Bone transplant made of a cortical bone substance having a screw shank and a screw head for introducing a screwing-in torque. Both the screw shank and the screw head are provided with an external thread, in which at least the external thread of the screw shank is a multi-start thread. Due to the design, on the one hand a certain stroke can be achieved with fewer revolutions or in a shorter time, whereby the screwing-in behavior is improved and the tendon tissue is protected. On the other hand, the use of multiple threads provides a high surface area for the tendon tissue to grow on the tendon anchor, which improves fixation of the tendon and increases rotational stability. The bone transplant according to the invention thus ensures good fixation of the tendon and can be implanted quickly.

A screw implant is provided for the distraction, fusion, or compression of two adjacent bone structures or two adjacent bone fragments. The implant is a fully threaded screw with a headless proximal end having a drive engagement feature and a blunt distal end for insertion into bone or related tissue. The implant has roughened and porous surfaces throughout and is fully coated with hydroxyapatite and/or tri-calcium phosphate to allow for bone in-growth. The implant may have uniform low pitch cortical threads, or variable pitch threads, with low pitch cortical threads on one end and larger pitch cancellous threads on the other end. The implant may be used for the distraction of spinal vertebrae. The implants may have a cannulation channel and fenestrations.

A bone fastener comprises a first member comprising a first surface defining an implant cavity. The first member includes a first part being non-rotatable relative to the first surface and a second part including a second surface defining a portion of the implant cavity and a slot. A second member is configured to penetrate tissue and is connectable with the first member. The first member is rotatable relative to the second member in a first plane of a body and the second part is movable relative to the first part in a second plane of the body such that the first part is relatively translatable in the slot. Implants, systems, instruments and methods are disclosed.

A surgical system includes a sleeve defining a passageway. An adapter is removably coupled to the sleeve. The adapter defines a channel. A delivery device includes a distal end positioned in a channel of the adapter. A bone fastener includes a head and a shank defining a cannula. A distal portion of the adapter is positioned in the shank such that the channel is in communication with a cannula of the shank. A plunger is movably disposed in a lumen of the delivery device. The plunger is configured to move a material through the lumen and the channel and into the cannula. Methods and kits are disclosed.

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.

A system for facet joint fusion includes a cannula having a body and a navigation arm mounted to the body. The navigation arm includes a base and a plurality of individual arms mounted to the base. The navigation arm also includes one or more markers mounted to the plurality of individual arms. The system also includes an imaging system configured to identify a position of the one or more markers relative to a facet joint of a patient. The system further includes a rotary tool that is configured to mount within the cannula. The rotary tool is configured to create a void in the facet joint by way of the cannula, and the void is configured to receive a bone graft or bone growth promoting material.

A surgical system includes a sleeve defining a passageway. An adapter is removably coupled to the sleeve. The adapter defines a channel. A delivery device includes a distal end positioned in a channel of the adapter. A bone fastener includes a head and a shank defining a cannula. A distal portion of the adapter is positioned in the shank such that the channel is in communication with a cannula of the shank. A plunger is movably disposed in a lumen of the delivery device. The plunger is configured to move a material through the lumen and the channel and into the cannula. Methods and kits are disclosed.

A surgical instrument comprises a first member extending between a proximal end and a distal end configured for fixation with tissue. A second member defines a longitudinal passageway and is connected with a navigation component such that the distal end is disposable with the passageway at a selected distance from the navigation component. The navigation component is positioned relative to a sensor to communicate a signal representative of an orientation of the first member. A third member extends between a proximal end and a distal end. The third member is mountable with the first member along the orientation such that the distal end of the third member is engageable with the tissue. Systems, spinal implants, constructs and methods are disclosed.

Disclosed herein are minimally invasive systems and method for stabilizing the spine, while preserving a degree of spinal flexion and extension of the spine at the level of the stabilized vertebrae postoperatively. The systems and methods can include an expandable anchor and rod that span an intervertebral disc. The anchor can have interstices, and ends in two adjacent vertebral bodies. The system can also include a volume of bone cement media.

A system for percutaneous or open facet joint fusion includes an imaging system configured to identify a docking location on a facet joint between a first vertebra and a second vertebra of a patient. The system also includes a cannula configured to be positioned at the docking location on the facet joint. The cannula includes one or more markers mounted thereto, and the imaging system is configured to identify the one or more markers to position the cannula at the docking location. The cannula also includes one or more actuators configured to move the one or more markers. The system further includes a rotary tool that is configured to mount within the cannula. The rotary tool is configured to create a void in the facet joint by way of the cannula, and the void is configured to receive a bone graft or bone growth promoting material.