KR102662128B1 - Manufactured method of an anti-migration stent and an anti-migration stent by manufactured method thereof - Google Patents

Abstract

The present invention relates to a method of manufacturing an anti-slip stent that does not slip in the lesion area of the lumen of the human body and to an anti-slip stent manufactured thereby. More specifically, it relates to a method of manufacturing an anti-slip stent manufactured thereby, and more specifically, to a method for forming a first coating film tape on the outer surface of a jig so that a gap is formed between them. Taping is performed in a spiral shape, a jig is inserted inside the stent, and the stent's interlocking and intersection parts are formed in the opposite spiral form of the first coating film tape so that a gap is formed between the second coating film tape on the outer surface of the stent. Taping is performed to prevent slipping, and an anti-slip stent is manufactured by heating and pressurizing the stent so that the first and second coating film tapes are adhered to each other. Then, the jig is removed, and the first and second coating film tapes are placed on the outer surface of the anti-slip stent. It relates to a method of manufacturing an anti-slip stent, characterized in that a plurality of non-overlapping through holes are formed, and an anti-slip stent manufactured thereby.

Description

Method for manufacturing an anti-slip stent and an anti-slip stent manufactured thereby

The present invention relates to a method of manufacturing an anti-slip stent and an anti-slip stent manufactured thereby. In particular, it relates to a method of manufacturing an anti-slip stent that does not slip in a lesion area due to the pressure of body fluid moving in the lumen of the human body and the shaking of the human body; It relates to an anti-slip stent manufactured thereby.

In general, if a lesion area that is narrowed or obstructed due to a tumor or other causes occurs in the lumen of the human body, such as the airway, esophagus, duodenum, biliary tract, urethral tract, etc., normal function cannot be achieved. As shown in Figure 1, the lumen of the human body cannot function normally. A stent (3) was inserted into the lesion area and expanded to enable normal function.

However, when the entire space 3a of the stent 3 is coated with the coating film 3b, there is a risk of slipping at the lesion site due to the pressure of body fluid moving in the lumen of the human body and the shaking of the human body.

So, as shown in FIG. 1, the stent 3 and other stents 3 did not have one or both ends coated with the coating film 3b.

As a result, the plurality of spaces 3a formed at one or both ends of the stent 3 were inserted into the lesion site and caught on the lesion site, thereby preventing the stent 3 from sliding around the lesion site.

However, since the plurality of spaces 3a were located adjacent to each other without any gaps between them, as the lesion area grew, they were connected to each other and grew into a large lump.

As a result, the lumen of the human body was restenosis or occluded by the grown lesion area.

In addition, the stent (3) was difficult to remove from the lumen of the human body due to the grown lesion area, and had to be re-operated with a new stent (3).

Accordingly, Patent Document 1 forms a plurality of spaces by weaving or intersecting wires made of superelastic shape memory alloy in the form of a mesh in a hollow cylindrical shape, and forming a plurality of bent edges in the circumferential direction at both ends and heat treating them. Including a cylindrical stent, wherein the cylindrical stent forms a first artificial blood vessel layer made of PTFE material that is in close contact with the entire inner surface, and a plurality of second artificial blood vessel layers made of PTFE material that are in close contact with a portion of the outer surface at predetermined intervals. As one artificial vascular layer and a plurality of second artificial vascular layers are heated and fused to each other while surrounding the cylindrical stent, a first section having a plurality of blocked spaces and a second section having a number of remaining unoccluded spaces are formed. It is formed in a plurality, and when an external force occurs, the space portion of each first section is fixed to the first and second artificial blood vessel layers that are adsorbed to each other, so the shape is not deformed, and when an external force occurs, the space portion of each second section is fixed to the second artificial blood vessel layer. Since it is not fixed to the first artificial vascular layer, which is not adsorbed due to the absence of an artificial vascular layer, the shape is deformed, so that each first section is inserted and caught by pressing the lesion area, and each second section is inserted into the space and is caught by the lesion area. A stent with improved anti-slip function was provided.

