A vertebral column correction system for correcting a spinal deformity without fusing the joint segments is disclosed. The vertebral column correction system may have first and second vertebral anchors secured to first and second vertebrae. The vertebral column correction system may further comprise one or more intermediate vertebral anchors secured to vertebrae between the first and second vertebrae. A connection member may be disposed within a head portion of the vertebral anchors. At least a portion of the connection member may be a flexible member, such as a flexible cord, configured for tensioning between at least two vertebral anchors for providing a desired amount of tension to apply a correctional force to the spinal column. A spring member, or other tensioning member, may maintain the tension of the connection member.

The present invention relates generally to a surgical device for the correction of deformities of the spinal column and finds particular, although not exclusive, utility in devices which are surgically implantable. Presently known implantable surgical devices are unable to provide for the progressive correction of spinal deformities assisted by active movements of the human body without fusion of the involved part of the spinal column. The present surgical device comprises a spinal column straightening means for permitting the relative rotation of two substantially adjacent vertebrae about a common axis substantially only in opposite rotational directions.

Methods of correcting a spinal deformity, including securing a first rod on a first side of a spine, securing an anchor on a second side of a spine, securing a lateral coupling between the rod and the anchor, translating and/or derotating the spine and securing a second rod on a second side of the spine to provide secondary stabilization to the spine.

A spinal implant comprises a first member. A fastener is connected with the first member. A second member includes a deformable element engageable with the fastener such that the second member is translatable relative to the fastener in a first axial direction and translation of the second member relative to the fastener in a second axial direction is resisted and/or prevented. Systems and methods are disclosed.

The present invention is directed to a spinal implant system that incorporates unique snap, or spring loaded, features to assist the surgeon in the placement of screws, rods, hooks and transverse connectors. The poly-axial movement also uses a more direct loading lower saddle into the bone screw to improve locking of the construct.

A spinal implant comprises a first member. A fastener is connected with the first member. A second member includes a deformable element engageable with the fastener such that the second member is translatable relative to the fastener in a first axial direction and translation of the second member relative to the fastener in a second axial direction is resisted and/or prevented. Systems and methods are disclosed.

The present invention relates generally to a surgical device for the correction of deformities of the spinal column and finds particular, although not exclusive, utility in devices which are surgically implantable. Presently known implantable surgical devices are unable to provide for the progressive correction of spinal deformities assisted by active movements of the human body without fusion of the involved part of the spinal column. The present surgical device comprises a spinal column straightening means for permitting the relative rotation of two substantially adjacent vertebrae about a common axis substantially only in opposite rotational directions.

A pedicle screw is provided. The pedicle screw includes a threaded shaft portion and a head portion that is supported on the threaded shaft portion for pivoting movement relative to the threaded shaft portion. A yoke portion is supported on the head portion for linear sliding movement relative to the head portion.

A system includes a first pedicle screw, a second pedicle screw, and an adjustable rod having an outer housing coupled to one of the first pedicle screw and the second pedicle screw, the outer housing having a threaded shaft secured to one end thereof extending along an interior portion thereof. The system farther includes a hollow magnetic assembly disposed within the outer housing and having a magnetic element disposed therein, the hollow magnetic assembly having an internal threaded surface engaged with the threaded shaft, the magnetic assembly being coupled to the other of the first pedicle screw and the second pedicle screw, wherein the hollow magnetic assembly rotates in response to an externally applied magnetic field to thereby lengthen or shorten the distance between the first pedicle screw and the second pedicle screw.

A scoliosis correction device has a plurality of saddles each having a guiding hole formed through the saddle, and secured to a pedicle; and at least a correction rod engageable within the guiding hole in the saddle; whereby upon spinal growth of a patient, the saddle or saddles as secured to the pedicle or pedicles will be moved in the correction rod, so that the correction device will be automatically and synchronously adjusted for keeping pace with the spinal growth of the patient. This correction device includes a saddle integrally formed for reducing the elements in construction of the correction device for saving cost and shortening surgery time for reducing operation risk.