KR101054828B1 - Electrode device for high frequency thermal therapy - Google Patents

Abstract

The present invention is a high frequency heat treatment electrode device that the cooling efficiency is increased by a simple structure to be distributed through the recovery line after supplying the cooling water supplied through the cooling water cooling line to the plurality of electrode needles by the driving of one cooling water motor In more detail, in order to supply a high frequency to the electrode needle and a plurality of electrode consisting of a connection line for receiving a high frequency, cooling water to the electrode body is assembled to the electrode needle inserted into the lesion forward A line portion comprising an electrode line having a connector connected to the RF generator, a recovery line for recovering the cooling water supplied from one cooling line circulating and supplying the cooling water into the electrode needle, and the line portion and the electrode portion are connected to each other and the line portion is cooled The cooling water supplied through the line is connected to the inside of the electrode needle through the connection line of the plurality of electrode units. Characterized in that consisting of a distribution recovery unit for recovering through the recovery line after the distribution supply to; Distributing the cooling water supplied through one cooling supply line to a plurality of electrode needles has the effect of improving the cooling efficiency.

Electrode needle, high frequency, heat treatment, electrode line, cooling line, recovery line, distribution recovery part

Description

An electrode device for a high frequency treatment

The present invention relates to an electrode device for high-frequency heat treatment, and in particular, a simple structure for distributing and supplying the cooling water supplied through the cooling water cooling line to the plurality of electrode needles by driving one cooling water motor. The present invention relates to an electrode device for high frequency heat treatment in which cooling efficiency is increased.

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

As described above, the surgical operation is mainly to remove the body of the lesion site, so the area is very wide, leaving a large scar, there was a problem such as requiring a long period of care.

In addition, the surgical operation is a secondary operation when the cancerous tissues and the like in the reorganized body has a major disadvantage, as well as economic burden and risk to the patient.

In recent years, non-surgical methods such as carotid artery embolization, percutaneous ethanol injection, systemic anticancer chemotherapy, and topical heat therapy are known.

Such local thermal treatments include radiofrequency ablation, microwave ablation, laser ablation, and the like. In recent years, thermal ablation is most effectively used.

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

In the electrode device for high frequency thermal therapy, as shown in FIG. 1A, the electrode needle 6 is assembled in front of the gripping body 5, and the high frequency is supplied to the electrode needle 6 behind the gripping body 5. Electrode needles are melted by high frequency heat inside the electrode line 4 and electrode needle 6

The cooling line (3) for circulating the cooling water is guided to prevent it.

The electrode needle 6 usually forms a current-carrying portion 6a and an insulating portion 6b of the remaining portion at a portion of the tip.

Referring to the procedure using the conventional high-frequency thermal therapy electrode device, as shown in Figure 1b, select the electrode needle 6 of the appropriate size according to the size of the lesion site of the body organ, assembled, not shown RF The electrode line 4 is connected to the generator, and another electrode line of the RF generator is connected to the pad 2 to be in contact with the body.

In addition, a cooling water pump (not shown) is connected to the cooling line 3 to allow the cooling water to be circulated and supplied to the inside of the cooling needle 6.

In this manner, the electrode needle 6 of the electrode device in the prepared state is inserted through the lesion site 200 such as the cancer tissue of the body organ, and then a high frequency is supplied to the electrode needle 6 by the RF generator. High frequency is supplied to the energization part 6a except for the insulating part 6b of the electrode needle 6, and the lesion part 200 is cauterized and necrotic by high frequency heat.

As described above, when cauterization of the lesion site 200 is completed, the electrode needle 6 is separated from the body to complete the procedure.

However, the conventional high frequency thermal treatment electrode device as described above can be configured as a cooling water pump or a cooling line for cooling in the case of one electrode needle, but for cooling each electrode needle in the case of multiple electrode needles. Since the cooling water pump and the cooling line for supplying the cooling water must be configured separately, the structure is complicated and there is an inconvenience in operation.

In order to solve the problem as described above, after connecting several electrode needles 6 to one holding body (5) at the same time using a plurality of electrode needles (6) using one cooling water pump and cooling line (3) An electrode device configured to supply cooling water is proposed.

