WO2001008577A1

WO2001008577A1 - Electrode for cutting biological tissue

Info

Publication number: WO2001008577A1
Application number: PCT/EP2000/007256
Authority: WO
Inventors: Klaus Fischer; Martin Hagg
Original assignee: Erbe Elektromedizin Gmbh
Priority date: 1999-07-30
Filing date: 2000-07-27
Publication date: 2001-02-08
Also published as: EP1199999A1

Abstract

The invention relates to an electrode for cutting biological tissue using a high-frequency current. During the cutting process, arc-like discharges occur between an electrically conductive, active electrode area and the tissue. The aim of the invention is to prevent too high a current flux in the tissue, in particular, at the first incision. To this end, the active electrode area comprises, at least after the start of a cutting operation, a multitude of individual surfaces which are accessible for the formation of the discharge and which are separated from one another by insulated zones. The individual surfaces have very small proportions in relation to a total surface of the active electrode area.

Description

Electrode for cutting a biological tissue

Besehreibung

The invention relates to an electrode for cutting a biological tissue according to the preamble of patent claim

1 ches 1, and method for producing such electrodes.

When cutting biological tissue with an electrode, the problem arises that biological tissue adheres to or even burns onto the electrode surface. In order to avoid this, a large number of different solutions have hitherto been proposed.

From DE 42 12 053 Cl it is known, for example, to coat the metallic surface of an electrode at least partially i with a hard material layer, which consists of a metal-metalloid compound. The advantage of such a coating of metallic hard material is its resistance to electric arcs and mechanical loads. 0

WO 96/20652 also discloses an electrode whose rough surface is partially provided with a metallic coating which makes the surface smoother and thereby reduces tissue sticking to the electrode during cutting and enables the electrode to be cleaned more easily.

From US 5,382,247 an electrosurgical electrode is known, the metallic surface of which is coated with a polymer coating which acts as an electrical and thermal insulator. The tip of the electrode remains free and the polymer layer has holes through which the gie penetrates from the electrode into the biological tissue to be cut.

No. 5,549,604 describes an electrode and a method for producing the electrode, the electrode being provided with an electrically conductive, pure amorphous silicone coating which is applied by means of a PECVD (plasma enhanced chemical vapor deposition) method. The silicone coating prevents biological tissue from sticking or sticking to the tip of the electrode during the cutting process.

WO 97/11649 also discloses an electrosurgical electrode with a silicone coating and a method for producing the electrode. The silicone coating has a different thickness. The silicone coating on the cutting edges of the electrode is particularly thin in order to allow an HF current to flow from the electrode into the biological tissue. On the other hand, the silicone coating on the flat areas of the electrode is particularly thick and acts as an insulator. The silicone coating prevents the biological tissue from sticking or sticking to the electrode during cutting.

When cutting, however, not only is the attachment or sticking of biological tissue to the electrode a problem, but also the gating phase, ie the phase until the cutting process begins. In the gate phase there are still no arc-like discharges between the electrode and the biological tissue to be cut, which increase the contact resistance between the electrode and the biological tissue and thus also limit the HF current flow into the tissue. Excessive RF current flow into the tissue can cause a too deep, unintentional te coagulation, ie damage to lower tissue areas.

From DE 29 46 728 AI a high-frequency surgical unit is known in which the HF current flow is not generated continuously, but in one or more time intervals in order to cut the electrode too deeply into the tissue due to an excessive HF current flow to avoid. In the case of unfavorable electrodes in particular, for example polypectomy slurries, it can, under certain circumstances, take a very long time to produce arcing-like discharges. During this time, an excessive HF current flowing into the tissue can damage it.

It is therefore an object of the present invention to provide an electrode for cutting a biological tissue, which enables a safe cutting of the tissue and which is of relatively simple construction.

This object is achieved by an electrode with the features of claim 1. Advantageous configurations of the electrode can be found in the dependent claims.

An electrode for cutting biological tissue by means of an HF current is thus shown, with arc-like discharges occurring during the cutting between an electrically conductive, active electrode region and the tissue. According to the invention, the active electrode area comprises, at least after the beginning of a cutting process, a multiplicity of individual areas which are accessible for the formation of the discharges and which are separated from one another by isolated areas, the individual areas being dimensioned very small relative to a total area of the active electrode area. An essential point of the invention lies in the small number and the small size of electrically active, ie conductive surfaces or individual surfaces which are present for the formation of arc-like discharges or arcs. As a result, the contact resistance between the electrode and the tissue to be cut is so great that only a very small amount of HF current flows into the tissue. Especially when cutting the tissue, too deep, unintentional coagulation of the tissue is avoided (even before arcing occurs).