In addition, Patent Document 2 includes a body that forms a plurality of cells by crossing wires and is provided in a hollow cylindrical shape; and a film installed to contact the inner surface of the body, 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 compared to the body portion. The film includes a body film located on the inner surface of the body and upper and lower head films located on the inner surface of the upper and lower head parts. A plurality of discharge holes are formed in the body film, and the body film is formed in the body film. When the film is installed in contact with the inner surface of the body, the plurality of discharge holes formed are located inside the cell formed in the body and are provided in a smaller size than the cell formed in the body, and when the stent is installed in the body film, the stent is In the area that is in contact with the lesion in the lumen where the stent is installed, multiple discharge holes are formed so that the lesion can enter through growth, and when installing the stent in the body capsule, the stent is installed in the area that is not in contact with the lesion in the lumen where the stent is installed. Provided is a multi-hole stent for the biliary tract, characterized in that the plurality of discharge holes are formed to ensure the discharge path of body fluid generated from the plurality of side branches formed around the lumen.

However, in the case of Patent Document 1, because the first artificial blood vessel layer surrounded the entire inner surface of the cylindrical stent, it was difficult to insert the lesion site into the space of the cylindrical stent.

In other words, it was difficult for the space portion of the cylindrical stent to get caught in the lesion site, so the multi-hole stent for biliary tract of Patent Document 1 had a risk of slipping in the lesion site.

And, in the case of Patent Document 2, the discharge hole had to be formed in the body shell.

In other words, unnecessary drilling work was required to form small discharge holes one by one in the multi-hole stent for biliary tract of Patent Document 2.

Patent Document 1: Domestic Patent No. 10-1772482 (registered on August 23, 2017) Patent Document 2: Domestic Patent No. 10-1650517 (registered on August 17, 2016)

Accordingly, the present invention minimizes the growth of the lesion area compared to the prior art, and prevents the lesion area from slipping more than before due to the pressure of body fluids moving in the lumen of the human body and the shaking of the human body, and has a curved shape to fit the lumen of the human body. The purpose is to provide a method of manufacturing an anti-slip stent that is different from the conventional one, and an anti-slip stent manufactured thereby.

In addition, the present invention aims to provide a method for manufacturing an anti-slip stent that can form a through hole into which a lesion is inserted more easily than before and an anti-slip stent manufactured thereby.

In order to achieve the above object, the present invention performs a taping operation of winding the first coating film tape on the outer surface of the jig in a spiral form so that a gap is formed between them, and a plurality of spaces and cross-links are formed with a wire made of a superelastic shape memory alloy. A jig is inserted into the inside of a hollow cylindrical stent that is heat treated by intersecting and weaving it in a mesh form to form rims and intersections, and a gap is formed between the second coating film tape on the outer surface of the stent and the first coating film tape. Taping is performed to avoid misalignment and intersection in an opposite spiral shape, and an anti-slip stent is manufactured by heating and pressurizing the stent so that the first and second coating film tapes are adhered to each other. Then, the jig is removed from the anti-slip stent. Provided is a method for manufacturing an anti-slip stent, wherein a plurality of through holes that do not overlap with the first and second coating film tapes are formed on the outer surface of the anti-slip stent, and an anti-slip stent manufactured thereby.

In the present invention, because the lesion area grows dispersedly through a plurality of through holes that are not adjacent to each other, it has the effect of preventing the lesion area from connecting with each other and growing into a large lump as it grows, compared to the conventional method.

In addition, as the multiple through holes are caught in the lesion area, the anti-slip stent has the effect of being fixed to the lesion area.

In other words, the growth of the lesion area is minimized compared to the conventional method, and the anti-slip stent is less likely to slip in the lesion area than before due to the pressure of body fluids moving in the lumen of the human body and the shaking of the human body.

In the present invention, since the staggered portion and intersection portion of the stent are not fixed to the first and second coating film tapes wound in opposite spiral shapes, the anti-slip stent has the effect of having compliance different from that of the prior art.

