THE EFFECTS OF DIFFERENT PROCESSIGN TECHNIQUIES ON THE ORGANOLEPTIC QUALITY OF SOYMILK PROCESSING AND STORAGE
Table Of Contents
- Cover page Title page Certification Dedication Acknowledgement Abstract Organization of the work Table of Contents
Chapter ONE
INTRODUCTION
- 1.1History of Soybeans
- 1.2Uses of Soybeans
- 1.3Composition of Soybeans
- 1.4Nutritional Quality of Soybeans
- 1.5Antinutritional Factors
- 1.6Trypsin Inhibitor
- 1.7Haemagluttins
- 1.8Soybeans Saponings
- 1.9Protein Quality of Soubeans
- 1.10Aims and Objectives
Chapter TWO
LITERATURE REVIEW
- 2.1Milk from Soybeans
- 2.2Nutritional Value of Soybeans
- 2.3Essential Amino Acid Content of Soybeans
- 2.4Undesirable Components of Soybeans 2.
- 4.1Trypsin Inhibitor 2.
- 4.2Clrease 2.
- 4.3Haemagluttuis 2.
- 4.4Gioterogens 2.
- 4.5Phytic acid 2.
- 4.6Bitter and Beeany Flavour 2.
- 4.7Flatus 2.
- 4.8Soymilk Flavour 2.
- 4.9Soymilk and Lipoxidase Activity 2.
- 6.1Nutritional Aspect of Soymilk 2.
- 6.2Proteins 2.
- 6.3Vitamins and Minerals 2.
- 6.4Fats
Chapter THREE
RESEARCH METHODOLOGY
- 3.1Materials
- 3.2Methods I Hot Extraction Method
- 3.3Method II Cold Extraction Method
- 3.4Method III Soaking Before Hot Extraction Method
- 3.5Method of Analysis
Chapter FOUR
DATA PRESENTATION AND ANALYSIS
- Result and Discussion
- 4.1Effect of Soaking Time on the Organoptic Qualities of Soymilk
- 4.2Effect of Soaking Time on the Protein Recovery and Total Solids
- 4.3Effect of Blanching Time on the Organoleptic Qualities of Soymilk
- 4.4Effect of Blanching Time on Protein Recovery and Total Solids
Chapter FIVE
SUMMARY, CONCLUSION AND RECOMMENDATIONS
- and Recommendation Conclusion Recommendation REFERENCES
Project Abstract
Soymilk was processed from soymilk (Glycine Max) seed using that different processing techniques A Hot extraction method B. Cold extraction method C. Soaking before hot extraction method. The soymilk samples were subjected to sensory evaluation using 9 point hedonic scale and proximate analysis. Result obtained showed that sample A was significantly different (P < 0.05) between sample B had a more acceptable colour (P < 0.05) than samples A and C this was no significant difference between sample A and C in terms of colour. The general acceptability of the sample showed that all the samples were acceptable.
Project Overview
1.0 INTRODUCTION
His
of Soymilk: Soybeans belongs to the family leguminous, subfamily
papiliondase and the genus Glycine Max. (Ricker and Morse, 1984), other
normendatures which have been used include phaseolus Max, Soja Max Piper
and Soja hispide moech.
It
is not known when this remarkable legume, soybean was first cultivated
in China. However as the first legume of which a written record was
made. This was in the books of the Emperor Shen hung, dated 1800BC
which describes the five principal and sacred crops of China, rice,
bean, wheat barely and millet, lafter in his milliohm there were chinses
writing, giving expert advice on growing soybean which was cultivated
more extensively in North than in Southern China, it reached Hapan and
other countries in East Asia at an early date.
Soybean
contain about 46% protein and 18% fat, characteristics which have
influenced it’s history: the ancient Chinese evolved methods of making
from it’s preparations with high protein content for example, Curd and
Shoyu, Shoyu is a dark brown liquid made by fermentation of a
combination of soybeans and cereals (F.A.O. 1970). The Chinese also ate
soybeans as a vegetable after it ahs sprouted.
The soybean was first heard of in Europe in 1712 through the German Botanist Egelbant Kalmpfer who had visited Japan. In the 18th
century, it was grown in some European botanical gardens (F.A.O, 1970),
it is first appearance in the United States in 1804, when Commander
Perry brought home two varieties from Japan (F.A.O, 1970).
