JP5631475B1 - Balloon catheter - Google Patents

Abstract

A balloon catheter that has excellent pushability when inserted into a blood vessel, can reliably prevent kinking at the rear end portion of the distal shaft, and can be smoothly inserted into a bent blood vessel. To provide. A distal end side shaft 10 made of a resin tube, a rear end side shaft 20 made of a metal tube, a balloon 30, an inner tube 40, and a core wire 50 are provided, and a straight portion 51 and a taper portion 52 are provided. A core wire 50 made of It is press-fitted between the outer peripheral surface. [Selection] Figure 1

Description

  The present invention relates to a rapid exchange type balloon catheter.

  Conventionally, a balloon catheter having an outer shaft and an inner tube is known (see, for example, Patent Document 1 and Patent Document 2).

In the rapid exchange type balloon catheter as shown in Patent Document 1 and Patent Document 2, a balloon is attached to the tip of the outer shaft, the tip of the inner tube is fixed to the tip of the balloon, and the rear end of the inner tube Open on the side of the outer shaft to form a guide wire port.
On the other hand, a rear end side shaft made of a metal tube is connected to a rear end of the outer shaft made of a resin tube.
Here, the lumen of the outer shaft (front end side shaft) and the rear end side shaft is an expansion lumen through which a fluid for expanding the balloon flows, and the lumen of the inner tube is a guide wire lumen for inserting the guide wire. It is.

In a rapid exchange type balloon catheter as shown in Patent Document 1 and Patent Document 2, a core wire is inserted as a reinforcing body into a lumen of an outer shaft made of a resin tube.
The rear end portion of the core wire is fixed to the inner peripheral surface of the rear end side shaft made of a metal tube by welding or the like. As a result, the rigidity of the rear end portion of the outer shaft (front end side shaft) requiring reinforcement, specifically, the rear end portion of the guide wire port formation position can be improved. Occurrence of the kink (buckling) of the part at the time can be suppressed to some extent.

  Here, the core wire usually has a straight portion having a constant diameter and a tapered portion (reduced diameter portion) located on the tip side of the straight portion. The taper portion of the core wire is reduced in diameter in the distal direction, and thereby the hardness (rigidity) of the balloon catheter can be gradually reduced toward the distal end.

However, in the balloon catheters as shown in Patent Document 1 and Patent Document 2, since the distal end portion of the core wire is not fixed to the inner peripheral surface of the outer shaft (the distal end is a free end), sufficient pushability is achieved. There is a problem that can not be demonstrated.
That is, when a pushing force is applied from the rear end side shaft when the balloon catheter is inserted into the blood vessel, the core wire moves (advances) in the axial direction with respect to the outer shaft (front end side shaft). The pushing force cannot be sufficiently transmitted to the distal shaft.

  In the case of a balloon catheter in which the distal end of the core wire is not fixed to the inner peripheral surface of the outer shaft, the rear end portion of the distal shaft (the position where the guide wire port is formed) To the tip position of the rear end side shaft) cannot be reliably prevented.

With respect to such a problem, Patent Document 3 below discloses a balloon catheter in which a core wire is fixed to the inner peripheral surface of the outer shaft at the rear end portion of the outer shaft (front end side shaft).
As in the balloon catheter described in Patent Document 3, the core wire fixed to the inner peripheral surface of the rear end side shaft is also fixed to the inner peripheral surface of the front end side shaft, thereby pushing the force from the rear end side shaft. Can be reliably transmitted to the tip side shaft, and good pushability can be exhibited. Moreover, the rigidity of the front end side shaft on the rear end side with respect to the fixing position of the core wire can be sufficiently increased, and the kink in the portion can be reliably prevented.

  However, when the core wire is firmly fixed to the inner peripheral surface of the distal end side shaft as in the balloon catheter described in Patent Document 3, the bending rigidity of the distal end side shaft becomes excessive and the flexibility is increased. Significantly damaged. As a result, there arises a problem that such a balloon catheter cannot be smoothly inserted into a bent blood vessel (for example, a meandering blood vessel in the heart).

