Food Biochemistry and Food Processing (2 edition)

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BLBS102-c21 BLBS102-Simpson March 21, 2012 13:39 Trim: 276mm X 219mm Printer Name: Yet to Come


21 Fish Gelatin 399

Figure 21.5.Reaction between phenolic compounds and side chain of gelatin.

and fewer free amino groups. Dynamic light scattering analyses
showed that such cross-linking results in denser polymeric net-
works. Aewsiri et al. (2009b) reported that cuttlefish skin gelatin
modified with oxidized phenolic compounds, including ferulic
acid and tannic acid, at the level above 5% (w/w of protein) ex-
hibited a decrease in the emulsion activity index (EAI). This was
possibly associated with the decrease in surface hydrophobicity
of the modified gelatin.

Genipin

Genipin is a hydrolytic product of geniposide and its related iri-
doid glucosides, which are extracted from the fruits ofGardenia
jasminoides Ellis(Yao et al. 2004) via enzymatic hydrolysis with
β-glucosidase (Butler et al. 2003). Genipin has been known as a
naturally occurring cross-linking agent (Nickerson et al. 2006b).
Genipin participates in both short- and long-range covalent
cross-linking ofε-amino groups in amine-containing polymers
(Nickerson et al. 2006a). It can react with amino acid or proteins
in the presence of oxygen to form dark blue pigments used in
the fabrication of food dyes (Touyama et al. 1994). Additionally,
it can form stable cross-linked products with resistance against

enzymatic degradation, comparable to that of glutaraldehyde-
fixed tissue (Huang et al. 1998, Sung et al. 1998). Further-
more, gelatin-derived bioadhesives display higher biocompat-
ibility and less cytotoxicity when cross-linked with genipin than
with other agents, such as formaldehyde, glutaraldehyde, and
epoxy compounds (Sung et al. 1999). The mechanism of the
reaction of amino acids or proteins with genipin is proposed by
Touyama’s group (Touyama et al. 1994a, 1994b). The formation
of the genipin–methylamine monomer is through a nucleophilic
attack by methylamine on the olefinic carbon at C-3 in genipin,
followed by the opening of the dihydropyran ring and an attack
by the secondary amino group on the resulting aldehyde group.
The blue-pigment polymers are presumably formed through the
oxygen radical-induced polymerization and dehydrogenation of
several intermediary pigments.
Yao et al. (2004) reported that genipin is a good cross-linker
for the gelatin. The rate of degradation and the degree of cross-
linking of the genipin-fixed gelatin depend upon genipin con-
centration. Moreover, increasing genipin concentration makes
the gelatin network gradually shift from being dominated by hy-
drogen bonds to covalent cross-linking (Nickerson et al. 2006b).
However, the concentration of genipin should exceed 0.5% (w/v)
of the overall weight of the gelatin-based material (25% (w/v))
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