KR101487146B1 - Electrode catheter - Google Patents

Abstract

The electrode 42 is provided on the outer circumferential side of the catheter main body 30 and has an opening 322. The electrode 42 extends to the inner tube 41a in a direction away from the elongating direction of the catheter body 30 And a protruding portion 62a protruding from the catheter distal end portion 40 is present on the base end side of the core wire 62. The exposed portion 62a of the catheter distal end portion 40 The rotation preventing portion 62b is present in the catheter main body portion 62a and between the catheter body portion 30 and the catheter distal end portion 40 is a locking engagement member 52 whose rotation with respect to the catheter body portion 30 is restricted, The engaging member 52 is an electrode catheter in which a rotation preventing portion 62b is inserted and a cutout portion for restricting the rotation of the core wire 62 is formed in contact with the rotation preventing portion 62b. According to this electrode catheter, operability can be improved and the torque resistance of the distal end of the catheter can be improved.

Description

ELECTRODE CATHETER

The present invention relates to an electrode catheter.

Electrode catheters have been used to directly detect weak electrical potentials in the heart. As the electrode catheter, for example, as disclosed in Patent Document 1, there is a type in which the distal end side is formed in a loop shape. In such an electrode catheter, the shape of a loop on the distal end side (hereinafter, referred to as a catheter tip end) is retained by inserting a core wire made of a shape memory alloy into the inside thereof. Further, in Patent Document 1, the core wire is drawn to the inner hole of a straight catheter body portion extending from the distal end portion of the loop-shaped catheter.

Japanese Patent No. 4545384 (paragraph 0019, Fig. 3, etc.)

However, as disclosed in Patent Document 1, when the core wire is elongated such as extended to the inner hole of the catheter body portion, the bending region adjacent to the distal end of the catheter is bent There is a problem that it becomes difficult. In order to solve such a problem, it is preferable to make the core wire as short as possible. In other words, it is preferable that the core wire is configured so as not to hang over the bend area.

However, if the core wire is shortened as described above, the following problems arise. That is, when the electrode catheter is manufactured using the short core wire, the core wire is inserted into the tube at the distal end of the catheter, and then the proximal end side of the core wire is inserted into the tube of the catheter body. The tube is bonded to the tube using an adhesive.

However, since the tube is made of resin, the resin tube is not good in adhesion to the core wire made of a shape memory alloy. Therefore, when a rotational torque is applied to rotate the tip of the catheter, the core wire is peeled off from the state of adhesion to the tube. If such peeling occurs, even if a torque for rotating the distal end of the catheter is imparted, the desired rotation can not be realized. In addition, when such peeling occurs, there is a possibility that the loop-shaped distal end portion of the catheter may fall off from the catheter body portion.

The object of the present invention is to provide an electrode catheter capable of improving the operability and improving the torque resistance of the distal end portion of the catheter.

In order to solve the above problem, an electrode catheter of the present invention comprises at least one electrode, a catheter tip end portion having an inner hole for inserting a lead wire connected to the electrode, And a distal end of the core wire is connected to the distal end of the catheter and has an inner hole for inserting the lead wire therethrough. The distal end of the core wire has a contact with the rotation preventing portion when the rotation preventing portion is inserted And a catheter main body portion having an inner hole which is connected to the proximal end portion of the engaging member and penetrates the lead wire through the insertion hole.

In addition to the above-described invention, the electrode catheter of the present invention is a widened portion whose diameter is expanded to be flatter than the diameter of the other portion of the core wire. The notch portion penetrates the engaging member along the extending direction A first flat hole portion capable of being inserted through the width enlarged portion and a second flat hole portion extending up to the middle portion of the engaging member along the extending direction and capable of inserting the width enlarged portion, It is preferable that the diameter expanding direction of the hole portion and the diameter expanding direction of the second flattened hole portion are different from each other in the circumferential direction of the engaging member.

In addition to the above-described invention, the electrode catheter of the present invention preferably has a distal portion of the catheter having a portion extending in a direction away from the elongating direction of the catheter body.

According to the present invention, operability in the electrode catheter can be improved. In addition, it is possible to improve the torque resistance of the distal end portion of the catheter.