  In addition, when the core wire fixing position on the inner peripheral surface of the front shaft is largely separated from the guide wire port forming position to the rear end side, the portion from the guide wire port forming position to the core wire fixing position Since the rigidity cannot be sufficiently increased, there is a possibility that kinks may occur in the portion.

JP 2002-28243 A JP 2003-164528 A Japanese Patent No. 5061614

The present invention has been made based on the above situation.
An object of the present invention is excellent in pushability when inserted into a blood vessel, and kinks (buckling) in the rear end portion of the distal end side shaft (portion from the formation position of the guide wire port to the distal end position of the rear end side shaft) It is an object of the present invention to provide a rapid exchange type balloon catheter that can be reliably prevented and can be smoothly inserted into a bent blood vessel.

(1) The balloon catheter of the present invention includes a distal end shaft made of a resin tube,
A rear end side shaft made of a metal tube connected to a rear end of the front end side shaft;
A balloon connected to the tip of the tip side shaft;
A resin tube that is inserted into the lumen of the distal shaft and the inside of the balloon to form a guide wire lumen, the rear end of the side surface of the distal shaft opening as a guide wire port, and the distal end of the balloon An inner tube whose front end is fixed to
A core wire that has a straight portion and a reduced-diameter portion, and has the reduced-diameter portion as a distal end side and is inserted through a lumen of the distal-end shaft;
The rear end side of the core wire is fixed to the inner peripheral surface of the rear end side shaft, and the straight portion of the core wire is press-fitted between the inner peripheral surface of the front end side shaft and the outer peripheral surface of the inner tube. Has been
The axial distance (L1) from the formation position of the guide wire port to the tip of the straight portion of the core wire is 1.0 to 50.0 mm,
When the straight portion of the core wire is press-fitted, the cross-section of the tip side shaft in the portion where the straight portion is press-fitted becomes an elliptical shape, and the major axis of the ellipse is (D ₁₁ ) and the minor axis is (D ₁₂ ), The value of (D ₁₁ ) / (D ₁₂ ) is 1.02 to 1.30 .

  According to the balloon catheter having such a configuration, the straight portion of the core wire fixed to the inner peripheral surface of the rear end side shaft is press-fitted between the inner peripheral surface of the front end side shaft and the outer peripheral surface of the inner tube. By fixing (connecting the front end side shaft and the rear end side shaft via the straight portion of the core wire), it is possible to exhibit excellent pushability and the rear end side (guide) from the fixing position of the core wire. Since the rigidity of the front end side shaft in the region including the part from the formation position of the wire port to the front end position of the rear end side shaft can be sufficiently increased, kink in the part can be reliably prevented.

  In addition, the core wire is not firmly (completely) fixed to the inner peripheral surface of the distal end side shaft, but a straight portion is press-fitted between the inner peripheral surface of the distal end side shaft and the outer peripheral surface of the inner tube. As a result, the core wire is fixed (in other words, semi-fixed using the elasticity of the resin), so when a bending stress is applied to the tip side shaft, the core wire moves (slids) in the axial direction relative to the tip side shaft. As a result, good flexibility is ensured in the distal shaft, and as a result, the distal shaft can be smoothly inserted into the bent blood vessel.

(2) In the balloon catheter of the present invention, the inner diameter of the resin tube constituting the distal shaft is (d ₁ ), the outer diameter of the inner tube is (D ₂ ), and the diameter of the straight portion of the core wire is (D _3). ), The value of D ₃ / (d ₁ -D ₂ ) is preferably 1.05 to 1.95. However, the inner diameter (d ₁ ) of the resin tube is the inner diameter when the core wire is not inserted.

