KR102125954B1 - Horizontally installable stent unit - Google Patents

Abstract

The present invention, the horizontally installable stent unit, a pair of catheters to form an inner space consisting of a long tubular shape along the longitudinal direction; A pair of stent bodies each coupled to surround the outer surface of the pair of catheters, and a cylindrical stent consisting of stent connections each of which is coupled to the stent body so as to connect the pair of stent bodies; It is a technical point to include a pair of guide wires that are installed through the inner space of the catheter and guide the pair of catheters to be moved to the lesion. Accordingly, when a cerebral aneurysm corresponding to a lesion is located at a branch of a blood vessel, a stent is inserted into both separated blood vessels where the neck of the cerebral aneurysm is located. You can prevent the deviation. In addition, the present invention can obtain an effect capable of horizontally installing the stent with two blood vessels branched from blood vessels in the direction in which the instrument approaches as well as a cerebral aneurysm.

Description

Horizontally installable stent unit {Horizontally installable stent unit}

The present invention relates to a horizontally installable stent unit, and more specifically, when a cerebral aneurysm corresponding to a lesion is located at a branch of a blood vessel, the stent is inserted into both separated blood vessels where the neck of the cerebral aneurysm is located. The present invention relates to a stent unit capable of preventing the separation of the coil during embolization of an aneurysm by inserting the stent horizontally to the neck. In addition, the present invention relates to a stent unit capable of horizontally installing a stent with two blood vessels branched from a blood vessel in a direction in which the instrument approaches as well as a cerebral aneurysm.

Cerebral aneurysm refers to a disease in which the inner wall of the cerebral blood vessel and the middle membrane are damaged and damaged, resulting in swelling of the walls of blood vessels and the formation of space in the blood vessels. If such a cerebral aneurysm is left untouched, the thickness of the blood vessel wall may be thinned or damaged by the pressure caused by the continued blood flow, and a problem may occur in which the corresponding area bursts.

Cerebral aneurysm ligation and coil embolization are largely used to treat cerebral aneurysms. Cerebral aneurysm ligation is a traditional method performed in neurosurgery. It is a surgical technique in which a skull piece is removed and a cerebral aneurysm located between brain tissues is ligated with a small clip. On the other hand, coil embolization is a surgical method in which a catheter is inserted through the femoral artery on the leg side to access the cerebral artery, and then the coil is inserted into the aneurysm to prevent it. Coil embolization, unlike cerebral aneurysm ligation, does not perform an cranial opening procedure, thus shortening the operation time and recovering within a few days after the procedure, which has the advantage of normal operation. The method using the coil embolization is to prevent the blood flow from flowing into the brain aneurysm by filling the coil inside the brain aneurysm. About 20% of the methods using coil embolization can be performed with coil embolization without the use of an auxiliary device. However, in the treatment of a cerebral aneurysm with a wide neck of the aneurysm, a technique of installing a cylindrical stent in the lumen of the capillaries where the cerebral aneurysm has occurred is used to block the entrance of the cerebral aneurysm.

Stent (stent) is a surgical instrument that is mainly used for intravascular procedures, is inserted into the catheter and installed in the blood vessel by moving in the direction in which the catheter is located. These stents are used to sufficiently occlude a cerebral aneurysm, or serve to safely support the embolic coil so that it does not escape into blood vessels. The role for preventing the escape of the embolization coil may be maximized when the stent properly blocks the neck of the cerebral aneurysm, but the stent may not completely cover the neck due to the appearance of the cerebral aneurysm. If such a stent can be placed horizontally against the neck of a cerebral aneurysm, the aneurysm can be safely and sufficiently occluded.

However, a cerebral aneurysm located in a cracked blood vessel cannot completely cover the neck using a stent due to the positional relationship between the blood vessel and the cerebral aneurysm, thus overlapping or dividing two or more stents 10 in various ways as shown in FIG. 1. You have to do it. At this time, FIG. 1A is a horizontally installed stent 10, which is very difficult to install in this way, and FIG. 1B does not completely cover the neck with the stent 10 installed only on one side of the blood vessel. In addition, FIGS. 1C and 1D are two stents 10 installed, and FIG. 1E also crosses and installs two stents 10, but this also fails to properly cover the neck. In this way, the neck of the cerebral aneurysm cannot be completely covered, or the stent 10 is overlapped within the blood vessel to narrow the blood vessel, or the stent 10 occupies a lot of space, so access to the next device is often blocked.

Korea Patent Office Registration Patent No. 10-1480514 Republic of Korea Patent Office Publication No. 10-2016-0022597 Republic of Korea Patent Office Publication No. 10-2014-0140077

Therefore, an object of the present invention, when a cerebral aneurysm corresponding to a lesion is located in a branch of a blood vessel, the stent is inserted into both separated blood vessels where the neck of the cerebral aneurysm is located, and the aneurysm is inserted horizontally against the neck of the cerebral aneurysm. It is to provide a stent unit that can prevent the separation of the coil during embolization of.

