KR100351319B1 - Stent graft - Google Patents

Abstract

The present invention is to minimize the size of the cross-sectional area and to reduce the movement in the vessel by minimizing the volume of the cross-sectional area and to ensure that the stent is excellent in the longitudinal flexibility is bonded to the outer wall of the artificial blood vessel, the size of the inserter, The present invention relates to an artificial blood vessel stent that can prevent and prevent the risk of falling of the connection with the stent.

The artificial blood vessel body is inserted into the artery to prevent the pressure inside the blood vessel from being applied to the weakened blood vessel wall, and the artificial blood vessel body is provided to the artificial blood vessel body and contracts when the external force is applied, and when the external force is removed, it expands to its original shape. In the artificial blood vessel stent comprising a stent for maintaining the artificial blood vessels in a constant shape,

The stent is coupled to the outer surface of the artificial blood vessel body at regular intervals, and consists of first and second unit structures connected in turn and zigzag to correspond to each other to form a node.

Description

Artificial blood vessel stent {STENT GRAFT}

The present invention relates to an artificial blood vessel stent, and more particularly, the volume of the cross-sectional area is minimized when it is contracted, the size of the inserter can be minimized, and the connection to the stent may fall while preventing deformation of the artificial blood vessel. The present invention relates to an artificial blood vessel stent that eliminates the risk and prevents the movement of the stent in the blood vessel when the stent is installed inside the blood vessel.

In general, an aneurysm is a disease caused by swelling of an artery, such as a balloon. It is a very dangerous disease because the weakened blood vessel wall can be ruptured if the pressure in the blood vessel rises above a certain size.

Conventional methods for treating such an aneurysm include a surgical procedure that replaces artificial blood vessels through surgical surgery, excision of the skin of the lesion to expose the artery to the outside, and then inserting an artificial blood vessel stent into the inside of the artery using an intubation apparatus. It is largely classified as an incision.

According to the above incision treatment method, the skin should be incised by a certain length, and it is desirable to reduce the pain to the patient and to reduce the incision of the skin so that the patient can recover quickly. In addition to the small size of the inserter, the cross-sectional area of the stent inserted into the inserter needs to be reduced to a small volume.

In addition, the contraction of the stent extends in the longitudinal direction, but the artificial blood vessels are not stretched at all, so when the stent is stretched a lot when contracting the artificial blood vessel stent, that is, the flexibility in the longitudinal direction is deteriorated and the shape of the artificial blood vessels is deformed. Since there is a risk that the connection with the stent falls, therefore, when the artificial vessel stent contracts, the pressing of the stent in the longitudinal direction is minimized, so the flexibility in the longitudinal direction needs to be excellent.

The artificial blood vessel stent inserted into the artery using the inserter as described above has an elastic force of its own so that the artificial blood vessel body and the artificial blood vessel body can be inserted into the artificial blood vessel body while maintaining the shape of the artificial blood vessel body. It is made of stents.

The conventional stent is generally made of stainless steel wire and are arranged at regular intervals, respectively, to form a plurality of turn parts zigzag turn to form a cylindrical shape, by connecting the turn part and the adjacent turn part again with a stainless steel wire Since the volume of the cross-sectional area is increased when the stent is contracted, the flexibility in the longitudinal direction is greatly reduced.

Therefore, the present invention has been proposed to solve the above problems, and an object of the present invention is to minimize the volume of the cross-sectional area when the contraction is contracted, the stent having excellent longitudinal flexibility is coupled to the outer wall of the artificial blood vessel, and the size of the inserter Minimize the risk of artificial blood vessel deformation, eliminate the risk of falling of the connection with the stent, and install an artificial blood vessel stent that prevents the movement of the stent in the vessels when installing the stent inside the vessel. To provide.

In order to achieve the above object, the present invention provides a artificial blood vessel body for blocking the pressure applied to the vessel wall is inserted into the artery and weakened inside the blood vessel, and provided to the artificial blood vessel body and contracted when an external force is applied. In addition, in the artificial blood vessel stent including a stent to expand the original shape when the external force is removed to maintain the artificial blood vessel in a constant shape,

The stent is coupled to the outer surface of the artificial blood vessel body at regular intervals, and is composed of first and second unit structures connected in turn by zigzag to correspond to each other to form a node.

1 is a partially exploded perspective view showing the artificial vessel stent in accordance with the present invention.

Figure 2 is a perspective view showing a bonding state of the artificial vessel stent in accordance with the present invention.

Figure 3 is a plan view showing an artificial vessel stent in accordance with the present invention.

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

1 is a partially exploded perspective view showing an artificial blood vessel stent according to the present invention, Figure 2 is a perspective view showing a bonding state of the artificial blood vessel stent according to the present invention, Figure 3 shows an artificial blood vessel stent according to the present invention Top view.

