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.

A spinal adjustment system including at least one thermally actuated pump element.

A system for moving a portion of a patient's body including a housing having a first cavity extending along a longitudinal axis, a first distraction rod having a proximal end and a distal end, the first distraction rod and the housing being telescopically displaceable with respect to each other along the longitudinal axis, the first distraction rod having a cavity extending along the longitudinal axis, a second distraction rod having a proximal end and a distal end and configured to be telescopically displaceable from within the second cavity along the longitudinal axis, and a drive system configured to move the first distraction rod in relation to the housing and to move the second distraction rod in relation to the first distraction rod.

The present disclosure relates to a dynamic-seal-less self-actuating growing rod system (100) comprising at least one cylindrical static rod (2), at least one piston rod (6), coaxially coupled with said static rod (2) and configured to distract longitudinally out of the static rod (2); at least one fluid source (8) holding at least one sterile biocompatible fluid at a pre-determined pressure; at least one fluid transfer port (10) configured to transfer said sterile biocompatible fluid in said fluid source (8) to at least one fluid receptacle (12) at the same pre-determined pressure, wherein said at least one fluid receptacle (12) is in contact with said second piston end (6b) of said piston rod (6) at a first receptacle end (12a) and is connected to said fluid transfer port (10) at a second receptacle end (12b).

A spinal adjustment system including at least one thermally actuated pump element.

An expandable rod system includes a first rod portion having an internal cavity, a second rod portion sealingly positioned within the internal cavity of the first rod portion and moveable in a first axial direction relative to the first rod portion, and an osmotic chamber for receiving an osmotic agent to facilitate movement of the second rod portion to expand the rod system. The rod system includes a lock assembly engageable with the second rod portion to prevent the second rod portion from moving in a second axial direction. The lock assembly includes a tapered ramped portion and a bearing member that is moveable within the tapered ramped portion such that when compression forces are imparted on the second rod portion, the bearing member becomes wedged in the tapered ramped portion.

A method of changing a bone angle includes creating an osteotomy between a first portion and a second portion of a tibia of a patient; creating a cavity in the tibia by removing bone material along an axis extending in a substantially longitudinal direction from a first point at the tibial plateau to a second point; placing a non-invasively adjustable implant into the cavity, the non-invasively adjustable implant comprising an adjustable actuator having an outer housing and an inner shaft, telescopically disposed in the outer housing, and a driving element configured to be remotely operable to telescopically displace the inner shaft in relation to the outer housing; coupling one of the outer housing or the inner shaft to the first portion of the tibia; coupling the other of the outer housing or the inner shaft to the second portion of the tibia; and remotely operating the driving element to telescopically displace the inner shaft in relation to the outer housing, thus changing an angle between the first portion and second portion of the tibia.

The present disclosure relates to a dynamic-seal-less self-actuating growing rod system (100) comprising at least one cylindrical static rod (2), at least one piston rod (6), coaxially coupled with said static rod (2) and configured to distract longitudinally out of the static rod (2); at least one fluid source (8) holding at least one sterile biocompatible fluid at a pre-determined pressure; at least one fluid transfer port (10) configured to transfer said sterile biocompatible fluid in said fluid source (8) to at least one fluid receptacle (12) at the same pre-determined pressure, wherein said at least one fluid receptacle (12) is in contact with said second piston end (6b) of said piston rod (6) at a first receptacle end (12a) and is connected to said fluid transfer port (10) at a second receptacle end (12b).

A method for adjusting an adjustable implant includes broadcasting identification information from an adjustable implant implanted within a subject, receiving wirelessly with the adjustable implant, from a device external to the subject, an adjustment setting configured to be executed by the adjustable implant, receiving wirelessly with the adjustable implant, from a device external to the subject, an instruction to perform the adjustment setting, activating a motor on the adjustable implant to perform the adjustment setting, and sending, to a device external to the subject, a progress of the adjustment setting.

A device for bone adjustment in a mammal. The device comprising two or more anchoring devices adapted to implanted intramedullary and attached to a bone in said mammal and an adjustment device for exerting force on said anchoring devices, said adjustment device being adapted to postoperatively adjust at least one of the distance between or orientation of, at least two of said anchoring devices. The operation device further comprises a motor and said operation device is adapted to operate said adjustment device. The operation device further comprises a gearbox connected to the motor, wherein an outgoing speed from the gear box is lower than the speed by the motor alone, accomplished by the gearbox, and wherein the outgoing speed of the gearbox is less than 10 turn per second during normal operation. The device also comprises a control device adapted to control the operation device, wherein the control device is: programmed to control the device according to a pre-programmed time-schedule, and programmed to control the device based on input from a sensor or measuring device sensing any possible physical parameter of the patient or any functional parameter of the system.