There is described an edible particulate material comprising from 80% to 100% by weight based on total weight of the material of a processable, microbially released, flavour acceptable bran-like material, characterized by the following parameters: (i) mean particle size by volume (Vol. MPS) of from 5 to 100 microns; (ii) volume particle size distribution (Vol. PSD) characterized by the parameters: D.sub.90,3 less than or equal to 350 microns, and D.sub.50,3 less than or equal to 50 microns, and optionally D.sub.10,3 less than or equal to 15 microns, (iii) mean particle sphericity as measured by a S.sub.mean of greater than or equal to 0.75; (iv) where processable means has oil holding capacity (OHC) of from 0.7 to 1.5; (v) where microbially released means material has common microbes below given limits (preferably free of common microbes) (vi) where flavour acceptable denotes a lipase activity (LA) and a peroxidase activity (PA) both less than or equal to 2 U/g optionally a low degree of roasted flavour notes as defined herein. The bran as described may added to foodstuffs for example be used as a bulk ingredient to replace sugar and/or to provide filling and/or coatings having improved hiding ability when used as layers in multilayer foodstuffs.

The invention relates to a method of producing a food or beverage product, comprising the steps of: providing an ingredient composition comprising, micellar caseins and whey proteins and having a pH of 6.1-7.1 and a concentration of 1-15 wt. % of proteins, and wherein the ingredient composition has a casein to whey protein ratio of 90/10-60/40, adding 3-25 mM divalent cations to provide a concentration of 3-8 mM free divalent cations in the ingredient composition, homogenising the ingredient composition; and subsequently pasteurising and stirring the ingredient composition at a temperature of 80°-100° C. for a period of 0.5-3 min to form agglomerated proteins comprising caseins and beta-lactoglobulin from the whey proteins, the agglomerates having a size of 5-50 microns as measured by D(.sub.4,3) mean diameter. The invention relates also to a food or beverage product comprising aggregated proteins comprising micellar casein and whey protein aggregates, wherein the product has a pH of 6.1-7.1, a concentration of 6-40 wt. % milk solids, a casein to whey protein ratio of 90/10-60/40, and a concentration of 3-8 mM free divalent cations, and wherein the agglomerates having a size of 5-50 microns mean diameter D(.sub.4,3) as measured by laser diffraction.

Novel coated bulking agent particles for reduction of calories in fat-based food products comprising sugar. A coated bulking agent particle comprising from 2 wt % to 70 wt % bulking agent and from 30 wt % to 98 wt % coating composition comprising sugar and surface active agent; wherein the ratio of sugar to surface active agent in the composition is from 2000:1 to 4:1 and from 50 wt % to 100 wt % of the sugar is in crystalline form; wherein the bulking agent is coated with the coating composition; an agglomerated coated bulking agent particle; a process of preparing the particles and a fat-based confection composition comprising the coated bulking agent particles.

A method and system for producing confectionery, wherein a tray with one or more mould cavities formed in moulding powder, such as starch, is provided. The moulding powder has an initial moisture content. Depositing liquid confectionery in the one or more mould cavities causes the moisture content of the moulding powder to increase. The tray is provided in a conditioning room configured for drying the deposited confectionery. The conditioning parameters of the conditioning room are adapted such that the moulding powder is dried to a desired moisture content, wherein the desired moisture content is such that the moulding powder is suitable for immediate re-use in subsequent confectionery production.

Described herein is a process for applying granular material on an outer side of a foodstuff product (P). This process comprises the steps of: providing a mould (102) having a mould cavity (S′) that is delimited, at least partially, by at least one mobile wall (106); positioning the product (P) in the mould cavity by setting the outer side (p1) in a position facing and at a distance from the mobile wall; introducing granular material in the gap (112) comprised between the mobile wall (106) and the outer side of the product; and moving the mobile wall (106) towards the outer side of the product so that it comes to press the granular material against the outer side (p1) of the product (P).

