JP3509155B2 - Balloon catheter - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to, for example, acute heart failure and the like.
For intra-aortic balloon pumping
Related to balloon catheters,
A balloon cap that can be inserted into a patient's blood vessel without using it
It has excellent insertion workability and hemostasis,
The present invention relates to a balloon catheter for preventing lower bleeding. [0002] Intra-aortic balloon pumping (Intra-aortic)
Aortic balloon pumping, hereinafter abbreviated as "IABP method"
Is a synthetic treatment for the treatment of heart failure such as heart failure.
Consists of a balloon section made of a polymer material and a catheter tube
Insert a balloon catheter into the aorta to
The balloon is removed from the catheter tube by the pump device in accordance with the movement.
Shuttle gas is introduced and led out to the
An assisted circulation method that assists cardiac function by expanding and contracting.
You. [0003] The balloon catheter used in the IABP method and
For example, Japanese Patent Application Laid-Open No. 63-206255 and
Balloon cassette as disclosed in JP-A-62-114565
Tell is known. This balloon catheter is
The following three methods are known for insertion into blood vessels.
Have been. A first method is as shown in FIG.
The indwelling sheath 2 is inserted from the skin 82 into the blood vessel 71,
Through the indwelling sheath 2, the balloon portion and the catheter tube
4 is inserted into a blood vessel.
Is the way. Bifurcation attached to the rear end of catheter tube 4
The part 6 is fixed outside the body, from which the balloon part is inflated.
Shuttle gas to introduce and retract
It is. During treatment of IABP, the indwelling sheath 2 is
It remains inserted in the blood vessel 71. Prior to insertion of the indwelling sheath 2, the blood vessel
The insertion slot 85 of 71 is spread by a dilator.
You. The second method is as shown in FIGS.
Using the detachable sheath 8 and the hemostatic plug 12
Is the law. In this method, first, as shown in FIG.
Then, the detachable sheath 8 is inserted into the insertion port 8 of the blood vessel 71 of the patient.
5 into the blood vessel 71 and through this sheath 8
Balloon catheter having balloon portion and catheter tube 4
Tell3 is inserted into the blood vessel. Next, the sheath 8 is
Torn along the direction to remove it,
The hemostatic plug 12 movably mounted is inserted into a blood vessel insertion port.
85, and as shown in FIG.
At the tip of the lug 12, the gap between the insertion port 85 and the catheter tube 4
Close the gap and prevent bleeding. Before inserting the separation-removable sheath 8,
The insertion port 85 of the blood vessel 71 is pushed and widened by a dilator.
I can do it. The third method is shown in FIGS.
As shown, only the dilator 16 and the guide wire 14 are used.
And a balloon having a balloon portion and a catheter tube 4
This is a method of inserting the catheter 3 into a blood vessel. This way
Then, as shown in FIG.
Along the wire 14 from the patient's skin 82 to the blood vessel 71
The dilator 16 is inserted into the inside, and the insertion port 85 of the blood vessel 71 is inserted.
After being spread, only the dilator 16 is removed. Moth
The id wire 14 is left inserted into the blood vessel 71.
Good. Next, as shown in FIG.
Insert the balloon catheter 3 into the blood vessel along 14
You. [0007] The above three methods
Have their strengths and weaknesses, respectively. In the first way
Is excellent in the workability of inserting the balloon catheter 3
However, during the IABP treatment, the indwelling sheath 2 is connected to the blood vessel 71 of the patient.
When the blood vessel 71 is thin,
Blood flow to the outflow side is obstructed, and side effects on the patient are likely to occur. In the second method, the disadvantages of the first method are improved.
Risk of side effects on patients during IABP treatment
Although the steepness is reduced, when the balloon catheter 3 is inserted
In addition, it is necessary to tear the detachable sheath 8
Has hemorrhage from blood vessels and hemostatic plug 1
The work of inserting and stopping 2 is complicated. In the third method, the detention used in the first method is performed.
Sheath 2 and detachable sheath 8 used in the second method
Since the use of the patient is not required, the burden on the patient can be significantly reduced.
