A method of harvesting plant product from a plant in a single pass using a combine harvester is disclosed. In the method, the plant has a protein content gradient that varies along a height of the plant. The method includes identifying, along a longitudinally-extending stalk of the plant, an upper protein gradient of the plant including high protein plant product and a lower protein gradient of the plant including lower protein plant product, wherein the high protein plant product from the upper protein gradient of the plant meets a threshold protein content that is higher than that of the lower protein plant product. The method also includes separately and substantially simultaneously harvesting the high protein plant product from the upper protein gradient and the lower protein plant product from the lower protein gradient in the single pass, and isolating the high protein plant product from the lower protein plant product.

In variants, a food product can be made from a waste product from an edible lipid extraction process.

In variants, a food product can be made from a waste product from an edible lipid extraction process.

A method for preparing a Pickering emulsion using a peanut protein isolate includes preparing a peanut protein isolate dispersion liquid from a peanut protein isolate solution as a raw material; preparing a mixed dispersion of protein and polysaccharide using a polysaccharide solution and the peanut protein isolate dispersion; adding transglutaminase to the mixed dispersion of protein and polysaccharide, preparing a monolithic gel by cross-linking reaction; preparing a microgel particle dispersion by using the monolithic gel as a raw material; and further adding the microgel particle dispersion to an edible oil to obtain a Pickering emulsion. During the preparation process, no inorganic material is added, and the obtained Pickering emulsion has good biosafety and strong biocompatibility. The prepared Pickering emulsion can keep stable at room temperature for 30 days or more, and can be used as a delivery system for fat-soluble and photosensitive active substances.

A method for preparing a Pickering emulsion using a peanut protein isolate includes preparing a peanut protein isolate dispersion liquid from a peanut protein isolate solution as a raw material; preparing a mixed dispersion of protein and polysaccharide using a polysaccharide solution and the peanut protein isolate dispersion; adding transglutaminase to the mixed dispersion of protein and polysaccharide, preparing a monolithic gel by cross-linking reaction; preparing a microgel particle dispersion by using the monolithic gel as a raw material; and further adding the microgel particle dispersion to an edible oil to obtain a Pickering emulsion. During the preparation process, no inorganic material is added, and the obtained Pickering emulsion has good biosafety and strong biocompatibility. The prepared Pickering emulsion can keep stable at room temperature for 30 days or more, and can be used as a delivery system for fat-soluble and photosensitive active substances.

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.

According to one embodiment, a protein product may include a mixture of water and particulate matter comprising protein. The mixture may include medium chain aldehydes and pyrazines. The ratio of a total concentration of medium chain aldehydes in the mixture to a total concentration of pyrazines in the mixture, as determined by gas chromatography-mass spectrometry, may be greater than or equal to 0.5 and less than or equal to 45. The mixture may also include from about 0.5 wt. % to about 8.0 wt. % total protein by weight of the mixture. In addition, the mixture may include from about 40 wt. % to about 98 wt. % water by weight of the mixture and less than or equal to about 4.0 wt. % oil and fat by weight of the mixture. The particulate matter may have an average particle size less than or equal to about 50 μm.

According to one embodiment, a protein product may include a mixture of water and particulate matter comprising protein. The mixture may include medium chain aldehydes and pyrazines. The ratio of a total concentration of medium chain aldehydes in the mixture to a total concentration of pyrazines in the mixture, as determined by gas chromatography-mass spectrometry, may be greater than or equal to 0.5 and less than or equal to 45. The mixture may also include from about 0.5 wt. % to about 8.0 wt. % total protein by weight of the mixture. In addition, the mixture may include from about 40 wt. % to about 98 wt. % water by weight of the mixture and less than or equal to about 4.0 wt. % oil and fat by weight of the mixture. The particulate matter may have an average particle size less than or equal to about 50 μm.

The present invention relates to a pea albumin characterized in that its emulsifying activity is improved as it can emulsify more than 600 ml of corn oil per gram of albumin. The invention also relates to a method for obtaining the pea albumin according to the invention. It finally relates to the use of the pea albumin according to the invention in industrial, in particular food and pharmaceutical applications.

The present invention relates to a pea albumin characterized in that its emulsifying activity is improved as it can emulsify more than 600 ml of corn oil per gram of albumin. The invention also relates to a method for obtaining the pea albumin according to the invention. It finally relates to the use of the pea albumin according to the invention in industrial, in particular food and pharmaceutical applications.