DE112017003589T5 - ULTRAPOLAR ELECTRO-SURGERY CUTTING AND ULTRAPOLAR ELECTRO-SURGICAL PROPULSIONS - Google Patents

Abstract

An ultrapolar electrosurgical cutting edge and ultrapolar electrosurgical pens. The ultrapolar electrosurgical blade has a non-conductive sheet with opposite planar sides, a cutting end and an opposite non-cutting end, a first active electrode and a first return electrode located on an opposite planar side, and a second active electrode and a second second return electrode located on the other opposite flat side. The ultrapolar non-telescopic and telescopic electrosurgical pens may be equipped with or without smoke evacuation and are capable of cutting with a sharp nonconductive cutting end of the ultrapolar electrosurgical cutting edge and upon activation of the active contacts and the return contacts, both on each side of the ultrapolar electrosurgical cutting edge are arranged to cut and coagulate.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority on the basis of the provisional US patent application 15 / 211.270 , registered on July 15, 2016; and the provisional U.S. Patent Application No. 15 / 211,431 , filed on July 15, 2016, the entire contents of which are hereby incorporated by reference.

FIELD OF THE INVENTION

The present invention relates generally to an ultrapolar electrosurgical blade and to ultrapolar electrosurgical pens which utilize monopolar energy in a bipolar mode for cutting and coagulation. The ultrapolar electrosurgical blade and ultrapolar electrosurgical pens are capable of cutting with a sharp nonconductive cutting end of an ultrapolar electrosurgical blade and cutting or coagulating upon activation of active electrodes and back electrodes, both of which are present on the electrosurgical blades ,

The ultrapolar electrosurgical blade of the present invention comprises a nonconductive sheet member having first and second opposite planar sides, a cutting end and an opposite non-cutting end, a first active electrode and a first return electrode, both on the first opposite plane Side of the non-conductive sheet member, and a second active electrode and a second rear electrode, both located on the second opposite planar side of the non-conductive sheet member. An ultrapolar electrosurgical pencil of the present invention comprises a handpiece having first and second ends and an ultra-polar electrosurgical cutting edge of the present invention positioned within the first end of the handpiece. The handpiece may further include a smoke evacuation channel formed therein for discharging smoke and / or debris from the surgical site.

The ultrapolar telescopic electrosurgical wand / handpiece of the present invention includes a handpiece member having a first end and a second end, a hollow telescoping member having a first end and a second end, the hollow telescoping member concentrically disposed within the first end of the first end Handpiece is positioned, an electrosurgical blade with both an active contact and a back contact, which are positioned within the first end of the hollow telescopic member, a first hollow, conductive tubular member which is in contact with either the active contact or the back contact within the hollow telescopic element disposed electrosurgical cutting edge, a first solid, cylindrical member which is in contact with that contact of the electrosurgical cutting edge, which is not in contact with the first hollow, conductive tubular member and within the hollow, a second hollow conductive tubular member disposed within the handpiece member so that at least a portion of the first solid cylindrical member is disposed within at least a portion of the second hollow conductive tubular member and a second solid cylindrical one An element disposed within the handpiece member so that at least a portion of the second solid cylindrical member is disposed within at least a portion of the first hollow conductive tubular member. The ultrapolar telescopic electrosurgical wand / handpiece of the present invention may also be capable of removing smoke and / or debris from the surgical site.

BACKGROUND OF THE INVENTION

Electrosurgery uses an electrosurgical RF generator (also known as ESU) and a handpiece with an electrode to generate a high voltage (RF) AC input with various voltages to cut or coagulate biological tissue. The handpiece may be a monopolar instrument with one electrode or a bipolar instrument with two electrodes. When using a monopolar instrument, a contact pad for a return electrode is attached to the patient and the high frequency electrical current flows from the generator to the monopolar instrument, through the patient to the contact site of the return electrode, and back to the generator. Monopolar electrosurgery is commonly used for its versatility and effectiveness. However, the excessive heat generated in monopolar electrosurgery can cause excessive tissue damage and tissue necrosis, as high voltage and high RF energy is applied to the patient via the back electrode positioned on the patient's back.

In bipolar electrosurgery, the patient's active exit and return functions both occur at the surgical site since both the active and return electrodes are located in the bipolar instrument. Therefore, the path of electric current is on limits the biological tissue that is between the active electrode and the return electrode. Although bipolar electrosurgery allows the use of lower voltages and lower energy, and thereby reduces or eliminates the likelihood of tissue damage and sparks associated with monopolar electrosurgery, it has limited ability to cut and coagulate major bleeding areas ,

Accordingly, there is a need for an electrosurgical blade which allows both the cutting and coagulation of large areas of tissue without tissue damage and which avoids the passage of energy through the patient. An ultrapolar electrosurgical blade with a sharp cutting edge and both an active electrode and a return electrode positioned on opposite sides of the electrosurgical blade, meets this need. The ultrapolar electrosurgical blades having a sharp cutting edge and an active electrode and a return electrode positioned on both opposite sides of the electrosurgical blade, as described with respect to the present invention, may be used with an electrosurgical handpiece / stylus, or which does not function as a fume evacuator but is also intended to be used with an electrosurgical wand / handpiece that is capable of evacuating smoke during the electrosurgical procedure.

A telescopic, ultrapolar electrosurgical handpiece / telescopic, ultrapolar electrosurgical pencil with an electrosurgical cutting edge with a sharp cutting edge and both an active electrode and a return electrode positioned on opposite sides of the electrosurgical cutting edge also allows for both precise cutting and coagulation of large areas of biological tissue. Furthermore, such an ultra-polar telescopic electrosurgical handpiece / telescoping electrosurgical stylus allows a user or surgeon to more easily and effectively gain improved access to the surgical site by using the telescopic element of the handpiece / stylus as well as within the telescoping element of the handpiece / stylus positioned ultrapolar electrosurgical cutting edge is extended. The ultra-polar telescopic electrosurgical handpiece / stylus of the present invention also allows a user or surgeon to remove smoke and / or debris from the surgical site while accurately cutting at the surgical site as well as cutting and coagulating large biological tissue areas at the surgical site can be performed.

SUMMARY OF THE INVENTION

The present invention relates to an ultra-polar electrosurgical cutting edge comprising a non-conductive sheet member having first and second opposite planar sides, a cutting end and a non-cutting end, a first active electrode and a first return electrode respectively opposed to the first with at least a portion of the first opposite planar side exposed near the cutting end of the non-conductive sheet, and having a second active electrode and a second return electrode located respectively on the second opposite planar side, at least one Part of the second opposite planar side is exposed near the cutting end of the non-conductive sheet member. In an exemplary embodiment of the ultrapolar electrosurgical blade of the present invention, the first active electrode located on the first planar side is mirrored with at least a portion of the second return electrode located on the second planar side and the first return electrode located on the first planar side is mirrored with at least a portion of the second active electrode located on the second planar side.

