KR20160081184A - Multi-hole stent for biliary tract - Google Patents

Abstract

The present invention relates to a multi-hole stent for biliary tract including a hollow cylindrical body forming multiple cells by intersecting wires and a thin film installed to be in contact with an inner lateral surface of the body. At least one discharge hole is formed in the thin film. The multi-hole stent for biliary tract recovers a narrowed diameter by being installed in a stenosed part within biliary tract through the discharge hole, thereby securing a passage for discharging bile. At the same time, the multi-hole stent for biliary tract is capable of preventing lesions such as a malignant tumor in the stenosed part from entering inside the stent due to the growth of the lesions and the stenosed part from being narrow again by installing the thin film on the inner lateral surface of the body. Moreover, the multi-hole stent for biliary tract is capable of providing a passage for discharging a body fluid generated in branches branched out from the biliary tract through the multiple holes formed in the thin film.

Description

[0001] MULTI-HOLE STENT FOR BILIARY TRACT [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a stent for denture.

Bile duct stenosis is usually divided into two types: benign biliary stricture and malignant biliary stricture, where benign biliary stricture occurs after surgery such as liver transplantation or gallbladder removal, or is caused by diseases such as cholangitis, , Biliary tract cancer, and other malignant tumors.

In this case, stent implantation is used as the main treatment method to facilitate the discharge of bile by narrowing the diameter of bile duct used as a pathway of bile, which is a digestive enzyme produced by hepatic stenosis caused by stenosis.

In order to resolve the obstructive biliary obstruction in the biliary tract, it is necessary to expand the narrowed diameter to maintain the growth rate of lesions such as malignant tumor at the site of stenosis, (Hereinafter referred to as " prior art ") of Korean Patent Registration No. 10-1065365 as a prior art related to such a stent.

However, in the case of the conventional technique, when the stent is provided in the form of a wire and is provided in the stenotic region of the bile duct, the stenotic region is initially expanded in the initial stage, but a lesion such as a malignant tumor is opened The restenosis occurred frequently after a certain period of time after the growth.

In addition, in order to prevent restenosis, when a cover is attached to a stent for wire stiffness, which is provided in the form of a wire of the prior art, and is provided at a stenosis site, entrance of the stent into the stent due to lesion growth is blocked, The inflow of the biliary fluid may be somewhat inhibited, resulting in stagnation of the bile, and occlusion may occur in the pathway of body fluids originating from a plurality of branches formed around the biliary duct.

The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a bile pathway through expansion of a stenotic region by a lesion in a bile duct to prevent restenosis And to provide a technique for securing an evacuation pathway for body fluids generated from side branches in the bile duct.

In order to achieve the above object, the present invention provides a multi-hole stent for a double-sided multi-hole stent comprising: a body formed of a plurality of cells by crossing of wires and provided in a hollow cylindrical shape; And a coating disposed to contact the inner surface of the body, wherein the coating has at least one or more discharge holes.

Here, the discharge hole is formed to have a smaller size than a cell formed on the body.

In addition, the discharge hole is formed to be located inside the cell formed in the body when the coating is provided on the inner surface of the body.

The body includes a body portion formed in a hollow cylindrical shape, and upper and lower head portions formed at both ends of the body portion with an expanded diameter relative to the body portion, wherein the coating is positioned on the inner side of the body portion And upper and lower head coating portions positioned on the inner surfaces of the upper and lower head portions. At least one or more discharge holes are formed in the body coating portion.

The present invention has the following effects.

First, by restricting the narrowed diameter that is provided at the stenotic region in the bile duct, it is possible to secure the discharge route of bile.

Second, it is possible to prevent entry into the stent and restenosis due to the growth of a lesion such as a malignant tumor in the stenotic region by providing a coating on the inner surface of the body.

Third, it is possible to provide a discharge pathway of body fluids arising from the peripheries around the bile duct through a plurality of discharge holes formed in the film.

