The invention relates to pulse products with improved flavor properties and digestive comfort. More specifically, the invention relates to a heat-treated germinated pulse and to a method of producing a heat-treated germinated pulse.

The invention relates to pulse products with improved flavor properties and digestive comfort. More specifically, the invention relates to a heat-treated germinated pulse and to a method of producing a heat-treated germinated pulse.

A technique for processing ancient, heritage and modern wheat, grains, seeds, beans, legumes, tuber and root vegetables create baking flours suitable for human consumption. The initial ingredient is incubated to initiate germination and activate internal enzymes and nutrient production for useful enzymes, proteins and nutrients. Germination is terminated and the product wet-milled to fracture or shear the outer hull, exposing the inner grain. The product is mixed with water at varying temperatures during which amylase is added. The mixture is incubated to facilitate saccharification of starches into sugars by the amylase enzymes. The mixture is pasteurized to denature the amylases and the mash pressed and/or strained to separate the liquid and solids. The solid phase is dried and milled into higher fiber, high protein, low carbohydrate flour. The liquid is carbohydrate-rich with substantial fiber, protein and other nutrients dissolved in the solution.

A technique for processing ancient, heritage and modern wheat, grains, seeds, beans, legumes, tuber and root vegetables create baking flours suitable for human consumption. The initial ingredient is incubated to initiate germination and activate internal enzymes and nutrient production for useful enzymes, proteins and nutrients. Germination is terminated and the product wet-milled to fracture or shear the outer hull, exposing the inner grain. The product is mixed with water at varying temperatures during which amylase is added. The mixture is incubated to facilitate saccharification of starches into sugars by the amylase enzymes. The mixture is pasteurized to denature the amylases and the mash pressed and/or strained to separate the liquid and solids. The solid phase is dried and milled into higher fiber, high protein, low carbohydrate flour. The liquid is carbohydrate-rich with substantial fiber, protein and other nutrients dissolved in the solution.

A technique for processing ancient, heritage and modern wheat, grains, seeds, beans, legumes, tuber and root vegetables create baking flours suitable for human consumption. The initial ingredient is incubated to initiate germination and activate internal enzymes and nutrient production for useful enzymes, proteins and nutrients. Germination is terminated and the product wet-milled to fracture or shear the outer hull, exposing the inner grain. The product is mixed with water at varying temperatures during which amylase is added. The mixture is incubated to facilitate saccharification of starches into sugars by the amylase enzymes. The mixture is pasteurized to denature the amylases and the mash pressed and/or strained to separate the liquid and solids. The solid phase is dried and milled into higher fiber, high protein, low carbohydrate flour. The liquid is carbohydrate-rich with substantial fiber, protein and other nutrients dissolved in the solution.

A technique for processing ancient, heritage and modern wheat, grains, seeds, beans, legumes, tuber and root vegetables create baking flours suitable for human consumption. The initial ingredient is incubated to initiate germination and activate internal enzymes and nutrient production for useful enzymes, proteins and nutrients. Germination is terminated and the product wet-milled to fracture or shear the outer hull, exposing the inner grain. The product is mixed with water at varying temperatures during which amylase is added. The mixture is incubated to facilitate saccharification of starches into sugars by the amylase enzymes. The mixture is pasteurized to denature the amylases and the mash pressed and/or strained to separate the liquid and solids. The solid phase is dried and milled into higher fiber, high protein, low carbohydrate flour. The liquid is carbohydrate-rich with substantial fiber, protein and other nutrients dissolved in the solution.

The present application relates to a fermented soybean composition and a method for preparing a fermented soybean composition.

Provided herein are compositions with enhanced protein content, compositions with functional proteins, protein combinations and methods for the preparation thereof.

The present disclosure provides a method for preparing a fermented soybean paste and a fermented soybean paste prepared thereby, the method comprising: a mixing step for mixing a Traditional Korean fermented soybean paste and a modified Korean fermented soybean paste to prepare a mixed fermented soybean paste; a first aging step for primarily aging the mixed fermented soybean paste at room temperature; and a second aging step for secondarily aging mixed fermented soybean paste, which has gone through the primary aging at low temperature. According to the method for preparing a fermented soybean paste and a fermented soybean paste prepared thereby, of the present disclosure, a distinctive deep and pleasant flavor of the Traditional Korean fermented soybean paste due to the combinative fermentation is maintained by mixing the traditional Korean fermented soybean paste and the modified Korean fermented soybean paste, and the protein degradation rate is increased using the high protease activity of the modified fermented soybean paste, thereby shortening the aging time and increasing the savory taste. In addition, according to the method for preparing a fermented soybean paste of the present disclosure, the mixed fermented soybean paste having gone through primary aging is secondarily aged at a low temperature, thereby preventing browning during the process, so that a fermented soybean paste with high preference can be produced, and the preparation time is relatively short while a pleasant flavor of the Traditional Korean fermented soybean paste is maintained, so that a fermented soybean paste with excellent quality can be mass-produced.

A prophylactic agent for spontaneous cancer may contain a plant fermentation product as a mixture of (a) to (g), fermentation products of: (a) barley, black soybean, red rice, black rice, adzuki bean, adlay, Japanese barnyard millet, foxtail millet, and/or proso millet; (b) mandarin orange, grape, apple, Vitis coignetiae berry, peach, persimmon, papaya, Japanese pear, watermelon, Japanese apricot, fig, Chinese quince fruit, kabocha squash, kumquat, Yuzu, loquat fruit, apricot, jujube, chestnut, matatabi fruit, and/or Japanese plum; (c) purple sweet potato, Jerusalem artichoke, carrot, onion, sweet potato, taro, Japanese wild yarn, daikon, red turnip, great burdock, lotus root, yacon, lily bulb, arrowhead, ginger, garlic, and/or turmeric; (d) cabbage, perilla, Moms leaf, fish mint, Japanese mugwort, Sasa veitchii, and/or dandelion; (e) kelp, wakame, and/or mozuku; (f) black sesame, walnut, and/or ginkgo nut; and (g) maitake and/or shiitake. A SAM evaluation system and/or SAMP mouse may evaluate such cancers and/or substances thereon.