JPH0426111Y2 - - Google Patents

Description

[Detailed Description of the Invention] "Industrial Application Field" The present invention relates to a catheter device used when administering a medical solution such as a contrast medium to a blood vessel or the like.

``Conventional technology'' In recent years, in cardiac catheterization tests, catheters are inserted percutaneously without cutting blood vessels.
Many techniques are used to administer medical solutions such as contrast media into blood vessels.

The procedure for percutaneously inserting a catheter will be explained with reference to FIG. 4, taking arterial puncture as an example.

First, puncture the artery 2 with the puncture needle 1 (a), and then
A guide wire 3 is inserted into the puncture needle 1, and the puncture needle 1 is pulled out, leaving the guide wire 3 in the artery 2 (b).

Next, the dilator 4 is inserted into the guide wire 3, and the tip of the dilator 4 is slid along the guide wire 3 and pushed into the artery 2 (c). and,
When dilation is completed, the dilator 4 is removed (d), and then the catheter 5 is slid along the guide wire 3 (e), and the catheter 5 is inserted into the artery 2. (f).

When the catheter 5 is inserted to a predetermined position in the artery 2, the guide wire 3 is removed, and then a medical solution such as a contrast medium is administered to the artery 2 through the catheter 5.

However, in the conventional catheter insertion procedure described above, after inserting the guide wire 3, the catheter 5 is inserted along the guide wire 3, and then,
The guide wire 3 must be removed, making the procedure complicated and time-consuming, and increasing the burden on the patient during this time.

As a countermeasure against this problem, a catheter body 8 has been proposed in which a tube 7 made of Teflon, silicone, etc. is attached to the outer periphery of a guide wire 6, as shown in FIG. When inserting the catheter main body 8 into a blood vessel or the like, first, the core 9 is inserted into the catheter main body 8, and the catheter main body 8 in this state is inserted into a puncture needle or a dilator inserted into the blood vessel or the like. After the catheter main body 8 is inserted to a predetermined position, the puncture needle or dilator and core 9 are removed, and the medicinal solution is administered to a blood vessel or the like through the catheter main body 8.

According to this device, since the guide wire 6 constitutes the catheter body 8, there is no need to remove the guide wire 6 when administering medication, and the guide wire 6 and tube 7 can be inserted separately into a blood vessel or the like. Since this is not necessary, the procedure is simplified and the burden on the patient is reduced.

However, in this device, the tip portion of the guide wire 6 located in the flexible tip portion 8a is attached to the tube 7, and therefore has poor flexibility. In addition, the tip flexible portion 8a of the catheter body 8
The diameter of the tip surface is increased in order to allow the chemical solution to be discharged from the tip. Therefore, when moving through a curved blood vessel, the guide bumps into the inner wall of the blood vessel, resulting in poor guiding performance and easy damage to the intima of the blood vessel.

``Problems to be solved by the invention'' This invention not only does not damage the intima when moving through blood vessels, etc., but also has excellent flexibility at the tip, which provides good guidance when moving through blood vessels. To provide a catheter device that can reduce the burden on a patient without requiring much effort for catheter insertion.

"Means for Solving the Problems" In order to achieve the above object, a catheter device according to the present invention includes a coiled guide wire and a coiled guide wire with a thickness of 0.05 to 0.2 mm coated on the outer periphery of the guide wire.
A tube made of synthetic resin and a core that is removably inserted into the guide wire, a flexible tip portion of the guide wire protrudes from the tip of the tube, and the flexible tip portion is configured to absorb a chemical solution from the outer periphery. Coil spacing is 50 to 200 μm to enable discharge
It is characterized by being spread out so as to have a slippery head at the tip.

"Operation" To explain how to use the catheter device of the present invention, first, a blood vessel is punctured with a puncture needle, and the catheter body is inserted into the blood vessel through the puncture needle. Note that, if necessary, the catheter body may be inserted after pushing the dilator into the blood vessel, or a part of the blood vessel may be incised and the catheter body may be inserted through the incision. In addition, there is a core (core wire) inside the catheter body.
may be inserted to increase rigidity during insertion.