However, the conventional high-frequency thermal therapy electrode device can be used when the area of the lesion is small because several electrode needles are fixedly connected to the gripping body and the gap between the electrode needles cannot be adjusted. If the area is large and the lesion site is located scattered there was a problem that can not be applied.

That is, in the conventional high frequency thermal treatment electrode device as described above, when the lesion area is wide, the electrode needles are fixed so that high frequency heat cannot be distributed and irradiated over the wide area, and when the lesion area is interspersed. At the same time there is a problem that can not be performed.

Due to this, a simple structure that can circulate a plurality of electrode needles simultaneously while receiving the cooling water supplied by one cooling water pump using one cooling line increases the cooling efficiency and improves the operability of the device. There is an urgent need for a thermal treatment electrode device.

The present invention has been made in view of the problems of the prior art as described above to provide an electrode device for high frequency heat treatment that can improve the cooling efficiency by distributing the cooling water supplied through one cooling supply line to a plurality of electrode needles. The purpose is to.

Another object of the present invention is to simplify the structure by simultaneously supplying and recovering the cooling water through the distribution recovery unit.

In addition, another object of the present invention is to separate and combine the dispensing recovery portion into the first to third body, so that a single replacement is possible in the event of a failure, resulting in less management costs, and the distribution space for the distribution of cooling water and the number of times for recovery It is to ensure the stability of the product by preventing the mixing of the cooling water circulated in the space isolating structure.

In order to achieve the above object, the present invention consists of a plurality of electrode parts consisting of a connection line for supplying a high frequency and cooling water to the electrode body is inserted into the electrode needle to the front of the lesion portion to the high frequency heat through the electrode needle lesion site ( In the electrode device for high-frequency heat treatment to treat by nebulization by irradiation to 200), a plurality of electrode lines coupled to a connector connected to the RF generator to supply a high frequency to the electrode needle of the electrode unit is coupled, each of the electrodes A line part consisting of a recovery line for recovering the cooling water supplied from one cooling line for circulating and supplying the cooling water into the needle, and the line part and the electrode part are connected to face each other, and is formed by combining the first, second and third bodies, Cooling water supplied through the cooling line passes through the distribution space formed between the first body and the second body to each connection line. It is distributed and supplied to the inside of the electrode needle through a plurality of auxiliary cooling lines that are introduced into the electrode needle. Provided is an electrode device for high frequency heat treatment, characterized in that consisting of a distribution recovery portion collected in the recovery space is formed through the recovery line.

As described above, the present invention has the effect of improving the cooling efficiency by distributing the cooling water supplied through one cooling supply line to a plurality of electrode needles.

In addition, the supply and recovery of the cooling water are simultaneously performed through the distribution recovery unit to simplify the structure, thereby increasing the ease of design and manufacturing.

In addition, it is possible to separate and combine the dispensing recovery parts into the first to third bodies, so that a single replacement is possible in the event of a failure, resulting in less management cost, and circulating in a structure that separates the dispensing space for dispensing the cooling water and the recovery space for recovery. There is an effect of ensuring stability by preventing the mixing of the cooling water.

When described in detail on the basis of the accompanying drawings a preferred embodiment of the present invention as follows.

As shown in FIG. 3, the electrode device for high frequency heat treatment according to the present invention is a device for treating necrosis by inserting and irradiating high frequency heat to the lesion site 200. The electrode unit 10, the line unit 20, and the separation unit are separated. The electrode unit 100 is configured by the recovery unit 30.

As shown in FIG. 4, the electrode part 10 has a connection line 13 through which high frequency and cooling water are supplied to the electrode body 12 into which the electrode needle 11 inserted into the lesion part 200 is assembled forward. It consists of a large number.

At this time, the electrode needle 11 is inserted into the separate guide port 11c to the outside of the electrode needle 11 for the procedure so that the guide port 11c moves forward and backward from the guide tube 11d. The protruding length of the electrode needle 11 may be adjusted.

The electrode needle 11 is formed of a portion of the outer surface of the end of the conductive portion (11a) and the rest of the insulating portion (11b), the guide tube of the guide (11c) is inserted into the electrode needle 11 ( 11d) is formed by forming a part of the outer surface of the end portion as the conducting portion 11e and the remaining portion as the insulating portion 11f, and the electrode needle 11 and the guide 11c are separated from each other.

