Process for preparing disodium 5,5-indigosulfonate, the feedstock being indigo, this process including the following steps: i) the indigo is subjected to a sulfonation treatment resulting in a mixture that contains 5,5-indigosulfonic acid, this process including: ii) a reduction treatment is applied to the mixture obtained in step i), and optionally a purification step, so as to obtain a composition including leuco-5,5-indigosulfonic acid, iii) the leuco-5,5-indigosulfonic acid is isolated from the composition resulting from step ii), iv) the leuco-5,5-indigosulfonic acid resulting from step iii) is oxidized to give disodium 5,5-indigosulfonate.

Process for preparing disodium 5,5-indigosulfonate, the feedstock being indigo, this process including the following steps: i) the indigo is subjected to a sulfonation treatment resulting in a mixture that contains 5,5-indigosulfonic acid, this process including: ii) a reduction treatment is applied to the mixture obtained in step i), and optionally a purification step, so as to obtain a composition including leuco-5,5-indigosulfonic acid, iii) the leuco-5,5-indigosulfonic acid is isolated from the composition resulting from step ii), iv) the leuco-5,5-indigosulfonic acid resulting from step iii) is oxidized to give disodium 5,5-indigosulfonate.

Colorant particles made from an insoluble protein-based substrate to which a dye is adsorbed are disclosed. The colorant particles are highly dispersible onto solid surfaces or within liquid systems, and thus can be used as substitutes for the alumina-based lake particles that are conventionally used as colorants in consumer products, such as food or beverage products, cosmetic products, pharmaceutical products, nutraceutical products, or toys.

Colorant particles made from an insoluble protein-based substrate to which a dye is adsorbed are disclosed. The colorant particles are highly dispersible onto solid surfaces or within liquid systems, and thus can be used as substitutes for the alumina-based lake particles that are conventionally used as colorants in consumer products, such as food or beverage products, cosmetic products, pharmaceutical products, nutraceutical products, or toys.

The present invention relates to a method of producing compositions with enhanced color properties and to compositions obtainable by such a method, especially cocoa-based compositions with enhanced color properties. The method comprises the steps of providing an initial composition comprising a polyphenol, adding an aqueous base to the initial composition to produce an aqueous mixture, heating the aqueous mixture to a temperature of 50 to 100 C. during a time period of 120 to 300 minutes, cooling the aqueous mixture, and optionally adjusting the pH of the aqueous mixture to between 6 and 9. The method further comprises oxygenising the aqueous base and/or the aqueous mixture, wherein the produced food product comprises chromophores having an absorption maximum between 505 to 515 nm and/or 428 to 438 nm.

The present invention relates to a method of producing compositions with enhanced color properties and to compositions obtainable by such a method, especially cocoa-based compositions with enhanced color properties. The method comprises the steps of providing an initial composition comprising a polyphenol, adding an aqueous base to the initial composition to produce an aqueous mixture, heating the aqueous mixture to a temperature of 50 to 100 C. during a time period of 120 to 300 minutes, cooling the aqueous mixture, and optionally adjusting the pH of the aqueous mixture to between 6 and 9. The method further comprises oxygenising the aqueous base and/or the aqueous mixture, wherein the produced food product comprises chromophores having an absorption maximum between 505 to 515 nm and/or 428 to 438 nm.

Heat-triggered colorants for altering the color of a food, methods for changing the color of a food using heat-triggered colorants, and methods for making heat-triggered colorants for food. The heat-triggered colorants may comprise a mixture comprising a carrier having a melting point and a GRAS (Generally Recognized as Safe) first food colorant having a color, and a coating encapsulating the mixture and masking the color of the first food colorant. When the heat-triggered colorant is exposed to a temperature greater than the melting point of the carrier, the carrier melts and releases the first food colorant, thereby unmasking the color of the first food colorant.

Heat-triggered colorants for altering the color of a food, methods for changing the color of a food using heat-triggered colorants, and methods for making heat-triggered colorants for food. The heat-triggered colorants may comprise a mixture comprising a carrier having a melting point and a GRAS (Generally Recognized as Safe) first food colorant having a color, and a coating encapsulating the mixture and masking the color of the first food colorant. When the heat-triggered colorant is exposed to a temperature greater than the melting point of the carrier, the carrier melts and releases the first food colorant, thereby unmasking the color of the first food colorant.

Alcohol-based, edible ink formulations comprising scalenohedral calcium carbonate particles are provided. The calcium carbonate particles can act as a white pigment to impart white color properties to the edible ink formulations. The edible ink formulations can be printed onto a variety of surfaces, including the surfaces of food products such as confectionery products and snack food products.

Alcohol-based, edible ink formulations comprising scalenohedral calcium carbonate particles are provided. The calcium carbonate particles can act as a white pigment to impart white color properties to the edible ink formulations. The edible ink formulations can be printed onto a variety of surfaces, including the surfaces of food products such as confectionery products and snack food products.