KR20230051909A - Catheter for treating spinal stenosis - Google Patents

Abstract

The present invention relates to a needle catheter for treating spinal stenosis, and more specifically, to a needle catheter for treating spinal stenosis, which enables a series of procedures such as tissue perforation, securing a passage to a lesion site, drug injection and the like to be performed continuously with a single catheter without replacing separate parts when invasive surgery to treat spinal stenosis is performed, to simplify a procedure and reduce a procedure time, and prevents damage and infection to surrounding tissues due to unnecessary operation of an instrument during the procedure to minimize side effects of the procedure, so that overall surgical satisfaction can be improved.

Description

Needle catheter for treating spinal stenosis

The present invention relates to a needle catheter for treating spinal stenosis, and more particularly, during an invasive procedure for treating spinal stenosis, a series of processes such as tissue perforation, passage to a lesion site, and drug injection are performed without replacing parts separately. By enabling continuous procedures with one catheter, it simplifies the procedure and shortens the procedure time, and improves the overall satisfaction of the procedure by minimizing the side effects of the procedure by preventing damage and infection of the surrounding tissues caused by the manipulation of unnecessary instruments during the procedure. It relates to a needle catheter for treating spinal stenosis.

Spinal stenosis treatment is a treatment to treat pain by using a so-called epidural catheter, approaching the end of the catheter to a spinal stenosis site and injecting a special drug through the catheter from the outside. This is a non-surgical treatment that removes inflammation and swelling around the spinal nerves or unnecessary scar tissue around the nerves.

In general, a catheter used for spinal stenosis treatment includes a thin flexible tube of about 30 cm to 60 cm, a main body fixed to the rear end of the flexible tube and having a flow path formed therein for guiding a drug solution supplied from a syringe to the flexible tube, It consists of a guide wire inserted into a flexible tube through the main body. The guide wire may be understood as a thin metal wire for reinforcing the rigidity of the flexible tube.

In order to treat spinal stenosis using a catheter of this structure, first, a needle is punctured in the affected area to secure a passage for the flexible tube to reach the target point, the needle is removed from the affected area, and then the flexible tube is inserted into the formed passage. .

At this time, since a guide wire is inserted into the flexible tube to give appropriate rigidity, entry to the affected area is facilitated, and when the flexible tube reaches the target point, the guide wire coupled to the flexible tube is removed, and the guide wire A syringe was attached to the main body from which the needle came out, and the drug solution was injected into the stenosis.

In other words, when performing spinal stenosis using a conventional catheter, several instruments had to be repeatedly replaced, so the procedure time was delayed for a long time and the procedure was very difficult. There was a problem of being exposed to side effects of the procedure due to concerns about damage and infection of surrounding tissues.

Republic of Korea Patent Publication No. 10-2018-0109574

The present invention was created to solve these problems in view of the above-mentioned problems in the prior art, and during the invasive procedure for the treatment of spinal stenosis, a series of processes such as tissue perforation, passage to the lesion site, and drug injection are replaced with separate parts. It simplifies the procedure and shortens the procedure time by enabling continuous procedures with one catheter without the need, and minimizes the side effects of the procedure by preventing damage and infection of the surrounding tissue due to the manipulation of unnecessary instruments during the procedure, thereby increasing overall satisfaction with the procedure. Its purpose is to provide a needle catheter for treatment of spinal stenosis that can be improved.

The present invention is a means for achieving the above object, a body portion including a tubular cylinder body and a needle coupled to one end of the tubular cylinder body; a piston body provided to be reciprocally movable inside the cylinder body; a flexible tube coupled to the piston body and extending into the needle; and a bending operation unit installed across the inside of the piston body and the flexible tube to bend one end of the flexible tube, wherein a fluid inlet port is branched on the other side of the piston body so that the piston body passes through the fluid inlet port. It is characterized in that the chemical solution is provided to be injected into the inside, and the chemical solution injected into the piston body flows out to the open end of the flexible tube via the inside of the flexible tube.

In addition, on the inner circumferential surface of the cylinder body, a plurality of first rotation guide grooves recessed along the circumferential direction are formed at equal intervals along the axial direction, and a plurality of first linear guide grooves recessed along the axial direction are formed along the circumferential direction. It is formed at an equal angle, and a first mounting hole is recessed on the outer circumferential surface of the piston body, a first elastic spring is installed on the first mounting hole, and the first rotation guide groove and the first linear guide groove are installed on the first elastic spring. It is characterized in that the first guide ball is coupled to the guide.

