OF GELATIN

pH of gelatin solution

Approximate molecular concentration of salt
required for precipitation

(NH4hSO4

Na2SO4

MgS04

KC1

MgCh

4 7

>Kf»M

XK6 M
^6 M

% M

K M
H M

*% M

H M
H M

>3 M
3 M
>3 M

>3 M
>3 M

>3 M

3 8 (gelatin chloride)

6 4 to 7 0 (Na gelatinate)

The question arises, How does it happen that sulphates are
better precipitants than chlorides? Some light is thrown on
this fact by experiments on the rate of solution.

Powdered gelatin of not too small a size of grain (going through
sieve 30 but not through sieve 60) was rendered isoelectric in the
way described in Chap. II and about 0.8 gm. was put into 100
c.c. of each of a series of solutions of NaCl, CaCl2, or Na2SO4,
varying in concentration from M/4,096 to 2 M. The suspensions
of the powdered gelatin were frequently stirred and the time
required to practically completely dissolve all the grains of
powdered gelatin in suspension at 35°C. was measured. The
ordinates in Fig. 73 are the solution times of isoelectric gelatin,
and the abscissae are the molecular concentrations of the salt
used. It is obvious that NaCl and still more CaCl2 increase the
rate of solution of isoelectric gelatin in water, and the more the
higher the concentration of the salts added. There exists,
however, a striking discontinuity in the Na2SO< curve. As long

246

THEORY OF COLLOIDAL BEHAVIOR

as the concentration of Na2SO4 is below M/32 it increases the
solubility of gelatin, and the more so the higher the concentration.
When, however, the concentration of Na2SO4 is above M/32, a
further increase in the concentration of Na2SO4 diminishes the
solubility of gelatin and the more so the higher the concentration
of Na2S04. (NH4)2SO4 acts like Na2SO4. We now understand

I

130
120

no

100
90
80
70
60
50
40
30
20
10

(

Influence of salts on
solution time of 0.87o
isoelectric gelatin
at 35 °C.

Eg

\1

5?

V

\

\

v

r

^

S.

\

1

#<

N

\s

\

4

V

1

"S

(^

V

^

N*.

LK

^f

ls>z

r*

t

^

Nr

x

\<

\

N

N

\,

i

^
1

H

y

<

^,

K*««(

\

* f « f

Concentration of salts

FIG. 73. — Influence of salts on the time required for the solution of 0.8 gm.
of powdered isoelectric gelatin in 100 c.c. salt solution at 35°C. and pH 4.7.
Notice difference of curve for Na2$O4 and for CaCh and Nad.

why we cannot precipitate solutions of isoelectric gelatin with
KC1 or MgCl2 in concentrations up to 3 M (see Table XLV) while
we can precipitate such solutions with sulphates but only at
concentrations above M/2.

It may be of interest to supplement these observations by the
results given in Table XLVa, on the influence of salt solutions
of three different molar concentrations, namely, M/1,024, M/512,

THE STABILITY OF PROTEIN SOLUTIONS

247

and M/256, on the time required to dissolve 0.8 gm. of powdered
isoelectric gelatin at 35°C. The salt solutions had a pH of 4.7.
It is obvious from the table that the dissolving power of the
chlorides increases with the valency of the cation while the dissolv-
ing power of the Na salts increases with the valency of the anion.

TABLE XLVo. — TIME IN MINUTES REQUIRED TO DISSOLVE 0.8 GM. OF
POWDERED ISOELECTRIC GELATIN AT 35°C.

M/256

M/512

M/1,024

LiCl

57

70

76

NaCl

49

66

75

KC1

56

70

80

MgCl2

32

40

61

CaCl2

32

40

62

BaCl2

31

46

66

CeCl2

26

35

44

LaCl3

23

Na2SO4

34

46

60

Na4Fe (CN)6

24

32

41

While isoelectric gelatin is only sparingly soluble, gelatin
salts are highly soluble. Doses of 0.8 gm. of powdered gelatin
of pH of about 3.3 dissolve very rapidly in 100 c.c. HC1 of the
same pH at 35°C. The addition of NaCl or CaCl2 no longer
increases the solubility, except for CaCU in concentrations above
M/16. Na2SC>4 or (NH^SC^ abruptly diminishes the solubility
at a concentration above M/4; and NaCl does so above a con-
centration of 1 M (Fig. 74).

Figure 75 shows the influence of the three salts on the solution
time of Na gelatinate of pH 10.5. Na2SO4 diminishes the solu-
bility abruptly at a concentration above M/8 while both NaCl
and CaCU increase the solubility of Na gelatinate, NaCl in
concentrations above M/2, and CaCl2 in concentrations above

M/16.

In all three cases, therefore, is the solubility of gelatin dim-
inished by sulphates, but only exceptionally by chlorides. This
explains the results contained in Table XLV. The solubility
of gelatin in water does not depend on the Donnan equilibrium.

248

THEORY OF COLLOIDAL BEHAVIOR

This conclusion is supported by an investigation of the influence
of the pH on the solubility of gelatin.

We have seen that addition of little acid to isoelectric gelatin
increases the osmotic pressure, viscosity, P.D., and swelling,
while beyond a certain pH the addition of more acid has a depress-

gelatin chloride pH 3.3
at 35° C.

Concentration of salts

FIG. 74. — Influence of salt on solution time of 0.8 gm. of powdered gelatin
chloride of pH 3.3 in 100 c.c. salt solution at pH 3.3. The gelatin is no longer
soluble beyond 1M NaCl.

ing effect. It was of interest to find out whether such a maximum
followed by a drop existed in the influence of acid on the solu-
bility of gelatin. This is not the case at least between pH 4.7
and 1.0, since the solubility increases steadily with increasing
hydrogen ion concentration, as was proven by measurements of

THE STABILITY OF PROTEIN SOLUTIONS

249

the dry weight of gelatin dissolved in a certain time at different
pH. This corroborates the conclusion that the solution (and
precipitation) of gelatin in water is not influenced by forces
governed by the Donnan equilibrium and does therefore not
show the characteristics of colloidal behavior. We are probably
dealing in this case with forces of residual valency between water

Influence of salts on

solution time of 0.6 %

Na gelatinate pH 10.5

at 35° C.

Concentration of salts

Fio. 75. — Influence of salts on solution time of 0.8 gm. of powdered Na gelatinate
in 100 c.c. salt solution at pH 10.5.

and gelatin molecules, these forces being increased, as a rule, by
the addition of salt to water, with the exception of the sulphates,
which diminish the forces when added beyond a certain concen-
tration at which the chlorides do not cause a diminution in
solubility. This explains why it is easier to salt out gelatin
from its aqueous solutions by sulphates than by chlorides.

250 THEORY OF COLLOIDAL BEHAVIOR

These experiments also show that the solution of solid gelatin
does not depend upon swelling (while the solution of casein
chloride is, as we shall see, determined by swelling). The swelling
of gelatin in acid reaches a maximum at pH of about 2.8 and then
diminishes upon further increase in hydrogen ion concentration,
while the rate of solution of solid gelatin granules continues to
increase steadily when the hydrogen ion concentration increases
beyond pH of 2.8 down to pH 1.0 (and possibly less). The
mechanism of swelling and the mechanism of solution of solid
gelatin in solutions of acid or alkali are determined by forces of
an entirely different character; the swelling by osmotic pressure,
and the solution in all probability by those forces which are
responsible for the solution of crystalloids. The role of secondary
valency forces in the process of solution is suggested by the follow-
ing quotation from Langmuir.

"Acetic acid is readily soluble in water because the COOH group
has a strong secondary valency by which it combines with water.
Oleic acid is not soluble because the affinity of the hydrocarbon chains
for water is less than their affinity for each other. When oleic acid
is placed on water the acid spreads upon the water because by so doing
the COOH can dissolve in the water without separating the hydrocarbon
chains from each other.

"When the surface on which the acid spreads is sufficiently large the
double bond in the hydrocarbon chain is also drawn onto the water
surface, so that the area occupied is much greater than in the case of
the saturated fatty acids.

"Oils which do not contain active groups, as for example pure paraffin
oil, do not spread upon the surface of water."1

It should be added that if we replace the H in the carboxyl
group of oleic acid by K the very soluble potassium oleate is
formed, so that the whole molecule is now dragged into the water.
The Na oleate is less soluble than K oleate. Ca oleate is again
sparingly soluble.

In the case of proteins we have to deal with hydrocarbon
groups possessing more affinity for each other than for water,
and with COOH and NH2 groups (or COO and NH3+ groups) with
a strong affinity for water. It is probable that the NH2 or

1 LANGMUIR, I., J. Am. Chem. Soc., vol. 39, p. 1850, 1917.

THE STABILITY OF PROTEIN SOLUTIONS 251

NHj groups of the protein molecule are more active on the acid
side of the isoelectric point and the COOH or COO groups on the
alkaline side of the isoelectric point. The analogy with the soaps
would also suggest that the nature of the non-protein ion is of
importance for the solubility of a protein salt. This is found to
be true especially in the case of casein-acid salts, casein chloride
being more soluble than casein nitrate, and the latter more
soluble than casein trichloracetate.

Until evidence to the contrary is furnished, we must consider
the possibility that the forces keeping proteins, such as gelatin
or crystalline egg albumin, in aqueous solutions are the same forces
which keep crystalloids in solution. The fact that gelatin
solutions set to a gel does not necessarily contradict this con-
clusion. When gelatin solutions approach the gel state, (i.e.,
when they reach a high viscosity), the relative distance of the
protein molecules or ions from each other remains the same and
the affinity of the active groups of the protein ions or molecules
for water is not changed. The concentration of salt required
for precipitation remains also practically the same.

3. At the isoelectric point the affinity of certain groups of the
gelatin molecule for water is a relative minimum, as is shown by
the fact that on standing at not too high a temperature, a 1 per
cent solution of isoelectric gelatin will become cloudy and the sus-
pended matter will settle; while this will not happen when the
pH is either above 4.8 or below 4.6. When a little alcohol is
added to such a solution near the isoelectric point, a rapid pre-
cipitation of the gelatin occurs. As soon as, however, the pH
is 4.4 or below, or 5.0 or above, the gelatin in solution remains
soluble even with an excess of alcohol, provided the anion of the
acid or the cation of the alkali added to the isoelectric gelatin is
monovalent (in the range of pH concerned), e.g., Cl, CH2COO,
H2PO4, HC204, etc., or Li, Na, K, NH4. When, however, these
ions are bivalent, e.g., SO4, Ca, Ba, the solubility of the gelatin
in alcohol is much less and the addition of a relatively small
amount of alcohol will cause precipitation of the gelatin.1 The
addition of alcohol diminished the attraction between the watery
groups of the gelatin molecule or ion and the solvent, and where
these forces are small, as e.g. at the isoelectric point, or when the

1 LOEB, J., J. Gen. PhysioL, vol. 3, p. 257, 1920-21.

252 THEORY OF COLLOIDAL BEHAVIOR

ion in combination with the gelatin is bivalent, comparatively
little alcohol suffices for precipitation regardless of the pH.

