A universal low-profile intercranial assembly includes a mounting plate and a low profile intercranial device composed of a static cranial implant and an interdigitating functional neurosurgical implant. The low profile intercranial device is shaped and dimensioned for mounted to the mounting plate.

An implant, a fitting plate suitable for placing of an implant, and a method for manufacturing an implant suitable for application on one or more bones.

Methods and systems of augmenting an implant intraoperatively and preparing a cone for revision surgical procedure are disclosed. A system includes a cutting device, a tracking and navigation system and a cutting system in operable communication with the cutting device and the tracking and navigation system. The cutting device includes a communication system, a cutting element, and a plurality of optical trackers. The tracking and navigation system is configured to detect a location of optical trackers. The control system is configured to cause the tracking and navigation system to detect the location of the cutting device, determine a revised shape for an implant cavity, cause the cutting device to cut the implant cavity to the revised shape, select a shape for a cone to be placed in the revised implant cavity, and machine the cone to the selected shape.

The present invention includes a method for generating a three-dimensional model of a bone. The method may further include generating a cut plan for excavating a portion of the bone according to the cut plan to allow the insertion of a custom implant. In a particular arrangement, the method may includes excavating the bone with an autonomous extremity excavator utilizing the cut plan generated by a processor. In a further arrangement, the method may include generating a digital model of a custom implant and generating, using the digital model, a physical model sharing the same dimensions as the digital module using manufacturing device.

A method of resurfacing a glenoid according to an according to an exemplary aspect of the present disclosure includes resurfacing a first section of a glenoid surface with and implant while leaving a second section of the glenoid surface uncovered by the implant.

Augmentation material having a wire and, in axial alignment along the wire, a plurality of groups of axially adjacent connecting elements that extend radially from the wire, wherein the connecting elements are designed such that, when a first group from the plurality of groups is pressed together with a further group from the plurality of groups, the connecting element of the two groups can be connected to one another in a positive-locking and/or friction-locking manner.

There is provided a device for supporting an object during machining thereof, the object having a first object surface having a patient-specific configuration and a second object surface opposite the first object surface. The device comprises a support member adapted to support the object, the support member having a support surface shaped using patient-specific modeling and configured to matingly engage at least a portion of the first object surface for exposing the second object surface for machining thereof.

A fiber-based surgical implant stabilized against fraying, includes a thermally crimped flat-knitted fabric of a biocompatible, optionally biodegradable, polymer material having a glass transition temperature or other thermally induced secondary conformational mobility threshold in the temperature range of from 20° C. to +170° C. Also disclosed is a corresponding fabric and methods of producing the implant and the fabric.

A device promotes osseointegration between two adjacent vertebrae. The device includes a spacer fabric having a top layer, a bottom layer, and intermediate filler fibers connecting the top layer and the bottom layer. The spacer fabric is capable of expanding to fill a gap between two adjacent vertebrae.

A method of cutting metallic foams that eliminates the problem of smeared surfaces is provided. The method involves infiltration of the foam with another material to serve as a support structure to the foam when being cut. The method can be executed using softer polymeric materials such as waxes, which are then frozen for machining. These materials are subsequently heated and removed from the foam. In a similar manner, epoxy material can be used, which requires no freezing. In this method, the epoxy material is burnt from the foam upon completion of machining. The method allows for machining foams using conventional machining processes, rather than non traditional methods such as electrical discharge machining.