KR20090119529A - Electrode needle for high frequency thermotherapy treatment - Google Patents

Abstract

PURPOSE: A structure of an electrode needle for high frequency thermotherapy is provided, which cauterizes the lesion region while protecting an organ, blood vessel, nerve, thyroid and so on. CONSTITUTION: A structure of an electrode needle for high frequency thermotherapy comprises an electrode needle(6) which cauterizes the lesion region; a current portion(6a) formed in the electrode needle; and an insulator(6c) which partially covers one side of the outer circumference of the current portion. The insulator is used by selecting the insulator in which a coating is possible as the polymeric insulating material including Teflon and etc.

Description

Electrode needle for high frequency thermotherapy treatment

The present invention relates to an electrode needle used in the electrode device for high-frequency heat therapy to heat the lesion part of cancerous tissues and the like of the body organs at high frequency, and cauterize it, especially the blood vessels, thyroid, nerves around the lesion of the human organs. Electrode of high frequency thermal therapy electrode device to protect the organs of the back while cauterizing only the lesion site, and to prevent the cells or blood which is the cause of lesions such as cancer cells which come out after the procedure from being transferred to other healthy cells. It is about saliva structure.

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

Surgical surgery as described above has a problem such as leaving a scar mainly because the body of the lesion must be excised.

In addition, such non-surgical methods, for example, carotid artery embolization, percutaneous ethanol injection, systemic anticancer chemotherapy, local heat therapy, etc. are known, and local heat therapy is known to be most effective.

Such localized thermal therapy includes radiofrequency ablation, microwave ablation, and laser ablation. Among these, radiofrequency ablation is known to be most effective.

The high-frequency heat treatment method is a method of treating necrotic tissue by necrolysis only by the high-frequency heat of cancer tissues, etc., without incision when cancer tissues generated in the human body occur.

Applicant has been described in detail in the patent registration No. 10-0647094 for such a high-frequency heat treatment method.

That is, as shown in Figure 1, the high-frequency heat treatment apparatus is the electrode line for supplying a high frequency to the electrode needle 6 on the gripping body 5, the electrode needle 6 is assembled in the front ( 4) and a cooling line 3 for circulating and supplying cooling water are connected.

In addition, the electrode needle 6 generally forms a current-carrying portion 6a and an insulating portion 6b of the remaining portion at a portion of the tip.

Electrode device for high-frequency heat treatment of this configuration selects and assembles the electrode needle (6) of the appropriate size according to the size of the lesion site of the body organ, the electrode line (4), cooling line (3) to the high-frequency generator (not shown) To connect a coolant pump (not shown).

The electrode needle 6 of the electrode device in the state prepared as described above is penetrated through a lesion such as cancer tissue of a body organ, and then the electrode needle 6 is supplied with a high frequency to the electrode needle 6 by a high frequency generator. The lesion site is cauterized and necrotic by the high frequency heat generated by the energizing section 6a except for the insulating section 6b.

The conduction portion 6a of the electrode needle 6 having such a structure is supplied with high frequency from the entire outer circumferential surface to cauterize the lesion site, so as to insert the catheter in the center of the lesion site A, as shown in FIG. This is possible at high frequencies occurring in the entire outer circumferential surface of the energizing portion 6a.

By the way, in the case of such an electrode needle 6 has the advantage of cauterizing the entire 360-degree direction to the center of the current-carrying portion (6a) of the electrode needle 6, as shown in Fig. 3 attached to the lesion When organs, blood vessels, nerves, and the like that are unrelated to each other are in proximity, organs, blood vessels, nerves, etc., which are not related to the lesion, may be damaged by the conduction portion 6a of the electrode needle 6 described above.

The present invention has been made in order to solve the above problems, when there are organs, blood vessels, nerves, etc. around the lesion to be cauterized, the electrode for cauterizing the lesion site while protecting the organs, blood vessels, nerves, thyroid, etc. To provide a saliva.

The electrode needle of the present invention coats an insulator on a part of the outer circumferential surface of the current conducting portion of the electrode needle as described above so that high frequency is generated in only one direction so that only the lesion site located on either side can be cauterized. It was possible.

When the high frequency heat treatment is performed by the electrode needle of the present invention as described above, only the lesion site can be cauterized while protecting the organs, blood vessels, nerves, thyroid, etc., which are close to the lesion site, and after the cauterization, It is effective to prevent the lesion cells of the lesion area from being buried to be exposed by the cover even though they pass through the skin layer so that they do not spread to other cells or blood.

Hereinafter, the present invention will be described in detail.

As shown in FIG. 4, the electrode needle of the present invention is provided by partially covering the insulator 6c on one side of the outer circumferential surface of the energizing portion 6a formed in the electrode needle 6 for cauterizing the lesion site. do.

In the present invention, the insulator described above is used by selecting an insulator that can be covered with a polymer insulating material such as Teflon.

