 

FQAM $PRAY~DREED CQTTAGE
CHEESE WHEY AS A SOURCE OF
SQLEDS EN SHEREEE

Thesis {or ﬂu Dogma of M. S.
hiZCHlGM S’FATE WHEELS???
Lee E. Blakely
1964

THESIS

      
   

  

LIBRARY

Michigan State
University

 

ABSTRACT

FOAM SPRAY-DRIED COTTAGE CHEESE WHEY AS A SOURCE OF

SOLIDS IN SHERBETS

by Lee E. Blakely

Dry whey solids obtained by foam Spray drying fresh concentrated
cottage cheese whey or whey which had been cultured with Lactobacillus
bulgarigus or Streptococcus thermophilis were used to replace 25, 50,
75, and 94.5 per cent of the serum solids in orange, lemon and raSp-
berry sherbet. Substitution of plain cottage cheese whey powder at
all levels uniformly gave a fine quality sherbet with no flavor criti-
cism. If all of the serum solids were replaced by cultured cottage
cheese whey the sherbets were judged as "slight fermented". Sherbets
made with whey solids added prior to pasteurization were judged good
and possessed smooth body and texture. Addition of whey solids to
the sherbet mix after pasteurization produced a slightly smoother
sherbet. The amount of citric acid required to lower the pH of orange,
lemon and raSpberry sherbet to 3.7 was reduced approximately 32, 50
and 26 per cent resPectively in sherbet with 94.5 per cent replacement
of serum solids by dry acid whey. The bacteriological quality of

whey powders and sherbets containing whey was excellent.

FOAM SPRAY-DRIED COTTAGE CHEESE WHEY AS A SOURCE OF

SOLIDS IN SHERBETS

BY

Lee E. Blakely

A THESIS

Submitted to the College of Agriculture
Michigan State University of Agriculture and
Applied Science in partial fulfillment
of the requirements for the degree of

MASTER OF SCIENCE

Department of Food Science

1964

E32‘3€?0:T
spar/H

ACKNOWEEDGEMENT

My sincerest thanks are extended to Dr. C. M. Stine for his
counsel and guidance in initiating this study and in the prepara-

tion of this manuscript.

Appreciation is also extended to Dr. L. G. Harmon and Robert

L. Bradley for reviewing this dissertation.

ii

TABLE OF CONTENTS

Page
INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
REVIEW OF LITERATURE . . . . . . . . . . . . . . . . . . . . . . . 2
Whey d13posal . . . . . . . . . . . . . . . . . . . . . . . . 3
Whey utilization . . . . . . . . . . . . . . . . . . . . . . 3
Sherbet formulation . . . . . . . . . . . . . . . . . . . . . 9
EXPERIMENTAL PROCEDURE . . . . . . . . . . . . . . . . . . . . . . 12
Condensing . . . . . . . . . . . . . . . . . . . . . . . . . 12
Production of a cultured high-acid whey . . . . . . . . . . . 12
Drying . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Pasteurization and homogenization . . . . . . . . . . . . . . 13
Freezing . . . . . . . . . . . . . . . . . . . . . . . . . . 14
Sherbet formulation . . . . . . . . . . . . . . . . . . . . . l4
ANALYTICAL PROCEDURES . . . . . . . . . . . . . . . . . . . . . . 16
Total solids determination . . . . . . . . .,. . . . . . . . 16
pH measurement . . . . . . . . . . . . . . . . . . . . . . . 16
Determination of titratable acidity . . . . . . . . . . . . . 17
Bulk denSity . . . . . . . . . . . . . . . . . . . . . . . . l7
Organoleptic evaluation . . . . . . . . . . . . . . . . . . . l7
Microbiological determinations . . . . . . . . . . . . . . . 17
RESULTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
DISCUSSION . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
SUMMARY AND CONCLUSION . . . . . . . . . . . . . . . . . . . . . . 38
APPENDIX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

B IBLIm WHY O O O O O O O O O O O O O O O O O O O O O 0 O O O O O 4 3

iii

TABLES

Page
1. General sherbet formula used in all trials. . . . . . . . , , 14

2. Sherbet formula with 94.5 per cent of the serum solids
substituted with whey solids. . . . .‘. . . . . . . . . . . . 15

3. Properties of orange, lemon and rasterry sherbet prepared
with various amounts of foam Spray-dried cottage Cheese
whey and adjusted to a pH of 3.7 with citric acid after
addition Of flavor. o o o o o o o o o o o o o o o o o o o o o 20

4. Properties of orange, lemon and rasterry sherbet prepared
with various amounts of foam Spray-dried cottage cheese
whey cultured with L, bulgaricus. . . . . . . . . . . . . . . 21

5. Properties of orange sherbet prepared with various amounts
of foam Spray-dried cottage cheese whey cultured with
g. thermOEhiliS. O O I O O O O O O O O O O O O O O O O O O I 22

6. The average reduction in quantity of citric acid needed to
lower the pH of some sherbets to 3.7. . . . . . . . . . . . . 23

7. Effect of whey solids added after pasteurization on the
observed tactual property in sherbets and their respective

mixes O O O O O O O O O I O O O O O O O O O O O O O O O O O O 28

8. Effect of whey solids added prior to pasteurization on the
observed tactual property in sherbets and their reSpective

mixes. 0 O O O I O O O O O O O O O O O O I O C O O O O O O O 28

9. Bacteriological quality of various whey powders after two
weeks Storage. 0 O I O O O O O O O O O O O O O O O O O O O O 29

10. Bacteriological quality of sherbets prepared with various
amounts of foam Spray-dried cottage cheese whey added prior
to and £0110W1ng pasteurization. o o o o o o o o o o o o o o 30

1a. Some properties of plain cottage cheese whey no. 6. . . . . . 40

2a. Some properties of cottage cheese whey no. 2 cultured with
L. bUIgari-cus. O O O O O O O O O O O O O O O O O O O O O O O 40

3a. Some properties of cottage cheese whey no. 8 cultured with
E. bulgaricus. O O O I O O O O O O O O O O O O O O O O 0 O O 41

4a. Some properties of cottage cheese whey no. 4 cultured with
g. themmhili-SO O O O O O O O O O O 0 I O C O O O O O O I O 41

5a. Some properties of plain cottage cheese whey no. 5. . . . . . 42

iv

INTRODUCTION

Increasing annual production of cottage cheese has resulted in

economic and public health problems associated with whey disposal.

Due to the low pH of cottage cheese whey and the distinct odors
and flavors produced by lactic fermentations, the usesfor cottage
cheese whey are much more limited than is the case for sweet cheese
whey. Fluid cottage cheese whey has been used in the manufacture
of sherbets. However, the inconvenience of handling liquid whey in
many plants and the great difficulty encountered in conventional
spray drying of cottage cheese whey has restricted the utilization
of whey in sherbets. The relative ease with which cottage cheese
whey can be foam Spray-dried suggested that such whey powders might

be readily substituted for serum solids in the manufacture of sherbet.

The purpose of this research was to determine whether foam
spray-dried cottage cheese whey could be used as a source of serum
solids in fruit flavored sherbet. If replacement of acidic whey
solids for serum solids was feasible from the standpoint of ease of
incorporation and quality of the frozen sherbet, then manufacturers
could realize economic return from such usage and also make use of

a presently wasted food ingredient.

