Abstract: The present invention is directed to implants and the modification of the surface of implants using amino acid or polypeptide functionalized rosette nanotubes.

Abstract: Devices, systems, and methods for therapies involving the application of an electrical signal within the body of a subject involve the use of an implanted piezoelectric nanogenerator to provide a self-generated electrical signal without the use of batteries. The electrical signal stimulates healing of a tissue, such as bone, or provides pain relief by inhibiting neuronal pain signals. An external signal generator induces mechanical stress in an implanted piezoelectric nanomaterial, which produces the electrical signal.

Abstract: The invention relates to a metallic, nanoporous canister used to encapsulate cellular and/or biotherapeutic agents. The device is biocompatible and functions to wholly isolate a therapeutically active agent and/or cells therein. Their implantation, and survival in vivo, permits the local or systemic diffusion of their encapsulated cellular and/or biomolecular and therapeutics factors with the potential to promote repair of damaged or degenerated tissues in mammalian hosts, primarily humans.

Abstract: The invention relates to a metallic, nanoporous canister used to encapsulate cellular and/or biotherapeutic agents. The device is biocompatible and functions to wholly isolate a therapeutically active agent and/or cells therein. Their implantation, and survival in vivo, permits the local or systemic diffusion of their encapsulated cellular and/or biomolecular and therapeutics factors with the potential to promote repair of damaged or degenerated tissues in mammalian hosts, primarily humans.

Abstract: Disclosed are peptides comprising an amphiphilic backbone and a cationic heparin-binding motif peptide. The peptides can be used in methods of antimicrobial treatment.

Abstract: One embodiment of the present invention is directed to compositions and methods for enhancing attachment of soft tissues to a metal prosthetic device. In one embodiment a construct is provided comprising a metal implant having a porous metal region, wherein said porous region exhibits a nano-textured surface.

Abstract: The invention relates to a metallic, nanoporous canister used to encapsulate cellular and/or biotherapeutic agents. The device is biocompatible and functions to wholly isolate a therapeutically active agent and/or cells therein. Their implantation, and survival in vivo, permits the local or systemic diffusion of their encapsulated cellular and/or biomolecular and therapeutics factors with the potential to promote repair of damaged or degenerated tissues in mammalian hosts, primarily humans.

Abstract: One embodiment of the present invention is directed to compositions and methods for enhancing attachment of soft tissues to a metal prosthetic device. In one embodiment a construct is provided comprising a metal implant having a porous metal region, wherein said porous region exhibits a nano-textured surface.

Abstract: Methods of manufacturing produce metal implants having nano-modified surfaces that contain antimicrobial properties. The methods may include immersing the implant in an acid, rinsing the acid-treated implant in an aqueous cleaner, and thereafter heating the rinsed implant. The nano-modified implants described herein may contain an increased surface roughness; surface features with increased width or height; and/or decreased surface energy. The implants that result from these methods contain a nano-modified surface that is resistant to microbial cell adhesion and ultimately reduce biomaterials-related infections at the implant site.

Abstract: Methods of manufacturing produce metal implants having nano-modified surfaces that contain antimicrobial properties. The methods may include immersing the implant in an acid, rinsing the acid-treated implant in an aqueous cleaner, and thereafter heating the rinsed implant. The nano-modified implants described herein may contain an increased surface roughness; surface features with increased width or height; and/or decreased surface energy. The implants that result from these methods contain a nano-modified surface that is resistant to microbial cell adhesion and ultimately reduce biomaterials-related infections at the implant site.

Abstract: One embodiment of the present invention is directed to compositions and methods for enhancing attachment of soft tissues to a metal prosthetic device. In one embodiment a construct is provided comprising a metal implant having a porous metal region, wherein said porous region exhibits a nano-textured surface.

Abstract: One embodiment of the present invention is directed to compositions and methods for enhancing attachment of soft tissues to a metal prosthetic device. In one embodiment a construct is provided comprising a metal implant having a porous metal region, wherein the porous region exhibits a nano-textured surface, and a biocompatible polymer matrix coating the nano-textured surface. The polymer matrix coating comprises a naturally occurring extracellular matrix with biocompatible inorganic materials distributed within the matrix, or a biocompatible polymer and an osteo-inductive agent.

Abstract: Methods for creating nanostructured surface features on polymers and polymer composites involve application of low pressure during curing of solid polymer material from a solvent solution. The resulting nanoscale surface features significantly decrease bacterial growth on the surface. Polymer materials having the nanoscale structuring can be used in implantable medical devices to inhibit bacterial growth and infection.

Abstract: Methods of manufacturing produce metal implants having nano-modified surfaces that contain antimicrobial properties. The methods may include immersing the implant in an acid, rinsing the acid-treated implant in an aqueous cleaner, and thereafter heating the rinsed implant. The nano-modified implants described herein may contain an increased surface roughness; surface features with increased width or height; and/or decreased surface energy. The implants that result from these methods contain a nano-modified surface that is resistant to microbial cell adhesion and ultimately reduce biomaterials-related infections at the implant site.

Abstract: Nanomaterials for neural and orthopedic prostheses are disclosed. Composite carbon nanofibers enhance neuronal growth and minimize glial scar tissue formation. Methods and compositions to promote neuronal growth and minimize scar tissue formation during prolonged monitoring and treatment of neural tissue are disclosed. Composite polyurethane carbon nanofiber is a suitable material for neural implant. Composite carbon nanomaterials decrease adhesion of astrocytes and fibroblasts.

Abstract: Nanocomposite materials are provided for attaching soft tissue to hard tissue of a mammalian subject. The materials include a biodegradable polymer network suffused with mineral nanoparticles. The nanocomposite materials have a surface structure that promotes the infiltration, adhesion and proliferation of cells such as osteoblasts and fibroblasts, and are useful to reconstruct enthesis tissue, such as a tendon bone insertion. Devices containing the nanocomposites and methods for implantation of the devices at a tendon-bone interface or ligament-bone interface are provided for reconstructive surgery.

Abstract: The present invention is directed to methods for inhibiting growth of pathogens and to substrates with selenium nanoparticles or selenium nanoclusters having antipathogenic properties.

Abstract: The present invention is directed to transfection complexes of rosette nanotubes and one or more nucleic acids.

Abstract: The present invention is directed to transfection complexes of rosette nanotubes and one or more nucleic acids.

Abstract: One embodiment of the present invention is directed to compositions and methods for enhancing attachment of soft tissues to a metal prosthetic device. In one embodiment a construct is provided comprising a metal implant having a porous metal region, wherein said porous region exhibits a nano-textured surface.