In the case of using the electrode needle 6 of the present invention, as shown in the accompanying drawings, Fig. 5, the high-frequency generation occurs only in one part of the direction in which the insulator 6c is not covered, that is, on one side of the energizing portion 6a. Since the high frequency is generated, the lesion part 11 located in the direction is cauterized by the high frequency heat, while in the part located in the insulator 6c, the high frequency is blocked by the insulator 6c, so that various organs, blood vessels, Nerves, thyroid gland 10, etc. will not be damaged by high frequency heat.

Therefore, the operator places the energizing part 6a of the electrode needle 6 toward the lesion part 11, generates a high frequency at the corresponding part, and performs the procedure of cauterizing the lesion part 11 as the heat and necroticing it. do.

The diameter of the electrode needle 6 of the present invention can be selected not only according to the size of the lesion site, but can also be selectively carried out with the size of the insulator 6c coated on the energizing section 6a.

In addition, the insulator 6c may be covered in the longitudinal direction of the electrode needle 6, and as shown in the accompanying FIG. 6, when there are organs or nerves in a position proximate to the inside of the lesion part 11. The insulator 6c may be covered only at a part of the depth of the energized portion 6a to be inserted, so that the lesion portion 11 may be cauterized while protecting the organ 10 of the corresponding portion.

Therefore, in the present invention, the insulator 6c is coated on any part of the outer circumferential surface of the energizing portion 6c so that a high frequency is generated only at any part of the outer circumferential surface of the energizing portion 6c, so that the lesion site 11 is cauterized by the heat. It is clear that it belongs to

On the other hand, the present invention can be implemented in the following method.

7A and 7B, a method of fixing the insulating plate 8 to one side of the energizing portion 6a formed in the electrode needle 6 for cauterizing the lesion area, such as micro welding or spot welding. The electrode needle fixed by this is provided.

The insulating plate 8 may use a flat plate, and as shown in FIG. 8, a curved insulating plate 9 configured to have a curved shape along the outer circumferential surface of the electrode needle 6 is used. You may do it.

The insulating plate 8 or the curved insulating plate 9 used in the present invention may use an insulating plate in which the metal itself is plated with a non-conductive metal plate or a non-conductive polymer compound. As shown in FIG. 9B, the metal plate 14 may be coated with a polymer insulating material 15 such as Teflon or the like.

In the present invention, as described above, the high frequency generated by the high frequency generator (not shown) is generated in the conduction portion 6a to generate heat, and in the direction in which the insulating plate 8 or the curved insulating plate 9 is located. High frequency is cut off and heat is not generated.

For this reason, as shown in FIG. 7 at the time of the procedure, when there are various organs, blood vessels, nerves, thyroid gland, etc., the procedure is performed by placing them behind the insulating plate 8 or the curved insulating plate 9 described above. While protecting the organs, the lesion site 11 is placed in front of the body, and the lesion site 11 is cauterized by the high frequency heat supplied through the energization section 6a.

Therefore, the operator places the conduction part 6a of the electrode needle 6 toward the lesion part 11 and performs the procedure of cauterizing the lesion part 11 as the heat by nebulization by the high frequency generated at the corresponding part and necroticing it. Do it.

The diameter of the electrode needle 6 of the present invention can be selected not only according to the size of the lesion portion, but also can be selectively performed by the size of the insulating plate 8 or the curved insulating plate 9 to be fixed by welding to the current-carrying portion 6a. have.

In addition, even if the insulating plate 8 or the curved insulating plate 9 is fixed to the current-carrying portion 6a of the electrode needle 6, as shown in FIG. 14 attached thereto, the position close to the inside of the lesion site 11 is shown. If there are organs or nerves, etc., it is possible to cauterize the lesion site 11 while protecting the organ 10 of the corresponding portion by fixing it only to a part of the depth of the energized portion 6a to be inserted.

Therefore, in the present invention, the insulating plate 8 or the curved insulating plate 9 is fixed to any part of the outer circumferential surface of the energizing portion 6a so that a high frequency is generated only at any part of the outer circumferential surface of the energizing portion 6a so that the lesion site 11 is caused by the heat. It is clear that the cauterization falls within the scope of the present invention.

In addition, in the present invention, the insulating plate 8 and the curved insulating plate 9 are formed in a flexible sheet and accommodated in a cover 12 which can accommodate them, as shown in FIGS. 11A and 11B. Can be used as

That is, since the insulating plate 8 or the curved insulating plate 9 is fixed to the conducting portion 6a of the electrode needle 6 separately, they are bent and inserted into the lesion site while being accommodated in the cover 12 to remove them. After the procedure is appropriately performed for the purpose, the procedure for removing the above-described insulating plate 8 or curved insulating plate 9 again with the cover 12 and removing them from the lesion site can be performed.

