JP3299742B2 - Vascular repair material - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a vaso-occlusive material using superabsorbent fibers,
The present invention relates to a vascular repair material suitably used for treatment of vascular disorders such as aneurysm and arteriovenous malformation (AVM) and a method of using the same.

<Prior Art> Endovascular surgical treatment for treating a vascular disorder using a vascular catheter without performing surgical invasion has been performed.

For example, in the treatment of cerebrovascular disease, a minute catheter is superselectively placed in the affected area of the artery, and an abnormal blood flow is blocked by an embolic substance introduced by the catheter to repair the blood vessel. It is intended for treatment of aneurysms and arteriovenous malformations (AVM). Cerebral aneurysms occur in 1 in 100 adults
An aneurysm that a person has in an arterial blood vessel, about 1 mm to about 20 m in diameter
It has a wide shape distribution up to m, and the site of occurrence extends to multiple branches of the cerebral artery. Of these, about 30% pass without rupture, but about 70% rupture and are said to cause subarachnoid hemorrhage. Arteriovenous malformations are the most common and well-known cerebrovascular malformations and consist of a collection of blood vessels with arteriovenous anastomosis between the meandering, dilated inflow and outflow vessels.

In embolization, such an affected part of the cerebral artery is occluded with an embolic substance, the blood flow in the affected part is stopped, and the affected part is solidified and treated. If necessary, the solidified affected part is removed.

The cerebral blood vessels lack the outer elastic membrane and the blood vessel wall is thinner than other parts, so the resistance to the lateral pressure of blood flow is weak,
Blood vessels travel in a complicated manner in the skull, and are likely to be damaged by the stress applied to the bifurcation and the like.

 For this reason, various embolic materials have been studied.

Conventionally, many cyanoacrylate-based materials have been used as liquids for vascular repair and occlusion (J. Biomed, Mate
r. Res., 17 , 167-177 (1983) MCHarpers et al.).

 Recently, ethylene-vinyl alcohol copolymer
(Evar ) Of dimethyl sulfoxide (DMSO) solution
Used as a repair material, allowing DMSO to diffuse in blood
bar To precipitate blood vessels and occlude blood vessels
Yes (Medical Tribune, October 26, 1989, 46-
47 pages).

On the other hand, there is a method of inflating a detachable balloon inside the aneurysm using a catheter to close the aneurysm, and placing the balloon inside the aneurysm (Journal of N.A.).
eurosurgery, 41 , 125-145 (1974), FASerbinenko).

In addition, polyvinyl alcohol (PVA) sponges, metal coils, alcohol, and sutures have been used according to the purpose of treatment.

<Problems to be Solved by the Invention> With conventional materials of cyanoacrylate type, solidification and polymerization are rapidly performed in blood vessels, so that it is difficult to inject an embolic substance, and it is necessary to remove the catheter to the outside of the sheath at once at the end of the injection. However, it is difficult to handle and cannot be re-injected even if the occlusion is insufficient. In addition, there is a problem that irritation to a living body is large.

In a system using EVAL dissolved in DMSO solvent, the solvent remains indefinitely in the center of EVAL deposited inside the aneurysm, and substances deposited in blood vessels tend to disperse small particles due to turbulent blood flow. In addition, there is a problem that the portion protruding into the blood vessel from the exit of the aneurysm adheres along the flow of the bifurcation.

In addition, since DMSO as a solvent is a chemical substance, its clinical application may be limited (Preprints of the 11th Annual Meeting of the Biomaterials Society of Japan (1989) 68, II-22 Hiroo Iwata and others).
Further, it is not a desirable solvent, for example, because it may damage resin-made equipment.

In the case of using a balloon, the reaction between the balloon and the inside of the aneurysm is weak, so that the cavity inside the aneurysm is not sufficiently filled,
The risk of recurrence is high if any lumen remains. Attempting to fill as many balloons as possible will change the shape of the aneurysm, and there is a risk of rupture of the aneurysm. Another problem is that a pulling force must be applied when the balloon is separated from the catheter.

