New insights into antibubble formation by single drop impact on a same-liquid pool.

HYPOTHESIS: Secondary drops (SDs) generated when falling drops impact a same-liquid bath can potentially generate antibubbles. Different mechanisms of antibubble formation can be identified and their size and formation probability (PAb) can be predicted. EXPERIMENTS: Surfactant solutions were dropped from various heights using a highly stable pulseless microfluidic pump in a same-liquid bath. The impact was recorded using a high-speed camera. The formation of SDs and antibubbles as well as their sizes were evaluated considering the falling-drop height (HFD) and dimensionless parameters. FINDINGS: This study reports new mechanisms for antibubble formation from SDs. A decrease in the surface tension yielded a thinner central jet, thereby yielding more SDs. Larger values of the HFD, impact velocity (U), and Weber number (We) increased the SD size and decreased the SD count; the increase in size increased the antibubble size. The number of SDs correlated with the formation of two distinct antibubbles or a single (coalesced) antibubble. The plots for PAb versus HFD, U, and We exhibited two distinct peaks. A moderate increase in the surfactant concentration enhanced PAb in the first regime, whereas an excessive concentration limited antibubble formation. Artificial neural modeling can successfully predict antibubble formation. These findings provide valuable insights for the research on controlled antibubble generation.

Enhancement of sensory and nutritional quality of Sel-roti by the incorporation of soy flour.

Sel-roti is a doughnut-like deep-fat fried, puffed, spongy, ring-shaped, and fermented rice-flour confectionary indigenous to Nepal. This study was aimed to enhance the sensory and nutritional quality of Sel-roti by incorporating soy flour. The best product was selected by a series of sensory evaluations, and the nutritional quality was then compared with the control. Sel-roti prepared by incorporating 10% of roasted soybean flour (RSF) had significantly superior (p < .05) sensory perceptions viz. color and appearance, texture, flavor, taste, and overall acceptance among the studied samples. The moisture, crude fat, crude protein, total ash, crude fiber, iron, calcium, and energy content in the best product were significantly increased (p < .05) by the incorporation of 10% RSF. However, total carbohydrates was significantly reduced (p < .05) at 10% RSF incorporation. The results can be used by food processors to formulate a batter for the production of Sel-roti with enhanced sensory and nutritional properties.

Pigments, ascorbic acid, total polyphenols and antioxidant capacities in deetiolated barley (Hordeum vulgare) and wheat (Triticum aestivum) microgreens.

The study was aimed to evaluate if deetiolation of barley and wheat microgreens after cultivaton in dark (for 5, 7 and 9 days) can enhance the contents of pigments, ascorbic acid, polyphenols, and equivalent antioxidant capacities (EAC) (measured by DPPH and FRAP assay) in correlation to other. Chlorophylls and carotenoids were higher in microgreens that were exposed more to daylight. In contrast, ascorbic acid, polyphenols and EAC of microgreens could be enhanced by 5-7 days of etiolation. However, prolonged etiolation reduced overall antioxidant capacities of microgreens. All evaluated parameters could be satisfactorily represented by regression expressions for the given number of days of etiolation and growth. The ascorbic acid and total carotenoids content had higher correlations with total chlorophyll contents, while the antioxidant capacities were highly correlated to total polyphenols content. The study confirms the potential of deetiolated cultivation of microgreens to enhance selective phytochemicals content and EAC of microgreens.

Profile of chlorophylls and carotenoids of wheat (Triticum aestivum L.) and barley (Hordeum vulgare L.) microgreens.

The use of cereal microgreens is increasing because of increased consumer's interest in healthier products. Chlorophyll (Chl) and Carotenoids (Car) are suggested to correlate with health promoting components like phenolics and antioxidant potential of the plant-part. They also play role against clinical conditions like thalassemia and hemolytic anemia and reduce the risk of some chronic diseases, such as cancer, cardiovascular diseases, skin diseases and age-related eye diseases. This study was carried out for the comprehensive profiling of Chl and Car in wheat (Triticum aestivum L.), and barley (Hordeum vulgare L.) micro-greens between 7 and 16 days on dry basis. Chl and Car content strongly correlated with the number of days of growth. Significantly high correlations existed among Chl a, Chl b, total Chl and total Car with concomitant Chl a/b and Chl/Car ratios. The peaks for the rate of accumulation of pigments were between 7-10 days on wheat and 10-13 days on barley. The maximum content of Chl and Car were 616.63 ± 18.45 mg/100 g DM and 54.80 ± 1.72 mg/100 g DM on day 16 and statistically not significant to variety of grain. The Chl level was slightly lower than Chl rich vegetables like kale and comparable to spinach and Car level was comparable to carrots, which is higher than most of the daily consumable fruits and vegetables. Further cell-based or in vivo studies of cereal microgreens could be considered to draw more valuable information related to human health.