KR20120124572A - Rotational Fragmentation Thrombectomy Catheter - Google Patents

Abstract

PURPOSE: A rotary thrombus removal catheter is provided to minimize damage to blood vessel injuries and to effectively remove thrombus. CONSTITUTION: A rotary thrombus removal catheter comprises a guide wire(1), a distal balloon(2), a sheath, and a plurality of crushing wires(30). The guide wire is inserted into blood vessels. The distal balloon is formed in the distal part of the guide wire and adheres closely to the inner wall of the blood vessels. The sheath surrounds the guide wire and is formed with a plurality of intake holes. The crushing wire is installed in the guide wire and crushes thrombus inside the blood vessels. The crushing wire is restored by elasticity.

Description

Rotational Fragmentation Thrombectomy Catheter

The present invention relates to a thrombus catheter, and more particularly, to a pulverized thrombus catheter that can effectively remove chronic blood clots as well as acute blood clots while minimizing distal embolism of blood vessel damage and disrupted blood clots.

Peripheral thrombosis is also observed with peripheral arterial obstruction, although thrombosis formed in the heart or other upper vessels may appear embolized distally. In general, about 5% of the adult population is estimated to have peripheral arterial disease. Of these, about 50% are known to have symptomatic peripheral arterial disease. As a device for treating such thrombosis, various thrombosis removal devices are used.

First, there were conventional thrombus inhalation devices using the hydrodynamic principle. These devices are designed to remove acute thrombosis, but chronic thrombosis that has been hardened after several days to several weeks cannot be effectively inhaled and removed, and there is a problem that the thrombus can be embolized distally during the procedure.

Next, there were conventional blood clot removal devices made of fragmentation. These crushing devices have the advantage of effectively removing the stiffened chronic blood clots, but the material is made of metal, there is a risk of causing blood vessel damage, there is also a problem that there is a risk of crushed blood clots embolized distal.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, the rotary crushing type having a structure capable of effectively removing not only acute blood clots but also chronic blood clots while minimizing blood vessel damage during rotational grinding. To provide a thrombus catheter.

Another object of the present invention is to provide a pulverized thrombus catheter having a structure which can prevent the pulverized thrombi from embolizing distal.

Technical problems to be achieved by the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned above will be clearly understood by those skilled in the art from the following description. Could be.

According to a feature of the present invention for achieving the above object, the present invention includes a guide wire inserted into the blood vessel; A distal balloon that is expandably provided at a distal portion of the guide wire and is in close contact with a blood vessel inner wall; A sheath provided to surround the guide wire and having a plurality of suction holes through which the removed thrombus is sucked; And a plurality of grinding wires installed in the guide wire to crush the blood clots in the blood vessel, wherein the grinding wires are elastically pressed into the sheath when inserted into the blood vessel, and out of the sheath when the thrombus is removed. It is moved and restored by elasticity.

It is characterized in that it further comprises a proximal balloon which is provided to be expandable in the proximal portion of the guide wire and in close contact with the inner wall of the blood vessel.

The guide wire is characterized in that the grinding shaft is installed rotatably installed at the end of the grinding wire.

An end of the grinding shaft has a sharp grinding tip is installed to guide the grinding wire.

The grinding shaft is hollow, and the inside of the grinding shaft is connected to one end of the grinding wire is characterized in that the wire adjustment opening for adjusting the length of the grinding wire in the front and rear direction.

The wire adjustment tool is characterized in that it is provided at the end of the control shaft inserted into the grinding shaft.

One end of the grinding wire is fixed to the end of the grinding shaft, the other end is characterized in that the circular arc shape is fixed to the wire control.

The grinding wire is characterized in that the arc shape is fixed to both ends of the guide wire.

The crushed wire is characterized in that it is made of fluorocarbon material.

According to another feature of the invention, the invention is a guide wire which is inserted into the blood vessel; A distal balloon that is expandably provided at a distal portion of the guide wire and is in close contact with a blood vessel inner wall; A proximal balloon that is expandably provided at a proximal portion of the guide wire and is in close contact with an inner wall of a blood vessel; A sheath provided to surround the guide wire and having a plurality of suction holes through which the removed thrombus is sucked; A grinding shaft rotatably installed on the guide wire so as to be located inside the sheath; And a plurality of grinding wires installed at an end of the grinding shaft to crush the blood clots in the blood vessel, wherein the grinding wires are elastically pressed into the sheath when inserted into the blood vessel, and the outside of the sheath when the thrombus is removed. Is moved to and restored by elasticity.