Fourth, when removing the multi-hole stent for the installed multi-hole stent, the phase of a plurality of discharge holes formed in the capsule is simultaneously moved with the stent in the removal direction, so that the lesion entering and protruding through the multi- Lt; / RTI >

Fifth, when a lesion such as a malignant tumor occurring in a stenotic region is removed and extracted, a protruding lesion entering through a plurality of vent holes formed in the stent can be easily removed by inserting a removing means into the stent.

Sixth, a certain portion of the stenotic region is inserted through the plurality of vent holes formed in the capsule, thereby providing a higher fixing force for preventing movement of the entire stent.

1 is a perspective view illustrating a biliary type multi-hole stent according to the present invention.
2 is a front view showing a biliary type multi-hole stent according to the present invention.
3 is an exploded perspective view showing a biliary type multi-hole stent according to the present invention.
FIG. 4 shows a growth pattern of a stenotic region according to the installation of a stenotic site of a conventional wire-type stent.
FIG. 5 illustrates a growth pattern of a stenotic region according to a conventional stent of a cover type and a biliary type multi-hole stent according to the present invention.
6 to 8 are perspective views illustrating various embodiments of a biliary type multi-hole stent according to the present invention.

The preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings, in which the technical parts already known will be omitted or compressed for the sake of brevity.

<Description of Components and Action of Multi-hole Stent for Demanding Shield>

1 to 3, the multi-hole stent 100 for a double-walled stent of the present invention includes a body 110; And a coating (120).

The body 110 forms a plurality of cells by intersection of the wires, and is provided in a hollow cylindrical shape. Here, the body 110 is more specifically a body part 111 located at the center as shown in FIG. 3 and provided in a hollow cylindrical shape; An upper head part 112 formed at one end of the body part 111 and extending to a diameter larger than the diameter of the body part 111; And a lower head portion 113 formed at the other end of the body portion 111 to have a diameter that is extended with respect to the diameter of the body portion 111. [

The plurality of cell structures opened by the shape of the body 110 and the intersection of the wires constituting the body may be variously formed without being limited to a specific form.

The coating 120 is disposed to contact the inner surface of the body 110, and at least one or more discharge holes 125 are formed in the coating 120.

Here, the coating may be selected from PTFE (Polytetrafluoroethylene), silicone, polyurethane, polyester, polypropylene, polyethylene, polyolefin, HDPE (high density polyethylene), and expanded PTFE &Lt; / RTI &gt; may be selected within the range of known materials.

Here, the coating 120 may include a body covering part 121 located on the inner surface of the body part 111 as shown in FIG. 3 so as to correspond to the configuration of the body 110; And upper and lower head coating portions 122 and 123 located on the inner surfaces of the upper and lower head portions 112 and 113, respectively.

In addition, the discharge hole 125 is provided with a circular hole having a smaller diameter than the plurality of cells formed in the body 110, as shown in FIG. When the film 120 is provided on the inner side of the body 110, the film 120 is formed to correspond to the inner space of the cell as shown in FIG.

Here, the formation position of the discharge hole 125 in the film 120 may be variously formed in a structure that is smaller than the size of the cell provided in the body 110 and is provided to be located in the cell, and more specifically, It is preferable that at least one film is formed on the coating portion 121.

The multi-hole stents 100, 200, 300, and 400 for use in the multi-hole stents 100, 200, 300, and 400 having the exhaust holes 125 formed in various forms on the body covering portion 121, As shown in FIG. 8 through FIG.

 In other words, the position of the discharge hole 125 may be formed in various directions on the body shell portion 121 by various embodiments, but the size of the discharge hole 125 and the size of the discharge hole 125 The position is smaller than the size of the cell formed in the body 110 and is formed in the film 120 so as to be located in the cell when coupled with the body 110. [

For example, the multi-hole stent 200 for double-sided according to the second embodiment is formed along a circumferential direction of a predetermined heat and both ends formed along the central circumferential direction of the body covering portion 221 as shown in Fig. The film 220 is formed so that the discharge hole 225 is located at a size smaller than the cell in the cell constituting the predetermined column.

