The present disclosure provides a whole muscle meat substitute and method for its production using additive manufacturing techniques. Specifically, the whole muscle meat substitute comprises one or more layers of digitally printed protein-containing strands, wherein each layer comprises a single convoluted strand or a plurality of strands such that segments between folds of the single strand or the plurality of strands are arranged in an essentially parallel along their longitudinal axis, the strand or strands comprising one or more bundles of axially aligned texturized protein fibers; and wherein at least a portion of the texturized protein fibers comprises elongated fibers having a length above 5 mm. The method disclosed herein comprises operating a digital printer to dispense onto a rinter bed a single convoluted protein containing strand or a plurality of individual protein containing strands, the single strand being folded or the plurality of said strands being arranged such that segments between folds of the single strand or the plurality of strands are essentially parallel along their longitudinal axis.

The present disclosure provides a whole muscle meat substitute and method for its production using additive manufacturing techniques. Specifically, the whole muscle meat substitute comprises one or more layers of digitally printed protein-containing strands, wherein each layer comprises a single convoluted strand or a plurality of strands such that segments between folds of the single strand or the plurality of strands are arranged in an essentially parallel along their longitudinal axis, the strand or strands comprising one or more bundles of axially aligned texturized protein fibers; and wherein at least a portion of the texturized protein fibers comprises elongated fibers having a length above 5 mm. The method disclosed herein comprises operating a digital printer to dispense onto a rinter bed a single convoluted protein containing strand or a plurality of individual protein containing strands, the single strand being folded or the plurality of said strands being arranged such that segments between folds of the single strand or the plurality of strands are essentially parallel along their longitudinal axis.

Compositions and methods are provided, wherein one or more plant protein(s) are combined with one or more fruit, vegetable, nut or grain sources of phenolics to generate protein-phenol complexes within the mixture. The source of phenolics primarily derive from plant waste, residuals, by-products or side streams, such as, for example, the solids which remain after the extraction of juice from fruit or oil pressed from olives, nuts or grains (e.g., pomace), or fruit and vegetables, etc., which could not be sold for some reason or another. In one embodiment, this mixture constitutes an Admixture that can be added to meat analogue formulations. In one embodiment, this mixture constitutes a Base Substance to generate a Meat Analogue and/or Final Product, which can provide a replacement for different types of meat including beef, buffalo, deer, chicken, turkey, pork, fish, shellfish, etc.

Compositions and methods are provided, wherein one or more plant protein(s) are combined with one or more fruit, vegetable, nut or grain sources of phenolics to generate protein-phenol complexes within the mixture. The source of phenolics primarily derive from plant waste, residuals, by-products or side streams, such as, for example, the solids which remain after the extraction of juice from fruit or oil pressed from olives, nuts or grains (e.g., pomace), or fruit and vegetables, etc., which could not be sold for some reason or another. In one embodiment, this mixture constitutes an Admixture that can be added to meat analogue formulations. In one embodiment, this mixture constitutes a Base Substance to generate a Meat Analogue and/or Final Product, which can provide a replacement for different types of meat including beef, buffalo, deer, chicken, turkey, pork, fish, shellfish, etc.

The invention refers to a method of producing a deformed fibrous protein product (12) from a wet textured product material (11). The wet textured product material (11) comprises at least 10 wt % of proteins possessing a fibrous structure and at least 35 wt % water. The in particular deformed fibrous protein product (12) being selected from the group consisting of a deformed product (12a), an initial pulled product (12b), a block product (12c), and a final pulled product (12d). The method comprising the step of a) elastic-plastically deforming the wet textured product material (11), thereby changing the fibrous structure to obtain the deformed product (12a).

The invention refers to a method of producing a deformed fibrous protein product (12) from a wet textured product material (11). The wet textured product material (11) comprises at least 10 wt % of proteins possessing a fibrous structure and at least 35 wt % water. The in particular deformed fibrous protein product (12) being selected from the group consisting of a deformed product (12a), an initial pulled product (12b), a block product (12c), and a final pulled product (12d). The method comprising the step of a) elastic-plastically deforming the wet textured product material (11), thereby changing the fibrous structure to obtain the deformed product (12a).

The purpose of the present invention is to provide a vegetable protein-containing food that has an excellent juicy feeling (juiciness), a meat-like hardness, a good chewiness and almost the same texture as a natural livestock meat-containing food. A vegetable protein-containing food that comprises (A) a granular vegetable protein, and/or a granular textured vegetable protein containing brown rice, (B) a fibrillated granular vegetable protein, and (C) a mixture of oil or fat, water and methyl cellulose. This vegetable protein-containing food has an excellent juicy feeling (juiciness), a meat-like hardness, a good chewiness and almost the same texture as a natural livestock meat-containing food, which makes it appropriately usable as a pseudo-meat food.

The present invention relates to a method of making a cold cut meat analogue, said method comprising: mixing a combination of two or more plant protein isolates, wheat gluten and optionally other ingredients, wherein the % (w/w) dry weight ratio of the combination of two or more plant protein isolates to wheat gluten ranges from 65:35 to 85:15, and wherein at least one plant protein isolate is derived from pea and/or at least one plant protein isolate is derived from soy; adding water and mixing to form a dough; extruding the dough by wet extrusion; cooling; and optionally cutting. A cold cut meat analogue made by the method of the invention is also provided.

The present invention relates to a method of making a cold cut meat analogue, said method comprising: mixing a combination of two or more plant protein isolates, wheat gluten and optionally other ingredients, wherein the % (w/w) dry weight ratio of the combination of two or more plant protein isolates to wheat gluten ranges from 65:35 to 85:15, and wherein at least one plant protein isolate is derived from pea and/or at least one plant protein isolate is derived from soy; adding water and mixing to form a dough; extruding the dough by wet extrusion; cooling; and optionally cutting. A cold cut meat analogue made by the method of the invention is also provided.

In some embodiments the present technology is directed to a system for dosing and mixing ingredients in a High Moisture Extrusion process, the system comprising: an extruder to mix ingredients to turn them into a protein extrudate, a cooling die to cool the protein extrudate and to cool an enhanced extrudate with ingredients added after the extruder, an interim plate connecting the extruder and the cooling die, to add and mix further ingredients, and facilitate movement of the protein extrudate and the enhanced extrudate into the cooling die, the interim plate further comprising one or more interim plate inlets to allow the entry of the protein extrudate from the extruder into the interim plate, and one or more dosing inlets for adding new ingredients to the protein extrudate that exits the extruder and enters the interim plate.