JPH04183477A - Catheter and manufacture thereof - Google Patents

Abstract

PURPOSE:To prevent the exfoliation of a light guide and an image fiber from the inner wall surface of an outer skin tube during use and improve reliability by fixing the light guide and image fiber on the top edge side of an outer skin tube whose inner surface wall is roughened or on the top edge side of the outer skin tube on which a plurality of holes projecting through the side wall are formed, by an adhesive. CONSTITUTION:A catheter 1 is introduced inside a hollow tubular sheath which is previously introduced into a vessel, and the top edge of the catheter 1 is allowed to reach a diseased part to be observed, confirming the image of an adhesive 6 compounded with fine gold powder through the X-ray scan, and then light is irradiated to the diseased part by a light guide 5, and the image of the diseased part is sent outside the body through a rod lens 3 and an image fiber 4, and observed. At this time, the catheter 1 is introduced through the bending inside the vessel, and since the image fiber 4 and the light guide 5 are fixed on the inner surface wall of an outer skin tube 2 having unevenness 2a by the adhesive 6, generation of exfoliation is prevented. Accordingly, the image of the diseased part can surely be sent outside the body.

Description

Detailed Description of the Invention [Field of Industrial Application] The present invention relates to a catheter introduced into a blood vessel or the like and used for direct visual observation and treatment of lesions inside the blood vessel, and a method for manufacturing the same. This paper relates to technology for fixing light guides and image fibers installed in

[Conventional technology]

Development of small-diameter catheters is underway for direct visual observation and treatment of lesions occurring in coronary arteries, cerebral blood vessels, etc., and such catheters are required to be highly reliable and easy to operate. .

Here, the structure of a conventional catheter is shown in Fig. 5(a).
This will be explained below with reference to (b).

In these figures, 21 is the distal end portion of a catheter that is introduced into the blood vessel to observe the lesion site within the blood vessel, and the outer skin tube 22 of the catheter 21 has an outer diameter of 0.5.
It consists of a hollow tubular body made of fluororesin. Inside it, an image fiber 24 with a rod lens 23 connected to the tip to condense an image of the lesion site, and a plurality of light guides 25 for irradiating light to the lesion site are attached using epoxy adhesive 11 FI 26. In the fixed catheter of this example, a Selfoc rod lens manufactured by Nippon Sheet Glass Co., Ltd. is used as the rod lens 23.

A catheter 21 having the structure shown in FIG.
and sent to the outside of the body via the image fiber 24. Using this image, the lesion site can be directly visually observed and diagnosed.

[Problem to be solved by the invention]

However, the conventional catheter 21 has the following problems.

■ When the catheter 21 is introduced into the blood vessel while being bent, the stress of this bending causes the outer skin tube 22 to
The adhesive 26 fixing the image fiber 24 and light guide 25 is attached to the outer skin tube 2 on the distal end side of the outer skin tube 2.
It may peel off from the inner wall of 2. When such detachment occurs, the image fiber 2 is placed at the focal site within the blood vessel.
4 and the tips of the light guides 25 cannot be directed accurately, making it impossible to send clear images. Furthermore, there is a risk that the rod lens 23 may fall into the blood vessel.

(2) The catheter 21 must be accurately introduced into the lesion site within the blood vessel in a short time. However, this is extremely inconvenient because there is no means to reliably confirm the position of the distal end of the catheter 21 introduced into the blood vessel from outside the body.

In view of the above problems, an object of the present invention is to adopt a fixing structure with high adhesive strength, further utilize an adhesive process to form a contrast area for X-ray fluoroscopy, and improve reliability and operability. The object of the present invention is to provide a feasible catheter and a method for manufacturing the same.

[Means to solve the problem]

In order to solve the above problems, the measures taken by the present invention provide a catheter that includes at least a plurality of light guides inside a hollow outer skin tube and an image fiber having an objective lens at its tip. The image fiber is fixed with adhesive to the tip side of the outer skin tube whose inner wall is roughened.

Alternatively, the light guide and the image fiber are fixed with adhesive to the distal end side of the outer skin tube, which has a plurality of holes penetrating from the outer wall to the inner wall.

The manufacturing method of such a catheter includes roughening at least the inner wall of the distal side of the hollow tubular outer skin tube with a chemical solution, or roughening the inner wall of the hollow tubular outer skin tube from the outer wall to the inner wall thereof, or roughening the inner wall of the hollow tubular outer skin tube with a chemical solution. After forming the hole,
A plurality of light guides and an image fiber having an objective lens at the tip are passed through the inside of the outer skin tube, and the light guide and image fiber are made to protrude from the tip. After applying adhesive to the protruding part, the image fiber and the light are inserted. The process involves pulling the guide back into the skin tube and then curing the adhesive.

