WO2014157253A1 - Medical device and medical device production method - Google Patents
Medical device and medical device production method Download PDFInfo
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- WO2014157253A1 WO2014157253A1 PCT/JP2014/058368 JP2014058368W WO2014157253A1 WO 2014157253 A1 WO2014157253 A1 WO 2014157253A1 JP 2014058368 W JP2014058368 W JP 2014058368W WO 2014157253 A1 WO2014157253 A1 WO 2014157253A1
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- wire
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- tube
- subtube
- layer
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Classifications
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61M—DEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
- A61M25/00—Catheters; Hollow probes
- A61M25/0009—Making of catheters or other medical or surgical tubes
- A61M25/0012—Making of catheters or other medical or surgical tubes with embedded structures, e.g. coils, braids, meshes, strands or radiopaque coils
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61M—DEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
- A61M25/00—Catheters; Hollow probes
- A61M25/0043—Catheters; Hollow probes characterised by structural features
- A61M25/005—Catheters; Hollow probes characterised by structural features with embedded materials for reinforcement, e.g. wires, coils, braids
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61M—DEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
- A61M25/00—Catheters; Hollow probes
- A61M25/01—Introducing, guiding, advancing, emplacing or holding catheters
- A61M25/0105—Steering means as part of the catheter or advancing means; Markers for positioning
- A61M25/0133—Tip steering devices
- A61M25/0147—Tip steering devices with movable mechanical means, e.g. pull wires
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61M—DEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
- A61M25/00—Catheters; Hollow probes
- A61M25/0043—Catheters; Hollow probes characterised by structural features
- A61M25/0045—Catheters; Hollow probes characterised by structural features multi-layered, e.g. coated
Definitions
- the present invention relates to a medical device and a method for manufacturing the medical device.
- two wire lumens (sublumen: sublumen) having a smaller diameter are opposed 180 degrees around a central lumen (main lumen: main lumen) defined by the inner layer.
- the catheter provided is described.
- a deflection wire (hereinafter referred to as an operation line) is inserted into the sub-lumen, and the distal end of the catheter is bent by pulling the operation line by operating the operation handle on the proximal end side. .
- two polymer tubes that define a wire lumen (hereinafter referred to as sublumen) are arranged along the outer surface of a thin inner layer made of a fluorine-based resin material or the like.
- An operation line is inserted through the subtube.
- a pressurized fluid is injected into the inside of the wire lumen, and compression is applied to the wire lumen when the outer layer of the tubular body is thermoformed. The inner diameter is maintained against the force.
- the sub-tube When the operation line is pulled to bend the tubular body, the sub-tube is eccentric from the axis and located outside or inside the bend, so the path length from the proximal end to the distal end is different from the axis This is because a shearing force is generated at the interface between the outer layer of the tubular body and the subtube.
- the catheter was illustrated and demonstrated here, the same subject is a subject which arises in general of the medical device which operates not only with a catheter but with an operation line.
- the present invention has been made in view of the above problems, and provides a medical device that can easily fix a sub-tube through which an operation line is inserted to a tubular body without peeling, and a method for manufacturing the medical device. .
- a long inner layer that defines a main lumen, a wire reinforcing layer formed by winding a reinforcing wire around the inner layer, and a longitudinal direction of the main lumen outside the wire reinforcing layer.
- a resin-made subtube that is arranged to extend and defines a sub-lumen having a smaller diameter than the main lumen; and a resin-made outer layer that encloses the wire reinforcing layer and the subtube.
- a tubular body an operation line that is movably inserted into the sub-lumen and has a tip connected to a distal portion of the tubular body, and pulling the operation line to pull the distal portion of the tubular body
- An operation portion that bends at least a part of the region, and the tubular body further includes a holding wire that is included in the outer layer and winds the subtube and the wire reinforcing layer together, and the holding wire is the subtube.
- the holding wire that co-winds the sub-tube through which the operation line is inserted and the wire reinforcing layer is included in the outer layer in a state of being fitted to the outer peripheral surface of the sub-tube. For this reason, since a holding
- the elongated sub-core wire is disposed on the outer peripheral surface of the wire reinforcing layer along the main core wire, and the holding tube is pressed against the surface of the sub-tube and the sub-tube and the wire reinforcing layer are
- a step of co-winding with the holding wire a step of forming an outer layer so as to enclose the wire-reinforced layer and the wire-reinforcing layer and the holding wire which are co-wound to form a tubular body;
- a method for manufacturing a medical device including a step of reducing the diameter and separating from the sub-tube to form a sub-lumen, and a step of removing the main core wire from the tubular body to form a main lumen. That.
- the present invention it is possible to easily fix the sub-tube for inserting the operation line in the medical device to the tubular main body without peeling with the holding wire.
- FIG. 4 is a schematic cross-sectional view taken along the line III-III in FIG. 3 at the distal end portion of the catheter according to the embodiment of the present invention. It is a typical expanded sectional view of a holding wire and a subtube. It is a typical longitudinal cross-sectional view which shows the front-end
- FIG. 5A is a partial cross-sectional view taken along the line VV of FIG. 4 relating to the first sub-tube.
- FIG. 5B is a partial cross-sectional view taken along the line VV of FIG. 4 regarding the second sub-tube.
- FIG. 5A is a partial cross-sectional view taken along the line VV of FIG. 4 relating to the first sub-tube.
- FIG. 5B is a partial cross-sectional view taken along the line VV of FIG. 4 regarding the second sub-tube
- FIG. 6A is a partial cross-sectional view taken along line VI-VI in FIG. 4, and is a cross-sectional view regarding the second length region of the first subtube.
- FIG. 6B is a partial cross-sectional view taken along line VI-VI in FIG. 4, and is a cross-sectional view regarding the first length region of the second subtube. It is a side view which shows the distal part of a tubular main body.
- Fig.8 (a) is the whole side view of the catheter of embodiment of this invention.
- FIG. 8B is an overall side view of the catheter showing a state in which the wheel operation unit is operated in one direction.
- FIG. 8C is an overall side view of the catheter showing a state in which the wheel operation unit is operated in the other direction.
- FIG. 1 is a cross-sectional view (transverse cross-sectional view) in which the vicinity of the distal end portion of the catheter 100 is cut perpendicularly to the longitudinal direction.
- FIG. 2 is an enlarged cross-sectional view of the holding wire 70 and the subtube 40.
- FIG. 3 is a cross-sectional view (longitudinal cross-sectional view) in which the vicinity of the distal end portion of the catheter 100 is cut in the longitudinal direction, and the first outer layer 52 and the second outer layer 54 are simplified and collectively shown as the outer layer 50.
- . 1 is a cross-sectional view taken along line III-III in FIG. FIG.
- FIG. 4 is a longitudinal sectional view schematically showing the first length region L1 and the second length region L2 of the subtube 40.
- the inner layer 24, the wire reinforcing layer 30, the second reinforcing layer 80, and the second marker 16 are shown in FIG. The illustration is omitted.
- the first outer layer 52 and the second outer layer 54 are simplified and collectively shown as the outer layer 50.
- FIG. 5A is a partial cross-sectional view taken along line VV of FIG. 4, and is a cross-sectional view regarding the first length region L1a of the first subtube 40a.
- FIG. 5B is a partial cross-sectional view taken along line VV in FIG. 4, and is a cross-sectional view regarding the second length region L2b of the second sub-tube 40b.
- FIG. 5A is a partial cross-sectional view taken along line VV of FIG. 4, and is a cross-sectional view regarding the first length region L1a of the first subtube 40a.
- FIG. 5B is a
- FIG. 6A is a partial cross-sectional view taken along line VI-VI in FIG. 4, and is a cross-sectional view regarding the second length region L2a of the first subtube 40a.
- FIG. 6B is a partial cross-sectional view taken along line VI-VI in FIG. 4, and is a cross-sectional view regarding the first length region L1b of the second sub-tube 40b.
- FIG. 8 will be described later.
- the catheter 100 is illustrated as a medical device.
- the present invention can be applied to endoscopes and other medical devices that can bend at least a partial region of the distal portion DE by pulling the operation line 60.
- the tip (part) or the distal end (part) means the end (part) opposite to the side connected to the operation part 90 of the tubular body 10, and the distal part DE (tip).
- (Part) means a certain region including the tip (distal end).
- the catheter 100 of the present embodiment includes a long tubular body 10, an operation line 60, and an operation unit 90.
- the tubular body 10 includes a long inner layer 24 that defines the main lumen 20, a wire reinforcing layer 30 formed by winding a reinforcing wire 32 around the main lumen 20 (inner layer 24), and an outer side of the wire reinforcing layer 30. It is arranged so as to extend in the longitudinal direction of the main lumen 20, and includes a long resin-made subtube 40 that defines a sublumen 42 having a smaller diameter than the main lumen 20, and includes the wire reinforcing layer 30 and the subtube 40. A resin outer layer 50 and a holding wire 70.
- the operation line 60 is movably inserted into the sub-lumen 42 and has a distal end connected to the distal portion DE of the tubular body 10.
- the operation unit 90 pulls the operation line 60 to bend at least a partial region of the distal portion DE of the tubular body 10.
- the holding wire 70 is included in the outer layer 50 and winds the sub-tube 40 and the wire reinforcing layer 30 together.
- the catheter 100 of this embodiment is characterized in that the holding wire 70 is fitted into the outer peripheral surface of the sub-tube 40.
- the catheter 100 of this embodiment is an intravascular catheter that is used by inserting the tubular body 10 into a blood vessel.
- the tubular main body 10 is also called a sheath, and is a hollow tubular and long member having a main lumen 20 formed therein. More specifically, the tubular body 10 is formed with an outer diameter and a length that allow entry into any of the eight sub-regions of the liver.
- the tubular body 10 has a laminated structure.
- An inner layer 24, a first outer layer 52, and a second outer layer 54 are laminated in this order from the inner diameter side with the main lumen 20 as the center, and the main part of the tubular body 10 is configured.
- a hydrophilic layer (not shown) is formed on the outer surface of the second outer layer 54.
- the inner layer 24, the first outer layer 52, and the second outer layer 54 are made of a flexible resin material, and each has an annular shape and a substantially uniform thickness.
- the first outer layer 52 and the second outer layer 54 may be collectively referred to as the outer layer 50.
- the inner layer 24 is the innermost layer of the tubular body 10, and the main lumen 20 is defined by the inner wall surface thereof.
- the cross-sectional shape of the main lumen 20 is not particularly limited, but is circular in this embodiment.
- the diameter may be uniform over the longitudinal direction of the tubular body 10 or may vary depending on the position in the longitudinal direction.
- the diameter (lumen) of the main lumen 20 can be continuously tapered from the distal end toward the proximal end.
- the material of the inner layer 24 include a fluorine-based thermoplastic polymer material.
- the fluorine-based thermoplastic polymer material examples include polytetrafluoroethylene (PTFE), polyvinylidene fluoride (PVDF), and perfluoroalkoxy fluororesin (PFA).
- PTFE polytetrafluoroethylene
- PVDF polyvinylidene fluoride
- PFA perfluoroalkoxy fluororesin
- the outer layer 50 constitutes the main wall thickness of the tubular body 10.
- the outer layer 50 according to the present embodiment includes a first outer layer 52 having an annular cross section that encloses the holding wire 70 and a second outer layer having an annular cross section that is provided around the first outer layer 52 and encloses the second reinforcing layer 80. 54.
- a wire reinforcing layer 30, a sub tube 40, and a holding wire 70 are provided in order from the inner diameter side.
- a second reinforcing layer 80 is provided inside the second outer layer 54 corresponding to the outer layer of the outer layer 50.
- the second reinforcing layer 80 is in contact with the outer surface of the first outer layer 52.
- the wire reinforcing layer 30 and the second reinforcing layer 80 are disposed coaxially with the tubular main body 10.
- the second reinforcing layer 80 is disposed so as to surround the wire reinforcing layer 30 and the subtube 40 so as to surround them.
- thermoplastic polymer material As the material of the outer layer 50 , a thermoplastic polymer material can be used. As this thermoplastic polymer material, polyimide (PI), polyamideimide (PAI), polyethylene terephthalate (PET), polyethylene (PE), polyamide (PA), polyamide elastomer (PAE), polyether block amide (PEBA), etc. Mention may be made of nylon elastomers, polyurethane (PU), ethylene-vinyl acetate resin (EVA), polyvinyl chloride (PVC) or polypropylene (PP).
