KR102621677B1 - Rotatable ercp dissection device - Google Patents

Abstract

The present invention relates to an endoscopic retrograde cholangiopancreatography incision, and more specifically, to easily rotate and bend the end of the inserted catheter in the direction desired by the operator, allowing the incision line and guide wire to be used for selective intubation and moving the incision line to the affected area. This relates to a rotatable endoscopic retrograde cholangiopancreatography incision that can minimize the incidence of procedure-related complications and improve the success rate of the procedure.

Description

Rotatable endoscopic retrograde cholangiopancreatography diagram {ROTATABLE ERCP DISSECTION DEVICE}

The present invention relates to an endoscopic retrograde cholangiopancreatography incision, and more specifically, to an endoscopic retrograde cholangiopancreatography incision that allows rotation of the end of the catheter through which the incision line and guide wire can be drawn out.

Endoscopic retrograde cholangiopancreatography (ERCP) is a medical technique that is useful not only in the diagnosis but also in the treatment of pancreatic and biliary diseases. It can intubate the pancreatic and bile ducts and incise the papillary sphincter inside the ducts.

However, even for doctors who can perform gastrointestinal endoscopy, a lot of surgical experience is needed to succeed in selective biliary intubation, and even for experienced pancreatobiliary specialists, the success rate of the procedure is high in patients with anatomical deformities after surgery. Compared to other upper gastrointestinal endoscopy procedures, the risk of complications is relatively high, so considerable caution is required during the procedure.

In general, the bile duct and pancreatic duct have various shapes for each patient, making selective intubation very difficult. Recently, there are methods using the double guide wire method or an uneven double lumen catheter, but the double guide wire method rather intubates the bile duct due to the cannulation of the pancreatic duct. Intubation may be difficult in some cases, and in the case of uneven double lumen catheters, there is the problem of the inconvenience of having to change to an incision because it is not an incision, and the possibility of procedure failure due to this.

In particular, in the case of the existing endoscopic retrograde cholangiopancreatography incision, the end of the catheter is bent to one side by pulling the incision line and the papillary sphincter can be incised using the incision line. However, the user cannot directly control the bending direction of the catheter. There is a problem that selective intubation of the bile duct and sieve duct is difficult due to the limited number of patients, and the success rate of the procedure may be low because it is difficult to use the incision line directly toward the affected area.

In addition, there is also the inconvenience that the guide wire, which flows into the incision and moves along the inside of the incision, and is pulled out to the distal end of the incision, making it difficult to intubate the bile duct, is difficult to direct the bile duct in the desired direction.

Republic of Korea Patent Publication No. 10-1602558 “Papillary incision diagram for endoscopic retrograde biliary pancreatography”

The present invention is intended to solve the above-mentioned problems. The end of the inserted catheter can be easily rotated and bent in the direction desired by the operator, allowing selective intubation and moving the incision line to the affected side, thereby minimizing the incidence of complications related to the procedure. The purpose is to provide a rotatable endoscopic retrograde cholangiopancreatography incision that can improve the success rate.

In addition, when rotating the catheter, the operator can easily rotate and bend it to the desired angle without affecting the built-in incision line, improving the accuracy and success rate of the procedure, reducing the time required for the procedure, and even for inexperienced operators. The purpose is to provide a rotatable endoscopic retrograde cholangiopancreatography incision that can be easily manipulated.

In addition, the guide wire can be interpolated and moved inside the catheter inserted into the pancreatic duct and drawn out to the outside of the catheter end, and the guide wire can also be rotated in the desired direction according to the rotation of the catheter and can be selectively bile ducted. The purpose is to provide a pancreatography incision view.

The problems to be solved by the present invention are not limited to the problems mentioned above, and other problems not mentioned can be clearly understood by those skilled in the art from the description below.

In order to solve the above-described problem, the present invention includes an operating unit consisting of a frame and a handle that penetrates the frame and can move along the frame extension direction; A catheter connected to the bottom of the control unit and introduced into the body; An incision line that has one end fixed to the handle and the other end fixed to the distal end of the catheter and built into the catheter; And a rotating part coupled to the end of the frame, the inner lower end of which is connected to the catheter and rotates along the outer circumferential surface of the end of the frame to rotate the catheter. A pair of incision lines through which the incision line can be passed is provided on one end of the catheter. An incision line entrance hole is formed, and the outer end of the incision line is exposed to the outside through a pair of the incision line entry holes, and when the handle is manipulated, the catheter is bent and the incision line is spaced apart from the outer peripheral surface of the catheter. It can be.

In addition, the incision line includes a fixture fitted and fixed to the inside of the distal end of the catheter; A moving tool spaced apart from the fixture and fitted inside the catheter; A cutting wire is formed in a space spaced apart from the fixture and the moving section, and both ends are coupled to the fixture and the moving section, respectively, and the center penetrates each of the cutting line access holes and is exposed to the outside in close contact with the outer peripheral surface of the catheter. ; and a steel wire, one end of which is coupled and fixed to the moving tool, and the other end of which is connected to the handle. When the handle moves to the upper side of the frame, the steel wire and the moving tool move along the moving direction of the handle, and the end of the catheter The handle is bent toward the moving direction so that the cutting wire and the catheter can be spaced apart.

