A surgical kit includes a shield for covering a portion of the spine of a subject. The shield can include an attachment portion adapted to engage a bone fixation assembly which is adapted to be fixed on multiple vertebra bones of the subject. The bone fixation assembly can include a vertebra joining member secured between two bone anchors. Each bone anchor can include a fastener portion adapted to be implanted into a vertebra bone and a head coupling portion adapted to secure the vertebra joining member. The shield can be coupled to the bone fixation assembly via separate coupling elements, such as a clip or an adjustable link secured between two vertebra joining members of the bone fixation assembly. Alternatively, the shield can include an integral attachment portion configured to engage the bone fixation assembly directly.

Systems, methods, and devices for securing a spinal rod are provided. A clamp assembly comprises a tulip comprising an opening comprising an inner surface, wherein the inner surface is threaded; and a threaded locking cap disposed in the opening, wherein threads of the locking cap and the inner surface include various geometries.

A surgical instrument comprises a first arm connected with a longitudinal element and a first spinal construct. The first arm is connected with the longitudinal element and includes a body engageable with a first spinal construct and rotatable relative to the first arm in a first orientation and a second orientation. A second arm is axially translatable relative to the first arm and includes a body engageable with a second spinal construct and is rotatable relative to the second arm in a first orientation and a second orientation. The bodies include locks. In some embodiments, spinal constructs, implants, systems and methods are disclosed.

Bone graft scaffold arrangements are described that can be used in minimally invasive posterolateral spinal fusion. The bone graft scaffold apparatus comprise a housing which comprises a cavity for receiving bone growth promoting materials and a plurality of apertures. In use these allow bone and blood vessels to grow through the plurality of apertures to form the bone bridge between vertebrae. Further the bone graft scaffold apparatus comprise at least one opening in the housing for receiving a shaft of an orthopaedic device, such as rod linking pedicle screws, or the shaft of a pedicle screw, or another suitable shaft in another surgical procedure. The apparatus can be attached to structural components such as rods and screws and used to form a continuous scaffold between vertebras to assist in forming a bone bridge.

A hinged bone screw and tool set is used for implanting such bone screws in a human spine, followed by the implantation of a longitudinal connecting member into the bone screws. The hinged bone screw includes a shank with an upper portion and a receiver with integral arms forming a U-shaped channel. A lower curved seat partially defining the U-shaped channel cooperates with an upper portion of the bone screw shank for hinged movement of the shank with respect to the receiver. The tool set includes an insertion tool, a bone screw driver, a reduction tool and a closure starter. The insertion tool includes a bone screw attachment structure and a laterally opening channel. The insertion tool further includes a threaded portion for cooperation with the reduction tool to provide synchronized placement of a closure structure in the bone screw receiver while reducing and capturing a longitudinal connecting member within the receiver. Further alternative bone screws are hinged, polyaxial or fixed and include lordosing or kyphosing lateral surfaces.

A spinal implant assembly comprising an intervertebral device configured to be installed in a spinal disc space, the intervertebral device having a head component and a body component, the spinal implant assembly further comprising a coupling body for coupling the head component of the intervertebral device and an elongate member, the coupling body and head component each having a longitudinal axis, wherein the head component can be received by the coupling body with its longitudinal axis at a selected angle within a predetermined range of angles relative to the longitudinal axis of the coupling body.

A pedicle screw implant construct kit, comprising at least one pedicle screw, at least one collar comprising a recess for receiving a rod, the collar configured to be coupled to a head of the pedicle screw, an elongated rod for connecting the collar to one more additional collars to couple between the pedicle screw and one or more additional screws, and a locking ring sized to be positioned over at least a distal portion of the collar to restrain relative movement of the screw head and rod by exerting radial compression force onto the collar. In some embodiments, the components of the kit are comprised of carbon reinforced composite material, optionally with no radiation blocking material. In some exemplary embodiments of the invention, the kit includes two locking rings on a collar, optionally both below the rod.

A screw-clamp apparatus is disclosed that includes a first clamp component comprising at least one hook, a second clamp component comprising at least one hook, a bone-screw hole located on the first clamp component, a bone screw configured to be inserted through the bone-screw hole and to be inserted into bone and a spacer-receiver located on the first clamp component. The second clamp component can be pivotably attached relative to the first clamp component. A portion of the bone screw can be configured to engage the second clamp component upon insertion to cause the second clamp component to pivot toward the first clamp component. The spacer-receiver can be configured to secure a spacer.

Minimally invasive methods and devices are provided for positioning a spinal fixation element in relation to adjacent spinal anchors. In an exemplary embodiment, the device is a percutaneous access device that can be coupled to a spinal anchor, and the method includes the step of positioning a spinal fixation element through at least one sidewall opening of at least two percutaneous access devices such that the spinal fixation element extends in a lengthwise orientation that is substantially transverse to the longitudinal axis of each percutaneous access device. The spinal fixation element can then be advanced in the lengthwise orientation to seat the spinal fixation element in or adjacent to the receiver heads of at least two adjacent spinal anchors. A fastening element or other closure mechanism can then be applied to each spinal anchor to engage the spinal fixation element within the receiver heads of the adjacent anchors.

A method for treating a spine includes disposing a body including vertebrae in a lateral orientation relative to a surgical fixed surface configured for supporting the body; creating an incision in tissue of the body along a substantially transverse plane of the body; spacing the tissue adjacent the incision along a sagittal plane of the body to define a surgical pathway to the vertebrae; and delivering at least one implant adjacent the vertebrae via the surgical pathway. Systems and implants are disclosed.