REVIEW OF LITERATURE

In 1962 the United States Department of Agriculture (48)
reported that 589 million pounds of cottage cheese curd were
produced from approximately 3,680 million pounds of skimmilk
equivalent. From the production of this cheese curd more than
three billion pounds of whey were left for use or disposal. If
the average total solids of this fluid whey was 6.62 per cent as
indicated by Webb and Hufnagel (52), 204 million pounds of whey

solids could be manufactured from this whey.

From the data of Stine and Sargent (40) on composition of
spray dried cottage cheese whey, one can calculate that 204 million
pounds of whey solids would yield 24 million pounds of very high
quality protein, possibly 2 million pounds of fat, 130 million
pounds of lactose and 17 million pounds of lactic acid. Utiliza-
tion of these presently wasted nutrients in foodstuffs is a matter

of worthy consideration in view of our world population explosion.

Increasing annual production of cottage cheese has also re-
sulted in economic and public health problems associated with whey
disposal. Many means of disposal and utilization of sweet whey have
been developed; however, the uses and disposal of acid whey from

cottage cheese are more limited because of low pH, odor and flavor.

Whey Disposal

The discharge of any industrial waste usually creates a diSposal
problem. Dairy wastes are particularly troublesomein this respect.
The large amount of organic matter in whey makes costly the disposal
in sewage systems. Dumping whey into streams is unlawful in some
states and may soon be in others because of the high biological oxi-
dation demand of such wastes and consequent pollution of the stream.
In a review of methods of treatment and disposal of dairy wastes
Southgate (39) suggests that biological filtration or the activated
sludge process are the best means of waste diaposal. In areas where
conditions permit, irrigation is a method of disposal of whey.
McDowall and Thomas (24) indicated that one acre of pasture land can
accept at least 5,000 gallonsof undiluted whey, provided there is a
period of about 14 days between dosings. Sharrett et a1. (37) showed
that when properly applied, whey could increase the fertility of the
soil; however, this method of utilization is limited by the fact that
whey production is fairly concentrated in certain regions and land for
disposal of the whey may not be available. This method of whey dis-
posal also causes odor problems unless the process is carefully adminis-

tered.
Whey Utilization

Feeding whey to livestock was one of the earliest means of whey
utilization. Raw liquid whey was used for pig and calf feed if the

stock were kept near the cheese factory. Since the livestock were

often remotely located from the cheese factory, condensed and dried
whey became the more practical product to ship or feed. Condensed
whey of 35-50% solids was found by Tufft(43) to be an excellent
chicken feed. Condensed as well as dried whey is useful in feeding
chickens because of the effects of lactOSe in preventing coccidiosis
and the beneficial effects of riboflavin and other nutrients on the
growth of chicks. Becker et al.(11) successfully used dried whey as
an ingredient in pig feed. Danielson et a1. (14) used a mixture of
dried skimmilk and dried whey in pig starter rations. An excess of

whey in the pig's diet was found to have a laxative effect.

Many methods have been suggested for converting whey into a
feedstuff suitable for ruminants. High-nitrogen feeds from whey
have been developed by Arnott et a1. (8) and Czarnetzky (12) for
feeding cattle. However, Hazzard et al. (21) found that dairy cows
fed high-nitrogen feeds often had lower milk and butterfat production

than cows on control diets.

Although raw, concentrated or dried whey is a useful livestock
food supplement, the use of whey for this purpose is limited because
of cost and nutritional considerations. Using whey solids in the
manufacture of food products for human consumption is more efficient,
from the human nutritional standpoint, than feeding whey solids to
animals and then consuming the animals as food to gain the nutrients

present in the whey.

There are many ways in which whey, either plain or modified, can

be used in food products. The utilization of whey in food and non-food

products is reviewed by Webb and Whittier (54, 55) and Wix and
Woodbine (56, 57). The chemical and physical properties, as well

as the flavors of food, in many instances are claimed to be improved
by the addition of whey solids. Webb and Whittier 1(55) report that
one of the largest outlets for whey solids is in the production of proc-
ess cheese foods, where plain condensed or dried whey solids are added
to the emulsified cheese mixture. Badad et a1. (9) used whey protein
in process cheese food production. Ziemba (60) reported on the pro-
duction of a free-flowing stabilized whey powder that gives soft body
characteristics to cheese foods and spreads. A whey cheese popular
in Scandinavia is called Mysost or Primost (50). "Albumin" cheese,
commonly known as Ricotta or Ziger, is made by precipitating the

proteins of whey in the presence of acid at elevated temperatures.

The baking industry is the largest single potential user of whey
solids (4). iMuch work has been reported on the use of whey solids in
' all types of bakery products (1, 4, 18, 22, 32, 60). Whey solids are
used in bread, rolls, fermented sweet products, cakes and other baked
goods. The lactose promotes desirable browning, while the heat-
coagulable proteins contribute to structure during baking. Cakes,
cookies and doughnuts are more tender and keep their softness longer

if whey is included in the mix.

Whey also has been used successfully in confections (l, 6, 51).
Webb and Whittier (55) formulated a whey fudge which contained 43 per
cent sweetened condensed whey. The sweetened condensed whey used in

the fudge formulation was manufactured according to the method of

Ramsdell and Webb (29). This method consists of condensing a mixture
of fresh whey and sugar. Processing whey in this manner preserves the

whey in a form directly usable in sweet foods.

Whey proteins help provide emulsion stability in soups and soups
containing whey solids are more natural in color than soups made with
milk solids (53). Since there are only small amounts of casein present
in whey, the use of whey solids in acid fruits, fruit juices and soups
is advantageous to reduce curd formation which normally would occur
during processing if milk solids were used. Ramsdell and Webb (30)
found that as muCh as 25% of the total solids of spray-dried soups
could be substituted with whey without the development of a whey

flavor.

Whey protein has foaming properties which can be compared to
those of egg albumin and Ramsdell and webb (29) suggested that modified
whey can be whipped for use in food preparations.. However, whey pro-
tein cannot be used in products in which air must be incorporated by
whipping and a firm structure set up by heat coagulation. Rogers
et al. (31) modified cheese whey and spray-dried sweet whey to produce

an edible foaming and aerating agent having many of the properties of

egg albumin, gelatin and soya derivatives.

Numerous other uses for whey solids have been developed. Whey
has been incorporated in products such as instant potatoes, salad
dressings, starch puddings, sauces, dips and comminuted meat products.
Detailed information about some of these uses for whey are to be found

in the text by Whittier and Webb (59).

The components of whey have been modified, allowing whey solids
to be used in a greater variety of products. The fat can by hydrolyzed
with lipases, the lactose fermented, proteins modified or minerals re-
moved (7). Whey can be blended with milk to produce a mixture which
has beneficial properties of both the milk and the whey. Barnes et a1.
1(10) produced an edible high-acid powder by blending cultured condensed
cottage cheese whey with skimmilk and spray drying the blend. By de-
mineralizing whey, an infant food has been made which has a composition
close to that of human milk. Stribley (41) reports that by using electro-
dialysis, the salt content of whey can be reduced to a level whereby
whey can be used in the manufacture of special baby food formulas which

closely resemble the composition of.human.milk.

The major constituent of whey is lactose. Lactose has been used
in infant foods, pharmaceuticals, the production of lactic acid, ribo-
flavin and ethyl alcohol. Lactose also has many non-food uses. In an
extensive review Whittier (58) discusses the production and utilization

of lactose.