In addition, when a material such as PVA is used, there are many therapeutic problems such as resistance occurs when injecting into a blood vessel using a catheter.

<Problem to be Solved by the Invention> An object of the present invention is to solve the problems in the prior art,
At the tip of the catheter, the lump has a certain degree of hardness and elasticity, does not splatter off from one end, does not move to unnecessary places due to being swung by the blood flow, and adheres to the aneurysm wall to form An object of the present invention is to provide a vascular repair material which can fill a lumen without any difficulty and at the same time facilitate removal of a catheter, and a method of using the same.

Further, the vascular repair material of the present invention is not limited to the embolic substance in the aneurysm, and provides a material and a method suitable for use in treating vascular malformations such as arteriovenous malformations, arteriovenous fistulas, hemostasis, tumors, and the like. Things.

<Means for Solving the Problems> The present invention provides a vascular repair material having superabsorbent fibers having a water absorption of 10 m / g or more. This vascular repair material can be inserted into a lesion vessel and used to block blood flow within the lesion.

The shape of the superabsorbent fiber is preferably such that it can pass through a lumen having an inner diameter of 3 mm or less.

Further, the superabsorbent fibers are preferably bound with a binder made of a water-soluble substance, which will be easily dissolved in blood as described below, or provided with blood coagulation properties.

 Hereinafter, the present invention will be described in detail.

The vascular repair material of the present invention will be described with reference to a preferred embodiment shown in FIG.

The blood vessel repair material 10 of the present invention has the superabsorbent fibers 1 having a water absorption of 10 m / g or more.

The superabsorbent fiber is not particularly limited as long as the superabsorbent polymer is formed in a fibrous form.

The superabsorbent polymer is a polymer that slightly crosslinks a water-soluble polymer to absorb several hundred times its own weight of water to form a hydrogel, and examples thereof include polyacrylic acid and salts of a copolymer thereof. Is done.

In order to make the superabsorbent polymer into a fibrous form, a method of forming it in a molten state with a nozzle, or forming it into a film and crushing it is used.

 As a super-absorbent fiber, super-absorbent processed by a special method
Fiber having a two-layer structure with a layer and an inner layer of acrylic fiber
When using fiber, water absorbs water and swells immediately upon contact with water
And the fiber properties are maintained by the core acrylic fiber
It is suitable because the physical properties hardly deteriorate even when water is absorbed.
JP-A-61-47873). Such super absorbent fiber is an example
For example, trademark Lanseal As a market by Toyobo Co., Ltd.
Sold.

 The water absorption of the super absorbent fiber must be 10m / g or more
It is. Below this, the effects of the present invention cannot be obtained. An example
For example, trademark Lanseal-F The water absorption of super absorbent fibers
It is 150m / g with distilled water.

The superabsorbent fibers may be used alone, or may be a mixture of two or more kinds, or may be mixed with other natural fibers or synthetic fibers in an amount not contrary to the object of the present invention, if necessary. Good.

When used as a vascular repair material, only the superabsorbent fibers may be used, but preferably, the superabsorbent fibers 1 are introduced into the living body using an adhesive 2 as shown in FIGS. It is formed into an arbitrary shape that can be easily introduced by using the method described above. The shape may be the short thread shape shown in Fig. 1 or the particle shape shown in Fig. 2, and may be a rod-shaped, sheet-shaped, spherical, elliptical, spindle-shaped, etc., which can be easily introduced into a blood vessel by a catheter or the like. Should be fine. In addition, as a method for forming, a method of binding with a binder, encapsulation, knitting, twisting, and the like may be appropriately combined.

As the binder, those that are easily soluble in blood are preferable, and dextran, pullulan, hyaluronic acid, polysaccharides such as lactose, oligosaccharides, glucose, monosaccharides such as mannitol, as well as proteins, water-soluble polymers, etc. Water-soluble substances are mentioned as examples.