The individual surfaces are preferably dimensioned so small that the HF current dries out the tissue sections touching the individual surfaces without substantial heating of the tissue to form essentially insulating tissue sections. The RF current is therefore so small due to the dimensioning of the individual surfaces that no damage to the underlying tissue layers can occur due to an excessive RF current.

20

The individual surfaces are preferably formed by (spark) breakdown of an insulation layer on the active electrode area. Essentially, an HF current flow into the tissue only comes about through a (spark) breakdown of the insulation layer. Before a breakdown, the active electrode area is isolated due to the insulation layer, as a result of which there is no substantial HF current flow in the tissue. ) In a preferred embodiment, the insulation layer is designed to be so completely penetrable that it covers the active electrode area essentially completely so that it is penetrated by the HF current when the tissue is touched before the electrode is used for the first time. A small number of individual surfaces is preferably formed in the insulation layer before the electrode is used for the first time.

In another embodiment, the individual surfaces are formed by targeted spark breakdowns before the electrode is used for the first time, while the insulation layer cannot be penetrated by the HF current during use. In this embodiment, the electrode can be prepared during manufacture.

In a further preferred embodiment, the individual surfaces are formed via channels in a porous layer, which isolates the active electrode area from direct contact with the tissue. When the electrode and tissue come into contact, there can be no current flow and thus in particular no unintentional, too deep coagulation of the tissue.

Advantageously, the insulation layer or the porous layer can be formed in such a way that tissue does not stick or stick during cutting.

In an alternative embodiment, the active electrode area is formed from a large number of individual elements.

The individual elements preferably comprise wires or electrically conductive fibers. The effective conductive area of the electrode is determined by the number of wires or electrically conductive fibers. By reducing the wires or the electrically conductive fibers under the individual elements, for example, the contact resistance between the electrode and the tissue can be increased. The electrode is particularly preferably designed in the form of a cord or ribbon. The electrode is preferably designed as a polypectomy tube. A rough or roughened surface of the electrode is particularly advantageous in order to prevent the polypectomy slurry from slipping when it is placed against the tissue to be cut, ie when wrapping the polyp around it.

Furthermore, the invention relates to a method for producing an electrode for cutting biological tissue by means of an HF current, wherein arc-like discharges occur during the cutting between an electrically conductive active electrode region and the tissue.

According to the invention, the active electrode area is covered with an insulation layer. A large number of individual surfaces are produced in the insulation layer and are accessible for the formation of the discharges. The individual surfaces are preferably formed by (spark) breakdown of the insulation layer on the active electrode region. The individual surfaces are particularly preferably formed by targeted spark breakdowns before the electrode is used for the first time. Furthermore, the active electrode region is formed from a large number of individual elements in a preferred embodiment of the method. The individual elements preferably comprise wires or electrically conductive fibers which are interwoven, interwoven, sewn or twisted with non-conductive wires.

Finally, the invention relates to the use of the electrode in endoscopy for the removal of polyps. The electrode is preferably used in an applicator for gas enterology. The electrode can also be used under water. The contact resistance between the electrode and the tissue is reduced by the water, so that there is a risk of an excessive HF current is particularly large and the electrode according to the invention can be used particularly advantageously here.

Further advantages and possible uses of the invention result from the following description of embodiments in conjunction with the figures.

Hieroei show:

10 shows an embodiment of an electrode for polypectomy and the basic arrangement when performing the polypectomy,

2 shows a cross section of the electrode according to a first embodiment of the invention,

3 is a plan view of the electrode according to the first embodiment of the invention,

4 shows a cross section of the electrode according to a second embodiment of the invention,

Fig. 5 is a plan view of an electrode according to a third embodiment of the invention.

_ ->

Fig. 6 shows an embodiment of the electrode for use in an endoscope for gastroenterology.

