KR101645273B1 - Bipolar electrode for radiofrequency ablation - Google Patents

Abstract

The present invention relates to a bipolar electrode for high-frequency thermal treatment, and more particularly, to a bipolar electrode for high-frequency thermal treatment, which comprises a first and a second coupling grooves formed at predetermined intervals and formed in a threaded shape, An active electrode member wound around a plurality of circuits while being fitted into a first coupling groove of the cylindrical body and connected to one terminal of the high frequency generator, and a second coupling groove of the cylindrical body, And the passive electrode body connected to the other terminal of the blood vessel is easy to move to a lesion part of a blood vessel such as a lower limb varicose vein, thereby reducing the risk of heat damage to the surrounding tissues outside the lesion area during the procedure .

Description

A bipolar electrode for radiofrequency ablation

[0001] The present invention relates to a bipolar electrode for high frequency thermal therapy, and more particularly, it relates to a bipolar electrode for radiofrequency thermal therapy, which can easily move to a lesion site of a blood vessel such as a lower limb varicose vein and adjusts the electrode heat to reduce the risk of heat damage to surrounding tissues. To a bipolar electrode for high-frequency thermal treatment.

Generally, if cancerous tissue develops in the body organs (liver, thyroid, etc.), it is treated by surgical and non-surgical methods.

Recently, non - surgical methods are widely used compared with surgical methods such as carotid chemoembolization, percutaneous ethanol injection, systemic chemotherapy, and localized heat therapy. Local heat treatment is most effective.

Local heat therapy includes radiofrequency thermal therapy, microwave cautery, and laser cautery. Of these, heat therapy by radiofrequency is most effective.

Therefore, by heating the lesion site at high frequency using the electrode as in Patent Document 1, the lesion site such as cancer tissue is cauterized and necrosis, or the vein lesion site such as the lower limb vein is heated to damage the vein wall to induce fibrosis of the vein To remove swollen blood vessels.

However, doctors and patients can easily move the electrodes to lesion sites of blood vessels such as varicose veins, and require safer electrodes that reduce the risk of heat damage to nearby tissues due to high-frequency heat. to be.

Patent Document 1: Korean Patent Laid-Open No. 10-2013-0128926 (Published Nov. 27, 2013)

Accordingly, it is an object of the present invention to provide an electrode that can be easily moved to a lesion site even if a collision occurs on the inner wall of a blood vessel when moving to a lesion site of a blood vessel such as a lower limb varicose vein.

In addition, it is an object of the present invention to provide an electrode that adjusts the heat generation range of a high frequency so as to reduce the risk of thermal damage to the surrounding tissues outside the lesion site during the procedure.

In order to accomplish the above object, the present invention provides a cylindrical body having a cylindrical body having first and second coupling grooves formed at predetermined intervals and formed in a threaded shape on an outer circumferential surface of the cylindrical body, And a passive electrode body connected to the other terminal of the high frequency generator by being wound around a plurality of circuits while being fitted into the second coupling groove of the cylindrical body. Thereby providing a bipolar electrode.

In addition, the present invention is characterized in that the first and second coupling grooves are formed on the outer circumferential surface at predetermined intervals and are formed in a threaded shape, a cylindrical body in which a cooling circulation path for circulating the cooling water supplied from the cooling pipe is formed, And a passive electrode wound around a plurality of circuits while being connected to the other terminal of the high frequency generator while being inserted into the second coupling groove of the cylindrical body and connected to the other terminal of the high frequency generator, And a bipolar electrode for high frequency heat treatment.

Since the active electrode body and the passive electrode body on which the high-frequency heat is generated are fitted into the first and second coupling grooves formed in the outer peripheral surface of the cylindrical body, even if a collision with the inner wall of the blood vessel occurs, The electrode body is not separated from the first and second coupling grooves.

In addition, since the outer peripheral surface of the cylindrical body, in which the active electrode member and the passive electrode member are fitted into the first and second coupling grooves, is smooth, there is an effect that the inner wall of the blood vessel is not hooked when the lesion is moved.

