KR20240015769A - Catheter unit for intraperitoneal ascites drain - Google Patents

Abstract

The present invention relates to a drainage tube unit for ascites drainage, which passes through the bladder wall, which is the standard for dividing the area between the abdominal cavity and the bladder, and has both ends located in the abdominal cavity and the bladder, respectively, and is shaped like a tube to form a flow path through which fluid can move inside. a main conduit portion, an abdominal anchoring portion extending from one end of the main conduit portion, passing through the bladder wall and positioned on the abdominal cavity side, and having an inlet through which ascites in the abdominal cavity flows, and a second end of the main conduit portion. a drainage tube extending and positioned on the bladder side and including a bladder-side anchoring portion formed with an outlet through which ascites is discharged; And, in the process of moving the bladder-side anchoring unit along the guide wire for guiding the drainage tube to the bladder wall, to prevent bladder-side fluid from flowing back into the abdominal cavity-side anchoring unit through the bladder-side anchoring unit. A tubular main body is coupled in a form that surrounds the through hole at the rear end of the anchoring unit, and is provided at the rear end of the tubular main body and is made of an elastically deformable material. The coupling of the tubular main body to the bladder side anchoring unit is prevented by the guide wire. The guide wire is deformed in the process of passing so as not to be received, thereby enabling the guide wire to pass through. After the guide wire is removed, it is restored to its original shape and the gap caused by the guide wire removal is closed, allowing the bladder side fluid to pass through the gap. It includes a cap member including an opening and closing portion that prevents reverse inflow.

Description

Drainage tube unit for ascites drainage {Catheter unit for intraperitoneal ascites drain}

The present invention relates to a drainage tube unit for ascites drainage, and more specifically, to prevent bladder-side fluid from flowing back into the drainage tube while the drainage tube is guided to the bladder wall along the guide wire used during the procedure for ascites drainage. It relates to a drainage tube unit for ascites drainage with an improved structure.

In liver cirrhosis or peritoneal disseminated disease (peritoneal metastasis of cancer, peritoneal carcinomatosis: when cancer metastasizes to the peritoneum from stomach/colon/pancreas/ovarian cancer, etc.), water-filled ascites (ascites) occurs inside the peritoneal cavity. Ascites) symptoms occur. When ascites symptoms worsen, patients experience symptoms such as discomfort, pain, and movement disorders due to abdominal distension.

In this case, as shown in Figures 1 and 2, repeated paracentesis (a procedure to repeatedly pierce the abdomen with a needle and drain the ascites outside the abdomen) must be performed for the purpose of improving symptoms, but the duration of symptom improvement Since this is not long, the patient undergoes paracentesis repeatedly at daily intervals (approximately 2 to 3 liters of ascites are drained per procedure).

This procedure causes a lot of discomfort, such as pain, because it requires piercing the abdomen with a thick needle to the inside of the peritoneum. In addition, as the number of repeated punctures accumulates, many complications occur, such as piercing the intestines, causing intestinal perforation, or bleeding and infection due to the procedure.

Among the methods for draining ascites, catheter insertion through the intestinal wall (PCD: Percutaneous Catheter Drainage) is a method of placing the catheter outside the abdominal wall. It is difficult to maintain the catheter for several days, and the risk of infection increases over time. This limits the patient's movement and causes a lot of discomfort in daily life.

Meanwhile, another method for draining ascites is to use a laparoscope, move the drainage tube to the bladder side along a guide wire, and discharge the ascites into the bladder through a drainage tube that penetrates the bladder wall. In this way, the drainage tube according to the prior art has the function of draining ascites from the abdominal cavity, but when moved along the guide wire, fluid from the bladder side can be reversed into the drainage tube, and after being placed on the bladder wall, fluid from the bladder side can be reversed back to the abdominal cavity. There is a problem with introducing it.

The prior art includes Registered Patent Publication No. 10-1671612.

The present invention was created to solve the above problems, and the purpose of the present invention is to prevent fluid from the bladder side from flowing back into the drainage tube while the drainage tube is guided to the bladder wall, and to prevent fluid inside the bladder, including ascites, from flowing back into the drain tube. The object is to provide a drainage tube unit for ascites drainage that prevents backflow into the abdominal cavity and increases product productivity.

