KR20120061340A - Electrode needle device for high frequency ablation - Google Patents

Abstract

PURPOSE: An electrode device for high frequency thermotherapy is provided to directly measure the temperature of a human body by locating a temperature sensor in a portion to be measured. CONSTITUTION: An electrode device for high frequency thermotherapy comprises an operation part(180) which is installed in a grip body to regulate the protruding length of a temperature sensor(161). An operating stand(181) is installed in the operation part and moved up and down. An end of a sensor line(162) is fixed to the operating stand for regulation of the temperature sensor connected to the other end thereof. The scale interval of the operating stand is predetermined with the sensor line protruded. The operation part regulates the protruding length of two or more temperature sensors at the same time.

Description

Electrode device for high frequency thermal therapy {ELECTRODE NEEDLE DEVICE FOR HIGH FREQUENCY ABLATION}

The present invention relates to an electrode device for high frequency thermal therapy that is cauterized and necrotic by heating a lesion site such as cancer tissue formed in a human or animal body organ at high frequency, and precisely measuring the temperature of the cauterized part to perform a precise procedure. The present invention relates to an electrode device for high frequency thermal therapy.

In general, when cancer tissues occur in body organs such as the liver, they are treated by surgical or non-surgical methods.

This surgical operation is mainly to remove the body of the lesion site, so the area is very large, leaving a large scar, there was a problem such as needing a lot of care period.

In addition, when cancer tissues, etc. in the body organs recur, the re-operation must be performed, there is a disadvantage, as well as economic burden, risks to the patient.

Because of this, non-surgical methods such as Transarterial chemoembolization (TACE), Percutaneous Ethanol Injection (PEI), Systemic chemotherapy, Partial heat treatment, local thermotherapy, etc. are known, but localized local therapy is most effective.

Local thermal therapy includes radiofrequency ablation (including microwave ablation) and laser ablation, among which radiofrequency ablation is most effectively used.

The high frequency heat treatment is a method of treating cancer tissues by necrotic necrosis by high frequency heat without causing ablation when cancer tissues occur in body organs such as liver.

The electrode device 10 for high frequency thermal therapy is an electrode line for supplying a high frequency to the electrode needle 20 on the gripping body 11 to which the electrode needle 20 is assembled as shown in FIG. 1. 12) and a cooling line 13 for circulating and supplying the coolant are connected.

In addition, the electrode needle 20 is provided at a position away from the tip of the electrode needle 20 and the conductive portion 22 electrically connected to the electrode line 12, the conductive portion 22 and the body tissue It is comprised including the insulating part 21 which insulates between. The conducting portion 22 may be formed of an electrically conductive hollow tube formed long in the longitudinal direction, and the insulating portion 21 may be formed by coating an insulator such as Teflon on the electrically conductive hollow tube.

Then, when the high frequency is supplied to the electrode needle 20 by the high frequency generator, the high frequency is supplied to the conducting portion 22, so that the temperature of the lesion site around the conducting portion 22 is increased. It will raise the temperature of 22). When the temperature of the energizing part 22 rises, carbonization phenomenon occurs in which lesions are pressed onto the surface of the energizing part 22. In this case, the carbonized part functions as an insulator, and thus the performance of the high frequency heat treatment is significantly reduced. .

Therefore, as shown as an example in FIG. 2, in order to cool the electrode needle 20, a cooling tube 23 connected to the cooling line 13 is installed in the electrode needle 20. The cooling pipe 23 may be used in various forms, but the coolant supplied from the cooling line 13 passes through the flow path space inside the cooling pipe 23 to form the cooling pipe 23 and the conductive part 22. It may be configured to circulate through the process of discharge through the space between the hollow tube.

In addition, a temperature sensor 24 connected to the sensor line 25 to measure the temperature of the electrode needle 20 is installed inside the electrode needle 20. The output of the high frequency applied to the electrode needle 20 is controlled through the temperature detected by the temperature sensor 24.