On the other hand, the addition of acid with monovalent anion
or alkali with monovalent cation to isoelectric gelatin, so that the
pH is either 4.4 or below or 5.0 or above increases the power of
attraction between gelatin and water to such an extent that now
the 1 per cent solution of originally isoelectric gelatin becomes
soluble even when comparatively much alcohol is added.

Isoelectric crystalline egg albumin remains clear in solutions
at low temperature, e.g., 2°C., for many months even in a con-
centration of 8 per cent. When the temperature is raised, a
change occurs in the molecule whereby its attraction for mole-
cules of water is diminished and a 1 per cent solution precipitates
at pH 4.8 at a temperature not far from 60°C. (the exact tempera-
ture was not ascertained). This precipitation is spoken of as the
heat coagulation of egg albumin. If we add slight quantities of
HC1 the temperature at which the coagulation occurs is raised.
At pH 4.39 the coagulation occurs on rapid heating at about 80°;
at pH 4.25 or below the forces of attraction between the molecules
of albumin and water become so great that heat coagulation no
longer occurs even at 95°C. ; the solution only becomes opalescent.
It was found that the pH at which heat coagulation of a 1 per cent
solution of crystalline egg albumin no longer occurs at 95°C. is
approximately the same for HC1, HBr, HNO3, CH3COOH, H3PO4,
and succinic acid. For oxalic and tartaric acids it is only slightly
lower, probably because at this pH some of the acid anions are
bivalent. The main fact is, that for H2SO4, whose anions are all
bivalent, the pH at which coagulation becomes impossible is
markedly lower; namely, 3.42. All this is in harmony with the
writer's observations on the effect of different acids on the solu-
bility of gelatin in alcohol-water mixtures.

On the alkaline side from the isoelectric point the critical pH
at which heat coagulation disappears is practically identical for
KOH and NaOH while the pH is considerably higher for
Ba(OH)2.1

The explanation of these phenomena is a part of the general
problem of solubility; they have no direct connection with the
theory of colloidal behavior.

1 Unpublished results.

THE STABILITY OF PROTEIN SOLUTIONS 253

4. When some of the water of a gelatin chloride or Na gelatin-
ate solution is replaced by ethyl alcohol, the mechanism which
keeps the gelatin in solution is not changed, but when we continue
increasing the relative amount of alcohol in the solution a critical
point is reached where the amount of salt required for the
precipitation changes abruptly.1 We must conclude that the
mechanism by which the gelatin is held in solution changes at or
near this critical alcohol concentration. It is possible to show
that when the amount of alcohol exceeds the critical limit the
forces guaranteeing the stability of the solution of gelatin in the
alcohol-water mixture are the forces resulting from a Donnan
equilibrium.

We will first show that such a critical point exists for the ratio
water: alcohol. Ten per cent solutions of gelatin chloride of
pH 3.0 or of Na gelatinate of pH 10.0 were prepared. Five
cubic centimeters of such a solution were first warmed to liquefy
the gelatin and then while still warm they were diluted with 45 c.c.
of a mixture of alcohol and water; the relative quantity of alcohol
and water in the 45 c.c. varying. Ten cubic centimeters of these
1 per cent solutions of gelatin chloride or Na gelatinate in water-
alcohol were titrated with a solution of a neutral salt, (NH4)2SO4,
NaCl, and CaCl2, at 20°C. until precipitation occurred. It was
noticeable that while it was not possible to precipitate the gelatin
at all with 2% M CaCl2 or 5 M NaCl and only with compara-
tively high concentrations of (NH4)2SO4 as long as the concentra-
tion of alcohol did not exceed a certain critical value, when this
critical limit was exceeded traces of these salts sufficed for pre-
cipitation. This is illustrated in Tables XLVI and XLVII.
When the solution contained no alcohol, i.e., when 45 c.c. of H2O
were added to 5 c.c. of the 10 per cent solution of gelatin chloride
of pH 3.0, 7.1 c.c. of 2 M (NH4)2SO4 were required to cause pre-
cipitation (Table XLVI) in 10 c.c. of the 1 per cent gelatin chloride
solution, and the quantity of (NH4)2SO4 required increased at
first the more H2O was replaced by alcohol. When the 45 c.c. of
liquid added to the 5 c.c. of 10 per cent gelatin solution consisted
of 18.75 c.c. of water and 26.25 c.c. of ethyl alcohol, 17.8 c.c. of 2 M
(NH4)2SO4 were required to cause precipitation in 10 c.c. of the
gelatin-alcohol-water mixture, but if now the proportion of

1 The rest of this chapter is based on experiments not yet published.

254

THEORY OF COLLOIDAL BEHAVIOR

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THE STABILITY OF PROTEIN SOLUTIONS 255

alcohol to water was shifted only slightly in favor of alcohol,
namely 17.5 c.c. of water and 27.5 c.c. of alcohol, 0.04 c.c. instead of
17.8 c.c. of 2 M (NH4)2SO4 sufficed for precipitation (Table XL VI).

In the case of NaCl the drop was still more striking. When
the 45 c.c. added to the 5 c.c. of 10 per cent gelatin solution con-
sisted of 8.75 c.c. of water and 36.25 c.c. of alcohol, it was
impossible to cause precipitation in 10 c.c. of the gelatin chloride-
alcohol-water mixture with any amount of 5 M NaCl. When,
however, the proportion of alcohol was only slightly increased,
namely 7.5 c.c. of water and 37.5 c.c. of alcohol, 0.2 c.c. of NaCl
sufficed for precipitation. In the case of CaCl2 the critical point
was reached when the ratio was 5 c.c. of water and 40 c.c. of
alcohol.

The existence of the critical point can equally well be demon-
strated in the case of Na gelatinate as is shown in Table XL VII.

What interests us is the following fact. The mechanism by
which gelatin chloride of pH 3.0 and Na gelatinate of pH 10.0
are kept in solution is not altered as long as not too much of the
water is replaced by alcohol, since in this case (NH4)2SO4 is
always a better precipitant than CaCl2 for both gelatin chloride
and Na gelatinate. When, however, the relative amount of
alcohol exceeds a certain critical point, the mechanism by which
the particles of gelatin are held in solution changes abruptly as is
indicated by two facts; namely, first that the concentration of the
salt required for precipitation becomes suddenly very small, and
second, that the efficient ion has now the opposite sign of charge to
that of the colloidal particle. Thus, in the case of gelatin chloride
(Table XL VI), the critical points for CaCl2 and NaCl are close
together while the critical point for (NH4)2SO4 is at a much lower
concentration of alcohol. In this case the gelatin ion has a
positive charge and the precipitating ion on the alcohol side of
the critical point is the anion. In Table XL VII the critical
points for (NH4)2SO4 and for NaCl are close together while the
critical point for CaCl2 lies at a much lower concentration of
alcohol. In this case the colloidal ion is negatively charged and
the precipitating ion of the salt is the cation. The valency effect
will be demonstrated more strikingly in a later part of this
chapter.

5. If the precipitating effect of low concentrations of neutral

256 THEORY OF COLLOIDAL BEHAVIOR

salts on colloidal solutions or suspensions is the result of the
Donnan equilibrium, the stability of such solutions must be due
to the fact that when isolated protein ions are beginning to
coalesce a Donnan equilibrium is set up between the solution
inside each nascent micella and the outside solution, which
results in a swelling of the nascent micella whereby the ions in the
process of coalescence are forced apart again. This prevents the
formation of new micellae from protein ions as well as the coales-
cence into larger complexes of the micellae already existing. More-
over, there must also originate a P.D. between the micella and
the solution, and the mutual repulsion of the micellae due to their
electrification will also prevent the coalescence of individual
micellae into a precipitate. If a salt is added, the forces guaran-
teeing the stability of the colloidal solution, e.g., the osmotic
pressure, swelling, and P.D. of the micellae are diminished.
When these forces fall below a certain minimal value the protein
particles will coalesce.

We have seen that the depressing effect of a salt on swelling,
osmotic pressure, and P.D. of protein particles is due to that ion
of the crystalloidal salt which has the opposite sign of charge to
that of the protein ion; and that the depressing effect of this
crystalloidal ion increases with its valency. Thus, Fig. 76
indicates the depressing effect of different concentrations of NaCl
and Na2SC>4 on osmotic pressure and P.D. of a 1 per cent gelatin
chloride solution of pH of originally 3.5. The abscissae are the
concentration of the salt added, the ordinates the osmotic pressure
and P.D. The figure shows that the depressing effect of the same
molecular concentration of Na2SO4 is much more than twice as
great as the depressing effect of NaCl. If we assume that the
protein ions and protein micellae can coalesce when the osmotic
pressure is 100 mm. and the P.D. about 4 millivolts, this low
osmotic pressure and low P.D. of the 1 per cent solution of gelatin
chloride of pH originally 3.5 will be produced when the NaCl
solution is about M/64 and the Na2SO4 about M/512. The
precipitating effect of Na2SO4 on gelatin chloride would then be
about eight times as great as the precipitating effect of NaCl.
The depressing effect of CaCl2 on the osmotic pressure, swelling,
and P.D. is about the same as that of a NaCl solution of the same
concentration of chlorine ions, showing that the depressing effect

THE STABILITY OF PROTEIN SOLUTIONS

257

is due to the anion. Hence, the precipitating effect of CaCU on
gelatin chloride is about the same as that of a NaCl solution of
the same concentration of Cl ions.

When the gelatin ion has a negative charge, e.g., in the case of
Na gelatinate, the depressing effect of neutral salts on the P.D.,
osmotic pressure, or swelling of the gelatin solution is due to the

4096 2048 IU2? 5IZ 256 125

Concentration of salt solution

FIG. 76. — Depressing effect of salts (NaCl and Na2SO4) on P.D. and on osmotic
pressure of a 1 per cent gelatin chloride solution of pH 3.5.

cation of the neutral salt and increases rapidly with the valency of
the salt. This is illustrated in Fig. 37, p. 107, which expresses
the effect of neutral salts on the swelling of Na gelatinate of a pH
of about 9.3. It is obvious that in order to depress the original
volume of the Na gelatinate to one-half a M/512 solution of
CaCl2 and a M/16 solution of NaCl and about M/32 solution of
are required. In other words, the depressing action of

17

258 THEORY OF COLLOIDAL BEHAVIOR

CaCl2 on the swelling of Na gelatinate is more than 10 times
as great as that of NaCl. While these data are only semiquan-
titative, they enable us to form an approximate estimate as
to whether or not the precipitating action of a salt on gelatin
can be due to a diminution of the osmotic pressure (or P.D.)
between the coalescent ions of gelatin in conformity with the
Donnan equilibrium.

