The present invention relates to a novel method for preparing acid-gellable whey protein aggregates in the form of concentrated suspensions or powders. Moreover, the present invention relates to a novel composition containing the acid-gellable whey protein aggregates, to a food product ingredient comprising the novel type of acid-gellable whey protein composition, and to a food product comprising the novel type of acid-gellable whey protein composition.

The present invention relates to a novel method for preparing acid-gellable whey protein aggregates in the form of concentrated suspensions or powders. Moreover, the present invention relates to a novel composition containing the acid-gellable whey protein aggregates, to a food product ingredient comprising the novel type of acid-gellable whey protein composition, and to a food product comprising the novel type of acid-gellable whey protein composition.

Described herein is a food that is suitable for use as a shelf stable nut butter based spread. The food has a protein content of at least 25% by weight, and a nut butter content of at least 50% by weight. The food retains a desirable eating experience, similar to a natural nut butter spread or a stabilized nut butter spread despite having a high protein content.

Described herein is a food that is suitable for use as a shelf stable nut butter based spread. The food has a protein content of at least 25% by weight, and a nut butter content of at least 50% by weight. The food retains a desirable eating experience, similar to a natural nut butter spread or a stabilized nut butter spread despite having a high protein content.

Process for the preparation of a fibrous product comprising protein and having a moisture content of at least 65% by weight by first preparing a homogenous mixture of protein material comprising cheese, a moisture binder material, a calcium-complex forming agent and water at a temperature between 70 and 90° C. under high shear with the pH of the homogenous mixture being from 6.4 to 7.5. The homogenous mixture has a water content of at least 75% by weight whilst total protein content is from 5 to 20% by weight. Into this homogenous mixture is mixed a hydrocolloid which precipitates with metal cations, after which a solution of a metal cation with a valency of at least 2 is added in order to form the fibrous product. This fibrous product is then isolated and cooled. The fibrous product thus obtained is particularly suitable for use in preparing meat substitute products.

High-purity glycomacropeptide with a low phenylalanine content may be obtained on an industrial scale by a method including: (A) bringing a whey protein mixture containing glycomacropeptide into contact with activated carbon; and (B) separating the glycomacropeptide from the activated carbon.

Meat substitutes include at least a dried milk product, a carbohydrate, and a liquid such as water. The dried milk product includes one or both of non-fat dry milk and buttermilk powder. The carbohydrate includes one or both of syrup solids, such as corn syrup solids, and a starch, such as modified corn starch. The meat substitutes include amino acids and sugars that undergo a Maillard reaction during preparation of the meat substitutes, yielding flavor compounds in, and non-enzymatic browning of, the meat substitutes. The meat substitutes can be used in the production of food products such as dairy-based jerky.

Meat substitutes include at least a dried milk product, a carbohydrate, and a liquid such as water. The dried milk product includes one or both of non-fat dry milk and buttermilk powder. The carbohydrate includes one or both of syrup solids, such as corn syrup solids, and a starch, such as modified corn starch. The meat substitutes include amino acids and sugars that undergo a Maillard reaction during preparation of the meat substitutes, yielding flavor compounds in, and non-enzymatic browning of, the meat substitutes. The meat substitutes can be used in the production of food products such as dairy-based jerky.

Methods for extracting protein from expired or spoiled milk is disclosed. In at least one embodiment, the method includes the steps of acid hydrolysis, first filtration, fine filtration, activation, salting out, degreasing, drying and packaging. Through the combined process of “protein activation” and “self-assembly salting out,” these methods enable the reuse and upcycling of expired and spoiled milk.

Methods for extracting protein from expired or spoiled milk is disclosed. In at least one embodiment, the method includes the steps of acid hydrolysis, first filtration, fine filtration, activation, salting out, degreasing, drying and packaging. Through the combined process of “protein activation” and “self-assembly salting out,” these methods enable the reuse and upcycling of expired and spoiled milk.