The present disclosure relates to a cannabis-infused product comprising a cannabinoid profile including one or more cannabinoid, a first composition for controlling onset of the cannabinoid profile and a second composition for extending offset of the cannabinoid profile in a subject having used the cannabis-infused product, wherein the second composition has a delayed onset compared to that one of the first composition. The present disclosure also relates to methods of manufacture and of using same.

A gluten-free grain concentrate (GFGC) food product and stepwise process to prepare GFGC from the treatment of raw unground wheat germ, is provided resulting in a product having at least three active components including (a) 1% to 3% 2,6-dimethoxy-1,4-hydroquinone; (b) 2% to 4% monomethoxy-1,4-benzoquinone; and (c) 0.5% to 1.5% monomethoxy-1,4-hydroquinone; and at least one inactive component: 2,6 dimethyl benzoquinone.

Non-meat food products are provided that have the appearance and the texture of cooked meat. Methods for making such non-meat food products are also provided. In an embodiment, a method includes mixing dry ingredients comprising vegetable proteins with wet ingredients including water and/or oil to form a non-meat dough; heating the non-meat dough under pressure; maintaining the pressure while transferring the heated non-meat dough to a cooling device; and gradually cooling the heated non-meat dough while gradually decreasing pressure on the heated non-meat dough, to form a non-meat food product. The mixing can be performed by a batch or continuous mixer; the heating can be performed by a device selected from the group consisting of a high shear emulsifier, a heat exchanger, and a dielectric heater; and the gradual cooling can be performed by a heat exchanger.

Non-meat food products are provided that have the appearance and the texture of cooked meat. Methods for making such non-meat food products are also provided. In an embodiment, a method includes mixing dry ingredients comprising vegetable proteins with wet ingredients including water and/or oil to form a non-meat dough; heating the non-meat dough under pressure; maintaining the pressure while transferring the heated non-meat dough to a cooling device; and gradually cooling the heated non-meat dough while gradually decreasing pressure on the heated non-meat dough, to form a non-meat food product. The mixing can be performed by a batch or continuous mixer; the heating can be performed by a device selected from the group consisting of a high shear emulsifier, a heat exchanger, and a dielectric heater; and the gradual cooling can be performed by a heat exchanger.

The invention provides novel microalgal food compositions comprising microalgal biomass that have been processed into flakes, powders and flours. The microalgal biomass of the invention is low in saturated fats, high in monounsaturated triglyceride oil and can be a good source of fiber. The invention also comprises microalgal biomass that is suitable as a vegetarian protein source and also as a good source of fiber. Novel methods of formulating food compositions with the microalgal biomass of the invention are also disclosed herein including beverages, baked goods, egg products, reduced fat foods and gluten-free foods. The provision of food compositions incorporating the microalgal biomass of the invention to ahuman have the further benefit of providing healthful ingredients while achieving levels of satiety sufficient to reduce further caloric intake. The invention also provides novel strains of microalgae that have been subject to non-transgenic methods of mutation sufficient to reduce the coloration of the biomass produced by the strains. Oil from the microalgal biomass can be extracted and is an edible oil that is heart-healthy. The novel microalgal biomass and oil therefrom can be manufactured from edible and inedible heterotrophic fermentation feedstocks, including corn starch, sugar cane, glycerol, and depolymerized cellulose that are purpose-grown or byproducts of existing agricultural processes from an extremely broad diversity of geographic regions.

The invention provides novel microalgal food compositions comprising microalgal biomass that have been processed into flakes, powders and flours. The microalgal biomass of the invention is low in saturated fats, high in monounsaturated triglyceride oil and can be a good source of fiber. The invention also comprises microalgal biomass that is suitable as a vegetarian protein source and also as a good source of fiber. Novel methods of formulating food compositions with the microalgal biomass of the invention are also disclosed herein including beverages, baked goods, egg products, reduced fat foods and gluten-free foods. The provision of food compositions incorporating the microalgal biomass of the invention to ahuman have the further benefit of providing healthful ingredients while achieving levels of satiety sufficient to reduce further caloric intake. The invention also provides novel strains of microalgae that have been subject to non-transgenic methods of mutation sufficient to reduce the coloration of the biomass produced by the strains. Oil from the microalgal biomass can be extracted and is an edible oil that is heart-healthy. The novel microalgal biomass and oil therefrom can be manufactured from edible and inedible heterotrophic fermentation feedstocks, including corn starch, sugar cane, glycerol, and depolymerized cellulose that are purpose-grown or byproducts of existing agricultural processes from an extremely broad diversity of geographic regions.

A process processing fresh brewer's spent grains (BSG), the process comprising the steps of: Producing a mash comprising barley malt; Separating the mash from BSG; Collecting the BSG; Microbiologically stabilizing the collected BSG; drying said BSG; and powdering said dried BSG.

Methods to produce cannabis plants are described, the methods include growing the cannabis plants in a growing medium within an interior of an enclosure by providing a common reservoir including water, and transferring the water from the common reservoir to the cannabis plants within the interior of the enclosure, the water within the common reservoir includes, fish, treated water, evaporator condensate, and a microorganism. Methods to asexually clone, harvest, trim, grind, and heat the cannabis plants are also described.

Methods to produce cannabis plants are described, the methods include growing the cannabis plants in a growing medium within an interior of an enclosure by providing a common reservoir including water, and transferring the water from the common reservoir to the cannabis plants within the interior of the enclosure, the water within the common reservoir includes, fish, treated water, evaporator condensate, and a microorganism. Methods to asexually clone, harvest, trim, grind, and heat the cannabis plants are also described.

Provided is a solid composition which is not too hard and excellent in edibility and to which a dry and good crispy texture and a favorable raw material-derived flavor are imparted regardless of a high content of insoluble dietary fiber. A solid composition includes a powder of an edible part and/or an insoluble dietary fiber localized site of one or more selected from the group consisting of dried vegetables, dried grains, dried pulses, and dried fruits is provided. The solid composition contains 3 mass % or more of protein. The solid composition contains 3 mass % or more of insoluble dietary fiber. The moisture content on wet basis is 11 mass % or less. The drying rate (105° C., 5 minutes) is 0.02 g/s.Math.m.sup.2 or more. A 50% integrated diameter of particles in an aqueous dispersion of the solid composition after ultrasonication is more than 5 μm and 600 μm or less.