A confectionary mix may include: 20 to 60 mass % of a rice flour containing 40 mass % or more of a brown rice flour; and 10 to 50 mass % of a processed starch. The processed starch may be one or more of a crosslinked starch, an etherified crosslinked starch, and an acetylated starch. A method for producing a confectionary may include preparing a dough using the confectionary mix.

Systems and methods describe improvements in the automated production of meat analogues. Ingredients are provided, including oil, water, binding agent(s), and one or more forms of protein to be separately and continuously conveyed through a facility. Concurrently to the ingredients being conveyed through the facility, a number of actions occur. The system emulsifies the oil, water, and binding agent(s) within an emulsifying machine to form a final emulsion. A hydration process is separately applied to at least one of the forms of protein. The system mixes and conveys the protein(s) with the final emulsion in a final mixer to form a final dough.

This invention relates to kits including novel oral food challenge meal formulations. In particular, the invention also relates to kits including novel oral food challenge meal formulations, wherein the placebo dose formulation is indistinguishable from non-placebo dose formulations.

Provided herein are compositions and methods to make and use engineered cells, for the purpose of increasing the cell density of a culture comprising metazoan cells and for the production of a cultured edible product.

A fat-containing composition obtained by converting insects or worms into nutrient streams, such as a fat-containing, an aqueous protein-containing and a solid-containing fraction, including (a) squashing insects or worms thereby obtaining a pulp, the insects or worms reduced in size, (b) heating the pulp to 70-100° C., and (c) subjecting the heated pulp to a physical separation step with the proviso that the method does not contain enzymatic treatment of the pulp. The fat-containing fraction contains at least 80 wt. % insect or worm fat with at least 40 wt. % saturated fats. The aqueous protein fraction can be dried to obtain dried protein material, which contains at least 50 wt. % insect or worm protein-derived matter and at most 25 wt. % insect or worm fat based on dry weight. The protein has a pepsin digestibility of at least 50%. The resulting nutrient streams can be used in food, petfood, feed and pharmaceutical industry.

A fat-containing composition obtained by converting insects or worms into nutrient streams, such as a fat-containing, an aqueous protein-containing and a solid-containing fraction, including (a) squashing insects or worms thereby obtaining a pulp, the insects or worms reduced in size, (b) heating the pulp to 70-100° C., and (c) subjecting the heated pulp to a physical separation step with the proviso that the method does not contain enzymatic treatment of the pulp. The fat-containing fraction contains at least 80 wt. % insect or worm fat with at least 40 wt. % saturated fats. The aqueous protein fraction can be dried to obtain dried protein material, which contains at least 50 wt. % insect or worm protein-derived matter and at most 25 wt. % insect or worm fat based on dry weight. The protein has a pepsin digestibility of at least 50%. The resulting nutrient streams can be used in food, petfood, feed and pharmaceutical industry.

A method including mixing a paste of oily seeds and water to produce a pre-mix; and microfluidizing at least the paste or premix at a pressure of at least 5,000 PSI. Examples of oily seeds include but are not limited to sesame seeds and olives. Products produced by the method constitute additional embodiments of the invention.

Methods for culturing filamentous fungi, in which the filamentous fungi are grown in a colloid of air and a fermentation medium, are provided. The methods result in more rapid and prolific growth of the filamentous fungus than has been achieved by previous methods. Biomats produced by the methods and air-medium colloids for use in the methods are also provided.

Methods for culturing filamentous fungi, in which the filamentous fungi are grown in a colloid of air and a fermentation medium, are provided. The methods result in more rapid and prolific growth of the filamentous fungus than has been achieved by previous methods. Biomats produced by the methods and air-medium colloids for use in the methods are also provided.

The invention relates to a process for preparing a pea extract comprising fibres, the process comprising the following steps: (a) bringing shelled peas into contact with an aqueous solution in order to form an aqueous composition comprising peas; (b) leaving the peas to hydrate in said aqueous composition for at least 30 minutes and at most 15 hours; (c) grinding said peas in order to as a result obtain ground peas; and (d) fractionating said ground peas in order to obtain at least one pea extract comprising fibres.

The invention also relates to a pea extract that can be obtained according to the process of the invention. The invention also relates to an edible composition comprising the pea extract according to the invention.