Food Biochemistry and Food Processing (2 edition)

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BLBS102-c15 BLBS102-Simpson March 21, 2012 13:21 Trim: 276mm X 219mm Printer Name: Yet to Come


15 Biochemistry of Raw Meat and Poultry 299

Figure 15.9.Classification of pork carcasses in the slaughterhouse.
(Courtesy of Industrias Carnicas Vaquero SA, Madrid, Spain.) ́

first, and a number for the fat level. In some countries, additional
grading systems may be added. For instance, in France, the color
is measured and rated 1 to 4 from white to red color.

New Grading Systems

New grading systems are being developed that take advantage of
the rapid developments in video image analysis and other new
physical techniques as well as those in biochemical assay tests.
New methodologies based on physical methods for the online
evaluation of meat yield and meat quality, applied as schematized
in Figure 15.10, include near infrared reflectance (NIR), video
image analysis, ultrasound, texture analysis, nuclear magnetic
resonance, and magnetic resonance spectroscopy techniques.

Physical Techniques

NIR is applied for the rapid and nondestructive analysis of meat
composition in fat, protein, and water (Byrne et al. 1998, Rod-
botten et al. 2000). This technique has also been applied to
aged meat, giving a good correlation with texture, and thus
constituting a good predictor for meat tenderness. In addition,
NIR spectroscopy allows for a minimal or nonnecessary sample
preparation (Niemoller and Behmer 2008). Video image analysis ̈
is very useful for the measurement of carcass shape, marbling,
and meat color. Conductivity has been in use for several years
to predict meat composition and quality.
Ultrasounds are based on the measurement of different param-
eters such as velocity, attenuation, and backscattering intensity
and may constitute a valuable tool for the measurement of meat
composition (Got et al. 1999, Abouelkaram et al. 2000). Texture

Figure 15.10.Example of application of physical-based methods
for the online evaluation of meat yield and quality. At the
slaughterhouse, the hand-held devices are applied to the carcass
between the last three and four ribs (place marked with anarrow).
The signal is then received in the unit and computer-processed. The
carcass quality is estimated and, depending on the technique, is
also classified by yield. (Courtesy of Industrias Carnicas Vaquero ́
SA, Madrid, Spain.)

analysis, as the image processing of the organization of gray
pixels of digitized images, can be used for the classification
of photographic images of meat slices (Basset et al. 2000). This
technique appears to give good correlation with fat and collagen,
which are especially visible under ultraviolet light, and would
allow classification according to three factors, muscle type, age,
and breed (Basset et al. 1999).
Nuclear magnetic resonance has good potential as a nonin-
vasive technique for better characterization and understanding
of meat features. Thus, magnetic resonance imaging can give
a spatial resolution that characterizes body composition. This
technique is well correlated to important meat properties such
as pH, cooking yield, and water-holding capacity (Laurent et al.
2000). Magnetic resonance spectroscopy may be useful to de-
termine the fatty acid composition of animal fat. This technique
may have further applications; for example, in the possible use
of^23 Na imaging to follow brine diffusion in cured meat products
(Renou et al. 1994).
The use of bioimpedance spectroscopy has shown good per-
formance for the assessment of meat quality, especially to dis-
tinguish among PSE, DFD, and normal pork meats (Castro-
Gir ́aldez et al. 2009, 2010a). The amount of ATP is character-
istic for each type of pork meat quality and the ion activity of
ATP may be correlated with the ionic dispersion in the dielectric
spectra (Castro-Giraldez et al. 2010b). ́
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