An orthopedic locking screw arranged in a bore of an orthopedic implant enables easy removal of a broken locking screw out of the implant. The orthopedic locking screw for a cooperation with a thread in the orthopedic implant comprises a longitudinally extending shaft. The shaft comprises a thread pattern section extending at least partially along the shaft. The thread pattern section comprises a first thread with a first direction, which is a functional thread configured for the cooperation with the thread in the orthopedic implant. The thread pattern section further comprises a second thread with a second direction opposite to the first direction of the first thread. The second thread is superimposed on the first thread and intersects the first thread. An orthopedic locking system comprises the orthopedic locking screw and the orthopedic implant. The locking screw is manufactured by applying the thread pattern section to the longitudinally extending shaft.

Bone nail (1) with a front portion (2), suitable for insertion into the bone and having a free end (3), a rear portion (5) having a free end (6), an outer surface (4); and a nail axis (7); wherein the rear portion (5) has a through hole (8) with a central axis (12) and with an inlet opening (9) located at the rear free end (6) and an outlet opening (10) located on the outer surface (4) of the rear section (5) whereby the through hole (8) is formed for receiving a polyaxial bone screw (11).

Systems and methods for fixing bone using an intramedullary nail locked to an encircling anchor including a bushing and a locking member. An exemplary system may include any combination of the nail, one or more bushings, one or more locking members, an instrument to guide installation of the bushing, at least one drill, and a driver that attaches to the bushing. The instrument may define a guide axis and be configured to be coupled to a bone such that the guide axis extends across the bone. The instrument may be used to guide a drill, the bushing, and/or the locking member along the guide axis into the bone. The nail may be configured to be placed along the medullary canal of the bone such that the nail extends through the bushing, and the locking member may be configured to lock the nail to the bushing.

Exemplary intramedullary implant systems are provided for performing surgical procedures. The intramedullary implant systems may be used for performing bone fracture, bone fusion, or osteotomy procedures within joints.

A bone fixation system includes an intramedullary nail and a lag screw. A proximal portion of the intramedullary nail includes a first proximal bore configured to accept the lag screw and a second proximal bore configured to accept a portion of an antirotation screw insertion tool. A distal portion of the intramedullary nail defines at least one opening configured to accept a distal locking screw. The lag screw includes a sheath and a rod mounted for sliding movement within the sheath. The rod has a threaded distal end defining a diagonal bore configured to accept an antirotation screw.

A system and method for osseous fixation is a surgical hardware device that allows bone fixation for purposes of fracture repair, arthrodesis, or other types of orthopedic applications. A partially threaded wire or pin is inserted into the bone and external compression and rotational stability are achieved with a locking cap. The locking cap may include serrations or other anti-rotation features which engage bone to provide rotational stability. Upon adequate bone healing, the external cap may be used to facilitate removal of the wire/pin from the bone.

Bone compression device with a primary body (2) having a primary bone fixation pin assembly (4, 5) extending at an angle to the longitudinal axis (A), and a secondary body (3) having a secondary bone fixation pin assembly (6, 7) extending at an angle to the longitudinal axis (A). The secondary body (3) is positioned in the inner bore (2a) and moveable with respect to the primary body (2) over an adjustment range. The primary body (2) comprises a guide pin (8) and the secondary body (3) comprises a guide slot (9) having an inner guide slot (9a), the guide pin (8) extending through the guide slot (9) and in contact with the inner guide slot (9a) during operation. An adjustment assembly (10) is provided which is connected to the primary body (2) and secondary body (3) for mutual adjustment thereof along the longitudinal axis (A).

A method for securing a fractured bone includes inserting an intramedullary nail into an intramedullary canal of the bone; driving a bone screw into the bone such that a head of the bone screw is anchored in a cortical region of the bone; installing a bone plate against the bone to cover the head of the bone screw with an inner surface of the bone plate; and driving a plate screw through a plate hole of the bone plate into the underlying bone.

A bone fixation system includes an intramedullary nail and a lag screw. A proximal portion of the intramedullary nail includes a first proximal bore configured to accept the lag screw and a second proximal bore configured to accept a portion of an antirotation screw insertion tool. A distal portion of the intramedullary nail defines at least one opening configured to accept a distal locking screw. The lag screw includes a sheath and a rod mounted for sliding movement within the sheath. The rod has a threaded distal end defining a diagonal bore configured to accept an antirotation screw.

An intramedullary nail may include a shank with a centerline defined along a length thereof. The intramedullary nail may also include a channel with a channel axis transverse to the centerline. The channel may have an obround shape in a first cross-sectional plane perpendicular to the channel axis at the centerline and a tapered profile in a second cross-sectional plane containing the channel axis. A proximal edge of the channel within the second cross-sectional plane may form a first angle relative to the channel axis and a distal edge of the channel within the second cross-sectional plane may form a second angle relative to the channel axis that is different from the first angle.