In addition, the present invention provides a stent unit capable of horizontally installing a stent with two blood vessels branched from a blood vessel in a direction in which the instrument approaches as well as a cerebral aneurysm.

The above object is made of a long tube shape along the longitudinal direction and a pair of catheters to form an interior space; A pair of stent bodies each coupled to surround the outer surface of the pair of catheters, and a cylindrical stent consisting of stent connections each of which is coupled to the stent body so as to connect the pair of stent bodies; It is achieved by a horizontally installable stent unit, each of which is installed through the inner space of the catheter and includes a pair of guide wires that guide the pair of catheters to move to the lesion.

Here, the pair of the catheter includes a stent support portion in which the outer surface to which the stent body is coupled is recessed by a predetermined thickness, and it is preferable that the stent body is supported on the stent support portion.

The stent connection portion is coupled only partially along the circumference to the outer surface of the stent body to enable bending, and the stent connection portion is preferably combined by 1/5 to 1/3 of the entire circumference of the outer surface of the stent body. .

In addition, the pair of catheters is made of fiber reinforced plastic (FRP) material, and it is preferable that the stent body and the stent connection are made of a shape memory alloy material.

According to the present invention, when a cerebral aneurysm corresponding to a lesion is located at a branch of a blood vessel, a stent is inserted into both separated vessels where the neck of the cerebral aneurysm is located, and an embolization of the aneurysm is performed by inserting the stent horizontally against the neck of the cerebral aneurysm. The coil can be prevented from falling off.

In addition, the present invention can obtain an effect capable of horizontally installing the stent with two blood vessels branched from blood vessels in the direction in which the instrument approaches as well as a cerebral aneurysm.

1 is a cross-sectional view showing a method of installing a stent according to the prior art,
2 is a cross-sectional view of a stent unit according to an embodiment of the present invention,
3 is a perspective view of the stent,
Figure 4 is a cross-sectional view of a stent unit according to the prior art and embodiments of the present invention,
5 is an explanatory view showing a method of installing a stent unit according to an embodiment of the present invention.

Hereinafter, a horizontally installable stent unit according to an embodiment of the present invention will be described in detail through the drawings.

2, the stent unit 100 includes a pair of catheters 110 and a stent 130.

The pair of catheters 110 is formed in an elongated tubular shape in the longitudinal direction to form an internal space, and includes proximal and distal ends, respectively, at both ends. Here, the proximal tip means an end close to the operator, and the distal tip means an end approaching the target point. The catheter 110 is flexible, but is preferably made of a fiber reinforced plastic (FRP) material having a stiffness that is not damaged by the external force of the operator's hand.

The stent 130 is composed of a pair of stent body 131 and a stent connection 133 as shown in FIG. 3. A pair of stent bodies 131 are respectively coupled to surround the outer surface in the proximal end region of the catheter 110, and the stent connection 133 is a pair of each coupled to the outer surface of the catheter 110 consisting of a pair. Both ends are respectively coupled with the stent body 131 to connect the stent body 131.

The stent 130 is in a state where the stent body 131 is coupled to the respective catheters 110 by the stent connection part 133, so that the stent 130 is configured to enable such a structure. It is desirable to be bonded to the outer surface. As shown in Figure 4a, in the case of a stent used for conventional cerebral aneurysm embolization, it is inserted into the internal space of the catheter and moves to the lesion. However, the stent unit 100 according to the present invention cannot be used through such a conventional structure. Therefore, in the present invention, the stent 130 is coupled to the outside of the catheter 110 as shown in FIG. 4B.

The pair of catheters 110 includes a stent support 111 in which the outer surface to which the stent body 131 is coupled is recessed by a predetermined thickness so that the stent 130 can be coupled to the outer surface of the catheter 110, The stent body 131 is supported on the stent support 111. If the recessed stent support 111 does not exist, the stent 130 is coupled in a protruding state from the outer surface of the catheter 110, and this structure is a process in which the catheter 110 is inserted into a blood vessel and moved to a lesion. The stent 130 may damage the blood vessel wall, or the stent 130 may be detached from the catheter 110. Therefore, such a problem can be prevented through the stent support 111. The thickness of the stent supporting portion 111 is preferably recessed to the same thickness as the thickness of the stent body 131, or is thin, but is not limited thereto.

When the catheter 110 and the stent 130 are inserted into the blood vessel, a pair of catheters 110 are inserted in the same direction and then split at the lesion site where the stent 130 is installed, so that the stent connection 133 is unfolded. do. Therefore, the stent connection portion 133 connecting the pair of stent bodies 131 to allow such movement is formed to be bendable. It is preferable that the stent connection part 133 is only partially coupled along the circumference to the outer surface of the stent body 131 to allow bending. When the stent connection portion 133 is coupled to the entire area along the outer surface circumference of the stent body 131, bending is impossible, so that only the circumference is coupled, preferably having a length corresponding to the length of the circumference as a cross section. A stent connection 133 may be formed. At this time, the stent connection part 133 may be formed in a plate shape or a dome shape, and if it is formed in a dome shape, it has a shape similar to the circumference of the stent body 131 and corresponds to a shape similar to the inner surface of the blood vessel. Therefore, the neck of the cerebral aneurysm can be easily occluded. The stent connection portion 133 is preferably coupled by 1/5 to 1/3 of the entire circumference of the outer surface of the stent body 131. If the stent body 131 is less than 1/5 around the outer surface, the cross-sectional area decreases, so that the neck cannot be easily occluded, and if it exceeds the 1/3 circumference, the stent connection 133 may not be easily bent.

