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.

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.

There are provided a surgical jig (24) which is directly used during surgery to make it possible to accurately recognize a position where a recess (44, 46) is to be formed in the surface of a surgical target bone (14) of a patient; and a verification jig (34) which is directly used during surgery to make it possible to precisely verify whether or not the recess (44, 46) formed in the surface of the surgical targeted bone (14) of the patient is of a required shape. The surgical jig (24) has an inner surface (26) matching the surface shape of the surgical target bone (14) of the patient, and a penetrating opening (30, 32) formed in correspondence with a site where the recess (44, 46) is to be formed. The verification jig (34) has a protrusion (40, 42) protruding from an inner surface (36) thereof in correspondence with the recess (44, 46) to be formed.

A tool, consisting of an enclosure and a rotatable knob retained by, and protruding from, the enclosure. The tool has a tube having a proximal end that is retained by the enclosure, and the tube has an axis of symmetry. A Geneva drive is retained within the enclosure, the Geneva drive consisting of a drive wheel fixedly attached to the rotatable knob and a driven wheel fixedly attached to the proximal end of the tube, so that an axis of rotation of the driven wheel coincides with the axis of symmetry of the tube. Thus, a continuous rotation of the rotatable knob causes the tube to rotate about the axis of symmetry in discrete angular steps.

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.

In one embodiment, a drill guide for an implantable medical device includes a template comprising a turntable having a drill guide opening; and a drill clip connected to the turntable. In one embodiment, a drill guide for an implantable medical device includes a template comprising a template opening and a turntable having a drill guide opening coaxially aligned with the template opening, a drill interface connected to the turntable, and a support element connected to the drill interface extending from the turntable and offset from the drill guide opening.

A positioning aid for surgical procedures has a carrier system and a template. The carrier system consists of a carrier plate, which is provided with a recess, and supports. The carrier plate can be secured to a cranial bone via the supports over an operating field for the surgical procedure. The template has a template plate which can be connected to the carrier plate in a play-free manner and which comprises a guiding aperture. The guiding aperture is arranged and oriented in the template plate, which consists of a blank, in an individualized manner according to coordinates ascertained in advance. The central longitudinal axis of the guiding aperture matches a trajectory for accessing the operating field for the surgical procedure when the carrier system and the template are assembled and the carrier system is secured to the cranial bone.

A surgical guide tool and methodology includes a non patient-specific platform including one or more supports for attaching to a body part of a subject. A non patient-specific block has a top planar surface and a bottom planar surface, and includes a guide aperture extending from the top planar surface to the bottom planar surface for guiding a surgical instrument in making at least one of a cut and a drill hole. An intermediate module is removably positioned between the platform and the block. The intermediate module has patient-specific dimensions such that the guide aperture has a desired alignment relative to the body part when the surgical guide tool is attached to the body part of the patient and the intermediate module is positioned between the platform and the block.

The present disclosure relates to a device that can guide perpendicular drilling and simultaneously measure flatness of an insertion surface through a locking protrusion by rotating the device in bone conduction implantation. According to the present disclosure, it is possible to measure flatness and guide perpendicular boring with a constant force even without using a separate flatness measurer in surgery. Further, it is also possible to guide drilling using a spacer having a smaller diameter by using an assistant guide member.