In addition, because the coating film is partially, rather than entirely, formed on the anti-slip stent by the first and second coating film tapes wound in opposite spiral shapes, the anti-slip stent has the effect of having different compliance than before.

In other words, there is an effect that the anti-slip stent is transformed into a curved shape differently from the conventional one to fit the curved lumen of the human body.

In the present invention, since the first and second coating film tapes are wound in opposite spiral shapes, there is an effect of forming a plurality of through holes on the outer surface of the anti-slip stent so that they are not located adjacent to each other.

In other words, there is an effect that the through hole into which the lesion site is inserted can be formed more easily than in the past, which requires drilling.

The present invention has the effect of minimizing the growth of the lesion area compared to the prior art because the lesion area grows while being caught in the wire, staggered part, and intersection area located in the through hole.

In other words, it is more effective in preventing restenosis or occlusion of the lumen of the human body by the lesion site than before.

In addition, after completion of treatment, removal of the stent is easier than before.

In the present invention, since the lesion area grows without being caught in the space located in the through hole, the anti-slip stent has the effect of being caught more on the lesion area than before to prevent it from slipping in the lesion area.

In addition, even if the pressure of body fluids moving in the lumen of the human body and the shaking of the human body occur, there is an effect of preventing jamming of the lesion area, the wire, the staggered portion, and the intersection portion.

In other words, it has the effect of preventing bleeding at the lesion site due to jamming, unlike before.

The present invention has the effect of increasing or decreasing the number of through holes when the widths of the first and second coating film tapes in the longitudinal direction of the anti-slip stent are the same or different from each other.

In other words, there is an effect of controlling the degree to which the anti-slip stent is caught in the lesion area, unlike before.

In the present invention, when the spacing between the first and second coating tapes is constant, a plurality of through holes of a certain size are formed, and the plurality of through holes of a certain size have the effect of being caught and fixed at the lesion site where they are inserted.

Additionally, if the spacing between the first and second coating tapes is not constant, multiple through holes of various sizes are formed, which has the effect of fixing the multiple through holes of various sizes to the lesion area where they are inserted.

In other words, there is an effect of controlling the degree to which the anti-slip stent is caught in the lesion area, unlike before.

In the present invention, since the acute angle between the center of the longitudinal direction of the anti-slip stent and the first and second coating film tapes is formed between 0° and 90°, the closer the acute angle is to 0 or 90°, the longitudinal direction or width of the anti-slip stent The shape of the through hole is transformed in this direction, which has the effect of stretching.

In other words, the anti-slip stent has the effect of being hung over the lesion area for a long time in the longitudinal or width direction of the lumen of the human body.

In other words, there is an effect of controlling the degree to which the anti-slip stent is caught in the lesion area, unlike before.

In the present invention, since the first and second coating film tapes are made of any one of PTFE, polyurethane, silicone, polyamide, polyester, and fluororesin, a coating film of the selected material is partially formed on the anti-slip stent, not entirely. It has an effect.

The present invention has the effect of further fixing the anti-slip stent to the lesion area because the multiple through holes are caught in the lesion area and the expansion part is caught deep in the lumen of the human body.

In other words, the anti-slip stent has the effect of preventing slipping at the lesion site more than before due to the pressure of body fluid moving in the lumen of the human body and the shaking of the human body.

1 is a front view showing a conventional stent;
2 to 13 are diagrams showing the manufacturing process of an anti-slip stent according to an embodiment of the present invention;
14 to 20 are diagrams showing the use state of an anti-slip stent according to an embodiment of the present invention;
Figures 21 to 32 are diagrams showing the use state of the anti-slip stent according to the first, second, third, fourth, fifth, sixth, seventh, and eighth modifications of the embodiment of the present invention.

Accordingly, the present invention as described above will be described in detail based on the accompanying drawings as follows.

As shown in Figures 2 to 13, in the manufacture of the anti-slip stent 1000 according to an embodiment of the present invention, a gap D1 is formed between the first coating film tape 200 on the outer surface of the jig 100. If possible, perform the taping work by winding it in a spiral shape.

