A spinal pedicle screw system includes distractions rods and has the ability to be distracted after the screws are inserted into the pedicle and maintain polyaxial motion via polyaxial joints.

Connector assemblies, systems, and methods thereof. A connector having body having a first end and a second end; a first connecting member at the first end, the first connecting member having a rod supporting member extending away from the first connector and a passage extending between the first connecting member and the rod supporting member; and a rod extending from the second end. The body and the passage extend co-axially, and a space is provided between the first end and the second end, the space being sized such that a spinal implant screw head is insertable in the space.

A facet joint replacement system includes a facet joint replacement device including an enclosing body and an articulating body. The enclosing body includes an interior surface defining an inner cavity of the enclosing body. The interior surface includes a first articulating surface and a projection extending inwardly relative to a surrounding area of the interior surface. The articulating body is positioned within the inner cavity of the enclosing body and is configured to move within the enclosing body. The articulating body includes a second articulating surface and a recess extending inwardly relative to a surrounding area of the articulating body and aligned with the projection of the interior surface of the enclosing body so as to allow movement of the projection along the recess of the enclosing body while constraining rotational motion of the articulating body within the enclosing body.

Systems and methods for producing osteogenic effect in spinal fixation systems using selectively anodized components are described. Anodization patterns can be selected to produce a desired electric field and osteogenic effect in tissues and structures surrounding the selectively anodized component.

A method of positioning an external adjustment device relative to a patient includes placing a magnetic viewing sheet adjacent to a patient. and identifying the location of an implanted magnetic assembly using the magnetic viewing sheet by visualizing a magnetic image of the implanted magnetic assembly in the magnetic viewing sheet. The external adjustment device is placed on the patient adjacent to the location where the magnetic image was located.

The present invention provides an orthopedic surgical tool for moving an implant to a surgical sight and installing the implant. The tool allows the surgeon the ability to navigate the implant through a surgical tube, then rotate the implant after reaching the sight and effect installation of the implant, and then effect its release from the tool. The implant can be rotated at any time during its installation within the constraints of other surgical devices.

An external adjustment device for non-invasively adjusting an implant, the external adjustment device including a controller in communication with an actuator associated with the adjustable implant and a sensor configured to receive information from or about the adjustable implant. The external adjustment device may further comprise a power source and a display. According to one exemplary embodiment, the external adjustment device comprises a magnetic element configured to generate a rotating magnetic field; and a driver configured to drive the magnetic element to generate the rotating magnetic field and configured to rotate a permanent magnet of an adjustable implant, wherein upon placing the external adjustment device in proximity to an adjustable implant having a permanent magnet the magnetic element is configured to magnetically couple with the permanent magnet, and wherein the external adjustment device is configured to non-invasively determine one or more of a magnetic coupling state and a stalled state of the magnetic element and the permanent magnet disposed within the adjustable implant.

An intramedullary orthopaedic device is disclosed including an intramedullary rod configured for insertion into a bone, the rod including a first elongate member having a first mating surface and at least a second elongate member having a second mating surface. The first mating surface is configured to engage with the second mating surface such that the elongate members are longitudinally moveable but substantially not rotationally moveable relative to each other. Each mating surface can have an elongate ridge and an elongate groove. A guided growth system and method is also disclosed.

A spinal construct includes an existing spinal rod implant defining a rod dimension and having at least one mating surface. At least one extension includes a mating surface engageable with the at least one mating surface of the existing spinal rod implant to comprise a connection having a dimension the same as the rod dimension. A coupling member is configured to fix the existing spinal rod implant with the at least one extension. Systems, surgical instruments, implants and methods are disclosed.

A method of positioning an external adjustment device relative to a patient includes placing a magnetic viewing sheet adjacent to a patient and identifying the location of an implanted magnetic assembly using the magnetic viewing sheet by visualizing a magnetic image of the implanted magnetic assembly in the magnetic viewing sheet. The external adjustment device is placed on the patient adjacent to the location where the magnetic image was located.