BLBS102-c35 BLBS102-Simpson March 21, 2012 14:9 Trim: 276mm X 219mm Printer Name: Yet to Come
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Biochemistry and Probiotics
Claude P. Champagne and Fatemeh Zare
Introduction
Biochemistry and Growth of Probiotic Cultures in Foods
Milk
Soy and Pulses
Prebiotics and Other Foods
Biochemistry and Stability During Storage in Foods
Protection Against Oxygen
Protection Against Acid
Biochemistry and Health Functionality
Survival to Gastric Acidity
Lactose Maldigestion
Blood Cholesterol Level
Gas Discomforts
Other Benefits
Conclusion
References
Abstract:The level of viable cells is essential to the functional-
ity of probiotic bacteria in foods. Many enzymatic activities have
been identified to be critical in the ability of probiotics cultures to
grow in food matrices, remain stable during storage, survive pas-
sage to the stomach and duodenum as well as to express activity in
the gastro-intestinal tract (GIT). The importance of the following
enzymatic activities on these functionalities will be addressed:α-
galactosidase for growth in soy and pulses as well as to help prevent
gas discomforts in the GIT,β-galactosidase for growth in milk as
well as to reduce lactose maldigestion problems in the GIT, pro-
teases for growth in milk and soy as well as to generate bioactive
peptides, oxidases and peroxidase to prevent oxygen toxicity during
fermentation and storage, proton-translocating ATPases for survival
to acid environments in foods and the GIT, bile salt hydrolase for
survival in the GIT and bioactivity toward cholesterol metabolism,
β-glucosidases for the release of bioactives (isoflavones, quercetin)
during fermentation.
INTRODUCTION
Probiotics are live microorganisms which, when administered
in sufficient quantity, confer a health benefit to the host (Araya
et al. 2002). Many health effects have been suggested: improved
carbohydrate digestion in the gastrointestinal (GI) tract, reduc-
tion of the incidence of diarrhoea, immune system enhancement,
blood cholesterol reduction (Shah 2000, Farnworth 2004). Of-
ficial recognition of these effects by regulatory agencies is be-
ginning (EFSA 2010). In light of these potential health benefits,
digestive health is considered as one of the ten key food trends
for 2010 (Mellentin 2010). As a result, the market for foods
which contain probiotic bacteria is in constant increase and is
predicted to reach US$30 billion by 2015 (Starling 2010).
From a technological and biochemical standpoint, this def-
inition of probiotics implies two important features: (1) the
cells must be viable, and (2) a certain quantity must be main-
tained. However, data suggest that, for some applications, non-
viable cells can present biological activity as well (Ouwehand
and Salminen 1998). The benefits of probiotics are increasingly
linked to specific biogenic metabolites (Stanton et al. 2005) that
may not necessarily require viable cells. In the current definition
of probiotics, fermented foods that carry bioactive compounds
but do not have viable cells are not considered to be as probi-
otics. If the functionality of the product is nevertheless directly
linked to some activity of the probiotic culture, then the concept
of “probioactive” may better apply to this health function. It
has been proposed that a probioactive be “a bioactive compound
influencing health that is synthesized by a probiotic culture or
that specifically results from the bioconversion of a food ma-
trix by a probiotic microorganism” (Farnworth and Champagne
2010). Exopolysaccharides, peptides, deconjugated metabolites
Food Biochemistry and Food Processing, Second Edition. Edited by Benjamin K. Simpson, Leo M.L. Nollet, Fidel Toldr ́a, Soottawat Benjakul, Gopinadhan Paliyath and Y.H. Hui.
©C2012 John Wiley & Sons, Inc. Published 2012 by John Wiley & Sons, Inc.
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