Provided herein are methods for evaluating tumor cell spheroids in a three-dimensional microfluidic device by determining changes in the relative levels of live cells and dead cells in aliquots cultured under different conditions. Methods described herein allow ex vivo recapitulation of the tumor microenvironment such that the in vivo effectiveness of a test compound in treating tumor tissue may be predicted.

The present invention relates to a composition comprising at least one carrier comprising a polysaccharide, at least one antioxidant and at least one amino acid selected from cysteine, lysine, alanine and arginine. It also relates to the use of such a composition for the protection of microorganisms during drying, storage and/or reconstitution, to a culture powder, to a process of making the culture powder and to products comprising the culture powder.

The present invention relates to a composition comprising at least one carrier comprising a polysaccharide, at least one antioxidant and at least one amino acid selected from cysteine, lysine, alanine and arginine. It also relates to the use of such a composition for the protection of microorganisms during drying, storage and/or reconstitution, to a culture powder, to a process of making the culture powder and to products comprising the culture powder.

A nutrient-germinant composition to aid in spore germination and a method for increased spore germination efficiency. The composition comprises L-amino acids, D-glucose and/or D-fructose, a phosphate buffer, an industrial preservative, and may include bacteria spores or they may be separately combined for germination. The method comprises providing a nutrient-germinant composition and bacteria spores, preferably of one or more Bacillus species, and heating to a preferred elevated temperature range of 41° C. to 44° C. for an incubation period of around 2 to 60 minutes. The nutrient-germinant composition is preferably in a concentrated liquid form that is diluted just prior to initiating the germination/incubation method at the point of use. The method may also include dispensing a germinated spore solution to a point-of-use/consumption, such as animal feed, water, or bedding, or a wastewater system or drain.

A nutrient-germinant composition to aid in spore germination and a method for increased spore germination efficiency. The composition comprises L-amino acids, D-glucose and/or D-fructose, a phosphate buffer, an industrial preservative, and may include bacteria spores or they may be separately combined for germination. The method comprises providing a nutrient-germinant composition and bacteria spores, preferably of one or more Bacillus species, and heating to a preferred elevated temperature range of 41° C. to 44° C. for an incubation period of around 2 to 60 minutes. The nutrient-germinant composition is preferably in a concentrated liquid form that is diluted just prior to initiating the germination/incubation method at the point of use. The method may also include dispensing a germinated spore solution to a point-of-use/consumption, such as animal feed, water, or bedding, or a wastewater system or drain.

The present disclosure provides a method of producing a population of lyophilized cells, comprising: (a) freezing a composition comprising a population of cells, an aqueous component, a polyol, a sugar, and a polysaccharide; and (b) removing at least 90% of the aqueous component from the frozen composition to produce the population of lyophilized cells. On some embodiments, the disclosure provides a method of producing a population of reconstituted viable cells, comprising: (a) freezing a composition comprising a population of cells, an aqueous component, a polyol, a sugar, and a polysaccharide; (b) removing at least 90% of the aqueous component from the frozen composition to produce the population of lyophilized cells, and (c) resuspending the population of lyophilized cells in a reconstitution agent to form a reconstituted composition, wherein at least 1% of the cells are viable.

The subject invention provides standardized, high concentration inocula in solid form for use as seed cultures in scaled-up cultivation. Further embodiments include methods of producing standardized inocula, as well as methods of preserving and storing the inocula for convenient use over extended periods of time.

The subject invention provides standardized, high concentration inocula in solid form for use as seed cultures in scaled-up cultivation. Further embodiments include methods of producing standardized inocula, as well as methods of preserving and storing the inocula for convenient use over extended periods of time.

The present invention relates to microbial cells, including but not limited to aerobic bacteria cells and anaerobic bacteria cells, as well as yeast cells, and methods for producing the cells, feed additives and compositions comprising the cells, and uses involving administration of the cells to animals.

The present invention relates to microbial cells, including but not limited to aerobic bacteria cells and anaerobic bacteria cells, as well as yeast cells, and methods for producing the cells, feed additives and compositions comprising the cells, and uses involving administration of the cells to animals.