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.

Crosslinked biodegradable block polyurethane copolymers prepared from a plurality of biodegradable polymers or oligomers linked together via urethane bonds and crosslinked via a citrate ester are disclosed. Such copolymers can include folic acid and fabricated into medical devices such as a nerve growth conduit and locally deliver folic acid to a site of injury such as a PNS injury site.

A system and methods for producing a structure including a plurality of fibers is provided. The system includes a polymer collector having a predefined pattern, wherein the collector is charged at a first polarity, and a spinneret configured to dispense a polymer, wherein the spinneret is charged at a second polarity substantially opposite the first polarity such that polymer dispensed from the spinneret forms a plurality of fibers on the predefined pattern of the fiber collector.

The present invention provides, in some aspects, bilayered and trilayered pharmaceutical implant compositions for the unidirectional delivery of anti-cancer compounds to the brain over a period of time (e.g., several weeks, 1, 2, 3, 4, 5, 6, 7 days, or 1, 2, 3, weeks, or any range derivable therein) following the removal of glioblastoma multiforme or other malignant tumors in the brain.

Described herein is the method of preparation for amnion based tissue conduits. Amnion based tissue conduits are obtained from placental and umbilical cord tissue. Wherein said tissues are separated into one or more layers of amnion, chorion and umbilical cord and incised into predetermined measurements. By incising tissues, the quantified measurements will be less readily able to degrade bioactive properties during the predetermined duration of exposure of super critical carbon dioxide sterilization and a disinfectant wash of amnion, chorion and umbilical cord.

Methods and compositions for repair and regeneration of neural tissue are provided. Particularly, methods and compositions for promoting neural tissue wound healing and treatment of traumatic brain injury using porous crystalline calcium carbonate particles and a biocompatible polymer, for example compositions comprising porous coral exoskeleton particles in combination with a biocompatible polymer, and optionally comprising neural growth agents and platelets for application to damaged neural tissue for enhancing neural regrowth and recovered functionality, in, for example, but not limited to, traumatic brain injury (TBI).

The present invention overcomes all the above drawbacks and provides a versatile method for the fabrication of multilayer hollow tubes that uses a layer-by-layer rod dipping approach using different biomaterials. The device enables fine control over fabrication parameters, such as ascending/descending speeds, rod rotational velocity, and crosslinking or polymerization time. All these technologies allows the generation of more complex multilayer hollow tubes such as vessel-like structures, urethral grafting, prostate grafting and the like.

The present disclosure relates to an apparatus for manufacturing a nerve conduit, more particularly to an apparatus for manufacturing a porous nerve conduit using glass fibers whereby microchannels are formed using the space between the glass fibers and the defective rate and location-dependent variation of each nerve conduit can be minimized through uniform decompression during the manufacture. The nerve conduit manufactured according to the present disclosure can be manufactured to have various diameters and lengths to be applicable to in vitro and in vivo researches on nerves.

The present invention relates to preparation and use of nanocellulose fibrils or crystals such as disintegrated bacterial nanocellulose, tunicate-derived nanocellulose, or plant-derived nanocellulose, together with carbon nanotubes, as a biocompatible and conductive ink for 3D printing of electrically conductive patterns. Biocompatible conductive bioinks described in this invention were printed in the form of connected lines onto wet or dried nanocellulose films, bacterial cellulose membrane, or tunicate decellularized tissue. The devices were biocompatible and showed excellent mechanical properties and good electrical conductivity through printed lines (3.8.Math.10.sup.1 S cm.sup.1). Such scaffolds were used to culture neural cells. Neural cells attached selectively on the printed pattern and formed connective networks. The devices prepared by this invention are suited as bioassays to screen drugs against neurodegenerative diseases such as Alzheimer's and Parkinson's, study brain function, and/or be used to link the human brain with electronic and/or communication devices. They can also be implanted to replace neural tissue or stimulate guiding of neural cells. They can also be used to stimulate the heart by using electrical signaling or to repair myocardial infarction and/or damage related thereto.

This document relates to decellularized nerve allografts. For example, decellularized nerve allografts and methods and materials for using decellularized nerve allografts to repair nerve injuries or bridge a severed nerve are provided.