The object of the present invention is to provide an emulsion composition that maintains emulsion stability even after high temperature process such as sterilization (heat resistance), shows a small change in particle size distribution between before and after heating, and maintains emulsion stability even under conditions where transformation of an oil phase component (for example, solidification or crystallization of the oil phase component due to temperature drop, or melting of the oil phase component due to temperature rise) occurs (temperature drop resistance), wherein the composition is easily handled during the production process. The object is solved by an oil-in-water emulsion composition containing solid particles, a predefined surfactant, an oil phase component, and an aqueous phase component, wherein the oil phase component includes a predefined oil component and the solid particles are distributed along the interface between the oil phase component and the aqueous phase component.

The object of the present invention is to provide an emulsion composition that maintains emulsion stability even after high temperature process such as sterilization (heat resistance), shows a small change in particle size distribution between before and after heating, and maintains emulsion stability even under conditions where transformation of an oil phase component (for example, solidification or crystallization of the oil phase component due to temperature drop, or melting of the oil phase component due to temperature rise) occurs (temperature drop resistance), wherein the composition is easily handled during the production process. The object is solved by an oil-in-water emulsion composition containing solid particles, a predefined surfactant, an oil phase component, and an aqueous phase component, wherein the oil phase component includes a predefined oil component and the solid particles are distributed along the interface between the oil phase component and the aqueous phase component.

Provided herein is a novel composition for oral administration and delivery of Noble gas, such as xenon or argon. Methods of treating and preventing neuronal or cardiovascular damage with such compositions are also provided.

A system and method for the continuous production of brown butter involves concentrating butter while retaining solids non-fat in the butter, and continuously transferring and heating the concentrated butter to cause the solids non-fat in the butter to react in a Maillard reaction to form a brown butter product. The system may use one or more of a heating vessel, an evaporator and a reaction vessel to form the brown butter in the continuous process. A brown butter product derived from butter includes reacted solids non-fat particulates from a Maillard reaction suspended by nascent fat crystals nucleated about the reacted solids non-fat particulates and by large fat crystal structures joined to the nascent fat crystals.

Stabilized oils including an edible oil and an antioxidant composition comprising cα-lipoic acid and least one of ascorbic acid, ascorbyl palmitate, green tea extract, lecithin, and rosemary extract or at least one of 1,2,4-benzenetriol, carnosic acid, dihydromyricetin, dihydrorobinetin, epigallocatechin, gallic acid, 3-hydroxytyrosol, myricetin, and nepodin, and methods of preparing such stabilized edible oils. The stabilized oils may have an Oxidative Stability Index (“OSI”) at 110° C. of at least 30 hours.

Disclosed herein is one or more food compositions comprising at least one edible ingredient and a texturizing agent comprising an inhibited starch and a non-granular, enzymatically-debranched waxy potato starch. Also disclosed herein is a process for making said food compositions, the method comprising adding a texturizing agent comprising an inhibited starch and a non-granular, enzymatically-debranched waxy potato starch to the composition, wherein an effective amount of the texturizing agent is added to thicken the food composition. The texturizing agent can be used to replace protein and/or fat in said one or more food compositions.

The present invention relates to a self-emulsifiable composition including a monoacyl phospholipid, a diacyl phospholipid, oils and fats, and a polyhydric alcohol, in which the content ratio between the monoacyl phospholipid and the diacyl phospholipid is in the range of monoacyl phospholipid:diacyl phospholipid=1:9 to 9:1 as a mass ratio.

The present invention relates to process for enlarging oleosomes and the process comprises subjecting isolated oleosomes to a high-shear mixing or a high-shear centrifugal force, and obtaining an oleosome composition. The invention further relates to oleosome compositions. It also relates to food and feed products, pharmaceutical products, personal care products, nutritional compositions and industrial products comprising said oleosome composition. The invention relates to the process of preparing nutritional compositions comprising oleosome compositions. The current invention further relates to the use of rotor-stator high-shear mixer and/or a disk-stack centrifuge for enlarging the average globule diameter of oleosomes in an oleosome composition

The present invention relates to process for enlarging oleosomes and the process comprises subjecting isolated oleosomes to a high-shear mixing or a high-shear centrifugal force, and obtaining an oleosome composition. The invention further relates to oleosome compositions. It also relates to food and feed products, pharmaceutical products, personal care products, nutritional compositions and industrial products comprising said oleosome composition. The invention relates to the process of preparing nutritional compositions comprising oleosome compositions. The current invention further relates to the use of rotor-stator high-shear mixer and/or a disk-stack centrifuge for enlarging the average globule diameter of oleosomes in an oleosome composition

The invention provides nanoemulsion for preparing plant-based meat, the nanoemulsion has a particle size ranging from 300 nm to 320 nm. The plant-based meat prepared by using the nanoemulsion of the present invention can retain flavors after various cooking methods. The plant-based meat of the present invention can withstand different pH values and temperatures, and remains stable at different concentrations of salt, sugar, lipids, protein, carbohydrates and a variety of organic compounds, and will not lower consumer’s flavor expectations and perceptions. The plant-based meat of the present invention retains more flavors, so less flavoring is needed, and the cost will be reduced.