In addition, since the first and second coupling grooves are elongated in the longitudinal direction of the outer circumferential surface of the cylindrical body, the active electrode assembly and the passive electrode assembly can be quickly fitted into the first and second coupling grooves.

In addition, since the cooling circulation path in which the cooling water is circulated is formed inside the cylindrical body, the heat of the high frequency generated in the active electrode body and the passive electrode body is cooled to control the exothermic range of the electrode, The risk of heat damage to the surrounding tissues is reduced.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing an apparatus including a bipolar electrode for high frequency thermal treatment according to first and second embodiments of the present invention;
2 and 3 are views showing a bipolar electrode for high frequency thermal treatment according to the first embodiment of the present invention,
4 and 5 are diagrams showing a bipolar electrode for high frequency thermal treatment according to a second embodiment of the present invention,
6 is a view illustrating an apparatus having a bipolar electrode for high frequency thermal treatment according to the third and fourth embodiments of the present invention,
7 to 9 are views showing a bipolar electrode for high frequency thermal treatment according to a third embodiment of the present invention
10 to 12 are views showing a bipolar electrode for high frequency thermal treatment according to a fourth embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

1, the electrode device for high frequency thermal treatment 100 to which the electrode 10 according to the first and second embodiments of the present invention is applied includes an electrode 10, a handle 20, an electrode line 30, , And a high frequency generator (50).

The handle 20 is disposed at the rear end of the electrode 10 as a portion to be gripped by a practitioner when the electrode 10 is intended to be used and the electrode line 30 is connected to the electrode 10 and the high- The high frequency generator 50 is a device for generating a high frequency alternating current and selectively connects the active electrode member 2 or the passive electrode member 3 of the electrode 10 to the positive electrode and the negative electrode terminal, Frequency alternating current is supplied to the high-frequency alternating current source 10.

As shown in FIGS. 2 and 3, the electrode 10 according to the first embodiment of the present invention has the first and second coupling grooves 1a and 1b spaced at predetermined intervals on the outer circumferential surface thereof, An active electrode member 2 wound around a plurality of circuits and connected to one terminal of the high frequency generator 50 while being fitted into the first coupling groove 1a of the cylindrical body 1, And a passive electrode body 3 which is fitted to the second coupling groove 1b of the cylindrical body 1 and is wound around a plurality of circuits and connected to the other terminal of the high frequency generator 50.

Here, the cylindrical body 1 has a circular shape at the tip so as to be easily inserted into a blood vessel such as a vein, and is connected to the end of the moving wire when applied to the catheter.

At this time, the cylindrical body 1 is made of an insulating material.

As shown in one side of the electrode 10, the first and second coupling grooves 1a and 1b are formed in the shape of a plate having a parallelogram shape in section and threaded along the outer peripheral surface of the cylindrical body 1 in a screw- And the active electrode member 2 and the passive electrode member 3 have a parallelogram shape in section so as to be easily fitted into the first and second coupling grooves 1a and 1b.

The active electrode member 2 and the passive electrode member 3 are wound on the first and second coupling grooves 1a and 1b in an inclined manner in the thread direction without protruding from the outer peripheral surface of the cylindrical body 1, .

That is, when the blood vessel lesion site such as lower limb varices is treated, the electrode 10 is prevented from being caught in the inner wall of the blood vessel such as the vein, and at the same time, Thereby preventing the passive electrode member 3 from being separated from the first and second coupling grooves 1a and 1b.

The active electrode unit 2 and the passive electrode unit 3 radiate the high frequency current generated by the high frequency generator 50 from the electrode 10 and the active electrode unit 2 is connected to the electrode line 30, The passive electrode body 3 is connected to the passive line 30b of the high frequency generator 50 through the passive line 30b of the electrode line 30 through the active line 30a of the high frequency generator 50, (Not shown). At this time, the active terminal 51 or the passive terminal 52 may be an anode or a cathode according to convenience.

