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DEPARTMENT OF. COMMERCE
| _ BUREAU OF FISHERIES
* HUGH M, SMITH, Commissioner

- PRINCIPLES. INVOLVED IN
THE PRESERVATION OF FISH BY SALT

By HARDEN F. TAYLOR
Chief Technologist
U.S. Bureau of Fisherses

APPENDIX Il TO THE REPORT OF THE U, S. COMMISSIONER
OF FISHERIES FOR 1922

Bureau of F isheries Document No, 919

PRICE, 5 CENTS —

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DEPARTMENT OF COMMERCE

.2 . BUREAU OF FISHERIES
HUGH M. SMITH, Commissioner

PRINCIPLES INVOLVED IN
THE PRESERVATION OF FISH BY SALT

By HARDEN F. TAYLOR
Chief Technologist
U.S. Bureau of Fisheries

APPENDIX II TO THE REPORT OF THE U. S. COMMISSIONER

OF FISHERIES FOR 1922

Bureau of Fisheries Document No. 919

PRICE, 5 CENTS

Sold by the Superintendent of Document Government Printing Office
Washington, D.C.

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GOVERNMENT PRINTING OFFICE
1922

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PRINCIPLES INVOLVED IN THE PRESERVATION OF FISH
BY SALT.’

By HARDEN F. TAYtLor,

Chief Technologist, U. S. Bureau of Fisheries.

Contribution from the Fishery Products Laboratory, Washington, D. C.

CONTENTS.

Page.
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et eR Waren lbh OSCE VCS 55 203 yo oe 9 ed ee a Es eh, 2
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Dryvesaline and brine salting compared: 2<+-—- 255+ 2b. seat 9
Mosse DV HSheoOr WU ents) tr pipes ses. Se Fake Ne? PT ca pe ee es ae iaL
Influence of method of cleaning fish on salting_________________________ 13
Improved method of salting fish especially for warm weather___________ 15
SOTA ETT SO EG dS APS Tere Ta Ce ie hg gi DY a a i Ae ae aM age er 16
TUROPEI RAI eTe ea SCTE OD eee aac Aron 2 the ee foie ae ee 16
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Accessory chemical agents and other factors in salting_________________ 20
OPEL SITTS ast A ee Se Re OS oS os dt Ad ee eae a 21
SUPpNaT erey Le bs ee a SR 7 ES a TRACERS TOPE Oe EO ere eee eee te eee Poi

INTRODUCTION.

The art of preserving fish by means of salt is of great antiquity.
It was practiced by the Phoenicians and Greeks and was brought to
a high degree of perfection by the Romans. Mixed with spices, salt
was used for the preservation of food on the shores of the Mediter-
ranean and the outlying country in the time of Christ, reference being
made in the Sermon on the Mount to a salt which has lost its savor,
meaning a salt in which the spices have lost their aroma by evapora-
tion. In the centuries following the art continued, both in the Occi-
dent and the Orient, to play an important part in world economy.
Shakespeare put in the mouth of his most wonderful character, Fal-
staff, the words: “If I be not ashamed of my soldiers, I am a soused
gurnet ”*—a pickled gurnard, the gurnard being held in such light
esteem that it was a term of contempt. ‘Whether “sousing” or pick-
ling made the fish doubly contemptible had better be left to the phi-
lologists to determine. ‘Less than 25 years after Shakespeare wrote
that play the Plymouth Colony landed in America and brought with

1 Appendix II to the Report of the U. S. Commissioner of Fisheries for 1922. B. F.
Doe. 919.
2 King Henry IV, pt. 1, Act IV, Scene II.

1

2 U. S. BUREAU OF FISHERIES.

them the arts of sousing and pickling fish. The descendants of the
Pilgrims are still pickling fish around Cape Cod and particularly
at Gloucester. ,

To a great many people it may seem that science has contributed
little or nothing to the improvement of methods of preserving fish
by salt. Perhaps this view is shared by a considerable number of
people who are engaged in the business of salting fish. To them it
may appear that salting fish is just salting fish, and “that’s all there
is to it.” It may be admitted readily that science has not so per-
vaded and dominated the fish-pickling industry as it has other an-
cient arts, but it has contributed something and is capable of con-
tributing a great deal more, and here hes the purpose of this paper.
That purpose is to present the rationale of salting and pickling fish,
so that the reasons for the various steps and modifications will be
readily understood and appreciated, to the end that the art may be
practiced more intelligently and successfully. It is a further pur-
pose of this paper, by showing what the few attempts made by
science have done for the art, to convince and persuade those on |
whom the industry depends for its existence and progress that science
can be expected to do a great deal more than it ever has done if it
is energetically studied and applied.

HOW SALT PRESERVES.

Salt preserves by extracting water. Spoiling is a series of chem-
ical activities for which water is necessary; remove the water and
spoiling is arrested. ‘The removal of water by means of salt is in
some senses a truer dehydration than actual drying in air, for changes
of an undesirable sort take place in air drying that are never cor-
rected, while salting may be done in such a way that few changes
other than removal of water are brought about. The statement that
salt preserves by extracting water is to be taken strictly and lter-
ally, for salt has no peculiar preserving or antiseptic quality, as
many people seem to think. Things live, die, and putrefy in the sea,
which is one-tenth saturated with salt. But by sufficient concentra-
tion salt, an otherwise almost inert, harmless substance, becomes a
powerful preservative, merely because, if concentrated sufficiently,
it extracts water.

The process of transferring water from one place to another, as
from the inside of a fish to the outside, under the influence of con-
centrated solutions, is known to physicists and chemists as osmosis.
This principle of osmosis is of almost universal application in
nature and is used by men in the arts, but a good understanding of it
is not common. By osmosis our food is taken from the intestines
to the blood without any communicating opening. By osmosis
oxygen is taken from the air into the blood without any leakage
of blood. By the same principle the kidney tubules remove unde-
sirable substances from the body while holding back all desirable
substances. By osmosis the roots of plants select the necessary
minerals from the soil. A weak sugar solution will readily ferment,
but if made concentrated it destroys yeast and bacteria by osmosis
and is therefore an excellent preservative of fruits. Salt is also a
preservative by virtue of its concentration. Any other neutral min-

=

PRESERVATION OF FISH BY SALT. 3

eral substance equally soluble would preserve in the same way that
salt does, but salt happens to be the only one that the human palate
and stomach will tolerate.

HOW SALT EXTRACTS WATER.

At the risk of appearing verbose the writer undertakes to elucidate
the principles that govern osmosis, because osmosis is nearly the
whole principle of salting fish. Without a knowledge of osmosis
people may salt fish successfully by rule, but without such a
knowledge it is quite impossible to understand the process.

If a thin animal skin or membrane separates two liquids and if
the liquids are alike and of the same concentration, nothing happens.
But if they are unlike and of different concentration, one or the
other or both of the liquids will pass through the skin to the other
side. This passage through the skin or membrane is called osmosis.
Just what components pass through the membrane, in what direc-
tion, and how much depend on many circumstances. For the pur-
poses of salting fish water is always the liquid, plus whatever is
dissolved in the water. The dividing membrane is the skin of the
fish and the membranous inclosures of the microscopic cells of which
the substance of the fish is composed. We thus have water and salt
outside, cell membrane between, and fish juice, or protoplasm, in-
side, and we desire to know what will happen and how we can in-
fluence the process to suit our needs. The quantity and direction
of flow through the skin or cell membrane will depend on (1) the
nature of the dividing membrane, and (2) the nature and quantity
of the substances dissolved in the water on each side.

