The present disclosure generally relates, in certain aspects, to cultivated meat and other cultivated animal-derived products. In some embodiments, such products may include fat replicas, which may improve taste, appearance, etc. In some cases, a fat replica can be formed by forming an emulsion of fat and a non-human blood plasma, then causing the blood plasma to crosslink and/or clot, e.g., forming a hydrogel containing the fat emulsion. In some cases, the fat replica may be used to make a cultivated meat product, e.g., by combining with muscle replicas, lysate of non-human red blood cells, etc. Other embodiments are generally directed to methods of making or using such fat replicas, the microcarriers, or the cultivated meat products, kits involving these, or the like.

A method for producing powderized cannabis oil, and the resulting powderized cannabis oil, in which concentrated cannabis oil is mixed with and absorbed by a modified starch powder, preferably maltodextrin, in a ratio of at least three grams of starch powder for every one-eighth of a gram of cannabis oil is disclosed. Further disclosed are beverages, baked goods and single-serve beverage brewing cartridges utilizing or incorporating the powderized cannabis oil to create human-consumable products that contain an emulsified, tasteless, and odorless dose of cannabis oil.

The invention deals with a dispersion of drops of a first phase in a second phase substantially immiscible with the first phase, the solubility of the first phase in the second phase being less than 5% by mass. Each drop includes a core formed with a first phase and a shell formed with a coacervate layer interposed between the first phase and the second phase.

The coacervate layer comprises a first precursor polymer of the coacervate and a second precursor polymer of the coacervate, one of the first phase and of the second phase is aqueous, and the other of the first phase and of the second phase is oily.

Various embodiments disclosed relate to oil and water emulsions including antioxidants. The emulsion can include an oil-phase; an aqueous-phase; an extract including carnosic acid, carnosol, or a mixture thereof; an extract containing rosmarinic acid; and an emulsifier.

The present invention addresses the problem of providing a premix for preparing an emulsion composition, which makes it possible to easily prepare a food containing a highly unsaturated fatty acid such as DHA or EPA, and an emulsion composition using the same. A premix for preparing an emulsion composition, which makes it possible to easily prepare a food containing a highly unsaturated fatty acid such as DHA or EPA, can be obtained by mixing a highly unsaturated fatty acid-containing fat or oil with a specific fat or oil and then mixing the resultant mixture with a preset amount of an aqueous solvent to thereby give an oil-in-water type emulsion. By using this premix, foods or drinks, for example, a drink in which an offensive taste derived from a highly unsaturated fatty acid is reduced can be easily prepared.

The invention relates to a method of propagating a mixture of two or more different micro-organism phenotypes, said method comprising the steps of: a) inoculating an aqueous culture medium with an inoculum comprising at least two different micro-organism phenotypes; b) mixing the inoculated aqueous medium with fat to produce a water-in-oil emulsion; c) incubating the emulsion at an incubation temperature in the range of 20-60 C. for at least 2 hours; d) heating the incubated emulsion to a temperature that is at least 5 C. above the incubation temperature to cause phase separation of the emulsion; e) repeating the cycle of steps a) to d) at a larger scale using viable cells contained in the aqueous phase of the phase separated emulsion as the inoculum; and f) collecting the propagated mixture of the two or more different micro-organism phenotypes wherein the fat has a solid fat content at the incubation temperature (N.sub.Tc) of at least 5 wt. %. The method according to the invention enables industrial scale production of mixed microbial cultures starting from an inoculum containing a mixture of micro-organisms with no, or only minor population variation during propagation, even if the inoculum contains both fast and slow growing micro-organisms.

The invention relates to a method of propagating a mixture of two or more different micro-organism phenotypes, said method comprising the steps of: a) inoculating an aqueous culture medium with an inoculum comprising at least two different micro-organism phenotypes; b) mixing the inoculated aqueous medium with fat to produce a water-in-oil emulsion; c) incubating the emulsion at an incubation temperature in the range of 20-60 C. for at least 2 hours; d) heating the incubated emulsion to a temperature that is at least 5 C. above the incubation temperature to cause phase separation of the emulsion; e) repeating the cycle of steps a) to d) at a larger scale using viable cells contained in the aqueous phase of the phase separated emulsion as the inoculum; and f) collecting the propagated mixture of the two or more different micro-organism phenotypes wherein the fat has a solid fat content at the incubation temperature (N.sub.Tc) of at least 5 wt. %. The method according to the invention enables industrial scale production of mixed microbial cultures starting from an inoculum containing a mixture of micro-organisms with no, or only minor population variation during propagation, even if the inoculum contains both fast and slow growing micro-organisms.

Methods and compositions for the production of non-meat consumable products are described herein. A meat substitute is described which is constructed from a muscle analog, a fat analog, and a connective tissue analog.

The invention relates to an oil-and-water emulsion comprising an aqueous phase and an oil phase, said emulsion containing: 15-40 wt. % water; 30-60 wt. % oil; 1.5-18 wt. % of cyclodextrin selected from alpha-cyclodextrin, beta-cyclodextrin and combinations thereof; 12-50 wt. % of saccharides selected from monosaccharides, disaccharides, non-cyclic oligosaccharides, sugar alcohols and combinations thereof. The emulsions according to the present invention are highly stable under ambient conditions, can easily be used as a base for the manufacture of a variety of icings, fillings and toppings. These base emulsions can suitably be aerated (creamed) to produce a creamed icing or filling, or a whipped topping that has excellent ambient temperature stability.

Examples are disclosed that relate to a food product and a method of manufacturing a food product. One disclosed example provides a food product including a foamed aquafaba-containing substrate network, a strengthening component configured to provide mechanical strength to the foamed aquafaba-containing substrate network, a polysaccharide-based viscosity-increasing component, and a starch.