A tibial trial insert system includes a bearing having a superior articulating surface and an inferior surface; a plate having a superior surface and an inferior fixation surface; a first adjustment assembly and a second adjustment assembly, each adjustment assembly arrangeable between the inferior surface of the bearing and the superior surface of the plate, and each adjustment assembly having a superior connector to engage the bearing and an inferior base to engage the plate. A plurality of shims are slidable between an inferior surface of the connector and a superior surface of the base of the first and/or second adjustment assembly to adjust a proximal/distal height of the respective adjustment assembly to adjust a proximal/distal spacing between the bearing and the plate. The first adjustment assembly allows adjustment of the spacing within a first range. The second adjustment assembly allows adjustment of the spacing within a second range.

An intervertebral implant can include a housing having a first end and second end with a top side and bottom side therebetween, with at least one engagement opening in the top side and/or bottom side, the implant having a first dimension from the top side to the bottom side; a shaft rotatably located within the housing and having a shaft head exposed through an end opening in the first end, the shaft head having a tool coupling member; the cam mechanism operably coupled with the shaft such that rotation of the shaft rotates the cam mechanism; and at least one engaging surface operably coupled to the cam mechanism such that rotation of the shaft protrudes and/or retracts each engaging surface through an engagement opening, wherein when each engaging surface protrudes through the engagement opening, the implant has a second dimension that is greater than the first dimension.

A glenoid trial and implant assembly for use in reverse total shoulder arthroplasty is provided along with a method for using the same. The glenoid trial and implant assembly includes a baseplate assembly, an adapter assembly, a glenoid trial, a glenoid implant, a humeral cup, and a positioning guide. The glenoid trial is coupled to the adapter assembly when the glenoid trial and implant assembly is assembled in a trialing configuration. The glenoid implant is coupled to the adapter assembly when the glenoid trial and implant assembly is assembled in an installed configuration. A temporary connection, which may be magnetic, releasably couples the glenoid trial to the adapter assembly and provides separation of the glenoid trial and the adapter assembly without requiring disassembly of the adapter assembly. A permanent connection fixes the glenoid implant to the adapter assembly.

A tool for locating a proper position for a portal incision for hip arthroplasty, the tool having at least one generally elongated body defining an axis, the generally elongated body having a slot at one end, the slot being angled at an approximately 45 degree angle relative to the axis of the generally elongated body, the slot configured to receive a cutting member or guide tool. A second generally elongated body may be connected to the first generally elongated body to form a right angle. If the lengths of the two generally elongated bodies are substantially equivalent, then when the second generally elongated body is inserted into the acetabulum, the first generally elongated body positions the slot in the proper location such that sliding a guide tool or cutting member through the slot allows a portal incision to be created in the proper location. In some embodiments, the generally elongated bodies may have adjustable lengths.

Spinal cage devices, systems, and methods of assembly and implanting the devices and systems are disclosed. The cage system includes a cage and at least one locking screw assembly configured to couple to the cage. The spinal cage system includes a cage with a body portion, an external plate, and a rod. The body portion includes at least one opening positioned between the first and second ends, a center opening in the first end, and at least one hole adjacent the center opening. The external plate includes an opening and at least two holes on opposite sides of the opening. The rod extends through the center opening in the cage, the first end configured to couple to the external plate, and the second end positioned in the at least one opening. Methods for assembling a spinal cage system and for implanting a cage system are also disclosed.

A tibial sample implant for use in knee joint replacement surgery has a lower part and an upper part. The upper part has a sliding surface designed to interact with a femoral component. A height adjustment mechanism can move the upper part in a guided manner relative to the lower part between a first position, in which the sliding surface is positioned at a first height above the lower part, and a second position, in which the sliding surface is positioned at a second height above the lower part. The height adjustment mechanism has a drive gear and a control cam. An output element is rotationally fixed to the upper part and has a support section supported on the control cam so that the upper part can be moved between the first position and the second position by a rotational movement of the drive gear.

According to one example, an extractor may include a main body and a coupling mechanism. The main body can include a slot configured to receive a fastener that couples the extractor to the tibial prosthesis, a groove extending to a lateral side and a medial side of the slot and a projection at least partially defining a side wall of the groove. The coupling mechanism can be connected to the main body and configured to connect with an instrument.

Systems and methods and augments for supporting an acetabular shell at a hip bone. An example system of modular augments can include first and second augments, each having a body extending from a respective first end portion to a respective second end portion. The first augment second end portion can include a first coupling element and the second augment first end portion can include a second coupling element. Together the first and second coupling elements can form a coupling mechanism to join the first and second augments together. In some examples, the coupling mechanism can include a bulbous tip portion and a recess to receive and retain the bulbous tip portion.

An expandable implant is disclosed having an adjustable height for insertion between two adjacent bony structures or joint surfaces, for example between two adjacent spinal vertebrae. The implant includes at least one gear associated with at least one threaded shaft. Rotation of the gear engages the threaded shaft to expand the implant. The implant can be inserted in a collapsed configuration and expanded in situ. The invention also provides methods for using the implant to facilitate arthrodesis or fusion of adjacent joint surfaces or spinal vertebrae.

Spinal cage devices, systems, and methods of assembly and implanting the devices and systems are disclosed. The cage system includes a cage and at least one locking screw assembly configured to couple to the cage. The spinal cage system includes a cage with a body portion, an external plate, and a rod. The body portion includes at least one opening positioned between the first and second ends, a center opening in the first end, and at least one hole adjacent the center opening. The external plate includes an opening and at least two holes on opposite sides of the opening. The rod extends through the center opening in the cage, the first end configured to couple to the external plate, and the second end positioned in the at least one opening. Methods for assembling a spinal cage system and for implanting a cage system are also disclosed.