A surgical forceps includes a housing having a movable handle coupled thereto and movable between an initial position and a compressed position. A drive bar is operably coupled to the movable handle such that movement of the movable handle between the initial and compressed positions effects longitudinal translation of the drive bar. The drive bar further includes a coupling member disposed at a distal end thereof. An end effector assembly includes first and second jaw members movable between spaced-apart and approximated positions. Each jaw member defines a cam slot. A cam pin is slidably disposed within the cam slot of each of the jaw members. The coupling member is configured to releasably engage the cam pin such that movement of the movable handle between the initial position and the compressed position effects movement of the jaw members between the spaced-apart position and the approximated position.

A catheter (e.g., high-density mapping catheter) and related catheter system is described herein. The catheter includes an elongated catheter shaft, and an electrode assembly. The electrode assembly includes a first spline assembly, a second spline assembly, and a distal coupler assembly. Each of the spline assembly includes a distal portion and spline assembly electrodes distributed along the spline assembly. The distal coupler assembly includes a base member and a distal electrode. The base member defines an opening configured to receive and accommodate the distal portion of the second spline assembly. The distal electrode is configured to be mounted to the base member to secure the distal portion of the second spline assembly within the opening. The distal electrode can be configured for cardiac mapping, tissue ablation, and/or bipolar pacing.

A tool assembly for use with an electrosurgical device for cutting tissue includes a base portion, a return lead, an electrical insulator, a center pin, and an active lead. The center pin extends from the base portion and through a lumen of the electrical insulator. The active lead is securely fixed to the base portion and extends between the base portion and a distal portion of the center pin such that a portion of the active lead extends around the distal portion of the center pin and first and second segments of the active lead are spaced apart from the return lead. Upon activation, electrosurgical energy is transmitted from the active lead through tissue to the return lead to cut tissue in contact with the active lead.

A surgical instrument includes a housing, a shaft, an end effector, a lead wire, and a first replaceable seal plate. The shaft extends distally from the housing. The end effector is supported adjacent a distal end of the shaft and includes a first jaw member and a second jaw member. One or both of the first jaw member or the second jaw member is movable relative to the other between an open position and an approximated position. The lead wire extends at least partially through the shaft and is adapted to connect to a source of electrosurgical energy. The first replaceable seal plate is configured for selective engagement with the first jaw member and configured for selective engagement with the lead wire. The first replaceable seal plate includes an electrically conductive portion and is configured for contacting tissue when engaged with the first jaw member.

A staple cartridge is disclosed that includes a first impedance sensing electrode and a second impedance sensing electrode. The first impedance sensing electrode is addressable to apply first energy to tissue positioned in a first zone. The second impedance sensing electrode is addressable to apply a second energy to tissue positioned in a second zone. A control circuit is configured to determine a thickness of the tissue positioned in the first zone based on the first energy and a thickness of the tissue positioned in the second zone based on the second energy. Advancement of a knife through an elongate slot of the staple cartridge is based on the determined thickness of the tissue in the first zone and the determined thickness of the tissue in the second zone.

A bipolar forceps includes a mechanical forceps including first and second shafts each having a jaw member extending from a distal end thereof and a handle disposed at a proximal end thereof for effecting movement of the jaw members relative to one another about a pivot. A disposable housing is configured to releasably couple to at least one of the shafts and an electrode assembly is configured to releasably couple to the disposable housing. The electrode assembly includes electrodes releasably coupleable to the jaw members. At least one of the electrodes includes a knife channel configured to receive a knife blade there through to cut tissue grasped between the jaw members. An actuation mechanism is configured to selectively advance the knife blade through the knife channel to cut tissue.

A body orifice remodeling device includes a cylindrical handpiece having a defined length which is adapted to be inserted into the body orifice and an elongated monopolar electrode mounted outside on the circumference of the cylindrical handpiece and extending substantially along the length of the handpiece. A source of radio frequency (RF) energy in the handpiece is configured to generate RF energy to the elongated monopolar electrode; and a source of electromagnetic stimulation energy (EMagS) in the handpiece is configured to generate (EMagS) energy.

An electrode structure inserting apparatus includes an electrode structure fixing unit to which the electrode structure is detachably fixed, and a vibration generator connected to the electrode structure fixing unit to vibrate the electrode structure fixing unit in an insertion direction of the electrode structure, and the electrode structure inserting apparatus inserts the invasive electrode structure into a nerve in a biological tissue.

A medical device may include an electrosurgical hand piece. The electrosurgical hand piece may have a housing with a proximal end, a distal end, and a chamber proximate the proximal end. The chamber may be configured to releasably retain and electrically couple with a power source. The electrosurgical hand piece may also include a treatment delivery element configured to releasably couple to the distal end of the housing. The treatment delivery element may be configured to communicate with the power source and deliver biphasic pulsed field ablation. The medical device may also include a charging element which may charge the power source using inductive charging or near-field (RF) wireless charging.

An energizable surgical attachment is configured for positioning about a shaft of a surgical instrument. The energizable surgical attachment includes an outer sheath defining a lumen extending longitudinally through the outer sheath, an energizable rod member coupled to the outer sheath, a connector attachment electrically coupled to the energizable rod member, and at least one o-ring disposed within the lumen of the outer sheath. At least a portion of the energizable rod member extends distally from the distal end of the outer sheath. The o-ring(s) are configured to establish a fluid-tight seal between the outer sheath and the shaft of the surgical instrument and to bias the outer sheath towards a stationary position relative to the shaft of the surgical instrument.