As shown in FIG. 3, the line part 20 has an inside in which a connector 21a is connected to an RF generator (not shown) to supply high frequency to the electrode needle 11 of the electrode part 10. The recovery line which recovers the cooling water circulated after being supplied from one cooling line 22 to which the electrode line 21 having the furnace temperature sensor 21b is incorporated is circulated and supplied with the cooling water into the electrode needle 11 ( 23).

Here, the electrode body 12 of the electrode unit 10 and the connector 21a of the line unit 20 are displayed in different colors so that they can be identified to adjust the radio frequency irradiation size according to the area and position of the lesion site. It is configured to.

That is, the electrode body 12 and the connector 21a of the electrode body 12 of the electrode part 10 and the connector 21a of the line part 20 are connected in the same line and are positioned on different lines in the same way. The electrode body 12 and the connector 21a are displayed in a different color.

The distribution recovery portion 30 is connected to the line portion 20 and the electrode portion 10 to face each other is formed by combining a plurality of bodies, the cooling water supplied through the cooling line 22 is formed between the body and the body After distributing and supplying the inside of the electrode needle 11 through a plurality of auxiliary cooling lines 32b inserted into the respective connection lines 13 through the distribution space 40 to circulate the inside of the electrode needle 11. Flow along the connection line 13 is collected in the recovery space 50 formed between the other body and the body is configured to be recovered through the recovery line (23).

As shown in FIGS. 5A, 5B, and 6, the distribution recovery unit 30 includes a first body 31, a second body 32, and a third body 33.

The first body 31 has a first coupling groove 31a formed at an upper portion thereof, and a supply line 22 at one side formed with a first sensor line hole 31b through which the electrode line 21 passes. The supply line hole 31c and the first recovery line hole 31d through which the lines 23 are respectively inserted are formed through the first coupling end 31e.

The first coupling groove 31a of the first body 31 has the same diameter as the first sensor line hole 31b, the supply line hole 31c, and the first recovery line hole 31d, and is located on the same line. An upper closing cap 31g having a hole (not shown) through which the temperature sensor 21b, the supply line 22, and the recovery line 23 penetrate is fitted into the first coupling groove 31a.

The second body 32 has a second coupling groove (32a) is formed in the upper portion so that the first coupling end (31e) of the first body 31 is fitted, the lower portion is located inside the electrode line (21) Second recovery line hole through which the recovery line 23 is inserted through one side of the second sensor line hole 32c to which the auxiliary cooling line 32b for supplying the cooling water is coupled while the temperature sensor 21b is inserted 32d is formed through the second coupling end 32e.

Here, the auxiliary cooling line 32b receives the cooling water supplied through the cooling line 22 between the first coupling end 31e of the first body 31 and the second coupling groove 32e of the second body 32. Are spaced apart to form a distribution space 40 for dispensing).

The third body 33 has a third coupling groove 33a formed at an upper portion thereof so that the second coupling end 32e of the second body 32 is fitted into the third body 33, and is located at the bottom of the electrode line 21 at the lower portion thereof. The third sensor line hole 33b, through which the connection line 13 into which the temperature sensor 21b and the auxiliary cooling line 32b are inserted, is formed through the third coupling end 33c.

In addition, a hole through which the connection line 13 passes through the same diameter as the third sensor line hole 33b and passes through the third defect end 33c of the third body 33 (not shown in the drawing). The formed lower closing cap 33e is fitted into the third coupling groove 33a.

At this time, between the second coupling end 32e of the second body 32 and the third coupling groove 33c of the third body 33, the cooling water supplied to the electrode needle 11 is circulated and then the connection line ( 13 is spaced apart and combined to form a recovery space 50 that is recovered through the recovery line 23 is moved to (23).

In addition, the outer circumferential surfaces of the first to third bodies 31 to 33 may include first to third sensor line holes 31b, 32c and 33b, supply line holes 31c, and first and second recovery line holes 31d and 32d. Coupling position indications 31f, 32f, and 33d are respectively formed to match the center of the.

