Functional exploration of taro starch (Colocasia esculenta) supplemented yogurt

Abstract Stabilizers are essential components of manufactured products such as yogurt. The addition of stabilizers improves the body, texture, appearance, and mouth feel of yogurt while also preventing technical defects such as syneresis. A study was conducted to optimize the concentration of taro starch in yogurt. The yogurt was fortified at different concentrations of taro starch. Taro starch levels were 0%, 0.5%, 1%, 1.5%, 2%, 2.5%, and 3%, with different storage times (0, 14, and 28 days). The Tukey honesty test was used for mean comparison (p < .1). The results of the study showed that maximum moisture and protein content was taken by using 0.5% taro starch and stored for 0 days while maximum fat % was attained in 1.5% taro starch treatment and storage time was 0 days. The maximum water‐holding capacity was increased by adding 1.5% taro starch under 14 days' storage time. Water‐holding capacity started decreasing with the increasing taro concentration. The acidity of yogurt started increasing with the increasing taro starch and the maximum acidity was taken at 2.5% taro starch concentration. The viscosity of the yogurt was maximum at 2% taro starch. As far as it concerned, sensory evolution, aroma, and taste started changing with the increasing taro starch concentration and increasing storage time. The study's goals were to optimize the taro concentration for stabilizing the yogurt synthesis and to probe the impact of taro starch on the physiochemical attributes of yogurt

Vegetable proteins as encapsulating agents: Recent updates and future perspectives

Abstract The use of proteinaceous material is desired as it forms a protective gelation around the active core, making it safe through temperature, pH, and O2 in the stomach and intestinal environment. During the boom of functional food utilization in this era of advancement in drug delivery systems, there is a dire need to find more protein sources that could be explored for the potential of being used as encapsulation materials, especially vegetable proteins. This review covers certain examples which need to be explored to form an encapsulation coating material, including soybeans (conglycinin and glycinin), peas (vicilin and convicilin), sunflower (helianthins and albumins), legumes (glutenins and albumins), and proteins from oats, rice, and wheat. This review covers recent interventions exploring the mentioned vegetable protein encapsulation and imminent projections in the shifting paradigm from conventional process to environmentally friendly green process technologies and the sensitivity of methods used for encapsulation. Vegetable proteins are easily biodegradable and so are the procedures of spray drying and coacervation, which have been discussed to prepare the desired encapsulated functional food. Coacervation processes are yet more promising in the case of particle size formation ranging from nano to several hundred microns. The present review emphasizes the significance of using vegetable proteins as capsule material, as well as the specificity of encapsulation methods in relation to vegetable protein sensitivity and the purpose of encapsulation accompanying recent interventions

Health benefits, importance, and challenges during production of cultured meat: An overview

ABSTRACTThe production of meat using animal stem cell-derived muscle tissue might conceivably do away with the need to sacrifice animals. The creation of “cultured,” “synthetic,” or “in vitro” meat has the potential to produce meat with distinct qualities more quickly and efficiently than normal meat. Although the process of growing muscle tissues in culture from stem cells has been known for a very long time, it has not yet been perfected for the production of cultured meat products for sale. Conditions for applying the technology, which is currently in its infancy, include a phenomenally high level of consumer acceptability and the development of commercially feasible large-scale production techniques. If the meat produced in vitro has physical traits that are identical to those of traditional meat in terms of color, flavor, aroma, consistency, and deliciousness, then it might be realistically viable. Higher the viability of meat production in vitro, the issues including searching for a good stem cell source and talking about the challenges faced throughout the expansion of cultured meat must be resolved. This review highlights the benefits and advancement of cultured meat, highlights its connection problems, and offers prospective solutions for production-related problems