The present invention provides a novel Pichia kluyveri strain (CCTCC NO: M 2015626) and the method of using this new strain to produce fermented nonalcoholic red bayberry juice. The method comprises incubating Pichia kluyveri CCTCC NO: M 2015626 with red bayberry juice in a fermentation process to make the fermented nonalcoholic juice, which includes an aerobic, anaerobic and a low temperature fermentation. The fermented bayberry juice of the present invention has bright color, low alcohol content (<0.5%) and high nutritional values. It maintains the characteristic fruity flavor of red bayberries with added mellow taste and aroma from the fermentation.

A composition including a. a spirulina-extract having phycocyanin, b. at least one multi-sulphated carrageenan and c. water wherein the amount of the phycocyanin is between 0.5 and 50 wt % DM, wherein the amount of the at least one multi-sulphated carrageenan is between 1 and 80 wt % DM, wherein the amount of the water is between 0.1 and 60 wt %, wherein the wt % ratio of carrageenan to phycocyanin ranges between 1:1 and 20:1, wherein the wt % DM are relative to the weight of the dry matter of the composition, and wherein wt % is relative to the total weight of the composition. A foodstuff containing the above composition.

The disclosure relates to methods for operating a pasteurizing device for pasteurizing foods filled into sealed containers. The foods are treated in treatment zones by applying a tempered, aqueous treatment liquid to an exterior of the containers. The treatment liquid is re-supplied to at least one treatment zone for reuse via circulation circuit pipes of a circulation circuit. A partial flow of the treatment liquid is continuously removed from the circulation circuit and filtered by means of a membrane filtration means. Furthermore, a biocide is apportioned to the treatment liquid as process chemical, such that a concentration of the biocide does not exceed 0.4 mmol/L. In addition, a pH-regulating agent comprising at least one inorganic or organic acid is apportioned to the treatment liquid as process chemical, such that a pH value of the treatment liquid is set to a range from 3.5 to 7.0.

The disclosure relates to methods for operating a pasteurizing device for pasteurizing foods filled into sealed containers. The foods are treated in treatment zones by applying a tempered, aqueous treatment liquid to an exterior of the containers. The treatment liquid is re-supplied to at least one treatment zone for reuse via circulation circuit pipes of a circulation circuit. A partial flow of the treatment liquid is continuously removed from the circulation circuit and filtered by means of a membrane filtration means. Furthermore, a biocide is apportioned to the treatment liquid as process chemical, such that a concentration of the biocide does not exceed 0.4 mmol/L. In addition, a pH-regulating agent comprising at least one inorganic or organic acid is apportioned to the treatment liquid as process chemical, such that a pH value of the treatment liquid is set to a range from 3.5 to 7.0.

Production of orange juice is described. Raw orange juice is ultrafiltrated in an ultrafilter, thereby obtaining a UF retentate and a UF permeate. The UF permeate is nanofiltered in a nanofilter, thereby obtaining a NF retentate and a NF permeate. The UF retentate and the NF permeate are mixed and then pasteurized in a pasteurizer. The pasteurized mixture forms the orange juice, which is filled in packages. An orange juice having a reduced sugar content while still providing a favorable taste and color is then obtained.

Production of orange juice is described. Raw orange juice is ultrafiltrated in an ultrafilter, thereby obtaining a UF retentate and a UF permeate. The UF permeate is nanofiltered in a nanofilter, thereby obtaining a NF retentate and a NF permeate. The UF retentate and the NF permeate are mixed and then pasteurized in a pasteurizer. The pasteurized mixture forms the orange juice, which is filled in packages. An orange juice having a reduced sugar content while still providing a favorable taste and color is then obtained.

Embodiments herein relate to one or more methods comprising heating of a kava product; pressurizing the kava product; electrically pulsing the kava product; homogenizing the kava product; cooling the kava product; and packaging of the kava product; wherein the method is configured to stabilize the kava product against microbiological decomposition.

Disclosed is a curcumin nanoparticle, including curcumin as core material and a wall material, where a weight ratio of the curcumin to the wall material is (5.5-7.5):100, and the wall material includes gum arabic and zein in a weight ratio of (1-5):5. The disclosure further provides a method of making the curcumin nanoparticle and a curcumin beverage containing the curcumin nanoparticle.

Disclosed is a curcumin nanoparticle, including curcumin as core material and a wall material, where a weight ratio of the curcumin to the wall material is (5.5-7.5):100, and the wall material includes gum arabic and zein in a weight ratio of (1-5):5. The disclosure further provides a method of making the curcumin nanoparticle and a curcumin beverage containing the curcumin nanoparticle.

The present invention pertains to novel beta-lactoglobulin (BLG) isolates as well as to a method of producing such isolates and to uses of the powders, e.g. in beverage applications.