The present invention is related to an enzyme that allows efficient removal of fructan from grain and vegetable raw material. The enzyme according to the invention produces grain and vegetable material having a fructan content significantly lower compared to that of the starting material.

A novel grape seed extract is enriched in procyanidins, has total polyphenols of less than 70%, and has a low degree of polymerization (dp). Other fractions of the extract have minimal polyphenols, fiber, and protein, but contain more than 90% sugars. In some specific examples, the individual extracts are obtained by sequential ultrafiltration of a water extract of the grape seeds. A first ultrafiltration provides a first permeate (Fraction A) enriched in sugars which is useful as a flavorant, and a first retentate. The first retentate is reconstituted and subjected to a second ultrafiltration at a higher molecular weight cutoff to produce a second permeate (Fraction B) that is enriched in low molecular weight polyphenols, and a second retentate (Fraction C) that is enriched in seed fiber. The Fractions are individually suitable for different nutraceutical products, or can be combined with each other in any combination and/or with other nutraceutical agents to enhance vascular and cognitive health.

Fluorine being present in the exoskeleton of crustaceans, and especially krill represents a problem for using krill as a source for food, feed, food additives and/or feed additives. There has been developed a process for removing such fluorine from krill material by subjecting the krill to disintegration and to an enzymatic hydrolysis process prior to or simultaneously with a removal of the exoskeleton particles producing a fluorine-reduced product. Inherent in the disclosed process is the ability to process krill material with a high polar lipid content for producing superior quality, low fluorine, products suitable for the food and feed as well as the pharmaceutical, neutraceutical and cosmetic industry.

The present invention relates to a vegetable powder, a process for preparing the powder and its use in food products. The vegetable powder may be used to improve a food product, in particular to improve its taste, flavour or texture. An improved food product according to the invention shows one or more of the following improvements in comparison to the food product to which no powder has been added: a rounder flavour profile, less off-notes, a sweeter taste, more umami taste, more kokumi taste or more creaminess. The powder according to the invention allows for clean and clear-labelled food products.

Methods of manufacturing products from material comprising oilcake, compositions produced from materials comprising processed oilcake, and systems for processing oilcake are provided herein. The method comprises de-solubilizing protein in a material comprising oilcake to produce a processed material comprising an insoluble protein fraction. The processed material is hydrolyzed to produce a mixture comprising the insoluble protein fraction and a hydrolyzed fraction. The insoluble protein fraction is separated from the hydrolyzed fraction. The insoluble protein fraction is processed into a product.

Provided is a method for producing a processed food, in which the generation of a sulfur smell or the imparting of an unpleasant flavor like an accumulated sulfur smell is suppressed.

[Means for Resolution]

Provided is a method for producing a processed food in which the generation of a sulfur smell is suppressed, including the following steps (A) and (B):

(A) a step of bringing a transglutaminase and/or a reducing sugar into contact with a solid food material containing a protein as a main nutritional component; and

(B) a step of subjecting the food material after the step (A) to a heat sterilization treatment.

Methods of manufacturing products from material comprising oilcake, compositions produced from materials comprising processed oilcake, and systems for processing oilcake are provided herein. The method comprises de-solubilizing protein in a material comprising oilcake to produce a processed material comprising an insoluble protein fraction. The processed material is hydrolyzed to produce a mixture comprising the insoluble protein fraction and a hydrolyzed fraction. The insoluble protein fraction is separated from the hydrolyzed fraction. The insoluble protein fraction is processed into a product.

The present disclosure provides a multicopper oxidase mutant with improved salt tolerance. Threonine at site 317 of wild-type multicopper oxidase WT was mutated to asparagine, leucine at site 386 was mutated to tyrosine, and serine at site 427 was mutated to glutamic acid by site-directed mutagenesis to obtain a mutant T317N-L386Y-S427E. Compared with WT, the tolerance of T317N-L386Y-S427E to 6%, 9%, 12%, 15% and 18% NaCl (W/V) is improved.

A process for producing a protein isolate from an oilseed meal, and the isolate thus obtained, said isolate comprising proteins and an amount of 4 wt % or less of phytic acid, said amount of phytic acid being by weight of proteins in said isolate. The process may comprise the following steps: a) providing an oilseed meal; b) mixing the oilseed meal with a first aqueous solvent to form a slurry at a pH ranging from 6 to 7.8, said slurry having a solid phase; c) separating said solid phase from said slurry, d) mixing said separated solid phase with a second aqueous solvent at a pH ranging from 1 to 3.5, preferably from 2 to 3, to form a mixture said mixture having a liquid phase; e) separating said liquid phase from said mixture formed in step d); f) f1) mixing the separated liquid phase to a phytase at a temperature and a pH suitable for phytase activity to obtain a mixture having a liquid phase and a solid phase; and/or f2) mixing the separated liquid to a salt, to obtain a resulting liquid composition having a molar concentration of said salt ranging from 0.05 M to 0.5 M, at a temperature ranging from 40 C. to 70 C., to obtain a mixture having a liquid phase and a solid phase; g) precipitating a solid phase from the liquid of step f) for example by a cooling down step of the mixture to a temperature of 30 C. or less; h) separating said solid precipitate from the liquid of step g) said liquid comprising a water-rich liquid phase and an oil-rich liquid phase; i) separating said water-rich liquid phase from said oil-rich liquid phase, j) subjecting said water-rich liquid phase obtained in step i) to one or several membrane filtration(s) to obtain a protein isolate; and k) optionally, drying said protein isolate to obtain a dry protein isolate.

A process to remove the glucosinolates of oilseed meals, such as Brassica carinata oilseed meals, is provided. In one embodiment, exogenous myrosinase is used to convert the glucosinolates to volatile isothiocyanate compounds, which can then be removed under conditions of mild heat and negative pressure. In another embodiment, heat and pressure are used to remove glucosinolates from Brassica carinata oilseed. The processed meals may contain less than 80% of their starting levels of glucosinolates and may be suitable for use in various applications, including as animal feeds.