KR101015329B1 - Surgical stent - Google Patents

Abstract

PURPOSE: A surgical stent is provided, which provides strong supporting force after surgical operation and prevents contraction in the axial direction even though being swollen in the radial direction. CONSTITUTION: A surgical stent comprises: a first curved portion(12) which is convex in the columnar direction; a second curved portion(13) which is concave in the columnar direction; a third curved portion(14) which is convex in the axial direction; a plurality of cells(11) which are arranged in the columnar direction and are equipped with a fourth curved portion(15) which is concave in the axial direction; and a stent ring(10) of a ring shape which is equipped with a fifth curved portion which is convex in the axial direction.

Description

Surgical stent

The present invention relates to a surgical stent, and more particularly to a cylindrical surgical stent that does not contract in the axial direction even when inflated.

If the passage of the lumen, such as the esophagus, blood vessels, or bile tracks of the human body, is abnormally narrowed due to congenital or acquired factors, deterioration of function and severely no function. In this case, by inserting a luminal extension mechanism called a stent into the stenosis of the human lumen, the passage of the lumen can be restored to normal.

For example, in cardiovascular surgery, a procedure is often performed to place the stent in a location where the artery is damaged. Once the stent is placed, the stent dilates the artery and strengthens blood flow. In particular, the preferred form of the stent to be implanted in an artery or the like is a cylindrical stent that can expand radially from a small diameter to a large diameter.

This cylindrical stent can be inserted into the artery through a catheter and travels internally through the arterial path of the patient until the unexpanded stent is positioned where desired. When the stent is positioned where it is desired, the balloon is inflated outwards using a balloon or other inflation mechanism to engage the artery. Such cylindrical stents must exhibit sufficient stiffness even after inflation, and this stiffness must be maintained even after the catheter is removed.

Cylindrical stents have a variety of shapes to provide adequate performance for a variety of environments. For example, US Patent Nos. 5,514,154, 5,421,955, 5,242,399, 5,531,741, 5,522,882, 5,507,771, 5,314,444, 5,496,277, 5,494,029, 5,507,767, etc. Various forms of cylindrical stents are disclosed for implantation into the lumen of the body.

In addition, when the surgeon places the stent in the lumen of the artery or body, it is very important to position it correctly in the desired position. If the length of the stent before and after expansion is different, it is very difficult to position the stent exactly at the desired position. This problem of mispositioning is difficult to reverse due to the fact that the stent not only expands easily, but also does not shrink once expanded.

However, when the cylindrical stent is expanded in the radial direction, there is a problem that the length in the axial direction is reduced. In particular, the stent disclosed in U. S. Patent No. 5,514, 154 (named Expandable stents) is accompanied by a slight contraction such as an axial contraction appearing at the end, even though it has a unique structure for limiting axial contraction. Therefore, there is a problem that it is difficult to position the stent after the expansion.

The present invention has been made to solve the above problems, it is an object of the present invention, there is no contraction in the axial direction even when expanding in the radial direction, to provide a stent having a strong supporting force after the procedure.

Surgical stent according to the present invention, in the surgical stent forming a cylindrical shape before and after expansion, the first curved portion convex in the circumferential direction, the second curved portion concave in the circumferential direction, the axially convex agent And a third curved portion and a fourth curved portion concave in the axial direction, wherein the first curved portion is connected to the third curved portion and the fourth curved portion to form an inflection point, respectively, and the second curved portion is the third curved portion. A plurality of cells connected to each of the portion and the fourth curved portion to form an inflection point, forming a closed curved surface therein and spaced apart in a line in the circumferential direction; And a circumferential link connecting the first curved portion and the second curved portion of the adjacent cell and having a fifth curved portion convex in the axial direction. Ring-shaped stent ring consisting of; And a point where the first curved portion and the second curved portion meet the circumferential link is a point deviating from the central axis of the first curved portion and the second curved portion.

In addition, the stent ring is arranged in a plurality spaced apart in the axial direction, the shaft link having a plurality of vertices and connecting the third curved portion and the fourth curved portion of the adjacent cell in a curved shape; It characterized in that it further comprises.

The first curved portion and the second curved portion are symmetrical with each other, the third curved portion and the fourth curved portion are symmetrical with each other, and the fifth curved portion has a shape symmetrical with respect to a central axis. .

In addition, the axial link is characterized in that it has two vertices.

The cell may further include: a strut connecting the third curved portion and the fourth curved portion; It includes more.

Using the surgical stent according to the present invention can minimize the contraction in the axial direction when inflated, there is an advantage that can be placed in the correct position.