According to the present invention, since a wire having a rigid material such as fluorocarbon is rotated to remove the blood clot, the blood clot can be effectively removed by crushing not only acute blood clots but also chronic blood clots. Because it uses the effect that can minimize the damage to blood vessels.

In addition, according to the present invention, the balloon is provided in the proximal and distal portions of the catheter, and there is an effect of preventing embolization of the thrombi removed by the wire to the distal portion.

1 is a block diagram of a pulverized thrombus removal catheter according to an embodiment of the present invention.
Figure 2 is a block diagram showing the state before the pulverized thrombus catheter crushing the thrombus in accordance with an embodiment of the present invention.

Hereinafter will be described in detail with reference to the accompanying drawings, an embodiment of a pulverized thrombus removal catheter according to the present invention.

1 is a block diagram of a pulverized thrombus catheter according to an embodiment of the present invention, Figure 2 is a block diagram showing a state before the pulverized thrombus catheter crushing thrombus according to an embodiment of the present invention to be.

According to this, the pulverized thrombus removal catheter according to the present invention is largely guide wire (1); A distal balloon (2) expandably provided at a distal portion of the guide wire (1); Sheath 10 is provided to surround the guide wire (1), the suction hole 12 is formed to suck the removed thrombus and a plurality of grinding wires installed in the guide wire (1) to crush the blood clots in the blood vessel (30). Hereinafter, each component will be described in detail.

First, the distal balloon 2 is expandably provided at the distal portion (right side in FIG. 1) of the guide wire 1, and the proximal balloon 4 is expandably provided at the proximal portion (the left portion in FIG. 1). The distal balloon 2 and the proximal balloon 4 inflate after insertion of the catheter and adhere to the inner wall of the blood vessel B, thereby preventing the thrombi removed by the catheter from embolizing to the distal portion. In other words, the removed thrombus is prevented from entering the distal side (right direction in FIG. 1). In addition, the catheter does not flow during the clotting operation of the catheter also serves to ensure that the work can be made stably.

On the other hand, in this figure, the balloon is shown as being provided in the distal portion and the proximal portion, respectively, but is not necessarily limited to this, it may be configured so that the distal balloon (2) is provided only on the distal side. This is because the thrombus removed by the grinding wire 30 may be sucked into the suction hole 12 of the sheath 10 located on the proximal side, but there is a risk of embolization because there is no separate suction means on the distal side. Of course, it is preferable that a balloon is provided at both the distal and proximal portions of the guide wire 1.

Although not specifically illustrated in the drawing, the distal balloon 2 and the proximal balloon 4 may be expanded by receiving fluid from a separate fluid supply device (not shown).

The sheath 10 is installed to surround the guide wire 1, and has a hollow long pipe shape. Then, the sheath 10 serves as a guide substantially when the catheter is inserted. Specifically, when the sheath 10 is inserted into the blood vessel (B) to remove the thrombus serves as a guide to the place where the thrombus to be crushed in the state where the grinding wire 30 is located inside as shown in FIG. Done. Of course, the distal balloon 2 and the proximal balloon 4 are not inflated at this time. Thus, the sheath 10 is preferably made of soft to minimize friction upon insertion into the vessel (B).

On the other hand, a plurality of suction holes 12 are formed on the outer surface of the sheath 10. The suction hole 12 may be formed on the outer surface of the sheath 10 with a predetermined interval in a plurality of rows in various shapes such as a circle and a rectangle. When the thrombus is removed by the grinding wire 30, the thrombus pulverized flows in the proximal direction in the left direction in FIG. At this time, the suction force is applied to the inside of the sheath 10 by a separate suction device (not shown), and the thrombus pulverized through the suction hole 12 may be sucked. In this way, the pulverized thrombi can be effectively removed without flowing in the blood vessel (B).

Next, at one side of the guide wire 1, the grinding shaft 20 is installed rotatably installed at the end of the grinding wire 30. The grinding shaft 20 also has a hollow pipe shape like the sheath 10. The grinding shaft 20 is rotated by receiving power from a separate driving device (not shown).

In addition, the inside of the grinding shaft 20 is provided with a wire adjuster 22 for adjusting the length of the front and rear direction of the grinding wire (30). One end of the grinding wire 30 is fixed to the adjustment opening 22, and the adjustment opening 22 is provided at the end of the adjustment shaft 24 provided inside the grinding shaft 20. Therefore, when the operator moves the control shaft 24 in the front and rear direction, the length of the front and rear direction of the grinding wire 30 capable of elastic deformation is adjusted. In other words, the grinding wire 30, one end of which is fixed to the adjuster 22 and the other end is fixed to the end of the grinding shaft 20, the length of the front and rear direction is adjusted when the adjusting tool 22 is adjusted in the front and rear directions Accordingly, the grinding wire 30 may protrude or contract in the radial direction with respect to the grinding shaft 20.

