Tools adapted for spinal surgery are provided. More specifically, tools having an elongate cylindrical cannula connected to a plurality of sharp-edged blades are provided for imparting a force for displacing vertebral bodies. Apparatuses and methods for accurate, rapid, and reliable placement of surgical cages or other medical implants in a patients spine are also provided.

An adjustable loop ring stripper for stretching an arterial wall outwardly as plaque is excavated inwardly.

Methods and devices for harvesting cancellous bone are disclosed. The bone-harvesting device may include a cannula and a bone receptacle in communication with the cannula, wherein the cannula including a cutting surface positioned at or adjacent the distal end, the cutting surface being oriented at an angle, the angle being greater than 90 degrees relative to the longitudinal axis of the cannula, and the harvested bone is adapted to move from a position adjacent to the cutting surface through the cannula into the bone receptacle. The cutting surface of the cannula may be positioned at or adjacent the distal end, and positioned at least in part radially outward of the outer face of the cannula. The cannula may include a cutting surface positioned at or adjacent the distal end and an occluding geometry that partially occludes the distal end of the cannula adjacent the cutting surface. In addition, a suction port may be provided in communication with the bone receptacle.

A cartilage repair technique employs a cutter-tissue trap combination device to harvest cartilage tissue from a low-weight-bearing site of a subject. Cut tissue is aspirated though a lumen of a tissue cutter. The lumen includes an outer shaft having a first distal window and an inner shaft having a second distal window. Edges of the first distal window and the second distal window cooperate to provide a cutting action there-between upon rotation of the inner shaft within the outer shaft. A tissue trap coupled to the tissue cutter is configured to collect tissue shavings of a desired size to efficiently deliver the collected shavings to a repair site during surgery. The tissue trap includes a filter in a housing configured between a removable inflow chamber and a removable outflow chamber.

A cartilage repair technique employs a cutter-tissue trap combination device to harvest cartilage tissue from a low-weight-bearing site of a subject. Cut tissue is aspirated though a lumen (1101) of a tissue cutter (1100). The lumen includes an outer shaft (1106) having a first distal window and an inner shaft having a second distal window. Edges of the first distal window and the second distal window cooperate to provide a cutting action there-between upon rotation of the inner shaft within the outer shaft. A tissue trap (1400) coupled to the tissue cutter is configured to collect tissue shavings of a desired size to efficiently deliver the collected shavings to a repair site during surgery. The tissue trap includes a filter (1502) in a housing configured between a removable inflow chamber (1404) and a removable outflow chamber (1406).

A device having a hub assembly and a lever coupled with the hub assembly is provided. The device includes a sheath coupled with the lever and extending from the hub assembly. The sheath has a surgical elevator with a surgical elevator edge along with a hypotube having an access hole. The device has a shaver blade assembly with an outer shaft having an outer blade and an inner blade within the outer blade. The outer shaft has a stop and an access hole near the outer and inner blades. The sheath partially surrounds the outer shaft and the lever moves between a first position and a second position. In the first position, the surgical elevator edge abuts the outer shaft stop and the outer shaft access hole aligns with the hypotube access hole. In the second position, the surgical elevator edge is spaced apart from the outer shaft stop.

A platform device for material excision or removal from vascular structures for either handheld or stereotactic table use may comprise a work element or elements configured to selectively open and close at least one articulable beak or scoopula configured to penetrate and remove intra-vascular materials or obstructions, or follow a central lumen of another device or over a wire in a longitudinal direction. Flush and vacuum tissue transport mechanisms may be incorporated. A single tube or an inner sheath and an outer sheath which may be co-axially disposed relative to a work element may be configured to actuate a beak or beaks or scoopulae and provisions for simultaneous beak or scoopula closing under rotation may be incorporated.

A surgical instrument includes a first member defining an axis and having a scraping surface configured to scrape tissue. A second member includes a cutting surface that is rotatable relative to the first member. The second member has a maximum length defined by opposite end surfaces of the second member. The end surfaces are each disposed within the first member. A third member includes an outer surface defining at least a portion of a passageway configured for disposal of the scraped tissue. The third member is fixed with the first member. The cutting surface is rotatable relative to the third member to transfer the scraped tissue along the axis. Systems and methods are disclosed.

A motorized suction dilation and curettage device includes a handheld grip with an integrated motor and a tube interface for coupling between the motor and a rotatable cylinder. The rotatable cylinder grips a rotatable tube coupled between a curette and a flexible hose of a vacuum machine. The vacuum machine generates a suction force through the flexible hose, rotatable tube, and attached curette. When the motorized suction dilation and curettage device is activated, the motor generates a rotational force that is applied to the rotatable tube and the attached curette via the tube interface, thereby enabling a health care provider to control motorized rotation of the curette.

A method for performing an efficient and thorough percutaneous discectomy includes making into the patient a percutaneous incision, which is a small stab wound, no more than approximately 10 mm in length. A stimulated combination neuro-monitoring dilating probe is passed through an approximately 10 mm or less skin incision and into a patient's disc space to establish a safe path and trajectory through Kambin's Triangle. Once a neuro-monitoring dilating probe is in the disc space, a second dilator is placed over the neuro-monitoring dilating probe and impacted into the disc space. Neuro-monitoring dilating probe may then be removed. An access portal optionally combined with a force dissipation device may then be placed over the second dilator and into the disc space. The second dilator is removed and then discectomy instruments may be placed through the access portal to perform the discectomy.