In particular, the diameter is 3 mm or less, more preferably 1 mm or less
In the case of a short string of 0.5 mm or less, movement in the catheter becomes easy.

Further, the formed shape is 3 mm or less, more preferably 1 mm
Those that can pass through a lumen having the following inner diameter are preferable. In addition, by using each of these binders alone or in combination of two or more, the swelling of the fiber inside the catheter can be suppressed or delayed, so that it is possible to easily operate the inside of the catheter. When the superabsorbent fiber is formed in this way, it is easy to pass through a thin catheter, and when placed in blood, the binder dissolves and spreads sufficiently to fill the lesion blood vessel.

In addition, blood coagulation is promoted by using fibers made of a material having a blood coagulation property or by adding a coagulation factor such as fibrinogen, thrombin, and Ca ²⁺ ions to the superabsorbent fibers.

In addition, the fibers used break down over time in vivo,
Any substance that is finally decomposed and absorbed can be suitably used after treatment is completed without worrying about long-term adverse effects on the living body.

<Operation> A method of blocking blood flow in a lesion using the vascular repair material of the present invention will be described below.

FIG. 3 is a schematic diagram showing a lesion where an aneurysm 6 is formed at a Y-shaped branch of a blood vessel 7. First, the tube 3 is inserted into the blood vessel 7 and the tip of the tube is guided into the aneurysm 6. The vascular repair material 10 of the present invention is inserted into the tube 3, the guide wire 4 is operated, and the vascular repair material 10 is moved toward the distal end of the tube while pushing the vascular repair material 10, and is placed inside the aneurysm 6. Depending on the size and shape of the aneurysm 6, the shape and number of the vascular repair material to be used are appropriately selected. Thereafter, the catheter 5 including the tube 3 and the guide wire 4 is pulled out of the blood vessel.

As soon as the blood vessel repair material comes into contact with blood, the binder 2 covering the surface dissolves in the blood, the superabsorbent fibers 1 inside begin to swell, the fibrous portion is loosened, and easily in the blood. It spreads and closes the lumen of the aneurysm 6.

When the blood vessel repair material 10 of the present invention is used by solidifying it with the binder 2, it can be easily moved through the thin catheter 5. In addition, the aneurysm 6 easily swells in blood and can be closed in the aneurysm 6 without applying unnecessary external pressure to the aneurysm 6. The superabsorbent fibers swollen by absorbing water in the aneurysm 6 cause a weak biological reaction (thrombus formation) and are effective for treatment. Further, the removal of the catheter 5 is easy.

<Examples> Hereinafter, the present invention will be described specifically with reference to Examples.
The present invention is not limited to these.

(Example 1) A cotton-like lump of super water-absorbing fiber (Lanseal F, 5d x 51 mm, Toyobo Co., Ltd.) was twisted while being stretched to form a thin thread. This is immersed in a 4.0% dextran aqueous solution and dried at room temperature. Twisting again in a state of being dried, a thread material having an outer diameter of 0.5 mm was finally obtained. The blood vessel repair material of the present invention was obtained by cutting into lengths of 6 mm each.

Example 2 A model 20 of a Y-shaped blood vessel 12 having an aneurysm-shaped aneurysm 14 formed at a bifurcation 11 shown in FIG. The inner diameter of the blood vessel 12 is 4.0 mm, the maximum diameter of the aneurysm 14 is 5.5
mm, and the inner diameter of the neck 13 was 2.0 mm. This blood vessel model 20
Was connected to a roller pump 16 (MARK-17 made by MED TECK) via an inflow pipe (inner diameter 5.0 mm) 15 shown in FIG. On the other hand, a discharge pipe 17 was connected to the downstream side of the blood vessel model 20, and distilled water was perfused at a flow rate of 104 m / min and a flow rate of 13.8 cm / sec. Y connector 18 on roller pump side of inflow pipe 16
One of the Y connectors 18 was connected to the roller pump 16 and the other was a tube inlet 19. An air vent 21 was provided on the model 20 side of the inflow pipe 15.