In addition, when the first guide ball is guided to one of the plurality of first rotation guide grooves, only rotational movement is allowed while the linear movement of the piston body is restricted, and the first guide ball is moved to one of the plurality of first linear guide grooves. When guided, it is characterized in that only linear movement is allowed in a state in which rotational movement of the piston body is restricted.

In addition, the bending operation unit, the cover is mounted on the other open end of the piston body and the operation hole is formed in the center; a lever rotatably installed in the operation hole; and a guide wire having one end fixed to one end of the flexible tube and the other end coupled to the lever, wherein a spirally recessed second rotation guide groove is formed on the inner wall surface of the operation hole and recessed along the axial direction. A plurality of second straight guide grooves are formed at an equal angle along the circumferential direction, a second mounting hole is formed in a depression on the outer circumferential surface of the lever, a second elastic spring is installed on the second mounting hole, and the second elastic spring has The second rotation guide groove and the second guide ball guided to the second linear guide groove are coupled, and when the second guide ball is spirally guided to the second rotation guide groove, the lever rotates and moves in a straight line at the same time, When the second guide ball is guided to one of the plurality of second linear guide grooves, only linear movement of the lever is allowed while rotational movement of the lever is restricted.

In addition, the bending operation unit further includes a swivel joint coupled between the other end of the guide wire and the lever and supporting the lever to idle in the guide wire, wherein the swivel joint is coupled to the other end of the guide wire and is centered. A first support plate in which a spline groove is recessed; a second support plate coupled to the lever and through which a first locking hole is formed in the center; and a thrust bearing interposed between the first support plate and the second support plate, wherein a second lock hole communicating with the first lock hole is formed at the center of the lever on the same line as the first lock hole, and the second lock hole communicates with the first lock hole. 2 A guide bar is formed inside the lock hole, a lock key is slidably coupled to the guide bar, and the lock key is discharged to the outside of the second lock hole and continuously passes through the first lock hole and the center of the thrust bearing to form a spline groove. It is characterized in that the rotational movement of the lever in place is limited when it is caught on.

The present invention simplifies the procedure by allowing a series of procedures, such as tissue perforation, passage to the lesion site, and drug injection, to be performed continuously with one catheter without replacing parts during invasive surgery for the treatment of spinal stenosis. Overall satisfaction with the procedure can be improved by shortening the procedure time and minimizing the side effects of the procedure by preventing damage and infection of the surrounding tissue due to the manipulation of unnecessary instruments during the procedure.

1 and 2 are views showing the appearance of a needle catheter for treating spinal stenosis according to the present invention.
Fig. 3 is a view showing a cross-sectional configuration of a cylinder body in the embodiment shown in Fig. 2;
Figure 4 is a view showing the overall cross-sectional configuration of the needle catheter for spinal stenosis treatment according to the embodiment shown in Figure 2;
5 is a view showing a cross-sectional configuration based on line AA shown in FIG. 4;
6 is a view showing a process in which the piston body is linearly moved;
7 is a view showing a process in which the piston body is rotated and moved;
8 is a view showing the appearance of a bending operation unit.
9 to 10 are views showing a cross-sectional configuration of a cover.
11 is a view showing a state in which one end of the flexible tube is bent by moving the lever to the other side.
12 is a view showing an exploded structure of the main part of the bending operation unit.
13 is a view showing a state in which a lock key is engaged and supported by a spline groove;
Fig. 14 is a view showing a cross-sectional configuration based on line AA shown in Fig. 13;

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the examples described in detail below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shapes of elements in the drawings may be exaggerated to emphasize a clearer description. It should be noted that in each drawing, the same members are sometimes indicated by the same reference numerals. Detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention are omitted.

The needle catheter for spinal stenosis treatment according to the present invention (hereinafter referred to as a catheter) performs a series of processes such as tissue perforation, passage to the lesion site, and drug injection during invasive surgery for the treatment of spinal stenosis without replacing parts separately. By enabling continuous procedures with one catheter, it simplifies the procedure and shortens the procedure time, and improves the overall satisfaction of the procedure by minimizing the side effects of the procedure by preventing damage and infection of the surrounding tissues caused by the manipulation of unnecessary instruments during the procedure. can make it

As a configuration for this purpose, the catheter according to the present invention is to include a body portion 100, a piston body 200, a flexible tube 300, and a bending operation portion 400, as shown in FIGS. 1 and 2 can be defined

First, the body portion 100 is composed of a tubular cylinder body 110 and a tubular needle 120 coupled to one end of the cylinder body 110.

