Food Biochemistry and Food Processing (2 edition)

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300 Part 3: Meat, Poultry and Seafoods

3
2 Mixing
Addition
of buffer

and
enzyme

1
Muscle sample
from carcass
extraction

5 4
Enzyme extract
and substrate
added to

Incubation
and
lecture in

6
Computer

reaction buffer in
multiwell plates

spectrofluorimeter

recording

Figure 15.11.Example of application of biochemical-based
methods for evaluation of meat quality. A sample of the carcass
(1) is mixed with buffer (2) for enzyme extraction and
homogenization (3). Enzyme extracts are placed in the wells of a
multiwell plate and synthetic substrates, previously dissolved in
reaction buffer, are added (4). The released fluorescence, which is
proportional to the enzyme activity, is read by a multiwell plate
spectrofluorometer (5) and computer-recorded (6).

Biochemical Assay Techniques

Biochemical assay methodologies are based on biochemical
compounds that can be used as markers of meat quality. The
mode of operation is essentially schematized in Figure 15.11.
Some of the most promising techniques include assay of pro-
teolytic muscle enzymes and use of peptides as biochemical
markers.
The assay of certain proteolytic muscle enzymes such as cal-
pain I, alanyl aminopeptidase, or dipeptidylpeptidase IV at just 2
hours postmortem, has shown good ability to predict the water-
holding capacity of the meat (Toldr ́a and Flores 2000). Modified
assay procedures, based on the use of synthetic fluorescent sub-
strates, have been developed to allow relatively fast and simple
measurements of enzyme activity with enough sensitivity.
Some peptides have been proposed as biochemical markers
for meat tenderness, which is particularly important in beef.
These are peptides with molecular masses ranging from 1282 to
5712 kDa, generated from sarcoplasmic and myofibrillar pro-
teins (Stoeva et al. 2000). The isolation and identification of
these peptides are tedious and time consuming, but once the
full sequence is known, Enzyme-linked immunosorbent assay
(ELISA) test kits can be developed, and this would allow rapid
assay and online detection at the slaughterhouse.

BIOACTIVE COMPOUNDS


It is well known that meat contains a large amount of proteins
with high biological value. However, in recent years, the bioac-
tivities of certain compounds that are present in meat, even
though in minor amounts, have received increased attention be-
cause they may have an important nutritional role.

CLA is a group of isomers of octadecadienoic acid that is
abundant in the fat of ruminants like cattle and sheep. The con-
tent may change depending on the breed, feed, and age. CLA has
been reported to reduce the risk for certain types of cancer like
the colorectal cancer as well as having other activities like an-
tiartherioesclerotic, antioxidative, and also playing certain role
in controlling obesity (Arihara and Motoko 2010).
Some of these substances are small peptides, which are present
in meat. Dipeptides carnosine and anserine are present in meat
although their content varies depending on the animal species
and the type of muscle metabolism (Aristoy et al. 2004, Aristoy
and Toldr ́a 2004, Mora et al. 2008). Both peptides have shown
good resistance to proteases and a good antioxidant activity.
Other bioactive peptides are derived from meat proteins after di-
gestion. These peptides exert an antihypertensive effect through
the inhibitory action on the angiotensin I converting enzyme. So,
several bioactive peptides have been identified and sequenced
after simulated in vitro gastrointestinal digestion of pork meat
proteins (Escudero et al. 2010a, 2010b).
In summary, there are many biochemical and chemical re-
actions of interest in raw meats that contribute to important
changes in meat and affect its quality. Most of these changes, as
described in this chapter, have an important role in defining the
aptitude of the meat as raw material for further processing.

REFERENCES


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