In addition, a recessed fitting groove is formed along the outer circumferential surface of the bottom of the frame, and the catheter has an inlet protrusion whose edge protrudes vertically at one end. The rotating part has a cylindrical shape with open upper and lower surfaces and has a plurality of teeth along the outer circumferential surface. is formed, and at the inner upper end, a fitting protrusion protrudes along the inner peripheral surface in a shape corresponding to the recessed shape of the fitting groove; and a recessed inlet groove along the inner circumferential surface in a shape corresponding to the protruding shape of the inlet protrusion is formed at the inner lower end, wherein the catheter is introduced into the lower surface of the rotating part so that the inlet protrusion is seated inside the inlet groove, and the rotating part The upper surface of the frame is retracted so that the fitting protrusion is seated inside the fitting groove, so that the rotary part may be rotatable along the inside of the fitting groove.

The present invention includes an operating unit consisting of a frame and a handle that penetrates the frame and is movable along a direction in which the frame extends; A catheter connected to the bottom of the control unit and introduced into the body; An incision line that has one end fixed to the handle and the other end fixed to the distal end of the catheter and built into the catheter; And a rotating part coupled to the end of the frame, the inner lower end of which is connected to the catheter and rotates along the outer circumferential surface of the end of the frame to rotate the catheter. A pair of incision lines through which the incision line can be passed is provided on one end of the catheter. A cut-out entrance hole is formed, and a first ring-shaped ring into which the user's finger can be inserted is formed at the top of the frame, and a ring-shaped second ring into which the user's finger can be inserted is formed on both sides of the handle. are formed, and the distal outer side of the incision line is exposed to the outside through a pair of incision line entrance holes. When the handle is manipulated, the catheter is bent and the incision line may be spaced apart from the outer peripheral surface of the catheter.

In addition, the incision line includes a fixture fitted and fixed to the inside of the distal end of the catheter; A moving tool spaced apart from the fixture and fitted inside the catheter; A cutting wire is formed in a space spaced apart from the fixture and the moving section, and both ends are coupled to the fixture and the moving section, respectively, and the center penetrates each of the cutting line access holes and is exposed to the outside in close contact with the outer peripheral surface of the catheter. ; and a steel wire, one end of which is coupled and fixed to the moving tool, and the other end of which is connected to the handle. When the handle moves to the upper side of the frame, the steel wire and the moving tool move along the moving direction of the handle, and the end of the catheter The handle is bent toward the moving direction so that the cutting wire and the catheter can be spaced apart.

In addition, a recessed fitting groove is formed along the outer circumferential surface of the bottom of the frame, and the catheter has an inlet protrusion whose edge protrudes vertically at one end. The rotating part has a cylindrical shape with open upper and lower surfaces and has a plurality of teeth along the outer circumferential surface. is formed, and at the inner upper end, a fitting protrusion protrudes along the inner peripheral surface in a shape corresponding to the recessed shape of the fitting groove; and a recessed inlet groove along the inner circumferential surface in a shape corresponding to the protruding shape of the inlet protrusion is formed at the inner lower end, wherein the catheter is introduced into the lower surface of the rotating part so that the inlet protrusion is seated inside the inlet groove, and the rotating part The upper surface of the frame is retracted so that the fitting protrusion is seated inside the fitting groove, so that the rotary part may be rotatable along the inside of the fitting groove.

The present invention includes an operating unit consisting of a frame and a handle that penetrates the frame and is movable along a direction in which the frame extends; A catheter connected to the bottom of the control unit and introduced into the body; An incision line that has one end fixed to the handle and the other end fixed to the distal end of the catheter and built into the catheter; A rotating part coupled to the end of the frame, the inner lower end of which is connected to the catheter and rotated along the outer peripheral surface of the end of the frame to rotate the catheter; And a guide wire that is inserted into the catheter, moves along the extension direction of the catheter, is drawn out to the distal end of the catheter, and protrudes outward, wherein the catheter communicates with the internal space of the catheter at the distal end, and the guide a pair of wire withdrawal holes formed on one side and the other so that the ends of the wire protrude outward; And a connection port provided on the upper side connected to the operation unit and through which the guide wire can be inserted into the catheter through the injection wire protruding to one side; is formed at the center of the injection wire, wherein the injection wire The guide wire may be inserted into the hole passing through the catheter.

In addition, the incision line includes a fixture fixed to one side of the inner end of the catheter; A moving tool spaced apart from the fixture and located on one side inside the distal end of the catheter; It is formed in a space spaced apart from the fixture and the moving section, and both ends are coupled to the fixture and the moving section, respectively, and both ends penetrate the incision line entrance hole, respectively, so that the center is in close contact with the outer peripheral surface of the catheter and exposed to the outside. cutting wire; and a steel wire, one end of which is coupled and fixed to the moving tool, and the other end of which is connected to the handle. When the handle moves to the upper side of the frame, the steel wire and the moving tool move along the moving direction of the handle, and the end of the catheter The handle is bent toward the moving direction so that the cutting wire and the catheter can be spaced apart.

At this time, the fixture and the moving device are provided in close contact with the inner surface of one side of the distal end of the catheter where the incision line access hole is located, the moving device moves along the inner surface of one side of the distal end of the catheter, and the guide wire is connected to the fixture and the moving device. It can move along one side of the inside of the catheter that is in close contact with the other side opposite to the inside of the catheter.