The artificial blood vessel stent according to the present invention includes an artificial blood vessel body (1) inserted into an artery to block the pressure inside the blood vessel from being applied to a weakened blood vessel wall;

The stent 3 is provided on the outer surface of the artificial blood vessel body 1 and is contracted when an external force is applied, and when the external force is removed, the stent 3 is expanded to its original shape to maintain the artificial blood vessel in a constant shape.

The stent 3 is coupled to the outer surface of the artificial blood vessel body 1 at regular intervals, and the first and second unit structures 5 and 7 which are connected in turn by zigzag to correspond to each other to form nodes. Is done.

The first and second unit structures 5 and 7 may be formed of a material having shape memory properties excellent in shrinkage and expandability.

The first and second unit structures 5 and 7 are preferably twisted at least once so as to increase expandability.

The first and second unit structures 5 and 7 are formed in such a manner that each of the first and second unit structures can be extended in the longitudinal direction about their connecting portion so that the flexibility in the longitudinal direction can be improved. The first and second unit structures 5 and 7 adjacent to the two unit structures are spaced apart from each other.

In addition, the first and second unit structures (5) (7) is preferably protruded by a predetermined length to the outside of both ends of the artificial blood vessel so as to ensure the expansion of a certain size.

The first and second unit structures 5 and 7 are connected to artificial blood vessels by a connecting string 9, and the connecting string 9 is connected to the first and second unit structures 5 when the stent is contracted. It is preferable that the first and second unit structures are connected to the kinks connected to each other so that the cross-sectional area of (9) can be reduced to a small volume.

The first and second unit structures 5 and 7 are connected to the artificial blood vessel body 1 by a connection string 11 at regular intervals so as to be more firmly connected to the artificial blood vessel body 1.

The artificial blood vessel stent constructed as described above is first inserted into an inserter (not shown) before being inserted into the artery while a part of the artery is incised, and for this purpose, the artificial blood vessel stent is contracted to be inserted into the inserter. .

That is, when the stent 3 is contracted together with the artificial blood vessel body 1 of the artificial blood vessel stent, the first and second unit structures 5 and 7 of the stent 3 are connected to each other, that is, the connecting string ( 9) the cross-sectional area is contracted to the minimum volume while opening in the longitudinal direction of the stent (3). In other words, the diameter of the inserter is smaller than the diameter of the artificial vessel stent in the initial state. When the side surface of the artificial vessel stent is pressed in order to insert the artificial vessel into the small diameter inserter by the elastic force of the first and second unit structures, The diameter of the artificial vessel stent may be inserted into the inserter so that the diameter of the artificial vessel stent is changed to a diameter smaller than that of the inserter so that the inserter can be inserted into the inserter.

At this time, since the first and second unit structures 5 and 7 are coupled to each other in a state in which the first and second unit structures 5 and 7 are adjacent to the pair of first and second unit structures adjacent to the first and second unit structures, the stents 3 are spaced apart from each other. During the contraction of the stent, the flexibility in the longitudinal direction is improved so that the length of the stent does not extend in the longitudinal direction, and the first and second unit structures 5 and 7 of the stent 3 are formed on the outer wall of the artificial blood vessel body 1. Since it is coupled, part of the first and second unit structures 5 and 7 is immersed in the inner wall of the blood vessel, thereby preventing movement of the stent in the blood vessel in the process of installing the stent inside the blood vessel.

As such, the present invention minimizes the volume of the cross-sectional area and reduces the movement of the stent, which may occur in the process of installing the stent in the interior of the blood family by combining the stent having excellent longitudinal flexibility with the outer wall of the artificial blood vessel. In addition, the size of the inserter is minimized, and the artificial blood vessels are prevented from being deformed, and the connection with the stent has the effect of removing the risk in advance.

Claims (5)

The artificial blood vessel body is inserted into the artery to prevent the pressure inside the blood vessel from being applied to the weakened blood vessel wall, and the artificial blood vessel body is provided to the artificial blood vessel body and contracts when the external force is applied, and when the external force is removed, it expands to its original shape. In the artificial blood vessel stent comprising a stent for maintaining the artificial blood vessels in a constant shape, The stent includes a plurality of first and second unit structures which are coupled to the outer surface of the artificial blood vessel body and are respectively connected to each other to form a node; The first and second unit structures are disposed to be spaced apart from another adjacent first and second unit structures; The first and second unit structures are artificial blood vessel stents are connected by twisting at least one time to increase the expandability. delete delete The artificial blood vessel stent of claim 1, wherein the first and second unit structures are connected to the artificial blood vessel body at regular intervals by a connecting string. The artificial blood vessel stent of claim 4, wherein the connecting strap is connected to a site where the first and second unit structures are twisted to each other so that the cross-sectional area of the first and second unit structures can be shrunk when the stent is contracted. .