The nature of the dividing membrane will be considered first.
Almost any substance can be made into a thin film or membrane.
Such things as glass, tin-foil, and mica may be exceedingly thin,
but are totally impermeable and therefore uninteresting in the pres-
ent connection. But other membranes or films, such as parchment
paper, gelatin films, animal bladders, and goldbeater’s skins are
permeable to a greater or smaller degree. Suppose pure water were
on one side of a membrane and water containing dissolved salt on
the other. If the membrane is perfectly permeable to all constitu-
ents, water will pass through to the salt solution and salt will pass
through to the water, and these movements will continue until the
two sides are alike and then stop. It is always the tendency for
the two liquids to come to equilibrium, and they would do so if the
membrane were perfectly permeable. Nearly all membranes, how-
ever, permit a freer flow of the solvent, in this case water, than they
do of the solute (that which is dissolved), in this case salt.

If the membrane permits the water to flow but absolutely prevents
passage of a dissolved substance, the membrane is said to be semi-
permeable. In the example taken above, of pure water on one side
and salt solution on the other, if the membrane were semipermeable
then the water would pass through to the salt solution, but the salt
could not get through to the water. The level of the pure water
would fall and that of the salt would rise. The difference in liquid
level would exert a pressure called osmotic pressure. Ideally semi-
permeable membranes are not realized in nature, though some of the

4 U. S. BUREAU OF FISHERIES.

membranes in plants and animals approach ideal semipermeability
while they are living. Ideal semipermeability with respect to par-
ticular dissolved substances has been achieved and is found in living
organisms.

It is to be remembered that in case of semipermeable membranes
the solvent will flow from the less concentrated to the more concen-
trated side of the membrane, so that if we wish to extract water we
need only to make the outside more concentrated than the inside. If
we wish to add water, we make the outside less concentrated than the
inside; that is, we use pure water outside, as has sometimes been done
unfairly to swell oysters and make them appear “ fat.”

It is also to be remembered that the degree of permeability of mem-
branes does not necessarily remain unalterable. The permeability
of the membrane can very readily be changed, as will be seen later.
There is reason for believing, for example, that the permeability of
fish to salt increases after death—for stale fish strike through more
quickly than fresh fish—and that permeability increases at tempera-
tures near the freezing point of water.

The tissues of fish consist mostly of cells. Each cell is a bag of
semiliquid, like the white of egg. The surface of every cell either is
or acts like a semipermeable membrane. If we surround the cell with
water, the inside will be more concentrated than the outside and
water will go in. If we surround the cell with strong salt solution,
water will pass out to the salt. Some salt will also pass into the cell,
which fact shows that the cell wall is not ideally semipermeable.

But what of the protein within the cell? Why does it not come out
while the salt is going in? In order to answer these questions it is
necessary to pass from a consideration of the nature of the mem-
brane in osmosis to a consideration of the nature of the dissolved
substance.

By a great many experiments it has been found that some dissolved
substances never pass through membranes under any circumstances,
while others will pass through some membranes. It is found that
those which never pass through are also those which on drying out
do not crystallize but shrink to a tough mass. They are called col-
loids. Examples of them are glue, albumen, gelatin, and soap. The
smallest possible particle of these substances is comparatively large,
too large, we may imagine, to go through the texture of the mem-
brane. They are not only large of molecule but complex in structure.
The bulk of animal bodies consists of colloids called proteins, dis-
solved in water. The other class of substances, those that may pass
through membranes and which on drying out crystallize in regular
geometrical shapes, are the crystalloids. Examples of this class are
salt, sugar, and like substances. It is not to be supposed, however,
that all crystalloids will pass with equal facility through any given
membrane. Nearly all membranes are in some measure selective of
particular crystalloids. The ideal semipermeable membrane permits
none to pass, but as membranes degenerate from ideal semipermea-
bility to complete permeability they permit more and more of these
dissolved things to pass through.

The phenomena of osmosis having been briefly reviewed, one may
readily perceive the importance of applying the principles to the
salting of fish. Salt is brought in contact with the exterior of the

-

PRESERVATION OF FISH BY SALT. 5

cell. It dissolves in some of the moisture, forming a saturated solu-
tion. This solution is separated from the contents of the cell by a
cell membrane which is more or less semipermeable. Water passes
out of the cell to the salt and the processes of decay are stopped be-
cause of insufficiency of water. The membrane, not being absolutely
semipermeable, permits some salt to enter and the fish remains salty.
The contents left in the cell are proteins or the valuable food ele-
ments of the fish which, being colloids, are not permitted by the cell
membrane to pass out. Thus water is extracted, salt enters, and the
fish is preserved.

When the time comes to eat the fish the process is exactly reversed.
The fish is bathed in pure water. The cell contents are more con-
centrated than the exterior, so water passes in. The cell membrane
is to some extent semipermeable, so the protein does not escape, but
the salt does. This exchange is carried to a point where the meat is
again plump and a sufficient quantity of salt has been removed.

Thus by exposing the meat of fish to salt we have removed the
water and caused some salt to enter the meat and have stored the
fish. We have then by exposing the fish to water put water back
in the cells and taken out the excess salt. The actual food material
of the fish—the cell protein—is still where it was, for practical pur-
poses unchanged. If every step has been scientifically correct we
have at the end very nearly the fresh fish we had to start with. But
there is the rub. At every turn it is possible to depart from the
scientifically correct. The principles of osmosis here very briefly
stated are the fundamentals of the art of salting fish. In all that
follows there will be frequent occasion to refer to osmosis.

FACTORS AFFECTING PERMEABILITY OF FISH.

The preservation of fish by salt is practiced extensively in the
cooler parts of the United States, but very little has been done south
of Chesapeake Bay. The reason fish have not been salted in the
warmer parts of the country is that the process has not been satis-
factory. Repeated efforts to salt alewives on the St. Johns River in
Florida previous to 1920 uniformly resulted in failure. In 1918 re-
search on this problem was undertaken under the immediate direction
of the writer. The results of a part of this program were published.*

The hypotheses which guided this work were somewhat as follows:
During the course of “striking through” the fish two things are
happening—(1) the flesh is breaking down by autolysis (a process
to be explained later) and (2) the salt is penetrating the flesh. Salt
arrests autolysis when it arrives, but considerable damage may be
done before the salt has reached the innermost parts of the fish. Now,
these two processes—salt penetration and autolysis—are running a
race,so to say. If the salt penetrates to the innermost parts before
autolysis has destroyed them, the salt wins the race and the fish is
saved. If before the salt can get to the innermost parts they have
been decomposed by autolysis to an intolerable degree, then autolysis
wins and the fish spoils. High temperatures accelerate both proc-
esses, but while accurate measurements have not been made we know

° Tressler, D. K.: Some Considerations Concerning the Salting of Fish. Appendix IV,
Report of the U. S. Commissioner of Fisheries for 1919, 55 pp. B. F. Doc. No. 88+.
Washington, 1920.

6 U. S. BUREAU OF FISHERIES.

by practical experience and by experiment that at a sufficiently ele-
vated temperature the fish will invariably spoil if blood be present.
Now, to make certain that the race mentioned shall always be won
by the salt, we may do one of two things, namely, retard the rate of
decomposition or accelerate the penetration of salt. Working at a
lower temperature is the only practicable means of retarding de-
composition, but since we desire a method suitable for warm climates
it is necessary to accelerate penetration of salt. How can the salt be
caused to penetrate fish more rapidly ?

The physiologists have shown that in living animals compounds of
calcium, barium, and magnesium have a marked effect in retarding or
arresting penetration of membranes. By examination of numerous
analyses of commercial brands of salt it was found that the salts of
calcium and magnesium are those nearly always present as impurities.
A few of these analyses are given herewith:

ANALYSIS OF VARIOUS SALTS FoR CurING FisH.t

| : Leslie
Turks | Trapani, Iviza, Diego Velvet
Substauces present. Island Italian | Spanish domesine Grain,

salt. salt. salt. salt. | Califor-

. nia salt.

Per cent. | Per cent. | Per cent. | Per cent. | Per cent.