The needle 120 has a sharp structure at one end so as to incise the skin tissue, and is made of a small-diameter tube made of a metal material considering that it is inserted into a deep location of the lesion site in the body.

Although not shown, one end of the needle 120 is bent at a certain angle to have a structure that allows the end to be more easily positioned at a target point when piercing the affected area.

The cylinder body 110 supports the needle 120 at one end and has an open structure at the other end, and is made in the form of a tube having a larger diameter than the needle 120, so that a piston body 200 to be described later is formed inside. it can work The inside of the cylinder body 110 and the needle 120 may communicate with each other.

As shown in FIG. 3, a plurality of first rotation guide grooves 111 recessed along the circumferential direction may be formed at equal intervals along the axial direction on the inner circumferential surface of the cylinder body 110.

That is, each of the first rotation guide grooves 111 may have a path in the form of a closed circle. The number or spacing between each of the first rotation guide grooves 111 is not particularly limited.

In addition, a plurality of first linear guide grooves 112 recessed along the axial direction may be formed at equal angles along the circumferential direction on the inner circumferential surface of the cylinder body 110 .

While the first rotation guide groove 111 has a path in the form of a closed circle, the first linear guide groove 112 may have a straight path that continuously penetrates each of the first rotation guide grooves 111 .

Accordingly, each of the first rotation guide groove 111 and the first linear guide groove 112 may be configured to be connected to each other in one channel, and the interval or number of the first linear guide groove 112 is particularly limited. Although not a bar, the accompanying drawings illustrate an embodiment in which two are formed with a phase difference of 180 degrees.

The first guide ball 240 of the piston body 200, which will be described later, may be guided to the first rotation guide groove 111 and the first linear guide groove 112.

Next, the piston body 200 is provided to be reciprocally movable inside the cylinder body 110 while supporting the flexible tube 300, and the operator can directly hold and operate the piston body 200.

That is, when the operator holds the piston body 200 exposed to the other end of the cylinder body 110 with his hand and moves it in the axial direction, the exposed length of the flexible tube 300 coupled to the piston body 200 can be adjusted. . At this time, the flexible tube 300 is coupled to the piston body 200 and has a structure extending into the needle 120, and is completely inserted into the needle 120 according to the axial movement of the piston body 200, or The open end of the needle 120 may be exposed.

Accordingly, the operator can finely position the flexible tube 300 at the lesion site by adjusting the position of the piston body 200 gripped by hand.

A fluid inlet port 210 is branched on the other side of the piston body 200 so that the chemical solution can be injected into the piston body 200 through the fluid inlet port 210 .

An injection device capable of injecting a separate chemical solution is connected to the fluid inlet port 210 so that the chemical solution can be supplied toward the inside of the piston body 200 at an appropriate pressure.

The drug solution injected into the piston body 200 flows out to the open end of the flexible tube 300 via the inside of the flexible tube 300, so that the drug solution can be delivered to the lesion site.

In some cases, a suction device may be connected to the fluid inlet port 210 to suction and discharge internal substances to the outside.

That is, the catheter according to the present invention has a structure in which the flexible tube 300 can be simultaneously inserted into the body while puncturing the body through the needle 120 during the procedure, and then, by operating the operator's piston body 200 When the position of the flexible tube 300 exposed to one end of the needle 120 is determined, the chemical solution can be directly injected through the injection device connected to the fluid inlet port 210 without removing the needle 120, Continuous treatment is possible without replacing parts.

On the other hand, the adjustment of the exposure length of the flexible tube 300 by the manipulation of the piston body 200 completely depends on the operator's hand sensation. If it is not operated properly, it is impossible to position one end of the flexible tube 300 at the exact lesion site.

In addition, when the position of the flexible tube 300 is determined, the position must be fixed in the body at least until the injection of the medicinal solution is completed. Random movement in the direction occurs so that the position of the flexible tube 300 is arbitrarily changed, preventing accurate injection of the drug into the lesion.

Thus, the catheter according to the present invention has a structure that allows the piston body 200 to be naturally guided without precise manual manipulation when operating the piston body 200, and also to fix the position at a specific position.

