KR20240004085A - Pin-combined Jig And Method For Manufacturing Stent Therewith - Google Patents

Abstract

The pin-coupled jig is composed of a cylindrical body having a plurality of pinholes that are open at least in an outward direction. The plurality of pinholes include a first pinhole, a second pinhole that is spaced longitudinally from the first pinhole and has the same size, and a second pinhole that is spaced longitudinally between the first pinhole and the second pinhole and has a smaller size than the first and second pinholes. It includes a pinhole set in which third pinholes are arranged. The pinhole sets are arranged spaced apart in the longitudinal and width directions.

Description

Pin-combined jig and method for manufacturing stents using the same {Pin-combined Jig And Method For Manufacturing Stent Therewith}

The present invention relates to stents, and more specifically, to a hook insertion stent that inserts and connects two opposing hooks (or twisted or bent portions), a method of forming the same, and a pin-coupled jig.

If a stenosis occurs in the lumen of the human body, such as the esophagus, duodenum, bile duct, ureter, trachea, etc., due to a tumor or other causes, the relevant organ cannot function normally. In this case, the stent can be inserted into the stenosis to expand the stenosis. In this way, stents are widely used to secure passage in the lumen of the human body.

The stent is composed of a cylindrical body with a mesh structure in the shape of multiple diamonds by weaving wires of superelastic shape memory alloy diagonally across from the top and bottom. This mesh-structured cylindrical body expands the stenosis area while performing a radial tension operation.

Korean Patent Publication No. 10-2001-0084836 (Stent) discloses a stent with a mesh structure in which a plurality of bending parts are formed along the circumferential surface and wires are connected by hanging from bottom to top or top to bottom in the bending parts.

Korean Patent Registration No. 1753206 (connection stent) is constructed by crossing metal wires to have multiple cells, and at the intersection points, the metal wires are connected by hanging from bottom to top or top to bottom.

However, like a conventional stent, if the wire is connected (hooking) from bottom to top or top to bottom at the bending part, there is a limit to reducing the working time, making it difficult to increase productivity.

In addition, as with a conventional stent, if the wire is hooked up and down (or forward and backward) in the bending part, the independent movement of the wire in the bending part is limited, and as a result, the performance of the stent (compression force, expansion force, etc.) is increased. It is difficult to improve.

[Prior patent literature]

1. Korean Patent Publication No. 10-2001-0084836 (Stent)

2. Korean Patent Registration No. 1753206 (connection stent)

The present invention is intended to solve these problems of the prior art,

First, in the process of weaving wires using a jig, it improves workability by reducing the time required to connect (or hook) wires at bends (or intersections).

Second, we aim to provide a stent, a method of forming it, and a pin-combined jig that can further increase the performance (compression force, expansion force, etc.) of the stent by maximizing the independent movement between the wires that are joined (or hooked) in the bending section. .

The stent according to the present invention to achieve this purpose may include a first bending portion and a second bending portion.

The first bending portion may be bent while protruding in a first direction and may include a 1-1 ring portion and a 1-2 ring portion integrally extending from the 1-1 ring portion in the protruding direction.

The second bending portion may be bent while protruding in a second direction opposite to the first direction, and may include a 2-1 ring portion inserted and coupled to the 1-2 ring portion.

In the stent of the present invention, the 1-2 ring portion is larger than the 2-1 ring portion and may be embedded in the 2-1 ring portion.

In the stent of the present invention, the 1-2 ring portion may have a size of 1.5 to 3.0 times that of the 2-1 ring portion.

In the stent of the present invention, the 1-1 ring portion and the 1-2 ring portion may have the same size.

In the stent of the present invention, the first direction may be the forward direction (direction from the starting point of weaving the wire to the return point), and the second direction may be the reverse direction (direction from the return point to the starting point).

In the stent of the present invention, the first bending portion may include a 1-3 ring portion integrally extending between the 1-1 ring portion and the 1-2 ring portion.

In the stent of the present invention, the 1-3 ring portion is smaller than the 1-1 ring portion and the 1-2 ring portion and may have the same size as the 2-1 ring portion.

The pin-coupled jig according to the present invention may be composed of a cylindrical body having a plurality of pinholes that are open at least in an outward direction. The plurality of pinholes include a first pinhole, a second pinhole that is spaced longitudinally from the first pinhole and has the same size, and a second pinhole that is spaced longitudinally between the first pinhole and the second pinhole and has a smaller size than the first and second pinholes. It may include a pinhole set in which third pinholes are arranged. The pinhole sets can be arranged spaced apart in the longitudinal and width directions.