Alternatively, the adhesive for fixing the light guide and the image fiber is filled with powder made of a metal or metal oxide that can be contrasted with XwA fluoroscopy, and such a catheter is a hollow tubular catheter. A plurality of light guides and an image fiber having an objective lens at the tip are passed through the inside of the sheath tube, and the light guide and image fiber are made to protrude from the tip of the sheath tube. Alternatively, it is manufactured by applying an adhesive filled with metal oxide powder, pulling the image fiber and light guide back into the jacket tube, and then curing the adhesive.

It is desirable that the outer skin tube of such a catheter is made of fluororesin.

[Effect]

When the light guide, guide, and image fiber are fixed with adhesive to the outer skin tube with a roughened inner wall, the outer skin tube, light guide, and image fiber are fixed by physical adhesive force in addition to chemical adhesive action. That will happen. In other words, the unevenness formed by the roughening of the surface causes the adhesive to get caught and become difficult to peel off (anchoring effect).
Further, even in the case where a plurality of holes penetrating from the outer wall to the inner wall of the outer skin tube are formed, the same effect as described above can be obtained. Therefore, the adhesive force between the outer skin tube and the light guide and image fiber is improved, and even if the catheter is bent, the light guide and image fiber will not peel off from the inner wall of the outer skin tube of the catheter, so that images of the lesion site can be reliably captured outside the body. It is possible to prevent the objective lens from falling off during use.

The above-mentioned catheter is manufactured by roughening the inside of the distal end of the hollow tubular outer skin tube with a chemical solution, or after forming a plurality of holes penetrating from the outer wall to the inner wall at the distal end of the hollow tubular outer skin tube. It can be easily manufactured by fixing the image fiber and light guide inside the outer skin tube with adhesive.

In addition, in catheters in which the resin that fixes the light guide and image fiber is filled with powder made of metal or metal oxide that can be contrasted with X-ray fluoroscopy, these powders can be used to contrast with X-ray fluoroscopy. It is extremely convenient because it can be used as a separate section, allowing the position of the catheter tip to be confirmed from outside the body.

Additionally, such catheters can be fabricated simply by using a resin filled with fluoroscopically contrastable metal or metal oxide powder, instead of traditional adhesives, making them a no-brainer. Since there is no need to form a contrast region in the process, there is no need to significantly increase manufacturing costs.

When a fluororesin is used for the outer sheath tube of the catheter, the outer sheath tube can be made thinner and has flexibility. Therefore, it is possible to increase the inner diameter of the cartel, make it extremely thin, and improve reliability and operability.

〔Example〕

First Embodiment Next, a catheter according to a first embodiment of the present invention will be described below with reference to FIGS. 1(a) and 1(b).

FIG. 1(a) is a cross-sectional view of the catheter, and FIG. 1(b) is a cross-sectional view of the catheter.
) is a front view of the tip.

In these figures, reference numeral 1 denotes the tip of a catheter that is introduced to the lesion site inside the blood vessel and sends an image of the lesion site to the outside of the body. It consists of a hollow tubular body made of ethylene. Inside, a rod lens 3 is connected to the tip to condense an image of the lesion site, an image fiber 4 is connected to the tip to send the image outside the body, and a rod lens 3 is connected to the tip of the rod lens 3 for condensing an image of the lesion site, an image fiber 4 for transmitting the image outside the body, and a rod lens 3 for irradiating the lesion site with light sent from outside the body. A plurality of light guides 5 are fixed with an epoxy adhesive 6. Here, the inner wall of the outer skin tube 2 is roughened to form countless unevenness 2a, and the image fiber 4 and the light guide 5 are inserted into the inside of these unevenness 2a with the adhesive 6. Fixed. In addition, the inside of the adhesive 6 is filled with fine gold powder,
These fine gold powders function as a marker (contrast material) in X-ray fluoroscopy, making it possible to confirm the tip position of the catheter 1. In the catheter 1 of this example, a Selfoc rod lens manufactured by Nippon Sheet Glass Co., Ltd. is used as the rod lens 3.

The catheter I having such a structure is manufactured by the following manufacturing method. First, as shown in FIG. 2 (a), the inner wall of the tip end of the outer skin tube 2 is roughened with a polytetrafluoroethylene adhesive primer solution, and then washed to remove the adhesive primer solution. Next, after passing the image fiber 4 connected to the rod lens 3 and the plurality of light guides 5 into the outer skin tube 2, as shown in FIG. 4 and the light guide 5 are made to protrude, and after applying an adhesive 6 containing fine gold powder to the protruding parts, the image fiber 4 and the light guide 5 are attached to the outer tube as shown in FIG. Pull it back inside 2. Thereafter, the catheter 1 is manufactured by curing the adhesive 6. In manufacturing the catheter 1 of this example, Tetra Edge NR-188 manufactured by Junkosha was used as an adhesive primer liquid to roughen the inner wall of the outer skin tube 2.