1 is a perspective view showing an overall configuration of an electrode catheter according to an embodiment of the present invention.
2 is a perspective view showing a state in which the catheter distal end portion and the engaging cap body are disassembled and enlarged;
3 is a longitudinal sectional view showing a configuration of the catheter main body.
4 is a partial cross-sectional view showing the configuration of the catheter tip.
Fig. 5 is a perspective view showing the configuration of the anchor member, Fig. 5 (A) is a perspective view showing the anchor member seen from the front end side, and Fig. 5 (B) is a perspective view showing the anchor member seen from the base end side.
Fig. 6 is a plan view showing the state of the anchor member seen from the front end side of the anchor member, and Fig. 6 (B) is a bottom view showing the state of the anchor member seen from the base end side.
6 is a cross-sectional view (AA sectional view in FIG. 6) of the tip end side in FIG. 6, and FIG. 7 is a transverse sectional view of the base end side in FIG. 6 Sectional view of FIG.
8 is a partial perspective view showing the shape of the vicinity of the enlarged portion of the core wire.
9A is a side view of the outer cap, FIG. 9B is a cross-sectional view of the tip end of the outer cap (II cross-sectional view in FIG. 9A) (A sectional view taken along the line II-II in Fig. 9 (A)), and Fig. 9 (D) is a longitudinal sectional view taken along the base end of the outer cap.

Hereinafter, an electrode catheter 10 according to an embodiment of the present invention will be described with reference to the drawings. In the following description, the side where the manipulating handle 20 is located on the proximal end side in the elongating direction of the electrode catheter 10 shown in Fig. 1, and the side on which the catheter distal end 40 opposite to the elongated distal end side is located is the distal end side Explain.

<Configuration>

Fig. 1 is a diagram showing an overall configuration of an electrode catheter 10. Fig. 1, the electrode catheter 10 has an operation handle portion 20, a catheter body portion 30, a catheter distal end portion 40, and a coupling cap body 50.

The operation handle portion 20 is connected to the proximal end side of the catheter body portion 30. The handle portion 20 is provided with a grip portion 21 that the user grips and allows the grip portion 22 to move in and out of the grip portion 21. [ In addition, a pull wire 60 including a metal wire made of NiTi alloy or the like is laid inside the catheter body 30. [ The distal end of the pull wire 60 is fixed to the catheter distal end portion 40 side and the proximal end portion is fixed to the inside of the grip portion 21. [ The proximal end of the catheter body 30 is fixed to the handle 22. As a result, when the handle portion 22 is moved in and out of the grip portion 21, the distal end portion 40 of the catheter is curved.

2, the catheter body 30 includes an outer tube 31 and a multi-lumen tube 32. The outer tube 31 is an outer tube portion that covers the multi-lumen tube 32. As shown in FIG. 1, the outer tube 31 is provided with a hard tube portion 311 and a soft tube portion 312. The hard tube portion 311 is a portion located closer to the base end than the soft tube portion 312 of the outer tube and the soft tube portion 312 is a portion located closer to the tip end than the hard tube portion 311. The hardness of the soft tube portion is softer than that of the soft tube portion. That is, the soft tube portion 312 is provided so as to be more flexible than the hard tube portion 311 so as to be flexibly curved in accordance with the operation of the operation handle portion 20. [

The multi-lumen tube 32 is a tubular member located in the inner space of the outer tube 31 described above. In this multi-lumen tube 32, a hole 321 for a pull wire and a hole 322 for a wire are formed. As shown in Fig. 3, the pull wire hole 321 is a hole portion through which the pull wire 60 is inserted, and is positioned outside the multi-lumen tube 32 in the radial direction. Further, the wire hole 322 is located outside the diameter in the same manner as the hole 321 for the pull wire. The conductor 61 is inserted through the hole 322 for the lead, and corresponds to the inner hole of the catheter body in the claims. In the present embodiment, two holes for pull wires are formed, and four holes 322 for conductors are formed. These holes are all formed by non-conduction with respect to the other holes. However, the numbers of the holes 321 for pull wires and the holes 322 for wires and their shapes are other than those shown in Fig. 3 and can be suitably changed.

The material of the outer tube 31 is made of a polyamide-based resin. Examples of the polyamide based resin include nylon 6, nylon 64, nylon 66, nylon 610, nylon 612, nylon 46, nylon 9, nylon 11, nylon 12, N-alkoxymethyl modified nylon, hexamethylenediamine- Block copolymers in which various aliphatic or aromatic polyamides such as a polymer and a methacryloyldiamine-adipic acid condensate are used as a hard segment and a polymer such as polyester or polyether is used as a soft segment, A polymer alloy (polymer blend, graft polymerization, random polymerization, etc.) of the above-mentioned polyamide and a resin having high flexibility, a flexible one obtained by softening the polyamide with a plasticizer, and the like. However, the aliphatic polyamide and the aromatic polyamide among the aliphatic polyamide (nylon resin) are preferable.

