KR101632796B1 - Detachble embolic coil assembly - Google Patents

Abstract

The present invention relates to a flexible tube having a cylindrical shape with both ends open in the longitudinal direction, a flexible tube having a round bar cross-sectional shape which is provided so as to be slidable in the longitudinal direction and rotatable inside the flexible tube, A connecting rod having a circular rod cross-sectional shape in which a latching groove bent in a curved shape is recessed so that the latching portion is engaged with the latching portion so as to be correspondingly inserted in the longitudinal direction one end outer side of the connecting rod, And a coil portion connected to the coil.
In such a detachable embolization coil assembly, a flexible tube is bent in a curved shape and a locking groove is inserted in a corresponding state so that the jaw and the connecting rod are connected, the connecting rod and the coil are inserted into the blood vessel, When the jaws are rotated in the direction opposite to the warping direction of the jaws, the jaws are moved backward along the jaw grooves of the jaws to release the mutual connection state. Even if the diameter of the jaws is small, It is possible to easily dispose it in the inside of the blood vessel.

Description

[0001] Detachable embolic coil assembly [0002]

The present invention relates to a discrete embolism coil assembly for disposing an embolic coil at a preselected location in a blood vessel of a body.

Generally, a long flexible catheter is used to deploy various devices within the blood vessels of the body. Such devices include dilatation balloons, Radiopaque fluids, liquid medications, and various types of occlusion devices such as balloons and embolization coils. An occlusion device, including an embolic coil, is used to treat aneurysms or to occlude blood vessels at a target location.

The coil disposed in the blood vessel may take the form of a spirally wound coil or alternatively may be a coil wound around a randomly wound coil, a convoluted coil, a coil wound around another coil, It has many other diverse structures. Such embolization coils are generally formed of a radiopaque and biocompatible metallic material such as platinum, gold, tungsten, or an alloy of these metals. Coils can be coated with a variety of materials to improve their thrombogenicity. Often, several coils are placed at a given location to occlude blood flow through the blood vessel by promoting thrombus formation at a particular location. Reduced blood flow reduces pressure on the aneurysm and reduces the risk of aneurysm rupture.

When the distal end of the catheter is properly positioned with the embolization coil disposed in the distal end of the catheter, the embolization coil is pushed out of the end of the catheter such that the embolization coil is released to a desired position via a pushing means such as a guide wire I will bear.

However, in the conventional embolization coil assembly, the hook portion of the pushing means and the hook portion of the embolization coil are interlocked with each other, so that the hook portion of the embolizing coil is released in a state where the embolization coil is pushed to the outside of the catheter. When the diameter of the blood vessel is narrow, there is a problem that the hooked portion of each hook is not released.

Such prior art embolization coil assemblies are disclosed in Korean Patent Laid-Open Publication No. 1994-702751 (Sep. 17, 1994).

It is an object of the present invention to provide a removable embolization coil assembly for stably separating and releasing an embolization coil even when the diameter of a blood vessel is narrow.

The present invention relates to a flexible tube having a cylindrical shape with both ends opened in the longitudinal direction, a circular rod cross-sectional shape provided inside the flexible tube so as to be capable of sliding in the direction of rotation and lengthwise and having a curved- A connecting rod having a circular rod cross-sectional shape recessed in a curved shape so as to engage with the engaging portion so as to be engaged with the engaging portion so as to be slidably inserted into the outer side surface of the one end in the longitudinal direction, And a coil portion connected to the other longitudinal end of the coil.

In addition, when the pivot is rotated in the direction opposite to the direction of the pivoting of the pivoting member in a state in which the pivoting member is engaged with the pivoting member, the pivoting member may be slid rearward .

The engaging portion may be disposed inside the radius of curvature of the connecting rod in a state of being inserted into the engaging groove.

In addition, the engaging portion may be disposed so as to protrude outward beyond the radius of curvature of the connecting rod in a state of being inserted into the engaging groove.

In addition, the jaws and the connecting rods may have flexibility.

