KR20140056610A - Peripheral blood vessel stent - Google Patents

Abstract

The present invention provides a peripheral blood vessel stent which includes a stent body and a stent bridge. The stent body includes: a first stent part formed in the shape of a ring by struts connected to each other and arranged in a zigzagged manner; a second stent part; and a third stent part. The stent bridge includes a first bridge formed to connect the first stent part and the second stent part at the same level and a second bridge formed to connect the second stent part and the third stent part at each different level.

Description

PERIPHERAL BLOOD VESSEL STENT < RTI ID = 0.0 >

The present invention relates to a peripheral vascular stent.

In general, many blood vessels in the human body are connected to the main body parts, which serves as a channel for circulation of blood. If blood vessel stenosis such as clogging or narrowing of various blood vessels due to various factors occurs, internal or external problems due to lowered blood circulation may occur.

In order to solve such a problem of stenosis of the blood vessel, stent implantation for expanding the narrowed blood vessel by inserting the instrument into the vascular stenosis site is mainly used.

Stenting is a technique that uses a tool such as a catheter to insert a compressed metal stent into the vessel stenosis and dilate the narrowed blood vessel by expanding the inserted stent to a certain volume within the vessel. This stent technique should support a certain level of rigidity because it supports the inner wall of the blood vessel and prevents blood vessel re-energization.

Particularly, in the case of a stent inserted into a peripheral blood vessel distributed in an arm or a leg where frequent movements occur due to a physical characteristic, it is necessary to include a certain level of flexibility as well as rigidity, since it can be deformed naturally according to the movement of the body in the blood vessel. have.

It is an object of the present invention to provide a peripheral vein stent including both stiffness and flexibility by varying the connection structure of the stent.

A peripheral vascular stent according to an embodiment of the present invention for realizing the above-mentioned problems includes a first stent part formed in a ring shape by struts connected to each other so as to be arranged in a staggered manner, a second stent part, A stent body having a portion; And

A stent bridge having a first bridge formed to connect the first stent and the second stent in the same phase and a second bridge configured to connect the second stent and the third stent in different phases; ≪ / RTI >

Each of the first stent portion and the third stent portion may further include a bent portion having a curved shape connecting two adjacent struts.

The second bridge may be formed to connect the bent portion of the third stent portion having a phase difference of 1/6 to 1/2 with the bent portion of the second stent portion.

The first bridge may be formed to be set in proportion to the number of struts of the first stent portion and the second stent portion.

The bend portion not connected by the first bridge and the second bridge may be formed by bending the end portion toward the central axis direction of the stent body.

The first bridge may be formed to linearly connect the bent portion of the second stent portion, which is located in the same phase symmetrical with the bent portion of the first stent portion.

The second bridge may be formed to connect the bent portion of the third stent portion, which is located at a different phase asymmetric with the bent portion of the second stent portion, in an oblique direction.

The stent body may further include a fourth stent, and the stent bridge may further include a third bridge formed to connect the third stent and the fourth stent in different phases.

The third bridge may be formed to connect the bent portion of the fourth stent portion, which is located at another phase asymmetric with the bent portion of the third stent portion, in a diagonal direction intersecting the extension line of the second bridge.

According to the peripheral vascular stent of the present invention configured as described above, the rigidity and flexibility of the stent can be included by bridges connecting the vital stent differently.

In addition, when the stent is bent due to the movement of the body, the damage of the inner wall of the blood vessel due to the bent portion can be reduced or prevented because the end of the bent portion is formed by bending in the direction of the central axis of the stent body.

1 is a plan view of a peripheral vein stent 10 according to an embodiment of the present invention.
FIG. 2 is a side view of a circumscribed peripheral vein stent 20 in accordance with an embodiment of the present invention.
3 is a perspective view in which an end portion of the bent portion 32 according to an embodiment of the present invention is formed in the direction of the central axis of the stent 30.

Hereinafter, a peripheral blood vessel 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, different embodiments are given the same or similar reference numerals, and the description thereof is replaced with the first description.

1 is a plan view of a peripheral vein stent 10 according to an embodiment of the present invention.

Referring to the drawings, the stent 10 may include a stent body 11 and a stent bridge 16. [

The stent body 11 may include a first stent portion 11a, a second stent portion 11b, a third stent portion 11c, and a fourth stent portion 11d. A plurality of struts 13 are arranged in a staggered arrangement and each of the stent portions 11a, 11b, 11c, and 11d is connected to each other. May be formed in proportion to the number of struts (13).

The stent bridge 16 may include a first bridge 16a, a second bridge 16b, and a third bridge 16c.

The first and second stent parts 11a and 11b may be connected by a first bridge 16a. The first bridge 16a can connect the bend portions 14 of the first and second stent portions 11a and 11b symmetrically arranged in the same phase in a linear direction. At this time, the first bridge 16a is formed in a plurality and is spaced apart from the adjacent bridges by a predetermined number of struts 13, so that the respective bends 14 can be connected. The first and second stent parts 11a and 11b are linearly connected at the shortest distance by the first bridge 16a in the same phase so that the first and second stent parts 11a, 11b can be improved.

