A method of making a flavoured sweetener or food product by incubating an unrefined plant extract containing sucrose as the main solute with a microorganism or microorganisms to form a modified unrefined plant extract; evaporating water from the modified sucrose-based plant extract to form a concentrate; and cooking the concentrate to develop colour and flavour to produce the flavoured sweetener is disclosed. The flavoured sweetener can serve as a coconut sugar substitute. In a preferred embodiment the unrefined plant extract comprises sugarcane juice or sugar beet juice, and the microorganisms may be selected from Stenotrophomonas maltophilia, Bacillus subtilis, Bacillus flexus, or a Klyveromyces species. The flavoured sweetener can be used to make a range of food and beverage ingredients and also food products including sauces, natural flavour extracts and flavour molecules, chocolate, health foods and convenience forms of the various forms of flavoured sweeteners.

The invention relates to a method the preparation of an inverted sugar product, called high test molasses, using novel reaction parameters. More particularly it relates to the preparation of high-test molasses using an acid wherein the loss of sugar due to use of acid and high temperature as in conventional method is eliminated.

The invention relates to a continuous method for obtaining a crystalline monosaccharide, comprising: continuous crystallization of the monosaccharide in a main crystallizer (10), wherein crystallization by evaporation and/or crystallization by cooling is carried out continuously on a crystal suspension in the main crystallizer in order to allow crystals of the monosaccharide to grow in the crystal suspension; separation of crystals of the monosaccharide out of the crystal suspension to obtain crystalline monosaccharide; continuous formation of a mass of crystallization magma for the main crystallizer (10) in a cascade, wherein the cascade comprises at least one first stage (13) and a final stage (15) connected in series and each stage comprises at least one pre-crystallizer (13A, 15A), wherein, in the at least one pre-crystallizer (13A) of the first stage (13), a solution is seeded with monosaccharide by means of monosaccharide seed crystals in order to obtain a pre-crystallization magma, and a mass of crystallization magma for the downstream stage (14, 15) is formed from the pre-crystallization magma by means of crystallization by cooling and/or crystallization by evaporation, and wherein a solution containing monosaccharide and a mass of crystallization magma from the upstream stage is supplied to the at least one pre-crystallizer (15A, 15B, 15C) of the final stage (15) to obtain a pre-crystallization magma, and in the at least one pre-crystallizer (15A, 15B, 15C) of the final stage (15) a mass of crystallization magma for the main crystallizer (10) is formed from the pre-crystallisation magma by means of crystallization by cooling and/or crystallization by evaporation; the continuous supply of a solution containing the monosaccharide and a mass of crystallization magma from the at least one pre-crystallizer (15A, 15B, 15C) of the final stage (15) of the cascade to the main crystallizer (10) to provide the crystal suspension.

A sugar liquid or solid sugar is derived from cellulose-containing biomass or blackstrap molasses, wherein content of one or more free amino acids selected from the group consisting of serine, threonine, asparagine, aspartic acid, glutamine, glutamic acid, proline, phenyl alanine, lysine, and histidine, which are impurities, is below the limit of detection.

The invention relates to a method the preparation of an inverted sugar product, called high test molasses, using novel reaction parameters. More particularly it relates to the preparation of high-test molasses using an acid wherein the loss of sugar due to use of acid and high temperature as in conventional method is eliminated.

A method for cultivation and processing of sugar beets the includes steps of: providing the sugar beets and/or sugar beet seedlings in a first step; supplying the sugar beets and/or the sugar beet seedlings with a nutrient solution during growth in a second step; harvesting at least partially fully grown sugar beets in a third step; processing the harvested sugar beets in a sugar production plant in order to extract sugar from the sugar beets in a fourth step; the nutrient solution used in the second step is at least partially obtained by recovering water in the fourth step which is recycled in the second step.

A method of producing a sugar liquid from biomass includes decomposing a fermentation inhibitor contained in a sugar aqueous solution obtained from biomass with a microorganism incapable of utilizing glucose and/or xylose or a crude enzyme derived from the microorganism, wherein the fermentation inhibitor includes one or more compounds selected from the group consisting of courmaric acid, coumaramide, ferulic acid, ferulamide, vanillin, vanillic acid, acetovanillone, furfural, and 3-hydroxymethylfurfural.

The application relates to compositions based on maple sap, fruit juice and/or vegetable juice having a high added value. In particular, said compositions have high concentrations in polyphenols, phosphorus, magnesium, calcium and potassium, for example. These concentrations are higher than those in maple sap made by previous traditional or commercial processes and higher than those in fruit or vegetable juices or syrups. Furthermore, said compositions have an antioxidant effect that is also higher than that in commercial maple sap made on an industrial or small scale and higher than that in commercial fruit or vegetable juices or syrups. The application also relates to processes for making such compositions.