The coupling position indications 31f, 32f, and 33d may include the first to third sensor line holes 31b, 32c, and 33b, the supply line hole 31c, when the first to third bodies 31 to 33 are coupled. The center of the first and second recovery line holes 31d and 32d is shifted or shifted to determine the coupling position in order to prevent distortion of the electrode line 21, the cooling line 22, and the recovery line 23. It is configured to be.

That is, the electrode line 21, the supply line 22, and the recovery line 23 may include the first sensor line hole 31b, the supply line hole 31c, and the first recovery line hole of the first body 31. 31d) are respectively penetrated through, whereby the supply line 22 is a distribution formed between the first coupling end 31e and the second coupling groove 32a of the first body 31 and the second body 32. The space 40 is exposed to the internal space.

In addition, the electrode line 21 and the recovery line 23 are coupled through the second sensor line hole 32c and the second recovery line hole 32d of the second body 32. At this time, the recovery line 23 ) Is exposed to the inner space of the recovery space 50 formed between the second coupling end 32e and the third coupling groove 33a of the second body 32 and the third body 33.

In addition, the electrode line 21 penetrates through the first, second and third sensor line holes 31b, 32d and 33b of the first to third bodies 31, 32 and 33, and the second to third bodies 32. Auxiliary cooling line 32b is penetrated through the second and third sensor line holes 32d and 33b of, 33 in a state in which the electrode line 21 is accommodated therein.

The auxiliary cooling line 32b is accommodated therein, and the connection line 13 of the electrode unit 10 is inserted into and coupled to the third sensor line hole 33b of the third body 33, and the auxiliary cooling line ( 32b) is inserted into the electrode needle 11 through the inside of the electrode body 12 of the electrode portion 10 along the connection line 13 so that the cooling water is supplied.

At this time, the inner diameter of the electrode needle 11 is formed larger than the outer diameter of the auxiliary cooling line 32b, the cooling water supplied from the auxiliary cooling line 32b by the space space generated between the electrode needle 11 It is configured to circulate inside.

As shown in FIG. 9, as another embodiment of the electrode device 100 according to the present invention, one electrode line 21 of the line part 20 branches into several parts after passing through the distribution recovery part 30. And may be configured to supply a current to the electrode needles 11 of the plurality of electrode units 10.

Referring to the procedure and operation using the electrode device of the present invention configured as described above are as follows.

As shown in FIG. 7 and FIG. 8, the electrode line 21 is connected to the RF generator not shown in the drawing, the cooling line 22 is connected to a cooling water pump (not shown), and the recovery line 23 is shown. ) Is connected to a storage tank (not shown) for storing the recovered coolant.

At this time, in order to improve the recovery efficiency of the cooling water recovered to the recovery line 23, the recovery line 23 may be connected to a cooling water recovery pump (not shown) and cooled to a constant temperature and resupply to the cooling line 22. You may.

Thereafter, the cooling water is circulated and supplied to the inside of the electrode needle 11, and the position of the lesion site 200 is checked to insert the guide tube 11d of the guide 11c together with the electrode needle 11 into the body. In stock, the electrode needle 11 protruding from the end of the guide tube 11c is inserted through the lesion site 200 such as cancer tissue.

Here, looking at the supply and recovery process of the cooling water, the cooling water is supplied through the cooling line 22 of the line part 20 by the operation of the cooling water pump to supply the first body 31 and the second body of the distribution recovery part 30. It is introduced into the distribution space 40 formed between the first coupling end 31e of the 32 and the second coupling groove 32a.

In this way, the coolant introduced into the distribution space 40 is distributed in three directions through the auxiliary cooling line 32b inserted into and coupled to the second sensor line hole 32c of the second body 32 to form the third body 33. It is supplied to the internal space of the electrode needle 11 through the interior of the connection line 13 coupled to the third sensor line hole (33b) of.

The coolant supplied to the electrode needle 11 moves along the inner space of the electrode needle 11 while reducing excessive heat generated by the influence of high frequency in the electrode needle 11 to move the second body ( 32 and the recovery space 50 formed between the second coupling end 32e and the third coupling groove 33a of the third body 33.