There is described an edible particulate material comprising from 80% to 100% by weight based on total weight of the material of a processable, microbially released, flavour acceptable bran-like material, characterized by the following parameters: (i) mean particle size by volume (Vol. MPS) of from 5 to 100 microns; (ii) volume particle size distribution (Vol. PSD) characterized by the parameters: D.sub.90,3 less than or equal to 350 microns, and D.sub.50,3 less than or equal to 50 microns, and optionally D.sub.10,3 less than or equal to 15 microns, (iii) mean particle sphericity as measured by a S.sub.mean of greater than or equal to 0.75; (iv) where processable means has oil holding capacity (OHC) of from 0.7 to 1.5; (v) where microbially released means material has common microbes below given limits (preferably free of common microbes) (vi) where flavour acceptable denotes a lipase activity (LA) and a peroxidase activity (PA) both less than or equal to 2 U/g optionally a low degree of roasted flavour notes as defined herein. The bran as described may added to foodstuffs for example be used as a bulk ingredient to replace sugar and/or to provide filling and/or coatings having improved hiding ability when used as layers in multilayer foodstuffs.

There is described an edible particulate material comprising from 80% to 100% by weight based on total weight of the material of a processable, microbially released, flavour acceptable bran-like material, characterized by the following parameters: (i) mean particle size by volume (Vol. MPS) of from 5 to 100 microns; (ii) volume particle size distribution (Vol. PSD) characterized by the parameters: D.sub.90,3 less than or equal to 350 microns, and D.sub.50,3 less than or equal to 50 microns, and optionally D.sub.10,3 less than or equal to 15 microns, (iii) mean particle sphericity as measured by a S.sub.mean of greater than or equal to 0.75; (iv) where processable means has oil holding capacity (OHC) of from 0.7 to 1.5; (v) where microbially released means material has common microbes below given limits (preferably free of common microbes) (vi) where flavour acceptable denotes a lipase activity (LA) and a peroxidase activity (PA) both less than or equal to 2 U/g optionally a low degree of roasted flavour notes as defined herein. The bran as described may added to foodstuffs for example be used as a bulk ingredient to replace sugar and/or to provide filling and/or coatings having improved hiding ability when used as layers in multilayer foodstuffs.

An edible filling formed of protein-containing solid particles in a fat-containing carrier having lecithin during wet particle size reduction to emulsify before enough starch is added to absorb excess or free fat-containing carrier when mixed together. One preferred particle size reduction method step employs wet grinding of proteins in a ball mill disposed in a fat containing oil or shortening carrier until substantially all of the proteins have been reduced in size to a particle size of less than 40 microns enabling the reduced size protein particles to remain in suspension in the resultant filling for an extended period of time increasing filling storage or shelf life while also producing a filling of more uniform appearance, texture and taste. Lecithin in excess of what is needed for emulsification is added during filling making to protect proteins and absorb excess water in the filling.

The present disclosure describes a flavor element configured for providing flavor to a user of an electronic vaporizer, along with nicotine reduction methods. The flavor element includes a flavor material configured to provide the flavor and is configured to attach to the electronic vaporizer. When attached to the electronic vaporizer and during inhalation by the user using the electronic vaporizer, the flavor element is configured to provide the flavor to the user in parallel with an inhalable aerosol provided by the electronic vaporizer. The inhalable aerosol is provided by the electronic vaporizer by at least partially vaporizing a vaporizable substance via a vapor element. The flavor provided via the flavor material is separate from the vaporizable substance.

The present disclosure describes a flavor element configured for providing flavor to a user of an electronic vaporizer, along with nicotine reduction methods. The flavor element includes a flavor material configured to provide the flavor and is configured to attach to the electronic vaporizer. When attached to the electronic vaporizer and during inhalation by the user using the electronic vaporizer, the flavor element is configured to provide the flavor to the user in parallel with an inhalable aerosol provided by the electronic vaporizer. The inhalable aerosol is provided by the electronic vaporizer by at least partially vaporizing a vaporizable substance via a vapor element. The flavor provided via the flavor material is separate from the vaporizable substance.