A preparation method of Antrodia cinnamomea water-insoluble dietary fiber. After ethanol and water extraction, Antrodia cinnamomea wastes are dried and superfine-comminuted to obtain Antrodia cinnamomea waste powder. The waste powder treated with NaOH solution containing NaBH4 is extracted it twice to obtain two extracts. The two extracts are combined and an appropriate amount of glacial acetic acid are added for neutralization. The extracts are centrifugalized and precipitate is collected. After washing the precipitate with ultrapure water, the precipitate is dissolved with LiCl-DMSO. The precipitate that is insoluble in the LiCl-DMSO solution is dialyzed and freeze-dried to obtain the water-insoluble dietary fiber component ACA-IDK of Antrodia cinnamomea. The LiCl-DMSO solution is subjected to ethanol/DMSO fractional precipitation, and then the precipitate is collected and dialyzed. The water-insoluble dietary fiber component ACA-DK of Antrodia cinnamomea is obtained after freeze-drying.

Provided is a food composition which include a myceliated high-protein food product and methods to make such compositions, which are mixtures of myceliated high-protein food products and other edible materials. A food composition includes dairy alternative products, ready to mix beverages and beverage bases; extruded and extruded/puffed products; sheeted baked goods; meat analogs and extenders; baked goods and baking mixes; granola; and soups/soup bases. Food compositions also include texturized plant protein which can be used for making meat-structured plant protein meat analog or meat extender products. The food compositions have reduced undesirable flavors and reduced undesirable aromas due to use of myceliated high-protein food products as compared to use of similar high-protein material that is not myceliated.

Provided is a food composition which include a myceliated high-protein food product and methods to make such compositions, which are mixtures of myceliated high-protein food products and other edible materials. A food composition includes dairy alternative products, ready to mix beverages and beverage bases; extruded and extruded/puffed products; sheeted baked goods; meat analogs and extenders; baked goods and baking mixes; granola; and soups/soup bases. Food compositions also include texturized plant protein which can be used for making meat-structured plant protein meat analog or meat extender products. The food compositions have reduced undesirable flavors and reduced undesirable aromas due to use of myceliated high-protein food products as compared to use of similar high-protein material that is not myceliated.

Methods for culturing filamentous fungi, in which the filamentous fungi are grown in a colloid of air and a fermentation medium, are provided. The methods result in more rapid and prolific growth of the filamentous fungus than has been achieved by previous methods. Biomats produced by the methods and air-medium colloids for use in the methods are also provided.

Provided is a method to prepare a protein food product based on solid state fermentation, which includes the steps of preparing a sterilized substrate comprising a grain such as rice or quinoa and a plant protein concentrate or isolate such as pea protein, inoculating the sterilized substrate with a filamentous fungal culture such as Morchella esculenta culture, and culturing the filamentous fungal culture in the substrate, resulting in a myceliated substrate that has texture more similar to meat and/or improved flavor and aroma when cooked as compared to control substrate (e.g., unmyceliated). Similarity in texture to cooked meat includes increased spring and cohesiveness on chewing, and also where the protein food product, and the improved flavor includes increased savory and umami and decreased bitterness and improved aroma includes decreased pea or beany aroma. Also provided are protein food products made by the methods provided and food compositions, for example, meat analog products, made using the methods and compositions provided.

Provided is a method to prepare a protein food product based on solid state fermentation, which includes the steps of preparing a sterilized substrate comprising a grain such as rice or quinoa and a plant protein concentrate or isolate such as pea protein, inoculating the sterilized substrate with a filamentous fungal culture such as Morchella esculenta culture, and culturing the filamentous fungal culture in the substrate, resulting in a myceliated substrate that has texture more similar to meat and/or improved flavor and aroma when cooked as compared to control substrate (e.g., unmyceliated). Similarity in texture to cooked meat includes increased spring and cohesiveness on chewing, and also where the protein food product, and the improved flavor includes increased savory and umami and decreased bitterness and improved aroma includes decreased pea or beany aroma. Also provided are protein food products made by the methods provided and food compositions, for example, meat analog products, made using the methods and compositions provided.

The present invention relates to a method for producing a vitamin- and protein-rich product, to a food product containing the vitamin- and protein-rich product, and to a nutrient medium appropriate for said method on the basis of agricultural tributaries or food tributaries.

The present invention relates to a method for producing a vitamin- and protein-rich product, to a food product containing the vitamin- and protein-rich product, and to a nutrient medium appropriate for said method on the basis of agricultural tributaries or food tributaries.

Several methods are described for generating mycelial scaffolds for use several technologies. In one embodiment, a mycelial scaffold is generated using a perfusion bioreactor system for cell-based meat technologies. In another embodiment, a mycelial scaffold is prepared for biomedical applications. The mycelial scaffolds may be generated from a liquid medium or from a solid substrate.

Several methods are described for generating mycelial scaffolds for use several technologies. In one embodiment, a mycelial scaffold is generated using a perfusion bioreactor system for cell-based meat technologies. In another embodiment, a mycelial scaffold is prepared for biomedical applications. The mycelial scaffolds may be generated from a liquid medium or from a solid substrate.