The procedure in our experiments was as follows : A stock solu-
tion of 5 per cent gelatin chloride of pH 3.0 was prepared; 2
c.c. of this solution were heated to about 45°C. to bring about
complete liquefaction, and 50 c.c. of absolute alcohol were added
while the gelatin was still warm and liquid. This concentration
of alcohol was in excess of that required for the critical limit, and
the gelatin solution was slightly opalescent. Ten cubic centi-
meters of this mixture of gelatin-alcohol-water were titrated with
different salt solutions until a precipitate was found. The con-
centration of the salt solution was selected in such a way that
not less than 0.3 and not more than 0.8 c.c. of solution were
required for precipitation to avoid the addition of too large a
volume of water to the solution. The difference in the relative
efficiency of the different electrolytes is therefore expressed chiefly
in the concentration of the solution required for precipitation.
The reader should bear in mind that the pH of the gelatin chloride
solution after the alcohol and the salt solution were added could
not be measured, and that it was probably higher than 3.0 and
about the same in all solutions. In order to be able to compare
the relative flocculating efficiency of different salts the flocculat-
ing concentration is expressed in equivalents of cubic centimeters
of M/1,024.

Table XL VIII shows that all salts with monovalent anion have
a lower flocculating power on gelatin chloride than salts with
divalent anion.

Salts with monovalent anion require a molecular concentration
of about 100/1,024, i.e., about M/10 concentration for precipita-
tion, while those of the second group require a molecular concen-
tration of about 10/1,024, i.e., about M/100 or less. This shows
that the difference in the flocculating power of monovalent and
bivalent anions has roughly the ratio of about 1:10, i.e., that it
corresponds to the ratio to be expected from Fig. 70 within the

THE STABILITY OF PROTEIN SOLUTIONS

259

limits of the accuracy of these experiments, which is not very
great.

TABLE XLVIII. — FLOCCULATING CONCENTRATION OF DIFFERENT SALTS

AND ACIDS IN AN ALCOHOL-WATER MIXTURE OF GELATIN CHLORIDE

Cubic

Equivalent,

Concentration

Nature

centimeters of

cubic

of salt used

of salt

salt solution

centimeters

required

M/1,024

M/8

RbCl

0.8

102.0

M/8

KC1

0.8

102.0

M/8

NaCl

0.8

102.0

M/8

LiCl

0.7

90.0

M/8

MgCl2

0.5

64.0

M/8

CaCl2

0.65

83.0

M/8

SrCl2

0.60

77.0

M/4

BaCl2

0.5

128.0

M/8

LaCl3

0.7

90.0

M/2

CeCl3

0.35

179.0

M/2

A1C1,

0.3

153.0

M/4

HC1

0.4

102.0

M/8

NaBr

0.8

102.0

M/4

HBr

.. 0.3

77.0

M/8

Nal

0.6

77.0

M/8

NaNO3

0.7

90.0

M/4

HN03

0.3

77.0

M/8

NaCNS

0.4

51.0

M/128

Na2SO4

0.8

6.4

M/32

H2SO4

0.35

11.2

M/64

Na2 oxalate

0.65

10.4

M/128

Na3 citrate

0.7

5.6

M/128

• Na4Fe(CN)6

0.4

3.2

It was almost impossible to cause flocculation with acetic acid,
oxalic acid, or tartaric acid. This suggests that secondary
valency forces may play some role.

These experiments then show that the relative efficiency of
Na2SO4 and NaCl for the flocculation of gelatin chloride in
alcohol-water solution is apparently of about the same order
of magnitude as their relative efficiency for the depression of the
osmotic pressure of gelatin solutions.

260

THEORY OF COLLOIDAL BEHAVIOR

Table XLIX shows the relative flocculating efficiency of
cations on alcoholic solutions of Na gelatinate. Ten cubic
centimeters of 1 per cent Na gelatinate of pH 10.0 were mixed
with 50 c.c. of absolute alcohol. The mixture is slightly opales-
cent. Ten cubic centimeters of the mixture were titrated with
various salt solutions until precipitation occurred.

TABLE XLIX. — FLOCCULATING CONCENTRATION OF DIFFERENT SALTS AND
ALKALIES IN AN ALCOHOL-WATER MIXTURE OF Na GELATINATE

Cubic

Equivalent,

Concentration

Nature of salt

centimeters

cubic

used

or alkali

of solution

centimeters

required

M/1,024

M/16

NaCl

0.6

38.4

M/16

NaBr

0.6

38.4

M/16

Nal

0.45

29.0

M/16

NaNO3

0.5

32.0

M/16

NaCNS

0.55

35.0

M/16

Na2S04

0.75

48.0

M/16

Na2 oxalate

0.6

38.4

M/16

Na$ citrate

0.6

38.4

M/32

Na4Fe(CN)6

0.8

25.6

M/16

KC1

0.5

32.0

M/16

LiCl

0.6

38.4

M/4

KOH

0.3

77.0

M/4

NaOH

0.35

90.0

M/256

MgCl2

0.55

2.2

M/512

CaCl2

0.85

1.7

M/512

SrCl2

0.8

1.6

M/512

BaCl2

0.65

1.3

M/512

LaCl3

0.6

1.2

M/512

CeCl3

0.7

1.4

M/200

Ca(OH)2

1.0

5.1

M/100

Ba(OH)2

0.9

9.2

There are again two distinct groups, this time according to the
valency of the cation. All electrolytes with monovalent cation

40 1

require a molecular concentration of almost ., . = and all

l,

THE STABILITY OF PROTEIN SOLUTIONS 261

salts with a cation of higher valency a concentration of almost
M/500.

We, therefore, find that for the flocculation of Na gelatinate,
originally of pH 10.0, salts with bivalent cation are about 20
times as efficient as salts with monovalent cation. This is
roughly in harmony with the relative influence of these ions on
the osmotic pressure of solutions of Na gelatinate, where the
efficiency of a M/ 16 solution of NaCl is equaled by that of a M/512
solution of CaCl2 (Fig. 37).

Schulze, Linder and Picton, and Hardy found that the precipi-
tating ion has the opposite sign of charge to that of the colloidal
particle and that the precipitating efficiency of the ion increases
with its valency. These experiments suggest that the rule of
Schulze, Linder and Picton, and Hardy is only a consequence
of the Donnan equilibrium.

6. If the osmotic pressure set up between coalescing protein
ions is able to prevent the formation of new micellae and thus to
contribute towards the stabilization of a solution of gelatin in a
solution of much alcohol and little water, we can predict another
result which will become clear from Fig. 77. This figure repre-
sents the influence of different concentrations of NaCl on the
osmotic pressure of 1 per cent solutions of originally isoelectric
gelatin brought to pH 1.8, 4.1, and 3.1 by the addition of different
quantities of HC1. It is obvious from the curves that it requires
a higher concentration of NaCl to bring the osmotic pressure of
the gelatin chloride solution to the same low value, e.g., 125 mm.,
when the pH is 3.1 than when it is 4.1. At pH 3.1 the concen-
tration of NaCl must be between M/64 and M/128 and at pH
4.1 the concentration can be less than M/512. At pH 1.8 no
addition of salt is required since the osmotic pressure is already
below 125 mm. If it be true that the difference of osmotic
pressure between the inside of the nascent micellae and the sur-
rounding solution is one of the forces guaranteeing the stability
of the solution of gelatin in an alcohol-water mixture when the
critical limit of alcohol is exceeded, it is obvious that the con-
centration of salt required for flocculation should vary with the
original pH of the gelatin solution in the way characteristic for
the Donnan equilibrium, namely that near the isoelectric point
little or no salt should be required for precipitation, that with

262

THEORY OF COLLOIDAL' BEHAVIOR

increasing hydrogen ion concentration (i.e. increasing addition of
HC1) the concentration of NaCl required for flocculation should
first increase and later — after a certain pH — diminish. We
will show that this is the case.

to
0

pH

1.6

\

450
425
400
375
350
325

30°
275

250
225

200

1T5
150

125

100

75

50

25

0

)24 512 256 128

Concentration of NaCl

FIG. 77. — Difference in the depressing action of NaCl solutions on the osmotic
pressure of gelatin chloride solution of different pH.

Ten cubic centimeters of a 5 per cent stock solution of iso-
electric gelatin containing various amounts of HC1 were brought
to about 45°C. and 40 c.c. of absolute ethyl alcohol were added.

N, r^

THE STABILITY OF PROTEIN SOLUTIONS

263

This was a quantity of alcohol in excess
of that required to bring the solution
to the critical point. After cooling to
room temperature, the 50c.c. of alcohol-
water solution of 1 per cent originally
isoelectric gelatin were titrated with a
2>^ M NaCl or 2J^ M CaCl2 solution
until permanent flocculation occurred.
The number of cubic centimeters of 2^
M NaCl and CaCl2 required varied with
the pH of the original gelatin solution as
Table L indicates. The pH in the table
are those which the solution of gelatin
would have had if it had been diluted
with 40 c.c. of water instead of with
alcohol. We do not know the actual pH
in the alcoholic solutions except that it
should be less than without alcohol.

Near the isoelectric point and in fact
up to about pH 4.0 or 3.8 of the pH
which would have been found had the
solution contained no alcohol, the
gelatin was not completely dissolved
even when no salt was added, and the
same was true when the pH (in our
arbitrary standard) fell below 1.6.
From pH 3.8 to pH 2.4 the cubic
centimeters of 2J^ M NaCl required
for flocculation increased from 0.03 c.c.
atpH 3.8 to 1.3 c.c. at pH 2.4; from
then on it diminished again. Since
the pH in the alcoholic solution was
probably less than it would have been
in a solution free from alcohol, the
maximal stability of the gelatin in an
alcohol-water mixture was at a pH
greater than 2.4. These results are
difficult to explain on any other basis
than the Donnan equilibrium.