Sodium chloride....... oehosoap Don Peet cee eee oc seen 96. 52 95. 82 98. 05 99.78 99. 96
Calenimichlonide: jn 4592. fA eA OME ac S| Be .32 SAD IL. 248233 eS ee
Calgiumsfilphatesisscc-e28= 254 eee een pee UROS Ts sdeboora | cose sen e 37 - 067

Mapnestum chloride 7 323. eee na caosen eases cee 1. 20 1 En th Aneseaoess - 00 - 00
Maenésiumsulphate. e2) -as253 7-8 ee eek ee . 80 1.75 . 80 00 - 010
DANGNOtC Haas os seins ars Coe cee nes see oe eee on ee -13 415 . 06 . 00 . 022

1 These figures represent analysis of single samples of each brand taken in the market and are not aver-
ages of numerous samples. Not only is some variation in manufacture unavoidable, but the chemical
determination of such small quantities ofimpuritiesis subject tosmallerrors. Therefore it should not be
expected that any purchased lot of salt would conform exactly to the composition shown here. The
figures represent in a general way the degree of purity that can be expected.

By appropriate methods of measuring the rate of penetration of
salt into fish it was found that if absolutely pure salt is used a very
rapid penetration is obtained, but that even small additions (from
3 to 5 per cent) of these salts of calcium and magnesium cause
a very pronounced retardation of penetration. For example, by
appropriate methods of analysis it was found that pure salt pene-
trated as deeply in less than five and one-half days as did salt con-
taining 1 per cent calcium chloride in nearly seven days. Similarly,
a salt containing 4.7 per cent magnesium chloride penetrated no far-
ther in five days than pure salt did in three. In order to bring about
a much more rapid penetration of the tissues then, we have but to
obtain a salt free from these impurities. The time gained by the use
of pure salt enables fish to be salted at a much higher temperature
and yet not spoil. Fish were salted in an incubator room in Wash-
ington at a temperature of 90° F. at first, rising to 100° F.—the
hottest summer weather. No unpleasant odor developed, and the fish
upon being cooked and eaten were pronounced excellent.

There was a further and somewhat unexpected difference between
the effects of pure and impure salts. The flesh of the fish salted by
impure salt is white, opaque, or chalky in appearance and much
harder or firmer in consistency; that of fish salted with pure salt is
translucent and somewhat yellowish and much softer. While the
former white, firm fish is the customary quality demanded in com-

PRESERVATION OF FISH BY SALT. rf

merce, there are strong reasons for believing the softer and yellowish
fish produced in pure salt to be superior. There is reason for be-
lieving that the whitening of the fish in impure salt is explained by
the fact that the calcium coagulates the protein, just as heat by coagu-
lating egg white causes it to be white and firm. But where there is
no calcium in the salt the protein retains its natural translucency and
yellowish color. The calcium in impure salt is retained by the fish, a
matter that will be discussed later under the subdivision on flavor of
salted fish.

While no investigations appear to have been made on the influence
of temperature on the permeability of fish flesh, investigations have
been made on a great variety of other living things, so that it is prob-
ably safe to generalize cautiously regarding such influences on fish.
Osmotic pressure varies, approximately, as absolute temperature.*
That is, if we double absolute temperature osmotic pressure is doubled,
other factors being held constant. The range from 32 to 100° F.
within which fish salting is usually done is, on the absolute scale,
rather narrow (491.4 to 559.4° A.), so the maximum variation due
to this cause would be about 14 per cent. It is, however, a com-
mon experience in pickling fish that the warmer the temperature the
more rapid the striking through, a difference too great to be accounted
for by temperature variations of osmotic pressure. The cell mem-
brane itself must change. Whether any more free permeability
caused by warm temperature is permanent after the fish is chilled
again is not known, but the question would be well worth investi-
gating. Cold, when in the neighborhood of freezing, also promotes
permeability, as has been proved by various experiments. It is quite
possible that fish chilled to a point near freezing (as in the mild cur-
ing of salmon) would strike through much more quickly than fish at
the customary warmer temperatures. This matter also should be
investigated.

Stale fish—that is, fish whose cell membranes have “ died ”—are
more permeable than fresh fish. Some fish were held in the labora-
tory all day at a temperature of about 75° F. and toward night were
salted in pure salt and put in an incubator at 100° F. By the next
day they were struck through. The combination of stale fish, high
temperature, and pure salt brought about extraordinarily rapid
penetration.

At this point mention should be made of another effect of salt
upon the protein constituents of fish. Strong solutions of salt pre-
cipitate certain protein substances, different substances falling out
successively from a mixture of dissolved proteins as the’ concentra-
tion of salt is iricreased. The nature of the proteins is not altered
by this precipitation, for upon replacement of the salt solution with
fresh water the proteins redissolve and appear to be restored to
their original condition. Salt thus causes a temporary precipita-
tion or fixation of proteins in fish, to ascertain extent hardening the
tissues and reducing the likelihood of changing. Not only does
quite pure salt penetrate the fish more rapidly, but when the time
comes to cook the fish it is found to soak out more rapidly also.

Practical experiments in the experimental kitchen of the Bureau of

OI Ee —Ee—————E—E——EE—E—eee EE nnn

4 Absolute temperature is based on absolute zero, the point of no heat, or absolute
cold, which is —273° C. or —459.4° F. If we use degrees the same size as Fahrenheit’s
degrees, then 0° F. is 459.4 absolute; 50° F. is 459.4 + 50—=509.4 absolute, ete.

77635°—22 2

tS

ro) U. S. BUREAU OF FISHERIES.

Fisheries indicate that fish preserved in very pure salt soak out in
bom a third to a half the time required by fish preserved in crude
Salt.

What is the practical lesson of this work? It shows that by the
judicious selection of salt, not on the basis of its cheapness but on the
basis of composition, one can produce a salt fish of almost any
desired quality. If salting is to be done in very warm weather it
will be necessary to use the purest grade of salt to secure very rapid
penetration. In this way a soft, yellowish fish of excellent quality
is obtained. Where weather is cool enough to permit, a salt contain-
ing more calcium and magnesium may be used, in which case a
whiter and firmer fish will be produced.

Can these very pure salts be obtained commercially? Several
brands of salt of the highest degree of purity are available both on
the east and west coasts and at a cost not much above the price of
cruder salt. In many cases the single item of fish saved that might
otherwise spoil will repay the extra cost of pure salt, te say noth-
ing of the improvement in quality of the salt fish.

FLAVORS OF SALT FISH.

The calcium and magnesium are taken up by the protein in the
cells and held, not coming out when the fish is soaked. Now, these
impurities, particularly calcium, have an acrid taste and greatly
accentuate the “saltiness” of salt. Pure salt is not so “salty” to the
taste as crude salt. If the calcium is held by the tissues at the time
of soaking out while the salt is removed, then after soaking there is
a much greater amount of calcium present in proportion to the
amount of sodium than there was in the original salt and a corre-
spondingly more acrid “salty” taste. It is therefore necessary to
soak out fish much longer or until they are “ flat” if they have been
cured with crude salt, while with pure salt they may be soaked out
until they suit the taste, after which they retain their original flavor.

Certain improvements in the flavor of fish have been noted after
they have been salted by improved methods. The fish variously
known as mud shad or gizzard shad (Dorosoma cepedianum) 1s
plentiful in certain parts of the country but is held in very low esteem
because of its muddy, unpleasant flavor. After being washed free
from blood and salted in pure salt this unpleasant flavor disap-
peared and the fish compared favorably with fish commonly more
esteemed. The muddy taste of the carp and other fish from muddy
ponds and streams is believed by some to be caused by species of
Oscillatoria, a blue-green alga growing in the slime of the fish; by
others it is believed to be humic acid derived from the mud. Per-
haps the two views could be entirely reconciled, but the actual
chemical compound or compounds responsible for the unpleasant
flavor seems to be removed by the brine.

