A method of producing helper T cells, comprising: (i) culturing T cells, which have been induced from pluripotent stem cells and into which a CD4 gene or a gene product thereof has been introduced, in a medium containing IL-2 and IL-15; and (ii) isolating CD40L-highly expressing T cells from cells obtained in step (i).

A pharmaceutical includes helper T cells induced from pluripotent stem cells. The helper T cells include CD4-positive CD40L-highly expressing T cells, dendritic cells, antigen, and cytotoxic T cells CD8-positive T cells. The pharmaceutical can be administered in a method for treating cancer to a patient having cancer cells expressing an antigen specifically recognized by CD4-positive T cells.

Provided herein are genetically engineered mammalian stem and progenitor cells that have increased potential to differentiate into regulatory T cells. Also provided are methods of making and use thereof.

The present invention discloses formulation of a serum-free medium used for human pluripotent stem cells, which comprises the following raw materials: inorganic salt components, organic components, amino acids and amino acid salts, energy substances and metabolic intermediates, vitamins and antioxidants, proteins and polypeptides, trace elements and chromogenic substances; while the culture process comprises the following steps: selecting a basic formulation, performing combination screening, identifying and evaluating results, and testing a new formulation of culture; and proportioning according to the following methods: adding aforesaid raw materials into 950 ml of water for injection, stirring gently until dissolved, and finally adding 2.438 g of sodium bicarbonate, and stirring gently until dissolved, and then adding 1 liter of water for injection, adjusting the pH to the desired value with 1 mol/L sodium hydroxide solution or 1 mol/L hydrochloric acid solution, finally filtering sterilized with 0.1 μm diameter filter under positive pressure, and storing the medium solution in dark place at 2° C.-8° C., the invention solves the problem of high cost of domestic import of serum-free formulation.

A technology of 3D printing integration of hard materials and cells, a preparation of bone-repair functional module with osteogenic microenvironment, bone organoid method and the application of quick repair of bone defects are provided. A preparation method of biological microenvironmental factors as independent osteogenic factors is further provided. The present integrated 3D printing technology realizes 3D printing of cells and hard materials synchronously by adjusting the temperature, so as to build a real sense of biomimetic bone tissue, which can be customized according to the specific defects and clinical needs of patients. In the present bone-repair functional module, the cells have high survival rate and proliferation activity on the surface of hard materials, and realize osteogenic differentiation and mineralization; after implantation, it has the dual metabolic functions of bone formation and bone resorption, promoting vascular and neurogenesis, improving elastic modulus and reducing stress shielding.

The present disclosure provides use of neurokinin 1 receptor (NK1R) as a marker for identifying and/or isolating multipotential cells. The present disclosure provides cell populations enriched by methods of the present disclosure and therapeutic uses of these cells and agents derived from these cells.

There is described herein a method of enriching a population of stem cells for hematopoietic progenitors. The method comprises inducing hematopoietic differentiation in a population of human embryonic stem cells or human induced pluripotent stem cells; sorting the population based on expression of CD43 and at least one of CD34, CD31 and CD144; and selecting a fraction that is at least one of CD34+CD43−, CD31+CD43− and CD144+CD43−. Also provided are populations of hematopoietic progenitors obtained by the methods described herein.

Disclosed are bone marrow stromal cell derived extracellular matrix protein extracts that are useful for the expansion and proliferation of mesenchymal stem cells and for various therapeutic applications.

Disclosed are means, methods and compositions of matter useful for induction of immunological responses towards tumor endothelial cells. In one embodiment the invention teaches fusion of dendritic cells and cells resembling tumor endothelial cells and administration of such chimeric cells as an immunotherapy for stimulation of tumor endothelial cell destruction. In other embodiments pluripotent stem cells are utilized to generate dendritic cells, wherein said dendritic cells are fused with pluripotent stem cell derived endothelial cells created in a manner to resemble tumor endothelial cells.

Methods for obtaining multipotent Apelin receptor-positive lateral plate mesoderm cells, mesenchymal stem cells, and mesangioblasts under serum-free conditions are disclosed.