1 and 2, the electrode device 10 for high frequency thermal therapy selects and assembles an electrode needle 20 of an appropriate size according to the size of the lesion part of a body organ, and the high frequency generator is formed on the electrode line 12. (Not shown), a cooling liquid pump (not shown) is connected to the cooling line 13 to circulate the cooling liquid into the electrode needle 20. In addition, another electrode of the high frequency generator is connected to the pad 15 to prepare for contact with the body 1.

In this state, the electrode needle 20 of the electrode device is inserted into the lesion site 2 such as cancer tissue through the skin, and then a high frequency generator is supplied with high frequency to the electrode needle 20 to supply the high voltage. The lesion site around the conducting portion 22 except for the portion where the insulation portion 21 is formed by supplying a high frequency wave is attenuated by nebulization by high frequency heat.

However, in the conventional high frequency thermal treatment electrode device 10, since the temperature sensor 24 is installed inside the electrode needle 20 where cooling is performed, the temperature sensor 24 measures the temperature of the coolant inside the electrode needle 20. Will be measured.

That is, since the temperature sensor 24 does not directly measure the temperature of the lesion site, there is a problem in that the output of high frequency cannot be properly adjusted according to the temperature of the lesion site.

In particular, when major body tissues (physical organs) such as gallbladders, which should not be damaged around the lesions, are located, they may be cauterized and damaged due to cauterization of the lesions.

In order to prevent this, the output of high frequency should be lowered so as not to damage the main body tissues, but in this case, cauterization of the lesion site may not be sufficient or may take a long time.

On the other hand, as shown in Figure 3 (a) the electrode needle 30 of the other form provided with a conductive part 32 made of a plurality of wires in the electrode needle body 31 in order to simultaneously cauterize a large lesion site A structure has been proposed.

Although the electrode needle 30 can cauterize a wide lesion at the same time through a plurality of wire-shaped conducting portions 32 that emerge from the tip of the electrode needle body 31, the electrode needle 30, in particular cauterization Since the conduction portion 32 is not cooled in contact with the lesion site, there is a problem in that carbonization phenomenon occurs in which the cauterized body tissue is pressed onto the surface of the conduction portion 32. As described above, when carbonization occurs in the energizing portion 32, carbides formed on the surface of the energizing portion 32 function as an insulator, and thermal treatment efficiency is extremely reduced.

Therefore, even if the high frequency output from the electrode needle 30 is increased, the temperature rise of the lesion site does not occur and the cauterization is insufficient.

In this case, as shown in FIG. 3 (a), even when the temperature sensor 33 is installed at the end of the power supply unit 32, the temperature sensor 33 is prevented due to carbonization and temperature rise of the power supply unit 32. There is a problem that the temperature of the cauterization site cannot be measured accurately.

Furthermore, as shown in FIG. 3 (b), the temperature sensor 33 connected to the sensor lines 33a and 33b is positioned at the tip of the energization part 32 so that the body tissues immediately adjacent to the energization part 32 are located. Only temperature is measured. That is, when cauterization is performed through the current collector 32, the temperature of the body tissue changes according to the distance from the current collector 32, but in the case of the electrode needle 30 illustrated in FIG. Since 33) is located only at the tip of the energizing part 32, there is a problem in that the temperature of the part of the body tissue spaced a certain distance from the energizing part 32 cannot be measured.

In particular, since the temperature sensor 33 is installed at the tip of the energizing portion 32, it is impossible to measure the temperature state of the main body organs in which damage should not occur. That is, there is a problem in that the temperature measurement around the body organs to be protected from cauterization cannot be performed in the state where cauterization of the lesion is performed.

In addition, in the case of the electrode needle 30 shown in FIG. 3 (a), the plurality of current collectors 32 protrude from the front end of the electrode needle body 31 at once or return to the front side, thus being fixed to the front end of the current collector 32. The protruding length of the temperature sensor 33 can not be individually adjusted, and thus, it is difficult to perform precise cauterization.

