Systems and methods include solutions for fixation at the rib head for fractures and osteotomies adjacent to the rib head and transverse process. The disclosed rib plates, anchor systems, other implants, and instrumentation may also be applied to mid-rib fractures. The systems and methods may be used in the treatment of rib deformities, including the correction of rib hump deformity via thoracoplasty, as well as general corrections of chest and rib deformities. Systems and methods herein may be used in chest wall reconstructions due to trauma, cancer, or deformity.

A coupling device includes a receiving part having a head receiving portion for pivotably receiving a head of a bone anchor and a rod receiving portion defining a recess for receiving the rod, the rod receiving portion having an engagement structure for engaging a locking member to lock the rod in the recess and a first engagement surface different from the engagement structure for engaging an instrument, wherein the first engagement surface is formed away from radially outwardly facing regions of the rod receiving portion, and a locking ring positionable around the head receiving portion and having a second engagement surface for engaging the instrument. The locking ring can assume an insertion position where the head of the bone anchor is insertable into the head receiving portion, and a pre-locking position where the head is prevented from removal from the head receiving portion.

A coupling device includes a receiving part having a head receiving portion for pivotably receiving a head of a bone anchor and a rod receiving portion defining a recess for receiving the rod, the rod receiving portion having an engagement structure for engaging a locking member to lock the rod in the recess and a first engagement surface different from the engagement structure for engaging an instrument, wherein the first engagement surface is formed away from radially outwardly facing regions of the rod receiving portion, and a locking ring positionable around the head receiving portion and having a second engagement surface for engaging the instrument. The locking ring can assume an insertion position where the head of the bone anchor is insertable into the head receiving portion, and a pre-locking position where the head is prevented from removal from the head receiving portion.

The device for treating early onset scoliosis includes first and second tubes having first and second rods slidably disposed therein. The first tube is adapted for fixation to at least one middle vertebra of a patient’s spine such that an open end thereof faces upward and a closed end thereof faces downward. The second tube is also adapted for fixation to at least one middle vertebra such that an open end thereof faces downward and a closed end thereof faces upward. A lower end of the first rod is positioned within the first tube and is resiliently biased. An upper end of the first rod is adapted for fixation to at least one upper vertebra. An upper end of the second rod is positioned within the second tube and is resiliently biased. A lower end of the second rod is adapted for fixation to at least one lower vertebra.

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 device for treating early onset scoliosis includes first and second tubes having first and second rods slidably disposed therein. The first tube is adapted for fixation to at least one middle vertebra of a patient's spine such that an open end thereof faces upward and a closed end thereof faces downward. The second tube is also adapted for fixation to at least one middle vertebra such that an open end thereof faces downward and a closed end thereof faces upward. A lower end of the first rod is positioned within the first tube and is resiliently biased. An upper end of the first rod is adapted for fixation to at least one upper vertebra. An upper end of the second rod is positioned within the second tube and is resiliently biased. A lower end of the second rod is adapted for fixation to at least one lower vertebra.

A guiding device for fixing flexible blades of spinal implants, which includes a guide device for transfixing flexible blades (1) that constitute the platforms (13) and (14), which have a box-shaped side, where the set of flexible blades (3) crosses and slides, and the other side has a hole (16) for its fixation to the double intermediate connector (5), which bears a pedicle screw (7); said set of flexible blades (3) being formed by two blades (4), overlapped, provided with longitudinal openings (9), through which they are joined by means of a fixing device (11), which allow them to slide over each other.

A system for robotic spinal manipulation includes a first robotic arm comprising an end effector; a second robotic arm configured to hold a spinal rod; at least one processor; and a memory storing instructions for execution by the at least one processor. The instructions, when executed, cause the at least one processor to control the first robotic arm to link the end effector with at least one vertebral screw implanted in a vertebra of a spine of a patient; control the second robotic arm to hold the spinal rod in a predetermined pose; and cause the first robotic arm to move the at least one implanted vertebral screw into engagement with the spinal rod.

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.

In one example, an implant holder supports a guiding connector that attaches to a vertebrae and that secures to an elongated support member by a cable tie. The implant holder has a handle portion that has a shaft that extends between proximal and distal ends of the handle portion. The distal end of the handle portion can be positioned proximate to the guiding connector when the guiding connector is supported by the implant holder. The implant holder has at least one holder defining a channel therethrough that receives the shaft of the handle portion such that the at least one holder is slidable along the shaft. The at least one holder secures the cable tie and at least one wing of the guiding connector to the handle portion.