3 () FIG. 1 shows an electrode 11 for polypectomy, which is connected to an active connection 14 of a high-frequency generator 10 (HF generator). A high-frequency alternating voltage is present at the active connection 14 of the HF generator 10. The HF generator 10 has control elements

35 for setting parameters of the high-frequency AC voltage such as the interval duration of voltage pulses, the choice of individual pulses or pulse series. As a cutting tool, the electrode has an active electrode region 12, which comprises a wire-shaped loop (polypectomy tube). The wire-shaped loop is placed around a polyp 42 that includes biological tissue 40. The biological tissue 40, that is to say the patient, is electrically connected to a neutral connection 15 of the high-frequency generator 10, for example earth. A high-frequency AC voltage for cutting the tissue is present between the active electrode area 12 of the electrode 11, in particular the wire-shaped loop, and the tissue 40 of the polyp 42.

The high-frequency alternating voltage depends on the voltage of the HF generator 10 and, if applicable, a voltage drop within the tissue 40. The polypectomy slurry can be surrounded in particular by argon gas, which is supplied by means of a gas supply 13. The argon gas favors the formation of arc-like discharges between the polypectomy slurry and the polyp 42 and prevents the generation of smoke. As soon as the voltage between the polypectomy tube and the tissue 40, in particular the polyp 42, exceeds the breakdown voltage of an insulation layer of the loop, arc-like discharges occur between the loop and the tissue 40.

Simultaneously with the occurrence of the arc-like discharges, a high-frequency current flow (HF current flow) occurs over the active electrode area 12 m, the tissue 40.

2 is a cross section of the surface of the active electrode region 12 and in particular the loop Electrode for polypectomy shown. The conductive material 20 of the electrode, in particular a metal, is coated with an insulation layer 21. The insulation layer 21 has a multiplicity of openings 22 which define conductive areas of the electrode surface, namely individual surfaces 26. When arc-like discharges occur, high-frequency current (HF current) flows into the tissue via these individual surfaces 26 of the electrode. The current flowing through the tissue is determined by the number and size of the em-

K) cell surfaces 26 so limited that damage to deeper tissue sections cannot occur due to excessive current flow. For this purpose, the individual surfaces 26 of the electrode surface are made relatively small in relation to the total surface of the electrode. The HF current flowing over these small individual surfaces 26 does have a very high current density at certain points, but the sum of the HF currents flowing over all individual surfaces 26 of the insulating coating 21 results in an overall low total current. The openings 22 can arise when the electrode is used for the first time when the insulation layer is broken through. They can also be generated in a targeted manner (in particular by generating electrical breakdowns) before they are used for the first time.

Since during the cutting of the tissue, the insulating coating 21 of the electrode by the arc-like

Can partially burn off discharges, contamination of the tissue with burned products is possible. The insulating coating 21 is therefore made from a biocompatible material, in particular from organic substances, which do not result in any harmful residues when burned.

3 shows the top view of a section of the active electrode region. Here, the insulating coating 21 has openings 22 which define the individual surfaces S. The RF current flow from the electrode to the tissue can essentially be determined by the diameter of these openings 22.

4 shows the cross section of a further embodiment of the insulating coating of the active electrode region 12. Here, the insulating coating 21 or insulation layer, which covers the metallic surface 20 of the electrode, has grains 25. The grains 25 bring about a porosity of the insulating coating 21, as a result of which these air channels are formed. The air channels cause an arc-like discharge to occur even at a low voltage between the active electrode region 12 and the tissue 40. The insulating coating 21, which envelops the entire electrically active region of the electrode, at the same time prevents an HF current flow from the electrode from occurring into the tissue without arc-like discharges. It is only the arc-like discharges that cause an HF current to flow, which, however, is limited between the electrode and the tissue due to the high contact resistance formed by the relatively small air channels

5 again shows the top view of a section of the active electrode region 12 of another embodiment of the electrode. Here, the electrode has conductive wires 23 and non-conductive wires 24 (shown obliquely), which are intertwined, twisted, woven or sewn together. E HF current flow from the electrode into the tissue occurs exclusively via the conductive wires 23. Here, too, the total HF current that can flow from the electrode into the tissue can essentially be determined via the number of conductive wires 23. A combination with the options described above (insulating coating, etc.) is very possible. 6 shows the use of the electrode in an endoscope for gastroenterology, that is, for mirroring the gastrointestinal area. An applicator 30 for gastroenterology has an endoscope for mirroring an intestine 41. Furthermore, the applicator 30 has an opening for gas supply for the supply of argon gas in particular, which prevents smoke formation during an electrosurgical cutting process. In addition, an extraction opening is provided for extracting argon gas and smoke or vapor pressure levels. Furthermore, a polypectomy tube 31, which can be controlled by an operator via the applicator 30, is provided for the removal of polyps 42 in the intestine 41. The polypectomy loop 31 is movably attached to the applicator 30 in such a way that the surgeon can extend the polypectomy loop 31 out of the applicator 30 and retract it into the applicator so as not to disturb the view, for example during endoscopy ,

