Surgical devices, systems, and methods are provided for applying monopolar energy and bipolar energy to tissue. In one embodiment, a surgical device is provided with an end effector that has first and second jaws movable between an open position and a closed position, and a conductive member that extends through the end effector. The conductive member has a retracted position in which the conductive member is substantially disposed within the end effector and an extended position in which the conductive member extends at least partially distally beyond the end effector. The conductive member is configured to conduct energy through tissue adjacent thereto when the conductive member is in the extended position. A trigger coupled to the handle is pivotally movable to move the conductive member between the retracted and extended positions.

The present invention provides a detection mechanism, a radio-frequency ablation catheter, and a radio-frequency ablation system. The radio-frequency ablation catheter comprises a handle portion (2), a needle tube portion (1), a central electrode (3), and a detection mechanism. The needle tube portion (1) comprises a first tube sleeve (11) and a second tube sleeve (12), the handle portion (2) comprises a cylinder sleeve (21) and a sliding button (22), the central electrode (3) comprises an electrode body (31), an electrode wire (26), and an electrode connector (23), and the detection mechanism comprises a fixing base (5), a traction wire, a connecting base (6), and multiple claw-shaped electrodes (7). A distal end of the traction wire is fixed on the fixing base (5), and a proximal end of the traction wire is fixed on the sliding button (22); and the claw-shaped electrodes (7) are fixed on the fixing base (5), and slidably provided in the connecting base (6). The traction wire is pulled by the sliding button (22) to drive the fixing base (5) to push the claw-shaped electrodes (7) in or out of the connecting base (6). This facilitates the control of the claw-shaped electrodes (7) by a user during surgery, the determination of the temperature or impedance of the claw-shaped electrodes (7), and thus the determination of the progress of ablation.

Described herein are methods and systems for using the treatment tip apparatuses and high-voltage connectors with robotic surgical systems. For example, retractable treatment tip apparatuses (e.g., devices, systems, etc.) including one, or more preferably a plurality, of electrodes that are protected by a housing (which may be retractable) until pressed against the tissue for deployment of the electrodes and delivery of a therapeutic treatment, are disclosed. In particular, these apparatuses may include a plurality of treatment needle electrodes and may be configured for the delivery of nanosecond pulsed electric fields. Also described herein are high-voltage connectors configured to provide high-voltage energy, such as nsPEF pulses, from a generator to the retractable treatment tip apparatuses.

An apparatus for harvesting a vessel from a body, includes: a cannula having a dissector for advancing along the vessel to create a tunnel, the dissector having a transparent portion; and an energy tool moveably coupled to the cannula, wherein the energy tool is configured to separate a pediculated vessel having at least a segment of the vessel and a pedicle around the segment of the vessel from surrounding tissue, and wherein at least a part of the energy tool is visible through the transparent portion of the dissector during use of the energy tool.

A colpotomy device includes a shaft assembly having a hollow outer shaft and an inner shaft disposed within, and rotatable and translatable relative to, the outer shaft, a handle assembly operably coupled to a proximal end of the shaft assembly, and configured to selectively rotate the inner shaft relative to the outer shaft, a colpotomy cup assembly including an outer cup and an inner cup disposed within the outer cup, wherein the inner cup is fixedly coupled to a distal end of the inner shaft, and the outer cup is fixedly coupled to a distal end of the outer shaft, and a cutting element coupled to the inner cup, such that the inner shaft the shaft assembly, inner cup, and cutting element rotate together relative to the outer shaft.

An esophageal ablation system including a positioner, an elongated, flexible shaft extending from the positioner, and a microwave emitter assembly disposed near the distal end of the shaft. The emitter assembly includes one or more microwave antennae and a balloon tor spacing the antennae relative to target tissue. The device may have an inner balloon for deploying the antenna. The systems, devices and methods disclosed are useful for treating Barrett's Esophagus, Esophageal Adenocarcinoma, and Squamous Cell Carcinoma.

The present disclosure relates to electrosurgical instruments for use in sealing various tissues. The instrument includes a housing having a shaft attached thereto and an end effector assembly attached to a distal end of the shaft, wherein the end effector assembly includes first and second jaw members attached thereto. The jaw members are movable relative to one another from a first position for approximating tissue to at least one additional position for grasping tissue therebetween. The jaw members have an elastomeric material disposed on an inner facing tissue contacting surface thereof with the elastomeric materials including an electrode disposed therein. The electrodes are offset a distance X relative to one another such that when the jaw members are closed about the tissue and when the electrodes are activated, electrosurgical energy flows through the tissue in a generally coplanar manner relative to the tissue contacting surfaces.

Devices and methods for treating tissue with microwave energy used in applications such as destroying a soft tissue by microwave ablation and/or creating point, line, area or volumetric lesions. Various embodiments of flexible, low-profile devices are also disclosed where such device can be inserted non-invasively or minimally invasively near or into the target tissue such as cardiac tissue. The devices disclosed herein comprise antennas wherein the field profile generated by an antenna is tailored and optimized for a particular clinical application. The antennas use unique properties of microwaves such as interaction of a microwave field with one or more conductive or non-conductive shaping elements to shape or redistribute the microwave field.

An implantable electrode catheter device comprising an inner electrode catheter and an outer electrode catheter. The outer electrode catheter including a catheter shaft having at least one electrode at a distal end and a lumen to receive the inner electrode catheter therein. The outer electrode is adjustable or movable relative to the inner electrode catheter in an axial direction. The inner electrode catheter has a fixation element disposed at a distal end. The inner electrode catheter together with the fixation element forms an indifferent electrode whereby radio frequency catheter ablation occurs between the electrode and the indifferent electrode.

A surgical apparatus is disclosed for delivering a therapeutic device to a desired location within the vasculature of a patient, which includes an elongated tubular body defining a longitudinal axis and having opposed proximal and distal end portions, the tubular body including an outer wall surrounding an interior lumen, wherein an elongated target opening is formed through the outer wall of the tubular body within the distal end portion thereof in communication with the interior lumen. At least one distal sensing electrode is provided on the tubular body adjacent a distal side of the target opening, and at least one proximal sensing electrode is provided on the tubular body adjacent a proximal side of the target opening, wherein the sensing electrodes allow placement of the target opening within the vasculature of a patient for the delivery of a therapeutic device to a desired location.