Abstract: Embodiments of a lever reducer and methods of using a lever reducer are provided. In some embodiments, the lever reducer system includes a first tower, a second tower, and a lever reducer configured to couple to the first tower and the second tower. The lever reducer can include a fulcrum configured to be coupled to the first tower and a swivel configured to be coupled to the second tower. The lever reducer is configured to vertically lift the second tower. The method can include coupling a first tower to a first vertebra, as well as coupling a second tower to a second vertebra. The method can include coupling a lever reducer to the first tower and the second tower by coupling a fulcrum to the first tower and a swivel to the second tower. The method can include applying a force to the lever reducer to vertically lift the second tower.

Abstract: A rod reducer assembly is provided and is selectively mountable to a pedicle screw assembly. The pedicle screw assembly includes a pedicle screw housing that defines a rod-receiving recess. The pedicle screw assembly includes an extension assembly that is coupled to the pedicle screw housing by a frangible member. The rod reducer is configured to reduce a spinal rod into the rod-receiving recess of the pedicle screw assembly. The rod reducer assembly may include a derotation sleeve configured to inhibit the frangible member from breaking while manipulating a spinal bone.

Abstract: A rod reducer assembly is provided and is selectively mountable to a pedicle screw assembly. The pedicle screw assembly includes a pedicle screw housing that defines a rod-receiving recess. The pedicle screw assembly includes an extension assembly that is coupled to the pedicle screw housing by a frangible member. The rod reducer is configured to reduce a spinal rod into the rod-receiving recess of the pedicle screw assembly. The rod reducer assembly may include a derotation sleeve configured to inhibit the frangible member from breaking while manipulating a spinal bone.

Abstract: A rod reducer assembly is provided and is selectively mountable to a pedicle screw assembly. The pedicle screw assembly includes a pedicle screw housing that defines a rod-receiving recess. The pedicle screw assembly includes an extension assembly that is coupled to the pedicle screw housing by a frangible member. The rod reducer is configured to reduce a spinal rod into the rod-receiving recess of the pedicle screw assembly. The rod reducer assembly may include a derotation sleeve configured to inhibit the frangible member from breaking while manipulating a spinal bone.

Abstract: A cutting tool for bone, cartilage, and disk removal includes a body with a first radial array of helical flutes formed along the body with a continuous radius in a first helical direction. The body has a second radial array of helical flutes formed along the body with a continuous radius in a second helical direction opposed to the first helical direction and intersecting the first array of helical flutes. Each helical flute forms a pair of spaced apart rake surfaces, which collectively perform a first and second cutting operations along a side of the body such that the intersecting rakes balance the cutting operation thereby minimizing axial loading of the cutting tool to permit bidirectional cutting while minimizing g inadvertent axial translation of the tool.

Abstract: A spinal spacer for engagement between vertebrae includes a body having a substantially contoured first end surface at a distal end and a second end surface opposite thereto at a proximal end. The body extends between the first and second end surfaces to define top and bottom vertebral engaging surfaces that are opposed to one another. The body extends between the top and bottom vertebral engaging surfaces to define opposed side surfaces. The top and bottom vertebral engaging surfaces intersect with the side surfaces to provide a substantially quadrilateral cross-section with rounded corners. The top and bottom vertebral engaging surfaces have a substantially streamlined convex profile. The surfaces converge at the distal end to define a substantially atraumatic blunt nose having a tip configured with planar and/or convex surfaces.

Abstract: A cutting tool for bone, cartilage, and disk removal includes a body with a first radial array of helical flutes formed along the body with a continuous radius in a first helical direction. The body has a second radial array of helical flutes formed along the body with a continuous radius in a second helical direction opposed to the first helical direction and intersecting the first array of helical flutes. Each helical flute forms a pair of spaced apart rake surfaces, which collectively perform a first and second cutting operations along a side of the body such that the intersecting rakes balance the cutting operation thereby minimizing axial loading of the cutting tool to permit bidirectional cutting while minimizing inadvertent axial translation of the tool.

Abstract: A spinal spacer for engagement between vertebrae includes a body having a substantially contoured first end surface at a distal end and a second end surface opposite thereto at a proximal end. The body extends between the first and second end surfaces to define top and bottom vertebral engaging surfaces that are opposed to one another. The body extends between the top and bottom vertebral engaging surfaces to define opposed side surfaces. The top and bottom vertebral engaging surfaces intersect with the side surfaces to provide a substantially quadrilateral cross-section with rounded corners. The top and bottom vertebral engaging surfaces have a substantially streamlined convex profile. The surfaces converge at the distal end to define a substantially atraumatic blunt nose having a tip configured with planar and/or convex surfaces.