JP5708850B1 - catheter - Google Patents

Abstract

A large-diameter resin tube and an operation wire tubule that are both inserted inside a reinforcing layer made of a coil are provided, and the inserted large-diameter resin tube and the operation wire tubule are radially inner by the coil. Provided are a catheter that can be prevented from being crushed in a direction and a method for manufacturing the catheter. A catheter 100 includes a large-diameter resin tube 14 forming a lumen 12, an operation line capillary 16 disposed outside the lumen 12, an operation line 18 inserted through the operation line capillary 16, and a large tube. A reinforcing layer 22 that is a coil that covers both the diameter resin tube 14 and the operation wire thin tube 16, and an outer layer 42 made of a resin member that covers the outer surface of the reinforcing layer 22. The distal end fixing portion 10 includes the distal end fixing portion 10 and the proximal end fixing portion 11 that grip the coil by being provided around the reinforcing layer 22 against the force of loosening the reinforcing layer 22 at the distal end portion and the proximal end portion. The outer layer 42 receives a biasing force that elastically biases radially outward from the coil in a region between the base end fixing portion 11 and the base end fixing portion 11. [Selection] Figure 1

Description

  The present invention relates to a catheter. In particular, the present invention relates to a catheter capable of bending a distal end portion by operating an operation line inserted therein.

  In recent years, catheters have been provided that can manipulate the direction of entry into a body cavity by bending the distal end by manipulating the manipulation line. In general, the operation line is disposed inside the catheter while being inserted into the resin tube. From the viewpoint of protecting the resin tube, a catheter in which a metal layer made of a coil is disposed outside the resin tube has been proposed.

  For example, in Patent Document 1, a first resin layer that is an innermost layer made of a fluororesin, a metal layer that is disposed outside the first resin layer, and a second resin layer that is the outermost layer disposed further outside the metal layer. An invention of an auxiliary device for inserting / removing a treatment instrument having a catheter comprising: The invention of the auxiliary device for inserting / removing the treatment tool is also referred to as “prior art 1” hereinafter. In Patent Document 1, it is described that the metal layer is made of a coil (for example, paragraph [0023] in Patent Document 1, FIG. 5 to FIG. 7).

  In the prior art 1, the first resin layer is protected by disposing the first resin layer inside the metal layer made of a coil.

JP 2007-301360 A JP 2013-48711 A

However, the conventional catheter in which the coil represented by the prior art 1 is arranged outside the resin tube has the following problems.
A metal layer that is a coil formed by winding a linear member such as a wire in a spiral direction is generally annealed so as to be clamped inward in the radial direction. Thus, the coil can maintain a predetermined diameter without being loosened. Here, annealing the coil means, for example, a process of heat-treating at an appropriate temperature in a state in which the coil is restrained from loosening outward in the radial direction, and then cooling to reduce the coil loosening force. Say.

  However, in this aspect, the resin layer may be clamped radially inward by the annealed coil depending on the design of the metal layer and the resin layer inserted therein and the degree of annealing treatment. In this case, the operation line insertion path provided inside the resin layer may be crushed and the operability of the operation line may be deteriorated.

  In particular, as shown in FIG. 3 of Patent Document 2, the above problem is remarkable in a catheter provided with a small diameter resin tube for inserting an operation line separately from a large diameter resin tube. That is, when both the large-diameter resin tube and the small-diameter resin tube are inserted into the coil that is a metal layer, the operation of the operation line inserted through the small-diameter resin tube is crushed in the radial direction by the coil. There was a possibility that the property would be poor.

The present invention has been made in view of the above problems. That is, according to the present invention, a large-diameter resin tube and an operation wire tubule inserted together are provided inside a reinforcing layer made of a coil, and the inserted large-diameter resin tube and the operation wire tubule are the coil. Provided is a catheter that is prevented from being crushed radially inward by a reinforcing layer .

The catheter of the present invention is a catheter having a lumen therein, a large-diameter resin tube forming the large-diameter lumen, a small-diameter operation line tubule disposed outside the lumen, and the operation line An operation wire inserted through a thin tube and having a distal end connected to the distal end of the catheter; a reinforcing layer that is a coil that covers both the large-diameter resin tube and the operating wire thin tube; An outer layer made of a resin member attached to cover the side surface, and the periphery of the reinforcement layer against the force of the reinforcement layer to loosen at the distal end portion of the reinforcement layer and the proximal end portion of the reinforcement layer Provided with a distal end fixing portion and a proximal end fixing portion made of a resin member that grips the reinforcing layer, and in the region between the distal end fixing portion and the proximal end fixing portion, the outer layer has the reinforcement Radially outward from the layer To have received a biasing force to resiliently biased, the intermediate portion is between the tip and the base end portion, an intermediate fixed portion made of a resin member provided around the reinforcing layer The dimension of the inner diameter of the intermediate fixing portion is a half point between the distal end fixing portion or the proximal end fixing portion and the intermediate fixing portion adjacent to the distal end fixing portion or the proximal end fixing portion. The outer diameter of the reinforcing layer is smaller in the range of 0.5 mm or more and 8 mm or less .

  In the catheter of the present invention, the force of loosening the coil constituting the reinforcing layer is restricted by the proximal end fixing portion and the distal end fixing portion. That is, the coil is fixed by the proximal end fixing portion and the distal end fixing portion while maintaining a winding loosening force. Therefore, the catheter of the present invention can protect the large-diameter resin tube and the small-diameter operation wire thin tube inserted inside the coil without being crushed inward in the radial direction by the coil. Since the operation line tubule is not crushed, the operability of the operation line inserted through the operation line tubule is favorably maintained.

(1a) is a side view of a catheter illustrating the first embodiment of the present invention, and (1b) is a catheter illustrating the first embodiment of the present invention, and the outer layer and the resin embedding part are not shown. FIG. It is sectional drawing which shows the II-II cross section of the catheter shown in FIG. It is sectional drawing which shows the III-III cross section of the catheter shown in FIG. It is sectional drawing which shows the IV-IV cross section of the catheter shown in FIG. (5a) is a partially enlarged explanatory view showing an inner tip coil and an operation line provided at the tip of the catheter according to one embodiment of the present invention, and (5b) is a catheter according to one embodiment of the present invention. It is a conceptual diagram which shows typically the inner side front end coil, outer side front end coil, and operation line which were provided in the front-end | tip part of a wire. (6a) is a cross section of the catheter according to the second embodiment of the present invention, showing a cross section cut at a position corresponding to the IV-IV cross section in FIG. 1, and (6b) is the second cross section. It is the conceptual diagram which decomposed | disassembled the multiple coil which comprises the reinforcement layer in the catheter concerning embodiment into one coil. It is process explanatory drawing explaining the process of the manufacturing method of the catheter concerning 2nd embodiment of this invention, (7a) shows an inner side tip coil formation process, (7b) and (7c) are main body coil part formation. (7d) shows the outer tip coil forming process, (7e) shows the fixing part forming process, the intermediate part forming process and the operation line locking process, and (7f) is the resin embedding part forming process. A process and an outer layer formation process are shown.

Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. In all the drawings, the same components are denoted by the same reference numerals, and redundant description will be appropriately omitted.
In the present embodiment, there are cases where the left and right directions are defined and illustrated as shown. However, this is provided for convenience in order to simply explain the relative relationship of the components, and does not limit the direction during the manufacture or use of the product implementing the present invention.
The various components of the catheter of the present invention do not have to be independent from each other, a plurality of components are formed as a single member, and a single component is formed of a plurality of members. That a certain component is a part of another component, a part of a certain component overlaps a part of another component, and the like.

In the context of the present invention, the proximal end of each elongate component constituting the catheter or the catheter refers to a predetermined length region including the proximal end of the catheter. Similarly, the distal end portion of each of the long components constituting the catheter or the catheter refers to a predetermined length region including the distal end of the catheter.
Moreover, the proximal end of each elongate structure which comprises a catheter or a catheter means the catheter in the operator side of the said catheter, or the edge part of each said structure. The distal end of each of the elongate components constituting the catheter or the catheter means the end opposite to the proximal end, and usually means the tip of the catheter or the operation side of the configuration. .
In describing the present invention, the term inside or outside may be used as appropriate. Unless otherwise specified, the inner side means the side facing the central axis of the catheter, and the outer side means the side not facing the central axis of the catheter.
In the description of the present invention, unless otherwise specified, a cross section means a cut surface cut in a direction perpendicular to the central axis of the catheter.
In the description of the present invention, unless otherwise specified, “axial direction” means the axial direction of the catheter.

<First embodiment>
Below, the main structure of the catheter 100 which is 1st embodiment of the catheter of this invention is demonstrated using FIGS. 1-4.
FIG. 1a is a side view of a catheter 100 illustrating a first embodiment of the present invention. FIG. 1B is a side view of the catheter 100 illustrating the first embodiment of the present invention, in which the outer layer 42 and the resin embedding portion 800 are omitted.
2 to 4 are cross-sectional views showing predetermined cross sections of the catheter 100 shown in FIG. 1b. In the cross section of the coil forming the reinforcing layer 22 shown in the cross sectional view relating to the description of the present invention, a cross section of the linear member constituting the coil is shown. 2 to 4 also show the outer layer 42 not shown in FIG. 1b.