The non-conductive sheet member may be made of a ceramic material, and the first and second active electrodes and the first and second back electrodes may comprise a stainless steel, copper and / or tungsten material. In another exemplary embodiment of the ultrapolar electrosurgical blade of the present invention, each of the first and second active electrodes and the first and second return electrodes may take the form of an elongated conductive layer extending over more than half the length of the non-conductive sheet extends. At least a portion of the elongate conductive layer of the first active electrode may extend to and along a partial length of one or more of the opposite longitudinal edges of the first opposing planar side, and at least a portion of the elongated conductive layer of the first return electrode may extend to and along a partial length of one or a plurality of opposite longitudinal edges of the first opposing planar side.

In yet another exemplary embodiment of the ultrapolar electrosurgical blade of the present invention, at least a portion of the elongated conductive layer is the second Return electrode on the second opposite planar side of the non-conductive sheet member with at least a portion of the elongated conductive layer of the first active electrode mirrored on the first opposite planar side of the non-conductive sheet member, and at least a portion of the elongated conductive layer of the second active electrode the second opposite planar side of the non-conductive sheet is mirrored with at least a portion of the elongated conductive layer of the first back electrode on the first opposite planar side of the non-conductive sheet.

In yet another exemplary embodiment of the ultra-polar electrosurgical blade of the present invention, the ultra-polar electrosurgical blade comprises a non-conductive sheet having first and second opposite planar sides with opposite longitudinal edges, a cutting end, and an opposite non-cutting end, a first active electrode with a hook-shaped configuration located on the first opposite planar side of the non-conductive sheet, a first back electrode having a rod-shaped configuration with at least a portion of the first back electrode positioned within the hook-shaped configuration of the first active electrode, without the first active one To touch an electrode, a second return electrode having a hook-shaped configuration, which is located on the second opposite planar side of the non-conductive sheet member, and a e second active electrode having a rod-shaped configuration, wherein at least a part of the second active electrode is positioned within the hook-shaped configuration of the second back electrode without contacting the second back electrode. The hook-shaped configuration of the first active electrode and the second back electrode may be located near the cutting end of the non-conductive sheet without covering at least a portion of the first and second opposite planar sides located near the cutting end of the non-conductive sheet , At least a portion of the hook-shaped configuration of the first active electrode located on the first opposite planar side may be mirrored with at least a portion of the hook-shaped configuration of the second back electrode located on the second opposite planar side and at least a portion of Rod-shaped configuration of the first return electrode may mirror with at least a portion of the rod-shaped configuration of the second active electrode. The non-conductive sheet member may be made of a ceramic material, and the first and second active electrodes and the first and second back electrodes may be made of a stainless steel, copper and / or tungsten material.

The first active electrode may take the form of a hook-shaped conductive layer, wherein at least a portion of the hook-shaped conductive layer extends to and along a partial length of the opposite longitudinal edges of the first opposite planar side of the non-conductive sheet member, and the first back electrode may be in the form of a assume rod-shaped conductive layer, wherein at least a part of the rod-shaped conductive layer extends to and along a partial length of one of the opposite longitudinal edges of the first opposite planar side of the non-conductive sheet member. Similarly, the second back electrode may take the form of a hook-shaped conductive layer with at least a portion of the hook-shaped conductive layer extending to and along a partial length of the opposite longitudinal edges of the second opposite planar side of the non-conductive sheet and the second active electrode take the form of a rod-shaped conductive layer, wherein at least a part of the rod-shaped conductive layer extends to and along a partial length of one of the opposite longitudinal edges of the second opposite planar side of the non-conductive sheet member.

Furthermore, a portion of the first and second active electrodes and a portion of the first and second return electrodes may extend to the opposite non-intersecting end of the non-conductive sheet. The ultra-polar electrosurgical blade of the present invention may further include a first conductive insert member communicating with both the first active electrode and the second active electrode located near the non-intersecting end of the non-conductive sheet member and a second conductive insert member which communicates with both the first return electrode and the second return electrode located near the non-intersecting end of the nonconductive sheet member. The first and second conductive inserts may each comprise a metallic contact element made of brass and / or copper.

The present invention also relates to an ultrapolar electrosurgical pencil having a handle having first and second ends and an electrosurgical blade positioned in the first end of the handle, the electrosurgical blade comprising a non-conductive sheet having first and second opposing planar sides. a cutting end and an opposite non-cutting end, a first active electrode and a first return electrode located on the first opposite planar side, wherein at least a part of the first opposite planar side is exposed near the non-conductive cutting end of the non-conductive sheet, and having a second active electrode and a second back electrode are on the second opposite planar side, wherein at least a portion of the second opposite planar side is exposed near the non-conductive intersecting end of the non-conductive planar member. The handpiece may further include a smoke evacuation channel formed therein for evacuating smoke and debris from the surgical site during activation of the electrosurgical wand. Furthermore, the handpiece may comprise at least one activation key for cutting and at least one activation key for coagulation.

The present invention further relates to an ultra-polar telescopic electrosurgical handpiece / pen capable of performing precise cutting at an operative site as well as cutting and coagulating large biological tissue areas at the surgical site. The ultrapolar telescopic electrosurgical pencil of the present invention is also capable of effectively and effectively gaining access to an operative site while providing improved visibility at the surgical site by extending the telescopic element of the ultrapolar telescopic electrosurgical handpiece / pen and within the telescoping telescope Element arranged ultrapolar electrosurgical cutting edge is delivered while at the same time smoke and / or residues are discharged from the surgical site.

In an exemplary embodiment, the ultra-polar telescopic electrosurgical handpiece / stylus of the present invention includes a handpiece member having first and second ends, a hollow telescoping member having first and second ends, at least a portion of the hollow telescoping member concentrically within of the first end of the handpiece member, an electrosurgical blade having both active contact and back contact positioned within the first end of the hollow telescoping member, a first hollow conductive tubular member in contact with the active contact of the electrosurgical Cutting edge and is disposed within the hollow telescopic tubular member, a first solid, conductive cylindrical member which is in contact with the back contact of the electrosurgical blade and within the hollow telescopic member a a second hollow conductive tubular member disposed within the handpiece member so that at least a portion of the first solid cylindrical member is disposed within at least a portion of the second hollow conductive tubular member and a second solid cylindrical member disposed within the handpiece member such that at least a portion of the second solid cylindrical member is disposed within at least a portion of the first hollow conductive tubular member. The handpiece member may further include a fume extraction passageway in communication with an interior of the hollow telescoping tubular member for discharging smoke and / or debris from the surgical site.

The ultrapolar telescopic electrosurgical handpiece / stylus may further include a first support member positioned within the handpiece member, wherein at least a portion of the second solid conductive cylindrical member and at least a portion of the second hollow conductive tubular member extend through the first support member , and / or a second support member positioned within the hollow telescoping member, wherein at least a portion of the active contact of the electrosurgical blade and at least a portion of the back contact of the electrosurgical blade extend through the second support member. The ultra-polar telescopic electrosurgical handpiece / stylus may also include a pivot member connected to the second end of the handpiece member to allow a vacuum tube connected to the pivot member to be rotated about an electrical lead connected to the handpiece member Use of the ultra-polar telescopic electrosurgical handpiece / stylus is facilitated by a surgeon by reducing the pull on or pulling the end of the ultrapolar telescopic electrosurgical handpiece / stylus opposite the electrosurgical blade.

