Various embodiments disclosed relate to an implant. The implant includes a substrate. The implant further includes a monolithic layer comprising a biocompatible metallic material, having at least one of an amorphous and a crystalline microstructure contacting the substrate.

An antibacterial device is disclosed that includes a substrate and an antibacterial coating or antibacterial surface being provided on at least a part of the substrate's surface. The antibacterial coating or surface includes Angstrom scale flakes, where the Angstrom scale flakes are arranged in a standing position on the substrate surface and are attached to the substrate surface via edge sides thereof. The Angstrom scale flakes can, for example, be graphene flakes, or graphite flakes having a thickness of a few atom layers. It has been found that such standing flakes are efficient in killing prokaryotic cells but do not harm eukaryotic cells.

An antibacterial device is disclosed that includes a substrate and an antibacterial coating or antibacterial surface being provided on at least a part of the substrate's surface. The antibacterial coating or surface includes Angstrom scale flakes, where the Angstrom scale flakes are arranged in a standing position on the substrate surface and are attached to the substrate surface via edge sides thereof. The Angstrom scale flakes can, for example, be graphene flakes, or graphite flakes having a thickness of a few atom layers. It has been found that such standing flakes are efficient in killing prokaryotic cells but do not harm eukaryotic cells.

The present invention relates to novel biocompatible oxygen gas generating devices that can be implanted into a living subject. In certain embodiments, the oxygen gas generating devices can be used to deliver oxygen gas to tissue in a subject, thereby stimulating tissue growth and repair. In other embodiments, the devices operate by electrolytically splitting endogenous water in a subject. In yet other embodiments, the device further comprises an implantable supercapacitor capable of supplying energy to the oxygen gas generating device.

An extended release immunomodulatory implant operatively arranged to facilitate bone morphogenesis, including an inner portion including one or more interleukins, and an outer portion including an immunomodulatory stimulant such as an antigen.

An extended release immunomodulatory implant operatively arranged to facilitate bone morphogenesis, including an inner portion including one or more interleukins, and an outer portion including an immunomodulatory stimulant such as an antigen.

An extended release immunomodulatory implant operatively arranged to facilitate bone morphogenesis, including an inner portion including one or more interleukins, and an outer portion surrounding the inner portion, the outer portion including an antigen operatively arranged to activate an innate immune system.

An extended release immunomodulatory implant operatively arranged to facilitate bone morphogenesis, including an inner portion including one or more interleukins, and an outer portion surrounding the inner portion, the outer portion including an antigen operatively arranged to activate an innate immune system.

Silicon carbide (SiC) is an inert material with excellent biocompatibility properties. The biocompatibility is associated with the chemical inertness of the material. Tissue response to inert material is the formation of thin fibrous capsule. In some embodiments described herein, the conversion of SiC from inert material to bioactive material capable of stimulating cell function and making direct bond with tissue is described and the body response to bioactive materials is direct binding without any fibrous capsule.

Silicon carbide (SiC) is an inert material with excellent biocompatibility properties. The biocompatibility is associated with the chemical inertness of the material. Tissue response to inert material is the formation of thin fibrous capsule. In some embodiments described herein, the conversion of SiC from inert material to bioactive material capable of stimulating cell function and making direct bond with tissue is described and the body response to bioactive materials is direct binding without any fibrous capsule.