The present invention provides novel methods for poling piezoelectric materials, e.g., collagen, which are carried out in the absence of liquid media and at a relatively low temperature. The present invention also provides electroactive scaffolds comprising poled collagen for promoting cell growth and differentiation.

The present disclosure describes compositions and methods to promote wound healing. The compositions and methods include an interleukin-1 beta (IL-1) receptor antagonist (IL-1Ra), such as anakinra. The IL-1Ra can be administered topically to a chronic wound including a diabetic ulcer.

Tissue scaffolds for neural tissue growth have a plurality of microchannels disposed within a sheath. Each microchannel comprises a porous wall having a thickness of about 100 m that is formed from a biocompatible and biodegradable material comprising a polyester polymer. The polyester polymer may be polycaprolactone, poly(lactic-co-glycolic acid) polymer, and combinations thereof. The tissue scaffolds have high open volume % enabling superior (linear and high fidelity) neural tissue growth, while minimizing inflammation near the site of implantation in vivo. In other aspects, methods of making such tissue scaffolds are provided. Such a method may include mixing a reduced particle size porogen with a polymeric precursor solution. The material is cast onto a template and then can be processed, including assembly in a sheath and removal of the porogen, to form a tissue scaffold having a plurality of porous microchannels.

The present invention relates to a built-in bio-sleeve and preparation method and use thereof. In order to provide a suitable built-in bio-sleeve material for dorsal nerve isolation surgery and penis enlargement surgery, a novel acellular allogeneic dermal matrix material is prepared in the present invention, which is manufactured into a built-in bio-sleeve for the treatment of premature ejaculation and short and small penis. The acellular allogeneic dermal matrix or the built-in bio-sleeve of the present invention is used for dorsal nerve isolation surgery, penis enlargement or lengthening surgery without cutting off the dorsal nerve, thereby avoiding the probability of psychological erectile dysfunction caused by the patient's worry about cutting off the dorsal nerve.

A polyacrylonitrile (PANi) based pharmaceutical composition providing a porous implant for use in treating spinal cord trauma and/or spinal cord injury. Particularly a pharmaceutical composition including polyacrylonitrile (PANi) and/or elastin (E) and/or collagen (C) to form a PANi-E and/or PANi-C and/or a PANi-EC polymer network. Particularly, a pharmaceutical composition including polyacrylonitrile (PANi), elastin (E), and collagen (C) together forming a polyacrylonitrile (PANi), elastin (E), collagen (C) polymer network (PANi-E-C), wherein the polyacrylonitrile (PANi) may be crosslinked to form a crosslinked interpenetrating polyacrylonitrile (PANi), elastin (E) and collagen (C) polymer network (xpi-PANi-E-C), and wherein secondary protein structures of elastin (E) and collagen (C) reorientate. The disclosure extends to use of the pharmaceutical composition in the treatment of spinal cord trauma and/or spinal cord injury.

The present invention provides, among other things, powerful new tools for therapeutic and research uses in the central and/or peripheral nervous system. The present invention provides, inter alia, compositions including a plurality of human nerve cells, a plurality of glial cells, and silk fibroin, as well as methods for making and using such compositions.

A tissue graft construct, materials and methods for repairing an injured nerve in a patient. The tissue graft construct includes a band of biocompatible matrix and the hormone prolactin. The graft can be formed into a conduit and used to deliver the hormone prolactin directly at the site of nerve injury to promote healing.

A graft containing a scaffold that includes a matrix in which are positioned mesenchymal progenitor cells (MPCs) has the capacity to substantially improve wound healing, including wounds resulting from injury to nerve, bone and vascular tissue. MPCs can be harvested from debrided muscle tissue following orthopaedic trauma. The traumatized muscle-derived progenitor cells are a readily available autologous cell source that can be utilized to effect or improve wound healing in a variety of therapeutic settings and vehicles.

Provided herein are implantable biomaterials for promoting regeneration of an injured biological tissue, the biomaterials including piezoelectric materials and an extracellular matrix specific to the injured biological tissue, wherein the piezoelectric materials and the extracellular matrix are electrospun together to provide tissue-specific bioactive piezoelectric nanofiber scaffolds. Also provided herein are methods of fabricating a tissue-specific bioactive piezoelectric nanofiber scaffold and methods of promoting regeneration of injured biological tissue by implanting the disclosed bioactive piezoelectric scaffolds.

Methods, devices and materials are for a pharmaceutically acceptable implant system. The implant system may comprise a neuromodulating agent, solid particulate hydrogel particle, a carrier medium in a different physical phase, and in situ formation of a singular depot for sustained release of said agent.