The present invention includes an operating unit consisting of a frame and a handle that penetrates the frame and is movable along a direction in which the frame extends; A catheter connected to the bottom of the control unit and introduced into the body; An incision line that has one end fixed to the handle and the other end fixed to the distal end of the catheter and built into the catheter; A rotating part coupled to the end of the frame, the inner lower end of which is connected to the catheter and rotated along the outer peripheral surface of the end of the frame to rotate the catheter; And a guide wire that is inserted into the catheter, moves along the extension direction of the catheter, is drawn out to the distal end of the catheter, and protrudes outward, wherein the catheter communicates with the internal space of the catheter at the distal end, and the guide a pair of wire withdrawal holes formed on one side and the other so that the ends of the wire protrude outward; And a connection port provided on the upper side connected to the operation unit and through which the guide wire can be inserted into the catheter through the injection wire protruding to one side; is formed at the center of the injection wire, wherein the injection wire The guide wire is inserted into a hole penetrating and inserted into the catheter, and inside the distal end of the catheter, an inclination is formed in the spaced apart inner space of the pair of wire outlet holes, respectively, toward the wire outlet hole, so that the guide wire is inclined. Accordingly, an inclined groove for selectively moving to the wire withdrawal hole is formed.

As such, the present invention allows selective intubation and movement of the incision line to the affected side by easily rotating and bending the end of the inserted catheter in the direction desired by the operator, thereby minimizing the incidence of complications related to the procedure and improving the success rate of the procedure. holds.

In addition, when rotating the catheter, the operator can easily rotate and bend it to the desired angle without affecting the built-in incision line, improving the accuracy and success rate of the procedure, reducing the time required for the procedure, and even for inexperienced operators. It has effects that can be easily manipulated.

In addition, the guide wire can be interpolated and moved inside the catheter inserted into the pancreatic duct and drawn out to the outside of the catheter end, and the guide wire can also be rotated and selectively moved in a desired direction according to the rotation of the catheter.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

Figure 1 shows a rotatable endoscopic retrograde cholangiopancreatography incision according to the present invention.
Figure 2 shows a side cross-sectional view of the operating unit according to the present invention.
Figure 3 shows a partially enlarged view of the distal end of the catheter on which the incision line according to the present invention is formed.
Figure 4 is a partially enlarged cross-sectional view of the end of the catheter with the incision line according to the present invention.
Figures 5 and 6 show an operational example of a rotatable endoscopic retrograde cholangiopancreatography incision according to the present invention.
Figure 7 shows an exploded perspective view of the operating unit, rotating unit, and catheter according to the present invention.
Figure 8 shows a cross-sectional view of an example of a combination of an operating unit, a rotating unit, and a catheter according to the present invention.
Figure 9 shows an example of rotation of the catheter according to the present invention.
Figure 10 shows a partially enlarged view of the catheter end of another embodiment of the present invention.
Figure 11 is a partial enlarged view of the top of the catheter of another embodiment of the present invention.
Figure 12 shows a cross-sectional view of the distal end of the catheter according to the present invention.
Figure 13 is a top view showing a cut surface of the end of the catheter according to the present invention.
Figure 14 is a partially enlarged view showing an example of drawing out a guide wire according to the present invention.
Figure 15 shows an example of rotation of the drawn out guide wire according to the present invention.
Figure 16 shows another embodiment of the wire withdrawal hole according to the present invention.

Since the present invention can make various changes and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail.

However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention. While describing each drawing, similar reference numerals are used for similar components.

When a component is said to be "connected" or "connected" to another component, it is understood that it may be directly connected to or connected to the other component, but that other components may exist in between. It should be. On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between.

The terms used in this application are only used to describe specific embodiments and are not intended to limit the invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Hereinafter, embodiments of the present invention will be described with reference to the attached drawings. The same symbols shown in each drawing represent the same members. In describing the present invention, detailed descriptions of related known functions or configurations are omitted in order to not obscure the gist of the present invention.

Figure 1 shows a rotatable endoscopic retrograde cholangiopancreatography incision according to the present invention.

Referring to FIG. 1, the present invention relates to an endoscopic retrograde cholangiopancreatography incision that allows rotation of the end of the catheter on which the incision line is formed. This incision device (1) includes a manipulation unit (100), a catheter (200), It consists of a cutting line 300 and a rotating part 400.

First, the operation unit 100 has one end connected to the catheter 200 and is also connected to the incision line 300 built into the catheter 200, so that the incision line 300 is manipulated through manipulation of the operation unit 100 to cut the incision line. The end of the catheter 200 may be bent in one direction due to the tension of 300.

In addition, a rotating unit 400 capable of rotating the catheter 200 is formed at the end of the operating unit 100, where the operating unit 100 and the catheter 200 are coupled. This rotating part 400 is fitted to the outer side of the distal end of the operating unit 100, and in a fixed state, when the rotating unit 400 rotates along the outer peripheral surface of the distal end of the operating unit 100 by the operator's force, it moves to the inner bottom of the rotating unit 400. The catheter 200, whose end is coupled and fixed, is also rotated together so that the cutting wire 310 with the incision line 300 exposed to the outside at the end of the catheter 200 can be rotated toward the affected area or inserted into the pancreatic or bile duct. .

Figure 2 shows a side cross-sectional view of the operating unit according to the present invention.

