This disclosure relates to assemblies and methods for repairing bone defects. The assemblies disclosed herein may be utilized for determining a dimension of a surgical site and removing bone prior to positioning a graft and/or implant at the surgical site.

The disclosed subject matter relates to a system and method for preparing a surface of a bone proximate a joint, in which the preparation includes boring a plurality of arced channels/troughs in the bone surface using an arch drill assembly guided by plural guide bores along a predetermined longitudinal arc. The bored troughs create a scalloped surface on the bone to which an inverse contoured joint insert/implant having cooperating convex ridges engages. The plural guide bores are also defined by the predetermined longitudinal arc which may be circular or helical. The disclosed subject matter minimizes bone removal and allows greater access options for preparing the bone surface.

Systems, methods, and devices for drilling and imaging an anatomical element are provided. An image may be received from an imaging device coupled to a housing. The image may depict hard tissue and/or soft tissue and the image may be processed using image processing to identify the hard tissue and/or soft tissue. A thickness of the hard tissue may be determined and instructions to perform a surgical step on the hard tissue when the thickness is less than a predetermined threshold may be transmitted.

Drill assemblies and methods for drilling into bone are provided. In general, a drill assembly can have a flexible distal portion configured to move between a substantially straight configuration, in which a longitudinal axis of the distal portion is aligned with a longitudinal axis of a proximal shaft portion of the drill assembly, and a curved configuration, in which the longitudinal axis of the distal portion is angularly offset from the longitudinal axis of the plurality of segments located between the proximal shaft and the drill tip. The drill assembly can include a connecting element extending from the proximal shaft, through the segments, and to the drill tip at a distal end of the drill assembly. The drill assembly can include a conformal covering on the distal portion thereof that is configured to curve.

The present invention provides a cutting tool for surgical procedures. More specifically, the present invention provides a rotary surgical cutting tool which overcomes the disadvantages of prior art surgical cutting tools by providing a rotary cutting tool having straight flutes, with each side of the flute being provided with a cutting edge that permits cutting in both directions during limited oscillatory motion of the rotary surgical cutting tool. The areas between the cutting edges are provided with relief to reduce friction while the flute moves the cut material away from the cutting edges.

A universal drill guide system includes a universal drill guide, interchangeable drill tubes, and interchangeable drill bits. Each interchangeable drill tube corresponds to one of the interchangeable drill bits, and can be detachably coupled to the universal drill guide. A cannulated drill with K-wire retention features a drill bit with a retention mechanism that prevents axial advancement of a K-wire during drilling. A drill removal tool includes a drill remover that can be placed around a drill bit to remove it from bone after a hole is drilled, while leaving a K-wire in place in the bone. A bone screw driver with K-wire retention includes a shaft that can be passed over a K-wire, a distal end for attachment to a cannulated bone screw, and a K-wire retention module for preventing advancement of the K-wire as the screw driver drives the cannulated bone screw into bone.

This disclosure relates to assemblies and methods for repairing bone defects. The assemblies disclosed herein may be utilized for determining a dimension of a surgical site and removing bone prior to positioning a graft and/or implant at the surgical site.

Devices, systems, and methods for performing a transcorporeal microdecompression are described. The transcorporeal microdecompression may include a bone void plug allograft and specialized instruments for performing the procedure. This procedure may be performed under navigation and/or with robotic assistance.

A cutter for cutting an implant is provided. The cutter includes a gearbox; a primary milling bit, a secondary milling bit and a lead screw operatively coupled to the gearbox; an input coupling coupled rigidly to the primary milling bit; and an implant coupler coupled rigidly to the lead screw, wherein the gearbox is operable to translate with respect to the lead screw and to drive the secondary milling bit in response to a driving force applied to the input coupling.

An apparatus and kit for making holes of controlled depth and different diameters on chondral and osteochondral surfaces, comprises: a reamer member (2) having a cutting head (3) for removing tissue from said chondral and osteochondral surface (A), said member (2) being mobile approaching the chondral and osteochondral surface (A) for arranging the head (3) at said tissue; guide means (4) for guiding the reamer member (2) that can be firmly associated with the chondral or osteochondral surface (A), said reamer member (2) being slidable along said guide means (4); and mechanical means (5) for controlling the depth of the hole interposed between the reamer member (2) and the guide means (4) for defining an end stop of the reamer member (2) in the respective movement towards said chondral and osteochondral surface (A).