As described above, when the insulating plate 8 or the curved insulating plate 9 is received by the cover 12 and removed from the lesion site, the lesion site cells that may be buried in the insulating plate 8 or the curved insulating plate 9 are formed in the skin layer. By preventing exposure to the third site, it is possible to prevent the third metastasis by the cells at the lesion site.

In this case, as shown in FIGS. 12A and 12B to which the cover 12 is easily accommodated, the insulating plate 8 or the curved insulating plate 9 may be chamfered and tilted. By having the true tapered surface 13, it can be accommodated in the cover 12 easily.

In addition, if necessary, as shown in FIG. 13, the cover 12 is pushed to the end of the electrode needle 6, that is, the lowermost end where the energization part 6a is positioned to prevent the discharge. At the end of the electrode needle 6, that is, the end of the energizing portion 6a, the stepped portion 13 is formed like an arrowhead, and the cover 12 is caught by the stepped portion 13 so that the insulating plate ( 8) or the curved insulating plate 9 can be accommodated.

1 is a front configuration diagram showing one embodiment of an electrode device to which the present invention is applied.

2 is a reference diagram showing a state to cauterize the lesion site with a conventional electrode needle,

3 is a reference diagram showing a problem when cauterizing the lesion site with a conventional electrode needle.

4A is a front configuration diagram of an active needle according to the present invention.

Figure 4b is a cross-sectional configuration of the electrode needle according to the present invention.

Figure 5 is an exemplary view of the lesion site cauterization according to the present invention.

Figure 6 is an embodiment showing an example of the lesion site cauterization according to the present invention.

Figure 7a is a perspective view of the main portion extract of the electrode needle according to the present invention.

7B is a cross-sectional configuration diagram of an electrode needle according to the present invention.

8A and 8B are reference perspective views showing another embodiment of the electrode needle according to the present invention.

Figure 9a is a cross-sectional view of the main portion of the excerpt of Figure 5a.

9A and 9B illustrate another embodiment of the present invention.

10 is an exemplary view of the lesion site cauterization according to the present invention.

11A and 11B are perspective views of main parts excerpts showing another embodiment according to the present invention;

Fig. 13 shows another embodiment of the electrode needle.

14 is a reference diagram showing a state at the time of the procedure of the present invention.

<Explanation of symbols for main parts of drawing>

 Electrode Probe: 6 Current Consumption: 6a

 Insulation: 6b Insulator: 6c

 Curved insulating plate: 9 Cover: 12

Claims (10)

In the electrode needle 6 constituted by the high-frequency electrode device used as a thermal treatment method for cauterizing the necrotic lesions, the conductive part 6a and the insulating part 6b are provided. The structure of the electrode needle for high frequency heat treatment, characterized in that the high frequency is not supplied to a part of the insulator (6c) to cover the insulator (6c) partially on any one of the outer peripheral surface of the conduction portion (6a). The method according to claim 1, The insulator (6c) is a structure of the electrode needle for high frequency heat treatment, characterized in that the polymeric insulating material such as Teflon. In the electrode needle of the electrode device for high frequency heat treatment which cauterizes the lesion area by heat generated by high frequency, The electrode needle structure of the electrode device for high frequency heat treatment, characterized in that the insulating plate (8) is fixed to one side of the energizing portion (6a) formed in the electrode needle (6) such as micro welding or spot welding. The method according to claim 3, Electrode needle structure of the electrode device for high frequency heat treatment, characterized in that the insulating plate (8) is a flat plate. The method according to claim 3, Electrode needle structure of the electrode device for high frequency heat treatment, characterized in that the insulating plate (8) is a curved insulating plate (9) configured to have a curved shape along the outer peripheral surface of the electrode needle (6). The method according to claim 3 or 4, The electrode needle structure of the electrode device for high frequency thermal therapy, characterized in that the insulating plate (8) or the curved insulating plate (9) is made of a metal plate (14) and coated on the surface thereof with a polymer insulating material (15) such as Teflon. The method according to claim 3, Electrode needle structure of the electrode device for high frequency heat treatment, characterized in that the insulating plate (8) is fixed only to a part of the depth of the energizing portion (6a). In the electrode needle of the electrode device for high frequency heat treatment which cauterizes the lesion area by heat generated by high frequency, High frequency heat, characterized in that the insulating plate (8) or curved insulating plate (9) fixed to any one side of the conducting portion (6a) configured in the electrode needle (6) made of a thin plate to be accommodated in the cover (12) Electrode needle structure of therapeutic electrode device. The method according to claim 8, Electrode needle structure of the electrode device for high frequency heat treatment, characterized in that the inclined tapered surface (13) by chamfering both the upper end of the insulating plate (8) or the curved insulating plate (9). The method of claim 8, Electrode needle structure of the electrode device for high frequency heat treatment, characterized in that the stepped end 13 is configured as an arrowhead at the end of the electrode needle (6).

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