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.

Embodiments described herein relate to restorative solutions for segmental peripheral nerve (PN) defects using allografted PNs for stimulating PN repair. More specifically, embodiments described herein provide for localized immunosuppression (LIS) surrounding PN allografts as an alternative to systemically suppressing a patient's entire immune system. Methods include localized release of immunosuppressive (ISV) agents are contemplated in one embodiment. Methods also include localized application of immunosuppressive (ISV) regulatory T-cells (Tregs) in other embodiments. Hydrogel carrier materials for delivery of ISV agents and are also described herein.

Disclosed are compositions, devices, systems, kits, and methods for neural ablation.

A method is disclosed for coating and patterning hydrogels in order to modify surface properties. The method exploits the water content of the hydrogel and the hydrophobicity of the reaction solvent to create a thin oxide adhesion layer on the hydrogel surface. This oxide adhesion layer enables rapid transformation of the hydrophilic, cell non-adhesive hydrogel into either a highly hydrophobic or a cell-adhesive hydrogel by reaction with an alkylphosphonic acid or an α,ω-diphosphonoalkane, respectively. Also disclosed are coated, patterned hydrogels and constructs comprising the coated, patterned hydrogels.

Luminal grafts and methods of making and using the same. An exemplary luminal graft of the present disclosure is configured as a generally tubular element configured for nerve cells to grow therethrough and comprises at least one sheet of biological tissue having elastin fibers and collagen fibers, with the elastin fibers being a dominant component thereof; and a plurality of microchannels formed on a surface of the at least one sheet of biological tissue, each of the microchannels extending longitudinally between a first end and a second end of the at least one sheet of biological tissue and configured to provide intraluminal structural guidance to nerve cells proliferating therethrough.

A method includes covering or contacting a portion of a recurrent laryngeal nerve of a subject with a shield including extraembryonic tissue. The covering occurs during a neck or reconstructive surgery of the subject.

The problem of attaching a donor nerve stump to a recipient nerve for an end-to-side coaptation is solved by the use of a tissue connector. The tissue connector can have a body for receiving the donor nerve stump and one or more overflaps for attaching the tissue connector with the donor nerve stump therein to the epineurium on the side of the recipient nerve. Sutures can also be used to secure the tissue connector and nerves in place.

The present disclosure provides magnetically templated tissue scaffolds, methods of making the magnetically templated tissue scaffolds, and various methods of employing the scaffolds for tissue growth and repair in vitro and in vivo, including peripheral nerve repair.

A biocompatible nerve conduit for nerve re-generation, wherein a porous fiber tube is coated with a bioresorbable hydrogel, with the fibers being formed from a polymer that supports nerve regeneration by preferential adsorption of endogenous proteins and braided with pores in the range from 5 to 200 micrometers using a kink-resistant braiding pattern and the hydro gel coating material and thickness being selected to control the overall porosity, so that nutrients and oxygen can diffuse through said hydrogel coating but the infiltration of fibrous tissue through the coating is prevented.

The subject invention provides devices and methods for alleviating discomfort associated with neuroma formation. The devices and methods of the invention effectively use the body's natural response of reconstructing implanted biomaterials to minimize the size of isolate, and protect a neuroma. In preferred embodiments, the subject device is a cylindrical cap, wherein the internal chamber of the cylindrical cap physically partitions the nerve to enable an arrangement of nerve fibers (as opposed to haphazardly arranged nerve fibers often produced in neuromas). Tabs arranged on the outside of the cap can be used to manipulate the cap into place on a nerve. The open end can also be configured with flaps that can be used to widen the open end for easier insertion of the nerve into the cap. In addition, the cap's material remodels into a tissue cushion after implantation, which protects the neuroma from being stimulated and inducing pain.