In the pin combination jig of the present invention, the pinhole sets can be arranged in a lattice form.

In the pin combination jig of the present invention, the pinhole sets can be arranged in a zigzag shape.

In the pin combination jig of the present invention, the first and second pinholes may have a size 1.5 to 3.0 times larger than the third pinhole.

The pin combination jig of the present invention may include first, second, and third pins. One side of the first, second, and third pins may be selectively inserted into the first, second, and third pinholes, respectively, and the other side may protrude outward.

The method of forming a stent using a pin-coupled jig according to the present invention may include a first bending portion forming step, a second bending portion forming step, and a bending portion coupling step.

In the first bending portion forming step, the wire is obliquely extended along the forward direction (the direction from the starting point of weaving the wire to the turning point), and is extended to surround 1/2 of the first pin to form 1/2 of the 1-1 ring portion. After forming and extending to surround the second pin to form the 1-2 ring portion, the remaining 1/2 of the 1-1 ring portion can be formed by surrounding the remaining 1/2 of the first pin.

In the second bending portion forming step, the wire may be obliquely extended along the reverse direction (direction from the return point to the starting point) and extended to surround the third pin to form the 2-1 ring portion.

In the bending portion coupling step, the 1-2 ring portion may be inserted and coupled to the 2-1 ring portion.

In the stent forming method of the present invention, the bending portion joining step can be performed manually.

Another method of forming a stent using a pin-coupled jig according to the present invention may include a first bending portion forming step, a second bending portion forming step, and a bending portion coupling step.

In the first bending portion forming step, the wire is obliquely extended along the forward direction (the direction from the starting point of weaving the wire to the turning point), and is extended to surround 1/2 of the first pin to form 1/2 of the 1-1 ring portion. and extending to surround 1/2 of the third pin to form 1/2 of the 1-3 ring portion, and extending to surround the 2nd pin to form the 1-2 ring portion, and then extending to form 1-2 ring portions surrounding 1/2 of the third pin. The remaining 1/2 of the 1-3 ring portion may be formed by surrounding the remaining 1/2, and the remaining 1/2 of the 1-1 ring portion may be formed by surrounding the remaining 1/2 of the first pin.

In the second bending portion forming step, the wire may be obliquely extended along the reverse direction (direction from the return point to the starting point) and extended to surround the third pin to form the 2-1 ring portion.

In the bending portion coupling step, the 1-2 ring portion may be inserted and coupled to the 2-1 ring portion.

In another stent forming method of the present invention, the bending portion joining step can be performed manually.

According to the stent of the present invention having this structure, its forming method, and the jig, the wires at the bending portion (or intersection) are crossed (i.e., hung from bottom to top or top to bottom) in the process of weaving the wires using the jig. By forming rings (or hooks, twists) rather than hooking them and connecting them by inserting them, automation is possible, and as a result, productivity can be greatly improved by increasing workability.

In addition, according to the stent, its forming method, and the jig of the present invention, a gap is created between the wires hooked (or inserted) in the bending portion, so that independent movement between the wires on both sides can be maximized, and as a result, the performance of the stent ( compression force, expansion force, etc.) may increase additionally.

Figure 1 shows a bending portion of a first embodiment stent according to the present invention.
Figure 2 shows the process of combining the bending portion in the first embodiment stent according to the present invention.
Figure 3 shows the bending portion of the second embodiment stent according to the present invention.
Figure 4 shows the process of combining the bending portion in the stent of the second embodiment according to the present invention.
Figure 5 shows a pin-coupled jig of the first embodiment according to the present invention.
Figure 6 shows a pin-coupled jig of a second embodiment according to the present invention.
Figures 7a and 7b show the process of forming a bending portion in the first embodiment stent according to the present invention.
Figures 8a and 8b show the process of forming a bending portion in the stent of the second embodiment according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 shows a bending portion of a first embodiment stent according to the present invention.

As shown in FIG. 1, the stent 100 of the first embodiment is configured to form a diamond-shaped mesh structure by combining (weaving) the wire W in the bending portion A while extending in the diagonal (or diagonal) direction. The overall shape can be cylindrical.

