An assembly for attachment to a first implant component has a size and shape of a second implant component to be implanted together with the first implant component. The assembly includes a first body and a second body removably connected to the first body. In a temporary configuration, the first and second bodies are prevented from separating while the first and second bodies permit relative movement therebetween. A modular kit includes a plurality of the first bodies each having a different size or shape, and a plurality of the second bodies each having a different size or shape. A method of assembling the assembly includes removably connecting the first body to the second body, such that the first and second bodies are prevented from separating while permitting relative movement therebetween, and positioning the assembly on the first implant component.

A temporary spacer device for a joint of the human body such as a knee joint includes a first component or femoral component, adapted to be constrained to a bone or to the femoral bone of a patient, at the joint of the human body; a second component or tibial component, adapted to be constrained to a bone or tibial bone of a patient, at the joint of the human body, and at least one stem having a proximal end, wherein the first component or femoral component and/or the second component or tibial component include at least one housing seat for the proximal end of the at least one stem, adapted to allow the inclination and/or rotation of the at least a stem with respect to an insertion axis of the proximal end into the at least one housing seat.

An expandable implant includes a top support assembly defining an upper surface configured to engage a first portion of bone, a first central aperture extending from the upper surface to an interior of the implant, and a first grid structure surrounding the first central aperture; a bottom support assembly defining a lower surface configured to engage a second portion of bone, a second central aperture extending from the lower surface to the interior, and a second grid structure surrounding the second central aperture; and a control assembly coupled to the top support assembly and the bottom support assembly and configured to control relative movement between the top support assembly and the bottom support assembly between a collapsed position and an expanded position.

An expandable implant includes a top support configured to engage a first portion of vertebral bone, a bottom support configured to engage a second portion of vertebral bone, and a control assembly coupled to the top support and the bottom support and configured to control relative movement between the top support and the bottom support. The control assembly includes a control member including a head and a body portion. The head includes a recess and the body portion includes at least one access port in fluid communication with the recess to enable delivery of fluid to an interior of the implant via the recess and at least one access port.

A steerable expandable implant including a base member, an adjustable member coupled to the base member, the adjustable member movable between a collapsed position and an expanded position, a pivot member rotatably received by the base member and configured to receive a tool such that the tool and the pivot member are rotatable relative to the base member between a first position and a second position, wherein the pivot member is translationally fixed relative to the base member, and a first control member received by the base member, wherein manipulation of the first control member causes the adjustable member to move between the collapsed position and the expanded position.

An interbody tool may include an upper portion with an upper contact surface and a plurality of upper legs; a lower portion with a lower contact surface and a plurality of lower legs, each of the lower legs moveably connected to one of the upper legs; a plurality of gauges, each gauge configured to measure a position of one of the plurality of upper legs relative to a corresponding one of the plurality of lower legs; at least one actuator configured to selectively push the upper portion away from the lower portion; and at least one sensor for measuring a force exerted by the at least one actuator.

An implant is insertable in the joint space to separate bones of the joint. The implant has two endplates each configured to engage a separate articulating bone of the joint, and a threaded member positioned between the two endplates and configured to increase the space between the two endplates when the threaded member is rotated. A rotatable gear is engaged with the threaded member, and is engageable with a rotating gear of a connected implantation tool, so that rotation of the gear on the tool causes rotation of the threaded member and expansion of the implant to separate the bones. Connector portions on the tool and the implant may be rotated together to securely engage the implant and the tool so that the gears of the tool and the implant can be rotated using an actuator outside of the body, when the implant is inside the body.

An implant is disclosed. The implant has a base including an extension arm cavity and a ratchet block cavity that intersects the extension arm cavity, an extension arm that is movably disposed in the extension arm cavity, and a ratchet block that is movably disposed between a first position and a second position in the ratchet block cavity. The ratchet block when disposed in the first position allows movement of the extension arm in an upward direction out of the extension arm cavity and blocks movement of the extension arm in a downward direction into the extension arm cavity. The ratchet block when disposed in the second position allows movement of the extension arm both in the upward direction out of the extension arm cavity and the downward direction into the extension arm cavity.

A spinal jack adapted for installation between first and second vertebral processes, including first and second inter-expandable jack halves arranged between retracted and expanded positions. Each of the jack halves further includes gripping portions adapted for engaging the vertebral processes. A worm gear mechanism provides for expanding or retracting the jack halves in order to establish a corrected adjusted orientation between the processes and includes each of stationary rotatable slave gears along with support stems with integrated worm gear interfaces for expanding the jack halves relative to each other.

An interbody tool may include an upper portion with an upper contact surface and a plurality of upper legs; a lower portion with a lower contact surface and a plurality of lower legs, each of the lower legs movably connected to one of the upper legs; a plurality of gauges, each gauge configured to measure a position of one of the plurality of upper legs relative to a corresponding one of the plurality of lower legs; at least one actuator configured to selectively push the upper portion away from the lower portion; and at least one sensor for measuring a force exerted by the at least one actuator.