New insights in food security and environmental sustainability through waste food management.

Food waste has been identified as one of the major factors that constitute numerous anthropogenic activities, especially in developing countries. There is a growing problem with food waste that affects every part of the waste management system, from collection to disposal; finding long-term solutions necessitates involving all participants in the food supply chain, from farmers and manufacturers to distributors and consumers. In addition to food waste management, maintaining food sustainability and security globally is crucial so that every individual, household, and nation can always get food. "End hunger, achieve food security and enhanced nutrition, and promote sustainable agriculture" are among the main challenges of global sustainable development (SDG) goal 2. Therefore, sustainable food waste management technology is needed. Recent attention has been focused on global food loss and waste. One-third of food produced for human use is wasted every year. Source reduction (i.e., limiting food losses and waste) and contemporary treatment technologies appear to be the most promising strategy for converting food waste into safe, nutritious, value-added feed products and achieving sustainability. Food waste is also employed in industrial processes for the production of biofuels or biopolymers. Biofuels mitigate the detrimental effects of fossil fuels. Identifying crop-producing zones, bioenergy cultivars, and management practices will enhance the natural environment and sustainable biochemical process. Traditional food waste reduction strategies are ineffective in lowering GHG emissions and food waste treatment. The main contribution of this study is an inventory of the theoretical and practical methods of prevention and minimization of food waste and losses. It identifies the trade-offs for food safety, sustainability, and security. Moreover, it investigates the impact of COVID-19 on food waste behavior.

Walnut fruit: Impact of ethylene assisted hulling on in vitro antioxidant activity, polyphenols, PUFAs, amino acids and sensory attributes.

The effects of three different hulling methods wiz natural heaping/traditional (T1), steeping (T2), and spraying (T3), on moisture, colour, fat, free amino acids, fatty acids, antioxidant activities, flavonoids, tannins, total phenolic content, and organoleptic qualities of walnut kernels were examined in this study. The kernels extracted from walnuts subjected to T3 method recorded significantly (p ≤ 0.05) highest DPPH inhibition (68.61 %), ABTS (54.56 %inhibition) and FRAP (0.106 µM trolox/100 g); flavonoids (1993.08 mg QE/100 g), tannin content (0.312 %) and phenols (0.736 mg GAE/g) compared to T1 and T2. Walnut kernels of T3 treatment group were rated better in terms of taste (3.8), odour (3.6) and overall acceptability (3.78) Furthermore, walnut kernels obtained from T3 treatment group exhibited the highest percentage of unsaturated fatty acids (UFAs) and sweet free amino acids. The outcome of the present study offers a fresh viewpoint regarding the hulling processes of green walnuts to meet the quality requirements of walnut kernels.