KR102655015B1 - Thyroid radiofrequency ablation electrodes - Google Patents

Abstract

The present invention is a thyroid high-frequency cauterization electrode that can simultaneously secure safety and treatment efficiency by performing fine cauterization by adjusting the length of the energizing part in a rotating manner and rapid cauterization by adjusting the length of the energizing part in a sliding manner with a single electrode. It's about.

Description

Thyroid radiofrequency ablation electrodes {THYROID RADIOFREQUENCY ABLATION ELECTRODES}

The present invention relates to a thyroid high-frequency ablation electrode, and more specifically, to a thyroid high-frequency ablation electrode that allows fine and rapid control of the insulating sheath from a single electrode.

High-frequency treatment changes the polarity of the electrode hundreds of thousands of times per second, causing ions in the tissue around the electrode to repeatedly move back and forth around the electrode, generating its own frictional heat. This causes irreversible protein degeneration in all cells when the temperature exceeds 50 degrees. becomes extinct. Using this principle, high frequencies have been used to treat liver cancer since the late 1990s, and are now widely used to treat various diseases such as lung cancer, kidney cancer, bone cancer, and uterine fibroids. It began to treat thyroid tumors about 15 years ago and has become a standard treatment for benign tumors, and is also being attempted in the treatment of malignant tumors around the world.

In the case of other tumors such as liver cancer, lung cancer, kidney cancer, etc., an electrode is inserted into the center of the tumor while looking at ultrasound, and treatment is performed for 5 to 15 minutes while the electrode is held still and fixed until the tumor and approximately 5 mm around the tumor are cauterized. do. On the other hand, thyroid cancer is treated by shortening the length of the current-carrying part through which high-frequency waves are transmitted while looking at ultrasound, and instead moving the electrode frequently to cauterize. These small cauterized areas are gathered together and treated until the entire tumor is cauterized. The reason is that most other tumors are spherical, but thyroid tumors are thin and long, so if you insert an electrode in the center and wait for a long time, there is a side effect of cauterizing too much normal tissue, and it is very dangerous for nerves and structures around the thyroid gland. Therefore, the fixed ablation technique is a very dangerous technique. Therefore, the use of a moving-shot technique is standard.

However, when using a mobile cauterization method, the border area of the tumor must be cauterized more carefully, and the center of the tumor must be cauterized quickly with relatively high power for higher efficiency. Therefore, at the border of the tumor, the length of the current-carrying part of the electrode is short and the output is weak accordingly, and the treatment is performed delicately. At the center of the tumor, the length of the current-carrying part must be long and the output strong to complete the treatment quickly. In the early days when high-frequency thyroid therapy was introduced, fixed electrodes for the current-carrying section were used, but electrodes that can adjust the length of the current-carrying section were developed in response to the needs mentioned above, and their use is gradually increasing. In the case of variable electrodes, there are two main ways to adjust the length of the insulating part: by using a sliding knob or by turning the ring structure in the front of the electrode handle. The sliding method is quick to adjust the length, but it is difficult to finely adjust the length of the current-carrying part, and the rotating method is good for fine adjustment, but when the range of variation is large, it requires a longer time to turn the ring and move the insulating sheath. Therefore, both have their own advantages and disadvantages.

KR 1963621 KR 2323448

The present invention overcomes the disadvantages of the above-mentioned prior art and adopts only the advantages by providing safety that can perform fine cauterization by adjusting the length of the current-carrying part in a rotating manner and rapid cauterization by adjusting the length of the electric-carrying part in a sliding manner with a single electrode. The purpose is to provide a thyroid high-frequency ablation electrode that maximizes treatment efficiency.

In order to achieve the above object, according to an embodiment of the present invention, a body including an end portion where a high-frequency output cable can be connected to a cauterization electrode, an upper groove portion where a sliding variable portion is located, and a tip portion to which a rotary variable portion is coupled, the body A cauterizing electrode that is inside and a portion of which protrudes outward through the distal end of the body, a tube-shaped insulating sheath surrounding the electrode, and a form that surrounds a part of the insulating sheath, are fixed to the insulating sheath and an adhesive material. A method switching unit is connected to the control method switching unit in the form of a screw, and the exposure length of the electrode can be finely adjusted by turning the rotary handle to move the control method conversion unit toward the distal end and at the same time move the connected insulating sheath toward the distal end. The rotary variable part, the control method switching part, and the rotary variable part cannot be moved in a state of being combined, and when the control method switching part is completely separated from the rotary variable part, the insulating sheath fixed with adhesive material is moved to the distal end by pushing the sliding handle. It may be a thyroid high-frequency ablation electrode including a sliding variable part that can quickly adjust the exposure length of the electrode by moving it in one direction, and a high-frequency generator for applying power to the electrode.

