Abstract: A composite screw preferably made of a metallic pin embedded in a polymeric tubular structure having the outwardly facing threads, wherein the metallic pin comprises a screw head, an intermediate shaft and a screw tip, and the polymeric threaded tube is either molded onto the metallic shaft or the threaded is machined after molding a polymeric structure onto the shaft.

Abstract: Various methods and devices are provided for stabilizing the posterior elements of the spine, and more preferably methods and devices are provided for sharing the load with the intervertebral disc, the facet joints, the ligaments, and the muscles of the spinal column. In certain exemplary embodiments, methods and devices are provided for substantially controlling or providing resistance to movement, e.g., flexion, extension, lateral bending, and/or axial rotation, of the adjacent vertebrae.

Abstract: A posterior dynamic spinal stabilization system having a sock or sleeve as the ligament to join a split rod so that during flexion, the ligament becomes taut to create an elongation limit, and during extreme extension, the upper and lower bumpers come together, thereby preventing further extension.

Abstract: A spinal pedicle rod comprising an internally reinforced polymeric core that is at least partially encased within at least one polymeric coating.A dynamic stabilization device for bones in which flexible rods are combined with a pair of dynamic anchoring devices comprising i) a shank for anchoring into a bone or a vertebra, ii) a head connected to the shank, iii) a receiving part for the head and iv) a mobile element acting on the head.

Abstract: A flexible rod for use in spinal stabilization having a tube having a helical slit defining a gap and an elastomeric jacket provided in the throughbore of the tube, within the gap, and upon the outer surface of the tube.

Abstract: This invention relates to an intervertebral motion disc having two opposing endplates, a central articulating core, and a peripheral helical shock absorber.

Abstract: The present invention relates to a dynamic stabilization system (DSS) having at least one rod having a ring formed therein (“the spring”) and a pair of pedicle screws adapted for fixation to separate vertebrae.

Abstract: An intervertebral disc prosthesis comprises a first endplate, a second endplate, and a bearing surface positioned between the first endplate and the second endplate. The bearing surface may be provided by a mobile bearing disc including a convex bearing surface configured to engage the first endplate and a concave bearing surface configured to engage the second endplate. The multiple bearing surfaces of the mobile bearing disc engage articulating surfaces on the endplates to form a plurality of articulating joints. Each articulating joint is configured to facilitate a particular type of movement for the segmental unit. Furthermore, each articulating joint is defined by a distinct center of rotation. The contact pair formed by the convex bearing surface of the bearing component and the concave bearing surface of the first endplate may provide a flexion/extension center of rotation for the prosthesis.

Abstract: A motion disc having an intermediate portion including a central articulating core component adapted to maintain the proper intervertebral spacing and a peripheral shock-absorbing component.

Abstract: An intervertebral disc prosthesis comprises a first plate designed for attachment to an upper vertebra and a second plate designed for attachment to a lower vertebra. A prosthesis core is positioned between the first plate and the second plate. At least one spring is connected between the first plate and the second plate. The spring comprises a U-shaped torsion bar including a first leg and a second leg. The first leg of the U-shaped torsion spring is attached to the first plate and the second leg is attached to the second plate. The spring provides a selected amount of resistance to movement of the first plate relative to the second plate. In one embodiment, the selected resistance is provided by the attachment locations of the spring to the plates. In another embodiment, the selected resistance is provided by a predetermined spring rate of the springs of the prosthesis.

Abstract: Various methods and devices are provided for stabilizing the posterior elements of the spine, and more preferably methods and devices are provided for sharing the load with the intervertebral disc, the facet joints, the ligaments, and the muscles of the spinal column. In certain exemplary embodiments, methods and devices are provided for substantially controlling or providing resistance to movement, e.g., flexion, extension, lateral bending, and/or axial rotation, of the adjacent vertebrae.

