JP2864094B2 - catheter - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a catheter.

[0002]

2. Description of the Related Art Conventionally, a so-called percutaneous coronary angioplasty (PTC) in which a catheter having a balloon at the distal end is inserted into a coronary artery of the heart and the balloon is inflated to enlarge an occluded portion.
A) is being performed.

[0003] However, in this PTCA, intimal damage is liable to occur, causing blood vessel dissociation and platelet deposition.

[0004] Recently, there has been proposed an idea of performing thermal coagulation welding by irradiating the laser beam from the inside of the balloon at the time of balloon expansion, but it has been extremely difficult to realize a catheter that uniformly irradiates the laser beam over the entire circumference.

Therefore, the present inventors have invented a catheter shown in FIG. 7 as a method of heating the balloon itself instead of the laser beam full-circle irradiation method.

That is, this catheter comprises a catheter base material a having a contrast medium feeding path, a balloon b attached to the front end of the base material a, a tip device c fixed to the front end of the balloon b, Comprises a heating tube d fixed to the tip tool c, and a laser fiber e inserted into the contrast medium feeding path of the base material a.

[0007] The heating tube d is composed of a tube body f made of a metal braid and connected to the contrast medium feeding path, and a resin tube g covering the tube body f.

Then, the contrast agent supplied to the contrast agent feed path enters the heating tube d, enters the balloon b from the outer periphery of the tip as indicated by an arrow h, and the balloon b expands as shown in FIG. The part expands.

At this time, the heating tube d is heated by the laser light from the laser fiber e, whereby the contrast agent passing through the heating tube d is heated, and the balloon b is heated.

[0010]

However, the catheter shown in FIG. 7 has a drawback that the tip of the heating tube d is locally heated by the irradiation of the laser beam from the laser fiber e. Since body f is a metal braid,
Certainly, the contrast medium flows out from the distal end portion of the tube body f, but this outflow is not smooth, and it takes a relatively long time to inflate the balloon b.

Therefore, according to the present invention, the distal end portion of the heat generating tube is not locally overheated, the contrast agent can smoothly enter the balloon, and the flexibility of the balloon or the insertion portion main body in the vicinity thereof can be improved. Another object of the present invention is to provide a catheter that does not impair its appearance or appearance.

Another object of the present invention is to provide a catheter capable of monitoring temperature variations in the balloon, and another object of the present invention to provide a catheter capable of monitoring the pressure in the balloon.

[0013]

To achieve the above object, one catheter according to the present invention is provided with an insertion section main body having a contrast medium feeding path and attached to a distal end of the insertion section main body. A balloon, and a heating tube that is provided inside the balloon and that is connected to the contrast agent feeding path, and
A catheter in which a laser fiber for irradiating a laser beam in the heating tube to heat a contrast agent in the heating tube is inserted through the contrast agent feeding path, wherein the heating tube includes a metal braided tube, and the metal tube. A resin tube for covering a base end or an intermediate portion of the braided tube, and a metal braided short cylinder is fixedly fitted to a distal end of the metal braided tube to form a double structure portion of the metal braid. And at the same time,
The inside of the heating tube and the inside of the balloon are connected and connected to each other, and a plurality of through holes are provided for supplying a contrast agent in the heating tube into the balloon.

Further, in order to achieve the above-mentioned other object,
Another catheter according to the present invention includes an insertion portion main body having a contrast agent feeding path, a balloon attached to a distal end of the insertion portion main body, and a balloon provided inside the balloon and connected to the contrast agent feeding path. A heating tube , and inside the heating tube.
To heat the contrast agent in the heating tube by irradiating a laser beam to the
A catheter fiber having a laser fiber inserted through the contrast medium feeding path, wherein the heating tube is a metal braided tube.
And cover the base end to the middle of the metal braided tube.
A resin tube, and the metal braided tube
A metal braided short cylindrical body is fitted and fixed to the tip end of the metal braid.
Forming a double structural part,
The inside of the tube and the inside of the balloon are connected and connected to each other,
A plurality of through holes for supplying the contrast agent into the balloon.
Only, further provided with a two thermocouples are arranged tip junction within the balloon to detect the temperature of the contrast agent enters into the balloon from the heating tube, platinum tip junction of each of the thermocouple It is a combination of plates.