Here, the first coating film tape 200 is made of any one of PTFE (polytetrafluoroethylene), polyurethane, silicone, polyamide, polyester, and fluororesin.

In addition, the space between the first coating film tapes 200 is formed at a constant interval D1.

In addition, the first coating film tape 200 has an acute angle (θ1) between the center of the longitudinal direction of the jig 100 and the first coating film tape 200 between 0°°<θ1<90°, that is, 45°. It is wound around the outer surface of the jig 100 to form .

In addition, a hollow cylindrical shape that is heat-treated by weaving and intersecting wires 310 made of a superelastic shape memory alloy in a mesh shape to form a plurality of space portions 320, interlocking portions 330, and intersection portions 340. The process of inserting the jig 100 into the stent 300 is performed.

Here, the first coating film tape 200 wound around the jig 100 is in close contact with the inner surface of the stent 300.

Additionally, the staggered portion 330 is formed by crossing the wires 310 by bending them, and the intersection portion 340 is formed by crossing the wires 310.

In addition, a staggered portion 330 and an intersection portion 340 are formed in the opposite spiral form of the first coating tape 200 so that a gap D2 is formed between the second coating tape 400 on the outer surface of the stent 300. ), perform winding taping work to avoid.

Here, the second coating film tape 400 is made of any one of PTFE (polytetrafluoroethylene), polyurethane, silicone, polyamide, polyester, and fluororesin.

In addition, the space between the second coating film tapes 400 is formed at a constant interval D2.

In addition, the second coating film tape 400 has an acute angle (θ2) between the center of the longitudinal direction of the stent 300 and the second coating film tape 400 between 0°°<θ2<90°, that is, 45°. It is wrapped around the outer surface of the stent 300 to be formed.

In addition, the width (W2) of the second coating film tape 400 in the longitudinal direction of the stent 300 is different from the width (W1) of the first coating film tape 200 in the longitudinal direction of the jig 100, that is, narrow. is formed

Then, after inserting the stent 300 into the thermal pressurizing device 1, the stent 300 is heated and pressed so that the first and second coating film tapes 200 and 400 are adhered to each other, creating an anti-slip stent ( 1000) is manufactured.

Here, the overlapping portions of the first and second coating film tapes 200 and 400 are bonded to form a coating film to fill the space 320.

Then, after removing the anti-slip stent 1000 from the heat pressurizing device 1, a process of removing the jig 100 from the anti-slip stent 1000 is performed.

Then, a plurality of through holes 500 that do not overlap the first and second coating film tapes 200 and 400 are formed on the outer surface of the anti-slip stent 1000.

Here, the plurality of through holes 500 are not located adjacent to each other with a gap formed between them.

In addition, since the staggered portion 330 and the intersection portion 340 are located in areas where the first and second coating tapes 200 and 400 do not overlap, they are attached to the first and second coating tapes 200 and 400. It becomes a state of freedom and not being fixed.

Additionally, the through hole 500 is located in the wire 310.

In addition, some of the through holes 500 that are not located in the wire 310 are located in the staggered portion 330 and the intersection portion 340, respectively.

In addition, the acute angles (θ1) (θ2) between the longitudinal center of the anti-slip stent 1000 and the first and second coating film tapes 200 and 400 are respectively between 0° and 90°, that is, 45°. As it is formed, the widths (W1) and (W2) of the first and second coating tapes 200 and 400 in the longitudinal direction of the anti-slip stent 1000 are different from each other, that is, the width (W2) of the second coating tape 400 is different from each other. ) is formed to be narrower than the width W1 of the first coating film tape 200.

Because of this, the through hole 500 is formed in a shape similar to an inclined rectangle.

In addition, the first and second coating film tapes 200 and 400 protruding from both ends of the anti-slip stent 1000 are removed.

