BLBS102-c21 BLBS102-Simpson March 21, 2012 13:39 Trim: 276mm X 219mm Printer Name: Yet to Come
21 Fish Gelatin 391
Levine 1987, Galea et al. 2000). Generally, gelatin quality is
determined by the length of collagen chains: longer chains pro-
duce higher quality gelatin (Tomka 1982, Galea et al. 2000). To
obtain the high-quality gelatin, acid process should be used for
gelatin production since this process disrupts acid-labile colla-
gen cross-links with negligible peptide bond hydrolysis and less
amino acids are destroyed (Slade and Levine 1987, Galea et al.
2000). However, raw materials with high amount of molecu-
lar cross-links result in the lower extraction yield (Galea et al.
2000). To increase the extraction yield, some proteases capable
of solubilizing the collagen or cleaving the cross-links have been
applied during acid process. In general, triple-helical domain of
collagen is relatively resistant to proteolytic attack, while the ter-
minal telopeptide regions, which contain inter- and intramolecu-
lar cross-links, are readily cleaved (Galea et al. 2000). Chomarat
et al. (1994) prepared bovine skin gelatin using pepsin or proc-
tase (isolated fromAspergillus niger) to solublize the collagen
prior to extraction at 90âŚC. Both enzymes solubilized collagen
with a yield of 75â76% as calculated from hydroxyproline con-
tent. After heating, collagen was converted to gelatin with yields
of 32% and 39% when pepsin and proctase were used as the ex-
traction aid, respectively. Nalinanon et al. (2008) reported that
the extraction yield of gelatin from bigeye snapper skin treated
with pepsin during swelling process was approximately two fold
higher than that of gelatin from skin without pepsin treatment.
Extraction of gelatin
When the heat is applied, collagen fibrils shrink to less than one-
third of their original length at a critical temperature known as the
shrinkage temperature (Foegeding et al. 1996). This shrinkage
involves a disassembly of fibers and a collapse of the triple-
helical arrangement of polypeptide subunits in the collagen
molecule. During the collagen to gelatin transition, many non-
covalent bonds are broken along with some covalent inter- and
intramolecular bonds (Schiff base and aldo-condensation bonds)
and a few peptide bonds are cleaved. Heat applied at tempera-
ture higher than transition temperature (Tmax) is able to disrupt
the bonds, mainly H-bond, which stabilizes collagen structure
(Fig. 21.2). This results in conversion of the helical collagen
structure to a more amorphous form known as gelatin. Never-
theless, when the collagen molecule is completely destructured,
glue is produced instead of gelatin (Foegeding et al. 1996).
The conversion of collagen to gelatin yields molecules of vary-
ing mass, depending on the temperatures used, indigenous pro-
teinases, and so on. Therefore, gelatin is a mixture of fractions
varying in molecular weight from 15 to 400 kDa (Gelatin Man-
ufacturers Institute of America 1993).
The maximum yield together with the desirable physical prop-
erties is the main objective for the processor. The pH of extrac-
tion can be selected either for the maximum extraction rate
Figure 21.2.Gelatin network associated with hydrogen bond, hydrophobic interaction, and ionic interaction.