  According to the balloon catheter having such a configuration, an appropriate pressure (clamping force) can be applied to the outer peripheral surface of the straight portion of the core wire by the inner peripheral surface of the distal shaft and the outer peripheral surface of the inner tube. Thus, the shaft on the distal end side has excellent rigidity and flexibility in a well-balanced manner.

  The balloon catheter of the present invention is excellent in pushability when inserted into a blood vessel, and reliably kinks at the rear end portion of the distal shaft (portion from the guide wire port formation position to the distal end position of the rear shaft). This can be prevented and can be smoothly inserted into a bent blood vessel.

It is sectional drawing which shows typically the longitudinal cross-section of the balloon catheter which concerns on one Embodiment of this invention. Sectional drawing which shows the cross section of the balloon catheter which concerns on one Embodiment of this invention (aa sectional drawing of FIG. 1, bb sectional drawing, cc sectional drawing, dd sectional drawing, ee sectional drawing) ).

The balloon catheter 100 of this embodiment shown in FIGS. 1 and 2 is used for percutaneous coronary angioplasty (PTCA) or the like.
The balloon catheter 100 includes a front end side shaft 10 made of a resin tube, a rear end side shaft 20 made of a metal tube connected to the rear end of the front end side shaft 10, and a balloon 30 connected to the front end of the front end side shaft 10. A resin tube that is inserted into the lumen of the distal shaft 10 and the inside of the balloon 30 to form a guide wire lumen, the rear end of the side surface of the distal shaft 10 opens as a guide wire port, and the balloon 30 The distal end portion is fixed to the distal end portion of the inner tube 40, and the distal end side shaft 10 is formed with an inner tube 40 having an open distal end, a straight portion 51, and a tapered portion 52 (reduced diameter portion). Core wire 50 inserted through the lumen of the core wire 50. The core wire 50 is a straight wire. 51 is fixed to the inner peripheral surface of the rear end side shaft 20 by welding on the rear end side of the rear end side 51, and between the inner peripheral surface of the front end side shaft 10 and the outer peripheral surface of the inner tube 40 on the front end side of the straight portion 51. It is press-fitted between.
In FIG. 1, 60 is a hub attached to the rear end of the rear end side shaft 20, and 70 is a strain relief.

  The distal shaft 10 of the balloon catheter 100 is made of a resin tube. The distal shaft 10 is formed with a lumen (expansion lumen) through which a fluid for expanding the balloon 30 is circulated.

The outer diameter (D ₁ ) of the resin tube constituting the distal shaft 10 is usually 0.7 to 1.0 mm.
The inner diameter of the resin tube constituting the distal shaft 10 (d ₁₎ is usually 0.65～0.95Mm.
The outer diameter (D ₁ ) and the inner diameter (d ₁ ) are the diameters when the core wire 50 is not inserted.

The length of the distal end side shaft 10 is usually 150 to 450 mm, and is 390 mm if a suitable example is shown.
Examples of the constituent material of the distal shaft 10 (resin tube) include thermoplastic resins such as polyamide, polyether polyamide, polyurethane, polyether block amide (PEBAX) (registered trademark) and nylon. Among these, PEBAX Is preferred.
The hardness of the distal shaft 10 (resin tube) is preferably 63-80 as measured by a D-type hardness meter.

The rear end side shaft 20 connected to the rear end of the front end side shaft 10 is formed with a lumen (extended lumen) communicating with the lumen of the front end side shaft 10.
The rear end side shaft 20 is composed of a metal tube (hypotube) such as stainless steel, Ni—Ti alloy, Cu—Mn—Al alloy, and a spiral slit is formed at the tip of the metal tube. It may be formed.

As shown in FIG. 1, the metal tube constituting the rear end side shaft 20 has its front end inserted into the rear end of the resin tube constituting the front end side shaft 10, and its rear end attached to the hub 60. Has been inserted.
The outer diameter of the metal tube constituting the rear end side shaft 20 is usually 0.5 to 0.8 mm.
Moreover, the internal diameter of the metal tube which comprises the rear end side shaft 20 shall be 0.4-0.7 mm normally.
The length of the rear end side shaft 20 is usually set to 900 to 1500 mm.

