The invention relates to a system and method for driving orthopedic bone screws. In one aspect the driver includes a powered driving rod that is configured to releasably couple with a recess in a bone screw via a threaded system for coupling and uncoupling the screw from the driving rod.

Intramedullary nails, aiming guide assemblies, and methods. The aiming guide assembly can include an aiming guide having a collet and a connection bolt configured to engage a connection bolt driver. The connection bolt may be self-retaining and engage with the connection bolt driver in a manner to prevent unintentional disengagement.

A bone fixation device for treatment of a bone fracture includes a fixation screw defining a transverse opening, a fixation arm configured for inserting the fixation screw through a bone fracture, a set screw, and an aiming arm configured for inserting the set screw into the transverse opening and engagement with the fixation screw. The set screw stabilizes the fixation screw.

A surgical tool, comprising a needle comprising an aperture of sufficient diameter for receiving a screw; a tool, insertable into said aperture for inserting said screw and capable of engaging with and turning the screw; said screw comprising a shaft having threads in a first direction, a head having a bottom face having a flange, and a coil; said coil wound around the screw shaft in an opposing second direction as to the first direction; said coil comprising a coil end which is defined to engage with the flange on the bottom face.

A compression screw for applying compression at a bone joint. The compression screw includes an axial screw body extending from a distal end to a proximal end with the distal end including a series of bone engaging threads configured to be self-drilling and self-tapping and the proximal end including a head which defines a radially extending shoulder. At least one proximal rotary cutting structure is defined proximally of the bone engaging threads. The at least one proximal rotary cutting structure is configured to be self-drilling such that a proximal portion of the axial screw body cuts into and advances within a bone of the bone joint as the axial screw body is advanced. A method of inserting the compression screw is also provided.

Disclosed is a system (100) for inserting an adapter. The system can include a docking station (104) and an adapter inserter (102). The docking station can include a handle block (108), a push assembly, and a linkage (320) connecting knob push handle (120) to an engagement tube pull block (324). The engagement tube pull block (324) can extend from the linkage through a portion of the handle bock. The adapter inserter (102) can include a handle body (112), an engagement assembly (116), and a clamp (412). The handle body can be sized to fit in a first recess (110) defined by the handle block body. The engagement assembly (116) can extend from a second end of the handle body (112) and can be configured to engage the adapter (132) at a tip of the engagement assembly. The clamp (412) can be located within and proximate a second end of the handle body so as to engage a portion of the engagement assembly.

A modular bone fixation implant includes a center post having exterior bone engaging features and configured to be implanted within a bone. The center post includes an aperture at an outer end of the center post. One or more interchangeable modular components may be placed within the bone and anchored to the aperture of the center post. Interchangeable modular components may include staples, bone plates, and spacers, each having at least a first end including a post engaging arm sized and shaped to seat within an interlocking feature of the aperture. A locking screw is provided to anchor all components to the center post when the interchangeable modular components have been placed.

An insertion guide for guiding a fastener having a head and a shaft. The insertion guide includes a sidewall constructed of a biocompatible material having an entrance end, an exit end, and a cavity extending from the entrance end to the exit end. The sidewall has a guide portion and a fastener connector portion. The guide portion of the sidewall extends from the entrance end toward the exit end, and the fastener connector portion of the sidewall extends from the exit end toward the guide portion. The sidewall in the guide portion is configured such that the cavity has a first cross-sectional distance greater than the head of the fastener. The sidewall in the fastener connector portion has a second cross-sectional distance greater than the shaft, and less than the head.

The present disclosure relates to an anchor. The anchor includes a suture bridge having a proximal end and distal end. The distal end of the suture bridge has a thickness greater than a thickness of the proximal end of the suture bridge. At least two ribs extend from the proximal end of the suture bridge to a proximal end of the anchor. At least one open helical coil wraps around the at least two ribs and extends, substantially, from the proximal end of the suture bridge to the proximal end of the anchor. The at least one open helical coil defines an internal volume communicating with a region exterior to the anchor through apertures between turns of the at least one open helical coil. The at least two ribs are engagable with a grooved shaft of a driver.

Driver instruments and related methods are disclosed herein, e.g., for applying a fastener to a bone anchor. Various features are disclosed for retaining the fastener to the driver instrument, such as tapered drive tips, as are various features for impacting the driver instrument into the fastener, such as slidable slap-hammer type handles. Driver instruments with interchangeable handles or handle geometries that can be changed without separating the instrument from an attached fastener are also disclosed.