The second and third stent parts 11b and 11c may be connected by a second bridge 16b. The second bridge 16b can connect the bending portion 14 of the third stent portion 11c located at another phase which is asymmetrical with the bending portion 14 of the second stent portion 11b in the oblique direction. The second and third stent parts 11b and 11c are connected in different phases by the second bridge 16b extending in the oblique direction so that the second and third stent parts 11b and 11c are moved along the second bridge 16b in the direction of each bending part 14, It can be moved by a distance. Therefore, it is possible to have a higher flexibility in comparison with the structure of the stent part which is connected and fixed by a straight line.

The third and fourth stent parts 11c and 11d may be connected by the third bridge 16c. The connection direction of the third and fourth bridges 16b and 16c may be the same as that of the second and third stent sections 11b and 11c described above, have. Therefore, the second and third stent portions 11b and 11c can have flexibility similar to the connection. In addition, the second and third bridges 17 and 19 are connected to one direction and the other direction of the third stent portion 11c in the diagonal directions intersecting with each other, so that they can be deformed in various directions according to the external movement.

The first, second and third bridges 16a, 16b and 16c can be set in proportion to the number of the struts 13 of the first and second stent parts 11a and 11b, Between each bridge being connected there may be 2 to 6 bends 14.

Thus, the stent body 11 is sequentially connected with the first stent portion 11a through the fourth stent portion 11d through stent bridges 16 in different phases, whereby stiffness in the stent portion connected in the same phase And the flexibility of the stent part connected at different phases can be improved.

The bent portions 14 of the second and third stent portions 11b and 11c and the third and fourth stent portions 11c and 11d connected to each other by the second and third bridges 16b and 16c are in a range of 1/6 1/2 phase difference, and in the present invention, it is preferable to have a phase difference of 1/4.

Depending on the position of the stent 10 and the positions of the strut 13, the bending portion 14 and the stent bridge 16 formed in the stent 10, . In the case where a plurality of struts 13, bends 14 and bridges are formed, the peripheral structure of the stent 10 may be dense and rigidity may be increased, but flexibility may be weakened due to high binding force. On the other hand, when too few struts 13, bends 14 and bridges are formed, the flexibility may be increased due to the simple structure, but the rigidity may be weakened.

Therefore, since stiffness and flexibility can be inseparable, it will be necessary to construct the number of the most efficient ratios. In the present invention, the preferred number of struts 13, bends 14, and bridges is 36, 18, and 4 based on the unidirectional stent. The present invention is not limited thereto and can be applied differently depending on experimental and process conditions.

The stent body 11 having such a configuration is configured such that the first stent portion 11a, the second stent portion 11b, the third stent portion 11c, and the fourth stent portion 11d are sequentially connected, The rigidity can be increased in the connection of the two stent parts 11a and 11b and the flexibility can be increased in the connection of the second and third stent parts 11b and 11c and the third and fourth stent parts 11c and 11d. Accordingly, the stent 10 in which the stent body 11 is repeatedly formed may include both stiffness and flexibility by continuing the stent part as described above.

In the case of the fourth stent part 11d, the bending part 14 in one direction is connected to the third stent part 11c in an oblique direction so as to increase the flexibility, and the bending part 14 in the other direction is connected to the second stent part 11b ) In a straight line direction to increase rigidity. Such a case where one stent part is overlapped and connected to the other stent part in the same phase and another phase in one direction and the other direction and that the stent 10 includes rigidity and flexibility through connection of the bridges, .

FIG. 2 is a side view of a circumscribed peripheral vein stent 20 in accordance with an embodiment of the present invention.

1, the bent portions 24 of the first and second stent portions 21a and 21b, which are symmetrically arranged in the same phase as described in Fig. 1, are connected by a first bridge 26a to a plurality of linear connection portions The rigidity can be improved by increasing the bonding force.

Further, the bending portions 24 of the second and third stent portions 21b and 21c, which are formed asymmetrically in different phases, can be connected to each other in a diagonal direction by the second bridge 26b. Considering that the material of the stent 20 is an elastic material, the second and third stent portions 21b and 21c diagonally connected to each other in a diagonal direction are arranged in a predetermined range limited by the diagonal second bridge 26b Can be deformed.

The third and fourth stent portions 21c and 21d have different phases through the third bridge 26c like the second and third stent portions 21b and 21c and the asymmetric bending portion 24 is inclined in the diagonal direction . By connecting through the third bridge 26c in the oblique direction intersecting the extended line of the second bridge 26b, it is possible to deform in various directions due to the movement of the outside, and flexibility and applicability can be improved.

The stent 20 shown in this figure has a structure in which each of the bent portions 24 formed in the stent portion is inserted into the inside of the blood vessel when the stent portions 21a, 21b, 21c, and 21d are not sufficiently expanded, They can be separated from each other by a predetermined interval. When the stent 20 is inserted for the purpose of inserting the inside of the blood vessel, the bending portion 24 of the stent portion formed in the confronting direction can be moved to the inside and spaced apart.