Further, in order to achieve the above-mentioned another object,
Another catheter according to the present invention includes an insertion portion main body having a contrast agent feeding path, a balloon attached to the distal end of the insertion portion main body, and a balloon that is provided inside the balloon and is connected to the contrast agent feeding path. A heating tube , and inside the heating tube.
To heat the contrast agent in the heating tube by irradiating a laser beam to the
A catheter fiber having a laser fiber inserted through the contrast medium feeding path, wherein the heating tube is a metal braided tube.
And cover the base end to the middle of the metal braided tube.
A resin tube, and the metal braided tube
A metal braided short cylindrical body is fitted and fixed to the tip end of the metal braid.
Forming a double structural part,
The inside of the tube and the inside of the balloon are connected and connected to each other,
A plurality of through holes for supplying the contrast agent into the balloon.
In addition, a pressure sensor for detecting the pressure in the balloon of the contrast agent that has entered the balloon from the heating tube is provided in the balloon.

In order to achieve the first object, another catheter according to the present invention comprises an insertion portion main body having a contrast medium feeding path, a balloon attached to a distal end of the insertion portion main body,
A heating tube, which is provided inside the balloon and is connected to the contrast agent feeding path, and is provided with a laser fiber for irradiating the inside of the heating tube with a laser beam to heat the contrast agent in the heating tube. A catheter inserted through the contrast agent feeding path, wherein the heating tube includes a metal braided tube, and a resin tube covering a base end portion or an intermediate portion of the metal braided tube; A metal braided short cylindrical body is internally fitted and fixed to the distal end of the tube to form a metal braided double structure, and the inside of the heating tube and the balloon inside are connected and connected to the double structure. A plurality of through-holes for supplying a contrast agent in the heating tube into the balloon are provided, and furthermore, a distal junction of two thermocouples for detecting a temperature in the balloon is disposed in the balloon, and the distal junction is provided. Attach a platinum plate to the part One, in the balloon, is provided with a pressure sensor for detecting the pressure of the contrast medium within the balloon.

Incidentally, it is preferable that the outer peripheral surface of the balloon or the outer peripheral surface of the distal end portion of the insertion portion main body is covered with an antithrombotic / lubricating coating layer. It is also preferable that the metal braided short cylinder is joined to the metal braided tube by forming a through-hole.

[0018]

When a laser beam is irradiated by a laser fiber, the contrast agent is heated by the laser beam, and the heated contrast agent is discharged (supplied) into the balloon from the through hole of the double structure of the heating tube. The balloon is inflated. Due to the inflation of the balloon, the obstruction can be expanded while heating.

However, since the metal braided double structure is formed at the tip of the heat generating tube, the tip is less likely to be overheated by laser light irradiation from the laser fiber. Further, since the supply of the contrast agent from the heating tube to the inside of the balloon is performed through the through-hole formed through the double structure portion, the contrast agent smoothly flows from the heating tube to the balloon.

Further, in the case where two thermocouples are provided, it is possible to detect the temperature at two predetermined locations in the balloon.
In addition, the temperature of a wide area can be detected by the platinum plate at the junction of the thermocouple.

Further, in the apparatus having the pressure sensor, the pressure of the contrast agent in the balloon can be detected, and the pressure in the balloon can be monitored.

When the outer peripheral surface of the balloon or the outer peripheral surface of the distal end portion of the main body of the insertion portion is covered with a thrombolytic / lubricating coating layer, it can be smoothly inserted into a blood vessel or the like, and the thrombus can be formed. Can be prevented.

[0023]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in detail with reference to the drawings showing embodiments.

FIG. 2 shows a catheter according to the present invention, which has an insertion portion 1 to be inserted into a body (blood vessel).

As shown in FIG. 1, the insertion portion 1 includes an insertion portion main body 2 and a balloon 3 attached to a distal end of the main body 2.
And.

As shown in FIG. 4, the insertion portion main body 2 has a contrast medium feeding path 5, a contrast medium returning path 6, a lumen 7 for a wire, and a lumen 8 for a thermocouple. The main body 2 is made of, for example, a fluorine-based resin such as FEP, or polyurethane or high-density polyethylene.

A laser fiber 9 is inserted through the contrast medium feeding path 5, and a pair of thermocouples is inserted through the thermocouple lumen 8.
10 and 10 are inserted. A wire tube made of a resin such as polyimide is provided at the distal end of the wire lumen 7.
11 are communicatively connected as shown in FIG.