A catheter 100 according to an embodiment of the present invention is a catheter 100 having a lumen 12 therein.
FIG. 2 shows a II-II cross section, which is a cross section in a region where the proximal end fixing portion 11 is provided at the proximal end portion of the catheter 100 shown in FIG. As shown in FIG. 2, the catheter 100 includes a large-diameter resin tube 14, an operation wire thin tube 16, an operation wire 18, a reinforcing layer 22, and an outer layer 42.
The large diameter resin tube 14 forms a large diameter lumen 12. The operation wire tubule 16 is a small-diameter tubular body disposed outside the lumen 12. The operation line 18 is inserted through the operation line capillary 16 and has a distal end connected to the distal end of the catheter 100. The reinforcing layer 22 is a coil that covers both the large-diameter resin tube 14 and the operation wire thin tube 16. The outer layer 42 is composed of a resin member that is attached so as to cover the outer surface of the reinforcing layer 22.
The catheter 100 is provided at the distal end portion of the reinforcing layer 22 and the proximal end portion of the reinforcing layer 22 around the reinforcing layer 22 against the unwinding force of the reinforcing layer 22, whereby the distal end fixing portion 10 that grips the reinforcing layer 22. (Refer FIG. 1) and the base end fixing | fixed part 11. The distal end fixing portion 10 and the proximal end fixing portion 11 are made of a resin member.
The catheter 100 receives an urging force that the outer layer 42 elastically urges radially outward from the coil that is the reinforcing layer 22 in a region between the distal end fixing portion 10 and the proximal end fixing portion 11. Yes.

That is, the coil that forms the reinforcing layer 22 provided on the catheter 100 is disposed on the catheter 100 in a state in which a force of loosening outward in the radial direction is maintained. The coil loosening force is restrained by the distal end fixing portion 10 and the proximal end fixing portion 11, and is restricted from being loosened. In the present invention, the loosening force refers to a force in which a coil formed by spirally winding a linear member in the axial direction attempts to expand the diameter outward in the radial direction. For example, the coil that is constrained in the wound state is loosened by releasing the restraint and autonomously reducing the number of turns to increase the diameter.
The outer layer 42 is attached to the reinforcing layer 22. Here, the term “installation” widely includes a state in which the inner surface of the outer layer 42 is provided so as to be attached to the reinforcing layer 22. The attachment includes a state in which the inner side surface of the outer layer 42 and the outer side surface of the reinforcing layer 22 are adhered, and a state in which the outer layer 42 is separated from the reinforcing layer 22 and is in contact with the outer layer 42 so as to be separated.
As described above, since the coil forming the reinforcing layer 22 retains the force of loosening, the outer layer 42 attached to the reinforcing layer 22 has a biasing force that elastically biases the coil outward in the radial direction. receive. The outer layer 42 is in contact with the outer surface of the reinforcing layer 22 where the distal end fixing portion 10, the proximal end fixing portion 11, and the intermediate fixing portion 24 are not provided, and is biased outward in the radial direction. The biased state can be confirmed by visual observation that the outer layer 42 is stretched.

  As described above, the catheter 100 according to the present embodiment includes the reinforcing layer 22 that is a coil that holds a winding and loosening force. Therefore, the large-diameter resin tube 14 and the operation wire thin tube 16 arranged inside the reinforcing layer 22 are prevented from being given a force that is tightened radially inward by the coil that is the reinforcing layer 22. Therefore, the operability of the operation line 18 inserted through the operation line capillary 16 is not deteriorated by being crushed in the radial direction.

  As shown in FIG. 1 and FIG. 2, an outer layer 42 made of a resin member is attached to the outer surface of the reinforcing layer 22 that is a coil that retains the unwinding force. The outer layer 42 is provided so as to cover the distal end fixing portion 10 and the proximal end fixing portion 11 from the outside. The outer layer 42 receives a biasing force that elastically biases radially outward from the coil in a region between the distal end fixing portion 10 and the proximal end fixing portion 11. Therefore, the outer layer 42 is well maintained in a state of being stretched in the outer direction, is prevented from causing wrinkles and the like, and is not easily damaged.

The distal end fixing portion 10 and the proximal end fixing portion 11 in the catheter 100 will be described.
As shown in FIG. 1B, the tip fixing portion 10 is provided so as to cover the tip portion of the reinforcing layer 22 from the outside. The tip portion of the reinforcing layer 22 means a predetermined length region at the distal end portion of the reinforcing layer 22.
In this embodiment, the distal end of the reinforcing layer 22 extends to the distal end of the catheter 100 or near the distal end, and the tip fixing portion 10 is closer to the proximal side than the distal end of the catheter 100. Is provided. As shown in FIG. 1b, the distal end of the tip fixing portion 10 in the present embodiment is located closer to the proximal side than the maximum bending point X where the bending rate of the catheter tip is maximum. That is, by providing the distal end fixing portion 10 while avoiding the maximum bending point X, the flexible bending operation at the distal end of the catheter 100 is not hindered.
However, it is not limited to this, In the modification of this embodiment which is not illustrated, the distal end fixing portion 10 may be provided at the distal end portion of the catheter 100 including the distal end bending portion.

As shown in FIG. 1B, the base end fixing portion 11 is provided so as to cover the base end portion of the reinforcing layer 22 from the outside. The proximal end portion of the reinforcing layer 22 means a predetermined length region at the proximal end portion of the reinforcing layer 22.
In the present embodiment, the proximal end portion including the proximal end of the reinforcing layer 22 is connected and fixed to the operation line operation portion 810. The proximal end fixing portion 11 in this embodiment has at least a region exposed from the operation line operation portion 810. However, it is not limited to this, The base end fixing | fixed part 11 may be provided in the insertion part of the reinforcement layer 22 inserted by the operation line operation part 810. FIG.

As shown in FIG. 1 b, the reinforcing layer 22 according to the present embodiment includes a main body coil portion 60 that forms the main body of the reinforcing layer 22 and a distal coil portion 62 provided in a region including the distal bent portion of the catheter 100. Yes. In the present embodiment, the distal end fixing portion 10 and the proximal end fixing portion 11 are provided at the proximal end portion and the distal end portion of the main body coil portion 60, respectively.
As a modification of the present embodiment (not shown), the reinforcing layer 22 may be composed of a series of coils from the distal end to the proximal end. In such a modification, the distal end fixing portion 10 and the proximal end fixing portion 11 are respectively provided at the proximal end portion and the distal end portion of the series of coils.

The distal end fixing portion 10 and the base end fixing portion 11 restrain the winding and loosening force of the main body coil portion 60. In other words, in the catheter 100 in which the distal end fixing portion 10 and the proximal end fixing portion 11 are provided, the reinforcing layer 22 (main body coil portion 60) is formed by a coil in which winding looseness is regulated without being annealed.
The main body coil unit 60 in the present embodiment is a long tubular body provided in a main region from the operation line operation unit 810 (FIG. 1 a) of the long catheter 100 to the vicinity of the proximal side of the distal bending portion. is there. The operation line tubule 16 inserted into the long tubular body is prevented from being crushed in the radial direction by the reinforcing layer 22, and the operability of the operation line 18 is good.

The means for fixing the distal end fixing portion 10 and the proximal end fixing portion 11 to the reinforcing layer 22 is not particularly limited as long as the loosening of the coil forming the reinforcing layer 22 can be restrained.
For example, the distal end fixing portion 10 and the proximal end fixing portion 11 in the catheter 100 embed the reinforcing layer 22, the operation wire tubule 16, and the large diameter resin tube 14 with a resin member.

FIG. 2 illustrates the above-described embedding state. The base end fixing portion 11 covers the outer surface of the reinforcing layer 22 and impregnates the outer surface of the large-diameter resin tube 14, thereby embedding the reinforcing layer 22, the operation wire thin tube 16, and the large-diameter resin tube 14. It is formed by. Although not shown, the region where the distal end fixing portion 10 is provided may be embedded with a resin member in the same manner as the proximal end fixing portion 11. As a result, the winding state between the proximal end and the distal end of the coil forming the reinforcing layer 22 is fixed, and the winding looseness of the coil sandwiched between the proximal end and the distal end is restricted. By fixing both the reinforcing layer 22 and the operation line thin tube 16 and the large-diameter resin tube 14 inserted therein with a resin member, the fixed state is solid. However, the above description does not exclude from the present invention an aspect in which the embedded state of the resin member between the distal end fixing portion 10 and the proximal end fixing portion 11 is different.
FIG. 2 shows a mode in which the resin member is filled without a gap from the outer surface of the reinforcing layer 22 to the outer surface of the large-diameter resin tube 14. However, the present invention is not limited to this, and the coil forming the reinforcing layer 22 is not limited thereto. As long as the loosening of the winding is restrained, a gap may be generated at an arbitrary position. Further, the resin member and the large-diameter resin tube 14 or the operation wire thin tube 16 in contact with the resin member may not be completely joined. The large-diameter resin tube 14 or the operation wire thin tube 16 may be peeled from the resin member so as to be operable inside the reinforcing layer 22.

  For example, the base end fixing part 11 embedded with the resin member can be formed as follows. At a predetermined position of the reinforcing layer 22, a thermoplastic resin is disposed around and heated to melt the resin so as to be impregnated from the outside of the reinforcing layer 22 to the outside of the large-diameter resin tube 14, and then cooled. Thereby, the base end fixing | fixed part 11 embedded by the resin member can be formed.