- the outer layer 50 may be mixed with an inorganic filler. Examples of the inorganic filler include contrast agents such as barium sulfate and bismuth subcarbonate. By mixing a contrast agent in the outer layer 50, the X-ray contrast property of the tubular body 10 in the body cavity can be improved.
- the first outer layer 52 and the second outer layer 54 are made of the same or different resin materials. Although the boundary surface between the first outer layer 52 and the second outer layer 54 is clearly shown in FIG. 1, the present invention is not limited to this. When the 1st outer layer 52 and the 2nd outer layer 54 are comprised with the same kind of resin material, the interface of both layers may be united naturally. That is, the outer layer 50 of the present embodiment may be formed of a multilayer in which the first outer layer 52 and the second outer layer 54 are distinguishable from each other, or the first outer layer 52 and the second outer layer 54 are integrated. It may be configured as a single layer.
- the wire reinforcing layer 30 is a protective layer that is provided on the inner diameter side of the operation line 60 in the tubular body 10 and protects the inner layer 24. The presence of the wire reinforcing layer 30 on the inner diameter side of the operation line 60 prevents the operation line 60 from being exposed to the main lumen 20 by breaking the first outer layer 52 and the inner layer 24.
- the wire reinforcing layer 30 is formed by winding a reinforcing wire 32.
- the material of the reinforcing wire 32 includes a metal material such as tungsten (W), stainless steel (SUS), nickel titanium alloy, steel, titanium, copper, titanium alloy or copper alloy, as well as the inner layer 24 and the first outer layer 52. Also, a resin material such as polyimide (PI), polyamideimide (PAI) or polyethylene terephthalate (PET) having high shear strength can be used.
- the reinforcing wire 32 is a fine stainless steel wire.
- the wire reinforcing layer 30 is formed by winding a reinforcing wire 32 in a coiled or mesh shape.
- the number of the reinforcing wires 32, the coil pitch, and the number of meshes are not particularly limited.
- the number of meshes of the wire reinforcing layer 30 refers to the number of intersections (number of eyes) per unit length (1 inch) viewed in the extending direction of the reinforcing wires 32.
- the opening size of the second reinforcing layer 80 as viewed in the extending direction of the second reinforcing wire 82 is defined by the above mathematical formula (1).
- the reinforcing wire 32 is wound obliquely around the inner layer 24.
- An angle formed by the extending direction of the reinforcing wire 32 with respect to the radial direction of the inner layer 24 is referred to as a pitch angle of the reinforcing wire 32.
- the pitch angle becomes a small angle.
- the pitch angle is a large angle close to 90 degrees.
- the pitch angle of the reinforcing wire 32 of the present embodiment is not particularly limited, but can be 30 degrees or more, preferably 45 degrees or more and 75 degrees or less.
- Circumferential opening dimension W (unit length (1 inch) / number of meshes ⁇ wire diameter of reinforcing wire 32) ⁇ ⁇ 2 (2)
- the opening dimension W in the circumferential direction of the wire reinforcing layer 30 is the length of a diagonal line when the opening shape of the wire reinforcing layer 30 viewed in the extending direction of the reinforcing wire 32 is regarded as a square.
- the blade layer formed by braiding the reinforcing wire 32 is illustrated as the wire reinforcing layer 30 of the present embodiment.
- the opening dimension W in the circumferential direction of the wire reinforcing layer 30 (blade layer) represented by the above formula (2) is larger than the outer diameter of the sub-tube 40.
- the first outer layer 52 is impregnated between the wire reinforcing layer 30 and the subtube 40. That is, any opening of the wire reinforcing layer 30 is completely shielded by the subtube 40 regardless of the positional relationship between the crossing position (eye position) of the reinforcing wires 32 intersecting in a mesh shape and the subtube 40. There is nothing. Thereby, in the manufacturing process described later, the first outer layer 52 is impregnated from the periphery of the subtube 40 into the inside of the openings, and the inner layer 24, the wire reinforcing layer 30, and the subtube 40 are fixed together.
- the second reinforcing layer 80 is a protective layer that is provided on the outer diameter side of the operation line 60 in the tubular body 10 and protects the second outer layer 54.
- the presence of the second reinforcing layer 80 on the outer diameter side of the operation line 60 prevents the operation line 60 from being exposed to the outside of the tubular body 10 by breaking the second outer layer 54 and the hydrophilic layer (not shown).
- the second reinforcing layer 80 is formed by winding the second reinforcing wire 82 into a coil or mesh shape.
- the above-described materials exemplified as the reinforcing wire 32 of the wire reinforcing layer 30 can be used.
- the second reinforcing wire 82 and the reinforcing wire 32 may be made of the same material or different materials.
- a blade layer in which fine wires made of the same material (stainless steel) as the reinforcing wire 32 are braided in a mesh shape is illustrated.
- the wire diameters of the second reinforcing wire 82 and the reinforcing wire 32 may be the same or different.
- the second reinforcing wire 82 and the reinforcing wire 32 have the same wire diameter.
- the size of the number of the reinforcing wires 32 constituting the wire reinforcing layer 30 and the number of the second reinforcing wires 82 constituting the second reinforcing layer 80 are not particularly limited, but are the same in this embodiment.
- both of the wire reinforcing layer 30 and the second reinforcing layer 80 are illustrated as blade layers made of 16 wires (reinforcing wires 32 and second reinforcing wires 82).
- the subtube 40 is a hollow tubular member that defines a secondary lumen 42.
- the subtube 40 is embedded in the outer layer 50 (first outer layer 52).
- the subtube 40 can be made of, for example, a thermoplastic polymer material.
- the thermoplastic polymer material include low friction resin materials such as polytetrafluoroethylene (PTFE), polyetheretherketone (PEEK), or tetrafluoroethylene / hexafluoropropylene copolymer (FEP).
- PTFE polytetrafluoroethylene
- PEEK polyetheretherketone
- FEP tetrafluoroethylene / hexafluoropropylene copolymer
- the subtube 40 is made of a material having a higher bending rigidity and tensile elastic modulus than the outer layer 50.
- the outer surface of the sub-tube 40 is subjected to etching treatment such as metal sodium treatment or plasma treatment. Thereby, the adhesiveness of the subtube 40 and the outer layer 50 is improved.
- a plurality of sub-tubes 40 are arranged facing the periphery of the main lumen 20. More specifically, as shown in FIG. 1, four subtubes 40 are arranged around the wire reinforcing layer 30 so as to face each other at intervals of 90 degrees, of which two subtubes 40 facing each other are 180 degrees. Each operation line 60 is inserted. The four sub tubes 40 are arranged in parallel to the axial direction of the tubular body 10.
- three or more subtubes 40 are evenly arranged around the main lumen 20 and face each other. As shown in FIG. 1, the four sub tubes 40 are arranged on the same circumference so as to surround the main lumen 20. Instead of this embodiment, three or less or five or more subtubes 40 may be arranged around the main lumen 20 at equal intervals.
- the bending rigidity of the tubular body 10 becomes equal regardless of the bending direction of the tubular body 10. For this reason, when the tubular main body 10 is torque-rotated in a bent state, it is possible to smoothly direct at least a part of the distal portion DE in a desired direction.
- the operation line 60 is slidably inserted in the sub tube 40.
- the distal end portion of the operation line 60 is fixed to the distal portion DE of the tubular main body 10.
- the operation line 60 of the present embodiment is fixed near the first marker 14 described later.
- a tensile force is applied to a position that is eccentric with respect to the axial center of the tubular body 10, so that the tubular body 10 is bent. Since the operation line 60 of the present embodiment is extremely thin and highly flexible, even if the operation line 60 is pushed distally, a pushing force is not substantially applied to the distal portion DE of the tubular body 10.
- the operation wire 60 may be formed of a single wire, but may be a stranded wire formed by twisting a plurality of thin wires.
- the number of fine wires constituting one stranded wire of the operation wire 60 is not particularly limited, but is preferably 3 or more. A preferable example of the number of thin wires is seven or three.
- the operation line 60 is a single wire, the diameter of the single line is referred to as the wire diameter of the operation line 60.
- the operation wire 60 is a stranded wire obtained by twisting a plurality of strands, the diameter of a circumscribed circle including the plurality of strands is referred to as the wire diameter of the operation wire 60.
- the operation wire 60 a low carbon steel (piano wire), stainless steel (SUS), a steel wire coated with corrosion resistance, titanium or a titanium alloy, or a metal wire such as tungsten can be used.
- the operation line 60 includes polyvinylidene fluoride (PVDF), high density polyethylene (HDPE), poly (paraphenylenebenzobisoxazole) (PBO), polyetheretherketone (PEEK), polyphenylene sulfide (PPS), Polymer fibers such as polybutylene terephthalate (PBT), polyimide (PI), polytetrafluoroethylene (PTFE), or boron fiber can be used.
- PVDF polyvinylidene fluoride
- HDPE high density polyethylene
- PBO poly (paraphenylenebenzobisoxazole)
- PEEK polyetheretherketone
- PPS polyphenylene sulfide
- Polymer fibers such as polybutylene terephthalate (PBT), polyimide (PI
- the holding wire 70 is a member characteristic of the present embodiment in which the subtube 40 and the wire reinforcing layer 30 are wound together.
- the holding wire 70 is formed by winding the coil around the subtube 40 or braiding it in a mesh shape.
- the holding wire 70 according to the present embodiment is a coil, and more specifically, a coil (multi-coil) in which a plurality of holding wires 70 are wound in multiple lines.
- the shape of the holding wire layer formed by winding the holding wire 70 of this embodiment is a substantially polygonal shape with the subtube 40 as a corner.
- the winding shape of the holding wire layer formed of the holding wires 70 is an angle with each sub-tube 40 as a corner. Round N-gon. More specifically, in the present embodiment in which the four sub tubes 40 are evenly arranged around the main lumen 20, the winding shape of the holding wire layer is a rounded square.
- the holding wire layer is formed by spirally winding the holding wire 70 so as to surround the outer sides of the plurality of sub tubes 40 arranged evenly around the main lumen 20.
- the holding wire 70 Due to the action of the winding tension applied to the holding wire 70, the holding wire 70 is stretched substantially linearly at the intermediate portion between the sub-tubes 40. However, when the bending rigidity of the holding wire 70 is large or the winding tension is small, the holding wire 70 may be curved in an arc shape at an intermediate portion between the sub-tubes 40. In this case, the winding shape of the holding wire layer may be substantially circular.
- the holding wire 70 may be in contact with the surface of the wire reinforcing layer 30 in addition to the outer surface of the subtube 40.
- the holding wire 70 is inserted into the peripheral surface of the subtube 40, specifically, the outer surface on the opposite side to the axis of the main lumen 20.
- the relative movement of the holding wire 70 and the subtube 40 in the axial direction is restricted.
- the tubular body 10 bends, the outside of the bend expands and the inside is compressed.
- the subtube 40 is made of a material having a higher bending rigidity and tensile modulus than the outer layer 50, the outer layer 50 is flexibly stretched or compressed, whereas the subtube 40 is stretched or compressed. Is small.
- the holding wire 70 functions as an anchor that engages both the outer layer 50 and the sub-tube 40, and the holding wire 70. Elastically deforms to relieve the above shearing force. Thereby, peeling of the interface between the sub-tube 40 and the outer layer 50 (hereinafter referred to as interface peeling) is prevented.
- the holding wire 70 is fitted into the peripheral surface of the subtube 40 means that a part or all of the holding wire 70 is virtually on the outer periphery of the subtube 40 in at least one cross section of the tubular body 10. It is located inside the surface (virtual outline).
- the virtual surface (virtual outer shape) on the outer periphery of the subtube 40 is a virtual outer peripheral surface of the subtube 40 when the holding wire 70 is not inserted.
- the virtual outer shape of the subtube 40 can be obtained from the outer peripheral surface of another portion that is close to the insertion portion of the holding wire 70 in the subtube 40 in the axial direction.
- the holding wire 70 being fitted into the peripheral surface of the subtube 40 includes at least the following two states.