The grinding wire 30 is positioned in the sheath 10 when the catheter is inserted into the blood vessel B, and is exposed to the outside as shown in FIG. 1 when the thrombus is removed. That is, the grinding wire 30 is elastically pressed inside the sheath 10, and when the grinding shaft 20 is moved forward when removing the thrombus, the grinding wire 30 is stretched while being restored by elasticity.

Thus, the grinding wire 30 is preferably made of a material having a predetermined rigidity for removing the thrombus while having elasticity. For example, the grinding wire 30 is preferably made of a fluorocarbon material among carbon-based materials. Since the grinding wire 30 made of fluorocarbon material has rigidity and has a large grinding force at the time of rotation, it is advantageous for removing blood clots and is a flexible material having elasticity rather than a metallic material, which does not damage blood vessel walls. In addition, the grinding force of the grinding wire 30 can effectively remove not only acute phase thrombus but also chronic phase thrombus.

1 and 2, the grinding wire 30 may have an arc shape in which one end is fixed to the end of the grinding shaft 20 and the other end is fixed to the wire control 22. Circular arc-shaped grinding wire 30 may be provided in plurality at a predetermined center angle around the grinding shaft (20). The arc-shaped crushed wire 30 is changed in shape according to the forward and rearward movement of the wire control opening (22). For example, when the wire adjuster 22 is moved forward, the grinding wire 30 further protrudes in a direction perpendicular to the grinding shaft 20, and conversely, when the wire adjusting device 22 is moved backward, the grinding wire 30 is moved to the grinding shaft 20. Contracts in a direction perpendicular to). The operator can effectively remove the blood clot while adjusting the degree of protrusion of the grinding wire 30 while moving the wire control (22).

Of course, the crushing wire 30 is not limited to the arc shape shown in Figs. 1 and 2, for example, may have a variety of shapes, such as the tip portion is curved to the outside, that is, similar to the broom.

In addition, at the end of the grinding shaft 20, a sharp tip 32 is provided. The crushing tip 32 is made of a sharp cone shape with a sharp tip and serves to primarily crush the thrombus upon removal of the thrombus and allow the grinding wire 30 to easily enter the thrombus.

When removing the cured chronic blood clots attached to the blood vessel wall, the magnitude of the force generated by friction with the grinding wire 30 varies slightly depending on the thickness of the blood clots. That is, the thrombus portion, which is the initial stage of grinding, is the furthest part from the vessel wall. As the hard blood clot is crushed by the friction with the grinding wire 30, the thickness of the blood clot becomes thin and close to the wall of the blood vessel having a viscoelastic property. will be. In other words, when removing the blood clot by rotating the grinding wire 30 at a high speed, the force at the boundary of the blood vessel B and the blood clot may be measured. The wire automatic drive unit (not shown) serves to automatically stop the grinding wire 30 at the portion where this force changes.

Hereinafter, the thrombus removal process of the pulverized thrombus catheter according to the present invention having the configuration as described above will be described in detail.

To treat patients with peripheral arterial thrombosis, the operator inserts a catheter into the blood vessel (B). The operator inserts the catheter up to the site where the thrombus is formed, wherein the catheter according to the present invention is inserted into the sheath 10 in a state in which the grinding wire 30 is elastically pressed (a state shown in FIG. 2). do. Of course, the distal balloon 2 and the proximal balloon 4 located at the distal and proximal portions are inserted together in a contracted state.

When the catheter is inserted to the desired position, the operator supplies fluid from a separate fluid supply device so that the distal balloon 2 and the proximal balloon 4 are expanded to be supported on the inner wall of the blood vessel B. FIG. This completes the preparation of the clot removal operation by the catheter.

Then, the operator moves the grinding shaft 20 forward so that the grinding wire 30 comes out of the sheath 10. In this process, the grinding wire 30 is restored to its original state as shown in FIG. 1 by elasticity. That is, the grinding wire 30 is expanded in the direction perpendicular to the grinding shaft 20. At this time, the operator may adjust the degree of protrusion of the grinding wire 30 in the radial direction while moving the control shaft 24 forward and backward according to the state of the thrombus (firmness, thickness, etc.).

Thereafter, the operator moves toward the thrombus while rotating the grinding wire 30. Before the grinding wire 30 removes the thrombi, the grinding tip 32 first contacts the thrombus so that the grinding wire 30 can smoothly enter.

