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


31 Bakery and Cereal Products 599

 The ability to quickly commence maltose utilization when
the glucose in the flour is depleted.
 The ability to store high concentrations of trehalose, which
gives tolerance to freezing and to high sugar and salt
concentrations.
 Tolerance to bread preservatives such as propionate.
 Viability and retained activity during various storage
conditions.

In the future, strains will probably be developed with even
more useful properties. In particular, the flavor-forming proper-
ties will receive special attention (Walker 1998b).

The Role of Yeast in Leavened Bread

When yeast is incorporated into the dough, conditions allow a
resumption of metabolic activity, although there is little actual
multiplication of the yeast during shorter bread-making pro-
cesses such as the straight dough and Chorleywood processes
(Fig. 31.2). The yeast has been produced under aerobic (respi-
ratory) conditions and is therefore adapted to this metabolism,
but conditions very quickly become anaerobic in bread dough
since the oxygen incorporated in the dough is soon depleted.
The sugars are metabolized to pyruvate by glycolysis; pyruvate
is then decarboxylated to acetaldehyde, thus producing carbon
dioxide; and then ethanol is formed by reduction of acetaldehyde
by NADH 2 (Fig. 31.3). For each molecule of glucose (or half
molecule of maltose) that is metabolized, two molecules each
of ethanol and carbon dioxide are produced. This fermentative

metabolism is the prevalent pathway inS. cerevisiaein dough
due both to the absence of oxygen and to the nonlimiting supply
of fermentable sugars (Maloney and Foy 2003).
The amount of maltose available is a complex interaction
between the amount of damaged starch, the level of amylases in
the flour and the stage, and length of the fermentation process.
Maltose accumulates during the early stages of the fermentation
because it is generated by amylase but is not metabolized by
the yeast because the presence of glucose represses maltose
utilization.
When readily fermentable sugars (glucose and fructose) are
exhausted, the yeast shows a lag in fermentation and then turns
its metabolism to the maltose produced from the action of
β-amylase on starch. If sucrose has been added in the bread
formulation (e.g., 4%), this is fermented in preference to mal-
tose, and the lag in the fermentation may not be observed. High
amounts of added sucrose (e.g., 20%) significantly retard fer-
mentation due to the high osmotic stress on the yeast (Maloney
and Foy 2003).
The products of yeast metabolism in dough fermentation vary
considerably with pH. In bread, the pH is usually below 6.0,
but above this, end products in addition to ethanol and CO 2
are formed, such as succinate, acetic acid, and glycerol, and less
ethanol and CO 2 are formed.S. cerevisiaeis also able to degrade
proteins and lipids, and several flavor compounds are produced
(Fig. 31.3).
It is generally not considered that the yeast fermentation is
important for bread flavor and aroma development in traditional

Figure 31.3.Biochemical changes during yeast fermentation of bread.
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