This invention relates generally to cellulose nanocrystal-based emulsions that can serve as a spray adjuvant for improved agrochemical application efficiency. More particularly, the cellulose nanocrystal-based emulsions are nanocellulose-stabilized Pickering emulsions having a semi-liquid formulation of colloidal cellulose nanocrystals and biopolymers that can substitute currently used surfactants and drift reducing agents in agrochemicals. The cellulose nanocrystal-based emulsions are suitable with both water soluble and oil soluble active ingredient chemistries, and the shear characteristics of the emulsions make them suitable for oil in water-based spray applications. Droplet size distribution can be tuned by changing the ingredient concentrations, thus helping control particle drift. Moreover, a stable cross-linked network formation facilitates the entrapment and encapsulation of volatile agrochemical chemistries, thus preventing their volatilization and reducing vapor drift.

The invention relates to a method of producing an emulsion or suspension from a biomass. The invention also relates to producing a powder or products produced therefrom. The invention also relates to an emulsion or suspension produced by a method as described herein. The invention also relates to a powder produced by a method as described herein or products produced therefrom.

The present invention relates to compositions with antioxidant properties, in particular for use in food or as food. In a first aspect the invention provides a composition comprising ginger powder, sage powder, and rosemary powder; wherein the particles of the ginger powder have a size of less than 800 m, and the sage powder and rosemary powder have a size of less than 500 m; and wherein the ginger powder (G), the sage powder (S), and the rosemary powder (R) are present in a weight ratio of G:S:R=1 to 4:1 to 3:1 to 3.

The invention also relates to a method for improving the oxidative stability of a food composition and to use of a combination of ginger powder, sage powder, and rosemary powder as an antioxidant, wherein the particles of the ginger powder have a size of less than 800 m, and the sage powder and rosemary powder have a size of less than 500 m; and wherein the ginger powder (G), the sage powder (S), and the rosemary powder (R) are present in a weight ratio of G:S:R=1 to 4:1 to 3:1 to 3.

The present application relates generally to emulsifiers and methods of production thereof, and specifically to emulsifiers prepared using renewable and/or agricultural products through a physical process. Flour of cereal grains, legumes, or other plant materials contains both protein and carbohydrate, in particular starch. The preparation procedure of flour emulsifier contains physical processing, including but not limited to specifically designed heating, milling, or the combinations of both. Emulsions of lipophilic materials are prepared using flour emulsifiers. The emulsions formed can be further dehydrated using spray drying, drum drying, freeze drying, vacuum drying, or other drying methods. The emulsions prepared using flour emulsifiers as well as their dehydrated products show enhanced stability against physical and chemical deteriorations as compared with those prepared using conventional emulsifiers, such as octenylsuccinate starch and gum arabic.

A fat delivery system includes particles of at least one emulsified fat at least partially encapsulated in gelled material. A food product includes a plant-based protein base and a plurality of fat delivery particles dispersed within the plant-based protein base. The food product may be a plant-based meat analogue that approximates the appearance, flavor and texture of certain meat products. Methods for making the fat delivery particles and the food product are also disclosed.

Disclosed is a nano-emulsion formulation of saffron and a method of preparation thereof. The method includes the steps of triturating saffron with liquid nitrogen. Preparing an ultrasonic assisted extract in a polar or non-polar solvent. Preparing a nano-emulsion using the extract and one or more surfactants, including tween and span.

Disclosed is a nano-emulsion formulation of saffron and a method of preparation thereof. The method includes the steps of triturating saffron with liquid nitrogen. Preparing an ultrasonic assisted extract in a polar or non-polar solvent. Preparing a nano-emulsion using the extract and one or more surfactants, including tween and span.

The present invention is directed towards compositions comprising a lecithin; a sugar alcohol, a sugar, or combinations of any thereof; and an alcohol. Compositions comprising a water soluble surfactant are further disclosed. Methods of separating oil from a mixture are disclosed. Methods of dispersing an oil are further disclosed. Compositions comprising a water-dilutable microemulsion are disclosed. Methods of making chewing gum are disclosed. Methods of recovering oil from a mixture are further disclosed.

The purpose of the present invention is to provide a method for manufacturing a soybean paste food or gel food that has a good taste and favorable smooth texture. It was found that a soybean paste food or gel food that has a good taste and favorable smooth texture can be obtained by statically heating a liquid food comprising a dietary fiber-containing soybean emulsion composition, said dietary fiber-containing soybean emulsion composition having a dietary fiber content of 2.5 wt % or more, a protein content of 25 wt % or more in terms of dry matter, a lipid content (the content of an extract with a chloroform/methanol mixture solvent) of 25 wt % or more in terms of dry matter, an average particle diameter of 10-100 m, a moisture content of 70-90 wt %, and a viscosity of 3000 mPa.Math.s or lower.

An edible and thermoreversible oleogel comprising an oil or mixture of oils, grease or mixtures of fats and a structuring agent or mixture of structuring agents on the basis of a distilled monoglyceride of saturated fatty acid having from 12 to 24 carbon atoms that contains more than 90% by weight of monoglycerides, the monoglycerides of the saturated fatty acid are at least 40% by weight of monoglycerides of stearic acid and at least 30% by weight of monoglycerides of palmitic acid. The oleogel is prepared by the combination of oil, grease, and the structuring agent followed by a heating of the mixture, which is then cooled to obtain the oleogel. The resulting oleogel can be used as a substitute for fat in food products.