The present invention is to solve at least some of the above problems, and to provide a high-frequency heat treatment electrode device that can directly measure the temperature of the body tissue to be cauterized while preventing the occurrence of carbonization in the energized portion For the purpose of

In addition, an object of the present invention is to provide an electrode device for high-frequency heat therapy that can accurately measure the temperature of the cautery site or body tissue at various distances from the electrode needle can be precisely performed.

In addition, an object of the present invention is to provide an electrode device for high-frequency heat treatment that can measure the temperature of several cautery sites or body tissues at the same time.

As an aspect for achieving the above object, the present invention in the electrode device for high frequency thermal therapy to cauterize the lesion site using a radio frequency radiated after being inserted into the body tissue, the tube connected to the electrode line for supplying high frequency An electrode needle having an entirety and a cooling unit connected to a cooling line for supplying a cooling liquid; And a temperature sensor connected to a sensor line and protruding to the outside of the electrode needle through a through hole formed in the electrode needle, to prevent carbonization from occurring on the surface of the current collector by cooling the current collector. At the same time, the temperature sensor provides an electrode device for high frequency heat treatment, which directly measures the temperature of the body tissue in which cauterization is performed.

Preferably, the cooling unit may be configured to cool the electrode needle including a cooling tube installed inside the electrode needle to be connected to the cooling line.

Also preferably, the electrode needle may be configured to guide the movement of the temperature sensor through the sensor tube having an electrode needle body connected to the electrode line and a sensor tube in which the sensor line is installed to allow the temperature sensor to be moved. have.

In this case, the sensor tube is fixed to the outside of the electrode needle body, the temperature sensor may protrude out of the electrode needle through the through hole formed in the sensor tube. Alternatively, the sensor tube may be provided inside the electrode needle body, and the temperature sensor may be configured to protrude out of the electrode needle through the through holes formed in the electrode needle body and the sensor tube, respectively. In addition, the sensor tube is composed of a tube for connecting the two through holes formed in the electrode needle body with each other, the sensor line is inserted through the through hole formed on the upper side of the electrode needle body to the lower side of the electrode needle body It may be configured to protrude into the body tissue through the formed through hole.

In addition, the sensor line is preferably configured so that electrical connection with the electrode line is not made so that cauterization does not occur in a portion connected to the temperature sensor.

The electrode needle includes an electrode needle body connected to the electrode line, and a guide tube surrounding the electrode needle body, and around the guide tube, a drug flowing in a flow path space between the electrode needle body and the guide tube is a body. Drug supply holes to be supplied to the tissue may be formed. Through this, the cauterization efficiency can be increased by widening the conductive portion of the high frequency.

Preferably, the electrode device for high frequency heat treatment according to an aspect of the present invention further comprises an operation unit for adjusting the protruding length of the temperature sensor; Accurate temperature measurement can be configured.

In this case, the temperature sensor may be provided in plural, and the operation unit may be configured to individually adjust or simultaneously adjust the protruding lengths of the plurality of temperature sensors.

On the other hand, the sensor line is made of a tube having an elastic restoring force or made of a tube formed of a shape memory alloy can be configured to easily appear in the through hole.

In addition, the electrode needle may be provided with a plurality of through holes, and the through holes may function as a passage through which the temperature sensor enters or serves as a passage for supplying drugs to a portion where cauterization is performed.

In addition, the electrode device for high-frequency heat treatment according to an aspect of the present invention is connected to the drug supply unit, the drug supply pipe protruding to the outside of the electrode needle through the through hole; may further include.

Through the above configuration, the present invention, in one aspect, by preventing the carbonization phenomenon in the energized portion by cooling the energized portion and at the same time by placing the temperature sensor directly to the temperature measuring portion of the body tissue to be cauterized The effect of measuring the temperature directly can be obtained.