To this end, a first mounting hole 220 is recessed on the outer circumferential surface of the piston body 200, and a first elastic spring 230 is installed on the first mounting hole 220, and the first elastic spring 230 has It has a structure in which the first guide ball 240 guided by the first rotation guide groove 111 and the first linear guide groove 112 is coupled.

That is, the first guide ball 240 is guided in at least one of the first linear guide groove 112 and the first rotation guide groove 111, and thus, without precisely manipulating the piston body 200 by hand. , It is possible to make the piston body 200 move forward or forward.

At this time, when the first guide ball 240 is connected to the first linear guide groove 112, the piston body 200 accurately linearly moves along the path of the first linear guide groove 112, conversely, the first guide When the ball 240 is connected to the first rotation guide groove 111, the piston body 200 can accurately rotate along the path of the first rotation guide groove 111.

For example, when the first guide ball 240 is guided to one of the plurality of first linear guide grooves 112, as shown in FIG. 6, only linear movement of the piston body 200 is restricted while rotational movement is allowed. Therefore, only the exposure length can be adjusted without rotation of the flexible tube 300 .

In addition, when the first guide ball 240 is guided to one of the plurality of first rotation guide grooves 111, as shown in FIG. 7, only rotational movement of the piston body 200 is restricted while linear movement is allowed. Accordingly, the flexible tube 300 can be rotated in place without moving in the axial direction.

One end of the flexible tube 300 may be bent curvedly by the guide wire 430 of the bending operation unit 400 to be described later. At this time, the guide wire 430 is coupled to the piston body 200 to form a piston body ( 200), the bent flexible tube 300 is rotated in place so that one end of the bent flexible tube 300 can be moved in various directions.

In addition, when the first guide ball 240 is connected to the first rotation guide groove 111 in a state in which the approximate exposed length of the flexible tube 300 is determined, the piston body 200 is no longer restricted from moving in the axial direction. A structure is provided so that at least the change in the exposed length of the flexible tube 300 can be suppressed.

Accordingly, excessive insertion of the flexible tube 300 into the body can be prevented, and the position of the flexible tube 300 can be easily fixed until the injection of the drug is completed.

Next, the bending operation unit 400 is installed across the inside of the piston body 200 and the flexible tube 300 and serves to bend one end of the flexible tube 300 .

More specifically, the bending operation unit 400 may be largely illustrated as including a cover 410, a lever 420, a guide wire 430, and a swivel joint 440.

First, the cover 410 may be mounted on the other open end of the piston body 200 and may have an operating hole 411 formed in the center.

A lever 420, a swivel joint 440, and the like can be accommodated in the operation hole 411 and communicated with the inside of the piston body 200.

The lever 420 is installed in the operation hole 411 and serves to pull the guide wire 430 connected thereto in one or the other direction as it moves in one or the other direction.

The guide wire 430 is configured to impart rigidity to the flexible tube 300, and has a structure in which one end is fixed to one end of the flexible tube 300 and the other end is coupled to the lever 420.

Guide wire 430 may be made of a thin metal wire having a predetermined ductility.

At this time, one end of the guide wire 430 may be eccentrically fixed to an inner edge portion of one end of the flexible tube 300 .

Accordingly, when the guide wire 430 is pulled to the other side, one end of the flexible tube 300 is elastically deformed in the direction in which the guide wire 430 is pulled and is bent in an approximate arc shape as shown in FIG. can

Meanwhile, as shown in FIG. 9 , a spirally recessed second rotation guide groove 412 may be formed on an inner wall surface of the operation hole 411 . The second rotation guide groove 412 may be understood as a structure such as a known female screw.

In addition, a plurality of second straight guide grooves 413 recessed along the axial direction may be formed at equal angles along the circumferential direction on the inner wall surface of the operation hole 411 .

The second rotation guide groove 412 may have a spiral path, while the second linear guide groove 413 may have a linear path continuously penetrating the second rotation guide groove 412 .

Accordingly, the second rotation guide groove 412 and the second linear guide groove 413 may be connected to each other as one channel, and the second rotation guide groove 412 and the second linear guide groove 413 will be described later. The second guide ball 423 to be can be guided.

On the other hand, like the operation of the piston body 200 described above, the operation of the lever 420 also completely depends on the operator's hand sensation. There is a risk of being damaged by the end of the flexible tube 300 to be.