Usage of sweet whey in foods has grown rapidly since 1954 when
U. S. Extra Grade Dry Whey was defined in the Federal Register (45).
These standards on flavor, color, sediment, moisture, acidity and
bacterial count assure that U. S. Extra Grade Dry Whey will be of
uniform high quality. Dry sweet whey has been used in ice cream
since World war II. ‘Many state standards now allow whey in one form
or another to be added to ice cream and/or sherbet. Federal definitions

and standards published in October, 1963 do not include whey as an

optional ingredient in ice cream, but the definitions do include whey

as an optional ingredient in sherbet (49).

Nielsen (27) indicated that the most commonly used level of whey
solids in ice cream is 20 per cent of the serum solids. Whey at this
level gives satisfactory body and texture characteristics to ice cream.
Leighton (23) showed that 19 to 65 per cent of the serum solids of ice
cream can be added as whey solids without the danger of sandiness.

The percentage serum solids that can be replaced with whey depends

upon the fat and serum solids content of the mix. Rosenberger and
Nielsen (33) summarized the advantages for using spray-dried whey pow-
der in ice cream as follows; (a) Cost --- whey solids are cheaper

than other common serum solids; (b) Improvement in the whipping ability;
(c) DiSpersibility; (d) Good body and texture and a slower melt-down.
The chief disadvantage of using whey powder is that the flavor of ice
cream may be slightly inferior to ice cream made from fresh cream and

concentrated skimmilk.

Good quality sherbets can be made by using whey solids in place
of the milk solids normally used in sherbet manufacture (5). Gholson
et al. (17) indicated that pineapple, orange and raspberry sherbets,
in which as much as 90 per cent of the serum solids was replaced with
whey solids were very desirable in all respects. Potter and Williams
(28) made an extensive study on the use of whey in sherbets. Sherbets
were made from fresh fluid whey obtained from the manufacture of cheddar,
swiss and cottage cheese. Condensed, sweetened condensed and dried
whey were also used to make sherbets. The addition of whey to sherbet

greatly improved whipping ability. Excessive overrun, caused by the

addition of whey to sherbet, could be avoided by adding 0.6 to 2 per
cent fat to the sherbet mix. Homogenization reduced the ability of
the added fat to retard whipping. The non-heat-coagulable protein
fraction of whey was found to be responsible for the unusual whipping

properties of whey sherbets.

Potter and Williams (28) found that citric acid was not necessary
to acidify sherbet mix when cottage cheese whey replaced the milk
solids normally used.‘ Savings in citric acid approximating 10 cents
per 100 pounds of sherbet base could be realized if cottage cheese
whey was used as a source of solids. No whey flavor was carried over
to the finished product when a good quality whey was used. Since most
of the acid coagulable casein is not present in whey, sherbet contain-

ing whey solids showed no tendency to curdle.

Potter and Williams (28) used fluid cottage cheese whey in sherbet
manufacture. Fluid whey is inconvenient and unecondmical to handle,
ship or store. Powder made from cottage cheese whey because of its
hygroscopicity, tends to clump and "ball" in conventional Spray drying
equipment and is difficult to handle in pneumatic conveyors. Foam
spray drying as developed by Hanrahan and Webb (19) produces a powder
which is easily and economically handled. The relative ease of pro-
ducing and handling foam spray-dried whey makes the use of dried acid

whey in sherbet manufacture attractive.
Sherbet Formulation

The choice of sherbet formula will depend upon individual

10

preferences for sweetness, texture and body, milk solids content and
acidity. A good sherbet should contain about 25 to 35 per cent carbo-
hydrate according to Frandsen and Arbuckle (16). By replacing 20 to

25 per cent (w/w) of the sucrose with dextrbse, Dahlberg (13) indicates
that surface crystallization of sucrose is prevented. As demonstrated
by Ross (36) a sherbet with the correct amount of sweetness and total
sugar content can be made using 20 per cent cane sugar and 8 per cent
corn syrup solids. Ross (34) stated that as the percentage of sugar
used in the formula is increased, body and texture improve, flavor
becomes more distinct and the acid gives a sharper flavor to the

sherbet.

Federal regulations now require that sherbets contain milk solids
(49). These solids contribute desirable properties to sherbets. Day
et al. (15) suggested that the level of total milk solids should be
about 4 to 5 per cent (w/w) of the sherbet formula. Solids~not-fat
improve body and texture and tend to prevent a weak body and coarse
texture (35). Too high a milk solids-not-fat (MSNF) content reduces
the intensity of fruit flavor and is therefore usually limited to 3
per cent or less. The usual fat content of sherbet is in the range of
l to 2 per cent. When the MSNF content of a sherbet is held constant

the rich flavor increases directly with increasing fat content.

Stabilizers are important in sherbets to improve shelf life and
control overrun. There are many sherbet stabilizers available, such

as the vegetable gums, pectins and propylene glycol alginate. The

11

choice of stabilizer and amount to use depends on overrun desired and

the body and melt-down characteristics sought by the manufacturer (44).

The amount of fruit that must be contained in sherbets now is
under Federal regulation (49). For a fine fruit flavored sherbet only
the best fruit juice or puree should be used, possibly in conjunction

with a pure flavor essence.

One of the most important considerations in the production of
sherbet is acidity. Unless the acidity of each batch is carefully
controlled the fruit flavor will not be at an optimum. The desired
acidity is dependent upon the type of fruit sherbet made. Day et a1.
(15) suggested that the most desirable acidity in a sherbet is 0.55
to 0.60%, expressed as citric acid. Frandsen and Arbuckle (16)
recommended that the titratable acidity of sherbet should be 0.35
to 0.52 per cent, expressed as lactic acid. Preferably the acidity
should be 0.47 to 0.52 per cent or in a pH range of 3.6 to 3.8. Each
batch of sherbet should be titrated for acidity just prior to the
addition of citric acid and then standardized to the desired acidity
or pH. Shortledge (38) advised that pastel shades in foods are the
most appetizing. The color of a sherbet should not be darker than

the color of the base fruit.

The percentage of overrun that is presently acceptable in most
consumer markets is 35 to 45 per cent (16). Color, pH and overrun
are characteristics which vary widely according to the area in which

the sherbet is manufactured and sold.

EXPERIMENTAL PROCEDURE

The purpose of this research was to determine if foam spray-
dried cottage cheese whey could be effectively used as a source of
serum solids in sherbets. Once the feasibility of using such whey
was established the remaining trials were directed toward ascertain-
ing the maximum replacement of normal serum solids consistent with
good flavor, body and texture. When acid whey is added to sherbet
mix there is a reduction in the quantity of citric acid needed to
lower the pH of the mix to the desired level. In all trials the
amount of citric acid needed to bring the pH of the base mix to 3.7

was determined.

Condensing: Fresh cottage cheese whey was obtained from the Michigan

State University dairy plant and filtered through a single gauze

faced 6 1/2 inch Rapid-Flo filter disk to remove small pieces of curd

which were present in the whey. The whey was preheated to 115 F, con-
centrated in a 16 inch Rogers vacuum pan to 40-50 per cent total

solids and immediately foam spray-dried.