In this way, the circulated cooling water collected in the recovery space 50 is a recovery line coupled to the second recovery line hole 32d and the first recovery line hole 31d of the second body 32 and the first body 31. Through 23 it is discharged to the RF generator.

That is, a brief description of the circulation of the coolant is given to the coolant motor of the RF generator-> the supply line 22 inserted into the supply line hole 31c of the first body 31-> the distribution space 40-> the second. Auxiliary cooling line 32b coupled to the second sensor line hole 32c of the body 32 and the third sensor line hole 33b of the third body 33 and positioned inside the connection line 13-> Blowing out of the electrode needle 11-> moves to recover along the gap between the electrode needle 11 and the auxiliary cooling line 32b, and cooling-> sub-cooling line 32b after passing through the electrode needle 11 Move to the separation gap of the connection line 13 installed in the-> move to the separation gap with the auxiliary cooling line 32b installed in the third sensor line hole 33b of the third body 33-> recovery space ( 50)-> recovery line (23)-> RF generator coupled through second recovery line hole (32d) of second body (32) and first recovery line hole (31d) of first body (31) This is done through a sequence of recovery.

Thus, by using a coolant motor and a cooling line 22 in the RF generator, the coolant can be simultaneously supplied to and recovered from the electrode needles 11 of the plurality of electrode units 10, thereby simplifying the structure and reducing the manufacturing cost. will be.

When the high frequency is supplied to the electrode needle 11 by operating the RF generator in such a state, the high frequency is applied to the conduction portion 11a located at the end of the electrode needle 11 and at the end of the guide tube 11c behind it. Through the conductive portion 11e positioned at the end of the guide tube 11c passing through the insulated portion 11b of the protruding length, it is cauterized at the same time in two positions at high frequency heat.

Such, the electrode unit 10 of the present invention is suitable for the case where the lesion site 200 is located scattered in two places at a predetermined interval spaced apart, a plurality of electrodes when the area of the lesion site 200 is large The needle 11 may be inserted at the same time.

At this time, the electrode needle 11 positioned inside the guide tube 11d is insulated from an outer surface of the guide tube 11d surrounding the guide tube 11d so that the electrode needle 11 is not affected by the high frequency.

In this way, when the cauterization of the lesion site 200 is completed, the guide 11c maintains the state inserted into the body and separates only the electrode needle 11.

This is to leave the insertion hole of the electrode needle 11 to the lesion site 200. When the high frequency heat treatment is required in the lesion site 200 again according to the procedure after the first procedure, the electrode needle 11 is removed. Instead of being inserted into the body organs, the procedure is performed again by using the guide tube 11d of the guide tool 11c inserted into the lesion site 200.

Therefore, even when performing the re-treatment, it is possible to eliminate the pain or risk of newly inserting the electrode needle 11 into the body organ.

In another embodiment, the electrode device 100 is advantageous in that the area of the lesion site 200 is large and scattered in several places, and the number of procedures can be reduced and the procedure can be performed.

In the above, the present invention has been illustrated and described with reference to specific preferred embodiments, but the present invention is not limited to the above-described embodiments and is not limited to the spirit of the present invention. Various changes and modifications can be made by those who have

1A and 1B are a front view and a use state diagram showing a conventional electrode device;

2 is a front view showing a conventional electrode device according to another example,

3 is a perspective view of an electrode device for high frequency heat treatment according to the present invention;

4 is a detailed front view of the electrode unit;

5a and 5b is an exploded perspective view of the top, bottom perspective of the distribution recovery portion,

6 is an exploded perspective view illustrating a state in which an electrode portion and a line portion are coupled to a distribution recovery portion;

7 is a partial exploded perspective view illustrating a supply and recovery process of cooling water supplied through a cooling line;

8 is a state diagram of use of the electrode device for high frequency heat treatment according to the present invention.

