Disclosed herein are human hepatocytes for example isolated human hepatic progenitor cells, artificial tissue or organ thereof, and kits or compositions thereof. Also disclosed herein are various methods of using a human hepatocyte disclosed herein.

Disclosed herein are organoids, or compositions thereof, produced through a process of aggregating gut endoderm monolayer and culturing the resultant gut endoderm aggregate. Examples of these aggregated organoids include but are not limited to aggregated liver organoids, aggregated gastric organoids, aggregated intestinal organoids, and aggregated colonic organoids.

Methods are provided for producing a population of hepatocyte-like cells (iHeps) from a population of adipocyte-derived stem cells (ASCs). Aspects of the methods include placing a population of ASCs into a three dimensional culture (e.g., hanging drop suspension culture, high density culture, spinner flask culture, microcarrier culture, etc.), and contacting the cells with a first and second culture medium. Also provided are methods of treating an individual, which include producing a population of iHeps from a population of ASCs, and administering an effective number of iHeps into the individual. Kits for practicing the methods are also described herein.

Methods are provided for producing a population of hepatocyte-like cells (iHeps) from a population of adipocyte-derived stem cells (ASCs). Aspects of the methods include placing a population of ASCs into a three dimensional culture (e.g., hanging drop suspension culture, high density culture, spinner flask culture, microcarrier culture, etc.), and contacting the cells with a first and second culture medium. Also provided are methods of treating an individual, which include producing a population of iHeps from a population of ASCs, and administering an effective number of iHeps into the individual. Kits for practicing the methods are also described herein.

Disclosed herein are human hepatocytes for example isolated human hepatic progenitor cells, artificial tissue or organ thereof, and kits or compositions thereof. Also disclosed herein are various methods of using a human hepatocyte disclosed herein.

This disclosure relates generally to new methods of maintaining the expression of hepatic genes in human hepatocytes and method for maintaining the functional hepatic enzyme activity of primary hepatocytes in culture. The disclosure also encompasses new methods of deriving a population of pure hepatocytes without selecting or sorting the cells from the cultured pluripotent cells.

Directed differentiation and maturation of mammalian hepatocytes, such as human hepatocytes. The hepatocyte obtained show a phenotype which is more similar to that of primary hepatocytes than previously shown. In particular, exposure of mammalian hepatocytes, such as human hepatocytes, to at least one maturation factor selected from the group consisting of Src kinase inhibitors, vitamin D including precursors, metabolites and analogs thereof, hypoxia inducing compounds, sphingosine and sphingosine derivatives, activators of peroxisome proliferator-activated receptors (PPARs), platelet-activating factor (PAF), PKC inhibitors, and combinations thereof.

The present disclosure concerns processes as well as additives for differentiating an endodermal cells into a posterior foregut cell, a posterior foregut cell into an hepatic progenitor cell and/or an hepatic progenitor cell into an hepatocyte-like cell. In some embodiments, the process can be conducted in the absence of serum. The hepatocyte-like cell population obtained from this process have a detectable Cyp3A4 activity and/or express a detectable level of albumin and/or of urea. The process can be designed to increase cellular yield.

Factors for extending the ability of isolated pluripotent stem cells to generate extraembryonic lineages in vivo, following in vitro culture, herein, chemical extenders of pluripotency (CEP). Methods of extending the ability of a pluripotent cell to generate embryonic and extraembryonic lineages. The cell to be reprogrammed is contacted with effective amounts of the CEPs for a sufficient period of time to reprogram the cell into a chemically induced extended pluripotent cell (ciEPSC). ciEPSC are identified as an extended pluripotent cell based on properties including: (i) morphologically and (ii) functionally for example, based on their ability contribute to both TE and ICM, in vivo. The ciEPSCs can be cultured or induced to differentiate into cells of a desired type, and used in a number of applications, including but not limited to cell therapy and tissue engineering.

Disclosed are digitized organoids comprising a detectable sensor, such as, for example, a Radio frequency identification (RFID) based sensor. Further disclosed are methods for making the digitized organoids. The disclosed methods allow for self-assembly mediated incorporation of ultracompact RFID sensors into organoids. Methods of using the digitized organoids are also disclosed.