Production of a Cultured HightAcid Whey; Several batches of whey were
cultured before concentration to ascertain whether any additional acid-
ity or other fermentation products might have beneficial effects on

the flavor of sherbets to which such whey was added. Fifty gallon

lots of fresh cottage cheese whey were inoculated with a 1 per cent

inoculum of either Lactobacillus bulgaricus or Streptococcus thermophilis

12

 

 

13
and incubated at 45 or 37 C, respectively, for 24 hours.

Drying}! The cottage cheese whey concentrate was foam spray-dried

using the nitrogen injection technique described by Hanrahan and

Webb (19). A Rogers co-current horizontal inverted tear-drop dryer
equipped with a Spraying Systems type SEC 6 nozzle with a 0.040 inch
orifice diameter was used for drying. Atomization pressure was 1000
lbs./sq. in. with nitrogen injected under a pressure of 1050 1bs./sq.
in. at a rate of 2.0 cubic ft./gal. as the concentrate left the high
pressure pump. Inlet air and exit air temperature averaged 260 F and
185 F, respectively, during spray drying. The powder was collected and

stored in polyethylene bags.

Pasteurization and Homogenization:‘ The pH of sherbet mixes containing
whey solids is markedly lower than the pH of mixes containing serum
solids which are normally used in sherbet manufacture. Since the pH
of mixes containing whey was low, trials were run to determine if this
lower pH would cause coagulation or precipitation and preclude the

pasteurization temperature normally used on such products.

Mixes were made containing only the following basic ingredients:
cream, sucrose,corn syrup solids, stabilizer and water. These mixes
were heated to 165 F,held for 30 minutes, subjected to two stage
homogenization at 2500 psi and immediately cooled to 33 F using a
surface cooler. Other mixes were made which included whey and/or

nonfat dry milk (NDM) as one of the basic ingredients. These mixes

14

were pasteurized at 150 F or 160 F for 30 minutes or flashed at 175 F,
followed by homogenization and cooling. The cooled mixes were then

aged at 34 F for 24 hours before freezing.

Freezing: Additional serum solids, if needed, fruit juice, flavor,
color and citric acid were added to the sherbet mix. The sherbet
mixes were frozen in an Emery Thompson 2 1/2 gallon batch freezer to
approximately 45 per cent overrun and hardened at -25 F in moving air.
The frozen samples were transferred to a freezer cabinet at 2 to 5 F

for observation of body and texture Changes.

Sherbet Formulation: The formula used in making sherbets was 20%
sucrose, 8% corn syrup solids, 0.5% stabilizer, 1.5% fat and 3.5%
serum solids. Table 1 indicates the general formula used in.making

the sherbets employed in all trials. Orange, lemon and raspberry

TABLE 1. Sherbet formula used in all trials.

 

 

 

Amount used (lbs) 'Ingredients
20.0 sucrose
8.0 frodex (42% dextrose equiv.)
3.8 cream (40% cream)
3.4 N114 (3.2% moisture)
0.5 stabilizer
64.3 combined weight of water,
fruit etc.

 

sherbets were made. The optimum amount of fruit, flavor and color to
add was determined in advance and this amount was used in all subse-
quent trials. In preparing ten pound batches of orange sherbet mix,

254.2 g of pure 4:1 frozen orange juice concentrate, 9.9 g of natural

15

orange and 2.8 g of orange color were added prior to freezing. When
lemon sherbet mixes were made, 170.2 g of frozen lemon juice, 8.7 g
of natural lemon flavor and 2.7 g of yellow color were added. Just
prior to freezing raspberry sherbet mixes,‘ 300 grams of fresh frozen
raspberry puree and 4.5 grams of natural raspberry flavor were added.
In all cases commercial 50% citric acid solution was used to adjust

the pH of the mix to 3.7 or 3.5.

Foam spray-dried cottage cheese whey was substituted at various
levels for the NDM normally used in preparing sherbet mixes. The per-
centage of the total serum solids that was replaced with whey solids
was considered the level of substitution. Therefore, 100 per cent
substitution of the serum solids with whey solids could not be accom-
plished since the cream contributes approximately 5.5 per cent of the
total serum solids. Table 2 illustrates the formula of a sherbet mix
which has essentially all of the serum solids substituted with whey
solids.

TABLE 2. Sherbet formula with 94.5 per cent of the serum solids sub-
stituted with whey solids (10 lb. batch).

 

 

Amount used (lbs) Ingredients
2.0 sucrose
0.8 frodex (42% dextrose equiv.)
0.38 cream (40% cream)
0.34 whey solids (3% moisture)
0.05 stabilizer
6.43 combined weight of water,

fruit, etc.

 

Some of the sherbet mixes were prepared with the serum solids, in

the form of dry whey and/or NDM, added after pasteruization and cooling.

16

The milk and/or whey solids were incorporated before the addition of
the fruit, flavor, color and citric acid. Other sherbet mixes were
prepared in such a manner that whey and/or NDM was added prior to
pasteurization. Comparisons were made between sherbets prepared with
whey solids incorporated into the mix either prior to or following

pasteurization.
ANALYTICAL PROCEDURES

Total Solids Determination: To determine the total solids of liquid
whey, condensed whey and sherbet the Mojonnier procedure was followed
(26). Total solids on NDM or whey powder were determined by the Cenco

Moisture Balance Method (26).

pH Measurements: pH determinations were made on liquid whey, condensed
whey and reconstituted whey powder. When preparing sherbet mixes, pH
readings were taken both prior to and following serum solids addition
and after the addition of fruit juice, flavor and color. A pH meter
was also used to indicate when the correct amount of citric acid had
been added to attain the desired pH in the sherbet mix. Since the
sherbet mixes just prior to freezing had relatively low temperatures

a buffer solution of known concentration and at the temperature of the

mix was used to standardize the pH meter.

pH measurements were made with a Beckman Zeromatic pH meter using

a calomel half cell and a glass electrode.

17

Determination of Titratable Acidity: The acidity of fluid and concen-
trated whey was found according to the procedure outlined by the Milk
Industry Foundation (26). Whey powder acidity was obtained using the

method recommended by the American Dry Milk Institute (2).

The titratable acidities of frozen sherbets, expressed as citric
acid, were determined on fluid sherbets following equilibration at room
temperature. After miXing, a 9 gram sample was weighed and titrated
to a pH of 8.4 (phenolphthalein endpoint), using the pH meter to indi-

cate the endpoint.

Bulk Density: The bulk density of a powder was determined by weighing
an empty 100 ml. graduated cylinder, filling with powder to the mark,
tapping the cylinder at intervals to settle powder, weighing the cyl-

inder plus powder and Calculating the bulk density as g/ml. (20).

Organoleptic Evaluation: The flavor, body and texture evaluations of
the sherbets were made by experienced judges. All samples were coded,
individually criticized and placed according to their relative prefer-

ence compared to other samples.

Microbiological Determinations: In several experiments the serum solids
or whey solids were added after pasteurization. Since the finished
sherbet would then contain dairy ingredients which technically had not
been pasteurized during mix processing, the assessment of microbial
populations seemed desirable. Standard plate counts for total and
coliform organisms were made to determine the bacteriological quality

of both whey powders and the finished sherbets(3, 26).