It is not difficult to understand how the alteration of taste may
be brought about by salting. The main bulk of the fish, pure protein
and pure fat, is believed to be tasteless and odorless. The substances
which give rise to taste are free fatty acids (decomposition products
from fats), amino acids (decomposition products of proteins), highly
odoriferous methylamines, and various waste materials classed by
the chemist as purines. ‘The absolute quantities and also the relative
proportions of these materials vary from_species to species of fish,

PRESERVATION OF FISH BY SALT. 9

and they even change in the same individual fish as staleness de-
velops. Now, most of these odoriferous substances are soluble in
water or brine, and after the salting process would be found in the
brine. They are not replaced when the fish is soaked out. It might
therefore be anticipated, as has actually been found, that the fresh
fish, disagreeable because of the presence of strong substances, are
rendered sweet by the removal thereof in the salting process.

If this lead were followed in detail, it is quite possible that salting
would turn out to be the best method of utilizing fishes that are of
a rather poor edible quality when in the fresh condition. This aspect
of the matter deserves particular attention of the canners. Man
species of fish of great abundance might in time be profitably packed
if the flavor were inviting. With highly improved technique in
salting, the undesirable flavors might be removed by curing and
soaking out before canning. This process would be unthinkable on
the basis of the customary salting methods where there is in the
end an excessive saltiness or flatness of flavor, but the mild, sweet
fish prepared by improved technique and pure salt is a much more
promising possibility for canning.

DRY SALTING AND BRINE SALTING COMPARED.

The next question taken up in the investigations referred to was
that of the relative merits of the application of the salt to fish in
the dry state and as a concentrated brine. In the Chesapeake Bay
region the herring are usually pickled in brine. By a strict compari-
son of the two methods it was found that there is developed a smaller
quantity of the products of decomposition—the amino acids—when
the salt is apphed dry. Not only this, but it was also found that salt
applied in the dry condition penetrates the fish more rapidly.

Among the products of protein decomposition are amino acids.
A determination of amino acid nitrogen was taken as a measure of
decomposition—the more of the amino acid nitrogen present the
greater the amount of decomposition. This being true, the following
table, summarized from Tressler’s results, will show the superiority
of dry salt over strong brine for preserving fish.

AMOUNTS OF AMINO ACID NITROGEN FORMED PER KILOGRAM OF FISH AT DIFFERENT
TEMPERATURES.

Amount of amino acid nitrogen per

Tie kilogram of fish after— Condition
Method of salting. pera- ates of
ture. 19 67 acnlee:
atari ieticss 5 days. | 7 days. | 9 days.

° F. | Grams.| Grams.|Grams. |Grams. | Grams.
nymiauassst.. 22.2 at. 63 0.078 { 0.083] 0.085] 0.085] 0.119 | Good.
IbminosAltens 24. cock - ba. sds 3420-25. 63 - 084 . 129 =135 . 183 . 234 Do.
TOPGEAR Fart epee SR Sia el aie ea ae ee 70 . 084 . 086 . 098 .097 . 126 Do.
rinacnlenees tir. he lille AS: 7 -100| .165| .158] .190| .292 Do.
Dry salted........ Oe Bene ee Cee eee Be 13:5 -077 . 092 099 . 104 .134 | Fair.
Mo sene dens sa sea te ene ee eee ee io) 7ae5 . 102 . 186 -179 . 228 -316 Do.
EINHEL OUR feng ao oy eee ESET Sia 80 . 074 - 086 .119 - 141 . 158 Do.
“BOTS 020 [eS ne ae 80 . 086 . 189 . 210 . 300 . 383 | Spoiled.
Drysatteu c2be 2. fo. Ake! yb ttt 24 87 . 076 . 089 . 159 . 195 . 208 Do.
Lee 73 5 a, i Pek, oe sae 87 . 097 . 244 . 266 .377 .510 Do.
rvinasioaerssese t 2tibe ss Sk es: 93 . 065 105 151 . 193 . 236 Do.

IBrimnewalfede acca. cr ok bebe. es. Sees: 93 - 080 . 238 - 320 - 465 . 666 Do.

LO U. S. BUREAU OF FISHERIES.

It is seen that the brine-salted fish consistently undergo a greater
decomposition than those salted with dry salt, as shown by the
abundance of decomposition products, amino acids. The average
excess of amino acid nitrogen in the six lots pickled in brine over
the six lots in dry salt is 51 per cent, a very material difference. It
will be noticed in the last column of the table that spoiling of fish
pickled in brine takes place at a lower temperature than it does in
dry salt. Fish were satisfactorily salted in dry salt at 80° F., but
at this temperature fish pickled in brine spoiled.

To complete the evidence in favor of using dry salt, the following
table from the same paper shows the rate of penetration of salt into
squeteague when applied dry in comparison with brine:

PENETRATION OF SALT.

Percentage chlorine in dry sample after—
Method of salting. Section of fish. ‘il
1 day. 4 days. | 7 days. | 10 days.

Dry salied sat pence eee aee | Outer layer, from surface to a 9.8 16, 2 19.6 19.5
depth of } centimeter.

Do es eee Inner layer, from 3 to 1 centi- 2.6 11.0 16.0 18.7

meter below surface.
Baile Salted 2929 S:63 9-2-8222) Outer layer, as above...-..-.. 8.4 15.3 17.3 17.8
ta)

Aaiison ees aebe. ees asa | Inner layer, as above.-.....--- 1.8 8.3 1222 15.7

What is the reason for the superiority of dry salt over strong
brine or pickle, especially since the dry salt very shortly forms its
own pickle? In answer to this question it is necessary to refer to the
principles of osmosis. It was shown that the flow of water is from
the less concentrated to the more concentrated. The relative con-
centrations govern the direction of flow and also the rate or quantity
of flow. Salt is going into the fish and water coming out. If brine
is used, it is losing some of its salt which penetrates the fish and is
being diluted with water which is coming out. This process rapidly
brings the contents of the cells into equilibrium with the brine; that
is, with the film of brine immediately in contact with the fish. Stir-
ring as usually done may cause a momentary increase of penetration
by removing the film of dilute brine adjacent to the fish, but we may
imagine that a new dilute film forms again very rapidly. If instead
of brine dry salt is placed in contact with the fish very material dif-
ferences are at once apparent. Part of the salt dissolving in the
free moisture forms strong brine, which begins its extraction of water
from the fish. The water coming from the fish is not able to dilute
the adjacent brine, because some of the excess of dry salt present
immediately dissolves, and thus assures saturated brine at all times.
It should also be obvious that since the very purpose of using salt
on fish is to extract water the addition of water at the beginning
simply supplies just so much water to the salt and satisfies the
affinity of salt for water to that extent. The water should come from
the fish and not elsewhere.

To put into words the conclusions from this section of the paper,
when salt is applied dry to the fish there is a more rapid penetration
of salt, less decomposition of fish, and it is possible to preserve fish

PRESERVATION OF FISH BY SALT. 11

at a higher temperature. The superiority of dry salt over brine
resides in the fact that the brine in contact with the fish is not per-
mitted to be diluted if salt is present in crystalline condition.

LOSS-BY FISH OF NUTRIENTS IN BRINE.

The liquid that comes from fish during the salting process is not
pure water, as every fisherman knows, but contains a quantity of
material derived from the fish. Most of the nitrogenous matter
found in brine represents just so much good food gone to waste and
just so many pounds of fish that might have fetched a good price
gone overboard. The quantity of protein that escapes into the brine
is highly variable, for reasons that will appear later. That some
idea may be had of the magnitude of the loss of fish substance in
brine the following figures are given. These figures were obtained
in the course of investigation on the recovery of valuable materials
from old brine:

Loss By FIsH oF NuTRIENT MATERIALS IN BRINE.

Grams | Avoirdu-
Ves ry pois
Brine. protein | ounces
per liter per

of brine. | gallon.

