KR101708859B1 - Stent - Google Patents

Abstract

According to the present invention, a plurality of struts are arranged in a zigzag arrangement along a circumferential direction to form one cell; And a bridge connecting the one cell and another cell adjacent to the one cell, wherein in each of the one cell and the other cell, the plurality of struts comprises an adjacent pair of struts having a first spacing A first strut pair provided; And a second strut pair having an adjacent pair of struts having a second spacing different from the first spacing.

Description

Stent {STENT}

The present invention relates to a stent used for vasodilation.

In general, complications such as restenosis are recurrent in patients who have been treated for arteriosclerosis in the form of medical procedures such as percutaneous transluminal coronary angioplasty (PTCA).

Restenosis is often treated by a procedure known as stenting. At this time, a medical device is implanted surgically into the involved artery to prevent the vessel from occluding after the procedure.

Stents are typically cylindrical in shape and are made primarily of biocompatible metals such as titanium or surge steel. Most stents are collapsible and delivered to the occluded artery through a catheter.

The stent may be attached to the catheter and expanded by inflation of the balloon within the stent that is self-expanding or removed with the catheter once the device is in place.

It is an object of the present invention to provide a stent capable of uniform expansion when inserted into a blood vessel.

It is another object of the present invention to provide a stent that coordinates the performance in terms of both radial strength and flexibility.

Still another object of the present invention is to provide a stent that can minimize the interference problem between struts.

According to an aspect of the present invention, there is provided a stent comprising: a plurality of struts arranged in a zigzag arrangement along a circumferential direction to form a single cell; And a plurality of bridges connecting the one cell and another cell adjacent to the one cell and spaced apart from each other along the circumferential direction of the one cell, And a plurality of bridge sections divided by an adjacent pair of the plurality of bridges, wherein a first bridge section of the plurality of bridge sections includes a first strut pair including a pair of adjacent struts having a first interval, Wherein a second bridge section following the first bridge section of the plurality of bridge sections includes a pair of adjacent struts disposed at positions corresponding to the first strut pair and having a second gap different from the first gap, Wherein each of the one cell and the other cell has a first bridge section and a second bridge section alternately arranged, Wherein all of the struts in the plurality of struts extend along a direction intersecting the circumferential direction or a direction parallel to the circumferential direction and are arranged to form an acute angle with a strut adjacent to the respective strut, The number of struts constituting one bridge section may be the same as the number of struts constituting the second bridge section.

Here, the second strut pair does not exist in the first bridge interval, and the first strut pair may not exist in the second bridge interval.

Wherein the first strut pair comprises a first strut and a second strut of the first bridge interval and the second strut pair comprises a first strut and a second strut of each of the second bridge sections, , The first spacing may be greater than the second spacing.

Wherein the first strut pair includes a fourth strut and a fifth strut in the first bridge interval and the second strut pair includes a fourth strut and a fifth strut in each of the second bridge intervals, , The first spacing may be greater than the second spacing.

Wherein each of the first bridge section and the second bridge section may further include a third strut pair having a pair of adjacent struts having a third spacing greater than the second spacing and less than the first spacing have.

Here, the bridge may be arranged to be inclined with respect to a direction in which the one cell and the other cell are arranged successively.

Here, the first bridge period in the one cell may have a phase difference in the other cell along the first bridge period and the circumferential direction.

Here, the phase difference may correspond to an angle along the circumferential direction of the first bridge section.
Here, each of the first strut pair and the second strut pair may be connected to the bridge.

According to the stent of the present invention configured as described above, the stent inserted into the blood vessel can be uniformly expanded.

According to the above stent, the stent performance in terms of radial strength and flexibility can be coordinated with each other.

According to the above stent, the interference problem between struts is minimized.

1 is a plan view showing a stent 100 according to an embodiment of the present invention.
2 is an enlarged view of a portion of the stent 100 of FIG.
FIG. 3 is an image of an appearance evaluation photograph of a sample produced for the stent 100 of FIG.

Hereinafter, a stent according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present specification, the same or similar reference numerals are given to different embodiments in the same or similar configurations.

1 is a plan view showing a stent 100 according to an embodiment of the present invention.

The stent 100 may have cells 110-170, struts 210-270, and bridges 310-360.

Each of the cells 110 to 170 is substantially in the form of a ring. By staggering the cells 110 to 170 along the longitudinal direction L, the stent 10 is generally pipe-shaped. The structure of the stent 100 is suitable for being inserted into the blood vessel and used to widen the cross-sectional area of blood flow in the blood vessel.