The bending part (A) is a part where the hook area of the wire (W) is inserted and connected, and is formed in a first direction (downward in FIG. 1, that is, from the starting point (top) of weaving the wire W to the turning point (bottom). It includes a first bending portion (A11) protruding in a direction (direction toward) and a second bending portion (A12) protruding in a second direction (upward in FIG. 1, that is, the direction from the turning point (bottom) to the starting point (top)). can do.

The first bending portion (A11) is bent while protruding in a first direction (downward in FIG. 1), and extends integrally with the 1-1 ring portion (R11) in the protruding direction from the 1-1 ring portion (R11). It may include a 1-2 ring portion (R12) formed.

The 1-1st ring part (R11) and the 1-2nd ring part (R12) may have a shape such as a circle, oval, or bell shape in plan view, with one wire (W) stacked on the lower and upper sides.

The 1-1 ring portion (R11) and the 1-2 ring portion (R12) may have the same shape and size.

In the first bending portion (A11), when the stent 100 is stretched (expanded) in the width direction (left and right in Figure 1), the size (or diameter) of the 1-1 ring portion (R11) decreases, The first-second ring portion (R12) may increase in size (or diameter).

The second bending portion A12 is bent while protruding in a second direction (upward in FIG. 1) and may include a 2-1 ring portion R21.

The 2-1 ring portion (R21) may be combined with the 1-2 ring portion (R12). Here, the 2-1st ring part (R21) can be coupled to (or inserted into) the 1-2th ring part (R12).

The 2-1 ring portion R21 may have a shape such as a circular shape, an oval shape, or a bell shape in plan, with one wire W stacked on the lower and upper sides.

The 2-1 ring portion (R21) may be configured to have a smaller size (or diameter) than the 1-1 ring portion (R11) and the 1-2 ring portion (R12) described above. (R11) and the 1-2 ring portion (R12) may have a size (or diameter) 1.5 to 3.0 times that of the 2-1 ring portion (R21). Here, if the size (or diameter) difference is less than 1.5 times, when the 2-1 ring portion (R21) internally couples the 1-2 ring portion (R12), the 1-2 ring portion (R12) 2-1 It may break away from the ring portion (R21). On the other hand, if the size (or diameter) difference exceeds 3.0 times, the wire (W) is elastic when the 1-2 ring portion (R12) is internally coupled to the 2-1 ring portion (R21) after heat treatment of the stent. Even if it has, it is not easy for the operator to manually insert the 1-2 ring portion (R12) into the 2-1 ring portion (R21), which may reduce workability.

In the second bending portion (A12), when the stent 100 is stretched (expanded) in the width direction (left and right in Figure 1), the size (or diameter) of the 2-1 ring portion (R21) may decrease. there is.

The wire W described above may be composed of metal, synthetic polymer, natural polymer, etc.

It may be desirable to use a shape memory alloy as the metal, for example, nickel-titanium shape memory alloy (Ni-Ti shape memory alloy), martensitic nickel-titanium shape memory alloy (martensitic Ni-Ti shape memory alloy) etc. can be used. As other metals, stainless steel, tantalum, tungsten, etc. can be used.

Synthetic polymers can be used as degradable polymers or non-degradable polymers. Degradable polymers include poly(lactic acid) and its copolymers, poly(glycolic acid) and its copolymers, and non-degradable polymers include polyamides. : nylons), poly(cyano acrylates), polyphosphazenes, etc.

Natural polymers include collagen, albumin, silk protein, poly(L-lysine), poly(L-glutamic acid), and poly(aspartic acid). acid)) etc. can be used.

The wire W may be made of one material or a combination of two or more materials. In order to maintain uniform longitudinal expansion rate and width direction compression rate, it may be desirable to make it of one material.

The wire W may be made of an elastic material, and its surface may be coated so that it can be used in the lumen of the human body.

Figure 2 shows the process of combining the bending portion in the first embodiment stent according to the present invention.

As shown in FIG. 2, in the bending portion (A), the 2-1 ring portion (R21) of the second bending portion (A12) is connected to the 1-2 ring portion (R12) of the first bending portion (A11). It can be combined by embedding .

Both the 1-2 ring portion (R12) and the 2-1 ring portion (R21) have elasticity, so the operator compresses the 1-2 ring portion (R12) in one direction to reduce the size (or diameter). After doing so, it can be inserted into the 2-1 ring portion (R21). In addition, the 1-2 ring portion (R12) and the 2-1 ring portion (R21) are composed of a shape memory alloy, so that the operator can reduce the size (or diameter) of the 1-2 ring portion (R12). After inserting into the 2-1 ring part (R21), when the external force applied to the 1-2 ring part (R12) is removed, the 1-2 ring part (R12) is restored to its original shape (circular, etc.) It can be firmly embedded (inserted) into the 2-1 ring portion (R12), which is small in size (or diameter).