PARAS OMITIN GE ELONT ALASKA caren cose eos eens atin «oes ae on Hits wee ce ate sence a 29. 30

3.9
SPER DD TIPE TONE Act OU COSCCL ser ote eee gs orcas oe Sen Slee nee saa ei see ease 34. 80 9.8
Mana ibrinednan Gloncester.p15 i toe yc sods eee! YE 23 5 85. RS et | 73.30 4.6

Since all the nitrogen in the brine was calculated as protein, these
figures are undoubtedly too high; but the bulk of the nitrogen is cer-
tainly of protein origin, so the figures may be taken to illustrate the
point made. If we assume fresh fish to be 75 per cent water and 25

per cent dry protein and express the results in customary units, the
_ figures show the equivalent amount of food-fish flesh dissolved in
brine to be 15.6, 39.2, and 18.4 ounces, respectively, or from 1 to 24
pounds to the gallon of brine. Bitting® calculated the losses in the
curing of codfish as follows: Loss of weight in dressing, 40 per cent;
loss in salting, 40 per cent of what remained after dressing; drying
on flakes, 9 per cent of the salted fish. The 40 per cent of the dressed
fish contains besides water much protein or valuable nitrogenous food.
It would certainly seem to be worth our while to examine into the
causes of this loss and to prevent or salvage it if possible.

How does this protein get out of the fish? It was said above that
protein is a colloid and that colloids do not diffuse through mem-
branes. A small amount must come from the blood and from the cut
surface on the fish, but most of it will probably be found to’come from
the interior cells by a process not yet investigated. We do know
something directly about autolysis, however, the great enemy of the
fish dealer, which liquefies the contents of fish flesh, and we have
every reason to believe that if autolysis were stopped the losses of
protein into brine would be reduced toa minimum. What is autolysis
and how does it do its damage?

5 Bitting, A. W.: Preparation of Cod and Other Salt Fish for Market, U. S. Depart-
ment of Agriculture, Bureau of Chemistry, Bulletin No. 133, 63 p. Washington, 1911.

12 U. S. BUREAU OF FISHERIES.

Protein, the colloid, can not pass through an osmotic membrane,
but proteins can be decomposed into simpler substances which readily
dissolve and pass through. The agency which breaks down protein
into these simpler substances is called an enzyme, and protein must
always be so liquefied or digested by enzymes before it can be ab-
sorbed through membranes; hence the necessity of digestion in the
stomach of animals preparatory to absorption of food through the
intestines. Now, animals, including fish, require a certain amount of
new protein to support the body activities, which, failing, the animal
would immediately perish. But the hazards in the existence of any
animal often make it obligatory to do without food for a shorter or
longer period. If the stomach became empty because of temporary
shortage of food or an injured mouth, the animal would die unless
special provision were made to supply protein from some other source.
But nature has provided a means whereby the proteins in the less im-
portant parts of the body can be used for the time being to support
the activities of the absolutely necessary vital parts. The stored pro-
tein is within cells and could not possibly be carried by the blood
stream to the point of need unless it could get out. So there is in
each cell stored along with the protein some enzyme ready in case of
threatened starvation to break the protein down into simpler sub-
stances which penetrate outward into the blood for transportation to
the point of need. Fish may thus live for a time at the expense of
their own bodies.

These enzymes, present in every part of the fish, while almost an
absolute necessity to the living fish, become the greatest enemy of
the dead fish, for they soften and liquefy the cell contents, cause
unpleasant tastes and odors, and permit the contents to escape from
the cell into brine. The proteins could not escape as long as they
were proteins, but when they are broken down by autolysis into sim-
pler substances the latter rapidly diffuse into the brine and are lost.
This at least is the hypothesis, supported by some facts.

What factors promote autolysis and what factors oppose it?
Warm temperatures promote it directly. A temperature sufficiently
high to destroy the enzyme stops it. Low temperatures retard it
directly.

If cells are ruptured, as they often are by rough handling of the
fish, autolysis rapidly decomposes the protein, and for this reason
every bruise received by the fish during capture and subsequent han-
dling results in the loss of so much protein during salting. A bruise
on a fish has about the same effect as does a bruise on an apple, pro-
moting rapid decomposition. Perhaps if the bruised fish turned _
brown, as the bruised apple does, the fisherman and packer would
be more caveful in the handling of their fish.

Factors that increase permeability of membranes seem to promote
autolysis. Low temperatures seem to increase the permeability of
the cells, so that fish that have been chilled decompose more rapidly
on being warmed than fish that have never been chilled, though as
long as the fish remain on ice the low temperature may prevent the
enzymes from doing their work. It is as if increased permeability
increases the escape of the enzymes, and that once escaped they play -
havoc if temperature conditions are allowed to become favorable.
The optimum temperature for autolytic activity is about human body

=

PRESERVATION OF FISH BY SALT. 13}

temperature, 98° F. The autolytic enzymes act under a slightly acid
condition. In neutral or alkaline medium they act very little, if at
all. It has been noticed by various investigators that autolysis does
not begin until two to four hours after death. During rigor mortis
there is a decided development of acid that may very materially pro-
mote autolysis. It may therefore be that salting fish immediately
after capture would strike through the fish before autolysis gains
any headway. It may be possible, also, to take advantage of the
- removal of soluble products by brine in the salvaging of fish on the
point of spoiling. Fish that have been held a long time are soft
and of a disagreeable odor, because autolysis and possibly some bac-
teria have decomposed the tissues to some extent.

One might reasonably expect research to show that if rapid pene-
tration is secured by means of pure salt the amino acids and other
sour or disagreeable substances in stale fish resulting from autolysis
would be removed by changing brine a few times, leaving the fish
in a condition quite wholesome and fit for food. It is, of course, not
intended here to encourage the practice of holding fish until they are
bad and then salting them, but it is recognized that it is in the
public interest neither to destroy food that can be used nor to mar-
ket fish unfit for food, and it is recognized as legitimate and desirable
to develop a means of saving fish whenever they have, through the
unavoidable exigencies of the fishing business, come near to spoiling.

It would not be profitable to present this complicated subject any
further here. Enough has been said to show that the loss in salting
fish by solution of protein in brine is very great. Some discussion
has been presented which will serve to show that losses of this kind
are preventable, to point out the probable direction in which the
remedy for this great loss will be found, and also, we hope, to assist
in convincing the skeptics that scientific work on this aspect of the
salting process would be worth while. It is of the greatest impor-
tance that research work be undertaken for the purpose of discover-
ing the conditions under which the cell proteins are digested and
pass out and for ascertaining the conditions under which these proc-
esses may be arrested. Specifically, such questions as follow should
be answered: Once the permeability of cells has been increased
by abnormally high or low temperature, does this increased per-
meability persist after a normal temperature has been restored?
When autolysis is set in action by a bruise, do autolytic enzymes
affect only the part bruised or do they escape and attack the unin-
jured cells, destroying them also? To what extent does the acid of
rigor mortis accelerate autolysis, and can this acceleration be pre-
vented by early application of salt? To what extent is loss of solu-
ble material in brine due to rough handling and to what extent to
other factors? Can advantage safely be taken of the removal of
products of protein decomposition by brine to salvage fish that are
on the point of spoiling? s

INFLUENCE OF METHOD OF CLEANING FISH ON SALTING.

In the various processes of salting or pickling fish the fish receive
no preliminary treatment, or they may be gibbed, beheaded, split
through belly, split through back, or cleaned perfectly by being cut

14 U. S. BUREAU OF FISHERIES.

open, scraped, and washed before the salt is applied. By what cri-
teria can we judge the merits of these various methods? The best
way to answer this question is: Other conditions being held con-
stant, which method or methods of cleaning result in least decom-
position during the salting process?

A series of trials was made by cleaning the fish by the various
methods and salting them by the same process and determining the
amounts of amino acid nitrogen developed. Two sets complete were
tried, one consisting of one sample each cleaned by the various
methods and held at a temperature of 79° F. during the salting
process; another set similar to the preceding but held at 88° F.
during the salting process. Both temperatures are high for salting
fish, and the test is correspondingly severe. The results are shown
in the following table, which is abbreviated from the paper by
Tressler : -

DEVELOPMENT OF AMINO ACID NITROGEN IN FISH CLEANED IN VARIOUS WAYS.