  The thermoplastic resin is not particularly limited. For example, in addition to polyimide (PI), polyamideimide (PAI), polyethylene terephthalate (PET), polyethylene (PE), polyamide (PA), nylon elastomer, polyurethane ( PU), ethylene-vinyl acetate resin (EVA), polyvinyl chloride (PVC), polypropylene (PP), or the like can be used. For example, the resin member is preferably selected from resins having a melting point lower than that of the resin constituting the large-diameter resin tube 14 and the operation wire capillary 16.

  In addition, the formation method of the base end fixing | fixed part 11 mentioned above and the resin member illustrated are applied also to the front end fixing | fixed part 10 suitably.

As shown in FIG. 1 b, the catheter 100 according to the present embodiment is a resin member provided around the reinforcing layer 22 at an intermediate portion between the proximal end portion of the reinforcing layer 22 and the distal end portion of the reinforcing layer 22. An intermediate fixing portion 24 is provided.
The intermediate fixing portion 24 is a fixing portion that resists the outward elastic force in the radial direction of the coil forming the reinforcing layer 22.
In the long catheter 100, by providing the intermediate fixing portion 24 at the intermediate portion, the shape retaining property of the reinforcing layer 22 that holds the unwinding force can be favorably maintained. In particular, when the distance between the distal end fixing portion 10 and the proximal end fixing portion 11 is 1 m or more, it is preferable to provide the intermediate fixing portion 24.

  The intermediate fixing part 24 is provided at one place or a plurality of places. In the catheter 100 according to this embodiment, one intermediate fixing portion 24 is provided in an intermediate region including a half of the longitudinal direction of the main body coil portion 60 constituting the reinforcing layer 22 and a point. In addition, the catheter 100 is provided with an intermediate fixing portion 24 between the intermediate region and the distal end fixing portion 10 and between the intermediate region and the proximal end fixing portion 11 (FIG. 1b). That is, the catheter 100 is provided with the intermediate fixing portions 24 at, for example, three places in total.

FIG. 3 shows a III-III cross section which is a cross section in the region where the intermediate fixing portion 24 of the catheter 100 shown in FIG. 1 is provided. The intermediate fixing part 24 in the present embodiment is a belt-like layer provided so as to cover the outer periphery of the reinforcing layer 22, as understood from FIGS. 1 b and 3, for example .

For example, the inner diameter 715 of the intermediate fixing portion 24 is smaller than the outer diameter 710 (FIG. 4) of the reinforcing layer 22 at a location where the intermediate fixing portion 24, the distal end fixing portion 10 and the proximal end fixing portion 11 are not provided.
4 shows an IV-IV cross section, which is a cross section in a region where the intermediate fixing portion 24, the distal end fixing portion 10 and the proximal end fixing portion 11 of the catheter 100 shown in FIG. 1 are not provided. The IV-IV cross section shows a cut surface formed by cutting a half point between the tip fixing portion 10 and the intermediate fixing portion 24 adjacent thereto.
The difference between the inner diameter 715 of the intermediate fixing portion 24 and the outer diameter 710 of the reinforcing layer 22 at the above point is, for example, several mm or less, and is included in a range from a level that can be confirmed by visual observation to a level that cannot be confirmed by visual observation. For example, the above difference is included in the range of 0.5 mm to 8 mm, and particularly in the range of 0.5 mm to 5 mm.

  In this way, by providing the intermediate fixing portion 24 so as to reduce the outer diameter of the reinforcing layer 22 between the distal end fixing portion 10 and the proximal end fixing portion 11, the inward in the radial direction with respect to the coil forming the reinforcing layer 22. An urging force for urging can be applied. The shape retention of the reinforcing layer 22 between the distal end fixing portion 10 and the proximal end fixing portion 11 is sufficiently achieved.

The resin member constituting the intermediate fixing portion 24 in the present embodiment exists outside the inner surface of the reinforcing layer 22 as shown in FIG. The inner diameter 715 of the intermediate fixing portion 24 is measured in the radial direction of the catheter 100 at predetermined points shown in FIGS. 1b and 4, and the outer diameter 740 of the large diameter resin tube 14, the outer diameter 760 of the operation wire tubule 16, and The sum can be equal to or less than the sum of the thicknesses of the reinforcing layers 22.
The predetermined point is a half point between the distal end fixing portion 10 or the proximal end fixing portion 11 and the intermediate fixing portion 24 adjacent to the distal end fixing portion 10 or the proximal end fixing portion 11. Specifically, for example, as shown in FIG. 1b, the predetermined point is a half point between the tip fixing portion 10 and the intermediate fixing portion 24 adjacent thereto. The cut surface cut | disconnected in the said half point is shown in FIG.

By adjusting the inner diameter 715 of the intermediate fixing portion 24 as described above, the reinforcing layer 22 and the large-diameter resin tube 14 and the operation wire tubule 16 inserted through the reinforcing layer 22 are provided at the location where the intermediate fixing portion 24 is provided. It is possible to press-contact relatively movably. In other words, in the region where the intermediate fixing portion 24 is provided, the operation wire capillary 16 can be sandwiched between the large-diameter resin tube 14 and the reinforcing layer 22 so as to be movable in the circumferential direction of the large-diameter resin tube 14.
Accordingly, when the operation line 18 is not operated and the catheter 100 is in a natural state, the arrangement state of the operation line tubule 16 inside the catheter 100 is stabilized. Further, when the operation line 18 may cause a difference between the path length in the natural state of the operation line 18 and the path length of the operation line 18 in the bent catheter 100, the operation line tubule 16 is a large-diameter resin tube. The difference can be adjusted by moving in the 14 circumferential directions.

Here, the dimension measured in the radial direction of the catheter 100 means a dimension of each component measured in a state where the centers of the large-diameter resin tube 14 and the operation wire capillary 16 are positioned in the radial direction of the catheter 100.
Specifically, the outer diameter 740 of the large diameter resin tube 14 means the outer diameter of the large diameter resin tube 14 having a substantially circular cross section. When the cross-sectional shape of the large-diameter resin tube 14 is other than a circle, it means the outer diameter of the large-diameter resin tube 14 measured in the radial direction described above.
Further, the outer diameter 760 of the operation wire tubule 16 means, for example, an outer diameter measured in the minor axis direction of the operation wire tubule 16 whose cross section has a major axis and a minor axis, a flat shape, an ellipse, or an ellipse. To do. This is because the operation line tubule 16 having a short axis and a long axis in the cross section is usually placed between the reinforcing layer 22 and the large diameter resin tube 14 so that the short axis is arranged in the radial direction of the catheter 100. In the case of the catheter 100 provided with the operation line tubule 16 having a substantially circular cross section (not shown), the outer diameter is an outer diameter of a circle measured in the substantially circular shape.
Further, the thickness of the reinforcing layer 22 means a dimension twice the diameter of the linear member forming the coil when the reinforcing layer 22 is a single coil. When the reinforcing layer 22 is a multiple coil in which a plurality of coil members are overlapped, twice the distance from the inner surface of the innermost coil member to the outer surface of the outermost coil member Is the thickness of the reinforcing layer 22 described above.

For example, as shown in FIG. 3, the intermediate fixing portion 24 in this embodiment is not impregnated beyond the reinforcing layer 22 to the center axis side. In other words, the inner side surface is located outside the inner side surface of the reinforcing layer 22. Although the formation method of this intermediate fixing | fixed part 24 is not specifically limited, For example, it can form as follows.
That is, the intermediate fixing portion 24 can be formed by disposing the heat-shrinkable member around the reinforcing layer 22 in a predetermined region and contracting the heat-shrinkable member radially inward by heating. For example, the resin member may be disposed substantially throughout the circumferential direction of the reinforcing layer 22.
As the heat shrink member, for example, a sheet-like or tube-like heat shrink member made of the same resin as the constituent resin of the base end fixing portion 11 described above can be appropriately selected and used.

  As a modification of the catheter 100 not shown, the resin member constituting the intermediate fixing portion 24 is between the outer side of the reinforcing layer 22 and the outer side surface of the large-diameter resin tube 14 beyond the inner side surface of the reinforcing layer 22. An arbitrary region may be impregnated. The intermediate fixing portion 24 can be formed following the method for forming the distal end fixing portion 10 or the proximal end fixing portion 11 described above.

Hereinafter, the configuration of the catheter 100 will be described in detail.
The catheter 100 includes a long and tubular tubular body 50, a tip portion 52 provided on the distal side of the tubular body 50, an operation line operation unit 810 provided on the proximal side of the tubular body 50, and the proximal side of the catheter 100. A syringe 812 provided on the end side is provided. The tip 52 can be displaced between a bent state and a straight state as indicated by double-ended arrows shown in FIG. 1 by operating the operation line 18 (FIG. 2). The tip portion 52 includes a maximum bending point X portion.
The tubular body 50 has a lumen 12 therein, and is a flexible tubular body that is inserted through a body cavity such as a blood vessel through an endoscope or directly.
The operation line operation unit 810 is an operation part for operating the operation line 18. The catheter 100 according to this embodiment includes a dial-type operation line operation unit 810 including a disk-shaped dial 816. The dial type operation line operation unit 810 has a connection part 818 near an arbitrary periphery of the dial 816, and the proximal end of the operation line 18 is fixed to the connection part 818. The pulling length of the operation line 18 is adjusted by rotating the dial 816 with respect to the central axis of the disk, whereby the operation line 18 can be operated. However, in the present invention, instead of the dial method, an operation line operation unit of another operation method can be appropriately selected and provided.