In this built-in (insertion) combination, when the stent 100 is stretched (expanded) in the width direction (left and right in Figure 2), the 1-2 ring portion (R12) increases in size (or diameter) and the second As the size (or diameter) of the -1 ring portion (R21) decreases, the 1-2 ring portion (R12) may be more firmly coupled to the 2-1 ring portion (R21).

Figure 3 shows the bending portion of the second embodiment stent according to the present invention.

As shown in FIG. 3, the stent of the second embodiment is formed to extend integrally between the 1-1 ring portion (R11) and the 1-2 ring portion (R12) in the first bending portion (A21). It may further include a 1-3 ring portion (R13).

The 1-3 ring portion (R13) is smaller than the 1-1 ring portion (R11) and the 1-2 ring portion (R12) and may have the same size as the 2-1 ring portion (R12).

The 1-3 ring portion (R13) may have a shape such as a circular shape, an oval shape, or a vertical shape in plan, with one wire (W) being stacked on the lower and upper sides.

Even in the stent of the second embodiment, the 2-1 ring portion (R21) can be coupled to the first bending portion (A21) while embedding (inserting) the lowermost 1-2 ring portion (R12).

In the stent of the second embodiment, the remaining components are the same as the corresponding components of the stent 100 of the first embodiment described above, so the detailed description of the remaining components is replaced with the related description of the stent of the first embodiment above. .

Figure 4 shows the process of combining the bending portion in the stent of the second embodiment according to the present invention.

As shown in FIG. 4, in the bending part, the 2-1st ring part (R21) of the second bending part (A12) embeds the 1-2 ring part (R12) of the first bending part (A21) Can be combined.

Also in the stent of the second embodiment, both the 1-2 ring portion (R12) and the 2-1 ring portion (R21) have elasticity, so that the operator compresses the 1-2 ring portion (R12) in one direction It can be inserted into the 2-1 ring portion (R21) after reducing the size (or diameter). In addition, the 1-2 ring portion (R12) and the 2-1 ring portion (R21) are composed of a shape memory alloy, so that the operator can reduce the size (or diameter) of the 1-2 ring portion (R12). After inserting into the 2-1 ring part (R21), when the external force applied to the 1-2 ring part (R12) is removed, the 1-2 ring part (R12) is restored to its original shape (circular, etc.) It can be firmly embedded (inserted) into the 2-1 ring portion (R12), which is small in size (or diameter).

In this built-in (insertion) combination, when the stent is stretched (expanded) in the width direction (left and right in Figure 4), the size (or diameter) of the 1-2 ring portion (R12) may decrease slightly, but Since the 1-2 ring portion (R12) is formed to be at least 1.5 times larger than the 2-1 ring portion (R21) and the size (or diameter) of the 2-1 ring portion (R21) is reduced, the 1-2 ring portion (R21) is formed to be at least 1.5 times larger than the 2-1 ring portion (R21). The ring portion (R12) can still be firmly internally coupled to the 2-1 ring portion (R21).

Figure 5 shows a pin-coupled jig of the first embodiment according to the present invention.

Figure 5 is an exploded view showing the outer surface of a pin-bonded jig (i.e., stent manufacturing frame), which is usually composed of a cylindrical shape. The pin-bonded jig has, for example, 14 lines of scale in the circumferential (horizontal) direction. , It may be divided into 32 lines of scale in the longitudinal (vertical) direction. The intersection point of the scale may be a bending point that can bend the wire.

As shown in FIG. 5, the pin-coupled jig of the first embodiment may be provided with a plurality of pinholes (P1 to P3) that are open at least in the outward direction.

The plurality of pinholes (P1 to P3) include a first pinhole (P1), a second pinhole (P2) spaced apart in the longitudinal direction from the first pinhole (P1) and having the same size (or diameter), and a first pinhole (P1). and a pinhole set (PS) arranged in a longitudinal direction between the second pinholes (P2) and a third pinhole (P3) having a smaller size (or diameter) than the first and second pinholes (P1, P2). You can.

