A synthetic edible proteinaceous material with a protein concentration of greater than 50% and the process for creating such proteinaceous material. The proteinaceous material is a substance comprising two materials: a denatured non-dairy protein isolate and a solid fat. By subjecting one or more of a variety of non-dairy isolated proteins to high-speed mixing, the protein denatures and can be mixed with a variety of solid fats to create a high-concentration protein colloid that is not only edible, but appetizing. The high-protein proteinaceous material can then be used as a standalone product or in various food supplements, including bars, baked goods, confections, or other edible products, particularly those for nutritional or medicinal purposes.

A synthetic edible proteinaceous material with a protein concentration of greater than 50% and the process for creating such proteinaceous material. The proteinaceous material is a substance comprising two materials: a denatured non-dairy protein isolate and a solid fat. By subjecting one or more of a variety of non-dairy isolated proteins to high-speed mixing, the protein denatures and can be mixed with a variety of solid fats to create a high-concentration protein colloid that is not only edible, but appetizing. The high-protein proteinaceous material can then be used as a standalone product or in various food supplements, including bars, baked goods, confections, or other edible products, particularly those for nutritional or medicinal purposes.

This application belongs to the field of biotechnology and discloses a method for producing a clam active peptide. The method for producing a clam active peptide comprises cleaning fresh clam meat with water, adding water and homogenizing with a colloid mill to prepare a clam meat slurry; adding water and complex protease for enzymolysis of the clam meat slurry, and heating to inactivate enzyme after the enzymolysis; centrifuging to collect an enzymatic hydrolyzate, capturing the enzymatic hydrolyzate having a molecular weight of lower than 2 KDa through microfiltration-ultrafiltration-nanofiltration membrane filtration, and drying to obtain the clam active peptide. The present disclosure produces a clam active peptide having pure color, outstanding taste, and blood pressure lowering function which is easily absorbed by human body using fresh clam meat as raw material, adopting a complex enzyme-membrane coupling technology through processing techniques such as enzymolysis, membrane separation purification and drying.

The present invention provides a process for the production of a meat analogue, comprising the steps of: a) introducing a meat batter comprising i) animal protein other than egg powder, ii) plant fiber and/or starch, and iii) egg powder, into a heating unit and heating the meat batter to a temperature above the melting point of the protein to produce a heat-treated product, b) cooling the heat-treated product by moving through a cooling unit, so that the heat-treated product has a temperature below water boiling temperature at ambient pressure when exiting the cooling unit, and c) dividing the cooled heat-treated product into pieces.

The present invention provides a process for the production of a meat analogue, comprising the steps of: a) introducing a meat batter comprising i) animal protein other than egg powder, ii) plant fiber and/or starch, and iii) egg powder, into a heating unit and heating the meat batter to a temperature above the melting point of the protein to produce a heat-treated product, b) cooling the heat-treated product by moving through a cooling unit, so that the heat-treated product has a temperature below water boiling temperature at ambient pressure when exiting the cooling unit, and c) dividing the cooled heat-treated product into pieces.

This disclosure provides a technology for developing alternative protein sources for use in industrial food production. The technology mines sequence data by a process that is done partly in silico. Instead of sampling and testing a vast library of compounds, machine learning and implementation narrows the field of functional candidates by predictive modeling based on known protein structure. Candidate proteins that are selected by this analysis are then produced and screened in a high-throughput manner by recombinant expression and testing to determine whether they have a target function. Multiple cycles of the machine learning, database mining, expression, and testing are done to yield potential ingredients suitable for assessment as part of a commercial food product.

This disclosure provides a technology for developing alternative protein sources for use in industrial food production. The technology mines sequence data by a process that is done partly in silico. Instead of sampling and testing a vast library of compounds, machine learning and implementation narrows the field of functional candidates by predictive modeling based on known protein structure. Candidate proteins that are selected by this analysis are then produced and screened in a high-throughput manner by recombinant expression and testing to determine whether they have a target function. Multiple cycles of the machine learning, database mining, expression, and testing are done to yield potential ingredients suitable for assessment as part of a commercial food product.

This disclosure relates to methods of size reducing, mixing, and folding subsets of a raw cell-based-meat product to improve the texture of a cell-based-meat product. The disclosed method can include collecting different portions of raw tissue product from either a single grown cell mass or different grown cell masses. The disclosed method can include finely chopping a first portion of cell mass into a fibrous pulp or paste and coarsely size-reducing a second portion of cell mass into segments. The first and second portions can be recombined and thoroughly mixed. In particular, the disclosed method includes mixing techniques that align fibers within the recombined portions. Examples of mixing techniques include dragging tines through the recombined portions, utilizing an extruder, and other methods. The combined mixture can further be flattened and folded to give the combined mixture additional structure and organization to better mimic conventional slaughtered meat.

This disclosure relates to methods of size reducing, mixing, and folding subsets of a raw cell-based-meat product to improve the texture of a cell-based-meat product. The disclosed method can include collecting different portions of raw tissue product from either a single grown cell mass or different grown cell masses. The disclosed method can include finely chopping a first portion of cell mass into a fibrous pulp or paste and coarsely size-reducing a second portion of cell mass into segments. The first and second portions can be recombined and thoroughly mixed. In particular, the disclosed method includes mixing techniques that align fibers within the recombined portions. Examples of mixing techniques include dragging tines through the recombined portions, utilizing an extruder, and other methods. The combined mixture can further be flattened and folded to give the combined mixture additional structure and organization to better mimic conventional slaughtered meat.

The invention relates to a shaped vegetarian meat product comprising: a) 30-80 wt. % water; b) 5-35 wt. % oil, said oil having a solid fat content at 20 degrees Celsius (N.sub.20) of at least 1.5%; c) 2-25 wt. % protein selected from algal protein, bacterial protein, dairy protein, egg protein, fungal protein, plant protein, and combinations thereof; d) 0-40 wt. % of one or more particulate ingredients selected from herbs, spices, vegetables and combinations thereof;
wherein the vegetarian meat product contains at least 4 vol. % of oil droplets having an equivalent spherical diameter in the range of 100 micrometer to 1,000 micrometer as determined by means of micro computed tomography. This shaped vegetarian meat product has a very attractive juicy appearance and texture.