When the catheter body is inserted into a blood vessel or the like in this manner, the flexible tip portion of the guide wire protruding from the tip of the tube advances along the intima and guides the catheter body. The flexible distal end has no tube attached to its outer periphery and the coil gap is widened, so it is extremely flexible and can guide the intima of the blood vessel without damaging it. Also,
Since the tip is provided with a head shaped to be easily slippery, the tip of the guide wire is prevented from getting caught on the inner wall of the blood vessel.

After the distal end of the catheter body is inserted to a predetermined position, the core is pulled out if it is to be used. Next, when a medical solution such as a contrast medium is injected from the proximal side of this catheter body, this medical liquid advances inside the catheter body, is discharged outward from the gap between the coils on the outer periphery of the flexible tip part, and flows into the blood vessel. .

In the present invention, the protruding length of the flexible tip portion of the guide wire is preferably 10 to 100 mm. If the protruding length is longer than the above, the flexible tip portion is likely to catch on the intima of the blood vessel, and if the protruding length is shorter than the above, the effect of improving guideability will be reduced.

In addition, the gap between the coils in the flexible tip part is
The thickness should be 50 to 200 μm. If the gap between the coils is shorter than the above, sufficient medicinal liquid discharge will not be ensured, and sufficient flexibility will not be obtained. If the gap between the coils is longer than the above, the outer periphery of the coil will tend to bite into the intima of a blood vessel or the like.

Furthermore, the shape of the head at the tip of the guidewire is
Although any shape is acceptable as long as it is easy to slip, a shape having a gently curved surface such as a hemisphere, a hyperboloid, or a paraboloid is preferably employed.

As the guide wire, a material with excellent strength and corrosion resistance, such as stainless steel, is used.
The wire diameter is preferably 0.05 to 0.2 mm. Note that the guide wire is not limited to a round wire, and may be a flat wire.

On the other hand, the tube is preferably made of a material that does not adversely affect the human body and has good slipperiness, such as Teflon, silicone, polyethylene, etc.
This tube can be easily attached to the outer periphery of the guide wire by covering the guide wire with a cylindrical tube and heat-shrinking it. Note that the thickness of the tube is 0.05 to 0.2 mm.

"Embodiments" Hereinafter, embodiments of the present invention will be described with reference to FIGS. 1, 2, and 3.

As shown in FIG. 1, the catheter device 11 includes:
The catheter body 11a includes a coiled guidewire 12, a tube 13 attached to the coiled guidewire 12, and a core 14 inserted through the coiled guidewire 12. The core 14 can be pulled out from the proximal side of the catheter body 11a.

In the case of this embodiment, the tube 13 is made of Teflon and has a thickness of 0.1 mm, and is attached to the outer periphery of the guide wire 12 with heat shrinkability.

In the present invention, the flexible distal end portion 12a of the guide wire 12 protrudes from the tube 13 by a predetermined length L (30 mm in this embodiment), and the distal end thereof has a parabolic head portion 12b. is formed. The head 12b is formed by melting the tip of the guide wire 12 using plasma or the like.

Further, the guide wire 12 is formed by winding a stainless steel wire with a wire diameter of 0.18 mm into a coil shape so as to be freely bendable. The portion of the guide wire 12 attached to the tube 13 is wound with the coils in contact with each other, thereby increasing the elastic modulus. Further, the tip flexible portion 12b of the guide wire 12 has a coil gap l of 0.2 mm.
The distal end flexible portion 12b is widened to ensure flexibility, and a drug such as a contrast medium can be ejected from this gap l. Note that the guide wire 12 is not limited to a round wire, but may be a flat wire.

The core 14, which is inserted into the guide wire 12 and increases the rigidity of the guide wire 12 when the catheter main body 11a is inserted into a blood vessel, is a flat wire having a relatively high elastic modulus and flexibility. It is made of round wire, etc., and the surface is coated with Teflon. Furthermore, a curved guide member 14a is attached to the tip. The core 14 is tapered such that it is thick at the base and becomes thinner at the distal end to improve flexibility at the distal end.

In addition, in FIGS. 2 and 3, the reference numeral 15
is a blood vessel such as an artery, and the catheter main body 11a is inserted into the blood vessel 15 through, for example, a puncture needle 16.

