Embodiments relate to a crosslinked citrate-based elastomer catheter that is biodegradable and kink resistant. Embodiments of the crosslinked citrate-based elastomer material swells when surrounded by fluid (body fluid) so as to anchor the catheter to tissue but not anchor it so much that movement or removal will cause tissue damage. The catheter can be used as a component to a peripheral nerve block device, for example. Embodiments of the catheter can include embedding biodegradable sensors, moieties, shape memory material, etc. to monitor and modulate functions of the catheter and/or peripheral nerve block.

Grafts modified with one or more bioactive substances are provided, as well as methods to make and use them. More particularly, the present invention relates to modified grafts having characteristics which facilitate tissue generation, repair, and reconstruction, and which are modified with bioactive substances, such as one or more proteins and minerals, whose bioactivity further facilitates tissue generation, repair, and reconstruction. Methods for producing the modified grafts include depositing the one or more bioactive substances onto, into, or both, a substrate material. In certain exemplary embodiments, the substrate material comprises a tissue derived matrix produced by processing one or more tissue samples, and the bioactive materials are precipitated from a solution produced during that processing, such as during demineralization of bone tissue samples or delipidation of adipose tissue samples, wherein the one or more bioactive substances comprise proteins and minerals endogenous to bone or adipose tissue, respectively.

Methods for making surgical implants (or grafts) for the repair of bone defects, and more particularly, surgical implants that include demineralized bone fibers, are disclosed. Also disclosed are methods for increasing the wettability and ensuring uniform density of such implants. The surgical implants have a wettability time of less than 5 minutes and a residual moisture content of less than 6% by weight, and they remain cohesive and retain their shape upon complete rehydration.

3D native tissue-derived scaffolding materials are made in various formats, including but not limited to hydrogel, sponge, fibers, microspheres, and films, all of which function to better preserve natural extracellular matrix molecules and to recapitulate the natural tissue environment, thereby effectively guiding tissue regeneration. Tissue-derived scaffolds are prepared by incorporating a homogenized tissue-derived suspension into a polymeric solution of synthetic, natural, or hybrid polymers. Such tissue-derived scaffolds and scaffolding materials have a variety of utilities, including: the creation of 3D tissue models such as skin, bone, liver, pancreas, lung, and so on; facilitation of studies on cell-matrix interactions; and the fabrication of implantable scaffolding materials for guided tissue formation in vivo. The tissue-derived scaffolds and scaffolding materials also provide the opportunity to correlate the functions of extracellular matrix with tissue regeneration and cancer metastasis, for example.

Coated bone grafts are provided as well as methods of use thereof and methods of making. In accordance with the instant invention, methods of preparing a coated bone graft (e.g., bone allograft) are provided. In certain embodiments, the method comprises electrospraying a composition comprising a polymer and, optionally, an agent, particularly a therapeutic agent, onto the surface of the bone graft. Therapeutic agents include, without limitation: bone stimulating agents, anti-fibrotic agents, antimicrobials, anti-inflammatory agents, and pro-angiogenesis agents.

The present disclosure relates to exosome bone graft systems and compositions and preservative systems and compositions as well as methods of use and methods of manufacturing of them.

The present invention pertains to novel bone graft substitute materials. These materials are porous, homogenously dispersed solid mixtures of calcium phosphate and pro-regenerative extracellular matrix (ECM)—and potentially any pharmaceutical agent and/or mineral—that have been infused with polydopamine. In some embodiments the bone graft materials have osteoinductive factors incorporated within them.

A solubilized notochordal cell matrix powder dissolved in a carrier solvent or formed as a gel is provided. The notochordal cell matrix powder originates from lyophilized and treated porcine nucleus pulposus tissue containing notochordal cells. The powder contains less than 20% of porcine nucleid acids, and the powder contains a substantially unchanged amount of porcine protein content compared to the originating porcine nucleus pulposus tissue. The solubilized notochordal cell matrix powder is capable of stimulating native or stem cells to proliferate and produce a significant increase inglycosaminoglycansand type-II collagen matrix. Embodiments of the invention can be used for the disc regenerative treatment of discogenic back and neck pain in an orthopaedic and/or pharmaceutical setting/approach.

A viable disc regenerative composition has a micronized material of nucleus pulposus and a biological composition made from a mixture of mechanically selected allogeneic biologic material derived from bone marrow having non-whole cellular components including vesicular components and active and inactive components of biological activity, cell fragments, cellular excretions, cellular derivatives, and extracellular components; and wherein the mixture is compatible with biologic function and further includes non-expanded whole cells. The biological composition is predisposed to demonstrate or support elaboration of active volume or spatial geometry consistent in morphology with that of disc tissue. The viable disc regenerative composition extends regenerative resonance that compliments or mimics disc tissue complexity.

Described herein are tissue grafts derived from the placenta with improved physical and biological properties. In one aspect, the tissue graft includes a first membrane comprising Wharton's jelly laminated with amnion, chorion, or a combination thereof. The presence of Wharton's jelly in the grafts enhances the performance of allograft amniotic-derived, caderivic allograft, xenograft, or alloplast soft tissue substitutes.