The pinhole set PS formed at the bending point can be arranged spaced apart in the longitudinal and width directions, and can be arranged in a grid shape as shown in FIG. 5. The number and arrangement of bending points (or pinhole sets) may vary depending on the diameter, length, and shape of the stent.

The first and second pinholes P1 and P2 may have a size (or diameter) 1.5 to 3.0 times larger than that of the third pinhole P3.

Although not explicitly shown in the drawing, a bending pin may be selectively inserted into the bending point of the pin-combined jig to support the bent wire. That is, first to third pins (not shown) may be inserted into the first to third pinholes (P1 to P3). One side (inside) of the first to third pins (not shown) may be selectively inserted into the first to third pinholes (P1 to P3), and the other side (outside) may protrude outward (away from the jig surface). The first to third pins (not shown) may be closely inserted and fixed in the first to third pinholes (P1 to P3), respectively.

Since it is difficult to distinguish between the 1st to 3rd pinholes (P1 to P3) and the 1st to 3rd pins (not shown) in the plan view, the description in Figure 5 and below (Figures 6, 7a, 7b, 8a, 8b) In the description, reference numerals (PS, P1 to P3) are used to refer to both pinhole set/pinhole and pin set/pin.

Figure 6 shows a pin-coupled jig of a second embodiment according to the present invention.

As shown in FIG. 6, the pin combination jig of the second embodiment can arrange pinhole sets/pin sets (PS: P1 to P3) in a zigzag form.

In the pin-combined jig of the second embodiment, the remaining components are the same as the corresponding components of the pin-combined jig of the first embodiment described above, so a detailed description of the remaining components is provided in the pin-combined jig of the first embodiment above. Replaced with the relevant explanation.

Figures 7a and 7b show the process of forming a bending portion in the first embodiment stent according to the present invention.

Figures 7a and 7b are developed views showing the outer surface of the pin-bonded jig (i.e., stent manufacturing frame) with the wire bent, and the pin-bonded jig has, for example, 14 grid lines in the circumferential (horizontal) direction. (x1, x2, x3, ..., x14) may be divided into 32 grid lines (y1, y2, y3, ..., y31, y32) in the length (vertical) direction, and the intersection of the grids The point may be a bending point that can bend the wire.

In the method of manufacturing a stent, bending the wire W from upward to downward (i.e., from Y1 to Y32) is called forward bending, and bending the wire W from downward to upward (i.e., from Y32 to Y1) is called forward bending. This can be defined as reverse bending. And, bending refers to the act of extending the wire W while bending it at the bending point.

The first method of forming a stent using a pin-coupled jig according to the present invention includes a first bending portion forming step (FIG. 7a), a second bending portion forming step (FIG. 7b), and a bending portion coupling step (FIG. 2). It can be included.

As shown in FIG. 7A, the first bending portion forming step extends the wire W obliquely along the forward direction (the direction from the starting point of weaving the wire to the turning point), but first bends at the bending points (X9, Y13). 1 1/2 of the pin (P1) may be extended to surround 1/2 of the pin (P1) on the distal side in the direction of travel to form the distal 1/2 of the 1-1 ring portion (R11).

Thereafter, the second pin (P2) is extended from the far side to form a 1-2 ring portion (R12), and then the 1-1 ring portion (R12) is formed surrounding the remaining 1/2 of the first pin (P1). R11) can form the remaining 1/2.

As shown in FIG. 7B, the second bending part forming step extends the wire W obliquely in the reverse direction (direction from the return point to the starting point), but at the bending points (X9, Y13) where the first bending part is formed. , may extend to surround the third pin (P3) to form a 2-1 ring portion (R21).

As shown in FIG. 2, the bending portion coupling step may be performed by manually inserting and combining the 1-2 ring portion (R12) into the 2-1 ring portion (R21).

Figures 8a and 8b show the process of forming a bending portion in the stent of the second embodiment according to the present invention.

As shown in FIGS. 8A and 8B, the second method of forming a stent using a pin combination jig includes a first bending portion forming step (FIG. 8a), a second bending portion forming step (FIG. 8b), and bending portion coupling. Step (FIG. 4) may be included.

As shown in FIG. 8A, the first bending portion forming step extends the wire W obliquely along the forward direction (the direction from the starting point of weaving the wire to the turning point), but first bends at the bending points (X9, Y13). 1 1/2 of the pin (P1) may be extended to surround 1/2 of the pin (P1) on the distal side in the direction of travel to form the distal 1/2 of the 1-1 ring portion (R11).

