KR20050100996A - Electrode for radiofrequency tissue ablation - Google Patents

Abstract

The present invention relates to a high-frequency electrosurgical electrode used to coagulate necrosis of living tissue with high-frequency electrical energy, and in particular, a closed end of an horn shape which is pointed toward one end so as to be inserted into the living tissue; A hollow electrode having an outer surface insulated and coated except for a predetermined length of a portion connected to the closed end in a hollow tube shape extending in the longitudinal direction from the other end of the closed end; It has a diameter smaller than the inner diameter of the hollow electrode is inserted into the hollow electrode, the refrigerant is supplied into the hollow electrode to cool the biological tissue in contact with the closed end and the hollow electrode, and the heat exchanged refrigerant is supplied to the hollow electrode A refrigerant conduit for discharging out of the living body through the space therebetween; Is formed to protrude or recessed on the surface of the closed end is made of an insertion guide portion for cutting the biological tissue so that the closed end is smoothly inserted into the biological tissue.

Description

Electrode for High Frequency Electrosurgical Instrument {ELECTRODE FOR RADIOFREQUENCY TISSUE ABLATION}

The present invention relates to a high frequency electrosurgical electrode used to coagulate necrosis of a living tissue with high frequency electrical energy, and more particularly, to a high frequency electrosurgical electrode that allows an end to be inserted into a living tissue more easily.

In general, a technique of coagulation or ablation of a desired biological tissue with high frequency energy by inserting an elongated hollow tube-shaped electrode into a living body is known. In this case, when a current is applied to the living tissue, the living tissue is heated to respond to the living tissue and blood vessels by a rather complicated biochemical apparatus. And blood).

Such an electrode is formed in a horn shape so as to be easily inserted into a living tissue, and is usually formed in a cone shape or triangular pyramid shape.

However, the electrode for the high frequency electrosurgical apparatus is carbonized due to excessive coagulation of biological tissue and blood near the electrode, and the carbonized biological tissue near the electrode acts as an insulator to enlarge the area where the biological tissue can coagulate. There is a problem that acts as an obstacle.

In addition, the electrode for the high-frequency electrosurgical device as described above is easily inserted into the biological tissue to be coagulated necrosis in the early stage because the tip is pointed even though it is formed in a horn shape, but as the end is inserted into the biological tissue, the diameter increases as the tip ends. While being inserted over a certain length, not only a certain amount of force should be applied, but also there is a problem that it is difficult to be inserted into a hard biological tissue.

The present invention has been made to solve the above-mentioned problems of the prior art, for expanding the coagulation portion of the biological tissue to be coagulated necrosis and at the same time using a high frequency electrosurgery device so that the end is easily inserted into the biological tissue The purpose is to provide an electrode.

Electrode for high frequency electrosurgical device according to the present invention for solving the above problems is a closed end of the horn shape is formed sharply toward one end to be inserted into the biological tissue; A hollow electrode having an outer surface insulated and coated except for a predetermined length of a portion connected to the closed end in a hollow tube shape extending in the longitudinal direction from the other end of the closed end; It has a diameter smaller than the inner diameter of the hollow electrode is inserted into the hollow electrode, the refrigerant is supplied into the hollow electrode to cool the biological tissue in contact with the closed end and the hollow electrode, and the heat exchanged refrigerant is supplied to the hollow electrode A refrigerant conduit for discharging out of the living body through the space therebetween; Is formed to protrude or recessed on the closed end surface is composed of an insertion guide portion for cutting the biological tissue so that the closed end is inserted into the biological tissue smoothly.

In the present invention, the insertion guide portion is a plurality of grooves formed to be recessed in the longitudinal direction on the closed end surface, or a plurality of ribs formed to protrude in the longitudinal direction on the closed end surface.

Here, the insertion guide portion is preferably formed with a plurality of the alternating groove portion and the rib.