According to another embodiment, the sliding variable part includes a handle part that protrudes from the surface of the body and can be pushed by the user in the direction of the distal end, a fixing part connected to the insulating sheath with an adhesive material, and the handle part and the fixing part. Unlike the fixing part, which includes a connection part that moves integrally and is located closer to the distal end than the control method switching part, the handle part is located on the side of the control method switching part and prevents the length of the body from becoming longer. It may be a working electrode.

According to another embodiment, the body may be a thyroid high-frequency ablation electrode whose length is 170 mm or less.

According to another embodiment, the ratio of the maximum length by which the rotary variable part can adjust the insulating sheath and the maximum length by which the sliding variable part can adjust the insulating sheath is 1:2 to 1:4, a thyroid high-frequency ablation electrode. It can be.

According to another embodiment, the rotary variable part includes a handle part connected to the longitudinal end of the body and a female thread part coupled to an adjustment method switching part inside the body, and the control method switching part is larger than the inner diameter of the female thread part of the rotary variable part. It includes a thick head and a male thread coupled to the female thread of the rotary variable portion, and in a state in which the male thread of the adjustment method switching portion and the female thread of the rotary variable portion are engaged and coupled, the sliding variable portion does not move, and the adjustment method switching portion When the coupling between the male screw portion and the female screw portion of the rotary variable portion is released and the control method switching portion is completely separated from the rotary variable portion, the sliding variable portion may be adjusted to be a thyroid high-frequency ablation electrode.

According to another embodiment, it may be a thyroid high-frequency ablation electrode that further includes a marker portion that can determine the degree of exposure of the electrode by checking the retraction distance of the insulating sheath adjusted through the rotary variable portion.

According to another embodiment, the length of the insulating sheath, which can be moved by turning the handle of the rotary variable part once, may be a thyroid high-frequency ablation electrode having a length of 1 mm to 3 mm.

The thyroid high-frequency cauterization electrode according to the present invention can perform fine cauterization by adjusting the length of the current-carrying section in a rotating manner and rapid cauterization by adjusting the length of the current-carrying section in a sliding manner with a single electrode, thereby maximizing safety and treatment efficiency. .

Figure 1 is a diagram for explaining the structure of a thyroid high-frequency ablation electrode according to an embodiment of the present invention.
Figure 2 is a diagram for explaining the control method switching unit of the thyroid high-frequency ablation electrode according to an embodiment of the present invention.
Figure 3 is a diagram for explaining the insulating sheath adjustment step of the thyroid high-frequency ablation electrode according to an embodiment of the present invention.

In order to fully understand the configuration and effects of the present invention, preferred embodiments of the present invention will be described with reference to the attached drawings. However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various forms and various changes can be made. However, the description of this embodiment is provided to ensure that the disclosure of the present invention is complete and to efficiently explain the scope of the invention to those skilled in the art to which the present invention pertains.

Referring to Figure 1, the thyroid high-frequency ablation electrode according to an embodiment of the present invention has a distal end (1a) where the high-frequency output cable can be connected to the ablation electrode, an upper groove portion (1b) where the sliding variable part (5) is located, and a rotary A body (1) including a tip portion (1c) to which the variable portion (4) is coupled, a cauterizing electrode (2) located inside the body (1) and partially protruding outward through the tip portion (1c) of the body, A tube-shaped insulating sheath (3) surrounding the electrode (2), a rotary variable part (4) that can finely adjust the insulating sheath (3), a sliding variable part (5) that can quickly adjust the insulating sheath (3), a rotary It includes an adjustment method switching unit (6) that prevents the sliding variable unit (5) from moving until the fine adjustment section of the variable unit (4) ends, and a high frequency generator for applying power to the electrode (2).

The end of the electrode (2) passing through the distal end (1c) of the body is sharp and used for cauterization, and the other side is connected to the high frequency generator and high frequency output cable.