- the first state is the state of the present embodiment in which the sub-tube 40 is locally thin at the insertion site of the holding wire 70 as shown in FIGS. 5 (b) and 6 (a).
- the sub-tube 40 of the present embodiment is locally thin while maintaining a circular cross-sectional shape.
- the second state is a state in which the cross-sectional shape of the sub-tube 40 is a concave shape as a whole with a uniform thickness over the entire circumference instead of the present embodiment.
- the cross-sectional shape of the sub-tube 40 is a concave shape such as a concave circular shape or a concave elliptical shape (kidney shape or curved ball shape).
- the state in which the holding wire 70 is fitted in the recessed portion is also said that the holding wire 70 is fitted in the peripheral surface of the sub-tube 40.
- the distance from the virtual surface (virtual outline) of the outer periphery of the subtube 40 to the deepest part of the holding wire 70 in the cross section of the insertion portion of the holding wire 70 is the insertion depth D of the holding wire 70 with respect to the peripheral surface of the subtube 40. (See FIG. 2).
- the insertion depth D in the catheter 100 of this embodiment is smaller than the thickness of the subtube 40.
- the insertion depth D may be equal to the thickness of the subtube 40 or may be larger than the thickness of the subtube 40.
- the holding wire 70 is wound over substantially the entire length of the subtube 40.
- the holding wire 70 As the material of the holding wire 70, any of the metal materials and resin materials described above that can be used as the reinforcing wire 32 can be used.
- the holding wire 70 is made of a material different from that of the reinforcing wire 32.
- the ductility of the holding wire 70 is preferably higher than the ductility of the reinforcing wire 32.
- austenitic soft stainless steel (W1 or W2) which is a dull material, or copper or copper alloy is used for the holding wire 70, while tungsten or stainless spring steel can be used for the reinforcing wire 32.
- the holding wire 70 is loosened when the holding wire 70 is coiled or braided into a mesh shape (coil winding in this embodiment) around the sub-tube 40.
- the sub-tube 40 is fixed by being stretched and deformed plastically.
- the wire reinforcing layer 30 is a member that prevents the occurrence of kinks in the tubular body 10 as described later, it is preferable to use a spring material having a high elastic restoring force.
- the first length region L1 and the second length region L2 exist side by side in the axial direction of the tubular body 10.
- the first length region L1 is a region where the insertion depth D of the holding wire 70 with respect to the peripheral surface of at least one of the sub tubes 40 is a predetermined depth.
- the second length region L2 is a region in which the insertion depth D is deeper than the first length region L1 (see FIG. 4). That is, regarding the first subtube 40a, the first length region L1 (L1a) is a region in which the holding wire 70 is relatively shallowly inserted (see FIG. 5A), and the second length region L2 (L2a) is a region in which the holding wire 70 is relatively deeply inserted (see FIG. 6A).
- the second length region L2 requires that the holding wire 70 is inserted into the subtube 40, whereas the first length region L1 does not fit the holding wire 70 into the surface of the subtube 40. Is allowed to touch. That is, the insertion depth D> 0 for the second length region L2, and the insertion depth D ⁇ 0 for the first length region L1.
- the first length region L1a and the second length region L2a are repeatedly present in the axial direction of the tubular body 10 a plurality of times. For this reason, even if said peeling arises in any position of an axial center direction, extension of peeling stops immediately by the 2nd length area
- the operation line 60 is inserted through the first sub-tube 40a and the second sub-tube 40b facing each other.
- These first subtube 40a and second subtube 40b have first length regions L1a and L1b and second length regions L2a and L2b, respectively.
- the first length region L1b is a region in which the holding wire 70 is relatively shallowly inserted (see FIG. 6B), and the second length region.
- L2b is a region in which the holding wire 70 is relatively deeply inserted (see FIG. 5B).
- the first length region L1 and the second length region L2 exist with respect to the plurality of subtubes 40 through which the operation lines 60 are inserted, interfacial peeling occurs in any of the subtubes 40. However, the subtube 40 is not detached inside the outer layer 50.
- the first length regions L1a and L1b and the second length regions L2a and L2b exist repeatedly in the axial direction. For this reason, even if interface peeling occurs at any position of the first sub-tube 40a and the second sub-tube 40b by pulling the arbitrary operation line 60, the extension is the second length region L2a, L2b. Stop immediately.
- the first length region L1a included in the first subtube 40a and the first length region L1b included in the second subtube 40b are present at different positions in the axial direction. That is, when each of the first length regions L1a and L1b repeats a plurality of times in the axial direction, the first length regions L1a and the first length regions L1a that are adjacent to each other in the circumferential direction of the tubular body 10 are adjacent to each other.
- One length region L1b exists at a different position in the axial direction.
- the second length region L2a of the first subtube 40a and the second length region L2b of the second subtube 40b are present at different positions in the axial direction. That is, when each of the second length regions L2a and L2b is repeatedly provided in the axial direction, the second length regions L2a and the second length regions L2a are adjacent to each other in the circumferential direction of the tubular body 10.
- the two-length region L2b exists at different positions in the axial direction.
- first length regions L1a and L1b may be in completely different positions without overlapping in the axial direction, or some length regions may overlap.
- the second length regions L2a and L2b may overlap.
- first subtube 40a and the second subtube 40b facing in the circumferential direction of the tubular body 10 are the first length regions L1a and L1b having a small insertion depth D in different positions, Alternatively, the second length regions L2a and L2b having a large insertion depth D are at different positions. Thereby, it is suppressed that interface peeling generate
- the first length region L1a included in the first subtube 40a and the second length region L2b included in the second subtube 40b are present at the same position in the axial direction. Further, the second length region L2a included in the first subtube 40a and the first length region L1b included in the second subtube 40b are present at the same position in the axial direction.
- the two length regions are present at the same position in the axial direction, when viewed in the axial direction of the tubular body 10, one length region substantially overlaps the other length region. Or is included. However, it does not exclude that a part of the one or other length region is slightly shifted in the axial direction.
- the first length region L1 and the second length region L2 are formed as in the present embodiment by spirally winding the holding wire 70 while periodically changing the winding tension of the holding wire 70 with respect to the subtube 40. be able to. A specific method will be described later.
- the length in the axial direction of the first length region L1 and the second length region L2 is equal to the winding pitch of the holding wire 70 or is an integral multiple of 1/2 of the winding pitch.
- the winding pitch of the holding wire 70 refers to a loop interval when attention is paid to one of the holding wires 70.
- the holding wire layer of this embodiment is a multi-strand coil composed of two coil wires (holding wire 70).
- FIG. 4 illustrates a state where the first length region L1 and the second length region L2 are repeated every 1.5 loops. In this case, the lengths in the axial direction of the first length region L1 and the second length region L2 are 1.5 times the winding pitch of the coil wire constituting the holding wire 70.
- the tubular main body 10 includes a second reinforcing layer 80 formed by winding a second reinforcing wire 82 in a circular cross section outside the holding wire 70.
- the second reinforcing layer 80 of the present embodiment is a blade layer in which fine metal wires are braided in a mesh shape. That is, the tubular main body 10 of this embodiment includes three metal layers, that is, a wire reinforcing layer 30, a holding wire 70, and a second reinforcing layer 80.
- the second reinforcing layer 80 is a member that imparts bending elasticity to the tubular body 10 together with the wire reinforcing layer 30. It is preferable that the tubular body 10 is elastically restored when the tensile load of the operation line 60 is removed after at least a partial region of the distal portion DE of the tubular body 10 is bent by the pulling operation of the operation line 60. . For this reason, it is preferable that the tubular main body 10 of this embodiment uses a spring metal material for the wire reinforcing layer 30 (reinforcing wire 32) and the second reinforcing layer 80 (second reinforcing wire 82). Therefore, the ductility of the holding wire 70 is higher than any of the ductility of the reinforcing wire 32 and the second reinforcing wire 82.
- the holding wire 70 is a member for winding and fixing the subtube 40 around the wire reinforcing layer 30 and for fitting the subtube 40 into the subtube 40 to suppress interfacial peeling from the outer layer 50. Therefore, the holding wire 70 may be lower in strength than the wire reinforcing layer 30 and the second reinforcing layer 80. Therefore, in this embodiment, as shown in FIG. 3, the winding pitch of the holding wires 70, that is, the loop interval between the adjacent holding wires 70, is determined by the wire reinforcing layer 30 (reinforcing wire 32) and the second reinforcing layer 80 ( It is larger than any of the pitch intervals of the second reinforcing wires 82).
- the pitch interval here refers to an interval in the axial direction of the tubular body 10 between adjacent reinforcing wires 32 or second reinforcing wires 82 wound in the same direction in the mesh.
- the loop interval between adjacent holding wires 70 is greater than one or both of the pitch intervals between the wire reinforcing layer 30 (reinforcing wire 32) and the second reinforcing layer 80 (second reinforcing wire 82). It may be small. Thereby, the subtube 40 and the wire reinforcing layer 30 can be suitably held by the holding wire 70.
- the loop interval between the adjacent holding wires 70 is set larger than the pitch interval of the wire reinforcing layer 30 (reinforcing wire 32) and smaller than the pitch interval of the second reinforcing layer 80 (second reinforcing wire 82). Also good.
- FIG. 7 is a side view showing the distal portion DE of the tubular body 10 of the present embodiment.
- the distal portion DE of the tubular body 10 is equipped with a marker portion (first marker 14) made of a radiopaque material as described above.
- the distal end (end point 71) of the holding wire 70 is bonded and fixed to the proximal end side of the marker portion (first marker 14) by an adhesive material 56.
- the first marker 14 is provided on the distal side of the end portion 72 on the distal end side of the holding wire 70.
- the first marker 14 is attached to the outer surface of the wire reinforcing layer 30 (reinforcing wire 32), and the holding wire 70 and the first marker 14 overlap at least partially in the radial direction of the tubular body 10.
- the end points 71 of the multifilamentary coil wires (holding wires) 70 a and 70 b are bonded and fixed in a state of being pressed against the end surface on the proximal end side of the first marker 14. That is, the coil strands (holding wires) 70a and 70b are fixed in a state in which the winding looseness is suppressed by the first marker 14.
- coil wires (holding wires) 70 a and 70 b are spirally wound around the surface of the wire reinforcing layer 30.
- the adhesive 56 is applied on the spirally wound coil strands (holding wires) 70a and 70b.
- the adhesive material 56 is filled in the openings of the reinforcing wires 32 and the coil wires (holding wires) 70a and 70b are partially embedded.
- the end points 71 of the coil strands 70a and 70b (holding wires) are separated from the proximal end surface of the first marker 14 by cutting the excess length of the coil strands 70a and 70b. It is fixed without. Thereby, the end points 71 of the coil strands 70a and 70b do not damage the outer layer 50 and the subtube 40.
- the wire reinforcing layer 30 is formed by braiding a plurality of reinforcing wires 32.
- the multiple reinforcing wires 32 intersecting each other constitute a rectangular mesh.
- the adhesive material 56 is filled in a plurality of openings adjacent to the proximal end side of the marker portion (first marker 14) in the wire reinforcing layer 30.
- the tips (end points 71) of the holding wires 70 (coil wires 70a and 70b) are bonded and fixed to the adhesive material 56.
- the wire reinforcing layer 30 may be caulked and fixed to the outer peripheral surface of the inner layer 24 by the ring-shaped first marker 14 without using the adhesive material 56.
- the adhesive material 56 is filled in a plurality of adjacent openings.
- the adhesive material 56 may be provided on the entire circumference along the base end side of the first marker 14, or may be provided only in a partial region including the end point 71.
- the plurality of openings of the wire reinforcing layer 30 filled with the adhesive material 56 constitute non-circular regions in the wire reinforcing layer 30 adjacent to each other.
- An organic adhesive or brazing can be used for the adhesive material 56.
- a room temperature curable adhesive a thermosetting adhesive, a solution adhesive, or a hot melt adhesive
- Room temperature curing adhesives include reactive adhesives such as cyanoacrylate adhesives, silicone adhesives, epoxy resin adhesives or acrylic resin adhesives, and UV curable adhesives such as urethane acrylates and epoxy acrylates.
- An agent can be used.
- An epoxy resin adhesive can be used as the thermosetting adhesive.
