Engineered multilevel cell sheet-derived blood vessels and methods of preparing and using them are disclosed. Blood vessels are generated by wrapping cell sheets around a rod-like device, such as an angiocath needle, to form a tube, which is stabilized with a cyanoacrylate membrane or fibrin glue followed by endothelialization. Such engineered blood vessels can be implanted in tissue and used in vascular surgery as vascular bypass or interposition grafts as well as for vascularization and perfusion of tissue or organs prior to transplant.

A method of making a cardiac construct is carried out by depositing a mixture comprising live mammalian cardiac cells (e.g., individual cells, organoids, or spheroids), fibrinogen, gelatin, and water on a support to form an intermediate cardiac construct; optionally co-depositing a structural support material (e.g., polycaprolactone) with the mixture in a configuration that supports the intermediate construct; and then contacting thrombin to the construct in an amount effective to cross-link the fibrinogen and produce a cardiac construct comprised of live cardiac cells that together spontaneously beat in a fibrin hydrogel. Constructs made and methods of using the same are also described.

The purpose of the present invention is to provide a cardiac cell culture material which specifically acts on cardiac cells. In addition, another purpose of the present invention is to provide artificial organ material obtained by culturing by using said cardiac cell culture material, and a method for producing the same. Thus, provided is a cardiac cell culture, wherein functional cardiac tissue is favorably built by using a cardiac cell culture material containing VCAM-1.

Provided herein are stem cell and exosome compositions having therapeutic utility to treat a variety of diseases and disorders, e.g., cardiovascular disease, Duchenne muscular dystrophy, and fibrotic disease.

A method of making a cardiac construct is carried out by depositing a mixture comprising live mammalian cardiac cells (e.g., individual cells, organoids, or spheroids), fibrinogen, gelatin, and water on a support to form an intermediate cardiac construct; optionally co-depositing a structural support material (e.g., polycaprolactone) with the mixture in a configuration that supports the intermediate construct; and then contacting thrombin to the construct in an amount effective to cross-link the fibrinogen and produce a cardiac construct comprised of live cardiac cells that together spontaneously beat in a fibrin hydrogel. Constructs made and methods of using the same are also described.

In some embodiments, the present invention provides methods including the steps of providing one or more human somatic cells, causing transient increased expression of OCT4, KLF4, SOX2, and cMYC in the somatic cells forming modified somatic cells, providing a plurality of inactivated embryonic fibroblasts, associating the modified somatic cells with the inactivated embryonic fibroblasts in a culture media comprising 20% KO DMEM xeno-free serum replacement and at least 15 ng/ml recombinant bFGF to form human induced neural stem cells.

The present invention pertains to a method for culturing a cell population including pluripotent stem cells and differentiated cells derived from pluripotent stem cells at a temperature of 40.5 C. or higher and reducing the pluripotent stem cells included in the cell population. The present invention also pertains to a method for reducing pluripotent stem cells from a cell population including pluripotent stem cells and differentiated cells derived from pluripotent stem cells, wherein the method includes a step for activating the TRPV-1 expressed in the pluripotent stem cells included in the cell population. The present invention makes it possible to reduce the pluripotent stem cells remaining in an undifferentiated state when inducing the differentiation of a pluripotent stem cell population.

A method of generating a population of cells useful for treating a nerve disease or disorder in a subject, the method comprising up-regulating a level of at least one exogenous miRNA in mesenchymal stem cells (MSCs) and/or down-regulating a level of at least one miRNA using a polynucleotide agent that hybridizes to the miRNA, thereby generating the population of cells useful for treating the nerve disease or disorder. Isolated populations of cells with an astrocytic phenotype generated thereby and uses thereof are also provided.

Fresh human pancreas tissue can be used as a source of cells when to identify and select a non-stem cell population that is predisposed to be a source for surrogate pancreatic cells that can be used in treating insulin-dependent diabetes. The progenitors of these surrogate pancreatic cells have no reprogramming genes integrated into their genomes, differentiate to the pancreatic lineage pursuant to a protocol that employs only defined reagents, and are substantially unable to differentiate to the mesodermal lineage.

Several embodiments relate to methods of repairing and/or regenerating damaged or diseased tissue comprising administering to the damaged or diseased tissues compositions comprising exosomes. In several embodiments, the exosomes comprise one or more microRNA that result in alterations in gene or protein expression, which in turn result in improved cell or tissue viability and/or function.