[Fish salted four hours after capture, with Diamond Flake salt containing 99.78 per cent sodium chloride; ’
salting period, nine days.]

Amino
acid
nitrogen
Average | formed
tempera-| during Condition of fish at

Method of cleaning. ture of | salting end of period.
salting. | period
per kilo
of fresh
fish.
Seah Grams
Wo‘cleaning salted round! 2Ce- eee ates asasee. Sse 79 0.77 | Badly spoiled, bloated.
Lia 0 012.6 Poppe, agers een ee Serrano OT ten ae RE ened os 79 -63 | Spoiled.
Head cut off, abdominal cavity split open, viscera, except 79 - 68 Do.
milt and roe, removed.
Cleaned periedy, milt and roe removed, kidney and mem- 79 .37 | Excellent condition.
branes scraped, and all blood washed out.
No cleanings saliediround 9: 2a ee sen eee ae eee 88 1.12 | Badly spoiled, bloated.
IPIpped ss PF 2 isa. = eens ao dew nee eae ee eae nee aeeee eee reeee 88 .76 | Badly spoiled.
Head cut off, abdominal cavity split open, viscera, except 88 . 82 0.
milt and roe, removed.
Cleaned perfectly, milt and roe removed, kidney and mem- 88 .47 | Excellent condition.
branes scraped, and all blood washed out.

Since amino acid nitrogen indicates decomposition, the conclu-
sions from this table are entirely obvious. Only those fish were
successfully salted at temperatures of 79 and 88° F. which had been
thoroughly cleaned and from which all blood had been removed.
While these high temperatures were chosen for the test: because severe
tests bring out differences in a more striking way, the differences will
still exist even at lower temperatures and manifest themselves in the
poorer or better quality of product. Now, it may be either the blood
or flesh, or both, in which the decomposition takes place. Since the
perfectly clean fish decompose only slightly, it may be that only the
blood decomposed in such cases as those given in the table, and that
the decomposed blood pervading the otherwise sound tissue gave the
appearance and odor of decomposition to the whole fish. On the
other hand, it is possible that the enzymes in the blood when present
operate to decompose not only the blood proteins but the tissue pro-
teins also. However, this may be, the indisputable fact remains
that if fish are to be salted in very warm weather it is absolutely

PRESERVATION OF FISH BY SALT. 15

obligatory that the blood be removed. The blood can not be re-
moved by mere eviscerating and rinsing in water. The kidney, a
very bloody organ inclosed by a membrane against the backbone,
must be scraped out before the fish is washed. If fish is cleaned in
this manner and salt of a very pure quality applied in the dry con-
dition, it is astonishing not only what severe temperatures it will
stand, but also how excellent it is when cooked.

IMPROVED METHOD OF SALTING FISH ESPECIALLY FOR WARM
WEATHER.

Several factors have now been shown to have a marked influence
on the quality of fish pickled in salt, namely, care in handling before
salting to prevent bruises, use of salt free from calcium and mag-
nesium (less than 1 per cent total impurity), packing in dry salt,
and thorough cleaning and removal of kidney and blood. By com-
bining all these factors into one method highly satisfactory results
under the most adverse conditions have been obtained.

A trial of the method was made in the herring season of 1920
(March, April, and May) on the St. Johns River, Fla. This region
was selected because it offered a combination of the conditions sought.
The climate is excessively warm, and there is an abundance of fish
(alewives) adapted to preservation by pickling in a region where an
industry might well be built up and where repeated efforts to salt
fish in the past had failed. Accordingly, the interest of local fisher-
men and dealers was enlisted to cooperate in the undertaking, and an
experienced fish packer from the Chesapeake Bay region was sent
to Florida, after he had been thoroughly instructed in the technology
of the process, to try salting by the proposed method on a small
commercial scale.

The details as conveyed to the fishermen for handling the fish were:
(1) Avoid (a) bruising the fish in removal from gill nets, (6) walk-
ing on, and (c) piling deep in boats; (2) salt as soon as possible;
(3) wash and scale in cold water; (4) behead and eviscerate and (a)
scrape out kidney or (6) split nearly through to the back and la
open; (5) wash in weak brine to remove all traces of blood; (6) ru
with fine salt of a high degree of purity and pack backs down in a
barrel, leaving fish lightly covered to form their own brine; (7) after
they have been struck through pack down and add other fish of the
same lot to fill barrel; and (8), in conclusion, (a) head up barrel and
pour saturated brine into bunghole to cover fish for storage, or (0),
if to be sold for consumption at once, take out of the brine and rub
in fine dry salt, then pack in sugar barrels or other light containers
and ship immediately.

The results fully justified expectations in every way. The fish
were preserved successfully, and none that had been handled in the
prescribed way spoiled. In eating qualities they were pronounced
as good as or better than the best commercial salt herring from the
Chesapeake Bay region. In order to test the absolute necessity of
the prescribed methods, other small batches were put up in different
ways—by using cheaper salt, leaving roes in, and other such modifica-
tions. These trials were failures without exception. About 80,000
fish were packed by the prescribed method and marketed the first
year.

16 U. S. BUREAU OF FISHERIES.

The successes and failures under these extremely adverse conditions
tell us much about what could be expected under more favorable con-
ditions. What succeeds under severe conditions will be a finer prod-
uct under more favorable conditions, and what spoils under severe
conditions will be an inferior product under conditions in which it
does not actually spoil. It should be noted that the product prepared
by this method is mild and sweet, approaching very closely fresh fish
in eating qualities, if it has been properly soaked out.

SCOTCH-CURED HERRING.

The discussion in this paper so far presupposes the desirability of
preserving as far as possible the flavor and eating qualities of fresh
fish. The Scotch cure does not involve this supposition but aims
cirectly at giving the cured fish a new and distinct flavor from partly
decomposed or fermented blood, the purpose being the same as that
governing the flavoring of cheese by ripening. The blood is not
removed, the fish rather being allowed to cure in its own blood pickle,
a distinctive flavor thereby being imparted. They are gibbed, rubbed
with dry, fine salt and packed, more fish being added to make up for
shrinkage, and shipped or stored in the original blood pickle. This
method is suitable for cold but not for warm climates. Since, how-
ever, Scotch-cured herring come in a special class of fermented
products where different motives and processes are concerned, the
method will not be further discussed here.

MILD-CURED SALMON.

In the preservation of salmon by salting advantage is taken of the
naturally cool temperatures prevailing in the Northwest, so that the
extreme of dehydration by salt is not necessary. Even here no
chances are taken, for in most instances the casks of mild-cured
salmon are held in cold storage at about 38° F. The selection of salt
is principally on the basis of fineness, because a fine-ground salt is
necessary to stick to the moist fish, only that which sticks to the fish
being used dry. It appears that in the mild curing of salmon some
of the principles already referred to may be important. It was
pointed out that calcium and magnesium salts combine with the fish
protein to form a white, hard flesh. In the case of salmon it is desir-
able to preserve the red color which is contained in the fat, but the
precipitation or coagulation of the otherwise transparent protein is
in all probability the cause of whitening, which masks the attractive
red color of the fat. Also, what was said about the loss of nitroge-
nous matter as a consequence of bruises applies to the mild curing of
salmon.

BEHAVIOR OF FAT DURING SALTING PROCESS.

So far in this paper discussion has been timited to the behavior
of the protein or meat constituents of fish. It will be found that fat
is also of the greatest importance and requires very careful considera-
tion and study. All fishes have some fat, but the quantity is variable
from species to species, between individuals of the same species, and
within a single individual from season to season. The distribution
of fat is also different in different species of fish. Some fishes, such

-

PRESERVATION OF FISH BY SALT. 17

as herring, salmon, and alewives, contain fat well distributed through-
out the body tissues. In others, such as cod and haddock, the fat
is localized in some particular part of the body, as in the species
mentioned the oil is contained in the lever, the flesh being almost
entirely destitute of oil. For reasons that will be set forth later fat
fish must not be exposed to the air because of untoward changes that
air causes in the fat; but no harm is done to the protein constituents.
Therefore fish which do not contain fat may be dried in air after
they are salted.

