Abstract: Palatable food products are provided with low bulk density of about 4-12 lb/ft3 and comprise an expanded matrix of intercommunicated pores defined by a skeletal structure of gelatinized starch. The products produce an audible crunch sound when crushed by applied force and include low calorie, energy-dense characteristics of about 2-6 Kcal/g. The total weight of the product comprises about 20-60% starch, about 30% or less flowable fat, about 2-12% water, and a coating of flavorants and/or aromants. The product can optionally comprise health promoting ingredients. The products are manufactured by extruding batched ingredients including starch and water under processing conditions to promote starch gelatinization to form a substantially homogenous dough that, after extrusion, expands into a porous matrix. The porous matrix can undergo vacuum infusion to fill the matrix with flowable fat, dry palatant, and wet palatant. After infusion, the porous matrix can be dust coated with dry palatant.

Abstract: Palatable food products are provided with low bulk density of about 4-12 lb/ft3 and comprise an expanded matrix of intercommunicated pores defined by a skeletal structure of gelatinized starch. The products produce an audible crunch sound when crushed by applied force and include low calorie, energy-dense characteristics of about 2-6 Kcal/g. The total weight of the product comprises about 20-60% starch, about 30% or less flowable fat, about 2-12% water, and a coating of flavorants and/or aromants. The product can optionally comprise health promoting ingredients. The products are manufactured by extruding batched ingredients including starch and water under processing conditions to promote starch gelatinization to form a substantially homogenous dough that, after extrusion, expands into a porous matrix. The porous matrix can undergo vacuum infusion to fill the matrix with flowable fat, dry palatant, and wet palatant. After infusion, the porous matrix can be dust coated with dry palatant.

Abstract: Palatable food products are provided with low bulk density of about 4-12 lb/ft3 and comprise an expanded matrix of intercommunicated pores defined by a skeletal structure of gelatinized starch. The products produce an audible crunch sound when crushed by applied force and include low calorie, energy-dense characteristics of about 2-6 Kcal/g. The total weight of the product comprises about 20-60% starch, about 30% or less flowable fat, about 2-12% water, and a coating of flavorants and/or aromants. The product can optionally comprise health promoting ingredients. The products are manufactured by extruding batched ingredients including starch and water under processing conditions to promote starch gelatinization to form a substantially homogenous dough that, after extrusion, expands into a porous matrix. The porous matrix can undergo vacuum infusion to fill the matrix with flowable fat, dry palatant, and wet palatant. After infusion, the porous matrix can be dust coated with dry palatant.

Abstract: Palatable food products are provided with low bulk density of about 4-12 lb/ft3 and comprise an expanded matrix of intercommunicated pores defined by a skeletal structure of gelatinized starch. The products produce an audible crunch sound when crushed by applied force and include low calorie, energy-dense characteristics of about 2-6 Kcal/g. The total weight of the product comprises about 20-60% starch, about 30% or less flowable fat, about 2-12% water, and a coating of flavorants and/or aromants. The product can optionally comprise health promoting ingredients. The products are manufactured by extruding batched ingredients including starch and water under processing conditions to promote starch gelatinization to form a substantially homogenous dough that, after extrusion, expands into a porous matrix. The porous matrix can undergo vacuum infusion to fill the matrix with flowable fat, dry palatant, and wet palatant. After infusion, the porous matrix can be dust coated with dry palatant.

Abstract: Food nanoemulsion compositions comprising a food safe nonionic surfactant, a hydrophobic food flavorant (e.g., an essential oil), a sugar alcohol kosmotrope, and water. The ratio of the sugar alcohol kosmotrope to the hydrophobic food flavorant is at least 8:1 by weight, and the composition advantageously requires little if any monohydric alcohols for stability and is also free of polyols in addition to the sugar alcohol. Such nanoemulsion compositions are formed from microemulsion concentrates with little or no kinetic energy input. The microemulsion phase inverts to the nanoemulsion upon dilution with additional water. Infinite dilution in water and oil is possible. The high ratio of sugar alcohol to flavorant controls the particle size distribution of the nanoemulsion composition and advantageously alters the organoleptic properties of the nanoemulsion to insert perception of the flavorant near the end of the palatal response.

