The present disclosure provides fasciculated nerve grafts of customizable lengths and diameters, and methods of preparing the same. The grafts are made by digesting native extracellular matrix (ECM) around the nerve fascicles of a nerve tissue, and the epineurial sheath. One or more of the individual fascicles may then be entubulated in an entubulation material, embedded in or coated with a coating material, or both, to form a fasciculated nerve graft. The fasciculated nerve grafts are customizable and designed to bridge nerve gaps; the modularity of the fasciculated nerve graft allows for restoring continuity to nerve defects of virtually any length and allows for matching the diameter of the patient's recipient nerve.

The present invention relates, in part, to blood-brain barrier-like tissues that comprise engineered E40RF1+ endothelial cells, and to various compositions and methods useful for making and using such blood-brain barrier-like tissues—both in vitro and in vivo.

A nerve conduit loaded with adipose-derived stem cells and a preparation method thereof are provided. The preparation method includes: S1, adding polycaprolactone and polyvinylpyrrolidone into a binary organic solvent, performing ultrasonic treatment, and then adding reduced graphene oxide nanoparticles to obtain a spinning solution; S2, electrospinning with the spinning solution and then washing for several times to obtain a semi-finished conduit product; and S3, injecting a cell mixture into the semi-finished conduit product to obtain the nerve conduit. A fiber surface of the nerve conduit has groove structures, and thus a specific surface area and cell adhesion sites are increased, and adhesion and proliferation of cells are facilitated. By loading the adipose-derived stem cells, neurotrophic phenotypic effect of peripheral nerve scaffold is improved, and can effectively avoid immunological rejection of transplantation, promote orientational growth of axons into the nerve conduit and promote myelination effect of Schwann cells.

The invention provides a method for producing a ciliary marginal zone stem cell induced to differentiate from a pluripotent stem cell, including either the following step (1) or step (2), or both of these steps: (1) a step of floating culturing cells obtained from a cell aggregate containing a ciliary marginal zone-like structure induced to differentiate from pluripotent stem cells, thereby obtaining a retinosphere; and (2) a step of collecting stage specific embryonic antigen-1 positive cells from cells obtained from a cell aggregate containing a ciliary marginal zone-like structure induced to differentiate from pluripotent stem cells.

The present invention provides novel compositions comprising multipotent cells or microvascular tissue, wherein the cells or tissue has been sterilized and/or treated to inactivated viruses, and related methods of using these compositions to treat or prevent tissue injury or disease in an allogeneic subject.

The present invention features a neural organoid that recapitulates in vitro most characteristics of the brain (e.g., human), and methods of using this neural organoid to study disease and to identify therapeutic agents for the treatment of neurological diseases and disorders.

The invention relates to a cell sheet construct for neurovascular reconstruction. The cell sheet construct has a vascular endothelial cell layer and a neural stem cell layer, and the two layers are physically in direct contact with each other, where the vascular endothelial cell layer forms branching vasculatures, and the neural stem cell layer differentiates into neurons. The invention also relates to a method for manufacturing the cell sheet construct, having the following steps: culturing vascular endothelial cells on a substrate to form a vascular endothelial cell layer, seeding neural stem cells on the vascular endothelial cell layer to make the neural stem cells be physically in direct contact with the vascular endothelial cell layer, and culturing the neural stem cells and the vascular endothelial cell layer to differentiate into neurons and branching vasculatures to form a cell sheet construct.

Provided herein are scaffold biomaterials including at least one bundle of microchannels, the bundle of microchannels having a plurality of decellularised microchannels isolated from plant or fungal tissue, the decellularised microchannels being arranged substantially parallel to each other within the bundle. Also provided are methods and uses of such scaffold biomaterials and bundles, as well as methods for the production of such scaffold biomaterials and bundles.

The present disclosure relates to a neural cell population, a neural cell-containing preparation, and a method for producing the population and preparation. More particularly, the present invention relates to a neural cell population derived from intraoral mesenchymal cells, wherein a proportion of normal diploid cells is 80% or more, a preparation containing the neural cell population, and a method for producing the population and the preparation.

Neurosupportive materials that possess strong tissue adhesion were synthesized by photocrosslinking two polymers, gelatin methacryloyl (GelMA) and methacryloyl-substituted tropoelastin (MeTro). The engineered materials exhibited tunable mechanical properties by varying the GelMA/MeTro ratio. In addition, GelMA/MeTro hydrogels exhibited 15-fold higher adhesive strength to nerve tissue ex vivo compared to traditionally used fibrin-based materials. Furthermore, the composites were shown to support Schwann cell (SC) viability and proliferation, as well as neurite extension and glial cell participation in vitro, which are essential cellular components for nerve regeneration. Finally, subcutaneously implanted GelMA/MeTro hydrogels exhibited slower degradation in vivo compared with pure GelMA, indicating its potential to support the growth of slowly regenerating nerves. Thus, GelMA/MeTro composites may be used as clinically relevant biomaterials to regenerate nerves and reduce the need for microsurgical suturing during nerve reconstruction.