The coil portion may include a helical coil body having one longitudinal end connected to the other longitudinal end of the connecting rod and a curved chip coupled to the other longitudinal end of the coil body.

The detachable embolism coil assembly according to the present invention is characterized in that a flexible tube is bent in a curved shape and an engaging groove is inserted into the flexible tube so as to be inserted in a corresponding state, , When the jaws are separated from the jaws, the jaws are moved backward along the jaw grooves of the jaws to release the mutual connection state. If the diameter of the jaws is small So that the coil part can be easily detached and installed inside the blood vessel.

1 is a top view of a discrete embolism coil assembly in accordance with an embodiment of the present invention.
2 is a cross-sectional view taken along the line II-II in Fig.
3 is a cross-sectional view according to another embodiment of Fig.
Fig. 4 is a state in which the jungle and the connecting rod shown in Fig. 1 are separated from each other.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

1 is a top view of a discrete embolism coil assembly in accordance with an embodiment of the present invention. Referring to FIG. 1, the detachable embolism coil assembly includes a flexible tube 100, a jaw 200, a connecting rod 300, and a coil part 400.

The flexible tube 100 is a cylindrical member for guiding the connection part 300 and the coil part 400 to be inserted into the blood vessel 10 in the body to be described later. In other words, the flexible tube 100 is connected to the joint 300 and the nose 200 by the jig 200 in a state in which the jig 200, the joint 300, and the coil 400 are inserted into the flexible tube 100, So that the portion 400 can be inserted into the blood vessel 10 while being moved in the jaws. In the flexible tube 100, when the user pushes the jaw 200 in a state where the jaw 200, the link 300, and the coil 400 are inserted into the flexible tube 100, So that the connecting member and the coil part 400 can be separated from the blood vessel 10 by being opened at both ends in the longitudinal direction.

The jamb 200 is a member having a circular rod cross-sectional shape for pushing the connecting rod 300 to be described later in a state where the jamb 200 is inserted into the flexible tube 100. The pivot 200 is slidably movable in the longitudinal direction of the flexible tube 100 while being inserted into the flexible tube 100, and is rotatable.

A hook 210 bent in one direction is formed at one end in the longitudinal direction of the jungle 200, that is, at an end connected to the link 300 to be described later. The engaging portion 210 is inserted into the engaging groove 310 of the connecting rod 300 to be described later so that the force is transmitted to the connecting rod 300 in the forward and backward movement of the pushing bar 200 . That is, the latching portion 210 of the jungle 200 is seated in the upper part of the connecting block 300, and more specifically, the latching block 210 is seated on the latching groove 310 of the connecting block 300 in a seated state. The jaw 200 may be inserted into the blood vessel 10 by inserting the connecting rod 300 into the blood vessel 10 and inserted into the blood vessel 10 from the inside of the flexible tube 100 When the diameter of the blood vessel 10 is larger than the diameter of the coupling part 300 and the diameter of the coupling part 300, the connecting part 300 moves downward due to the load of the coupling part 300, The engagement state of the engagement portion 210 and the engagement groove 310 is released. If the diameter of the blood vessel 10 is smaller than the diameter of the coupling part 210 and the diameter of the coupling part 300, So that it is released from the state where it is inserted into the engagement groove 310 of the connection block 300 when it is pulled backward.

The connecting rod 300 is a member having a circular rod cross-sectional shape so that the coil part 400 to be described later is detachably connected to the pivot 200. That is, the connecting rod 300 moves the jaws 200 in the flexible tube 100 in a state where the coil part 400 is connected to the jaws 200 in a correspondingly sliding manner, 200, the coil unit 400 can be installed in a state where the coil unit 400 is detached and inserted into the blood vessel 10, while being disconnected from the swing arm 200 according to the rotation direction of the swing arm 200. The connecting rod 300 is slidably installed in the flexible tube 100 in the longitudinal direction.

