An infant formula milk powder is rich in milk fat globule membrane protein, phospholipids, and oligosaccharides. A preparation method includes using raw cow milk as raw material, cleaning and pre-sterilizing raw cow milk, adding MFGM-rich whey protein powder, α-lactalbumin powder, galactooligosaccharides, polyfructoses and other ingredients into the pre-sterilized raw cow milk, and performing pre-sterilization, homogenization, sterilization, concentration, and spray drying. By means of formula adjustment, the contents of biologically active substances having special functional components such as MFGM-protein, lactoferrin, α-lactalbumin, total galactooligosaccharide, total polyfructose, sialic acid, total phospholipid, sphingomyelin, lecithin, phosphatidylserine, phosphatidylethanolamines, phosphatidylinositol, ganglioside, triglyceride and diglyceride in the infant formula milk powder are increased, thereby facilitating the colonization of probiotics in the intestinal microbiota of an infant, especially significantly enriching lactic acid bacteria in an intestinal tract, while reducing unclassified bacterial family and other miscellaneous bacteria.

The present disclosure provides a human milk fortifier product composition with, a protein component in the milk fortifier in an amount ranging from 6 wt/wt % to 35 wt/wt % on solids basis; a fat component in the in the milk fortifier in an amount ranging from 0.1 wt/wt % to 36 wt/wt % on solids basis; a carbohydrate in the milk fortifier selected from the group of Lactose and Oligosaccharides present in the in an amount from 25 wt/wt % to 75 wt/wt % on solids basis; small molecules consisting of Oligosaccharides in the human milk fortified by the said fortifier is at least 25% more than the human milk alone. The majority of small molecules consisting of Vitamin A, Vitamin D, Vitamin E, LCPUFA, Epidermal growth factor and many others are retained in the fortifier product.

A method for producing a mixture of oil and fluid food product includes placing a funnel into a pressure tank such that a stem of the funnel extends at least halfway down into the pressure tank. The pressure tank is flushed with nitrogen. Oil flows into the pressure tank through the funnel. A flow of nitrogen into the pressure tank is maintained through a side inlet of the pressure tank. Oil is dispensed from a pressure tank into the transfer line flowing a flow of fluid food product from a batch tank. The dispensed oil is dispersed into the flow of fluid food product in a inline shear mixer creating oil-in-fluid food product droplets. The oil-in-fluid food product droplets flow to the batch tank with the flow of fluid food product. The oil-in-fluid food product droplets are distributed in a volume of fluid food product in the batch tank.

Disclosed are techniques and systems for producing microbials having anaplerotic oils that are rich in odd-chain fatty acids, and other beneficial components, at higher concentrations than those present in other natural dietary sources of OCFA, at lower cost, and higher production yield. Further, disclosed are examples of incorporation of these higher concentration OCFA products into food for human and non-human animal consumption.

The present invention provides a composition for debittering hydrolyzed proteins and a product, preparation and use thereof. The composition comprises a short chain fatty acid, a medium chain fatty acid and a long chain fatty acid, wherein, based on total mass of the short chain fatty acid, the medium chain fatty acid and the long chain fatty acid which is 100%, the medium chain fatty acid is present in an amount of 0.2-4.7%, the long chain fatty acid is present in an amount of 95.1-99.4%, and the remaining is the short chain fatty acid. The present invention can effectively reduce the bitter taste of hydrolyzed proteins and is widely used.

The present invention is directed to isolated microorganisms as well as strains and mutants thereof, biomasses, microbial oils, compositions, and cultures; methods of producing the microbial oils, biomasses, and mutants; and methods of using the isolated microorganisms, biomasses, and microbial oils.

The present disclosure relates to cannabinoid-containing product for human consumption having an improved taste profile and to methods of manufacturing same. The present disclosure also relates to a process for making a cannabinoid-containing product for human consumption, comprising the following steps extraction of a cannabinoid and waxes from cannabis plant material with carbon dioxide under supercritical conditions to obtain an extract containing the cannabinoid and waxes, adding an emulsifier to the extract containing the cannabinoid and waxes to make a cannabinoid-containing emulsion for human consumption.

The present invention provides a novel process for preparing fortified milk compositions from whole mammalian milk. The process of the present invention generally involves converting dried mammalian milk into a fats-enriched fraction, a protein-enriched fraction, and a carbohydrate-enriched fraction. The process comprises treating the dried milk with a fats extracting agent to provide a fats-enriched fraction, and a residual fraction comprising proteins and carbohydrates; separating said fats-enriched fraction from the residual fraction; and removing the fats extracting agent from the separated fats-enriched fraction to produce a dry fraction of oily, fats-enriched material and a fraction enriched in proteins and carbohydrates.

The present invention relates to a composition comprising long chain polyunsaturated fatty acids (LC-PUFA) and ferrous sulphate monohydrate. Ferrous sulphate monohydrate advantageously does not cause significant oxidation of LC-PUFAs.

The invention concerns a sweetened dairy product comprising a dairy material, at least one steviol glycoside, and a lactase enzyme.