When inserted into the blood vessel, the stent connection portion 133 must be horizontally spread over the blood vessel to occlude the neck when the neck of the cerebral aneurysm is reached after being inserted in a bent state. It is preferably made of a shape memory alloy material, and like the stent connection 133, the stent body 131 is preferably made of a shape memory alloy material. In some cases, the stent body 131 may also be made of a shape memory alloy material, so that the stent connection portion 133 and the stent body 131 may be made of the same material, and the stent connection portion 133 and the stent body 131 may form one mold. It can also be manufactured in one piece.

A pair of guide wires 150 are installed through the inner space of the catheter 110, respectively, and serve to guide the pair of catheters 110 to be moved to the lesion. That is, after the guide wire 150 is first inserted into the blood vessel to determine the path, a pair of catheters 110 along the guide wire 150 are moved to the lesion through each guide wire 150, and the catheters 110 As it exits, the stent 130 is horizontally installed in the lesion to obstruct the neck.

The installation method of the stent unit 100 according to the present invention will be described in detail through FIG. 5 as follows. 5A shows the neck of a cerebral aneurysm. There are horizontally formed blood vessels and vertically formed blood vessels around the neck. In general, vertical blood vessels have a larger diameter than horizontal blood vessels, so it is easier to insert the stent into the vertical blood vessel. However, when a conventional stent is inserted into a vertical vessel, there is a problem in that a plurality of stents must be inserted as shown in FIG. 1. Therefore, in order to solve this, it is possible to use the stent unit 100, which can be inserted into a vertical vessel and installed horizontally after insertion.

The installation method of the stent unit 100 of the present invention, as shown in FIG. 5B, first inserts a pair of guide wires 150 into vertical vessels, and installs each guide wire 150 in horizontal vessels in opposite directions to each other. . Then, as shown in Figure 5c, a pair of guide wires 150 is inserted into each pair of catheters 110 and stents 130 coupled to the catheters 110, and along the guide wire 150 as shown in Figure 5d. Move from vertical vessels to horizontal vessels. Thereafter, as shown in FIG. 5E, the stent connection portion 133 in a bent state and the stent body 131 inserted in a reduced diameter state are opened to horizontally install the stent 130 in the blood vessel. At this time, since the stent body 131 and the stent connection portion 133 are made of a shape memory alloy, before reducing the diameter of the stent body 131 and before the stent connection portion 133 is bent, it returns to the original shape. Finally, as shown in FIG. 5E, the catheter 110 is removed from the stent 130, and the guide wire 150 is similarly removed, so that the stent 130 is horizontally installed on the neck. At this time, since the catheter 110 is made of a flexible material, it can be easily removed if the operator pulls the catheter 110 outward after the stent 130 is installed.

Among the blood vessels close to the neck of the cerebral aneurysm corresponding to the lesion, the horizontal blood vessel has a smaller diameter than the vertical blood vessel, so when using a conventional stent, there is a limit to horizontally installing the stent to the horizontal blood vessel as shown in FIG. However, when the stent unit 100 of the present invention is used, the stent 130 can be easily installed in the horizontal blood vessel while inserting the stent 130 into the vertical blood vessel, thereby completely occluding the neck of the cerebral aneurysm.

10: stent
100: stent unit
110: catheter
111: stent support
130: stent
131: stent body
133: stent connection
150: guide wire

Claims (6)

In the stent unit that can be installed horizontally,
A pair of catheters formed in a long tubular shape along the longitudinal direction to form an inner space;
A pair of stent bodies each coupled to surround the outer surface of the pair of catheters, and a cylindrical stent consisting of stent connections each of which is coupled to the stent body to connect a pair of the stent bodies;
It includes; a pair of guide wires that are respectively installed through the inner space of the catheter and guide the pair of catheters to be moved to the lesion;
The stent connection,
It has a set length (L) and is made of a shape memory alloy material, but is only partially coupled along the circumference to the outer surface of the stent body to allow bending, and 1/5 to 1/3 of the entire circumference of the outer surface of the stent body Horizontally installable stent unit, characterized by being joined by the perimeter. According to claim 1,
The pair of the catheter includes a stent support portion in which the outer surface to which the stent body is coupled is recessed by a predetermined thickness, and the horizontally installable stent unit is characterized in that the stent body is supported on the stent support portion. delete delete According to claim 1,
The pair of the catheter is a horizontally installable stent unit, characterized in that made of a fiber reinforced plastic (FRP) material. delete

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