The hooks 210 of the jaws 200 are engaged with the hooks 210 of the jaws 200 on the outer side of the jaws 200, The engaging groove 310 curved in one direction is recessed and formed.

2, when the engaging portion 210 of the jaw 200 is inserted into the engaging groove 310 of the link 300, the outer surface of the engaging portion 210 is engaged with the link 300, As shown in FIG. 3, the outer surface of the locking part 210 protrudes outward beyond the radius of curvature of the outer surface of the connecting block 300. However, as shown in FIG. 3, It is of course possible to arrange them so as to be arranged in a straight line. 2, the total diameter of the connecting rod 300 when the jaw 200 and the connecting rod 300 are connected to each other has a diameter of the connecting rod 300 so that the movement of the connecting tube 300 in the flexible tube 100, It is possible to facilitate the mutual departure from each other. In the case of FIG. 3, when the jaws 200 are connected to the jaws 300, the jaws 200 are mutually contacted with each other to enable stable movement when the jaws 300 are pushed or pulled by the jaws 200.

The locking part 210 of the jaw 200 and the locking groove 310 of the connecting block 300 are curved in one direction so as to correspond to each other. The jumping platform 200 is hooked to the jumping platform 300 so that the jumping platform 300 is moved corresponding to the forward and backward movement of the jumping platform 200. [ When the locking part 210 of the jaw 200 and the locking groove 310 of the connecting part 300 are to be released from each other, 300 to the inside of the blood vessel 10 from the inside of the flexible tube 100 to move the connecting rod 300 downward by its own weight, The state in which the latching portion 210 of the connecting block 300 is inserted into the latching groove 310 of the connecting block 300 is released. In contrast, when the blood vessel 10 is thin and the coupling unit 300 is introduced into the blood vessel 10, the coupling unit 210 of the coupling unit 200 is inserted into the coupling groove 310 of the coupling unit 300 The other end of the coil section 400 to be described later is rotated in the direction opposite to the direction in which the locking section 210 is bent, Only the coupling portion 210 of the jamb 200 is inserted into the coupling groove 310 of the coupling portion 300 and the coupling portion 300 of the coupling portion 300 coupled to the coil portion 400 is also fixed. So that the jaws 200 and the link 300 can be disconnected from each other.

The jaw 200 and the link 300 may be formed of a flexible material so as to be deformed corresponding to the deformation of the flexible tube 100 inside the flexible tube 100 Do.

The coil unit 400 is inserted into the blood vessel 10 of the human body when the jamb 200 and the connecting rod 300 are disconnected in a state where the coil unit 400 is connected to the connecting rod 300, ). The coil unit 400 is connected to the other longitudinal end of the connecting unit 300, and is moved corresponding to the movement of the connecting unit 300. Here, the coil part 400 includes a coil body 410 and a chip 420.

The coil body 410 is a portion that densely fills the inside of the blood vessel 10 in a state where the coil body 410 is inserted into the blood vessel 10. One end in the longitudinal direction of the coil body 410 is connected to the other end in the longitudinal direction of the link 300. Here, the coil body 410 is formed by winding a wire made of a platinum alloy or a wire obtained by surface-treating a platinum alloy with a polymer, spirally wound around the coil body 410. However, the coil body 410 is not only harmless to the human body, It is needless to say that the present invention can also be applied to a complex shape coil for stably blocking the blood vessel 10 in addition to the spiral shape.

The chip 420 prevents the inner wall of the blood vessel 10 from being damaged when the coil body 410 is inserted into the blood vessel 10. The chip 420 is coupled to the other end in the longitudinal direction of the coil body 410 and the surface portion contacting the inner wall of the blood vessel 10 is formed to have a smooth curved shape.

A method of installing a coil into a blood vessel 10 using a detachable embolus coil assembly according to an embodiment of the present invention will now be described. And the coil part 400 are inserted and inserted into the portion of the blood vessel 10 to which the tip of the flexible tube 100 is to be inserted.

