An isolated biological stem cell or a set of biological stem cells that include human mesenchymal stem cell line 120816CT, deposited under ATCC Accession number PTA-124321, and differentiated into at least one type of cell selected from the group: neural stem cells, nephron progenitor cells, cardiomyocytes, neurons, glial cells, and vascular endothelial cells. The neurons comprise cholinergic neurons or dopaminergic neurons. A method of treating at least one human physical condition is also disclosed. The method includes injecting a patient with stem cell line 120816 CT to treat osteoarthritis, tendonitis, herniated disc, ligament damage, acute and chronic kidney disease and injury, Parkinson's disease, traumatic brain injury, Alzheimer's disease, amyotrophic lateral sclerosis, spinal cord injury, other skeletal muscular disorders, Lupus erythematosus, multiple sclerosis, cardiovascular disease, Graft-versus host disease, liver dysfunction or diseases, Type 1 and Type 2 diabetes, myocardial ischemia, heart failure, coronary artery disease, and other disorders characterized by inflammation.

The present invention relates to methods for making in vitro retinal cultures, tissue, or retinal organoids, from pluripotent cells as well as the improved synthetic retinal tissue and retinal organoids themselves. It also relates to retinal organoids that replicate in vitro many characteristics of the retina (e.g., human or mammalian), and methods of using this retinal organoid to study disease and to identify therapeutic agents for the treatment of retinal diseases and disorders.

Methods of producing stem cell conditioned media to treat mammalian injuries or insults. In at least one embodiment of a method for isolating non-endothelial adipocyte-depleted stromal cells of the present disclosure, the method comprises, comprising dissociating subcutaneous adipose tissue isolated from a mammal into a cell suspension, removing adipocytes from said cell suspension, resulting in a non-endothelial adipocyte-depleted cell suspension, and culturing the non-endothelial adipocyte-depleted cell suspension in a media containing growth factors VEGF, bFGF, EGF, and IGF, such that a mixed population of cells comprising a first population of further differentiated non-endothelial adipocyte-depleted CD34+/VE-cadherin− cells and a second population of further differentiated non-endothelial adipocyte-depleted CD34+/VE-cadherin+ cells are obtained and expanded.

The invention provides a method of producing a synthetic retina, comprising: i) providing a three dimensional stem cell culture throughout the differentiation time course, ii) differentiating the three dimensional stem cell culture for a first time period in a first neural cell culture medium comprising: a) L-glutamine; b) B27 supplement; and c) an IGF-1 receptor agonist, iii) subsequently differentiating the three dimensional stem cell culture for a second time period in a second neural cell culture medium comprising: a) L-glutamine; b) B27 supplement; c) N2 supplement; and d) an IGF-1 receptor agonist, wherein said synthetic retina contains laminated retinal tissue comprising.

Compositions and methods for the treatment of leukodystrophy, particularly, H-ABC are disclosed.

The present disclosure relates to methods for producing dopaminergic cells and evaluating their functionality. When pluripotent human embryonic stem cells are cultured on plates coated with laminin-111, laminin-121, laminin-521, laminin-421, or laminin-511 in cell culture medium containing a GSK3 inhibitor and a TGF-β inhibitor as well as timely administered fibroblast growth factor, desired neural cells are produced at far higher rates. Useful cell culture kits for producing such dopaminergic cells are also described herein, as are methods of using such cells for stem cell therapy.

The present invention provides methods and uses of neural cells differentiated from adult stem cells of the oral mucosa for cell therapy of neurological and psychiatric diseases and disorders. Methods for direction of differentiation of oral mucosal stem cells into neuronal or neuron supporting cells are also provided.

Methods and compositions are provided for the treatment of a mitochondrial disease in an individual with the mitochondrial disease. Aspects of the methods include administering an inhibitor of a Pumilio-like protein and/or an inhibitor of a serine/arginine-rich family of pre-mRNA splicing factor (SR) protein to a subject. Also provided are methods, compositions, systems and kits for transdifferentiating target cells to neurons, which find use in producing neurons for the development of new therapies, for experimental evaluation, as a source of lineage- and cell-specific products, and the like, for example, for use in treating human disorders of the CNS.

The present invention provides methods of transdifferentiation of somatic cells, for example, directly converting a somatic cell of a first cell type, e.g., a fibroblast into a somatic cell of a second cell type, are described herein. In particular, the present invention generally relates to methods for converting a somatic cell, e.g., a fibroblast into a motor neuron, e.g., an induced motor neuron (iMN) with characteristics of a typical motor neuron. The present invention also relates to an isolated population comprising induced motor neurons (iMNs), compositions and their use in the treatment of motor neuron diseases such as ALS and SMA. In particular, the present invention relates to direct conversion of a somatic cell to an induced motor neuron (iMN) having motor neuron characteristics by increasing the protein expression of at least three motor-neuron inducing (MN-inducing) factors selected from Lhx3, Ascl1, Brn2, Myt1l, Isl1, Hb9, Ngn2 or NeuroD1 in a somatic cell, e.g., a fibroblast to convert the fibroblast to an induced motor neuron (iMN) which exhibits at least two characteristics of an endogenous motor neuron.

The present invention relates to a method for producing cholinergic neurons comprising obtaining neural progenitor cells from stem cells so as to continuously produce cholinergic neural cells with high purity and the same traits, followed by differentiating the neural progenitor cells into the cholinergic neurons, and cholinergic neurons produced therefrom. Since the method of preparing the cholinergic neurons provided in the present invention enables not only production of the cholinergic neurons with high purity, but also rapid production of the cholinergic neurons with the same traits, it can be widely used for effectively treating degenerative cranial nerve diseases such as Alzheimer's disease.