So, as shown in FIGS. 14 to 17, the anti-slip stent 1000 according to an embodiment of the present invention is operated through a stent delivery device into the lumen 2 of the human body through which food, bile, blood, etc. pass. , the stenosis or occlusion lesion area (2a) that occurs in the lumen (2) of the human body is expanded.

And, the through hole 500 of the anti-slip stent 1000 is caught in the lesion site 2a as the lesion site 2a is inserted.

That is, the anti-slip stent 1000 is fixed so as not to slip at the lesion site 2a.

In addition, the lesion area 2a grows through the through hole 500, but the lesion area 2a grows dispersedly due to the plurality of through holes 500 that are not adjacent to each other.

In addition, the lesion area 2a grows while being caught on the wire 310, the staggered portion 330, and the intersection portion 340, respectively, located in the through hole 500.

That is, the lesion area 2a does not grow significantly toward the inside of the anti-slip stent 1000.

And, as shown in FIGS. 18 to 20, the anti-slip stent 1000 according to an embodiment of the present invention is implanted into the curved lumen 2 of the human body using a stent delivery device.

Then, since the slip-resistant stent 1000 is not fixed to the first and second coating film tapes 200 and 400 at the staggered portion 330 and intersection portion 340, the curved lumen of the human body (2) In response, the staggered portion 330 and the intersection portion 340 are deformed and the shape of the space portion 320 is deformed.

That is, the anti-slip stent 1000 is transformed into a curved shape to fit the curved lumen 2 of the human body, and expands the lesion area 2a that is stenotic or blocked in the lumen 2 of the human body. I will do it.

In addition, the through hole 500 located inside the curved shape of the anti-slip stent 1000 is closed by narrowing the space between the second coating film tapes 400 due to deformation of the space 320, and the anti-slip stent 1000 is closed. The through hole 500 located on the outside of the curved shape of the stent 1000 is maintained in an open state due to the space between the second coating film tapes 400 being widened due to deformation of the space 320.

In addition, the lesion site 2a cannot be inserted into the through hole 500 located inside the curved shape of the anti-slip stent 1000, and the through hole located outside the curved shape of the anti-slip stent 1000 500 is caught in the lesion area 2a as the lesion area 2a is inserted.

That is, the anti-slip stent 1000 is fixed so as not to slip at the lesion site 2a.

And, only in the through hole 500 located outside the curved shape of the anti-slip stent 1000, the lesion area 2a grows while being caught by the wire 310, the staggered portion 330, and the intersection portion 340. .

That is, the lesion area 2a does not grow significantly toward the inside of the anti-slip stent 1000.

And, as shown in FIG. 21, the through hole 500 of the anti-slip stent 1000 according to the first modified example of the embodiment of the present invention is located in the space 320.

That is, the through hole 500 is not located at the wire 310, the crossing portion 330, and the intersection portion 340.

So, as shown in FIG. 21, the anti-slip stent 1000 according to the first modified example of the embodiment of the present invention is implanted into the lumen 2 of the human body through a stent delivery device, thereby forming the lumen 2 of the human body. ) The stenosis or occlusion that occurs in the lesion area (2a) is expanded.

And, the through hole 500 of the anti-slip stent 1000 is caught in the lesion site 2a as the lesion site 2a is inserted.

And, since the through hole 500 is located in the space 320, the lesion area 2a grows without being caught by the wire 310, the staggered part 330, and the intersection part 340.

That is, the through hole 500 is further caught by the grown lesion area 2a.

In other words, the anti-slip stent 1000 is further fixed to prevent slipping at the lesion site 2a.

In addition, when the pressure of the body fluid moving in the lumen 2 of the human body and the shaking of the human body occur, the lesion area 2a is not caught by the wire 310, the staggered portion 330, and the intersection portion 340.

And, as shown in FIG. 22, the anti-slip stent 1000 according to the second modification of the embodiment of the present invention includes the first and second coating film tapes 200 and 400 in the longitudinal direction of the anti-slip stent 1000. ) are formed so that the widths (W1) and (W2) are equal to each other.

Then, a greater number of through holes 500 than in the embodiment are formed on the outer surface of the anti-slip stent 1000.

