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16 Biochemistry of Processing Meat and Poultry 311
02
0.25
0.3
0.35
0
0.05
0.1
0.15
0.2
0.25
02040608
Activity (U/g
× 1000)
Glucuronidase
N acetyl glucosamidase
0
80
Time (d)
N
Figure 16.9.Evolution ofβ-glucuronidase and
N-acetyl-β-glucosaminidase during the processing of a
dry-fermented sausage (Toldra, unpublished data). ́
of process, and extent of cooking (Toldr ́a 2002). The generation
rate observed during in vitro incubations of muscle lipases with
pure phospholipids is the following (in order of importance):
linoleic>oleic>linolenic>palmitic>stearic>arachidonic
acid. Lipolysis may also vary depending on the type of muscle, as
oxidative and glucolytic muscles exhibit different lipase activity
(Flores et al. 1996). The generation of free short-chain fatty acids
is very low due to the lack of adequate substrate (Motilva et al.
1993b). Studies comparing pale, soft, exudative (PSE) versus
normal pork reported that phospholipase A2 activity was higher
and well correlated with the occurrence of the PSE syndrome
(Chen et al. 2010). Reverse correlation was also reported for
the antioxidant activity of glutathione peroxidase (Chen et al.
2010). The physical and chemical conditions in the muscle and
adipose tissue, especially during cooking, may affect the enzyme
activity (see Tables 16.3 and 16.4). The evolution of muscle
lipases during aging of pork meat is shown in Figure 16.11.
Lipolysis in Fermented Meats
Depending on the raw materials, type of product, and processing
conditions, the degree of contribution of endogenous and micro-
bial origin lipases will vary (Toldr ́a 2007). The relative impor-
tance of both enzyme systems has been checked with mixtures
of antibiotics and antimycotics used in sterile meat model sys-
tems ( Molly et al. 1997). The results showed a minimal effect of
antibiotics, and it was concluded that lipolysis is mainly brought
about by muscle and adipose tissue lipases (60–80% of total
free fatty acids generated), even though some variability might
be found, depending on the batch and the presence of specific
strains (Molly et al. 1997). Other authors have also observed
that fatty acids are released in higher amounts when starters are
added, but that there is significant lipolysis in the absence of mi-
crobial starters (Montel et al. 1993, Hierro et al. 1997). When pH
drops during fermentation, the action of muscle lysosomal acid
lipase and acid phospholipase becomes very important. Some
strains are selected as starters based on their contribution to
lipolysis. So,Micrococcaceaepresent a highly variable amount
of extra- and intracellular lipolytic enzymes, dependent on the
strain and type of substrate (Casaburi et al. 2008). The action of
the extracellular enzymes on the hydrolysis of triacylglycerols
becomes more important after 15–20 days of ripening (Ordonez ̃
et al. 1999). Other microorganisms used as starters areStaphy-
lococcus warneri,which gives the highest lipolytic activity, and
Triacylglycerols
In muscle and adipose tissue: In muscle tissue:
Diacylglycerols
Lipase Phospholipids
Phospholipases
Monoacylglycerols
Lipase Lysophospholipids
Lysophospholipase
Free
fatty acids
Free
fatty acids
Monoacylglycerol lipase
Oxidation
Volatile compounds
Volatile compounds
Oxidation
Figure 16.10.General scheme of lipolysis during the processing of meat and meat products.