The present disclosure provides a provisional tibial prosthesis system for a set of prosthetic knee joints for implantation in a natural knee, the provisional tibial prosthesis system including a bearing component and a bearing support, the spacing of the bearing component from the bearing support is adjustable to allow for representation of a variety of different sized final tibial prostheses. In this system, only one provisional bearing component corresponding to each level of constraint is needed and shims are used to adjust the spacing of the bearing component from the beating support. The shims are slidably insertable between the bearing component and the bearing support in an anterior/posterior direction to allow for adjustment of the spacing of the bearing component from the bearing support. The number of provisional components needed during knee surgery is reduced and adjustment of the system only requires the knee joint to be distracted by a distance equal to the height of a particular shim.

A spinal implant includes a first member having a wall that defines an axial cavity. A second member extends between a first end and a second end and defines a longitudinal axis. The second member is configured for disposal with the axial cavity and translation relative to the first member. A third member has an outer surface engageable with tissue and an inner surface disposed to dynamically engage the first end in response to the engagement of the outer surface with the tissue. Systems and methods are disclosed.

A spinal implant includes a first member having a wall that defines an axial cavity. A second member extends between a first end and a second end and defines a longitudinal axis. The second member is configured for disposal with the axial cavity and translation relative to the first member. A third member has an outer surface engageable with tissue and an inner surface disposed to dynamically engage the first end in response to the engagement of the outer surface with the tissue. Systems and methods are disclosed.

An example expandable interbody device can include a structural body having an upper endplate and a lower endplate. The device can include at least one wedge block and at least one linkage block arranged between the upper and lower endplates. The linkage block can include a plurality of linkages and a shear pin disposed at a respective proximal end of each of the linkages. The device can include a drive screw extending through the wedge and linkage blocks. The drive screw can be configured to rotate and drive the wedge block to expand the upper and lower endplates of the structural body from the closed position to an intermediate position. Additionally, the drive screw can be further configured to rotate and drive the linkage block to expand the upper and lower endplates of the structural body from the intermediate position to an open position.

An interspinous spacer that includes a body having a distal portion and a proximal portion; an actuator at least partially disposed in the body; and a first arm and a second arm, where the first and second arms are rotatably coupled to a distal portion of the body and coupled to the actuator, where the actuator, first arm, and second arm are configured, upon rotation of the actuator in a first direction, to move the first and second arms from an implantation position, in which the first and second arms extend from the distal portion of the body back toward the proximal portion of the body, to a deployed position, in which the first and second arms extend away from the body.

An interlocking reverse hip prosthesis including an acetabular cup having an opening in the central portion of the cup being implanted in the acetabular cavity. The opening has a circular extending wall protruding into the concave portion of the cup a distance at least equal to the diameter of the opening. The inward extension of the cup provides a female Morse taper suited for receiving the male Morse tapered post of the acetabular ball. After implantation of the acetabular cup, the surgeon can easily secure the cup to the acetabular bone using several screws without the interference of the central peg (as in prior implants). The femoral ball is then attached to the cup via central Morse taper.

An example expandable interbody device can include a structural body having an upper endplate and a lower endplate. The device can include at least one wedge block and at least one linkage block arranged between the upper and lower endplates. The linkage block can include a plurality of linkages and a shear pin disposed at a respective proximal end of each of the linkages. The device can include a drive screw extending through the wedge and linkage blocks. The drive screw can be configured to rotate and drive the wedge block to expand the upper and lower endplates of the structural body from the closed position to an intermediate position. Additionally, the drive screw can be further configured to rotate and drive the linkage block to expand the upper and lower endplates of the structural body from the intermediate position to an open position.

A spinal implant includes a first member having a wall that defines an axial cavity. A second member extends between a first end and a second end and defines a longitudinal axis. The second member is configured for disposal with the axial cavity and translation relative to the first member. A third member has an outer surface engageable with tissue and an inner surface disposed to dynamically engage the first end in response to the engagement of the outer surface with the tissue. Systems and methods are disclosed.

A spinal implant includes a first member having a wall that defines an axial cavity. A second member extends between a first end and a second end and defines a longitudinal axis. The second member is configured for disposal with the axial cavity and translation relative to the first member. A third member has an outer surface engageable with tissue and an inner surface disposed to dynamically engage the first end in response to the engagement of the outer surface with the tissue. Systems and methods are disclosed.

An example expandable interbody device can include a structural body having an upper endplate and a lower endplate. The device can include at least one wedge block and at least one linkage block arranged between the upper and lower endplates. The linkage block can include a plurality of linkages and a shear pin disposed at a respective proximal end of each of the linkages. The device can include a drive screw extending through the wedge and linkage blocks. The drive screw can be configured to rotate and drive the wedge block to expand the upper and lower endplates of the structural body from the closed position to an intermediate position. Additionally, the drive screw can be further configured to rotate and drive the linkage block to expand the upper and lower endplates of the structural body from the intermediate position to an open position.