The present disclosure relates to medical devices including occlusion devices, clot retrieval systems, and stents. More particularly, the medical devices described herein measure characteristics for intravascular treatment sites. The medical devices may include pressure sensors and/or length sensors that may be used to determine the effectiveness of the medical devices during or after treatment. These sensors may be particularly helpful when used on an occlusion device or a clot removal device.

Certain aspects relate to systems with robotically controllable field generators and applications thereof. For example, a robotic medical system may include a first robotic arm that is configured to couple to an electromagnetic (EM) field generator. The first robotic arm be capable of moving the EM field generator. The robotic medical system may also include one or more processors. The processors may determine an EM position of an EM sensor within the EM field in an EM coordinate frame associated with the EM field generator. The processors also determine a position of the EM field generator in a robotic coordinate frame associated with the first robotic arm. The processors determine a registration between the EM coordinate frame and the robotic coordinate frame based on the position of the EM field generator. Based on the registration, the processors may determine a position of the EM sensor in the robotic coordinate frame.

Certain aspects relate to systems with robotically controllable field generators and applications thereof. A robotic medical system may include a robotic arm coupled to an electromagnetic (EM) field generator configured to generate an EM field, and the first robotic arm may be configured to move the EM field generator. The medical system may also include a medical instrument configured for insertion into a patient. The medical instrument may comprise an EM sensor and one or more processors. The processors may: determine a position of the EM sensor within the EM field; and adjust a position of the EM field generator by commanding movement of the first robotic arm based on the determined position of the EM sensor.

Certain aspects relate to a medical system that includes a robotically controllable field generator and an instrument guide. The instrument guide may guide a percutaneously insertable instrument along an insertion axis. The instrument guide may also be positioned on an electromagnetic (EM) field generator, where the EM field generator can generate an EM field. A first robotic arm may be coupled to the EM field generator and it may move the EM field generator and the instrument guide. The system then determines: an EM target positioned within a patient, and a registration that maps positions within an EM coordinate frame associated with the EM field to positions within a robotic coordinate frame. The system may also determine, based on the registration, a position of the EM target within the robotic coordinate frame. Based on the position of the EM target within the robotic coordinate frame, move the first robotic arm may move to align the insertion axis of the instrument guide with the EM target.

Certain aspects relate to systems with robotically controllable field generators and applications thereof. In one application, a robotic medical system, comprising a first robotic arm coupled to an electromagnetic (EM) field generator configured to generate an EM field, an EM sensor, and a processor. The processor may be configured to transmit a command to the first robotic arm to cause movement of the EM field generator along a robotic trajectory while the EM sensor remains at a location. An EM sensor trajectory of the EM sensor within the EM field corresponding to a period of time in which the EM field generator moved along the robotic trajectory may be detected. The robotic trajectory and the EM sensor trajectory may be analyzed to determine a difference between the robotic trajectory and the EM sensor trajectory; and EM distortion at the location may be detected comparing the difference and a threshold.

A stapling end effector includes an anvil assembly having a distal end and defining a plurality of staple forming pockets, and a cartridge assembly pivotal relative to the anvil assembly such that the end effector is movable between open and clamped positions. The anvil assembly supports a plurality of staples corresponding to the plurality of staple forming pockets. The surgical stapling instrument further includes a sensing tip disposed on a distal end of the end effector. The sensing tip is formed of a flexible material and includes at least one sensor for measuring at least one mechanical property. The mechanical property may include force, pressure or torque.

A method for recording a mandibular kinematics of an individual comprises: attaching a first marker comprising a plurality of reflective patches or beads to an attachment device fixed to a mandibular arch of the individual, wherein the first marker comprises an inner face provided with two attachment lugs and the attachment device comprises: an intra-oral portion having a general U shape coming into contact with an outer face of teeth of the mandibular arch, an extra-oral portion comprising two recesses each adapted for receiving a respective lug of the first marker, said recesses being separated by a tab adapted for being elastically deformed when one of the lugs is engaged in a respective recess so as to exert a pressure force on said lug, and a connecting portion connecting the intra-oral portion and the extra-oral portion, attaching a second marker provided with a plurality of reflective patches or beads to a forehead of the individual, and recording relative displacements of said first and second markers during mandibular movements made by the individual with the infrared camera.

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 method for performing a surgical procedure includes planning a resection of a bone of a patient. A volume of the bone is removed according to the planned resection using a surgical tool. As the bone is removed, data corresponding to a shape and volume of the removed bone is tracked with a computer system operatively coupled to the surgical tool. A prosthesis is implanted onto the bone of the patient based on the tracked data corresponding to the shape of the removed bone.

An apparatus and method for diagnosis or treatment of a vessel or organ. The apparatus includes a deformable body such as a catheter having a tissue ablation end effector and an irrigation channel in fluid communication therewith. At least two sensors are disposed within a distal extremity of the deformable body, the sensors being responsive to a wave in a specified range of frequency to detect deformations resulting from a contact force applied to the distal extremity. A microprocessor can be operatively coupled with the sensors to receive outputs therefrom, the microprocessor being configured to resolve a multi-dimensional force vector corresponding to the contact force. In one embodiment, the sensors are fiber Bragg grating sensors, and the wave is injected into the fiber Bragg grating strain sensors from a laser diode.