In addition, the present invention has an effect that the current supply portion of the electrode needle can be stably cooled by providing a cooling tube inside the electrode needle.

And, as an aspect of the present invention, by adjusting the protruding length of the temperature sensor through the operation portion, it is possible to accurately measure the temperature of the cautery site or body tissue at various distances from the electrode needle. In particular, when major body organs (eg, gallbladder, etc.) that are not to be damaged are located near the cautery part, the effect of stably performing the procedure without damaging the main body organs is possible by placing a temperature sensor on the main body organs. Can be obtained.

In addition, the present invention as one aspect, it is possible to measure the temperature of several cautery sites or body tissues at the same time through a plurality of temperature sensors can obtain the effect that the procedure can be performed while monitoring the temperature of several parts at the same time.

In another aspect, the present invention, the sensor line is not electrically connected to the electrode line can be cauterized in the sensor line to prevent the occurrence of carbonization in the sensor line, through which the temperature sensor connected to the sensor line The effect of accurate temperature measurement can be obtained.

In addition, according to the present invention, since the sensor line and the electrode line are formed as separate lines that are not electrically connected to each other, the cauterization can be effectively performed according to the procedure or condition by distinguishing the cauterized part from the part where the temperature is measured. It will work.

In addition, the present invention has an effect that the cauterization efficiency can be increased by increasing the conductive portion by supplying a drug such as saline to a portion where cauterization is made.

1 is a schematic view showing a conventional high-frequency heat treatment electrode device.
2 is a cross-sectional view showing an example of a conventional electrode needle.
Figure 3 is a schematic diagram showing an example of another conventional electrode needle, (a) is a schematic diagram of the electrode needle, (b) is a cross-sectional view showing the energizing portion and the temperature sensor.
Figure 4 is a schematic diagram showing an electrode device for high frequency heat treatment according to an embodiment of the present invention.
5 is a detailed view of the electrode needle portion in the electrode device for high-frequency heat treatment shown in Figure 4, (a) is an enlarged view of the electrode needle portion, (b) is a cross-sectional view taken along the line AA of (a).
6 (a) and 6 (b) are schematic diagrams showing an embodiment of a sensor line.
Figure 7 is a schematic diagram showing the operation portion and the electrode needle of the electrode device for high frequency heat treatment according to an embodiment of the present invention.
Figure 8 is a schematic diagram showing the operation portion and the electrode needle of the electrode device for high frequency heat treatment according to another embodiment of the present invention.
9 is a schematic diagram showing a state in which the energizing portion protrudes from FIG. 8.
10 is a schematic view showing an operation unit and an electrode needle according to another embodiment of the present invention.
11 is a schematic view showing an operation unit and an electrode needle according to another embodiment of the present invention.
12A is a longitudinal sectional view showing an electrode needle according to an embodiment of the present invention.
12B is a cross sectional view along line BB of FIG. 12A;
13 is a cross-sectional view showing an electrode needle according to another embodiment of the present invention.
14 is a cross-sectional view showing an electrode needle according to another embodiment of the present invention.
15A is a longitudinal sectional view showing an electrode needle according to still another embodiment of the present invention;
15B is a cross sectional view along line CC of FIG. 15A;

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

The present invention relates to an electrode device for high frequency thermal therapy that cauterizes a lesion site by using a radio frequency radiated after being inserted into body tissue.

First, referring to Figures 4 and 5 will be described with respect to the electrode device 100 for high frequency heat treatment according to an embodiment of the present invention.

As shown in Figure 4 and 5, the electrode device 100 for high frequency thermal therapy according to an embodiment of the present invention is the electrode needle 110 and the electrode needle 110 is assembled to one end of the gripping body 190 A) a temperature sensor 161 protruding to the outside.

The electrode needle 110 is provided at a position away from the tip of the electrode needle 110 and the conductive portion 123 is connected to the electrode line 210 for supplying a high frequency between the conductive portion 123 and the body tissue And a cooling unit connected to the cooling line 220 for circulating and supplying the coolant.