- Solution type adhesives include acrylic resin emulsion adhesives, ⁇ -olefin adhesives, urethane resin solvent adhesives, ethylene-vinyl acetate resin emulsion adhesives, vinyl acetate resin emulsion adhesives or polyvinyl acetate resin solution adhesives. Agents can be exemplified.
- the hot melt adhesive include ethylene-vinyl acetate resin hot melt adhesive, polyurethane resin hot melt adhesive, and polyolefin resin hot melt adhesive.
- brazing, solder or silver candy can be exemplified.
- the adhesive material 56 preferably has a higher melting point than the outer layer 50, particularly the second outer layer 54.
- the outer layer 50 is thermoformed around the holding wire 70 (holding wire layer)
- the end points 71 of the coil wires (holding wires) 70a and 70b are fixed, so that the end 72 is loosened.
- a room temperature curable adhesive which is a cyanoacrylate-based instantaneous adhesive is preferably used.
- the holding wire layer is formed by winding a plurality of coil wire (holding wires) 70a and 70b.
- the tips (end points 71) of the multi-element coil wires (holding wires) 70 a and 70 b are bonded and fixed to the adhesive 56 at substantially the same position in the circumferential direction of the tubular body 10.
- the coil wires (holding wires) 70a and 70b of the present embodiment are bundled and fixed by bonding at the tips (end points 71).
- the coil wires (holding wires) 70 a and 70 b may not be bundled, and the end points 71 may be dissociated from each other in the axial direction of the tubular body 10.
- end points 71 of the coil strands (holding wires) 70a and 70b are at substantially the same position in the circumferential direction of the tubular main body 10 excludes that the end points 71 face each other across the main lumen 20.
- the end points 71 are on the same side with respect to the main lumen 20 and are slightly displaced in the circumferential direction.
- the wall thickness of the sub tube 40 is smaller than both the holding wire 70 and the operation wire 60. Further, the wire diameter of the holding wire 70 is smaller than the wire diameter of the operation wire 60. Since the holding wire 70 has a small diameter and a small radius of curvature, when the holding wire 70 is fitted into the sub-tube 40 at a predetermined depth, the center angle of the holding wire 70 can be increased. . For this reason, extension of interfacial peeling can be prevented satisfactorily.
- the distal part DE of the tubular main body 10 is provided with a first marker 14 and a second marker 16 located on the proximal side of the first marker 14.
- the first marker 14 and the second marker 16 are ring-shaped members made of a material that does not transmit radiation such as X-rays such as platinum.
- the tip of the operation line 60 is fixed to a portion of the tubular main body 10 that is more distal than the second marker 16. By pulling the operation line 60, the distal portion of the distal portion DE with respect to the second marker 16 is bent. In the catheter 100 of this embodiment, the distal end portion of the operation line 60 is fixed to the first marker 14.
- the mode of fixing the operation line 60 to the first marker 14 is not particularly limited, and examples include solder bonding, thermal fusion, adhesion with an organic adhesive, and mechanical engagement between the operation line 60 and the first marker 14. Can do.
- the inner diameter of the second marker 16 is larger than the inner diameter of the first marker 14.
- the first marker 14 is disposed so as to be in contact with or substantially in contact with the outer surface of the wire reinforcing layer 30.
- the inner diameter of the first marker 14 is larger than the outer diameter of the wire reinforcing layer 30 and smaller than the inner diameter of the second reinforcing layer 80.
- the radial positional relationship between the inner wall surface and outer peripheral surface of the first marker 14 and the subtube 40 is not particularly limited. When the operation line 60 is fixed to the outer peripheral surface of the first marker 14, the outer peripheral surface of the first marker 14 is positioned inside (inner diameter side) the arrangement position of the tip of the subtube 40 as shown in FIG. 3.
- the outer diameter of the first marker 14 can be set.
- the end surface may overlap with the distal end of the subtube 40 in the radial direction.
- the outer peripheral surface of the first marker 14 may be located on the outer diameter side with respect to the arrangement position of the tip of the subtube 40.
- the second marker 16 is disposed so as to be in contact with or substantially in contact with the outer surface of the second reinforcing layer 80.
- the inner diameter of the second marker 16 is larger than the outer diameter of the second reinforcing layer 80.
- the distal end of the wire reinforcing layer 30 reaches the region where the first marker 14 is disposed.
- the arrangement region of the first marker 14 is a length region in which the first marker 14 is formed when viewed in the axial direction of the tubular main body 10. The same applies to the second marker 16.
- the distal end of the wire reinforcing layer 30 is located on the distal side of the tubular body 10 with respect to the proximal end of the first marker 14. Further, the distal end of the wire reinforcing layer 30 is located in the vicinity of the distal end of the first marker 14.
- the wire reinforcing layer 30 reaches the region where the first marker 14 is disposed, so that the discontinuity of the bending rigidity of the tubular body 10 at the proximal end of the first marker 14 is alleviated and the kink Occurrence is prevented.
- the distal end of the second reinforcing layer 80 is more proximal than the proximal end of the first marker 14 and more distal than the proximal end of the region where the second marker 16 is disposed.
- the distal end of the second reinforcing layer 80 is located in the vicinity of the distal end of the second marker 16. Thereby, a discontinuity is generated in the bending rigidity of the tubular body 10 at the distal end of the second marker 16. For this reason, when the operation line 60 is pulled, the tubular body 10 can be sharply bent slightly on the distal side of the second marker 16.
- the wire reinforcing layer 30 is continuously formed up to the region where the first marker 14 is disposed as described above, and thus the tubular body 10 is kinked. There is nothing. In other words, one of the wire reinforcing layer 30 and the second reinforcing layer 80 is continuously formed up to the vicinity of the distal end of the tubular body 10 to prevent kinking, and the other is terminated in the middle of the distal portion DE.
- the bending position is clearly defined by causing a discontinuity of bending rigidity in the main body 10.
- the proximal ends of the wire reinforcing layer 30 and the second reinforcing layer 80 are located at the proximal end of the tubular body 10, that is, inside the operation unit 90.
- the distal end of the inner layer 24 may reach the distal end of the tubular body 10 or may terminate on the proximal side of the distal end.
- the position where the inner layer 24 terminates may be inside the region where the first marker 14 is disposed.
- the wire reinforcing layer 30 is a blade layer
- the first outer layer 52 is impregnated from the periphery of the subtube 40 into the inside of the opening of the wire reinforcing layer 30, so that the inner layer 24, the wire reinforcing layer 30, and The sub-tube 40 is exemplified as being integrally fixed.
- the first outer layer 52 corresponding to the inner layer of the outer layer 50 may not be substantially impregnated between the wire reinforcing layer 30 and the subtube 40.
- the outer diameter of the subtube 40 may be larger than the opening dimension W in the circumferential direction of the wire reinforcing layer 30 represented by the above formula (2). And the opening just under the subtube 40 may be closed by the subtube 40, and there may be an opening which has the cavity part which the 1st outer layer 52 is not completely filled.
- the reinforcing wire 32, the holding wire 70, and the second reinforcing wire 82 are all illustrated as having a circular cross section, but these are not limited to a circular cross section, It may be a line such as an ellipse or a polygon in cross section.
- a hydrophilic layer (not shown) formed on the outer surface of the second outer layer 54 constitutes the outermost layer of the catheter 100.
- the hydrophilic layer may be formed over the entire length of the tubular body 10 or may be formed only in a partial length region on the tip side including the distal portion DE.
- the hydrophilic layer is made of, for example, a maleic anhydride polymer such as polyvinyl alcohol (PVA) or a copolymer thereof, or a hydrophilic resin material such as polyvinyl pyrrolidone.
- the typical dimension of the component of the catheter 100 of this embodiment is demonstrated.
- the diameter of the main lumen 20 can be 400 ⁇ m to 600 ⁇ m (including the upper limit value and the lower limit value; the same applies hereinafter), the inner layer 24 can have a thickness of 5 ⁇ m to 30 ⁇ m, and the outer layer 50 can have a thickness of 10 ⁇ m to 200 ⁇ m.
- the thickness of the sub-tube 40 is thinner than the inner layer 24 and can be 1 ⁇ m to 10 ⁇ m.
- the inner diameter of the wire reinforcing layer 30 is 410 ⁇ m to 660 ⁇ m
- the outer diameter of the wire reinforcing layer 30 is 450 ⁇ m to 740 ⁇ m
- the inner diameter of the second reinforcing layer 80 is 560 ⁇ m to 920 ⁇ m
- the outer diameter of the second reinforcing layer 80 is 600 ⁇ m to 940 ⁇ m.
- the inner diameter of the first marker 14 may be 450 ⁇ m to 740 ⁇ m
- the outer diameter of the first marker 14 may be 490 ⁇ m to 820 ⁇ m
- the inner diameter of the second marker 16 may be 600 ⁇ m to 940 ⁇ m
- the outer diameter of the second marker 16 may be 640 ⁇ m to 960 ⁇ m.
- the width dimension of the first marker 14 (the dimension in the longitudinal direction of the tubular body 10) can be 0.3 mm to 2.0 mm, and the width dimension of the second marker 16 can be 0.3 mm to 2.0 mm.
- the radius (distance) from the axis of the catheter 100 to the center of the subtube 40 can be 300 ⁇ m to 450 ⁇ m, the inner diameter (diameter) of the subtube 40 can be 40 ⁇ m to 100 ⁇ m, and the thickness of the operation line 60 can be 25 ⁇ m to 60 ⁇ m.
- the tubular body 10 has a diameter of 700 ⁇ m to 980 ⁇ m, that is, an outer diameter of less than 1 mm, and can be inserted into a blood vessel such as a celiac artery.
- FIG. 8 (a) is an overall side view of the catheter 100 of the present embodiment.
- FIG. 8B is an overall side view of the catheter 100 showing a state in which the wheel operation unit 92 is operated in one direction (clockwise in FIG. 8).
- FIG. 8C is an overall side view of the catheter 100 showing a state in which the wheel operation unit 92 is operated in the other direction (counterclockwise in FIG. 8).
- the catheter 100 has an operation unit 90 that is provided at the proximal end of the tubular main body 10 and that individually pulls a plurality of operation lines 60 (see FIGS. 1 to 3).
- the operation unit 90 includes a main body case 94 that is gripped by the user's hand, and a wheel operation unit 92 that is provided so as to be rotatable with respect to the main body case 94.
- the proximal end portion of the tubular main body 10 is introduced into the main body case 94.
- the two sub tubes 40 through which the operation line 60 is inserted branch from the tubular main body 10 inside the front end portion of the main body case 94.
- the base end portion of the operation line 60 drawn from each of the sub tubes 40 is connected to the wheel operation portion 92.
- one operation line 60 can be pulled to the proximal end side to apply tension, and the other can be loosened. Accordingly, the pulled operation line 60 bends at least a partial region of the distal portion DE of the catheter 100 (see FIGS. 8B and 8C).
- the bending of the tubular body 10 includes an aspect in which the tubular body 10 is bent in a “shape” and an aspect in which the tubular body 10 is curved in a bow shape.
- At least a partial region of the distal portion DE of the catheter 100 is included in the same plane. Can be selectively bent in the first or second direction.
- An uneven engagement portion is formed on the peripheral surface of the wheel operation portion 92.
- a vertical knurled waveform is illustrated.
- a recess 95 is formed in the main body case 94 at a position in contact with the wheel operation unit 92.
- the concave portion 95 is provided with a slider 98 that slides forward and backward toward the wheel operation portion 92.
- a protrusion 99 is formed at the tip of the slider 98 facing the wheel operation unit 92. The protrusion 99 is smaller than the opening width of the concave-convex engaging portion (vertical knurling) on the peripheral surface of the wheel operating portion 92.
- FIG. 8A shows a state in which the protrusion 99 of the slider 98 and the wheel operation unit 92 are not engaged and the wheel operation unit 92 can rotate.
- 8B and 8C the protrusion 99 of the slider 98 and the wheel operation portion 92 are engaged to restrict the rotation of the wheel operation portion 92, and the bent state of the distal portion DE is maintained. Indicates the state.
- Rotating the operation unit 90 about the axis of the tubular body 10 allows the distal portion DE of the tubular body 10 to be torque-rotated at a predetermined angle.
- the direction of the distal portion DE of the catheter 100 can be freely controlled.
