Implants, systems, and methods for securing a flexible band, thereby providing a desired correction to the spine. The implant may secure the flexible band to a spinal rod and/or a pedicle screw. The implant may include a first locking member configured to secure the spinal rod and a second locking member configured to secure the band. The band may be looped around bony anatomy and tensioned to achieve correction and provide fixation as an alternative and/or supplement to pedicle screws during spinal deformity surgery.

A rod system, in particular, for the spine, includes a first rod, a second rod, and a connector for connecting the first rod and the second rod. The connector includes a main body defining a first rod seat configured to hold the first rod in a fixed manner and a second rod seat configured to accommodate a second rod, and a fixation member and a closure member that are interchangeably mountable to the main body. When the fixation member is mounted to the main body, the fixation member is engageable with the portion of the second rod to hold the second rod in a fixed manner relative to the main bod, while when the closure member is mounted to the main body, the closure member is configured to hold the second rod to the main body in a slidable manner.

An implantable growing rod assembly adapted to be secured along a length of a spine for treating deformities of the spine. The assembly includes a housing, a fixed rod extending along a longitudinal axis away from the housing, and an expansion rod extendible from the housing along the longitudinal axis. A driver assembly is fixed to the housing and adapted to translate the expansion rod along the longitudinal axis.

Systems, devices, and associated methods for correcting spinal column deformities that help minimize a number of attachment anchors utilized for correction, facilitate use of straight or contoured rods, and/or help promote a more natural, physiologic motion of the spinal column.

Spinal correction surgical techniques and methodologies for correction of scoliosis using non fusion anterior scoliosis correction, including soft tissue releases, unique correction techniques such as de-rotation, and unique single and dual anchor screw/cord applications.

Hydraulically expandable spinal rods and methods of use thereof are disclosed. The spinal rod may include a piston rod, a static rod, and a hydraulic pressure chamber for accepting hydraulic fluid and causing the piston rod to move in an expansion direction relative to the static rod. Upon connection of the piston and static rods to a patient's spinal column, the hydraulic spinal rod may be expanded to aid in correction of an underlying spinal deformity.

A bone fixation system where an alignment rod is engaged by pedicle screws. The alignment rod has sections of buttress thread. Each pedicle screw has a threaded shaft that supports a slotted receptacle. A set screw threads into the slotted receptacle. A spring plates is interposed between the set screw and the alignment rod. The spring plates contain protrusions that engage the sections of buttress thread on the alignment rod. The threaded shaft of the pedicle screw has an upper section and a lower section. A threaded connecting rod interconnects the sections. The upper section, lower section and threaded connecting rod all have external threads of the same thread pitch.

A spinal stabilization device that can be used to non-invasively correct spacing and curvature between at least two vertebral structures. The spinal stabilization device includes two telescoping tubes wherein ends of the two tubes can have pedicle screws that can be fastened to two or more vertebral bones. The overall length of the spinal stabilization device can be adjusted by moving the inner tube within the outer tube. Both the outer tube and the inner tube have multiple holes for receiving fasteners, wherein a fastener can be inserted through a hole in the outer tube into a hole in the inner tube for interlocking the inner tube and outer tube. The extension of the fastener into the holes and retraction from the holes can be controlled non-invasively from an external source. When the fastener is disengaged, the inner tube and the outer tube can freely move relative to each other, and the positions of the two or more vertebral bones can be non-invasively adjusted by subjecting a person to predefined movements and body posture. Upon achieving the desired positions, the fastener can be engaged to interlock the inner tube and the outer tube.

A rod system, in particular, for the spine, includes a first rod, a second rod, and a connector for connecting the first rod and the second rod. The connector includes a main body defining a first rod seat configured to hold the first rod in a fixed manner and a second rod seat configured to accommodate a second rod, and a fixation member and a closure member that are interchangeably mountable to the main body. When the fixation member is mounted to the main body, the fixation member is engageable with the portion of the second rod to hold the second rod in a fixed manner relative to the main bod, while when the closure member is mounted to the main body, the closure member is configured to hold the second rod to the main body in a slidable manner.

An implantable growing rod assembly adapted to be secured along a length of a spine for treating deformities of the spine. The assembly includes a housing, a fixed rod extending along a longitudinal axis away from the housing, and an expansion rod extendible from the housing along the longitudinal axis. A driver assembly is fixed to the housing and adapted to translate the expansion rod along the longitudinal axis. Examples of the implantable growing rod assembly include a smart growing system, and an autonomous growing rod system.