The usage mode of the catheter 1 described above is that the catheter 1 is introduced inside a hollow tubular sheath that has been introduced into a blood vessel in advance, and
While confirming the image of the adhesive 6 mixed with fine gold powder using fluoroscopy, the tip of the catheter 1 is brought to the lesion site to be observed, and then the light guide 5 irradiates the lesion site with light. An image of the lesion site is sent to the outside of the body via a rod lens 3 and an image fiber 4 for observation. At this time, the catheter 1 is introduced into the blood vessel while being bent, but since the image fiber 4 and the light guide 5 are fixed to the inner wall of the outer skin tube 2 having the unevenness 2a with the adhesive 6, peeling may occur. do not have. Therefore,
Images of the lesion can be reliably sent outside the body. Also,
Since polytetrafluoroethylene is used for the outer tube 2, the wall thickness of the outer tube 2 can be made thinner, and it is also flexible, so that the inner diameter of the catheter 1 can be enlarged and ultra-thin, and the operability can be improved. realizable. Furthermore, since the adhesive 6 filled with fine gold powder functions as an X-ray fluoroscopic marker, the position of the tip of the catheter 1 can be recognized from outside the body. Such a marker can be formed by simply using the adhesive 6 filled with fine gold powder instead of the conventional resin.

In addition, it can be easily formed even if it has an extremely small diameter, and there is no need to attach a metal marker in a separate process, so there is no increase in manufacturing costs.

<Second Example> Next, the catheter according to the second example is shown in FIG.
This will be explained below with reference to (b).

FIG. 3(a) is a cross-sectional view of the catheter, and FIG. 3(b) is a cross-sectional view of the catheter.
) is a front view of the tip.

In these figures, 11 is the distal end of a catheter that is introduced into the blood vessel and used to observe the lesion within the blood vessel, and the outer sheath tube 12 of the catheter 11 is a hollow tube made of polytetrafluoroethylene with an outer diameter of 0.4 m. It consists of a tubular body. Inside thereof, an image fiber 14 having a Rondo lens 13 connected to its tip and a plurality of light guides 15 are fixed with an epoxy adhesive 16. Here, the outer skin tube 12 has a plurality of through holes 12a penetrating from the outer wall to the inner wall thereof, and the image fiber 14 and the light are inserted into the through holes 12a with the adhesive 16. Guide 1
5 is fixed.

In addition, tungsten powder is blended inside the adhesive 16, and the adhesive 1 filled with tungsten powder is
6 functions as an X-ray fluoroscopic marker (contrast material), making it possible to confirm the position of the tip of the catheter 11 introduced into the blood vessel.

In the catheter 11 having such a structure, instead of the step of roughening the inner wall of the outer sheath tube 2 in the first embodiment, the distal end side of the outer sheath tube 12 is irradiated with a laser beam, as shown in FIG. After forming a plurality of through holes 12a, the device is manufactured by performing the same steps as in the first embodiment.

The manner of use of the catheter 11 described above is the same as that of the catheter 1 of the first embodiment, and the catheter 11 is introduced into the blood vessel while being bent. 1
Since it is fixed to the inner wall of 2 with adhesive 16, peeling does not occur. In addition, since polytetrafluoroethylene is used for the outer skin tube 12, the diameter of the catheter 11 is reduced, and it has flexibility.
Reliability and operability have improved. Further, since the adhesive 16 filled with tungsten powder functions as a marker (contrast material) for X-ray fluoroscopy, the tip of the catheter 11 can be confirmed from outside the body. Moreover, markers can be easily formed even on ultra-thin diameter catheters, and
No separate process is required and there is no significant increase in manufacturing costs.

In addition to the above-mentioned examples, the same effect can be obtained by using titanium powder as a contrast material for X-ray fluoroscopy that is blended into the resin, and metal oxides may also be used. On the other hand, any material that can be contrasted may be used.Also, in all of the above embodiments, an epoxy adhesive was used as the adhesive, but an acrylic adhesive or the like may be used, without limitation.

In addition to polytetrafluoroethylene, the fluororesin used for the outer skin of the catheter may be, for example, ethylenetetrafluoroethylene polymer.

Further, a swinging traction wire or the like may be disposed inside the outer skin tube so as to swing the tip of the catheter, and there are no restrictions on the structure of the other end of the catheter.

In the method for manufacturing a catheter, a step of polishing the distal end of the catheter may be further performed.

〔Effect of the invention〕

As described above, in the catheter according to the present invention, the light guide and the image fiber are placed on the distal end side of the outer sheath tube whose inner wall is roughened, or on the distal end side of the sheath tube where a plurality of holes penetrating the side wall are formed. , is characterized by being fixed with adhesive. Therefore, the adhesive gets into the irregularities or through-holes at the tip of the outer tube, improving adhesive strength, and the light guide and image fiber do not separate from the inner wall of the outer tube during use, making the catheter highly reliable. can be realized.

