An ablation system and a nerve detection device thereof are provided. The nerve detection device includes a power supply module, a computation and control module, an energy generation module and a blood pressure monitoring module. The energy generation module connects to a detecting catheter and to detect a given site in an artery by outputting first energy to the detecting catheter. The blood pressure monitoring module connects to a blood pressure sensor monitoring a patients blood pressure prior to and during the detecting of the given site by the energy generation module with the first energy and to output the blood pressure monitoring result, and further transmitting the blood pressure monitoring result to the computation and control module. The computation and control module determines, based on the blood pressure monitoring result, whether there is an ablation target at the given site.

A surgical instrument including a housing, a shaft, and end effector, and a sensor. The shaft extends distally from the housing. The end effector is disposed at a distal end of the shaft and includes first and second jaw members that are moveable relative between first and second configurations. The first and second jaw members are spaced relative to one another in the first configuration and are closer to one another for approximating tissue in the second configuration. A gap distance is defined between the first and second jaw members. The sensor is positioned within the housing and operable to determine the size of the gap distance. The first and second jaw members configured to be electrical activated to treat tissue between the first and second jaw members when the size of the gap distance is within an acceptable range.

Embodiments of a system and method for assessing hip arthroplasty component movement are generally described herein. A method may include receiving data from a sensor embedded in a femoral head component, the femoral head component configured to fit in an acetabular component, determining information about a magnetic field from the data, and outputting an indication of an orientation, coverage, or a force of the femoral head component relative to the acetabular component.

In a method for spatially localizing mass-spectrometry analysis of an analyte derived from an energy event, an electrical device is used to deliver an energy event to a substrate, and the analyte produced is analyzed using mass spectrometry. Electrical signals sent to and received from the electrical device under different modes of operation are sensed and classified according to each different mode of operation. A location of the electrical device is tracked in three dimensions during the energy event, and a processor is used to perform spatial-temporal alignment of the mass-spectrometry, the determined modes of operation of the electrical device, and the tracked location of the electrical device, wherein mass spectrometry data corresponding to the determined modes of the electrical device are identified and localized within the site of the energy event. The substrate may be tissue in a surgical site, and the electrical device may be an electrocautery device.

A medical device including an evaluation unit and an electrode line. The electrode line includes at least one temperature sensor. The temperature sensor delivers a temperature signal to the evaluation unit. The evaluation unit evaluates periodic fluctuations of a signal level of the temperature signal and generates an evaluation output signal qualifying constant wall touching of the electrode line according to whether periodic fluctuations of a signal level of the temperature signal lie below or above a predetermined limit value.

A surgical system includes an end effector assembly having first and second jaw members, a generator, and one or more machine learning applications. The first and/or second jaw member is movable relative to the other from a spaced-apart position to an approximated position for grasping tissue therebetween. The jaw members are configured to conduct energy therebetween and through tissue grasped therebetween. The generator includes an energy output configured to supply energy to the jaw members, a main controller configured to control the energy output, and sensor circuity configured to sense impedance and/or power. The machine learning application(s) is configured to determine a type of tissue grasped between the first and second jaw members based upon the impedance and/or power sensed by the sensor circuitry.

An electrosurgical device (10) is provided that is operable to deliver microwave energy within a controlled angular expanse to cause targeted tissue ablation. The device (10) comprises a blocking or reflecting material such as cylindrical members (34) that are laterally spaced from the antenna (20) that is operable to emit the microwave energy. The reflecting material creates regions in and/or surrounding the device into which sensors (51), such as thermocouple wires, may be placed to monitor a condition associated with the device or the patient's body.

The present disclosure relates to a thermal ablation probe device that integrates deployable sensors with a freezing probe or heating probe for use in ablating tissues. The ablation probe includes a longitudinal body including a thermal ablation energy source which may be, e.g., a cryosource or a heat source. The longitudinal body has a proximal end and a distal end terminating at a probe tip; and at least one deployable assembly disposed within the longitudinal body. The deployable assembly includes a flexible and substantially rigid deployment member, and at least one sensor affixed to a distal end of the deployment member. The ablation probe further includes a control mechanism for controlling deployment and retraction of the deployable assembly.

An arthritis treatment system includes a cooling treatment mechanism for administering a cooling treatment protocol to a patient. The system also includes a heating treatment mechanism for administering a heating treatment protocol to the patient, distinctly and simultaneously with the cooling treatment protocol. The system further includes a controller for controlling both the cooling and heating treatment mechanisms. The arthritis treatment system simultaneously provides the cooling and heating treatment protocols to the patient, and the controller algorithmically adjusts the cooling and heating treatment protocols.

A surgical instrument includes a housing, a shaft extending distally from the housing, an end effector disposed at a distal end of the shaft, an actuator operably coupled to the housing, an actuation assembly, and a sensor module. The actuation assembly extends through the housing and the shaft and includes a distal end operably coupled to the end effector or a component associated therewith, a proximal end operably coupled to the actuator, and a spring. Actuation of the actuator manipulates the end effector or deploys the component relative thereto. The sensor module is disposed within the housing and configured to sense a property of the spring indicative of an amount the spring has been compressed. The sensor module is further configured, based upon the sensed property, to determine a condition of the end effector or the relative position of the component.