As shown in FIG. 2, a branch portion 14 is provided at the base end of the main body 2. From the branch portion 14, a thermocouple tube 15 communicatively connected to the thermocouple lumen 8 is formed. A contrast agent discharge tube 16 communicatively connected to the agent return path 6,
A fiber insertion / contrast injection tube 17 connected to the contrast agent feed path 5 and a guide wire tube 18 connected to the wire lumen 7 are branched. Further, the thermocouple tube 15 has tubes 20 and 21 branched through a branch portion 19, and the tubes 20 and 21 are connected to the connectors 2 and 3, respectively.
2, 23 are connected. Also, a Y connector 24 is attached to the fiber insertion / contrast agent injection tube 17.
That is, the laser fiber 9 is inserted into one branch pipe 24a of the Y connector 24, and the contrast agent is injected into the contrast agent injection tube 17 from the other branch pipe 24b. Note that a connector 25 is attached to an end of the laser fiber 9.

The balloon 3 is provided with a heating tube 26 as shown in FIG. The heating tube 26 is communicatively connected to the contrast medium feeding path 5 and is a metal braided tube.
27, and a resin tube 28 covering the base end to the middle of the tube 27. The metal braided tube 27
Is made of a flat braid such as stainless steel as shown in FIG. The resin tube 28 may be made of, for example, an imide resin such as polyimide, polyester imide, or polyamide imide, or a fluororesin such as PTFE or PFA.
Made of heat resistant resin of 200 ℃ or more.

That is, the base end of the resin tube 28 is inserted and fixed in the front end opening of the contrast medium feeding passage 5 of the main body 2, and the front end opening of the metal braided tube 27 is closed, The intermediate portion is inserted into the resin tube 28 in a tight fit.

At the tip of the metal braided tube 27,
The metal braid short tubular body 29 is internally fitted and fixed to form a metal braid double structure portion 30. As shown in FIG. 3, a plurality of through holes 31 are provided in the double structure portion 30. That is, the contrast agent that has entered the heating tube 26 from the contrast agent feed path 5 does not flow out of the portion covered with the resin tube 28 into the balloon 3, but enters the double structure portion 30. In this double structural part 30, the balloon 3
Spill into the interior. Although the number and arrangement pitch of the through holes 31 can be freely changed, the hole diameter of the through holes 31 is preferably, for example, 100 μm to 300 μm.

The distal end of the laser fiber 9 is inserted up to the base end of the heat generating tube 26, and a laser beam is emitted from the distal end. When the laser light is applied, the metal braided tube 27 of the heat generating tube 26 absorbs the laser light and is heated, while the contrast agent sent from the contrast medium feeding path 5 causes the heating tube 26 to emit heat.
Heated while flowing through the inside, the heated contrast agent enters the balloon 3 through the through holes 31.

By the way, the penetration of the through hole 31 into the double structure portion 30 is performed by, for example, irradiating a laser beam (different from the laser beam of the laser fiber 9). That is, the metal braided short tubular body 29 is inserted into the metal braided tube 27, and a laser beam is irradiated in this state to form the through-hole 31. In this case, when forming the through hole 31, the metal braided tube 27 and the metal braided short cylinder are used.
The tube 27 and the short cylinder 29 can be joined by dissolving a part of the tube 29.

Thus, a pair of platinum plates 32, 32 spaced apart at a predetermined interval are wound and attached to the wire tube 11. Each platinum plate 32, 32 has a thermocouple 1
0 and 10 are joined at the tip joints 10a and 10a.

Therefore, the temperature of the contrast agent in the balloon 3 can be detected by the thermocouples 10, 10, and the platinum plates 32, 32 at the distal end joints 10a, 10a can average the temperature of the wide area. Temperature can be detected and the platinum plate 32,
Since the distances 32 are provided separately, it is possible to monitor the temperature variation of the contrast agent in the balloon 3.

Further, on the outer peripheral surface of the wire tube 11,
A pressure sensor 33 is provided. The pressure sensor 33 is, for example,
An optical fiber type small-diameter pressure sensor or the like that detects the pressure by increasing or decreasing the reflected light based on this change can be used as the sensor tip flat surface curves in a bulge in response to the pressure. Thus, the pressure of the contrast agent in the balloon 3 can be detected.

Therefore, the pressure in the balloon 3 can be monitored, and the pressure in the balloon 3 can be maintained at a predetermined pressure.