In practice these differences are well recognized. In the case of
cod and haddock, in which the muscle tissue is free from fat, the
greater part of free water is extracted in the usual way by salt,
later assisted by the pressure of piles or kenches, in which the lower
layers are pressed by the weight of the upper layers in the kench,
and finally by drying out-of doors or in artificial drying tunnels.
Fish prepared by this method are packed and shipped in the dry
state, with advantages in saving of freight and simpler handling in
general. In the case of mackerel and herring and such other fishes
as have fat tissues the fish must at all times be carefully excluded
from contact with air. If the fish are directly exposed to air for a
time, the fish “ rust ”—that is, the fat becomes reddened and rancid—
and the value of the fish for food is very greatly impaired. This
rusting, especially of salt mackerel, is of immediate and pressing
practical importance, for there is a regular waste of a large per-
centage of mackerel on our northeastern coast for no other cause than
rustiness and rancidity. This aspect of the subject has not been in-
vestigated to any great extent, but there is just as much reason to ex-
pect valuable results to accrue from work on this problem as have
accrued from the work already described.

Fats consist of a combination of glycerin with fatty acids. In
the absolutely pure state, which is scarcely attainable, in fact, they
would presumably be colorless, odorless, and tasteless. They usu-
ally contain a greater or smaller quantity of coloring matter dis-
solved, and under certain conditions the combination, glycerin-fatty
acid, may be broken down, free glycerin and free fatty acid resulting.
Free fatty acid has both taste and odor; in fact, our choicest fishes,
such as salmon, shad, and mackerel, owe much of their peculiarly pala-
table flavor to the small amount of free fatty acid present. But
many of the free fatty acids of fish oils readily oxidize on exposure
to air and light, developing during the process a darker color and
an unpleasant odor and taste which we call rancidity. Once fats
have become rancid they can never be restored to their original
sweetness.

What conditions promote rancidity? First, the fat must be de-
composed or “split ” into glycerin and free fatty acid. Next it must
oxidize. Just as fish contain autolytic enzymes that decompose pro-
tein, so they also contain fat-splitting eyzymes. These enzymes re-
quire moisture and warmth for their activities. Fat that has been
removed from the tissue that produced it may be kept under proper
condition for a long time, because only a small amount of fat-split-
ting enzyme goes with the oil, but when the fat is not removed from
the original source all the enzyme is present and available to produce

18 U. S. BUREAU OF FISHERIES.

decomposition. So in salt fish the fat is in the presence of moisture
and an abundance of enzyme, and the necessary warmth is usually
present also, ideal conditions for decomposition. The fat having
been split to fatty acid, there are two factors, so far as known—
namely, air and hght—which promote oxidation.

Some little study has been devoted to the effect of salts, such
as sodium chloride and calcium chloride, on the splitting of fats,
but not enough is known about the effect of these substances in con-
centration to be of any assistance. Whether or not bruises have the
effect in promoting decomposition of fat that they have in promot-
ing decomposition of protein is not known but would be well worth
knowing, and here further investigation is certain to be of value. It
is known that much of the fat in living fish is contained within in-
closed cells, and that even the fattest fish is not greasy when fresh.
But whenever the cells are ruptured by rough handling, decomposi-
tion or whatever cause, the oil escapes and is exposed to all the un-
favorable influences of enzymes, moisture, air, and light, and the
fish becomes greasy; eventually it will become rancid. And, further,
oi! escaped from the fish, being of a lower specific gravity than
brine, at once rises to the top of the barrel and is lost as food.

All sorts of possible preventives of rust are practiced or suggested
for practice—such things as impermeable barrels, air-proof covering
over the liquid, a reducing substance in the brine to absorb
the oxygen, cool, dark storage, and the like. There is, of course,
much dissolved oxygen in the juice of the fish and in the brine and
also considerable amounts of free oxygen occluded in the cavities
of the fish to effect considerable rancidity, even if all outside air is
excluded. This dissolved and occluded air can be removed by a
vacuum pump, but this has never been tried commercially, so far as
the writer is aware. Very little improvement can be expected until
the problem has been thoroughly investigated by scientific methods.
In the improved technique recommended by the Bureau of Fisheries
in Florida complete covering of the salt fish by brine in tight barrels

was specified.

REDDENING OF COD AND HADDOCK.

If cod and haddock escape rusting because of lack of fat, they
are subject to another enemy perhaps as bad, namely, reddening, by
which large quantities of cod and haddock are lost every year. For
the past three years work has been conducted by the division of
scientific inquiry of the Bureau of Fisheries on the causes of redden-
ing and significant results have been obtained. The cause, in gen-
eral, has been known for many years to be bacteria, but otherwise
little has been known of the origin of these bacteria or of their
peculiarities.

Briefly stated, the results of the work cited are as follows: The
bacteria that cause reddening are of two distinct kinds—a spirochaete,
which in colonies is pale pink, and a bacillus whose colonies are deep
red. The two organisms grow in such close harmony that mixed
colonies occur which vary in color from pale pink to deep crimson
as the proportions of the two organisms present vary. The evidence
points to the solor sea salts from the tropical and subtropical seas
as the source of the infection. Solar sea salts, both American and
foreign, are infected. Mined salts seem to be free from the infection.

PRESERVATION OF FISH BY SALT. 19

Every species of bacteria is acclimated to some particular set of
conditions, some of them almost incredible for living things. These
red bacteria are accustomed to live and grow either on moist salt or
very strong salt solutions. If bacteria are particularly resistant to
some condition, as to strong salt in this case, it does not follow that
they are likewise resistant to all severe conditions. It is the bac-
teriologist’s business, by studying all the habits and peculiarities of
the organism, to discover its weakest point where attack will destroy
it. The strongest resistance of these bacteria, that against salt, is
also the weakest, for it has been found that water less than 15 per
cent saturated destroys them. ‘Thus, the present indications are that
the best and simplest remedy for the trouble is clean, fresh water
and plenty of it. ‘There is some evidence that may support the view
that the usual impurities in salt, calclum and magnesium compounds,
are essential to the growth and multiplication of these bacteria.
The implication here is, of course, that pure salt itself would be a
poor supporter of the bacteria. Of course, it would be futile to try
to stop the reddening of cod as long as every shipment of salt brings
new infection, and the butts, floors, buildings, and the surroundings
at packing plants are heavily infected. Facts already given indi-
cate also that for other reasons salt free from impurity is better.
The results of the study of reddened cod only emphasize this advice.

The research on reddening should not, however, end here. We are
again dealing with questions of permeability. The bacteria are ad-
justed to strong salt solutions, that is, the body fluid is of such con-
centration and their covermg membrane is of such partial perme-
ability that when surrounded by strong salt solution they live nor-
mally, but when water or weak brine surrounds them these relations
_are disturbed and they die. Probably water enters the cell in ex-
cessive quantity. It is known that the reddening does not attack
fat fish. Perhaps the fat acts directly on the membrane, or indi-
rectly by acting on the calcium and magnesium in the salt, to effect
the disturbance.

RECOVERY OF BRINE.