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264 THEORY OF COLLOIDAL BEHAVIOR

We conclude from these experiments that gelatin forms a
colloidal suspension in a mixture with much alcohol and little
water and that the stability of the suspension depends in this
case upon the forces set up by the Donnan equilibrium between
the micellae and the surrounding liquid, these forces being osmotic
pressure and P.D.

In aqueous solutions or in solutions with little alcohol and much
water the stability of the gelatin solution depends on forces which
have no connection with the Donnan equilibrium and which may
be the forces of secondary valency between gelatin ions or mole-
cules and the molecules of water which are supposed to be respon-
sible for the stability of crystalloidal solutions in general.

These forces of secondary valency do not cease to exist (though
they are weak) in solutions with much alcohol and little water,
and these forces may contribute also to the stability of the solu-
tion. This seems to be indicated by some of the data in Table
XL VIII. This table shows that M/10 NaCl precipitates gelatin
from the solution in much alcohol and little water. If the forces
due to the Donnan equilibrium alone determine the stability of
the suspension, a M/20 CaCl2 solution and a M/30 LaCl3 solution
should have the same effect, since only the anion acts in the case
of the Donnan effect when gelatin is positively charged. Table
XL VIII shows that the CaCl2 and LaCls solutions required for
precipitation are higher than M/20 or M/30, namely M/12 for
CaCl2 and M/ll for LaCla. This means that Ca and still more
La have an inhibiting effect on the precipitation. We have seen
that Ca and La increase the solubility of isoelectric gelatin in
water, i.e., they increase the forces of attraction between water
and gelatin (see Table XL VIII). It is possible that the inhibition
of the precipitating effect of Cl by La and Ca is due to the
augmenting effect of these cations on the solubility of gelatin in
water. This inhibiting effect on precipitation is often spoken of
as the peptization effect. While the precipitating effect is due to
the action of salts on the Donnan equilibrium, the peptization
effect seems to be due to the influence of salts on the secondary
valency forces between molecules of gelatin and solvent, in these
experiments at least.

A few remarks may be added concerning the precipitation of
crystalline egg albumin from aqueous solutions by salts at room

THE STABILITY OF PROTEIN SOLUTIONS 265

temperature. While the precipitation of solutions of sodium
alburninate and of isoelectric albumin requires enormous con-
centrations of salts, the precipitation of solutions of albumin
chloride of pH 2.0 or below is brought about by salt solutions of
much lower concentrations (e.g., M/2 NaCl, M/4 MgCl2, etc.).
This is, perhaps, connected with the fact that solutions of albumin
chloride become opalescent at high hydrogen ion concentrations,
and, therefore, assume more the character of suspensions.

The precipitation of albumin chloride by salts, from solutions
in much alcohol and little water, gives results similar to those
reported for the precipitation of gelatin chloride from solutions
in much alcohol and little water. The inhibiting action of the
divalent and trivalent cations was also observed in the case of
the precipitation of albumin chloride from alcoholic solutions.
The precipitation of Na alburninate by salts, from solutions in
much alcohol and little water, gives results similar to those
reported for the precipitation of Na gelatinate from solutions in
much alcohol and little water. The alcoholic albumin solutions
used were slightly opalescent, or in other words, they were no
longer solutions but primarily suspensions of micellae.

CHAPTER XV
THE STABILITY OF PROTEIN SOLUTIONS (Continued)

B. THE STABILITY OF SOLUTIONS OF CASEIN IN WATER1

Since isoelectric casein is practically insoluble in water it is
easy to study the mechanism of solution of granules of casein in
aqueous solutions of acid and alkali. When this is done it is
found that this mechanism is entirely different in the two media.
In an alkaline solution, e.g., NaOH, casein granules dissolve very
much as do particles of sodium oleate, the solution of which is
accompanied by phenomena of spreading. According to Quincke
such phenomena of spreading are due to a sudden lowering of
surface tension between the surface layer of soap and water,
whereby projecting small particles of the surface are torn off so
that the surface of the granules soon becomes smooth. This
happens in the case of casein granules in alkali. There is no
swelling noticeable in the particle.

The forces which drive the Na caseinate into solution are not
the forces of the Donnan equilibrium. If this were the case the
rate of solution of the granules should reach a maximum at a
pH of between 10.0 and 12.0 and should then diminish. As a
matter of fact the rapidity of solution increases indefinitely with
the pH of the NaOH. In M/2 NaOH the solution of the granule
occurs almost instantaneously. This agrees with the fact that
solutions of Na caseinate in water require very high concentra-
tions of NaCl or LiCl or NH4C1 for precipitation.

A Na caseinate solution of pH 7.0 was prepared containing
2 gm. of originally isoelectric casein in 100 c.c. solution. Five
cubic centimeters of this solution were added to 5 c.c. of solutions
of different salts also of pH 7.0. No precipitation was observed
when the concentration of NaCl in the caseinate solution was
M or that of LiCl was 3>^ M, or that of NH4C1 was 2 M.

1 LOEB, J., and LOEB, R. F., J. Gen. Physiol., vol. 4, p. 187, 1921-22.

266

THE STABILITY OF PROTEIN SOLUTIONS 267

Precipitation occurred in (NH^SCK when the concentration of
this salt in the casein solution was 2 M. Precipitation occurred
in low concentrations of CaCl2, namely M/128. In this latter
respect the solution of Na caseinate differed from a solution of
Na gelatinate in water. The facts indicate that the stability of
a solution of Na caseinate in water is not due to a Donnan
equilibrium.

It can be shown that the solution of granules of isoelectric
casein in HC1 depends on forces regulated by the Donnan equi-
librium and that the rule of Hardy is only a consequence of this
fact. This can be proven by microscopic observation of the
mechanism of the solution of solid particles of originally isoelectric
casein in solutions of acids of different concentration. It was
found that the particles of casein swell in a solution of HC1,
becoming more and more transparent the more they swell, and
that when the swelling has reached a certain stage, the particles
disappear — they are dissolved. When in the swollen stage,
slight agitation may make them fall apart. T. B. Robertson
had suggested such a mechanism for the solution t)f Na caseinate,
but we have seen that the mechanism of solution in this latter
case is different. There is no doubt, however, that the swelling
of casein particles is a necessary prerequisite for the solution of
casein-acid salts, since such particles are only dissolved when
their swelling exceeds a definite limit.

The method of procedure was as follows: A small number of
granules of isoelectric casein of the same size (going through a
sieve with mesh 100 but not through a sieve with mesh 120)
were put into 50 c.c. of water containing different quantities of
different acids and kept at 24°C. At various intervals, i.e.,
after 15, and 60 minutes, and 6, and 24 hours, the diameter of
about 15 grains was measured with a micrometer under a micro-
scope and the average diameter calculated. The particles were
not stirred, and care was taken to avoid their breaking into
smaller fragments. The averages after 1 hour are plotted in
Fig. 78. The abscissae are the logarithms of the concentrations
of acid of the aqueous solution, the ordinates are the average
diameters of the particles. It is obvious that the average
diameter of the particles increases at first with the increase of
the concentration of the acid, reaching a maximum at about pH

268

THEORY OF COLLOIDAL BEHAVIOR

2.0 of the outside solution, and with a further increase in the
concentration of the acid the swelling becomes less again.

Figure 79 gives the measurements of the same particles after
24 hours. At this time all the particles in the region of greatest
solubility for HC1 and for H3PO4, i.e., between pH of the outside

Swelling of casein
in different acids
at 24° C in 1 hour

Concentration of acids

FIG. 78. — Influence of different acids on the swelling of casein.

solution of 1.8 and 2.9, had completely dissolved and could no
longer be measured.

Figure 79 shows another fact; namely, that the rate of swelling
is not the same in different acids. It is about the same inHCl
and H3PO4 (for the same pH) but decidedly less in HNO3 and
still less in H2SO4 and trichloracetic acid. It was found that the
rate of solution of casein in these different acids followed closely

THE STABILITY OF PROTEIN SOLUTIONS

269

the rate of swelling. It took longer to dissolve casein in HNO3
than it did in HC1 (at 20°C.); and the casein was practically
insoluble in H2SC>4 and trichloracetic acid in 24 hours.

The rate of swelling is a function apparently not only of the
osmotic pressure inside the particle caused by the Donnan equilib-

2.5

N H H H
lOOD 500 200 100

Concentration of acids

Fio. 79. — Connection between swelling and solution of casein particles.

rium, but also of the force of cohesion between the particles.
Procter and Wilson have suggested that the rapid increase of
swelling of solid gelatin with a rise in temperature is due to a
corresponding diminution of cohesion between the molecules of
gelatin with rising temperature. The influence of the anionof
gelatin-acid salts on the cohesion of the particles of a solid gel is
apparently much smaller than the influence of the anion on the

270

THEORY OF COLLOIDAL BEHAVIOR

cohesion of particles of casein-acid salts. The forces of cohesion
in the case of casein sulphate and casein trichloracetate seem to be
so great that they cannot be overcome by the osmotic pressure
due to the Donnan equilibrium; and hence, no swelling (and as a
consequence no solution) of solid casein is possible in H2SO4 or
trichloracetic acid. The influence of valency on the Donnan
equilibrium is the same in the case of the swelling of casein and of

5.5

5.0

4.5

4.0

3.5

3.0

X

Depressing effect of
NaCl on swelling
and solution of
casein in acid

\

1524

Concentration of NaCl

I

FIG. 80. — Depressing action of NaCl on swelling and solution of casein in acid.

gelatin; what is different is the influence of certain ions on the
relative affinity of casein ions for water and for each other.

Procter and Wilson have shown that the theory of the Donnan
equilibrium explains the depressing effect of a salt on the swelling
of solid gelatin. Microscopic measurements of the influence of
NaCl on the rate of swelling of individual grains of casein particles
in M/100 HC1 were made at 24°C., and the results plotted in

THE STABILITY OF PROTEIN SOLUTIONS

271

Fig. 80. The ordinates are the average
diameters of the particles after 1 and 24 hours
respectively. The abscissae are the concentra-
tions of NaCl. The depressing effect is
similar to that found in the case of the swell-
ing of a jelly of gelatin. After 24 hours the
particles had dissolved in the NaCl solutions
of a concentration below M/256, but not in
concentrations of NaCl higher than M/256.

