A method and apparatus for marking a target with a radiopaque marker is disclosed. The method may include providing a radiopaque filament and inserting at least portion of the radiopaque filament into tissue. The filament may extend continuously and at last partially around a perimeter of the target so that the filament is disposed in a plurality of surgical planes to demarcate the target with the radiopaque maker.

An apparatus, system, and method is disclosed for correcting a condition present in a patient. In some implementations, the apparatus may include a proximal end. In addition, the apparatus may include a distal end. The apparatus may include a body having a superior side, an inferior side, a medial side, a lateral side, a proximal side, and a distal side. Moreover, the apparatus may include a marker configured to identify a location for a reference feature that corresponds to a model reference for a bone of the patient's foot. Also, the apparatus may include a bone engagement surface configured to register to an anatomical structure of the bone, the bone engagement surface defined based on medical imaging taken of the bone.

A registration marker comprising a radiotransparent substrate and a pattern formed in at least two dimensions, which is disposed on the substrate and is optically visible. The registration marker also has a multiplicity of radiopaque elements, which are disposed in the substrate and are spatially arranged in at least two dimensions to provide a unique pattern.

A registration marker (40), consisting of a radiotransparent substrate (44) and a pattern (58) formed in at least two dimensions, which is disposed on the substrate and is optically visible. The registration marker also has a multiplicity of radiopaque elements (60), which are disposed in the substrate and are spatially arranged in at least two dimensions to provide a unique pattern.

Systems, methods and a sensor alignment mechanism are disclosed for medical navigational guidance systems. In one example, a system to make sterile a non-sterile optical sensor for use in navigational guidance during surgery includes a sterile drape having an optically transparent window to drape the optical sensor in a sterile barrier and a sensor alignment mechanism. The alignment mechanism secures the sensor through the drape in alignment with the window without breaching the sterile barrier and facilitates adjustment of the orientation of the optical sensor. The optical sensor may be aligned to view a surgical site when the alignment mechanism, assembled with the sterile drape and optical sensor, is attached to a bone. The alignment mechanism may be a lockable ball joint and facilitate orientation of the sensor in at least two degrees of freedom. A quick connect mechanism may couple the alignment mechanism to the bone.

Embodiments of the invention provide a system and method for resecting a tissue mass. The system for resecting a tissue mass includes a first sensor for measuring a signal corresponding to the position and orientation of the tissue mass. The first sensor is dimensioned to fit inside of or next to the tissue mass. The system also includes a second sensor attached to a surgical instrument configured to measure the position and orientation of the surgical instrument. A controller is in communication with the first sensor and the second sensor, and the controller executes a stored program to calculate a distance between the first sensor and the second sensor. Accordingly, visual, auditory, haptic or other feedback is provided to the clinician to guide the surgical instrument to the surgical margin.

A biopsy site marker includes a marker element. The marker element includes a first portion and a second portion. The first portion and the second portion each being configured to be displaced outwardly when deployed to a biopsy site. The marker element further including one or more anchors being configured to engage tissue of the biopsy site when the first portion and the second portion are displaced outwardly.

Systems and methods for medical object tracking are provided. The system may include a plurality of radio frequency transceivers that each emit a radio frequency signal at a first respective frequency. The system may further include a radio frequency beacon that is attachable to the medical object and that emits a second radio frequency signal at a second respective frequency different than the first respective frequency in response to receiving the radio frequency signal. The system may also include a control device in communication with the plurality of radio frequency transceivers, the control device including processing circuitry that determines a location of the medical object in three-dimensional space based at least in part on the second radio frequency signal. The beacon may include a platform, a first fixation element that extends from the platform; and a second fixation element that is tilted relative to the first fixation element.

Aspects of the present disclosure relate to systems, devices and methods for performing a surgical step or surgical procedure with visual guidance using an optical head mounted display. Aspects of the present disclosure relate to systems, devices and methods for displaying, placing, fitting, sizing, selecting, aligning, moving a virtual implant on a physical anatomic structure of a patient and, optionally, modifying or changing the displaying, placing, fitting, sizing, selecting, aligning, moving, for example based on kinematic information.

Systems and methods for treating a lung of a patient. One embodiment of a method comprises positioning a leadless marker in the lung of the patient relative to the target, and collecting position data of the marker. This method further comprises determining the location of the marker in an external reference frame outside of the patient based on the collected position data, and providing an objective output in the external reference frame that is responsive to movement of the marker. The objective output is provided at a frequency (i.e., periodicity) that results in a clinically acceptable tracking error. In addition, the objective output can also be provided at least substantially contemporaneously with collecting the position data used to determine the location of the marker.