  The syringe 812 is an injection site for processing a chemical solution or the like through the lumen 12 to a desired location in the body cavity. Inside the operation line operation unit 810, there is a lumen (not shown) extending in the extending direction of the catheter 100. The lumen 12 and the syringe 812 communicate with each other through the lumen, and the medicine introduced from the syringe 812 flows through the lumen and the lumen 12 to the distal end opening 32 of the catheter 100 and can be released into the body cavity. . As a modification of the present embodiment, a medical instrument such as a microcatheter including a guide wire may be inserted into the lumen 12 instead of the syringe 812.

  The large-diameter resin pipe 14 is a resin tubular member having a lumen 12 communicating with the inside. It is preferred that at least the tubular body 50 extends from the proximal end to the distal end of the tubular body 50. The material of the large diameter resin tube 14 is not particularly limited, and for example, a fluorine-based thermoplastic polymer can be used. More specifically, polytetrafluoroethylene (PTFE), polyvinylidene fluoride (PVDF), perfluoroalkoxy fluororesin (PFA), or the like can be used. As described above, by using a fluorine-based resin for the large-diameter resin tube 14, the delivery property when supplying a contrast medium or a drug solution to the affected area through the lumen 12 of the catheter 100 is improved.

  The small-diameter operation line thin tube 16 is a resin tubular member through which the operation line 18 is inserted. It is preferred that at least the tubular body 50 extends from the proximal end to the distal end of the tubular body 50. When terminating at a position proximal to the maximum bending point X of the manipulation wire tubule 16, the manipulation line 18 is exposed from the distal end of the manipulation wire tubule 16 and beyond the maximum bending point X, the distal end of the catheter 100. Extends to the end. In the present invention, the “large diameter” in the large-diameter resin tube 14 and the “small diameter” in the small-diameter operation line capillary 16 compare the inner diameter of the large-diameter resin tube 14 and the inner diameter of the operation line capillary 16, and Represents a magnitude relationship. That is, the inner diameter of the large-diameter resin tube 14 is larger than the inner diameter of the operation wire thin tube 16. In general, the outer diameter of the large-diameter resin tube 14 is larger than the outer diameter of the operation wire thin tube 16.

The material of the operation wire tubule 16 is, for example, polyether ether ketone (PEEK), polysulfone (PSF), polytetrafluoroethylene (PTFE) from the viewpoint of slidability in the sliding direction of the operation wire tubule 16 inserted inside. , Fluorine polymer materials such as polyvinylidene fluoride (PVDF) can be suitably used.
From the viewpoint of smooth movement of the operation line thin tube 16 with respect to the outer peripheral direction of the large-diameter resin tube 14, a material capable of reducing friction with the large-diameter resin tube 14 can be selected. From this point of view, for example, the material of the operation wire tubule 16 and the material of the large diameter resin tube 14 may be different. More specifically, one preferable combination is to select a fluorine-based resin such as PTFE as the material of the large-diameter resin tube 14 and to select PEEK as the material of the operation wire capillary 16. However, the above description does not exclude that the material of the operation wire thin tube 16 and the material of the large diameter resin tube 14 are the same.

The operation line 18 is a member for performing an operation for bending the distal end of the catheter 100. The distal end portion of the operation line 18 is fixed to the distal end portion of the catheter 100, and the proximal end portion is fixed to the connection portion 818 in the dial 816. The operation line 18 is inserted into a communication hole formed inside the operation line capillary 16 so as to be slidable. Therefore, when the operation line thin tube 16 moves in the outer peripheral direction of the large diameter resin tube 14, the operation line 18 also moves in the outer peripheral direction of the large diameter resin tube 14 together with the operation line thin tube 16.
The distal end portion and the proximal end portion of the operation line 18 may protrude from the end portion of the operation line capillary 16, respectively.

  The material of the operation line 18 is not particularly limited. For example, PEEK, polyphenylene sulfide (PPS), polybutylene terephthalate (PBT), polymer fiber such as PI or PTFE, or SUS, corrosion-resistant coated steel wire. A metal wire such as titanium or a titanium alloy can be used.

  As shown in FIG. 2, the cross-sectional inner diameter of the operating wire capillary 16 in the present embodiment has a major axis and a minor axis. For example, the shape including the cross-sectional inner diameter of the operation wire capillary 16 is an ellipse, an ellipse, a rectangle, or the like. Further, the outer diameter of the cross section of the operation wire capillary 16 in this embodiment has a major axis and a minor axis. The major axis of the sectional inner diameter and the major axis of the sectional outer diameter, and the minor axis of the sectional inner diameter and the minor axis of the sectional outer diameter extend in substantially the same direction.

The shape of the operation line 18 used in the present invention is not particularly limited as long as it is inserted into the operation line capillary 16 and the distal end of the catheter 100 can be operated to be bendable, and is arbitrarily determined. The operation line 18 in the present embodiment is a flat wire (see FIG. 2). A flat wire is a long member having a cross-sectional shape including a major axis and a minor axis. The cross-sectional shape may be a rectangle as shown in FIG. 2, or may be an ellipse or an ellipse.
When the operation line 18 is a flat wire, and the cross-sectional inner diameter of the operation line capillary 16 has a major axis and a minor axis, the state of the inserted operation line 18 is stable, and the operation line 18 is operated. Operation is stable at times.

Next, the reinforcing layer 22 will be described. The catheter 100 has a reinforcing layer 22 that covers both the large-diameter resin tube 14 and the operation wire tubule 16.
The reinforcing layer 22 is a layer for reinforcing the tubular main body 50 of the catheter 100 and is a layer for enclosing the large-diameter resin tube 14 and the operation wire thin tube 16 in one space.
For example, as shown in FIG. 4, in a region that does not have the distal end fixing portion 10, the proximal end fixing portion 11, and the intermediate fixing portion 24, the large-diameter resin tube 14 and the operation wire thin tube 16 are released inside the reinforcing layer 22. May be arranged. In other words, the reinforcing layer 22 and the large-diameter resin tube 14 are separated from each other so that they can be separated from each other, and the operation wire thin tube 16 may be loosely inserted between the reinforcing layer 22 and the large-diameter resin tube 14. . According to such an arrangement, the operation wire tubule 16 can move in the circumferential direction of the large-diameter resin tube 14. That the reinforcing layer 22 and the large-diameter resin tube 14 are separated means that they are disposed so as to be substantially separated from each other. Further, the operation wire tubule 16 is loosely inserted between the reinforcing layer 22 and the large diameter resin tube 14. The operation wire tubule 16 is inserted without being coupled to the large diameter resin tube 14 and the reinforcement layer 22. Means that Such bonding includes chemical bonding or adhesion and physical fixation.

  The coil forming the reinforcing layer 22 has a single cylindrical shape as a whole. For example, the coil forming the reinforcing layer 22 is formed by winding a linear member in a spiral shape in the axial direction. The coil is wound so that the edges of adjacent metal wires (that is, loops) abut or overlap each other, or the coil is wound so that the edges of adjacent metal wires are separated from each other. It can be any or a combination of windings. The coil has a tube shape, for example.

Examples of the linear member forming the coil that forms the reinforcing layer 22 include a metal wire. By selecting a metal wire as the constituent material of the reinforcing layer 22, it is possible to sufficiently maintain the force of loosening the coil wound in the axial direction.
As the metal material constituting the metal wire, in addition to fine metal wires such as stainless steel (SUS) and nickel titanium alloy, fine wires of polymer fibers such as polyimide (PI), polyamideimide (PAI) or polyethylene terephthalate (PET) are used. be able to. The cross-sectional shape of the metal wire is not particularly limited, and may be a circle, an ellipse, a square, a rectangle, a polygon, or the like. In this embodiment, a thin wire with a circular cross section or a flat plug wire with a flat cross section is preferably used. Can do.

  The reinforcing layer 22 may be a coil formed by winding a single linear member, or may be a multi-strand coil formed by multiple winding using two or more linear members. Specifically, the main body coil portion 60 constituting the reinforcing layer 22 in the present embodiment is a three-strand coil formed by winding three linear members to substantially the same diameter as shown in FIG. FIG. 2 shows a cross section of three linear members in the cross section of the reinforcing layer 22.

  The reinforcing layer 22 may be composed of a single coil composed of one coil, or may be composed of a multiple coil in which two or more coils overlap in the radial direction. Specifically, the main body coil portion 60 constituting the reinforcing layer 22 in the present embodiment is composed of a single coil as shown in FIG. An example of the reinforcing layer 22 made of multiple coils is shown as a second embodiment to be described later.

  The reinforcing layer 22 in the present embodiment has a main body coil portion 60 and a tip coil portion 62 which are separate members. The reinforcing layer 22 having one cylindrical shape is configured by connecting the distal end portion of the main body coil portion 60 and the proximal end portion of the tip coil portion 62. However, the coil forming the reinforcing layer 22 can be appropriately changed to a coil that is one member continuous from the distal end to the proximal end.

  For example, as shown in FIG. 5, the tip coil portion 62 in the present embodiment can be constituted by multiple coils. FIG. 5A is a partially enlarged explanatory view showing the inner distal end coil 62A and the operation line 18 provided at the distal end portion of the catheter 100 according to the present embodiment. FIG. 5 b is a partially enlarged explanatory view showing the inner tip coil 62 </ b> A, the outer tip coil 62 </ b> B, and the operation line 18 provided at the tip portion of the catheter 100 according to the present embodiment. In FIG. 5b, each loop of 62A is not shown.

