The present invention is an implant for bone. The current implant is particularly useful in spinal surgical procedures.

A spinal distraction system, according to one aspect, includes an adjustable spinal distraction rod comprising first and second members, the adjustable spinal distraction rod configured for non-invasive elongation of the first and second members. The system includes an anchor rod configured for mounting to a bone of a subject, the anchor rod having one or more spring-biased tabs disposed at one end thereof, and a connector having first end and a second end, the first end having a receiving cup configured for detachable mounting on the anchor rod, wherein the one or more spring-biased tabs are configured to engage with an inner surface of the receiving cup, the connector having a second end operatively coupled to an end of a first member and wherein the second member is configured for mounting to a second bone of a subject.

A system, including various apparatus and methods, for surgical navigation is provided. The system is configured to track the spine of a patient by capturing images via one or more cameras. The cameras are configured to capture images of one or more arrays. The system transmits the images to a computer system. The one or more arrays are releasably secured with the spine of the patient, such as by a spine pin or a spine clamp. The system can determine the spatial position and orientation of relevant anatomical features, implants, and instruments using and processing the captured images.

To provide a bone fixation device able to firmly fix bone elements. A bone fixation device, comprising: a base section having a first space that holds a rod; a hook formed with a second space in which a bone element is accommodated together with a art of the base section; and a sandwiching part that is installed to the base section and that sandwiches the bone element which has been accommodated in the second space together with a pail of the hook, wherein the sandwiching part is shiftable allowing attachment to the bone element.

Occipital plate systems are described. The occipital plate systems include an occipital plate having an upper portion and lower portion. The lower portion can include an opening for receiving one or more lateral members therethrough. The lateral members include top and/or side apertures for receiving lateral connectors that are attached to polyaxial screw receiving members. The occipital plate systems can also include low-profile clamping arms that are operably attached to an occipital plate via an extension member and articulating joint member. The clamping arms, along with tension cables attached intermittently along its length, can be used in addition to or instead of screws and hooks to secure an occipital plate system to vertebrae.

A spinal implant configured to connect to a vertebra. The spinal implant comprises a ball and socket joint allowing poly-axial movement. The ball and socket joint includes a socket having a multiple radius tear drop geometry with a larger radius and a smaller radius, so that the ball can move freely within the larger radius of the socket until it is seated into the smaller radius of the socket upon locking of the ball and socket joint.

An instrument for spinal rotation that aligns and holds direct vertebral rotation (DVR) lever arms relative to each other to achieve an initial axial alignment of a segment of vertebrae and allows the final DVR rotation by rotating the instrument and lever arms together. A method of direct vertebral rotation that allows rotating the vertebrae to be aligned relative to each other, and collectively rotating the vertebrae to be aligned relative to adjacent spinal segments by rotating the direct vertebral rotation instrument. A system for direct vertebral rotation having at least two pedicle screws. The system also includes at least two levers attachable to the pedicle screws and a clamping instrument configured to clamp the levers.

A spinal jack adapted for installation between first and second vertebral processes and including an upper spinal jack body and a lower spinal jack body having gripping portions adapted for engaging the vertebral processes. A pair of upwardly extending sleeves are integrated into the lower spinal body and coaxially receive a pair of downwardly extending stems integrated into the upper spinal body. A pair of spring actuated and stepped pins are incorporated into the lower jack body and, when inwardly actuated, engage recessed locations configured along the stems in order to define an adjusted separation distance between the bodies. In a second variant, a rotatable gear is incorporated into one of the bodies and engages a pair of outer beveled gears, with additional gears actuated by the outer bevel gears and in turn engaging any of opposing teeth or threads configured into the extending stems in order to define an adjusted separation distance between the bodies.

Implants, systems, and methods for securing a flexible band, thereby providing a desired correction to the spine. The implant may secure the flexible band to a spinal rod and/or a pedicle screw. The implant may include a first locking member configured to secure the spinal rod and a second locking member configured to secure the band. The band may be looped around bony anatomy and tensioned to achieve correction and provide fixation as an alternative and/or supplement to pedicle screws during spinal deformity surgery.

A spinal stabilization system may include at least one pedicle screw comprising a threaded base to be connected to a superior pedicle of a vertebra and a screw head attached to the threaded base. The system may further include at least one pars interarticularis clamp comprising an elongate body defining a screw head connection point to be connected to the screw head of the pedicle screw, and a laminar hook coupled to the elongate body and configured to wrap around an edge of the lamina and compress the pars interarticularis of the vertebra when the screw head connection point is connected to the screw head.