Referring to FIG. 2, the operating unit 100 can move in the vertical direction along the frame 110 where one end of the cut line 300 is inserted and the outer peripheral surface of the frame 110, and the cut line inserted into the inside of the frame 110 (300) It consists of a handle (120) connected to one end.

The frame 110 has a cylindrical shape, and at the top, a first ring 111 through which the operator can insert his or her finger is formed in a ring shape along with a second ring 122 formed on the handle 120.

In addition, through holes 112 are formed on both sides of the frame 110, respectively, penetrating the frame 110 in the horizontal direction. These through holes 112 are formed to have the same shape and position on both sides of the frame 110, and a through bar 121 formed inside the handle 120 penetrates through the through holes 112. With the handle 120 inserted into the operating unit 100, the handle 120 is allowed to move in the vertical direction along the through hole 112.

A space is formed inside the frame 110, and the lower end is open, so that the cut line 300 is inserted into this open side and is coupled and fixed to the penetrating bar 121 of the handle 120 that penetrates the internal space, thereby forming the handle 120. According to the movement, the incision line 300 may move to the upper side inside the frame 110 and be pulled.

At this time, the handle 120 has a through bar 121 passing through a pair of through holes 112 formed on both sides of the frame 110, and the through bars 121 fixed to the inside of the handle 120 The handle 120 moves along the inner space of 112, but is completely spaced above or below the frame 110, thereby preventing the handle 120 from being separated from the frame 110.

Additionally, a recessed fitting groove 113 is formed along the outer peripheral surface of the open lower end of the frame 110. The fitting groove 113 is formed so that the rotating part 400 coupled with the catheter 200 can be coupled to the end of the frame 110. The fitting groove 113 is formed by the fitting protrusion 410 of the rotating part 400, which will be described later. As the rotary part 400 and the catheter 200 are introduced into the inside, the rotary part 400 and the catheter 200 can be combined with the manipulation part 100, and when the rotary part 400 rotates, the fitting protrusion 410 rotates along the inside of the fitting groove 113 to form the rotating part. (400) can be rotated easily.

The handle 120 penetrates the frame 110 and moves in the vertical direction along the outer peripheral surface of the frame 110, and a penetrating bar 121 penetrating horizontally is formed in the inner space through which the frame 110 penetrates.

The end of the cut line 300 introduced into the frame 110 is fixedly coupled to the center of the through bar 121, that is, the center of the through bar 121 built into the frame 110. Therefore, the incision line 300 is pulled as the handle 120 moves.

In addition, ring-shaped second rings 122 are protruding on both sides of the handle 120, and the operator inserts his or her thumb into the first ring 111 and places the index and middle fingers on the second ring. The handle 120 can be easily pulled to the upper side of the frame 110 by inserting it into (122), so that the cut line 300 connected to the handle 120 can be pulled to the upper side of the frame 110.

By pulling the incision line 300 connected through the operation unit 100 having this configuration, the end of the catheter 200 is bent to one side by the tension of the incision line 300, and this causes it to come into close contact with the outer peripheral surface of the end of the catheter 200. The incision wire 310 of the incision line 300 positioned in the state is spaced apart from the catheter 200 so that the incision wire 310 can remove the papillary sphincter muscle, etc. within the trachea.

The catheter 200 is provided connected to the lower end of the manipulation unit 100 and can be coupled to the manipulation unit 100 through the rotation unit 400.

This catheter 200 has a sufficient length so that it can be inserted into the body and cannulated into the pancreatic or bile duct, and an incision line 300 can be inserted into the inside of the catheter 200 and fixed to the end of the catheter 200.

On one distal side of the catheter 200, a cut line entrance hole 210 is formed through which the external and internal spaces of the catheter 200 can communicate with each other, and these cut line entrance holes 210 are formed in a pair, but the catheter ( 200) They are formed spaced apart from each other in the direction of extension.

The incision line 300 built into the catheter 200 penetrates the incision line entrance hole 210 so that the incision wire 310 can be provided in close contact with one side of the outer circumferential surface of the catheter 200.

That is, rather than the entire incision line 300 being exposed to the outside as shown in FIG. 1, the incision line entrance hole 210 is provided so that only the portion of the incision wire 310 that actually removes the nipple sphincter protrudes outward from the catheter 200. This is formed and the incision line 300 built into the end of the incision line 300, that is, the end of the catheter 200, is provided outside the catheter 200, so that the incision wire 310 can be used through the bend of the catheter 200. .

In addition, one end of the catheter 200 coupled to the rotating portion 400 of the distal end of the catheter 200 is formed to protrude perpendicularly from the outer peripheral surface of the catheter 200 to form an inlet protrusion 220 with an expanded outer diameter.

This inlet protrusion 220 can be connected to the manipulation unit 100 through the rotary part 400 by being inserted into and fixed to the inner bottom of the inlet groove 420 at the inner bottom of the rotary part 400, which will be described later, and thereby rotates the rotary part 400. Accordingly, the catheter 200 is also rotated so that the end of the catheter 200 on which the cutting wire 310 is formed can rotate in accordance with the rotation angle of the rotating part 400.

Figure 3 is a partially enlarged view showing the distal end of the catheter with the incision line according to the present invention, Figure 4 is a partially enlarged cross-sectional view of the distal end of the catheter with the incision line according to the present invention, and Figures 5 and 6 show the distal end of the catheter with the incision line according to the present invention. An example of operation of a rotatable endoscopic retrograde cholangiopancreatography incision is shown.