Wear. However, in this method, the balloon catheter
Bleeding from the blood vessel insertion port 85 after inserting the
In order to stop, the outer diameter of the dilator 16 is
Smaller than the outside diameter of the
4 is smaller than the outer diameter. For this reason, the catheter tube 4
It is difficult to insert the balloon part attached to the tip of the camera. That is,
At the time of insertion, the balloon portion is folded,
If 5 is too narrow, the balloon will be loosened, making insertion difficult.
Often becomes difficult. [0010] The outer diameter of the dilator 16 is
The diameter is made approximately the same as the outer diameter of the tube 4, and pushed and spread by the dilator 16.
The inner diameter of the insertion hole 85 is about the same as the outer diameter of the catheter tube 4.
, The insertion of the balloon catheter 3 becomes easy.
However, some blood leaked from the insertion port 85, causing subcutaneous bleeding
Cause foci of hematoma, or produce various side effects.
May cause. As mentioned above, the above three methods
Each has its own strengths and weaknesses.
The method has attracted attention. Therefore, a bar suitable for the third method
The development of a rune catheter is desired. The present invention
In consideration of the actual situation, patients can be
Type balloon catheter inserted into the blood vessels
It has excellent insertion workability and hemostasis, and prevents subcutaneous bleeding.
To provide a balloon catheter that can be
Aim. [0012] To achieve the above object,
Next, the balloon catheter according to the present invention is inserted into the aorta.
To expand and retract to assist in cardiac function.
A balloon portion to be deflated, and a shuttle gas inside the balloon portion.
Touch the rear end of the balloon section to introduce and
The connected catheter tube is connected to the rear end of the catheter tube.
The shuttle gas is introduced into the catheter tube and
Where the outgoing and outgoing shuttle gas inlet and outlet are formed
A balloon catheter having the catheter
End of branch pipe ~ side (Large diameter part)
For the outer diameter of the catheter tube at the portion (small diameter portion),
It is increased by 50%, preferably 2 to 20%. [0013] Bifurcation of a catheter tube with a large outer diameter
Part end ~ side Length range is the connection between the bifurcation and the catheter tube.
At least 3 cm from the connection, and at least 1/2 of the total length of the catheter tube
It is preferably in the following range. 3cm or more
Is generally the distance from the surface of the patient's skin to the port
Because the method is 3-5 cm, it is not more than at least 3 cm
And the large diameter part of the catheter tube is inserted into the insertion port of the blood vessel
Not because it is. In addition, IABP treatment
About the full length of the catheter tubing
The balloon part is correct with one half inserted into the blood vessel.
Because it is located in the normal position (near the heart),
The length should be less than half the length of the catheter tube.
You. The balloon catheter according to the present invention can be used for a patient's blood.
To insert into a vessel, first insert it into the vessel through the patient's skin.
Insert the irrator and push open the vascular opening. Daile
Outer diameter of the catheter is about the same as the outer diameter of the small diameter portion of the catheter tube
It is. Then guide wire through this dilator
Is inserted into the blood vessel. Next, the dilator is
Along the guide wire and, instead, along the guide wire.
Thus, the balloon catheter is inserted into the blood vessel. At this time, the insertion port of the blood vessel is a catheter tube.
The balloon diameter is about the same as the outer diameter of the small diameter part of
It can be easily inserted from the insertion port without opening
You. In addition, a balloon catheter is inserted into the blood vessel,
Rune approaches normal position in blood vessel (near heart)
The large diameter portion of the catheter tube is inserted into the blood vessel through the insertion port
Is done. Therefore, the gap between the insertion port of the blood vessel and the catheter tube
The gap is closed and there is no danger of subcutaneous bleeding. Hereinafter, a balloon catheter according to the present invention will be described.
This will be described in detail based on an embodiment shown in the drawings. As shown in FIG.
As described above, a balloon catheter according to one embodiment of the present invention
20 is a valve that expands and contracts in accordance with the heartbeat.
And an edge portion 22. The balloon portion 22 has a thickness of about 100
It is composed of a thin film of about 150 μm. The material of the thin film is
Although not particularly limited, the material is excellent in bending fatigue resistance.