These stent portions may be repeatedly connected in the 'same phase-different phase-different phase' by the first bridge 26a, the second bridge 26b, and the third bridge 26c.

The fourth stent portion 21d of the figure is connected to the third stent portion 21c in a different phase in one direction and is connected to the second stent portion 21b repeated in the other direction Phase. ≪ / RTI > Therefore, it is possible to realize both rigidity and flexibility with a difference in direction through one stent part.

In this figure, each stent section is connected in such a way that the 'same phase-different phase-different phase' is repeated, but if the stiffness or flexibility is to be further strengthened according to the experimental or process conditions, the stent section You can add more. In addition, the number of the struts 23, the bent portions 24, and the bridges 26a, 26b, 26c may be adjusted to an optimum ratio to change the rigidity or flexibility.

The stent 20 having the above-described configuration can be bent to a certain extent when the subject's body inserted with the stent 20 is generated. In this case, Will be described in detail with reference to FIG.

3 is a perspective view in which an end portion of the bent portion 32 according to an embodiment of the present invention is formed in the direction of the central axis of the stent 30.

Referring to the drawings, the stent portion 31 in which the plurality of bent portions 32 are formed in one direction and the other direction, respectively, may bend in a certain range due to external motion and impact. In this case, the bent portion 32 except for the bent portion 32 connected through the bridge 33 can be partially protruded in the direction in which deformation occurs.

Since the stent 30 is held in contact with the blood vessel wall outwardly, there is a possibility that the blood vessel wall is damaged when the bending portion 32 protrudes outward. Therefore, by forming the end portion of the bending portion 32 that is not connected to the bridge 33 to be bent at a predetermined angle in the direction of the central axis of the stent 30, it is possible to prevent the end portion of the bending portion 32 from damaging the blood vessel wall have. This can be confirmed in more detail through the enlarged part of the drawing.

Generally, the end portion of the bent portion 32 is formed in a corner shape, and can have a sharp structure. By forming the end portion with a smooth structure, it is possible to reduce or prevent damage to a blood vessel wall that may occur in a conventional sharp structure. When the end portion of the bent portion 32 is formed in the direction of the center of the blood vessel, the blood circulates partially due to collision with the blood circulating in the blood vessel, thereby preventing the blood circulation. Thus, May be desirable.

The stent portion 31, which is connected in the same phase and in different phases through the structure and structure, is repeatedly formed in a predetermined pattern, thereby providing the stent 30 including both rigidity and flexibility. In addition, since the end of the bent portion 32 is formed to face the direction of the center of the blood vessel, the damage of the blood vessel wall due to the bent portion 32 can be reduced or prevented.

Such peripheral vascular stents are not limited to the construction and operation of the embodiments described above. The above embodiments may be configured such that all or some of the embodiments may be selectively combined so that various modifications can be made.

10, 20, 30: stent
11, 21: stent body
11a, 21a: a first stent part
11b, 21b: a second stent part
11c, 21c: a third stent part
11d, 21d: a fourth stent part
13, 23: strut
14, 24:
16, 26: Stand bridge
16a, 26a: a first bridge
16b, 26b: a second bridge
16c, 26c: third bridge

Claims (9)

A stent body having a first stent portion, a second stent portion, and a third stent portion formed in a ring shape by struts connected to each other so as to be arranged in a zigzag manner; And
A stent bridge having a first bridge formed to connect the first stent part and the second stent part in the same phase and a second bridge formed to connect the second stent part and the third stent part in different phases; 0.0 > a < / RTI > peripheral vascular stent.
The method according to claim 1,
Wherein each of the first stent portion and the third stent portion comprises:
Further comprising a bend having a curved shape connecting two adjacent struts.
3. The method of claim 2,
Wherein the second bridge comprises:
And the bending portion of the third stent portion having a phase difference of 1/6 to 1/2 with the bending portion of the second stent portion.
3. The method of claim 2,
The first bridge
And is formed to be set in proportion to the number of struts of the first stent portion and the second stent portion.
3. The method of claim 2,
Wherein the bent portion, which is not connected by the first bridge and the second bridge,
Wherein the distal portion is bent and formed so as to face the central axis direction of the stent body.
3. The method of claim 2,
The first bridge
And is configured to linearly connect the bend of the second stent portion, which is located in the same phase symmetrical with the bend of the first stent portion.
3. The method of claim 2,
Wherein the second bridge comprises:
And the bending portion of the third stent portion, which is located at a different phase asymmetrical with the bent portion of the second stent portion, is formed to connect in an oblique direction.
8. The method of claim 7,
The stent body further includes a fourth stent portion,
Wherein the stent bridge further comprises a third bridge configured to connect the third stent and the fourth stent in different phases.
9. The method of claim 8,
The third bridge includes:
And is configured to connect the bend of the fourth stent portion in a different phase asymmetrical with the bend of the third stent portion in an oblique direction intersecting an extension of the second bridge.

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