The disclosure provides various embodiments of catheters having articulable ends that can be used for various procedures. Embodiments of methods are also provided that can be performed with catheters in accordance with the present disclosure.

A surgical fluid management system delivers fluid for distending a uterine cavity to allow cutting and extraction of uterine fibroid tissue, polyps and other abnormal uterine tissue. The system comprises a fluid source, fluid deliver lines, one or more pumps, and a filter for re-circulating the distension fluid between the source and the uterine cavity. A controller can monitor fluid retention by the patient.

Disclosed herein are embodiments of an electrosurgical device that include one or more floating electrodes and are specifically adapted to remove, resect, ablate, vaporize, denaturize, coagulate and form lesions in soft tissues, preferably in combination with a resectoscope, particularly in the context of urological, gynecological, laparoscopic, arthroscopic, and ENT procedures. Specific adaptations for urological and gynecological applications, for example BPH treatment, are also described.

Disclosed is a multifunctional medical device, apparatus or system that is capable of performing a surgical procedure or operation and also capable of removing or reducing smoke particles generated by the surgical procedure or operation on a subject, the apparatus comprising a plurality of electrodes, two of which are configured to be in electrical communication with or being electrically connectable to opposite poles of a source of high voltage dc electricity to ionize, and remove or reduce smoke particles, and at least one of which is also configured to be part of a RF circuit to perform a surgical procedure or operation such as tissue cutting, cauterization, tissue sealing or coagulating at a surgical site on the subject. Also disclosed is a method of employing the above disclosed device, apparatus or system or variations thereof to perform a surgical procedure or operation at a surgical site and to remove or reduce smoke particles generated during the surgical procedure or operation.

An energy-delivering assembly probes formed from an elongated energy-delivering member have one or more electrodes defined along an energy-delivering region of the energy-delivering member. An electrode-defining insulation member is provided over the energy-delivering member to define and space apart at least a first electrode from a second electrode. One or more of the electrodes and/or insulation members are configured and/or have characteristics or properties which reduce/minimize/eliminate arcing between/across electrodes of the energy-delivering assembly.

A method for controlling an electrosurgical instrument capable of producing a cutting plasma for cutting or vaporizing tissue when in operation at such tissue, wherein an electrosurgical generator generates a voltage signal being basically sinusoidal and the voltage signal is applied to the electrosurgical instrument, applying the voltage signal to the electrosurgical instrument results in an operating current signal capable of providing the cutting plasma, and the operating current signal including a linear current component being sinusoidal having a fundamental frequency and a nonlinear current component not having the fundamental frequency, wherein the operating current signal is controlled depending on the nonlinear current component in order to control the cutting plasma.

A control system includes an electric pulse host including control and feedback circuits, and an electrode group. The control circuit includes a main control module (MCM) connected with a pulse transmission module, a first electrode control unit and the electrode group. The MCM controls the pulse transmission module to output a pulse signal and selects a specific electrode through the first electrode control unit to release the pulse signal to act on an ablation site. The feedback circuit includes the MCM connected with an electrophysiological signal sampling module, a second electrode control unit and the electrode group. The MCM selects an electrode through the second electrode control unit, samples an electrocardiogram signal through the electrophysiological signal sampling module, determines a treatment progress according to the sampled electrocardiogram signal, and adjusts the pulse signal output by the pulse transmission module in real time according to the treatment progress.

An apparatus and a method for producing a virtual electrode within or upon a tissue to be treated with radio frequency alternating electric current. An apparatus in accord with the present disclosure includes a supply of a conductive or electrolytic fluid to be provided to the patient, an alternating current generator, and a processor for creating, maintaining, and controlling the ablation process by the interstitial or surficial delivery of the fluid to a tissue and the delivery of electric power to the tissue via the virtual electrode. A method in accord with the present disclosure includes delivering a conductive fluid to a predetermined tissue ablation site for a predetermined time period, applying a predetermined power level of radio frequency current to the tissue, monitoring at least one of several parameters, and adjusting either the applied power and/or the fluid flow in response to the measured parameters.

A high frequency electrosurgical power generator configured to produce electrical power at a frequency of about 1 to about 14 MHz and preferably having an essentially sinusoidal waveform with a voltage level up to 1,000 Vrms, and a current level up to 5 Amps. The output of the high frequency electrosurgical power generator is connected to an electrosurgical tool configured to receive the voltage and current produced by the electrosurgical power generator and deliver the voltage and current to an electrosurgical site. The output of the electrosurgical generator preferably is an essentially sinusoid waveform with a frequency between about 3 MHz and about 8 MHz, up to about 700 volts rms, up to about 2 amps, with a total power of up to 1,000 watts.

The disclosed technology is directed to a RF power generator and feedback control system used to regulate the electrical power delivered to a cutting filament (i.e., a cutting electrode) of an electrosurgical instrument. The electrosurgical instrument uses the delivered energy to form a cutting arc for ablating a tissue mass to access a target tissue therein. The instrument forms a basket-like receptacle around the target tissue to excise the target tissue from the ablated tissue mass. As the instrument forms the receptacle, the length of exposed filament ablating the tissue changes. To this end, the RF power generator described herein is configured to vary the total power delivered during the deployment of the instrument based on a measurement of output power derived from a differential phase angle between a current sense output and a voltage sense output, in some embodiments, to maintain a uniform power density along the length of exposed filament.