- the catheter 100 includes a hub 96 provided in communication with the main lumen 20 of the tubular body 10.
- a syringe (not shown) is attached to the hub 96.
- the hub 96 is provided at the rear end of the main body case 94, and a syringe is mounted from the rear of the hub 96 (right side in FIG. 8A).
- the drug solution or the like can be supplied into the body cavity of the patient via the main lumen 20.
- the chemical solution include a contrast agent, a liquid anticancer agent, physiological saline, and NBCA (n-butyl-2-cyanoacrylate) used as an instantaneous adhesive.
- medical devices such as embolization coils and beads (emboli globular material) are not limited to liquids.
- FIG. 9 is a longitudinal sectional view of the inner structure 26 in which the inner layer 24 and the wire reinforcing layer 30 are formed around the main core wire 22.
- FIG. 10 is a side view of the cored tube 46 in which the subtube 40 is formed around the subcore wire 44.
- FIG. 11 is a perspective view schematically showing the winding process of the holding wire 70.
- FIG. 12 is a side view showing a state in which the second reinforcing wire 82 is wound around the sub-tube 40.
- This manufacturing method includes an inner structure preparation step, a sub tube holding step, a main body forming step, a sub core wire extraction step, and a main core wire extraction step.
- the inner structure preparation step is a step of preparing the inner structure 26 including the main core wire 22 and the wire reinforcing layer 30 in which the reinforcing wire 32 is wound around the main core wire 22.
- the sub-core wire 44 covered with the resin sub-tube 40 is disposed on the outer peripheral surface of the wire reinforcing layer 30 along the main core wire 22, and the holding wire 70 is pressed against the surface of the sub-tube 40.
- the sub-tube 40 and the wire reinforcing layer 30 are wound together by the holding wire 70 while being bitten.
- the main body forming step is a step of forming the tubular main body 10 so as to include the sub-tube 40, the wire reinforcing layer 30, and the holding wire 70 that are wound together.
- the sub-core wire extracting step is a step of forming the sub-lumen 42 by extending and reducing the diameter of the sub-core wire 44 and separating it from the sub-tube 40.
- the main core wire extraction step is a step of forming the main lumen 20 by extracting the main core wire 22 from the tubular body 10.
- the inner layer 24 is formed around the main core wire 22.
- the main core wire 22 is a mandrel (core material), and is a wire material having a circular cross section that defines the main lumen 20.
- the material of the main core wire 22 is not particularly limited, but a copper or copper alloy wire material plated with silver can be used. In addition, stainless steel can be used as the material of the main core wire 22.
- the inner layer 24 can be formed by dipping the main core wire 22 in a coating liquid in which a fluorine-based polymer such as polytetrafluoroethylene (PTFE) is dispersed in a solvent and then drying.
- PTFE polytetrafluoroethylene
- a multi-strand reinforcing wire 32 is braided into a mesh shape on the outer surface of the inner layer 24 to form the wire reinforcing layer 30.
- the ring-shaped first marker 14 is caulked and fixed around the tip of the reinforcing wire 32, and then the reinforcing wire 32 is excised on the distal side of the first marker 14.
- the inner structure 26 is produced.
- the cored tube 46 shown in FIG. 10 is manufactured simultaneously with the inner structure preparation step or before and after the inner structure preparation step.
- the sub tube 40 is formed on the peripheral surface of the sub core wire 44.
- the secondary core wire 44 is a wire having a circular cross section that defines the secondary lumen 42.
- the material of the sub-core wire 44 is not particularly limited, but a metal material having a higher strength than the main core wire 22, such as stainless steel, can be used.
- the sub-core wire 44 has a smaller diameter than the main core wire 22.
- the sub-core wire 44 can be suitably peeled off from the sub-tube 40 by extending and reducing the diameter without breaking the sub-core wire 44 in the sub-core wire removing step.
- the wall thickness of the subtube 40 is preferably thinner than the inner layer 24.
- the subtube 40 is made of a fluorine-based polymer such as polytetrafluoroethylene (PTFE)
- the subtube 40 can be formed by dipping the subcore wire 44 in a coating liquid in which the polymer is dispersed in a solvent and then drying it.
- the core tube 46 is produced by covering the periphery of the sub-core wire 44. Also good.
- the sub-core wire 44 is disposed on the outer peripheral surface of the wire reinforcing layer 30 along the main core wire 22 and is wound together with the holding wire 70.
- the timing at which the sub-core wire 44 is arranged along the main core wire 22 and the timing at which the sub-core wire 44 and the main core wire 22 are wound together by the holding wire 70 are substantially the same.
- a plurality of (four in the present manufacturing method) cored tubes 46 are sent out along the inner structure 26 through the through holes 112 of the insertion jig 110, and a plurality of winder devices 120 are disposed around the cored tubes 46.
- the bobbin heads 122 are rotated in the same direction.
- a holding wire 70 is wound around the bobbin head 122.
- the insertion jig 110 is formed with a main through hole 114 through which the inner structure 26 is inserted.
- Four through holes 112 are formed at regular intervals around the main through hole 114.
- the main core wire 22 exposed at the front end of the inner structure 26 and the sub core wires 44 exposed at the front ends of a plurality of (four in the present manufacturing method) cored tubes 46 are integrated by a jig (not shown). It is fixed to. In this state, the bobbin head 122 is rotated while pushing the inner structure 26 and the cored tube 46 at a predetermined feed speed with the first marker 14 facing the tip side (upward in FIG. 11). As a result, the holding wire 70 is wound around the wire reinforcing layer 30 and the subtube 40 in a coil shape. By adjusting the feed speed of the inner structure 26 and the cored tube 46 and the rotational speed of the bobbin head 122, the winding pitch of the holding wire 70 can be increased or decreased.
- the holding wire 70 is spirally wound while periodically changing the winding tension of the holding wire 70 with respect to the subtube 40.
- the method for periodically changing the winding tension of the holding wire 70 is not limited to one.
- a plurality of bobbin heads 122 are evenly arranged around the inner structure 26 and then the inner structure 26 is periodically eccentric by an external force, and the plurality of bobbin heads 122 are connected to the inner structure.
- a second method of eccentrically arranging around 26 is illustrated.
- the first method is characterized in that, in the sub-tube holding step in which the holding wire 70 is wound together, the inner structure 26 is wound together with the holding wire 70 while being eccentric relative to the sub-core wire 44 in the radial direction. .
- the four sub-core wires 44 are arranged around the wire reinforcing layer 30 so as to face each other at intervals of 90 degrees.
- positioning the three subcore wires 44 it is good to make it face 120 degree
- the positions of the plural (two) bobbin heads 122 are selected so that the winding points 74 of the multiple (two) holding wires 70 are rotationally symmetrical around the wire reinforcing layer 30. Thereby, the individual winding tension of the multiple holding wires 70 is offset.
- the inner structure 26 is forcibly decentered to make the insertion depths D of the multiple holding wires 70 different from each other.
- a gripping tool 126 is mounted around the inner structure 26.
- the gripping tool 126 slidably holds the inner structure 26 that is pushed out at a predetermined feed speed through the main through hole 114.
- One or both of the gripping tool 126 and the insertion jig 110 is driven so as to relatively move in the radial direction of the inner structure 26 by a driving unit (not shown).
- 11 illustrates a state in which the gripping tool 126 is provided apart from the insertion jig 110 in the feeding direction of the inner structure 26, the gripping tool 126 is integrated with the insertion jig 110. It may be provided.
- the drive unit reciprocally swings the gripping tool 126 in a direction connecting the pair of sub tubes 40 facing each other by 180 degrees.
- the swing cycle is set different from the rotation cycle of the bobbin head 122 or an integral multiple of the rotation cycle.
- the oscillation cycle may be variable.
- region L1b with small insertion depth D is formed in the 2nd subtube 40b.
- a second length region L2b having a large insertion depth D is formed in the second sub-tube 40b. Is done.
- region L1a with small insertion depth D is formed in the 1st subtube 40a in the same position of an axial center direction.
- the inner structure 26 is reciprocally swung, but the present invention is not limited to this.
- the inner structure 26 may be rotated and oscillated along the periphery of the main through hole 114. That is, the eccentric inner structure 26 may be rotated so that the axis of the inner structure 26 (main core wire 22) draws a circle smaller than the main through hole 114.
- the first length region L1 and the second length region L2 can be formed equally for all the subtubes 40 (four in this manufacturing method).
- the plurality of bobbin heads 122 around which the multiple holding wires 70 are wound are rotated in a state where they are arranged asymmetrically around the inner structure 26 (not shown).
- the positional relationship between the two bobbin heads 122 is 120 degrees or more and less than 180 degrees at the central angle with the inner structure 26 as the center. be able to.
- the bobbin head 122 is too close, the resultant force of the winding tension causes the inner structure 26 to be excessively decentered.
- the structure 26 can be periodically eccentric.
- the oscillation period of the inner structure 26 may be changed in one tubular body 10 by the first method and the second method.
- region L2 which are repeated can be changed according to the distance from the front-end
- FIG. As an example, the length of the first length region L1 and the second length region L2 is shortened in the distal portion DE, and the length of the first length region L1 and the second length region L2 is shortened in the middle portion and the proximal portion. It is good to lengthen the length. Thereby, the adhesiveness of the subtube 40 and the outer layer 50 in the distal part DE which bends notably when the operation line 60 is pulled can be improved favorably.
- the sub-core wire 44 is wound around the main core wire 22 while being sent out, but the present invention is not limited to the above.
- the sub-core wire 44 and the main core wire 22 may be wound together by the holding wire 70 after the substantially entire length of the sub-core wire 44 is temporarily fixed to the main core wire 22 with a jig or the like in advance.
- an outer layer is formed so as to enclose the inner structure 26, the cored tube 46, and the holding wire 70 (hereinafter, “structure”), and the tubular main body 10 is formed.
- first outer layer 52 is formed around the structure.
- the first outer layer 52 may be formed by coating extrusion in which a molten resin material is applied to the surface of the structure.
- a resin ring or resin tube formed in an annular shape or a tubular shape in advance may be attached around the structure, and then heat-formed using a heat-shrinkable tube or the like.
- the first outer layer 52 embeds the subtube 40 and the holding wire 70 fitted therein. As a result, the holding wire 70 anchors both the first outer layer 52 and the subtube 40.
- the 2nd reinforcement wire 82 is braided around the subtube 40 embed
- the second marker 16 is caulked and fixed around the tip of the second reinforcing layer 80
- the second reinforcing wire 82 is excised on the distal side of the second marker 16.
- a second outer layer 54 (see FIG. 1) is formed so as to cover the second reinforcing layer 80 and the second marker 16.
- the second outer layer 54 may be formed by coating extrusion in which a molten resin material is applied and formed on the surface of the second reinforcing layer 80, or a resin ring or resin tube previously formed in an annular shape or a tubular shape is used as the structure. You may heat-shape after mounting around.
- the sub-core wire 44 is stretched to be reduced in diameter and peeled off from the sub-tube 40.
- the operation line 60 is inserted into some or all of the sub-tubes 40 out of the plurality.
- the operation line 60 is inserted only into the pair of first sub-tube 40a and second sub-tube 40b facing each other by 180 degrees, and the operation line 60 is not inserted into the other two sub-tubes 40.
- the sub core wire 44 having a reduced diameter may be used as the operation line 60 without being removed from the sub tube 40.
- the operation line 60 having a sufficiently small diameter compared to the inner diameter of the sub tube 40 is used, After the core wire 44 is removed, a different operation line 60 may be inserted into the sub-tube 40.
- the main core wire 22 is extracted from the tubular body 10 to form the main lumen 20.
- the sub core wire extraction step and the main core wire extraction step may be performed simultaneously, or the main core wire extraction step may be performed after the sub core wire extraction step is performed first.
- the main core wire 22 is inserted into the main lumen 20
- expansion deformation of the tubular body 10 is suppressed. Therefore, when the sub core wire 44 is extended in the sub core wire extraction process, the sub core wire 44 follows. And the subtube 40 does not extend. For this reason, the sub-core wire 44 which is smaller in diameter than the main core wire 22 and easily breaks can be satisfactorily extracted from the sub-tube 40.