As a material suitably used as the outer tube 31, for example, "PEBAX" (registered trademark of ARKEMA) can be mentioned from the viewpoint of workability.

The material of the multi-lumen tube 32 may be the same as that of the outer tube 31 described above. However, when the multi-lumen tube 32 is made harder than the outer tube 31, the insertion performance of the catheter body 30 is deteriorated. Therefore, the multi-lumen tube 32 has a hardness lower than that of the outer tube 31 It is preferable that it is formed of a material. In the multi-lumen tube 32, the periphery of the hole 321 for the pull wire and / or the hole 322 for the lead wire may be formed as a separate member from the other portion of the multi-lumen tube 32. As such a separate member, a resin having a smaller friction than other portions of the multi-lumen tube 32 (for example, fluororesin) may be used.

In addition, a group of conductors 61A incorporating a predetermined number of conductors 61 are inserted through the hole 322 for the conductor. The lead wire group 61A extends from the operation handle portion 20 and the distal end side of the lead wire group 61A is electrically connected to the electrodes 42 and 43 existing in the catheter distal end portion 40 respectively.

2, the catheter distal end portion 40 has a loop shape spreading on an imaginary plane that is substantially perpendicular to the central axis of the catheter body portion 30. As shown in Fig. In other words, the electrode catheter 10 has a &quot; portion extending in the direction away from the elongating direction of the catheter body portion &quot; Such a loop shape can be said to be a suitable shape when measuring the potential in the peripheral direction within the blood vessel.

4 is a cross-sectional view in a state in which the catheter distal end portion 40 is straightened. 4, the catheter distal end portion 40 has a tube member 41, a ring-shaped electrode 42, and a tip electrode 43. The tube member 41 is formed in a hollow shape and has a hollow portion 61a and a core wire 62 (corresponding to the inner hole of the catheter distal end portion in the claims) Is inserted. The material of the tube member 41 is the same as that of the outer tube 31 described above.

A ring-shaped electrode 42 is provided on the outer tube portion 41b of the tube member 41 at predetermined intervals along the stretching direction. The ring-shaped electrode 42 corresponds to the electrode in the claims. The ring-shaped electrode 42 is fixed to the outer tube portion 41b through an adhesive, for example. More specifically, the outer tube portion 41b is provided with a concave portion 41c that is concave toward the center from the outer circumferential surface thereof, and the ring-shaped electrode 42 is fixed to the concave portion 41c with an adhesive. In addition, the distal end portions of any one of the wires 61 are electrically connected to the respective ring-shaped electrodes 42. In Fig. 2, seven ring-shaped electrodes 42 are provided, but the number of the ring-shaped electrodes 42 may be any number. The ring-shaped electrode 42 is made of a chemically stable material having conductivity. Examples of such materials include platinum, gold, iridium, and alloys thereof.

The distal electrode 43 is an electrode provided at the tip end side of the catheter distal end portion 40, and the outer tube is provided so as to form at least a hemispherical shape (less than half hemispherical bulb). Since the tip electrode 43 exerts such a shape, it is possible to prevent the tip electrode 43 from damaging the blood vessel. 4, the distal end portion 43a is provided with a leg portion 43a and a concave portion 43b. When the leg portion 43a is inserted into the inner tubular portion 41a, 43 are provided on the distal end side of the tube member 41. [ Further, the spherical portion 43b is provided with an insertion through hole 43b1 which is an inner cavity portion.

As shown in Fig. 2, the catheter distal end portion 40 is provided at the proximal end side with a retaining cap body 50. The outer peripheral cap 51 and the anchor member 52 are provided in the engaging cap body 50 (corresponding to the "engaging member" in the claims). 2, a core wire 62 including a metal wire is provided in the distal end portion 40 of the catheter to maintain the distal end loop shape. The outer cap 51 is a tubular member that covers the anchor member 52.