The incision line 300 can be combined with the catheter 200 to cut the nipple sphincter muscle. One end of this incision line 300 is fixed to the center of the penetrating bar 121 of the handle 120, and the other end is fixed to the end of the catheter 200 to perform an incision procedure through the intubated catheter 200. can do.

The other end of the incision line 300 is formed with a fixture 501 and a movable member 502 spaced apart from each other in the direction in which the incision line 300 extends, as shown in FIGS. 3 and 4, and the fixture 501 and the movable member 502 are In the space spaced apart from the liver, a cutting wire 310 is formed that protrudes to the outside of the catheter 200 and cuts the nipple sphincter muscle, etc.

First, the fixture 501 is formed in a cylindrical shape at the other end of the incision line 300, and is fixed inside the end of the catheter 200.

The mobile device 502 is formed to be spaced apart from the fixture 501, and a cut wire 310 is formed in the spaced space to connect the fixture 501 and the mobile device 502. At this time, the distal end of the cutting wire 310 is connected and fixed to the center of one side of the moving device 502, and a steel wire 320 connected to the handle 120 is provided to the center of the other side.

Therefore, in normal times, as shown in FIG. 5, when the user is not using the handle 120, the fixture 501 and the mover 502 are maintained in a fixed state inside the catheter 200, so that the cutting wire 310 is connected to the catheter 200. It is maintained in close contact with the outer circumferential surface, and through this, the user can minimize collision between the cutting wire 310 and the body when introducing the catheter 200 into the body.

In addition, as shown in Figure 6, when the user pulls the handle 120 to use the cutting wire 310, the steel wire 320, the moving tool 502, and the cutting wire 310 are moved to the side where the handle 120 moves. , the fixture 501 is fixed to the inner end of the catheter 200, and the end of the catheter 200 is bent as shown in FIG. 9 described later, and through this, the catheter 200 and the cutting wire 310 are spaced apart from each other. The cutting wire 310 is formed in a shape that can cut the nipple sphincter, etc.

Figure 7 shows an exploded perspective view of the operating unit, rotating unit, and catheter according to the present invention, Figure 8 shows a cross-sectional view of a combination example of the operating unit, rotating unit, and catheter according to the present invention, and Figure 9 shows the rotation of the catheter according to the present invention. It shows an example.

By bending the end of the catheter 200 through the handle 120, the incision wire 310 is spaced apart from the outer peripheral surface of the catheter 200 so that it can be used for an incision procedure, and at the same time, the bile duct or duct into which the catheter 200 introduced into the body will be inserted It must be moved to a sieve tube, etc., but since the shape of the sieve tube is diverse and is not made of a straight line, there is a need to rotate the direction in which the catheter 200 faces to fit the tube into which it is to be inserted.

In addition, when the nipple sphincter is located in one direction and on the side opposite to the one direction, the nipple sphincter located in one direction must be removed and the nipple sphincter located on the opposite side must also be cut by simply rotating the catheter 200, but it is simply connected to the catheter 200. When the operating unit 100 itself is rotated, the accuracy of rotation is reduced, and there is a risk that the cutting wire 310 may collide with the body during rotation, causing bleeding.

Therefore, in order to solve this problem, a rotating part 400 that can rotate only the catheter 200 is formed at the bottom of the manipulation unit 100, and by rotating this rotating part 400, only the catheter 200 can be easily rotated. do.

The rotating part 400 has a cylindrical shape and has a shape with a plurality of teeth formed along the outer peripheral surface, so that the user holds the teeth 401 and finely rotates the rotating part 400 to adjust the rotating part 400 and the catheter ( 200) can be rotated.

This rotating part 400 has a fitting protrusion 410 formed on the inner top as shown in FIG. 8, and when the operating unit 100 and the rotating unit 400 are coupled, the fitting protrusion 410 is drawn into the fitting groove 113 and is engaged. The rotating unit 400 is coupled to the bottom of the operating unit 100, and when the user holds the rotating unit 400 and rotates it, the fitting protrusion 410 can rotate consistently along the inside of the fitting groove 113.

In addition, an inlet groove 420 that is coupled to the inlet protrusion 220 of the catheter 200 is formed at the inner bottom of the rotating unit 400.

The lead-in groove 420 is formed by inserting one end of the catheter 200 on which the lead-in protrusion 220 is formed when the rotary unit 400 and the catheter 200 are combined into the open lower surface of the rotary unit 400, so that the lead-in protrusion 220 is formed when the rotary unit 400 and the catheter 200 are combined. The catheter 200 is inserted into the inlet groove 420 and fixed to the rotating part 400.

At this time, the lead-in groove 420 is recessed to the same extent as the protruding width of the lead-in protrusion 220, so that the lead-in protrusion 220 is fitted and fixed inside the lead-in groove 420, and through this, the catheter ( 200) can be rotated. In addition, a separate friction protrusion (not shown in the drawing) is additionally formed on the inner surface of the inlet groove 420 to prevent the catheter 200 from idling inside the inlet groove 420 when the rotary part 400 rotates, thereby preventing the catheter 200 from idling inside the inlet groove 420. When rotating, the lead-in groove 420 and the lead-in protrusion 220 are fitted together so that the catheter 200 can be rotated together with the rotating part 400 in a fixed state.

