A surgical instrument comprises a handle assembly including an actuator mounted for manipulation through an actuation stroke. An elongate shaft extends distally from the handle assembly and defines a longitudinal axis. A reciprocating member extends at least partially through the elongate shaft, and is mounted for longitudinal motion through the elongate shaft in response to manipulation of the actuator through the actuation stroke. A drive mechanism includes a first rotating component coupled to the actuator about a first circumference to induce rotational motion in the first rotating component. A second rotating component is coupled to the first rotating component such that rotational motion in the first rotating component induces rotational motion in the second rotating component. The second rotating component is coupled to the reciprocating member about a second circumference such that rotational motion of the second rotating component induces longitudinal motion in the reciprocating member. The second circumference is greater than the first circumference.

An electrosurgical probe for ablating tissue includes an elongated shaft having an axis and a distal end. An electrically insulating housing at the distal end of the shaft has a window, and an interior channel in the shaft extends through the housing to the window. The window faces laterally relative to the axis, and a moveable member with a blade-like electrode edge is disposed within the window. A motor drives the energized electrode edge axially in the window to ablate tissue.

The various embodiments disclosed herein relate to arms or forearms of medical devices that are configured to couple with quick-release end effectors, quick-release end effectors for use with such medical devices, and arms or forearms coupled to such quick-release end effectors. Certain forearms and end effectors have magnetic couplings, while others have mechanical couplings, and further implementations have both magnetic and mechanical couplings.

Provided is a robotic system that includes a surgical instrument with a wrist including an elongate shaft extending between a proximal end and a distal end, a wrist extending from the distal end of the elongate shaft, and an end effector extending from the wrist. The end effector may include a first jaw and a second jaw, the first and second jaw being moveable between an open position in which ends of the jaws are separated from each other, and a closed position in which the ends of the jaws are closer to each other as compared to the open position. The surgical instrument may also include at least one rotary cutter extending from the wrist and positioned at least partially within a recess formed in a face of the first jaw.

A method and apparatus for treating tissue are disclosed, including intra-operative mapping of a probe ablation zone. The method uses a system that maps the proximal and distal margins of the probe ablation zone using tools that access the ablation target. In some embodiments, the tools comprise a bone drill, and an introducer assembly, including a cannula and a stylet. The tools have features or markings that cooperate to indicate which probe to use to achieve the desired ablation. The method further facilitates planning probe placement for delivering energy to treat (ablate) a desired ablation volume of a target tissue by using a system that maps both the target tissue and possible probe ablation zones.

According to some embodiments, a medical instrument comprises an elongate body having a proximal end and a distal end and a pair of electrodes or electrode portions (for example, a split-tip electrode assembly). Systems and methods are described herein that perform contact sensing and/or ablation confirmation based on electrical measurements obtained while energy of different frequencies are applied to the pair of electrodes or electrode portions. The contact sensing systems and methods may calibrate network parameter measurements to compensate for a hardware unit in a network parameter measurement circuit or to account for differences in cables, instrumentation or hardware used.

Disclosed herein are systems and methods for locating and identifying nerves innervating the wall of arteries such as the renal artery. The present invention identifies areas on vessel walls that are innervated with nerves; provides indication on whether energy is delivered accurately to a targeted nerve; and provides immediate post-procedural assessment of the effect of energy delivered to the nerve. The methods includes evaluating a change in physiological parameters after energy is delivered to an arterial wall; and determining the type of nerve that the energy was directed to (sympathetic or parasympathetic or none) based on the evaluated results. The system includes at least a device for delivering energy to the wall of blood vessel; sensors for detecting physiological signals from a subject; and indicators to display results obtained using said method. Also provided are catheters for performing the mapping and ablating functions.

An electrosurgical wand for reducing tissue is disclosed. The wand includes a handle and an elongate shaft, the shaft having a major longitudinal axis, a conduit extending therethrough and a non-insulated distal end portion defining a first electrode. The first electrode has a distal most edge configured to mechanically pierce tissue, and an arcuate surface extending proximally from the distal most edge along the major longitudinal axis, the arcuate surface having a convex surface that faces in a distal direction. First and second arcuate edges define lateral edges of the arcuate surface. A second electrode is disposed at an opening of the conduit and electrically isolated from the first electrode. The second electrode comprises an aperture, configured to aspirate fluid and tissue debris therethrough.

A balloon-type electrode catheter according to the present invention includes an outer tube, an energizing connector, a balloon including neck portions on both ends of an expansion portion, an inner tube, a distal end tip, strip electrodes formed on an outer surface of the balloon, a metal ring attached to the distal end side neck portion with a distal end portion of each of the strip electrodes secured to an outer circumferential surface of the metal ring, and a lead wire electrically connecting each of the strip electrodes and the energizing connector with a distal end of the lead wire fixed to an inner circumferential surface of the metal ring and with a proximal end of the lead wire fixed to the energizing connector.

A catheter including: an elongated body sized to traverse vasculature; a lumen formed in the elongated body; and a pull-wire. The elongated body has a transition zone disposed between proximal and distal ends of the elongated body, a first shaft extending from the proximal end of the elongated body to the transition zone and defining a longitudinal axis, and a second shaft extending proximally from the distal end to the transition zone. The lumen defines a curved path curved about the longitudinal axis and extending from the distal end to the transition zone, and a straight path extending from the transition zone to the proximal end. The pull wire extends within the curved and straight paths, and is anchored to the second shaft such that translation of the pull-wire near the proximal end deflects the second shaft substantially along the curved path.