The third pin (P3) may be extended to surround 1/2 from the far side to form 1/2 of the 1-3 ring portion (R13).

The first-second ring portion (R12) may be formed by extending and surrounding the second pin (P2) from the far side.

Thereafter, while moving upward, the remaining half of the 1-3 ring portion R13 may be formed while surrounding the remaining half of the third pin P3.

Finally, the remaining half of the 1-1 ring portion R11 may be formed by surrounding the remaining half of the first pin P1.

As shown in FIG. 8B, the second bending part forming step extends the wire W obliquely in the reverse direction (direction from the return point to the starting point), but at the bending points (X9, Y13) where the first bending part is formed. , may extend to surround the third pin (P3) to form a 2-1 ring portion (R21).

As shown in FIG. 4, the bending portion coupling step may be performed by manually inserting and combining the 1-2 ring portion (R12) into the 2-1 ring portion (R21).

The present invention has been described above by way of examples, which are intended to illustrate the present invention. Those skilled in the art will be able to transform or modify these embodiments into other forms. However, since the scope of rights of the present invention is determined by the scope of the patent claims below, such variations or modifications may be interpreted as being included in the scope of rights of the present invention.

100: stent W: wire
A: bending part A11, A21: first bending part
A12: 2nd bending part R11: 1-1 ring part
R12: 1-2 ring portion R13: 1-3 ring portion
R21: 2-1 ring part PS: Pinhole (or pin) set
P1~P3: Pinhole (or pin)

Claims (9)

Consisting of a cylindrical body having a plurality of pinholes open at least in an outward direction,
The plurality of pinholes include a first pinhole, a second pinhole spaced apart from the first pinhole in the longitudinal direction and having the same size, and a second pinhole spaced longitudinally between the first pinhole and the second pinhole and the first and second pinholes. It includes a pinhole set in which third pinholes having a smaller size are arranged,
A pin-coupled jig, wherein the pinhole set is arranged spaced apart in the longitudinal and width directions. The method of claim 1, wherein the pinhole set is
Pin-jointed jigs arranged in a grid. The method of claim 1, wherein the pinhole set is
A pin-jointed jig arranged in a zigzag pattern. The method of claim 1, wherein the first and second pinholes are
A pin-coupled jig having a size 1.5 to 3.0 times larger than the third pinhole. According to paragraph 1,
A pin-coupled jig including first, second, and third pins, one side of which is selectively and closely inserted into the first, second, and third pinholes, and the other side protruding outward. In the method of manufacturing a stent using the pin combination jig of claim 5,
The wire is extended obliquely along the forward direction (the direction from the starting point of weaving the wire to the turning point), and extends to surround 1/2 of the first pin to form 1/2 of the 1-1 ring portion, and surrounds the 2nd pin. extending to form a 1-2 ring portion while forming a first bending portion, and then surrounding the remaining 1/2 of the first pin to form the remaining 1/2 of the 1-1 ring portion;
A second bending portion forming step of extending the wire obliquely in the reverse direction (direction from the return point to the starting point) and extending the wire to surround the third pin to form a 2-1 ring portion; and
A stent manufacturing method comprising a bending portion coupling step of inserting and coupling the 1-2 ring portion to the 2-1 ring portion. The method of claim 6, wherein the bending part combining step is
Stent manufacturing method performed manually. In the method of manufacturing a stent using the pin combination jig of claim 5,
The wire is extended obliquely along the forward direction (the direction from the starting point of weaving the wire to the turning point), and extends to surround 1/2 of the first pin to form 1/2 of the 1-1 ring portion, and 1/2 of the 3rd pin. It extends around /2 to form 1/2 of the 1-3 ring part, extends around the second pin to form a 1-2 ring part, and then surrounds the remaining 1/2 of the third pin. forming a first bending portion forming the remaining 1/2 of the 1-3 ring portion and surrounding the remaining 1/2 of the first pin to form the remaining 1/2 of the 1-1 ring portion;
A second bending portion forming step of extending the wire obliquely in the reverse direction (direction from the return point to the starting point) and extending the wire to surround the third pin to form a 2-1 ring portion; and
A stent manufacturing method comprising a bending portion coupling step of inserting and coupling the 1-2 ring portion to the 2-1 ring portion. The method of claim 8, wherein the bending part combining step is
Stent manufacturing method performed manually.