The present invention relates to a method for preparing a human intestinal epithelial model. The human intestinal epithelial model, prepared by the method according to the present invention, has all characteristics of goblet cells, enteroendocrine cells, and Paneth cells, and thus can highly mimic the function of actual human intestinal cells, so that the human intestinal epithelial model can be effectively used for development of new drugs, evaluation of drug absorption and toxicity, or evaluation of engraftment of intestinal microorganisms, or as a composition for in vivo transplantation.

An object of the present invention is to provide a culture medium for producing extracellular vesicles, a culture medium kit, an additive, and a method for producing extracellular vesicles, whereby the production of extracellular vesicles is promoted. The present invention is to provide a culture medium for producing extracellular vesicles. The culture medium for producing extracellular vesicles contains a basal medium for culturing animal cells, and at least one component selected from L-glutamine or a salt thereof, transferrin, selenious acid or a salt thereof, insulin, insulin-like growth factors, a serotonin compound, and transforming growth factor β. Furthermore, in a case of containing L-glutamine or a salt thereof, the culture medium for producing extracellular vesicles contains L-glutamine or a salt thereof with a concentration of 5 mM or more in the culture medium for producing extracellular vesicles. The present invention is to further provide a culture medium kit, an additive, and a method for producing extracellular vesicles.

Disclosed are constructs and methods to accelerate maturation of human pluripotent stem cell derived cardiomyocytes by maintaining them on a Cardiac Mimetic Matrix (CMM) substrate.

Human pluripotent stem cells are differentiated in vitro into oligodendro-spheroids comprising oligodendrocytes for use in analysis, screening programs, and the like.

It is a main object of the present invention to provide a new producing method capable of efficiently performing direct conversion or induction from a somatic cell to an insulin-producing cell. The present invention can include, for example, a process for producing an insulin-producing cell by direct differentiation induction from a somatic cell, comprising a step of culturing a somatic cell in a serum-free differentiation induction medium, or a step of culturing a somatic cell in a differentiation induction medium containing 5 μg/mL or more of insulin. According to the present invention, insulin-producing cells having a high insulin secretion ability can be produced directly and efficiently from a somatic cell. The insulin-producing cells obtained according to the present invention are useful in regenerative medicine and the like.

A cell/tissue culture system comprising at least one bioreactor configured to hold at least one type of cell to cultivate tissue, a dialysis unit comprising a dialysis membrane, a fresh medium unit, and a waste removal unit configured to remove metabolic waste from dialysate, wherein the metabolic waste comprises ammonia and lactate, and wherein the waste removal unit comprises biocatalysts or enzymes configured to breakdown lactate and generate carbon sources that promote cell growth.

An object of the present invention is to provide an endodermal cell population for obtaining optimal somatic cells as cell therapy preparations. The endodermal cell population of the present invention has a reduced content proportion of undifferentiated cells in the cell population and contains endodermal cells differentiable into optimal somatic cells as cell therapy preparations. Further, a somatic cell derived from the endodermal cell population of the present invention has excellent therapeutic effects as a cell therapy preparation.

The present invention addresses the problem of providing: a culture medium that is for adherent culturing of pluripotent stem cells exhibiting high growth ability and that does not contain serum or albumin; and a highly versatile method for adherent culturing of pluripotent stem cells using the culture medium. According to the present invention, by adding, to a culture medium, a hydrophilic polymer that is conventionally known to inhibit adhesion of cells to the surface of a cell culture base material, so that the adhesion of pluripotent stem cell to the surface of the cell culture base material is enhanced, high growth ability is imparted in adherent culturing of pluripotent stem cells without adding serum or albumin thereto. In addition, by adding an antioxidant substance along with such a polymer to a culture medium, very high growth ability is imparted in adherent culturing of pluripotent stem cells.

This disclosure relates to methods of preserving cells for space exploration, methods of culturing cells, and cell growth media. In certain embodiments, methods comprise contacting cells, such as stem cells, induced pluripotent cells, progenitor cells, and cardiac associated cells, with a cell growth medium disclosed herein providing replicated cells. In certain embodiments, methods comprise preserving and culturing cells in outer space comprising; a) freezing cells providing frozen cells; b) transporting the frozen cells to outer space; c) thawing the cells providing thawed cells; and d) culturing the thawed cells with a growth medium disclosed herein.

The subject invention concerns materials and methods for expansion of stem cells, such as mesenchymal stem cells (MSC), that improve translational success of the cells in the treatment of various conditions. The subject invention utilizes cell self-aggregation as a non-genetic means to enhance their therapeutic potency in a microcarrier bioreactor. In one embodiment of the method cells are cultured in a container or vessel in the presence of thermally responsive microcarriers (TRMs) wherein cells adhere to the surface of the TRMs. After a period of time the cell culture temperature is reduced so that the cells detach from the TRMs. The detached cells are allowed to form 3D aggregates. The 3D aggregates can be collected and treated to dissociate the cells. Dissociated cells can then be used for transplantation in methods of treatment or for in vitro characterization and study.