9A, the outer circumferential cap 51 has a tip diameter reduction portion 51a formed so as to reduce the diameter toward the tip end, and a tubular shape having an outer diameter substantially equal to the outer diameter of the outer tube 31 And a portion 51b. The inner diameter of the tip end of the tip diameter reduction portion 51a is reduced in diameter toward the front end (see Fig. 9 (B)) and substantially coincides with the outer diameter of the tube member 41. [

The inner shape of the outer cap 51 is formed such that the longitudinal end face of the tip diameter reduction portion 51a is circular (see FIG. 9 (C)). The inside of the tubular portion 51b is formed so that its longitudinal section is substantially circular, but flat portions 51c and 51c that extend from the proximal end to just before the tip diameter reduction portion 51a are provided so as to be parallel to each other (See Fig. 9 (D)).

The base end of the outer cap 51 covers the multi-lumen tube 32 and the distal end of the outer cap 51 covers the tube member 41. The multi-lumen tube 32 and the tube member 41 are fixed to the outer cap 51 in this state. As the fixing method, a method such as adhesion by an adhesive or fusing is used. That is, the outer cap 51 is integrally fixed to the catheter body 30 and the catheter tip 40. The material of the outer cap 51 is the same as that of the outer tube 31 described above.

The core wire 62 has a base end side formed in a straight line shape and a tip end side in a loop shape as shown in Fig. Specifically, as shown in Fig. 4, the core wire 62 is inserted into the inner cylinder portion 41a of the catheter distal end portion 40, and its distal end is fixed to the rigid portion 43b. The proximal end side of the core wire 62 is a protruding portion 62a protruding from the tube member 41. [ 2 and 4, a large portion of the core wire 62 is drawn into the inner tube portion 41a of the tube member 41, but the base member 41 of the tube member 41 And a protruding portion 62a protruding from the protruding portion 62a. The core wire 62 is made of a shape memory alloy. Examples of the shape memory alloy include a Ni-Ti alloy. A preferred Ni-Ti alloy is nitinol.

More specifically, the core wire 62 is inserted into the insertion through hole 43b1 of the solid portion 43b and the tip end side of the core wire 62 is inserted into the inner wall surface 43b2 of the insertion through hole 43b1. (Bottom surface in Fig. 4). A lead wire 61 is also inserted into the insertion through hole 43b1 and the lead wire 61 is also provided on the inner wall surface 43b2 of the concave portion 43b.

The core wire 62 has a loop shape as shown in Fig. That is, when an external force is applied to the core wire 62, it easily deforms from the loop shape as shown in Fig. However, when the external force is removed from the core wire 62, the core wire 62 is set to return to the loop shape (stored shape) as shown in Fig.

The protruding portion 62a on the proximal end side of the core wire 62 is provided with a width enlarging portion 62b. As shown in Fig. 8, the width expanding portion 62b is a portion where a portion protruding toward the outer diameter side exists in a dimension larger than the diameter of the core wire 62. In Fig. That is, when the direction toward the outer diameter side described above is referred to as the width direction, the width direction dimension (width dimension) of the width enlarged portion 62b is formed larger than the diameter of the core wire 62. [

The width of the preferred width increasing portion 62b is 1.5 to 3 times the diameter of the core wire 62, but may be a width other than the above. In the following description, the portion of the width increasing portion 62b which contacts the flat bottom portion 53c1 is referred to as a width enlarged end face 62b1. The width expanding portion 62b corresponds to an example of the rotation preventing portion in the claims.

An anchor member (52) is disposed on the inner cylinder of the outer cap (51). The anchor member 52 corresponds to the engagement member described in the claims. The anchor member 52 is made of resin, ceramics, or metal. As shown in Figs. 5 to 7, the anchor member 52 has a concave portion and a hole portion formed in a cylindrical member. In detail, a wire insertion through hole 53 is formed in the center of the anchor member 52 in the radial direction. The wire insertion through hole 53 is a hole portion for inserting the base end side of the core wire 62. 5A and 6A) from the opening on the distal end side to the middle portion and a hole shape from the opening on the base end side to the middle portion (See FIG. 5 (B) and FIG. 6 (B)). More specifically, as shown in Figs. 5 (A) and 6 (A), the hole shape from the opening on the distal end side of the wire insertion through hole 53 to the middle portion is formed in the wire insertion through hole 53 (The Y direction in FIG. 6 (A) is particularly long) while the center in the radial direction of the core wire 62 bulges in a circular shape corresponding to the core wire 62.

