BLBS102-c21 BLBS102-Simpson March 21, 2012 13:39 Trim: 276mm X 219mm Printer Name: Yet to Come
21 Fish Gelatin 397
Figure 21.4.Impact of endogenous protease associated with fish skin on degradation of gelatin molecules.
strength was noticeable when extraction temperature of 75◦C
was used for extraction of gelatin from the skin of both sharks
(Kittiphattanabawon et al. 2010).
Emulsifying and Foaming Properties
Emulsions and foams are heterogeneous systems consisting of
one phase dispersed in another. An emulsion is a dispersion or
suspension of two immiscible liquids, while a foam is a gas
phase dispersed in liquid (Hill 1998). Proteins extracted from
the different natural sources, for example, soy, milk, fish, meat,
and plant, can be used as the emulsifier or foaming agents be-
cause of their ability to facilitate the formation and improve
the stability of emulsion or foam (Surh et al. 2006). Gelatin is
surface-active and is capable of acting as an emulsifier in oil-in-
water emulsions and foaming agent (Lobo 2002, Cho et al. 2004,
Surh et al. 2006, Aewsiri et al. 2008, Binsi et al. 2009, Kwak
et al. 2009, Aewsiri et al. 2009a, Jongjareonrak et al. 2010).
The hydrophobic areas on the peptide chain are responsible for
giving gelatin its emulsifying and foaming properties (Galazka
et al. 1999, Cole 2000). Gelatin concentration has an impact on
interfacial properties, but these properties are also governed by
the source of the raw material.
Aewsiri et al. (2008) reported that the higher emulsifying and
foaming properties were observed in gelatin from precooked
tuna fin when the concentration of gelatin was increased. In
contrast, the emulsifying capacity of gelatin from bigeye snap-
per (Priacanthus hamrur) decreased with increasing gelatin
concentration (Binsi et al. 2009). Additionally, Aewsiri et al.
(2009a) studied the emulsifying properties, emulsion activity
index (EAI) and emulsion stability index (ESI), and foaming
properties, foam expansion (FE) and foam stability (FS) of
gelatin from cuttlefish skin with and without bleaching using
hydrogen peroxide (H 2 O 2 ). Emulsions containing gelatin from
bleached dorsal and ventral skin were more stable than those of
gelatin without bleaching. A longer bleaching time and higher
H 2 O 2 concentration led to a lower ESI of gelatin for all samples,
except for gelatin from dorsal skin in which the highest ESI was
obtained when the skin was bleached with 5% H 2 O 2 for 48 hours
(p<0.05). Surh et al. (2006) found that the oil-in-water emulsion
prepared with high-molecular weight fish gelatin (∼120 kDa)
was more stable than that prepared with low-molecular weight
fish gelatin (∼50 kDa). For foam-forming ability, gelatin from
unbleached skin, both dorsal and ventral, had a slightly lower
FE than gelatin extracted from bleached skin, while bleaching
had no effect on the FS of gelatin from ventral skin, but gelatin
from dorsal skin bleached with 5% H 2 O 2 for 48 hours showed
the highest FS (Aewsiri et al. 2009a). Jongjareonrak et al. (2010)
reported that foam capacity and foam stability of gelatin from
farmed giant catfish were higher than that from calfskin. Gelatin
from shark cartilage and precooked tuna fin showed lower foam
capacity and foam stability than gelatin from porcine skin (Cho
et al. 2004, Aewsiri et al. 2008).
Film formation
Film and coating from biopolymers such as proteins and polysac-
charides have been receiving increasing attention since synthetic
packaging films have led to serious ecological problems because
of their nonbiodegradability. Proteins are important biopolymers
possessing good film-forming ability (Benjakul et al. 2008).
Moreover, their mechanical and barrier properties are generally
superior to polysaccharide-based films (Cuq et al. 1998). Among
all proteins, gelatin has attracted the attention for the develop-
ment of edible films due to its abundance, biodegradability, and
excellent film-forming properties (Gennadios et al. 1994, Bigi
et al. 2002). Thus, it is one of the first materials applied to edible
coatings and films. The main parameters affecting film-forming
properties of gelatin are the source of raw material, extraction
method, molecular weight, film preparation method, and degree
of hydration or type and level of plasticizer used (Jongjareonrak
et al. 2006a, 2006b).
Gimenez et al. (2009) suggested that giant squid gelatin ob- ́
tained from pepsin aid process during the swelling step showed
good film-forming properties. Its puncture force, puncture de-
formation, and water permeability were 4.94 N, 46%, and