What
was called the second stage in the history of soybeans did not begin
until the first decade of the present century, when it become an
important export from East – Asia at first mainly to Europe and alter to
the importing countries was as a source of oil for soap making and
other purposes and for the manufacture of livestock feed.
Then
the third stage began in the early nineteen thirties, it is silent
feature has been the large stage cultivation of the soybean in the
United States, combined with the application of Modern Technology which
enable it to be put to a variety of uses both as food and folder and as
raw materials for manufacturing processes, while soybean has to a
considerable extent becomes an industrial crop in the United States, it
continues to be grown in East Asia as a food crop processed for
consumption by time honoured methods. (FAO, 1970).
The fourth stage began during the first decade of the 20th
century A.D. at the period in which this crop was first introduced of
soybeans in Nigeria shows that middle belt of the country to be the best
producer of soybean production (Ezedinmma, 1964). In Nigeria, nearly
all of the soybean production estimated at 30,000 tons is used for human
food. A response to increase in demand for soybean for soybean as a
source of protein and vegetable oil, national programme in Nigeria have
explained their research on the crop. Since 1987 (IITA; Annual Report
1985) currently more feather have been added to the number of products
that can be obtained from soybeans in Nigeria, such products like
soymilk as it had been recently demonstrated at the food investigation
centuries in Enugu.
Soymilk
in the traditional sense is simply an aqueous extract of whole soybean,
A detailed description of the technique used for the preparation of the
soymilk as well as its composition will be found in chapter 3.
Soymilk
according to the nutritionist a possible substitute for cow or human
milk particularly in the feeding of infant who are allegic to animal
milk or where cows milk may be found to be two expensive or
unavailable. Miller, (1962) soybean or vegetable milk or flu-changin
chinse is reported to have been developed and used in china before the
Christian era (paker and Morse 1943) by the philosopher who was credited
with the first step in the processing of tofu and yuba. Then, the
traditional milk is made by soaking the bean in water overnight, wet
milling the bean, heating the wet mash to improve flavour and
nutritional value and filtration. The milk produce is sold to the public
in streets and canteens in china in 1984.
In
recent years large scale production ha evolved along with commercial
marketing of soymilk in Hongkong, Taiwan, Thailand, South Korea,
Sinapere, Malaysiaa and not the United States (Babara, 1984).
Uses of Soybeans
Soybeans
are a native crop of Eastern Asia where they have `served as an
important part of the diet for centuries. The Japanese for example
obtain 12 – 13% of their dietary protein from soybean product, for many
of their traditional soy foods, the oriental people soak soybeans in
water and then grind or cook them.
Hot
water extraction of ground beans yields soybean milk which is consumed
as such or is treated with calcium salts to precipitate the protein
plus oil in the form of bean curd or tofu, fermentation of cooked
soybeans yield products including soy sauce, misso, notto and tempheh.
Except
for soy sauce, one of the traditional oriental foods is consumed in
significant amounts in this country. Soybeans are a relative new corner
to the American scene. They have only been gown in quantity since the
late 1920’s when soybean processing become an established industry, the
two major products were oil and defaulted meals.
In
the mid – 1`930’s large portion of the oil began to be used for foods
such as shortening, margarine, cooking oil mayonnaise and salad
dressing, because of its high protein content and good nutritional
value, when properly processed, the meal was used primarily for animal
feeds.
Soybeans
have expanded in the last 30 year from a minor crop to a major cash
crops. Indeed in value to the farmer soybeans now rank second to corn
and above wheat, potatoes, oats, cotton and a variety of other crops
better known to the consumers, only within the last ten years however,
have every many edible products. Containing soybean derivatives been
directly associated with their source. In shortening their presence was
“hidden†by statements similar to the followings. ‘A blend of
hydrogenated vegetable oils or in salad dressing, merely “vegetable oil
or a blend of vegetable oilâ€. Today a long list of foods containing
soybean derived product can be prepared by careful reading of the labels
in the supermarket, yet most of these are even not specifically
identified as soybean. Product from corn, wheat, oats and many other
commodities are so labeled for example corn flakes, wheat, garn,
oatmeal, but not soybean. There are several reasons for this an enmity,
soybean have a short history of sue in the U.S.A. the flavour and
texture of soybean products are comparatively strange to people outside
the orient.