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

The drainage tube unit for ascites drainage according to the present invention to achieve the above object passes through the bladder wall, which is the standard for dividing the area between the abdominal cavity and the bladder, and has both ends located in the abdominal cavity and bladder, respectively, and a flow path through which fluid can move is formed on the inside. a main conduit portion formed in a tubular shape, an abdominal cavity-side anchoring portion extending from one end of the main conduit portion, passing through the bladder wall and positioned on the abdominal cavity side, and forming an inlet through which ascites in the abdominal cavity flows; a drainage pipe extending from the other end of the main conduit portion and located on the bladder side, including a bladder-side anchoring portion formed with an outlet through which ascites is discharged; And, in the process of moving the bladder-side anchoring unit along the guide wire for guiding the drainage tube to the bladder wall, to prevent bladder-side fluid from flowing back into the abdominal cavity-side anchoring unit through the bladder-side anchoring unit. It is joined in a form that surrounds the through hole at the rear end of the anchoring part. It is formed of a tubular body and a rear end of the tubular body and is made of an elastically deformable material, so that the guide wire is not disturbed by the guide wire when coupled to the bladder side anchoring portion. An opening and closing part that allows the passage of the guide wire, and after the guide wire is removed, it is restored to its original shape and closes the gap caused by the guide wire removal, preventing bladder fluid from flowing back through the gap. It includes; a cap member including a.

The opening and closing portion is connected to the rear end of the tubular main body and is cut radially with respect to the center to form a plurality, and is made of an elastically deformable material, so that the guide wire is deformed in the process of passing and restores its shape in the process of removal. It can be.

The cap member preferably further includes a pressing portion that protrudes inside the tubular body portion to secure a large coupling force between the tubular body portion and the bladder-side anchoring portion.

The present invention is formed in the form of a conduit, is coupled to the bladder-side anchoring part in a form that surrounds the bladder-side anchoring part of the drainage tube, and is positioned at a position corresponding to the outlet of the bladder-side anchoring part so that the outlet can be selectively opened and closed. It may further include a membrane having a tubular structure including a check valve.

The membrane is made of an elastically deformable material, so that it can be coupled to the bladder-side anchoring portion by deformation, and can be in close contact with the bladder-side anchoring portion by a restoring force after deformation.

In the present invention, it is preferable that the outer surface of the bladder-side anchoring portion and the corresponding inner surface of the membrane have a concavo-convex shape to ensure greater fixing force after coupling.

In the drainage tube unit for ascites drainage according to the present invention having the above-described configuration, the tubular body portion of the cap member is coupled in a form that surrounds the through hole at the rear end of the bladder-side anchoring portion, and the opening and closing portion of the cap member is connected to the rear end of the tubular body portion. It is provided in and is made of an elastically deformable material, which causes deformation in the process of passing the guide wire, enabling the passage of the guide wire. After the guide wire is removed, the shape is restored and the gap caused by the guide wire removal is restored to its own structure. By closing the drainage tube to the bladder wall, it prevents fluid from the bladder side from flowing back into the drainage tube, suppresses the backflow of fluid inside the bladder, including ascites, into the abdominal cavity, and increases product productivity. It has the effect of telling.

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

Figures 1 and 2 are diagrams for explaining the surgical procedure for ascites drainage according to the prior art.
Figure 3 is a conceptual diagram showing the process of placing a drainage tube unit for ascites drainage on the bladder wall by laparoscopy according to an embodiment of the present invention.
Figure 4 is a perspective view for explaining an embodiment of the present invention.
Figure 5 is a view for explaining a cap member employed in one embodiment of the present invention.
Figure 6 is a cross-sectional view taken along line VI-VI of Figure 5.
Figure 7 is a view showing the operating state of the cap member employed in one embodiment of the present invention.
Figure 8 is a diagram for explaining the membrane employed in one embodiment of the present invention.
Figure 9 is a view showing a state in which the outlet is opened and closed by the check valve of the membrane employed in one embodiment of the present invention.
Figure 10 shows a drainage pipe unit for ascites drainage according to another embodiment of the present invention, and is a diagram for explaining the uneven shape adopted in another embodiment of the present invention.