Therefore, when the anti-slip stent 1000 according to the second modified example of the embodiment of the present invention is operated, a larger number of through holes 500 than in the embodiment are inserted into the lesion site 2a while the lesion site 2a is inserted. ) is caught.

And, as shown in Figures 23 and 24, the distance between the first and second coating film tapes 200 and 400 of the anti-slip stent 1000 according to the third and fourth modifications of the embodiment of the present invention is constant. It is formed with intervals (D1) (D2) that are not used.

Then, through holes 500 having more diverse sizes than the embodiment are formed on the outer surface of the anti-slip stent 1000.

Therefore, when the anti-slip stent 1000 according to the third and fourth modifications of the embodiment of the present invention is operated, the through hole 500 is inserted into the lesion area (2a) of various sizes compared to the embodiment. 2a) is caught.

And, as shown in Figures 25 and 26, the center of the longitudinal direction of the anti-slip stent 1000 according to the fifth and sixth modifications of the embodiment of the present invention and the first and second coating film tapes 200 and 400 ), the acute angles (θ1) and (θ2) are formed respectively smaller or larger than 45° in the embodiment.

Then, on the outer surface of the anti-slip stent 1000, when the acute angles θ1 and θ2 are smaller than 45° in the embodiment, a through hole 500 of a shape similar to a square extending in the longitudinal direction of the anti-slip stent 1000 is provided. is formed

In addition, when the acute angle (θ1) (θ2) of the outer surface of the anti-slip stent 1000 is greater than 45° in the embodiment, a through hole 500 of a shape similar to a square extending in the width direction of the anti-slip stent 1000 is provided. is formed

Therefore, when the anti-slip stent 1000 according to the fifth and sixth modifications of the embodiment of the present invention is operated, the through hole 500, which is longer than the embodiment in the longitudinal or width direction of the anti-slip stent 1000, causes lesions. As the site 2a is inserted, it becomes caught in the lesion site 2a.

And, as shown in FIGS. 27 to 29, the jig 100 of the anti-slip stent 1000 according to the seventh modification of the embodiment of the present invention is formed at one end or both ends of the jig 100, , an expanded tube 110 with a larger diameter than the jig 100 is included.

Here, the expansion portion 110 is formed in various shapes, and may be formed in a shape different from the shape shown in FIG. 27.

In addition, the stent 300 is formed at one or both ends of the stent 300, has a larger diameter than the stent 300, and includes an expansion portion 350 into which the expansion portion 110 is inserted. do.

Here, the expanded tube 350 is formed in the same shape as the expanded tube 110.

In addition, the first coating film tape 200 is wound around the expansion part 110 together with the jig 100 in a spiral shape, and the second coating film tape 400 is wound around the expansion part 350 together with the stent 300. 1. The coating film tape 200 is wound in an opposite spiral shape to avoid the staggered portion 330 and the intersection portion 340.

Therefore, when the anti-slip stent 1000 according to the seventh modification of the embodiment of the present invention is operated, the expansion portion 350 enters deeper into the lumen 2 of the human body than the stent 300 and becomes stuck.

That is, the anti-slip stent 1000 is further fixed to prevent slipping at the lesion site 2a.

And, as shown in FIGS. 30 to 32, the expansion portion 110 of the anti-slip stent 1000 according to the eighth modification of the embodiment of the present invention is partially or entirely attached to the first coating film tape 200. It is wound, and the expansion part 350 is partly or entirely wrapped around the second coating film tape 400.

Here, the second coating film tape 400 wraps around part or all of the expanded tube 350 without avoiding the staggered part 330 and the intersection part 340.

Therefore, when the anti-slip stent 1000 according to the eighth modification of the embodiment of the present invention is operated, the expansion portion 350 enters deeper into the lumen 2 of the human body than the stent 300 and becomes stuck.

That is, the anti-slip stent 1000 is further fixed to prevent slipping at the lesion site 2a.

