The invention relates to a screw (1), preferably a bone screw, comprising a shaft (2) with a tip (3), a head (4) and a thread (5). The shaft further comprises a longitudinal axis (A). An array of radial cross-sectional surfaces (Q) of the head (4) extend through the longitudinal axis (A) of the screw (1), the location of each radial cross-sectional surface (Q) being defined by an azimuth angle (6) in a plane (E) perpendicular to the longitudinal axis (A). Each radial cross-sectional area (Q) has an area defined by the longitudinal axis (A) and the outer surface of the screw (8). The thread (5) extends into the head (4) in such a way that the surface areas of the radial cross-sectional surfaces (Q′) in a first azimuth angle range (9) are constant and the surface areas of the radial cross-sectional surfaces (Q″) in a second azimuth angle range (10), which is different from the first, have a different, preferably smaller, value than the surface areas in the first azimuth angle range (9). The first azimuth angle range (9) is at most 350°, preferably at most 345°.

A surgical fixation system includes at least one anchoring element with an anchoring portion for anchoring to a bone and with a receiving portion for a stabilization element for connecting to a further anchoring element. The stabilization element is arrangeable and fixable in the receiving portion with a fixing element. The fixation system includes an abutment element arranged on the receiving portion. The receiving portion abuts against the anchoring portion for the placement of the stabilization element. The abutment element has at least one deformation region for deforming in dependence on a fixing force of the fixing element acting on the stabilization element.

Devices, systems, and methods of bone stabilization. The bone stabilization system includes a bone plate having an upper surface and a lower surface configured to be in contact with bone, the bone plate having an opening extending from the upper surface to the lower surface. The opening is configured to receive a fastener, which may be either a locking fastener or a compression fastener. The locking fastener has a threaded head portion configured to engage and lock to the bone plate, and the compression fastener is configured to dynamically compress the bone.

A locking fixation device for treating extra-articular fractures includes a connector assembly connected to two end plates. Rotation of the connector assembly about an axis extending therethrough converts rotational motion to linear motion, and advances the end plates in a linear direction away from (lengthening) or toward (compression) each other.

A bone screw fixation system includes a bone screw body having a screw head at one end of the screw and a screw tip at an opposite end of the screw, the screw head having an internal complex geometric shaped drive and internal threads within the screw head; and a screw inserter compatible with the screw head and having a complex geometric shaped drive configured to matingly engage the internal complex geometric shaped drive of the screw head and a threaded tip configured to thread into the internal threads of the screw head.

The present application relates to a spherical bead (30) to be interposed between a locking bone screw head (2) and a receiving hole (34) in a bone plate (10) and to an implant construct comprising such a bead.

A reverse shoulder system can include, for example, a glenoid baseplate comprising a longitudinal axis, the glenoid baseplate further including a stem and a central channel within a sidewall of the stem. The stem can include a longitudinal axis. The longitudinal axis of the glenoid baseplate can be angled with respect to the longitudinal axis of the stem, wherein the longitudinal axis of the glenoid baseplate is not perpendicular with respect to the longitudinal axis of the stem. Other components including a glenosphere, tools, and methods of use are also disclosed.

A surgical technique can be performed utilizing a detachable driver-implant system and comparatively small surgical incision. The clinician can make an incision through the skin of the patient and retract the skin along the incision to expose a first bone region. The clinician can insert an implant into one or more bone portions using a detachable driver-implant system and then detach the driver, leaving the implant in the one or more bone portions. The clinician can reposition the skin of the patient at least partially over the end of the implant to expose a second bone region not exposed while the first bone region was exposed. After optionally performing one or more surgical steps on second bone region, the clinician can reposition the skin to again expose the first bone region. The clinician can then reattach the driver to the implant and remove the implant from the bone portions.

A bone stimulator (30,40,50,610,810,910), a bone stimulation system (200,600,800, 900) and method for bone fracture healing of a broken bone (930,830,630,55) in a body, which can speed up the healing rate. Accordingly, ultrasound (214) is used by the present system to power up the implanted bone stimulator (30,40,50,610,810, 910) for generating a stimulating electric current passing through a broken area (931, 831,631,56) in the broken bone (930,830,630,55) for bone fracture healing.

A clamp assembly for orthopedic use having a housing that includes a top surface, a recess, a distal base and a bottom surface, the recess defining a longitudinal axis and extending through the housing from the top surface through the distal base and toward the bottom surface, and at least two through slots, each one of being disposed at a bottom or a side a surface of the housing. The assembly including a securement assembly positionable within the recess in a co-axial relationship to a mating surface on the recess, and a band sized for travel along a predetermined path defined in part by the through slots in the housing, wherein at least one of the through slots is a starting point for travel of the band along the predetermined path.