Methods for preparation of plant-based whey protein concentrates are provided. Also provided are the plant-based whey protein concentrates made using the methods. The methods utilize an enzymatic reaction to reduce the molecular weight of soluble carbohydrates in a plant-based whey and a single nanofiltration/ultrafiltration and/or diafiltration step to separate soluble non-protein components from the proteins.

The present disclosure relates to a method of producing lactic acid bacteria dual-coated with protein and polysaccharide by using a protein hydrolysate, and lactic acid bacteria having a dual coating, produced by the method. The lactic acid bacteria having a dual coating of protein and polysaccharide, produced according to the present disclosure, have very excellent dry-freezing viability, acid resistance and bile resistance. Accordingly, the lactic acid bacteria having a dual coating of protein and polysaccharide according to the present disclosure will be very useful for the production of fermented milk, processed milk, fermented soy products, processed foods, functional beverages, functional foods, common foods, etc.

Use of a protein hydrolysate for the preparation of baked goods, preferably cakes, particularly fat free cakes, wherein the molecular weight of the protein hydrolysate is between 600 and 2400 Da and the solubility of the protein hydrolysate is at least 85%.

An egg-free albumen replacement includes a starch, an edible gum and a hydrolyzed pea protein. The egg-free albumen replacement can include the hydrolyzed pea protein in an amount of 3 to 75 wt. %, based on the combined weights of the starch, edible gum and hydrolyzed pea protein in the replacement composition. At least some of the hydrolyzed pea protein in the egg-free albumen replacement can include partially hydrolyzed pea protein.

The present disclosure relates to an additive for treating beverages made from plant musts, particularly wine, beer, cider or fruit juices, and more particularly for improving the quality of such beverages, namely, for example, protein stability and for avoiding the cloudiness of such beverages. In its broadest application, such an additive includes a cysteine protease and a cofactor.

Methods of manufacturing products from material comprising oilcake, compositions produced from materials comprising processed oilcake, and systems for processing oilcake are provided herein. A product is produced by a method comprising de-solubilizing protein in a first material comprising oilcake to produce a processed material comprising an insoluble protein fraction by extruding the first material in a pressure range of 10 bar to 80 bar. The processed material is hydrolyzed to produce a mixture comprising the insoluble protein fraction and a hydrolyzed fraction. The insoluble protein fraction is separated from the hydrolyzed fraction. The insoluble protein fraction is processed into the product by extruding the insoluble protein fraction in a pressure range of 10 bar to 80 bar.

Provided is a method for producing a plant protein product which includes treating the plant protein with at least one an exogenous enzyme comprising an oxidoreductase and/or a hydrolase. The method results in a treated protein product that has reduced undesirable aromas and/or reduced undesirable tastes, compared to an untreated plant protein product. In a further embodiment, the method further includes mixing the treated protein product with another material to form a food composition. Also provided are compositions made by the methods of the invention.

A process for producing a plant protein ingredient and the plant protein ingredient is disclosed. The process may include comminuting the plant material into particles, thereby obtaining comminuted plant material; separating the particles of the comminuted plant material into a finer fraction and a coarser fraction; washing the finer fraction with an aqueous alcohol solution for reducing the solubility of proteins contained in the finer fraction, thereby obtaining a washed finer fraction; enzymatically treating the washed finer fraction to remove at least a part of the phytate and/or cell wall components to obtain an enzymatically treated finer fraction, and optionally removing at least a part of water soluble components from the enzymatically treated finer fraction, thereby obtaining the plant protein ingredient; and drying the plant protein ingredient to a moisture content of at most 45% (w/w).

To provide a feed that does not pollute rearing water, improves the immunity activity of leptocephalus larvae, is capable of directly feeding eel leptocephalus, and is capable of effectively inducing the growth of said larvae into glass eels. This micro-encapsulated aquaculture feed includes: an oil phase 11 having an oil-soluble nutrient component; a water phase 13 which is present inside the oil phase 11, and which includes a water-soluble nutrient component; and a film 15 which includes the oil phase 11 and the water phase 13. The water-soluble nutrient component includes at least one hydrolysate from among hydrolysates of amino acids, oligopeptides, and proteins.

The present invention relates to a nutritional formulation containing a pea protein isolate, characterized in that the pea protein isolate: contains between 0.5 and 2% of free amino acids, has a viscosity: from 13 to 1610.sup.3 Pa.Math.s. at a shear rate of 10 s.sup.1, from 10 to 1410.sup.3 Pa.Math.s. at shear rate of 40 s.sup.1, and from 9.8 to 1410.sup.3 Pa.Math.s. at a shear rate of 600 s.sup.1, has a solubility: from 30 to 40% in pH zones from 4 to 5 from 40 to 70% In pH zones from 6 to 8.

The invention also relates to the use of this nutritional formulation as a single protein source or as a food supplement, intended for infants, children and/or adults.