According to some embodiments, systems and methods of ultrasonic detection of implantable medical device distraction are provided. The system includes a first elongate member and a second elongate member. The first elongate member has a first end that is configured to be attached to a first location on the skeletal system of a subject, a second end, and at least one landmark identifiable using ultrasound. The second elongate member has a first end that is movably coupled to the second end of the first elongate member, a second end configured to be attached to a second location on the skeletal system, and at least one landmark identifiable using ultrasound. Movement of the first elongate member in relation to the second elongate member causes a corresponding movement of the at least one first landmark in relation to the at least one second landmark which can be detected using ultrasound.

A method for inserting an interspinous spinal implant into an opened gap between first and second spinous processes of adjacent superior and inferior vertebras, respectively includes the following. First forming an opened gap between a first spinous processes of a superior vertebra and a second spinous processes of an adjacent inferior vertebra by first inserting a decompression knife into diseased areas of the adjacent superior and inferior vertebras, then cutting fascia tissue, then separating soft tissue from bone by rocking the decompression knife back and forth, and then inserting a broach cutter into the diseased areas of the adjacent superior and inferior vertebras and cutting interspinous ligament between the adjacent superior and inferior vertebras. Next, determining and selecting an appropriate sized and shaped interspinous spinal implant for the opened gap by inserting a sizing tool into the opened gap, and sizing the opened gap with the sizing tool. Next, inserting the selected interspinous spinal implant into the opened gap with an insertion tool, and then compressing first and second elongated components of the interspinous spinal implant onto first and second opposite sides of the first and second spinous processes with a compressor tool, respectively. Finally, locking the interspinous spinal implant onto the first and second spinous processes of the adjacent superior and inferior vertebras with a locking driver.

The present disclosure provides an interspinous process device. The interspinous process device may include a main body having a cavity formed therein, the main body being configured to be disposed between the two adjacent spinous processes; and a spacer configured to be arranged in the cavity of the main body. When the main body is disposed between the two adjacent spinous processes and the spacer is arranged in the cavity of the main body, a volume of the cavity may be greater than a volume of the spacer, a height of the cavity may be equal to a height of the spacer, and a width of the cavity may be greater than a width of the spacer.

An implantable device may comprise a barrel, the barrel having an upper portion and a lower portion. The barrel may be configured to transition from a collapsed form having a first height to an expanded form having a second height and wherein the second height is greater than the first height. The implantable device may further include an actuator assembly disposed in the barrel, the actuator assembly comprising a front ramped actuator in engagement with the barrel, a rear ramped actuator in engagement with the barrel, and a central screw that extends from the rear ramped actuator through the front ramped actuator. The implantable device may further comprise a first plate and a second plate.

An interspinous process device is configured for placement between adjacent spinous processes on a subject's spine. The device includes a housing configured for mounting to a first spinal process, the housing having a lead screw fixedly secured at one end thereof. A magnetic assembly is at least partially disposed within the housing and configured for mounting to a second spinal process. The magnetic assembly includes a hollow magnet configured for rotation within the magnetic assembly, the hollow magnet comprising a threaded insert configured to engage with the lead screw. An externally applied magnetic field rotates the hollow magnet in a first direction or a second, opposite direction. Rotation of the hollow magnet in the first direction causes telescopic movement of the magnetic assembly out of the housing (i.e., elongation) and rotation in the second direction causes telescopic movement of the magnetic assembly into the housing (i.e., shortening).

An implantable device may include a barrel, the barrel having an upper portion and a lower portion. The implantable device may further include an actuator assembly disposed in the barrel, and a central screw that extends from a rear ramped actuator through a front ramped actuator. The implantable device may further include a first plate having multiple projections extending from one side of the first plate. The implantable device may further include a second plate having multiple projections extending from one side of the second plate, the second plate configured to be received on the central screw. The barrel may be configured to transition from a collapsed form having a first height to an expanded form having a second height and wherein the second height is greater than the first height.

A surgical kit includes a shield for covering a portion of the spine of a subject. The shield can include an attachment portion adapted to engage a bone fixation assembly which is adapted to be fixed on multiple vertebra bones of the subject. The bone fixation assembly can include a vertebra joining member secured between two bone anchors. Each bone anchor can include a fastener portion adapted to be implanted into a vertebra bone and a head coupling portion adapted to secure the vertebra joining member. The shield can be coupled to the bone fixation assembly via separate coupling elements, such as a clip or an adjustable link secured between two vertebra joining members of the bone fixation assembly. Alternatively, the shield can include an integral attachment portion configured to engage the bone fixation assembly directly.

A system and method for providing a spinal implant having a main body, a proximal anchor, a distal anchor, and an internal plunger. The proximal anchor comprises a nut having an internal bore. The distal anchor comprises a plurality of wings having a first closed configuration and a second open configuration. The internal plunger is housed within a central bore of the main body. The distal end of the internal plunger is operatively connected to the first wing and the second wing to selectively move the wings between the first closed configuration and the second open configuration, and vice versa.

Various surgical instruments, implants, and their methods of use are disclosed. The surgical instruments are usable to insert various implants into a patient through an access portal in a minimally-invasive manner. The implants are rotatable between different orientations using the instruments to change the footprint of the implant and allow the implant to be inserted through the minimally-invasive access portal.

An insertion instrument for inserting an implant includes an elongated main body having a proximal handle and a distal portion that selectively couples to the implant. A wing actuation tool is slidably engaged in a central passage of the elongated main body to fix the implant to the elongated main body. The wing actuation tool temporarily attaches to the implant allowing for deployment and retraction of wings of the implant during surgery. Longitudinal translation of the wing actuation tool deploys an actuation plunger of the implant.