Abstract
Whey being a by-product of dairy industry, although is highly nutritive, was previously regarded as a waste but with time found its application in feedstock, pharmaceutical and food industry. Whey’s composition varies with respect to multiple factors such as source of milk, type of whey (acid or sweet whey) etc. Main challenge in whey utilization is that it has less quantity of whey constituents which need to be purified. Previously, the methods such as heat or acid treatment, precipitation and salting out were efficient only on laboratory scale and caused degradation of native protein structure making it difficult to understand its functional, nutritional and therapeutic properties, shifting focus towards innovative techniques which give product of high purity, are rapid, efficient, cost effective, eco-friendly and easy to be scaled up. Among such techniques, membrane separation and chromatography are widely employed ones. There is always a concern about purity and use of a single technique leads to compromise between purification level and overall purified product yield, shifting focus towards coupling of separation techniques. The following article is a comprehensive approach towards novel approaches for the isolation and separation of different whey constituents such as whey protein isolate and whey protein hydrolysate etc. along with their application in dairy, food and pharmaceutical industry and animal feedstock.
Highlights
During cheese and casein manufacturing; coagulation of casein proteins by chymosin; a by-product of great significance is obtained; named whey which is a multi-component protein [1]
The results showed that approximately 92% highest recapture of LPO was obtained
The results showed that 94% recovery of Bovine serum albumin (BSA) and 80% recovery of LF was obtained
Summary
During cheese and casein manufacturing; coagulation of casein proteins by chymosin; a by-product of great significance is obtained; named whey which is a multi-component protein [1]. It was discovered about 3000 years ago when the milk coagulation was observed during storage and transport of calves’ stomach (an old mean of milk storage) which is naturally rich in enzyme chymosin; leading to initiation of cheese and whey industry [2]. The methods employed cause degradation of individual whey components during processing; making it difficult to understand it’s functional; nutritional and therapeutic properties. That’s why there is a need of employing such protocols which will produce each whey component on pilot scale without harming its functional properties or structure [2]
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