- a hydrophilic layer (not shown) is further formed on the surface of the second outer layer 54, and the operation unit 90 is attached to the proximal end portion of the tubular main body 10. As described above, the catheter 100 can be obtained.
- the various components of the present invention do not have to be individually independent, that a plurality of components are formed as one member, and one 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.
- a long inner layer defining a main lumen, a wire reinforcing layer formed by winding a reinforcing wire around the inner layer, and extending outside the wire reinforcing layer along the longitudinal direction of the main lumen.
- a long resin-made subtube defining a sub-lumen having a smaller diameter than the main lumen, and a resin-made outer layer containing the wire reinforcing layer and the subtube.
- An operation portion to be bent, and the tubular main body further includes a holding wire that is enclosed in the outer layer and winds the subtube and the wire reinforcing layer together, and the holding wire is disposed on the outer diameter side of the subtube. It is characterized by being fitted on the peripheral surface Medical equipment.
- the medical device according to the above (1) which is arranged side by side in the axial direction of the tubular main body.
- the operation line is inserted through the first sub-tube and the second sub-tube opposed to each other, and the first sub-tube and the second sub-tube each have the first length.
- the medical device according to (3) or (4), wherein the medical device has a region and the second length region.
- the first length region included in the first subtube and the first length region included in the second subtube are present at different positions in the axial direction.
- the medical device as described in 5).
- the first length region of the first subtube and the second length region of the second subtube are present at the same position in the axial direction, The above (6) or (7), wherein the second length region of the subtube and the first length region of the second subtube are present at the same position in the axial direction.
- the holding wire is a multi-strand coil in which a coil wire is wound in a multi-strand.
- the length in the axial direction of the first length region and the second length region is equal to a winding pitch of the coil element wire or is an integral multiple of the winding pitch.
- the marker portion made of a radiopaque material is provided at the distal portion of the tubular body, and the distal end of the holding wire is bonded and fixed to the proximal end side of the marker portion with an adhesive.
- the wire reinforcing layer is formed by braiding a plurality of reinforcing wires, and the adhesive is filled inside a plurality of openings adjacent to the proximal end side of the marker portion in the wire reinforcing layer.
- the holding wire is formed by winding a plurality of coil strands, and the tips of the plurality of coil strands are bonded and fixed to the adhesive at substantially the same position in the circumferential direction of the tubular body.
- 17.) The medical device according to (15) or (16), wherein the plurality of openings are adjacent to each other to form a non-circular region in the wire reinforcing layer.
- the medical device further includes a hub provided in communication with the main lumen and to which a syringe is attached.
- a sub core wire is arranged on the outer peripheral surface of the wire reinforcing layer along the main core wire, and the holding tube is pressed against the surface of the sub tube and the sub tube and the wire reinforcing layer are shared by the holding wire.
- a method for manufacturing a medical device comprising: a step of separating from a tube to form a secondary lumen; and a step of removing the main core wire from the tubular body to form a main lumen.
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Abstract
The purpose of the present invention is to provide a medical device in which a sub-tube into which an operating wire is inserted can be fixed to a tubular shape, without separation. The catheter (100) of the present invention is provided with a long tubular body (10), the operating wire (60), and an operating unit (90). The tubular body (10) includes: a long inner layer (24) that demarcates a main tubular cavity (20); a wire-reinforced layer (30) formed around the inner layer (24) by coiled reinforcing wire (32); the resin sub-tube (40) that is positioned on the outside of the wire-reinforced layer (30) so as to extend along the length direction of the main tubular cavity (20), and demarcates a sub-tubular cavity (42) having a smaller diameter than the main tubular cavity (20); a resin outer layer (50) that envelopes the wire-reinforced layer (30) and the sub-tube (40); and a supporting wire (70). The operating wire (60) is passed through the inside of the sub-tubular cavity (42) such that movement is possible, and the tip is connected to a distal part of the tubular body (10). The support wire (70) is enveloped by the outer layer (50) and is wound around both the sub-tube (40) and the wire-reinforced layer (30). The support wire (70) is fitted to the outer-radial side peripheral surface of the sub-tube.
Description
本発明は、医療用機器および医療用機器の製造方法に関する。
本願は、2013年3月27日に、日本に出願された特願2013-067082号に基づき優先権を主張し、その内容をここに援用する。 The present invention relates to a medical device and a method for manufacturing the medical device.
This application claims priority on March 27, 2013 based on Japanese Patent Application No. 2013-067082 filed in Japan, the contents of which are incorporated herein by reference.
本願は、2013年3月27日に、日本に出願された特願2013-067082号に基づき優先権を主張し、その内容をここに援用する。 The present invention relates to a medical device and a method for manufacturing the medical device.
This application claims priority on March 27, 2013 based on Japanese Patent Application No. 2013-067082 filed in Japan, the contents of which are incorporated herein by reference.
カテーテルや内視鏡など、体腔内に媒体や機器を導入する種々の長尺の医療用機器が知られている。近年、内視鏡のみならずカテーテルに関しても、遠位端部を屈曲させることにより体腔への進入方向が操作可能なものが提供されている。
Various long medical devices that introduce media and devices into body cavities such as catheters and endoscopes are known. In recent years, not only endoscopes but also catheters have been provided that can manipulate the direction of entry into a body cavity by bending the distal end.
たとえば、特許文献1には、内層により画定される中央内腔(主管腔:メインルーメン)の周囲に、これよりも細径の2つのワイヤ内腔(副管腔:サブルーメン)を180度対向して設けたカテーテルが記載されている。このサブルーメンの内部には変向ワイヤ(以下、操作線という)が挿通されており、基端側の作動ハンドルを操作して操作線を牽引することによりカテーテルの先端が曲がるようになっている。
For example, in Patent Document 1, two wire lumens (sublumen: sublumen) having a smaller diameter are opposed 180 degrees around a central lumen (main lumen: main lumen) defined by the inner layer. The catheter provided is described. A deflection wire (hereinafter referred to as an operation line) is inserted into the sub-lumen, and the distal end of the catheter is bent by pulling the operation line by operating the operation handle on the proximal end side. .
特許文献1のカテーテルにおいては、ワイヤ内腔(以下、副管腔という)を画定する2本のポリマーチューブ(以下、サブチューブという)を、フッ素系樹脂材料などからなる薄い内層の外面に沿って敷設し、このサブチューブの内部に操作線が挿通されている。特許文献1において管状本体(シース)の外層を成形するにあたっては、ワイヤ内腔の内部に加圧流体を注入しておき、管状本体の外層の熱成形の際にワイヤ内腔に負荷される圧縮力に抗して内径を維持することとしている。
In the catheter of Patent Document 1, two polymer tubes (hereinafter referred to as subtubes) that define a wire lumen (hereinafter referred to as sublumen) are arranged along the outer surface of a thin inner layer made of a fluorine-based resin material or the like. An operation line is inserted through the subtube. In forming the outer layer of the tubular body (sheath) in Patent Document 1, a pressurized fluid is injected into the inside of the wire lumen, and compression is applied to the wire lumen when the outer layer of the tubular body is thermoformed. The inner diameter is maintained against the force.
しかしながら、管状本体の外層の熱成形時に負荷される圧縮力は大きいため、これを十分に相殺するほど加圧流体の圧力を高めることは困難である。また、管状本体が圧縮される前に僅かでも早く加圧流体によりサブチューブの内圧を高めてしまうとサブチューブが破裂してしまうなど、特許文献1の方法を実施することは困難を伴う。そして、管状本体の外層の熱成形時に負荷する圧縮力を小さくした場合には、サブチューブと管状本体の外層との接着不良が生じ、管状本体を屈曲させたときにサブチューブが剥離する虞がある。操作線を牽引して管状本体を屈曲させたときサブチューブは軸心から偏心して屈曲の外側または内側に位置するため、近位端から遠位端までの経路長が軸心とは相違することとなり、管状本体の外層とサブチューブとの界面に剪断力が生じるからである。
However, since the compressive force applied during the thermoforming of the outer layer of the tubular body is large, it is difficult to increase the pressure of the pressurized fluid enough to offset this. In addition, it is difficult to implement the method of Patent Document 1 such that if the internal pressure of the sub-tube is increased by the pressurized fluid just before the tubular body is compressed, the sub-tube bursts. If the compressive force applied during thermoforming of the outer layer of the tubular body is reduced, poor adhesion between the subtube and the outer layer of the tubular body may occur, and the subtube may peel off when the tubular body is bent. is there. When the operation line is pulled to bend the tubular body, the sub-tube is eccentric from the axis and located outside or inside the bend, so the path length from the proximal end to the distal end is different from the axis This is because a shearing force is generated at the interface between the outer layer of the tubular body and the subtube.
なお、ここではカテーテルを例示して説明したが、同様の課題はカテーテルに限らず操作線で操作を行なう医療用機器の全般において生じる課題である。
In addition, although the catheter was illustrated and demonstrated here, the same subject is a subject which arises in general of the medical device which operates not only with a catheter but with an operation line.
本発明は上記課題に鑑みてなされたものであり、操作線を挿通するためのサブチューブを容易に管状本体に対して剥離なく固定し得る医療用機器、およびその製造方法を提供するものである。
The present invention has been made in view of the above problems, and provides a medical device that can easily fix a sub-tube through which an operation line is inserted to a tubular body without peeling, and a method for manufacturing the medical device. .
本発明によれば、主管腔を画定する長尺の内層と、前記内層の周囲に補強ワイヤを巻回してなるワイヤ補強層と、前記ワイヤ補強層の外側に前記主管腔の長手方向に沿って延在するように配置され、前記主管腔よりも小径の副管腔を画定する樹脂製のサブチューブと、前記ワイヤ補強層および前記サブチューブを内包する樹脂製の外層と、を含む長尺の管状本体と、前記副管腔の内部に移動可能に挿通され先端が前記管状本体の遠位部に接続された操作線と、前記操作線を牽引操作して前記管状本体の前記遠位部の少なくとも一部領域を屈曲させる操作部と、を備え、前記管状本体がさらに、前記外層に内包され前記サブチューブと前記ワイヤ補強層とを共巻きする保持ワイヤを含み、前記保持ワイヤが前記サブチューブの外径側の周面に嵌入していることを特徴とする医療用機器が提供される。
According to the present invention, a long inner layer that defines a main lumen, a wire reinforcing layer formed by winding a reinforcing wire around the inner layer, and a longitudinal direction of the main lumen outside the wire reinforcing layer. A resin-made subtube that is arranged to extend and defines a sub-lumen having a smaller diameter than the main lumen; and a resin-made outer layer that encloses the wire reinforcing layer and the subtube. A tubular body, an operation line that is movably inserted into the sub-lumen and has a tip connected to a distal portion of the tubular body, and pulling the operation line to pull the distal portion of the tubular body An operation portion that bends at least a part of the region, and the tubular body further includes a holding wire that is included in the outer layer and winds the subtube and the wire reinforcing layer together, and the holding wire is the subtube. On the outer diameter side of the Medical equipment, characterized in that by entering is provided.
上記の医療用機器によれば、操作線を挿通するサブチューブとワイヤ補強層とを共巻きする保持ワイヤが、サブチューブの外径側の周面に嵌入した状態で外層に内包されている。このため、保持ワイヤがサブチューブおよび外層の双方に対してアンカーとなるため、サブチューブと外層との剥離が防止される。
According to the medical device described above, the holding wire that co-winds the sub-tube through which the operation line is inserted and the wire reinforcing layer is included in the outer layer in a state of being fitted to the outer peripheral surface of the sub-tube. For this reason, since a holding | maintenance wire becomes an anchor with respect to both a subtube and an outer layer, peeling with a subtube and an outer layer is prevented.