The vent hole 125 provided in various forms on the capsule 120 plays a variety of roles in comparison with the conventional stent 20 and 30 for improving the stability of the stent in the bile duct Thereby enabling the stent to be applied.

 As shown in FIG. 4 (a), the conventional wire-type stent 20 is installed in the stenosed region 10 to be expanded as compared with the conventional wire-type stent 20 shown in FIG. The wire 23 is formed so as to maintain the expanded constant diameter as shown in Fig. 4 (b). However, in this case, as shown in FIG. 4 (c), the stenosis site 10 in which a lesion such as a malignant tumor develops gradually grows into the cell space in the stent, and as a result, the wire 23 ) And cause restenosis.

Thereafter, in order to prevent entry of lesions such as malignant tumors into the stent and prevent restenosis, a cover-type coating 35 is provided on the wire-type stent 20 to form a cover- The conventional cover type stent 30 has a problem of blocking the discharge path of bodily fluid and bile which can be provided from the side through unconditional occlusion as shown in Fig. 5 (a) did.

5 (b), the discharge hole 125 is formed in the coating film 120 in a predetermined pattern, and the biliary stent 100 according to the present invention, It is possible not only to secure the discharge route but also to prevent the restenosis by reducing the entry of excessive lesions, and to secure the discharge pathway of bodily fluid generated from a plurality of side branches formed around the bile duct and bile provided through the side surface.

5 (b), a portion of the discharge hole 125 formed in the coating 120 is discharged through the discharge hole 125A into which the lesion does not extend to the inside, And the vent hole 125B into which a part of a lesion such as a malignant tumor enters also serves as an auxiliary space for the removal of the entered lesion.

For example, in a process of removing a stent through a pulling member after a predetermined time has elapsed after inserting a multi-hole stent for a fenestration 100, a lesion portion which has grown into the inside of the stent through the vent hole 125B, The foreign matter generated in the stent 100 can be easily removed simultaneously with the multi-hole stent 100 for immobilization due to the phase of the discharge hole 125B moved in association with the pulling of the stent.

In addition, the vent hole 125B of the multi-hole stent 100 for fenestration is expanded to the inside of the stent through the surgical tumor removing means that enters the inside of the stent, so that the lesion can be easily removed and removed By securing and securing the site, removal surgery can be assisted.

In addition, the vent hole 125B in which a part of a lesion such as a malignant tumor enters the stenosed region may be formed by a lesion in the stenosed region 10, It is possible to assist the fixing force on the base 10 to realize higher mobility.

The embodiments disclosed in the present invention are not intended to limit the scope of the present invention but to limit the scope of the technical idea of the present invention. The scope of protection is to be construed in accordance with the following claims, and all technical ideas within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

10: stenosis site
20: Conventional wire-type stent
23: wire of conventional wire type stent
30: conventional cover type stent
33: Conventional cover type stent wire
35: Conventional cover-type stent coating
100, 200. 300, 400: multi-hole stent
110: Body
111:
112: upper head portion
113: Lower head part
120: Coating
121: Body shell part
122: upper head coating portion
123: Lower head coating portion
125: discharge hole

Claims (4)

A body forming a plurality of cells by intersection of the wires and provided in a hollow cylindrical shape; And
And a coating disposed to contact the inner surface of the body,
Characterized in that at least one discharge hole is formed in the film
Multi - hole stent for fenestration.
The method according to claim 1,
And the discharge hole is formed to be smaller in size than a cell formed in the body
Multi - hole stent for fenestration.
3. The method of claim 2,
And the discharge hole is formed to be located inside the cell formed in the body when the film is provided on the inner surface of the body.
Multi - hole stent for fenestration.
The method according to claim 1,
Wherein the body includes a body portion formed in a hollow cylindrical shape and upper and lower head portions formed at both ends of the body portion with a diameter expanded relative to the body portion,
Wherein the coating comprises a body covering part located on the inner side of the body part and upper and lower head covering parts located on the inner side of the upper and lower head parts,
Wherein at least one or more discharge holes are formed in the body covering portion
Multi - hole stent for fenestration.

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