The present application provides: a suppressor of pluripotent stem cell aggregation for use in suspension culture of pluripotent stem cells, comprising a cell cycle arresting agent; a method for producing a pluripotent stem cell aggregate(s), comprising a step of subjecting pluripotent stem cells to suspension culture in a culture medium comprising the suppressor; a pluripotent stem cell aggregate obtained by the method; and a composition for culture of pluripotent stem cells comprising a cell aggregate(s) of pluripotent stem cells, a culture medium, and a cell cycle arresting agent. According to the method, it is possible, in suspension culture of pluripotent stem cells, to produce a cell aggregate(s) with high cell viability and appropriate size in a high yield while maintaining the undifferentiated state of the cells and suppressing the aggregation.

A method for culturing primary cells from solid tumor tissues of lung cancer and primary tumor cells from pleural effusion of lung cancer, and the auxiliary reagents. A method for culturing primary cells from solid tumor tissues of lung cancer and primary tumor cells from pleural effusion of lung cancer and the auxiliary reagents. The core of the technology is as follows: (1) solid tumor of lung cancer are treated by using a mild cell dissociating reagent, and lung cancer cells in pleural effusion are dissociated by a mild method, ensuring the vitality of cancer cells to the greatest extent; (2) a special serum-free medium is prepared, and tumor cells derived from solid tumor tissues of lung cancer are cultured in vitro by using a suspension culture system, ensuring the normal amplification of the cancer cells while eliminating the interference of normal cells to the greatest extent.

Disclosed are methods of differentiating stem cells in order to obtain hepatocyte-like cells, the method comprising the steps of a) subjecting definitive endoderm to at least one epigenetic modulator to obtain hepatoblasts and b) subjecting the hepatoblasts to at least one stem cell differentiation pathway inhibitor to obtain hepatocyte-like cells; wherein steps a) and b) do not comprise the use of a growth factor. In one preferred embodiment, the epigenetic modulator may be sodium butyrate and/or DMSO and the stem cell differentiation pathway inhibitor may be SB431542 and/or DMSO. Also disclosed are hepatocyte-like cells obtained from the method and uses of these cells such as drug screening.

This application relates to non-human primate (NHP) induced pluripotent stem cell (IPSC)-derived hepatocytes, for example, Cynomolgus monkey (Macaca fascicularis) induced pluripotent stem cell-derived hepatocytes, and methods of producing the same. Moreover, this application relates to methods of using NHP IPSC-derived hepatocytes for drug screening, drug safety assessment and in models of infection.

Provided in the present invention is a cell freezing medium for clinical use. In particular, the cell freezing medium of the present invention comprises the following components: (1) human albumin; (2) cryoprotectant: the cryoprotectant comprises a combination of one or more of dimethyl sulfoxide, glycerol, and ethylene glycol; (3) a saline buffer; wherein the salt buffer is a solution containing Na.sup.+, K.sup.+, Mg.sup.+, Cl.sup.−, and CH.sub.3COO.sup.− ions; (4) a vitamin; and (5) an amino acid, wherein the human albumin concentration is 1%-20% (w/v). The cell, after long-term cryopreservation with the freezing medium of the present invention, has a high viability, and the cellular efficiency maintains a high uniformity. The grade of purity of the freezing medium of the present invention is the pharmaceutical grade or USP grade; and the freezing medium is safe and reliable for clinical use, and can be used or conventional adherent and suspension cells.

An object of the present invention is to provide human fatty-liver model cells showing symptoms of the hepatic tissue of fatty liver. The present invention relates to human fatty-liver model cells, which are produced by culturing human hepatocytes derived from fatty liver in a medium containing dimethyl sulfoxide.

The present disclosure provides a method of separating hematopoietic stem cells from umbilical cord blood, including the following steps: a hydroxyethyl starch solution is added into cord blood and mixed uniformly, then centrifuged to get an upper liquid layer and a lower erythrocyte layer; the liquid in the upper layer and the erythrocytes in the lower layer are centrifuged respectively; an upper plasma layer and a basal cell layer are obtained after the centrifugation of the upper liquid layer, the cells in the basal layer are resuspended; a superficial buffy-coat layer is obtained after the centrifugation of the erythrocytes, and the superficial buffy-coat layer is metered with the plasma in the upper layer, and then centrifuged to get a lower cell layer, which is precipitated to remove erythrocytes and then resuspended; the above resuspended cells are added into freezing medium, mixed uniformly and then stored in a liquid nitrogen tank.

An artificial antigen presenting cell system comprising one or more gelated human dendritic cells and a controlled release system capable of releasing one or more cytokines. Also provided herein are methods for producing the gelated human dendritic cells and uses of the artificial antigen presenting cell system for activating immune cells.

Described herein are compositions and methods to cryopreserve sporozoites. In some aspects, the method can include the step of placing harvested salivary glands containing sporozoites into an insect-based medium.

Provided are a medium composition for culturing animal cells for producing a recombinant extracellular matrix protein, a method of producing the recombinant extracellular matrix protein with high purity, and a method of assaying a monomer of the recombinant extracellular matrix protein.