3.4. Total volatile basic-nitrogen

3.4. Total volatile basic-nitrogen (TVB-N)

Changes in TVB-N of vacuum-packaged, sulphited, 50% N2 + 50% CO2 and 100% N2-treated GRS samples with storage time (months) are showed in Fig. 2. At initial stage of storage, all treated GRS samples displayed relatively acceptable TVB-N values that could be likened to those of other related crustacean shrimp subject to non-thermal preservative treatments (Bono, Badalucco et al., 2012). By comparisons, the TVB-N of all treated GRS samples at storage exhibited slight increases initially, which thereafter appeared fairly fluctuated (P < 0.05). Like the present study, a similar trend of TVB-N was also detected by Bono, Badalucco et al. (2012) in deep water rose shrimp subject to MAP combined treatment conditions. At second half of storage and onwards, increases in TVB-N were found particularly at 50% N2 + 50% CO2-treated group relative to the other treated GRS samples that showed somewhat stable trends. Furthermore, the authors’ of this study opine that the gradual increases in TVB-N at first half of investigated storage of 100% N2- and 50% N2 + 50% CO2-treated GRS groups appear akin, with 50% N2 + 50% CO2 particularly suggestive of rather positive effect of CO2 inclusion in mitigating volatile amine production. Furthermore, while it is somewhat surprising that increases in TVB-N appeared rapid between months 4 and 6 specifically for 50% N2 + 50% CO2-treated GRS group, and that such increases would not be compatible with the standard index of seafood freshness (Bono, Badalucco et al., 2012), the continuous increases in TVB-N thereafter to best of knowledge is the first record of the rather opposite effect of MAP gas mixtures of 50% N2 + 50% CO2 working in the capacity of preservative treatments, which could suggest the action of other useful factors such as free amino acid deamination as well as degradation of nucleotides actuating the production of TVB-N. In addition, the differences in TVB-N found at treated-GRS samples would substantiate the formation of dimethylamine (DMA) from trimethylamine N-oxide (TMAO) by non-enzymatic reactions ( Bono, Badalucco et al., 2012, Okpala, 2015b and Okpala et al., 2014), which could rapidly accelerate if sulphite treatments were incorporated (Spinelli & Koury, 1979). It is also believed that enzymatic production of DMA and formaldehyde (FA) from TMAO can also be readily nitrosated onto N-nitrosodimethylamine ( Bono, Badalucco et al., 2012, Okpala et al., 2014 and Spinelli and Koury, 1979). Hence, the cumulative effect of the sulphite treatment might as well detriment the overall quality of shrimp. While TVB-N values of treated GRS samples herein can be compared with other Mediterranean shrimp species ( Bono, Badalucco et al., 2012 and Lopez-Caballero et al., 2002), the TVB-N results obtained at the end of storage would surpass the widely accepted limit of 30 mg/100 g. This 30 mg/100 g limit of acceptability of TVB-N however, in addition to the wide category of crustacean products that may present similar TVB-N outcomes if subjected to similar conditions like that of present study thus necessitates additional evaluation concerning the limit of acceptability specifically at frozen storage.