The present invention is directed to a heat sterilized spoonable nutritional composition comprising: a protein source in an amount of 12 to 20% by weight of the composition, the protein source consisting of whey protein containing whey protein micelles and a source of casein, wherein the nutritional composition is a liquid or semi-liquid composition having a viscosity of between 400 and 4000 mPa.Math.s at 20? C. measured at a shear rate of 100 s.sup.?1. The inventive heat sterilized spoonable nutritional composition preferably has a cysteine content of 1.2 to 2.4% by weight of the composition. The present invention is furthermore directed to a process for preparing a heat sterilized spoonable nutritional composition comprising protein in an amount of 12 to 20% by weight based on the weight of the composition, said protein consisting of whey protein containing whey protein micelles and casein, which comprises the steps of: (i) Providing an aqueous solution of a protein source consisting of whey protein containing whey protein micelles and (ii) Adding a protein source containing casein; (iii) Optionally performing a homogenization treatment step; (iv) Performing an indirect UHT heat treatment step; (v) Optionally performing a homogenization treatment step, wherein following steps (i) to (v) a heat sterilized spoonable nutritional composition is obtained having a viscosity of between 400 and 4000 mPa.Math.s at 20? C. measured at a shear rate of 100 s.sup.?1. Finally, the invention concerns the use of a protein source consisting of whey protein containing whey protein micelles and a source of casein, for preparing a spoonable nutritional composition and/or for controlling the viscosity of a liquid or semi-liquid spoonable nutritional composition, wherein the spoonable nutritional composition comprises 12 to 20 weight % total protein. The invention also concerns medical uses and treatments applying or using the inventive heat sterilized spoonable nutritional composition.

The present invention is directed to a heat sterilized spoonable nutritional composition comprising: a protein source in an amount of 12 to 20% by weight of the composition, the protein source consisting of whey protein containing whey protein micelles and a source of casein, wherein the nutritional composition is a liquid or semi-liquid composition having a viscosity of between 400 and 4000 mPa.Math.s at 20? C. measured at a shear rate of 100 s.sup.?1. The inventive heat sterilized spoonable nutritional composition preferably has a cysteine content of 1.2 to 2.4% by weight of the composition. The present invention is furthermore directed to a process for preparing a heat sterilized spoonable nutritional composition comprising protein in an amount of 12 to 20% by weight based on the weight of the composition, said protein consisting of whey protein containing whey protein micelles and casein, which comprises the steps of: (i) Providing an aqueous solution of a protein source consisting of whey protein containing whey protein micelles and (ii) Adding a protein source containing casein; (iii) Optionally performing a homogenization treatment step; (iv) Performing an indirect UHT heat treatment step; (v) Optionally performing a homogenization treatment step, wherein following steps (i) to (v) a heat sterilized spoonable nutritional composition is obtained having a viscosity of between 400 and 4000 mPa.Math.s at 20? C. measured at a shear rate of 100 s.sup.?1. Finally, the invention concerns the use of a protein source consisting of whey protein containing whey protein micelles and a source of casein, for preparing a spoonable nutritional composition and/or for controlling the viscosity of a liquid or semi-liquid spoonable nutritional composition, wherein the spoonable nutritional composition comprises 12 to 20 weight % total protein. The invention also concerns medical uses and treatments applying or using the inventive heat sterilized spoonable nutritional composition.

A Pickering particle dry powder and a preparation method are used in food processing. The preparation method includes stirring peanut protein isolate and water as raw materials to obtain peanut protein isolate dispersion, subjecting the peanut protein isolate dispersion to ultrasonic treatment, subjecting the resultant to cross-linking reaction with transglutaminase to obtain a monolithic geld, shearing and homogenizing the monolithic gel to obtain a microgel particle dispersion, spray drying the microgel particle dispersion to obtain the Pickering particle dry powder. The Pickering particle dry powder prepared by the ultrasonic-assisted enzyme method is still in nanometer level after rehydration, which is beneficial to preparing Pickering emulsion with strong stability. The preparation method has the advantages of simple operation and low cost, which is beneficial to actual production in the food industry.

A Pickering particle dry powder and a preparation method are used in food processing. The preparation method includes stirring peanut protein isolate and water as raw materials to obtain peanut protein isolate dispersion, subjecting the peanut protein isolate dispersion to ultrasonic treatment, subjecting the resultant to cross-linking reaction with transglutaminase to obtain a monolithic geld, shearing and homogenizing the monolithic gel to obtain a microgel particle dispersion, spray drying the microgel particle dispersion to obtain the Pickering particle dry powder. The Pickering particle dry powder prepared by the ultrasonic-assisted enzyme method is still in nanometer level after rehydration, which is beneficial to preparing Pickering emulsion with strong stability. The preparation method has the advantages of simple operation and low cost, which is beneficial to actual production in the food industry.

An encapsulation method is disclosed for the capture of natural flavors within a clean-label derived from a malt comprising at least partially germinated whole grain seed, pulses, legumes, false grains or flour derived therefrom. Moreover, a spray dryable malted rice composition is disclosed that has rice present at an amount that is at least about 30% by weight.

An encapsulation method is disclosed for the capture of natural flavors within a clean-label derived from a malt comprising at least partially germinated whole grain seed, pulses, legumes, false grains or flour derived therefrom. Moreover, a spray dryable malted rice composition is disclosed that has rice present at an amount that is at least about 30% by weight.

A device for heating a concentrate comprises a drying tower comprises a plurality of pressurized spray nozzles, a feed tank fluidly connected with an inlet of a low-pressure heat, a feed pump, and a high-pressure piston pump connected on an inlet side with the outlet of the low-pressure heat exchanger. A first high-pressure line section of the high-pressure line is configured to connect the outlet of the high-pressure piston pump with the inlet of the additional high-pressure heat exchanger. A second high-pressure line section of the high-pressure line is configured to connect the outlet of the additional high-pressure heat exchanger with the pressurized spray nozzles. A means for defined shear loading of the concentrate is located in an outlet-side channel and comprises an annular-shaped space.

A device for heating a concentrate comprises a drying tower comprises a plurality of pressurized spray nozzles, a feed tank fluidly connected with an inlet of a low-pressure heat, a feed pump, and a high-pressure piston pump connected on an inlet side with the outlet of the low-pressure heat exchanger. A first high-pressure line section of the high-pressure line is configured to connect the outlet of the high-pressure piston pump with the inlet of the additional high-pressure heat exchanger. A second high-pressure line section of the high-pressure line is configured to connect the outlet of the additional high-pressure heat exchanger with the pressurized spray nozzles. A means for defined shear loading of the concentrate is located in an outlet-side channel and comprises an annular-shaped space.

A method for heating a concentrate in an installation for spray drying comprises increasing a pressure of the concentrate from a low pressure level at a flow temperature to a high pressure level. The concentrate is heated at a high pressure level to a spraying temperature using a high-pressure heat exchanger. The concentrate is shear loaded using a shearing device and immediately transferring the concentrate to a location of pressurized spraying, wherein a transfer time for the immediate transfer is determined by a fluidic effective distance between the shearing device and the location of the pressurized spraying.

A method for heating a concentrate in an installation for spray drying comprises increasing a pressure of the concentrate from a low pressure level at a flow temperature to a high pressure level. The concentrate is heated at a high pressure level to a spraying temperature using a high-pressure heat exchanger. The concentrate is shear loaded using a shearing device and immediately transferring the concentrate to a location of pressurized spraying, wherein a transfer time for the immediate transfer is determined by a fluidic effective distance between the shearing device and the location of the pressurized spraying.