The balloon 3 is made of, for example, an imide-based resin such as polyimide, polyamide imide, or polyester imide, or a heat-resistant resin such as a fluororesin such as PTFE, PFA, or the like. Is inserted and fixed to the main body 2 by bonding or the like,
The distal end 11a of the wire tube 11 is inserted into the distal opening 3b.
Is fixed to the wire tube 11 with an adhesive S. The distal end 27a of the metal braided tube 27 of the heating tube 26 is also inserted and adhered to the distal end opening 3b of the balloon 3.

A tube 34 made of a flexible resin made of a resin such as PE or PTFE is fixed to the distal end 11a of the wire tube 11 via an adhesive S. In addition, platinum, gold,
A marker 35 made of a metal such as tungsten is provided.

Then, on the outer peripheral surface of the distal end portion of the insertion portion 1,
A thrombolytic / lubricious coating layer 36 is coated.
The antithrombotic / lubricious coating layer 36 is made of, for example, a heparin-blended polyvinyl alcohol-based resin or a blend of half-esterified maleic anhydride and a methacrylate-styrene-urethane copolymer. That is, the antithrombotic / lubricating coating layer 36
Is the outer peripheral surface of the balloon 3 or the distal end portion 2a of the insertion portion main body 2.
It is provided on the outer peripheral surface (excluding the part inserted into the balloon 3) and the outer peripheral surface of the tube body 34, and its length dimension is set to, for example, about 200 mm, and its wall thickness is
For example, it is set to about 3 to 30 μm.

Next, a method of using the catheter constructed as described above will be described.

First, a guide wire (not shown) inserted through the guide wire tube 18, the wire lumen 7, the wire tube 11, and the tube body 34 of the insertion portion body 2 is inserted into the body (blood vessel), and the guide is inserted. The insertion section 1 is inserted into a body (blood vessel) while being guided and guided by a wire.

When the balloon 3 reaches the occluded portion of the blood vessel, the contrast medium feed path 5 (specifically, the gap 13 between the inner surface of the feed path 5 and the outer surface of the laser fiber 9 (see FIG. 4) ), The contrast agent is supplied from the branch tube 24b of the Y connector 24, the contrast agent is supplied to the heat generating tube 26, and a laser beam is irradiated from the laser fiber 9 to heat the contrast agent.
The balloon 3 is supplied from the through-holes 31 of the heavy structural part 30 into the balloon 3 so that the balloon 3 is inflated and the closed part is expanded while being heated.

In this case, the temperature of the contrast agent in the balloon 3 is detected by the two thermocouples 10, 10, and the temperature of the contrast agent in the balloon 3 can be set to a desired temperature. That is, the temperature of the contrast agent in the balloon 3 can be adjusted by detecting the temperature of the contrast agent in the balloon 3 and adjusting the irradiation amount of the laser light or the like based on the detected temperature.

The pressure of the contrast agent in the balloon 3 is detected by the pressure sensor 33, and the pressure of the contrast agent in the balloon 3 can be set to a desired pressure.

Incidentally, the temperature of the contrast agent in the balloon 3 is, for example, 50 to 90 ° C., preferably 60 to 75 ° C., and the pressure of the contrast agent in the balloon 3 is, for example,
0.5 to 10 kg / cm ² , preferably 1.0 to 3 kg / cm ² .

After expanding the closed portion, the balloon 3
The contrast agent is discharged to the outside through the contrast agent return path 6 of the insertion portion main body 2 opened to the base end portion of the balloon 3 and the contrast agent discharge tube 16, and the balloon 3 is contracted.
When the insertion portion 1 is pulled out of the blood vessel, the percutaneous coronary angioplasty is completed.

By the way, according to this catheter, a flexible tube 34 is attached to the distal end of the insertion portion 1, and the predetermined portion of the distal end of the insertion portion 1 has antithrombotic and lubricating properties. Since the functional coating layer 36 is provided, it can be smoothly inserted into blood vessels and the like,
Does not cause thrombosis.

Since a double structure portion 30 made of a metal braid is provided at the tip of the heat generating tube 26, the double structure portion can be formed even by irradiating a laser beam from the laser fiber 9.
No more than 30 tips overheat. That is, the heating tube 26
Can be effectively prevented.

The double structure 30 has a plurality of through holes 31.
Are penetrated, the contrast agent in the heating tube 26 smoothly flows into the balloon 3, and the balloon 3 can be inflated quickly.

