The present invention includes methods for effecting phenotype conversion in a cell by transfecting the cell with phenotype-converting nucleic acid. Expression of the nucleic acids results in a phenotype conversion in the transfected cell. Preferably the phenotype-converting nucleic acid is a transcriptome, and more preferably an mRNA transcriptome.

The disclosure generally relates to methods and compositions for preparing a neural tissue construct. In particular, provided herein are methods for generating a neural tissue construct using glutamatergic cortical progenitor cells; GABAergic interneuron progenitor cells; and bio-ink.

A method of generating neural stem cells or motor neurons is disclosed, the method comprising up-regulating a level of at least one exogenous miRNA and/or down-regulating at least one miRNA using an agent which hybridizes to the miRNA in mesenchymal stem cells (MSCs) or down-regulating Related to testis-specific, vespid and pathogenesis protein 1 (RTVP-1).

The present invention provides a method for producing astrocytes from neural progenitor cells, the method comprising: (1) culturing neural progenitor cells in a culture medium comprising a neurotrophic factor; (2) dissociating the cells obtained in the step (1); and (3) subjecting the cells obtained in the step (2) to adherent culture in a culture medium comprising a neurotrophic factor using an uncoated culture vessel.

Described are oxysterols, pharmaceutical compositions including the oxysterols, and methods of using the oxysterols and compositions for treating diseases and/or disorders related to myelin injury, such as neonatal brain injury, traumatic brain injury, spinal cord injury, cerebral palsy, seizures, cognitive delay, multiple sclerosis, stroke, autism, leukodystrophy, schizophrenia and bipolar disorder.

Provided are methods and compositions from reprogramming human glial cells into human neurons. The reprogramming is achieved using combinations of compounds that can modify signaling via Transforming growth factor beta (TGF-β), Bone morphogenetic protein (BMP), glycogen synthase kinase 3 (GSK-3), and γ-secretase/Notch pathways. The reprogramming is demonstrated using groups of three or four compounds that are chosen from the group thiazovivin, LDN193189, SB431542, TTNPB, CHIR99021, DAPT, VPA, SAG, purmorphamine. Reprogramming is demonstrated using the group of LDN193189/CHIR99021/DAPT, the group of B431542/CHIR99021/DAPT, the group of LDN193189/DAPT/SB431542, the group of LDN193189/CHIR99021/SB431542, a three drug combination of SB431542/CHIR99021/DAPT. Reprogramming using functional analogs of the compounds is also provided, as are pharmaceutical formulations that contain the drug combinations.

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 present invention provides a method for producing a human cell aggregate containing a midbrain-hindbrain boundary neural progenitor tissue, including subjecting an aggregate of human pluripotent stem cells to suspension culturing in a serum-free medium containing insulin, and treating, in the suspension culturing, the aggregate of human pluripotent stem cells or a human cell aggregate derived therefrom with a ROCK inhibitor, a TGFβ signal inhibitor, and a first fibroblast growth factor. Furthermore, the human cell aggregate containing the midbrain-hindbrain boundary neural progenitor tissue is subjected to suspension culturing in a serum-free medium to induce formation of a neuroepithelial structure by neural progenitor in the neural progenitor tissue, whereby the human cell aggregate containing the cerebellar plate tissue can be obtained.

A method of producing induced pluripotent stem cells including a step for introducing an initialization factor into somatic cells of a mammal, and culturing in a neural stem cell culture medium to obtain induced neural stem cell-like cells, and a step for cultivating said induced neural stem cell-like cells in a growth medium to obtain induced pluripotent stem cells, wherein the initialization factor contains an OCT family, a SOX family, a KLF family, a MYC family, a LIN28 family and a P53 function inhibitor.

The disclosure relates to growing cells, directing cells to grow into specified cell types, genetically and physically manipulating cells, and addressing one or more individual cells within a mixed cell population. Aspects of the disclosure relate to vectors useful to induce developmental changes in cells, in which those vectors have a temporal component. Vectors of the disclosure encode a controllable, temporal series of events. Once the vectors are delivered into target cells, a series of discrete and different genetic events may be induced. The disclosed methods generally provide for the temporal encoding of multiplex genetic effectors in vector format for cell state transitions.