Devices and methods for the treatment of open and closed wound spinal cord injuries are disclosed. For example, described herein are devices and methods for mitigating secondary injury to, and promoting recovery of, spinal cord primary injuries. More particularly, certain embodiments of the present invention are directed to polymeric mini-tubes that may be used for the treatment of spinal cord injuries. In addition, other embodiments are directed to polymeric fill-in bandages that may be used for the treatment of spinal cord injuries. For example, an erodible, or biodegradable, form of biocompatible polymer of the present invention is fabricated for surgical implantation into the site of the spinal cord injury.

Described herein are novel compositions comprising multimodal TRAIL agents and cells engineered to express such multimodal TRAIL agents, including cells encapsulated in a scaffold or matrix, for use in the treatment of disorders such as cancer.

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.

In various aspects and embodiments, the invention provides a tissue engineered neuromuscular interface comprising: an extracellular matrix core; the extracellular matrix core comprising: a population of neurons at a first end of the extracellular matrix core, the population of neurons having axons extending at least a portion of the way along the extracellular matrix core; wherein the population of neurons is selected from the group consisting of one or more motor neurons, one or more motor neurons co-cultured with one or more sensory neurons, and a co-aggregate comprising one or more motor neurons and one or more sensory neurons.

The present invention relates to a method for manufacturing a peripheral nerve-mimicking microtissue and to uses thereof, and relates to a method for manufacturing a peripheral nerve-mimicking microtissue having a diameter of 100?20 ?m composed of about 100 to 500 cells, comprising isolating an culturing peripheral nerve-derived stem cells (PNSCs), and forming a cell-to-cell and cell-to-extracellular matrix binding through suspension culture of the isolated and cultured PNSCs, wherein the microtissue produced by culturing in a suspended culture environment has structural properties in which about 100 to 500 cells are assembled through cell-to-cell binding by ?-catenin, the extracellular matrix (ECM) produced and secreted by the PNSCs between cells accumulates, and binding is performed by ?1-integrin between the accumulated ECM and cells, and this is similar to the peripheral nerve composition and constituent cells that are regenerated after injury. Functionally, the present invention can induce nerve tissue regeneration by secreting neurotrophic agents that act centrally on nerve regeneration in the peripheral nerve-mimicking microtissue.

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.

Methods for treating a patient having a disease or condition related to IVD degeneration are provided. The methods comprise administering cells obtained from human umbilical cord tissue, or administering pharmaceutical compositions comprising such cells or prepared from such cells and optionally a hydrogel. In some embodiments, administering the cells promotes repair and regeneration of degenerated IVD tissue in the patient. Pharmaceutical compositions for use in the inventive methods, as well as kits for practicing the methods are also provided.

This document provides methods and materials for treating nerve injuries and/or neurological disorders. For example, compositions including an amnion tissue preparation and/or a stem cell preparation as well as methods for using such compositions to treat a nerve injuries and/or neurological disorders are provided.

The invention is directed to a nerve cap for covering a nerve stump, comprising a tubular body with a closed end and an open end and essentially consisting of biodegradable polymeric material to prevent or treat symptoms caused by neuroma. The polymeric material preferably comprises a poly(DL-lactide-co--caprolactone) copolymer obtained by the copolymerizaton of DL-lactide and -caprolactone, which copolymer has a lactide content of 51-75 mol %.

A method of producing an acellular cornea includes steps of subjecting a cornea of an animal to a decellularization process, and has not the step of treating the cornea with a protease, a chelating agent, a detergent, a glycerol, or a combination thereof. When a native cornea is processed by the method, the native structure and conformation of the native cornea are preserved while immunogenic matters are reduced to a level that the thus produced cornea may serve as a three-dimensional scaffold for host cells to grow thereon after transplantation.