Although
the Chinese and Japanese have covered soybeans into a variety of
products most of these foods have little physical or flavour identity
with the original bean. Some people agree that green soybean are a
delicious dish when properly harvested and cooked but their sale and the
sale and the ale of mature beans for baking are extremely small.
Soybean products have problems related to their flavour and flavour
stability to their ruction in foods and to their physiological effects.
Despite these problems soybean oils have become a major material in our
food industry. Soybean now supply more than half of the total visible
fits and oils consumed in the U.S.A
Soybean
composition (PREXIMATE), commercial soybean constitute and 2%
hypocotyls and phumule. Proximate composition for whole beans and
fractions are given in Table 1
TABLE 1: PROXIMATE COMPOSITION OF SOYBEANS AND SEED PARTS
Fraction
Protein (Nx 6.25)
Fat %
Carbohydrate %
Ash %
Whole bean
40
21
34
4.9
Cotyledon
43
23
29
5.0
Hall
8.8
1
86
4.3
Hypocotyls
41
11
43
4.4
The constituents of major interest oil and protein make-up about 60% of
the bean, but about one third consist of carbohydrates including
polysaccharides, stachyose (3.8%), raffinese 1.1% phosphatides, sterols,
ash and other minor constituents are also depend on variety, soil
fertility and weather conditions.
NUTRIENTIONAL PROPERTIES OF SOYBEAN
Over
50 years ago Osborne and Mendel (1980) found that rates grew poorly
when feed with raw soybean meal and that dry head did not improve the
nutritional value of the meal.
Rates grew normally, however when the meal was cooked on a steam for
3hrs. In the past 50yrs a vast literature was developed on the nutritive
properties of soybean protein, but moist heat is still used to improve
the nutritional quality of soybean protein product for foods and feeds.
The literature on this subject is often confusing and contradictory ;
two recent reviews gives concise summaries of pertinent work for the
last 30yrs. Alleged antinutritional factors and protein quality
therefore are discussed only briefly.
Antinutritional factors
Since
moist heat readily inactivates the anti-growth factors raw soybean
meal, many workers believe that the factors are proteininhibitors and
hemagluthins, non protein components such as sapynins have b suggested
as anti-nutritional factors but recent work does not support this view.
TRYPSIN INHIBITORS
More
than five trysin inhibitors are reported for soybeans but only two-the
kenitz and the Bowman Birk inhibitors have been purified and studied in
details Kaw soybean meal contains 1.4% kunity inhibitor and 0.6^
Bowman-Birk inhibitor.
Although both inhibitors are active against boline trypsin the kunity
inhibitor has any how activity the esterase activity of human trypsin.
The activity of human trypsin however is inhibited to a significant
extent by kunity inhibition when case is sued as a substrate to measure
proteolytic activity. It is not known whether ingestion of the
inhibiters affects the presence in humans.
From the practical standpoint, Trypsin inhibitors do not appear to be a
serious problem in feeds and food since they are largely inactivated by
moist heat. Condition of heating time, temperature, moisture content
and particle size influence the rate and extent of trypsin inhibitors
inactivation for example, atmospheric steaming (1000C)
inactivates more than 95% of the trypsin inhibitor activity of raw,
defatted soybean flakes in 15mins. Protein efficiency shows an
accompanying increase in this same time and flakes of 19% moisture gave a
higher protein efficiency ratio than flakes of 5% moisture. In
contrast, steaming whole soybeans chips, or cotyledons for 20mins only
partially inactivated trypsin inhibitors apparently because of the large
particle size. Atmospheric steaming inactivates most of the trypsin
inhibitor in whole soybeans in 15mins. In initial moisture content is
20%. If the beans are soaked in water overnight 60% moisture 25mins. In
boiling water sufficient to inactivate the inhibitors. Small but
measurable trypsin inhibitors activity can often be deflected after
heating the known stability of Bowman-kirk inhibitor suggested that the
residual inhibitor may be of this types. Measurements of residual
chymotrypsin inhibitor activity would clarify this point because the
Bowman-kirk inhibitor is a strong inhibitor of chymotrtpsin.