The first and second hollow conductive tubular members and the first and second solid conductive cylindrical members of the ultrapolar telescopic electrosurgical handpiece / pin of the present invention may be made of stainless steel, copper and / or titanium. Furthermore, the first and second hollow conductive tubular members may each have an insulating part on their outer surfaces.

The electrosurgical blade of the ultrapolar telescopic electrosurgical handpiece / stylus may include a non-conductive sheet with opposite planar sides have both an active contact and a back contact on each opposite planar side of the non-conductive sheet member. The electrosurgical blade may further comprise a non-conductive sharp cutting tip which may be formed of the non-conductive sheet member, and the non-conductive sharp cutting tip and the non-conductive sheet member may be made of a ceramic material.

The ultra-polar telescopic electrosurgical handpiece / stylus of the present invention may also include a locking member for locking the hollow telescoping tubular member in position relative to the handpiece member. The ultrapolar telescopic electrosurgical handpiece / stylus of the present invention may also include at least one activation button for cutting and at least one activation button for coagulation.

In another exemplary embodiment, the ultrapolar telescopic electrosurgical handpiece / stylus of the present invention comprises a handpiece member having first and second ends, a hollow telescoping member having first and second ends, at least a portion of the hollow telescoping member being concentric is positioned within the first end of the handpiece member, an electrosurgical blade having both an active contact and a back contact positioned within the first end of the hollow telescopic member, a first solid conductive cylindrical member which is in contact with the active contact of the electrosurgical cutting edge and is disposed within the hollow telescopic tubular member, a first hollow, conductive tubular member which is in contact with the back contact of the electrosurgical cutting edge and within the hollow telescopic, r a second solid conductive cylindrical member disposed within the handpiece member so that at least a portion of the second solid cylindrical member is disposed within at least a portion of the first hollow conductive tubular member and a second hollow conductive one tubular member disposed within the handpiece member so that at least a portion of the first solid cylindrical member is disposed within at least a portion of the second hollow conductive tubular member. As with the exemplary embodiment described above, the handpiece member may further include a fume extraction passageway communicating with an interior of the hollow telescopic tubular member for evacuating smoke and / or debris from the surgical site.

This second exemplary embodiment of the ultrapolar telescopic electrosurgical handpiece / pin may include a first support member positioned within the handpiece member, wherein at least a portion of the second solid cylindrical member and at least a portion of the second hollow conductive tubular member extend through the first support member and / or have a second support member positioned within the hollow telescoping member, wherein at least a portion of the active contact of the electrosurgical blade and at least a portion of the back contact of the electrosurgical blade extend through the second support member. This embodiment may also include a pivot member connected to the second end of the handpiece member to allow a vacuum hose connected to the pivot member to be rotated about an electrical lead connected to the handpiece member, thereby facilitating use of the ultra-polar telescopic electrosurgical handpiece / Pen is facilitated by a surgeon by the train on the end of the ultra-polar, telescopic electrosurgical handpiece / pin or pulling it is opposite to the electrosurgical cutting edge reduced.

As in the first exemplary embodiment, the first and second hollow conductive tubular members and the first and second solid conductive cylindrical members of the second exemplary embodiment of the ultrapolar telescopic electrosurgical handpiece / pin of the present invention may be made from stainless steel, copper, and / or. or titanium. Furthermore, the first and second hollow conductive tubular members may each have an insulating part on their outer surfaces. Further, the electrosurgical blade of the second exemplary embodiment of the ultrapolar telescopic electrosurgical handpiece / stylus may comprise a nonconductive planar member having opposite planar sides with both active contact and back contact on each opposite planar side of the nonconductive planar member. The electrosurgical blade may further comprise a non-conductive sharp cutting tip which may be formed of the non-conductive sheet member, and the non-conductive sharp cutting tip and the non-conductive sheet member may be made of a ceramic material.

Furthermore, as in the first exemplary embodiment, the second exemplary embodiment of the ultra-polar telescopic electrosurgical handpiece / pin of the present invention may also include a locking member locking the hollow telescoping tubular member in position relative to the handpiece member, and having at least one activating key for cutting and at least one activating key for coagulation.

list of figures

• 1 ist eine Seitenansicht einer beispielhaften Ausführungsform der ultrapolaren elektrochirurgischen Schneide der vorliegenden Erfindung;
• 2 ist eine Draufsicht der beispielhaften Ausführungsform der in 1 gezeigten ultrapolaren elektrochirurgischen Schneide der vorliegenden Erfindung;
• 3 ist eine entgegengesetzte Seitenansicht der beispielhaften Ausführungsform der in 1 gezeigten ultrapolaren elektrochirurgischen Schneide der vorliegenden Erfindung mit der in 1 gezeigten ultrapolaren elektrochirurgischen Schneide, die um 180 Grad verdreht ist;
• 4 ist eine Querschnittsansicht entlang Linie 4-4 von 1;
• 5 ist eine Querschnittsansicht entlang Linie 5-5 von 1;
• 6 ist eine Querschnittsansicht entlang Linie 6-6 von 1;
• 7 ist eine Endansicht der ultrapolaren elektrochirurgischen Schneide von 1 und 3, die eine beispielhafte Ausführungsform eines Trägerelements zum Halten der ultrapolaren elektrochirurgischen Schneide der vorliegenden Erfindung zeigt, sodass die leitenden Einsätze in Verbindung mit den aktiven Elektroden und den Rückelektroden der elektrochirurgischen Schneide leicht in einen elektrochirurgischen Stift eingeführt werden können;
• 8 ist eine teilweise perspektivische Ansicht der beispielhaften Ausführungsform der in 1 gezeigten ultrapolaren elektrochirurgischen Schneide der vorliegenden Erfindung;
• 9 ist eine seitliche Querschnittsansicht einer beispielhaften Ausführungsform eines ultrapolaren elektrochirurgischen Stifts der vorliegenden Erfindung;
• 10 ist eine seitliche perspektivische Ansicht einer ersten beispielhaften Ausführungsform des ultrapolaren, teleskopischen elektrochirurgischen Handstücks/Stifts der vorliegenden Erfindung, die die inneren Komponenten des ultrapolaren, teleskopischen elektrochirurgischen Handstücks/Stifts zeigt, wie sie erscheinen würden, wenn man in das Handstück/den Stift hineinsehen könnte;
• 11 ist die gleiche Ansicht wie in 10 gezeigt, wobei aber das ultrapolare, teleskopische elektrochirurgische Handstück/der Stift um 180 Grad relativ zu dem Schwenkelement des ultrapolaren, teleskopischen elektrochirurgischen Handstücks/Stifts verdreht gezeigt ist, wobei das Schwenkelement in der gleichen Position gehalten wird, wenn das Handstückelement und das hohle, teleskopische Element des ultrapolaren, teleskopischen elektrochirurgischen Handstücks/Stifts um 180 Grad verdreht sind;
• 12 ist eine seitliche perspektivische Ansicht einer zweiten beispielhaften Ausführungsform des ultrapolaren, teleskopischen elektrochirurgischen Handstücks/Stifts der vorliegenden Erfindung, die die inneren Komponenten des ultrapolaren, teleskopischen elektrochirurgischen Handstücks/Stifts zeigt, wie sie erscheinen würden, wenn man in das Handstück/den Stift hineinsehen könnte; und
• 13 ist die gleiche Ansicht wie in 12 gezeigt, wobei aber das ultrapolare, teleskopische elektrochirurgische Handstück/der Stift um 180 Grad relativ zu dem Schwenkelement des ultrapolaren, teleskopischen elektrochirurgischen Handstücks/Stifts verdreht gezeigt ist, wobei das Schwenkelement in der gleichen Position gehalten wird, wenn das Handstückelement und das hohle, teleskopische Element des ultrapolaren, teleskopischen elektrochirurgischen Handstücks/Stifts um 180 Grad verdreht sind.

