A humeral head implant system includes a head component including a first articulating surface, a second bottom surface extending from the first spherical articulating surface, a first cavity extending a first distance into the head component from the second bottom surface, and a second cavity extending into the head component along a cavity axis. The head component defines a head axis extending through a center of the first articulating surface parallel to the cavity axis. A base component defines a slot extending from a first width to a second width. An insert component includes an insert body, a first engagement feature, and a slot engagement feature. The first engagement feature is received in the second cavity along the cavity axis. The insert body has an insert thickness less than the first distance, and the slot engagement feature slides into the slot in a direction transverse to the cavity axis.

A surgical apparatus configured to be placed in the musculoskeletal system to precisely separate a first bone from a second bone. The surgical apparatus has one or more sensors to measure one or more parameters and supports one or more bone cuts for installing a prosthetic component. The surgical apparatus has three distraction mechanisms configured to increase or decrease a height between a first support structure and a second support structure. The tilt mechanism adjusts the tilt between the first support structure relative to the second support structure. The tilt mechanism of the surgical apparatus is adjusted from a first tilt to a second tilt to support a bone cut on one of the first or second bones.

A surgical apparatus comprising a first distraction mechanism, a second distraction mechanism, and a third distraction mechanism. The surgical apparatus is configured to be placed in a joint of the musculoskeletal system to precisely separate the first bone from the second bone to support one or more bone cuts for installing a prosthetic joint. The first distraction mechanism simultaneously changes a height of a first side and a second side of the joint. The change in height is equal on the first and second sides. The second distraction mechanism changes the height on the first side of the joint but not the second side. The third distraction mechanism changes the height of the second side of the joint but not the first side. The surgical apparatus further includes at least one module to measure loading applied by the joint to the surgical apparatus.

A spinal implant apparatus that is an expandable spacer including features to minimize or eliminate spacer cant or offset during and after completing the expansion process. The spacer includes a top component, a base component in engagement with the top component, and an expansion mechanism arranged to change the top component's position with respect to the base component. The mechanism for causing expansion may be a screw, a cam, a wedge or other form of distracting device. In one embodiment, the expandable spacer includes a base component with a set of towers and a top component with a set of corresponding silos, where the towers and silos are configured to minimize or eliminate tilt of the top component as it extends upwardly from the base component.

A surgical apparatus configured to be placed in the musculoskeletal system to precisely separate a first bone from a second bone. The surgical apparatus has one or more sensors to measure one or more parameters and supports one or more bone cuts for installing a prosthetic component. The surgical apparatus has at least one distraction mechanism configured to increase or decrease a height between a first support structure and a second support structure. A tilt mechanism comprises the at least one distraction mechanism. The tilt mechanism couples through a first pivot point and a second pivot point and adjusts a tilt of the second support structure relative to the first support structure. In one embodiment, loading applied to the second support structure is distributed between the first pivot point and the second pivot point during operation of the surgical apparatus.

A humeral head implant system includes a head component including a first articulating surface, a second bottom surface extending from the first spherical articulating surface, a first cavity extending a first distance into the head component from the second bottom surface, and a second cavity extending into the head component along a cavity axis. The head component defines a head axis extending through a center of the first articulating surface parallel to the cavity axis. A base component defines a slot extending from a first width to a second width. An insert component includes an insert body, a first engagement feature, and a slot engagement feature. The first engagement feature is received in the second cavity along the cavity axis. The insert body has an insert thickness less than the first distance, and the slot engagement feature slides into the slot in a direction transverse to the cavity axis.

A knee-joint endoprosthesis, which can be used for a knee-joint replacement operation, has a tibia component, a meniscus component and a screwed connection. The tibia component has a distal fastening portion and a proximal connecting portion. The distal fastening portion is configured for fastening to a proximal tibia. The meniscus component has a proximal sliding surface and a distal mating connecting portion. The proximal sliding surface is configured to articulate with a femoral joint component. The distal mating connecting portion is configured to form a joining connection with the proximal connecting portion of the tibia component. The screwed connection, which is configured for additional fixation of the joining connection, has a screw element inserted in a longitudinal bore of the meniscus component, and a mating screw element assigned to the tibia component. The screw element can be screwed to the mating screw element to form the screwed connection.

A surgeon can secure an acetabular component to an acetabular bone. The surgeon can insert a pair of anchors through a corresponding pair of holes in the acetabular component into a corresponding pair of pilot holes drilled into the acetabular bone. Each anchor is attached to a length of suture before insertion. The surgeon can tie the sutures from the anchors together, to secure the acetabular component against the acetabular bone. The surgeon can position the tied lengths of suture in a suture channel formed in the acetabular component. The suture channel can prevent the suture from interfering with a liner that contacts the acetabular component. The surgeon can repeat as needed, using multiple pairs of anchors, multiple holes and suture channels in the acetabular component, and multiple pilot holes in the acetabular bone. The surgeon can use soft anchors or screw anchors.

An implantable compensating sleeve is applied between an oblong implant section of a first implant, and a second implant that encloses the oblong implant section of said first implant. The compensating sleeve has a sheath having a sheath body and a passage, running from the proximal to the distal end of the sheath body, for receiving said oblong implant section of the first implant. The sheath body is divided, by slits which cut into the sheath body in the longitudinal direction and originate alternately from the distal and from the proximal edge of the sheath body, into meander-like segments each comprising two longitudinal arms. The sheath body is radially expandable in at least one subsection. On the inner surface of the sheath body facing the passage, at least one bulge extends in the longitudinal direction of a meander-like segment, forming an inner profile that protrudes into the passage.

An orthopedic fixation system includes an implant and an implant insertion device. The implant transitions between a natural shape and an insertion shape and includes a bridge and first and second anchoring members extending from the bridge. The first and second anchoring members each include a segment extending exterior to the bridge to provide an engagement point. The implant insertion device moves between loaded and unloaded positions. The implant insertion device in its loaded position by-passes the bridge and engages the segment of the first anchoring member at its engagement point and the segment of the second anchoring member at its engagement point such that the implant insertion device constrains the implant in its insertion shape. The implant insertion device in its unloaded position releases the implant.