A cookie that provides a prebiotic effect and/or a probiotic effect to a consumer is described. The cookie fails to contain refined sugars, synthetic vitamins, genetically modified organisms (GMOs), artificial sweeteners, and artificial preservatives. The cookie comprises at least two baked food compositions formed into a biscuit. Each of the at least two baked food compositions contains a polyphenol, a resistant starch, and a prebiotic soluble fiber. A crème filing is sandwiched between the at least two baked food compositions. The crème filing comprises a resistant starch, a nut butter, a vegetable fat, and spores of a probiotic bacterium. Consumption of the cookie increases Lactobacillus bulgaricus and butyrate in the consumer.

The texture and flavor of bran and germ for the production of whole wheat flour and for the production of baked goods containing whole wheat flour is improved by treating bran and germ with water and an enzyme composition comprising xylanase, pentosanase, or mixtures thereof to hydrate the bran and germ and to enzymatically convert insoluble fiber of the bran and germ into soluble fiber and sugars. The enzymatic conversion is conducted so as to decrease the water holding capacity of the bran and germ and provides a bran and germ product having reduced grittiness and a reduced whole wheat flavor, while avoiding adverse effects on baking functionality. The enzymatic treatment with the xylanase and/or pentosanase may be initiated upon whole wheat berries or grains during tempering, or it may be initiated upon a separated bran and germ fraction obtained after grinding or milling of whole wheat berries or grains.

A viscoelastic composition includes a gel matrix comprising hydrated hydrocolloid gel and cross-linked protein, at least one gluten-free flour source, a starch, and a leavener. In some embodiments, the gel matrix imparts gluten-like properties to a gluten-free viscoelastic composition.

Gluten-free tortillas are made from a composition including a gluten-free flour mixture constituting from 50-60% of weight of the composition, with the gluten-free flour mixture consisting of a combination of rice or tapioca flour, oat flour and quinoa flour. In particular embodiments, the flour mixture includes substantially equal amounts of the rice or tapioca flour, oat flour and quinoa flour by weight of the composition. In addition, the composition includes an enzyme for structural integrity purposes. In embodiments utilizing rice flour in the tri-flour blend, the composition can also comprises about 8% by weight of tapioca starch. Further, the gluten-free tortilla may be soft flat tortilla or a soft shaped tortilla having a formed shape selected from a cup, bowl, U- or square bottomed shaped taco shell, boat, tube, envelope or cone.

Gluten-free tortillas are made from a composition including a gluten-free flour mixture constituting from 50-60% of weight of the composition, with the gluten-free flour mixture consisting of a combination of rice or tapioca flour, oat flour and quinoa flour. In particular embodiments, the flour mixture includes substantially equal amounts of the rice or tapioca flour, oat flour and quinoa flour by weight of the composition. In addition, the composition includes an enzyme for structural integrity purposes. In embodiments utilizing rice flour in the tri-flour blend, the composition can also comprises about 8% by weight of tapioca starch. Further, the gluten-free tortilla may be soft flat tortilla or a soft shaped tortilla having a formed shape selected from a cup, bowl, U- or square bottomed shaped taco shell, boat, tube, envelope or cone.

The present invention is directed to an extruded food product constituent composed of a gelling food product constituent extrudate and method of extruding a gelling food product constituent extrudate used as an ingredient of a food product normally using a gelling gum, like guar gum, xanthan gum or carrageenan as an ingredient. The gelling food product extrudate is composed of cold-water soluble gelling pregelatinized starch formed of starch in a starch-containing admixture modified by extrusion at extrusion pressures greater than 2000 PSI that gels when mixed with water, which preferably also modifies additional starch or starches in the admixture into a plurality of different molecular weight polymers of a cold-water soluble gellant that polymerize forming a gel when mixed with water, preferably forming a hydrocolloid gel, which more preferably is a self-gelling gel, which even more preferably is a thermo-reversible gel crosslinked by one or more proteins freed by or modified during extrusion. Preferred admixtures configured to produce gelling extrudates include admixtures composed of cereal grains, including sorghum, wheat, oats, barley and/or corn, and/or legumes, including chick pea, yellow pea, pea and/or lentils with legume containing admixtures producing gelling extrudates that form thicker gels whose viscosity increases over time that are well suited for use in non-dairy dairy substitutes like non-dairy butter, non-dairy creamers, non-dairy whipped cream, non-dairy yogurt, non-dairy cream cheese, non-dairy cheese, and non-dairy ice cream.

The present invention relates to technical means for producing a dried buckwheat noodle which is excellent in flavor and texture and can be produced stably. More specifically, the present invention provides: processed buckwheat flour, wherein a degree of pregelatinization of starch is 70% or more, and wherein, in gel filtration chromatography analysis of a water extract of the processed buckwheat flour, a proportion of a peak area (A) for a weight average molecular weight (Mw) of 10 to 5,000 with respect to the total peak area (A/total peak area×100) is 20% or more; a dried buckwheat noodle wherein the processed buckwheat flour is used as a raw material; and a method for producing the same.

A device for orienting wound dough products includes a first conveyor belt circulating with a first conveying speed and transporting a wound dough product having an end protruding from a circumference of the dough product. A second conveyor belt receives the wound dough product from the first conveyor belt and circulates with a second conveying speed which is different from the first conveying speed. The difference between the first conveying speed and the second conveying speed sets the wound dough product received from the first conveyor belt in a desired rolling motion on the second conveyor belt, wherein after the wound dough product has reached a defined end position in which the end of the wound dough product abuts on the second conveyor belt, the rolling motion of the wound dough product stops.

A device for orienting wound dough products includes a first conveyor belt circulating with a first conveying speed and transporting a wound dough product having an end protruding from a circumference of the dough product. A second conveyor belt receives the wound dough product from the first conveyor belt and circulates with a second conveying speed which is different from the first conveying speed. The difference between the first conveying speed and the second conveying speed sets the wound dough product received from the first conveyor belt in a desired rolling motion on the second conveyor belt, wherein after the wound dough product has reached a defined end position in which the end of the wound dough product abuts on the second conveyor belt, the rolling motion of the wound dough product stops.

A device for orienting wound dough products includes a first conveyor belt circulating with a first conveying speed and transporting a wound dough product having an end protruding from a circumference of the dough product. A second conveyor belt receives the wound dough product from the first conveyor belt and circulates with a second conveying speed which is different from the first conveying speed. The difference between the first conveying speed and the second conveying speed sets the wound dough product received from the first conveyor belt in a desired rolling motion on the second conveyor belt, wherein after the wound dough product has reached a defined end position in which the end of the wound dough product abuts on the second conveyor belt, the rolling motion of the wound dough product stops.