The distal coil portion 62 has an inner distal coil 62A (FIG. 5a) provided on the central axis side of the catheter 100 and an outer distal coil 62B (FIG. 5b) provided outside the inner distal coil 62A. Yes. Between the inner tip coil 62 </ b> A and the outer tip coil 62 </ b> B, an operation line 18 that extends further distally from the distal end of the operation wire capillary 16 is disposed.
By arranging the operation line 18 between the inner tip coil 62A and the outer tip coil 62B, the operation line 18 enters the lumen 12, and the operation line 18 protrudes to the outside of the catheter 100, that is, to the body cavity side. It is prevented.

In the present embodiment, the linear members constituting the inner tip coil 62A and the outer tip coil 62B are wound in the same spiral direction.
The diameters of the linear members constituting the inner tip coil 62A and the outer tip coil 62B may be the same or different. For example, the diameter of the inner tip coil 62A is set to the outer tip coil 62B. It can be made smaller than the diameter of the coil.
The pitches of the coils constituting the inner tip coil 62A and the outer tip coil 62B may be the same or different. For example, as shown in FIGS. 5a and 5b, the pitch of the outer tip coil 62B can be made larger than the pitch of the inner tip coil 62A.

More specifically, for example, the inner tip coil 62A is formed in a substantially tube shape by winding the linear member in a state close to or close to the close winding, and the inner tip coil 62A is formed in the proximal direction toward the distal end. The outline of the tip hole 725 (FIG. 5a) to be inserted may be clarified. The tip hole 752 communicates from the distal end of the lumen 12 provided inside the large-diameter resin tube 14 to the distal end opening 32 and substantially extends the lumen 12 to the distal end opening 32. As a result, the drug distribution in the lumen 12 and the insertion property of medical instruments such as a guide wire can be improved.
Alternatively, the outer tip coil 62B may be configured by pitch winding using a linear member having a relatively large diameter with respect to the inner tip coil 62A. As a result, the outer tip coil 62B having a larger cross-sectional diameter than the inner tip coil 62A can be relatively flexible. For example, a flat wire having a width larger than the diameter of the inner tip coil 62A may be used as the thick-line member, but is not limited thereto.

As shown in FIG. 5b, the distal end of the operation line 18 is provided with a folded portion 38 formed by folding the surplus portion 38A (FIG. 5a) extending distally from the distal end of the reinforcing layer 22 to the proximal side. . By providing the folded portion 38, the operation line 18 is locked to the distal end of the reinforcing layer 22. As a result, the operation line 18 is locked to the distal end portion of the catheter 100.
The tip of the folded portion 38 has an intrusion portion 38B that is inserted from the outside to the inside of the reinforcing layer 22, as shown in FIG. 5b. This ensures the locking of the operation line 18 to the reinforcing layer 22 and prevents the distal end of the operation line 18 from protruding toward the body cavity. For example, the intrusion portion 38B extends over two or more loops inside the coil forming the reinforcing layer 22 from the distal side toward the proximal side.
In the present embodiment, the intrusion portion 38B enters from the outside of the outer tip coil 62B and is disposed between the outer tip coil 62B and the inner tip coil 62A.

Next, the resin embedding unit 800 will be described. A distal end portion of the catheter 100 is provided with a resin embedding portion 800 in which a resin member is impregnated in the axial direction from the outer periphery as shown in FIG. 1a. The resin embedding unit 800 may be impregnated with a resin member from the outer periphery to at least an intermediate position in the thickness direction of the reinforcing layer 22.
For example, the reinforcing layer 22 that is the tip coil portion 62 may be impregnated with a resin member so as to reach the inner tip coil 62A from the outer surface of the outer tip coil 62B. Accordingly, the outer tip coil 62B and the operation wire 18 are embedded by the resin member, and the outer tip coil 62B, the operation wire 18 and the inner tip coil 62A can be integrally held by the resin member. By providing the resin embedding part 800, the rigidity of the distal end of the catheter 100 can be increased moderately, and the safety can be improved by embedding the metal member at the distal end of the catheter 100 entering the body cavity with the resin. it can.
From the viewpoint of improving safety, a resin-made tip cap 820 may be attached to the tip of the catheter 100 that is distal to the resin embedding part 800 as shown in FIG.

  The resin material for forming the resin embedding part 800 may be a material made only of a resin, or a material obtained by adding an arbitrary additive to a resin. As the resin material constituting the resin embedding part 800, the same resin as the constituent resin of the base end fixing part 11 described above can be used.

Next, the outer layer 42 will be described.
The catheter 100 has an outer layer 42 that covers the reinforcing layer 22. The outer layer 42 is a film-like layer composed of a resin member attached so as to cover the outer surface of the reinforcing layer 22. The outer layer 42 in this embodiment constitutes the outermost layer of the catheter 100. By providing the outer layer 42, the coil forming the reinforcing layer 22 is prevented from coming into direct contact with the body cavity, so that the body cavity is protected.

In the catheter 100 according to this embodiment, the resin member constituting the outer layer 42 does not reach the inner surface of the reinforcing layer 22 as shown in FIGS. The outer layer 42 is in contact with the outer surface of the reinforcing layer 22, and the resin member may partially enter the middle of the thickness direction of the coil constituting the reinforcing layer 22.
In the present embodiment, the outer layer 42 is not embedded so that the resin member covers the linear member constituting the reinforcing layer 22 up to the inner surface. Therefore, the load on the outer layer 42 received from the operation of the reinforcing layer 22 is small, and the outer layer 42 is not easily damaged when the catheter 100 is bent.

The outer layer 42 in the present embodiment covers the tip fixing portion 10 and terminates on the proximal side of the distal end of the catheter 100. As shown in FIG. 1 a, a resin embedding portion 800 is provided on the distal side of the distal end of the outer layer 42. The distal end portion of the outer layer 42 may be formed by riding on the proximal end portion of the resin embedding portion 800, or may end up before reaching the resin embedding portion 800 by riding up to an intermediate region of the tip fixing portion 10. May be. Further, the distal end of the outer layer 42 and the proximal end of the resin embedding part 800 may be substantially in contact with each other.
The proximal end portion of the outer layer 42 covers the proximal end fixing portion 11.

The method for forming the outer layer 42 is not particularly limited. For example, the outer layer 42 can be formed by disposing a heat-shrinkable material such as a tube or sheet around the reinforcing layer 22 and heat-shrinking the heat-shrinkable material by heating from the outer periphery. .
For example, the heat-shrinkable member is disposed in contact with the circumferential direction of the reinforcing layer 22 and is heated in this state, whereby the heat-shrinkable member is contracted so that the reinforcing layer 22 is tightened inward in the radial direction. It is good to form. As a result, the coil which is the reinforcing layer 22 holding the unwinding force biases the outer layer 42 outward. The outer layer 42 is provided on the catheter 100 while being stretched outward.
As the resin material constituting the outer layer 42, the same resin as the constituent resin of the base end fixing portion 11 described above can be used.

As described above, the resin member forming the distal end fixing portion 10 and the base end fixing portion 11, the resin member forming the intermediate fixing portion 24, and the resin member forming the outer layer 42 are all resin materials made of the same thermoplastic resin. Can be used.
However, in forming these plural configurations, the resin member used need not be limited to the same resin.
For example, as an example, by appropriately selecting a resin member, the melting point of the resin member forming the distal end fixing portion 10 or the base end fixing portion 11 can be made equal to or lower than the melting point of the resin member forming the outer layer 42. Thus, at least the outer surface of the distal end fixing portion 10 or the proximal end fixing portion 11 is melted by heat treatment during the formation of the outer layer 42, and the outer layer 42 and the distal end fixing portion 10 or the proximal end fixing portion 11 are joined. Is possible. That is, the outer layer 42 can be joined to the reinforcing layer 22 via the distal end fixing portion 10 or the proximal end fixing portion 11.
As another example, the melting point of the resin member forming the intermediate fixing part 24 may exceed the melting point of the resin member forming the outer layer 42 by appropriately selecting the resin member. Accordingly, it is possible to avoid joining the outer layer 42 and the intermediate fixing portion 24 by melting each other even by the heat treatment at the time of forming the outer layer 42. That is, the outer layer 42 is not joined to the reinforcing layer 22 via the intermediate fixing portion 24 in the intermediate region of the catheter 100.

<Second embodiment>
Next, the catheter 110 which is 2nd embodiment of this invention is demonstrated using FIG. The catheter 110 is configured in the same manner as the catheter 100 except that the main body coil unit 60 is configured by multiple coils. Therefore, regarding the configuration other than the main body coil unit 60, the description of the first embodiment is appropriately referred to, and the description here is omitted.
FIG. 6 a is a cross-sectional view of the catheter 110. Specifically, the cross section shown in FIG. 6 is a cross section of the main body coil portion 60 in which the distal end fixing portion 10, the base end fixing portion 11, and the intermediate fixing portion 24 are not provided, and is the same as the IV-IV cross section shown in FIG. A cross section cut at a position is shown. FIG. 6B is a conceptual diagram showing the three coils constituting the triple coil layer constituting the reinforcing layer 22 shown in FIG. In FIG. 6b, the outer diameter a, the outer diameter b, and the outer diameter c, which are the outer diameters of the three coils, have a relationship of outer diameter a <outer diameter b <outer diameter c.