The present invention will be described below in conjunction with the attached drawings, wherein like reference numerals designate like elements.

• 1 FIG. 4 is a side view of an exemplary embodiment of the ultrapolar electrosurgical blade of the present invention; FIG.
• 2 FIG. 10 is a top view of the exemplary embodiment of FIG 1 shown ultrapolar electrosurgical cutting edge of the present invention;
• 3 FIG. 3 is an opposite side view of the exemplary embodiment of FIG 1 shown ultrapolar electrosurgical cutting edge of the present invention with the in 1 shown ultrapolar electrosurgical cutting edge, which is rotated 180 degrees;
• 4 is a cross-sectional view along line 4-4 from 1 ;
• 5 is a cross-sectional view along line 5-5 from 1 ;
• 6 is a cross-sectional view along line 6-6 from 1 ;
• 7 is an end view of the ultrapolar electrosurgical cutting edge of 1 and 3 showing an exemplary embodiment of a support member for holding the ultrapolar electrosurgical blade of the present invention so that the conductive inserts in conjunction with the active electrodes and back electrodes of the electrosurgical blade can be easily inserted into an electrosurgical pencil;
• 8th FIG. 14 is a partial perspective view of the exemplary embodiment of FIG 1 shown ultrapolar electrosurgical cutting edge of the present invention;
• 9 Figure 4 is a side cross-sectional view of an exemplary embodiment of an ultra-polar electrosurgical pencil of the present invention;
• 10 Figure 4 is a side perspective view of a first exemplary embodiment of the ultrapolar telescopic electrosurgical handpiece / stylus of the present invention showing the internal components of the ultrapolar telescopic electrosurgical handpiece / stylus as they would appear if one could look into the handpiece / stylus ;
• 11 is the same view as in 10 however, the ultra-polar telescopic electrosurgical handpiece / stylus is shown rotated by 180 degrees relative to the pivotal element of the ultra-polar telescopic electrosurgical handpiece / stylus with the pivotal element held in the same position when the handpiece element and the hollow telescopic Element of the ultra-polar, telescopic electrosurgical handpiece / stylus rotated 180 degrees;
• 12 FIG. 12 is a side perspective view of a second exemplary embodiment of the ultrapolar telescopic electrosurgical handpiece / stylus of the present invention showing the internal components of the ultrapolar telescopic electrosurgical handpiece / stylus as they would appear if one could look into the handpiece / stylus ; and
• 13 is the same view as in 12 however, the ultra-polar telescopic electrosurgical handpiece / stylus is shown rotated by 180 degrees relative to the pivotal element of the ultra-polar telescopic electrosurgical handpiece / stylus with the pivotal element held in the same position when the handpiece element and the hollow telescopic Element of the ultra-polar, telescopic electrosurgical handpiece / pen are rotated 180 degrees.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

The exemplary embodiments of the ultrapolar electrosurgical blade and ultrapolar electrosurgical pin of the present invention enable a user or surgeon to perform cutting with the sharp non-conductive tip of the electrosurgical blade as well as coagulating large areas of biological tissue with the electrosurgical blade by using the electrosurgical cutting edge is applied with one of its sides, on which both an active electrode and a return electrode are located. The electrosurgical cutting edge and the electrosurgical pencil of the present invention may also perform cutting with the active electrode and the back electrode of the electrosurgical cutting edge. Exemplary embodiments of the ultrapolar electrosurgical blade and the ultrapolar electrosurgical pin of the present invention include an electrosurgical blade comprising a non-conductive sheet having opposite planar sides, a cutting end and a non-cutting end, a first active electrode and a first return electrode, each on an opposite planar side of the non-conductive sheet, and a second active electrode and a second back electrode each positioned on the other opposite planar side of the non-conductive back electrode. The cutting end of the non-conductive sheet may form a sharp, nonconductive cutting end for cutting biological tissue, while the active and back electrodes located on either side of the nonconductive sheet are used to perform coagulation as well as Cutting of biological tissue can be used.

1 and 3 show opposite side views of an exemplary embodiment of the ultrapolar electrosurgical cutting edge 10 of the present invention, which is a non-conductive sheet member 12 with a first and a second opposite flat side 14 (please refer 1 ) 16 (please refer 2 ) with opposite longitudinal edges 18 , a cutting end 20 and an opposite non-cutting end 22 , a first active electrode 24 and a first return electrode 28 , each on the first opposite flat side 14 of the non-conductive planar element 12 at least a portion of the first opposite planar side 14 near the nonconductive cutting end 20 of the non-conductive planar element 12 is exposed, and a second active electrode 44 and a second return electrode 38 having, respectively, on the second opposite planar side 16 of the non-conductive planar element 12 at least a portion of the second opposite planar side 16 near the nonconductive cutting end 20 of the non-conductive planar element 12 is exposed. The first and second active electrodes 24 . 44 and the first and second return electrodes 28 . 38 each may take the form of an elongated conductive layer extending over more than half the length of the nonconductive sheet member 12 extends.

As in the 1 and 3 As shown in the exemplary embodiment shown, at least a portion of the first active electrode may be formed 24 and at least a part of the first return electrode 28 to and along a partial length of at least one of the opposite longitudinal edges 18 the first opposite flat side 14 of the non-conductive planar element 12 extend. Furthermore, at least a part of the second return electrode 38 to and along a partial length of at least one of the opposite longitudinal edges 18 the second opposite flat side 16 of the non-conductive planar element 12 extend. As continues in the in 1 and 3 As shown in the exemplary embodiment of the ultrapolar electrosurgical cutting edge, at least a portion of the first active electrode may be provided 24 that are on the first opposite level side 14 located with at least a portion of the second return electrode 38 that are on the second opposite level side 16 is located, mirrored, and at least a portion of the first return electrode 28 that are on the first opposite level side 14 may be with at least a portion of the second active electrode 44 be mirrored, located on the second opposite flat side 16 located. In addition, the first active electrode 24 a hook-shaped configuration 26 and the first return electrode 28 can be a rod-shaped configuration 30 having at least a portion of the rod-shaped configuration 30 the first return electrode 28 inside the hook-shaped configuration 26 the first active electrode 24 is positioned. Furthermore, the second return electrode 38 a hook-shaped configuration 40 and the second active electrode 44 can be a rod-shaped configuration 46 having at least a portion of the rod-shaped configuration 46 the second active electrode 44 inside the hook-shaped configuration 40 the second return electrode 38 is positioned.