Particularly, when the active electrode member 2 and the passive electrode member 3 are irradiated with high frequency energy while maintaining a predetermined gap therebetween, the pitch P (P) between the active electrode member 2 and the passive electrode member 3 The heat generating range is a rectangular cylindrical shape surrounding the cylindrical body 1 as shown in Fig.

As shown in FIGS. 4 and 5, the electrode 10 according to the second embodiment of the present invention has the first and second coupling grooves 1a and 1b formed at predetermined intervals and formed long in the longitudinal direction An active electrode member 2 fitted to the first coupling groove 1a of the cylindrical body 1 and connected to one terminal of the high frequency generator 50 and a cylindrical body 1 And a passive electrode body 3 fitted to the second coupling groove 1b of the high frequency generator 50 and connected to the other terminal of the high frequency generator 50.

Here, the cylindrical body 1 has a circular tip at its tip to facilitate insertion of blood vessels such as veins, and is connected to the end of the moving wire when applied to the catheter.

At this time, the cylindrical body 1 is made of an insulating material.

As shown in one side of the electrode 10, the first and second coupling grooves 1a and 1b are plate-shaped in the shape of a rectangle formed in a long length along the outer circumferential surface of the cylindrical body 1, The electrode body 2 and the passive electrode body 3 are formed in a rectangular shape so as to be easily fitted into the first and second coupling grooves 1a and 1b of the cylindrical body 1. [

At this time, as shown in the plane of the electrode 10, the first and second coupling grooves 1a and 1b are formed in a curved shape in a curved surface toward the outer side of the cylindrical body 1, (2) and the passive electrode member (3) are curved outward and inward toward the outer side.

The first engaging groove 1a is formed on the other side opposite to the one side of the outer circumferential surface of the cylindrical body 1 and the pair of second engaging grooves 1b are arranged in a direction orthogonal to the first engaging groove 1a, (1).

The active electrode assembly 2 and the passive electrode assembly 3 are fitted into the first and second coupling grooves 1a and 1b without protruding from the outer circumferential surface of the cylindrical body 1. [

That is, when the blood vessel lesion area such as the lower limb varicose veins is treated, the electrode 10 is prevented from being caught by the inner wall of the blood vessel such as the vein. At the same time, even if a collision occurs on the inner wall of the blood vessel, Thereby preventing the passive electrode member 3 from being separated from the first and second coupling grooves 1a and 1b.

In addition, since the active electrode member 2 and the passive electrode member 3 according to the second embodiment of the present invention are formed in a rectangular shape having curved outer and inner sides, The first and second coupling grooves 1a and 1b having a curved surface form the active electrode member 2 and the passive electrode member 3 which are threadedly engaged with the two coupling grooves 1a and 1b, It can be quickly fitted and fitted.

The active electrode unit 2 and the passive electrode unit 3 are connected to the active terminal 51 and the passive terminal 52 of the high frequency generator 50 in the same manner as in the first embodiment of the present invention. The active terminal 51 or the passive terminal 52 may be an anode or a cathode according to circumstances.

The active electrode member 2 and the passive electrode member 3 are spaced apart from each other by a pitch P between the active electrode member 2 and the passive electrode member 3 The heat generation range is a rectangular cylindrical shape surrounding the cylindrical body 1 as shown in Fig. 5, similarly to the first embodiment of the present invention.

6, an electrode device 100 for high frequency thermal treatment to which an electrode 10 according to the third and fourth embodiments of the present invention is applied includes an electrode 10, a handle 20, an electrode line 30, , A cooling pipe (40), and a high frequency generator (50).

The handle 20 is disposed at the rear end of the electrode 10 as a portion to be gripped by a practitioner when the electrode 10 is intended to be used and the electrode line 30 is connected to the electrode 10 and the high- And the cooling pipe 40 is connected to the handle 20 to supply and recover the cooling water to the electrode 10 and to circulate the cooling water. The high frequency generator 50 is a device for generating a high frequency AC and selectively supplies an active electrode member 2 or a passive electrode member 3 of the electrode 10 to the positive electrode and the negative electrode terminal to supply a high frequency AC to the electrode 10 .

