KR101109719B1 - A stent Expansion formula - Google Patents

Abstract

The present invention relates to an expandable stent, a conventional stent has flexibility but does not maintain anti-pressure resistance, and also maintains anti-pressure resistance but does not maintain flexibility.

The present invention is to maximize the flexibility and anti-pressure resistance to the stent in order to solve the above problems and to be able to fully counter the vascular force to facilitate the procedure and contraction, and at the same time to expand the site to be treated.

In order to achieve this object, in the present invention, the upper unit bent portion formed by connecting a plurality of streamlined triangular bending members integrally along the longitudinal direction, and a plurality of streamlined inverted triangular bending members integrally connected along the longitudinal direction By constructing the lower unit bent portion configured, by connecting both sides of the upper unit bent member and the lower unit bent member to constitute a plurality of peanut-shaped unit bends in the longitudinal direction as a whole to form a cylindrical bent body, such bends The stent was configured by connecting a plurality of in the transverse direction with a "S" shaped connection in the transverse direction.

Expandable stents, laser processed stents, vascular stents, lumen stents, stents.

Description

A stent expansion formula

The present invention relates to an expandable stent, and more particularly, to expand and expand the lesion site, which is treated by coronary artery disease such as angina pectoris, myocardial infarction, or in the passage of the body (luminal) such as the airways, gastrointestinal tract, and biliary tract. It relates to an expandable stent for effective maintenance.

In general, stents have been used interchangeably with terms such as intravascular catheterization and expandable implants. It is used to have a path having the original size by expanding a lesion area that blocks and narrows the inside of the lumen by a lesion site such as a cancer occurring in the body passage (luminal cavity).

Such a stent includes a stent manufactured by a method of weaving a shape memory alloy wire as many applications and registered by the present inventors, or a stent made of a metal mesh made of stainless steel.

These stents have their own characteristics, but since the stent must support the lesion site and have the original passage of the vessel or lumen of the treated site, it is necessary to provide a sufficient pressure resistance to reach the procedure site. Flexibility is required because it must pass through the lumen.

Korean Patent Laid-Open Publication No. 10-1999-0013858 provides a stent in which wavy protrusions are formed in a horizontal branch to improve the flexibility of the stent, and 10-2001-0052430 provides a stent for improving flexibility in the longitudinal direction. Providing stents.

In addition, US Pat. No. 6,042,606 and US Pat. No. 6,398,805 provide an anti-pressure stent to effectively withstand the pressure of blood vessels.

However, the above-mentioned patents have flexibility but do not maintain anti-pressure resistance, and also have a problem of maintaining anti-pressure resistance but not maintaining flexibility.

The present invention is to maximize the flexibility of the stent of the present invention in order to solve the above problems and to facilitate the procedure, and also to maximize the anti-pressure resistance to be able to oppose the blood vessel force to shrink and at the same time the procedure It is to be able to expand evenly to the site.

In order to achieve the above object, in the present invention, the upper unit bent portion formed by connecting a plurality of streamlined triangular bending members integrally along the longitudinal direction, and a plurality of streamlined reverse triangular bending members integrally along the longitudinal direction. The lower unit bent portion formed by connecting the upper unit bent member and the lower unit bent member connected to each other as a whole constitute a plurality of peanut-shaped unit bent in the longitudinal direction to form a cylindrical curved body, such It consists of a plurality of the curved body in the transverse direction, but connected in the lateral direction with the "S" shaped connection, the "S" shaped connection is characterized in that the "S" type is composed of two curved ends and three straight ends Provide an expandable stent.

The stent of the present invention as described above can be effectively distributed external force because the cylindrical curved body consisting of a single unit is formed by connecting a plurality of integrally by the streamlined triangle and the bending member, the improvement of the dispersion force eventually It has an effect of having a corresponding force against the force generated in the expansion of the blood vessels, and bends inward by the "S" -shaped connection because the bent body formed in the transverse direction are connected to each other by the "S" -shaped connection in each unit After being stretched or stretched outwards, and after being narrowed inwardly or stretched outwards, a natural tendency to return to the original position occurs, providing a stent with overall flexibility.

Hereinafter, the present invention will be described in detail with reference to FIGS. 1 to 3 as follows.

The stent of the present invention is made of a cylindrical stainless steel or a cylindrical raw material having a material harmless to the human body, which is manufactured by a laser cutting method.