As shown in FIG. 5, the conducting unit 123 may be formed of an electrically conductive hollow tube formed to be elongated in the longitudinal direction, and the insulating unit 122 may be formed by coating an insulator such as Teflon on the electrically conductive hollow tube. have.

And, the cooling unit is configured to cool the electrode needle 110, including a cooling tube 130 installed inside the electrode needle 110 to be connected to the cooling line 220, as shown as an example in FIG. Can be. That is, a process in which the coolant supplied from the cooling line 220 is discharged through the space between the electrode needle body 120 forming the cooling tube 130 and the conducting unit 123 through the flow path space inside the cooling tube 130. Cooling through the circulation can be achieved through.

In addition, the electrode needle 110 may include an electrode needle body 120 connected to the electrode line 210, a sensor tube 150 installed to guide the temperature sensor 161 and the sensor line 162 connected thereto. have.

4 and 5, when the sensor tube 150 is installed outside the electrode needle body 120, the high frequency applied from the electrode line 210 is the tip of the electrode needle body 120 and the sensor tube It is preferable to be configured to propagate to the lesion site through the sensor tube 150 located on the outside through the electrode tip 155 of 150. To this end, the sensor tube 150 has a conductive portion 152 is formed in a portion adjacent to the electrode tip 155, the insulating portion 153 for insulation in the portion spaced a predetermined distance from the electrode tip 155 to be formed. Can be.

Meanwhile, as shown in FIG. 4, drugs such as water or saline (hereinafter, referred to herein as “drugs”) in the lesion area where cauterization is made are meant to include all liquids including water, saline and other chemical solutions. Three way valve 240 having a drug supply port 241 may be installed to increase the high frequency conductive range by supplying. The three-way valve 240 is used for drug supply, and the structure of the electrode needle 110 to which the drug is supplied will be described later with reference to FIGS. 15A and 15B.

The temperature sensor 161 is configured to protrude to the outside of the electrode needle 110 through a through hole 154 formed in the sensor tube 150 of the electrode needle 110.

For example, as illustrated in FIGS. 4 and 5, when the sensor tube 150 is installed outside the electrode needle body 120, the sensor line 162 and the temperature sensor 161 connected thereto are connected to the sensor tube ( It is accommodated in the space between the 150 and the electrode needle body 120, protrudes to the outside of the sensor tube 150 through the through-hole 154 formed in the sensor tube 150, the lesion site or temperature measurement that is cauterized The temperature of the body organs (tissues) required is measured.

At this time, the sensor line 162 may be made of a tube having an elastic restoring force or a tube formed of a shape memory alloy to facilitate entry and exit through the through hole 154. For example, as shown in FIG. 6, the sensor line 162 may be formed of a tube and may include a wire 162a connected to the temperature sensor 161 therein. At this time, as shown in Figure 6 (a) two wires 162a may be configured to be connected to one side and the other side of the temperature sensor 161, one wire as shown in Figure 6 (b) Directly connected to the temperature sensor 161 and the other one wire may be configured to be connected to the conductive tube. Such wires may be connected to various control-related devices (G) such as monitors.

In addition, the sensor line 162 may have a shape in which an end is bent toward the through hole 154 so as to allow a smooth penetration and exit of the through hole 154.

4, the sensor line 162 is exposed from the gripping body 190 and may be connected to a control related device such as a monitor. However, a variety of well-known structures may be used.

Meanwhile, in FIGS. 5A and 5B, two sensor lines 162 are provided in a space between the sensor tube 150 and the electrode needle body 120. Only one may be provided, or two or more may be provided. In addition, the through-hole 154 through which the temperature sensor 161 enters and exits may also be installed in several places along the longitudinal direction of the electrode needle 110 and / or at the same height.

