The present invention relates to a multiple emulsion comprising or consisting of P1/O/W2, wherein P1 is an aqueous phase forming droplets or a gas phase forming bubbles, said droplets or bubbles being dispersed in O thereby forming P1/O, wherein O is an oily phase comprising crystals, wherein W2 is an aqueous phase comprising at least one hydrophilic surfactant, wherein P1/O globules are formed in W2, wherein said oily phase O comprises at least 90%, preferably at least 92%, and even preferably at least 95%, by mass of triglycerides with respect to the mass of the O phase. The present invention relates to a process for preparing such multiple emulsion and applications thereof. Food, cosmetic and pharmaceutical compositions as well as a packaging containing a composition are claimed.

The present invention relates to a multiple emulsion comprising or consisting of P1/O/W2, wherein P1 is an aqueous phase forming droplets or a gas phase forming bubbles, said droplets or bubbles being dispersed in O thereby forming P1/O, wherein O is an oily phase comprising crystals, wherein W2 is an aqueous phase comprising at least one hydrophilic surfactant, wherein P1/O globules are formed in W2, wherein said oily phase O comprises at least 90%, preferably at least 92%, and even preferably at least 95%, by mass of triglycerides with respect to the mass of the O phase. The present invention relates to a process for preparing such multiple emulsion and applications thereof. Food, cosmetic and pharmaceutical compositions as well as a packaging containing a composition are claimed.

The disclosure generally provides for lipid compositions, foodstuffs, and methods for reducing lipid migration in a food product, the methods comprise sonicating a low saturated lipid with a high intensity ultrasound, and incorporating the sonicated low saturated lipid to a food composition.

The disclosure generally provides for lipid compositions, foodstuffs, and methods for reducing lipid migration in a food product, the methods comprise sonicating a low saturated lipid with a high intensity ultrasound, and incorporating the sonicated low saturated lipid to a food composition.

The invention is directed to a method of preparing a milk substitute from starch and protein that are first isolated from a root, tuber, cereal, nut or legume. The method comprises preparing an emulsion comprising at least 0.3 wt. % of emulsifying agent (modified starch and optionally native protein), at least 0.2 wt. % denatured protein, at least 1.0 wt. % of lipid. By first isolating the starch and protein from the plant source and then at a later step recombining these in the desired form and quantities, the invention el allows for more control of the final composition and organoleptic properties of the milk substitute.

The invention is directed to a method of preparing a milk substitute from starch and protein that are first isolated from a root, tuber, cereal, nut or legume. The method comprises preparing an emulsion comprising at least 0.3 wt. % of emulsifying agent (modified starch and optionally native protein), at least 0.2 wt. % denatured protein, at least 1.0 wt. % of lipid. By first isolating the starch and protein from the plant source and then at a later step recombining these in the desired form and quantities, the invention el allows for more control of the final composition and organoleptic properties of the milk substitute.

The present invention is directed to an extruded food product constituent composed of a gelling food product constituent extrudate and method of extruding a gelling food product constituent extrudate used as an ingredient of a food product normally using a gelling gum, like guar gum, xanthan gum or carrageenan as an ingredient. The gelling food product extrudate is composed of cold-water soluble gelling pregelatinized starch formed of starch in a starch-containing admixture modified by extrusion at extrusion pressures greater than 2000 PSI that gels when mixed with water, which preferably also modifies additional starch or starches in the admixture into a plurality of different molecular weight polymers of a cold-water soluble gellant that polymerize forming a gel when mixed with water, preferably forming a hydrocolloid gel, which more preferably is a self-gelling gel, which even more preferably is a thermo-reversible gel crosslinked by one or more proteins freed by or modified during extrusion. Preferred admixtures configured to produce gelling extrudates include admixtures composed of cereal grains, including sorghum, wheat, oats, barley and/or corn, and/or legumes, including chick pea, yellow pea, pea and/or lentils with legume containing admixtures producing gelling extrudates that form thicker gels whose viscosity increases over time that are well suited for use in non-dairy dairy substitutes like non-dairy butter, non-dairy creamers, non-dairy whipped cream, non-dairy yogurt, non-dairy cream cheese, non-dairy cheese, and non-dairy ice cream.

The present invention is directed to an extruded food product constituent composed of a gelling food product constituent extrudate and method of extruding a gelling food product constituent extrudate used as an ingredient of a food product normally using a gelling gum, like guar gum, xanthan gum or carrageenan as an ingredient. The gelling food product extrudate is composed of cold-water soluble gelling pregelatinized starch formed of starch in a starch-containing admixture modified by extrusion at extrusion pressures greater than 2000 PSI that gels when mixed with water, which preferably also modifies additional starch or starches in the admixture into a plurality of different molecular weight polymers of a cold-water soluble gellant that polymerize forming a gel when mixed with water, preferably forming a hydrocolloid gel, which more preferably is a self-gelling gel, which even more preferably is a thermo-reversible gel crosslinked by one or more proteins freed by or modified during extrusion. Preferred admixtures configured to produce gelling extrudates include admixtures composed of cereal grains, including sorghum, wheat, oats, barley and/or corn, and/or legumes, including chick pea, yellow pea, pea and/or lentils with legume containing admixtures producing gelling extrudates that form thicker gels whose viscosity increases over time that are well suited for use in non-dairy dairy substitutes like non-dairy butter, non-dairy creamers, non-dairy whipped cream, non-dairy yogurt, non-dairy cream cheese, non-dairy cheese, and non-dairy ice cream.

Stabilized oils including an edible oil and an antioxidant composition comprising α-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.

Stabilized oils including an edible oil and an antioxidant composition comprising α-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.