A dynamic stabilization assembly includes a core, typically in the form of a tensioned cord, at least one pair of bone anchors, a spacer surrounding the core located between the bone anchors, at least one elastic bumper and at least one fixing or blocking member. The core is slidable with respect to at least one of the bone anchors, the spacer and the bumper. The bumper is compressed. Bone screws of the assembly include closure structures that lock against the bone screw independent of any fixing or sliding of the core with respect to the bone screw.

A receiver assembly for securing an elongate rod to a bone anchor includes a receiver having a channel configured to receive the elongate rod and a helically wound receiver guide and advancement structure formed into interior surfaces of the receiver. The receiver assembly further includes a threaded plug configured for positioning within the channel to secure the elongate rod to the receiver in a locked configuration, with the threaded plug having a lower axially protruding portion configured to compress the rod so as to prevent rotational and axial movement between the rod and the receiver in the locked configuration.

A pivotal bone anchor assembly includes a receiver having a cavity for receiving the head of a shank, a first channel for receiving an elongate rod, and an axial bore extending upward from a bottom opening of the receiver to a discontinuous thread adjacent a top of the receiver with opposed alignment members protruding inwardly beneath the discontinuous thread. The assembly also includes a pressure insert having a second channel for receiving the underside of the elongate rod, a lower surface for applying downward pressure on the shank head, and an outer cylindrical surface with opposite elongate recesses. The pressure insert is loaded into a first position within the axial bore and then rotated into a second position in which the opposed alignment members become positioned within the opposite elongate recesses to hold the second channel of the pressure insert in alignment with the first channel of the receiver.

An implant for the stabilization of bones or vertebrae is provided, the implant being a solid body including a longitudinal axis that defines a longitudinal direction and including a flexible section that has a surface and has a length in the longitudinal direction, the flexible section including at least one cavity located near the surface and having a width in the longitudinal direction that is smaller than the length of the flexible section, the at least one cavity being connected to the surface through at least one slit, and a width of the slit in the longitudinal direction being smaller than the width of the cavity.

This invention relates to a skeletal support member (1) and more specifically, but not exclusively, to a skeletal support member (1) for use in spinal or intramedullary surgery. In accordance with the invention there is provided a skeletal support member (1) comprising an elongate body with integrally formed inner (2) and outer (3) portions, at least one mechanical attribute of the inner portion (2) differing from a corresponding mechanical attribute of the outer portion (3), and the inner portion (2) being shaped and sized such that a corresponding mechanical attribute of the body varies longitudinally. It is envisaged that the invention will provide a skeletal support member (1) which has varying mechanical properties along the length thereof in at least one direction which may be specifically tailored to allow specific movement and apply corrective forces and moments which are bespoke to a patient.

Systems and methods are provided for treating and/or correcting spinal deformities. An implantable spinal system comprises first and second fasteners, such as bone anchors, and a connector element extendible between the first and second bone anchors. The connector element is configured for distraction between the first and second bone anchors on a concave side of the vertebral column. The connector element provides sufficient force to distract the spine to correct the curved portion of the vertebral column. The implantable spinal system may be particularly useful as a distraction and motion preservation system for treatment of scoliosis in a growing child, adolescent or adult. The system may be configured to at least partially correct the curved portion of a spinal column in at least two different planes, such as the frontal plane and/or the sagittal plane, or to correct a rotation in the transverse plane.

A pivotal bone anchor assembly includes a shank with a head, an anchor portion, and a neck extending between the head and the anchor portion, and a receiver with upright arms defining a channel for receiving a rod and a central bore extending downward to a lower portion of the receiver. The assembly also includes a retaining structure rotatably coupled with the receiver with an internal seating structure pivotally supporting the head while providing for independent rotation of the shank prior to locking the assembly with the rod and a closure. The retaining structure includes an external surface and a slot extending between the seating structure and the external surface with a concave cut-out configured to closely receive the neck so as to provide for increased articulation between the shank and the receiver along the slot, and with the shank and the retaining structure being rotatable together around a centerline axis to align the increased articulation in any radial direction around the circumference of the receiver.

A receiver assembly includes a receiver having a first channel, a through-space with internal recesses beneath a guide and advancement structure, and internal ridges projecting inwardly below the internal recesses. The assembly also includes an insert having a second channel, side structures protruding laterally outward below top surfaces, and opposed lower extensions extending downwardly below the second channel, with the insert being loadable into the through-space with the second channel in non-alignment with the first channel. The insert is the non-threadably rotatable within the through-space to align the second channel with the first channel and to move the side structures into the internal recesses above the internal ridges, with subsequent downward displacement of the insert within the through-space causing the opposed lower extensions to engage the capture head of a bone anchor with a frictional engagement that inhibits the bone anchor from moving upward within the through-space.

A system for use during a surgical procedure includes a control unit configured to obtain a horizontal pelvic line (HPL) and a central sacral vertical line (CSVL); obtain a horizontal shoulder line (HSL) and an orthogonal midline (OM); compare the HPL and the CSVL with the HSL and the OM; determine an angle between the HPL and the HSL; and convert the angle to a patient position.

A pivotal bone anchor assembly includes a shank with a head and an anchor portion, and a receiver with a channel for receiving a rod and a lower portion of an axial bore for receiving the shank head, with the axial bore including a stop structure and a downwardly-facing surface beneath a helically wound thread. The assembly also includes an insert having an upwardly-facing seat, a lower surface for engaging the shank head, a side structure for engaging the stop structure, and an upwardly-facing surface positioned radially outward from the upwardly-facing seat, with the insert being installed into the axial bore in a first angular position. Subsequent rotation of the insert within the axial bore moves the upwardly-facing surface under the downwardly-facing surface to inhibit upward movement of the insert within the axial bore, with further rotation being inhibited by the side structure coming into engagement with the stop structure.