Next, a method of using the catheter device of the present invention having the above configuration will be explained.

First, the puncture needle 16 is percutaneously punctured into the blood vessel 15, and then the catheter main body 11a, whose core has been inserted in advance, is inserted into the puncture needle 16, and its tip is guided into the blood vessel 15.

When the catheter main body 11a is further pushed in, the catheter main body 11a is supported by the core 14 and inserted into the blood vessel 15, and the tip flexible portion 1
The head 12b of the tube 2a advances along the blood vessel 15, and the flexible tip portion 12a bends and advances inside the blood vessel 15. Note that if the tube 13 provides sufficient rigidity, the catheter main body 11a can be inserted into the blood vessel 15 as it is without using the core 14.

In this case, since the following tip flexible portion 12a of the guide wire 12 is exposed from the tube 13,
The absence of the tube 13 improves flexibility, making it easier to bend along the blood vessel. In addition, the head 12b
Since it is formed in a parabolic shape, even if it hits the inner wall of the blood vessel 15, it will slip and will be prevented from getting caught. Furthermore, since the length L of the flexible distal end portion 12a is relatively short at about 30 mm, and the gap l between the coils is relatively narrow at about 0.2 mm, the coil will not bite into the intima of the blood vessel during insertion. Therefore, blood vessel 15
can be easily inserted without damaging the intima of the patient.

When the distal end of the catheter main body 11a is inserted into the blood vessel 15 to a predetermined location, the core 14 is removed, and then a medical solution such as a contrast agent is injected into the catheter main body 11a. Then, this medicinal solution is administered into the blood vessel 15 from the coil gap l on the outer periphery of the flexible tip portion 12a. Since the drug solution flows out from the outer periphery of the flexible tip portion 12a, it is likely to be mixed uniformly into the blood. Note that when the catheter main body 11a is inserted without using the core 14,
The drug solution can be injected as is.

In this manner, after the medicinal solution is administered into the blood vessel and predetermined operations such as imaging and treatment are completed, the catheter main body 11a is removed, and the puncture needle is removed to complete the catheter insertion. In this case, since the length L of the flexible tip portion 12a is short and the coil gap l is relatively narrow,
The flexible tip portion 12a will not get caught on the intima of the blood vessel 15 during removal.

"Effects of the Invention" As explained above, according to the present invention, the catheter body is composed of the guide wire and the tube attached to the outer periphery of the guide wire. Medicinal solutions can be administered and catheter insertion can be performed quickly, thereby reducing the burden on the patient. In addition, the flexible tip of the guide wire protrudes from the tip of the tube, and the gap between the coils is widened at the flexible tip, making it highly flexible and easy to bend along curved paths such as blood vessels. , the guiding performance during catheter insertion is improved. Furthermore, the head provided at the tip of the guidewire makes it easy to slip even if the tip hits the inner wall of a blood vessel or the like, thereby preventing it from getting caught.
Therefore, the catheter can be smoothly inserted without damaging the lining of the blood vessel.

[Brief explanation of drawings]

1 to 3 show embodiments of the present invention,
Fig. 1 is a side sectional view of the catheter device, Fig. 2 is a partially sectional side view of the catheter device inserted into a blood vessel, and Fig. 3 is an enlarged sectional view of the main part when administering a drug solution.
FIG. 4 and subsequent figures show a conventional example. FIG. 4 is a schematic diagram showing a catheter insertion procedure, and FIG. 5 is a side sectional view of a conventional catheter device. In the figure, 11 is a catheter device, 11a is a catheter body, 12 is a coiled guide wire, 12a
is a flexible tip portion, 13 is a tube, and l is a coil gap.

Claims (1)

[Scope of utility model registration request] The above-mentioned method comprises a coiled guide wire, a synthetic resin tube with a thickness of 0.05 to 0.2 mm coated on the outer periphery of the guide wire, and a core that is removably inserted into the inside of the guide wire. The flexible tip of the guide wire protrudes from the tip of the tube, and in order to make it possible to discharge the drug solution from the outer periphery, the flexible tip of the guide wire is widened so that the coil spacing is 50 to 200 μm, and the tip has a shape that makes it easy to slip. A catheter device characterized in that it is provided with an eggplant head.