<Description of Symbols for Main Parts of Drawings>

10 electrode part 11 electrode needle

11a: energization part 11b: insulation part

11c: guide 11d: guide

11e: energization part 11f: insulation part

12: electrode body 13: connection line

20: line portion 21: electrode line

21a: connector 22: cooling line

23: recovery line 30: distribution recovery unit

31: first body 31a: first coupling groove

31b: first sensor line hole 31c: supply line hole

31d: First recovery line hole 31e: First coupling end

31g: Upper finish cap 31f, 32f, 33d: Coupling position indication

32: second body 32a: second coupling hole

32b: auxiliary cooling line 32c: second sensor line hole

32d: second recovery line hole 32e: second coupling end

33: third body 33a: third coupling groove

33b: third sensor line hole 33c: third coupling end

40: distribution space 50: recovery space

100: electrode device 200: lesion area

Claims (5)

Electrode needle 11 is composed of a plurality of electrode portions (10) consisting of a connection line 13 for supplying a high frequency and cooling water to the electrode body 12 is assembled to the front electrode electrode 11 is inserted into the lesion area (200) In the high-frequency heat treatment electrode device for treating necrosis by irradiation to the lesion site 200 through the), In order to supply a high frequency to the electrode needle 11 of the electrode portion 10, a plurality of electrode lines 21 coupled to the connector 21a connected to the RF generator is coupled, each inside the electrode needle 11 A line part 20 including a recovery line 23 for recovering the cooling water supplied from one cooling line 22 for circulating and supplying the cooling water to the furnace, The line part 20 and the electrode part 10 are connected to face each other, and the first, second and third bodies 31, 32, and 33 are formed to be coupled to each other, and the coolant supplied through the cooling line 22 is provided. Of the electrode needle 11 through a plurality of auxiliary cooling lines 32b inserted into respective connection lines 13 through a distribution space 40 formed between the first body 31 and the second body 32. Each of them is distributed and supplied inside to circulate the inside of the electrode needle 11, and then flows along the connection line 13 between the second body 32 and the third body 33 formed between the other body and the body. High frequency heat treatment electrode device, characterized in that consisting of the distribution recovery portion 30 is collected in the recovery space 50 is formed through the recovery line (23). The method according to claim 1, wherein the electrode body 12 of the electrode portion 10 and the connector 21a of the line portion 20 are displayed in different colors to adjust the radio frequency irradiation size according to the area and position of the lesion site. Electrode device for high-frequency heat treatment, characterized in that configured to be distinguishable. The dispensing recovery part 30 is supplied to one side of which the first coupling groove 31a is formed at an upper portion, and a first sensor line hole 31b is formed at the lower portion thereof, through which the electrode line 21 passes. A first body 31 having a supply line hole 31c through which the line 22 and the recovery line 23 are inserted, and a first recovery line hole 31d penetrating the first coupling end 31e; Secondary cooling grooves 32a are formed at an upper portion of the first coupling end 31e of the first body 31 so as to be coupled to each other, and an auxiliary cooling for supplying cooling water with the electrode line 21 inserted therein. A second recovery line hole 32d through which the recovery line 23 is inserted through one side of the second sensor line hole 32c to which the line 32b is coupled, is formed through the second coupling end 32e Body 32, A third coupling groove 33a is formed at an upper portion thereof so that the second coupling end 32e of the second body 32 is inserted therein, and an electrode line 21 and an auxiliary cooling line 32b are inserted into the lower portion thereof. High frequency heat treatment electrode device, characterized in that the third sensor line hole (33b) to which the connection line 13 is coupled is composed of a third body (33) formed through the third coupling end (33c). According to claim 3, It is supplied through the cooling line 22 between the first coupling end (31e) of the first body 31 and the second coupling groove (32a) of the second body (32) Spaced apart to form a distribution space 40 for distributing the cooling water to the auxiliary cooling line 32b, Between the second coupling end 32e of the second body 32 and the third coupling groove 33a of the third body 33, the cooling water supplied to the electrode needle 11 is circulated and then connected to the connection line. Electrode device for high-frequency heat treatment, characterized in that the spaced apart to be configured to form a recovery space 50 is drained through the (13) to move to the recovery line (23). According to claim 1, One electrode line 21 of the line portion 20 passes through the distribution recovery section 30 and then branched into several to the electrode needle 11 of the plurality of electrode portions 10 Electrode device for high frequency heat treatment, characterized in that configured to supply.

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