Abstract: Bran treatment methods are described, comprising acidifying bran with a acid to pH's ranging from 4-6 forming acidified bran and thereafter treating with low levels of ozone to oxidize native bitter constituent, ferulic acid, preferably to vanillin to provide better flavored bran. The treated bran is useful as an ingredient for use in products such as flour based food products such as flours, pastas, dry mixes, refrigerated uncooked doughs, pet foods, ready-to-eat cereals, breads, tortilla, and grain based snacks.

Abstract: The present invention is directed to a food emulsion composition, in the form of a nanoemulsion, comprising a food safe nonionic surfactant, alcohol co-solvent and an essential oil. The food emulsion composition can be used for a wide variety of food and beverage compositions, including but not limited to, dressings, marinades, sauces, condiments, beverages and the like. The encapsulated nanoemulsion flavorant compositions are beneficial because they make flavorants appear comparable with other compositions with twice the amount of flavorants which are non-encapsulated in an nanoemulsion. In addition, the nanoemulsion compositions better stability and show less signs of oxidation over time at room temperature than non-encapsulated formulations. Less oxidation and better stability results in lesser appearance of rancid aromas and bitter flavors.

Abstract: A method of bleaching bran, comprising treating bran with a hydrogen peroxide solution to produce lightened bran having fewer native flavor components is disclosed. In one embodiment, a bleached bran product suitable for admixing with whole wheat flour to produce white whole wheat flour having an “L” value on the Hunter scale of at least about 75 is disclosed. In one embodiment, cleaned bran is treated with a solution of chelating agents to remove or inactivate transition metals. Thereafter, exposure to oxidant substances, such as hydrogen peroxide, ozone, and so forth, in the presence of an alkaline compound produces bleached bran, which can be washed and dried for use in products such as flours, pastas, and so forth.

Abstract: A method of bleaching bran, comprising treating bran with a hydrogen peroxide solution to produce lightened bran having fewer native flavor components is disclosed. In one embodiment, a bleached bran product suitable for admixing with whole wheat flour to produce white whole wheat flour having an “L” value on the Hunter scale of at least about 75 is disclosed. In one embodiment, cleaned bran is treated with a solution of chelating agents to remove or inactivate transition metals. Thereafter, exposure to oxidant substances, such as hydrogen peroxide, ozone, and so forth, in the presence of an alkaline compound produces bleached bran, which can be washed and dried for use in products such as flours, pastas, and so forth.

Abstract: Bran treatment methods are described, comprising acidifying bran with a acid to pH's ranging from 4-6 forming acidified bran and thereafter treating with low levels of ozone to oxidize native bitter constituent, ferulic acid, preferably to vanillin to provide better flavored bran. The treated bran is useful as an ingredient for use in products such as flour based food products such as flours, pastas, dry mixes, refrigerated uncooked doughs, pet foods, ready-to-eat cereals, breads, tortilla, and grain based snacks.

Abstract: Disclosed are microwave shelf stable popcorn articles that contain real butter. The articles comprise any conventional microwave popcorn bag and an improved popcorn/fat charge. In addition to kernel popcorn and fat, the charge further essentially includes about 1% to 8% of a high fat butter constituent. By virtue of selecting a particularly defined high fat butter ingredient, microwave popcorn articles can be prepared that are shelf stable.

Abstract: Disclosed are microwave shelf stable popcorn articles that contain real butter. The articles comprise any conventional microwave popcorn bag and an improved popcorn/fat charge. In addition to kernel popcorn and fat, the charge further essentially includes about 1% to 8% of a high fat butter constituent. By virtue of selecting a particularly defined high fat butter ingredient, microwave popcorn articles can be prepared that are shelf stable.