A medical device may include a handle, a sheath fixed relative to the handle, a longitudinal actuator movable relative to the handle, an end effector, a member extending proximally from the end effector through the sheath, with a portion of the member being fixed relative to the longitudinal actuator, and a rotation actuator. Movement of the rotation actuator may cause rotation of the member relative to the sheath, and movement of the longitudinal actuator may cause longitudinal movement of the member relative to the rotation actuator.

An electrode unit which performs treatment on tissue in a subject by using a high frequency current under observation with an endoscope includes: two electrode support members disposed in a separated manner in a direction along a predetermined axis; a base part extending along an axis intersecting with the predetermined axis, and having a distal end coupled with proximal ends of the two electrode support members; and an electrode having both ends supported by the two electrode support members, wherein the electrode includes an exposed portion in a region which overlaps with at least one of the two electrode support members when viewed from a second direction which is opposite to a first direction in which the two electrode support members are pushed against the subject during use of the electrode unit, the exposed portion being exposed only in the second direction.

The disclosure relates to a medical instrument for minimally invasive tissue ablation by means of an HF electrode, with a hollow shaft, wherein the HF electrode is electrically insulated from the hollow shaft, is arranged at a distal end of the latter and, in order to ablate tissue, protrudes axially beyond the hollow shaft at least in part. The angle orientation of the HF electrode relative to the hollow shaft is adjustable in a controlled manner to a working position in which the HF electrode, protrudes radially beyond an outer circumference of the hollow shaft in order to ablate tissue. In the working position, by means of suitable adjustment of the shaft and of the HF electrode, a position can always be found in which the distal end of the HF electrode sufficiently reaches or touches tissue portions that are to be ablated in the region of the bladder neck.

An RF treatment device according to an embodiment of the present invention comprises a body having an RF generator, and a handpiece connected to the body, wherein the handpiece: includes a rolling member having a plurality of needles formed to protrude, and a body part, which rotatably supports the rolling member while at least some of the plurality of needles are exposed, which transmits, to the rolling member, RF energy transmitted from the RF generator, and which is formed so that the RF energy is transmitted to the rolling member even while the rolling member is rotating; and further includes a speed measurement unit for detecting information related to the speed of the rolling member, and an RF control unit for controlling the output of the RF energy on the basis of information detected by the speed measurement unit.

A surgical instrument is configured to reduce conductivity between an RF electrosurgical portion and a cutting portion. This reduces improves the efficiency and consistency of the generated RF field, with higher current densities nearest the target tissue, improving the performance of the RF electrosurgical instrument. The conductivity may be reduced using a layer of insulating material, a projecting insulating portion or a cutting portion constructed from an insulating material. Further, by providing a lubricous insulating layer shedding may be reduced, increasing the usable life of the cutting portion.

An electrosurgical instrument end effector includes an active electrode received by an insulating material, the active electrode including a primary suction aperture which provides access to a primary fluid channel extending from the active electrode, through the insulating material, to a lumen. The lumen is arranged to carry fluid to and from a surgical site when in use. The end effector further includes at least one additional fluid channel providing alternative access to the primary fluid channel from the active electrode, wherein the at least one additional fluid channel bypasses the primary suction aperture.

An electrode unit for a medical resectoscope for the electrosurgical resection of tissue in a fluid-filled cavity in a patient includes an elongated rod-shaped electrode shaft which on its distal end has an electrode support and a cutting electrode that is fastened to the electrode support and may be acted on by alternating current. A spatula element that is designed for supporting tissue and that extends distally beyond the cutting electrode is situated on the electrode support, the spatula element having two support flanks that extend distally on both sides of the cutting electrode to form outer edges of the spatula element, at least one of the support flanks having an inwardly directed indentation to form a constriction in the area of the cutting electrode.

Methods of assembling a medical device including pivotably connecting a coupling link to a first lever. The coupling link including a main body and a tab extending away from the main body. The first lever having a first pivot and a boss. The method further including nesting the first lever and the coupling link with a second lever such that a recess in the second lever is supported by the boss, and such that an inner surface of the second lever is supported by the coupling link to provide a portion of the medical device in a sub-assembled state.

A bipolar resectoscope (1) has a shaft (2, 2′) with an insulating insert (8) at its distal end (7). A working element (3) is mountable in the shaft (2, 2′) and a cutting electrode (4) is longitudinally displaceable in the shaft (2, 2′). The insulating insert (8) has an exposed conductive area of a neutral electrode (5, 5′). The area of the passive neutral electrode (5, 5′) exposed transverse to the longitudinal axis (34) forms an electrically conductive roof of the insulating insert (8, 8′). An inlet area (26) of the insulating insert (8, 8′) has an inner wall (38, 38′) with two opposing electrically conductive contact surfaces (39, 39′) of the neutral electrode (5, 5′) that are parallel to the longitudinal axis (33) and contact two parallel electrically conductive contact tubes (24) of a fork (26) and opening a cutting loop (25) of the cutting electrode (4).

An ablation device includes a feedline including an inner conductor having a distal end, an outer conductor coaxially disposed around the inner conductor, and a dielectric material disposed therebetween, an elongated electrically-conductive member longitudinally disposed at the distal end of the inner conductor and having a proximal end, a first balun structure disposed over a first portion of the outer conductor and positioned so that a distal end of the first balun structure is located at a first distance from the proximal end of the electrically-conductive member and a second balun structure disposed over a second portion of the outer conductor and positioned so that a distal end of the second balun structure is located at a second distance from the proximal end of the electrically-conductive member.