Hereinafter, a drainage tube unit for ascites drainage according to an embodiment of the present invention will be described in detail with reference to the attached drawings.

Figure 3 is a conceptual diagram showing the process in which a drainage tube unit for ascites drainage according to an embodiment of the present invention is placed on the bladder wall by laparoscopy, Figure 4 is a perspective view for explaining an embodiment of the present invention, and Figure 5 is a It is a drawing for explaining the cap member employed in one embodiment of the present invention. FIG. 6 is a cross-sectional view taken along VI-VI of FIG. 5, and FIG. 7 is a view showing the operating state of the cap member employed in one embodiment of the present invention. Figure 8 is a diagram for explaining the membrane employed in one embodiment of the present invention, and Figure 9 is a diagram showing a state in which the outlet is opened and closed by the check valve of the membrane employed in one embodiment of the present invention.

As shown in these drawings, the drainage pipe unit for ascites drainage according to an embodiment of the present invention includes a drainage pipe 100 and a cap member 200.

The drainage tube 100 passes through the bladder wall 10, which is the standard for dividing the area between the abdominal cavity (B) and the bladder (A), and both ends are located in the abdominal cavity (B) and the bladder (A), respectively. The drainage pipe 100 includes a main conduit portion 110, an abdominal cavity-side anchoring portion 120, and a bladder-side anchoring portion 130 to allow fluid, including ascites, to move from the abdominal cavity to the bladder.

As shown in FIGS. 3 and 4, the main conduit portion 110 of the drainage tube 100 is shaped like a tube, has a flow path for fluid movement on the inside, and is disposed at both ends in the abdominal cavity and bladder, respectively. The main conduit portion 110 is capable of shape deformation and restoration and may be made of a flexible, corrosion-resistant material, and both ends are connected to the abdominal cavity anchoring portion 120 and the bladder anchoring portion 130, respectively. .

In addition, the abdominal cavity-side anchoring portion 120 of the drainage tube 100 extends from one end of the main conduit portion 110, passes through the bladder wall 10, and is located on the abdominal cavity B side. The abdominal cavity-side anchoring unit 120 is provided with inlets 121 that communicate with the flow path between the abdominal cavity B and the main conduit portion 110, and the fluid (ascites in the abdominal cavity) flowing into the inlet 121 flows into the flow path. Let it be moved to . The abdominal cavity-side anchoring unit 120 has a tubular structure and is made of a material capable of changing and restoring its shape, and is integrated with the main conduit unit 110.

The bladder side anchoring portion 130 of the drainage pipe 100 extends from the other end of the main conduit portion 110 and is located on the bladder A side. In addition, the bladder side anchoring part 130 has an outlet so that the fluid that flows into the inlet 121 of the abdominal cavity side anchoring part 120 and passes through the passage of the main conduit part 110 can be discharged into the bladder (A). (131) are provided. Here, the discharge ports 131 communicate with the flow path of the main conduit portion 110 and the inside of the bladder A, and may be formed in plural numbers along the circumferential direction of the bladder side anchoring portion 130.

Referring to Figures 5 and 6, the cap member 200 is used in the process of moving the bladder-side anchoring portion 130 along the guide wire 30 for guiding the drainage tube 100 to the bladder wall 10. It is intended to prevent bladder-side fluid from flowing back into the abdominal cavity-side anchoring part 120 through the bladder-side anchoring part 130 and includes a tubular body part 210 and an opening and closing part 220.

The tubular body portion 210 of the cap member 200 is made in the form of a tube and has a structure surrounding the bladder side anchoring portion 130 and the rear end through hole 132 of the bladder side anchoring portion 130. It is coupled to the side anchoring portion 130. The tubular body portion 210 may be made of a material capable of elastic deformation and may be deformed in shape to be coupled to the bladder-side anchoring portion 130 and restored to its shape to be in close contact with the bladder-side anchoring portion 130. In addition, the tubular body portion 210 is connected to the opening/closing portion 220 at a portion opposite to the rear end through hole 132.