7 to 9, the electrode 10 according to the third embodiment of the present invention has the first and second coupling grooves 1a and 1b formed on the outer circumferential surface at predetermined intervals and formed into a thread shape A cylindrical body 1 in which a cooling circulation path 1c in which cooling water supplied from a cooling pipe 40 is circulated is formed and a first connection groove 1a of the cylindrical body 1 is fitted, An active electrode member 2 wound around a high frequency generator 50 and connected to one terminal of the high frequency generator 50 and a second coupling groove 1b of the cylindrical body 1, And a passive electrode body 3 connected thereto.

Here, the cylindrical body 1 has a circular tip at its tip to facilitate insertion of blood vessels such as veins, and is connected to the end of the moving wire when applied to the catheter.

The cylindrical body 1 is made of an insulating material and the cooling circulation path 1c includes a cylindrical inflow path 1c 'into which the cooling water supplied from the cooling pipe 40 flows, And a cylindrical discharge passage 1c '' formed outside the discharge passage 1c 'for discharging the cooling water introduced from the inlet passage 1c' to the cooling pipe 40 '.

At this time, the discharge path 1c '' and the inflow path 1c 'are extended to the tip of the cylindrical body 1. Since the discharge path 1c' 'is longer than the inflow path 1c' The cooling water flowing into the inlet path 1c 'is moved from the tip end of the cylindrical body 1 to the rear end of the cylindrical body 1 through the discharge path 1c "and is recovered to the cooling pipe 40 again.

The active electrode member 2, the passive electrode member 3 and the first and second coupling grooves 1a and 1b are composed of the active electrode member 2, the passive electrode member 3 ) And the first and second coupling grooves 1a and 1b.

The active electrode member 2 and the passive electrode member 3 are wound on the first and second coupling grooves 1a and 1b in an inclined manner in the thread direction without protruding from the outer peripheral surface of the cylindrical body 1, .

That is, when the blood vessel lesion area such as the lower limb varicose veins is treated, the electrode 10 is prevented from being caught by the inner wall of the blood vessel such as the vein. At the same time, even if a collision occurs on the inner wall of the blood vessel, Thereby preventing the passive electrode member 3 from being separated from the first and second coupling grooves 1a and 1b.

The active electrode unit 2 and the passive electrode unit 3 radiate the high frequency current generated by the high frequency generator 50 from the electrode 10 and the active electrode unit 2 is connected to the electrode line 30, The passive electrode body 3 is connected to the active terminal 51 of the high frequency generator 50 via the passive line 30b of the electrode line 30 through the active line 30a of the high frequency generator 50, (51) and the passive terminal (52), respectively. At this time, the active terminal 51 or the passive terminal 52 may be an anode or a cathode according to convenience.

Particularly, when the active electrode member 2 and the passive electrode member 3 are irradiated with high frequency energy while maintaining a predetermined gap therebetween, the pitch P (P) between the active electrode member 2 and the passive electrode member 3 , The heat generation range is a rectangular cylindrical shape surrounding the cylindrical body 1 as shown in Fig.

9, the cooling water is circulated in the cooling circulation path 1c to cool the electrode 10 in which the high-frequency energy is radiated, so that the electrode 10 is finer than the first and second embodiments of the present invention, (10), and at the same time, it reduces the risk of heat damage to parts of the blood vessels, such as lower limb varices.

10 to 12, in the electrode 10 according to the fourth embodiment of the present invention, the first and second coupling grooves 1a and 1b are formed at predetermined intervals and formed long in the longitudinal direction A cylindrical body 1 in which a cooling circulation path 1c in which cooling water supplied from a cooling tube 40 is circulated is formed and a first coupling groove 1a of the cylindrical body 1 is fitted, A passive electrode body 50 which is fitted to the second coupling groove 1b of the cylindrical body 1 to be connected to the other terminal of the high frequency generator 50 and which is connected to one terminal of the generator 50; (3).

Here, the cylindrical body 1 has a circular tip at its tip to facilitate insertion of blood vessels such as veins, and is connected to the end of the moving wire when applied to the catheter.

