KR20210050048A - Magnesium alloy stent - Google Patents

Abstract

The present invention relates to a magnesium alloy stent used for vasodilation. According to the magnesium alloy stent according to the present invention, since the stent is made of a magnesium alloy material, after a certain period of time, the stent may be self-decomposed and absorbed into the blood vessel.

Description

Magnesium alloy stent {MAGNESIUM ALLOY STENT}

The present invention relates to a magnesium alloy stent used for vasodilation.

In general, complications such as restenosis are a recurring problem in patients treated for atherosclerosis in the form of medical procedures such as percutaneous cervical coronary angiogenesis (PTCA).

Restenosis is often treated by a process known as stenting. At this time, a medical device is surgically implanted into the affected artery to prevent the blood vessel from being closed after the above procedure.

The stent is usually cylindrical and is mainly made of a biocompatible metal such as titanium or surgical steel. Most stents are collapsible and are delivered through a cervical catheter to a closed artery.

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

These stents are left inserted into blood vessels. In order to improve this situation, after performing the function of preventing restenosis of blood vessels for a certain period of time, a method of causing the stent to disintegrate may be considered.

An object of the present invention for this purpose is to provide a magnesium alloy stent that is formed of a material that is decomposed after a certain period of time and can overcome the problem of damage that may occur during an intravascular procedure by the material.

A magnesium alloy stent according to an aspect of the present invention for realizing the above object includes a plurality of struts formed of a magnesium alloy and arranged in zigzag along a circumferential direction to form one cell; And a bridge formed of a magnesium alloy and connecting the one cell and another cell adjacent to the one cell, wherein the plurality of struts in each of the one cell and the other cell comprises the one cell and the A first strut disposed along a direction forming a first angle with respect to an imaginary line along an extension direction in which other cells are successively disposed; And a second strut disposed along a direction forming a second angle different from the first angle with respect to the virtual line, wherein the connecting portion of the first strut and the second strut has a first radius of curvature. And the bridge includes: a first convex portion connected to the one cell and having a 2-1 radius of curvature; A second convex portion connected to the other cell and having a 2-2 radius of curvature and formed to be convex in a direction opposite to the first convex portion; And a connection portion connecting the first convex portion and the second convex portion, wherein the first radius of curvature may have a value larger than each of the 2-1 radius of curvature and the 2-2 radius of curvature. .

Here, the first radius of curvature may have a value ranging from 2 to 4 times the 2-1 radius of curvature or the 2-2 radius of curvature.

Here, when the first convex portion is connected to the first strut in the one cell, the second convex portion may be connected to the first strut in the other cell.

Here, the connection portion may have a linear shape arranged in a direction forming an acute angle with respect to the extension direction.

Here, the connection part may have a width of 1/2 of the width of each of the plurality of struts.

Here, in each of the one cell and the other cell, only two bridges may be provided along the circumferential direction.

Here, at least one of the plurality of struts may have a wave pattern shape.

Here, in the one cell and the other cell, the round portions may be arranged in a support zag based on the virtual line.

Here, a pair of marker installation units respectively installed on a pair of the plurality of struts may be further provided, and the pair of marker installation units may be provided on a pair of cells disposed at the outermost of the cells. .

According to the magnesium alloy stent according to the present invention configured as described above, since the stent is formed of a magnesium alloy material, the stent can be self-decomposed and absorbed into blood vessels after a certain period of time.

In addition, such a stent may have an optimal structural design that prevents damage from occurring during compression and expansion for insertion into blood vessels.

1 is a photograph showing a case of damage of a stent made of a magnesium alloy compared to a magnesium alloy stent 100 according to an embodiment of the present invention.
2 is a perspective view showing a part of a magnesium alloy stent 100 according to an embodiment of the present invention.
3 is a plan view showing the magnesium alloy stent 100 of FIG. 2 unfolded.
4 is an enlarged plan view of a portion of FIG. 3.
FIG. 5 is a photograph of an expanded product in which the magnesium alloy stent 100 of FIG. 2 is implemented.

Hereinafter, a magnesium alloy stent according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The magnesium alloy stent 100 according to an embodiment of the present invention is formed of a magnesium alloy material. These magnesium alloy stents 100 may be absorbed into blood vessels and decomposed after a certain period of time. In order to achieve this function, the magnesium alloy stent 100 may be composed of 3.7 to 4.3% by weight of yttrium, 2.4 to 4.4% by weight of rare earth, 0.4% by weight of zirconium, and magnesium as the residual.

Such a magnesium alloy has characteristics different from the cobalt-chromium alloy, which is a conventional stent material, in terms of strength due to its decomposition performance. Specifically, the magnesium alloy used in the magnesium alloy stent 100 has a strength of 1/5 and an elongation of only 1/10, compared to cobalt-chromium.

Although such a magnesium alloy is used, the characteristics of the stent according to a conventional design will be described with reference to FIG. 1.