RESULTS

The fresh cottage cheese whey collected for processing had a
total solids content of 6 to 7 per cent; immediately following con-
centration to 25 to 55 per cent total solids, the whey was foam spray-
dried. Analyses were made to determine the pH, total solids and
titratable acidity of the fresh whey and concentrate used in pro-
ducing the various foam Spray-dried powders. Titratable acidity,
moisture and bulk density were determined on the whey powders used
in preparing sherbet mixes (Appendix la - 5a). The resulting powders
had low bulk densities and moisture contents, were free flowing and
readily soluble in the mixes to which they were added. Foam spray-
dried cottage cheese whey is hygroscopic unless crystallization
techniques are employed, and must be packaged and stored to avoid

moisture absorption.

The titratable acidity of cottage cheese whey obtained from the
cheese vat was 0.45 to 0.53 per cent, expressed as lactic acid.
Culturing whey with L, bulgarigus or S, thermophilis raised the
acidity of the whey, thus enabling production of high acid powders.

When L, bulgaricus was used to culture whey the acidity was raised

 

to 0.70 to 0.96 per cent and the corresponding whey powders made from
such whey had acidities of 11.86 to 12.50 per cent on a dry basis.
Plain foam Spray-dried cottage cheese whey powders had acidities of
5.93 to 6.68 per cent. When whey was cultured with S. thermophilis
the titratable acidity increased only slightly over that observed in

the original whey. Powder made by foam Spray drying whey cultured

18

19
with S, thermophilis-had a titratable acidity of 7.00 per cent.

In preparing sherbets wherein whey was substituted for the
serum solids normally used, individual batches of mix were processed.
These mixes were designed so that 25, 50, 75 or 94.5 per cent of their
serum solids were replaced by foam spray-dried plain or cultured
cottage cheese whey. A control containing NDM as the only concen-

trated source of serum solids was included in every group.

The pH of mixes with added serum solids was observed and recorded
before the addition of fruit and flavor. The pH of the base mix,
before addition of fruit juice and flavor, decreased as the content
of dried cottage cheese whey increased (Tables 3 to 5). The extent
to which the pH of the mix is lowered is also dependent upon the
acidity of the whey powder employed. The lower pH of the base mixes
containing whey results in a reduction of the quantity of citric acid

needed to lower the pH of the sherbet to the desired level.

The data contained in Table 6 illustrate average reductions in
the quantity of citric acid needed to lower the pH of orange, lemon
and raspberry sherbets to 3.7. The greatest reduction in the quantity
of citric acid required was noted in lemon sherbets, followed by
orange and raspberry. In some orange, lemon and raspberry sherbets,
reductions in the quantity of citric acid required were as high as

42, 54 and 30 per cent respectively.

When sherbets were adjusted to a lower final pH of 3.5 more citric

acid was required than sherbets adjusted to 3.7. Orange sherbets

20

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has? no sumo mom

a

moss do sumo mom a

 

 

 

 

omnmoo .Hm snooam poow ooow om.m mH.m 0H.n m.qm
omuooo .Hm nuooam ooom ooow oo.m mm.m oq.m mm
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omuooo .Hm nuooam ooow ooom om.o oa.o mm.o mm
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when om ammo 0 what on memo o nmuuoommmm maoaog mowcmuo Anson Homv
moﬁHom hose
on eunuxou um uo>wam Anew sows moHHOm
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no Ho>mHm mo cowusuwumASm

m m ou N um wououm monumnm mo huwaono

aowuaooo mnemon
xwa cameo
mo aoHuomom

 

 

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Houmm oHoo oauuwo Suez m.m mo mm m on ooumnnom one more omooso ammuuoo ooauoumoumm Boom mo
muzsoao msoauo> sues ooummon noouosm headphone one :oaoH «owamuo mo mowuuomoum .m mnm<e

21

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omumoo .Hm nuooEm onoow ovoow om.q wH.¢ o~.q m.am
omumoo .Hm nuooam ooow ooow mm.q mm.q om.¢ mm
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omumoo .Hm nuooam ooow poow om.o mm.m om.m mm
omumoo .Hw :uooam coow ooom om.o ow.o oaeo o
ammo co ammo 0 when oo whom o omuuonmmom nsoamn.lmwwnmuo Auaoo Homv
moHHom hogs
um manuxou um Ho>mHm Ammv sows moHHOm
mvﬂﬂ hﬁom NHOHOO Shmm HO
HO Ho>mHm mo dowusuﬁumosm
m m on N um wououm workman mo huaamno dowuﬁoom ouowmo
xwa demon

mo coauomom

E
.mmmmwmwasn em nuﬁs omnnuaso moss choose owmuuoo ooauou%wumm Boom mo

muqsoam mnowuop sues venomonm monuosm huuonmmmu one coaoa aowamuo mo mowuuomoum .q mum<a

22

TABLE 5. Properties of orange sherbet prepared with various amounts
of foam spray-dried cottage cheese whey cultured with S, thermophilis.

 

 

 

 

 

 

Reaction of Quality of
Substitution basic mix
of serum before addition Body and
solids with of flavor or Flavor at texture atc
whey solids colora:
(per cent) (pH) 0 days 60 days 0 days 60 days

0 6.40 good good smooth sl. coarse
25 5.90 good good smooth sl. coarse
50 5.65 good good smooth sl. coarse
75 5.20 goodd goodd smooth sl. coarse
94.5 5.10 goodd goodd smooth sl. coarse

 

a For data on whey used in this trial consult Appendix, Table 4a.

b pH of sherbet adjusted to 3.5 with citric acid after addition of

flavor.

C Stored at 2 to 5 F.

d Judges criticized sample as having a "whey flavor".

23

TABLE 6. The average reduction in quantity of citric acid needed to
lower the pH of some sherbets to 3.7. ‘

 

 

 

 

 

Serum solids Average reduction of citric acid (per cent)
substituted with plain
cottage cheese " ' 'Flavor of Sherbet'
whey solids
(per cent) Orange Lemon RaSpberry
25 18 21 ll
50 22 27 13
75 26 29 16

94.5 32 50 26

 

24

containing whey replacing 25, 50, 75 and 94.5 per cent of the normal
serum solids required 10, 12, 16 and 26 per cent less citric acid
respectively. Lemon sherbets adjusted to a final pH of 3.5 and with
whey substitution levels identical to those of the orange sherbets
showed reductions in quantity of citric acid required of 5, 10, 18 and

30 per cent respectively.

Sherbet mixes prepared substituting whey which had been further
cultured with L, bulgaricus before drying had lower pH values than
mixes containing noncultured whey solids. Results of these trials
on orange, lemon and raspberry sherbets are recorded in Table 4. At
75 and 94.5 per cent serum solids substitution in orange sherbets
36 and 54 per cent less citric acid, respectively was needed to adjust
the pH to 3.6. Lemon sherbet containing the same serum solids substi-
tution required 46 and 55 per cent less citric acid. RaSpberry sher-
bets prepared in the same manner required 28 and 43 per cent less

citric acid.

Whey powders prepared from liquid whey cultured with S, thermophilis
were used in making sherbet (Table 5). A similarity was noted in pH
values for base mixes containing whey solids prepared by drying whey

cultured with S, thermophilis and the pH values of base mixes contain-

 

ing plain whey solids substituted for milk solids. Orange sherbets
made with 25, 50, 75 and 94.5 per cent of the serum solids replaced
with such powders required 8, 12, 20 and 24 per cent less citric acid,
respectively, to adjust their pH to 3.5. The above percentage re-

ductions in citric acid are almost identical to those reductions in

25

citric acid are almost identical to those reductions in citric acid
obtained when plain whey solids were substituted for the normal serum
solids in orange sherbets adjusted to the same pH. Therefore, there
is no advantage gained by culturing whey with S. thermophilis prior

to spray drying.