Preferably, for example, made of polyurethane
Is done. The outer diameter and length of the balloon portion 22 are
The inner volume of the balloon portion 22 which greatly affects the auxiliary effect;
It is determined according to the inner diameter of the arterial blood vessel and the like. Balloon part 2
The inner volume of 2 is not particularly limited, but is 30 to 50 cc.
Yes, the outer diameter of the balloon portion 22 is preferably 14 to 16 mm.
Preferably, the length is preferably 210 to 270 mm. The distal end of the balloon portion 22 has a blood connection.
The tip portion 25 in which the through-hole 23 is formed does not fuse with heat.
Shishi is attached by means such as bonding. This tip
On the inner peripheral side of the portion 25, the distal end of the inner tube 30 is not heat-sealed.
Are attached by means such as bonding. The rear end of the balloon portion 22 has a metal contact.
On the outer peripheral side of the connection tube 27, the distal end of the catheter tube 24
Are connected. Formed inside this catheter tube 24
The balloon portion 22 passes through the
The shuttle gas is introduced or led out inside the balloon
22 expands or contracts. balloon
The connection between the part 22 and the catheter tube 24 is performed by heat fusion or
It is performed by bonding with an ultraviolet curing resin type adhesive
You. The inner tube 30 includes a balloon portion 22 and a
The inside of the teller tube 24 extends in the axial direction, and a branch portion 2 described later
6 is connected to the blood pressure measurement port 32,
Inside, the inside of the balloon portion 22 and the catheter tube 2
4 does not communicate with the shuttle gas passage 29 formed therein.
Blood passage 31 is formed. Of the tip 25
The blood communication hole 23 is located in the aorta. Blood pressure in the aorta
Fluctuation occurs when the inner tube 30 is sealed in advance with physiological saline or the like.
Is transmitted to the blood pressure measurement port 32 of the branch portion 26.
Measurement from there. The inner tube 30 located in the balloon portion 22
When the balloon catheter 20 is inserted into an artery,
Balloon part 22 is wound and inserted into the artery conveniently.
Also used as a guide wire insertion lumen when inserting
You. The outer diameter of the inner tube 30 is not particularly limited, but may be 1.0 to
2.0 mm. The thickness of the inner tube 30 is about 0.1 to
0.4 mm. The inner tube 30 is made of, for example, polyurethane.
Of tin, polyvinyl chloride, polyethylene, nylon, etc.
Plastic tube or metal spring reinforced tube
And stainless steel tubes. At the rear end of the catheter tube 24 is the patient's body.
A branch 26 installed outside is connected. Branch 26
Is formed separately from the catheter tube 24 and heat-sealed or
Is fixed by means such as adhesion. The branch section 26
Shuttle gas passageway 29 in the
For introducing or discharging the shuttle gas into the
First passage 47 in which shuttle gas inlet / outlet 28 is formed
Then, a blood pressure measurement port 32 communicating with the inner tube 30 is formed.
A second passage 45 is formed. The shuttle gas inlet / outlet 28 is, for example,
6 is connected to the pump device 10 shown in FIG.
0, the shuttle gas is introduced into the balloon portion 22 or
Is derived. As the gas introduced
Although not particularly limited, according to the drive of the pump device 10
Viscous so that the balloon expands or contracts quickly
Helium gas having a small diameter is used. Also pump
The device 10 is not particularly limited.
An apparatus as shown in JP-A-39265 is used. The blood pressure measuring port 32 shown in FIG.
Is connected to the blood pressure fluctuation measuring device 11 shown in FIG.
2 Changes in blood pressure in the artery taken through the blood communication hole 23 at the tip
The movement can be measured. This blood pressure measurement device 11 measures
Based on the determined blood pressure fluctuation, the pump
The balloon unit 22 is controlled in a short cycle of 1 second or less by controlling the device 10.
It is designed to expand and contract. In this embodiment, the outer diameter of the catheter tube 24 is
Are not the same along the axial direction,
Change the outer diameter of the branch portion side end (large diameter portion 24a) side to other
To the outer diameter of the catheter tube 24 at the portion (small diameter portion 24b).