The opening and closing portion 220 of the cap member 200 is provided at the rear end of the tubular body portion 210 and is disposed opposite to the rear end through hole 132 of the bladder side anchoring portion 130. The opening and closing portion 220 is formed of an elastically deformable material such as silicon, and is provided with a guide wire ( 30) can be passed.

That is, the opening and closing part 220 is a process through which the guide wire passes when the bladder-side anchoring part 130 of the drainage tube 100 is guided to the bladder side along the guide wire 30, as shown in FIG. Deformation occurs to enable passage of the guide wire 30. In addition, the opening/closing part 220 is restored to its original shape after the guide wire 30 is removed, thereby closing the gap resulting from the guide wire removal, allowing bladder-side fluid to enter the bladder-side anchoring part 130 through the gap. It is possible to prevent reverse inflow into the rear end through hole 132. Here, the opening and closing portion 220 is in close contact with the outer surface of the guide wire when the guide wire passes through and forms a gap corresponding to the outer diameter of the guide wire, and when the guide wire is removed, the shape is restored and the gap is closed.

In the drainage tube unit for ascites drainage according to an embodiment of the present invention having this configuration, the tubular body portion 210 of the cap member 200 surrounds the rear through hole 132 of the bladder side anchoring portion 130. It is coupled, and the opening and closing portion 220 of the cap member is provided at the rear end of the tubular body portion 210 and is formed of an elastically deformable material, so that the guide wire 30 is deformed in the process of passing through the guide wire 30. It allows the passage of the guide wire 30, and the shape is restored after the guide wire 30 is removed, thereby closing the gap due to the removal of the guide wire 30 due to its structure, thereby guiding the drainage tube 100 to the bladder wall 10. In the process, it prevents fluid from the bladder side from flowing back into the drainage tube, prevents fluid inside the bladder, including ascites, from flowing back into the abdominal cavity, and has the effect of increasing product productivity.

Meanwhile, as shown in FIG. 6, the cap member 200 is made of an elastically deformable material and is connected to the rear end of the tubular main body 210, and has a cut portion S cut radially with respect to the center. It includes and is formed in plural, each shape is deformed when the guide wire 30 passes through the center, and each shape can be smoothly restored when the guide wire 30 is removed. That is, when the guide wire 30 passes through the center of the cap member 200, the end facing the center deforms in shape to form a gap, and when the guide wire is removed, the end restores its shape to form a gap at the center side. closes.

In addition, the cap member 200 preferably further includes a pressing portion 230, as shown in FIG. 7. The pressing portion 230 of the cap member 200 protrudes from the inside of the tubular body portion 210 and is provided in plurality in opposite directions. At this time, the pressing portion 230 is integrally formed on the inside of the tubular body portion 210 and has elasticity, so that when the cap member 200 is coupled to surround the rear through hole side of the bladder side anchoring portion 130. It is in close contact with the outer surface of the bladder-side anchoring portion 130, and allows greater coupling force between the tubular body portion 210 and the bladder-side anchoring portion 130 to be secured.

Meanwhile, this embodiment may further include a membrane 300 as shown in FIGS. 4 and 8. The membrane 300 is coupled to the bladder-side anchoring portion 130 of the drainage pipe 100 and is provided with a check valve 210 for opening and closing the outlet 131 of the bladder-side anchoring portion 130. The membrane 300 is formed in the form of a conduit and has a structure surrounding the bladder-side anchoring portion 130, and is coupled to the bladder-side anchoring portion 130. The membrane 300 is flexible and can be made of a corrosion-resistant material that can change and restore its shape, so that it can be changed in shape during the installation process on the bladder side along with the bladder-side anchoring portion 130 and after installation. The shape is restored and placed on the bladder side.

The check valve 310 of the membrane 300 is provided at a position corresponding to the outlet 131 of the bladder side anchoring part 130 and selectively opens and closes the outlet 131. One part of the check valve 210 is connected to the membrane 300, and the other part changes and restores its position by the flow of fluid discharged to the outlet 131, thereby opening and closing the outlet.