FIG. 6 shows another embodiment. In this case, the insertion section main body 2 of the insertion section 1 is formed of a tube.
Inside the main body 2, a contrast agent feeding tube 37 forming the contrast agent feeding path 5, a contrast agent returning tube 38 forming the contrast agent returning path 6, a wire tube 39, and a thermocouple tube 40. Are inserted.

In this case, the tube 37 for feeding the contrast agent enters the balloon 3, and the tip portion of the tube 37 which has entered the balloon 3 also serves as the resin tube 28 of the heating tube 26. Note that the contrast agent feeding tube 37, the contrast agent returning tube 38, the wire tube 39, and the thermocouple tube 40 are connected to various devices via the branch portion 14 (see FIG. 2) in the same manner as in the above-described embodiment. Connected to.

Therefore, this catheter has the same operation and effect as the catheter shown in FIG.

Thus, the metal braided tube 27 of the heating tube 26
And the metal braided short cylinder 29 is made of a flat braid made of stainless steel, titanium, steel, gold-plated tungsten, or the like.
27 indicates the outer diameter D (see FIG. 3) of, for example, 0.3 to
1 mm, preferably 0.4 to 0.7 mm, and its inner diameter d
(See FIG. 3), for example, 0.2-0.9 mm, preferably
The short cylinder 29 has an inner diameter d ₁ (see FIG. 3) of, for example, 0.2 to 0.9 mm, preferably 0.3 to 0.6 mm.
0.6 mm, and its length L (see FIG. 3) is, for example,
It is preferably from 0.2 to 0.8 mm, more preferably from 0.3 to 0.6 mm. The outer diameter D ₁ (see FIG. 3) of the short cylinder 29 is substantially the same as the inner diameter d of the tube 27. 1 and 3, the double structural portion 30 is provided at the distal end of the resin tube 28, but a part (that is, the base end) of the double structural portion 30 is provided at the distal end of the resin tube 28. May be supported.

The laser fiber 9 may have a tapered tip at the tip. In this case, the tapered portion is inserted into the heating tube 26 over substantially the entire length of the heating tube 26. Therefore, the laser light is emitted from the outer peripheral surface of the tapered portion of the laser fiber 9 and the heating tube 26
Approximately the entire inner surface is heated substantially uniformly.

[0056]

Since the present invention is configured as described above, the following effects can be obtained.

The metal braided double structural part 30 effectively prevents overheating of the tip of the heat generating tube 26, prevents damage to a part of the heat generating tube 26, and enhances safety.
The catheter has excellent durability, and the flexibility and appearance of the distal end of the insertion section 1 are not impaired.

The through-holes 31 provided in the double structure portion 30.
As a result, the heated contrast agent flows smoothly into the balloon 3, and the balloon 3 is quickly inflated, so that the workability is excellent.

In the case where two thermocouples 10 and 10 are provided, a platinum plate is attached to the junctions 10 a and 10 a of the thermocouples 10 and 10.
Since 32 and 32 are combined, it is possible to detect the temperature of a wide range, and also to effectively monitor the variation in the temperature of the contrast agent in the balloon 3. The temperature of the contrast agent can be adjusted to heat the occlusion at a desired temperature.

With the provision of the pressure sensor 33, the pressure of the contrast agent in the balloon 3 can be monitored, whereby the pressure of the contrast agent in the balloon 3 is adjusted to a desired value, and the closed portion is closed. It can be surely expanded.

With the antithrombotic / lubricating coating layer 36, the insertion portion 1 can be smoothly inserted into a blood vessel or the like of the body, and does not cause thrombus formation.

[Brief description of the drawings]

FIG. 1 is an enlarged sectional view of a main part showing one embodiment of a catheter according to the present invention.

FIG. 2 is an overall simplified diagram.

FIG. 3 is an enlarged vertical sectional view of a main part.

FIG. 4 is an enlarged cross-sectional view of a main part.

FIG. 5 is an enlarged sectional view of a metal braided tube.

FIG. 6 is an enlarged cross-sectional view of a main part of another embodiment.

FIG. 7 is an enlarged sectional view of a main part of a conventional catheter.

