Methods for derivation, culture, and maturation of small hepatic progenitor cells are described.

Methods for derivation, culture, and maturation of small hepatic progenitor cells are described.

This invention provides compositions and methods for cryoprotection of recombinant live cancer cells. Specifically, an improved cryoprotective medium is provided which includes a hydroxyethyl starch and/or derivative thereof alone or in combination with either DMSO or glycerol.

This invention provides compositions and methods for cryoprotection of recombinant live cancer cells. Specifically, an improved cryoprotective medium is provided which includes a hydroxyethyl starch and/or derivative thereof alone or in combination with either DMSO or glycerol.

The present application provides methods of functionalizing an organ or tissue of a mammal by administering a nutrient (e.g., peracetylated N-azido galactosamine Ac4GalNAz) to the mammal or by culturing an organ or tissue in a bioreactor containing such nutrient. The present application also provides methods of selectively functionalizing extracellular matrix (ECM) of an organ or tissue of a mammal by administering a nutrient (e.g., peracetylated N-azido galactosamine Ac4GalNAz) to the mammal. In some aspects, the present application provides a decellularized scaffold of a mammalian organ or tissue comprising an extracellular matrix, wherein the extracellular matrix of the decellularized scaffold is functionalized with a chemical group that is reactive in a bioorthogonal chemical reaction, such as an azide chemical group. The present application also provides biological prosthetic mesh and mammalian organs and tissues for transplantation prepared according to the methods of the application.

The present application provides methods of functionalizing an organ or tissue of a mammal by administering a nutrient (e.g., peracetylated N-azido galactosamine Ac4GalNAz) to the mammal or by culturing an organ or tissue in a bioreactor containing such nutrient. The present application also provides methods of selectively functionalizing extracellular matrix (ECM) of an organ or tissue of a mammal by administering a nutrient (e.g., peracetylated N-azido galactosamine Ac4GalNAz) to the mammal. In some aspects, the present application provides a decellularized scaffold of a mammalian organ or tissue comprising an extracellular matrix, wherein the extracellular matrix of the decellularized scaffold is functionalized with a chemical group that is reactive in a bioorthogonal chemical reaction, such as an azide chemical group. The present application also provides biological prosthetic mesh and mammalian organs and tissues for transplantation prepared according to the methods of the application.

Provided is a composition and an application thereof. The composition is used to prepare a medium for inducing differentiation of human pluripotent stem cells to liver precursor cells. By means of screening active components, optimizing the composition ratio and adding a GSK3-beta inhibitor, a Nodal activator, a BMP activator, a BMP inhibitor and a Hedgehog activator, human pluripotent stem cells are induced to differentiate to liver precursor cells. The process is simple and efficient, the content of positive cells is high, and the cost of cell differentiation is reduced. The invention can be used for research and application in drug development and regenerative medicinal treatment, and has broad application prospects.

Disclosed are a novel pharmaceutical composition and use thereof, the novel pharmaceutical composition at least comprising an effective amount of mitochondria and at least one pharmaceutically acceptable carrier; the novel pharmaceutical composition is administered to an individual to send the mitochondria into injured or subject-to-oxidative-stress lung cells; thus treating or improving lung injury or related diseases thereof.

Disclosed are a novel pharmaceutical composition and use thereof, the novel pharmaceutical composition at least comprising an effective amount of mitochondria and at least one pharmaceutically acceptable carrier; the novel pharmaceutical composition is administered to an individual to send the mitochondria into injured or subject-to-oxidative-stress lung cells; thus treating or improving lung injury or related diseases thereof.

The present invention provides a technique that serves as a platform for inducing human organ cells at a low cost, stably and in a large quantity. A cell inducible after differentiating pluripotent stem cells and then passaging the resultant cells at least once or more times, which is negative for undifferentiated (pluripotent) cell markers NANOG, OCT4, MYC and LIN28A, negative for endoderm cell markers CXCR4, CER1, HHEX and GATA4, positive for intestinal endoderm cell markers CDX2 and HOXB9, negative for a mesenchymal cell marker brachyury (T), negative for a pancreatic cell marker PDX1, and capable of differentiating into at least a hepatocyte, a pancreatic cell and an intestinal cell. Also provided are methods of preparing and amplifying the above cells; a method of preparing organ cells using the above cells; and a method of constructing a working cell bank for preparing organ cells, comprising cryopreserving the above cells.