When foam Spray-dried cottage cheese whey was added to cold mixes
the powder went into solution easily. After incorporation of the whey
powder the mix was allowed to stand in the cold for a short period of
time to permit the collapse of the unstable foam which results when
foam spray-dried products are reconstituted. Sherbet mixes not allow-
ed to stand in the cold occasionally exhibited a tendency to foam
slightly on.meltdown. Foaming naturally was not observed in sherbets
to which whey solids had been added prior to pasteurization of the

mix.

Following freezing of the flavored mixes to approximately 45
per cent overrun, hardening at -25 F and tempering in a cabinet held
at 2 to 5 F, all samples were evaluated for flavor, body and texture
after 0 and 60 days storage in the cabinet (Tables 3 - 5). The data
in Table 3 indicate typical results obtained from 35 trials in which
over 700 pints of sherbet were made. All of the samples of sherbet
which contained varying amounts of foam spray-dried plain cottage
cheese whey were considered good by the judges, as were the corres-
ponding controls. There was no unanimity of agreement as to which

sample might be considered superior to the others. Often, the samples

26

chosen as best were those containing 75 and 94.5 per cent substitutions;
however, all judges agreed that differences were slight. After two
months storage in a cabinet at 2 to 5 F all samples were slightly coarse
in texture. 'Meltdown of the control and other samples was similar and

uniform.

Sherbets made with various amounts of the serum solids replaced
with foam Spray-dried whey powder prepared from cultured whey were
evaluated as to flavor, body and texture. The texture and body of
sherbets prepared with the above type of whey solids were comparable to
plain whey sherbets. Sherbets containing S, bulgaricus whey solids at
the 94.5 per cent level of substitution were often described by the
judges as having a "slight fermented" flavor. At the 75 and 94.5 per
cent level of serum solids substitution with S, thermophilis whey solids

the judges detected a "Whey flavor".

This research conclusively demonstrates that good sherbets can be
made by substitution of serum solids with foam Spray-dried plain cottage
cheese whey. Satisfactory sherbets can also be prepared using foam
spray-dried L, bulgagicus cultured cottage cheese whey in substitution
of as high as 75 per cent of the original serum solids of the basic
sherbet formula. However the slight advantage of using cultured whey
in sherbet is definitely offset by the added expense and inconvenience

of preparing such whey.

Trials were conducted in which the acid whey solids were added

before and after pasteurization of the mix in order to ascertain if

27

sherbets of equally good body and texture characteristics could be
produced by either method of incorporation. Identical methods of
pasteurization, homogenization and cooling were followed for these
mixes. Pasteurization conditions were varied to determine if the

type of heat treatment would influence the production of a tactual
flavor. Judges evaluated the mixes before the addition of color and
flavor for a tactual flavor (Tables 7 and 8). At the 25 and 50 per
cent substitution levels a "slightly chalky" flavor was detected which
was independent of the heat treatment to which the mixes had been sub-
jected. When the mixes were frozen and evaluated judges were unable
to differentiate between any of the samples, regardless of the heat
treatment used. All of the sherbets were judged as good irrespective
of when the serum solids were added or the heat treatment used. When

comparisons were made between sherbets prepared with whey solids added

prior to pasteurization and cooling, the sherbets prepared by the latter

method were smoother. When the samples were individually judged no

objectionable tactual flavor was detected. Only when direct comparisons

were madewas a difference in smoothness detected. Therefore, good sher-

bets can be made by either method, with the smoothest sherbets resulting

when the whey solids are added after pasteurization.

Samples of sherbet were allowed to warm to room temperature. These

melted samples were then titrated to a pH of 8.4 using a pH meter and
calomel and glass electrodes. The titratable acidity of the melted
sherbet was then calculated. Acidities ranged between 0.49 and 0.69
per cent, expressed as citric acid and were dependent upon the final pH

to which the sherbet had been adjusted.

28

TABLE 7. Effect of whey solids added after pasteurization on
the observed tactual property in sherbets and their reSpective
mixes‘. L ‘ ' ‘ '. ; ‘Z . '. . t ’ A . . i ' ‘ ; . ' _ l ; ; L . ‘ ‘ .

 

 

Degree of tactual flavor observeda

 

 

 

 

 

 

Substitution Pasteurization_temperature, F.
of serum
solids with 150 160 175
whey solids
(per cent) sherbet mix sherbet mix sherbet mix
0 - - - - - -
25 - - - - - -
50 - - - - - -
75 - - - - - -
94.5 - - - - - -

 

a slight chalky +, none -.

TABLE 8. Effect of whey solids added prior to pasteurization on
the observed tactual property in sherbets and their reSpective
mixes,

 

Degree of tactual flavor observeda

 

 

 

 

 

 

Substitution Pasteurization temperature,,F.
of serum
solids with 150 160 175
whey solids
(per cent) sherbet mix sherbet mix sherbet mix
0 - - - _ - -
25 — + - +- - +
50 - + - -|- .. +
75 - - - - - _
94.5 - - - - - _

chalky +3 none -.

29

The total solids of some of the orange, lemon and rasterry
sherbets were determined. Average percentages of 36.50, 34.78 and

38.40 were found for orange, lemon and raSpberry sherbet, respectively.

In many of the trials whey solids were added to sherbet mixes
either before or after pasteurization. In either case the bacterio-
logical quality of the ingredient added is of importance, and particu-
larly so if the ingredient is added after pasteurization. Therefore,
the bacteriological quality of the foam Spray-dried whey used in mak-
ing sherbets was determined. No Special precautions to prevent
bacterial contamination were exercised in handling the liquid whey
during concentration and drying. Coliform tests were negative for
all powders. A bacterial estimate of not more than 50,000 per gram
as determined by the standard plate count is the Federal Standard
for U. S. Extra Grade Dry Whey and U. S. Extra Grade Nonfat Dry Milk
(45, 46). Whey powders produced for use in sherbets had relatively
low bacteria counts (Table 9). Powders made from cultured whey, in

TABLE 9. Bacteriological quality of various whey powders after two

weeks storage.
W

Standard plate

 

 

 

 

Sample no. Type of whey count at 35C
1 plain <3000
2 cultured, _I_.., bulgari cus (3000
3 plain 400
4 cultured, S, thermophilis 700
5 plain 650
6 plain <3000
7 cultured, S, bulgaricus 11000
8 cultured, S, bulgaricus 2320

 

 

some instances, had counts comparable to those obtained from plain

whey powders.

30

Sherbets which contained whey solids were examined for bacterio-
logical quality. Comparisons were made between Sherbets made with
foam Spray-dried cottage cheese Whey added prior to pasteurization
and those sherbets made with whey solids added following pasteurization
to determine if the whey powders added after pasteurization would in-
crease the standard plate count of the sherbet. The Michigan Ice Cream
Law states that sherbet shall not contain more than 75,000 bacteria per
gram (25). The data obtained on the bacteriological quality of Sherbets
prepared with various amounts of foam Spray-dried cottage cheese whey
indicates that the counts were relatively low (Table 10). All sherbets

exhibited negative coliform tests.