さらに、本発明によれば、長尺の主芯線と、前記主芯線の周囲に補強ワイヤを巻回したワイヤ補強層と、を含む内側構造体を準備する工程と、樹脂製のサブチューブで被覆された長尺の副芯線を前記主芯線に沿って前記ワイヤ補強層の外周表面に配置し、保持ワイヤを前記サブチューブの表面に押圧して食い込ませながら前記サブチューブと前記ワイヤ補強層とを前記保持ワイヤで共巻きする工程と、共巻きされた前記ワイヤ補強層および前記ワイヤ補強層ならびに前記保持ワイヤを内包するように外層を形成し、管状本体とする工程と、前記副芯線を伸張および縮径させて前記サブチューブから剥離させて副管腔を形成する工程と、前記主芯線を前記管状本体から抜去して主管腔を形成する工程と、を含む医療用機器の製造方法が提供される。
Furthermore, according to the present invention, a step of preparing an inner structure including a long main core wire and a wire reinforcing layer in which a reinforcing wire is wound around the main core wire, and covering with a resin subtube The elongated sub-core wire is disposed on the outer peripheral surface of the wire reinforcing layer along the main core wire, and the holding tube is pressed against the surface of the sub-tube and the sub-tube and the wire reinforcing layer are A step of co-winding with the holding wire; a step of forming an outer layer so as to enclose the wire-reinforced layer and the wire-reinforcing layer and the holding wire which are co-wound to form a tubular body; There is provided a method for manufacturing a medical device including a step of reducing the diameter and separating from the sub-tube to form a sub-lumen, and a step of removing the main core wire from the tubular body to form a main lumen. That.
本発明によれば、医療用機器において操作線を挿通するためのサブチューブを、保持ワイヤにより容易に、管状本体に対して剥離なく固定することが可能である。
According to the present invention, it is possible to easily fix the sub-tube for inserting the operation line in the medical device to the tubular main body without peeling with the holding wire.
以下、本発明の実施形態を図面に基づいて説明する。なお、すべての図面において、同様の構成要素には同一符号を付し、その詳細な説明は重複しないように適宜省略する。また、特徴部分を明示するため、すべての図面において縮尺は実際の態様と必ずしも一致しておらず、各図の間でも縮尺は異なる。
Hereinafter, embodiments 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 detailed description thereof is omitted as appropriate so as not to overlap. Further, in order to clearly show the characteristic portion, the scale is not necessarily the same as the actual mode in all the drawings, and the scale is different between the drawings.
図1から図8を参照して、本実施形態の医療用機器の概要について説明する。図1は、カテーテル100の先端部近傍を長手方向に対して垂直に切った断面図(横断面図)である。図2は、保持ワイヤ70およびサブチューブ40の拡大断面図である。図3は、カテーテル100の先端部近傍を長手方向に沿って切った断面図(縦断面図)であり、第一外層52及び第二外層54を簡略化して外層50としてまとめて図示している。また、図1は図3のIII-III線断面図である。図4はサブチューブ40の第一長さ領域L1および第二長さ領域L2を模式的に示す縦断面図であり、内層24、ワイヤ補強層30、第二補強層80および第二マーカー16は図示省略している。また、図4では第一外層52及び第二外層54は簡略化して外層50としてまとめて図示している。図5(a)は、図4のV-V線で示す部分断面図であり、第一のサブチューブ40aの第一長さ領域L1aに関する横断面図である。図5(b)は図4のV-V線で示す部分断面図であり、第二のサブチューブ40bの第二長さ領域L2bに関する横断面図である。図6(a)は、図4のVI-VI線で示す部分断面図であり、第一のサブチューブ40aの第二長さ領域L2aに関する横断面図である。図6(b)は図4のVI-VI線で示す部分断面図であり、第二のサブチューブ40bの第一長さ領域L1bに関する横断面図である。図8に関しては後述する。
The outline of the medical device of the present embodiment will be described with reference to FIGS. FIG. 1 is a cross-sectional view (transverse cross-sectional view) in which the vicinity of the distal end portion of the catheter 100 is cut perpendicularly to the longitudinal direction. FIG. 2 is an enlarged cross-sectional view of the holding wire 70 and the subtube 40. FIG. 3 is a cross-sectional view (longitudinal cross-sectional view) in which the vicinity of the distal end portion of the catheter 100 is cut in the longitudinal direction, and the first outer layer 52 and the second outer layer 54 are simplified and collectively shown as the outer layer 50. . 1 is a cross-sectional view taken along line III-III in FIG. FIG. 4 is a longitudinal sectional view schematically showing the first length region L1 and the second length region L2 of the subtube 40. The inner layer 24, the wire reinforcing layer 30, the second reinforcing layer 80, and the second marker 16 are shown in FIG. The illustration is omitted. In FIG. 4, the first outer layer 52 and the second outer layer 54 are simplified and collectively shown as the outer layer 50. FIG. 5A is a partial cross-sectional view taken along line VV of FIG. 4, and is a cross-sectional view regarding the first length region L1a of the first subtube 40a. FIG. 5B is a partial cross-sectional view taken along line VV in FIG. 4, and is a cross-sectional view regarding the second length region L2b of the second sub-tube 40b. FIG. 6A is a partial cross-sectional view taken along line VI-VI in FIG. 4, and is a cross-sectional view regarding the second length region L2a of the first subtube 40a. FIG. 6B is a partial cross-sectional view taken along line VI-VI in FIG. 4, and is a cross-sectional view regarding the first length region L1b of the second sub-tube 40b. FIG. 8 will be described later.
本実施形態では、医療用機器としてカテーテル100を例示する。本発明はカテーテル100のほか、操作線60を牽引して遠位部DEの少なくとも一部領域を屈曲させることができる内視鏡その他の医療用機器に適用することができる。
なお、本発明において先端(部)又は遠位端(部)とは、管状本体10の操作部90と接続された側とは反対側の末端(部)を意味し、遠位部DE(先端部)とは先端(遠位端)を含む一定領域を意味する。 In this embodiment, thecatheter 100 is illustrated as a medical device. In addition to the catheter 100, the present invention can be applied to endoscopes and other medical devices that can bend at least a partial region of the distal portion DE by pulling the operation line 60.
In the present invention, the tip (part) or the distal end (part) means the end (part) opposite to the side connected to theoperation part 90 of the tubular body 10, and the distal part DE (tip). (Part) means a certain region including the tip (distal end).
なお、本発明において先端(部)又は遠位端(部)とは、管状本体10の操作部90と接続された側とは反対側の末端(部)を意味し、遠位部DE(先端部)とは先端(遠位端)を含む一定領域を意味する。 In this embodiment, the
In the present invention, the tip (part) or the distal end (part) means the end (part) opposite to the side connected to the
本実施形態のカテーテル100は、長尺の管状本体10、操作線60、及び操作部90を備えている。管状本体10は、主管腔20を画定する長尺の内層24と、主管腔20(内層24)の周囲に補強ワイヤ32を巻回してなるワイヤ補強層30と、このワイヤ補強層30の外側に主管腔20の長手方向に延在するように配置され、主管腔20よりも小径の副管腔42を画定する樹脂製の長尺なサブチューブ40と、ワイヤ補強層30およびサブチューブ40を内包する樹脂製の外層50と、保持ワイヤ70とを含む。操作線60は、副管腔42の内部に移動可能に挿通され先端が管状本体10の遠位部DEに接続されている。操作部90は、操作線60を牽引操作して管状本体10の遠位部DEの少なくとも一部領域を屈曲させる。保持ワイヤ70は、外層50に内包され、サブチューブ40とワイヤ補強層30とを共巻きしている。
本実施形態のカテーテル100は、保持ワイヤ70が、サブチューブ40の外径側の周面に嵌入していることを特徴とする。 Thecatheter 100 of the present embodiment includes a long tubular body 10, an operation line 60, and an operation unit 90. The tubular body 10 includes a long inner layer 24 that defines the main lumen 20, a wire reinforcing layer 30 formed by winding a reinforcing wire 32 around the main lumen 20 (inner layer 24), and an outer side of the wire reinforcing layer 30. It is arranged so as to extend in the longitudinal direction of the main lumen 20, and includes a long resin-made subtube 40 that defines a sublumen 42 having a smaller diameter than the main lumen 20, and includes the wire reinforcing layer 30 and the subtube 40. A resin outer layer 50 and a holding wire 70. The operation line 60 is movably inserted into the sub-lumen 42 and has a distal end connected to the distal portion DE of the tubular body 10. The operation unit 90 pulls the operation line 60 to bend at least a partial region of the distal portion DE of the tubular body 10. The holding wire 70 is included in the outer layer 50 and winds the sub-tube 40 and the wire reinforcing layer 30 together.
Thecatheter 100 of this embodiment is characterized in that the holding wire 70 is fitted into the outer peripheral surface of the sub-tube 40.
本実施形態のカテーテル100は、保持ワイヤ70が、サブチューブ40の外径側の周面に嵌入していることを特徴とする。 The
The
以下、本実施形態を詳細に説明する。本実施形態のカテーテル100は、管状本体10を血管内に挿通させて用いられる血管内カテーテルである。
Hereinafter, this embodiment will be described in detail. The catheter 100 of this embodiment is an intravascular catheter that is used by inserting the tubular body 10 into a blood vessel.
管状本体10はシースとも呼ばれ、内部に主管腔(メインルーメン)20が通孔形成された中空管状かつ長尺の部材である。より具体的には、管状本体10は、肝臓の8つの亜区域の何れにも進入させることが可能な外径および長さに形成されている。
The tubular main body 10 is also called a sheath, and is a hollow tubular and long member having a main lumen 20 formed therein. More specifically, the tubular body 10 is formed with an outer diameter and a length that allow entry into any of the eight sub-regions of the liver.
管状本体10は積層構造を有している。主管腔20を中心に、内径側から順に内層24、第一外層52および第二外層54が積層されて管状本体10の主要部は構成されている。第二外層54の外表面には親水層(図示せず)が形成されている。内層24、第一外層52および第二外層54は、可撓性の樹脂材料からなり、それぞれ円環状で略均一の厚みを有している。第一外層52および第二外層54を併せて外層50と呼称する場合がある。
The tubular body 10 has a laminated structure. An inner layer 24, a first outer layer 52, and a second outer layer 54 are laminated in this order from the inner diameter side with the main lumen 20 as the center, and the main part of the tubular body 10 is configured. A hydrophilic layer (not shown) is formed on the outer surface of the second outer layer 54. The inner layer 24, the first outer layer 52, and the second outer layer 54 are made of a flexible resin material, and each has an annular shape and a substantially uniform thickness. The first outer layer 52 and the second outer layer 54 may be collectively referred to as the outer layer 50.
内層24は管状本体10の最内層であり、その内壁面により主管腔20を画定する。主管腔20の横断面形状は特に限定されないが、本実施形態では円形である。横断面円形の主管腔20の場合、その直径は、管状本体10の長手方向に亘って均一でもよく、または長手方向の位置により相違してもよい。たとえば、管状本体10の一部または全部の長さ領域において、先端から基端に向かって主管腔20の直径(管腔)が連続的に拡大するテーパー状とすることができる。
内層24の材料は、例えば、フッ素系の熱可塑性ポリマー材料を挙げることができる。このフッ素系の熱可塑性ポリマー材料としては、具体的には、ポリテトラフルオロエチレン(PTFE)、ポリビニリデンフルオライド(PVDF)およびペルフルオロアルコキシフッ素樹脂(PFA)を挙げることができる。内層24をこのようなフッ素系ポリマー材料で構成することにより、主管腔20を通じて薬液等を供給する際のデリバリー性が良好となる。また、主管腔20にガイドワイヤーを挿通する場合に、ガイドワイヤーの摺動抵抗が低減される。 Theinner layer 24 is the innermost layer of the tubular body 10, and the main lumen 20 is defined by the inner wall surface thereof. The cross-sectional shape of the main lumen 20 is not particularly limited, but is circular in this embodiment. In the case of the main lumen 20 having a circular cross section, the diameter may be uniform over the longitudinal direction of the tubular body 10 or may vary depending on the position in the longitudinal direction. For example, in a part or all of the length region of the tubular main body 10, the diameter (lumen) of the main lumen 20 can be continuously tapered from the distal end toward the proximal end.
Examples of the material of theinner layer 24 include a fluorine-based thermoplastic polymer material. Specific examples of the fluorine-based thermoplastic polymer material include polytetrafluoroethylene (PTFE), polyvinylidene fluoride (PVDF), and perfluoroalkoxy fluororesin (PFA). By configuring the inner layer 24 with such a fluorine-based polymer material, the delivery property when supplying a drug solution or the like through the main lumen 20 is improved. Further, when the guide wire is inserted into the main lumen 20, the sliding resistance of the guide wire is reduced.
