The presently disclosed subject matter provides hydrogel precursor compositions (e.g., solutions) for forming three-dimensional hydrogels that support growth of physiologically relevant tissue when at least one cell is cultured in the three-dimensional hydrogel, kits comprising the hydrogel precursor composition, three-dimensional hydrogels, methods of forming the three-dimensional hydrogels, methods of growing the physiologically relevant tissue using the three-dimensional hydrogels, physiologically relevant tissue grown in the three-dimensional hydrogels, methods of producing hormone-responsive tissue (e.g., milk-producing mammary tissue and related methods of producing milk), methods of screening for candidate agents useful for modulating hormonal responses (e.g., modulating milk production), method of screening for candidate therapeutic agents using the physiologically relevant tissue grown in the three-dimensional hydrogels (e.g., personalized cancer treatments), and related methods of treatment (e.g., administering agents identified using the methods herein, transplanting physiologically relevant tissue produced using the methods, etc.).

The present invention relates to culture systems comprising differentiated stem cells, that may be used for identifying agents useful in treating degenerative nervous system disorders and are suitable for high-throughput screening applications. It is based, at least in part, on the discovery that co-cultures of (i) astrocytes expressing a mutated SODI gene and (ii) stem-cell derived motor neurons manifested cell death via a Bax-dependent mechanism, and modeled motor neuron death in amyotrophic lateral sclerosis.

The presently disclosed subject matter relates to the generation of induced pluripotent stem cell (iPSC)-derived neuronal cell lines from subjects diagnosed with polyhydramnios-megalencephaly-symptomatic-epilepsy (PMSE) and assays making use of such cell lines to identify mammalian target of rapamycin (mTOR) signalling modulators as well as anti-epileptogenic compounds.

This document relates to decellularized nerve allografts. For example, decellularized nerve allografts and methods and materials for using decellularized nerve allografts to repair nerve injuries or bridge a severed nerve are provided.

Methods and compositions for somatic cell proliferation as well as increasing viability of somatic cells are provided. The compositions include heparin binding protein isolated from a medium conditioned by growth of pluripotent stem cells, such as, human embryonic stem cells, human embryonic carcinoma cells. The methods include contacting a somatic cell with a heparin binding protein composition for a sufficient period of time to provide for enhanced proliferation and/or viability of the somatic cell as compared to the absence of the heparin binding protein composition.

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.

In related-art methods of differentiating pluripotent stem cells into a desired cell type, there has not been established a differentiation induction method using human ES/iPS cells and being highly efficient. Many attempts have been made, including a stepwise differentiation induction method based on the control of culture conditions or the addition of, for example, various cell growth factors/differentiation factors to a culture solution, but the use of complicated culture steps is a big problem. A method of inducing differentiation into a desired cell type within a short period of time and with high efficiency by use of a pluripotent stem cell that actively undergoes cell differentiation, which is obtained by reducing an undifferentiated state of the pluripotent stem cell, has been developed, and thus the present invention has been completed.

Methods for Generating Neural Crest-Like Cells and Nociceptor-Like Cells from Human Pluripotent Stem Cells are Provided Along with the Related Compositions.

Compositions are described for direct protein delivery into multiple cell types in the mammalian inner ear. The compositions are used to deliver protein(s) (such as gene editing factors) editing of genetic mutations associated with deafness or associated disorders thereof. The delivery of genome editing proteins for gene editing and correction of genetic mutations protect or restore hearing from genetic deafness. Methods of treatment include the intracellular delivery of these molecules to a specific therapeutic target.

The invention provides pharmaceutical compositions comprising human immature dental pulp stem cells (hIDPSCs) wherein the hIDPSCs express CD44 and CD13. The invention also provides methods of treating a neurological disease or condition comprising systemically administering to a subject a pharmaceutical composition comprising hIDPSCs wherein the hIDPSCs express CD44 and CD13. For example, for treating neurological diseases or conditions including supporting the neuro-protective mechanism in subjects diagnosed with early HD or repairing lost DA neurons in subjects diagnosed with PD.