The insulating sheath (3) is in the form of a tube, and the electrode (2) wrapped in the insulating sheath (3) is in an insulated state, so that the electrode (2) can be divided into a current-conducting part and an insulating part through the insulating sheath (3). The insulating sheath (3) can be moved in the longitudinal direction, and the length of the current-carrying part can be adjusted by moving the insulating sheath (3).

The sliding variable part 5 has a handle part 5a that protrudes into the groove part 1b of the body and can be moved by the user, and is fixed to the insulating sheath 3 inside the body 1, and the movement of the handle part 5a It includes a fixing part 5b that moves by a corresponding length and a connection part 5c connecting the handle part 5a and the fixing part 5b.

The sliding variable part handle part (5a) is located in contact with the side of the control method switching part (6), and the sliding variable part fixing part (5b) is located closer to the distal end of the body than the control method switching part (6) and the insulating sheath (3) ) and is connected with an adhesive material.

If the sliding variable part handle part (5a) is positioned in contact with the sliding variable part fixing part (5b), the distance from the rotary variable part handle part (4a) increases and the length of the body (1) becomes excessively long, allowing the user to use it with one hand. It is inconvenient to hold and work.

Therefore, the sliding variable part fixing part 5b is located closer to the distal part 1a of the body than the control switching part 6a in order to directly connect to the insulation sheath 3, but the sliding variable part handle 5a is located closer to the control switching part 5a. It is located in contact with the side of (6a) and has a connecting portion (5c) connecting the fixing portion (5b) and the handle (5a). The handle part (5a), the fixing part (5b), and the connecting part (5c) of the sliding variable part are manufactured as one piece.

The length of the body 1 is preferably 170 mm or less, more preferably 160 mm or less, and most preferably 150 mm or less. If the length of the body 1 is longer than necessary, it becomes inconvenient for the user to hold it with one hand and work.

The rotary variable portion includes a handle portion (4a) connected in a ring shape to the distal end (1c) of the body and a female thread portion (4b) coupled to the adjustment method switching portion (6b) inside the body (1). The rotary variable part 4 does not move in the longitudinal direction, and only the ring-shaped handle part 4a rotates.

Referring to Figure 2, the control method switching part 6 is a plastic screw in the form of a hollow tube, and the inside of the control method switching part 6 has an insulating sheath 3, and the insulating sheath 3 and the control method switching part (6) is fixed with adhesive material.

The adjustment method switching unit (6) has a head portion (6a) thicker than the inner diameter of the rotary variable portion female thread portion (4b), a male thread portion (6b) coupled to the rotary variable portion female thread portion (4b), and a rotary variable portion (4). It includes a marker portion (6c) that can determine how much it has rotated, that is, the degree of adjustment of the insulating sheath (3).

Adjustment method When the male screw part (6b) of the switching part and the female screw part (4b) of the rotary variable part are engaged and coupled, the sliding variable part (5) does not move, and the coupling of the male screw part (6b) and the female screw part (4b) is released. When the male thread portion 6b is completely separated from the female thread portion 4b, adjustment of the sliding variable portion 5 becomes possible.

The control method switch marker part (6c) is thin and long and passes through the inside of the rotary variable part handle part (4a) when the control method switch male thread part (6b) and the rotary variable part female screw part (4b) are engaged and coupled. Therefore, part of it is exposed to the outside. Referring to Figure 1, a band-shaped pattern is inserted at regular intervals on the exposed portion to enable the user to determine how much the rotary variable part 4 has rotated, that is, the degree of adjustment of the insulating sheath 3.

When the connection between the male screw part of the control method switching unit (6b) and the female screw part of the rotary variable part (4b) is completely released and the fine adjustment step is completed, the exposed portion of the marker part of the control method switching part (6c) is all exposed to the rotary variable part handle ( It moves to the inside of 4a) and becomes invisible from the outside.

When the rotary variable handle part 4a is turned clockwise, the engagement between the male screw part 6b of the adjustable rotary part and the female screw part 4b of the rotary variable part is disengaged, and the control switching part 6 moves backward. The control type switch (6) and the insulating sheath (3) fixed with adhesive material also move backward. As the insulating sheath (3) moves backward, the exposed portion of the electrode (2), that is, the length of the conductive portion, becomes longer. The direction in which the rotary variable handle (4a) is turned can be changed.

By moving the rotary variable handle part (4a) one turn, the length of the energizing part can be finely adjusted to the user's desired length. The length of the insulating sheath (3), which can be moved by turning the rotary variable handle portion (4a) once, is preferably 1 mm to 3 mm.