That the solution of casein chloride is thus
regulated to a large extent by the Donnan
effect was ascertained also by measurements
of the quantity of casein chloride dissolved
at 20°C. at various pH of the solution. One
gram of isoelectric powdered casein was put
into 100 c.c. of solutions of HC1 of different
concentration and kept in these solutions in
one case for 1 hour, in a second case for 22
hours. The mass was then poured into grad-
uated cylinders and the undissolved part was
allowed to settle to the bottom for 2 and for
6 hours respectively at 20°C. The super-
natant liquid was removed and the sediment
dried over night in an oven at about 100°C.
Table LI gives the result. The dry weight
of 1 gm. of isoelectric casein was found to be
0.870 gm. and this weight diminished by the
dry weight of the sediment was the amount
dissolved. Table LI shows that the rate of
solution increases with diminishing pH from
4.36 to 2.18 where the solubility of casein
chloride is a maximum ; with a further decline
in pH the solubility diminishes again. This
is in agreement with the Donnan effect.

In a similar way the depressing effect of
NaCl on the rate of solution of casein
chloride was ascertained (Fig. 80). Solutions
of 12.5 c.c. of 0.1 N HC1 in 100 c.c. and
containing 1 gm. of powdered, originally

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272

THEORY OF COLLOIDAL BEHAVIOR

isoelectric casein were prepared in 0, M/2,048, M/ 1,024, to
M/4 NaCl. The pH of a solution of 1 gm. of casein in 100 c.c.
containing 12.5 c.c. of 0.1 N HC1 was 2.12 and this pH was the
same in all solutions made up in NaCl. The solution was kept
at 20°C. for 16 hours and then allowed to settle for 24 hours at
20° in 100 c.c. graduated cylinders. The dry weight of the sedi-
ment was determined and this weight when deducted from the dry
weight of 1 gm. isoelectric casein, namely, 0.870 gm., was the
amount that had gone into solution after a correction was made
for the free NaCl held in 2 c.c. solution which was arbitrarily
assumed not to have been removed. Though this latter correc-
tion was somewhat arbitrary, it could have caused a noticeable
error only when the concentration of the salt solution exceeded
M/64. For the solutions of M/64 and below this error was
negligible. Table LII gives the number of milligrams of casein
which had gone into solution.

TABLE LII

Concentration of NaCl

M/2,048

M/1,024

M/512

M/256

M/128

M/64

Milligrams dis-
solved

714

685

665

615

449

282

The main fact is that a slight increase in the concentration of
NaCl causes a noticeable drop in the rate of solution. Thus,
M/1,024 NaCl causes a noticeable diminution in the solubility
of a 1 per cent solution of casein chloride of pH 2.12 at 24°.

These observations then indicate that the solution of solid
particles of casein chloride is brought about by the ultimate
elements being forced apart mechanically through the process of
swelling. The force acting in this swelling is the hydrostatic
pressure of the water which is forced into the interstices of the
solid particles by the osmotic pressure of the solution in the
interstices between the casein ions. Procter and Wilson have
shown that the application of Donnan's theory of membrane
equilibrium accounts quantitatively for this swelling on the
assumption that swelling is caused by the excess of the osmotic
pressure inside the gel over that of the surrounding solution

THE STABILITY OF PROTEIN SOLUTIONS 273

(Chap. XI). As soon as the osmotic pressure in the particle
exceeds the forces of cohesion between the casein ions of the
particle, the casein ions constituting the particle are separated.

The question then arises, How can the Donnan effect stabilize
the particles of casein chloride in solution, and how can we explain
the precipitating effect of low concentrations of neutral salts?
Let us assume that the ultimate particles in a solution of casein
chloride of pH 2.2 are, (a) isolated casein ions, (6) isolated casein
molecules, and (c) small casein aggregates or micellae. The
Donnan equilibrium furnishes two kinds of forces preventing
that degree of coalescence of these particles which is required for
precipitation; namely, the osmotic pressure and the membrane
potentials. When isolated protein ions collide and remain
attached to form a micella, a Donnan equilibrium is established
between the nascent micella and the surrounding solution.
The Donnan equilibrium demands that there be a higher con-
centration of electrolytes inside than outside and this difference
in osmotic pressure leads to water being attracted into the mi-
cella. The increase in hydrostatic pressure will force the protein
molecules apart again and thus tends to prevent the formation
of the micellae. Moreover, if micellae exist in the casein chloride
solution (aside from isolated casein ions and molecules) the coales-
cence of different micellae into larger aggregates must be prevented
by the potential difference between the micellae and the surround-
ing solution. As a consequence of this P.D., the micellae must
repel each other. This charge as well as the osmotic pressure
caused by the Donnan equilibrium is a minimum at the isoelectric
point, rises rapidly with increasing hydrogen ion concentration,
reaching a maximum, and diminishes again with a further increase
in hydrogen ion concentration as shown in a preceding chapter.
The osmotic pressure and charge are also diminished by the
addition of salt. In this case, both the osmotic pressure as well
as the P.D. are depressed, in accordance with Donnan's theory,
and when this depression reaches a certain degree the casein
particles coalesce. They will also aggregate without the addition
of salt at or near the isoelectric point where these forces due to
the Donnan equilibrium are also zero or sufficiently low.

These conclusions were supported by experiments on the pre-
cipitation of casein chloride solutions by salts. The concentra-

18

274 THEORY OF COLLOIDAL BEHAVIOR

tions required should be comparatively low and this was found
to be the case. One per cent solutions of casein chloride of pH
2.2 were prepared in different concentrations of salts in water of
about the same pH. That concentration was determined which
causes an almost instantaneous complete precipitation of the
protein from the solution so that the supernatant liquid became
as clear as water. These concentrations were as follows :

NaCl about M/8

NaNO3 about M/8

CaCl2 about M/8

Na trichloracetate about M/16

Na2SO4 about M/32

Though the results are only semi-quantitative, the validity of
Hardy's rule and the valency effect are easily recognizable. It
is also obvious that the concentrations of electrolytes required
for instantaneous, complete precipitation of casein chloride are
considerably lower than those required for the precipitation of
Na caseinate from their watery solution.

Hardy's rule, that only that ion of a neutral salt is active in
precipitation which has the opposite sign of charge to that of the
colloidal ion, and that the efficiency of the ion increases with the
valency, is simply the expression of the Donnan effect, as is also
the fact that very low concentrations of electrolytes suffice for
precipitation. The reader will notice that it is unnecessary to
assume that the ions are adsorbed by the casein or that the ad-
sorption of ions annihilates the electrical charges on the particles
of casein.

CHAPTER XVII

COLLOIDAL SUBSTANCES, COLLOIDAL STATE, AND
COLLOIDAL BEHAVIOR

Graham had suggested the distinction between colloidal and
crystalloidal substances, but it was found later that one and the
same substance, e.g., NaCl," may behave when in solution either
as a crystalloid or as a colloid. It then was proposed to drop the
distinction between colloidal and crystalloidal substances and to
distinguish between the colloidal and the crystalloidal state of
matter. The reasons are summed up in the following quotation
from Burton:

" Modern work has shown that it is incorrect to speak of colloidal
substances as a particular class. Krafft has observed that the alkali
salts of the higher fatty acids — stearate, palmitate, oleate — dissolve
in alcohol as crystalloids with normal molecular weights, but in water
they are true colloids. The reverse is true of sodium chloride; Paal
found that the latter gave a colloidal solution in benzol, while, of course,
it gives a crystalloidal solution in water (Karczag). More recently,
von Weimarn has demonstrated, by the preparation of colloidal solu-
tions of over two hundred chemical substances (salts, elements, etc.),
that, by proper manipulation, almost any substance which exists in
the solid state can be produced in solution, either as a colloid or as a
crystalloid; and that, as shown by many other workers, in some cases
it is merely a matter of the concentration of the reacting components
whether one gets crystalloidal or colloidal solutions.

''Consequently, we now speak of matter being in the colloidal state
rather than of certain substances as colloids — the essential character-
istic of the colloidal state being that the substance will exist indefinitely
as a suspension of solid (or, in some cases, probably liquid) masses of
very small size in some liquid media, e.g., water, alcohol, benzol, gly-
cerine, etc. According to the medium employed the resulting solutions
or suspensions are called, after Graham, hydrosols, alcosols,benzosols,
glycersols, etc."1

1 BURTON, E. F., The Physical Properties of Colloidal Solutions, 2d ed.,
pp. 8-9, London, New York, Bombay, Calcutta, and Madras, 1921.

275

276 THEORY OF COLLOIDAL BEHAVIOR

If we apply the conclusion drawn in this statement to the
proteins, it follows that we have no longer any right to insist
that proteins can form only colloidal solutions. If solutions of
gelatin and of crystalline egg albumin behave like crystalloidal
solutions in water and if gelatin solutions in alcohol behave like
colloidal solutions, we have no right to say that nevertheless
albumin and gelatin are in the colloidal state when dissolved in
water. Such an assumption is as arbitrary as to say that NaCl
is in a colloidal state when dissolved in water simply because it
is in a colloidal state when dissolved in benzol. The idea that
the two proteins mentioned must be* in the colloidal state when
dissolved in water is a survival from the time when it was custom-
ary to discriminate between colloidal and crystalloidal substances
instead of between colloidal and crystalloidal states, and the
terms emulsoids or hydrophilic colloids when applied to proteins
which require high concentrations of salt for their precipitation
are also a survival from that time. The fact that the molecules
of protein are large does not matter, since the chemical constitu-
tion of solute and solvent and not the mere size of the molecules of
solute determines the stability of their solution. The large size
introduces only interesting complications inasmuch as it makes it
possible that one and the same molecule may have groups with a
different degree of attraction for the molecules of water or solvent.

In Burton's statement just quoted only one colloidal property
is taken into consideration; namely, the stability of colloidal
solutions. We have seen, however, that as far as the proteins
are concerned there are a number of other properties of colloidal
solutions which are all as characteristic for colloids as are the
conditions for the stability of the solutions; and that as a matter
of fact the stability of colloidal solutions depends on these other
properties, such as the P.D. and the osmotic pressure. It is,
therefore, no longer possible to base our definition of colloids
exclusively on data derived from a study of the stability of
colloidal solutions.

The general characteristics of colloidal behavior may be stated
as follows :

1. Low concentrations of neutral salts depress the osmotic
pressure, P.D., viscosity, and stability of colloidal solutions and
the swelling of gels.

COLLOIDAL SUBSTANCES 277

2. This depressing effect of the salt is always due to that ion
which has the opposite sign of charge to that of the colloidal
particle.

3. The depressing effect increases with the valency of the
effective ion.

4. When the colloidal substance used is an amphoteric electro-
lyte the addition of little acid or alkali to the isoelectric substance
increases the osmotic pressure, P.D., viscosity, stability of the
solution, and swelling of gel until a point is reached where the
further addition of acid or alkali will have the opposite effect.

