A concentrated orange carrot permeate, wherein a) the amount of fructose is 2.5 to 30.0 wt. % on a dry matter basis, b) the amount of glucose is 3.0 to 20.0 wt. % on a dry matter basis, c) the amount of sucrose is 0.5 to 60.0 wt. % on a dry matter basis, and d) the dry matter is 55 to 85 wt. %, wherein the amounts of fructose and glucose are determined according to ASU L 31.00-12, wherein the amount of sucrose is determined according to ASU L 31.00-13, and wherein the dry matter is determined according to ASU L 26.11.03-1a. A caramelized concentrated orange carrot permeate, a mix of the concentrated orange carrot permeate and the caramelized concentrated orange carrot permeate, to the use of said products in food applications and to food products containing concentrated orange carrot permeate and/or caramelized concentrated orange carrot permeate.

The invention provides a method for treating root—or tuber juice, comprising a) a pretreatment of the root—or tuber juice to remove root—or tuber lipids to a level below 28 g/kg dry weight; b) cooling the root—or tuber juice to a temperature of −0.3° C. to −16° C. to form ice crystals; and c) separating the ice crystals from the root—or tuber juice to obtain, as a first root—or tuber juice product, a concentrated root—or tuber juice. In addition, the invention provides methods to obtain protein depleted root—or tuber juice products, as well as products comprising root—or tuber free amino acids, and uses thereof.

The invention provides a method for treating root- or tuber juice, comprising a) a pretreatment of the root- or tuber juice to remove root- or tuber lipids to a level below 28 g/kg dry weight; b) cooling the root- or tuber juice to a temperature of −0.3° C. to −16° C. to form ice crystals; and c) separating the ice crystals from the root- or tuber juice to obtain, as a first root- or tuber juice product, a concentrated root- or tuber juice. In addition, the invention provides methods to obtain protein depleted root- or tuber juice products, as well as products comprising root- or tuber free amino acids, and uses thereof.

Described herein is a concentrated sweet potato leaf protein in dried form, along with methods for producing it. The concentrated leaf protein has a protein content of greater than 21% by weight, and can have other beneficial components such as polyphenols. The concentrated leaf proteins are suitable for use in food and beverages, as protein supplementation, or as agents for gelling, foaming, and whipping.

A method of producing reduced-sugar fruit juice (with or without pulp) and reduced-sugar fruit must. The reduced-sugar fruit juice has similar nutrition, but with less sugar and calories than 100% fruit juice. Reduced-sugar grape must has similar nutrition and flavor profile, but with less sugars and calories than 100% grape must.

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.

This paper describes a concentrated sweet potato leaf protein in dried form, along with methods for producing it. The concentrated leaf protein is high in protein content, high in purity, and can have other beneficial components such as polyphenols. The concentrated leaf proteins are suitable for use in food and beverages, as protein supplementation, or as agents for gelling, foaming, whipping and the like.

A method for preparing a filtered beverage includes filtering a raw beverage using a cross-flow ultrafiltration device to produce a solids fraction and a liquid fraction; heating the solids fraction to a temperature of 60° C. or greater to produce a pasteurized solids fraction; microfiltering the liquid fraction through a microfilter having a size cut-off of 1 μm or smaller to produce a microfiltered liquid fraction; and combining the pasteurized solids fraction and the microfiltered liquid fraction to result in the filtered beverage.

A reduced calorie nutrient enriched food product is produced by converting sucrose to monosaccharides and by selectively separating high molecular weight nutrients and sucrose in a food product such as a juice. The sucrose may be converted to non-digestible oligosaccharides. The process may also include separating a feed juice into a solids-rich fraction and a clarified juice fraction; treating the clarified juice fraction to form a high molecular weight-rich and oligosaccharide-rich fraction that can be combined with the solids-rich fraction to form a reduced calorie nutrient enriched liquid.

A method for preparing a filtered beverage includes filtering a raw beverage using a cross-flow ultrafiltration device to produce a solids fraction and a liquid fraction; heating the solids fraction to a temperature of 60° C. or greater to produce a pasteurized solids fraction; microfiltering the liquid fraction through a microfilter having a size cut-off of 1 μm or smaller to produce a microfiltered liquid fraction; and combining the pasteurized solids fraction and the microfiltered liquid fraction to result in the filtered beverage.