A balloon 30 is attached to the distal end of the distal shaft 10.
The balloon 30 is expanded by the liquid flowing through the lumens of the front end side shaft 10 and the rear end side shaft 20. Here, examples of the liquid include physiological saline and a contrast medium.
The diameter of the balloon 30 at the time of expansion is usually 1.0 to 5.0 mm, preferably 2.0 to 3.5 mm.
The length of the balloon 30 is usually 5 to 40 mm, preferably 15 to 30 mm.
As a constituent material of the balloon 30, the same balloon as that of a conventionally known balloon catheter can be used, and PEBAX can be cited as a suitable material.

The inner tube 40 constituting the balloon catheter 100 extends to the lumen of the distal shaft 10 and the interior (lumen) of the balloon 30, and forms a lumen (guide wire lumen) for inserting a guide wire. It is a tube.
The rear end of the inner tube 40 is opened on the side surface of the distal end side shaft 10, and the opening 41 is a guide wire port.
The distal end portion of the inner tube 40 is fixed to the distal end portion of the balloon 30, and an opening 42 is formed at the distal end of the inner tube 40.

The outer diameter of the inner tube 40 (D ₂₎ is usually 0.48～0.60Mm.
The inner diameter (d ₂ ) of the inner tube 40 is usually 0.35 to 0.45 mm.
The axial distance (L3) from the position where the opening 41 of the inner tube 40 serving as the guide wire port is formed to the rear end position of the balloon 30 is usually 150 to 300 mm.

  The axial distance (L4) from the formation position of the opening 41 of the inner tube 40 to the tip of the rear end side shaft 20 is usually 0 to 50 mm, preferably 5 to 50 mm. In addition, when this distance (L4) is 5 mm or more, it is particularly effective to adopt the configuration of the present invention.

As a constituent material of the inner tube 40, the same synthetic resin as the constituent material of the distal shaft 10 can be mentioned, and among them, PEBAX is preferable.
The hardness of the distal shaft 10 is preferably 63 to 80 as measured by a D-type hardness meter.

  The core wire 50 constituting the balloon catheter 100 includes a straight portion 51 and a tapered portion 52. The core wire 50 is inserted through the lumen of the front end side shaft 10 with the tapered portion 52 as the front end side, and a part of the rear end side of the core wire 50 is inserted through the lumen of the rear end side shaft 20.

  The core wire 50 is spotted on the inner peripheral surface of the rear end side shaft 20 (the inner peripheral surface at a position about 10 to 150 mm away from the distal end position of the rear end side shaft 20 to the proximal end side) on the rear end side of the straight portion 51. By being welded, it is firmly fixed to the rear end side shaft 20.

  The core wire 50 is press-fitted between the inner peripheral surface of the front shaft 10 and the outer peripheral surface of the inner tube 40 at the distal end side of the straight portion 51 (the straight portion 51 is sandwiched between two resin tubes. To the distal end side shaft 10.

Thus, the straight portion 51 of the core wire 50 fixed to the inner peripheral surface of the rear end side shaft 20 is press-fitted between the inner peripheral surface of the front end side shaft 10 and the outer peripheral surface of the inner tube 40 and fixed. Therefore, the pushing force from the rear end side shaft 20 can be reliably transmitted to the front end side shaft 10, and good pushability can be exhibited.
Further, the rear end side of the core wire 50 (straight portion 51) is fixed [the portion from the guide wire port formation position to the front end position of the rear end shaft 20 (in FIG. 1, the length of the portion is (L4) It is possible to sufficiently increase the rigidity of the distal end side shaft 10 in the region including]), and to reliably prevent kinking in the portion.

