A composition for preparing a protein-containing noodle containing a vegetable raw material and a method for preparing a protein-containing noodle using the same are disclosed. The composition for preparing a protein-containing noodle contains vegetable proteins, potato fibers, alginate, and starch. According to embodiments, low-calorie, high-protein-containing noodles with high protein content and excellent flavor may be prepared by using vegetable protein as the main raw material for noodles, and the mouthfeel and textural properties of the noodles may be greatly improved by using the vegetable proteins in combination with potato fibers, alginate, and starch. In addition, the raw material pretreatment and noodle making process are simplified, and thus, noodles may be prepared in a simple way and may be applied to mass production.

A composition for preparing a protein-containing noodle containing a vegetable raw material and a method for preparing a protein-containing noodle using the same are disclosed. The composition for preparing a protein-containing noodle contains vegetable proteins, potato fibers, alginate, and starch. According to embodiments, low-calorie, high-protein-containing noodles with high protein content and excellent flavor may be prepared by using vegetable protein as the main raw material for noodles, and the mouthfeel and textural properties of the noodles may be greatly improved by using the vegetable proteins in combination with potato fibers, alginate, and starch. In addition, the raw material pretreatment and noodle making process are simplified, and thus, noodles may be prepared in a simple way and may be applied to mass production.

Provided herein are methods for producing an adzuki bean protein isolate having high functionality for a broad range of food applications. In some embodiments, the methods for producing the isolate comprise one or more steps selected from: (a) extracting one or more adzuki bean proteins from an adzuki bean protein source in an aqueous solution, for example, at a pH between about 6.5-10.0; (b) purifying protein from the extract using at least one of two methods: (i) precipitating protein from the extract at a pH near the isoelectric point of a globulin-rich fraction, for example a pH between about 5.0-6.0; and/or (ii) fractionating and concentrating protein from the extract using filtration such as microfiltration, ultrafiltration or ion-exchange chromatography; and (c) recovering purified protein isolate.

Provided herein are methods for producing an adzuki bean protein isolate having high functionality for a broad range of food applications. In some embodiments, the methods for producing the isolate comprise one or more steps selected from: (a) extracting one or more adzuki bean proteins from an adzuki bean protein source in an aqueous solution, for example, at a pH between about 6.5-10.0; (b) purifying protein from the extract using at least one of two methods: (i) precipitating protein from the extract at a pH near the isoelectric point of a globulin-rich fraction, for example a pH between about 5.0-6.0; and/or (ii) fractionating and concentrating protein from the extract using filtration such as microfiltration, ultrafiltration or ion-exchange chromatography; and (c) recovering purified protein isolate.

A method for producing instant fried noodles with which puffing of the noodles are prevented compared with ordinary fried noodles is provided. The instant fried noodles made by the method thus can have dense texture and high transparency. In the method, a noodle belt is prepared from noodle dough obtained by kneading a main raw material powder with 20 to 60 ml, more preferably 30-50 ml, of a liquid-form edible fat or oil added per kg of the main raw material powder; the noodle belt is rolled out into a determined noodle thickness by performing rolling operation three times or less, more preferably twice or less; the rolled noodle belt is cut into noodle strings using a cutting blade; and the noodle strings are steamed and fry drying.

A method for producing instant fried noodles with which puffing of the noodles are prevented compared with ordinary fried noodles is provided. The instant fried noodles made by the method thus can have dense texture and high transparency. In the method, a noodle belt is prepared from noodle dough obtained by kneading a main raw material powder with 20 to 60 ml, more preferably 30-50 ml, of a liquid-form edible fat or oil added per kg of the main raw material powder; the noodle belt is rolled out into a determined noodle thickness by performing rolling operation three times or less, more preferably twice or less; the rolled noodle belt is cut into noodle strings using a cutting blade; and the noodle strings are steamed and fry drying.

An anti-inflammatory combination for improving nutrient metabolisms, intestinal functions and intestinal microecology and an anti-inflammatory food containing the anti-inflammatory combination are disclosed. The anti-inflammatory combination includes inulin, galacto-oligosaccharide, polydextrose, and a water-insoluble dietary fiber. Furthermore, a weight ratio of inulin, galacto-oligosaccharide, polydextrose and water-insoluble dietary fiber is 10-30:5-30:10-40:10-50. The anti-inflammatory food includes cereal flour, and the ratio of the cereal flour to the anti-inflammatory combination is 65-95:35-5. The anti-inflammatory combination is capable of reducing intestinal permeability, blood endotoxins, heavy metals and inflammatory factors, enhancing immunity, improving intestinal microecology and body biochemical indicators, and preventing chronic diseases.

An anti-inflammatory combination for improving nutrient metabolisms, intestinal functions and intestinal microecology and an anti-inflammatory food containing the anti-inflammatory combination are disclosed. The anti-inflammatory combination includes inulin, galacto-oligosaccharide, polydextrose, and a water-insoluble dietary fiber. Furthermore, a weight ratio of inulin, galacto-oligosaccharide, polydextrose and water-insoluble dietary fiber is 10-30:5-30:10-40:10-50. The anti-inflammatory food includes cereal flour, and the ratio of the cereal flour to the anti-inflammatory combination is 65-95:35-5. The anti-inflammatory combination is capable of reducing intestinal permeability, blood endotoxins, heavy metals and inflammatory factors, enhancing immunity, improving intestinal microecology and body biochemical indicators, and preventing chronic diseases.

The present invention aims to provide a saccharide composition suitable for a cyclic-tetrasaccharide-containing starch syrup which has low viscosity, low water activity, low coloration property, and low calorie content, and which is unlikely to cause precipitation of crystals of saccharides during storage, and to provide a use of the composition and a production method for the composition. The object is achieved by providing a cyclic-tetrasaccharide-containing saccharide composition having the following characteristics (1) to (3): (1) the saccharide composition includes a branched cyclic tetrasaccharide in addition to the cyclic tetrasaccharide, wherein the content of the cyclic tetrasaccharide with respect to the total solid content of the saccharide composition obtained by allowing glucoamylase and α-glucosidase to act on the above saccharide composition is 38% by mass or higher, on a dry solid basis; (2) the ratio of α-1,4-linked glucose in the total glucose residues constituting the saccharide composition in methylation analysis is over 9% and 15% or lower, and (3) the ratio of α-1,4,6-linked glucose in the total glucose residues constituting the saccharide composition in methylation analysis is less than 6%; and providing a use of the composition and a production method for the composition.

An example modular meal system includes two or more modular meal components. Example modular meal components include a tray, a meal component disposed within the tray, and a sauce component disposed within the tray. The meal component is selected from a protein component, a starch component, a vegetable component, an appetizer component, and a dessert component. Each modular meal component is configured and/or formulated to reach at least 165° F. or at least 167° F. when heated from frozen for a heating time period within the range of from about 20 minutes to about 60 minutes and at a heating temperature within the range of about 350° F. to about 450° F.