A spinal stabilization system having a pedicle screw which includes (i) a shaft with external threads and a head segment on one end of the shaft; (ii) a first drive socket positioned in the head segment; (iii) a second drive socket on a shaft end opposite the first drive socket; and (iv) wherein the shaft end opposite the first drive socket has a lesser diameter than the shaft end at the head segment. The system further includes an intervertebral stabilization structure having an elongated body with rotating ring segments attached to each end of the elongated body.

A spinal correction system for implantation in a patient, the system including a reciprocating adjuster and/or a resistance adjuster coupled to a stabilizing member, for example. The resistance adjuster includes a potential energy drive, a slide unit, and a resistance unit. The reciprocating adjuster includes a piston unit, a transfer unit coupled to the piston unit, and a return mechanism.

A spinal construct includes at least one body including a first biasing member engageable with a longitudinal element for translation thereof relative to the body in a first direction. A second biasing member is engageable with a lock. The lock is connected with the longitudinal element to resist and/or prevent translation of the longitudinal element relative to the body in a second direction. Implants, surgical instruments, systems and methods are disclosed.

A method for treating a spinal disorder includes the steps of: disposing an expandable spinal construct in a selected configuration; fixing the spinal construct in the selected configuration with a member; attaching a first end of the spinal construct with tissue; attaching a second end of the spinal construct with tissue; and disengaging the member from the spinal construct to release the spinal construct from the selected configuration. Implants, surgical instruments, systems and methods are disclosed.

A spinal construct comprises a connector defining a longitudinal axis and extending between a first end and a second end. The connector defines a cavity and includes a member that is selectively disposable in the cavity at one of a plurality of positions between the ends. A first longitudinal element is dynamically movable within the cavity and engageable with the member to limit movement in a first axial direction. The first longitudinal element is connectable with vertebral tissue. A second longitudinal element is disposable within the cavity and connectable with vertebral tissue. Systems and methods are disclosed.

The present invention provides for a joint fixation device and method utilizing magnetic members with at least one magnetic member positioned on each of opposite sides of a joint and secured to skeletal components. The magnetic members include at least one permanent magnet. The magnetic members can be configured to provide an attracting force or a repelling force. They can also be configured to provide a torque about the joint.

Disclosed herein are a spinal fixation assembly and method to provide adequate rigidity and support for a vertebral column without requiring additional pedicle screws and spinal rods. The spinal fixation assembly includes a spinal rod loop with multiple sides configured to be attached to a vertebral body with two or more pedicle screws. Each pedicle screw is adapted to fit at various locations along the spinal rod loop.

An improved scaffold assembly for supporting any plurality of vertebrae, each of which including an inter-vertebral disc and articular processes. A plurality of combination socket anchors and insertable bone screws with enlarged heads are affixed to varied surface locations of at least one vertebral bone. In combination with the socket anchors, a rod extends between selected anchors for providing support between successive vertebrae. The socket anchors include crimping tabs to assist in engaging the rods thereto. The rods are further constructed of a bendable material which, upon being reconfigured, provide customized and scalable support for variations in vertebral orientation. The interiors of the socket anchors exhibit concave surfaces to permit angularly adjustability of the screws during affixation thereof. The socket anchors further include locking screws for engaging the insertable bone screws and can also include bone engaging prongs extending from underside locations, as well as providing multiple length adjustable engagement of the bone screw.

A coupling assembly configured to couple a surgical screw to another coupling assembly and another surgical screw is disclosed. The coupling assembly comprises a body that includes a receptacle configured to receive a head portion of the surgical screw and hold the head portion through an interference fit. The body further includes either a female member, a male member, or both, the female member and the male member configured to mate with a female member and a male member of the other coupling assembly and thereby join the coupling assembly to the other coupling assembly. Embodiments of the coupling assembly provide for adjustment of the distance between the coupling assemblies, as well as misalignment of various axes of the coupling assembly relative to the surgical screw and the male member. Some embodiments provide fewer parts, greater flexibility during the surgical implantation, and a smaller profile than previous coupling mechanisms.

Disclosed herein are a spinal fixation assembly and method to provide adequate rigidity and support for a vertebral column without requiring additional pedicle screws and spinal rods. The spinal fixation assembly includes a spinal rod loop with multiple sides configured to be attached to a vertebral body with two or more pedicle screws. Each pedicle screw is adapted to fit at various locations along the spinal rod loop.