The non-conductive, planar element 12 may consist of a ceramic material, which also has a sharp, cutting end 20 can form. The first and second active electrodes 24 . 44 and the first and second return electrodes 28 . 38 can be made of stainless steel, copper and / or tungsten. The hook-shaped configuration 26 the first active electrode 24 and the hook-shaped configuration 40 the second return electrode 38 can get close to the cutting end 20 of the non-conductive, planar element 12 while allowing at least a portion of the first and second opposite sides 14 . 16 of the non-conductive planar element 12 near the nonconductive cutting end 20 is exposed. This makes it possible to perform precise cutting with the sharp, non-conductive cutting end 20 the ultrapolar electrosurgical cutting edge 10 ,

The ultrapolar electrosurgical cutting edge 10 can also be a support element 31 which may take the form of a variety of configurations as long as it is capable of the non-conductive sheet member 12 and its associated active electrode and back electrode to carry, so that the ultrapolar electrosurgical cutting edge 10 easy with an instrument such. B. can be connected to an electrosurgical pencil. The ultrapolar electrosurgical cutting edge 10 can also a first conductive insert element 50 that with the first active electrode 24 and the second active electrode 44 near the opposite non-cutting end 22 of the non-conductive planar element 12 in communication, and a second conductive insert 52 having, with the first return electrode 28 and the second return electrode 38 near the opposite non-cutting end 22 of the non-conductive planar element 12 communicates.

2 is a plan view of the ultrapolar electrosurgical cutting edge 10 the present invention with the non-conductive, planar element 12 that with dashed line inside the support element 31 is shown. 4 is a cross-sectional view along line 4-4 from 1 , which is the non-conductive, planar element 12 and the first active electrode 24 and the first return electrode 28 that lie on one side (the first opposite flat side 14 ) of the non-conductive, planar element 12 and the second active electrode 44 and the second return electrode 38 shows that are on the other side (the second opposite flat side 16 ) of the non-conductive, planar element 12 are located. As in 4 shown are two parts of the first active electrode 24 on one side of the non-conductive, planar element 12 shown, and two parts of the second return electrode 38 are on the other side of the non-conductive, planar element 12 depending on where the cross section was taken. 5 shows another cross section of the ultrapolar electrosurgical cutting edge 10 of the present invention along line 5-5 from 1 , 5 shows a part of the first active electrode 24 and a part of the first return electrode 28 on one side of the non-conductive, planar element 12 , and a part of the second active electrode 44 and a part of the second return electrode 38 on the other side of the non-conductive, planar element 12 , 6 is a cross-sectional view along line 6-6 from 1 , which is the non-conductive, planar element 12 together with the first and second active electrodes 24 . 44 and the first and second return electrodes 28 . 38 disposed within the support member 31 , shows. 6 also shows the first conductive insert 50 the ultrapolar electrosurgical cutting edge 10 that with the first and the second active electrode 24 . 44 is in communication, and the second conductive insert 52 the ultrapolar electrosurgical cutting edge 10 connected to the first and second back electrodes 28 . 38 communicates.

An end view of the ultrapolar electrosurgical cutting edge 10 from 1 and 3 shows an exemplary embodiment of a support member 31 for holding the ultrapolar electrosurgical cutting edge 10 of the present invention, so that the conductive inserts 50 . 52 connected to the active electrodes and the back electrodes 24 . 44 . 28 . 38 the electrosurgical cutting edge 10 be easily connected to an instrument such as a B. an electrosurgical pencil can be introduced. In an exemplary embodiment, the carrier element 31 the shape of a hollow cylindrical element 60 with a non-conductive insert 62 and conductive tubular members 64 . 66 assume, in which the first and the second conductive insert element 50 . 52 can be introduced. It will be understood by those skilled in the art that the support member is for holding the ultrapolar electrosurgical blade 10 The present invention may take any number of forms or configurations.

8th FIG. 14 is a partial perspective view of the exemplary embodiment of FIG 1 shown ultrapolar electrosurgical cutting edge 10 of the present invention. How to get in 8th can see, the active electrodes and the back electrodes of the cutting edge are on opposite planar sides of the non-conductive sheet-like element 12 , wherein the upper part of the non-conductive, planar element 12 non-conductive and free of electrodes.

A side cross-sectional view of an exemplary embodiment of an ultrapolar electrosurgical pencil 70 of the present invention is in 9 shown. The ultrapolar electrosurgical pencil 70 has a handpiece 72 with a first end 74 and a second end 76 on, and an ultrapolar electrosurgical cutting edge 10 is within the first end 74 positioned the handpiece. In the 9 shown ultrapolar electrosurgical cutting edge 10 is like that in 1 to 3 shown cutting edge 10 educated. Conductive wires 80 . 82 connect the first and the second conductive insert element 50 . 52 with the circuit board, with at least one activation key 86 for cutting and at least one activation key 88 can be provided for coagulation. The hand piece 72 can have a smoke extraction duct 71 to facilitate the removal of smoke and / or debris from the surgical site in performing the cutting and / or coagulation.

The exemplary embodiments of the ultrapolar telescopic electrosurgical handpiece / stylus of the present invention allow a user or surgeon to perform precise cutting as well as coagulation. The ultra-polar telescopic electrosurgical handpiece / stylus of the present invention also provides for the concomitant removal of smoke and / or debris from the surgical site as well as the telescopic adjustment of the length of the ultrapolar telescopic electrosurgical handpiece / stylus, as the case may be. what kind of access to the surgical site is needed. The ultra-polar telescopic electrosurgical handpiece / stylus of the present invention also includes a pivot member connected to the end of the handpiece member opposite the electrode to allow a vacuum tube connected to the pivot member to rotate about an electrical lead connected to the handpiece member whereby the use of the ultrapolar telescopic electrosurgical handpiece / stylus by a surgeon is facilitated by reducing the pull on the end of the ultrapolar telescopic electrosurgical handpiece / stylus or pulling it out during electrosurgery. The ultrapolar telescopic electrosurgical handpiece / stylus is used interchangeably throughout this specification with electrosurgical handpiece / stylus, electrosurgical handpiece, electrosurgical stylus and handpiece / stylus, and all such terms are intended to refer to the same subject matter of the invention.