5. The depressing effect of an excess of acid or alkali is also due
to the ion which has the opposite sign of charge to that of the
colloidal particle, and the efficiency of that ion also increases
with its valency.

It is obvious that the stability of colloidal solutions is only one
of a number of properties which all possess the same characteristic
features. It has been shown in the preceding chapters that
all these characteristics find their explanation in the Donnan
equilibrium.

If, on the basis of this knowledge, we continue the mode of
reasoning expressed in the quotation from Burton, we come to the
further conclusion that it is no longer correct to discriminate
between the colloidal and the crystalloidal state of matter, for
the same substance may behave in the same state either like a
colloid or a crystalloid. We have seen that a 1 per cent solution
of crystalline egg albumin in water at room temperature and at a
pH much above 1.0 will behave like a colloid or as if it were in the
colloidal state in regard to osmotic pressure or in regard to P.D.
when separated from water by a collodion membrane; but the
same solution of crystalline egg albumin will behave like a
crystalloid or as if it were in the crystalloidal state in regard to
the stability of the solution and practically also in regard to
viscosity (as long as the temperature and the concentration of
the solution are not too high and the pH not too low) . The reason
for this is plain in the light of the preceding chapters. Proteins
(and, perhaps, substances in general) will show colloidal behavior
when the following two conditions are fulfilled: first, the sub-
stance must be capable of dissociating electrolytically, and second,
one of the two oppositely charged ions must be prevented from

278 THEORY OF COLLOIDAL BEHAVIOR

diffusing while the other is free to diffuse. In this case a Donnan
equilibrium is established resulting in an unequal distribution
of the diffusible ions on both sides of the membrane. The
forces resulting from this distribution of crystalloidal ions are
the only cause of those phenomena which are designated as
colliodal.

In general the block in the diffusion of one kind of ions can
be brought about by two kinds of conditions: first, by mem-
branes with a selective permeability; and, second, by the cohesion
between ions of one kind. An electrolyte which exists in a true
solution (and this is in all probability true for crystalline egg
albumin) will show colloidal behavior in regard to osmotic pres-
sure and to P.D. when separated from pure water by a membrane
which is permeable for all ions in the solution except one. More-
over, when ions of one type are attracted to each other with
greater force than they are attracted by the molecules of the
solvent, aggregates are formed, and when these aggregates are
permeable to other ions than those forming the aggregate, a
Donnan equilibrium is also established and colloidal behavior
follows again. This latter condition leads to the colloidal
character of swelling, viscosity, and of the stability of suspen-
sions. Since 1 per cent solutions of crystalline egg albumin are
very stable at room temperature and as long as the pH is not too
low, there are few or practically no aggregates in such a solution,
and the crystalline egg albumin behaves in regard to viscosity
and in regard to the stability of its solutions essentially as if it
were in the crystalloidal state. Of course, the proof has to be
furnished that crystalline egg albumin exists in the form of
isolated molecules in agneous solution. S0rensen has calculated
the molecular weight of crystalline egg albumin from measure-
ments of the osmotic pressure of this substance and has obtained
results which make this conclusion probable.1

The behavior of gelatin is especially interesting. Gelatin
solutions in water show colloidal behavior in regard to osmotic
pressure and P.D. when the solutions are separated from pure
water by a collodion membrane or by some other membrane with
similar selective permeability. Gelatin solutions in water show

1 S0RENSEN, S. P. L., Studies on proteins: Compt. rend. trav. Lab, Carlsberg,
vol. 12, Copenhagen, 1915-17.

COLLOIDAL SUBSTANCES 279

also colloidal behavior in regard to viscosity when the tempera-
ture is not too high, and this is due, as we have seen, to the exist-
ence in such solutions of submicroscopic particles of gel in which
the diffusion of the protein ions is prevented by the forces of
cohesion between the protein ions forming the gel. The degree
of swelling, and the relative volume occupied by these particles
in the solution is regulated by the Donnan equilibrium and, hence
the viscosity of a gelatin solution is also regulated by the Donnan
equilibrium ; in other words, the viscosity of gelatin solutions has
the peculiarities of colloidal behavior. Only in one respect do
the aqueous solutions of gelatin behave as if gelatin were in the
crystalloidal state, namely in respect to the stability of solutions.
It requires high concentrations of salts to precipitate gelatin
from its aquoues solutions and the sign of charge of the precipitat-
ing ion has no relation to the sign of charge of the protein ion.
Of course, it remains still to be proved that gelatin exists in
aqueous solution essentially in the form of isolated ions or molecules
and almost exclusively so if the temperature is above 35°C. This
proof can only be furnished if the calculations of the molecular
weight from osmotic pressure measurements are supported by
other measurements, especially by determinations of the chemical
constitution of the gelatin molecule. Dakin's1 analysis leads
to a molecular weight which is quite compatible with the results
from the osmotic pressure determinations (see Chap. X).

We have seen that solutions of gelatin in alcohol-water mixtures
behave like suspensions inasmuch as they can be precipitated
by low concentrations of salt and inasmuch as the precipitating
ion has now the opposite sign of charge to that of the protein ion.
When the gelatin solution is in this state, it differs in two respects
from a gelatin solution in pure water: it has a comparatively
low viscosity, and it no longer" sets to a gel. It is also, as a rule,
opalescent. The change in viscosity can be shown in the follow-
ing way.2

To 1 gm. of isoelectric gelatin enough HC1 is added so that in
a 1 per cent solution in water the pH would be about 3.0. This
gelatin is dissolved in mixtures of water and alcohol, heated
rapidly to 45°C., and cooled rapidly to 15°C. The time of

1 DAKIN, H. D., J. Biol. Chem., vol. 44, p. 499, 1920.

2 The following experiments have not yet been published.

280

THEORY OF COLLOIDAL BEHAVIOR

outflow through a viscometer is measured immediately at 15°C.
As a control the time of outflow at 15°C. of identical water-
alcohol mixtures but containing no gelatin is also measured. The
ratio of the time of outflow of the gelatin-water-alcohol mixture
to that of the water-alcohol mixture without gelatin, i.e.,
the relative viscosity of the gelatin solution, is given in Table
LIII. The upper horizontal row gives the relative amount of
alcohol in per cent, the second row the appearance of the solution,
the third the time of outflow of the gelatin solution in seconds,
the fourth row the time of outflow of the alcohol-water mixture
without gelatin, and the last row the relative viscosity of the

TABLE LIII. — INFLUENCE OF INCREASING QUANTITIES OF ALCOHOL ON THE

VISCOSITY OF A 1 PER CENT SOLUTION OF GELATIN CHLORIDE OF

ORIGINALLY pH 3.0

Concentration of alcohol in per cent

0

40

70

80

85

87.5

90

slightly

very

Appearance of solution

clear

opalescent

opalescent

opales cent

Time of outflow of gelatin

solution in seconds

207

266

506

362

229

185

163

Time of outflow of alcohol +

water, without gelatin

80

233

225

194

178

168

160

Relative viscosity

2.590

2.860

2.250

1.860

1.286

1.100

1.020

gelatin solution. It is obvious that the viscosity drops sharply
between 80 per cent and 85 per cent of alcohol, and that at 85
per cent, where the solution is already opalescent, the relative
viscosity is only 1.286 and only 1.1 for 87.5 per cent alcohol.

In a second experiment the same solutions were prepared but
the solutions were kept for 2 days in a thermostat at 9°C., the
mixtures were then rapidly brought to 15°C., and the viscosities
determined. The solution containing 60 per cent of alcohol or
less had set to a jelly; the solution containing 70 per cent was
almost solid, but the solutions containing 80 per cent or more were
all completely liquid. Their relative viscosity was measured
(Table LIV) and was found to be only slightly larger than at
the beginning, when the solution contained 85 per cent or more

COLLOIDAL SUBSTANCES

281

alcohol, while the viscosity had risen considerably when the
solution contained less than 80 per cent alcohol.

The opalescence of the alcoholic solutions indicates the pres-
ence of aggregates of gelatin, but since the relative viscosity of
these alcoholic solutions is low as compared with the viscosity of
solutions of gelatin in pure water, and since the alcoholic solutions
no longer set to a jelly, the micellae in the watery solution and in
the alcohol-water mixture, containing 80 per cent alcohol or
more, must be different. The fact that the viscosity ratio is
low in the opalescent gelatin-alcohol solutions (which no longer
can set to a jelly) indicates that the micellae in this solution

TABLE LIV. — VISCOSITY AT 15°C. AFTER THE SOLUTION HAD BEEN KEPT
AT 9°C. FOR 2 DAYS

Concentration of alcohol

80
per cent

85
per cent

90
per cent

Appearance of solution

slightly
opalescent

521.0

194.0

2.685

opalescent

247.0

178.0
1.390

very
opalescent

180.0

160.0
1.125

Time of outflow of gelatin solution in
seconds

Time of outflow of alcohol-water
mixture without gelatin

Relative viscosity of gelatin solution. . .

occlude less water than the micellae formed in the solutions of
gelatin in water (or in water with not too much alcohol) .

This is in harmony with the assumption (made in Chap.
XIV) that the forces which hold gelatin in solution in pure
water or in water with little alcohol, are different from those
which hold the gelatin in solution when the critical limit for
alcohol has been exceeded. In aqueous solutions or in solutions
with much water and little alcohol where setting of gelatin to a
jelly is possible, the molecules or ions of jelly are distributed
evenly in the solvent probably on account of the strong forces
of residual valency between solute and solvent. The large
gelatin molecules can adhere to each other only through those

282 THEORY OF COLLOIDAL BEHAVIOR

groups which have a stronger attraction for each other than they
have for the solvent. The other groups adhere strongly to the
solvent, and hence they cannot come in contact with each other
even when the gelatin sets to a jelly. When a 1 per cent solution
of gelatin sets to a gel the distribution of the gelatin molecules
in the solvent undergoes probably no profound change. What
may change is, perhaps, the orientation of the gelatin molecules
or ions towards each other, but not their average distance from
each other. When, however, too much alcohol is added, i.e.,
when the solution is on the alcohol side of the critical point, the
forces of attraction between gelatin and solvent are weakened
to such an extent that the groups which were formerly attracted
by the solvent are now more strongly attracted to each other than
they are to the molecules of solvent. In the micellae thus formed
the protein ions or molecules are in much closer contact than they
are in a jelly, and hence they occlude much less water than the
micellae formed in pure water or in mixtures of water with little
alcohol. The latter micellae increase the viscosity of the solution
more than the micellae formed in an excess of alcohol. The gelatin
would be precipitated in the latter solutions if it were not for the
fact that the coalescence of the protein ions and molecules- is
prevented by the forces set up as a consequence of the Donnan
equilibrium, namely, forces of osmotic pressure and of P.D., as
stated. When, however, a small quantity of salt is added the
forces set up by the Donnan equilibrium are diminished and
nothing now prevents the forces of attraction between the
gelatin molecules from causing the separating out of the gelatin
from solution. It should also be recalled that at the isoelectric
point not only the P.D. but also the osmotic pressure of protein
solutions is a minimum and that salts depress the osmotic pres-
sure as well as the P.D.