In summary, the electrode according to the invention essentially has the advantage that an excessively high HF current flow from the electrode into tissue to be cut is avoided before arcing-like discharges occur between the electrode and the tissue, and in particular a possibly too deep coagulation. In one embodiment of the electrode with an insulating

Coating, the insulating coating can in particular be designed in such a way that sticking or sticking of the cut biological tissue to the electrode is avoided. A rough or roughened surface of the electrode is very advantageous in order to prevent the electrode, which is designed as a polypectomy slurry, from slipping when it is placed against the tissue to be cut, ie the polyp. LIST OF REFERENCE NUMBERS

High-frequency generator electrode active electrode area gas supply active generator connection neutral generator connection conductive material (especially metal; insulation layer openings openings conductive wires non-conductive wires Korner single flat applicator polypectomy slurry biological tissue intestinal polyp

Claims

Electrode for cutting a biological tissue

s claims

1. Electrode for cutting biological tissue (40) by means of an HF current, arcing-like discharges occurring during the cutting between an electrically conductive, active electrode region (12) and the tissue (40), characterized in that the active electrode region (12 ) comprises, at least after the beginning of a cutting process, a multiplicity of individual surfaces 5 (26) which are essentially freely accessible from the outside in order to form the discharges and which are separated from one another by isolated regions (21), the individual surfaces (26) relative to a total surface of the active electrode area are dimensioned very small.

2. Electrode according to claim 1, so that the individual surfaces (26) are dimensioned so small that the HF current touches the individual surfaces (26)

Tissue sections dry out on the surface without substantial heating of the fabric to form essentially insulating tissue sections. 3. Electrode according to claim 1 or 2, so that the individual surfaces (26) are formed by (spark) breakdown of an insulation layer (21) on the active electrode region (12). 5

4. Electrode according to claim 3, characterized in that the insulating layer (21) is designed so that it can penetrate the active electrode area (12) essentially completely so that it can penetrate the RF current when the tissue (40) is touched before the electrode is used for the first time

5. Electrode according to claim 4, so that a small number of individual surfaces (26) are formed in the insulation layer (21) before the electrode (11) is used for the first time.

6. Electrode according to claim 3, so that the individual surfaces (26) are formed by targeted spark strikes before the electrode is used for the first time, while the insulation layer (21) cannot be penetrated by the HF current during use. 0

Electrode according to Claim 1 or 2, ie that the individual surfaces (26) are porous via channels m

Layer (21, 25) are formed, which the active

Electrode area compared to a direct touch of the

Fabric isolated.

Electrode according to claim 1 or 2, d a d u r c h g e ke n n z e i c hn e t that the active electrode region from a variety of

Individual elements (23, 24) is formed.

Electrode according to claim 8, characterized in that the individual elements comprise wires or electrically conductive fibers (23).

10. Electrode according to one of claims 1 to 9, so that the electrode is formed like a cord or band

11. Electrode according to claim 10, since the electrode is designed as a polypectomy tube (31).

12. A method for producing an electrode for cutting biological tissue (40) by means of an HF current, whereby arc-like discharges occur during the cutting between an electrically conductive, active electrode region (12) and the tissue (40), thereby not characteristic , 0 that the active electrode area (12) with a

Insulation layer (21) is coated, and in the insulation layer (21) a plurality of individual surfaces is generated, which are accessible to form the discharges. 5

13. The method according to claim 12, so that the individual surfaces (26) are formed by (spark) breakdown of the insulation layer (21) on the active electrode region (12).

14. The method according to claim 13, characterized in that the individual surfaces (26) before a first Use of the electrode can be formed by targeted sparking.

15. The method according to any one of claims 12 to 14, so that the active electrode region (12) is formed from a multiplicity of individual elements (23, 24).

16. The method according to claim 15, that the individual elements comprise wires or electrically conductive fibers (23) which are interwoven, intertwined, sewn or twisted with non-conductive wires (24).

17. Use of an electrode, in particular according to claim 10 or 11 in endoscopy for the removal of polyps (42) (polypectomy).

Use according to claim 17, in which the electrode is placed in an applicator (30) for

Gastroenterology is used.