In the following description, a portion having a long flat shape in the Y direction is referred to as a first flat hole portion 53a. The portion of the wire insertion through hole 53 which is bulged in the arc shape than the first flat hole portion 53a is referred to as a arc shape extending portion 53b. 6, the X direction and the Y direction are orthogonal to each other, and the Z direction in FIG. 7 is orthogonal to the X direction and the Y direction.

On the other hand, as shown in Figs. 5 (B) and 6 (B), the hole shape from the opening on the proximal end side of the wire insertion through hole 53 to the middle portion is formed to have a substantially cross shape. That is, as shown in Fig. 6B, the wire insertion through hole 53 is formed so that the flat shape in the Y direction (the first flattened hole portion 53a) and the flattening in the X direction intersect and become a cross shape Respectively. However, at the intersection of the flattened shape in the X direction and the flattened shape in the Y direction, the shape becomes slightly swollen corresponding to the diameter of the core wire 62. In the following description, the flat hole portion in the X direction crossing the first flat hole portion 53a is referred to as a second flat hole portion 53c. The first flat-hole portion 53a and the second flat-hole portion 53c correspond to the notch in the claims.

The length of the first flat hole portion 53a in the Y direction (wide width direction) is longer than the diameter of the core wire 62 and is formed to be long enough to allow insertion of the width enlarged portion 62b of the core wire 62 have. The length of the first flat hole portion 53a in the X direction (narrower direction) is set to a length enough to allow the width enlarged portion 62b to pass through sufficiently.

The second flat hole portion 53c is formed to have a width and a length that allow the width enlarged portion 62b of the core wire 62 to be inserted. The width of the second flat hole portion 53c is narrower than the width of the first flat hole portion 53a. That is, the first flat hole portion 53a has a margin for inserting the width enlarged portion 62b. As shown in Fig. 7 (A), the second flat hole portion 53c is formed only to the middle portion in the axial direction of the anchor member 52. [ That is, the flat bottom portion 53c1 of the second flat hole portion 53c is present inside the anchor member 52. [ The flat bottom portion 53c1 makes contact with the width enlarged end face 62b1 of the width enlarged portion 62b of the core wire 62 and makes it possible to prevent the width enlarged portion 62b from falling toward the distal end side .

Here, the width dimensions of the first flat hole portion 53a and the second flat hole portion 53c are as follows. When the width enlarged portion 62b of the core wire 62 is drawn into the second flat hole portion 53c, the outer wall surface of the width enlarged portion 62b is in contact with the second flat hole portion 53c And the width enlarged portion 62b is restricted from rotating toward the first flat hole portion 53a. That is, the width dimension of the second flat portion 53c is a width dimension corresponding to the restriction of such rotation. In addition, the second flat hole portion 53c is formed to be narrower than the first flat hole portion 53a. Therefore, the range in which the width enlarged portion 62b is rotated within the second flat hole portion 53c is formed in a state in which it is overwhelmingly smaller than the first flat hole portion 53a.

Further, as shown in Figs. 5 to 7, a pull wire engaging support hole 54 is formed on the outer diameter side of the wire insertion through hole 53 of the anchor member 52. As shown in Fig. In the present embodiment, two pull wire engagement holes 54 are formed, but any number of the pull wire engagement holes 54 may be used. The pull wire engaging support hole 54 is a hole portion for supporting the distal end side of the pull wire 60. The pull wire engaging support hole 54 is formed such that the diameter from the opening on the proximal end side to the opening on the distal end side is smaller than the diameter from the opening on the distal end side to the middle portion. In the following description, the hole portion from the opening on the proximal end side to the middle portion of the pull wire engaging support hole 54 is referred to as a small diameter portion 54a, and similarly, the hole portion from the opening on the distal end side to the middle portion is referred to as a large diameter Portion 54b. In addition, a hook support member (not shown) is provided at the front end side of the pull wire 60. The diameter of the engagement support member is larger than the inner diameter (diameter) of the small diameter portion 54a of the pull wire engagement support hole 54 and the inner diameter (diameter) of the large diameter portion 54b of the pull wire engagement support hole 54, . The latching support members include a pin-shaped member, a nut-shaped member, and the like.