The struts 210 to 270 are the basic members forming each of the cells 110 to 170. The struts 210 to 270 may be formed in the form of wires made of a biocompatible metal such as titanium or surge steel. The struts 210 to 270 are disposed in a plurality of cells 110 to 170 to form cells 110 to 170, respectively. To this end, the plurality of struts 210 to 270 are arranged in a jig manner along the circumferential direction C of the stent 100. Whereby the struts 210 to 270 extend along a direction that intersects the circumferential or circumferential direction of the cells 110 to 170 and the individual struts can be arranged to form an acute angle with the adjacent struts.

The bridges 310 to 360 are structures for connecting adjacent ones of the cells 110 to 170. Specifically, the bridges 310 to 360 connect the struts 210 to 270 of the cells 110 to 170 with the adjacent struts 210 to 270 of the cells 110 to 170, respectively. The bridges 310 to 360 are spaced apart from each other along the circumferential direction of the cells 110 to 170.

The specific structure of the stent 100 is described with reference to FIG.

2 is an enlarged view of a portion of the stent 100 of FIG.

In the figure, a second cell 120, a third cell 130, and a fourth cell 140 are illustrated as a plurality of cells 110 to 170 for convenience of explanation.

The strut pattern of one section in the second cell 120 has five struts 221a, 221b, 222, 223a, 223b / 226a, 226b, 227, 228a arranged on both sides with respect to the first bridge 311 , 228b. The strut pattern of the section may be referred to as one bridge section. Specifically, the five struts 221a, 221b, 222, 223a, and 223b are partitioned by a pair of adjacent bridges 311 and 322 to form a first bridge section. Similarly, the five struts 226a, 226b, 227, 228a, 228b are delimited by a pair of adjacent bridges 311 and 323 to form a second bridge section. Here, each cell is constituted by alternately arranging the first bridge section and the second bridge section.

At this time, some of the struts 221a, 221b, 222, 223a, 223b in the first bridge section are arranged to have a first interval between adjacent struts. In contrast, some of the struts 226a, 226b, 227, 228a, 228b in the second bridge section are arranged to have a second spacing between adjacent struts. The first spacing may be greater than the second spacing.

Further, adjacent struts having a first spacing may be referred to as a first strut pair. Specifically, the first and second struts 221a and 221b on one side of the first bridge 311 and the fourth and fifth struts 223a and 223b are first strut pairs, respectively. At this time, the first strut pair is connected to the bridge 311 or 322. Here, the second and third struts 221b and 222 on one side of the first bridge 311 and the third and fourth struts 222 and 223a, respectively, are smaller than the first spacing but larger than the second spacing May be referred to as a third strut pair having a spacing, i. E. A third spacing.

Similarly, adjacent struts having a second spacing may be referred to as a second strut pair. Specifically, the first and second struts 226a and 226b of the first bridge section, and the fourth and fifth struts 228a and 228b, respectively, become the second strut pair. At this time, the second strut pair is connected to the bridge 311 or 323. Here, the second and third struts 226b and 277 of the second bridge section, and the third and fourth struts 277 and 228a, respectively, are also spaced apart from the first gap but larger than the second gap, Lt; RTI ID = 0.0 > 3 < / RTI >
Here, the second strut pair does not exist in the first bridge interval, and the first strut pair does not exist in the second bridge interval.

In the third cell 130, which is another cell adjacent to the second cell 120, a strut pattern of one section in the third cell 130 is divided into five strands each disposed on both sides with respect to the second bridge 322 Struts 231a, 231b, 232, 233a, 223b / 236a, 236b, 237, 238a, 238b.

At this time, the strut pattern in the third cell 130 is the same as that of the second cell 120. However, the strut pattern of the third cell 130, specifically one bridge section, has a phase difference along another circumferential direction C with respect to another bridge section in the second cell 120. Specifically, the phase difference corresponds to the angle between the first bridge 311 and the second bridge 322, that is, the angle along the circumferential direction of the first bridge section.

The bridges 310 to 360 may have the first bridge 311, the second bridge 322, and the third bridge 323 described above.

The first bridge 311 is the center of the strut pattern of the second cell 120.

The second bridge 322 is the center of the strut pattern of the third cell 130. The second bridge 322 is also connected to the fifth and sixth struts 223b and 224 of the first bridge 311 of the second cell 120.

The third bridge 323 is connected to the fifth and sixth struts 228b and 229 on the other side of the first bridge 311 of the second cell 120.