And increase the size by 2 to 50%, preferably 2 to 20%.
You. Outer diameter of the small diameter portion 24b of the catheter tube 24
Is comparable to the outside diameter of a conventional catheter tube and is
Or 1.5 to 4.4 mm. In addition, the catheter tube 24
The thickness of the small diameter portion 24b is preferably 0.05 to
0.4 mm. The overall length of the catheter tube 24 is preferably
Is about 300 to 800 mm. Meat of catheter tube 24
The thickness is substantially the same for the large diameter portion 24a and the small diameter portion 24b.
Preferably, there is. However, the manufacture of the catheter tube 24
For reasons such as the above, a slight difference in wall thickness is a practical problem.
No title. The length of the large diameter portion 24a of the catheter tube 24
La is connected from the connecting portion between the branch portion 26 and the catheter tube 24.
3cm or more, less than 1/2 of the total length of the catheter tube 24
It is preferably within the range. Smell in catheter tube 24
Connecting portion 24c between the large diameter portion 24a and the small diameter portion 24b.
Is preferably tapered. Skin 82 and
This is because the insertion into the blood vessel 71 becomes smooth. As described above, the cassettes having the different outer diameters in the axial direction.
To manufacture the tellurium tube 24, for example, as shown in FIG.
First, an outer diameter corresponding to the outer diameter of the large diameter portion 24a is provided.
Prepare the resin tube to be heated, and apply heat to one end
While drawing. Thereby, the large diameter portion 24a
To manufacture a catheter tube 24 having a small diameter portion 24b.
Can be Between the large diameter portion 24a and the small diameter portion 24b
A tapered shape is automatically formed in the connection portion 24c. The outer diameter corresponding to the outer diameter of the small diameter portion 24b
Prepare a resin tube with a diameter, and add one end
The small-diameter portion 24
a catheter tube 24 having a large diameter portion 24a and a large diameter portion 24a
You can also. Also in this case, the large diameter portion 24a and the small diameter
The tapered shape is automatically applied to the connection portion 24c with the portion 24b.
Formed. In these cases, the large diameter portion 24a and the small diameter portion 24a
The portion 24b can be integrally formed. Also,
As another means, as shown in FIG.
The tube and the large-diameter tube are connected by bonding or fusion.
The large diameter portion 124a and the small diameter portion 124
b.
You. In this case, the large diameter portion 124a and the small diameter portion 124
tapering the outer periphery of the connecting portion 124c with the b
Is preferred. Materials for constructing such a catheter tube 24
Although the quality is not particularly limited, polyurethane, poly
Vinyl chloride, polyethylene terephthalate, polyamide
And the like. Next, the balloon camera of this embodiment is used.
A method of inserting the catheter 20 will be described. First, as shown in FIG.
The puncture needle 70 is pierced from above, and the tip is
Position within 1. Next, insert inside the puncture needle 70
Pull out a certain stylet 84 and insert the stylet 84
A guide wire 72 (shown in FIG. 4) is drawn out of the hole.
Is inserted into the blood vessel 71. Next, along the inserted guide wire 72,
Then, the puncture needle 70 is extracted, and then, as shown in FIG.
Along the guide wire 72, a tapered tip
The insertion port 85 further into the blood vessel 71 and push the insertion port 85 further.
spread. The outer diameter of the dilator 74 is
4 is about the same as the outer diameter of the small diameter portion 24b. Next, the dilator 74 is connected to a guide wire.
-72 and take it out quickly.
As shown in FIG.
The tell 20 is inserted into the blood vessel 71. Remove the dilator 74
Until the balloon catheter 20 is inserted.
Press on the patient's skin to prevent bleeding. When the balloon catheter 20 is inserted, blood
The insertion port 85 of the tube 71 is connected to the small-diameter portion 2 of the catheter tube 24.
4b is about the same as the outside diameter, so the balloon part can be released
And can be easily inserted from the insertion port 85. Sa
Furthermore, the balloon catheter 20 is inserted into the blood vessel 71,
As shown in FIG. 6, the balloon portion 22 is positioned at the normal position in the blood vessel.