Figure 3 is a diagram illustrating a process of adjusting the length of the current-carrying portion by moving the insulating sheath 3 of the thyroid high-frequency ablation electrode according to an embodiment. In stage 1, the initial stage before adjusting the length of the current-carrying part, the length of the current-carrying part is the minimum length. The female threaded portion of the rotary variable portion (4b) and the male threaded portion of the adjustable switching portion (6b) are fully engaged, and at this time, the sliding variable portion (5) cannot move.

The sliding variable part fixing part 5b and the control type switching part 6 are respectively fixed with an insulating sheath 3 and an adhesive material. That is, the sliding variable part 5, the control type change part 6, and the insulation sheath 3 move in the same direction and the same length at the same time, and the control type change part male thread part 6b is connected to the rotary variable part female thread part 4b. If it is combined with and cannot move, the sliding variable part (5) and the insulating sheath (3) also cannot move.

In the first stage, the maximum value that can be exposed to the outside is exposed to the control method switch marker portion 6c.

In step 2, which is the fine adjustment step of the rotary variable part 4, the insulating sheath 3 can be finely moved by rotating the rotary variable part handle part 4a. When the rotary variable handle part (4a) is rotated clockwise, the rotary variable part female screw part (4b) connected to the rotary variable part handle part (4a) also rotates in the same direction, and at the same time, the adjustment method switch male screw part (6b) ) is gradually released. As the connection between the female screw part of the rotary variable part (4b) and the male screw part of the control method switching part (6b) is loosened, the control switching part (6) moves in the direction of the distal end (1a) of the body, and the fixed insulating sheath (3) also moves. It moves toward the distal end (1a) of the body. As the entire control method switching part (6) moves in the direction of the distal end (1a) of the body, the exposed portion of the control method switching part marker part (6c) also moves inward to the rotary variable handle part (4a) and is exposed to the outside. part is reduced. The degree to which the insulating sheath (3) has moved can be easily identified through patterns displayed at regular intervals.

The insulating sheath (3) cannot be adjusted by moving the sliding variable portion handle (4a) until the connection between the rotary variable portion female thread portion (4b) and the adjustment type switch portion male thread portion (6b) is completely loosened.

In step 2, the user can accurately determine the length of the adjusted energizing part. Since the initial length of the energizing part is known and the length of the energizing part adjusted when the rotary variable handle part (4a) is moved one turn, the user can adjust it to the desired length. On the other hand, the length of movement of the sliding variable handle portion 5a at one time varies depending on the user, and it is difficult to accurately determine the adjusted length of the energizing portion.

Therefore, if the sliding variable portion handle portion 5a can be moved in step 2, the advantage of being able to finely adjust the length of the current-carrying portion to the desired length disappears.

In step 3, which is the quick adjustment step of the sliding variable portion 5, the insulating sheath 3 can be quickly moved by pushing the sliding variable portion handle portion 5a toward the distal end 1a of the body. At this time, the adjustment method switching unit male screw part 6b is completely disconnected from the rotary variable part female screw part 4b and is completely separated from the rotary variable part female screw part 4b. When the sliding variable part handle part 5a is pushed in the direction of the distal end 1a of the body, the sliding variable part fixing part 5b connected as one also moves in the direction of the distal part 1a of the body, and the sliding variable part fixing part 5b is moved. The fixed insulating sheath (3) also moves toward the distal end (1a) of the body.

Although it is difficult to finely adjust the insulating sheath (3) to the desired length of the sliding variable parts (5a, 5b), it is possible to quickly adjust the length of the current-carrying part to the maximum length with one movement.

In step 3, the exposed portion of the control type switch marker portion 6c is not visible from the outside because it has been moved inside the rotary variable handle portion 4a.

The ratio of the maximum length by which the rotary variable parts (4a, 4b) can adjust the insulating sheath (3) and the maximum length by which the sliding variable parts (5a, 5b) can adjust the insulating sheath (3) is 1:2~1: It is 4.

In the case of other tumors during high-frequency treatment, an electrode is inserted into the center of the tumor while looking at ultrasound, and the electrode is cauterized while remaining stationary and stationary until the tumor and approximately 5 mm around the tumor are cauterized. On the other hand, thyroid tumors have a thin, long, spherical shape, so if you insert an electrode in the center and wait for a long time, there is a side effect of cauterizing too much normal tissue, and there are very dangerous nerves and tissues around the thyroid gland, so it is standard to use a mobile cauterization method. am.