10 Figure 4 is a side perspective view of a first exemplary embodiment of the ultrapolar telescopic electrosurgical handpiece / stylus 110 of the present invention, which includes the internal components of the ultrapolar telescopic electrosurgical handpiece / stylus 110 shows how they would appear when looking at the handpiece / pen 110 could look into it. The ultra-polar telescopic electrosurgical handpiece / stylus 110 has a handpiece element 112 with a first end 114 and a second end 116 , a hollow, telescopic element 118 with a first end 120 and a second end 122 , wherein at least a part of the hollow telescopic element 118 concentric within the first end 114 of the handpiece element 112 is positioned, an electrosurgical cutting edge 124 with both an active contact 126 as well as a back contact 128 that are within the first end 120 of the hollow, telescopic element 118 are positioned, a first hollow, conductive tubular member 130 that is in contact with the active contact 126 the electrosurgical cutting edge 124 stands and inside the hollow, telescopic element 118 is arranged, a first solid, conductive cylindrical element 132 in contact with the back contact 128 the electrosurgical cutting edge 124 stands and inside the hollow, telescopic element 118 is arranged, a second hollow, conductive tubular member 134 that inside the handpiece element 112 is arranged so that at least part of the first solid, cylindrical element 132 within at least a portion of the second hollow conductive tubular member 134 is arranged, and a second solid, conductive cylindrical member 136 on that within the handpiece element 112 is arranged, so that at least part of the second solid, conductive cylindrical element 136 within at least a portion of the first hollow conductive tubular member 130 is arranged. It will be understood by one of ordinary skill in the art that other means for connecting the active contact also exist 126 and back contact 128 the electrosurgical cutting edge 124 with a printed circuit board located in or on the handpiece element 112 can be used to activate the cutting and / or coagulation, such. For example, wires each covered, for example, with an insulating member as long as the insulated wires are durable and capable of ensuring that the respective wires connected to the active contacts and the back contacts do not come into contact with each other. However, the solid conductive cylindrical members and the hollow conductive tubular members described with reference to the exemplary embodiments shown and illustrated herein are considered to be a better means of connecting the active contacts and the back contacts of the ultrapolar electrosurgical blade to the printed circuit board. which enables the activation of cutting and / or coagulation with the handpiece / pin. Furthermore, the use of the solid conductive cylindrical members and the hollow conductive tubular members described with reference to the exemplary embodiments shown and illustrated herein forms a handpiece / pin which is much less likely to fail a handpiece / stylus that is much less prone to malfunction that could result in injury to a patient and / or user / surgeon during use of the handpiece / stylus.

How to get in the 10 As shown in the exemplary embodiment shown, the electrosurgical pencil / handpiece of the present invention includes a handpiece element 112 and a hollow, telescopic element 118 which have both channels formed therein, which merge into each other to allow removal of smoke and / or debris from the surgical site. During evacuation, the smoke moves and / or the debris moves through the continuous channel and flows or flows around the first and second hollow conductive tubular members 130 . 134 and the first and second solid conductive cylindrical members 132 . 136 which are arranged in the continuous channel. Furthermore, a first carrier element 140 within the handpiece element 112 positioned so that at least part of the second solid conductive cylindrical member 136 and at least a portion of the second hollow conductive tubular member 134 through the first carrier element 140 extend. Furthermore, a second carrier element 142 inside the hollow, telescopic element 118 positioned so that at least a portion of the active contact 126 the electrosurgical cutting edge 124 and at least part of the return contact 128 the electrosurgical cutting edge 124 through the second carrier element 142 extend. The first and second hollow conductive tubular members 130 . 134 and the first and second solid conductive cylindrical members 132 . 136 may be stainless steel, copper and / or titanium, and the outer surfaces of the first and second hollow conductive tubular members 130 . 134 can each be covered with an insulating part.

The electrosurgical cutting edge 124 is an ultra-polar electrosurgical cutting edge with a non-conductive sheet and opposite flat sides and active contact 126 and a back contact 128 on each opposite planar side of the non-conductive sheet element. The ultrapolar electrosurgical cutting edge 124 also has a non-conductive sharp cutting tip 145 on. The non-conductive sharp cutting tip 145 may be formed of the non-conductive sheet member, and both may be made of a ceramic material.

The ultra-polar telescopic electrosurgical handpiece / stylus 110 also has a pivoting element 146 on, that with the second end 116 of the handpiece element 112 is connected, so that the pivoting element 146 relative to the handpiece element 112 rotates. The pivoting element 146 allows a vacuum hose connected to the pivot member 148 one with the handpiece element 112 connected electrical line 150 can be rotated, whereby the use by a surgeon of the ultra-polar, telescopic electrosurgical handpiece / pin 110 is facilitated by pulling on the end of the ultrapolar telescopic electrosurgical handpiece / stylus 110 or pulling it out during electrosurgery is reduced.

11 is the same view as in 10 but with the ultrapolar telescopic electrosurgical handpiece / stylus shown 110 180 degrees relative to the pivoting element 146 of the ultra-polar, telescopic electrosurgical handpiece / stylus 110 is rotated, wherein the pivot member is held in the same position when the handpiece element 112 and the hollow, telescopic element 118 of the ultra-polar, telescopic electrosurgical handpiece / stylus 110 twisted 180 degrees. How to get in 11 can see, has the ultrapolar electrosurgical cutting edge 124 also a second active contact 127 and a second back contact 129 which are located on the opposite planar side of the non-conductive sheet member, to the opposite flat side, which is the active contact 126 and the back contact 128 contains, is opposite. How to get in 10 and 11 can see, stand the active contact 126 and the second active contact 127 both in contact or in communication with the first hollow conductive tubular member 130 , and the back contact 128 and the second back contact 129 Both are in contact or in communication with the first solid conductive cylindrical member 132 , This configuration of the ultra-polar, telescopic electrosurgical handpiece / stylus 110 allows a user or surgeon to biologic tissue with the non-conductive sharp cutting tip 145 to cut, biological tissue with active contact 126 and the back contact 128 on one side of the electrosurgical cutting edge 124 to coagulate biological tissue with the second active contact 127 and the second back contact 129 on the other side of the electrosurgical cutting edge 124 to coagulate, and with active contact 126 and the back contact 128 and with the second active contact 127 and the second back contact 129 at the electrosurgical cutting edge 124 to cut.

The ultra-polar, telescopic electrosurgical handpiece / stylus 110 also has a locking element 160 on to the hollow, telescopic element 118 in position relative to the handpiece element 112 to lock. Furthermore, as in 10 and 11 shown the ultrapolar, telescopic electrosurgical handpiece / stylus 110 also at least one activation key 170 for cutting and at least one activation key 172 for coagulating on.