1 is a photograph showing a case of damage of the magnesium alloy stent compared to the magnesium alloy stent 100 according to an embodiment of the present invention.

Referring to FIG. 1, due to the characteristics of the magnesium alloy, when designing the magnesium alloy stent with the same design as the stent of another material, the stent may be damaged during compression and expansion.

The contents of the structural design for solving the problem of damage in the compression and expansion process while utilizing the natural decomposition ability of the magnesium alloy material as it is will be described with reference to FIG. 2 and the like.

2 is a perspective view showing a part of the magnesium alloy stent 100 according to an embodiment of the present invention, and FIG. 3 is a plan view showing the magnesium alloy stent 100 of FIG. 2 unfolded.

Referring to the drawings, the magnesium alloy stent 100 may have a plurality of cells 10 and 30 disposed in succession with each other. Cells 10 and 30 generally form a circular ring. Accordingly, the outer circumferential direction in which each of the cells 10 and 30 extends may be referred to as a circumferential direction C, and a direction in which the cells 10 and 30 are arranged in succession may be referred to as an extension direction E. The direction toward the central axis of the cells 10 and 30 may be referred to as the central direction D. In addition, in this drawing, there are six cells in total, but for convenience, reference numerals are assigned only to the first cell 10 and the second cell 30. Here, the first cell 10 may be referred to as one cell, and the second cell 30 may be referred to as another cell. This designation is also established in the relationship between the second cell 30 and the third cell, the third cell and the fourth cell, and the like.

The magnesium alloy stent 100 generally forms a pipe shape by arranging one cell 10 and the other cell 30 successively along the extension direction E. The structure of the magnesium alloy stent 100 is suitable for use in order to increase the flow cross-sectional area of blood in the blood vessel when inserted into the blood vessel.

The basic structure constituting one cell 10 and the other cell 30 is a strut. The strut is formed of the magnesium alloy material described above. The strut may have a wire shape with a generally square cross section. Struts may be arranged in a zigzag shape along the circumferential direction in each of one cell 10 or another cell 30. These struts may be specifically divided into a first strut 110 and a second strut 130. Based on the virtual line VL along the extension direction E, if the first strut 110 is disposed to be inclined in one direction, the second strut 130 may be disposed to be inclined in the other direction. The first strut 110 or the second strut 130 may have a wave pattern shape. This makes it possible to prevent interference between struts while improving the force in the radial direction of the stent 100.

The connecting portion of the first strut 110 and the second strut 130 may constitute a round portion 150 having a set radius of curvature. The first strut 110 and the second strut 130, and further, the round portion 150 may be integrally formed. In addition, the round portions 150 may be arranged zigzag based on the virtual line VL. This provides a meaning of mitigating interference between the round units 150 when the stent 100 is compressed.

The bridge 170 is a component that connects one cell 10 and another cell 30. When the bridge 170 is connected to the first strut 110 of one cell 10, the bridge 170 may also be connected to the first strut 110 in the other cell 30. Specifically, the bridges 170 are connected to the central portions of each of the first struts 110, respectively. The bridge 170 may be integrally formed with each of the first struts 110. In contrast, the bridge 170 connected to the second strut 130 of one cell 10 is connected to the second strut 130 of another cell 30. When the one cell 10 and the other cell 30 are connected, only two bridges 170 are provided along the circumferential direction (C). The inventor has confirmed that a large number of bridges 170 in excess of two causes fracture of the stent 100 rather. Specifically, if the fracture probability in the two bridges 170 is 17%, the fracture probability in the three bridges 170 is increased to 50%.

A pair of cells located at the outermost of the cells may be provided with a marker installation unit 190. The marker installation unit 190 is a structure in which a radiopaque marker for confirming the position of the stent 100 is installed. Specifically, the marker installation unit 190 may have a structure having two grooves. When the stent 100 is compressed, the marker installation unit 190 is preferably disposed only in the outermost cells in order to reduce the overall volume of the stent 100.

More specific structural design matters of the magnesium alloy stent 100 will be described with reference to FIGS. 4 and 5.

FIG. 4 is an enlarged plan view of a part of FIG. 3, and FIG. 5 is a photograph of a state in which the product in which the magnesium alloy stent 100 of FIG. 2 is implemented is expanded.

Referring to the drawings, if the first strut 110 is disposed along a direction forming a first angle α with respect to the virtual line VL, the second strut 130 is It is arranged along the direction forming the 2 angle β. The first angle α and the second angle β have different values. Specifically, if the first angle α is greater than the second angle β in one cell 10, the second angle β is greater than the first angle α in the other cell 20. Even so, the sum of these can always be determined to be a value within the range of the acute angle.

The first strut 110, the second strut 130, and further the bridge 170 have the same thickness, but their widths may be different. Here, the thicknesses of the first strut 110, the second strut 130, and further the bridge 170 are defined as lengths of one cell 10 along the central direction D toward the central axis of the cell. In contrast, the width is defined as the respective length along the circumferential direction C of one cell 10. Compared to the widths of the first and second struts 110 and 130, the width of the bridge 170 may be approximately 1/2. This is in consideration of maintaining the shape of the first strut 110 and the second strut 130 and preventing fracture when the stent 100 is compressed and expanded.