  Further, the core wire 50 is not completely fixed to the inner peripheral surface of the distal end side shaft 10, but the straight portion 51 is press-fitted between the inner peripheral surface of the distal end side shaft 10 and the outer peripheral surface of the inner tube 40. As a result, the core wire 50 is fixed (semi-fixed), and therefore when the bending stress is applied to the distal shaft 10, the core wire 50 can be moved (slid) in the axial direction relative to the distal shaft 10. As a result, good flexibility is ensured for the distal shaft 10. As a result, the distal shaft 10 can be smoothly inserted into the bent blood vessel.

  When the tapered portion 52 of the core wire 50 is press-fitted between the inner peripheral surface of the distal end side shaft 10 and the outer peripheral surface of the inner tube 40 instead of the straight portion 51, the core wire 50 is inserted into the distal end side shaft 10. Since the core wire 50 cannot move in the distal direction, the flexibility secured by the relative movement of the core wire 50 in the distal direction cannot be secured. Further, when the press-fitting and fixing of the taper portion 52 is released by moving the core wire 50 toward the rear end direction with respect to the front end side shaft 10, the contact between the core wire 50 and the front end side shaft 10 and the inner tube 40 is made. Therefore, good pushability cannot be exhibited, and the occurrence of kinks at the rear end portion of the front end side shaft 10 cannot be prevented.

The diameter (D ₃ ) of the straight portion 51 of the core wire 50 varies depending on the inner diameter (d ₁ ) of the resin tube constituting the distal shaft 10 and the outer diameter (D ₂ ) of the inner tube 40, and at least D ₃ / (d It is necessary that the value of ₁₋ D ₂ ) is adjusted to be larger than 1.0. The diameter (D ₃ ) of the straight portion 51 is usually 0.1 to 0.3 mm.

The diameter of the straight portion 51 (D _3), it is preferable that the value of _{D 3 / (d 1 -D 2} ) is adjusted to be 1.05 to 1.95.
By adjusting the diameter (D ₃ ) so that the value of D ₃ / (d ₁ -D ₂ ) is 1.05 to 1.95, the distal end side with respect to the outer peripheral surface of such a straight portion 51 Appropriate pressure (clamping force) can be applied by the inner peripheral surface of the shaft 10 and the outer peripheral surface of the inner tube 40. As a result, the distal end side shaft 10 has excellent rigidity and flexibility in a balanced manner. It will be a thing.

When the value of D ₃ / (d ₁ −D ₂ ) is less than 1.05, the straight portion of the core wire cannot be sufficiently fixed to the tip side shaft. On the other hand, when the value of D ₃ / (d ₁ -D ₂ ) exceeds 1.95, the straight portion of the core wire may be press-fitted between the inner peripheral surface of the distal end side shaft and the outer peripheral surface of the inner tube. It may not be possible, or the cross-sectional shape of the shaft after press-fitting and fixing may be greatly deformed to impair operability.

  In the balloon catheter 100 of the present embodiment, the cross-section of the distal shaft 10 at the portion where the straight portion 51 of the core wire 50 is press-fitted and fixed has an elliptical shape.

When the major axis of this ellipse is (D ₁₁ ) and the minor axis is (D ₁₂ ), the value of (D ₁₁ ) / (D ₁₂ ) is preferably 1.02 to 1.30.

Since the value of (D ₁₁ ) / (D ₁₂ ) in the ellipse is 1.02 to 1.30, the pushability according to the present invention can be achieved without impairing the matching of the distal shaft 10 to other devices. The effect of improving the rigidity and the effect of improving the rigidity of the rear end portion of the front shaft can be sufficiently exhibited.

