Abstract: In a general aspect, an apparatus can include a plate configured for implantation in a body of a patient. The plate can include a plurality of pores and be configured for placement between a cancellous bone of a spinal vertebra and a corresponding cartilaginous endplate as a replacement for a bony endplate of the spinal vertebra.

Abstract: As detailed herein, a biocompatible apparatus comprises a porous material comprising ceramic nanotubes bound together with a filler material. The proportion of the filler material may be selected to provide porosity for the porous material that is biocompatible, and the porous material may be shaped to provide a compliant biomedical device. In one embodiment, the compliant biomedical device is a stent such as intravascular stent. A method for fabricating a biocompatible device is also described herein. The method may include growing ceramic nanotubes on a substrate, infiltrating the ceramic nanotubes with a filler material to provide a porous material having a porosity that is biocompatible, and removing the porous material from the substrate to provide a biocompatible ceramic device. The method may also include coating the biocompatible ceramic device with a drug-eluting material.

Abstract: Microbially-resistant materials are disclosed and described, along with devices, surfaces, and associated methods. Such materials can be coated onto device surfaces, system surfaces, structures, and the like.

Abstract: Microbially-resistant materials are disclosed and described, along with devices, surfaces, and associated methods. Such materials can be coated onto device surfaces, system surfaces, structures, and the like.

Abstract: A spinal implant includes a plurality of frame segments that define a first frame array, the first frame array being coupled to a first mounting connection. A plurality of contiguous segments define a second frame array, the plurality of contiguous segments being coupled to a second mounting connection and being coupled to the first frame array. The first frame array and the second frame array are positioned relative to one another such that application of a force in a first direction to the first and second mounting connections results in application of a force in an opposing direction to the plurality of contiguous segments.

Abstract: A spinal implant includes a plurality of frame segments that define a first frame array, the first frame array being coupled to a first mounting connection. A plurality of contiguous segments define a second frame array, the plurality of contiguous segments being coupled to a second mounting connection and being coupled to the first frame array. The first frame array and the second frame array are positioned relative to one another such that application of a force in a first direction to the first and second mounting connections results in application of a force in an opposing direction to the plurality of contiguous segments.

Abstract: As detailed herein, a biocompatible apparatus comprises a porous material comprising ceramic nanotubes bound together with a filler material. The proportion of the filler material may be selected to provide porosity for the porous material that is biocompatible, and the porous material may be shaped to provide a compliant biomedical device. In one embodiment, the compliant biomedical device is a stent such as intravascular stent. A method for fabricating a biocompatible device is also described herein. The method may include growing ceramic nanotubes on a substrate, infiltrating the ceramic nanotubes with a filler material to provide a porous material having a porosity that is biocompatible, and removing the porous material from the substrate to provide a biocompatible ceramic device. The method may also include coating the biocompatible ceramic device with a drug-eluting material.

Abstract: A spinal implant comprising a plurality of contiguous segments that define a segment array, said plurality of contiguous segments extending from a first side of the segment array to a second side of the segment array in an overlapping configuration, said plurality of contiguous segments operable to apply a torque to a degenerate spinal segment in each of three orthogonal axes. At least one mounting connection is configured to connect said spinal implant to a mounting mechanism, said mounting mechanism being configured to attach said spinal implant to said degenerate spinal segment.