Methods are provided for producing differentiated cells from stem cells, including producing hepatocytes. Compositions thereof are also provided, as are methods of treating a liver disorder.

The disclosure provides methods of treating a tissue, organ, organoid or organ culture, the method comprising treating a tissue, organ, organoid or organ culture in vitro with a composition comprising one or more cell turnover factors produced by cells exposed to a stress condition. The disclosure also provides methods of increasing regeneration of a tissue in an organ of a subject, the method comprising administering to the subject a composition comprising one or more cell turnover factors produced by cells exposed to a stress condition, wherein the composition is administered to the subject in an amount sufficient to increase regeneration of the tissue relative to a subject that is not treated with the composition.

Provided is a method of preparing a three-dimensional cell spheroid, the method including forming the cell spheroid by co-culturing adipose-derived stem cells or mesenchymal stem cells with hepatocytes. According to the cell spheroid prepared by the method, the secretome secreted by the adipose-derived stem cells affects hepatocyte maturation, and therefore, hepatic functions of the finally formed three-dimensional cell spheroid, i.e., organoid, may be enhanced. Further, a composition including a culture medium of the adipose-derived stem cells may prevent or treat liver diseases including hepatitis, hepatotoxicity, cholestasis, fatty liver, etc., and may enhance hepatic functions.

The present disclosure provides a method of deriving hepatic macrophages from stem cell-derived monocytes, through the use of hepatic macrophage culture medium comprising a hepatocyte conditioned medium and a basal medium, wherein the conditioned medium is obtained through culturing hepatocytes in a serum-free culture medium in the presence of an extracellular matrix. Also disclosed is a kit used for such a method and hepatic macrophages derived using the method and uses thereof.

The present invention provides a composition and method for organ perfusion and cell culture.

The present disclosure relates to a non-alcoholic fatty liver artificial tissue model. As compared to a conventional technology by which tissues are cultured only in Matrigel including a device composed of a decellularized liver tissue-derived extracellular matrix and a plurality of microchannels or a decellularized liver tissue-derived extracellular matrix, the present disclosure enables better mimicking of an actual non-alcoholic fatty liver disease due to the presence of Kupffer cells and hepatic stellate cells. Also, according to the present disclosure, the growth of liver organoids can be improved and fat accumulation and inflammation in the liver organoids can be caused to occur well through free fatty acid treatment, and the phenotypes of non-alcoholic fatty liver can be better expressed.

The present disclosure provides a method of deriving endothelial cells, comprising (a) culturing lateral plate mesoderm cells under oxygen-deprived condition to obtain endothelial lineage cells; and (b) culturing endothelial cells from (a) on an extracellular matrix to maintain and expand the endothelial lineage cells. Also disclosed herein is a cell co-culture system comprising an endothelial cell culture and a hepatocyte cell culture, as well as a microfluidic-based system comprising said cell co-culture system. Also disclosed herein is a method of disease modelling or drug testing using said cell co-culture system or said microfluidic-based system.

The present invention provides a co-culture system and method for assessing cellular cholesterol (Choi) efflux and uptake in vitro. The co-culture system mimics in vivo Choi efflux and uptake in the context of mammalian physiology. The methods and systems provided can be used in some embodiments to evaluate the effect of a pharmacological agent on cellular Choi efflux and uptake or for diagnostic purposes.

Engineered, living, three-dimensional liver tissue constructs including: one or more layers, wherein each layer contains one or more liver cell types, the one or more layers cohered to form a living, three-dimensional liver tissue construct free of pre-formed scaffold. Also disclosed are arrays and methods of making the same.

Disclosed is a process of manufacturing cell spheroids using a bioink. More particularly, provided is a method of manufacturing a cell spheroid, the method including extruding a first bioink including an alginate; extruding a second bioink including cells into the extruded first bioink; adding a calcium chloride (CaCl2) solution to the alginate included in the first bioink; and dissolving the second bioink, present in the first bioink, in a cell culture medium to form a cell spheroid from the cells.