An electrosurgical system includes a resectoscope and a generator. The resectoscope includes a fixed electrode, a movable electrode movable relative to the fixed electrode, and first and second switches actuated in first and second positions of the movable electrode, respectively. The generator is configured to supply energy to the fixed electrode and/or the movable electrode when the movable electrode is moving from the first position to the second position and to inhibit the supply of energy when the movable electrode is moving from the second position to the first position. The generator is configured to determine a direction of movement of the movable electrode based upon signals received from the first and second switches.

A surgical treatment apparatus includes a treatment portion unit; at least one operation portion provided in the treatment portion unit that is movable in response to an operation of an operator; a detection subject portion provided in the operation portion; a gripping portion that is detachable and attachable relative to the treatment portion unit; a non-contact type detection portion that is provided in the gripping portion separately from the operation portion and is capable of detecting an operation of the detection subject portion in accordance with the operation of the operation portion; an energy supply portion provided within the gripping portion, that supplies energy to the treatment portion; and a driving device connected to the gripping portion, that supplies energy to the energy supply portion in accordance with a detection result of the detection portion.

A deployment mechanism for selectively deploying and retracting an energizable member and/an insulative member relative to an end effector assembly of a surgical instrument includes one or more actuators, a clutch assembly, and a drive assembly. The clutch assembly is configured to couple to the actuator(s) to provide rotational motion in the first direction in response to such rotation of the actuator(s) and to decouple from the actuator(s) in response to rotation thereof in the second direction. The drive assembly is operably coupled to the clutch assembly and is configured to convert the rotational motion provided by the clutch assembly into longitudinal motion to translate the energizable member and/or insulative member from a storage position to a deployed position and to translate the energizable member and/or the insulative member from the deployed position back to the storage position.

An electrosurgical wand is disclosed. The electrosurgical wand includes a handle that defines a proximal end of the electrosurgical wand. The electrosurgical wand includes an elongate shaft coupled to the handle; the elongate shaft defines a suction lumen therein. The electrosurgical wand also includes an electrically insulative spacer (404) coupled to the distal end of the elongate shaft, whereby the spacer defines a suction channel (412) fluidly coupled to the suction lumen. The electrosurgical wand includes a first means for blocking defined by the spacer, an active electrode (402) coupled on the distal end of the spacer and a second means for blocking associated with the active electrode and in operational relationship to the first means for blocking. In the electrosurgical wand, the first means for blocking includes an annular trough (416) that fully encircles the suction channel of the spacer and the second means for blocking includes an annular wall (414).

A tool has a handle and an elongate shaft that extends distally from the handle. A distal portion of the shaft is inserted into a subject during a surgical procedure. An optical fiber delivers laser energy to a tip at the distal portion of the shaft. The tip includes a mechanical cutting mechanism including a moving part that absorbs the laser energy, thermally conducts the absorbed energy to tissue that is disposed between the moving part and another part, and moves with respect to the other part in order to cut tissue that is disposed between the parts using a mechanical force that is lower than a mechanical force that would be required to cut the tissue in the absence of the laser energy. Other embodiments are also described.

A monopolar telescopic electrosurgery pencil with argon beam capabilities which includes telescoping members contained within the pencil and a monopolar electrosurgery blade assembly with a non-conductive tube member for an inert gas.

Tissue ablation systems and methods are provided, wherein a cardiac catheter incorporates a pressure detector for sensing a mechanical force against the distal tip when engaging an ablation site. Responsively to the pressure detector, a controller computes an ablation volume according to relationships between the contact pressure against the site, the power output of an ablator, and the energy application time. A monitor displays a map of the heart which includes a visual indication of the computed ablation volume. The monitor may dynamically display the progress of the ablation by varying the visual indication.

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 arthroscopic tissue resecting probe includes an elongated shaft having outer and inner sleeves which are formed from an electrically conductive material extending about an axis to a working end. Outer and inner resecting windows are formed in the sleeves in the working end. The working end includes a ceramic body having a collar portion extending fully around a region of the outer sleeve proximal to outer resecting window. A radiofrequency (RF) electrode is disposed on an outer surface of the ceramic body and is spaced-apart from the outer resecting window.

A method of creating an AV fistula between adjacent first and second vessels includes inserting a guidewire from the first vessel into the second vessel. Inserting a catheter including a proximal member and a distal member over the guidewire such that a distal tip of the distal member comes into contact with a selected anastomosis site. Moving the distal member and the proximal member together to clamp tissue surrounding the aperture between the distal face of the proximal member and a proximal face on the distal member. Applying energy to an active heating member on the proximal member to cut and form the aperture, and to weld the edges thereof in order to create a desired fistula between the two vessels. Using a passive heating member disposed on the distal member to create a heating gradient across a tissue contacting surface of the distal member.