Various angularly-adjustable spinal fixation systems are provided and generally include an articulating connector having first and second elongate rods extending therefrom, and first and second polyaxial bone screw assemblies configured to seat the first and second rods therein. The rods are configured to be seated within receiver heads of the polyaxial bone screw assemblies when the screws are implanted in opposed lateral sides of a vertebra, thereby allowing the receiver heads to be manipulated relative to the rods to reduce one or more posterior fractures. A joint on the articulating connector can also be manipulated to reduce one or more anterior fractures. The entire construct can be locked to maintain the fractures in the reduced configuration.

Articulating implant connectors and related methods are disclosed herein. Exemplary connectors can include first and second bodies that are rotatable relative to one another about a rotation axis and selectively lockable to resist or prevent such rotation. Each of the bodies can be configured to couple to a rod or other fixation component, and the connector can be used to lock first and second rods together even when the rods are obliquely angled with respect to one another.

A spinal rod connector includes first and second arm assemblies and a fastener. The first arm assembly includes a first base portion and a first head portion defining a first slot configured to receive a first spinal rod. The first base portion includes a hook and an extension member including a housing. The second arm assembly is adjustable with respect to the first arm assembly. The second arm assembly includes a second base portion including a hook, a second head portion defining a second slot configured to receive a second spinal rod, and an elongate member extending from the second base portion. The elongate member is configured to be received in the housing of the first arm assembly. The elongate member is rotatable about an axis offset from a longitudinal axis of the housing. The fastener is configured to be received in the housing to secure the elongate member.

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 bone fixation system for implanting in bone, the system comprising a plurality of bone fastener assemblies that attach to bone, a pair of elongate members that attach to the plurality of bone fastener assemblies, a connector member that contacts the pair of elongate members, and a plurality of locking caps that secure the connector member and the elongate members to the plurality of bone fastener assemblies, wherein at least one of the plurality of locking caps comprises a cap portion and a hook portion, where the cap portion is adapted to rotate while the hook portion is stationary.

The present invention relates to a fixing rod connecting device and, more specifically, to a fixing rod connecting device, comprising: a main body having a space into which one or more rods can be inserted; and a fixing screw fastened to the main body so as to fix the rod, wherein one side surface of the main body is formed to have a predetermined upward inclination angle relative to the other side surface thereof, thereby eliminating interference with other surgical instruments when the fixing screw is fastened, enabling an incision area of a patient to be minimized, and enabling three-dimensional alignment and fixation of the rod.

The invention relates to a vertebral implant placed after a laminectomy and fixed by transfacet screws arranged in a translaminar direction. The invention also relates to a placement instrument and to a method for the placement of an implant.

Articulating implant connectors and related methods are disclosed herein. Exemplary connectors can include first and second bodies that are rotatable relative to one another about a rotation axis and selectively lockable to resist or prevent such rotation. Each of the bodies can be configured to couple to a rod or other fixation component, and the connector can be used to lock first and second rods together even when the rods are obliquely angled with respect to one another.

An adjustable spinal stabilization system for maintaining preselected spacing and movement between adjacent vertebrae in a spinal column and for providing overall stability thereto. The system includes at least one interlaminar member positioned in the spaces intermediate a first vertebra and the vertebrae positioned immediately above or immediately below and adjacent to the first vertebra. The interlaminar member is operatively connected to an adjustable support structure and cooperates therewith to maintain the preselected spacing between adjacent vertebrae and to provide overall stability to the spinal column.

A transverse connector includes a cross member assembly, a first connector assembly, and a second connector assembly. The cross member assembly includes a cross member, a first ring, and a second ring. The cross member has a first end portion and a second end portion. The first ring is receivable on the first end portion of the cross member and the second ring is receivable on the second end portion of the cross member. The first and second connector assemblies are coupled to the first and second rings of the cross member assembly, respectively, to support the cross member between the first and second connector assemblies. The first and second connector assemblies are configured to selectively and releasably secure to bone anchors.