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3 Enzymes in Food Analysis 45Table 3.2.(Continued)Food Component Enzymes Involved Commercial Kit ReferenceOther Components
Citric acid Citrate lyase Wiseman 1981, Mello and
Kubota 2002,
Prodromidis and
Karayannis 2002, Cock
et al. 2009
Catechol/polyphenols Polyphenol oxidase, tyrosinase
Oxalate Oxalate oxidase
Lactate Transaminase, lactate dehydrogenase
Aspartame Carboxyl esterase, alcohol oxidase,
aspartase, carboxypeptidase,
chymotrypsin, glutamate oxidase
Alcohol Alcohol dehydrogenase Megazyme International Wiseman 1981, Mello and
Kubota 2002, Cock et al.
2009
Ascorbic acid Ascorbic acid oxidase Megazyme International
Xylitol Alkaline phosphatase (ELISA) Sreenath and Venkatesh
2010enzyme reactor (Matsumoto et al. 1988). In the analysis of wine
components, Zeravik et al. (2009) have discussed the use of (a)
PQQ-bound dehydrogenases for the determination of glucose,
alcohol, and glycerol; (b) tyrosinase, laccase, and peroxidase for
phenolic compounds; and (c) sulfite oxidase for sulfite content.
For analysis of starch, a complex polysaccharide, the under-
lying principles of starch liquefaction and saccharification are
utilized. Theα-amylases hydrolyze starch, releasing maltose
units and limit dextrin. This is characterized by viscosity re-
duction or what is more commonly referred to by the starch
industry as liquefaction. Further treatment with pullulanase and
amyloglucosidases (glucoamylases) results in hydrolysis of the
maltose units and limit dextrin, ultimately producing glucose
units that are subsequently analyzed by some of the methods
discussed earlier. Figure 3.5 illustrates the salient features of the
amylase, pullulanase, and amyloglucosidase reaction. Analyses
of other polysaccharides have been conducted in similar fashion
by initial breakdown to simpler sugars using different carbo-
hydrases depending on the nature of the substrate. Dextranases
have been used for dextrans, cellulases for cellulose, hemicel-
lulases for hemicelluloses in dietary fiber, and pectinases and
polygalacturonases for polysaccharides in soy sauce and other
plant-based foods (Wiseman 1981). Table 3.2 provides a list ofsome of the enzymatic methods for food component analysis
along with some of the commercially available test kits.Other Food ComponentsAlcoholAlcohol (ethanol) content in beer, wine, and other alcoholic bev-
erages is a very important quality attribute and is also required
for regulatory classification. The NAD-dependent alcohol de-
hydrogenase is widely used for analysis of alcohol content in
foods and alcoholic beverages. The enzyme catalyzes oxida-
tion of ethanol to acetaldehyde in an equilibrium reaction that
also produces NADH. The reaction is made to proceed in the
forward direction by acetaldehyde reaction with semicarbazine
or hydrazine. The absorbance change resulting from NAD+to
NADH conversion is proportional to alcohol content. Similar
NAD-dependent assays have been used for measuring glycerol
content in foods. Figure 3.6 shows the principle underlying the
method for glycerol analysis.CholesterolConsumption of cholesterol-rich foods and their association
with atherosclerosis, hypertension, and high incidence of otherD-FructoseFructos dehydrogenase2[Fe(CN) 6 ]4– 2e–
Electrode
+400 mV5-Keto-D-fructose 2[Fe(CN) 6 ]3– 2H+Figure 3.4.Schematic representation of the principle of fructose sensor based on fructose dehydrogenase.