Human pluripotent stem cells (hPSCs), especially induced pluripotent stem cells (iPSCs) provide a promising starting material to produce mimetic innate immune cells such as natural killer (NK) cells and ?? T-cells for cancer immunotherapy. To facilitate consistent mass production, an overall manufacturing scheme to make mimetic innate immune cells from hPSCs was designed and demonstrated. Particularly, a robust protocol to differentiate hPSCs into NK cells or ?? T-cells through sequential hematopoietic differentiation on stromal cell line deficient in expressing M-CSF and lymphoid commitment on stromal cell line deficient in expressing M-CSF ectopically expressing DLL1 without employing CD34+ cell enrichment and spin embryoid body formation is established. Using this two-stage protocol, the generation of functional mimetic NK cells and functional mimetic ?? NKT-cells was demonstrated from hPSCs, including hESCs, peripheral blood cell-derived iPSCs (PBC-iPSCs). non-T cell-derived iPSCs or ?? T cell-derived iPSCs and the use of these mimetic innate immune cells in killing cancer cells.

Embodiments are described that relate to methods and systems for growing cells in a hollow fiber bioreactor. In embodiments, the cells may be exposed to a number of growth factors including a combination of recombinant growth factors. In other embodiments, the cells may be grown in co-culture with other cells, e.g., hMSC's. In embodiments, the cells may include CD34+ cells.

The present invention relates to a method for obtaining extracellular vesicles derived from mesenchymal stromal cells (MSCs), wherein the extracellular-vesicles are essentially free of vesicles not derived from the MSCs, and wherein the extracellular-vesicles are essentially free of heparin. The invention further relates to the extracellular vesicles derived from mesenchymal stromal cells (MSCs), to a pharmaceutical composition comprising such extracellular-vesicles and to the use of the pharmaceutical composition in the treatment of (a) bone defect(s), tendon defect(s) and/or spinal cord injury. The pharmaceutical composition of the invention can further comprise one or more Bone Morphogenic Proteins (BMPs), such as BMP2.

A method is provided for producing a live cartilaginous material useful for implantation into a patient. A method of treating a patient comprising implanting a cartilaginous material prepared according to the provided method in an anatomical site in a patient also is provided.

Disclosed herein are cell preparations useful for modulating various peripheral immune functions, methods for making said cell preparations, and methods for their use.

The present invention relates to gene editing methods to engineer primary immune cells that are made resistant to proteasome inhibitors, such as Bortezomib, Carfilzomib, Ixazomib, Marizomib, Delanzomib or Oporozomib, for their use in cell immunotherapy in combination with proteasome inhibitor treatments.

Disclosed herein are quantitative assays for measuring the potential of a substance, or a source of a substance, to promote neurogenesis and gliogenesis. Substances that promote neurogenesis and gliogenesis are also disclosed.

A virus infection model which overcomes the drawbacks of conventional hepatitis virus infection models is provided.

A method for constructing a virus infection model capable of recapitulating a viral life cycle, comprising infecting a cell condensate formed by culturing a tissue or organ cell in vitro with a virus. A virus infection model capable of recapitulating a viral life cycle, comprising a virus-infected cell condensate, wherein the cell condensate is formed by culturing a tissue or organ cell in vitro. A method of screening for substances with antiviral activity, comprising using the virus infection model.

The present invention relates to a composition including stem cell-derived microvesicles as an active ingredient for promoting neurogenesis. The stem cell-derived microvesicles according to the present invention can promote neurogenesis and migration of nerves and also promote angiogenesis in vascular endothelial cells, and thus can be usefully used in treatment of neurological damage.

Various embodiments of the invention provide methods of treating diabetes and other glucose regulation disorders. In one embodiment, the method comprises removing L-cells from a donor, obtaining stem cells from a patient, and culturing the L-cells in the presence of the stem cells under conditions such that the stem cells differentiate into stem cell-derived L-cells (SCDLC). An amount of the SCDLC is introduced into the patient sufficient to cause a lowering of the patient's blood glucose level after ingestion of food. In another embodiment, the method comprises removing K-cells from a donor, obtaining stem cells from a patient, and culturing the K-cells in the presence of the stem cells under conditions such that the stem cells differentiate into stem cell-derived K-cells (SCDKC). An amount of the SCDKC is introduced into the patient sufficient to cause a lowering of the patient's blood glucose level after ingestion of food.