The cylindrical body 1 is made of an insulating material and the cooling circulation path 1c includes a cylindrical inflow path 1c 'into which the cooling water supplied from the cooling pipe 40 flows, And a cylindrical discharge passage 1c '' formed outside the discharge passage 1c 'for discharging the cooling water introduced from the inlet passage 1c' to the cooling pipe 40 '.

At this time, the discharge path 1c '' and the inflow path 1c 'are extended to the tip of the cylindrical body 1. Since the discharge path 1c' 'is longer than the inflow path 1c' The cooling water flowing into the inlet passage 1c 'is moved from the tip of the cylindrical body 1 to the rear end of the cylindrical body 1 through the discharge passage 1c "and is recovered to the cooling pipe 40 again.

The active electrode member 2, the passive electrode member 3 and the first and second coupling grooves 1a and 1b correspond to the active electrode member 2 and the passive electrode member 3 according to the second embodiment of the present invention. ) And the first and second coupling grooves 1a and 1b.

The active electrode assembly 2 and the passive electrode assembly 3 are fitted into the first and second coupling grooves 1a and 1b without protruding from the outer circumferential surface of the cylindrical body 1. [

That is, when the blood vessel lesion area such as the lower limb varicose veins is treated, the electrode 10 is prevented from being caught by the inner wall of the blood vessel such as the vein. At the same time, even if a collision occurs on the inner wall of the blood vessel, Thereby preventing the passive electrode member 3 from being separated from the first and second coupling grooves 1a and 1b.

In addition, since the active electrode member 2 and the passive electrode member 3 according to the fourth embodiment of the present invention are formed in a rectangle having curved outer and inner sides, The first and second coupling grooves 1a and 1b having a curved surface form the active electrode member 2 and the passive electrode member 3 which are threadedly engaged with the two coupling grooves 1a and 1b, It can be quickly fitted and fitted.

The active electrode member 2 and the passive electrode member 3 are connected to the active terminal 51 and the passive terminal 52 of the high frequency generator 50 in the same manner as in the third embodiment of the present invention. The active terminal 51 or the passive terminal 52 may be an anode or a cathode according to circumstances.

The active electrode member 2 and the passive electrode member 3 are spaced apart from each other by a pitch P between the active electrode member 2 and the passive electrode member 3 , The heat generation range is a rectangular cylindrical shape surrounding the cylindrical body 1 as shown in Fig. 11 similarly to the third embodiment of the present invention.

12, as in the third embodiment of the present invention, the cooling water is circulated in the cooling circulation path 1c to cool the electrode 10 from which high-frequency energy is radiated, 1,2 The present invention can more finely control the exothermic range of the electrode 10 and reduce the risk of heat damage occurring at a non-lesion site of blood vessels such as varicose veins.

The operation and effect of the bipolar electrode 10 for high frequency thermal treatment of the present invention will be described as follows.

As shown in FIGS. 1 to 3, the electrode 10 according to the first embodiment of the present invention is inserted into a blood vessel together with the initiation of a blood vessel lesion site such as a varicose vein, And is placed at an accurate target position, that is, a lesion site, by a labeling means such as an X-ray marker.

At this time, the active electrode member 2 and the passive electrode member 3 are wound on the first and second coupling grooves 1a and 1b obliquely in the screw thread direction without protruding from the outer peripheral surface of the cylindrical body 1, The electrode 10 can be moved to the lesion area without being caught by the inner wall of the blood vessel such as the vein when the electrode 10 moves, because the outer circumferential surface of the electrode 1 is smoothly fitted.

In other words, since the electrode 10 is not caught on the inner wall of a blood vessel such as a vein, it can be quickly positioned in a lesion site without delay due to a hook.

In other words, even if the active electrode unit 2 and the passive electrode unit 3 collide with the inner wall of the blood vessel such as the vein, the phenomenon that the active electrode unit 2 and the passive electrode unit 3 are separated from the cylindrical body 1 is prevented, It is not necessary to replace the active electrode member 2 and the passive electrode member 3 at the same time.