In the above, the present invention has been shown and described by taking specific preferred embodiments as examples, but the present invention is not limited to the above-described embodiments and is within the scope of the spirit of the present invention and is within the scope of common knowledge in the technical field to which the invention pertains. Various changes and modifications will be possible by those who have it.

100: Jig 110: Expansion part
200: first coating film tape 300: stent
310: wire 320: space part
330: staggered portion 340: intersection portion
350: expansion part 400: second coating film tape
500: Through hole 1000: Anti-slip stent

Claims (30)

A taping operation is performed by winding the first coating film tape 200 on the outer surface of the jig 100 in a spiral shape so that a gap D1 is formed therebetween,
A hollow cylindrical stent (300) made of a shape memory alloy and heat-treated by weaving and intersecting wires (310) in the form of a mesh to form a plurality of spaces (320), interlocking portions (330), and intersections (340). Inside, insert the jig 100,
A staggered portion 330 and an intersection portion 340 are formed in the opposite spiral shape of the first coated tape 200 so that a gap D2 is formed between the second coated tape 400 on the outer surface of the stent 300. Perform winding taping work to avoid
After manufacturing the anti-slip stent 1000 by heating and pressing the stent 300 so that the first and second coating film tapes 200 and 400 are adhered to each other, the jig 100 is installed on the anti-slip stent 1000. remove,
A method of manufacturing an anti-slip stent, characterized in that a plurality of through holes 500 that do not overlap the first and second coating film tapes 200 and 400 are formed on the outer surface of the anti-slip stent 1000. According to paragraph 1,
A method of manufacturing an anti-slip stent, characterized in that the through hole (500) is located in the wire (310). According to paragraph 2,
A method of manufacturing an anti-slip stent, characterized in that some of the through holes (500) are located in the staggered portion (330). According to paragraph 2,
A method of manufacturing an anti-slip stent, characterized in that some of the through holes (500) are located at the intersection (340). According to paragraph 1,
A method of manufacturing an anti-slip stent, characterized in that the through hole 500 is located in the space 320. According to paragraph 1,
A method of manufacturing an anti-slip stent, characterized in that the widths (W1) and (W2) of the first and second coating film tapes 200 and 400 in the longitudinal direction of the anti-slip stent 1000 are formed to be the same or different from each other. According to paragraph 1,
A method of manufacturing an anti-slip stent, characterized in that the spacing (D1) is made constant or not constant. According to paragraph 1,
A method of manufacturing an anti-slip stent, characterized in that the spacing (D2) is made constant or not constant. According to paragraph 1,
The acute angle (θ1) between the longitudinal center of the anti-slip stent (1000) and the first coating film tape (200) is formed between 0°<θ1<90°,
A method of manufacturing an anti-slip stent, characterized in that the shape of the through hole 500 is modified according to the acute angle θ1 formed as 0°< θ1 < 90°. According to paragraph 1,
The acute angle (θ2) between the longitudinal center of the anti-slip stent (1000) and the second coating film tape (400) is formed between 0°<θ2<90°,
A method of manufacturing an anti-slip stent, characterized in that the shape of the through hole 500 is deformed according to the acute angle θ2 formed as 0°< θ2 <90°. According to paragraph 1,
The first coating film tape 200 is a method of manufacturing an anti-slip stent, characterized in that the first coating film tape 200 is made of any one of PTFE (polytetrafluoroethylene), polyurethane, silicone, polyamide, polyester, and fluororesin. According to paragraph 1,
The second coating film tape 400 is a method of manufacturing an anti-slip stent, characterized in that the second coating film tape 400 is made of any one of PTFE (polytetrafluoroethylene), polyurethane, silicone, polyamide, polyester, and fluororesin. According to paragraph 1,
The jig 100 is formed at one or both ends of the jig 100 and includes an expanded tube 110 with a larger diameter than the jig 100,
The stent 300 is formed at one or both ends of the stent 300, has a larger diameter than the stent 300, and includes an expansion portion 350 into which the expansion portion 110 is fitted. Method for manufacturing a non-slip stent characterized by: According to clause 13,