1 is a schematic perspective view of a surgical stent in accordance with the present invention.
2 is an exploded view of the stent of FIG. 1.
3A is an exploded view when the surgical stent in accordance with the present invention is contracted.
3B is an exploded view when the surgical stent in accordance with the present invention is inflated.
FIG. 4 is a diagram for comparing a deformed state when a force acts on a vertex and an eccentric action on a cell.
5 is a schematic perspective view of a surgical stent in another embodiment according to the present invention.
6 is an exploded view of the stent of FIG. 5.

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

1 is a schematic perspective view of a surgical stent according to the invention, Figure 2 is a development of the stent of Figure 1, Figure 3a is a development view when the surgical stent in accordance with the present invention, Figure 3b is a present invention Is a developed view when the surgical stent is expanded. For reference, `` axial direction '' refers to the direction of the arrow i shown in the drawings, 'radial direction' means the direction of the arrow j shown in the drawings, 'circumferential direction' It means the direction of the arrow k shown in the figure. In addition, in the following, 'concave' means a curved shape that goes in the direction indicated by arrows i, j, k, and 'convex' means a curved form that protrudes toward the direction indicated by arrows i, j, k.

1 and 2, the surgical stent according to the present invention includes a stent ring 10 arranged in a row in the axial direction and an axial link 30 connecting the respective stent rings 10 in the axial direction. It is composed of

Referring to FIG. 2, the stent ring 10 includes a plurality of cells 11 and circumferential links 20 connecting the cells 11 in the circumferential direction.

The cell 11 has a deformed truss shape. In more detail, the cell 11 includes a first curved portion 12 convex in the circumferential direction, a second curved portion 13 concave in the circumferential direction, and a third curved portion 14 convex in the axial direction. And the fourth curved portion 15 concave in the axial direction. In addition, the first curved portion 12 is connected to the third curved portion 14 and the fourth curved portion 15 to form an inflection point 16, respectively, and the second curved portion 13 is connected to the third curved portion ( 14) and the fourth curved portion 15 are connected to form an inflection point 16, respectively. As a result, the cell 11 forms a closed curved surface therein.

As shown in FIG. 2, the first curved portion 12 and the second curved portion 13 are preferably symmetrical with each other, and the third curved portion 14 and the fourth curved portion 15 are also symmetrical with each other. In addition, the shape in which the first curved portion 12 and the second curved portion 13 are larger than the third curved portion 14 and the fourth curved portion 15 is stable.

The cells 11 are arranged spaced apart in a row in the circumferential direction, each cell 11 is connected to the circumferential link (20). The circumferential link 20 has a fifth curved portion 21 which is convex in the axial direction and connects the first curved portion 12 and the second curved portion 13 of the adjacent cell 11. In particular, the point 22 which meets the first curved portion 12 and the second curved portion 13 is eccentrically positioned at a point beyond the vertices of the first curved portion 12 and the second curved portion 13. desirable.

FIG. 4 is a diagram for comparing a deformed state when a force acts on a vertex and an eccentric action on a cell. Referring to FIG. 4, the advantages of the case where the connecting point 22 of the circumferential link 20 and the cell 11 are eccentric with the vertex are as follows.

FIG. 4 (a) is a comparison between before and after deformation when a force due to expansion acts on the vertices of the first curved portion 12 and the second curved portion 13, and FIG. 4 (b) shows the eccentricity. This is a comparison between before and after deformation when an inflated force is applied at the point. For reference, in FIG. 4B, the amount of movement of the fourth curved portion 15 is small, and is shown in addition to the amount of movement of the third curved portion 14.

Referring to FIG. 4A, when the circumferential force acts on the vertices of the first curved portion 12 and the second curved portion 13 during expansion, the third curved portion is formed due to the symmetrical shape. The vertices of the 14 and the fourth curved portions 15 are moved inward at the same ratio. On the contrary, referring to FIG. 4B, when the same circumferential force acts on the eccentric point, the vertex of the third curved portion 14 moves while the center axis of the vertex moves toward the action point of the force as compared to before deformation. Minimize this attempt to move inward. That is, in the case of (a) of FIG. 4, deformation due to the action of the force does not occur significantly at the vertices of the first curved portion 12 and the second curved portion 13, but the same as in FIG. Since the deformation occurs at the same time while moving the vertex at the same time, it is possible to minimize the amount that the distance between the vertex of the third curved portion 14 and the fourth curved portion 15 is reduced. That is, d ₁ The d ₂ The smaller one can be seen in FIG. 4.

In addition, since the eccentric, the space that can increase the length of the circumferential link 20, that is, the circumferential link 20 is a cell compared to the circumferential link 20 is connected at the vertex as shown in FIG. The distance between (11) and the point where it is connected is increased, so that the enlargement can be performed at a larger rate when the stent is expanded during the procedure. In other words, assuming that the stent is inflated at a constant rate, the force applied to the cell 11 having the eccentric coupling structure as in the present invention is smaller than that of the cell having the coupling structure as shown in FIG. Means that.

