Various embodiments are directed to electrosurgical systems for providing an electrosurgical signal to a patient. A control circuit may, for a first application period, apply the electrosurgical signal to first and second electrodes according to a first mode. In the first mode, the control circuit may limit the electrosurgical signal to a first maximum power when the impedance between the first and second electrodes exceeds a first mode threshold. The control circuit may also, for a second application period after the first application period, apply the electrosurgical signal according to a second mode. In the second mode, the control circuit may limit the electrosurgical signal to a second mode maximum power when the impedance between the first and second electrodes exceeds a second mode threshold. The second maximum power may be greater than the first maximum power.

Embodiments of present disclosure relates to method and device for controlled emission of radiation. Device comprises probe unit, sensor unit and switch unit. Probe unit is configured to emit radiation on surface of object. Probe unit is supported, via an elastic, to supporting structure of device. Sensor unit is placed at predefined distance from probe unit, along supporting structure, to establish contact with surface. Sensor unit comprises flexible material, mounted to supporting structure, with cavity and first force sensing unit placed in cavity of flexible material. First force sensing unit is configured to detect first force transferred from surface sensor unit. Switch unit is configured to control emission of radiation on surface, based on first force detected by first force sensing unit, upon contact of sensor unit with surface and identification of probe unit to be one of in contact with surface or at minimal distance from surface.

The present invention relates to an RF treatment apparatus controlling the RF energy so that the target tissue is maintained within a range of a treatment temperature if the target tissue is determined to have reached the treatment temperature based on the impedance, a method of controlling the RF treatment apparatus, and a skin treatment method using RF energy. The RF treatment apparatus, the method of controlling the RF treatment apparatus and the skin treatment method using RF energy according to the present invention have an effect in that they can improve the accuracy and efficiency of treatment because whether a target tissue corresponds to a treatment temperature is determined based on impedance of the tissue and the volume of the target tissue corresponding to the treatment temperature can be maximized while maintaining the target tissue to the treatment temperature for a predetermined time.

A medical device includes a handpiece, a lever with a grip surface attached to the handpiece, and a pressure sensor associated with the grip surface. When a user of the medical device applies a grip pressure to the lever, the lever moves to provide an input to a first function of the medical device, and concurrently the pressure sensor produces a pressure signal that is read by a control unit to control a second function

Energy delivery devices and methods that have one or more features to measure or estimate the amount of energy dose delivered to a target material. Methods and systems for calculating an energy dose to be delivered to the target material. The devices and methods deliver an accurate energy dose to the target material. Devices, systems and methods using microwave energy delivery devices can calculate the energy dose from returned power measurements. Systems and methods adjusting one or more energy delivery parameters or one or more system components while delivering an energy dose to achieve a desired thermal effect.

The present disclosure is directed to a method for treating tissue in a passageway within a body. The method may include positioning a medical device adjacent a treatment site in the passageway. The medical device may include an elongate member having a proximal end and a distal end, and an energy emitting portion positioned adjacent the distal end. The method may further include supplying an amount of energy from an energy source to the energy emitting portion. A first portion of the amount of the energy may be transmitted through the energy emitting portion to the tissue and a second portion of the amount of energy may be reflected from the energy emitting portion. The method may further include monitoring a signal corresponding to one of the first portion of the amount of energy and the second portion of the amount of energy.

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 joint surgical system includes, a treatment tool, a high-frequency output section which outputs high-frequency energy to the treatment tool, an ultrasonic output section which outputs ultrasonic energy to the treatment tool, a measurement section which measures a temperature of the liquid, and a control section which controls the high-frequency output section to stop output of the high-frequency energy and controls the ultrasonic output section to continue output of the ultrasonic energy when a measurement temperature measured by the measurement section is equal to or higher than a predetermined temperature.

A system and method for detecting faults within an electrosurgical instrument having a shield and an active electrode uses multiple possible fault conditions. In one embodiment the monitoring system comprises an electrosurgical generator coupled to the electrosurgical instrument and adapted to deliver power to the active electrode of the electrosurgical instrument, monitoring circuitry coupled to the electrosurgical generator and the electrosurgical instrument.

Medical devices and related methods, and, more specifically, cryogenic surgical systems and related methods are disclosed. Some example cryogenic surgical systems may include a cryosurgical control unit configured to cool a cryosurgical probe to a temperature colder than a temperature at which flow of cryogenic fluid to the probe is stopped. Some example tank level indicating systems may utilize the pressure of the fluid in the tank and a temperature of the exterior wall of the tank to indicate liquid level.