The present invention provides a fixation device that includes an elongate shank defining a longitudinal axis and having at least one engaging member for applying the fixation device within tissue and securing the fixation device in the tissue once implanted formed thereon, and a drive head having a proximal end, a distal end and a radial cross-sectional geometry, where the drive head is mated to the elongate shank, and includes at least one anti-rotational member integral therewith, Fixation device kits utilizing the fixation device, and methods of fixation in tissue are also provided.

A positioning mark apparatus of a surgery navigation system and an implementation instrument thereof are disclosed. The positioning mark apparatus includes a positioning base and a frequency modulated radio frequency positioning module. One end of the positioning base is a lock portion having a screw structure, another end is a head having a joint structure, and a free end of the head has a fitting structure. The frequency modulated radio frequency positioning module has a sleeving structure that cooperates with the head structure and buckles with the joint structure. The frequency modulated radio frequency positioning module includes an antenna unit, a printed circuit board unit electrically connected to the antenna unit, and an electronic component battery unit supplying power to the printed circuit board unit. The frequency modulated radio frequency positioning module may transmit, according to a received frequency modulated signal, a feedback signal including a radio frequency signal to the external.

A spinal implant system comprises a plate including a surface that defines a first cavity and a second cavity. The first cavity is oriented to implant a multi-axial fastener with a sacrum. The second cavity is oriented to implant a fastener with an ala of a sacrum. A surgical instrument is engageable with the plate. At least one of the plate and the surgical instrument includes an engagement surface for connection therebetween. Systems and methods of use are disclosed.

A fastener assembly can include a proximal fastener member, a distal fastener member and an internal fastener member. The proximal fastener can include a fastener head and an internal wall defining an anti-rotation feature. The distal fastener can include a proximal end defining an internal bore and an external anti-rotation feature, and a distal end defining a bone anchor. The internal fastener can be positioned in the cannulated proximal fastener and threadably coupled to the distal fastener such that the proximal end of the distal fastener is telescopically received in a distal end of the proximal fastener. Rotation of the internal fastener in a first rotational direction can telescopically retract the distal fastener into the proximal fastener so as to be adapted to compress a bone fracture. Rotation of the internal fastener in an opposite rotational direction can extend the distal fastener relative to the proximal fastener.

Provided is a human bone treatment unit. The human bone treatment unit is used to treat human bones, and includes: a main body part that passes through a human bone and a treatment rod and is then fastened to the bone; and a head part for enabling coupling between the bone and the treatment rod by means of an external force applied from the outside, wherein the head part is integrally formed with the main body part, provided with an engagement recess having a non-circular cross-section which is engaged with a screwdriver for creating the external force, and has an engagement surface having a non-circular cross-section that makes it possible to be additionally engaged with the screwdriver in a state in which the engagement between the screwdriver and the engagement recess is not possible.

A sterilizable disposable surgical instrument is formed by an implant for bone fusion as well as an implant sleeve surrounding the implant for bone fusion. The implant has a distal implant section, a proximal implant section, and a coupling section with a polygonal cross-section profile between the distal and proximal implant section. The implant sleeve has a protective cap and a handle, which can be connected to one another. A first bore is configured in the protective cap in the longitudinal direction and receives the proximal implant section of the implant. A second bore is configured in the handle running in the longitudinal direction and receives the distal implant section of the implant for bone fusion. A coupling region having a through-opening is configured in the second bore in the handle, into which the coupling section of the implant for bone fusion engages in an integral and force-locking manner.

The outer periphery of a head section (11e) of a medical screw (11) is provided with an inverse external screw thread (11h) that is formed in the opposite screw direction from that of a screw thread (11b) provided to a tip section (11a). An inverse internal screw thread (14a) provided to the leading end of a rod-shaped body constituting an extraction jig (14) is rotated in the opposite direction from the screw direction of the screw thread (11b) so as to be screwed onto the inverse external screw thread (11h) and thereby integrate the screw (11) and the extraction jig (14). The screw (11) is gently extracted from the bone fracture site (D) and is removed from the body by rotating the extraction jig in the reverse direction from the insertion direction of the screw (11).

Stand alone fusion cage assemblies that can be secured to the adjacent vertebral bodies via an in-line approach that is substantially perpendicular to the anterior wall of the stand alone cage (or substantially parallel to the cage insertion direction).

A method and device for inserting screws into a patient, such that when the device is removed the device does not stick to the screw. The device, being a push-off driver, may have a handle, an inner driver, and a threaded driver sleeve having a button mechanism and a plurality of spheres, and an inner sleeve. The method includes the steps of assembling a push-off driver attaching a bone screw to the push-off driver inserting the bone screw and detaching the bone screw from the driver by unthreading the threaded driver sleeve from the polyaxial screw which causes the spheres in the recess of the inner driver to back up against the start of the recess and causing the threaded driver sleeve to push-off the polyaxial screw from the inner driver.

A bone anchor includes an anchor member including a first material, and having a tubular section extending along a longitudinal axis, a region configured to expand radially outwards from the longitudinal axis, and a bone engagement structure projecting from at least a portion of the expandable region of the tubular section, and a core member including a second material, and configured for insertion into and connection to the anchor member. When the core member is in the anchor member and is actuated relative to the anchor member, the tubular section is adjustable between a first position where the expandable region of the tubular member has a first length and a first maximum diameter, to a second position where the expandable region of the tubular member has a length shorter than the first length and a maximum diameter greater than the first maximum diameter.