That is, the configuration of the stent of the present invention described below is to be manufactured by the method of removing the remaining parts while leaving the parts configured below when manufacturing while cutting the cylindrical stainless steel with a laser as described above.

The stent of the present invention prepared by this method will be described in detail.

Upper unit bent part (4) formed by connecting a plurality of integrally formed along the longitudinal direction by forming an upper unit bending member (3) integrally connected in a longitudinal direction to the streamlined triangular bending members (1), (2) , The lower unit bent part 14 constituted by connecting a plurality of units integrally along the longitudinal direction by configuring the lower unit bent member 13 having the streamlined reverse triangular bent members 11 and 12 integrally connected in the longitudinal direction. By connecting the two sides of the upper unit bending member (3) and the lower unit bending member 13 to each other with a connecting portion (5) as a whole constitute a plurality of peanut-shaped unit bending body 10 in the longitudinal direction of the cylindrical The first heat curved body 20 is constituted,

As described above, the upper unit bent part 3 is formed by connecting a plurality of unit members along the longitudinal direction by constituting the upper unit bent member 3 in which the streamlined triangular bent members 1 and 2 are integrally connected in the longitudinal direction ( 4) and the lower unit bent part composed of a streamlined inverted triangular bent member 11 and 12 integrally connected in the longitudinal direction to form a lower unit bent member 13 integrally connected to a plurality in the longitudinal direction. (14) to connect both sides of the upper unit bending member (3) and the lower unit bending member 13 to each other by the connecting portion (5) (15), the overall peanut-shaped unit bending body 10 in the longitudinal direction Comprising a plurality of to configure a cylindrical second heat curved body 30,

As described above, the upper unit bent part 3 is formed by connecting a plurality of unit members along the longitudinal direction by constituting the upper unit bent member 3 in which the streamlined triangular bent members 1 and 2 are integrally connected in the longitudinal direction ( 4) and the lower unit bent part composed of a streamlined inverted triangular bent member 11 and 12 integrally connected in the longitudinal direction to form a lower unit bent member 13 integrally connected to a plurality in the longitudinal direction. (14) to connect both sides of the upper unit bending member (3) and the lower unit bending member 13 to each other by the connecting portion (5) (15), the overall peanut-shaped unit bending body 10 in the longitudinal direction Comprising a plurality of to form a third columnar curved body 40,

In the same manner as the above, the cylindrical fourth heat curved body 50 is constituted by the cylindrical N-1 heat curved body N-1 and the cylindrical N-th heat curved body N,

The unit curved body 10 of the cylindrical first heat curved body 20 and the unit curved body 10 of the cylindrical second heat curved body 30 are connected to each other by an "S" shaped connection part 70. Thereby integrally connecting the cylindrical first heat curved body 20 and the cylindrical second heat curved body 30,

The unit bent body 10 of the cylindrical second heat curved body 30 and the unit bent body 10 of the cylindrical third heat curved body 40 are connected to each other by an "S" shaped connection part 70. The cylindrical third heat curved body 30 and the cylindrical third heat curved body 40 and the cylindrical third heat curved body 40 and the cylindrical fourth row by the same method of integrally connecting. The curved body 50 is integrally connected to each other, and eventually, the cylindrical N-1 heat curved body (N-1) and the cylindrical N-th heat curved body (N) are integrally connected to each other to be connected to the whole as a whole Provided is a stent of the present invention.

The stent of the present invention is to have a maximum pressure resistance while maximizing flexibility, which will be described in detail below.

First, in the present invention, in order to improve the breakdown voltage resistance, the cylindrical first heat curved body (20) to N-th heat curved body (N) consisting of a unitary streamlined triangular curved members (1), (2) and streamlined The inverted triangular bending members 11 and 12 are configured as one unit, but are connected to a plurality of them integrally.

The reason for this is that since the N-th heat-curve bodies N to N-th heat-curve bodies N are each formed of a curved triangle or an inverted triangle, the external force can be effectively dispersed. Improving the dispersing force will eventually have a response to the force generated when the blood vessels expand.

In addition, flexibility is required, as described above, to perform the stent of the present invention through the lumen or blood vessel to the position of the procedure, flexibility is required, which is the first heat bending body 20 to the N heat bending Sieves (N) are each connected to the "S" shaped connection portion 70 in one unit.

