The present invention relates to a process for treating protein-rich seeds, these seeds being selected from at least one of the following seeds: fava beans, peas, white lupin, blue lupin, yellow lupin. characterized in that it comprises in particular the following successive steps: a) use of seeds of at least one of the abovementioned plant species, provided that these seeds have a protein content, and/or a starch content, and/or a fat content, of a value greater than or equal to a predetermined value, and, at least one of the compounds from the following group: antinutritional factor (ANF), crude cellulose, neutral detergent fiber (NDF), in a content below a predetermined level; b) pressurizing the seeds from step a) for more than 10 seconds at a minimum pressure of 10 bars until a temperature of more than 80° C. is reached.

Provided are food products having structures, textures, and other properties similar to those of animal meat, and that comprise substantial amounts of cell wall material. Also provided are methods and processes for producing such food products.

Provided are food products having structures, textures, and other properties similar to those of animal meat, and that comprise substantial amounts of cell wall material. Also provided are methods and processes for producing such food products.

Pulse proteins of reduced astringency are obtained by fractionating pulse protein products which are completely soluble and heat stable in aqueous media at acid pH value of less than about 4.4 into lower molecular weight, less astringent proteins and higher molecular weight, more astringent proteins.

The present description is related to novel mannanases, compositions including mannanase, to methods for producing mannanases and to methods of using mannanases to degrade and modify mannan containing material.

The present invention describes a process for modifying sweetness, liquorice, astringency, powdery/chalk, fulness, thickness and/or digestibility and/or protease inhibitory activity of a protein comprising food.

A gluten free native rapeseed protein isolate comprising <10 ppm gliadin and processes to obtain the gluten free native rapeseed protein isolate comprising <10 ppm gliadin.

The present disclosure relates to a low-calorie, sugar-reduced soymilk comprising soybean extract solution, allulose, and soybean oil. The soymilk of the present disclosure includes allulose, and thus the soymilk has superior emulsion stability in spite of the addition of a small amount of an emulsifier and has excellent mouthfeel and taste, while having low calories than an existing product using sugar.

Described are methods of removing phospholipids and other off-flavor-causing compounds from edible proteins using a cyclodextrin treatment. The methods include treating soy protein with cyclodextrins such as -cyclodextrin to form cyclodextrin-compound complexes and then separating the resulting complexes from the protein. Optionally, prior to treating the protein with cyclodextrin, the protein is sonicated and then treated with a phospholipase, such as phospholipase A.sub.2. Versions of the methods described herein are capable of removing more than 99% of phospholipids from soy protein.

Improved meals, improved meal compositions, and improved aquaculture feed compositions are provided based on plant meal, wherein anti-nutritional effects of one or more anti-nutritional substances (ANS) are mitigated. Also provided are methods for making and using the improved meals, improved meal compositions, and improved aquaculture feed compositions. Also provided are kits using the improved meals, improved meal compositions, and improved aquaculture feed composition. The improved meals, improved meal compositions, and improved aquaculture feed compositions demonstrate that plant meal protein digestibility may be improved, for example, for replacing fish meal protein.