The present invention provides muscle-derived progenitor cells that show long-term survival following transplantation into body tissues and which can augment non-soft tissue following introduction (e.g. via injection, transplantation, or implantation) into a site of non-soft tissue (e.g. bone). Also provided are methods of isolating muscle-derived progenitor cells, and methods of genetically modifying the cells for gene transfer therapy. The invention further provides methods of using compositions comprising muscle-derived progenitor cells for the augmentation and bulking of mammalian, including human, bone tissues in the treatment of various functional conditions, including osteoporosis, Paget's Disease, osteogenesis imperfecta, bone fracture, osteomalacia, decrease in bone trabecular strength, decrease in bone cortical strength and decrease in bone density with old age.

The present invention provides muscle-derived progenitor cells that show long-term survival following transplantation into body tissues and which can augment soft tissue following introduction (e.g. via injection, transplantation, or implantation) into a site of soft tissue. Also provided are methods of isolating muscle-derived progenitor cells, and methods of genetically modifying the cells for gene transfer therapy. The invention further provides methods of using compositions comprising muscle-derived progenitor cells for the augmentation and bulking of mammalian, including human, soft tissues in the treatment of various cosmetic or functional conditions, including malformation, injury, weakness, disease, or dysfunction. In particular, the present invention provides treatments and amelioration of symptoms for gastro-esophageal pathologies like gastro-esophageal reflux.

The present invention relates to generation of functional beta cells from human pluripotent stem cell-derived endocrine progenitors. The present invention also relates to functional beta cells produced by said methods and uses of said beta cells.

The method for tin vitro or ex vivo amplification of human adipose tissue stem cells includes: —extracting a stromal vascular fraction of a human adipose tissue including endothelial cells of the human adipose tissue vascular network and human adipose tissue stem cells, and an extracellular matrix of the human adipose tissue, the extracellular matrix including endothelial cells of the human adipose tissue vascular network, human adipose tissue stem cells and collagen; —mixing the stromal vascular fraction and the extracellular matrix; and—culturing the mixture obtained in the preceding step, in suspension, in a culture medium.

The disclosed technology includes methods, systems, and devices for generating patient-specific functional thymic epithelial progenitor (TEP) cells. In some implementations, a method may include generating iPSCs from HSC; causing differentiation of the iPSC into thymic epithelial progenitor (TEP) cells, generating thymic epithelial cells by transplantation of the TEP cells into a host, wherein the TEP cells may differentiate into mature functional thymic epithelial cells (TECs). In some implementations, a system may include a cell population of patient specific cells, a population of iPSCs, a culture system for differentiating the iPSCs into a population of patient-specific TEP cells for transfer to a host or the patient to allow the TEP cells to differentiate into mature, functional TEC.

The present disclosure provides methods and compositions for genetically modifying lymphocytes, for example T cells and/or NK cells, in shorter times than previously and/or in whole blood or a component thereof. In some embodiments a lymphodepletion filter assembly is used before or after forming a reaction mixture where lymphocytes are contacted with recombinant retroviral particles in a closed system, to genetically modify the lymphocytes.

Provided herein, in one aspect, is a population of retinal neurons including photoreceptors precursor cells (PRPCs) generated in vitro from human pluripotent stem cells (hPSCs) that can be used as a cell source for regenerative therapies, drug discovery and disease modeling. Methods and compositions for making and using the same are also provided.

Disclosed herein are methods for generating SC-β cells using chemically defined, completely serum free media, and isolated populations of SC-β cells for use in various applications, such as cell therapy.

Disclosed herein are methods for generating SC-β cells using chemically defined, completely serum free media, and isolated populations of SC-β cells for use in various applications, such as cell therapy.

Disclosed herein are methods for generating SC-β cells using chemically defined, completely serum free media, and isolated populations of SC-β cells for use in various applications, such as cell therapy.