ABSTRACT
In the current study, partially defatted coconut flour (PDCF) was prepared using deoiled cake obtained after virgin coconut oil processing. The proximate analysis of PDCF revealed the presence of 5.21% moisture, 14.03% fat, 21.34% protein, 46.39% fiber and 3.27% ash, along with prominent functional properties. Herein, muffins were prepared by incorporation of PDCF as a replacement of refined wheat flour (RWF) at 0, 25, 50, 75 and 100% flour blend. Significant changes in batter rheology were observed after 25 to 100% replacement of RWF with PDCF, which indicated a decrease in peak viscosity and final viscosity by 65.05 to 83.59% and 61.57 to 85.17% respectively, an increase in specific gravity of batter by 0.857-0.929 g/L. The prepared muffins had significant variations in colour of crust and crumb regions as represented by changes in L*a*b*, Hue angle (h°) and Chroma (C) and textural properties such as hardness, springiness, guminess, cohesiveness, chewiness, and resilience. Incorporation of 50% PDCF significantly (P < 0.05) increased the overall acceptability of the muffins (with a maximum score of 8.5), with a fiber content of 5.53 ± 0.23% and protein content of 7.57 ± 0.30%. Storage stability studies performed at 25 ± 2 °C for seven days revealed an increase in microbial count, and reduction in textural properties but both to be in acceptable regime. Supplementary Information: The online version contains supplementary material available at 10.1007/s13197-023-05857-2.
ABSTRACT
Cold plasma (CP) is an upcoming technology implemented for the preservation of highly perishable foods, especially aquatic food products (AFPs). The high moisture content, high-quality protein with all essential amino acids and unsaturated fatty acids makes AFP more susceptible to microbial spoilage and oxidation of lipids and proteins. Spoilage lowers the nutritive value and could generate toxic components, making it unsafe for consumption. In recent times, the rising demand for food products of aquatic origin with preserved quality and extended shelf-life has been recorded. In addition, minimally or nonthermally processed and preserved foods are gaining great attention. CP technology has demonstrated an excellent ability to inactivate microorganisms without promoting their resistance and triggering some deteriorative enzymes, which are typical factors responsible for the spoilage of AFP. Consequently, CP could be recommended as a minimal processing intervention for preserving the quality of AFP. This review focuses on different mechanisms of fish spoilage, that is, by microorganisms and oxidation, their inhibition via the application of CP, and the retention of quality and shelf-life extension of AFP.
