Abstract: According to one embodiment of the invention, a spinal fixation system includes a bone screw having a longitudinal access and a fixation rod configured to connect the bone screw to at least one additional bone screw. The fixation rod is lateral to the longitudinal axis. A coupling mechanism includes a bone screw securing device configured to secure the coupling mechanism to the bone screw and a fixation rod securing device configured to secure the coupling mechanism to the fixation rod. The spinal fixation system further includes a fastening mechanism. Rotation of the fastening mechanism secures the bone screw securing device to the bone screw and the fixation rod securing device to the fixation rod.

Abstract: A spinal implant is configured to be received between bony spinal protrusions of adjacent vertebrae particularly, but not necessarily, in the lumbar region of the spine and hold them apart. The spinal implant may be used interlaminar, interbody or interbony protrusion. The present bony spinal protrusion spacer is not fixed to any bony structures of the vertebrae and, as such, use of the present bony spinal protrusion spacer does not result in fusion. It may therefore be removed if necessary. Attachment structures formed as part of the bony spinal protrusion spacer receive and engage portions of adjacent bony protrusions. The attachment structures provide one or more ridges, bumps, protrusions, projections, lips, flanges, overhangs, overhangs that are threadably engaged, extensions and/or the like that form one or more pockets or cavities into which portions of adjacent bony spinal protrusions are separately lodged and held.

Abstract: An orthopedic implant structure is provided for joining and retaining components of a multi-part orthopedic device. The orthopedic implant joining and retaining structure may be embodied in two or more components of the multi-part orthopedic device. In one form, the multi-part orthopedic implant structure is a resilient snap structure such as a resilient flange in one part and a channel structure formed in another part of an orthopedic implant. A channel of the channel structure may have a cavity formed at a rear of the channel that accepts a configured lip formed on an end of the resilient flange. According to another embodiment, the retaining structure includes resilient snap flanges formed on an interconnection component of the multi-part orthopedic implant. A corresponding bore in another part of the multi-part orthopedic implant receives the interconnection component.

Abstract: A spinal fixation system includes a pedicle screw having a longitudinal axis. A fixation element is configured to connect the pedicle screw to at least one additional pedicle screw. A coupling mechanism includes a pedicle screw securing device adapted to secure the coupling mechanism to the pedicle screw and a fixation element securing device configured to secure the coupling mechanism to the fixation element. A fastening mechanism is configured to fasten both the pedicle screw securing device and the fixation element securing device. The fastening mechanism is located along the longitudinal axis of the pedicle screw.

Abstract: A device for insertion into a spinal (intervertebral or intravertebral) space is expandable from a first circumference to a second circumference through axial compression of segments of the device, particularly once the device has been properly situated within a vertebral space. The interbody/intravertebral body device is characterized by a plurality of axially stacked, individual segments that are provided on a central insertion and deployment rod. Each segment includes a central plate or body to which are pivotally attached plate or leaf structures. Pivoting of the structures provides a collapsed or unexpanded position of the first circumference and an open or expanded position of the second circumference.

Abstract: A spinal fixation system includes a pedicle screw having a longitudinal axis. A fixation element is configured to connect the pedicle screw to at least one additional pedicle screw. A coupling mechanism includes a pedicle screw securing device adapted to secure the coupling mechanism to the pedicle screw and a fixation element securing device configured to secure the coupling mechanism to the fixation element. A fastening mechanism is configured to fasten both the pedicle screw securing device and the fixation element securing device. The fastening mechanism is located along the longitudinal axis of the pedicle screw.

Abstract: A device for insertion into a spinal (intervertebral or intravertebral) space is expandable from a first circumference to a second circumference through axial compression of segments of the device, particularly once the device has been properly situated within a vertebral space. The interbody/intravertebral body device is characterized by a plurality of axially stacked, individual segments that are provided on a central insertion and deployment rod. Each segment includes a central plate or body to which are pivotally attached plate or leaf structures. Pivoting of the structures provides a collapsed or unexpanded position of the first circumference and an open or expanded position of the second circumference.

Abstract: A modular spine plate is formed of two or more spine plate components that connect to one another through projection and socket interfaces. The projection and socket interfaces may provide for snap fit features that allow locking connectivity between the spine plate components. The modular spine plate components constitute a single end plate component and a single center or middle plate component. The end plate component has a first end plate leg and a second end plate leg. One of the first and second end plate legs includes an end socket while the other of the first and second end plate legs includes an end projection sized to be received in the end socket. The center plate component has a first center plate leg, a second center plate leg, a third center plate leg, and a fourth center plate leg. One of the first and second center plate legs includes a center socket while the other of the first and second center plate legs includes a center projection.

Abstract: N-level internally dynamizing cervical plates and cervical plate constructs in accordance with the present principles, provide unconstrained sliding interconnection between the various plate components after installation on a cervical spine. A tongue-and-groove configuration between the various plate segments provides a constant thickness over the dynamizing portions. Detents provided relative the tongue-and-groove portions allows the various plate components to be permanently joined, but movable relative to one another. Various bone screw anti-backing, anti-rotation or locking devices for cervical bone plates are also provided that allow releasable locking of bone screws relative to the cervical plate.