Therefore, through the rotation unit 400, the user can finely adjust the rotation angle of the catheter 200 and rotate the end of the catheter 200 in the desired direction as shown in FIG. 9, and the catheter 200 is located at the bottom of the operation unit 100. ) is not directly coupled, it is also possible to prevent shock, movement, etc. caused by manipulation of the operating unit 100 from being transmitted to the catheter 200.

The incision device 1 having the above-described configuration allows the catheter 200 to be inserted into the pancreatic duct to cut the papillary sphincter muscle within the pancreatic duct. In the case where an additional catheter or wire must be inserted into the fine-sized bile duct connected to the pancreatic duct during the procedure, It can happen.

However, since the diameter of the catheter 200 is a certain size because the incision line 300 must be inserted, there is a problem that the inner diameter is quite narrow and it is somewhat difficult to perform a fine bile duct.

Therefore, in the present invention, a guide wire 500 is inserted into the catheter 200 and drawn out to the distal side of the catheter 200, where the incision line 300 protrudes, to perform a bile duct. You can. These embodiments will be described through FIGS. 10 to 15.

Figure 10 is a partial enlarged view showing the end of a catheter according to another embodiment of the present invention, Figure 11 is a partially enlarged view showing the top of the catheter according to another embodiment of the present invention, and Figure 12 is a cross-sectional view showing the end of the catheter according to the present invention. , Figure 13 is a top view showing the cut surface of the end of the catheter according to the present invention, Figure 14 is a partial enlarged view showing an example of a guide wire being drawn out according to the present invention, and Figure 15 is a rotation of the drawn out guide wire according to the present invention. It shows an example.

Referring to FIG. 10, in the previous embodiment, the cylindrical fixture 301 and movable tool 302, which have the same diameter as the inner diameter of the catheter 200, provide an entry/exit space for the guide wire 500 introduced into the catheter 200. To form the inside of the catheter 200, it has a plate shape attached to the incision line entrance hole 210 through which the incision wire 310 is drawn out.

Therefore, the guide wire 500 is connected to the catheter formed on the lower side of the incision line 300 through the incision line 300 that is provided in close contact with or attached to one inner side of the catheter 200, that is, the inside where the incision line entry hole 210 is formed. (200) Allows movement along the inside.

At this time, the fixture 301 is formed in a fixed state inside the distal end of the catheter 200, and the moving device 302 moves in the direction in which the catheter 200 extends according to the user's manipulation of the handle 120, similar to the above-described embodiment. It can be. This moving tool 302 is not fixed to be movable inside the catheter 200, but must remain fixed on one side of the catheter 200 so that the guide wire 500 can easily enter and exit the catheter 200. ) It is combined with a moving tool 302 inside, so that the moving tool 302 can be easily slid and moved when moving along the inner extending direction of the catheter 200 by manipulating the steel wire 320 and the handle 120 by the user. A pair of moving rails 240 are attached to one side of the catheter 200 along which the moving tool 302 moves (see FIG. 12).

The moving rail 240 is formed to extend corresponding to the moving distance of the handle 120 moving in the vertical direction outside the frame 110. These movable rails 240 are spaced apart to correspond to the width of the movable device 302, and both ends of the movable device 302 are coupled and fixed while being inserted into the rail grooves 241 recessed on the inside of the movable rail 240. It can be.

That is, the moving tool 302 is located in the space between the moving rails 240, and the rail groove 241 is recessed in a shape corresponding to the side end of the moving tool 302 at the inner center of the moving rail 240. It is formed so that both ends of the moving tool 302 are fitted inside the pair of rail grooves 241, and the moving tool 302 moves inside the moving rail 240 according to the handle 120 and the steel wire 320. The sphere 302 is allowed to move along the extension direction of the moving rail 240.

Accordingly, the moving tool 302 moves along the moving rail 240, and the end of the catheter 200 can be bent through the fixture 301 and the moving tool 302 according to the above-described embodiment.

Meanwhile, although the wire drawing holes 250 are shown as a pair in FIGS. 10 to 16, the wire drawing holes 250 do not necessarily consist of two, and may be formed as a single wire drawing hole 250 at the center of the end of the catheter 200.

In addition, as shown in FIG. 11, a connection port 230 may be formed at the top of the catheter 200 coupled to the manipulation unit 100 so that the guide wire 500 can be inserted.

The connection port 230 is coupled and fixed to the upper outer peripheral surface of the catheter 200, and a tubular injection wire 231 into which the guide wire 500 can be inserted is formed on one side. This injection wire 231 has a perforated center, and a hole is formed inside the connection port 230 through which the inside of the injection wire 231 communicates with the inside of the catheter 200, so that the user can insert the guide wire 500 into the injection wire. It can be inserted through (231) into the distal end of the catheter 200 where the cutting wire 310 is formed along the extension direction of the catheter 200.

As shown in FIG. 12, the guide wire 500 inserted into the catheter 200 is drawn out of the catheter 200 through the wire withdrawal hole 250 formed at the end of the catheter 200 and flows into the bile duct connected to the pancreatic duct. Allows for insertion.

At this time, an inclined hole 251 is formed inside the distal end of the catheter 200 so that the guide wire 500 can be selectively withdrawn toward the wire withdrawal hole 250.