The radius of curvature of the round portion 150 is specifically defined as a first radius of curvature R ₁ . The first radius of curvature R ₁ may be about 0.1576 mm in the same manner as in the existing product shown in FIG. 1 or in this embodiment.

The bridge 170 may have a convex convex portion along the same direction as the convex direction of the round portion 150. Specifically, a first convex portion 171 corresponding to the round portion 150 of one cell 10 and a second convex portion 175 corresponding to the round portion 150 of another cell 30 are formed. Can be. Here, if the first convex portion 171 is convex upward in the drawing, the second convex portion 175 is convex downward in the drawing.

If the radius of curvature of the first convex part 171 is a 2-1 radius of curvature (R _2-1 ), the radius of curvature of the second convex part 175 is called a 2-2 radius of curvature (R _2-2 ). can do. Here, the 2-1 radius of curvature (R _2-1 ) or the 2-2 radius of curvature (R _2-2 ) is a value that is significantly larger than 0.0069 mm in the existing product illustrated in FIG. 1 and can reach 0.055 mm. have. When the 2-1 radius of curvature (R _2-1 ) or the 2-2 radius of curvature (R _2-2 ) is 0.0069 mm, the diameter of the stent 100 is 3.5 mm when the round portion 150 is expanded. Although fractured, in the case of 0.055 mm, fracture did not occur even if the diameter was expanded to 4.1 mm (see FIG. 5).

_{The 2-1th} radius of curvature R2-1 or the 2nd-2nd radius of curvature R2-2 of 0.055 mm reaches a level of 1/3 compared to the _first radius of curvature R _{1 of 0.1576 mm.} Through an additional experiment, the inventor confirmed that the determination of the former at a level of 1/4 to 1/2 of the latter is effective in preventing fracture of the round portion 150 when the stent 100 is expanded.

The first convex portion 171 and the second convex portion 175 may be connected by a connection portion 179. The connection part 179 may have a linear shape arranged in a direction forming an acute angle with respect to the extension direction E. Due to the structure of the connection part 179, the stress applied to the round part 150 may be reduced.

The magnesium alloy stent as described above is not limited to the configuration and operation of the embodiments described above. The above embodiments may be configured so that all or a part of each of the embodiments may be selectively combined so that various modifications may be made.

10: one cell 20: another cell
100: magnesium alloy stent 110: first strut
130: second strut 150: round portion
170: bridge 171: first convex
175: second convex portion 179: connection portion
C: circumferential direction D: center direction
E: extension direction

Claims (9)

A plurality of struts formed of a magnesium alloy and arranged in zigzag along a circumferential direction to form one cell; And
It is formed of a magnesium alloy and includes a bridge connecting the one cell and another cell adjacent to the one cell,
The plurality of struts in each of the one cell and the other cell,
A first strut disposed along a direction forming a first angle with respect to an imaginary line along an extension direction in which the one cell and the other cell are disposed in succession; And
And a second strut disposed along a direction forming a second angle different from the first angle with respect to the virtual line,
The connecting portion of the first strut and the second strut constitutes a round portion having a first radius of curvature,
The bridge,
A first convex portion connected to the one cell and having a 2-1 radius of curvature;
A second convex portion connected to the other cell and having a 2-2 radius of curvature and formed to be convex in a direction opposite to the first convex portion; And
And a connection portion connecting the first convex portion and the second convex portion,
The first radius of curvature is,
The magnesium alloy stent having a larger value than each of the 2-1 radius of curvature and the 2-2 radius of curvature.
The method of claim 1,
The first radius of curvature is,
Magnesium alloy stent having a value ranging from 2 to 4 times the 2-1 radius of curvature or the 2-2 radius of curvature.
The method of claim 1,
When the first convex portion is connected to the first strut in the one cell, the second convex portion is connected to the first strut in the other cell, the magnesium alloy stent.
The method of claim 1,
The connection part,
Magnesium alloy stent having a linear shape arranged in a direction forming an acute angle with respect to the extension direction.
The method of claim 1,
The connection part,
A magnesium alloy stent that is 1/2 of the width of each of the plurality of struts.
The method of claim 1,
The bridge,
In each of the one cell and the other cell, only two are provided along the circumferential direction, the magnesium alloy stent.
The method of claim 1,
At least one of the plurality of struts,
Magnesium alloy stent having a wavy shape.
The method of claim 1,
In the one cell and the other cell,
The round portions are arranged in a support zag based on the virtual line, magnesium alloy stent.
The method of claim 1,
Further comprising a pair of marker installation units respectively installed on a pair of the plurality of struts,
The pair of marker mounting portions,
Magnesium alloy stent provided with one each in a pair of cells disposed at the outermost of the cells.

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