When using mobile cauterization, the border of the tumor must be cauterized more carefully, and it is more efficient to cauterize the center of the tumor quickly with relatively high power.

In one embodiment, the length to which the electrode 2 is initially exposed in the first step, that is, the length of the conductive portion, is 3 mm, and the length of the conductive portion adjusted by the rotary variable portion 4 in the second step is 3 mm to 7 mm, The length of the current-carrying part adjusted by the sliding variable part 5 in step 3 is 7 mm to 16 mm.

After carefully cauterizing the border area of the thyroid tumor while finely adjusting the length of the current-carrying section between 3 mm and 7 mm using the rotary variable section (4), the length of the current-carrying section is adjusted to 7 mm to 16 mm using the sliding variable section (5). The center of the thyroid tumor is quickly cauterized by quickly adjusting the distance between the two.

The reason why 7mm is used as the boundary between the two control methods is because the tumor border area is usually cauterized with fine control from 3mm to 7mm, and when the center of the tumor is cauterized quickly by increasing the output, the energizing area is usually 10mm or more. When the rotary variable handle part (4a) is turned clockwise, the insulation sheath (3) moves backward by 2 mm.

However, one embodiment only explains one recommended embodiment and does not limit the length of the current carrying part.

Using the electrode of the present invention has the advantage of maximizing safety and treatment efficiency by allowing both fine cauterization and rapid cauterization to be achieved with one electrode.

1: body
1a: Body (end)
1b: Body (groove)
1c: Body (tip)
2: electrode
3: Insulation sheath
4: Rotary variable part
4a: Rotary variable part (handle part)
4b: Rotary variable part (female thread part)
5: sliding variable part
5a: Sliding variable part (handle part)
5b: Sliding variable part (fixed part)
5c: Sliding variable part (connection part)
6: Control method switching unit
6a: Control method switching part (head part)
6b: Control method switching part (male thread part)
6c: Control method switching section (marker section)

Claims (7)

A body including an end portion where the high-frequency output cable can be connected to the cauterization electrode, an upper groove portion where the sliding variable portion is located, and a front end portion where the rotary variable portion is coupled;
a cautery electrode located inside the body and a portion of which protrudes outward through the distal end of the body;
A tube-shaped insulating sheath surrounding the electrode;
It includes a head part thicker than the inner diameter of the rotary variable part, a male screw part coupled to the rotary variable part in a screw shape, and a marker part that can determine the degree of exposure of the electrode, and has a shape that surrounds a part of the insulating sheath, and the insulating sheath and An adjustment method switch fixed with adhesive material;
A rotary variable part that is coupled to the male screw portion of the control method switching unit and can finely adjust the exposure length of the electrode by turning the rotary knob to move the control method switching unit toward the distal end and simultaneously moving the connected insulating sheath toward the distal end;
It cannot be moved when the control method switching unit and the rotary variable part are combined, and when the control method switching unit is completely separated from the rotary variable part, the insulating sheath fixed with adhesive material is moved toward the distal end by pushing the sliding handle. A sliding variable portion that can quickly adjust the exposure length of the electrode; and
Includes a high-frequency generator for applying power to the electrode;
The marker part is exposed to the outside when the rotary variable part and the control method switching part are engaged and coupled, and when the coupling is completely released, it moves inside the rotary variable part and becomes invisible from the outside, so the applied control method is determined by whether or not the marker part is exposed. A high-frequency ablation electrode for the thyroid gland that can be checked.
According to clause 1,
The sliding variable part includes a handle part that protrudes from the surface of the body and can be pushed by the user in the direction of the distal end, a fixing part connected to the insulating sheath with an adhesive material, and a connection part that moves the handle part and the fixing part as one body. However, unlike the fixing part located closer to the distal end than the control method switching part, the handle part is located on the side of the control method switching part to prevent the length of the body from becoming longer.
According to clause 1,
A thyroid high-frequency ablation electrode whose body length is 170 mm or less.
According to clause 1,
A thyroid high-frequency ablation electrode wherein the ratio of the maximum length by which the rotary variable part can adjust the insulating sheath and the maximum length by which the sliding variable part can adjust the insulating sheath is 1:2 to 1:4.
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