Fluidized Bed Drying of Wheatgrass: Effect of Temperature on Drying Kinetics, Proximate Composition, Functional Properties, and Antioxidant Activity.

Wheatgrass is a valuable source of nutrients and phytochemicals with therapeutic properties. However, its shorter life span makes it unavailable for use. So, storage-stable products must be developed through processing in order to enhance its availability. Drying is a very important part of the processing of wheatgrass. Thus, in this study, the effect of fluidized bed drying on the proximate, antioxidant, and functional properties of wheatgrass was investigated. The wheatgrass was dried in a fluidized bed drier at different temperatures (50, 55, 60, 65, 70 °C) using a constant air velocity of 1 m/s. With increasing temperature, the moisture content was reduced at a faster rate, and all drying processes took place during the falling rate period. Eight mathematical models under thin layer drying were fitted into the moisture data and were evaluated. The Page model was the most effective in explaining the drying kinetics of wheatgrass, followed by the Logarithmic model. The R2, chi-square, and root mean squared value for Page model was 0.995465-0.999292, 0.000136-0.0002, and 0.013215-0.015058, respectively. The range of effective moisture diffusivity was 1.23-2.81 × 10-10 m2/s, and the activation energy was 34.53 kJ/mol. There was no significant difference in the proximate composition of was seen at different temperatures. The total phenolic content (117.16 ± 0.41-128.53 ± 0.55 mgGAE/g), antioxidant activity (33.56 ± 0.08-37.48 ± 0.08% (DPPH), and FRAP (1.372 ± 0.001-1.617 ± 0.001 mgAAE/g) increased with the rise in temperature. A significant increase was observed in functional properties, except for the rehydration ratio, which decreased with rising temperature. The current study suggests that fluidized bed drying improves the nutritional retention of wheatgrass with good antioxidant activity and functional properties that can be used to make functional foods.

Detoxification of Meghalayan cherry (Prunus nepalensis) kernel and its effect on structural and thermal properties of proteins.

Valorizing food wastes and by-products can improve economic and environmental sustainability of the food production chain. In this regard, Meghalayan cherry kernels are a good source of proteins, but the presence of toxic compounds like amygdalin, makes them underutilized. Therefore, the present study was focused on detoxifying Meghalayan cherry kernel using thermal, soaking and ultrasound treatments and studying their impact on the structural and thermal characteristics of protein isolate. The results showed that all three treatments significantly reduced amygdalin content, with complete detoxification achieved after 30 and 60 min at 70 °C and 60 °C, respectively, in ultrasound, and after 90 and 120 min at 70 °C and 60 °C, respectively, in soaking + thermal treatment. The detoxification treatments significantly affected the protein content and weight-loss of Meghalayan cherry kernel. Fluorescence spectroscopy and FTIR showed alterations in Meghalayan cherry kernel protein isolate (MCKPI) secondary and tertiary structure. The fluorescence intensity was observed at 340 nm for native and detoxified protein isolate, and the lowest peak for MCKPI-US depicts conformational changes. The fading of bands in SDS-PAGE confirms structural changes due to thermal and sonication effects. SEM images demonstrated that more cracks and porous structures were seen in treated MCKPI than native MCKPI. Detoxification treatment increased thermal stability, resulting in lesser weight loss and higher denaturation temperature than native MCKPI. In this study, ultrasound treatment demonstrated the most pronounced effects on the detoxification of MCKPI and its thermal and structural properties, suggesting that Meghalayan cherry kernel is one of the most promising substrates for zero-waste bioprocess development.

Recent Advances in Drumstick (Moringa oleifera) Leaves Bioactive Compounds: Composition, Health Benefits, Bioaccessibility, and Dietary Applications.

Based on the availability of many nutrients, Moringa oleifera tree leaves have been widely employed as nutrients and nutraceuticals in recent years. The leaves contain a small amount of anti-nutritional factors and are abundant in innumerable bioactive compounds. Recently, in several in vivo and in vitro investigations, moringa leaves' bioactive components and functionality are highlighted. Moringa leaves provide several health advantages, including anti-diabetic, antibacterial, anti-cancer, and anti-inflammatory properties. The high content of phytochemicals, carotenoids, and glucosinolates is responsible for the majority of these activities as reported in the literature. Furthermore, there is growing interest in using moringa as a value-added ingredient in the development of functional foods. Despite substantial study into identifying and measuring these beneficial components from moringa leaves, bioaccessibility and bioavailability studies are lacking. This review emphasizes recent scientific evidence on the dietary and bioactive profiles of moringa leaves, bioavailability, health benefits, and applications in various food products. This study highlights new scientific data on the moringa leaves containing nutrient and bioactive profiles, bioavailability, health benefits, and uses in various food items. Moringa has been extensively used as a health-promoting food additive because of its potent protection against various diseases and the widespread presence of environmental toxins. More research is needed for utilization as well as to study medicinal effects and bioaccesibility of these leaves for development of various drugs and functional foods.