12 Figure 4 is a side perspective view of a second exemplary embodiment of the ultrapolar telescopic electrosurgical handpiece / stylus 200 of the present invention, which includes the internal components of the ultrapolar telescopic electrosurgical handpiece / stylus 200 shows how they would appear when looking at the handpiece / pen 200 could look into it. The ultra-polar telescopic electrosurgical handpiece / stylus 200 has a handpiece element 212 with a first end 214 and a second end 216 , a hollow, telescopic element 218 with a first end 220 and a second end 222 , wherein at least a part of the hollow telescopic element 218 concentric within the first end 214 of the handpiece element 212 is positioned, an electrosurgical cutting edge 224 with both an active contact 226 as well as a back contact 228 that are within the first end 220 of the hollow, telescopic element 218 are positioned, a first solid, conductive cylindrical member 230 that is in contact with the active contact 226 the electrosurgical cutting edge 224 stands and inside the hollow, telescopic element 218 is arranged, a first hollow, conductive tubular member 232 in contact with the back contact 228 the electrosurgical cutting edge 224 stands and inside the hollow, telescopic element 218 is arranged, a second solid, conductive cylindrical member 234 that inside the handpiece element 212 is arranged, so that at least part of the second solid, conductive cylindrical element 234 within at least a portion of the first hollow conductive tubular member 232 is arranged, and a second hollow, conductive tubular member 236 on that within the handpiece element 212 is arranged so that at least part of the first solid, conductive cylindrical element 230 within at least a portion of the second hollow conductive tubular member 236 is arranged. It will be understood by one of ordinary skill in the art that other means for connecting the active contact also exist 226 and back contact 228 the electrosurgical cutting edge 224 with a printed circuit board located in or on the handpiece element 212 can be used to activate the cutting and / or coagulation, such. For example, wires that are each covered, for example, with an insulating member as long as the insulated wires are durable and capable of ensuring that the respective wires connected to the active contacts and the back contacts do not come into contact with each other. However, the solid conductive cylindrical members and the hollow conductive tubular members described with reference to the exemplary embodiments shown and illustrated herein are considered to be a better means of connecting the active contacts and the back contacts of the ultrapolar electrosurgical blade to the printed circuit board. which enables the activation of cutting and / or coagulation with the handpiece / pin. Furthermore, the use of the solid conductive cylindrical members and the hollow conductive tubular members described with reference to the exemplary embodiments shown and illustrated herein forms a handpiece / pin which is much less likely to fail a handpiece / stylus that is much less prone to malfunction that could result in injury to a patient and / or user / surgeon during use of the handpiece / stylus.

How to get in the 12 As shown in the exemplary embodiment shown, the electrosurgical pencil / handpiece 200 the present invention, a handpiece element 212 and a hollow, telescopic element 218 which have both channels formed therein, which merge into each other to allow removal of smoke and / or debris from the surgical site. During discharge, the smoke moves and / or the residues pass through the continuous channel and flow or flow around the first and second solid conductive cylindrical members 230 . 234 and the first and second hollow conductive tubular members 232 . 236 which are arranged in the continuous channel. Furthermore, a first carrier element 240 within the handpiece element 212 positioned so that at least part of the second solid conductive cylindrical member 236 and at least a portion of the second hollow conductive tubular member 234 through the first carrier element 240 extend. Furthermore, a second carrier element 242 inside the hollow, telescopic element 218 positioned so that at least a portion of the active contact 226 the electrosurgical cutting edge 224 and at least part of the return contact 228 the electrosurgical cutting edge 224 through the second carrier element 242 extend. The first and second hollow conductive tubular members 232 . 236 and the first and second solid conductive cylindrical members 230 . 234 may be stainless steel, copper and / or titanium, and the outer surfaces of the first and second hollow conductive tubular members 232 . 236 can each be covered with an insulating part.

The electrosurgical cutting edge 224 is an ultra-polar electrosurgical cutting edge with a non-conductive sheet and opposite flat sides and active contact 226 as well as a back contact 228 on each opposite planar side of the non-conductive sheet element. The ultrapolar electrosurgical cutting edge 224 also has a non-conductive sharp cutting tip 245 on. The non-conductive sharp cutting tip 245 may be formed of the non-conductive sheet member, and both may be made of a ceramic material.

The ultra-polar telescopic electrosurgical handpiece / stylus 200 also has a pivoting element 246 on, that with the second end 216 of the handpiece element 212 is connected, so that the pivoting element 246 relative to the handpiece element 212 rotates. The pivoting element 246 allows a vacuum hose connected to the pivot member 248 one with the handpiece element 212 connected electrical line 250 can be rotated, whereby the use by a surgeon of the ultra-polar, telescopic electrosurgical handpiece / pin 200 is facilitated by pulling on the end of the ultrapolar telescopic electrosurgical handpiece / stylus 200 or pulling it out during electrosurgery is reduced.

13 is the same view as in 12 but with the ultrapolar telescopic electrosurgical handpiece / stylus shown 200 180 degrees relative to the pivoting element 246 of the ultra-polar, telescopic electrosurgical handpiece / stylus 200 is rotated, wherein the pivot member is held in the same position when the handpiece element 212 and the hollow, telescopic element 218 of the ultra-polar, telescopic electrosurgical handpiece / stylus 200 twisted 180 degrees. How to get in 13 can see, has the ultrapolar electrosurgical cutting edge 224 also a second active contact 227 and a second back contact 229 which are located on the opposite planar side of the non-conductive sheet member, to the opposite flat side, which is the active contact 226 and the back contact 228 contains, is opposite. How to get in 12 and 13 can see, stand the active contact 226 and the second active contact 227 both in contact or in conjunction with the first solid conductive cylindrical member 230 , and the back contact 228 and the second back contact 229 both are in contact or in communication with the first hollow conductive tubular member 232 , This configuration of the ultra-polar, telescopic electrosurgical handpiece / stylus 200 allows a user or surgeon to biologic tissue with the non-conductive sharp cutting tip 245 to cut, biological tissue with active contact 226 and the back contact 228 on one side of the electrosurgical cutting edge 224 to coagulate biological tissue with the second active contact 227 and the second back contact 229 on the other side of the electrosurgical cutting edge 224 to coagulate, and with active contact 226 and the back contact 228 and with the second active contact 227 and the second back contact 229 at the electrosurgical cutting edge 224 to cut.

The ultra-polar, telescopic electrosurgical handpiece / stylus 200 also has a locking element 260 on to the hollow, telescopic element 218 in position relative to the handpiece element 212 to lock. Furthermore, as in 12 and 13 shown the ultrapolar, telescopic electrosurgical handpiece / stylus 200 also at least one activation key 270 for cutting and at least one activation key 272 for coagulation.

The detailed description of exemplary embodiments of the invention lists various exemplary embodiments of the invention. These exemplary embodiments and manners are described in sufficient detail to enable one skilled in the art to practice the invention, and are not intended to limit the scope, applicability, or configuration of the invention in any way. Rather, the following disclosure is intended to teach both the implementation of the exemplary embodiments and types, and any equivalent embodiments or manners known to or apparent to those skilled in the art. Furthermore, all examples provided are non-limiting illustrations of the exemplary embodiments and manners that are similarly available to any embodiments and types that are known or apparent to those skilled in the art.

Other combinations and / or modifications of structures, arrangements, applications, proportions, elements, materials, or components used in the practice of the present invention in addition to those not expressly recited herein may be varied or otherwise specific to particular environments, manufacturing specifications, design parameters or other operating requirements without departing from the scope of the present invention, and are intended to be included in this disclosure.