In addition, by using the three-way valve 240 having a drug supply port 241, the drug can flow in the space between the sensor tube 150 and the electrode needle body 120, in this case, the drug is a through hole 154 ), It is leaked to the lesion site and the conductive site can be widened.

Examples of such drugs may include, but are not limited to, physiological saline.

As described above, the electrode device 100 for high frequency heat treatment according to the present invention prevents the carbonization phenomenon from occurring on the surface of the electrified portion 123 through the cooling of the energized portion 123. At the same time, by protruding the temperature sensor 161 to the outside of the electrode needle 110, it is possible to directly measure the temperature of the body tissue that is cauterized or the adjacent body organs (body tissue).

In particular, the cauterization is directly performed through the sensor line 162, so that the sensor line 162 is not electrically connected to the electrode line 210 in order to prevent carbonization from occurring in the sensor line 162. desirable. In this case, since carbonization does not occur due to cauterization in the sensor line 162, accurate temperature measurement is possible in the temperature sensor 161 connected to the end of the sensor line 162. In addition, since the sensor line 162 is configured to be independent of the energization unit 123, it is possible to obtain an advantage that precise treatment is possible by measuring the temperature of body tissue away from the energization unit 123 by a predetermined distance.

Next, with reference to FIGS. 4 and 7 to 11 will be described with respect to the operation unit 180 of the electrode device 100 for high frequency heat treatment according to an embodiment of the present invention.

The operation unit 180 is configured to adjust the protruding length of the temperature sensor 161. Such an operation unit 180 is preferably installed on the gripping body 190 as shown in FIG. 4 to facilitate adjustment, but the installation position thereof is not particularly limited.

In addition, the operating table (181) provided in the operation unit 180 is moved up and down while operating the operating line (162) to adjust the degree of protrusion of the temperature sensor 161 connected to one end of the sensor line 162 and the sensor line 162 ( The other end of the sensor line 162 is fixed to 181.

Moving the operation table 181 downward increases the protruding distance from the electrode needle 110. For example, when the operating table 181 is moved to the length where the scale "1" is located, the distance from which the temperature sensor 161 protrudes from the electrode needle 110 through the through hole 154 becomes "L1", and the scale When the operating table 181 is positioned at the positions "2" and "3", the protruding distance may be "L2" and L3 ", respectively. Scale intervals of the operating table 181 are protruding from the sensor line 162. It may be predetermined according to the time development shape, and as an example, the unit of the scale may be centimeter (cm).

And, as shown in Figure 7 may be provided with a plurality of the temperature sensor 161, in this case, the operation unit 180 may be configured to adjust the protruding length of the plurality of temperature sensors 161 at the same time.

In addition, as shown in Figures 8 and 9, the temperature sensor 161 may be installed in a plurality in the vertical direction to protrude toward the lesion site through the corresponding through hole 154. In this case, as in FIG. 7, the plurality of temperature sensors 161 may be adjusted at the same time, but each temperature sensor 161 is individually adjusted or the temperature sensors 161 at the same height are simultaneously adjusted. Can be.

Meanwhile, as shown in FIG. 10, a plurality of through holes 154 are formed in the sensor tube 150, so that some of the through holes 154 may be used as passages through which the temperature sensor 161 enters and exits, and a portion thereof. May be configured to be used as a passage for supplying a drug to a portion where cauterization takes place. At this time, as shown in FIG. 4, a drug supply pipe 165 connected to a drug supply unit (not shown), such as a three-way valve having a drug supply port 241, is installed, and cauterization is performed through the drug supply pipe 165. Drugs can be supplied to the part. As such, when the drug supply pipe 165 is used, the drug can be supplied to a part farther from the electrode needle 110, so that the high frequency conductive range can be greatly expanded.

In addition, unlike the structure of FIG. 10 using the drug supply pipe 165, the through hole 154 is supplied by directly supplying a drug to the space between the electrode needle body 120 and the guide tube 150 without the drug supply pipe 165. It is also possible to configure the drug to be supplied to the cauterized site.

