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.

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.

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.

Disclosed is a method for the manufacturing of pasta filata cheese, wherein skim milk is first supplied to a transport system having a plurality of separate transport containers, wherein curd is produced from the skim milk in the region of a first process section of the transport system, by the addition of acidification cultures; wherein the curd produced is coagulated in the region of a second process section, wherein the coagulated curd is exposed to an acidification process for an acidification period in the region of a third process section; and wherein the acidified curd is removed from the transport system in an outgoing section at the end of the acidification period and is supplied to a subsequent process step in which the acidified curd is divided into portions. The curd remains in the transport system up to the removal of the curd after the end of the acidification process.

The present invention discloses a novel probiotic fermented beverage based on whey, comprising whey and a high probiotic microorganism concentration in the range of 10.sup.7-10.sup.8 CFU/mL, and a method for producing said beverage. The probiotic microorganism is a commercial yogurt culture of Streptococcus salivarus subsp. thermophilus and Lactobacillus delbruecki subsp. bulgaricus and a commercial culture of Lactobacillus acidophilus. The method for producing the probiotic fermented whey based beverage comprises recovering whey by an enzymatic coagulation process, percolation, enriching and pasteurizing whey, fermentation, sweeting and flavoring. The beverage comprises the following physico-chemical characteristics: pH 5.00.00; titratable acidity 68.01.4 mL NaOH 0.1N/100 mL; total solids 12.40.1% w/v; fat 0.80.1% w/v; protein 10.1% w/v; cinder 0.550.02% w/v; Total sugar 10.00.2% w/v; Reducing sugar 4.200.15% w/v; and Energic value 87.20.00 cal/100 g sample. The beverage comprises the following physico-chemical characteristics and probiotics count at 4 C. and 8 C.: 1-21 day shelf-life; pH 4.77-4.85; titratable acidity 72-73 mL NaOH 0.1N/100 mL; and probiotic count of about 3110.sup.7-3910.sup.7 CFU/mL.

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.

Provided in the present disclosure are a milk coagulant, a method for obtaining asclepain of Asclepias Linn. and cysteine protease B of Calotropis R. Br., as well as a method of producing cheese. The milk coagulant includes at least one of the asclepain of Asclepias Linn. and the cysteine protease B of Calotropis R. Br.

A low-mineral quark matrix is suggested, which is obtainable by (a) subjecting raw milk to heat treatment, separating the cream, (b) subjecting the skimmed milk such obtained to an ultrafiltration step and/or a reverse osmosis step, producing a retentate R1, which represents a dairy protein concentrate, and a permeate P1, (c) subjecting the permeate P1 to an electrodialysis step, producing a salt-depleted diluate D1, (d) combining the diluate D1 with the retentate R1, (e) subjecting the combination product such obtained to heat treatment until denaturation sets in, (f) fermenting the denaturation product such obtained by the addition of starter cultures and rennet, and (g) adjusting or standardising the fermentation product such obtained to defined dry matter and protein contents.