That is, as shown in FIG. 9, the check valve 310 is changed in shape and position according to the flow of the fluid when fluid is discharged through the outlet 131 of the bladder-side anchoring part 130, so that the outlet 131 ) is opened, and when there is no fluid flow after the discharge, the shape is restored by elasticity and the position is restored to close the outlet and prevent the fluid in the bladder from flowing back into the outlet 131. In addition, the check valve 310 closes the outlet 131 by receiving pressure from the bladder-side fluid when the bladder-side fluid attempts to flow back into the outlet 131 in the absence of multiple discharges.

In this embodiment, the check valve 310 is placed in the discharge port 131 only by fitting the membrane 300 and the bladder side anchoring portion 130, and the check valve 310 moves through the plurality of flows. By selectively opening and closing the outlet 131, it is easy to implement a valve configuration to prevent backflow of ascites discharged into the drainage tube for drainage of ascites, and to prevent backflow of fluid inside the bladder, including ascites, into the abdominal cavity. It has the effect of preventing damage and increasing product productivity.

Meanwhile, the membrane 300 is formed of an elastically deformable material, is coupled to the bladder-side anchoring portion 130 by its deformation, and comes into close contact with the bladder-side anchoring portion 130 by a restoring force after the deformation, thereby securing the bladder. It is coupled to the side anchoring portion 130 and the check valve 310 is disposed on the discharge port 131 side.

In other words, the membrane 300 is deformed so that the area of the internal space can be expanded, and in the deformed state, it is inserted into the bladder-side anchoring part 130. The membrane 300 is restored to its shape after being combined, and when the area of the internal space is reduced due to the restoration of its shape, the membrane 300 comes into close contact with the bladder-side anchoring part 130 and is coupled to the bladder-side anchoring part. Here, the shape deformation of the membrane 300 may be implemented by a jig or tweezers that supports the membrane and can apply an external force to the membrane.

Referring to FIG. 8, the abdominal cavity-side anchoring portion 120 employed in this embodiment is formed of an elastically deformable material, and when deformed, passes through the inside of the laparoscope while being disposed long along the same axis as the main conduit portion 110. Thus, it is preferably configured to approach the bladder wall 10, and to be wound around the bladder wall 10 by being wound into a ring shape by elastic restoring force when it is separated from the inside of the laparoscope after the approach.

In addition, the bladder side anchoring portion 130 is formed of an elastically deformable material and is disposed long along the same axis as the main conduit portion 110 by deformation so that it passes through the inside of the laparoscope and approaches the bladder wall 10, After access, when separated from the laparoscope, it can be placed in the bladder (A) in a ring-shaped state due to elastic restoring force.

In this embodiment, the abdominal cavity-side anchoring portion 120 of the drainage tube 100 is located in the abdominal cavity B, is wound into a ring shape by elastic restoring force, and is caught on the bladder wall 10, and the bladder-side anchoring portion 130 ) is located in the bladder (A) in a state in which it is wound into a ring shape by elastic restoring force and prevents the separation of the drainage tube 100 from the bladder wall 10, thereby providing a fixing force to the bladder wall, which is the standard for dividing the area between the abdominal cavity and the bladder. Not only does it increase the volume, but it can also prevent pain and complications caused by repeated procedures for ascites drainage and minimize patient discomfort.

The drainage tube unit for ascites drainage according to an embodiment of the present invention has been described above. Hereinafter, a drainage pipe unit for ascites drainage according to another embodiment of the present invention will be described.

Figure 10 shows a drainage pipe unit for ascites drainage according to another embodiment of the present invention, and is a diagram for explaining the uneven shape adopted in another embodiment of the present invention.

This embodiment is largely similar in structure to the previously described embodiment, but there is a difference in the structure of the bladder-side anchoring portion 130 and the membrane 300 of the drainage tube 100.

That is, the bladder side anchoring portion 130 employed in this embodiment may include a convex-convex shape on the outer surface corresponding to the inner surface of the membrane 300. In addition, the membrane 300 preferably includes a convex-convex shape on the outer surface corresponding to the inner surface of the bladder side anchoring portion 130. The uneven shape formed on the outer surface of the bladder-side anchoring part 130 and the inner surface of the membrane 300, respectively, is such that when the membrane 300 is coupled to the bladder-side anchoring part 130, the bladder-side anchoring part 130 It is possible to further secure the fixing force of the membrane 300 and prevent the membrane 300 from arbitrarily moving in the bladder side anchoring portion 130.