The catheter 110 has a reinforcing layer 22 that is a multi-coil layer in which two or more coils overlap in the radial direction. The winding direction of at least one coil in the multiple coil layer is different from the winding direction of the other coils.
Note that the coil winding directions differ from each other when the coil loop of one coil in the multi-coil layer is tilted in the range of more than 0 ° and less than 90 ° with respect to the axial center of the catheter 110 when viewed from the side. Means that the loop is inclined in the range of more than 90 ° and less than 180 °. The understanding of the difference in coil winding direction described above is common throughout the description of the present invention unless otherwise specified.

Thus, the reinforcement strength of the reinforcement layer 22 improves by changing the winding direction of each coil which comprises a multiplex coil. Further, since the loop in one coil and the loop in the other coil cross each other, it is possible to avoid the operation wire tubule 16 that is formed as an inner layer projecting outward from the gap between the loops and breaking through the outer layer 42. The multiple coil layer may be provided in the whole or at least the main body coil portion 60 of the reinforcing layer 22.
In addition, description of the multiple coil layer demonstrated in this embodiment does not exclude that the whole or one part of the reinforcement layer 22 is provided with the multiple coil which has the same winding direction in the catheter of this invention.

In the multi-coil layer in the catheter 110, it is one preferred example of the present embodiment that the coil loosening force of the outermost coil is larger than the coil loosening force of the coil located on the most axial side. is there.
Due to the large winding and loosening force of the coil located on the outermost side, the urging force for urging radially outward can be sufficiently applied to the outer layer 42 attached to the reinforcing layer 22.

A comparison of the coil loosening force of each coil in the multiplex coil can be performed as follows, for example.
In the catheter 110, the outer diameter of each coil is measured at a half point between the distal end fixing portion 10 or the proximal end fixing portion 11 and the intermediate fixing portion 24 adjacent to the distal end fixing portion 10 or the proximal end fixing portion 11. Thus, the outer diameter is obtained when fixed. The said point is a point shown by the IV-IV cross section shown, for example in FIG. Next, the distal end fixing portion 10 or the base end fixing portion 11 and the intermediate fixing portion 24 located on both sides of the point are removed to release the fixed state of the coils, and each coil is autonomously wound and loosened. After that, the outer diameter of each coil that has been loosened is measured to obtain the outer diameter dimension at the time of unlocking. Calculate the difference obtained by subtracting the fixed outer diameter from the fixed fixed outer diameter in each coil. It can be determined that the greater the calculated difference, the greater the winding loosening force.
In particular, it can also be determined that the larger the ratio of the outer diameter dimension at the time of unlocking to the outer diameter dimension at the time of fixing, the greater the winding loosening force.

For example, in the catheter 110 according to this embodiment, the reinforcing layer 22 can be formed of a triple coil layer as shown in FIG. 6a. In particular, the main body coil unit 60 can be constituted by a triple coil.
That is, in the present embodiment, the multiple coil layer is a triple coil layer having three coils that are the inner coil 60A, the intermediate coil 60B, and the outer coil 60C from the central axis side of the catheter 110.
As shown in FIG. 6b, the winding direction of the intermediate coil 60B is different from the winding direction of the inner coil 60A and the winding direction of the outer coil 60C.

  By providing the intermediate coil 60B having different winding directions in the intermediate layer of the triple coil layer, it is possible to prevent the loops of the three coils from overlapping. The loop of the inner coil 60A and the outer coil 60C and the loop of the intermediate coil 60B cross in a side view.

Any two or more or all of the coils forming the multiple coil layer may have the same or different pitch. For example, the pitch of the outer coil 60C and the pitch of the inner coil 60A may be substantially equal, and the pitch of the intermediate coil 60B may be larger than the pitch of the inner coil 60A and the outer coil 60C. The pitch here refers to the apparent pitch of each coil, and refers to the distance between adjacent loops in the axial direction, regardless of whether they are multiple or single.
Each coil constituting the multiple coil layer may be closely wound or pitch-wound. Since the outer coil 60 </ b> C forms an outer layer of the reinforcing layer 22, the outer shape of the reinforcing layer 22 can be established by close winding. Since the outer coil 60 </ b> C is closely wound, it is possible to stabilize the attachment state of the outer layer 42 attached to the reinforcing layer 22.

Each coil constituting the multiple coil layer may be a multi-strip coil or a single-strip coil.
For example, in the triple coil described above, the inner coil 60A and the outer coil 60C may be multi-strip coils composed of a plurality of linear members that are larger than the number of linear members forming the intermediate coil 60B.
More specifically, for example, as shown in FIG. 6a, the reinforcing layer 22 (main body coil portion 60) of the catheter 110 is composed of an inner coil 60A that is a triple coil, an intermediate coil 60B that is a single coil, and a triple coil. A certain outer coil 60C.

<Third embodiment>
Next, a third embodiment which is an example of a method for manufacturing a catheter of the present invention (hereinafter also referred to as “the manufacturing method”) will be described.
The method for manufacturing a catheter of the present invention makes it possible to use a coil that retains the unwinding force as a reinforcing layer of the catheter, and thus easily manufactures the catheter of the present invention.
This manufacturing method includes a reinforcing layer forming step, a fixing portion forming step, and an outer layer forming step. Further, other steps are performed as appropriate.
The reinforcing layer forming step forms the reinforcing layer 22 made of a coil by winding a linear member around an arbitrary core member 700 in a spiral shape. The reinforcing layer 22 has the large-diameter resin tube 14 and the operation wire thin tube 16 inserted therein.
In the fixing portion forming step, the distal end fixing portion 10 and the proximal end that fix the coil against the force of elastic winding and loosening outward in the radial direction of the coil at the proximal end portion and the distal end portion of the coil forming the reinforcing layer 22 The fixing part 11 is formed of a resin member.
In the outer layer forming step, the heat shrinkable member is arranged around the reinforcing layer 22 having the above-described unwinding force, and the heat shrinkable member is heat shrunk by heating the heat shrinkable member and is attached to the outer surface of the reinforcing layer 22. As a result, the outer layer 42 is formed.
In addition, when forming a coil with a linear member in this manufacturing method, when forming a single-strip coil with one linear member, and forming a multi-strip coil with a plurality of linear members And may be selected as appropriate.

According to this manufacturing method, the reinforcing layer 22 made of a coil that retains the unwinding force can be provided on the catheter 110 by performing the reinforcing layer forming step and the fixing portion forming step.
Moreover, the outer layer 42 which receives the urging | biasing force elastically urged | biased to radial direction outward from the coil which makes the reinforcement layer 22 can be formed by implementing an outer layer formation process as a post process of a reinforcement layer formation process.
The outer layer forming step can be performed after the reinforcing layer forming step and before or after the fixing portion forming step. When the outer layer forming step is performed before the fixing portion forming step, the reinforcing layer formed in the reinforcing layer forming step is temporarily fixed so that the winding looseness is maintained within a desired range.

An example of a method for manufacturing the catheter 110 will be described in detail with reference to FIGS. 7a to 7f. 7a to 7f show the steps essential to the manufacturing method and the steps that are optionally performed.
The reinforcing layer forming step in the present embodiment includes a main body coil portion forming step and a tip coil portion forming step. The tip coil portion forming step includes an inner tip coil forming step and an outer tip coil forming step. For example, the main body coil portion forming step may be performed between the inner front end coil forming and fixing and the outer front end coil forming step.

First, as shown in FIG. 7a, a large-diameter resin tube 14 is prepared in which a core material 700 is inserted and the core material 700 is exposed and extended from at least one end. The arbitrary core material used in the present embodiment is the large-diameter resin tube 14 through which the core material 700 is inserted. When the large-diameter resin tube 14 has sufficient rigidity for winding the linear member, the large-diameter resin tube 14 that does not pass through the core material 700 may be used as an arbitrary core material.
As the tip coil portion forming and fixing, first, an inner tip coil forming step is performed. That is, the linear member is wound around the core member 700 exposed from the large-diameter resin tube 14 to form the inner tip coil 62A. At this time, as shown in FIG. 7 a, the linear member is wound between the exposed core member 700 and the distal end portion of the large-diameter resin tube 14, and is wound around the distal end portion of the large-diameter resin tube 14. The inner tip coil 62A that rides may be formed. Although not shown in the drawing, the coil is temporarily fixed with a clamp or the like while holding the loosened winding until the coil formed by winding the linear member in each manufacturing process is finally fixed. Good.

  In the core material 700 used in the present embodiment, the exposed end portion is gradually reduced in diameter toward the tip end. Thereby, the diameter of the distal end portion of the tip coil portion 62 is reduced toward the distal end by winding the linear member along the inclined surface of the end portion. As a modification, a cylindrical core member having a uniform outer diameter may be used, and the diameter of the lumen communicating with the inside of the formed catheter may be made substantially constant.

Next, the main body coil portion forming step is shown in FIGS. 7b and 7c. A first linear shape is formed so as to cover both the large-diameter resin tube 14 and the operation wire thin tube 16 in which the core material 700 is exposed and extends from at least one end portion (the end portion on the left side of the drawing) through which the core material 700 is inserted. A main body coil forming step of forming the main body coil portion 60 by winding the member in a spiral shape is performed.
The 1st linear member here means the linear member for forming the main body coil part 60, and the case where it is one and the case where it is multiple is included.