And, as shown in Figure 11, it is also possible to be provided with a plurality of adjusters (181a, 181b) so as to adjust the protruding length of the plurality of temperature sensors 161, respectively. In this case, the protruding degree of each temperature sensor 161 can be separately adjusted according to the procedure.

Next, with reference to Figures 12 to 15 looks at the structure of the electrode needle 110 of various forms that can be used in the electrode device 100 for high frequency thermal therapy according to the present invention.

12A and 12B, the sensor tube 150 in which the sensor line 162 and the temperature sensor 161 are installed may be provided inside the electrode needle body 120. In this case, a cooling tube 130 for cooling the electrode needle 110 is installed in the electrode needle body 120, and the sensor tube 150 includes a flow path portion and a sensor line 162 through which the cooling liquid F1 flows. It will block the installed space. As such, when the sensor tube 150 is provided inside the electrode needle body 120, the through hole 124 formed in the electrode needle body 120 and the through hole 154 formed in the sensor tube 150 are provided. The temperature sensor 161 protrudes out of the electrode needle 110.

Unlike this, as illustrated in FIG. 13, the sensor tube 150 may be attached to the outside of the electrode needle body 120 in a fixed state. In this case, the sensor line 162 to which the temperature sensor 161 is connected may be a sensor. It passes in and out of the electrode needle 110 through the through hole 154 formed in the tube 150.

In addition, as shown in FIG. 14, the sensor tube 150 may be configured as a tube connecting two through holes 124 formed in the electrode needle body 120 to each other. In this case, the sensor line 162 is inserted through the through hole 124 formed on the upper side of the electrode needle body 120 and through the through hole 124 formed on the lower side of the electrode needle body 120. It may be configured to protrude inward.

In the case of having the structure of the sensor tube 150 shown in FIG. 14, the upper through hole 124 is formed at a position exposed to the outside of the body during the procedure, and the lower through hole is at a position adjacent to the energizing part 123. Can be formed. In the case of the electrode needle 110 having such a structure, the sensor line 162 is introduced into the sensor tube 150 through the upper through hole 124 from the outside of the body, regardless of before or during cauterization. Protruding into the body tissue through the through hole 124 of the temperature can be measured, so there is an advantage that can easily measure the temperature of the body tissue if necessary. In particular, a plurality of sensor tubes 150 as shown in Figure 14 can be installed along the longitudinal direction of the electrode needle body 120 or a plurality of radially installed at the same height, in this case the temperature measurement is required The sensor line 162 can be introduced into the corresponding sensor tube 150 can be obtained.

On the other hand, as shown in Figure 15a and 15b, the electrode needle 110 may be configured to supply the drug (F2) to the cauterization site in order to widen the conduction range of the high frequency to the portion where cauterization is made.

Specifically, the electrode needle 110 illustrated in FIGS. 15A and 15B includes an electrode needle body 120 connected to the electrode line 210, a guide tube 140 surrounding the electrode needle body 120, and a sensor line. It may be configured to include a sensor tube 150 is installed 162, the cooling tube 130 to form a coolant (F1) flow path for cooling the electrode needle 120 inside the electrode needle body 120 This is installed. At this time, the flow path space between the guide tube 140 and the electrode needle body 120 is connected to the drug supply unit (not shown), the drug flowing through the flow path space drug supply holes formed in the circumference of the guide tube 140 Through 144 is supplied to the part of the body tissue to be cauterized.

As described above, the electrode device 100 for high-frequency heat treatment according to an embodiment of the present invention is a portion of the electrode needle 110, in particular an energizing part, by cooling the electrode needle 110 connected to the electrode line 210. (123) Body tissues or adjacent body organs (body tissue) where cauterization occurs by protruding the temperature sensor 161 to the outside of the electrode needle 110 while preventing the occurrence of carbonization by pressing the site of the cauterized lesions. Because the temperature is measured directly, the reliability of the measured temperature is high and through this, a stable procedure is possible without damaging major organs (body tissues) that should not be damaged.