Referring to FIG. 13, the inclined hole 251 is formed inside the distal end of the catheter 200, and slopes are formed on both sides, so that the slope is inclined toward the wire withdrawal hole 250.

Therefore, the guide wire 500 inserted into the distal end of the catheter 200 collides with the inclined port 251 and selectively moves to the wire withdrawal hole 250 formed on one side or the other side along the slope of the inclined port 251. It is possible to withdraw, and the guide wire 500 drawn out of one wire withdrawal hole 250 can protrude and extend to the end of the catheter 200 as shown in FIG. 14.

Through this, the user can rotate the rotating part 400 to rotate the catheter 200 within the pancreatic duct to one side, and the guide wire 500 can be pulled out through the wire drawing hole 250 on the same side as the rotated side, thereby allowing the guide wire 500 to be pulled out to a fine size. The guide wire 500 can be easily inserted into the bile duct.

That is, the guide wire 500 can be selectively withdrawn in a desired direction through the pair of wire withdrawal holes 250, and this has the advantage of selectively inserting the guide wire 500 into the bile duct.

In addition, the end of the catheter 200 can be rotated to the position where the bile duct is formed, and through this, the guide wire 500 can also be easily moved to the position of the bile duct so that bile duct insertion can be easily performed.

In addition, the guide wire 500 does not collide with the incision line 300 in the process of moving along the inside of the catheter 200, so it can easily move inside the catheter 200, which has the advantage of enabling selective bile duct insertion. have

Meanwhile, as described above, the wire draw-out hole 250 is made up of a single or plural wire at the end of the catheter 200, and the guide wire 500 is passed through the desired wire draw-out hole 250 according to the user's intention to bring the guide wire 500 to the outside of the catheter 200. The wire withdrawal holes 250 may not necessarily be formed only at the end of the catheter 200, but may be formed spaced apart from each other as shown in FIG. 16. This will be explained through FIG. 16.

Figure 16 shows another embodiment of the wire withdrawal hole according to the present invention.

Referring to FIG. 16, the wire withdrawal holes 250 are formed in a pair, and one wire withdrawal hole 250 is formed with a perforation in the center of the end of the catheter 200 to extend the guide wire 500 to the outside of the end of the catheter 200. may protrude and extend, and another wire withdrawal hole 250 may be formed on the side of the catheter 200 at a certain distance from the end of the catheter 200.

That is, the guide wire 500 is inserted into the bile duct connected to one side of the pancreatic duct where the catheter 200 is inserted, but if it is difficult to move the end of the catheter 200 to the side where the pancreatic duct and the bile duct are connected, the guide wire 500 is inserted into one side of the catheter 200. The guide wire 500 does not have to penetrate the entire catheter 200 through the formed wire withdrawal hole 250, but protrudes and extends outward from one side of the catheter 200 through the wire withdrawal hole 250 formed on the side to easily enter the bile duct. can be inserted into

At this time, the wire withdrawal hole 250 formed on the side of the catheter 200 is not necessarily formed on the same side as the side provided with the cutting wire 310, and is located at various positions on the outer surface of the catheter 200 depending on the manufacturer's intention. It can be formed in the side, and the wire draw-out hole 250 formed on the side is spaced at a certain distance from the end of the catheter 200. At this time, the space width between the end of the catheter 200 and the wire draw-out hole 250 formed on the side is about 5 mm. It is preferable to be formed on the side of the spaced apart catheter 200, but it is not limited thereto.

Optimal embodiments are disclosed in the drawings and specification. Here, specific terms are used, but they are used only for the purpose of explaining the present invention and are not used to limit the meaning or scope of the present invention described in the claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the attached patent claims.

1: Incision device
100: control panel 110: frame
110: first ring 112: through hole
113: Fitting groove 120: Handle
121: Penetrating bar 122: Second ring
200: Catheter 210: Incision line entry hole
220: Inlet protrusion 230: Connection port
240: moving rail 241: rail groove
250: Wire withdrawal hole 251: Inclined hole
300: Cut line 301: Fixture
302: Moving device 310: Cutting wire
320: Steel wire 400: Rotating part
401: sawtooth 410: insertion protrusion
420: Inlet groove 500: Guide wire

Claims (10)

