Frozen storage of shellfish is an i

Frozen storage of shellfish is an important preservation
method; however deterioration in texture, flavor, and color of
muscles frequently occurs with poor conditions during the
process (Hale &Waters, 1988). Freezing slows enzyme activity and
inhibits microorganism growth. However, lipid hydrolysis and
oxidation still occur. The extent of quality loss of marine frozen
food is dependent upon many factors, which include storage
temperature and time, packaging, rate of freezing–thawing, and
temperature fluctuations and freeze–thaw abuse (Srinivasan,
Xiong, & Blanchard, 1997). Prolonged frozen storage of Egyptian
shore crabs (Carcinus maenas) at 10 C affected the chemical
characteristics of crab meat (Aman, Moustafa, Zoueil, & Ghaly,
1983). However, the sensory quality of blue crab (Callinectes
sapidus) was maintained at 18 C for 10 months. Muscle proteins
of freshwater prawn tails are susceptible to freezing–thawing
processes, particularly during the first month of frozen storage
(Srinivasan et al., 1997). Ice crystals and the increase in ionic
strength of the system during frozen storage induced myosin
denaturation and the disruption of the actin–myosin complex, as
indicated by the decrease in both Ca2þ-ATPase and Mg2þ–Ca2þ-
ATPase activities, respectively (Benjakul & Bauer, 2000, 2001). Ang
and Hultin (1989) reported that crosslinking of cod myosin stored
at 25 and 80 C correlated with the decrease in ATPase activity.
Lipid hydrolysis and lipid oxidation generally take place in fish
muscle during the extended frozen storage (Aubourg, 1999).
Subramanian (2007) reported that the lipid hydrolysis and
oxidation took place in raw marine crab (Portunus pelagicus)
during 120 days of frozen storage at 41 C.