An olefin tube 22 having an inner diameter of 0.65 mm was inserted into the experimental system from the tube inlet 19, and the tip of the tube 22 was guided to the bulge portion 14 of the model. The vascular repair material prepared in Example 1 is inserted into the tube 22, the vascular repair material is pushed into the tube 22 with the guide wire, and the guide wire is further pushed to place the vascular repair material in the aneurysm 14 of the model 20. did.
The vascular repair material began to swell immediately upon contact with water, and further spread within the aneurysm portion 14 and closed the interior of the aneurysm due to the unwinding force of the twisted fibers. Five minutes after the placement, the vascular repair material almost completely closed the inside of the aneurysm. During this time, all the vascular repair material stayed in the aneurysm portion 14, and the phenomenon of being carried away by the water flow did not occur. Also, the removal of the tube 22 was easy.

(Comparative Example 1) As a restoration material, Eval (Kuraray KK.EP.F104) was used.
A 10 wt% dimethyl sulfoxide solution was inserted into the knob 14 of the same model 20 using the same experimental system as in Example 2.

Eval 25 precipitated from the solution blocked the knob portion 14, but eval was deposited from the solution that overflowed excessively from the neck 13 and adhered to the branched tube wall 23. The inside of the knob 14 was transparent, and the solvent dimethylsulfoxide 24 remained, and hardly hardened.

(Comparative Example 2) A repair material was produced in the same manner as in Example 1 except that Egyptian cotton (diameter: 10 to 20 µm) was used instead of the superabsorbent fiber. Using the same experimental system as in Example 2, the same model 20 was inserted into the aneurysm 14.

Even when it was placed inside the aneurysm and brought into contact with water, it did not spread out and did not swell.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a preferred embodiment of the blood vessel repair material of the present invention. FIG. 2 is a sectional view showing another embodiment of the blood vessel repair material of the present invention. FIG. 3 is a schematic diagram illustrating the operation of the present invention. FIG. 4 is a schematic diagram illustrating an experimental system of an example. FIG. 5 is an enlarged plan view of a broken line portion shown in FIG.
It is a schematic diagram explaining a Y-shaped blood vessel model. DESCRIPTION OF SYMBOLS 1 ... high-absorbency fiber, 2 ... binder, 3 ... tube, 4 ... guidewire, 5 ... catheter, 6 ... aneurysm, 7 ... blood vessel, 10 ... vascular repair Material, 11 ... branch part, 12 ... blood vessel, 13 ... neck, 14 ... nodule, 15 ... inflow tube, 16 ... roller pump, 17 ... discharge tube, 18 ... Y connector, 19 ... ... Tube insertion port, 20 ... Model, 21 ... Air vent, 22 ... Tube, 23 ... Tube wall, 24 ... Dimethyl sulfoxide, 25 ... Eval deposited

────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-2-112407 (JP, A) JP-A-63-281660 (JP, A) JP-A-2-31762 (JP, A) (58) Field (Int.Cl. ⁷ , DB name) A61L 15/00-33/18

Claims (4)

(57) [Claims] 1. The superabsorbent fiber having a water absorption of 10 m / g or more is made of a water-soluble substance selected from polysaccharides, oligosaccharides, monosaccharides, glucose, proteins and water-soluble polymers, and is easy to use in blood. A blood vessel repair material characterized by being bound with a binder soluble in water. 2. The highly water-absorbing fiber having a water absorption of 10 m / g or more and having blood coagulation properties is selected from polysaccharides, oligosaccharides, monosaccharides, glucose, proteins and water-soluble polymers. A blood vessel repair material comprising a water-soluble substance and bound with a binder that is easily dissolved in blood. 3. The blood vessel repair material according to claim 1, wherein the superabsorbent fiber has a super-absorbent outer layer and a fiber inner layer core. 4. The method according to claim 1, wherein the shape in which the superabsorbent fibers are formed is a shape capable of passing through a lumen having an inner diameter of 3 mm or less. The vascular repair material according to the above.