As shown in Fig. 7 (B), the engagement support bottom 54c exists at the boundary between the small-diameter portion 54a and the large-diameter portion 54b. The engaging support bottom 54c is a portion where the bottom face of the engaging support member (not shown) provided on the distal end side of the pull wire 60 collides with the base end side. Thereby, the distal end side of the pull wire 60 is hooked on the anchor member 52.

A recessed portion 55 is formed on the outer circumferential side of the anchor member 52. 5 to 7, the concave portion 55 is a portion recessed from the outer circumferential side of the anchor member 52 toward the center. In the present embodiment, four concave portions 55 are formed, but any number of concave portions 55 may be used. The concave portion 55 is formed in a shape that is cut away from the outer peripheral surface of the anchor member 52 in a curved shape toward the center in the radial direction. As shown in Fig. 6, the inner wall surface on the radial center side of the concave portion 55 is formed so that, when, for example, a group of conductive wires 61A having an outer shape integrated into a circular shape is located, And is formed in an arc shape corresponding to the arc-shaped portion 61A. A group of conductors 61A is laid on the inner hole (corresponding to the inner hole of the engaging member in the claim) formed by the concave portion 55 and the inner peripheral surface of the outer peripheral cap 51.

Further, flat portions 56 and 56 are provided on the outer circumferential surface of the anchor member 52. The flat portions 56 and 56 are portions provided in parallel on the outer peripheral surface of the anchor member 52 in a flat shape. The anchor member 52 is designed such that the flat portions 56 and 56 are engaged with the flat portions 51c and 51c of the outer cap 51 when the anchor member 52 is disposed in the outer cap 51 have. As a result, when the anchor member 52 is disposed inside the outer cap 51, rotation relative to the outer cap 51 is prevented.

Hereinafter, the portion relating to the latching cap body 50 in the method of manufacturing the electrode catheter 10 having the above-described structure will be described.

In the electrode catheter 10 according to the present embodiment, the anchor member 52 is formed so that the straight portion on the base end side of the core wire 62 is inserted from the tip side (left side in Fig. 7) of the anchor member 52, (62). By this insertion, the enlarged width portion 62b is projected from the proximal end side of the anchor member 52. In this insertion, the outside of the width enlarging portion 62b is located in the first flat hole portion 53a. After the width enlarged portion 62b is protruded from the proximal end side of the anchor member 52, the width of the anchor member 52 and the core wire 62 ) Adjusts the relative rotational position.

Then, after the rotation adjustment, the core wire 62 is relatively moved with respect to the anchor member 52 in a direction opposite to the above-described insertion direction (direction from right to left in Fig. 7). Then, the width-widened end face 62b1 contacts the flat bottom portion 53c1, but the core wire 62 is regulated to move toward the tip end side (to fall to the tip end side) by the contact. At this position, the core wire 62 and the anchor member 52 are installed.

Thereafter, the outer cap 51 covers the anchor member 52. The outer cap 51 and the multi-lumen tube 32 (or the outer tube 31) are then closed by the proximal end side of the outer cap 51, The outer tube 31).

This installation may be realized by solidifying the adhesive between the outer cap 51 and the multi-lumen tube 32 (or the outer tube 31) with an adhesive interposed therebetween. The outer cap 51 and the multi- And the tube 32 (or the outer tube 31) may be thermally fused.

The outer cap 51 and the distal end portion 40 of the catheter are provided before and after the attachment between the outer cap 51 and the multi-lumen tube 32 (or the outer tube 31). In this installation, the tube member 41 is covered by the distal end of the outer cap 51, and then the outer cap 51 and the tube member 41 are provided. This mounting may be achieved by solidifying the adhesive by interposing an adhesive between the outer cap 51 and the tube member 41 or by thermally fusing the outer cap 51 and the tube member 41 good.

Here, after the catheter tip 40 is deformed, the enlarged portion 62b is held in the second flattened hole 53c. In addition, the state in which the engaging support member is drawn (positioned) in the large-diameter portion is maintained. It is preferable that the width-enlarged end face 62b1 is in contact with the flat bottom portion 53c1, and it is preferable that the bottom face on the proximal end side of the engaging support member contacts the engaging support bottom portion 54c.

<About action>

In the electrode catheter 10 having the above-described configuration, a width enlarged portion 62b is provided on the proximal end side of the core wire 62, and the outside of the enlarged width portion 62b is connected to the second flattened hole 62a of the anchor member 52 (Positioned) in the lower portion 53c. Thus, when the core wire 62 tries to rotate with respect to the anchor member 52, the outer wall surface of the width enlarged portion 62b collides with the inner wall surface of the second flat hole portion 53c. Thereby, the core wire 62 is prevented from rotating relative to the anchor member 52.