At recent study reports trypsin inhibitor activity commercial protein
isolate but no inhibitor was detected in canned frankfurters containing
1.5% isolate. The heat treatment during canning inactivated the residual
inhibitor.
Many of the conclusion drawn from studies on kunity inhibitor must be
viewed with some reservations because of the heterogeneity of certain
commercial preparation even when crystallized five times. The
possibility that a protein impurities or a tightly bound non-protein
impurity is responsible for some of the biological properties of the
inhibitor has received slight consideration until recently.
Hemagglatinins –Soybean contain at least four proteins capable of
causing clumping of red blood cells of rabbits and rates in
invitrotests. These proteins are designated haemagluttinins; these
proteins are in many legumes. Defected soy flour contains about 3%
lemaglutinins. The major hemagluttinin in soybeans has been insolated
and characterized. It is a glycoprotein containing 4.5% mannose and 1%
glucesanine and has a molecular weight of 110,00 and appear to contain
two polypeptide chains. The ability of hemaggluttinins to cause clumping
of red blood cells in a test tube serves as a useful assay procedure
but there is no evidence that agglutination of red cells occurs when
hemagluttinins are ingested. Hemagglutinins is readily inactivated by
pepsin; thus it probably does not service passage through the stomach.
Furthermore, undigested hemagglutinin would have to be absorbed from the
intestine to come into contact with red blood cells an occurrence which
seems unliky because of the high molecular weight of the hemagglutinin.
Soybean hemagglutinins are readily inactivated when maximum growth
response is obtain. Hemagglutinins this ;present no known problems in
foods of preparation includes proper heating of the soy ingredient at
some step of processing.
Soybean saponings – saponins are complex glycosides of triterpenoid
alcohols and occur in soybeans to the extent of 0.5% and because of
their polarity, the saponins are insoluble in hexane and remain in
defatted meal; defatted meal contains 0.6^ saponins. Although
antinutritional properties have been ascribed to soybean saponins,
recent studies show t hem to be harmless when ingested by chicks rates
and nice aft 0.5 to 3% of the diet. At the highest level the saponins
content was about three fold higher than in a 50% soybean meal
supplemented diet. Neither saponings nor sapogenine were found in blood
of rates, mice or chicks kept in diet containing 20% soybean seed,
thus the saponins are not absorbed thy remain intact until they leave
the enzymes in the colon. The saponin inhibit various enzymes including
cholinesterase and chymotrypsin but inhibition is not specific.
Soyprotein and other dietary protein will also bind saponins.
Approximately 0.4% saponins were obtained from a laboratory preparation
of soyprotein isolate when isolates where ehated in dilate and solutions
crystalline bit apparently modified. Saponins were obtained. The effect
of interaction of the saponins with soy protein is still unknown, the
saponins are an extremely complex mixture and only limited separations
have been obtained to date.
Protein quality of soybean.
Until the 1960’s information on the nutritive value of soybean protein
was largely limited to defatted flakes, meals and flours. Moreover most
of the studied were concerned with use of soybean means as an animals
feed. Since commercial introduction of concentrates and isolates in 1959
and their increasing use in foods, these fractions have received
considerably more attention studies with human, however, are still
limited. The quality of soy protein depends on several factors:-
a) Amino acids composition
b) Presence of anti-nutritional factors
c) Digestibility
d) Overall composition of the diet
e) Nutrient
requirement of the species involves. Item a, b, and c are of primary
importance in considering the various soy protein forms as protein
sources.
In
the preparation of isolates for example fractionation occurs; this
results in a change in amino acid composition as well as in removal of
the antinutritional factors occurring in the whey, items of and e are of
greater importance when a specific food is being considered i.e. an
infant food dietary item or a soack food nutritional requirements for an
infant differ greatly from the needs of an adult who may be trying too
loose weight.
Aims and objectives of the project
The
processing of soybeans into soymilk is aimed at gaining consumer
acceptance of the legume by removal of the toxicants that contain and
also improving organoleptic qualities of soymilk with special
consideration to some adverse effect of these operation in soymilk
quality.
This
project re views the effects of different methods used in the
processing of soybeans into soymilk on the quality of the milk produced
during processing and storage.