Methods, apparatuses and systems for ablation therapy. A configurable ablation probe includes at least two electrodes, the surface areas of which can be manipulated and then fixed by the user. Some methods include adjusting the relative surface areas during a sequence of ablation steps to preferentially create lesions closer to one electrode or the other. Some methods include adjusting the position of one of the electrodes during therapy delivery to create elongated lesions.

Electrosurgery blades including electrosurgery blade assemblies having argon beam capability. The electrosurgery blade includes a thin conductive member having a lead sharp cutting end and an opposite noon-cutting end and a non-conductive coating covering the thin conductive member such that at least a portion of the lead cutting end and at least a portion of the opposite non-cutting end of the thin conductive member remain exposed. An electrosurgery blade assembly having argon beam capability includes the previously described electrosurgery blade, a non-conductive tube member having a hollow tubular shaped opening positioned on top of the electrosurgery blade, and a conductive hollow tubular member contained within at least a portion of the non-conductive tube member.

An electrosurgical instrument includes a light source, a first conductor, a second conductor, an insulation material positioned between the first conductor and the second conductor, and a light pipe that carries light from the light source to the insulation material.

An irrigated balloon catheter for use in an ostium of a pulmonary vein, includes a flex circuit electrode assembly adapted for circumferential contact with the ostium when the balloon is inflated. Adapted for both diagnostic and therapeutic applications and procedures, the balloon catheter may be used with a lasso catheter or focal catheter. The flex circuit electrode assembly includes a substrate, a contact electrode on an outer surface of the substrate, the contact electrode having a “fishbone” configuration with a longitudinally elongated portion and a plurality of transversal fingers, and a wiring electrode on an inner surface of the substrate, and conductive vias extending through the substrate electrically coupling the contact electrode and the writing electrodes. Microelectrodes with exclusion zones are strategically positioned relative to the electrodes. The electrodes may also be split into electrode portions.

A method of constructing an inflatable electrode assembly configured for irrigation, comprises: providing a flex circuit having a substrate with a pre-formed aperture, the substrate constructed of a material having a greater heat resistance or a first melting temperature; providing a balloon member with a membrane, the membrane constructed of a material having a lesser heat resistance or a second melting temperature lower than the first melting temperature of the substrate; affixing the substrate to the membrane wherein a surrounding portion of the substrate around the pre-formed aperture masks a surrounding portion of the membrane so as to expose a target portion of the membrane; and applying heat to the target portion of the membrane through the pre-formed aperture of the substrate, wherein the heat applied, without melting the substrate, melts the target portion of the membrane in forming an aperture in the membrane.

An end effector for an electrosurgical instrument is disclosed which includes a first jaw, a first energy delivery surface, a first distal end, and a first proximal end. A second jaw of the end effector includes a second energy delivery surface, a second distal end, and a second proximal end. The end effector also includes an electrically conductive gap setting member which defines a distal gap distance between the first and second energy delivery surfaces. At least one pivot is fixed to one of the jaws to set a proximal gap distance between the first and second energy delivery surfaces. A method for making an end effector and a method for assembling an end effector for an electrosurgical instrument are also disclosed.

An end effector includes a first and second jaw member each comprising a first and second electrode. The first and second jaw members are movable relative to the other between an open position and a closed position. An electrically conductive member is located at the distal end of the first jaw member. The electrically conductive member is sized and configured to define a minimum distance between the first and second electrodes along the length of the first and second electrodes. An electrically insulative member is located on one of the first jaw member or the second jaw member. The electrically insulative member is sized and configured to engage tissue and has a dimension extending from one of the first jaw member or the second jaw member. The dimension is less than the minimum distance.

Ablation systems of the present disclosure facilitate the safe formation of wide and deep lesions. For example, ablation systems of the present disclosure can allow for the flow of irrigation fluid and blood through an expandable ablation electrode, resulting in efficient and effective cooling of the ablation electrode as the ablation electrode delivers energy at a treatment site of the patient. Additionally, or alternatively, ablation systems of the present disclosure can include a deformable ablation electrode and a plurality of sensors that, in cooperation, sense the deformation of the ablation electrode, to provide a robust indication of the extent and direction of contact between the ablation electrode and tissue at a treatment site.

An ultrapolar electrosurgery blade includes top and bottom thin elongated conductive members in vertical alignment and spaced apart from one another along their lengths, a non-conductive coating covering both the top and bottom thin elongated conductive members and the space located between them to create opposing non-conductive sides of the blade with conductive cutting and ends and conductive non-cutting ends exposed, and both return and active contact layers located on each of the opposing non-conductive sides of the blade. An ultrapolar electrosurgery blade assembly having argon beam capability further includes a non-conductive tube member having a slot positioned over the top of the ultrapolar electrosurgery blade and a conductive hollow tubular member contained within at least a portion of the non-conductive tube member.

An end effector has a first jaw member that includes a first electrode, and second jaw member that includes a second electrode, an electrically conductive member located at the distal end of either the first jaw member or the second jaw member, and an electrically insulative member located either on the first jaw member or the second jaw member. The electrically conductive member is configured to define a distance between the first and second electrodes along the length of the first and second electrodes, the electrically conductive member having a first stiffness. The electrically insulative member is located either on the first jaw member or the second jaw member and is sized and configured to engage tissue. The electrically conductive member has a first stiffness and the electrically insulative member has a second stiffness. The first stiffness is greater than the first stiffness.