On the other hand, in the present invention, the insertion guide portion may be composed of a screw cutter formed so as to protrude spirally around the closed end surface, the screw cutter is preferably formed such that the screw cutter extends to the non-insulated portion of the hollow electrode. Do.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1A is a perspective view illustrating an electrode for a high frequency electrosurgical apparatus according to a first embodiment of the present invention, and FIG. 1B is a hole formed in an uncoated portion of an electrode for a high frequency electrosurgical apparatus according to a first embodiment of the present invention. Figure 2 is an exploded perspective view showing an electrode for a high frequency electrosurgical apparatus according to a first embodiment of the present invention, Figure 3 is a high end electrosurgical electrode end according to a first embodiment of the present invention Side view.

Electrode for high frequency electrosurgical apparatus according to the present invention is a hollow electrode 10 made of a material flowing current in the shape of a hollow tube formed long in the longitudinal direction as shown in Figure 1a to 3 as well as such a hollow electrode 10 Most of the is formed to be an insulating coating (12) with an insulator, such as Teflon, the horn-shaped closed end 20 to the end of the hollow electrode 10 is formed to be pointed toward the end so that it can be inserted into the biological tissue, On the surface of the closed end 20, an insertion guide 30 is formed to allow the closed end 20 to be smoothly inserted into a living tissue.

In this case, the closed end portion 20 is formed of an integral conductive material or welded integrally at the end of the hollow electrode 10 by a solid conductive material, and thus the insulating coating 12 of the hollow electrode 10 is formed. The hollow electrode 10 is connected to the electricity supply line 42 so as to supply a high frequency current so that high frequency current is transmitted only to the portion not closed and the closed end 20 so that coagulation necrosis occurs only in the vicinity thereof.

Here, the hollow electrode 10 is configured to cool the hollow electrode 10 and the biological tissue adjacent thereto in order to enlarge the coagulation region of the biological tissue, and specifically, the hollow electrode (10) inside the hollow electrode (10). A refrigerant conduit 40 having a diameter smaller than the inner diameter of 10) (approximately 0.4 mm in and out) is installed, and a temperature sensor line 50 is inserted into the refrigerant conduit 40 to allow the inside and the inside of the hollow electrode 10. Sensing the temperature in the closed end portion 20 area to control the output of the electrode later, the supply pipe 44 for allowing the refrigerant to flow into the refrigerant conduit 40 is installed to be connected to the refrigerant conduit 40 and the A discharge pipe 46 for discharging the refrigerant between the hollow electrode 10 and the refrigerant conduit 40 is installed to be connected to the hollow electrode 10 and the refrigerant conduit 40.

At this time, reference numeral 60, which is not shown, is a handle formed of an insulating material on the outer circumference of the hollow electrode so that the user can easily hold the high frequency electrosurgical device.

In the electrode having the above configuration, since the refrigerant in a pressurized state (pressurized to a high pressure of about 700 to 1060 KPa) is flowed in the hollow electrode 10 and the refrigerant conduit 40, it is shown in FIG. 1A. Based on the configuration, the refrigerant flows rapidly between the hollow electrode 10 and the refrigerant conduit 40 to cool the closed end portion 20 and the hollow electrode 10 in contact with the biological tissue.

In addition, at least one hole 14 is drilled on the outer surface of the hollow electrode 10 in which the insulating coating 12 is not formed, thereby preventing the explosive ejection of the pressurized refrigerant by a mechanical method. The surroundings are cooled by the refrigerant flowing out through the hole 14, and in order to prevent the refrigerant pressurized through the hole 14 from being ejected, a flow resistance of the refrigerant discharged through the hole 14 is applied. The refrigerant may be configured to be discharged little by little, which is described in detail in patent application No. 10-2003-0026106 filed by the present applicant.

Of course, the electrode for a high-frequency electrosurgical device as described above may use physiological saline to be discharged to the outside of the living body while being cooled while the refrigerant is circulated, and for example, 0.9% saline, that is, an isotonic solution may be used. have.