Unless expressly stated otherwise, Applicant's intention is that the words and phrases in the specification and claims have the commonly accepted generic meaning or meaning and usage as commonly understood by those of ordinary skill in the art. In the event that these meanings deviate, the words and phrases in the description and claims are intended to have the broadest possible generic meaning. If another particular meaning is intended for a word or sentence, the description will clearly outline and define the particular meaning.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 15211270 [0001]
• US 15/211431 [0001]

Claims (21)

An ultrapolar electrosurgical device comprising: an ultrapolar electrosurgical cutting edge with: a non-conductive sheet member having first and second opposite planar sides, a cutting end and an opposite non-cutting end; a first active electrode and a first return electrode, each located on the first opposite planar side of the non-conductive sheet, wherein at least a portion of the first opposite planar side is exposed near the cutting end of the non-conductive sheet; and a second active electrode and a second return electrode, each located on the second opposite planar side of the non-conductive sheet, wherein at least a portion of the second opposite planar side is exposed near the cutting end of the non-conductive sheet. Ultrapolare electrosurgical device according to Claim 1 wherein at least a portion of the first active electrode located on the first opposite planar side is mirrored with at least a portion of the second return electrode located on the second opposite planar side, and at least a portion of the first opposing planar side Return electrode is mirrored with at least a portion of the second active electrode on the second opposite planar side. Ultrapolare electrosurgical device according to Claim 1 , wherein the non-conductive, planar element consists of a ceramic material. Ultrapolare electrosurgical device according to Claim 1 wherein the first and second active electrodes and the first and second return electrodes are each made of stainless steel, copper and / or tungsten. Ultrapolare electrosurgical device according to Claim 1 wherein the first active electrode, the first return electrode, the second active electrode and the second return electrode each comprise an elongated conductive layer extending over more than half the length of the non-conductive sheet member. Ultrapolare electrosurgical device according to Claim 5 wherein at least a portion of the elongate conductive layer of the first active electrode extends to and along a partial length of at least one of opposite longitudinal edges of the first opposing planar side of the non-conductive sheet. Ultrapolare electrosurgical device according to Claim 5 wherein at least a portion of the elongated conductive layer of the first return electrode extends to and along a partial length of at least one of opposite longitudinal edges of the first opposing planar side of the non-conductive sheet. Ultrapolare electrosurgical device according to Claim 5 wherein at least a portion of the elongated conductive layer of the second back electrode on the second opposite planar side of the non-conductive sheet is mirrored with at least a portion of the elongated conductive layer of the first active electrode on the first opposite planar side of the non-conductive sheet; wherein at least a portion of the elongated conductive layer of the second active electrode on the second opposite planar side of the non-conductive sheet is mirrored with at least a portion of the elongated conductive layer of the first back electrode on the first opposite planar side of the non-conductive sheet. Ultrapolare electrosurgical device according to Claim 1 further comprising a handpiece having a first end and a second end, wherein the ultrapolar electrosurgical cutting edge is positioned within the first end of the handpiece. Ultrapolare electrosurgical device according to Claim 9 wherein the handpiece further comprises a smoke evacuation channel formed therein. Ultrapolare electrosurgical device according to Claim 9 wherein the handpiece comprises at least one activation button for cutting and at least one activation button for coagulation. Ultrapolare electrosurgical device according to Claim 1 , further comprising: a handpiece member having a first end and a second end; a hollow telescoping member having a first end, the ultrapolar electrosurgical blade positioned within the first end of the hollow telescoping member, and at least a portion of the hollow telescoping member concentrically positioned within the first end of the handle member; a first hollow conductive tubular member which is in contact with the first and second active electrodes of the ultrapolar electrosurgical Cutting edge is located and disposed within the hollow telescopic tubular member; a first solid conductive cylindrical member that is in contact with the first and second back electrodes of the ultrapolar electrosurgical blade and disposed within the hollow telescopic member; a second hollow conductive tubular member disposed within the handpiece member such that at least a portion of the first solid cylindrical member is disposed within at least a portion of the second hollow conductive tubular member; and a second solid conductive cylindrical member disposed within the handpiece member such that at least a portion of the second solid conductive cylindrical member is disposed within at least a portion of the first hollow conductive tubular member. Ultrapolare electrosurgical device according to Claim 12 wherein the handpiece element further comprises a fume extraction duct communicating with an interior of the hollow telescopic tubular member for removing smoke and debris from the surgical site. Ultrapolare electrosurgical device according to Claim 13 , further comprising a first support member positioned within the handpiece member, and wherein at least a portion of the second solid conductive cylindrical member and at least a portion of the second hollow conductive tubular member extend therethrough. Ultrapolare electrosurgical device according to Claim 14 , further comprising a second support member positioned within the hollow telescoping member, and wherein at least a portion of the first and second active electrodes of the ultrapolar electrosurgical blade and at least a portion of the first and second return electrodes of the ultrapolar electrosurgical blade extend therethrough extend. Ultrapolare electrosurgical device according to Claim 14 wherein the handpiece comprises at least one activation button for cutting and at least one activation button for coagulation. Ultrapolare electrosurgical device according to Claim 1 , further comprising: a handpiece member having a first end and a second end; a hollow telescoping tubular member having a first end and a second end, the ultrapolar electrosurgical blade positioned within the first end of the hollow telescoping tubular member, and at least a portion of the hollow telescoping member concentrically positioned within the first end of the handle member ; a first solid conductive cylindrical member that is in contact with the first and second active electrodes of the ultrapolar electrosurgical blade and disposed within the hollow telescopic tubular member; a first hollow conductive tubular member in contact with the first and second back electrodes of the ultrapolar electrosurgical blade and disposed within the hollow telescopic tubular member; a second solid conductive cylindrical member disposed within the handpiece member so that at least a portion of the second solid cylindrical member is disposed within at least a portion of the first hollow conductive tubular member; and a second hollow conductive tubular member disposed within the handpiece member such that at least a portion of the first solid cylindrical member is disposed within at least a portion of the second hollow conductive tubular member. Ultrapolare electrosurgical device according to Claim 17 wherein the handpiece element further comprises a fume extraction duct communicating with an interior of the hollow telescopic tubular member for removing smoke and debris from the surgical site. Ultrapolare electrosurgical device according to Claim 18 , further comprising a first support member positioned within the handpiece member, and at least a portion of the second solid cylindrical member and at least a portion of the second hollow conductive tubular member extending therethrough. Ultrapolare electrosurgical device according to Claim 19 , further comprising a second support member positioned within the hollow telescoping member, and wherein at least a portion of the first and second active electrodes of the ultrapolar electrosurgical blade and at least a portion of the first and second return electrodes of the ultrapolar electrosurgical blade extend therethrough extend. Ultrapolare electrosurgical device according to Claim 19 wherein the handpiece has at least one activating button for cutting and includes at least one activation button for coagulation.

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