As shown in FIG. 4, the "S" -shaped connection part 70 is composed of two curved ends 70-1 and three straight ends 70-2. Therefore, when the stent of the present invention moves along the twisted lumen or blood vessel, the straight end 70-2 connecting the bent end 70-1 is applied to the bent end 70-1. By applying the bending end 70-1 is bent inward or outward to act.

By this action, the stent of the present invention can be easily bent as a whole, and also after bending, that is, after the bending end 70-1 is narrowed inward or extended outward, the action of returning to the original position is prevented. It occurs naturally.

Since the process of this action and the reaction is eventually bent form even when passing through the point where the first heat curved body 20 to the N-th heat curved body (N) bent in accordance with the shape, respectively through the lumen or blood vessel It can be easily passed while bending along.

This will eventually be bent or stretched in the overall configuration of the stent, so that it has the flexibility to easily pass along the bent lumen or blood vessel.

In this way, the present invention can be easily performed by maximizing the flexibility of the stent, and also to maximize the anti-pressure resistance to sufficiently oppose the force of the vessel to shrink and at the same time to expand the site to be treated uniformly It can be seen that it can be done.

In the present invention, the upper unit bending member 3 and the lower unit bending member 13 are connected to each other by the connecting portion 5 to constitute a whole peanut-shaped unit bending body 10, which is shown in FIG. As shown in the figure, the upper unit bending member 3 and the lower unit bending member 13 may be directly connected to each other without the connecting portion 5 to form the second unit bending body 60 having a peanut shape.

As described above, the cylindrical first heat curved body 20 to the N-th heat curved body N formed of one unit unit the streamlined triangular bending members 1 and 2 and the streamlined inverse triangle bending. While the members 11 and 12 are constituted by one unit, a plurality of them are integrally connected.

The reason for this is that since the N-th heat-curve bodies N to N-th heat-curve bodies N are each formed of a curved triangle or an inverted triangle, the external force can be effectively dispersed, and the dispersion force The result is that the response to the force generated during vasodilation eventually becomes coherent.

Flexibility As described above, since the N-th heat-curve (N) is connected to each of the "S" -shaped connecting portion 70 in one unit, the flexibility is maintained as it is.

1 is an exploded view of a state in which the cylindrical stent of the present invention is deployed.

2 and 3 is a cross-sectional view of a partial excerpt of the present invention stent.

4 is a reference configuration of the main portion of the excerpt of the present invention stent.

5 is another exemplary embodiment of the present invention.

Description of the Related Art

1.2: streamlined triangular bending member 3: upper unit bending member

4: upper unit bent part 5: connection part

10: peanut-shaped unit bending body 13: lower unit bending member

14: lower unit bend 20: cylindrical first heat curved body

20: cylindrical second heat curved body 40: cylindrical third heat curved body

N-1: N-1th heat curved body N: Nth heat curved body

Claims (3)

In stents produced by laser cutting of stainless steel, An upper unit bent part (4) formed by connecting a plurality of units integrally along the longitudinal direction by constituting the upper unit bent member (3) integrally connecting the streamlined triangular bent members (1) and (2) in the longitudinal direction; The lower unit bent part 14 formed by connecting the streamlined reverse triangular bent members 11 and 12 integrally in the longitudinal direction and integrally connecting a plurality of the lower unit bent members 13 in the longitudinal direction is formed. By connecting both sides of the upper unit bending member (3) and the lower unit bending member 13 to each other by the connecting portion 5 to form a plurality of peanut-shaped unit bending body 10 in the longitudinal direction as a whole Constitute a one-row bend body 20, As described above, the cylindrical second heat curved body 30, the cylindrical third heat curved body 40, the cylindrical fourth heat curved body 50, and the cylindrical N-1 heat curved body N -1) and the cylindrical N-th heat bending body (N) in sequence, The cylindrical second heat curved body 30, the cylindrical third heat curved body 40, the cylindrical fourth heat curved body 50 ... the cylindrical N-1 heat curved body N-1 And connect each of the N-th columnar curved body (N) of the cylindrical "S" shaped connection portion 70, The "S" shaped connection part 70 is an expandable stent, characterized in that "S" type is composed of two curved ends (70-1) and three straight ends (70-2). delete The method according to claim 1, Expandable stent, characterized in that the upper unit bending member (3) and the lower unit bending member 13 directly connected to each other to form a peanut-shaped second unit curved body (60).

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