Therefore, the catheter according to the present invention enables precise traction operation of the lever 420, thereby enabling detailed bending of the flexible tube 300, and at the same time, bending of the flexible tube 300 is more difficult at parts of the body that do not require preciseness. It has a structure that allows it to be done quickly and intuitively.

To this end, a second mounting hole 421 is recessed on the outer circumferential surface of the lever 420, and a second elastic spring 422 is installed on the second mounting hole 421. It has a structure in which the second guide ball 423 guided by the second rotation guide groove 412 and the second linear guide groove 413 is coupled.

That is, the second guide ball 423 is guided in at least one of the second linear guide groove 413 and the second rotation guide groove 412, and at this time, the second guide ball 423 is the second linear guide. When connected to the groove 413, the lever 420 can accurately move in a straight line along the path of the second straight guide groove 413, and more quickly pull the lever 420 to the other side to bend the guide wire 430. Alternatively, the lever 420 can be pulled to one side to restore the bent guide wire 430 to its original straight state.

Conversely, when the second guide ball 423 is connected to the second rotation guide groove 412, the second guide ball 423 is moved in a spiral shape, so that the lever 420 must be rotated. It is possible to pull to one side or the other side, so that the guide wire 430 can be bent or unfolded more precisely.

For example, as shown in FIG. 11, when the second guide ball 423 is spirally guided in the second rotation guide groove 412, the lever 420 rotates and moves linearly at the same time, and the lever 420 is moved more precisely. It is possible to bend the guide wire 430 by a small amount by a traction operation.

In addition, when the second guide ball 423 is guided to one of the plurality of second linear guide grooves 413, only the linear movement of the lever 420 is allowed while the rotational movement of the lever 420 is restricted, so that the lever 420 is operated without any interference. It is possible to move quickly in one direction or the other direction, so that the guide wire 430 is equipped with a structure that allows it to be bent more intuitively.

In summary, when the second guide ball 423 is connected to the second rotation guide groove 412, the lever 420 is guided in the rotational direction, enabling precise bending of the flexible tube 300. Accordingly, when the second guide ball 423 is connected to the second linear guide groove 413, the lever 420 is quickly moved in a straight line without rotation of the lever 420, enabling rapid bending of the flexible tube 300. .

On the other hand, the rotation of the lever 420 is entirely a means for bending the guide wire 430, and if the guide wire 430 is bent, as the lever 420 rotates, the guide wire 430 rotates together. In this case, since the guide wire 430 may rotate independently of the rotation of the piston body 200, the flexible tube 300 is moved by the guide wire 430 relatively rotating inside the flexible tube 300. Twisting problem occurs.

Accordingly, in order to prevent unnecessary rotational movement of the guide wire 430, the swivel joint 440 is coupled between the other end of the guide wire 430 and the lever 420, and the lever 420 is idle in the guide wire 430. It has a structure to support it.

More specifically, as shown in FIG. 12, the swivel joint 440 is coupled to the other end of the guide wire 430 and includes a first support plate 441 in which a spline groove 441a is recessed in the center, and the lever 420. It is coupled to and includes a second support plate 442 through which a first locking hole 442a is formed in the center and a thrust bearing 443 interposed between the first support plate 441 and the second support plate 442. can be exemplified.

The first support plate 441 and the second support plate 442 are provided to be able to rotate relative to each other through the thrust bearing 443, and thus, coupled with the second support plate 442 with respect to the fixed guide wire 430 The lever 420 is configured to relatively rotate.

That is, even if the lever 420 in a state where the second guide ball 423 is connected to the second rotation guide groove 412 rotates, the guide wire 430 does not interlock with this rotation, and the piston body 200 ) According to the rotation of the piston body 200 until the overall rotation of the bending operation unit 400 coupled to the body 200, it is possible to maintain a fixed position.

Meanwhile, at the center of the lever 420, a second locking hole 424 communicating with the first locking hole 442a is formed on the same line as the first locking hole 442a, and the second locking hole 424 A guide table 425 is formed inside, and a lock key 426 is slidably coupled to the guide table 425.

At this time, the locking key 426, the second locking hole 424, the first locking hole 442a, the center of the thrust bearing 443, and the spline groove 441a may be provided on the same line.

The lock key 426 is slidably operated inside the second lock hole 424, but as shown in FIG. 13, when the lock key 426 is moved to one side, the lock key 426 moves to the second lock hole ( 424) It can be discharged to the outside and continuously pass through the first locking hole 442a and the center of the thrust bearing 443 to be caught and supported by the spline groove 441a.

