Food Biochemistry and Food Processing (2 edition)

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BLBS102-c31 BLBS102-Simpson March 21, 2012 14:0 Trim: 276mm X 219mm Printer Name: Yet to Come


596 Part 5: Fruits, Vegetables, and Cereals

Amylases The primary function of starch-hydrolyzing en-
zymes is to mobilize the storage polysaccharides to read-
ily metabolized carbohydrates when the grain germinates
(Hoseney 1998).
α-Amylase hydrolyzesα-1,4 glycosidic bonds at random in
the starch molecule chain but is unable to attack theα-1,6 link-
ages at the branching points on the amylopectin molecule. The
activity ofα-amylase causes a rapid reduction in size of the large
starch molecule, and the viscosity of a heated solution or slurry
of starch is greatly decreased. It is most active on gelatinized
starch, but granular starch is also slowly degraded.
β-Amylase splits off two glucose units (maltose) at a time
from the nonreducing end of the starch chain, thus providing a
large amount of fermentable carbohydrate.β-Amylase is also
called a saccharifying enzyme since its action causes a marked
increase in sweetness of the hydrated cereal. Neither the hydrol-
ysis of amylopectin nor of amylose is completed byβ-amylase,
since the enzyme is not able to move past the branching points.
The presence of bothα-andβ-amylases, however, leads to
a much more comprehensive hydrolysis, sinceα-amylase pro-
duces several new reducing ends in each starch molecule.
The level ofα-amylase is very low in intact grain but increases
markedly on germination, whereasβ-amylase levels in intact and
germinated grain are similar.
Flour containing too muchα-amylase absorbs less water and
therefore results in heavy bread. In addition, the dough is sticky
and hard to handle, and the texture of the loaf is usually faulty,
having large open holes and a sticky crumb texture. However,
some activity is required, and bakers may add amylase either
as an enzyme preparation or as wheat or barley malt in order
to slightly increase loaf volume and improve crumb texture.
The thermal stability of amylases from different sources dictates
their activity during the baking process. Microbial amylases with
greater thermal stability have been used in bread to decrease
firming (retrogradation) upon storage since these enzymes are
not fully denatured during baking.

Proteases Proteinases and peptidases are found in cereals, and
their primary function is to make small amino nitrogen com-
pounds available for the developing seed embryo during germi-
nation, when the levels of these enzymes also increase. However,
whether these enzymes have a role in bread baking is not certain.
Peptidases may furnish the yeast with soluble nitrogen during
fermentation, and a proteinase in wheat that is active at low pH
may be important in acidic fermentations such as sourdough
bread.

Lipases Lipases are present in all grains, but oats and pearl
millet have a relatively high activity of lipase compared with
wheat or barley (Linko et al. 1997). In flour of the former grain
types, hydrolytic rancidity of the grain lipids and added baking
fat may be a problem.

Lipids

Lipids are present in grains as a large number of different com-
pounds, and they vary from species to species and also within

each cereal grain. Most lipids are found within the germ. Wheat
flour contains about 2.5% lipids, of which about 1% are po-
lar lipids (tri- and diglycerides, free fatty acids, and sterol es-
ters) and 1.5% are nonpolar lipids (phospholipids and galactosyl
glycerides). During dough mixing, much of the lipid forms hy-
drophobic bonds to the gluten protein (Hoseney 1998).

BREAD


Many different types of bread are produced in the world. Bread
formulations and technologies differ both within and between
countries due to both traditional and technological factors in-
cluding: (1) which cereals are traditionally grown in a country
and their suitability for bread baking, (2) the status of bread in
the traditional diet, (3) changes in lifestyle and living standards,
(4) globalization of eating habits, and (5) economic possibilities
for investing in new types of bread-making equipment.
The basic production of most bread involves the addition of
water to wheat flour, yeast, and salt. Other cereal flours may
be blended into the mixture, and other optional ingredients in-
clude sugar, fat, malt flour, milk and milk products, emulsifiers,
and gluten (for further ingredients and their roles in bread, see
Table 31.1). The mixture is worked into an elastic dough that
is then leavened by the yeast to a soft and spongy dough that
retains its shape and porosity when baked. An exception to this
is the production of bread containing 20–100% rye flour, where
the application of sourdough and low pH are required.

Bread Formulation

The formulation of bread is determined by several factors. In
a simple bread, the baking properties of the flour are of vital
importance in determining the characteristics of the loaf using
a given technology. In addition, the bread obtained from using
poor bread flour or suboptimum technology may be improved
by using certain additives (Table 31.1).
The major methods used to prepare bread are summarized in
Figure 31.2. In the straight dough method, all the ingredients are
added together at the start of the process, which includes two
fermentation steps and then two proofing steps. In the sponge
and dough method, only part of the dry ingredients are added
to the water, and this soft dough undergoes a fermentation of
about 5 hours before the remainder of the ingredients are added
and the dough is kneaded to develop the structure. Although
these processes are time consuming, their advantages are that
they develop a good flavor in the bread and that the timing and
technology of the processes are less critical (Hoseney 1998).
Mechanical dough development processes, such as the Chorley-
wood bread process developed in the United Kingdom in the
1960s, radically cut down the total bread-making time. The fer-
mentation step is virtually eliminated, and dough formation is
achieved by intense mechanical mixing and by various additives
that hasten the process (Kent 1983). The resulting loaf has a high
volume and a thin crust but lacks flavor and aroma. The trend
is now away from this kind of process due to customer demand
for more flavorful bread and reduced use of additives.
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