TABLE 10. Bacteriological quality of sherbets prepared with various
amounts of foam Spray-dried cottage cheese whey added prior to or
following pasteurization.

 

 

 

 

 

m
Substitution
of serum Standard plate count at 35 C
‘ S°lids with Serum solids added
whey solids
(per cent) prior to pasteurization following pasteurization
0 3000 <3000
0 2900 <3000
94.5 3000 6400
94.5 3000 <3000
75 790 <3000
75 300 5500

50 510 <3000

 

DISCUSSION

Large, porous, highly diSpersible particles are produced by the
foam Spray drying technique of Hanrahan and Webb (19). Bulk density
is, among other factors, directly related to particle size. “With
particles of uniform large size large voids exist between particles
and bulk density is low. Powders produced for use in sherbets in this
research had average bulk densities of 0.35 g/ml when water pump nitro-
gen was injected at a rate of 2 cu. ft./gal. of concentrate before dry-
ing. Other factors which affect bulk density of the powder produced
are total solids of the concentrate, dimensions of the nozzle orifice
and drying conditions. Cottage cheese whey powders with bulk densities
of 0.55 g/ml have been produced by injecting a minimum amount of nitro-
gen. For the purposes of this research a powder was desired which
would be readily soluble and processing conditions were selected accord-

ingly, albeit at the sacrifice of high bulk density.

Whey powders produced by any straightforward spray drying techniques
are very hygroscopic. The hygroscopic tendency of these powders can be
partially eliminated by inducing lactose crystallization before or dur-
ing drying by adaptation of one of the producers suggested by Whittier
and Webb (59). After foam Spray drying, a second stage consisting of
moisture pickup, lactose crystallization and redrying will produce a
more stable powder. An alternative method is the crystallization of
lactose in the concentrated whey followed by Spray drying of the result-
ant slurry. Powders produced by either method are easier to handle and

store than those having all of the lactose in the amorphorus state.

31

32

The sherbet formulation used in this study was the result of com-
bining formulas known to produce good quality sherbets (15, 34, 36, 38).
The amount of fruit juice or puree needed to impart fine flavor was
determined by trial and error. The flavors contributed by the natural

frozen fruit juices were generally fortified with natural fruit essences.

When foam Spray-dried cottage cheese whey is substituted for the
serum solids in sherbets the pH of the base mix, before the addition
of the fruit juice and flavor, decreases as the amount of dried cottage
cheese whey is increased. The extent the pH is lowered depends upon
the titratable acidity of the powder and the amount of dried whey added
to the mix. The titratable acidity of the powder depends upon the
acidity of the original whey. In cultured whey the presence of addi-
tional acidic fermentation products causes the titratable acidity of
powders made from such whey to be higher than the acidity of those pow-
ders obtained by foam Spray drying plain cottage cheese whey. Addition-
al acidity in the original whey does not always mean that the powder
produced from such whey will have a corresponding increase in titratable
acidity. By comparing the data obtained from two cultured wheys that
were foam Spray-dried, it can be seen that the acidity of cultured whey
no. 2 is less than the acidity of cultured whey no. 8 (Tables 2a and
3a, Appendix). The powders produced from these cultured wheys have
approximately the same titratable acidity. A possible explanation for
the similar acidities is the increasing vapor temperature of the whey
in the vacuum pan as concentration progresses and accompanying loss of
volatile acidity. Also the fermentation pattern of volatile acids pro-

duced may well vary with the culture used, so that one lot of whey may

33
have greater or less volatile acidity than another.

Reductions in the quantity of citric acid needed to lower the pH
of the sherbets to the desired level was found to vary with the citrus
flavor used, desired final pH of sherbet, type of whey used to replace
the serum solids and percentages of serum solids replaced. The last

two factors affecting percentage reductions have been discussed previous-

ly.

Orange, lemon and raspberry mixes containing fruit, flavor, and
with 0-94.5 per cent of their serum solids replaced have typical pH
values of 4.9 to 4.3, 4.7 to 4.0 and 5.8 to 4.6, respectively. The
percentage reduction of citric acid is dependent upon the difference
between the amount of citric acid used to reach the desired pH in the
control mixes and the amount used in the mixes containing whey. The
greater percentage reduction in citric acid used in the lemon flavored
sherbet mixes is attributed to the fact that the lemon juice plus dried
Whey at the 94.5 per cent substitution level brings the Sherbet mix
through a buffering zone, thus substantially reducing the amount of
citric acid needed to adjust the mix to the desired pH. Mixes contain-
ing orange and raspberry juice plus dried whey at the 94.5 per cent
substitution level did not overcome this buffering capacity to as great

an extent as did the more acidic lemon juice.

Among the samples containing whey solids added after pasteurization
there was noted a tendency for slight foaming during meltdown. This was
presumably due to liberation of air and injected nitrogen in the Spray-

dried foam particle and can be eliminated by allowing the mix to stand

34

under agitation in the cold for a short period of time before freezing
the mix. Foaming was not a problem in samples containing whey solids
which had been added prior to pasteurization, since the air and injected

nitrogen in the Spray-dried foam particle is liberated during pasteurization.

Potter and Williams (28) reported that good quality sherbets could
be made using fresh fluid cottage cheese whey as a Source of serum solids
instead of the milk solids normally used. Sugar, Stabilizer, flavor and
enough 40 per cent cream to yield a fat content of 2 per cent in the fin-
ished Sherbet were added to fluid acid whey. Sherbets made in this manner
had a whey Solids content of 4 to 5 per cent and required no additional
citric acid to adjust the mix to a rather low selected titratable acidity
of 0.37 per cent. A sherbet containing cottage cheese whey with a
titratable acidity of 0.53 per cent as the major source of serum solids
had a final pH of 4.49 and a titratable acidity of 0.37 per cent expressed
as lactic acid. By using cottage cheese whey in this manner in Sherbets
a savings in citric acid approximating 10 cents per 100 pounds of sherbet
base could be realized. Whey sherbets possessed a smooth texture and no
whey flavor existed in the finished Sherbet made from whey that had not
developed more acidity than was originally produced in the normal cheese

making process.

The inconvenience of handling and storing liquid whey in many
plants and the great difficulty encountered in conventionally Spray
drying of cottage cheese whey has restricted the use of cottage cheese
whey in sherbets. Use of the nitrogen injection technique described

by Hanrahan and Webb (19) to foam Spray dry cottage cheese whey

35

eliminated these handling and storage problems. Foam spray-dried whey
powders are free flowing, highly diSpersible and upon reconstitution

yield a clean, acid-flavored whey.

Sherbets made with 94.5 per cent of their serum solids replaced
with whey powder had a whey solids content of 3.3 per cent. The pH
values of sherbet bases containing 94.5 per cent of their serum solids
replaced with foam Spray-dried plain cottage cheese whey were in the

pH range of 5.30 to 5.00. If whey cultured with L, bulgaricus was

 

foam Spray-dried and used in place of plain cottage cheese whey powder
at the 94.5 per cent level of substitution, pH values in the range of
4.30 to 4.18 were obtained. The pH considered desirable in the finished
sherbets was 3.7. Therefore, citric acid or some other edible acid was
still needed to attain this pH regardless of the type or quantity of

whey used.