an operating unit consisting of a frame and a handle that penetrates the frame and can be moved along a direction in which the frame extends;
A catheter connected to the bottom of the control unit and introduced into the body;
An incision line that has one end fixed to the handle and the other end fixed to the distal end of the catheter and built into the catheter; and
It is coupled to the end of the frame, and the inner lower end is connected to the catheter and rotates along the outer peripheral surface of the end of the frame to rotate the catheter.
A pair of incision line entrance holes through which the incision line can pass is formed on one side of the distal end of the catheter,
A recessed fitting groove is formed along the outer peripheral surface of the bottom of the frame,
The catheter is formed with a lead-in protrusion whose edge protrudes vertically,
The outer end of the incision line is exposed to the outside through a pair of incision line entrance holes, and when the handle is manipulated, the catheter is bent and the incision line is spaced apart from the outer peripheral surface of the catheter,
The rotating part,
It has a cylindrical shape with the upper and lower surfaces open and multiple teeth are formed along the outer circumferential surface.
At the inner upper end, a fitting protrusion protrudes along the inner peripheral surface in a shape corresponding to the recessed shape of the fitting groove; and
At the inner bottom, a recessed inlet groove is formed along the inner peripheral surface in a shape corresponding to the protruding shape of the inlet protrusion,
The catheter is inserted into the lower surface of the rotating part so that the inserting protrusion is seated inside the inserting groove, and the upper surface of the rotating unit is inserted into the bottom of the frame so that the fitting protrusion is seated inside the fitting groove, so that the rotating part is placed inside the fitting groove. A rotatable endoscopic retrograde cholangiopancreatography incision, characterized in that it can be rotated along.
According to paragraph 1,
The incision line is,
A fixture fitted and fixed inside the distal end of the catheter;
A moving tool spaced apart from the fixture and fitted inside the catheter;
A cutting wire is formed in a space spaced apart from the fixture and the moving section, and both ends are coupled to the fixture and the moving section, respectively, and the center penetrates each of the cutting line access holes and is exposed to the outside in close contact with the outer peripheral surface of the catheter. ; and
It consists of a steel wire, one end of which is coupled and fixed to the moving tool, and the other end connected to the handle,
When the handle moves to the upper side of the frame, the steel wire and the moving tool are moved along the moving direction of the handle, and the end of the catheter is bent toward the moving direction of the handle to separate the cutting wire from the catheter. Possible endoscopic retrograde cholangiopancreatography incision diagram.
delete an operating unit consisting of a frame and a handle that penetrates the frame and can be moved along a direction in which the frame extends;
A catheter connected to the bottom of the control unit and introduced into the body;
An incision line that has one end fixed to the handle and the other end fixed to the distal end of the catheter and built into the catheter; and
It is coupled to the end of the frame, and the inner lower end is connected to the catheter and rotates along the outer peripheral surface of the end of the frame to rotate the catheter.
A pair of incision line entrance holes through which the incision line can pass is formed on one side of the distal end of the catheter,
A first ring-shaped ring is formed at the top of the frame into which the user's finger can be inserted,
A second ring-shaped ring into which the user's finger can be inserted is formed on both sides of the handle,
The outer end of the incision line is exposed to the outside through a pair of incision line entrance holes,
A recessed fitting groove is formed along the outer peripheral surface of the bottom of the frame,
The catheter is formed with a lead-in protrusion whose edge protrudes vertically,
When the handle is manipulated, the catheter is bent and the incision line is spaced apart from the outer peripheral surface of the catheter,
The rotating part,
It has a cylindrical shape with the upper and lower surfaces open and multiple teeth are formed along the outer circumferential surface.
At the inner upper end, a fitting protrusion protrudes along the inner peripheral surface in a shape corresponding to the recessed shape of the fitting groove; and
At the inner bottom, a recessed inlet groove is formed along the inner peripheral surface in a shape corresponding to the protruding shape of the inlet protrusion,
The catheter is inserted into the lower surface of the rotating part, so that the inserting protrusion is seated inside the inserting groove, and the upper surface of the rotating unit is inserted into the bottom of the frame, and the fitting protrusion is seated inside the fitting groove, so that the rotating part is placed inside the fitting groove. A rotatable endoscopic retrograde cholangiopancreatography incision, characterized in that it can be rotated along.
According to paragraph 4,
The incision line is,
A fixture fitted and fixed inside the distal end of the catheter;
A moving tool spaced apart from the fixture and fitted inside the catheter;
A cutting wire is formed in a space spaced apart from the fixture and the moving section, and both ends are coupled to the fixture and the moving section, respectively, and the center penetrates each of the cutting line access holes and is exposed to the outside in close contact with the outer peripheral surface of the catheter. ; and
It consists of a steel wire, one end of which is coupled and fixed to the moving tool, and the other end connected to the handle,
When the handle moves to the upper side of the frame, the steel wire and the moving tool are moved along the moving direction of the handle, and the end of the catheter is bent toward the moving direction of the handle to separate the cutting wire from the catheter. Possible endoscopic retrograde cholangiopancreatography incision diagram.
delete delete delete delete an operating unit consisting of a frame and a handle that penetrates the frame and can be moved along a direction in which the frame extends;
A catheter connected to the bottom of the control unit and introduced into the body;
An incision line that has one end fixed to the handle and the other end fixed to the distal end of the catheter and built into the catheter;
A rotating part coupled to the end of the frame, the inner lower end of which is connected to the catheter and rotated along the outer peripheral surface of the end of the frame to rotate the catheter; and
It consists of a guide wire that is inserted into the catheter, moves along the direction of extension of the catheter, and is drawn out to the end of the catheter and protrudes outward,
The catheter is
a pair of wire draw-out holes at the end communicating with the internal space of the catheter and formed on one side and the other so that the end of the guide wire protrudes outward; and
A connection port is provided on the upper side connected to the operation unit and through which the guide wire can be inserted into the catheter through an injection wire protruding to one side; is formed,
Formed at the center of the injection wire, the guide wire is inserted into a hole penetrating the injection wire and inserted into the catheter,
Inside the distal end of the catheter, a slope is formed in the spaced apart inner space of the pair of wire draw-out holes toward the wire draw-out hole, so that the guide wire selectively moves to the wire draw-out hole along the slope. Rotatable endoscopic retrograde cholangiopancreatography incision.