The first coating film tape 200 is wound around the expansion part 110 together with the jig 100 in a spiral shape,
The second coating film tape 400 is wound around the expansion part 350 together with the stent 300 in a spiral shape opposite to that of the first coating film tape 200 to avoid the staggered part 330 and the intersection part 340. Method for manufacturing an anti-slip stent characterized by: According to clause 13,
The expansion portion 110 is partly or entirely wrapped around the first coating film tape 200,
A method of manufacturing an anti-slip stent, characterized in that the expansion portion (350) is partially or entirely wrapped around the second coating film tape (400). A hollow cylindrical stent (300) made of a shape memory alloy and heat-treated by weaving and intersecting wires (310) in the form of a mesh to form a plurality of spaces (320), interlocking portions (330), and intersections (340). On the inner surface, the first coating film tape 200 is formed in a spiral shape so that a gap D1 is formed therebetween,
On the outer surface of the stent 300, a staggered portion 330 and an intersection portion 340 are formed in the opposite spiral shape of the first coated tape 200 so that a gap D2 is formed between the second coated tape 400. Formed to avoid,
The stent 300 is heated and pressed so that the first and second coating film tapes 200 and 400 are adhered to each other, thereby forming an anti-slip stent 1000,
An anti-slip stent, characterized in that a plurality of through holes 500 that do not overlap with the first and second coating film tapes 200 and 400 are formed on the outer surface of the anti-slip stent 1000. According to clause 16,
An anti-slip stent, characterized in that the through hole (500) is located on the wire (310). According to clause 17,
An anti-slip stent, characterized in that some of the through holes (500) are located in the staggered portion (330). According to clause 17,
An anti-slip stent, characterized in that some of the through holes (500) are located at the intersection (340). According to clause 16,
An anti-slip stent, characterized in that the through hole (500) is located in the space (320). According to clause 16,
An anti-slip stent, characterized in that the widths (W1) (W2) of the first and second coating film tapes (200) (400) in the longitudinal direction of the anti-slip stent (1000) are the same or different from each other. According to clause 16,
An anti-slip stent, characterized in that the spacing (D1) is constant or irregular. According to clause 16,
An anti-slip stent, characterized in that the spacing (D2) is constant or irregular. According to clause 16,
The acute angle (θ1) between the longitudinal center of the anti-slip stent 1000 and the first coating film tape 200 is formed between 0°<θ1<90°,
An anti-slip stent, characterized in that the shape of the through hole 500 is deformed according to the acute angle θ1 formed as 0°< θ1 < 90°. According to clause 16,
The acute angle (θ2) between the longitudinal center of the anti-slip stent 1000 and the second coating film tape 400 is formed between 0°<θ2<90°,
An anti-slip stent, characterized in that the shape of the through hole 500 is deformed according to the acute angle θ2 formed of 0°< θ2 < 90°. According to clause 16,
The first coating film tape 200 is an anti-slip stent, characterized in that it is made of any one of PTFE (polytetrafluoroethylene), polyurethane, silicone, polyamide, polyester, and fluororesin. According to clause 16,
The second coating film tape 400 is an anti-slip stent, characterized in that it is made of any one of PTFE (polytetrafluoroethylene), polyurethane, silicone, polyamide, polyester, and fluororesin. According to clause 16,
The stent 300 is formed at one or both ends of the stent 300, and includes an expansion portion 350 with a larger diameter than the stent 300. According to clause 28,
The first coating film tape 200 is formed in a spiral shape on the inner surface of the expansion part 350,
The second coating film tape 400 is formed on the outer surface of the expansion part 350 in a spiral shape opposite to that of the first coating film tape 200 to avoid the crossing part 330 and the intersection part 340. Anti-slip stent. According to clause 28,
The first coating film tape 200 is formed on part or the entire inner surface of the expanded tube 350,
The second coating film tape 400 is an anti-slip stent, characterized in that formed on part or the entire outer surface of the expansion portion 350.

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