A roll-in margarine composition with reduced saturated fatty acids content containing 60% to 80% by weight of a fatty phase and 40% to 20% by weight of an aqueous phase containing water, proteins and soluble and/or insoluble dietary fibers is disclosed. The fatty phase consists of 30% to 45% of a vegetable fat rich in stearic acid and 70% to 55% of a vegetable oil. The soluble fibers can be beta-glucans, concentrated algae, pea fiber, potato fiber, psyllium fiber, guar fiber, and the insoluble fibers can be celluloses, wheat fiber, pea integument fiber, carrot fiber and bamboo fiber. A process for preparing the margarine composition is also disclosed.

High-protein food additives are prepared by reacting a protein material with L-cysteine, or a derivative thereof, with homogenization and heating. The homogenization and heating is preferably carried out on an aqueously slurry of the protein material and L-cysteine. The homogenized and reacted slurry is then dried to form a powder. The resultant food additive may be incorporated into a wide variety of food products to enhance the physical characteristics thereof.

Composite flour includes native plant flour and complexed MCT and/or other nutritional oil at least partially encapsulated by wall material and incorporated within the composite flour, wherein polysaccharide from a portion of the native plant flour forms part of the wall material. The wall material includes protein, e.g., pea protein, polysaccharide released from the native plant flour, and emulsifier(s), and/or polysaccharide fiber, e.g., acacia fiber. The native plant flour may be gluten-flour, gluten-free flour and/or low carbohydrate seed, nut or vegetable flour. Composite flours can replace traditional flours to make food products, such as baked, fried or boiled goods but with benefits, such as reduced gluten and/or carbohydrates, increased freshness and volume and improved texture and taste compared to alternative flours and even all-purpose flour. Composite flour can be blended with native flour and/or another composite flour to form blended flour.

The present invention addresses the problem of providing modified gluten capable of imparting excellent freezing tolerance to a bread dough and a method for manufacturing the modified gluten. Provided is a method for manufacturing modified gluten which comprises a step for heating a solution containing gluten together with an organic acid having two or more carbonyl groups per molecule, said organic acid being used in an amount of 1 part by weight or more per 100 parts by weight of gluten, at 70 C. or higher for 30 minutes or longer.

The subject invention provides unique and novel LOW CARBOHYDRATE HIGH PROTEIN PIZZA BASE. In the first embodiment, said LOW CARBOHYDRATE HIGH PROTEIN PIZZA BASE provides raised, textured pizza base that contain such as but not limited to rice and chicken protein. Other poultry such as but not limited to turkey can be used to replicate said chicken. Uniquely said LOW CARBOHYDRATE HIGH PROTEIN PIZZA BASE is being used as a replacement for traditional high carbohydrate low protein dough used as a pizza base.

Gluten and a plant protein are combined with an aqueous solution to make a dough useful for making either an expanded wafer or a leather snack food product. When compressed between two heated surfaces, the dough flattens while releasing moisture to produce an expanded wafer. The expanded wafers may be cut into shapes and/or topped with various snack food toppings to make either sweet or savory snack food products. The wafers may also be used to make a sandwich-type snack food using at least two wafers with a filling in between. Alternatively, the expanded wafer be infused with flavoring solutions to form leather snack food products.

Composite flour includes native plant flour and complexed MCT and/or other nutritional oil at least partially encapsulated by wall material and incorporated within the composite flour, wherein polysaccharide from a portion of the native plant flour forms part of the wall material. The wall material includes protein, e.g., pea protein, polysaccharide released from the native plant flour, and emulsifier(s), and/or polysaccharide fiber, e.g., acacia fiber. The native plant flour may be gluten-flour, gluten-free flour and/or low carbohydrate seed, nut or vegetable flour. Composite flours can replace traditional flours to make food products, such as baked goods, fried goods, boiled goods, or uncooked goods, but with benefits, such as reduced gluten and/or carbohydrates, increased freshness and volume and improved texture and taste compared to alternative flours and even all-purpose flour. Composite flour can be blended with native flour and/or another composite flour to form blended flour.

A reconstituted reduced FODMAPS wheat gluten protein-based flour is disclosed for use in producing a food product suitable for consumption by a wheat intolerant consumer without development of associated defining symptoms of wheat intolerance The reduced FODMAPS wheat gluten protein-based flour includes as a constituent a proportion of wheat gluten protein recovered from a source wheat flour and additional constituents of types which have been recovered from wheat flour or other non-wheat source and which have been substantially depleted of FODMAPS content.

Composite plant-MCT flour includes MCT oil encapsulated by and/or complexed with wall material and incorporated within the composite plant-MCT flour, wherein polysaccharide from the plant flour forms part of the wall material. The wall material includes protein, e.g., pea protein, carbohydrate, and emulsifier(s), and/or polysaccharide fiber, e.g., acacia fiber. The plant flour may be gluten-flour, gluten-free flour and/or low carbohydrate seed, nut or vegetable floor. Composite plant-MCT flour can replace traditional flours to make food products, such as baked, fried or boiled goods but with benefits, such as reduced gluten and/or carbohydrates, increased freshness and volume and improved texture and taste compared to alternative flours and even all-purpose flour.

A method of preparing a functionalized wheat protein product is provided. The method comprises an enzyme treatment step wherein a wheat protein composition is contacted with a primary enzyme, and optionally with a secondary enzyme. The primary enzyme comprises a protease that is naturally occurring in a fruit.