The fact that a Donnan equilibrium is established between
micellae and surrounding liquid, whereby the opposite ions of
electrolytes are distributed in a definite way between the two
constituents, makes it clear why in the case of precipitation of
colloids some of the precipitating electrolyte must be found in the
precipitate, and that there can, as a rule, be no stoichiometric
relation between the quantity of salt and the mass of protein in
the precipitate.

COLLOIDAL SUBSTANCES 283

We can form, on the basis of what has been said, a more
definite picture of the difference between gel formation and pre-
cipitation. When gelatin is dissolved in pure water or in much
water with little alcohol, probably only one of the groups of the
gelatin molecule has a greater affinity for other like groups
than for the molecules of water, while all the other groups of the
gelatin molecules have much stronger affinities for water than
for each other. Hence in this state the gelatin molecules can
form networks by their "oily" group (i.e., the groups with little
affinity for water), the "oily" group of one molecule adhering to
an "oily" group in the neighboring molecule. The rest of the
groups of these molecules must, however, remain separated,
since their "watery" groups (i.e., the groups with strong affinity
for water) cannot adhere to each other. The result is a network
in which the distribution of the molecules in the water is not
disturbed, since the forces of attraction between the "watery"
groups of the protein molecule and the molecules of water will
prevent the molecules of gelatin from attracting each other
except at the one "oily" group. Since the "watery" groups
prevail in bulk over the oily group of the gelatin molecule or
ion, a solid network or a gel formation results instead of pre-
cipitation. Under these conditions we observe the gel form
of micellae. In a solution with much alcohol and little water
(i.e., on the alcohol side of the critical point) the situation becomes
reversed. The forces of attraction between the "watery"
groups and the solvent — which is now mainly alcohol — are weak,
and since they form the bulk of the gelatin molecules the latter
will attract each other in many points, thus causing a close con-
tact over a wide area and this gives rise to the precipitation form
of the micellae. On the other hand, the few "oily" groups of the
gelatin molecule may now be attracted by the alcohol and this
may aid in stabilizing the solution; but at the best these forces
must be weak.

In the case of crystalline egg albumin the forces of attraction
between the watery group and the molecules of water are very
strong and the mutual attraction of the oily groups for each
other must be very feeble, since no gel formation occurs at ordin-
ary temperature, low concentration, or a pH above 1.2. When,
however, the temperature or the hydrogen ion concentration is

284 THEORY OF COLLOIDAL BEHAVIOR

sufficiently raised, a change occurs — nobody knows of what
nature — in the molecule, the solutions become opalescent and
the albumin may set to a solid gel. In this case "oily" groups
must be activated or formed which were not active or did not
exist before and their natural attraction must cause the gel
formation.

In the case of casein solutions in acid all the properties of the
solution, stability, viscosity, osmotic pressure, and P.D., possess
colloidal character. The forces of attraction between the mole-
cules or ions of casein on the acid side of the isoelectric point for
each other are very strong and for the water molecules compara-
tively feeble. In the case of casein chloride or casein phosphate
and to a lesser extent casein nitrate, they are just strong enough to
make a solution possible ; but the stability of the solution depends
largely on the forces set up by the Donnan equilibrium between
the nascent micellae or the existing micellae and the surrounding
solution. In the case of casein trichloracetate or casein sulphate
the forces of mutual attraction between the casein molecules for
each other are so much greater than those for water that these
two salts are practically insoluble. On account of this great
attraction for each other the granules of casein cannot swell in
sulphuric acid or trichloracetic acid. Solutions of Na caseinate
behave like crystalloidal solutions in regard to stability but like
colloidal solutions in regard to viscosity, P.D., and osmotic
pressure.

This shows the complications which may be due to the large
size and complex constitution of large molecules, especially of
proteins. The problems of gel formation or of precipitation are
not colloidal problems, they are a part of the more general prob-
lem of solubility. These problems enter only in a secondary
way into the problem of colloidal behavior, since the phenomena
of aggregation are only a means of preventing the diffusion of an
ion, thereby creating the conditions for the establishment of a
Donnan equilibrium.

We now understand why it is not correct to define colloidal
solutions as solutions in which the ultimate unit is a micella,
i.e., an aggregate of molecules or ions. The colloidal behavior of
solutions of salts of crystalline egg albumin in regard to osmotic
pressure and P.D. is only due to the non-diffusibility of the pro-

COLLOIDAL SUBSTANCES 285

tein ion through the collodion membrane and depends in no way
upon the existence of micellae. The existence of micellae could
only diminish the value of the osmotic pressure and of the P.D.
The results of our work lead to the conclusion that there is only
one source of colloidal behavior, namely, the Donnan equilibrium,
at least as far as the proteins are concerned. Without a Donnan
equilibrium there can be no colloidal behavior of proteins. A
Donnan equilibrium will always arise when the diffusion of one
kind of ions is blocked while the diffusibility of oppositely charged
ions is unrestricted, regardless of the nature of the block restrict-
ing the diffusibility and regardless of the nature of the ion the
diffusion of which is prevented.

The writer hopes that the methods, experimental results, and
theoretical conclusions described in this book may be found of
use not only in the study of the colloidal behavior of other
substances than proteins but also in physiology. Life phenomena
cannot be dissociated from colloidal behavior, and the idea of an
organism or of living matter consisting exclusively or chiefly
of crystalloidal material or material with purely crystalloidal
behavior is inconceivable. Organisms have been defined as
chemical machines consisting essentially of colloidal material
capable of growing and automatically reproducing themselves.1
If this be true, advance in physiology will be chiefly a hit or miss
game until science is in possession of a mathematical theory of the
colloidal behavior of the substances of which living matter is
composed. If Donnan's theory of membrane equilibria furnishes
the mathematical and quantitative basis for a theory of colloidal
behavior of the proteins, as the writer believes it does, it may be
predicted that this theory will become one of the foundations on
which modern physiology will have to rest.

. J., "The Dynamics of Living Matter," New York, 1906.

INDEX

Adsorption formula, 3

theory, 10-13, 119, 157
"Adsorption compounds," 88
Aggregation hypothesis, 15-17, 113,

119, 241
Alanine, 197

Albumin, crystalline egg, combina-
tion curves of, 46, 47
conductivity of, 118
crystalloidal and colloidal be-
havior of, 278, 282
heat coagulation of, 252
influence of concentration of, on
osmotic pressure, 187, 188
osmotic pressure of, 43-45
P.D. of, 145-148
precipitation of, 244, 252, 265
preparation of, 43-45
stoichiometrical behavior of, 40,

44-49, 60, 61
titration curves of, 44, 60
viscosity of, 198-202
Alcoholic solutions of gelatin, 279
micellae of gelatin in alcoholic
and aqueous solutions, 280
precipitation, 251-255, 258-261,

263-264
prevention of gel formation in,

281

viscosity of, 280
Allmand, A. J., 22
Amino-acids, 197
Aniline, 8

Anomalous osmosis. 158, 164
Arrhenius, S., 196, 201, 203, 204,

212, 227, 230
Ash-free gelatin, 35, 36

B

Baker, J. C., 52, 53, 222
Bancroft, W. D., 12, 110
Beutner, R., 166-168
Blood albumin, 13, 115
Born, M., 19, 118, 197
Brakeley, Miss, 197
Bredig, 11

Bugarszky, S., 4, 32, 41
Burton, E. F., 11, 275, 276, 277

Cane sugar, influence of, on vis-
cosity, 109
Casein, crystalloidal and colloidal

behavior of, 284
isoelectric point of, 9
osmotic pressure of, 72, 236
precipitation of, 266-274
preparation of, 52, 53
solubility of, 71, 86, 193, 222,

251, 266-272
stability of, 266
stoichiometrical behavior of, 54,

55

swelling of, 222-229, 267-272
titration curves of, 54, 61
viscosity of, 86, 87, 221-230
Cells and tissues, P.D. of, 166-168
Chlorine ion potentials, 135-137
Clark, W. M., 4, 43
Coagulation, heat, of egg albumin,

252
Collodion membranes, preparation

of, 67
Colloidal behavior and living matter,

285
causes of, 277, 278

287

288

INDEX

Colloidal behavior, characteristics

of, 1, 112, 276, 277
solution, 2, 3, 8
state, 2, 275-285
substances, 275
Colloids, classification of, 243

and crystalloids, difference

between, 1-6, 112, 275
"hydrophilic," 243
"hydrophobic," 243
"lyophilic," 243
"lyophobic," 243
Combination curves, albumin and

acids, 46, 47
gelatin and acids, 51
Compton electrometer, 120, 121,

154, 155, 159
Conductivity, of albumin solutions,

118
of gelatin solutions, 38, 116,

117

Contraction, muscular, 111
Crystalloidal behavior of proteins,

277, 278

and colloidal behavior of, albu-
min, 278, 283
casein, 284
gelatin, 278, 283

J)

Dakin, H. D., 63, 187, 279
Donnan, F. G., 19, 22, 119, 130
Donnan's membrane equilibrium,

12

application of, 127-149
theory of, 19-26, 123-125

E

Edema, 111

Egg albumin, see Albumin.

Ehrenberg, 25

Einstein, A., 196, 201, 202, 203, 210,

211, 212, 230
Electrical charges of micellae, 9, 12,

150-168

Electrical endosmose, 164, 165

field, migration in, 6
Electrolytes in precipitation of

proteins, 282

Electrolytic dissociation, 41
Emulsion, 11
Emulsoids, 243
Euler, 198

Fibrin, swelling of, 106, 107

Field, A. M., 36

Film formation of proteins, 165

Fischer, 76, 77

Flocculation, see Precipitation.