The above method for manufacturing a catheter includes a step of roughening the inner wall of the catheter with a drug or a step of forming a through hole, so the inner wall of the outer skin tube can be easily processed into a structure with high adhesive strength. be able to.

On the other hand, in catheters in which the resin that fixes the light guide and image fiber is filled with powder made of metal or metal oxide that can be contrasted by X-ray fluoroscopy, the adhesive itself is This allows the tip of the catheter to be confirmed from outside the body, making it highly operable.
It's convenient.

Moreover, since it can be manufactured by using the above-mentioned resin in place of the conventional resin, no separate process is required, and a significant increase in cost does not occur.

Furthermore, if fluororesin is used for the outer tube of such a catheter, the wall thickness of the outer tube should be thinned (
Moreover, since it is flexible, it is possible to increase the inner diameter of the catheter, make it extremely thin, and improve reliability and operability.

[Brief explanation of the drawing]

FIG. 1(a) is a sectional view of a catheter according to a first embodiment of the present invention, and FIG. 1(b) is a front view of its distal end. FIGS. 2(a) to 2(C) are process perspective views showing a part of the manufacturing method. FIG. 3(a) is a sectional view of a catheter according to a second embodiment of the present invention, and FIG. 3(b) is a front view of its distal end. FIG. 4 is a process perspective view showing a part of the manufacturing method. FIG. 5(a) is a front view of the tip of a conventional example, and FIG. 5(b) is a sectional view thereof. [Explanation of symbols] 1.11.21...Catheter 2.12.22...Outer tube 2a...Irregularities 12a...Through hole 4.14.24...Image fiber 5.15.2
5... Light guide 6.16.26... Adhesive. Figure 2 Guan Figure 4

Claims (10)

[Claims] (1) A catheter comprising at least a plurality of light guides and an image fiber having an objective lens at the tip inside a hollow outer skin tube, wherein the light guide and the image fiber have roughened inner walls. The catheter is fixed to the distal end side of the outer skin tube with an adhesive. (2) A catheter comprising at least a plurality of light guides and an image fiber having an objective lens at its tip inside a hollow tubular outer skin tube, wherein the light guide and the image fiber penetrate from the outer wall to the inner wall. A catheter characterized in that the outer skin tube has a plurality of holes formed therein and is fixed to the distal end side with an adhesive. (3) The catheter according to claim 1 or 2, wherein the adhesive is filled with powder made of metal or metal oxide that can be contrasted with X-ray fluoroscopy. (4) In a catheter comprising at least a plurality of light guides and an image fiber having an objective lens at its tip inside a hollow tubular outer tube, the light guide and the image fiber are bonded to the distal end side of the outer tube. A catheter characterized in that the adhesive is fixed with an adhesive, and the adhesive is filled with powder made of metal or metal oxide that can be contrasted under X-ray fluoroscopy. (5) The catheter according to any one of claims 1 to 4, wherein the outer skin tube is made of a fluororesin. (6) A step of roughening at least the inner wall of the distal end side of the hollow outer skin tube with a chemical solution, and then passing a plurality of light guides and an image fiber having an objective lens at the tip into the inside of the outer skin tube. protruding the light guide and the image fiber from the tip of the outer skin tube; applying an adhesive to the protruding portion; and then pulling the light guide and the image fiber back into the outer skin tube;
A method for manufacturing a catheter, comprising the step of curing the adhesive. (7) Forming a plurality of holes penetrating from the outer wall of the outer skin tube to the inner wall thereof on the distal end side of the hollow outer skin tube, and then a plurality of light guides and an image fiber having an objective lens at the tip. a step of passing the light guide and the image fiber through the inside of the sheath tube and protruding the light guide and the image fiber from the tip of the sheath tube, a step of applying an adhesive to the protruding portions, and a step of applying an adhesive to the protruding portion; A method for manufacturing a catheter, comprising the steps of: pulling the adhesive back into the outer skin tube; and curing the adhesive. (8) The catheter according to claim 6 or 7, wherein the adhesive is filled with powder made of metal or metal oxide that can be contrasted with X-ray fluoroscopy. Production method. (9) Passing a plurality of light guides and an image fiber having an objective lens at the tip inside a hollow tubular outer tube, and protruding the light guide and the image fiber from the tip of the outer tube; applying an adhesive filled with a metal or metal oxide powder that can be imaged under X-ray vision, and then pulling the light guide and the imaging fiber back into the skin tube; A method for manufacturing a catheter, comprising the step of curing an adhesive. (10) The method for manufacturing a catheter according to any one of claims 6 to 9, wherein the outer skin tube is made of a fluororesin.