A system for implanting an inter-body device between adjacent vertebrae comprises an inter-body device having a plurality of cans secured to a flexible bridge and having a relief portion therebetween. An inserter tube and complementary bullnoses are advantageously secured to the vertebrae by an extension arm for securing the assembly precisely in place. A plurality of articulating trial implants are provided to test fit a disc space for the proper sized inter-body device.

Disclosed are surgical implants for providing therapy to a treatment site, tool sets and methods for percutaneously accessing and deploying the implants within the spines. The treatment site may be a vertebral body, disc, and/or motion segments in the lumbar and sacral regions of the spine.

Disclosed herein are systems and methods for intervertebral body fusion that provide more robust support within the disc space. Intervertebral body fusion devices can have a unitary monolithic body including a plurality of body segments interconnected with each other by flexure members. Devices be configured to be inserted through an opening in a compressed configuration and then expanded within the disc space to an expanded configuration. In the expanded configuration, devices can have a greater mediolateral or transverse to the disc space footprint. This wider footprint provides greater support for the vertebrae relative to the size of the opening through which the device is inserted.

A bone structural device including a plurality of bone structural segments, wherein adjacent bone structural segments are pivotally connected to one another about a pivot axis, and the bone structural segments are expandable in height, which is in a direction generally parallel to the pivot axis.

The disclosure relates to a system comprising a foam structure and a surgical fixation device for attaching the foam structure to bone, the foam structure comprising: a porous body made of at least one biocompatible implant material, wherein the porous body is coated with a coating, which is capable of stimulating bone ingrowth.

Various embodiments provide systems and methods for repairing or replacing intervertebral discs as a treatment for derangements. Systems and methods may comprise an inter vertebral disc implant for deployment into an intervertebral disc space wherein the nucleus has been at least partially evacuated from the deranged intervertebral disc. The intervertebral disc implant may be intraoperatively and postoperatively filled and/or re-filled with a growth matrix. The intervertebral disc implant may be differentially permeable to the growth matrix to provide directional growth and/or diffusion of the growth matrix to restore height to the intervertebral disc space. Systems and methods may further comprise an implant delivery device for deploying the intervertebral disc implant into the intervertebral disc space.

A disc implant device can be provided in a generally planar rectangular sheet having a first elongated side, a second elongated side opposing the first elongated side, a first end, and a second end opposing the first end. The generally planar rectangular sheet is structured with alternating segments of joint ridges, each segment of joint ridges being configured to form a spacing joint segment and alternating segments of arm ridges, each arm segment being configured to form a plurality of radially extending arms, the joint segments providing flexibility to the device. When the disc implant is folded or rolled from its planar configuration to a generally cylindrical configuration, the arm segments are axially collapsible and radially expandable such that in such a configuration, the implant includes segments of radially expanded arms separated by spacing joint segments.

An interbody cage for the spinal column structured as a scaffold made of at least two folding and unfolding scaffoldings: one base member (also named a cage body) which receives the pivoting means of a pivoting member (also named an extension member), and one extension member, structured to pivot around an axis on the cage body from a first folded or stowed configuration to a second unfolded or deployed configuration such that the perimeters of the contact surfaces between the interbody cage and the vertebrae and/or the height of the interbody cage increase from the stowed configuration to the deployed configuration.

A bone joint spacer has two endplates which have a bone engaging surface on one side, and ramps extending from an opposite side. A shaft has a threaded end, and another end which has ramp followers which mate with the endplate ramps of both endplates. A collar slides over the threaded end of the shaft, and also has ramp followers which mate with the endplate ramps of both endplates. A nut threads onto the end of the shaft and pushes the collar towards the ramp followers of the shaft. This movement causes the ramp followers to slide the ramp followers of the collar and the shaft against the endplate ramps, pushing the endplates apart. Two of these spacers can be combined by a link plate so that the spacers can be aligned or curved into a U-shape to be inserted into the body and positioned between bony surfaces, respectively.

An implantable prosthesis that includes a biased coiling member and a conforming coiling member. The biased coiling member may be biased to curve from a substantially linear configuration to a nonlinear configuration. The conforming coiling member may be engaged with and curved by the biased coiling member from the substantially linear configuration to the nonlinear configuration. The biased coiling member may define a longitudinal axis when in the substantially linear configuration. The biased coiling member and the conforming coiling member may move relative to each other along the longitudinal axis. The prosthesis may be implanted in a surgical procedure that minimizes incision sizes and may be considered less invasive than typical implant procedures, especially spinal implant procedures.