The presented disclosure is a prosthesis for performing radial head replacement in the setting of fractures or degenerative conditions of the radial head, and other conditions including avascular necrosis. The presented radial head replacement prostheses can be implanted in a cement-less or cemented fashion. The prosthesis of the presented disclosure comprises a radial head replacement which in various embodiments includes (1) one or more interlocking screw holes along the stem, (2) a radial head replacement prosthesis with a two component design and with a tapered connection, (3) a radial head replacement prosthesis with a two component design and with a cylindrical connection, (4) a radial head replacement prosthesis with a two component design and with a curved stem, (5) a radial head replacement prosthesis with a two component design and with an inter-component screw connection, and (6) a radial head replacement prosthesis with a one-piece design.

This invention improves upon prior art total disc replacements (TDRs) by more closely replicating the kinematics of a natural disc. The preferred embodiments feature two or more fixed centers of rotation (CORs) and an optional variable COR (VCOR) as the artificial disk replacement (ADR) translates from a fixed posterior COR that lies posterior to the COR of the TDR to facilitate normal disc motion. The use of two or more CORs allows more flexion and more extension than permitted by the facet joints and the artificial facet (AF). AF joint-like components may also be incorporated into the design to restrict excessive translation, rotation, and/or lateral bending.

The invention is generally related to an intervertebral implant for replacing an intervertebral disc of the human spine. The intervertebral implant includes a first conformable endplate, the first conformable endplate being conformable to a boney vertebral endplate under an anatomical load, a second endplate and a core between the endplates, wherein the first conformable endplate partitions the core from the boney vertebral endplate, whereby the core does not contact the boney vertebral endplate. The invention is also directed to a method of replacing an intervertebral disc. The method includes removing at least a portion of an intervertebral disc to form an intervertebral disc space, implanting a first conformable endplate, into the intervertebral disc space and in contact with a first honey vertebral endplate, the first conformable endplate being conformable to the first boney vertebral endplate under an anatomical load; implanting a second endplate into the intervertebral disc space and in contact with a second boney vertebral endplate; and implanting a core between the first conformable endplate and the second endplate, wherein the first conformable endplate partitions the core from the first boney vertebral endplate, whereby the core does not contact the first boney vertebral endplate.

An orthopaedic prosthetic component is provided. The orthopaedic prosthetic component comprises a porous three-dimensional structure shaped to be implanted in a patient's body. The porous three-dimensional structure comprises a plurality of unit cells. At least one unit cell comprises a first geometric structure having a first geometry and comprising a plurality of first struts, and a second geometric structure having a second geometry and comprising a plurality of second struts connected to a number of the plurality of first struts to form the second geometric structure.

The present invention pertains to an implant for treatment of a bone lesion site, the implant including a polymer porous film and a layer containing a biocompatible material, wherein the polymer porous film is a polymer porous membrane of a three-layer structure having a porous surface layer A, a porous surface layer B, and a macrovoid layer interposed between the surface layer A and the surface layer B; the average pore diameter of the pores in surface layer A is smaller than the average pore diameter of the pores in surface layer B; the macrovoid layer has a partition joined to the surface layers A and B and a plurality of macrovoids enclosed by the partition and the surface layers A and B; and the pores in the surface layers A and B communicate with the macrovoids.

The present invention relates generally to a prosthetic spinal disc for replacing a damaged disc between two vertebrae of a spine and methods for inserting said discs. The intervertebral prosthetic discs are provided with connections for facilitating implantation and removal and features which enhance primary and secondary stability over time.

A modular acetabular cup assembly includes an acetabular cup, and a liner seated in the cup. The cup includes an end face, an apex opposite the end face, and a central axis extending between the apex and a center point of the end face. The liner includes an articular surface having a center of rotation which defines a pivot point of the acetabular cup assembly. In certain embodiments, the pivot point is laterally offset from the center point such that the end face is located between the pivot point and the apex.

The present disclosure relates to a system for augmentation of a tibial component. The system includes an augmentation component having a first porous structure, a second porous structure, a top portion having a top surface, and a bottom portion having a bottom surface arranged opposite the augmentation component from the top surface. The system also includes a tibial component and an instrument, with the tibial component being configured to couple to the augmentation component. The instrument includes an engagement portion having a geometry complimentary to that of the augmentation component. Further, a method of augmenting a tibial component is disclosed with the steps of collecting imaging data from a patient, identifying a void in the distal tibia, obtaining an augmentation component that corresponds to the void, coupling the augmentation component to the tibial component and implanting the tibial component into the tibia so the augmentation component occupies the tibial void.

A unitary intervertebral device, having no moving components is provided for non-fusion articulation and fusion applications. The interbody articulating device allows for limited flexion and rotation between the implant and an adjacent vertebra, helping to preserve or restore near-normal motion between adjacent vertebrae. Rotational motion is achieved through one or more protrusions incorporated into the spinal interbody device. In one articulating form, a first protrusion extends perpendicularly from one bearing surface of the interbody device to form a rotational protrusion, while at least a second protrusion extends from the opposite bearing surface of the interbody device to form a non-rotational protrusion. In another form, a single protrusion extends axially from one bearing surface of the interbody device to form a spike or anchoring, rotating protrusion, while the opposite bearing surface may be slightly rounded and/or comprising a bone-ingrowth promoting surface. Similarly configured fusion salvage devices are also described.

A mobile cage system for restoring motion kinematics of the spine featuring a pair of opposing caps that form a cavity and a nucleus disposed in the cavity. The system allows for motion of the caps relative to the nucleus. The mobile cage system provides sufficient support so as to eliminate the need for incorporation of a metal plate or rod and pedicle screws that may be used for spinal fusions. The mobile cage system of the present invention also prevents vertical collapse of the vertebrae and complete bone fusion, and the mobile cage system helps preserve intervertebral motion of the spine.