Various embodiments disclosed relate to a non-stick layer for cutting elements on electrosurgical cutting tools. The present disclosure includes systems, devices, and methods of making and using a non-stick layer on cutting elements. The non-stick layer can include coatings, surface structures, or combinations thereof. In one example, the medical device includes a hydrophobic coating with a hydrophobic nanoscale physical structure. In one example, the medical device includes a heated cutting assembly, such as a resistive heated cutting assembly.

A method of and apparatus for treating tissue wherein a handpiece with a cartridge of motor driven needles is placed in contact with tissue. The motor is energized to drive the needles. Energy is applied energy to the needles. Tissue impedance at the start of treatment is measured. Tissue impedance at the end of treatment is measured. The operator is then notified that corrective action is needed if the measured ending impedance is higher than the measured starting impedance indicating the needles are not inserted into the tissue.

An electrosurgical instrument has dual zone smoke evacuation for providing efficient capture and evacuation of smoke generated during an electrosurgical procedure. A hand piece with a proximal and a distal end is coupled to a front piece having a distal opening leading into an interior conduit. An extendable section is at least partially disposed within the interior conduit and extends distally out of the distal opening of the front piece. The extendable section is selectively translatable within the interior conduit. A negative pressure source enables the capture and evacuation of smoke through both the extendable section and the interior conduit.

A system for altering an energizable instrument for performing a procedure on the subject. The instrument may be tracked during a procedure and a controller may alter operation thereof during the selected procedure. The energizable instrument may have energy provided to a working end to heat a working end to a selected temperature for various procedures such as cutting, coagulation, vaporization, or the like.

A surgical system for performing a capsulotomy of a lens capsule of an eye includes an elastic ring, a suction cup, an interface, a converter, and a control console. The elastic ring includes a conductive surface. The interface may be coupled to an air port and/or a fluid line of a phacomachine. The converter detects a pulse of air from the phacomachine via the interface, and produce an electrical signal in response. Fluid received from the phacomachine is delivered into the suction cup. The system is configured to remove the fluid from the suction cup and between the suction cup and a surface of the eye to form a suction seal. The control console is configured to, in response to receiving the electrical signal, drive a series of electrical pulses through the conductive surface of the elastic ring, causing the elastic ring to perform a tissue cutting operation.

An electrode assembly for use with an electrosurgical instrument includes a base portion, a return lead adapted to be electrically coupled to a return terminal of an electrosurgical generator, an electrical insulator supported on a distal portion of the return lead, a tensioning mechanism, and an active lead adapted to be electrically coupled to an active terminal of the electrosurgical generator. The tensioning mechanism includes a slider slidably disposed in the base portion, a rotation rod threadably coupled to the slider, and a spring proximally biasing the slider. The active lead having a first end portion securely fixed to the base portion and a second end portion slidably coupled to the rotation rod of the tensioning mechanism. A portion of the active lead extends around the electrical insulator. Rotation of the rotation rod causes axial displacement of the second end portion of the active lead to tension the active lead about the electrical insulator.

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 ultrapolar telescopic electrosurgery pencil that can be used in both monopolar and bipolar modes for cutting and coagulation. The ultrapolar telescopic electrosurgery pencil can operate at very low power levels (such as 15-20 Watts or less) to both cut and coagulate tissue thereby reducing patient risk and damage to tissue. An ultrapolar electrosurgery blade having a top, a bottom, opposing planar sides, a cutting edge, and a non-cutting end, an active electrode positioned on one of the opposing planar sides such that at least a portion of the opposing planar side is exposed near the cutting edge, and a return electrode positioned on the other opposing planar side such that at least a portion of the other opposing side is exposed near the cutting edge.

An electrosurgical pencil (10) includes a handle (14), a manifold (15) disposed within the handle (14), a suction tube (18) and a blower tube (16) operably coupled to the manifold (15), and an electrode assembly (20) removably coupled to the manifold (15). The suction tube (18) is configured to evacuate fluid from a surgical site and the blower tube (16) is configured to deliver fluid to a surgical site. The electrode assembly (20) includes an outer tubular member (28), an inner tubular member (26), and an electrode (25). The outer tubular member (28) defines at least one suction aperture (28A) and a suction lumen (28L) in fluid communication with the suction tube (18). The inner tubular member (26) is disposed within the suction lumen (28L) of the outer tubular member (28) and defines at least one blower aperture (26A) and blower lumen (26L) in fluid communication with the blower tube (16). The electrode (25) is configured to deliver electrosurgical energy to tissue.

An operation support device includes a connecting body in which a first support body and a second support body are detachably connected to each other; a first shaft engaging section; a shaft connecting member having a connection engaging section engaged with the first shaft engaging section; and a shaft fixing member. The shaft fixing member is movably installed with respect to a first shaft section or a second shaft section and is configured to selectively form a shaft engagement fixing state in which the connection engaging section is held down to retain an engagement state such that the connection engaging section is engaged with the first shaft engaging section and a second state in which holding down to the connection engaging section is released in accordance with a moved position with a moved position of the shaft fixing member.