A method for producing a collagenous material in particle form, includes: extracting a collagen- and fat-containing animal raw material using an aqueous extraction solution; optionally separating at least one part of the aqueous phase from the extraction residue; separating the extraction residue into a collagenous solid phase, an aqueous phase, and a fat phase; mixing at least one part of the collagenous solid phase with at least one part of the aqueous phase; at least partly drying the mixed phases; and comminuting the dried phases in order to obtain the collagenous material in particle form.

Disclosed herein are methods for efficiently isolating collagen form a collagen source. The methods are inexpensive and do not require the use of proteolytic enzymes, decolorizing agents, antibacterial and antifungal agents, and the like. Further, the collagen produced by the methods described herein is substantially free of odor and discoloration. Still further, the collagen produced by the methods described herein is suitable to be used in cosmetics, food products, and pharmaceuticals or nutritional supplements.

Methods and systems are provided for mixing and heat exchange of fluids. In one example, a fluid mixing and heat exchange device includes a hot water tank, a mixing chamber spaced away from the hot water tank and fluidly coupled to a first liquid reservoir, a first chilling module fluidly coupled to the mixing chamber, a coolant tank fluidly coupled to the first chilling module, a radiator fluidly coupled to the coolant tank, and a dispensing manifold fluidly coupled to the mixing chamber and adapted to dispense a mixed and chilled fluid mixture to a plurality of fluid vessels.

Methods for producing a meat substitute with plant-based fat contents are disclosed. The methods include the use of protein and/or polysaccharide polymer with fibrillar properties in combination with protein sources of essential amino acids such as plant-based protein. These polymers may be mixed together and then combined with an oil phase emulsion to produce a precursor emulsion. The precursor emulsion may then be processed into three-dimensional fiber structures that include muscle-like fibers with fat encapsulation of the proteins. A contemplated method for forming the fibers includes centrifugally spinning the precursor emulsion to form the fibers.

The present application relates to a composition for a gelled food including vegetable cream, and a gelling agent which includes agar and guar gum, a gelled food including the composition for a gelled food, a method for preparing a composition for a gelled food, the method including (A) mixing a gelling agent which includes agar and guar gum in water to prepare a gelled product and (B) mixing the gelled product with vegetable cream to prepare a mixture, and a method for producing a gelled food, the method including heat sterilizing a composition for a gelled food produced by the method for producing a composition for a gelled food.

According to embodiments, a dry powdered composition which may be reconstituted to provide a gelatin product includes powdered gelatin and a pelletized colorant. The pelletized colorant includes a pigment-protein complex and at least one encapsulating agent for encapsulating the pigment-protein complex. The pelletized colorant has a rate of dissolution a rate of dissolution of less than 2 grams/minute in water having an initial temperature of from about 95 C. to about 100 C. Methods of making food products with the pelletized colorant are also disclosed. In embodiments, when the food products are measured on the L*a*b* color space, the food products have an L* value of about 49 to about 57, an a* value of about 10 to about 16, and a b* value of from about 11 to about 20.5.

A nutraceutical food product includes a solid matrix and a liquid combined into a gel. The nutraceutical food product may include an immune modulator, such as transfer factor and/or a nanofraction immune modulator. A fruit component may be included in the nutraceutical food product. The fruit component may include at least one oligoproanthocyanidin-containing fruit, such as aai.

The present invention relates to a meat processed food, into which a gel-like material is locally and quantitatively filled. Provided is a method for producing a meat processed food, having a step of cooling a gelling agent solution prepared by adding a gelling agent into water and then heating and dissolving the gelling agent, so as to prepare a gel-like material having fluidity; and a step of filling the gel-like material into a plurality of predetermined positions inside a meat-containing raw material.

A complete meal mimic is provided. It may be in the form of a small mass, and may contain free amino acids or peptides to mimic proteins in a meal. Digestion of the mimic may be at a controlled rate, emulating that of real food. The mimic may include the equivalent of 10-30 g protein in the form of amino acids and peptides, 10 to 20 grams of carbohydrates in the form of starches and fiber and 10 to 30 g of lipids from different oils. The oils may be one or more from avocado, coconut, and flaxseed. The mimic also may contain micro-nutrients provided by meals, including minerals and vitamins in bio-available forms. The mimic may stand in the place of a meal in the 100 calories to 500 calories range. The flavor of the mimic may include natural bitter blockers and/or mushroom powder.

The present invention relates to a sugar confectionery composition comprising an alcohol-containing phase and a sweet-containing phase, wherein the composition, when set, is in the form of a single-phase amorphous mass. The invention also relates to a method of manufacturing a sugar confectionery composition, comprising steps of: preparing an alcohol-containing phase at a first temperature; preparing a sweet-containing phase at a second temperature; incorporating one of the two phases into another to form a mixture; setting the mixture to form the composition; wherein, when set, the composition is in the form of a single-phase amorphous mass.