Abstract: Spinal implants and methods to repair annular defects in intervertebral discs and provide dynamic stability to the spine in the vicinity of a repaired disc are described. Some implants include head and tail portions. In some embodiments, the head portion of an implant is enlarged relative to the tail portion. Some head portions and tail portions are adapted to support adjacent vertebrae and resist collapse of the intervertebral disc. Head portions provide a spacer function to maintain separation between adjacent vertebrae. A tapered portion of some implants engages end plates of adjacent vertebrae to resist forces tending to push the implant out of the intervertebral space. The tail portion of some implants includes a tail flange (which in some embodiments is of similar diameter to the head portion) that abuts extradiscal lips of the adjacent vertebrae and resists forces tending to push the implant deeper into the intervertebral space.

Abstract: Spinal implants are disclosed that can be used for annular repair, facet unloading, disc height preservation, disc decompression, or for sealing a portal through which a nucleus implant was placed. In some embodiments, an implant is placed within the intervertebral disc space, primarily within the region of the annulus fibrosus. In some embodiments, the implant is expandable. In some embodiments, the implant has a sealing tail structure comprising a tail flange and a linkage. In some embodiments, the sealing tail structure limits the extrusion or expulsion of disc material, either annulus fibrosus or nucleus, into the posterior region of the spine where it could impinge on nerves. In some embodiments, the tail structure is retained in place within the annulus fibrosus by means of an anchor. In some embodiments, the anchor is constructed from multiple components.

Abstract: Spinal implants are disclosed that can be used for annular repair, facet unloading, disc height preservation, disc decompression, or for sealing a portal through which a nucleus an intervertebral implant was placed. In some embodiments, an implant is placed within the intervertebral disc space, primarily within the region of the annulus fibrosus. In some embodiments, the implant is expandable. In some embodiments, the implant has a sealing tail structure comprising a tail flange and a linkage. In some embodiments, the sealing tail structure limits the extrusion or expulsion of disc material, either annulus fibrosus or nucleus, into the posterior region of the spine where it could impinge on nerves. In some embodiments, the tail structure is retained in place within the annulus fibrosus by means of an anchor. In some embodiments, the anchor is constructed from multiple components.

Abstract: Spinal implants are disclosed that can be used for annular repair, facet unloading, disc height preservation, disc decompression, or for sealing a portal through which an intervertebral implant was placed. In some embodiments, an implant is placed within the intervertebral disc space, primarily within the region of the annulus fibrosus. In some embodiments, the implant is expandable. In some embodiments, the implant has a sealing tail structure comprising a tail flange and a linkage. In some embodiments, the sealing tail structure limits the extrusion or expulsion of disc material, either annulus fibrosus or nucleus, into the posterior region of the spine where it could impinge on nerves. In some embodiments, the tail structure is retained in place within the annulus fibrosus by means of an anchor. In some embodiments, the anchor is constructed from multiple components.

Abstract: Spinal implants are disclosed that can be used for annular repair, facet unloading, disc height preservation, disc decompression, or for sealing a portal through which an intervertebral implant was placed. In some embodiments, an implant is placed within the intervertebral disc space, primarily within the region of the annulus fibrosus. In some embodiments, the implant is expandable. In some embodiments, the implant has a sealing tail structure comprising a tail flange and a linkage. In some embodiments, the sealing tail structure limits the extrusion or expulsion of disc material, either annulus fibrosus or nucleus, into the posterior region of the spine where it could impinge on nerves. In some embodiments, the tail structure is retained in place within the annulus fibrosus by means of an anchor. In some embodiments, the anchor is constructed from multiple components.

Abstract: Spinal implants are disclosed that can be used for annular repair, facet unloading, disc height preservation, disc decompression, or for sealing a portal through which an intervertebral implant was placed. In some embodiments, an implant is placed within the intervertebral disc space, primarily within the region of the annulus fibrosus. In some embodiments, the implant is expandable. In some embodiments, the implant has a sealing tail structure comprising a tail flange and a linkage. In some embodiments, the sealing tail structure limits the extrusion or expulsion of disc material, either annulus fibrosus or nucleus, into the posterior region of the spine where it could impinge on nerves. In some embodiments, the tail structure is retained in place within the annulus fibrosus by means of an anchor. In some embodiments, the anchor is constructed from multiple components.

Abstract: Spinal implants and methods to repair annular defects in intervertebral discs and provide dynamic stability to the spine in the vicinity of a repaired disc are described. Some implants include head and tail portions. In some embodiments, the head portion of an implant is enlarged relative to the tail portion. Some head portions and tail portions are adapted to support adjacent vertebrae and resist collapse of the intervertebral disc. Head portions provide a spacer function to maintain separation between adjacent vertebrae. A tapered portion of some implants engages end plates of adjacent vertebrae to resist forces tending to push the implant out of the intervertebral space. The tail portion of some implants includes a tail flange (which in some embodiments is of similar diameter to the head portion) that abuts extradiscal lips of the adjacent vertebrae and resists forces tending to push the implant deeper into the intervertebral space.

Abstract: Spinal implants and methods to repair annular defects in intervertebral discs and provide dynamic stability to the spine near a repaired disc are described. Some implants include head and tail portions. In some embodiments, the head portion is enlarged relative to the tail portion. Some head portions and tail portions are adapted to support adjacent vertebrae to resist intervertebral disc collapse. Head portions provide a spacer function to maintain separation between adjacent vertebrae. In some implants, a tail portion engages end plates of adjacent vertebrae to resist extrusion of the implant from the intervertebral space. The tail portion of some implants includes a tail flange (in some embodiments of similar diameter to the head portion) abutting extradiscal lips of adjacent vertebrae and resisting forces tending to push the implant deeper into the intervertebral space. Some embodiments are compliant, while some include bone-compaction holes to stabilize the implant in situ.