A tissue engineering material for nerve injury repair, a preparation method therefor and an application thereof. The tissue engineering material for nerve injury repair is an N-cadherin crosslinked linear ordered collagen scaffold. By crosslinking N-cadherin with a linear ordered collagen scaffold, the prepared tissue engineering material can efficiently induce migration of neural stem cells towards an injury region so that the neural stem cells are enriched in the injury region, and can effectively inhibit deposition of inhibitory factors such as chondroitin sulfate proteoglycan, promote differentiation of the neural stem cells into neurons, and then promote recovery of electrophysiological and motion functions. The N-cadherin crosslinked linear ordered collagen scaffold also has a stable ordered topological structure and excellent mechanical properties, and can be used to repair nerve injuries such as spinal cord injury.

Methods for differentiating human pluripotent stem cells to dorsal neuroectoderm progenitors and further to glial progenitor cells and oligodendrocyte progenitor cells (OPCs) using inhibitors of BMP signaling and MAPK/ERK signaling are provided. Also provided are cells and cellular compositions obtained by such methods, and uses of such cells. Further provided are methods and protocols for efficiently differentiating human pluripotent stem cells to OPCs in the absence of the ventralizing morphogen SHH or a SHH signaling activator. The methods of the present disclosure reproducibly produce dorsal neuroectoderm progenitor cells by day 7 of the differentiation process, glial progenitor cells by day 21 of the differentiation process and OPCs by day 42 of the differentiation process.

High-yield mammalian transient expression systems can include a cell culture media (particularly serum free, non-animal derived, and/or chemically defined media) for introducing macromolecules and compounds (e.g., nucleic acid molecules) into cells (e.g., eukaryotic cells). Cells containing such introduced materials can then be cultured in the cell culture media. In particular, the invention allows introduction of nucleic acid molecules (e.g., vectors) into cells (particularly mammalian cells) and expression of proteins encoded by the nucleic acid molecules in the cells. The invention obviates the need to change the cell culture medium each time a different procedure is performed with the cells (e.g., culturing cells vs. transfecting cells). The invention also relates to compositions and kits useful for culturing and transforming/transfecting cells.

Techniques and systems are disclosed for a bioassay that is an in vitro mimic of peripheral nerve generation using the sensory neurons that innervate the peripheral nervous system. In some embodiments, the techniques may assist in detecting the bioactivity or potency of nerve grafts (e.g., processed, acellular human allografts) for fostering or supporting peripheral nerve regeneration. In various embodiments, techniques comprise affixing neurons (e.g., a DRG) to a nerve graft segment to form a test construct; culturing the test construct in a medium; analyzing the test construct to indicate the amount of outgrowing nerve structure; and determining the potency of the nerve graft from a metric derived from the analysis. In some embodiments, techniques and materials may be used to test the effect of a varied test condition on nerve growth.

The present disclosure relates generally to methods of inducing differentiation of pluripotent stem cells into enteric nitrergic neurons, and enteric nitrergic neurons produced by such methods. Also provided are used of such enteric nitrergic neurons for screening potential therapeutic agents suitable for preventing and/or treating enteric nervous system disorders, such as gastroparesis, esophageal achalasia, chronic intestinal pseudo-obstruction, and hypertrophic pyloric stenosis, and applications of such enteric nitrergic neurons in regenerative medicine, such as cell transplantation therapy, for preventing and/or treating enteric nervous system disorders.

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.

A process of using a fish plasma component in a nutrient medium for cell culture includes obtaining a fish that is a progeny of domesticated broodstock that are reared under consistent and reproducible conditions. Blood is obtained from the fish, and plasma is separated from the blood. One or more specific components of the plasma are then extracted, and cells are cultured in a nutrient medium using the one or more extracted plasma components, and none of any remainder of the plasma. The plasma and/or the plasma components is/are tested for presence and/or level of endotoxin. Extracting the one or more specific components of the plasma, and/or culturing the cells is only performed if the testing indicates an endotoxin level below a predetermined threshold. The cells cultured using the extracted one or more plasma components are other than fish cells.

Methods are described for preparing auditory progenitor cells from gingival mesenchymal cells, for uses such as restoring hearing in hearing impaired individuals. In one aspect, a method of treating hearing loss associated with loss of sensory neurons in a human subject is provided, the method comprising the steps of: a. obtaining a population of gingival mesenchymal stem cells (GMSCs); b. optionally expanding the population of GMSCs in vitro; c. encapsulating the population of GMSCs in an elastic three-dimensional scaffold; d. exposing the encapsulated population of GMSCs to a composition comprising one or more growth factors; e. allowing co a sufficient period for the population of GMSCs to differentiate towards auditory progenitor cells; f. optionally retrieving the auditory progenitor cells from the scaffold; and g. introducing the auditory progenitor cells into the inner ear of the subject.

Objects to be achieved are to provide a nerve cell with which it is possible to visualize and quantify the intracellular tau without using the exogenous promoter and to provide a pluripotent stem cell with which the nerve cell can be produced, to provide a method of screening a substance, including using the pluripotent stem cell or nerve cell described above, and a substance screened by the above method, and to provide a kit including a targeting vector and a gRNA.

There is provided a pluripotent stem cell including a DNA encoding a reporter molecule, the DNA being introduced adjacent to an endogenous tau gene such that a tau protein is expressed as a fusion protein fused with a reporter molecule.

Uses of n-butylidenephthalide (BP) in dopaminergic progenitor cell transplantation are provided, wherein the uses include using BP to enhance the therapeutic effect of dopaminergic progenitor cell transplantation, and using a combination of BP and BP-treated dopaminergic progenitor cells in dopaminergic progenitor cell transplantation. The uses especially relate to using BP to enhance the therapeutic effect of dopaminergic progenitor cell transplantation on Parkinson’s disease.