Batches of whey were cultured with either L, bulgaricus or S,

thermophilis before concentration to ascertain whether any additional

 

acidity or fermentation product might have beneficial effects on the
flavor of Sherbets containing solids prepared from such whey. Whey
additionally fermented with S, thermophilis was found to contribute

an undesirable flavor to the finished sherbet. Whey cultured with

L, bulgaricus was successfully used to substitute up to 75 per cent

of the serum solids. At levels above 75 per cent a "Slight fermented"
flavor could sometimes be detected. As previously noted these cultured
wheys did not substantially further reduce the citric acid needed to
adjust the pH of the mix to 3.7 and would therefore be impractical to

prepare.

36

When whey solids were added to the unpasteurized Sherbet base,
replacing 25 or 50 per cent of the normal milk Solids, a tactual flavor
defect occasionally was observed in the unfrozen mix. This defect was
not observed in unfrozen mixes at the 0.75 or 94.5 per cent substitution
levels or at any substitution level in the frozen sherbet. In sherbet
bases having 25 or 50 per cent of their normal milk solids replaced
with whey solids there is a greater amount of casein present than in
those mixes with 75 or 94.5 per cent of their normal milk solids re-
placed with whey solids. Under the conditions of pH and heat that exist
when pasteurizing a mix containing whey solids the possibility exists
that some of the casein precipitates and is detectable as a tactual
flavor only in those mixes containing relatively large amounts of normal
milk solids. Apparently the texture of the frozen sherbet masks the

tactual flavor present in the unfrozen mix.

After hardening the frozen sherbets at -25 F., the samples were
transferred to a freezer cabinet at 2 to 5 F. for observation of body
and texture changes. At temperatures of 2 to 5 F. a greater quantity
of water in the Sherbet would be equilibrating as ice-water than at a
lower Storage temperature. After two months storage at these tempera-
tures all sherbet samples were Slightly coarse in texture. Temperatures
in the 2 to 5 F. range are optimum for lactose crystallization in a
sherbet; nevertheless, lactose crystals were not observed in any of

the sherbets.

The bacteriological quality of whey powders is esPecially important
if this product is to be used in food for human consumption. At the

present time there are no Federal Standards for Specific grading

37

requirements for cottage cheese whey. The Specific grading requirements
for U. S. Extra Grade Spray-dried sweet whey Specifies that the powder
should not have a bacterial estimate greater than 50,000 per g (45).

U. S. Extra Grade nonfat dry milk Should have a bacterial estimate not
greater than 50,000 per g (46). The bacterial estimates of plain foam
Spray-dried cottage cheese wheys that were produced for use in this
research were less than 3000 per g by the standard plate count. Cultured
whey that had been foam Spray-dried had higher bacterial estimates, with
the highest plate count being 11,000 per g. By comparing the bacterial
estimates of cottage cheese whey powders with the estimates set as
maximum for Extra Grade sweet whey and nonfat dry milk the whey powders
produced in this research had bacterial estimates substantially below

those specified for dry sweet whey and nonfat dry milk.

The bacteriological quality of sherbets made with various amounts
of whey solids was good. Bacterial extimates of frozen sherbets made
with whey solids were well below the 75,000 bacteria per g that Michigan

Law sets as maximum (25). Sherbets that were made with whey solids

added after pasteurization exhibited a maximum of 6,400 organisms per

g.

SUMMARY AND CONCLUSIONS

Sherbets were prepared using plain or cultured foam Spray-dried
cottage cheese whey solids to substitute for 25, 50, 75 and 94.5 per
cent of the original serum solids in the basic Sherbet formula. Cultured
cottage cheese whey solids were prepared by foam Spray drying liquid

Whey that had been cultured with either S, thermophilis or S, bulgaricus.

 

Sherbets were prepared from mixes to which the serum solids, in the
form of whey powder, were added prior to and following pasteurization.
Samples of sherbet were evaluated for flavor, body and texture at 0 and
60 days storage. ‘The bacteriological quality of sherbets and the wheys

used in preparing these sherbets was determined.

Satisfactory sherbets were prepared using plain cottage cheese
whey solids in substitution of 94.5 per cent of the normal milk solids
in the sherbet base. Substitutions of as high as 75 per cent of the
original serum solids with L, bulgaricus whey solids were possible
Without producing an off flavor. Whey solids made from cottage cheese
whey cultured with S, thermophilis contributed no beneficial properties

to Sherbets in which they were used.

Sherbets exhibiting excellent flavor characteristics and possess-
ing smooth body and texture were made when the whey solids were incor-
porated in the base mix before and after pasteurization. Those sherbets
prepared with whey solids added after pasteurization were smoother than

sherbets made with whey solids added prior to pasteurization.

Average reductions of 32, 50 and 26 per cent of the normal citric

acid usage can be accomplished in orange, lemon and raSpberry Sherbets

38

39

respectively when 94.5 per cent of their serum solids have been re-
placed with plain cottage cheese whey solids. The amount of reduction
is a function of the acidity and amount of whey used, the type of fruit

used for flavoring and the final pH desired.

Foam Spray-dried cottage cheese whey with low bacterial populations
were produced. Bacterial estimates were less than 3,000 per gram in
plain whey powders and never exceeded 11,000 per gram in cultured whey

powders.

Sherbets which had whey solids substituted for their serum solids

before and after pasteurization exhibited low bacterial estimates.

APPENDIX

TABLE la. Some properties of plain cottage cheese whey no. 6.

 

Total Solids

original whey 6.29%

concentrate 53.27%
pH

original whey 4.90

concentrate 4.30
Titratable Acidity

original whey 0.46%

concentrate 3.17%

powder 0.61%
Moisture, Powder 2.40%
Bulk Density, Powder 0.35g/m1

 

TABLE Za. Some properties of cottage cheese whey no. 2 cultured
with S, bulgaricus.

 

Total Solids

original whey 6.46%

concentrate 22.24%
pH

original whey 4.80

cultured whey 4,40

concentrate 3.70
Titratable Acidity

original whey 0.42%

cultured whey 0.69%

concentrate 3.35%

powder 1.15%
Moisture, Powder 1.50%
Bulk Density, Powder 0.20g/m1

 

41

TABLE 3a.. Some properties of cottage cheese whey no. 8 cultured with
S, bulgaricus.

Total Solids

original whey 6.64%

concentrate 40.13%
pH .

original whey 4.70

cultured whey 3.90

concentrate 3.70

Titratable Acidity

original whey 0.53%
cultured whey 0.96%
concentrate 5.12%
powder 1.16%
Moisture, Powder 1.00%
Bulk Density, Powder 0.28g/ml

 

TABLE 4a. Some properties of cottage cheese whey no. 4 cultured with
S, thermophilis.

 

Total Solids

original whey 7.26%

concentrate 40.37%
pH

original whey 4.75

concentrate 4.55

Titratable Acidity

original whey 0.53%
cultured whey 0.58%
concentrate 2.98%
pOWder 0.65%
Moisture, Powder 1.30%

Bulk Density, Powder 0.18g/ml

 

42

TABLE 5a. _Some properties_of_plain cottage_cheese whey no. 5.

 

pH

reconstituted powder 4.73
Titratable Acidity -

powder 0.61%
Moisture, Powder 3.00%

Bulk Density, Powder 0.36g/m1

 

10.

ll.

12.

13.

14.

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