An oblique expanding fusion cage device including a body with a superior portion and an inferior portion. The superior portion and the inferior portion have a proximal end and a distal end. The fusion cage device also includes a pathway, an opening, and an expanding member. The pathway travels from the proximal end to the distal end of the device between the superior and inferior portions. The opening in the proximal end of the body enables access to the pathway. The expanding member may be removably inserted into the opening and is moveable toward the distal end of the body, wherein the expanding member engages the superior portion and the inferior portion as the expanding member moves distally within the pathway.

A method of manufacturing an orthopedic implant is provided. The method includes creating a 3D model of an orthopedic implant having a solid portion and a porous portion and selectively adjusting a physical property of at least one of porosity of the porous portion, lattice thickness of the porous portion, beam profile of the porous portion, and topography of the 3D model. The entire implant is then additively manufactured based on the 3D model.

The present invention is a spinal implant that can be inserted into a surgically created cavity of one or more regions of the mammalian spine. Among other things, the biocompatible implant and end cap or biocompatible implant, end cap and spacer combinations can assist with the restoration of the normal anatomic spinal alignment and spinal stability.

An apparatus for placement at an anatomical site, the apparatus including an orthopedic implant, which includes a front end, a rear end, a top, a bottom, a right side, a left side, and a central part connecting the right and left sides. The top surface of the implant has a top surface defining a first sloping surface running downwardly from the front end to the rear end of the implant, and the implant having a second sloping surface running downwardly from one side to the opposite side of the implant, and the first and second sloping surfaces are perpendicular to each other. At least a portion of the implant is shaped to define a porous matrix, the porous matrix being shaped to define a plurality of pores that extend through the porous matrix, the pores being sized to receive inserted bone graft material into the pores. At least the central part has a plurality of said pores therein, and the central part defines at least one fixation passageway that passes through the implant from the top of the implant to the bottom of the implant, the at least one fixation passageway having a diameter larger than an average diameter of the pores and is extending almost perpendicular to said second sloping surface running downwardly from one side to the opposite side of the implant, and is adapted to accept a fixation element.

An osteoimplant is provided which comprises a coherent aggregate of elongate bone particles, the osteoimplant possessing predetermined dimensions and shape. The osteoimplant is highly absorbent and sponge-like in nature. Also provided herein are a method of fabricating the osteoimplant and a method of repairing and/or treating bone defects utilizing the osteoimplant.

In various embodiments, an implant for interfacing with a bone structure includes a web structure including a space truss. The space truss includes two or more planar truss units having a plurality of struts joined at nodes and the web structure is configured to interface with human bone tissue. In some embodiments, a method is provided that includes accessing an intersomatic space and inserting an implant into the intersomatic space. The implant includes a web structure including a space truss. The space truss includes two or more planar truss units having a plurality of struts joined at nodes and the web structure is configured to interface with human bone tissue.

Various embodiments of implant systems and related apparatus, and methods of operating the same are described herein. In various embodiments, an implant for interfacing with a bone structure includes a web structure, including a space truss, configured to interface with human bone tissue. The space truss includes two or more planar truss units having a plurality of struts joined at nodes. Implants are optimized for the expected stress applied at the bone structure site.

An intervertebral implant for positioning within an intervertebral space between adjacent first and second vertebral bodies. The intervertebral implant includes an implant body extending along a longitudinal axis of the intervertebral implant that is adapted to align with a vertical axis of the spine. The implant body includes a top plate and a bottom plate disposed longitudinally opposite and spaced apart from the top plate along the longitudinal axis. Further, the implant body includes at least one cross-arm obliquely extending between the top plate and the bottom plate. Furthermore, the implant body includes a lattice structure disposed at least between the at least one cross-arm and the top plate and between the at least one cross-arm and the bottom plate.

A femoral neck prosthesis (10) with a cross-section defined by a perimeter comprising: first and second arcuate portions (12, 14) disposed opposite one another; and first and second substantially straight portions (16, 18) disposed opposite one another and in between the first and second arcuate portions, wherein the first and second straight portions are non-parallel with respect to one another.

A device for insertion into a spinal (intervertebral or intravertebral) space is expandable and contractable. The device includes a body assembly, a top member configured to fit within a gap in the body assembly, a drive gear disposed within the body assembly at a distal end of the body assembly, a proximal gear assembly, and a distal gear assembly. The drive gear includes a receiver accessible from outside the body assembly and configured to be rotated in order to rotate the drive gear. Each gear assembly is attached to the top member. The distal gear assembly engages the drive gear. Rotation of the drive gear in a first direction causes the gear assemblies to translate the top member away from the body assembly, and rotation of the drive gear in a second direction causes the gear assemblies to translate the top member towards the body assembly.