The present invention generally relates to methods and device for treatment of spinal deformity, wherein at least one tether is utilized to maintain the distance between the spine and the an ilium to (1) prevent increase in abnormal spinal curvature, (2) slow progression of abnormal curvature, or (3) impose at least one corrective displacement and/or rotation.

A medical implant assembly includes a polyaxial bone anchor having a shank, a receiver, a lower compression insert with planar surfaces for closely receiving an elongate connecting member with planar surfaces and a one-piece closure structure. The connecting member is made from a polymer. The closure structure engages both the connecting member and the insert with the engagement between the closure structure and the insert securely locking the polyaxial mechanism even if the connecting member exhibits creep.

A device for bracing the vertebrae of the human spinal column, having at least one pedicle screw with a head that is formed so as to be at least partially spherical and that is received into an at least partially spherical mounting area of a pedicle head, wherein the pedicle head has a centric recess which includes the mounting area and a slit for receiving a rod that is arranged transversely with respect to the centric recess, as well as an internal thread which is formed inside the centric recess opposite the mounting area and inside of which a safety screw for clamping the rod is arranged, wherein the safety screw is provided with an anti-rotation device at that side that is facing towards the rod.

Mechanical modifications to a spinal rod that will enable the rod to accept various coating technologies in such a way that the spinal construct's biomechanical performance is not compromised. These modifications preserve construct biomechanics in the presence of a coating and increase the bactericidal payload of an anti-infective spinal rod coating.

A system for installing a vertebral stabilization system. The system includes an installation tool including a handle portion and a shaft extending distally from the handle portion. The shaft includes a conduit and a staple mechanism. The system also includes a flexible implant member extending along the conduit configured to be advanced out from a distal end of the shaft, and a staple housed in the staple mechanism. The staple is configured to secure the flexible implant member to a vertebra. The handle portion is configured to selectively advance the flexible implant member from the shaft and to selectively actuate the staple mechanism.

The present invention discloses fusion systems and methods of assembly and use. The fusion systems include a first fastener, a second fastener, and an elongate member with a first end and a second end. The first end being secured to the first fastener and the second end being secure to the second fastener. The method of assembling a fusion system and methods of using the fusion systems are also disclosed.

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 polyaxial bone screw assembly includes a threaded shank body having an integral upper portion receivable in an integral receiver, the receiver having an upper channel for receiving a longitudinal connecting member and a lower cavity cooperating with a lower opening. A down-loadable compression insert, a down-loadable friction fit split retaining ring having inner and outer tangs and an up-loadable shank upper portion cooperate to provide for pop- or snap-on assembly of the shank with the receiver either prior to or after implantation of the shank into a vertebra. The shank and receiver once assembled cannot be disassembled.

Methods of correcting a spinal deformity, including securing a first rod on a first side of a spine, securing an anchor on a second side of a spine, securing a lateral coupling between the rod and the anchor, translating and/or derotating the spine and securing a second rod on a second side of the spine to provide secondary stabilization to the spine.

A pivotal bone anchor assembly includes a shank, a receiver with an open channel in communication with a central bore, and a pressure insert with an upwardly-facing seating surface for receiving an elongate rod. The receiver bore includes a downwardly-facing surface below a closure top mating feature and one or more integral structures protruding inwardly toward a central longitudinal axis. The insert includes one or more notches formed into an outer side surface and an upwardly-facing surface positioned radially outward from the seating surface. Upon installation into the receiver bore, the insert is rotatable about the longitudinal axis until the insert upwardly-facing surface is rotated under the receiver downwardly-facing surface to inhibit upward movement of the insert within the receiver bore along the longitudinal axis and the receiver inwardly-protruding structures become positioned within the insert outer notches to prevent further rotation of the insert within the receiver bore.