Here, the core wire 62 is provided at the distal end portion 40 of the catheter. In addition, the catheter distal end portion 40 has a loop shape as shown in Fig. 2 in the state where no external force is applied due to the shape memory characteristic of the core wire 62, and the rotation of the catheter distal end portion 40 Is integrally formed with the core wire (62). Therefore, when the distal end portion 40 of the catheter is rotated, for example, in a blood vessel, a large load (torque) is generated in a portion closer to the proximal end side than the loop portion when the loop-

In this case as well, the rotation of the core wire 62 and the anchor member 52 is restricted based on the part shape, not the simple adhesion, and the rotation of the anchor member 52 and the outer cap 51 The distal end portion 40 of the catheter is prevented from falling off the catheter body portion 30 because it is regulated based on the part shape.

The pull wire 60 is inserted into the pull wire engaging support hole 54 of the anchor member 52 and the wire group 61A is located in the recess 55 of the anchor member 52 . In addition, the pull wire 60 is inserted into the pull wire hole 321 of the multi-lumen tube 32, and the lead wire group 61A is similarly inserted into the lead wire hole 322 of the multi-lumen tube 32 Is penetrated. This also makes it difficult for the anchor member 52 to be twisted with respect to the catheter body portion 30 by the presence of the pull wire 60 and the wire group 61A. In other words, even if the anchor member 52 tries to rotate with respect to the catheter body portion 30, the anchor member 52 is hard to rotate due to the presence of the pull wire 60 and the wire group 61A.

As described above, even if the catheter distal end portion 40 tries to rotate with respect to the catheter body portion 30, (1) the outer wall surface of the width enlarged portion 62b hits against the inner wall surface of the second flat hole portion 53c (2) By the presence of the pull wires 60 and the wire group 61A, the rotation of the anchor member 52 relative to the catheter body portion 30 is restricted so that the distal end portion 40 of the catheter is in contact with the catheter body portion It becomes difficult to rotate about the rotating shaft 30.

<Effect>

In this embodiment, the core wire 62 is shortened to prevent the core wire 62 from entering the catheter body 30 side (the soft tube 312) in order to improve operability. As a result, the soft tube 312 becomes easy to bend, and the operability of the electrode catheter 10 can be improved.

In addition, in this embodiment, rotation of the catheter distal end portion 40 with respect to the catheter body portion 30 is regulated as described above. That is, in this embodiment, the core wire 62 is not secured to the catheter body 30, and therefore the catheter body 30 of the catheter tip 40, It is possible to improve the anti-torque characteristics. That is, according to the present embodiment, it is possible to effectively prevent the distal end portion 40 of the catheter 40 from rotating with respect to the catheter body portion 30, and to improve the operability of the electrode catheter 10.

&Lt; Modifications >

As described above, the electrode catheter 10 according to the embodiment of the present invention has been described. However, the present invention can be modified in various ways. Hereinafter, the description will be given.

In the above-described embodiment, the electrode catheter 10 of the type in which the catheter distal end portion 40 is formed in a loop shape is described. However, the present invention is not limited to the above-described types. For example, the present invention can be applied to an electrode catheter having a relatively large structure at the tip, such as an electrode catheter of a type in which a plurality of catheter tip portions are divided into a plurality of catheter tip portions radially.

The width enlarged portion 62b is positioned in the second flat hole portion 53c to restrict the rotation of the catheter distal end portion 40 with respect to the catheter body portion 30. In this embodiment, However, the restriction of rotation of the catheter distal end portion 40 with respect to the catheter body portion 30 may be realized by positioning the enlarged width portion 62b in the first flattened hole portion 53a. That is, since the first flat hole portion 53a is formed in a flat shape like the second flat hole portion 53c, by positioning the width enlarged portion 62b in the first flat hole portion 53a, The rotation of the catheter body 40 relative to the catheter body 30 can be regulated. When the configuration in which the width enlarged portion 62b is located in the first flat hole portion 53a is adopted, the second flat hole portion 53c may not be present in the anchor member 52. [ When the configuration in which the width enlarged portion 62b is located in the first flattened hole portion 53a is adopted, it is possible to prevent the first flattened hole portion 53a from being pulled out from the width enlarged portion 62b. But may be provided on the base end side of the anchor member 52 of the wire 62.