4A and 4B and 5A and 5B are a perspective view and a cross-sectional view of the electrode end of the high-frequency electrosurgical apparatus according to the first and second embodiments of the present invention, Figure 6 is a high frequency in accordance with a third embodiment of the present invention An electrode end for an electrosurgical instrument is an enlarged perspective view.

In particular, the closed end portion 20 has a triangular pyramid shape, as shown in Figs. 4A to 4B, the groove portion 32 is formed to be recessed in the longitudinal direction on the surface thereof, the other portion is automatically rib (34) To form the insertion guide portion 30, or similarly as shown in Figs. 5A to 5B, ribs 34 are formed to protrude in the longitudinal direction on the surface thereof, and other portions are automatically grooved. The insertion guide portion 30 can also be configured as (32).

At this time, the groove portion 32 and the rib 34 is preferably to be formed alternately on the surface of the closed end portion 20.

Of course, the closed end portion 20 may be configured in a variety of horn shape, the insertion guide portion 30 may also be configured in a variety of shapes and forming positions of the groove portion 32 and the rib 34. have.

Meanwhile, as shown in FIG. 6, the closed end portion 20 has a conical shape that is formed relatively longer than the closed end portion 20 in the first and second embodiments, and has a hollow shape to allow the refrigerant to circulate therein. It is preferable that the screw thread is formed so that the screw cutter 130 may be formed to spirally protrude around the surface thereof, and the screw cutter 130 may have the hollow electrode 10 as well as the closed end 20. More preferably, it is formed so as to extend even the non-insulated part of.

Of course, holes 114 are formed in the non-insulated portions of the closed end 20 and the hollow electrode 10 to allow the refrigerant to flow out, and the holes 114 are the closed end 20 and the hollow electrode 10. In the non-insulated part of), three places are formed along the circumferential direction, and two to four lines are preferably formed in the longitudinal direction.

In this case, the screw cutter 130 is configured to be thinner as it moves away from the center of the closed end portion 20, and is configured to have a larger outer diameter as it moves away from the end of the closed end portion 20, so that the closure even in a relatively hard biological tissue. Allow the end 20 to be easily inserted.

As described above, the closed ends of the configurations shown in FIGS. 4A to 6 are all connected to the electrodes for cooling the closed ends 20 and the hollow electrodes 10 contacting the biological tissues based on the configuration of FIGS. 1A or 1B. Can be applied.

Although the high-frequency electrosurgical device according to the present invention can be used in various applications, it will be described here as an example applied to the surgery of liver cancer patients for convenience of explanation.

The surgeon inserts an electrode for a radiofrequency electrosurgical device according to the present invention through the skin into the body, and then inserts the tip into a biological tissue (eg, a region of the liver) to coagulate necrosis.

As described above, when the closed end portion 20 and the hollow electrode 10 are inserted into the biological tissue penetrating the skin, the closed end portion 20 is protruded or recessed in the longitudinal direction on the surface of the insertion guide portion 30 Or a spirally projecting screw cutter 130 cuts off the biological tissue around the closed end 20, the hollow electrode 10 having a relatively large diameter is easily inserted into the biological tissue.

Thereafter, the high frequency electrosurgical electrode is applied with a high frequency current through the electric supply line 42 from an external power source, and the portion of the hollow electrode 10 that is not the insulating coating 12 and around the closed end 20. Allow part of the tissue to coagulate necrosis.

At the same time, the saline solution is pressurized to a high pressure and flows along the inside of the refrigerant conduit 40 through the supply pipe 44, and then hits the closed end 20 again to the refrigerant conduit 40 and the hollow electrode ( 10) flows through the discharge pipe 46 and is discharged out of the human body. As such, the refrigerant is rapidly circulated so that the portion of the closed end 20 and the hollow electrode 10 that is not the insulating coating 12 is removed. Cooling, thereby preventing the overheated portion of the closed end portion 20 and the hollow electrode 10 from being overheated to carbonize the surrounding biological tissues, thereby widening the solidification region of the surrounding biological tissues.