Freundlich, H., 3

Friederithal, H., 4, 9

Garner, W. E;, 22

Gel formation and precipitation,

difference in, 283
Gelatin, calculation of P.D. of, 124,

125, 130-133

combination curves of, 51
conductivity of, 38, 116, 117
crystalloidal and colloidal be-
havior of, 278, 283
curve for observed P.D.-of, 122
effects of salts on rate of solution

of, 245-251

influence of concentration of,
on osmotic pressure,
184-187

on P.D., 145, 146
isoelectric point of, 9
osmotic pressure of, 38, 68-70,
73, 169-188, 233-235,
256-257
of mixtures of liquid and

powdered, 236-238
P.D. of, 120-149, 256, 257
precipitation of, critical point
of alcohol concentration in,
253-255

INDEX

289

Gelatin, precipitation of, from alco-
holic solutions, 251-255,
258-261, 263-264
from aqueous solutions, 244,

245

stability of, 243
stoichiometrical behavior of, 40,

49-52, 55-59, 62
swelling of, 38, 76-82, 189-194
titration curves of, 50, 59, 62
viscosity of, 38, 82-86, 90-99,
198, 201, 203, 204, 213-221
of mixtures of liquid and

powdered, 238-241
Gelatin suspensions, effect of salts

on, 157-166

electrical charge of, 152-154
influence of acid and alkali on,

155-157

influence of pH on, 155
stability of, 150-152
viscosity of, 206-212
Glass, 3
Globulins, 7, 8
Glycocoll, 8, 197, 198
Graham, T., 1, 2, 10, 113, 275

H

Hardy, W. B., 6, 7, 8, 10, 11, 16, 37,
150, 151, 155, 163, 243,
261, 267, 274

Hardy's rule of precipitation, 144
Hatschek, E., 196, 212
Heat coagulation, 252
Hedestrand, G., 198
Hildebrand, J. H., 43, 48
Hirschf elder, A. D., 106, 111
Hitchcock, D. I., 35
Hober, R., 14, 111
Hofmeister, F., 13, 14, 25, 65, 76
Hofmeister ion series, 13, 25, 65-87,

99-111

in osmotic pressure, 65-76
in swelling, 76-82, 105-107
in viscosity, 82-87, 99-104
Hooke's law, 190
19

Hydration theory, 17-19, 114-119,

130, 197, 230
Hydrogen ion concentration, effect

of salts on, 101, 106
influence of, on charge of sus-
pended particles, 155
on conductivity, 117, 118
on osmotic pressure, 68-76,

172-179, 234, 237
on P.D., 122, 126-129, 131,

134

on swelling, 76-82, 222, 227
on viscosity, 83-87, 99, 198,
199, 207-209, 213, 216,
225, 226, 234, 240
Hydrogen ion potentials, 135-137
"Hydrophilic" colloids, 243
"Hydrophobic colloids, 243

Isoelectric point,, conception of,

6-10
method of determining of,

37-39
of casein, 9
of gelatin, 9
of oxyhemoglobin, 9
of proteins, 6
of serum albumin, 9
of serum globulin, 9

K

Karczag, 275
Kohlrausch, 19, 114, 118
Kossel, W., 33, 41
Krafft, 275
Kruger, K., 62

Langmuir, I., 3, 33, 41, 250
Laqueur, E., 17, 89
Lewis, G. N., 41
Lewis, W. C. McC., 12
Liebermann, L., 4, 32, 41

290

INDEX

Lillie, R. S., 14, 16, 66, 88, 89, 179
Linder, 11, 16, 163, 261
Loeb, R. F., 193, 195, 243
Lorenz, R., 19, 118, 197
"Lyophilic" colloids, 243
"Lyophobic" colloids, 243

M

MacDonald, J. S., 166

Manabe, K, 69, 115

Matula, J., 69, 115

Membrane equilibrium, application

of, 127-149

theory of, 19-26, 123-125
Membrane potentials, 120-149

calculation of, 125, 130, 131
explanation of curves of, 127-

132
method of measuring, 120-

122
of solutions of egg albumin,

145-148
action of neutral salts on,

148
of solutions of gelatin, 120-

149
action of neutral salts on,

139-144, 256, 257
influence of concentration

on, 145, 146
influence of pH on, 122,

126-129, 131, 134
influence of sign of charge

on, 144
influence of valency on,

132-135

Membranes, preparation of collo-
dion, 67
Mica, 3
Micelhe, 2, 12

as units of colloidal solutions,

284, 285
origin of electrical charges of,

150-168

Michaelis, L., 4, 9, 11, 37, 43, 116
Migration of particles, 6-9, 37, 114

Moore, A. R., Ill
Mostynski, B., 116

N

Naegeli, 2, 113

Nernst formula, 21, 25, 124, 125, 137

Neutral salts, action of, 88-111,

139-144; 157-166
curves for, 91-96, 98, 100,

102, 104, 105, 107, 180,

183, 217, 219, 220, 246,
248, 249, 257, 262

on osmotic pressure, 88, 179-

184, 257, 262
on P.D., 139-148

on precipitation, 244, 245,

251-255, 258-261, 266-274
on rate of solution of gelatin,

245-251
on swelling, 105-107, 228,

229, 271-272
on viscosity, 90-100, 102-104,

210-212, 217-220
Northrop, J. H., 32, 36

Occlusion theory of viscosity, 212,

230
Oil, 11

Osborne, T. B.t 4
Osmotic pressure, 65-76, 169-188,

232-242
action of salts on, 88, 179-

184, 256, 257, 262
curves of, 180, 183,257,262
curves of, albumin-acid salts,

71

calculated, 173, 177
casein-acid salts, 72
gelatin-acid salts, 68, 73,

174, 177, 234, 237
metal albuminates, 75
effect of heating of solution

on, 233-235

influence, of cane sugar on, 109
of concentration of protein
on, 184-188

INDEX

291

Osmotic pressure, influence of pH
on, 68-76, 172-179, 234,
237
of valency on, 65-76, 172-

179, 256, 257

of mixtures of liquid and
powdered gelatin, 236-238
theory of, 168-172
Ostwald viscometer, 82, 195, 200
Ostwald, Wo., 76, 77
Oxy hemoglobin, 9

Paal, 275

Pauli, W., 4. 13, 17, 18, 19, 27, 32,
69,74,88,89,114-116,118,
130, 197

Pekelharing, C. A., 36
Pepsin digestion, 36
Perrin, J., 7, 151, 165
Picton, 11, 16, 163, 261
Platinum, 3
Potential differences, between solid

gel and solution, 152-154
of cells and tissues, 166-168
see Membrane potentials.
Powis, F., 11

Precipitation, 10-13, 113, 243-274
critical point of alcohol con-
centration in, 253-255
effect of valency in, 258-261.

274

of casein, 266-274
of egg albumin, 244, 252, 265
of gelatin, in alcoholic solutions,
251-255, 258-261, 263, 264
in aqueous solutions, 244, 245
Preparation of proteins, 27-36
Procter, H. R., 3, 23, 24, 25, 62, 63,
124, 130, 143, 169, 170, 189,
190-192, 269, 270, 272
Proteins, isoelectric point of, 9, 37-

39

preparation of pure, 27-36
stability of solutions of, 243-274
titration experiments with, 40-
64

Quincke, 266

Q

R

Reyher, R., 17

Ringer, W. E., 36

Robertson, T. B., 4, 25, 32, 230, 267

Sackur, O., 17, 32, 89

Schulze, 11, 16, 163, 261

Serum albumin, 9

Smith, C. R., 36

Smoluchowski, M., 196, 204, 205.

212
Solubility, of casein, 71, 86, 193,

222, 251, 266-274
of gelatin, effect of salts on,

245-251
S0rensen, S. P. L., 4, 9, 28, 32, 42,

43, 45, 147, 244, 278
Stability, of protein solutions, 243-

274

of suspensions, 150-152
Stoichiometrical behavior, of albu-
min, 40, 44-49, 60, 61
of casein, 54, 55
of gelatin, 40, 49-52, 55-59,

62

Surface tension, 11
Suspensions of gelatin, effect of salts

on charge of, 157-166
electrical charge of, 152-154
influence of acid and alkali

on, 155-157
influence of pH on charge of,

155

stability of, 150-152
viscosity of, 206-212
Suspensoids, 243
Swelling, 76-82, 189-194

curves for, 38, 79, 80, 81, 222
effect of salts, 105-107, 228, 229
curves for, 105, 107

292

INDEX

Swelling, influence of pH on, 76-82,

222, 227
of valency on, 76-82, 105-

107

of casein, 222-229, 267-272
of fibrin, 106, 107
of gelatin blocks, 76
of powdered gelatin, 38, 77-82
theory of, 23-26, 189-194

Titration, 5, 40-64

for bromine, 38, 39, 55-57
with NaOH, 56
Titration curves, albumin in acids,

44, 46

in alkalies, 60
casein in acids, 54

in alkalies, 61
gelatin in acids, 50, 59
in alkalies, 62

U

Ultramicrons, 3
Urea, 8

Valency effect, 13-15, 65-87, 99-111,

132-135, 172-179, 256-261

on osmotic pressure, 65-76,

172-179, 256, 257
on P.D., 132-135
on precipitation, 258-261
on swelling, 76-82, 105-107
on viscosity, 82-87, 99-104
Van Slyke, L. L., 52, 53, 222
van't Hoff, 169
Viscosity, of albumin solutions,

198-202, 205
curves for, 199-200
influence of, concentration on,

200

pH on, 198, 199
temperature on, 205
of amino acids, 197, 198
of casein solutions, 86, 87,
221-320

Viscosity, of casein solutions, curves

for, 87, 225, 262
influence of, pH on, 86, 87,

225, 226

valency on, 86, 87
of gelatin solutions, 82-86, 198,

203, 204, 213-221
curves for, 38, 83-85, 198,

201, 213, 215, 216, 221
effect of salts on, 90-100,

102-104, 217
curves for, 91-96, 98,
100, 102, 104, 217,
219, 220
effect of standing on, 213-

220
influence of, cane sugar on,

109
concentration on, 201,

203, 204
pH on, 83-86, 198, 213,

216, 221, 240
temperature on, 201, 215,

219-221

valency, 82-86, 99
of gelatin suspensions, 206-212
curves for, 207-210
effect of salts on, 210-212
influence of pH on, 207-209
of mixtures of liquid and pow-
dered gelatin, 238-241
theory of, 195-231

W

Weimarn, von, 275

Werner, A., 32, 33, 41, 42

Wilson, J. A., 3, 23, 24, 62, 63, 124,
130, 143, 151, 170, 189, 190,
191, 192, 269, 270, 272

Wilson, W. H., 3, 190

Wintgen, R., 62

Wood, T. B., 8, 10

Zsigmondy, R., 2, 3, 5, 11, 76, 77,
113, 204, 205

UNIVERSITY OF CALIFORNIA LIBRARY
BERKELEY

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