(Near the heart 1), as shown in FIG.
The large-diameter portion 24a of the catheter tube 24 is inserted into the blood vessel 7 from the insertion port 85.
Inserted in 1. Therefore, the insertion port 85 of the blood vessel 71
The gap with the catheter tube 24 is closed, and subcutaneous hemorrhage may occur.
Disappears. Finally, the guide wire 72 is removed from the blood vessel 71.
Withdrawing, fixing the branch part 26 to the patient's skin, using the IABP method
I do. As shown in FIG. 6, the balloon unit 22
To a predetermined position in the arterial blood vessel near
Can help the heart function.
Make sure that the tube 24 does not shift within the blood vessel 71.
Is important. Using the balloon catheter 20 of this embodiment
Improves the insertion workability and hemostasis,
Bleeding can be prevented. In addition, the valve of the present embodiment
Side catheter 20, the branch side of the catheter tube 24.
edge ~ side The large diameter portion 24a is formed,
In the portion 24a, the outer periphery of the inner tube 30 and the inside of the catheter tube 24
Sectional area of shuttle gas passage 29 formed between the circumference
Becomes larger. As a result, the flow path of the shuttle gas passage 29
Resistance is reduced by 4% or more, and inflation and deflation of the balloon section
Responsiveness is improved by 8% or more, and the assisting effect of cardiac function is remarkable
Be improved. In addition, kink (break) of the catheter tube 24
From the viewpoint of effectively preventing pushback by blood flow and blood flow.
The catheter tube 24 is connected to a base tube and a surface tube.
It is preferable to configure a double tube structure. The base tube is
100Kg / mm in linear elastic modulus ^Two With the above hard synthetic resin
It is composed of polyamide, polyimide,
Resin (PFA, PTFE, ETFE, etc.) or
It is composed of polyvinyl chloride (PVDF) or the like. Ma
The surface tube is made of antithrombotic material,
Is made of polyurethane. It is composed of a base tube and a surface tube.
The inner diameter and thickness of the catheter tube are not particularly limited.
However, the inner diameter is preferably 1.5 to 4.0 mm,
The thickness is preferably between 0.05 and 0.4 mm. Also,
The thickness of the base tube alone is 0.03-0.35 mm.
You. It is composed of a base tube and a surface tube.
Catheter tubing can be extruded, for example
It can be formed by a method. Or the base tube
And the surface tube are molded separately, and in the later process
Can be formed by gluing or heat bonding
You. Furthermore, a surface layer tube formed on the outer periphery of the base tube is formed.
The probe can be constructed by the solution immersion method, spray method, etc.
it can. Thus, the catheter tube has a double tube structure.
Then, the inner base tube is made to have a linear elastic modulus of 100 kg /
mm ^Two Made of the above hard synthetic resin, the outer surface tube
If the tube is made of antithrombotic material, the catheter tube
Has moderate rigidity and is easy to insert into the patient's blood vessels.
The balloon connected to the tip of the catheter tube
After being set at a predetermined position in the blood vessel of the patient,
Will not be returned. The outer surface tube has excellent antithrombotic properties.
The material is made of
Absent. Next, another embodiment of the present invention will be described.
You. Bifurcation 42 used in balloon catheter of this embodiment
Then, as shown in FIG.
The formed first passage 47 is inserted in the axial direction of the catheter tube 24.
The blood pressure measurement port 44 is formed
The second passage 45 to be inserted is positioned with respect to the axis of the first passage 47.
It is configured to be arranged with a fixed inclination. Further, in the branching section 42 of this embodiment, the second
The end of the inner tube 30 is held in the passage 45,
Is eccentric so as to contact the inner wall of the catheter tube 24
First inner tube end holder 48 and second inner tube end for placement
The part holder 50 is mounted. The first inner tube end holder 48 is shown in FIGS.
The holder main body 52 and the holder main body 52 are
And a pair of claw portions 54 and 56 protruding in the axial direction.
You. The end of the inner tube 30 is loosely inserted into the holder main body 52.