Then, when the arrangement of the electrode 10 is confirmed, a high-frequency alternating current is radiated between the active electrode member 2 and the passive electrode member 3 by operating the high frequency generator 50. At this time, Frequency energy is radiated between the electrode body and the electrode body adjacent to each other at a pitch P between the electrode body 2 and the passive electrode body 3 so that a cylindrical high frequency energy radiation region is formed.

Thus, the temperature of the lesion tissue is elevated by the heat of the high-frequency energy, so that a vein lesion site such as a varicose vein can be treated.

As shown in FIGS. 1, 4 and 5, the electrode 10 according to the second embodiment of the present invention is disposed in a vein lesion region such as a lower limb varicose vein, as in the first embodiment of the present invention.

At this time, the active electrode member 2 and the passive electrode member 3 are formed in the same shape as that of the active electrode member 2 and the passive electrode member 3 according to the first embodiment of the present invention, Even if the electrode 10 collides with the inner wall of the blood vessel such as the vein when the electrode 10 moves, the electrode 10 can be prevented from colliding with the inner wall of the cylindrical body 1, 10) can be moved to the lesion site without being caught.

That is, the electrode 10 according to the second embodiment of the present invention is located at the lesion site as quickly as in the first embodiment of the present invention.

In other words, even if the active electrode unit 2 and the passive electrode unit 3 collide with the inner wall of the blood vessel such as the vein, the phenomenon that the active electrode unit 2 and the passive electrode unit 3 are separated from the cylindrical body 1 is prevented, It is not necessary to replace the active electrode member 2 and the passive electrode member 3 at the same time.

Thus, the temperature of the lesion tissue is elevated by the heat of the high-frequency energy, so that a vein lesion site such as a varicose vein can be treated.

Even if the active electrode member 2 and the passive electrode member 3 are separated from the cylindrical body 1 by collision with the inner wall of the blood vessel such as the vein, (1a) and (1b) so that the retry of the operation can be promptly performed.

6 to 9, the electrode 10 according to the third embodiment of the present invention is inserted into a blood vessel together with the start of a blood vessel lesion site such as a lower limb varicose vein, And is placed at an accurate target position, that is, a lesion site, by a labeling means such as an X-ray marker.

At this time, since the electrode 10 is not caught on the inner wall of a blood vessel such as a vein as in the other embodiments, it is located in a lesion area quickly and enables high-frequency energy to be radiated to a lesion site.

Then, when the arrangement of the electrode 10 is confirmed, a high-frequency alternating current is radiated between the active electrode member 2 and the passive electrode member 3 by operating the high frequency generator 50. At this time, Frequency energy is radiated between the electrode body and the electrode body adjacent to each other at a pitch P between the electrode body 2 and the passive electrode body 3 so that a cylindrical high frequency energy radiation region is formed.

9, the heat generation range of the electrode 10 is adjusted by circulating the cooling water to the cooling circulation path 1c to cool the electrode 10 radiating the high-frequency energy.

That is, by adjusting the high-frequency energy exothermic range of the electrode 10, it is possible to reduce the lesion site to a minimum thickness, that is, to reduce the risk of thermal damage to other adjacent tissues than the first and second embodiments of the present invention.

In addition, since the electrode 10 can quickly cool the active electrode member 2 and the passive electrode member 3 with the cooling water circulated in the cooling circulation path 1c, The time can be reduced, and at the same time, the patient's physical burden due to the long-term operation can be reduced.

In addition, since the cooling water circulated in the cooling circulation path 1c flows into the inflow passage 1c 'and moves from the tip of the cylindrical body 1 to the rear end of the cylindrical body 1 through the discharge passage 1c " The staying time in the cooling circulation path 1c becomes longer.

That is, the high-frequency energy heating range of the electrode 10 can be maintained steadily.

In addition, there is an effect that the time for changing the high-frequency energy heating range of the electrode 10 can be delayed due to the disadvantage of the supply of the cooling water, and at the same time, the working time is earned so that the cooling water can be supplied again.

