The invention relates to the deep-fried food, in particular in the use of hydrolyzed gluten in duster composition for deep fried food.

A method of preparing a protein concentrate and protein concentrate compositions are described. The method relates to combining an aqueous process stream from a grain milling process with an oil seed material to form a slurry, steeping the slurry, and isolating a protein concentrate from the slurry. In one embodiment, the aqueous process stream comprises a soluble protein. In some embodiments, the method includes additional steps such as enzymatic treatment, washing of the isolated protein concentrate, and drying the protein concentrate.

The present invention describes a bio-based process to produce high quality protein concentrate (HQPC) by converting plant derived celluloses and carbohydrates into bioavailable protein via aerobic incubation, including the use of such HQPC so produced as a nutrient, including use as a fish meal replacement in aquaculture diets.

The present invention describes a bio-based process to produce high quality protein concentrate (HQPC) by converting plant derived celluloses and carbohydrates into bioavailable protein via aerobic incubation, including the use of such HQPC so produced as a nutrient, including use as a fish meal replacement in aquaculture diets.

A process of extracting or purifying proteinaceous material and/or fibraceous material from brewer's spent grain (BSG), the process comprising the steps of: Providing brewer's spent grain; Performing saccharification by enzymatic treatment of the brewer's spent grain and a fermentation of the saccharified brewer's spent grain with lactic acid bacteria and/or acetic acid bacteria and/or probiotics to obtain a fermented broth; and extracting and/or purifying proteinaceous and/or fibraceous material from the fermented BSG.

A process of extracting or purifying proteinaceous material and/or fibraceous material from brewer's spent grain (BSG), the process comprising the steps of: Providing brewer's spent grain; Performing saccharification by enzymatic treatment of the brewer's spent grain and a fermentation of the saccharified brewer's spent grain with lactic acid bacteria and/or acetic acid bacteria and/or probiotics to obtain a fermented broth; and extracting and/or purifying proteinaceous and/or fibraceous material from the fermented BSG.

The present invention relates to a powdered creamer composition comprising plant protein having a specific median molecular weight, sodium bicarbonate and citric acid which has good sensorial properties and is stable when added to beverages such as coffee without the need for additional stabilisers.

The present invention relates to a powdered creamer composition comprising plant protein having a specific median molecular weight, sodium bicarbonate and citric acid which has good sensorial properties and is stable when added to beverages such as coffee without the need for additional stabilisers.

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.

A process for splitting protein materials of animal or plant origin to peptides with molecular weights from below 10 KDa to 260 KDa, decontamination of bone meal and destroying allergenic proteins. For these purposes the protein materials in an aqueous medium are subjected to the action of an alternate electric current at p H 7.5-9, temperature 30 C.-160 C. at a pressure of 1-6 bar and within a reaction time from 5 to 150 min. A protein splitting reactor comprising at least two electrodes contained within a cylindrical vessel having inlet and outlet ports at opposite ends; wherein one electrode is electrically and mechanically connected with the vessel wall and is a neutral point connected to earth; wherein the second electrode is electrically isolated from the first electrode and is connected to a single phase of an electric power supply.