An electrically conductive irrigation fluid for use in bipolar resectoscopic surgery, wherein the irrigation fluid being brought into contact with the electrode of a resectoscope and tissue being coagulated and/or resected by means of the electrode surrounded by the irrigation fluid, wherein the irrigation fluid includes metal ions. Moreover, the method relates to a resectoscopy system including a resectoscope and an irrigation system that is connected to the resectoscope, the resectoscope having a handle and a tubular shaft, and the shaft including an electrode instrument that is arranged so as to be longitudinally displaceable and has in its distal end region an electrode to which high-frequency current can be applied, wherein the irrigation system includes an irrigation fluid, which can be conducted through the shaft of the resectoscope to the electrode.

A catheter includes an elongate shaft, an electrode assembly, a connective stem, a coupler, a first magnetic position sensor, and a second magnetic position sensor. The electrode assembly includes microelectrodes. The connective stem includes a first connective stem member and a second connective stem member. The connective stem defines a first sensor receptacle and a second sensor receptacle in an exterior surface of the connective stem. The coupler is configured for coupling with the connective stem. The first magnetic position sensor is disposed in the first sensor receptacle and elongated along a first sensor longitudinal axis. The second magnetic position sensor disposed in the second sensor receptacle and elongated along a second sensor longitudinal axis that is not parallel to the first sensor longitudinal axis.

An excision apparatus for removing cellular tissue includes a housing provided with a fixation portion. The fixation portion is configured to be arranged on cellular tissue such that a closed space is formed by the cellular tissue and an inner surface of the fixation portion. The fixation portion is configured to fixedly retain the cellular tissue near the inner surface by removal of air from the closed space via an air evacuating means. The apparatus further includes a cutting element moveably arranged in the housing such that the cutting element is movable between a retracted position and an extended position with respect to the fixation portion. The cutting element includes an electrode arranged at a distal end of the cutting element and is configured for cutting a section of cellular tissue retained by the fixation portion when the cutting element is in the extended position.

Methods and apparatuses are disclosed for providing pulsed electrical treatment (including high voltage, sub-microsecond pulsed electric energy) to body vessels. The apparatus may include deployable electrodes that conform to transitional surfaces. These apparatuses may include multiple wire loops forming petal-like electrodes configured to expand with an expandable member, such as a balloon.

A tool assembly for use with an electrosurgical device for cutting tissue includes a base portion, a return lead, an electrical insulator, a center pin, and an active lead. The center pin extends from the base portion and through a lumen of the electrical insulator. The active lead is securely fixed to the base portion and extends between the base portion and a distal portion of the center pin such that a portion of the active lead extends around the distal portion of the center pin and first and second segments of the active lead are spaced apart from the return lead. Upon activation, electrosurgical energy is transmitted from the active lead through tissue to the return lead to cut tissue in contact with the active lead.

An endoscopic forceps includes an elongate shaft defining an instrument axis. An end effector includes first and second jaw members each supporting an opposed sealing surface for clamping tissue. At least one of the jaw members is movable relative to the instrument axis such that the jaw members are movable between a first spaced-apart configuration and a second closed configuration for grasping tissue. A cutting instrument includes a reciprocating blade translatable relative to the sealing surfaces to sever tissue clamped between the jaw members. The reciprocating blade contacts an undersurface of at least one of the jaw members when the jaw members are in the second configuration to define a gap distance between the sealing surfaces. A handle adjacent the proximal end of the elongate shaft is operable to induce motion in the jaw members, and an actuator is operable to selectively translate the reciprocating blade.

A control handle for a steerable catheter body for navigation of the catheter body through a biological lumen and manipulation at a treatment site. The control handle includes a housing assembly that houses a piston assembly and a resistance adjusting assembly. The resistance adjusting assembly can be adjusted to provide the desired frictional characteristics of the user for control of the resistance between the piston assembly and the housing assembly. In one embodiment, the piston assembly is configured to provide a frictional resistance that varies dynamically to substantially match the restorative force across the range of catheter tip deflection. Other embodiments include a vibrating member that provides tactile feedback to the operator to indicate conditions at the distal end of the catheter, such as contact force.

Various embodiments disclosed relate to a non-stick layer for cutting elements on electrosurgical cutting tools. The present disclosure includes systems, devices, and methods of making and using a non-stick layer on cutting elements. The non-stick layer can include coatings, surface structures, or combinations thereof. In one example, the medical device includes a hydrophobic coating with a hydrophobic nanoscale physical structure. In one example, the medical device includes a heated cutting assembly, such as a resistive heated cutting assembly.

Systems and methods for cutting tissue using a transcatheter approach are disclosed. In some examples, the systems and methods are implemented as part of a delivery system that includes an implant with a support structure and a cutting element coupled to the support structure, such that the cutting element configured to cut tissue.

A tissue specimen removal device comprises a specimen bag; a flexible ring, the flexible ring configured to form a top opening of the specimen bag; a cannula assembly comprising: an inner tube portion and an outer tube portion. The device may further comprise a connector carrier, the connector carrier configured to retain at least one connector housing, the at least one connector housing comprising one or more connector portions and reside within an interior of the connector carrier, and wherein the connector carrier can be moved from a position within the cannula assembly to outside the cannula assembly.