Then, the connecting rod 300 is pushed through the pivot 200 to be inserted into the blood vessel 10. That is to say, when the pivot 200 is pushed toward the inner side of the blood vessel 10 in a state where the latching portion 210 of the pivot 200 is inserted into the latching groove 310 of the connecting pivot 300, The connecting part 300 is pushed into the blood vessel 10 correspondingly and consequently the coil part 400 connected to the connecting part 300 is inserted and arranged in the blood vessel 10.

When the connecting rod 300 and the coil part 400 are inserted into the blood vessel 10 at a position where the blood vessel 10 is to be installed by the pivoting force of the pivot 200, (210) and the coupling groove (310) of the connection unit (300) are interlocked with each other. The tip 420 of the coil section 400 is fixed to the blood vessel 10 in the human body so that the tip end of the tip 420 of the coil section 400 is coupled to the coil body 410 of the coil section 400. [ The jaw 200 and the link 300 are connected to each other when the jaw 200 is rotated in a direction opposite to the direction in which the jaw 210 is bent, State. 4, when the jaw 200 is rotated in a direction opposite to the direction in which the jaw 210 is bent, only the jaw 210 of the jaw 200 is engaged with the jaw 210 of the jaw 300, It is possible to release the mutual connection state of the jungle 200 and the link 300 while being slid rearward along the guide 310.

In this way, when the swing arm 200 is rotated in the direction opposite to the direction of the swing of the swing arm 210 when the swing arm 200 is disengaged from the swing arm 300 in the blood vessel 10, The coupling portion 210 is moved backward along the coupling groove 310 of the connecting block 300 to release the mutual coupling state. Even if the diameter of the blood vessel 10 is small, So that it can be easily detached from the blood vessel 10.

As described above, the detachable embroidery coil assembly is configured such that the engaging portion 210 bent in a curved shape inside the flexible tube 100 and the engaging groove 310 are engaged with each other in an inserted state, When the jaw 200 and the jaws 300 are detached after inserting the jaws 300 and the coil part 400 into the blood vessel 10, When the base 200 is rotated in a direction opposite to the direction of the bending of the latching unit 210, the latching unit 210 is moved backward along the latching groove 310 of the linking unit 300, The coil section 400 can be easily detached from the blood vessel 10 even if the diameter of the blood vessel 10 is small.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: flexible tube 200: jungle
210: latching part 300: connecting part
310: latching groove 400: coil part
410: coil body 420: chip

Claims (6)

A flexible tube having a cylindrical shape with both longitudinal ends open;
A flexible tube having a circular rod cross-sectional shape and slidable in the longitudinal direction and inside the flexible tube, the flexible tube having a curved bent portion at one end in the longitudinal direction;
A connecting rod having a circular rod cross-sectional shape which is slidably installed on the inside of the flexible tube and is formed with an engaging groove bent in a curved shape so that the engaging portion is engaged with the engaging portion in a correspondingly inserted state; And
And a coil part connected to the other longitudinal end of the connecting rod,
When the connecting rod is inserted into the blood vessel inside the flexible tube,
When the diameter of the blood vessel is larger than the diameter of the connecting rod, the connecting rod is slid downward on the latching portion due to its own weight to release the latching state between the latching portion and the latching groove,
Wherein when the diameter of the blood vessel is smaller than the diameter of the connecting rod, when the pivot is rotated in a direction opposite to the direction in which the latching portion is bent, the latching portion slides rearward in the latching groove, . delete The method according to claim 1,
Wherein the engaging portion is disposed inside the radius of curvature of the connecting rod in a state of being inserted into the engaging groove. The method according to claim 1,
Wherein the engaging portion is disposed so as to protrude outward beyond a radius of curvature of the connecting block when the engaging portion is inserted into the engaging groove. The method according to claim 1,
Wherein the jaw and the link are flexible. The method according to claim 1,
Wherein the coil portion includes:
A spiral coil body having one longitudinal end connected to the other longitudinal end of the connecting rod,
And a curved chip coupled to the other longitudinal end of the coil body.

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