The present invention relates to a method for preparing a monoglyceride hydrate product, which product may be used as an emulsifier in various food and non-food applications. The present invention further relates to the monoglyceride hydrate product obtainable by said method. The invention further relates to a monoglyceride hydrate product, comprising monoglycerides, with saturated fatty acid residues, water and non-hydrogenated monoglycerides and/or diglycerides having unsaturated fatty acid residues.

The present invention relates to a method for preparing a monoglyceride hydrate product, which product may be used as an emulsifier in various food and non-food applications. The present invention further relates to the monoglyceride hydrate product obtainable by said method. The invention further relates to a monoglyceride hydrate product, comprising monoglycerides, with saturated fatty acid residues, water and non-hydrogenated monoglycerides and/or diglycerides having unsaturated fatty acid residues.

This specification discloses thermally inhibited waxy cassava starches and edible compositions made therefrom. In one aspect edible compositions have improved creaminess compared to prior art starches, independent of starch usage level and the viscosity provided by the starch. In an embodiment the edible composition comprises between 0.1% and 35.0% by weight. In various embodiments the thermally inhibited waxy cassava starch has a peak viscosity of between about 100, and 2000 Brabender units or between 500 and 1500 Brabender Units.

This specification discloses thermally inhibited waxy cassava starches and edible compositions made therefrom. In one aspect edible compositions have improved creaminess compared to prior art starches, independent of starch usage level and the viscosity provided by the starch. In an embodiment the edible composition comprises between 0.1% and 35.0% by weight. In various embodiments the thermally inhibited waxy cassava starch has a peak viscosity of between about 100, and 2000 Brabender units or between 500 and 1500 Brabender Units.

The present invention relates to beverage products. In particular, the invention is concerned with a protein system induced by controlled aggregation of milk proteins which imparts outstanding sensory attributes on beverage product, in particular when containing low fat and/or low sugar. A method of producing such beverage and the products obtainable from the method are also part of the present invention.

The present invention relates to beverage products. In particular, the invention is concerned with a protein system induced by controlled aggregation of milk proteins which imparts outstanding sensory attributes on beverage product, in particular when containing low fat and/or low sugar. A method of producing such beverage and the products obtainable from the method are also part of the present invention.

The present invention relates to the field of processing pea protein compositions. The present invention particularly relates to a method for preparing a high solubility pea protein composition and a product prepared thereby. The method of the present invention includes a step of subjecting a pea protein composition to high pressure homogenization. The method of the present invention significantly improves the solubility of pea protein compositions. The present invention further provides a pea protein composition prepared by the method, the pea protein composition having better solubility.

A stabilized composition of fat soluble nutrient(s) includes a water soluble polymer and at least one nutraceutically acceptable excipient. The composition can be in the form of significantly amorphous aqueous microparticulate mixtures or as a solid beadlet product. A process for preparation of a stabilized composition includes a fat soluble nutrient solubilized in an organic solvent embedded in an aqueous polymer phase by evaporation, so as to obtain an aqueous microparticulate mixture. This mixture is stable, soluble and can be formulated for end use or can be layered on inert core for example to obtain stable beadlet(s) for use in solid dosage forms. Such stabilized aqueous microparticulate and solid beadlet compositions exhibit good solubility and dispersibility. Stabilized compositions of fat soluble nutrients can be prepared using industrially convenient equipment and can be formulated as per requirement for use in health applications.

Compositions and methods that relate to improved chocolate milk are provided. The chocolate milk may be shelf stable and k-carrageenan free. The chocolate milk does not undergo visually detectable phase separation for at least 7 days. The chocolate milk that does not undergo the visually detectable phase separation contains from 1%-10% micellar casein w/v. Methods for preparing shelf stable k-carrageenan free chocolate milk are also provided and include mixing cocoa powder, sugar, milk, and micellar casein to obtain a mixture, and optionally heating and homogenizing the mixture, and subsequently subjecting the mixture to High Pressure Jet Processing (HPJ) or high pressure homogenization of at least 300 MPa, thereby producing the shelf table k-carrageenan free chocolate milk. The shelf stable k-carrageenan free chocolate milk of produced using such a method may be refrigerated temperature for at least 14 days, and does not undergo detectable phase separation for at least 14 days.

Compositions and methods that relate to improved chocolate milk are provided. The chocolate milk may be shelf stable and k-carrageenan free. The chocolate milk does not undergo visually detectable phase separation for at least 7 days. The chocolate milk that does not undergo the visually detectable phase separation contains from 1%-10% micellar casein w/v. Methods for preparing shelf stable k-carrageenan free chocolate milk are also provided and include mixing cocoa powder, sugar, milk, and micellar casein to obtain a mixture, and optionally heating and homogenizing the mixture, and subsequently subjecting the mixture to High Pressure Jet Processing (HPJ) or high pressure homogenization of at least 300 MPa, thereby producing the shelf table k-carrageenan free chocolate milk. The shelf stable k-carrageenan free chocolate milk of produced using such a method may be refrigerated temperature for at least 14 days, and does not undergo detectable phase separation for at least 14 days.