And the outer periphery of the inner tube 30 is bonded to the main body 52.
And an adhesive insertion hole 59 therefor. Claws 54, 5
6 is configured so that the end of the inner tube 30 is sandwiched between them.
And at the base end side, as shown in FIG.
Has a substantially semicircular shape,
As shown in (C), the inner tube 30 is sandwiched on both sides.
Has a shape in which the projections 54a and 56a are formed.
You. One lower claw portion 56 is connected to the other upper claw portion.
This portion is configured to be longer than the portion 54, and as shown in FIG.
1 The inner tube end holder 48 is inserted into the second passage 45 of the branch portion 42.
In the inserted state, the first ends of the claws 54 and 56
The passage 47 is configured so as not to be narrowed as much as possible. The claw portions 54 and 56 allow the inner tube 30
The ends can be held flexibly. Moreover,
As shown in FIG. 8A, the claws 54 and 56
The end of the tube 30 is held elastically and the inner tube 30 is
As shown in FIG.
Eccentrically so as to contact the inner wall of the pipe 24
Swelling. The second through hole at the rear end of the first inner tube end holder 48
A second inner pipe end holder 50 is mounted in the passage 45.
As shown in FIG. 11, the second inner tube end holder 50 has
In addition, the end of the inner tube 30 is securely inserted into the end.
A fixed hole 60, a blood pressure measurement port 44 communicated with the inner tube 30;
Is formed. The second inner tube end holder 50 is
By the locking projection 62 formed on the outer periphery,
Locked. The end of the inner pipe 30 is held at the end of the first and second inner pipes.
It is fixed in the second passage 45 of the branch portion 42 with the holding tools 48 and 50.
First, the end of the inner tube 30 is connected to the second passage of the branch portion 42.
Through the passage 45, and from the passage 45 to the outside of the branch portion 42.
put out. Next, the first inner tube end holder 4 is inserted into the second passage 45.
8 and resilient the end of the inner tube 30 between the claws 54 and 56
Hold. Then, the end of the inner tube 30 is pulled, and the inner tube 3 is pulled.
0 is inside the catheter tube 24 as shown in FIG.
Arrange eccentrically so as to contact the wall. That
Thereafter, the end of the inner tube 30 is cut into an appropriate length,
The end is adhered to the first inner tube end holder 48. That
Then, the second inner pipe end holder 50 is 2 Insert into passage 45
Then, the end of the inner tube 30 is inserted into the end fixing hole 60 of the holder 50.
Fix it. In the balloon catheter of this embodiment,
Communicates with the shuttle gas inlet / outlet 46 formed in the fork 42
The first passage 47 along the axial direction of the catheter tube 24
The blood pressure measurement port
Conventional example arranged straight along the axial direction of the pipe
2% improvement in shuttle gas flow path resistance compared to
From the viewpoint of responsiveness, it can be further improved by 4%. Further, in the present embodiment, the second communication
The first inner pipe end holder 48 is attached to the passage 45.
So that the inner tube 30 is in contact with the inner wall of the catheter tube 24
It is arranged eccentrically. As a result, in the catheter tube 24
The flow path resistance of the formed shuttle gas passage 29 is
Can be reduced by 4% compared to
Can be good. Conventionally, the catheter tube 24 is
When meandering along the tube, the inner tube 3
0 relatively meanders, and the flow path resistance of the shuttle gas passage 29 is reduced.
In this embodiment, the inner tube 30 is
Eccentrically arranged so as to contact the inner wall of the water pipe 24
Therefore, the flow path resistance of the shuttle gas passage 29 is reduced.
You. The present invention is limited to the above-described embodiment.
It is not intended to be modified in various ways within the scope of the present invention.
Can be. For example, in the present invention,
Is not limited to blood pressure measurement, but is used for other purposes
You may do it. In the embodiment shown in FIGS.
Are a first inner tube end holder 48 and a second inner tube end holder 50
Means that they are molded separately, but they are molded together
Is also possible. Also, the branch portion 42, the first inner tube end holder
48 and the second inner tube end holder 50
The structure can be variously modified within the scope of the present invention. Further, the inner tube 30 is connected to the catheter tube 24.
