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 method for producing powderized cannabis oil, and the resulting powderized cannabis oil, in which concentrated cannabis oil is mixed with and absorbed by a modified starch powder, preferably maltodextrin, in a ratio of at least three grams of starch powder for every one-eighth of a gram of cannabis oil is disclosed. Further disclosed are beverages, baked goods and single-serve beverage brewing cartridges utilizing or incorporating the powderized cannabis oil to create human-consumable products that contain an emulsified, tasteless, and odorless dose of cannabis oil.

Food products prepared from whole grain oat flour having soluble components. The soluble whole oat flour maintains its standard of identity as whole grain and thus has the characteristics of whole grain oats. Aspects of the present invention relate to the use of the soluble oat flour in liquid food products such as beverages, semi-solid food products such as yogurt, and solid food products such as bakery items in order to provide enhanced health benefits.

A grain flour includes milled grains of at least one grain selected from the group consisting of barley and oat. In the grain flour, the average grain diameter is in the range of 40-100 m. The content of grains having a grain diameter less than 20 m is not greater than 20 mass %, the content of grains having a grain diameter in the range of 20-100 m is in the range of 20-60 mass %, the content of grains having a grain diameter greater than 100 m and not greater than 500 m is in the range of 20-60 mass %, and the content of grains having a grain diameter greater than 500 m is not greater than 5%. An application food using the grain flour is produced from a starting material which contains at least 5% of the grain flour. A method for producing the grain flour is also provided.

Embodiments of the disclosure can relate to dough products and method of making the same. In one example embodiment of the disclosure, a method for making a yeast-based dough product may include preparing a yeast broth by dispersing an amount of yeast into water and mixing the amount of yeast with water until a homogenized solution is reached; mixing the yeast broth with a pre-blend of dry ingredients to form a batter, and without allowing a resting period, baking the batter at an elevated temperature. The amount of yeast utilized may be determined based at least in part on achieving instantaneous gassing without a rise in batter volume when mixing the yeast broth with the pre-blend of dry ingredients.

Embodiments of the disclosure can relate to dough products and method of making the same. In one example embodiment of the disclosure, a method for making a yeast-based dough product may include preparing a yeast broth by dispersing an amount of yeast into water and mixing the amount of yeast with water until a homogenized solution is reached; mixing the yeast broth with a pre-blend of dry ingredients to form a batter, and without allowing a resting period, baking the batter at an elevated temperature. The amount of yeast utilized may be determined based at least in part on achieving instantaneous gassing without a rise in batter volume when mixing the yeast broth with the pre-blend of dry ingredients.

Methods of production of edible filamentous fungal biomat formulations are provided as standalone protein sources and/or protein ingredients in foodstuffs as well as a one-time use or repeated use self-contained biomat reactor comprising a container with at least one compartment and placed within the compartment(s), a feedstock, a fungal inoculum, a gas-permeable membrane, and optionally a liquid nutrient medium.

Methods of production of edible filamentous fungal biomat formulations are provided as standalone protein sources and/or protein ingredients in foodstuffs as well as a one-time use or repeated use self-contained biomat reactor comprising a container with at least one compartment and placed within the compartment(s), a feedstock, a fungal inoculum, a gas-permeable membrane, and optionally a liquid nutrient medium.

An acetic acid bacteria-containing composition comprising nonanal and methylheptenone, and having a peak area ratio of nonanal to methylheptenone (nonanal:methylheptenone), as determined by stir bar sorptive extraction thermal desorption gas chromatography-mass spectrometry (SBSE-GC/MS), of 1:10 to 100:1.

A method to produce a nutrient-dense and flavorful fermented shelf stable food product are described. The method comprises using defined fungal and bacterial strains in a solid-state fermentation process of legumes, grains and/or seeds. Following fermentation under specified environmental conditions, minimal downstream processing is performed to preserve the flavors generated via fermentation. This resulting product can be used to make nutritious, highly flavorful food products.