Disclosed herein is an epidural catheter with an RF generation function. More specifically, the epidural catheter with an RF generation function may include a main body, an inserting part being connected to the main body and being inserted inside a physical body, and a manipulating part being provided in the main body and being connected to the inserting part or an internal assembly part of the inserting part, so as to manipulate the inserting part or to perform a function of the inserting part, wherein two steering wires may be interpolated in the inserting part, the two steering wires being manipulated by the manipulating part so as to allow flexion of the inserting part to be controlled, and wherein, by allowing power status to be turned on/off using the main body as medium, the steering wires may act as electrodes.

Provided is a bipolar electrode probe, which includes a conductive needle, an insulation layer, a conductive sleeve, and an insulation sleeve. The conductive needle has a longitudinal direction and a transverse direction perpendicular to the longitudinal direction. The insulation layer covers the conductive needle and has a first opening. The conductive sleeve covers the insulation layer and has a second opening. The insulation sleeve covers the conductive sleeve. When the bipolar electrode probe is turned on, a longitudinal electric field is formed from a front end of the conductive needle to the conductive sleeve along the longitudinal direction. A transverse electric field is formed from the conductive needle to the conductive sleeve via the first opening and the second opening along the transverse direction.

A dual blade device and method useable for performing an ab interno procedure within a human eye to remove a strip of trabecular meshwork tissue.

An electrosurgical dissection apparatus is disclosed, and includes a thermally insulating body, a thermally conductive insert, at least one active electrode, and at least one return electrode. The at least one active electrode is disposed on the thermally conductive insert, and the at least one return electrode is spaced from the at least one active electrode by a portion of the thermally insulating body. The thermally conductive insert is configured to cauterize tissue dissected by radiofrequency energy passing from the at least one active electrode to the at least one return electrode.

A medical device that has high pushing performance is capable of forming a hole in a biological tissue in a living body, is capable of being arbitrarily shaped, and is capable of suppressing a kink. The medical device may be used to form a hole in an oval fossa in a living body. The medical device includes: a hollow dilator made of resin; a core made of metal that is disposed in a part in a circumferential direction of the dilator and extends in a long axis direction of the dilator; and an output unit that is disposed in a distal portion of the dilator and outputs energy to form the hole in the oval fossa, in which the core is embedded in between an inner peripheral surface and an outer peripheral surface of the dilator, and the core has conductivity and is electrically connected to the output unit.

An end effector assembly includes a base portion including a pivot assembly. A first portion of the pivot assembly is pivotally coupled to the distal end portion of the elongated shaft. A second portion of the pivot assembly is pivotally coupled to a distal portion of the push rod. The push rod moves the second portion of the pivot assembly between a proximal position and a distal position. An electrode substantially covers a distal surface of the base portion. The electrode receives electrosurgical energy from the electrosurgical generator and transmits the electrosurgical energy to treat tissue.

An ablation cannula comprising a tubular body, a tip at an end of the tubular body adapted to facilitate the insertion of the cannula into a vein or body cavity, the tip having a distal end, a transducer disposed within the tip, and at least one bore hole in the tip through which a medication or other fluid may be administered, wherein the borehole is separated from the distal end of the tip by a first distance, which may be approximately 2.5 millimeters. The tip may contain at least three boreholes substantially equally spaced around the circumference of the tip. The boreholes may have a diameter of approximately 0.21-0.51 millimeters. Additional configurations are described herein. The transducer is preferably a radio frequency transducer, and an insulative material may be disposed on a selected portion of the tip to attenuate energy emitted from the radio frequency transducer through the insulative material.

An electrosurgical instrument capable of performing both thermal ablation and electroporation in a minimally invasive manner. The instrument is dimensioned to fit within an instrument channel of an endoscope to enable non-percutaneous insertion. The instrument comprises a radiating tip mounted at a distal end of a coaxial transmission line to receive microwave EM energy from the coaxial transmission line and emit it as a field around the radiating tip. The instrument further comprises an auxiliary transmission line arranged to convey electromagnetic energy having an electroporation waveform to a microelectrode array mounted on the radiating tip. The electroporation waveform may be a radiofrequency or low frequency electromagnetic (EM) signal. The microelectrode array may comprise a plurality of nanoscale conductive electrode elements.

One embodiment of the present invention relates to an electrosurgical device for conducting surgery. The device includes a tubular housing and a plurality of electrodes disposed within said tubular housing. The device further includes an actuator connected to the plurality of electrodes to extend and retract at least one of the plurality electrodes to and from the tubular housing.

A method and apparatus are disclosed for providing forward fluid delivery through an energy delivery device that avoids coring when it delivers energy to a tissue. The device has a distal face defining an opening, with the distal face including at least one electrically exposed portion and at least one electrically insulated portion. An embodiment of the energy delivery device includes an elongate member defining a lumen structured to receive a fluid, and a distal face defining an aperture in communication with the lumen. The distal face includes an electrically exposed conductive portion and an electrically insulated portion. The electrically exposed conductive portion is configured such that the energy it delivers while the energy delivery device is advanced into a tissue punctures the tissue without the tissue substantially occluding the lumen and without creating embolic particles.