The thrombus removed by the crushing wire 30 is introduced into the proximal portion. At this time, the thrombus flows through the suction hole 12 to operate the suction device to prevent embolization to the distal portion.

The scope of the present invention is not limited to the embodiments described above, but may be defined by the scope of the claims, and those skilled in the art may make various modifications and alterations within the scope of the claims It is self-evident.

1: guide wire 2: distal balloon
4: proximal balloon 10: sheath
12: suction hole 20: grinding shaft
22: wire regulator 24: control shaft
30: grinding wire 32: grinding tip

Claims (16)

A guide wire inserted into the blood vessel;
A distal balloon that is expandably provided at a distal portion of the guide wire and is in close contact with a blood vessel inner wall;
A sheath provided to surround the guide wire and having a plurality of suction holes through which the removed thrombus is sucked; And
A plurality of grinding wires installed on the guide wires to grind the blood clots in the blood vessel;
The grinding wire is elastically pressed inside the sheath when inserted into the blood vessel, and when the blood clot removed, the rotating crushing thrombus catheter, characterized in that moved to the outside of the sheath and restored by elasticity. The method of claim 1,
Rotating type thrombus catheter characterized in that it further comprises a proximal balloon that is provided in the proximal portion of the guide wire in close contact with the blood vessel inner wall. The method of claim 1,
The guide wire is a pulverized thrombus removal catheter, characterized in that the grinding shaft is installed rotatably installed at the end of the grinding wire. The method of claim 3, wherein
Rotating-type thrombus removal catheter, characterized in that the tip of the grinding shaft is provided with a sharp grinding tip to guide the grinding wire. The method of claim 3, wherein
The grinding shaft has a hollow shape, and the inside of the grinding shaft is connected to one end of the grinding wire is a rotary milling thrombus removal catheter, characterized in that the wire adjustment mechanism for adjusting the length of the grinding wire in the front and rear direction is installed. The method of claim 5, wherein
The wire control sphere is a rotary pulverized thrombus removal catheter, characterized in that provided at the end of the control shaft inserted into the grinding shaft. The method of claim 3, wherein
The grinding wire is one end is fixed to the end of the grinding shaft, the other end is a rotary crushing thrombus removal catheter, characterized in that the arc shape is fixed to the wire control. The method of claim 1,
The grinding wire is a pulverized thrombus removal catheter, characterized in that the arc-shaped both ends are fixed to the guide wire. The method of claim 1,
The grinding wire is a pulverized thrombus removal catheter, characterized in that made of fluorocarbon (Fluorocarbon) material. A guide wire inserted into the blood vessel;
A distal balloon that is expandably provided at a distal portion of the guide wire and is in close contact with a blood vessel inner wall;
A proximal balloon that is expandably provided at a proximal portion of the guide wire and is in close contact with an inner wall of a blood vessel;
A sheath provided to surround the guide wire and having a plurality of suction holes through which the removed thrombus is sucked;
A grinding shaft rotatably installed on the guide wire so as to be located inside the sheath; And
It is provided at the end of the grinding shaft includes a plurality of grinding wires for grinding the blood clots in the blood vessel,
The grinding wire is elastically pressed inside the sheath when inserted into the blood vessel, and when the blood clot removed, the rotating crushing thrombus catheter, characterized in that moved to the outside of the sheath and restored by elasticity. 11. The method of claim 10,
Rotating-type thrombus removal catheter, characterized in that the tip of the grinding shaft is provided with a sharp grinding tip to guide the grinding wire. 11. The method of claim 10,
The grinding shaft has a hollow shape, and the inside of the grinding shaft is connected to one end of the grinding wire is a rotary milling thrombus removal catheter, characterized in that the wire adjustment mechanism for adjusting the length of the grinding wire in the front and rear direction is installed. 13. The method of claim 12,
The wire control sphere is a rotary pulverized thrombus removal catheter, characterized in that provided at the end of the control shaft inserted into the grinding shaft. 11. The method of claim 10,
The grinding wire is one end is fixed to the end of the grinding shaft, the other end is a rotary crushing thrombus removal catheter, characterized in that the arc shape is fixed to the wire control. 11. The method of claim 10,
The grinding wire is a pulverized thrombus removal catheter, characterized in that the arc-shaped both ends are fixed to the guide wire. 11. The method of claim 10,
The grinding wire is a pulverized thrombus removal catheter, characterized in that made of fluorocarbon (Fluorocarbon) material.

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