  For example, the main body coil portion forming step in the reinforcing layer forming step may be a step of forming multiple coil layers by forming a plurality of coils having different winding directions as the main body coil portion 60. That is, a linear member is wound around the core member 700 in one direction to form a first coil, and a different linear member is wound around the outer periphery of the first coil from the winding direction of the first coil. A second coil is formed by winding in a direction.

Specifically, first, as shown in FIG. 7 b, a linear member is wound around the outer periphery of the large-diameter resin tube 14 and the operation wire thin tube 16 to form the inner coil 60 </ b> A. For example, three linear members are used to form a triple coil as the inner coil 60A. By winding the linear member in a direction different from the winding direction of the inner tip coil 62A, the winding direction of the inner tip coil 62A and the winding direction of the inner coil 60A are made different. The distal end of the inner coil 60A rides on the proximal end of the inner tip coil 62A and terminates. Thus, the inner coil 60A and the inner tip coil 62A are connected (first series connection step).
Next, a linear member is wound around the outer periphery of the inner coil 60A opposite to the winding direction of the inner coil 60A to form the intermediate coil 60B. For example, a single coil is formed as the intermediate coil 60B using a single linear member. Although not shown, the intermediate coil 60B is terminated at a position substantially equivalent to the distal end portion of the inner coil 60A.

After the formation of the intermediate coil 60B, as shown in FIG. 7c, a linear member is wound around the outer periphery of the intermediate coil 60B opposite to the winding direction of the intermediate coil 60B to form the outer coil 60C. For example, three linear members are used to form a triple coil as the outer coil 60C. The outer coil 60C is terminated at substantially the same position as the distal end portions of the inner coil 60A and the intermediate coil 60B to form the main body coil portion 60.
In the present embodiment, the operation wire 18 is inserted into the operation wire tubule 16 before the main body coil portion forming step, during the main body coil portion forming step, or after the main body coil portion forming step.

For example, in the main body coil portion forming step in the reinforcing layer forming step described above, the check tension of each coil in the multiple coil layer may be made different. Specifically, the check tension for the linear member constituting the first coil (inner coil) is made larger than the check tension for the linear member constituting the second coil (outer coil). Thereby, the unwinding force of the second coil (outer coil) may be larger than the unwinding force of the first coil (inner coil). The magnitude of the unwinding force is the same as the unwinding force described in the catheter 100 described above.
More specifically, for example, the tension of the intermediate coil 60B or the outer coil 60C may be larger than the tension of the inner coil 60A. Or you may make the check tension of the outer side coil 60C larger than the check tension of the intermediate coil 60B.
Here, the check tension means an additional stress applied to the linear member in order to press the linear member against a predetermined core member in the winding direction to form a curl when forming the coil. That is, the check tension is a force per unit area that is applied to the linear member in order to apply a winding rod.

Next, the outer tip coil forming process will be described with reference to FIG.
The outer tip coil forming step is performed after the inner tip coil forming step. In the outer tip coil forming step, a second linear member that is a second coil is spirally wound so as to cover both the inner tip coil 62A and the exposed operation wire 18 to form the outer tip coil 62B. A tip coil portion 62 is formed by the inner tip coil 62A and the outer tip coil 62B.

  Note that the operation line 18 is exposed from the distal end of the operation wire capillary 16 before or during the outer tip coil forming step. By forming the outer tip coil 62B so as to cover both the inner tip coil 62A and the exposed manipulation line 18, the manipulation line 18 can be disposed between the inner tip coil 62A and the outer tip coil 62B. Further, the surplus portion 38A is secured by extending the operation line 18 sandwiched between the inner tip coil 62A and the outer tip coil 62B from the tip side of the inner tip coil 62A and the outer tip coil 62B.

The reinforcing layer 22 is formed by connecting the distal end portion of the main body coil portion 60 and the proximal end portion of the tip coil portion 62 to form the connecting region, and the reinforcing layer forming step is completed.
Specifically, in addition to the above-described first connecting step, the proximal end portion of the outer tip coil 62B is connected to the distal end portion of the main body coil portion 60 (second connecting step). The tip coil portion 62 is connected.
The second connecting step can be performed, for example, by inserting the proximal end portion of the outer tip coil 62B between the inner coil 60A and the intermediate coil 60B or between the intermediate coil 60B and the outer coil 60C. . Alternatively, the second connecting step may be performed by entwining the end of the coil at the proximal end of the outer tip coil 62 </ b> B with the end of the coil at the distal end of the main body coil 60.
As described above, the reinforcing layer forming step including the tip coil portion forming step and the main body coil portion forming step is performed. As a result, the reinforcing layer 22 and the operation line 18 inserted through the reinforcing layer 22 from the distal end portion (the end portion on the left side of the drawing) of the large-diameter resin tube 14 and the operation wire thin tube 16 to the distal side. Can be extended.

Next, the fixing part forming step and the operation line locking step will be described with reference to FIG.
In the fixing portion forming step, the distal end fixing portion 10 and the proximal end that fix the coil against the force of elastic winding and loosening outward in the radial direction of the coil at the proximal end portion and the distal end portion of the coil forming the reinforcing layer 22 The fixing part 11 is formed of a resin member. FIG. 7 e shows a state in which the distal end fixing portion 10 is formed at the distal end portion of the main body coil portion 60 constituting the reinforcing layer 22, and the proximal end fixing portion 11 is not shown. Since the coil part formation process can refer suitably the description regarding formation of the base end fixing | fixed part 11 demonstrated in 1st embodiment, detailed description is omitted here.

In this manufacturing method, in addition to the fixing part forming step, an intermediate fixing part forming step is further performed.
The intermediate fixing portion forming step resists the force of winding the coil outward in the radial direction at the intermediate portion of the coil forming the reinforcing layer 22 in which the large-diameter resin tube 14 and the operation wire thin tube 16 are inserted. Thus, the intermediate fixing portion 24 for fixing the coil is formed of a resin member.

In the intermediate fixing portion forming step, the heat shrinkable member may be arranged in the circumferential direction in the intermediate portion of the coil forming the reinforcing layer 22, and the inner diameter 715 (FIG. 3) in the intermediate fixing portion 24 after formation may be adjusted as follows. . In other words, the heat shrinkable member may be heat shrunk by heating from the outside of the heat shrinkable member so that the inner diameter 715 of the intermediate fixing portion 24 is equal to or less than the sum of the dimensions of the predetermined portions. The sum of the dimensions of the predetermined locations is the outer diameter 740 of the large diameter resin tube 14 measured in the radial direction of the catheter 110 at a half point between the proximal end fixing portion 11 and the formed intermediate fixing portion. (FIG. 4), the outer diameter 760 (FIG. 4) of the operation wire tubule 16, and the sum of the thicknesses of the reinforcing layers.
Since the description regarding the adjustment of the inner diameter 715 in the intermediate fixing portion 24 and the intermediate portion forming step can refer to the description of the intermediate fixing portion 24 in the first embodiment as appropriate, the detailed description is omitted here.

Next, the operation line locking step will be described.
In the operation line locking step, as described above, the operation line 18 extending between the inner tip coil 62A and the outer tip coil 62B is extended further to the distal side than the distal end of the tip coil portion 62, so that the operation line is retained. A portion 38A is provided (eg, FIG. 7b). Then, as shown in FIG. 7e, the surplus portion 38A is folded back to the proximal end side of the catheter 110 to form the folded portion 38. The intrusion portion 38B is formed by intruding the tip of the folded portion 38 from the outside to the inside of the outer tip coil 62B.
Thereby, the operation line 18 is locked to the distal end portion of the catheter 110.

Next, a resin embedding portion forming step for forming the resin embedding portion 800 and an outer layer forming step for forming the outer layer 42 are performed using FIG.
The resin embedding step is a step of embedding with a resin member from the outer side surface to the inner side surface of the tip coil portion 62.
For example, by impregnating a resin member from the outer surface of the outer tip coil 62B constituting the tip coil portion 62 to the inner tip coil 62A, the outer tip coil 62B, the operation wire 18 and the inner tip coil 62A are integrated. The resin embedding part 800 to be fixed to is formed.
Since the resin embedding part forming step can refer to the explanation regarding the formation of the resin embedding part 800 in the first embodiment as appropriate, the detailed explanation is omitted here.

The outer layer forming step is a step of forming the outer layer 42 made of a resin member that is attached so as to cover the outer surface of the reinforcing layer 22. The heat-shrinkable member is disposed around the reinforcing layer 22 that retains the unwinding force, and the heat-shrinkable member is heat-shrinked by heating the heat-shrinkable member and attached to the outer surface of the reinforcing layer 22. Can be formed.
For the outer layer forming step, the description related to the formation of the outer layer 42 in the first embodiment can be referred to as appropriate, and therefore the detailed description is omitted here.
By removing the core material 700 from the large-diameter resin tube 14, the lumen 12 that is a hole communicating with the inside of the large-diameter resin tube 14 is formed, and the tip described in the first embodiment is provided inside the tip coil portion 62. Hole 752 (FIG. 5a) is formed. By providing the tip hole 752, the lumen 12 provided inside the large diameter resin tube 14 can be communicated to the distal end of the catheter 110.
The catheter 110 can be manufactured by the manufacturing method described above.

