A spinal rod connector includes first and second arm assemblies and a fastener. The first arm assembly includes a first base portion and a first head portion defining a first slot configured to receive a first spinal rod. The first base portion includes a hook and an extension member including a housing. The second arm assembly is adjustable with respect to the first arm assembly. The second arm assembly includes a second base portion including a hook, a second head portion defining a second slot configured to receive a second spinal rod, and an elongate member extending from the second base portion. The elongate member is configured to be received in the housing of the first arm assembly. The elongate member is rotatable about an axis offset from a longitudinal axis of the housing. The fastener is configured to be received in the housing to secure the elongate member.

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

Surgical instruments, methods, and systems are provided for securing spinal fixation elements to bone. For example, a spinal fixation system is provided that has a receiver with proximal and distal ends. The proximal end of the receiver is configured to receive various fixation members, such as spinal rods and set screws, therein. The distal end of the receiver has a hook member that is operably coupled thereto and has an opening that is configured to receive bone therein. The hook member is configured to be secured to bone without penetrating the bone.

Systems and methods for en bloc derotating a spinal column are provided. In one exemplary embodiment, the method can include manipulating first and second frames coupled respectively to a first set of vertebrae and a second set of vertebrae to derotate the first and second sets of vertebrae relative to one another, and subsequently locking a linkage assembly coupled respectively to the first and second frames to maintain the first and second sets of vertebrae in a derotated position.

Thoracic/lumbar and cervical spinous process staples which staple/fuse adjacent spinous processes are disclosed. Thoracic/lumbar transverse process staples which staple/fuse adjacent transverse processes are also disclosed. Each embodiment has upper and lower claws connected by a ratchet spring mechanism, along with a multiplicity of bone fastener prongs attached to the upper and lower claws. Two sets of prongs on each staple claw are spaced by a distance approximately equal to the distance separating adjacent spinous or transverse processes so as to facilitate stapling/fusion of two adjacent processes. Also disclosed are staple prongs with multiple perforations which enable incorporation of bone fusion material thereby facilitating stapling/fusion of spinal elements.

A screw-clamp apparatus is disclosed that may include a first clamp component comprising a first attachment end and at least one hook on a first hook end, a second clamp component comprising a second attachment end and at least one hook on a second hook end, a bone-screw hole located in one of the first clamp component and the second clamp component, a bone screw configured to be inserted through the bone-screw hole and to be inserted into bone, a first spacer-receiver located on one of the first clamp component and the second clamp component, and a length adjusting mechanism configured to adjust a longitudinal length of the screw-clamp apparatus. The first attachment end and the second attachment end are configured to attach the first clamp component and the second clamp component together. The first spacer-receiver is configured to secure a spacer.

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.

The present disclosure relates to an interspinous omnidirectional dynamic stabilization device, including a first fixing part, a second fixing part, a connecting structure and an elastic structure. The first fixing part and the second fixing part are fixedly connected to each other through the connecting structure and elastic structure. The bottoms of the first fixing part and the second fixing part are provided with one or more barbs. The elastic structure is made up of one or more U-shaped structures connected to each other. The first fixing part and the second fixing part are provided with fixing holes respectively.

A device and method for use which stabilizes a target motion segment of the spine without the use of screws or any form of hardware implanted into the vertebrae. By being comprised of modular segments and assembled onto the target motion segment at the time of implantation, it can be provided in kit form designed for each patient. The stabilization apparatus general comprises elements; one is adjustably secured to the posterolateral aspect of the caudal vertebra of the target motion segment, with another element being secured to the base of the spinous process of the cranial vertebra of the target motion segment. These two elements are then coupled to each other by either an elongated rod-like connecting element, or extensions from the two anchoring elements which then couple.

A system of devices and methods for use by which one or more target motion segments of the cervical spine are stabilized without any violation of the cortical bone of the target vertebrae. The devices are brought against strategic aspects of these vertebrae, thus permitting the disclosed inventions to achieve secure control of each vertebra. Connecting elements then stabilize the constructs. Preferred and alternative embodiments of the invention are disclosed, along with methods of implantation, and adjunct devices used in the implantation of the disclosed invention.