A method for preparing corn glycopeptides, and a product and use thereof, and belongs to the technical field of food and medicine production. The method for preparing corn glycopeptides includes the preparation of corn peptides powder and the glycosylation reaction between corn peptides and amino sugar; the preparation raw material of the corn peptides powder is a corn protein rich in branched chain amino acids; and the corn peptides and the amino sugar are subjected to the glycosylation reaction catalyzed by a transglutaminase, and finally the corn glycopeptides is obtained. The method for preparing corn glycopeptides provided by the present disclosure is simple; and the prepared corn glycopeptides have antagonistic and protective effects on alcoholic liver injury, and can be applied to the preparation of related foods, medicines and health care products.

The present invention relates to a protein preparation produced from hemp seeds and to a cost-effective method for the preparation thereof. The protein preparation has a protein content or more than 65% by mass, a fat content of less than 6% by mass and a brightness L* of greater than 70. The protein preparation has a neutral taste, is bright and of superior quality so that it is suitable for foodstuff applications with high colour demands such as vegetable dairy alternatives (drinks, yoghurt, cheese) or bright vegetable alternatives to meat, poultry or fish.

The present invention relates to the use of turbine mixing during enzymatic hydrolysis of aquatic protein from species such as fish, aquatic mammals, crustaceans and/or mollusks, to obtain high quality aquatic protein hydrolysates, having very low oxidation, improved organoleptic profile and improved biological activity of interest, for human consumption and cosmetics. The turbine mixing can inhibit oxidation during hydrolysis, contribute to an increase in the bio-activity and decrease the bitter taste of the final product. The process can vary in starting material, pre-treatment, type and amount of enzyme, hydrolysis conditions, time, degree of hydrolysis and post-treatment.

The present invention relates to the use of turbine mixing during enzymatic hydrolysis of aquatic protein from species such as fish, aquatic mammals, crustaceans and/or mollusks, to obtain high quality aquatic protein hydrolysates, having very low oxidation, improved organoleptic profile and improved biological activity of interest, for human consumption and cosmetics. The turbine mixing can inhibit oxidation during hydrolysis, contribute to an increase in the bio-activity and decrease the bitter taste of the final product. The process can vary in starting material, pre-treatment, type and amount of enzyme, hydrolysis conditions, time, degree of hydrolysis and post-treatment.

The present invention relates to the use of a TET protein as a N-terminus aromatic amino acid residues specific exopeptidase, said TET protein comprising the amino acid sequence as set forth in SEQ ID NO: 1.

The present invention relates to the use of a TET protein as a N-terminus aromatic amino acid residues specific exopeptidase, said TET protein comprising the amino acid sequence as set forth in SEQ ID NO: 1.

The present disclosure relates to disrupting algae cell walls, in order to obtain protoplast with high nutrient digestibility for use as a food ingredient and/or as feed for farmed fish and shellfish species, which leads to the production of added value sea food items and to more sustainable and better performing food chains. The present disclosure described a method for obtaining proteins or a rich-protein extract from algae, comprising the steps of: disrupting a cell wall of algae by physical-mechanical means using a vibratory grinding mill with rings; submitting the disrupted algae to an enzymatic hydrolysis carried out with a mixture of enzymes; wherein the enzyme mixture is a mixture of at least two enzymes selected from the following list: lipase, pectinase, cellulase, hemicellullase, endo exo-arabanase, amylase, or mixtures thereof; provided that at least one of the enzymes is lipase, pectinase, amylase.

The invention relates to a protein hydrolysate and a process for making such protein hydrolysate. In particular the invention relates to a collagen hydrolysate and a process for making such collagen hydrolysate. Further the invention relates to a food, pet food, cosmetic, pharmaceutical or technical application comprising the protein hydrolysate of the present invention and further food, pet food, cosmetic, pharmaceutical or technical constituents.

The invention relates to a protein hydrolysate and a process for making such protein hydrolysate. In particular the invention relates to a collagen hydrolysate and a process for making such collagen hydrolysate. Further the invention relates to a food, pet food, cosmetic, pharmaceutical or technical application comprising the protein hydrolysate of the present invention and further food, pet food, cosmetic, pharmaceutical or technical constituents.

The present disclosure relates to pharmaceutical field, providing a hydrolyzed chicken sternal cartilage extract, method for producing the same and use thereof. The hydrolyzed chicken sternal cartilage extract has a type II collagen content of 50% and a chondroitin sulfate content of 20%. In China, a huge amount of livestock and poultry are consumed, and the total consumption almost reaches of the worldwide livestock and poultry consumption. Chicken sternal cartilage is one of the main by-products in broiler chicken processing. In the present disclosure, a hydrolyzed chicken sternal cartilage extract rich in type II collagen and chondroitin sulfate is obtained by using biological enzymatic hydrolysis technique. Experiments results show that the hydrolyzed chicken sternal cartilage extract produced by the present disclosure has a good anti-inflammatory effect and can be used to prepare medications for treating osteoarthritis.