Medical devices and methods for making and using the same are disclosed. An example medical device may include a medical device for renal nerve ablation. The medical device may include an elongate shaft having a distal region. An expandable member may be coupled to the distal region. A plurality of electrodes may be coupled to the expandable member and a single conductive member may be coupled to each electrode. Where one of the plurality of electrodes is active, the remaining electrodes may be inactive and act as ground or return electrodes. The electrode of the plurality of electrodes that is active may change over time.

A medical probe includes a shaft and a basket assembly. The shaft is configured for insertion into a cavity of an organ of a patient. The basket assembly, which is connected at a distal end of the shaft, includes (a) multiple electrically-conductive spines that are electrically-connected to one another so as to form a distributed electrode, and (b) a plurality of spine mounted electrodes, which are disposed along the spines and are configured to (i) sense electrical activity in the cavity, (ii) ablate and (iii) prevent the distributed electrode from indenting tissue in the cavity.

An arthroscopic cutting probe includes an elongated shaft assembly having a distal end, a proximal end, and a longitudinal axis therebetween. A working end at the distal end of the elongated shaft assembly includes a first active electrode and a second active electrode The shaft assembly is rotates the first electrode relative to the second electrode about the longitudinal axis, and a return electrode is carried on the shaft assembly proximal of the working end. The first and second active electrodes are electrically coupled to each other and electrically isolated from the return electrode.

A system for tissue puncture includes a radiofrequency (RF) generator, an RF puncture device, and at least a first intracorporeal grounding (IG) electrode. RF generator includes an RF output port and a ground return port. The RF puncture device includes an elongate member having a shaft and a tip. The tip includes an intracorporeal RF puncture electrode that is positionable adjacent a target site within a patient’s body, and the shaft includes a first electrical conductor that is electrically connected to the intracorporeal RF puncture electrode and is electrically connectable to the RF output port for delivering RF energy from the RF generator to the intracorporeal RF electrode. The IG electrode is positionable within the patient’s body proximate the target site, and is electrically connectable to the ground return port for returning current to the RF generator.

An ultrapolar electrosurgery blade includes top and bottom thin elongated conductive members in vertical alignment and spaced apart from one another along their lengths, a non-conductive coating covering both the top and bottom thin elongated conductive members and the space located between them to create opposing non-conductive sides of the blade with conductive cutting and ends and conductive non-cutting ends exposed, and both return and active contact layers located on each of the opposing non-conductive sides of the blade. An ultrapolar electrosurgery blade assembly having argon beam capability further includes a non-conductive tube member having a slot positioned over the top of the ultrapolar electrosurgery blade and a conductive hollow tubular member contained within at least a portion of the non-conductive tube member.

An electrosurgical wand. At least some of the illustrative embodiments are electrosurgical wands configured as a surgical forceps including opposed legs that defines respective distal end portions, the legs of the forceps operable to be actuated between an open position and a closed position, an active and return electrode disposed on one of the respective distal end portions, a discharge aperture on one of the distal end portions coupled to a first fluid conduit, and an aspiration aperture through the return electrode on the other of the distal end portions fluidly coupled to a second fluid conduit. In embodiments, the position of the forceps' legs, and the electrical energy applied to the electrodes, is adjusted to provide dissection or coagulation to the tissue. A stop or latch on the forceps' legs may maintain the active and return electrode a fixed distance from one another.

An apparatus for treating tissue in a tissue treatment region. The apparatus can comprise an electrode ring having an interior perimeter and an electrode probe having a proximal end and a distal end. The distal end of the electrode probe can be structured to axially translate relative to the interior perimeter of the electrode ring. The electrode ring and the electrode probe can be operably structured to conduct current therebetween when at least one of the electrode ring and the electrode probe is energized by an energy source. Further, the energy source can be a Radio Frequency (RF) energy source, a pulsed energy source, an irreversible electroporation energy source, or a pulsed irreversible electroporation energy source. A current from the energy source can be selected to non-thermally ablate tissue in the tissue treatment region.

In some aspects, a surgical system for taking advantage of capacitive coupling is presented. The surgical system may include: a monopolar energy generator; a surgical instrument configured to transmit electrosurgical energy through the electrode to tissue of a patient at a surgical site; and at least one detection circuit configured to: measure an amount of conductivity in a return path of the electrosurgical energy; determine that the amount conductivity in the return path falls below a predetermined threshold; and transmit a signal to cause the monopolar generator to increase current leakage in the surgical system by increasing alternating current frequency in the electrosurgical energy generation. The monopolar energy generator may further include a sensor configured to determine that a monopolar energy circuit is completed by detecting that the current leakage has reached a ground terminal in the monopolar energy generator.

An electrosurgical instrument is provided for the treatment of tissue, the instrument (3) including a shaft (14) and a tip portion including at least one electrode (16), located at the distal end of the shaft. A fluid impermeable sheath (25) covers at least a proportion of the shaft and extends to the tip portion where it terminates in a distal end portion (26). A metallic shroud (29) is provided, comprising an annular ring portion (30) and a rearwardly extending cylindrical portion (31). The ring portion (30) is connected to the tip portion, and the cylindrical portion (31) overlies the distal end portion (26) of the sheath (25) so as to prevent ingress of fluids at the distal end portion of the sheath.

The present invention relates to a bipolar electrode, and more particularly, to an electrode for high-frequency heat treatment capable of cauterizing and necrotizing lesions by heating the lesions, such as a cancer tissue of a body organ, with a high frequency, in particular, an overlapping bipolar electrode for high-frequency heat treatment capable of cauterizing lesions of tubular organs, such as a blood vessel, with a minimum invasion.