Of course, the temperature sensor line 50 senses the temperature inside the portion of the closed end 20 and the hollow electrode 10 that is not the insulating coating 12, so that the coagulation area of the surrounding biological tissues is expanded. The output of electricity supplied to the hollow electrode 10 is controlled.

In addition, the pressurized refrigerant is discharged through the hole 14 formed in the portion of the hollow electrode 10 that is not the insulating coating 12 so that the portion of the hollow electrode 10 that is not coated with the insulating coating or the Cooling the closed end 20 also allows for broadening the coagulation area of the biological tissue.

The electrode for the high frequency electrosurgical apparatus according to the present invention configured as described above allows the refrigerant to be circulated inside the hollow electrode in which the closed end is integrally formed at the end, so that the hollow electrode and the closed end are cooled even when a high frequency current is generated in the hollow electrode. It is possible to enlarge the solidified part of the living tissue by preventing carbonization of the surrounding living tissue, and since the recessed / protruding groove and the rib or spiral screw cutter are formed on the closed end surface, the insertion guide portion or The screw cutter cuts hard tissue so that the closed end is easily inserted into the tissue.

1A is a perspective view showing an electrode for a high frequency electrosurgical apparatus according to a first embodiment of the present invention;

Figure 1b is a perspective view showing the appearance of a hole is formed in the uncoated portion of the electrode for high-frequency electrosurgical surgery according to a first embodiment of the present invention,

2 is an exploded perspective view showing an electrode for a high-frequency electrosurgical apparatus according to a first embodiment of the present invention,

Figure 3 is a side cross-sectional view showing the electrode end of the high frequency electrosurgical apparatus according to the first embodiment of the present invention,

4A and 4B are an enlarged perspective view and a cross-sectional view of an electrode end of a high frequency electrosurgical apparatus according to a first embodiment of the present invention;

5A and 5B are an enlarged perspective view and a cross-sectional view of an electrode end of a high frequency electrosurgical apparatus according to a second embodiment of the present invention;

Figure 6 is an enlarged perspective view of the electrode end of the high-frequency electrosurgical apparatus according to a third embodiment of the present invention.

<Explanation of symbols on main parts of the drawings>

10: hollow electrode 12: insulation coating

14: hole 20: closed end

30: insertion guide portion 32: groove portion

34: rib 40: refrigerant conduit

42: electricity supply line 44: supply piping

46: exhaust pipe 50: temperature sensor line

60: handle

Claims (6)

A closed end of an horn shape having a sharp point toward one end so as to be inserted into biological tissue, A hollow electrode having an outer surface insulated and coated except for a predetermined length of a portion connected to the closed end in a hollow tube shape extending in the longitudinal direction from the other end of the closed end; It has a diameter smaller than the inner diameter of the hollow electrode is inserted into the hollow electrode, the refrigerant is supplied into the hollow electrode to cool the part of the hollow electrode in contact with the closed end and the biological tissue, and the heat exchanged refrigerant is supplied to the hollow A refrigerant conduit discharged through the space between the electrode and the living body; High frequency electrosurgical electrode, characterized in that formed in the protruding or recessed surface of the closed end portion is made of an insertion guide for cutting the biological tissue so that the closed end is smoothly inserted into the biological tissue. The method of claim 1, The insertion guide portion is a high frequency electrosurgical electrode, characterized in that a plurality of grooves formed to be recessed in the longitudinal direction on the closed end surface. The method of claim 2, The insertion guide part is a high frequency electrode surgical electrode, characterized in that the plurality of ribs formed to protrude in the longitudinal direction on the closed end surface. The method of claim 3, wherein The insertion guide portion is a high-frequency electrode surgical electrode, characterized in that a plurality of grooves alternately formed with the rib. The method of claim 1, The insertion guide portion is a high-frequency electrode surgical electrode, characterized in that the screw cutter formed to spirally project around the closed end surface. The method of claim 5, The screw cutter is a high-frequency electrode surgical electrode, characterized in that formed to extend to the non-insulated portion of the hollow electrode.