Even crude salt now costs considerably more than coal. Yet the
fish packers, who are usually very careful to economize in coal, are
prodigal in the use of salt. Every hundred pounds of brine that
goes overboard contain about 25 pounds of salt, to say nothing of the
valuable nitrogenous matter that the brine has extracted from the
fish. Considerable work has been done by the writer and his as-
sociates on the development of a process to recover salt and other
substances of value from old pickle by precipitating the proteinace-
ous matter with sodium silicate. A trial plant was in use and under
observation at an important fish-packing establishment for over a
year but was not satisfactory under,the circumstances. Brine pure
enough for use was recovered, while a substance very rich in
nitrogen was yielded as a by-product. This substance in the dry
condition is nearly white and friable and contains enough nitrogen
to command a handsome price as fertilizer if suitable for that pur-
pose, but it may be more valuable for other uses. The method re-
covered brine, and for this reason some other method that would pro-

=:

20 U. S. BUREAU OF FISHERIES.

duce dry salt may be better. The experience gained in the work
already done indicates that the recovery of valuable material from
brine would not go well as a part of a small fish business but, having
its own peculiar problems, would be more properly conducted as a
separate business. In any event, this promising subject is com-
mended to the chemists and engineers for study. We can not doubt
that a few years will bring forth a complete solution of the prob-
lem of recovering things of value from brine that will make us
wonder why we ever threw it away.

ACCESSORY CHEMICAL AGENTS AND OTHER FACTORS IN SALTING.

Various other chemicals are sometimes used in salt or along with
it for various purposes. Some of these will be briefly discussed.

Saltpeter performs two functions in brine for the preservation of
meat, namely, it combines with the red substance of blood, hemo-
globin, which is unstable, to form a permanently stable red deriva-
tive, nitroso-hemoglobin. By virtue of its oxidizing power it may
also oxidize hydrogen sulphide into sulphur dioxide and water; that
is, a very foully odoriferous stuff to a substance which both bleaches
and sterilizes. Saltpeter is, however, little used in curing fish, for
the red color is undesirable, and hydrogen sulphide is rarely trouble-
some.

Boric or boracic acid is sometimes added to the final application of
salt to dried salt cod. This is to prevent reddening. Undoubtedly it
does do so, and undoubtedly most of it is removed from the fish when
the latter is soaked up before cooking. Nevertheless, it seems that
the end of this practice is not distant. Boric acid has long ago been
condemned as a food preservative. With the comparatively small
amount of scientific investigation that has already been done we have
reason to hope that not only can reddening be prevented, but that
by the general refinement and improvement of methods it will be-
come unnecessary to use artificial preservatives to prevent reddening.

A method of promoting the preservation of fish by salt by the aid
of sodium hypochlorite along with the salt has been patented. The
original idea, it is understood, was to decompose the salt in sea water
by electrolysis, sodium hypochlorite being formed. It was claimed
that the sodium hypochlorite penetrates faster than ordinary salt.
This substance contains some oxygen that may be given off to act as
a sterilizing agent, and after the oxygen is given off ordinary salt
or sodium chloride remains. What advantages the process possessed
are not altogether apparent, for nothing appears to have come of it.
It may be said, however, that sodium hypochlorite readily destroys
urea, so that this substance might be advantageous in the preservation
of grayfish and sharks but is unstable and must be used as soon as
it is made.

The size and shape of the fish obviously have much to do with the
time required for salt to penetrate through. Salt effects no preserva-
tion of parts until it reaches them. A thick fish may spoil, while a
thin fish may be saved; hence the splitting of fish. Other methods
of applying the salt to the inner parts of fish may be used, such as a
needle syringe, whereby the brine is forced into the tissues, and com-
pressed air, which is used to force brine into fish after the excess air
has been removed from them in vacuo. It should also be possible

PRESERVATION OF FISH BY SALT. 91

to insert a needle in the gill arch and with pressure completely irri-
gate the whole system of arteries and veins of a fish, removing abso-
lutely all the blood at one stroke without cutting the fish.

CONCLUSIONS.

The preservation of fish by means of salt is an excellent method,
even in the crude and inexact manner in which the art has hitherto
been practiced. The comparatively small amount of scientific re-
search that has been done on the problems and principles involved
has not only justified itself in practice but furnishes abundant
grounds for the expectation that a great deal more of valuable results
will follow further work. It is not mere guesging to say that when
advantage is taken of all that is known of improved salting methods
a fish nearly if not quite equal in edible qualities to fresh fish is ob-
tained, and in some cases the quality is decidedly improved by salting.

There is every reason to expect a good future for the salt fish in-
dustry, but progress must be made. Preservation by this method is
eminently practicable, simple, and reliable for holding and transport-
ing our sea fishes to the inland population.

SUMMARY.

1. A discussion of the principles involved in the preservation of
fish by salt has been presented.

2. Salt possesses no inherently peculiar preserving qualities, but
preserves food by extracting water.

3. The principle by which salt (and other soluble substances) in
concentrated solution extracts water is called osmosis. Osmosis is
the passage or interchange of liquids and solutions through mem-
branes which are more or less permeable. The permeability of cell
membranes in fishes appears to be affected by high and low tem-
peratures. The presence in or absence from the salt of certain im-
purities, notably calcium and magnesium compounds, the treatment
of the fish, and the staleness of the fish, are factors which govern the
permeability and have an important bearing on the preservation of
fish by salt.

4. Calcium and magnesium compounds in addition to retarding
penetration cause a whitening and hardening of the fish. There are
chemical reasons for looking upon this whitening and hardening by
these compounds as undesirable.

5. The flavor of fish is often altered by the salting process. Cal-
cium salts retained in the tissue increase the salty taste and make
necessary a prolonged soaking out. Undesirable flavors of fishes
from muddy waters may sometimes be removed by salting the fish.

6. Salt applied dry penetrates the fish more rapidly and effects a
quicker cure with less danger of spoilage in warm weather.

7. There is a very material loss of protein material from fish
during the salting process. This material probably arises from the
decomposition products ordinarily unable to pass out of the cells but
which are digested by autolysis, an internal destructive process.

8. Autolysis is increased by crushing, bruising, rough handling,
pewing, elevated temperatures, low temperatures followed by a rise,
and, in general by factors that increase cell permeability. It is

22 U. S. BUREAU OF FISHERIES.

retarded or arrested by continued low temperatures, sufficiently high
temperatures, and by salt. .

9. The damage done by autolysis appears to be in large part pre-
ventable.

10. Fish containing blood, or otherwise not well cleaned, spoil at
a lower temperature than those thoroughly cleaned and freed from
blood. Thoroughly cleaned fish may be salted at from 90 to 100° F.
if pure salt is used.

11. A method of curing fish embodying the improvements cited
was tried in Florida on a small commercial scale with gratifying
success.

12. Scotch-cured herring develop a peculiar flavor which is derived
from the fermente@ or otherwise altered blood. This method has
for its aim an alteration to suit particular tastes, while other meth-
te of salting discussed aim at the preservation of the fresh qualities
of fish.

13. There are reasons for expecting that the improvements made
in the salting of other fish, particularly those which depend on the
use of a very pure salt, will find application in the mild curing of
salmon.

14. Fats undergo certain changes after the fish is salted, resulting
in a condition known as “rusting.” Rusting consists of oxidation
of fat after the latter has been split into free fatty acids. This split-
ting is caused by tissue enzymes in the presence of warmth and mois-
ture. Oxidation is brought about through the agency of light in
the presence of water. While rusting causes large losses of fish, the
means of preventing it, such as tight barrels, air-tight covering, and
cool dark storage, are not very satisfactory. The problem demands
further investigation.

15. Fishes whose flesh is not fat and therefore not prone to rust
are subject to damage by reddening. Reddening is caused by two
organisms, a spirochaete and a bacillus. They may be destroyed by
fresh water or live steam. They originate probably in solar sea salt
and are apparently not found in mined salt or other purified Ameri-
can salt.

16. Some work has been done toward the development of a process
for recovery of salt and other valuable materials from brine. There
are a number of promising possibilities which should make this an
attractive field for chemists and engineers.

17. Certain substances are sometimes used as adjuncts in salting
fish. Saltpeter preserves a pink color and neutralizes hydrogen sul-
phide. Boric acid is used for preserving cod against reddening.
Sodium hypochlorite has been proposed as advantageous in conjunc-
tion with salt. It may be produced electrolytically from sea water.

18. The size and shape of the fish influences the rate of penetration
of salt into it. Certain mechanical methods of forcing brine into
large fish may be advantageous.

O