In an embodiment, a process for producing a dough-substitute baking compound, comprises mixing, in a single vessel, a combination of almond flour, tapioca flour, coconut flour, garlic, and salt, thereby creating a dry combination. Mozzarella cheese is added to the dry combination to create a semi-dry mixture, and hot cooked cauliflower is mixed in to form a slurry. Olive oil, almond milk, salt, and garlic, are then added in to create a final dough, which is shaped and baked.

The invention relates to a closed continuous process to sterilise flour to reduce the enzymatic activity within the flour as well as to reduce microbial contamination of the flour and thereby minimise pasting of the starch and maintaining the flour in its native form. The invention also relates to the flour obtained by the method as well as the use of the flour.

Baking (e.g., pancake) mixes comprising at least one type of whole grain flour, at least one natural sweetener, at least one solid fat and a leavening system are provided herein. Packaged food products comprising single-serving containers containing said baking (e.g., pancake) mixes, as well as methods of preparing pancakes, are also provided. The baked goods (e.g., pancakes) described herein are preferably 100% whole grain and free from preservatives and/or artificial colorings.

The invention pertains to a soft-baked biscuit that is high in protein, and methods of making the same, that includes a protein component, a multi-textured mouth feel, and crispy inclusions contrasting with a moist and chewy matrix. The protein component may include a powdered protein source and a particulate protein source. The particulate protein source may be in the form of protein crisps, pops, tots, flakes, puffs, inclusions, pellets, bits, and/or particles. In some embodiments of the invention, the protein source includes a powdered protein source in an amount of about 35% by weight of the protein source to about 85% by weight protein powder and about 15% by weight to about 65% by weight particulate protein such as protein crisps. In another embodiment, the softbaked biscuit may include a protein component and a grain flour, wherein the flour is at least 4% by weight of the soft-baked biscuit. In still further embodiments of the invention, the soft-baked biscuits may be high in protein due to the inclusion of two protein sources while maintaining a low density of up to 0.92 g/cm.sup.3 and a water activity (Aw) of between about 0.5 and about 0.7.

The present invention relates to a composition for preparing low-gluten and low-carbohydrate baked and pastry goods, containing the following ingredients: a) flour, obtained from one or more nuts and/or oil seeds of non-legumes, b) mucilage polysaccharide-containing plant products or mucilage polysaccharides isolated from these plant products, c) protein component consisting of at least 40% animal protein in the dry weight. Such a composition contains a maximum of 0.1% gluten and is preferably gluten-free, i.e. has a gluten content less than 20 mg/kg (<20 ppm gluten content). Due to the low gluten and carbohydrate content of components a), b) and c), the composition according to the invention is suitable for producing low-gluten and in particular preferably gluten-free baked and pastry goods, having a low carbohydrate content of generally <15% relative to the food ready for consumption, and in particular for production of low-gluten, preferably gluten-free baked and pastry goods, which, relative to food ready for consumption, have the following nutrient profile: less than 10% carbohydrates, more than 10% protein, 1-40% fat.

A food product of the milk biscuit type mainly constituted of milk ingredients having organoleptic qualities, in particular crunchiness and puffiness, of a biscuit, where the milk biscuit includes 30 to 60% by weight of the total weight of the milk biscuit of proteins, of which at least 80% is of milk origin, 12 to 45% by weight of the total weight of the milk biscuit of mono- and/or disaccharides, of which at least 60% by weight of said mono- and/or disaccharides is lactose, 1 to 40% by weight of the total weight of the milk biscuit of lipids; and less than 6% by weight of the total weight of the milk biscuit of water.

A method for preparing bread dough includes providing a yeast mixture including active dry yeast, water, and sweetened condensed milk; providing a shortening mixture including vegetable shortening, water, salt, and sugar; heating the shortening mixture, such that substantially most of the vegetable shortening is melted; adding whole milk and room-temperature water to the shortening mixture; adding egg yolk to the shortening mixture; adding flour to the shortening mixture; combining the shortening mixture and the yeast mixture to form a combined mixture; adding flour to the combined mixture; and thoroughly mixing the combined mixture in order to distribute moisture evenly throughout the combined mixture.

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.

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 floor. 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.

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.