As described above, only the circumferential link 20 deforms at the time of expansion while minimizing the deformation of the cell 11, particularly the distance between the vertices of the third curved portion 14 and the fourth curved portion 15. do. When inserted along the vessel while contracted, the circumferential link 20 is almost folded as shown in FIG. 3A. After the stent is positioned at a desired position, the circumferential link 20 is expanded to deform the circumferential link 20 as shown in FIG. 3B.

The stent ring 10 is connected to each other by the axial link 30, the axial link 30 has a curved shape having two vertices 31, and the third curved portion 14 of the adjacent cell 11 The fourth curved portion 15 is connected. The shaft link 30 should be able to accommodate such bending when the stent is mounted on a curved vessel, etc., and has a structure that can secure a supporting force when it is expanded and fixed. This structure is embodied in a curved shape with two vertices 31, which accommodate the deformation of the cell 11 but also serve to support the vessel wall in a wide range to prevent the vessel wall from invading into the stent. do.

On the other hand, the axis link 30 need not limit the number of vertices 31 to two. That is, when the procedure is performed in a large number of warpage of the blood vessels, a stent having three or more vertices 31 may be used, and a stent having one vertex 31 may be used in a straight section. In general, however, it is stable to use the axial link 30 having two vertices 31 as in the present embodiment.

FIG. 5 is a schematic perspective view of a surgical stent of another embodiment according to the present invention, and FIG. 6 is an exploded view of the stent of FIG. 5 and 6, a surgical stent of another embodiment will be described.

Basically, the surgical stent of another embodiment according to the present invention has the same configuration as the embodiment shown in FIGS. 1 and 2, and the struts 17 connecting the third curved portion 14 and the fourth curved portion 15. ) Is additionally provided. The strut 17 can prevent the contraction in the axial direction by minimizing the deformation of the cell 11 that occurs during expansion. Since other configurations are the same as those in the above-described embodiment, detailed descriptions thereof will be omitted.

On the other hand, the cell 11, the circumferential link 20 and the shaft link 30 are all made of a flexible metal material. Such materials may be used as used for ordinary stents. In addition, it is preferable to form a space for accommodating the drug by performing a nano-fine process on the surface of the cell 11, the circumferential link 20 and the axial link 30 in order to further process the drug such as thrombolytics.

In addition, in order to improve the visibility of the stent, the cells 11 formed at the end of the stent may be clearly visible through the medical imaging device during or after implantation of the stent in the body lumen of the patient. It is preferably formed of a radio-opaque material such as gold, silver, platinum, or the like.

Using the stent as described above can minimize the contraction in the axial direction when inflated, there is an advantage that can be placed in the correct position.

In the above, the present invention has been described in detail with reference to preferred embodiments, but the present invention is not limited to the above embodiments, and various modifications can be made by those skilled in the art within the technical idea of the present invention. Is obvious.

10 ... stent ring 11 ... cell
12 ... first curve part 13 ... second curve part
14 ... 3rd curve 15 ... 4th curve
17 struts 20 circumferential links
21 ... Fifth Curve Section 30 ... Axial Link

Claims (5)

In a surgical stent that forms a cylindrical shape before and after expansion,
A first curved portion convex in the circumferential direction, a second curved portion concave in the circumferential direction, a third curved portion convex in the axial direction, and a fourth curved portion concave in the axial direction, the first curved portion being the third curve And an inflection point, respectively, and an inflection point, and the second curve part is connected to each of the third curve part and the fourth curve part to form an inflection point, thereby forming a closed curved surface therein, and a circumference A plurality of cells spaced apart in a line in a direction; And
A circumferential link connecting the first curved portion and the second curved portion of an adjacent cell and having a fifth curved portion convex in the axial direction; It comprises a ring-shaped stent ring consisting of,
Surgical stent, characterized in that the point where the first curved portion and the second curved portion meets the circumferential link is a point away from the central axis of the first curved portion and the second curved portion. The method according to claim 1,
A plurality of stent rings are arranged spaced apart in the axial direction,
An axial link having a plurality of vertices and connecting a third curved portion and a fourth curved portion of an adjacent cell in a curved shape; To
Surgical stents, characterized in that it further comprises. The method of claim 2,
The first curved portion and the second curved portion are symmetric with each other,
The third curved portion and the fourth curved portion are symmetric with each other,
And the fifth curved portion has a symmetrical shape with respect to a central axis. The method of claim 3,
The shaft link,
Surgical stent, characterized in that it has two vertices. 5. The method according to any one of claims 1 to 4,
The cell,
A strut connecting the third curved portion and the fourth curved portion; of
Surgical stents, characterized in that it further comprises.

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