When the value of (D ₁₁ ) / (D ₁₂ ) is less than 1.02, the pushability is improved because the straight portion of the core wire inserted through the lumen of the distal shaft is not sufficiently press-fitted and fixed. The effect and the effect of improving the rigidity at the rear end portion of the front end side shaft may not be sufficiently exhibited. Alternatively, the lumen (guide wire lumen) of the inner tube may be blocked.
On the other hand, when the value of (D ₁₁ ) / (D ₁₂ ) exceeds 1.30, the distal end side shaft and other devices such as that the distal end side shaft having such a cross-sectional shape cannot be accommodated in the guiding sheath. The matching with may be impaired.

The axial distance (L1) from the position where the opening 41 of the inner tube 40 serving as a guide wire port is formed to the tip of the straight portion 51 of the core wire 50 is usually 1.0 to 50.0 mm.
If the distance (L1) is too short, the core wire 50 (straight portion 51) cannot be sufficiently fixed (clamped), and the pushability improvement effect and the rigidity improvement effect at the rear end portion of the distal end side shaft are achieved. May not be fully demonstrated.
On the other hand, if this distance (L1) is too long, “direction of bending” appears in the distal shaft 10, and the operability (insertability into the blood vessel) of the balloon catheter may be impaired.

  The length (L2) of the tapered portion 52 of the core wire 50 is usually 50 to 250 mm, although it varies depending on the axial distance (L3) from the position where the opening 41 is formed to the rear end position of the balloon 30.

  The balloon catheter 100 of this embodiment is excellent in pushability when inserted into a blood vessel, and is in the rear end portion of the distal end side shaft 10 (portion from the formation position of the guide wire port to the distal end position of the rear end side shaft 20). Kink can be reliably prevented, and since the distal shaft 10 has appropriate flexibility, it can be smoothly inserted into a bent blood vessel.

As mentioned above, although one Embodiment of this invention was described, this invention is not limited to these, A various change is possible.
For example, the reduced diameter portion of the core wire may be intermittently reduced in the distal direction.
Moreover, the several straight part from which a diameter differs may be connected with the core wire through the reduced diameter part. In this case, one of the straight portions is press-fitted between the inner peripheral surface of the distal end side shaft and the outer peripheral surface of the inner tube.

DESCRIPTION OF SYMBOLS 100 Balloon catheter 10 Front end side shaft 20 Rear end side shaft 30 Balloon 40 Inner tube 41 Opening (guide wire port)
42 Opening 50 Core wire 51 Straight part 52 Taper part 60 Hub 70 Strain relief

Claims (2)

A tip side shaft made of a resin tube;
A rear end side shaft made of a metal tube connected to a rear end of the front end side shaft;
A balloon connected to the tip of the tip side shaft;
A resin tube that is inserted into the lumen of the distal shaft and the inside of the balloon to form a guide wire lumen, the rear end of the side surface of the distal shaft opening as a guide wire port, and the distal end of the balloon An inner tube whose front end is fixed to
A core wire that has a straight portion and a reduced-diameter portion, and has the reduced-diameter portion as a distal end side and is inserted through a lumen of the distal-end shaft;
The rear end side of the core wire is fixed to the inner peripheral surface of the rear end side shaft, and the straight portion of the core wire is press-fitted between the inner peripheral surface of the front end side shaft and the outer peripheral surface of the inner tube. Has been
The axial distance (L1) from the formation position of the guide wire port to the tip of the straight portion of the core wire is 1.0 to 50.0 mm,
When the straight portion of the core wire is press-fitted, the cross-section of the tip side shaft in the portion where the straight portion is press-fitted becomes an elliptical shape, and the major axis of the ellipse is (D ₁₁ ) and the minor axis is (D ₁₂ ), The balloon catheter is characterized in that the value of (D ₁₁ ) / (D ₁₂ ) is 1.02 to 1.30 . When the inner diameter of the resin tube constituting the distal shaft is (d ₁ ), the outer diameter of the inner tube is (D ₂ ), and the diameter of the straight portion of the core wire is (D ₃ ),
The balloon catheter according to claim 1, wherein the value of D ₃ / (d ₁ -D ₂ ) is 1.05-1.95.

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