In the above-described embodiment, the wide direction of the first flat hole portion 53a is orthogonal to the wide direction of the second flat hole portion 53c. However, the width direction of the both should not necessarily be an orthogonal arrangement. If the first flat hole portion 53a and the second flat hole portion 53c do not overlap each other in the circumferential direction of the anchor member 52, It may be a batch.

In the above-described embodiment, the first flat hole portion 53a and the second flat hole portion 53c correspond to the cut-out portion in the claims. However, only one of the first flat hole portion 53a and the second flat hole portion 53c may correspond to the notch portion. A notch shape other than the first flattened hole portion 53a and the second flattened hole portion 53c may be formed in the anchor member 52 so as to form a notch portion. Such a notched shape may be a groove shape capable of positioning the width enlarged portion 62b.

Furthermore, in the above-described embodiment, the anchor member 52 covered with the outer cap 51 does not specifically describe whether or not the anchor member 52 is rotating with the outer cap 51. However, the flat portion 56 existing on the outer peripheral surface of the anchor member 52 may be used so that the anchor member 52 does not rotate with respect to the outer peripheral cap 51. In this case, the adhesive is placed on the flat portion 56, or the inner wall surface of the outer cap 51 is thermally deformed toward the flat portion 56, or the outer peripheral surface of the anchor member 52 including the flat portion 56 The inner wall surface of the outer cap 51 may be thermally fused.

The catheter main body 30 may have only the outer tube 31 (single lumen), while the multi-lumen tube 32 is provided only on the distal end side.

10 ... Electrode catheter
20 ... The handle portion
30 ... The catheter body portion
31 ... Outer tube
32 ... Multi-lumen tube
40 ... Catheter tip
41 ... The tube member
41a ... The inner tube (corresponding to the inner hole of the catheter tip)
42 ... The ring-shaped electrode (corresponding to the electrode)
50 ... Clamping cap body (corresponding to engaging member)
51 ... Outer cap
51a ... Tip diameter reduction portion
51b ... The cylindrical portion
51c ... Plane portion
52 ... Anchor member
53 ... Wire insertion hole
53a ... The first flat hole portion (corresponding to a part of the notch portion)
53b ... The arc-
53c ... The second flat hole portion (corresponding to a part of the notch portion)
53c1 ... Flat bottom
54 ... Pull wire clamping hole
54a ... Small diameter portion
54b ... Large diameter portion
54c ... [0030]
55 ... Concave portion
56 ... Flat part
60 ... Pull wire
61 ... ferry
61A ... Taeseon County
62 ... Core wire
62a ... Projecting portion
62b ... Width enlargement part (corresponding to rotation prevention part)
62b1 ... Widened end face
311 ... The hard tube portion
312 ... The soft tube portion
321 ... Hole for pull wire
322 ... Hole for lead (corresponding to the inner hole of the catheter body)

Claims (3)

A catheter tip having at least one electrode and having an inner hole for inserting a lead wire connected to the electrode,
A core wire inserted into an inner hole of the catheter distal end portion and provided on the proximal end side of the rotation preventing portion formed to have a diameter larger than that of the other portion,
An engaging member having a distal end connected to the distal end of the catheter and having an inner hole for inserting the lead wire therethrough and having a cutout portion shaped to contact the rotation preventing portion when the rotation preventing portion is inserted;
And a catheter main body portion connected to the proximal end portion of the engaging member and having an inner hole for inserting the lead wire therethrough. [2] The apparatus according to claim 1, wherein the rotation preventing portion is a width enlarged portion that is diametrically expanded so as to be flatter than the diameter of another portion of the core wire,
The cutout portion is provided with a first flat hole portion which penetrates the engaging member along the stretching direction and allows the width enlargement portion to be inserted therethrough, and a second flat hole portion which extends along the stretching direction and forms a middle portion of the engaging member And a second flat hole portion capable of inserting the width enlargement portion is formed,
Wherein the diameter enlarging direction of the first flat hole portion and the diameter enlarging direction of the second flat hole portion are different from each other in the circumferential direction of the engaging member. The electrode catheter according to claim 1 or 2, wherein the distal end of the catheter has a portion extending in a direction away from the elongating direction of the catheter body.

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