A medium-based method for inducing specific differentiation of dental stem cells into dopaminergic neurons is provided. The method includes seeding the dental stem cells at a concentration of 5000 cells/cm.sup.2, following 24-hour incubation, introducing the cells into first part neurogenic induction medium and continuing the medium application for 4 days; subsequently, introducing the cells into the second part neurogenic induction medium and continuing the medium application for 2 days; and terminating the differentiation at the end of 6 days. The objective of the present invention is to develop cellular applications for use in treatment of neurodegenerative diseases and medications related to the said diseases.

The present invention provides a method for producing dopaminergic neuron progenitor cells from pluripotent stem cells, which method comprises the steps of: (i) performing adherent culture of pluripotent stem cells on an extracellular matrix in a medium containing a reagent(s) selected from the group consisting of BMP inhibitor, TGFβ inhibitor, SHH signal-stimulating agent, FGF8, and GSK3β inhibitor; (ii) collecting Corin- and/or Lrtm1-positive cells from the cells obtained in Step (i) using a substance which binds to Corin and/or a substance which binds to Lrtm1; and (iii) performing suspension culture of the cells obtained in Step (ii) in a medium containing a neurotrophic factor.

Culturing of organized 3D networks of neuronal cells is provided. Individual neuronal cells are encapsulated in gel beads. The gel beads are self-assembled into ordered structures in a bioreactor. Subsequent culturing of the cells in the bioreactor leads to the formation of an organized 3D network of the neuronal cells. Such structures have many applications, especially for as says of neuronal network function and/or structure.

This disclosure relates to methods for expanding inner ear supporting cells (e.g., Lgr5+ inner ear supporting cells) and differentiating inner ear supporting cells (e.g., Lgr5+ inner ear supporting cells) to inner ear hair cells (e.g., atonal homolog 1 (Atoh1)+ inner ear hair cells) and the use of the inner hear supporting cells and hair cells, e.g., for identifying candidate therapeutic compounds for the treatment of hearing loss and balance loss. Additionally, the methods described herein can be used in the treatment of a subject having hearing loss and balance loss that would benefit from increased proliferation and differentiation of inner ear supporting cells (e.g., Lgr5+ inner ear supporting cells).

Provided subject matter relates to tissue engineering. More specifically provided are kits, devices and methods for in situ repair and regeneration of guided and functional growth of cells and cell components by providing into the injury site biomaterial solution including the cell(s), magnetic particles and solidifying the biomaterial while applying the magnetic field.

Provided herein, inter alia, are compositions and methods comprising glial-derived extracellular vesicles for the prevention and treatment of neuropathies. In aspects, the glial-derived extracellular vesicles may include one or more of the following miRNA, an adeno-associated virus (AAV), siRNA, vRNA, mRNA, lncRNA, DNA, tetraspanins, amino acids, metabolites, signaling proteins, chaperones, cytoskeletal proteins, enzymes, or combinations thereof.

A method of producing a synthetic retina, including differentiating a stem cell culture in a culture medium and supplementing the culture with: (i) Triiodothyronine from about day 18 of cell differentiation; and (ii) retinoic acid for a first time period.

A cell-containing structure is provided that allows ready-to-use nerve drug response evaluation with high reproducibility to be easily performed. The cell-containing structure for evaluating an electrical property of neurons includes: (a) a culture surface to which the neurons are able to be adhered; (b) a cell mass that is adhered to the culture surface and contains at least one of the neurons; and (c) a plurality of electrodes for measuring the electrical property of the cell mass, wherein a spontaneous firing frequency of cells contained in the cell mass is 0.25 Hz or more per electrode.

The present invention provides novel methods for poling piezoelectric materials, e.g., collagen, which are carried out in the absence of liquid media and at a relatively low temperature. The present invention also provides electroactive scaffolds comprising poled collagen for promoting cell growth and differentiation.

The present disclosure provides methods for generating midbrain dopamine neurons and precursors thereof, midbrain dopamine neurons and precursors thereof generated by such methods and compositions comprising such cells, and uses thereof for preventing, modeling, and/or treating a neurological disorder.