Integrated molding on the inner wall by gluing, fusing or extrusion molding
It can also be fixed by such means. Thus, inside
By fixing the tube 30 to the inner wall of the catheter tube 24,
The catheter 24 is tortuous along the arterial vessel
However, the inner tube 30 is positioned at a predetermined position on the inner wall of the catheter tube 24.
Fixed to. For this reason, the inner tube is
Of eddy currents and channels due to meandering in pipes
An increase in resistance can be effectively prevented. In addition, the valve of the present embodiment
Balloon catheter, the balloon section is inflated and deflated
Energy loss of the shuttle gas is small. That
As a result, the response of inflation and deflation of the balloon portion is improved.
be able to. As described above, according to the present invention,
For example, without using a sheath, a balloon
It is necessary to insert a balloon catheter because a tel is inserted.
The number of parts to be inserted is small,
Workability is improved. Also, the bifurcation side end of the catheter tube
~ side The large-diameter portion has a large-diameter portion,
Closes the entrance to improve hemostasis and prevent subcutaneous bleeding
Can be stopped.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic sectional view of a main part of a balloon catheter according to one embodiment of the present invention. 2 (A) and 2 (B) are cross-sectional views of a main part showing a method for manufacturing the catheter tube shown in FIG. 1. FIG. 3 is a sectional view of a main part showing a method for inserting the balloon catheter shown in FIG. 1; FIG. 4 is a sectional view of a main part showing a method for inserting the balloon catheter shown in FIG. 1; FIG. 5 is a sectional view of a main part showing a method for inserting the balloon catheter shown in FIG. 1; FIG. 6 is a schematic diagram showing a use state of the balloon catheter of the present embodiment. FIG. 7 is an enlarged sectional view of a branch portion used in another embodiment of the present invention. 8 (A) and 8 (B) respectively show Viii shown in FIG. 7;
It is sectional drawing which follows the A-ViiiA line and the ViiiB-ViiiB line. FIG. 9 is a side view of the first inner tube end holder shown in FIG. 7; FIGS. 10A, 10B, and 10C are cross-sectional views taken along lines XA-XA, XB-XB, and XC-XC shown in FIG. 9, respectively. FIG. 11 is a sectional view of the second inner tube end holder shown in FIG. 7; FIG. 12 is a schematic view showing an example of a method for inserting a balloon catheter. FIGS. 13A and 13B are schematic views showing another example of a method for inserting a balloon catheter. FIGS. 14A and 14B are schematic views showing another example of a method for inserting a balloon catheter. [Description of Signs] 20 Balloon catheter 22 Balloon part 23 Blood introduction port 24 Catheter tube 24a Large diameter part 24b Small diameter part 25 Tip parts 26, 42 Branch parts 28, 46 Shuttle gas inlet / outlet 29 Shuttle gas passage 30 Inner tube 31 Blood passage 32, 44 Blood pressure measurement port 45 Second passage 47 First passage 48 First inner tube end holder 50 Second inner tube end Holders 54, 56 ... claw

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-5-123403 (JP, A) JP-A-3-73167 (JP, A) JP-A-5-137797 (JP, A) JP-A-4- 35671 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) A61M 25/00-25/18 A61M 1/10

Claims (1)

(1) A balloon portion inserted into the aorta and inflated and deflated so as to perform an assisting function of the heart function, and a shuttle gas is introduced and introduced into the balloon portion. As described above, a catheter tube connected to the rear end of the balloon portion, and a branch portion to which the rear end of the catheter tube is connected and a shuttle gas inlet / outlet for introducing and leading a shuttle gas into and out of the catheter tube. Wherein the outer diameter of the catheter tube at the branch portion side end is larger by 2 to 50% than the outer diameter of the other portion of the catheter tube. The length range of the end of the catheter tube at the branch portion side is 3c from the connection portion between the branch portion and the catheter tube.
A balloon catheter having a length of not less than m and not more than 1/2 of the entire length of the catheter tube.