The first to third embodiments of the present invention have been described above. The present invention is not limited to the above-described embodiment, and includes various modifications and improvements as long as the object of the present invention is achieved. The matters described in each embodiment can be applied to other embodiments as appropriate.
Moreover, the order of description of each process in 3rd embodiment does not limit this manufacturing method. As long as the desired catheter can be manufactured, the order of the steps can be appropriately changed. Moreover, you may further add arbitrary processes suitably before or after each process demonstrated, or between one process and another process.

The above embodiment includes the following technical idea.
(1) A catheter having a lumen inside,
A large diameter resin pipe forming the large diameter lumen;
A small-diameter operating line tubule disposed outside the lumen;
An operating line inserted through the operating line capillary and having a distal end connected to the distal end of the catheter;
A reinforcing layer that is a coil that covers both the large-diameter resin tube and the operation wire tubule;
An outer layer made of a resin member attached to cover the outer surface of the reinforcing layer;
Have
A distal end fixing portion made of a resin member that grips the reinforcing layer by being provided around the reinforcing layer against a force of loosening the reinforcing layer at a distal end portion of the reinforcing layer and a proximal end portion of the reinforcing layer; While having a proximal end fixing part,
In the region between the distal end fixing portion and the proximal end fixing portion, the outer layer receives a biasing force that elastically biases radially outward from the reinforcing layer.
(2) The catheter according to (1), wherein an intermediate fixing portion made of a resin member provided around the reinforcing layer is provided at an intermediate portion between the proximal end portion and the distal end portion.
(3) The catheter according to (2), wherein an inner diameter of the intermediate fixing portion is smaller than an outer diameter of the reinforcing layer at a location where the intermediate fixing portion, the distal end fixing portion, and the proximal end fixing portion are not provided. .
(4) The resin member constituting the intermediate fixing portion exists outside the inner side surface of the reinforcing layer, and
The inner diameter of the intermediate fixing portion is a half point between the distal end fixing portion or the proximal end fixing portion and the intermediate fixing portion adjacent to the distal end fixing portion or the proximal end fixing portion. The catheter according to the above (2) or (3), which is not more than the sum of the outer diameter of the large-diameter resin tube measured in the radial direction, the outer diameter of the operating wire tubule, and the thickness of the reinforcing layer.
(5) The reinforcing layer is a multiple coil layer in which two or more coils overlap in the radial direction,
The catheter according to any one of (1) to (4), wherein a winding direction of at least one of the coils in the multiple coil layer is different from a winding direction of the other coil.
(6) The catheter according to (5), wherein the coiling force of the coil located on the outermost side is greater than the coiling force of the coil located on the most axial side.
(7) The multiple coil layer is a triple coil layer having three coils that are an inner coil, an intermediate coil, and an outer coil from the central axis side of the catheter,
The catheter according to (5) or (6), wherein the winding direction of the intermediate coil is different from the winding direction of the inner coil and the winding direction of the outer coil.
(8) The catheter according to (6), wherein the inner coil and the outer coil are multi-strip coils composed of a plurality of linear members that are larger than the number of linear members that form intermediate coils.
(9) The tip fixing portion and the base end fixing portion are any one of the above (1) to (8), in which the reinforcing layer, the operation wire tubule, and the large-diameter resin tube are embedded with a resin member. The catheter according to one item.
(10) A catheter manufacturing method for manufacturing the catheter according to any one of (1) to (9) above,
A reinforcing layer forming step of forming the reinforcing layer made of the coil by spirally winding a linear member around an arbitrary core material;
Resist the force of the coil that is elastically wound outward in the radial direction of the coil at the proximal end portion and the distal end portion of the coil forming the reinforcing layer in which the large-diameter resin tube and the operation wire thin tube are inserted. A fixing portion forming step of forming a distal end fixing portion and a proximal end fixing portion for fixing the coil with a resin member;
A heat-shrinkable member is disposed around the reinforcing layer having the winding-relaxing force, and the heat-shrinkable member is heat-shrinked by heating the heat-shrinkable member and attached to the outer surface of the reinforcing layer. Forming an outer layer; and
A method for producing a catheter, comprising:
(11) In the middle part of the coil forming the reinforcing layer in which the large-diameter resin tube and the operation wire thin tube are inserted, the coil resists the force of winding and loosening outward in the radial direction of the coil. The method for producing a catheter according to (10), further comprising an intermediate fixing portion forming step of forming an intermediate fixing portion for fixing the catheter with a resin member.
(12) In the intermediate fixing part forming step, a heat shrink member is arranged in the circumferential direction in the intermediate part,
The inner diameter of the intermediate fixing portion after formation is measured in the radial direction of the catheter at a half point between the proximal end fixing portion and the intermediate fixing portion after formation. The catheter according to (11), wherein the heat shrinkable member is heat-shrinked by heating from the outside of the heat-shrinkable member so as to be equal to or less than a sum of a diameter, an outer diameter of the operation wire tubule, and a thickness of the reinforcing layer. Production method.
(13) In the reinforcing layer forming step, the linear member is wound around the core material in one direction to form a first coil, and the different linear members are arranged on the outer periphery of the first coil. The method for producing a catheter according to any one of (10) to (12), wherein the second coil is formed by winding in a direction different from a winding direction of the first coil.
(14) The winding force of the first coil is increased by making a check tension for the linear member constituting the first coil larger than a check tension for the linear member constituting the second coil. The catheter manufacturing method according to (13), wherein the loosening force of the second coil is larger than the loosening force.

DESCRIPTION OF SYMBOLS 10 ... Tip fixing | fixed part 11 ... Base end fixing | fixed part 12 ... Lumen 14 ... Large diameter resin pipe 16 ... Operation wire thin tube 18 ... Operation line 22 ... Reinforcement layer 24 ... Intermediate fixing part 32 ... Distal end opening 38 ... Folded part 38A ... Surplus part 38B ... Intrusion part 42 ... Outer layer 50 ... Tubular body 52 ... Tip 60 ... Body coil portion 60A ... Inner coil 60B ... Intermediate coil 60C ... Outer coil 62 ... Tip coil portion 62A ... Inner tip coil 62B ... Outer tip coil 100 ... Catheter 110 ... Catheter 700 ... Core material 710 ... Outer diameter 715 ... Inner diameter 740 ... Outer diameter 752 ... End hole 760 ... Outer diameter 800 ... Resin embedded part 810 ... Operation line operation unit 812 ... syringe 816 ... dial 8 8 ... connecting portion 820 ... end cap a, b, c ... outer diameter X ... maximum bending point

Claims (7)

A catheter having a lumen therein,
A large diameter resin pipe forming the large diameter lumen;
A small-diameter operating line tubule disposed outside the lumen;
An operating line inserted through the operating line capillary and having a distal end connected to the distal end of the catheter;
A reinforcing layer that is a coil that covers both the large-diameter resin tube and the operation wire tubule;
An outer layer made of a resin member attached to cover the outer surface of the reinforcing layer;
Have
A distal end fixing portion made of a resin member that grips the reinforcing layer by being provided around the reinforcing layer against a force of loosening the reinforcing layer at a distal end portion of the reinforcing layer and a proximal end portion of the reinforcing layer; While having a proximal end fixing part,
In the region between the distal end fixing portion and the proximal end fixing portion, the outer layer receives a biasing force that elastically biases radially outward from the reinforcing layer ;
In an intermediate portion between the base end portion and the tip end portion, an intermediate fixing portion made of a resin member provided around the reinforcing layer is provided.
The dimension of the inner diameter of the intermediate fixing portion is the half point between the distal end fixing portion or the proximal end fixing portion and the intermediate fixing portion adjacent to the distal end fixing portion or the proximal end fixing portion. A catheter characterized by being smaller than the outer diameter of the reinforcing layer in a range of 0.5 mm to 8 mm . The resin member constituting the intermediate fixing portion exists outside the inner side surface of the reinforcing layer, and
The inner diameter of the intermediate fixing portion is a half point between the distal end fixing portion or the proximal end fixing portion and the intermediate fixing portion adjacent to the distal end fixing portion or the proximal end fixing portion. 2. The catheter according to claim 1, which is equal to or less than a sum of an outer diameter of the large-diameter resin tube measured in a radial direction, an outer diameter of the operation wire capillary, and a thickness of the reinforcing layer . The reinforcing layer is a multiple coil layer in which two or more coils overlap in the radial direction,
The catheter according to claim 1 or 2, wherein a winding direction of at least one of the coils in the multi-coil layer is different from a winding direction of the other coil . The catheter according to claim 3, wherein the unwinding force of the coil located on the outermost side is larger than the unwinding force of the coil located on the most axial side . The multi-coil layer is a triple coil layer having three coils that are an inner coil, an intermediate coil, and an outer coil from the central axis side of the catheter,
The catheter according to claim 3 or 4, wherein a winding direction of the intermediate coil is different from a winding direction of the inner coil and a winding direction of the outer coil . The catheter according to claim 5, wherein the inner coil and the outer coil are multi-strand coils composed of a plurality of linear members larger than the number of linear members forming the intermediate coil . The catheter according to any one of claims 1 to 6, wherein the distal end fixing portion and the proximal end fixing portion embed the reinforcing layer, the operation wire tubule, and the large-diameter resin tube with a resin member. .

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