Abstract: Food products and methods of making the same are described, wherein the food products and methods incorporate one or more carotenoids or carotenoid-containing compositions in order to provide the food product with a desired coloring. The desired coloring is maintained in the food product despite subjecting some or all of the ingredients of the food product to harsh conditionings steps (e.g., high pH conditions) during the process of preparing the food product. In some embodiments, the food product is a vegetarian or vegan food product. The food product may be a meat or seafood alternative.

Abstract: Methods of separating components traditionally considered as waste material from mold-fermented compositions are described. The waste components can be separated either from unfiltered compositions or from a separation stream separated from a composition. In some embodiments, filamentous fungus used in the production of the mold-fermented composition is specifically targeted for separation. Incorporation of separated waste components into various products are also described herein. In some embodiments, the separated components are used in alternative meat products and other foods designed for human consumption. Separated components can also be used in animal feed, as feed stock for other fermentation processes, or for use in treating food, creating cosmetics, or chemical processes.

Abstract: Methods of producing fungi-based textured protein food products are described, the methods generally including providing a fungi-based protein source, mixing the fungi-based protein source with other ingredients (including secondary protein sources) to form a blend, and extruding the blend. The method may include performing the extrusion using operating parameters that result in denaturing the secondary proteins while leaving fungal fibers of the fungi-based proteins intact. Fungi-based textured protein food products are also described, the fungi-based textured protein food products including intact fungal fibers aligned with networks of denatured non-fungal protein formed about and around the fungal fibers.

Abstract: Described herein are various embodiments of methods for binding together textured substrates using mycelium-producing fungi. The method can generally include providing a textured substrate, such as a textured protein substrate, that may or may not be subjected to various pre-processing steps used to help promote mycelium growth inside, outside or inside and outside of the textured substrate, inoculating the textured substrate with mycelium-producing fungi, and growing mycelium inside, outside, or inside and outside of the textured substrate to bind the textured substrate. The bound textured substrate can be used as a high protein food, such as meat substitutes, meat analogues, or seafood analogues. In some embodiments, the mycelium-producing fungi is used to bind together multiple textured substrates to form larger composite food products.

Abstract: Described herein are various embodiments of methods for binding together textured substrates using mycelium-producing fungi. The method can generally include providing a textured substrate, such as a textured protein substrate, that may or may not be subjected to various pre-processing steps used to help promote mycelium growth inside, outside or inside and outside of the textured substrate, inoculating the textured substrate with mycelium-producing fungi, and growing mycelium inside, outside, or inside and outside of the textured substrate to bind the textured substrate. The bound textured substrate can be used as a high protein food, such as meat substitutes, meat analogues, or seafood analogues. In some embodiments, the mycelium-producing fungi is used to bind together multiple textured substrates to form larger composite food products.

Abstract: Methods of separating components traditionally considered as waste material from mold-fermented compositions are described. The waste components can be separated either from unfiltered compositions or from a separation stream separated from a composition. In some embodiments, filamentous fungus used in the production of the mold-fermented composition is specifically targeted for separation. Incorporation of separated waste components into various products are also described herein. In some embodiments, the separated components are used in alternative meat products and other foods designed for human consumption. Separated components can also be used in animal feed, as feed stock for other fermentation processes, or for use in treating food, creating cosmetics, or chemical processes.

Abstract: Described herein are various embodiments of methods for binding together textured substrates using mycelium-producing fungi. The method can generally include providing a textured substrate, such as a textured protein substrate, that may or may not be subjected to various pre-processing steps used to help promote mycelium growth inside, outside or inside and outside of the textured substrate, inoculating the textured substrate with mycelium-producing fungi, and growing mycelium inside, outside, or inside and outside of the textured substrate to bind the textured substrate. The bound textured substrate can be used as a high protein food, such as meat substitutes, meat analogues, or seafood analogues. In some embodiments, the mycelium-producing fungi is used to bind together multiple textured substrates to form larger composite food products.

Abstract: Methods of separating components traditionally considered as waste material from mold-fermented compositions are described. The waste components can be separated either from unfiltered compositions or from a separation stream separated from a composition. In some embodiments, filamentous fungus used in the production of the mold-fermented composition is specifically targeted for separation. Incorporation of separated waste components into various products are also described herein. In some embodiments, the separated components are used in alternative meat products and other foods designed for human consumption. Separated components can also be used in animal feed, as feed stock for other fermentation processes, or for use in treating food, creating cosmetics, or chemical processes.