An electrosurgical device is disclosed. The electrosurgical device includes a handle, a shaft extending distally from the handle, and an end effector coupled to a distal end of the shaft. The end effector comprises a first electrode and a second electrode. The second electrode includes a first position and a second position. The second electrode is configured to move from the first position to the second position when a force is applied to the end effector by a tissue section. The first electrode and the second electrode define a treatment area when the second electrode is in the second position.

A medical treatment device includes a pair of holding members configured to grasp a target part to be connected and dissected in a body tissue. At least one holding member of the pair of holding members includes an energy application portion having a treatment surface configured to contact the target part when the target part is grasped by the pair of holding members to apply energy to the target part. The treatment surface includes a high-output area configured to apply energy to the target part at a first output value for dissecting at least the target part, and a low-output area configured to apply energy to the target part at a second output value smaller than the first output value. The high-output area and the low-output area are provided continuously to each other.

An electrosurgical probe can be detachably secured to a handpiece having a motor drive unit and an RF current contact. The electrosurgical probe includes an elongate shaft having a longitudinal axis, a distal dielectric tip, and a proximal hub which is detachably securable to the handpiece. A hook electrode is reciprocatably mounted in the distal dielectric tip, and an RF connector on the hub is couplable to the RF current contact in the handpiece when the hub is secured to the handpiece. A drive mechanism in the hub mechanically couples to the hook electrode, and drive mechanism engages a rotational component in the motor drive unit when the hub is secured to the handpiece. The drive mechanism converts rotational motion from the rotational component into axial reciprocation and transmits the axial reciprocation to the hook electrode to axially displace the hook electrode between a non-extended position and an extended position relative to the dielectric tip.

An electrosurgical system includes an RF electrosurgical generator, an electrosurgical instrument, and a pump. The radio frequency (RF) electrosurgical generator includes: an output socket for providing a RF output signal to an electrosurgical instrument according to an operating mode of the generator; and an output port arranged to output and return a loop signal for controlling a pump, wherein the generator is configured to generate the loop signal based at least in part on the operating mode of the generator. A method of controlling a pump in an electrosurgical system includes generating a loop signal at an electrosurgical generator based at least in part on an operating mode of the generator; outputting the loop signal to a loop cable; sensing, using a sensing device, the loop signal from the loop cable; and controlling the pump based on an output of the sensing device.

An electrosurgical generator includes: a power supply configured to output a DC waveform; a current or voltage source coupled to the power supply and configured to output current; and a power converter coupled to the current source. The power converter includes at least one power switching element operated at a switching waveform and configured to generate a radio frequency waveform based on the energy from the current or voltage source. The radio frequency waveform includes at least one pulse having an overshoot peak. The electrosurgical generator further includes a clipper circuit coupled to the current source and the power converter, the clipper circuit configured to generate a clipping voltage to clip the overshoot peak; and a controller coupled to the power converter and configured to modulate the switching waveform to generate the radio frequency waveform.

A housing, a UVC emitting light source combined to the housing for emitting UVC light outside the housing onto the area of interest, and a controller combined to the UVC light source for controlling the intensity of the UVC light emitted onto the area of interest.

In an example, an electrosurgical generator includes a power converter configured to convert a supply power received from a power source to an output power. The output power is suitable for delivering electrosurgical energy. The electrosurgical generator also includes a current sensor configured to sense a current of the output power and generate a logarithmic and analog representation of the current, and a voltage sensor configured to sense a voltage of the output power and generate a logarithmic and analog representation of the voltage. The electrosurgical generator further includes a controller configured to: (i) receive the logarithmic and analog representation of the current sensed by the current sensor, (ii) receive the logarithmic and analog representation of the voltage sensed by the voltage sensor, and (iii) adjust, based on the logarithmic and analog representation of the current and the voltage, a voltage

Disclosed herein is a system for treating skin and/or nails with cold plasma. The system includes a discharge device, which includes a handle and an applicator mounted thereon, and control infrastructure, which includes a waveform generator. The applicator includes an elongated tube housing therein a cathode. The handle includes a flyback amplifier. The waveform generator is configured to induce the flyback amplifier to establish a voltage at the cathode. The voltage produced by the flyback amplifier is configured to allow generating a self-sustaining Townsend avalanche when a distal end of the tube is positioned sufficiently near a target site on a skin surface or a nail of a subject, such as to produce a cold plasma discharge directed at the target site and having an average power between about 0.1 μW and about 10 μW, so that the target site is not heated.

A system for monitoring tissue lesion development during a medical ablation process applied to a patient, the system comprising a catheter ablation device having at least one catheter electrode, the device connectable via an electrical feedline to a source of electrical energy and configured to apply ablation energy to ablate tissue in a target region, a plurality of external electrodes for application to the body of the patient, measurement circuitry for determining an electrical characteristic of a current path between the at least one catheter electrode and the external electrodes in the absence of said application of ablation energy, and an electrical controller. The system can be used for monitoring the size of a lesion during a catheter ablation process applied to the tissue of a subject, comprising alternating between an ablation phase involving delivery of ablation energy to a catheter electrode and a measure phase involving measuring an electrical characteristic of a current path passing through a lesion area formed by the ablation, in which the two phases are sequentially repeated until analysis of the measurement results indicate attainment of a desired lesion size.

A surgical instrument comprising a shiftable transmission is disclosed. The transmission comprises a mechanism for assuring that the transmission is in one of a plurality of predefined configurations.