While the invention has been shown and described with respect to particular embodiments, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as set forth in the claims below. I want to make it clear.

100 ... Electrode for high frequency heat treatment 110 ... Electrode needle
120 ... Electrode needle body 122 ... Insulation
123 ... current carrying part 124 ... through hole
130 ... cooling tube 140 ... guiding tube
150 ... sensor tube 154 ... through-hole
161 ... temperature sensor 162 ... sensor line
165 ... drug supply line 180 ... control panel
190. Holding body 210. Electrode line
220 ... cooling line 240 ... three-way valve
241 ... Drug supply connector

Claims (13)

In the electrode device for high-frequency heat treatment to cauterize the lesion site using a radio frequency radiated after being inserted into the body tissue,
An electrode needle having an energization part connected to an electrode line for supplying high frequency, and a cooling part connected to a cooling line for supplying a coolant; And
A temperature sensor connected to a sensor line and protruding outside the electrode needle through a through hole formed in the electrode needle;
Including,
The electrode device for high frequency heat treatment, which prevents carbonization from occurring on the surface of the current carrying part by cooling the current carrying part and simultaneously measures the temperature of the body tissue where the temperature sensor is cauterized. The method of claim 1,
The cooling unit is an electrode device for high frequency heat treatment, characterized in that it comprises a cooling tube installed inside the electrode needle to be connected to the cooling line. The method of claim 1,
The electrode needle is an electrode device for high-frequency heat treatment, characterized in that it comprises an electrode needle body connected to the electrode line, and the sensor tube is installed so that the movement of the temperature sensor. The method of claim 3,
The sensor tube is fixed to the outside of the electrode needle body,
The temperature sensor is an electrode device for high frequency thermal therapy, characterized in that protruding to the outside of the electrode needle through the through hole formed in the sensor tube. The method of claim 3,
The sensor tube is provided inside the electrode needle body,
The temperature sensor is an electrode device for high-frequency heat treatment, characterized in that protruding to the outside of the electrode needle through the through hole formed in the electrode needle body and the sensor tube, respectively. The method of claim 3,
The sensor tube is composed of a tube connecting the two through-holes formed in the electrode needle body,
The sensor line is inserted through the through-hole formed in the upper side of the electrode needle body protrudes into the body tissue through the through-hole formed in the lower side of the electrode needle body, characterized in that the high-frequency heat treatment electrode device. The method of claim 1,
The sensor line is an electrode device for high frequency heat treatment, characterized in that the electrical connection is not made with the electrode line. The method of claim 1,
The electrode needle includes an electrode needle body connected to the electrode line, and a guide tube surrounding the electrode needle body,
Electrode device for high frequency heat treatment, characterized in that the drug supply hole for supplying the drug flowing through the flow path space between the electrode needle body and the guide tube body tissue is formed around the guide tube. The method of claim 1,
An operation unit for adjusting the protruding length of the temperature sensor;
Electrode device for high frequency heat treatment, characterized in that it further comprises. 10. The method of claim 9,
The temperature sensor is provided with a plurality,
The operation unit is a high-frequency heat treatment electrode device, characterized in that for controlling the length of the projection of the plurality of temperature sensors individually or simultaneously. The method of claim 1,
The sensor line is an electrode device for high-frequency heat treatment, characterized in that made of a tube having an elastic restoring force or a tube formed of a shape memory alloy. The method of claim 1,
The electrode needle is provided with a plurality of through holes,
The through-hole is an electrode device for high-frequency heat treatment, characterized in that the function as a passage for the temperature sensor enters or serves as a passage for supplying drugs to the portion where cauterization is made. The method of claim 12,
A drug supply pipe connected to the drug supply unit and protruding to the outside of the electrode needle through the through hole;
Electrode device for high frequency heat treatment, characterized in that it further comprises.

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