Tools for positioning an implant into the sacroiliac joint. A directional cannula includes a main body having a bore that receives the implant. A cut-out, allowing access to the joint, is formed in a leading end of the main body. A pair of parallel prongs extend from the leading end of the main body in transversely spaced apart relation to one another. A drill guide has a main body of rectangular transverse cross-section and a cylindrical head formed integrally with the main body. A transverse width-reducing step is formed in the main body near its distal end. First and second bores are formed in the cylindrical head and in the main body. Both bores are eccentric relative to the drill guide longitudinal axis of symmetry. The drill guide is rotated 180 after first and second drilling operations, prior to third and fourth drilling operations.

A fastener caddy for use with a bone plate. The fastener caddy includes preloaded fasteners that are positioned above the fastener apertures in the bone plate once the caddy is coupled to the bone plate. The caddy permits the driving of fasteners with the fastener already in proper alignment and without the need to retrieve each individual fastener. Once the fasteners are installed into the bone plate.

A fastener guide that includes a body. The body includes a through-bore configured for receiving a fastener and an end configured for contacting a bone plate. The fastener guide further includes at least one member configured for contacting and retaining the fastener within the body.

A surgical system includes an implant having a first attachment mechanism and an insertion instrument having a proximal end, a distal end, and a second attachment mechanism disposed at the distal end for removable connection with the first attachment mechanism. The proximal end of the insertion instrument is pivotable with respect to the implant. The insertion instrument can include an inserter and a guide. A method of using the surgical system is provided.

An intervertebral expandable implant with first and second vertebral body engagement surfaces includes first and second implant structures defining first and second angled wedge portions. The first angled wedge portion has first and second inwardly-facing rails and first and second inwardly-facing slots. The second angled wedge portion has first and second outwardly-facing rails and first and second outwardly facing slots. The first implant structure is slidably-engaged with the second implant structure with the first inwardly-facing rail positioned in the first outwardly-facing slot, the second inwardly-facing rail positioned in the second outwardly facing slot, the first outwardly-facing rail positioned in the first inwardly-facing slot, and the second outwardly-facing rail positioned in the second inwardly-facing slot.

A self-drilling bone fusion screw apparatus is disclosed which includes at least first and second sliding boxes. A first screw member having a tapered end and a threaded body is disposed within the first sliding box, and a second screw member having a tapered end and a threaded body disposed within the second sliding box. An adjuster adjusts the height of the sliding boxes. The screw members are screwed into vertebral bodies in order to fuse the vertebral bodies together. A plurality of the self-drilling bone fusion screw apparatuses may be attached together and/or integrated via a plate or cage. Also disclosed is a cervical facet staple that includes a curved staple base and at least two prongs attached to the bottom surface of the curved staple base.

Methods and devices are provided for anchoring a ligament or tendon to bone. In one embodiment, a surgical implant is provided having a sheath and an expander that is received within the sheath. Various delivery tools, including a sheath inserter and a driver, are also provided. In use, the sheath inserter can be used to position a tendon within a prepared bone hole, and it can be used to deliver the sheath with a guidewire coupled thereto into the bone hole. The driver can be provided for delivering the expander into the sheath. A loader can optionally be used to load the driver and expander onto the guidewire coupled to the implanted sheath.

Tools for positioning an implant into the sacroiliac joint. A directional cannula includes a main body having a bore that receives the implant. A cut-out, allowing access to the joint, is formed in a leading end of the main body. A pair of parallel prongs extend from the leading end of the main body in transversely spaced apart relation to one another. A drill guide has a main body of rectangular transverse cross-section and a cylindrical head formed integrally with the main body. A transverse width-reducing step is formed in the main body near its distal end. First and second bores are formed in the cylindrical head and in the main body. Both bores are eccentric relative to the drill guide longitudinal axis of symmetry. The drill guide is rotated 180? after first and second drilling operations, prior to third and fourth drilling operations.

A modular system is provided for assembling a structure to secure to opposite sides of a fracture in a bone of a subject. The modular system includes a plate with a perimeter including a plurality of openings. The perimeter defines an interior area within the plate. The modular system also includes a link with one or more openings along a linear axis defining the link. The one or more openings of the link include a connector to receive a fastener to be secured in the bone. The plurality of openings of the plate includes a first opening with an inner diameter configured to removably receive an outer diameter of the connector of the link so that the link is rotatably received within the first opening. A method is also provided for assembling the structure using the modular system and securing the assembled structure to opposite sides of the bone fracture.

Compression devices for joining tissue and methods for using and fabricating the same.