The first bridge 311, the second bridge 322, and the third bridge 323 may all be parallel to each other. Further, they may be arranged to be inclined with respect to the longitudinal direction L. [

The operation of the stent 100 according to such a configuration can be described with reference to the second cell 120.

First, when the stent 100 is inflated, the struts 221a, 221b, 222, 223a, 223b of the first bridge 311 are relatively compressed and the struts 226a of the other side of the first bridge 311 , 226b, 227, 228a, 228b are relatively inflated. At this time, since the first interval is larger than the second interval, the struts can be uniformly expanded.

Further, since the bridges 310 to 360 are inclined in the longitudinal direction L, the flexibility of the stent 100 is improved. Further, by the connection of these bridges 310-360, adjacent ones of the cells 110-170 have a phase difference in the strut pattern. Due to this phase difference, the possibility that struts of adjacent cells interfere with each other at the time of stent 100 deformation is lowered.

In addition, since the bridges 310 to 360 all have the same size and orientation, the forces received by the struts 210 to 270 have the advantage that they are the same in all struts, whether tensile or compressive.

In the specific design of the stent 100, the struts 210 to 270 were determined to have a length of 1.449 mm and a width of 0.1415 mm. This is confirmed by the finite element analysis and the experiment to have the optimum radial strength and flexibility.

Further, three bridges 310 to 360 are staggered in the circumferential direction C so as to have maximum flexibility while expanding the blood vessel with sufficient mechanical strength without causing injury after deploying the blood vessel with many bends Respectively. The more the number of bridges 310 to 360 is, the more the uniform expansion can be achieved. However, since more than three bridges lower the flexibility of the stent 100, three bridges are suitable.

In addition, the size of the cells 110 to 170 can be adjusted by adjusting the number and angles of the struts 210 to 270. At this time, 30 struts 210 to 270 are designed in the circumferential direction (C).

The evaluation of the appearance of the strut thus manufactured can be referred to the photographic image of Fig.

Referring to FIG. 3, it can be seen that after stenting, the stent is sufficiently spaced apart from struts of adjacent cells and does not overlap with each other.

Further, even when the stent is bent, it can be seen that there is no problem that the adjacent cells overlap each other.

The stent is not limited to the configuration and operation of the embodiments described above. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

100: stent 110 to 170: cell
210 to 270: Stent 310 to 360: Bridge

Claims (9)

A plurality of struts arranged in a zigzag arrangement along the circumferential direction to form one cell; And a plurality of bridges connecting the one cell and another cell adjacent to the one cell and spaced from each other along the circumferential direction of the one cell,
Wherein each of the one cell and the other cell includes a plurality of bridge sections that are defined by adjacent pairs of the plurality of bridges,
Wherein a first bridge interval of the plurality of bridge sections includes a first strut pair having a pair of adjacent struts having a first interval,
And a second bridge section following the first bridge section of the plurality of bridge sections includes a pair of adjacent struts disposed at positions corresponding to the first strut pair and having a second gap different from the first gap A second strut pair,
Wherein each of the one cell and the other cell is configured such that the first bridge section and the second bridge section are alternately arranged,
All of the struts in the plurality of struts extend along a direction that intersects the circumferential direction or parallel to the circumferential direction and are arranged to form an acute angle with a strut adjacent to the respective strut,
Wherein the number of struts constituting the first bridge section is equal to the number of struts constituting the second bridge section.
The method according to claim 1,
The second strut pair does not exist in the first bridge section,
And the first strut pair does not exist in the second bridge section.
The method according to claim 1,
Wherein the first strut pair comprises a first strut and a second strut of the first bridge interval,
The second strut pair comprising a first strut and a second strut of each of the second bridge sections,
Wherein the first spacing is greater than the second spacing.
The method according to claim 1,
Wherein the first strut pair comprises a fourth strut and a fifth strut of the first bridge interval,
The second strut pair includes a fourth strut and a fifth strut of each of the second bridge sections,
Wherein the first spacing is greater than the second spacing.
The method according to claim 1,
Wherein each of the first bridge section and the second bridge section includes:
And a third strut pair having a pair of adjacent struts having a third spacing greater than the second spacing and less than the first spacing.
The method according to claim 1,
The bridge includes:
Wherein the one cell and the other cell are disposed obliquely with respect to the direction in which they are arranged one after the other.
The method according to claim 1,
Wherein the first bridge section in the one cell has a phase difference along the circumferential direction with respect to the first bridge section in the other cell.
8. The method of claim 7,
The phase difference,
Corresponding to an angle along the circumferential direction of the first bridge section.
The method according to claim 1,
Each of the first strut pair and the second strut pair being connected to the bridge.

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