A directly compressible composition includes more than 30% by weight of allulose. The directly compressible composition can form tablets. A method for the manufacture of allulose granules includes: a step (a) of preparing a granulation liquid comprising allulose; a step (b) of granulating powdery allulose, by applying the granulation liquid obtained in step (a) onto moving powdery allulose; a step (c), simultaneous with step (b), of drying the granules obtained in step (b); a step (c) of maturation of the granules obtained in step (c); and a step (d) of recovering the granules obtained in step (c) or (c).

A directly compressible composition includes more than 30% by weight of allulose. The directly compressible composition can form tablets. A method for the manufacture of allulose granules includes: a step (a) of preparing a granulation liquid comprising allulose; a step (b) of granulating powdery allulose, by applying the granulation liquid obtained in step (a) onto moving powdery allulose; a step (c), simultaneous with step (b), of drying the granules obtained in step (b); a step (c) of maturation of the granules obtained in step (c); and a step (d) of recovering the granules obtained in step (c) or (c).

Disclosed are particles comprising pectin and gelatin. The particles may be useful for preparing any of a variety products such as, for example, soft pharmaceutical capsules, hard pharmaceutical capsules, and foodstuffs. Also disclosed are methods for preparing the particles, the method comprising: (a) dissolving pectin in an aqueous solution to produce an aqueous solution of dissolved pectin; (b) mixing the aqueous solution of dissolved pectin with liquid gelatin to produce a gelatin/pectin mixture; (c) drying the gelatin/pectin mixture; and (d) milling the gelatin/pectin mixture to produce the plurality of particles.

Disclosed are particles comprising pectin and gelatin. The particles may be useful for preparing any of a variety products such as, for example, soft pharmaceutical capsules, hard pharmaceutical capsules, and foodstuffs. Also disclosed are methods for preparing the particles, the method comprising: (a) dissolving pectin in an aqueous solution to produce an aqueous solution of dissolved pectin; (b) mixing the aqueous solution of dissolved pectin with liquid gelatin to produce a gelatin/pectin mixture; (c) drying the gelatin/pectin mixture; and (d) milling the gelatin/pectin mixture to produce the plurality of particles.

Nutrients and/or nutrient supplements compacted into soluble pods are described, namely the invention is a combination of formulation with compaction methods and coating/encapsulating methods. The formulation includes combining nutrients and/or nutrient supplements with at least one dissolution agent, and with at least one binding agent. The methods include compaction and coating/encapsulating the resulting compact-pod or formula to generate a single serve compact-pod unit that can be dissolved into a beverage or liquid.

Nutrients and/or nutrient supplements compacted into soluble pods are described, namely the invention is a combination of formulation with compaction methods and coating/encapsulating methods. The formulation includes combining nutrients and/or nutrient supplements with at least one dissolution agent, and with at least one binding agent. The methods include compaction and coating/encapsulating the resulting compact-pod or formula to generate a single serve compact-pod unit that can be dissolved into a beverage or liquid.

Methods are disclosed for making a shelf stable food containing a flavorant having improved intensity over shelf life. Methods include applying a powdered flavorant to a surface of dried fruit pieces prior to combining the dried fruit pieces with a binder to form an aggregate. Shelf stable foods made according to the disclosed methods are also disclosed.

Methods are disclosed for making a shelf stable food containing a flavorant having improved intensity over shelf life. Methods include applying a powdered flavorant to a surface of dried fruit pieces prior to combining the dried fruit pieces with a binder to form an aggregate. Shelf stable foods made according to the disclosed methods are also disclosed.

A process for modifying starches comprises atomizing an aqueous slurry of a non-pregelatinized, granular, high amylose starch into to an internal chamber in a bi-fluid nozzle of a dryer and treating the atomized slurry, in the internal chamber, with medium pressure steam to produce a slurry of partially treated starch granules followed by discharging the slurry into a reactor where it is contacted with superheated steam to produce dry, particulate, cold water-swelling, intact, high amylose starch granules. The cold water-swelling, intact, high amylose starch granules have greater than 15% solubles. At a starch concentration of 1%, in UDMSO (9 volumes DMSO and 1 volume 6M urea) at 25 C., the ratio of apparent viscosity of said cold water-swelling, intact, high amylose starch granules to the apparent viscosity of the parent non-pregelatinized, granular, high amylose starch is lower than 1.00. The cold water-swelling, high amylose granular starch of the invention is useful in the manufacture of food products, especially confectionery products and convenience food products.

A process for modifying starches comprises atomizing an aqueous slurry of a non-pregelatinized, granular, high amylose starch into to an internal chamber in a bi-fluid nozzle of a dryer and treating the atomized slurry, in the internal chamber, with medium pressure steam to produce a slurry of partially treated starch granules followed by discharging the slurry into a reactor where it is contacted with superheated steam to produce dry, particulate, cold water-swelling, intact, high amylose starch granules. The cold water-swelling, intact, high amylose starch granules have greater than 15% solubles. At a starch concentration of 1%, in UDMSO (9 volumes DMSO and 1 volume 6M urea) at 25 C., the ratio of apparent viscosity of said cold water-swelling, intact, high amylose starch granules to the apparent viscosity of the parent non-pregelatinized, granular, high amylose starch is lower than 1.00. The cold water-swelling, high amylose granular starch of the invention is useful in the manufacture of food products, especially confectionery products and convenience food products.