[Explanation of symbols]

 2 Insertion part main body 2a Tip 3 Balloon 5 Contrast agent feeding path 9 Laser fiber 10 Thermocouple 10a Tip joint 26 Heating tube 27 Metal braided tube 28 Resin tube 29 Metal braided short cylinder 30 Double structure 31 Through hole 32 Platinum Plate 33 Pressure sensor 36 Antithrombotic and lubricious coating layer

────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-4-117958 (JP, A) JP-A-7-124260 (JP, A) JP-A-7-95987 (JP, A) JP-A-6-95987 121828 (JP, A) JP-A-5-285222 (JP, A) (58) Fields investigated (Int. Cl. ⁶ , DB name) A61M 25 / 00,29 / 02

Claims (6)

(57) [Claims] 1. An insertion section main body having a contrast medium feeding path, a balloon attached to a tip of the insertion section main body, and a heating tube housed in the balloon and connected to and connected to the contrast medium feeding path, And a laser fiber for irradiating the heating tube with a laser beam to heat a contrast agent in the heating tube, and the laser fiber is inserted through the contrast agent feeding path, wherein the heating tube is a metal braid. A tube, a resin tube covering the base end to the intermediate portion of the metal braided tube,
And a metal braided short cylindrical body is fixedly fitted to the distal end of the metal braided tube to form a double-structured portion of the metal braid. A catheter provided with a plurality of through holes which are connected to the inside of a balloon to supply a contrast agent in the heating tube into the balloon. 2. An insertion portion main body having a contrast agent feeding path, a balloon attached to a tip of the insertion portion main body, and a heat generating tube housed in the balloon and connected to and connected to the contrast agent feeding path, And irradiates the inside of the heating tube with laser light.
Laser heating for heating the contrast agent in the heating tube.
The bar, a catheter is inserted into the contrast medium feed path, said heating tube, and a metal braided tube, the metal braid Ji
A resin tube that covers the base end to the intermediate part of the tube,
And a metal braid is provided at the tip of the metal braided tube.
Forming a double structure of metal braid by internally fitting and fixing the braided short cylinder
And the inside of the heating tube and the valve
The contrast agent in the heating tube is connected to
A plurality of through-holes to be supplied into the balloon, and further comprising two thermocouples for detecting the temperature of the contrast agent that has entered the balloon from the heat-generating tube, with a distal end joint disposed in the balloon, A catheter, wherein a platinum plate is connected to each of the junctions of the thermocouples. 3. An insertion portion main body having a contrast agent feeding path, a balloon attached to a distal end of the insertion portion main body, and a heat generating tube housed in the balloon and connected to the contrast agent feeding path. And irradiates the inside of the heating tube with laser light.
Laser heating for heating the contrast agent in the heating tube.
The bar, a catheter is inserted into the contrast medium feed path, said heating tube, and a metal braided tube, the metal braid Ji
A resin tube that covers the base end to the intermediate part of the tube,
And a metal braid is provided at the tip of the metal braided tube.
Forming a double structure of metal braid by internally fitting and fixing the braided short cylinder
And the inside of the heating tube and the valve
The contrast agent in the heating tube is connected to
A plurality of through-holes to be supplied into the balloon, and a pressure sensor for detecting a pressure in the balloon of the contrast agent that has entered the balloon from the heating tube is provided in the balloon. Catheter. 4. An insertion portion main body having a contrast agent feeding path, a balloon attached to a distal end of the insertion portion main body, and a heat generating tube housed in the balloon and connected to the contrast agent feeding path. And a laser fiber for irradiating the heating tube with a laser beam to heat a contrast agent in the heating tube, and the laser fiber is inserted through the contrast agent feeding path, wherein the heating tube is a metal braid. A tube, a resin tube covering the base end to the intermediate portion of the metal braided tube,
And a metal braided short cylindrical body is fixedly fitted to the distal end of the metal braided tube to form a double-structured portion of the metal braid. A plurality of through-holes are provided to connect and connect the inside of the balloon to supply the contrast agent in the heating tube into the balloon, and further, a distal end junction of two thermocouples for detecting the temperature inside the balloon is provided inside the balloon. And a pressure sensor for detecting a pressure of a contrast agent in the balloon is provided inside the balloon. 5. The catheter according to claim 1, wherein the outer peripheral surface of the balloon or the outer peripheral surface of the distal end portion of the insertion portion main body is coated with an antithrombotic / lubricating coating layer. 6. The catheter according to claim 1, wherein the metal braided short cylinder is joined to the metal braided tube by forming a through hole by laser light irradiation.