6, 10 to 12, the electrode 10 according to the fourth embodiment of the present invention is disposed in a vein lesion area such as a lower limb varicose vein, as in the third embodiment of the present invention.

At this time, since the electrode 10 is not caught on the inner wall of a blood vessel such as a vein as in the other embodiments, it is located in a lesion area quickly and enables high-frequency energy to be radiated to a lesion site.

Then, when the arrangement of the electrode 10 is confirmed, a high-frequency alternating current is radiated between the active electrode member 2 and the passive electrode member 3 by operating the high frequency generator 50. At this time, Frequency energy is radiated between the electrode body and the electrode body adjacent to each other at a pitch P between the electrode body 2 and the passive electrode body 3 so that a cylindrical high frequency energy radiation region is formed.

At this time, as shown in FIG. 12, the heat generating range of the electrode 10 is adjusted by circulating cooling water in the cooling circulation path 1c so as to cool the electrode 10 radiating high-frequency energy.

That is, by adjusting the high-frequency energy exothermic range of the electrode 10, it is possible to reduce the lesion site to a minimum thickness, that is, to reduce the risk of thermal damage to other adjacent tissues than the first and second embodiments of the present invention.

In other words, since the electrode 10 can quickly cool the heat of the active electrode member 2 and the passive electrode member 3 with the cooling water circulated in the cooling circulation path 1c, And at the same time reduce the patient's physical burden due to long-term operation.

Even if the active electrode member 2 and the passive electrode member 3 are separated from the cylindrical body 1 by collision with the inner wall of the blood vessel such as the vein, (1a) and (1b) so that the retry of the operation can be promptly performed.

In addition, since the cooling water circulated in the cooling circulation path 1c flows into the inflow passage 1c 'and moves from the tip of the cylindrical body 1 to the rear end of the cylindrical body 1 through the discharge passage 1c " The staying time in the cooling circulation path 1c becomes longer.

That is, the high-frequency energy heating range of the electrode 10 can be maintained steadily.

In addition, there is an effect that the time for changing the high-frequency energy heating range of the electrode 10 can be delayed due to the disadvantage of the supply of the cooling water, and at the same time, the working time is earned so that the cooling water can be supplied again.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, Various changes and modifications may be made by those skilled in the art.

1: Cylindrical body 1a: First coupling groove
1b: second coupling groove 1c: cooling circulation path
2: active electrode body 3: passive electrode body
10: Bipolar electrode for high-frequency thermal therapy
20: Handle 30: Electrode line
40: Cooling tube 50: High frequency generator
100: Bipolar electrode device for high frequency thermal therapy

Claims (4)

A cylindrical body 1 in which first and second coupling grooves 1a and 1b are formed on the outer circumferential surface at a predetermined interval and formed in a threaded shape,
An active electrode member 2 which is inserted into the first coupling groove 1a of the cylindrical body 1 and is wound on a plurality of circuits to be connected to one terminal of the high frequency generator 50,
And a passive electrode body (3) fitted to the second coupling groove (1b) of the cylindrical body (1) and wound around a plurality of circuits to be connected to the other terminal of the high frequency generator (50) For bipolar electrodes. The method according to claim 1,
Wherein the first and second coupling grooves (1a, 1b) are elongated in the longitudinal direction of the cylindrical body (1). The first and second coupling grooves 1a and 1b are formed on the outer circumferential surface at predetermined intervals and are formed into a threaded shape and a cylindrical body 1b having a cooling circulation path 1c in which cooling water supplied from the cooling pipe 40 is circulated 1)
An active electrode member 2 which is inserted into the first coupling groove 1a of the cylindrical body 1 and is wound on a plurality of circuits to be connected to one terminal of the high frequency generator 50,
And a passive electrode body (3) fitted to the second coupling groove (1b) of the cylindrical body (1) and wound around a plurality of circuits to be connected to the other terminal of the high frequency generator (50) For bipolar electrodes. The method of claim 3,
Wherein the first and second coupling grooves (1a, 1b) are elongated in the longitudinal direction of the cylindrical body (1).

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