A prosthetic ball for use in a ball and cup joint system includes a spherical cap articulation portion defined by a first radius of curvature, and a toroidal articulation portion defined by a second radius of curvature having a circular origin such that the toroidal articulation portion is defined by a portion of the inner surface of a spindle torus.

Systems and methods for providing deeper knee flexion capabilities. In some instances, such systems and methods include a tibial component that has an asymmetrical articular plateau that includes a medial tibial condylar surface and a lateral tibial condylar surface. In some cases, at least one of the medial condylar surface and the lateral condylar surface includes a concave articulation surface having a lowest point that disposed from a posterior edge of the tibial component by between about 18% and less than about 35% of a total anteroposterior dimension of the tibial component. Other implementations are also discussed.

A super-elastic implant system and method can include: a rigid mandrel; and an implant including a main body in the shape of a tube, the main body formed of a shape set material configured to have: a stress induced martensitic phase in a deformed shape having a straight end, the deformed shape based on the main body being constrained on the mandrel, and an austenitic phase having a non-linear curve, the non-linear curve in the location of the straight end, and the austenitic phase based on the main body being removed from the mandrel.

An anchor for an implantable device for arthroplasty can include a hollow anchor body defining an interior cannula space. A slot can extend along a length of the anchor body. The slot can provide an opening from the interior cannula space to an exterior of the anchor body. The slot can have a slot width that is smaller than an internal width dimension in the interior cannula space. The anchor can also include a rounded edge at a transition between the slot and at least one of an interior surface of the anchor body or an exterior surface of the anchor body.

A process for printing a talus implant comprising the steps of scanning a joint for a damaged talus, and scanning a contralateral joint for a healthy talus. Next, the process includes obtaining dimensions for a talus based upon an initial scan and then obtaining dimensions for a talus based upon the scan of the contralateral joint. Next the process includes inverting the dimensions of the talus in the contralateral joint and then comparing the dimensions of the calculated talus with a pre-set of dimensions in a database. Next the process includes exporting a set of dimensions to a printer to print a talus implant.

Fibrocartilage implants characterized by circumferential fiber networks embedded in arcuate or torroidal scaffolds with orthogonal fiber networks embedded therein to prevent separation of the circumferential fiber networks. The fiber networks convert axial compressive forces on the scaffolds to tensile loads on the circumferential fibers. Artificial knee meniscus and vertebral disc implants are disclosed, as well as articular disc implants for joints such as the temporomandibular joint and wrist. Methods for implanting the fibrocartilage devices are also disclosed.

Systems and methods for providing deeper knee flexion capabilities. In some instances, such systems and methods include a resection block for resectioning a popliteal surface of a femur. In some cases, the resection block is configured to be seated on a distal portion of a femur. Additionally, some implementations of the resection block define a first slot that is sized and shaped to receive a cutting device. In some implementations, the first slot is defined in the resection block such that the first slot substantially aligns with a first portion of a popliteal surface of the femur when the resection block is seated on the distal portion of the femur. Other implementations are also discussed.

An orthopaedic knee prosthesis includes a tibial bearing and a femoral component configured to articulate with the tibial bearing. The femoral component includes a posterior cam configured to contact a spine of the tibial bearing and a condyle surface curved in the sagittal plane. The radius of curvature of the condyle surface decreases gradually between early-flexion and mid-flexion. Additionally, in some embodiments, the radius of curvature of the condyle surface may be increased during mid-flexion.

Systems and methods for providing deeper knee flexion capabilities. In some instances, such systems and methods include a resection block for resectioning a popliteal surface of a femur. In some cases, the resection block is configured to be seated on a distal portion of a femur. Additionally, some implementations of the resection block define a first slot that is sized and shaped to receive a cutting device. In some implementations, the first slot is defined in the resection block such that the first slot substantially aligns with a first portion of a popliteal surface of the femur when the resection block is seated on the distal portion of the femur. Other implementations are also discussed.

Apparatus and method used to reduce the movement between vertebrae or fractured bones. The implantable device can be deformed from its shape-set configuration for ease of deployment and return to a pre-set shape upon completion of deployment. The apparatus can serve to stabilize fractured bones or as a distraction device and support structure between vertebrae. Device may be made of a material with shape memory and superelastic properties which facilitate the method of implantation. The pre-set shape of the device may include dimensions/geometries which are similar to the natural curvature of the human spine or bone without the use of hinging or connection between multiple pieces. Once deployed, the device can serve to constrain the flow of bone growth material between the inside and outside of the device.