Abstract: Various methods and devices are provided for stabilizing the posterior elements of the spine, and more preferably methods and devices are provided for sharing the load with the intervertebral disc, the facet joints, the ligaments, and the muscles of the spinal column. In certain exemplary embodiments, methods and devices are provided for substantially controlling or providing resistance to movement, e.g., flexion, extension, lateral bending, and/or axial rotation, of the adjacent vertebrae.

Abstract: Various methods and devices are provided for stabilizing the posterior elements of the spine, and more preferably methods and devices are provided for sharing the load with the intervertebral disc, the facet joints, the ligaments, and the muscles of the spinal column. In certain exemplary embodiments, methods and devices are provided for substantially controlling or providing resistance to movement, e.g., flexion, extension, lateral bending, and/or axial rotation, of the adjacent vertebrae.

Abstract: Various methods and devices are provided for stabilizing the posterior elements of the spine, and more preferably methods and devices are provided for sharing the load with the intervertebral disc, the facet joints, the ligaments, and the muscles of the spinal column. In certain exemplary embodiments, methods and devices are provided for substantially controlling or providing resistance to movement, e.g., flexion, extension, lateral bending, and/or axial rotation, of the adjacent vertebrae.

Abstract: A spinal anchor assembly for securing a fixation element includes an anchor element and a twist-in cap. The anchor element is configured for attachment to a bone, typically by comprising a mono- or polyaxial screw or hook, and includes a proximal portion having an open slot for receiving the fixation element and having radially inwardly protruding flange segments. The twist-in cap is received in and closes the open slot. The proximal portion of the anchor and the cap are adapted to twist-lock together by a partial rotation of the cap from an open position to a closed position to cover the slot so as to capture the fixation element and to lock the cap in the closed position.

Abstract: A posterior stabilization device is provided for controlling movement between adjacent vertebrae. In one exemplary embodiment, the stabilization device can include one or more joints that rely on rotational or sliding movement to allow flexion of adjacent vertebrae, and that control extension, lateral bending, axial rotation, and anterior-posterior shear, preferably by providing one or more flexible connectors and/or a flexible central spacer for connecting to the adjacent superior and inferior vertebrae.

Abstract: The present invention provides various methods and devices for mating spinal fixation elements, such as fixation rods, to various spinal anchoring devices, such as plates, hooks, bolts, wires, and screws. In an exemplary embodiment, an implantable spinal connector is provided having a clamp member with top and bottom portions that are connected to one another at a terminal end thereof, and that are adapted to seat a spinal fixation element there between. The top and bottom portions are preferably movable between an open position in which the top and bottom portions are spaced a distance apart from one another, and a closed position in which the portions are adapted to engage a spinal fixation element positioned there between. The connector can also include a bore extending through the top and bottom portions for receiving a locking mechanism that is effective to lock the top and bottom portions in the closed position to retain a spinal fixation element there between.

Abstract: A spinal anchor assembly for securing a fixation element includes an anchor element and a twist-in cap. The anchor element is configured for attachment to a bone, typically by comprising a mono- or polyaxial screw or hook, and includes a proximal portion having an open slot for receiving the fixation element and having radially inwardly protruding flange segments. The twist-in cap is received in and closes the open slot. The proximal portion of the anchor and the cap are adapted to twist-lock together by a partial rotation of the cap from an open position to a closed position to cover the slot so as to capture the fixation element and to lock the cap in the closed position.

Abstract: A bone screw is provided having a head adapted to mate with a driver tool, and a shank formed from first and second helical threads that extend distally from the head around a core. The core defines a minor diameter which, along at least a portion of the shank, is preferably equal to or less than a thickness of the threads between the proximal and distal facing flanks. The bone screw is particularly advantageous in that the shape of the threads provides a high pullout strength, and results in a relatively small core diameter, thereby reducing or eliminating the risk of damage to the bone. The small core diameter also provides a sufficiently flexible screw with an adequate bending strength to handle forces acting on the screw, and to prevent breakage of the screw or the screw head.

Abstract: This invention relates to an intervertebral motion disc having an articulation interface and a locking interface.