The concavo-convex shape 400 may be formed entirely or only partially on the outer surface of the bladder side anchoring portion 130 and the inner surface of the membrane 300 to face each other. In addition, the concavo-convex shape 400 is formed integrally with the outer surface of the bladder-side anchoring part 130 and the inner surface of the membrane 300, or is formed in the form of a patch to form a shape between the outer surface of the bladder-side anchoring part 130 and the membrane 300. It may be attached to the inner surface in various ways.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited to the embodiments described above, but is defined by the claims, and various modifications and developments can be made in the technical field to which the present invention pertains. Self-explanatory.

A: Bladder B: Abdominal cavity
10: bladder wall 20: laparoscope
30: Guide wire 100: Drainage tube
110: main conduit part 120: abdominal cavity anchoring part
121: Inlet 130: Bladder side anchoring part
131: outlet 132: rear end through hole
200: cap member 210: tubular body portion
220: opening and closing part 230: pressurizing part
300: membrane 310: check valve
400: uneven shape

Claims (6)

A main conduit section that passes through the bladder wall, which is the standard for dividing the area between the abdominal cavity and the bladder, and has both ends located in the abdominal cavity and the bladder, respectively, and has a tube shape so that a flow path capable of fluid movement is formed on the inside, and extends from one end of the main conduit section. an abdominal cavity-side anchoring portion that is formed and located on the abdominal cavity side after passing through the bladder wall, and is formed with an inlet through which ascites in the abdominal cavity flows; and an abdominal cavity-side anchoring portion that is formed extending from the other end of the main conduit portion and is located on the bladder side, and is formed on the bladder side. A drainage pipe including a bladder-side anchoring portion formed with an outlet through which the gas is discharged; and
This is to prevent bladder-side fluid from flowing back into the abdominal cavity-side anchoring unit through the bladder-side anchoring unit during the process of moving the bladder-side anchoring unit along the guide wire for guiding the drainage tube to the bladder wall. Combined in a form that surrounds the rear through hole It is formed of a tubular main body and a rear end of the tubular main body and is made of an elastically deformable material, so that the guide wire is not deformed in the process of passing so that the coupling of the tubular main body to the bladder side anchoring portion is not disturbed by the guide wire. An opening and closing part that allows the passage of the guide wire, and after the guide wire is removed, it is restored to its original shape and closes the gap caused by the guide wire removal, preventing bladder fluid from flowing back through the gap. A cap member comprising a; A drainage pipe unit for ascites drainage comprising a.
According to paragraph 1,
The opening and closing part,
It is connected to the rear end of the tubular main body, but is cut radially with respect to the center to form a plurality, and is formed of an elastically deformable material, so that the shape is deformed in the process of passing the guide wire and the shape is restored in the process of removal. A drainage tube unit for draining ascites.
According to paragraph 1,
The cap member is,
A drainage tube unit for ascites drainage, characterized in that it further includes a pressurizing portion that protrudes inside the tubular body portion and ensures a large coupling force between the tubular body portion and the bladder side anchoring portion.
According to paragraph 1,
A check valve is formed in the form of a conduit, is coupled to the bladder-side anchoring portion in a form surrounding the bladder-side anchoring portion of the drainage tube, and is provided at a position corresponding to the outlet of the bladder-side anchoring portion to selectively open and close the outlet. A drainage tube unit for ascites drainage, characterized in that it further comprises a membrane having a tube structure.
According to paragraph 4,
The membrane is,
A drainage tube unit for ascites drainage, characterized in that it is formed of an elastically deformable material, is coupled to the bladder-side anchoring portion by deformation, and is in close contact with the bladder-side anchoring portion by a restoring force after deformation.
According to paragraph 4,
A drainage tube unit for ascites drainage, characterized in that the outer surface of the bladder-side anchoring portion and the corresponding inner surface of the membrane have a concave-convex shape to secure greater fixing force after joining.

Images