In this way, when the lock key 426 is held in the spline groove 441a, the lock key 426 is pressed onto the first support plate 441 which is coupled to the guide wire 430 and fixed in position, and thus, the second By receiving the lock key 426 through the lock hole 424, the rotational movement of the lever 420 interlocked with the lock key 426 is limited.

Therefore, when the flexible tube 300 needs to be fixed during the procedure, the locking key 426 is moved to one side so that it is caught in the spline groove 441a, due to the structure that restricts the movement of the guide wire 430. 300) can be fixed, so that a more stable procedure can be performed.

The embodiments of the present invention described above are merely exemplary, and those skilled in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, it will be well understood that the present invention is not limited to the forms mentioned in the detailed description above. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims. It is also to be understood that the present invention includes all modifications, equivalents and alternatives within the spirit and scope of the present invention as defined by the appended claims.

100: body part
200: piston body
300: flexible tube
400: bending operation unit

Claims (5)

A body portion including a tubular cylinder body and a needle coupled to one end of the tubular cylinder body;
a piston body provided to be reciprocally movable inside the cylinder body;
a flexible tube coupled to the piston body and extending into the needle; and
A bending operation unit installed across the inside of the piston body and the flexible tube to bend one end of the flexible tube; includes,
A fluid inlet port is branched on the other side of the piston body so that the chemical solution can be injected into the piston body through the fluid inlet port, and the chemical solution injected into the piston body passes through the inside of the flexible tube to the open end of the flexible tube. A needle catheter for treating spinal stenosis, characterized in that outflow into. The method of claim 1,
On the inner circumferential surface of the cylinder body, a plurality of first rotation guide grooves recessed along the circumferential direction are formed at equal intervals along the axial direction, and a plurality of first linear guide grooves recessed along the axial direction are formed at equal angles along the circumferential direction. is formed,
A first mounting hole is recessed on the outer circumferential surface of the piston body, a first elastic spring is installed on the first mounting hole, and the first elastic spring has a first guide groove that is guided by the first rotation guide groove and the first linear guide groove. A needle catheter for treating spinal stenosis, characterized in that the guide ball is coupled. The method of claim 2,
When the first guide ball is guided to one of the plurality of first rotation guide grooves, only rotational movement is allowed while the linear movement of the piston body is restricted, and when the first guide ball is guided to one of the plurality of first linear guide grooves A needle catheter for treating spinal stenosis, characterized in that only linear movement is allowed in a state in which rotational movement of the piston body is restricted. The method of claim 3,
The bending operation unit,
a cover mounted on the other open end of the piston body and having an operating hole formed therein;
a lever rotatably installed in the operation hole; and
A guide wire having one end fixed to one end of the flexible tube and the other end coupled to the lever,
A spirally recessed second rotation guide groove is formed on the inner wall surface of the operation hole, and a plurality of second linear guide grooves recessed along the axial direction are formed at an equal angle along the circumferential direction,
A second mounting hole is recessed on the outer circumferential surface of the lever, a second elastic spring is installed on the second mounting hole, and a second guide guided by the second rotation guide groove and the second linear guide groove is installed on the second elastic spring. balls are joined
When the second guide ball is spirally guided to the second rotation guide groove, the lever rotates and moves linearly at the same time. When the second guide ball is guided to one of a plurality of second linear guide grooves, the lever rotates and moves. A needle catheter for treating spinal stenosis, characterized in that only linear movement is allowed in a restricted state. The method of claim 4,
The bending operation unit,
A swivel joint coupled between the other end of the guide wire and the lever and supporting the lever to rotate in the guide wire; further comprising,
The swivel joint,
A first support plate coupled to the other end of the guide wire and having a spline groove recessed in the center;
a second support plate coupled to the lever and through which a first locking hole is formed in the center; and
A thrust bearing interposed between the first support plate and the second support plate; includes,
At the center of the lever, a second locking hole communicating with the first locking hole is formed on the same line as the first locking hole, a guide bar is formed inside the second lock hole, and a lock key is slidably coupled to the guide bar. becomes,
When the locking key is discharged to the outside of the second locking hole and continuously passes through the first locking hole and the center of the thrust bearing and is caught in the spline groove, the rotational movement of the lever in place is restricted. .

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