The present invention relates to a mixed reality system integrated with a surgical navigation system including a group of moveable position markers configured on a surgical instrument; a position sensor sensing the group of moveable position markers to acquire an instrument coordinate for the surgical instrument; a registered positioning marker configured in proximity to a surgical area to acquire a surgical area coordinate for the surgical area; a plurality of mixed reality sensors detecting the registered positioning marker and a plurality of mixed reality information; a computing unit module configured to receive the instrument coordinate, the surgical area coordinate, the plurality of mixed reality information, and a digital model of the surgical area, to render the digital model corresponded to the surgical area, and to add a digital instrument object into the digital model in accordance with the instrument coordinate; and a mixed reality display providing for a user to view and showing the digital model and the digital instrument object to the user upon the receipt thereof.

The application describes devices, systems and methods related to an implantable device that is a stent or a heart valve. The implantable device includes a pressure sensor. The implantable device is for being introduced into a subject and for being wirelessly read out by an outside reading system. The pressure sensor comprises a casing with a diffusion blocking layer for maintaining a predetermined pressure within the casing and a magneto-mechanical oscillator with a magnetic object providing a permanent magnetic moment. The magneto-mechanical oscillator transduces an external magnetic or electromagnetic excitation field into a mechanical oscillation of the magnetic object, wherein at least a part of the casing is flexible for allowing to transduce external pressure changes into changes of the mechanical oscillation of the magnetic object.

A surgical introducer system having a sidewall that forms an introducer passage, and a probe receptacle at the distal end of the introducer. The probe receptacle begins at a proximal end and terminates at a distal end with the proximal receptacle end being between the distal receptacle end and the proximal introducer end. The receptacle's inner surface tapers continuously from the proximal end to the distal receptacle end, with the lateral size being greater at the proximal receptacle end. The inner surface receives the distal tip of a navigation probe and restricts movement of the distal probe tip in the lateral direction, and the sidewall is spaced from the navigation probe shaft to allow the shaft to move in the lateral direction within the passage when the distal probe tip is positioned in the probe receptacle.

Certain implementations of the disclosed technology may include active marker devices, retrofits, systems, and methods for determining the position of interventional devices under MRI. A marker device is provided that utilizes an optical fiber, an acousto-optical sensor region that includes an electro-mechanical conversion assembly, and one or more antenna(e). The one or more antennae are configured to receive MRI radio-frequency (RF) electromagnetic energy and produce a corresponding electrical signal corresponding to the position. The acousto-optical sensor region may include a resonator and may be modulated by acoustic waves generated responsive to the electrical signal received from the one or more antennae. The acousto-optical sensor region may be interrogated by light via the optical fiber to determine the position of the device for providing an active marker in the MRI image.

Medical apparatus includes a flexible insertion tube having a distal end configured for insertion into a cavity in a body of a living subject and containing a lumen passing through the insertion tube to the distal end. An inflatable balloon is deployable from the distal end of the insertion tube and configured to be inflated by passage of a fluid through the lumen while the probe is deployed in the cavity in the body. At least one flexible circuit substrate is attached to a surface of the inflatable balloon. One or more electrodes, which include a conductive material disposed on an outer side of the at least one flexible circuit substrate, contact tissue in the cavity in the body when the balloon is inflated. A spiral conductive trace is disposed on the at least one flexible circuit substrate.

Improved cross-calibration between magnetic resonance imaging (MRI) coordinates and optical tracking coordinates is provided. Initial calibration is performed with a calibration tool that includes wireless active markers that can be tracked using the MRI scanner, and an optical marker that can be tracked using the optical tracking system. Data from one or more poses of this tool are used to provide an initial cross-calibration. In use, this initial calibration is corrected to account for differences between actual camera position and the reference location. Here the reference location is the camera location at which the initial calibration was performed.

A system for tracking the position of one or more medical devices for insertion into the body of a patient is disclosed. The system may also be used to locate one or medical devices at a later time after placement thereof. The present system employs multiple radiating elements that can be simultaneously detected by a sensor unit of the system, wherein at least one of the radiating elements is included with the medical device. Another of the radiating elements may be placed at a predetermined point on the skin of the patient to serve as a landmark to help determine the location of the medical device with respect to the landmark. Detection of the radiating elements by the sensor unit enables the relative positions of the radiating elements to be ascertained and depicted on a display, to assist a clinician in accurately positioning the medical device, such as a catheter.

A system for cardiac treatment includes a monitoring probe having a probe distal end, a magnetic field generator coupled to the probe distal end, a catheter having a catheter distal end, a magnetic sensor coupled to the catheter distal end, and a console. The monitoring probe is configured for insertion into an esophagus of a patient. The catheter is configured for insertion into a heart of a patient. The console is configured to drive the magnetic field generator to emit magnetic fields, to receive signals from the magnetic sensor in response to the magnetic fields, and to estimate respective distances between the catheter distal end and the probe distal end based on the signals.

There is described a system for tracking at least one tool relative to a bone in computer-assisted surgery. The system generally has a processing unit; and a non-transitory computer-readable memory communicatively coupled to the processing unit and comprising computer-readable program instructions executable by the processing unit for: continuously emitting an electromagnetic field in a surgical volume incorporating at least one electromagnetic sensor on a bone and/or tool; continuously receiving a signal indicative of a position and/or orientation of the electromagnetic sensor relative to the emitting of electromagnetic field; processing the signal to determine the position and/or orientation of the at least one electromagnetic sensor; obtaining geometrical data relating the at least one electromagnetic sensor to the bone and/or tool; and continuously tracking and outputting a first position and/or orientation of the bone and/or tool using the geometrical data and the position and/or orientation of the at least one electromagnetic sensor.

A magnetic sensor-based tracking system, a method, and computer readable media for tracking an apparatus having a magnetic field generating device through an environment having a consistent magnetic field are provided. The magnetic sensor-based tracking system includes the apparatus having the magnetic field generating device, one or more magnetic field sensing devices, and a controller. Each of the one or more magnetic field sensing devices is configured in operation to be located within a sensible range of an expected path of the magnetic field generating device as it passes through the environment, the expected path including a plurality of regions. The controller is coupled to the one or more magnetic field sensing devices and configured in operation to utilize magnetic field sensing of the one or more magnetic field sensing devices to track the apparatus within the environment by obtaining at least one magnetic field reading from at least one of the one or more magnetic sensing devices and computing a position and an orientation of the apparatus within the environment based on at least one solution set obtained from a pre-obtained magnetic field model.