An anchoring system for cannulas or tools to be inserted into a surgical workspace in the body, particularly the brain, of a patient. The system comprises a grommet which may be fixed to the skull to both secure the system to the skull and protect the skull opening from passage of cannulas and tools, a resilient clip with grasping jaws adapted to firmly grasp a cannula or tool, and a flexible membrane secured to the outer rim of the grommet and the clip.

A method and device for ensuring better placement of an implant, such as an implant that is affixed via bone bed drilling to a recipient's skull. In particular, the technology comprises an apparatus and method of deploying the same that can lead to an improved goodness of fit of the implant. The apparatus and process of the present disclosure are particularly applicable to affixing auditory prostheses such as cochlear implants. The implant is provided with a template that has the same dimensions as the implant that is to be affixed. This template has a dye-impregnated material on its distal surface that is used during bone bed drilling to identify bony spots that have to be drilled away to get a flat surface and a better alignment of the implant with the bone bed. The template may also be provided in kit form.

Disclosed is a system to engage a plurality of tools. In the system a drive shaft and collet may be assembled to engage and disengage, selectively, a plurality of tools. User selection may allow use of a plurality of tools during a procedure or during a plurality of procedures.

A therapeutic hydrogel material includes a hyaluronic acid-based hydrogel matrix containing naked heparin nanoparticles distributed and entrained within the matrix. The naked heparin nanoparticles contained in the matrix are not immobilized to any other molecules at the time of delivery. In one aspect of the invention, the therapeutic hydrogel material is used to repair ischemic tissue in a subject (e.g., mammal). The therapeutic hydrogel material may also be used to treat wounds or other damaged tissue. To treat the subject or patient, the site of application is located and the therapeutic hydrogel material is injected or otherwise delivered (with or without a delivery device) to the delivery location along with a crosslinker.

The present invention provides minimally invasive subdural evacuating systems and methods of use thereof. The subdural evacuating systems include a cutting component and a rod component, wherein the rod component provides an external physical indicator that the surface of the dura mater has been reached, permitting the cutting component to accurately pierce the dura mater with minimal to no risk of damaging any adjacent anatomy.

A surgical system includes a surgical tool, a tracking system configured to obtain tracking data indicative of positions of the surgical tool relative to an anatomical feature, an indicator light configured to emit light, and a computer system programmed to control the indicator light to change a color of the light based on the tracking data.

A ventricular guide for ventriculostomy which includes a curved base plate, an upstanding support member which extends upwardly from the base plate and an upper support member which extends transversely from the upper end of the upstanding member. A first tubular guide, having a bore extending therethrough, is secured to one end of the upper support member. A second tubular guide, having a bore extending therethrough is secured to the other end of the upper support member. The bores of the tubular guides may have a drill bit, needle or catheter extending downwardly therethrough.

A method of generating resection data for use in planning an arthroplasty procedure on a patient bone covered at least partially in cartilage includes receiving a three-dimensional patient bone model comprising a bone model surface, and correlated with a position and orientation of the patient bone via a navigation system. The method further includes identifying a target region on the bone model surface of the model for intra-operative registration, and receiving location data for a first plurality of points based on the intra-operative registration of the cartilage on the patient bone in locations corresponding to points within the target region on the bone model surface. The method further includes determining resection depth based at least in part on the location data for the first plurality of points; and generating resection data using the resection depth, the resection data configured to be utilized by the navigation system during the arthroplasty procedure.

An anchoring system for cannulas or tools to be inserted into a surgical workspace in the body, particularly the brain, of a patient. The system comprises a grommet which may be fixed to the skull to both secure the system to the skull and protect the skull opening from passage of cannulas and tools, a resilient clip with grasping jaws adapted to firmly grasp a cannula or tool, and a flexible membrane secured to the outer rim of the grommet and the clip.

A method includes generating an anatomical model corresponding to an anatomical feature of a patient, proposing a component for coupling to the anatomical feature of the patient, positioning a virtual model corresponding to the component in a proposed location relative to the anatomical model, generating a planned resection geometry based on a virtual relationship between the virtual model and the anatomical model, tracking movement of a surgical instrument relative to the anatomical feature, and simultaneously displaying the planned resection geometry, the anatomical model, and a graphic corresponding to the surgical instrument on a display based in part on the tracked movement of the surgical instrument relative to the anatomical feature.