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.

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.

The present invention provides a high protein bakery product containing low amounts of sugar and wheat flour, which may be gluten-free if required. The bakery product is suitable to be cooked in a microwave. There is also provided a method of forming the bakery product.

The present invention provides a high protein bakery product containing low amounts of sugar and wheat flour, which may be gluten-free if required. The bakery product is suitable to be cooked in a microwave. There is also provided a method of forming the bakery product.

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.

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.

A shelf-stable ready-to-eat packaged focaccia, is described having appearance and organoleptic qualities comparable to those of a fresh focaccia, which has a relative humidity comprised between 25 and 32%, preferably 27% and water activity (a.sub.w) comprised between 0.85 and 0.92, preferably 0.89, and blind holes on its surface having depth of at least 50% of the thickness of the focaccia. A process for the production of a ready-to-eat shelf-stable packaged focaccia is also described which comprises the steps of: a) preparing a dough for focaccia comprising, by weight based on the total weight of the dough, 40-60% flour, 20-35% water, 7-16% vegetable oils and/or fats and/or fractions thereof, of which 1-6% extra virgin olive oil, 0.5-4% yeast, 0.1-3% salt, 0-15% at least one organoleptically characterising ingredient; 0-0.1% at least one baking processing aid, 0-0.8% at least one emulsifier and 0-1.5% dietary fibres; b) extrusion of the dough thus prepared thus obtaining a plurality of sheets of extruded raw dough for focaccia, and subsequent lamination of the plurality of sheets of raw dough for focaccia thus obtaining a layer of laminated raw dough for focaccia; c) first leavening of the layer of laminated raw dough for focaccia thus obtained at a temperature comprised between 20 and 30? C.; d) shaping of the layer of leavened raw dough for focaccia thus obtained forming a plurality of blind holes on the surface of the dough and filling of the holes with a saline solution; e) second leavening of the raw dough thus obtained at a temperature comprised between 30 and 37? C.; f) oiling of the upper surface of the dough thus obtained with filling with the oil of said holes; g) baking of the raw dough thus obtained in an oven at a temperature comprised between 210 and 240? C.; and h) packaging of the focaccia thus obtained.

The invention relates to a system and method for improvingly controlling the production of food products from granular raw materials such as for instance cereal rice formed into crackers. More in particular, the invention relates to an adjustable mechanical stop mechanism for better controlling the distance between the dies where pressure-baking of food occurs, and to provide the possibility of adjustable distance between the dies in case of multiple compressions of the food material, for which different die spacings can then be installed, leading to very repeatable and unchanging food processing conditions and thus an improved and much more constant quality of end product such as a cracker.

The invention relates to a system and method for improvingly controlling the production of food products from granular raw materials such as for instance cereal rice formed into crackers. More in particular, the invention relates to an adjustable mechanical stop mechanism for better controlling the distance between the dies where pressure-baking of food occurs, and to provide the possibility of adjustable distance between the dies in case of multiple compressions of the food material, for which different die spacings can then be installed, leading to very repeatable and unchanging food processing conditions and thus an improved and much more constant quality of end product such as a cracker.

Disclosed is a baked food which comprises a cereal flour, an oil or fat component, astaxanthin and optionally an emulsifying component, has such a structure that the oil or fat component containing the astaxanthin is held in voids in a structure formed by a starch of the cereal flour, and has a porosity of 10 to 70%. Specifically disclosed is a baked food produced from an astaxanthin-containing dough, which can stably hold astaxanthin therein for a long period.