内層24の材料は、例えば、フッ素系の熱可塑性ポリマー材料を挙げることができる。このフッ素系の熱可塑性ポリマー材料としては、具体的には、ポリテトラフルオロエチレン(PTFE)、ポリビニリデンフルオライド(PVDF)およびペルフルオロアルコキシフッ素樹脂(PFA)を挙げることができる。内層24をこのようなフッ素系ポリマー材料で構成することにより、主管腔20を通じて薬液等を供給する際のデリバリー性が良好となる。また、主管腔20にガイドワイヤーを挿通する場合に、ガイドワイヤーの摺動抵抗が低減される。 The
Examples of the material of the
外層50は、管状本体10の主要な肉厚を構成する。本実施形態の外層50は、保持ワイヤ70を内包する断面円環状の第一外層52と、この第一外層52の周囲に設けられて第二補強層80を内包する断面円環状の第二外層54と、を含んでいる。
The outer layer 50 constitutes the main wall thickness of the tubular body 10. The outer layer 50 according to the present embodiment includes a first outer layer 52 having an annular cross section that encloses the holding wire 70 and a second outer layer having an annular cross section that is provided around the first outer layer 52 and encloses the second reinforcing layer 80. 54.
外層50の内側層にあたる第一外層52の内部には、内径側から順にワイヤ補強層30、サブチューブ40および保持ワイヤ70が設けられている。外層50の外側層にあたる第二外層54の内部には、第二補強層80が設けられている。第二補強層80は、第一外層52の外表面に接している。ワイヤ補強層30と第二補強層80は、管状本体10と同軸に配置されている。第二補強層80はワイヤ補強層30およびサブチューブ40の周囲を取り囲むように、これらと離間して配置されている。
Inside the first outer layer 52 corresponding to the inner layer of the outer layer 50, a wire reinforcing layer 30, a sub tube 40, and a holding wire 70 are provided in order from the inner diameter side. A second reinforcing layer 80 is provided inside the second outer layer 54 corresponding to the outer layer of the outer layer 50. The second reinforcing layer 80 is in contact with the outer surface of the first outer layer 52. The wire reinforcing layer 30 and the second reinforcing layer 80 are disposed coaxially with the tubular main body 10. The second reinforcing layer 80 is disposed so as to surround the wire reinforcing layer 30 and the subtube 40 so as to surround them.
外層50の材料としては熱可塑性ポリマー材料を用いることができる。この熱可塑性ポリマー材料としては、ポリイミド(PI)、ポリアミドイミド(PAI)、ポリエチレンテレフタレート(PET)、ポリエチレン(PE)、ポリアミド(PA)、ポリアミドエラストマー(PAE)、ポリエーテルブロックアミド(PEBA)などのナイロンエラストマー、ポリウレタン(PU)、エチレン-酢酸ビニル樹脂(EVA)、ポリ塩化ビニル(PVC)またはポリプロピレン(PP)を挙げることができる。
外層50には無機フィラーを混合してもよい。無機フィラーとしては、硫酸バリウムや次炭酸ビスマスなどの造影剤を例示することができる。外層50に造影剤を混合することで、体腔内における管状本体10のX線造影性を向上することができる。 As the material of theouter layer 50, a thermoplastic polymer material can be used. As this thermoplastic polymer material, polyimide (PI), polyamideimide (PAI), polyethylene terephthalate (PET), polyethylene (PE), polyamide (PA), polyamide elastomer (PAE), polyether block amide (PEBA), etc. Mention may be made of nylon elastomers, polyurethane (PU), ethylene-vinyl acetate resin (EVA), polyvinyl chloride (PVC) or polypropylene (PP).
Theouter layer 50 may be mixed with an inorganic filler. Examples of the inorganic filler include contrast agents such as barium sulfate and bismuth subcarbonate. By mixing a contrast agent in the outer layer 50, the X-ray contrast property of the tubular body 10 in the body cavity can be improved.
外層50には無機フィラーを混合してもよい。無機フィラーとしては、硫酸バリウムや次炭酸ビスマスなどの造影剤を例示することができる。外層50に造影剤を混合することで、体腔内における管状本体10のX線造影性を向上することができる。 As the material of the
The
第一外層52と第二外層54とは、同種または異種の樹脂材料からなる。図1では第一外層52と第二外層54との境界面を明示してあるが、本発明はこれに限られない。第一外層52と第二外層54とを同種の樹脂材料で構成した場合、両層の境界面は渾然一体に融合していてもよい。すなわち、本実施形態の外層50は、第一外層52と第二外層54とが互いに区別可能な多層で構成されていてもよく、または第一外層52と第二外層54とが一体となった単一層として構成されていてもよい。
The first outer layer 52 and the second outer layer 54 are made of the same or different resin materials. Although the boundary surface between the first outer layer 52 and the second outer layer 54 is clearly shown in FIG. 1, the present invention is not limited to this. When the 1st outer layer 52 and the 2nd outer layer 54 are comprised with the same kind of resin material, the interface of both layers may be united naturally. That is, the outer layer 50 of the present embodiment may be formed of a multilayer in which the first outer layer 52 and the second outer layer 54 are distinguishable from each other, or the first outer layer 52 and the second outer layer 54 are integrated. It may be configured as a single layer.
ワイヤ補強層30は、管状本体10のうち操作線60よりも内径側に設けられて内層24を保護する保護層である。操作線60の内径側にワイヤ補強層30が存在することで、操作線60が第一外層52および内層24を破断させて主管腔20に露出することを防止する。
ワイヤ補強層30は補強ワイヤ32を巻回してなる。補強ワイヤ32の材料には、タングステン(W)、ステンレス鋼(SUS)、ニッケルチタン系合金、鋼、チタン、銅、チタン合金または銅合金などの金属材料のほか、内層24および第一外層52よりも剪断強度が高いポリイミド(PI)、ポリアミドイミド(PAI)またはポリエチレンテレフタレート(PET)などの樹脂材料を用いることができる。本実施形態では、補強ワイヤ32としてステンレス鋼の細線を挙げる。 Thewire reinforcing layer 30 is a protective layer that is provided on the inner diameter side of the operation line 60 in the tubular body 10 and protects the inner layer 24. The presence of the wire reinforcing layer 30 on the inner diameter side of the operation line 60 prevents the operation line 60 from being exposed to the main lumen 20 by breaking the first outer layer 52 and the inner layer 24.
Thewire reinforcing layer 30 is formed by winding a reinforcing wire 32. The material of the reinforcing wire 32 includes a metal material such as tungsten (W), stainless steel (SUS), nickel titanium alloy, steel, titanium, copper, titanium alloy or copper alloy, as well as the inner layer 24 and the first outer layer 52. Also, a resin material such as polyimide (PI), polyamideimide (PAI) or polyethylene terephthalate (PET) having high shear strength can be used. In this embodiment, the reinforcing wire 32 is a fine stainless steel wire.
ワイヤ補強層30は補強ワイヤ32を巻回してなる。補強ワイヤ32の材料には、タングステン(W)、ステンレス鋼(SUS)、ニッケルチタン系合金、鋼、チタン、銅、チタン合金または銅合金などの金属材料のほか、内層24および第一外層52よりも剪断強度が高いポリイミド(PI)、ポリアミドイミド(PAI)またはポリエチレンテレフタレート(PET)などの樹脂材料を用いることができる。本実施形態では、補強ワイヤ32としてステンレス鋼の細線を挙げる。 The
The
ワイヤ補強層30は、補強ワイヤ32をコイル巻回またはメッシュ状に編組してなる。補強ワイヤ32の条数や、コイルピッチ、メッシュ数は特に限定されない。ここで、ワイヤ補強層30のメッシュ数とは、補強ワイヤ32の延在方向にみた単位長さ(1インチ)あたりの交差本数(目の数)をいう。また、下記の数式(1)で表されるパラメータを、補強ワイヤ32の延在方向にみたワイヤ補強層30の目開き寸法と呼称する。
ワイヤ延在方向の目開き寸法=単位長さ(1インチ)/メッシュ数-ワイヤの線径 ・・・(1) Thewire reinforcing layer 30 is formed by winding a reinforcing wire 32 in a coiled or mesh shape. The number of the reinforcing wires 32, the coil pitch, and the number of meshes are not particularly limited. Here, the number of meshes of the wire reinforcing layer 30 refers to the number of intersections (number of eyes) per unit length (1 inch) viewed in the extending direction of the reinforcing wires 32. Moreover, the parameter represented by the following mathematical formula (1) is referred to as an opening size of the wire reinforcing layer 30 viewed in the extending direction of the reinforcing wire 32.
Opening dimension in the wire extending direction = unit length (1 inch) / number of meshes-wire diameter (1)
ワイヤ延在方向の目開き寸法=単位長さ(1インチ)/メッシュ数-ワイヤの線径 ・・・(1) The
Opening dimension in the wire extending direction = unit length (1 inch) / number of meshes-wire diameter (1)
後述する第二補強層80に関しても、上記の数式(1)により、第二補強ワイヤ82の延在方向にみた第二補強層80の目開き寸法を定義する。
Regarding the second reinforcing layer 80 described later, the opening size of the second reinforcing layer 80 as viewed in the extending direction of the second reinforcing wire 82 is defined by the above mathematical formula (1).
補強ワイヤ32は、内層24の周囲に斜めに巻回されている。内層24の径方向に対する補強ワイヤ32の延在方向の為す角を、補強ワイヤ32のピッチ角という。補強ワイヤ32が密ピッチで巻回されている場合、ピッチ角は小さな角度になる。逆に補強ワイヤ32が管状本体10の軸心に沿って浅い角度で巻回されている場合、ピッチ角は90度に近い大きな角度になる。本実施形態の補強ワイヤ32のピッチ角は特に限定されないが、30度以上、好ましくは45度以上、かつ75度以下とすることができる。
ここで、下記の数式(2)で表されるパラメータを、ワイヤ補強層30の周方向の目開き寸法W(図1を参照)と呼称する。
周方向の目開き寸法W=(単位長さ(1インチ)/メッシュ数-補強ワイヤ32の線径)×√2 ・・・(2)
ワイヤ補強層30の周方向の目開き寸法Wは、補強ワイヤ32の延在方向にみたワイヤ補強層30の目開き形状を正方形とみなした場合の対角線の長さである。 The reinforcingwire 32 is wound obliquely around the inner layer 24. An angle formed by the extending direction of the reinforcing wire 32 with respect to the radial direction of the inner layer 24 is referred to as a pitch angle of the reinforcing wire 32. When the reinforcing wires 32 are wound at a dense pitch, the pitch angle becomes a small angle. Conversely, when the reinforcing wire 32 is wound at a shallow angle along the axial center of the tubular body 10, the pitch angle is a large angle close to 90 degrees. The pitch angle of the reinforcing wire 32 of the present embodiment is not particularly limited, but can be 30 degrees or more, preferably 45 degrees or more and 75 degrees or less.
Here, the parameter represented by the following mathematical formula (2) is referred to as a circumferential opening size W of the wire reinforcing layer 30 (see FIG. 1).
Circumferential opening dimension W = (unit length (1 inch) / number of meshes−wire diameter of reinforcing wire 32) × √2 (2)
The opening dimension W in the circumferential direction of thewire reinforcing layer 30 is the length of a diagonal line when the opening shape of the wire reinforcing layer 30 viewed in the extending direction of the reinforcing wire 32 is regarded as a square.
ここで、下記の数式(2)で表されるパラメータを、ワイヤ補強層30の周方向の目開き寸法W(図1を参照)と呼称する。
周方向の目開き寸法W=(単位長さ(1インチ)/メッシュ数-補強ワイヤ32の線径)×√2 ・・・(2)
ワイヤ補強層30の周方向の目開き寸法Wは、補強ワイヤ32の延在方向にみたワイヤ補強層30の目開き形状を正方形とみなした場合の対角線の長さである。 The reinforcing
Here, the parameter represented by the following mathematical formula (2) is referred to as a circumferential opening size W of the wire reinforcing layer 30 (see FIG. 1).
Circumferential opening dimension W = (unit length (1 inch) / number of meshes−wire diameter of reinforcing wire 32) × √2 (2)
The opening dimension W in the circumferential direction of the
本実施形態のワイヤ補強層30として、補強ワイヤ32を編組したブレード層を例示する。上記の数式(2)で表されるワイヤ補強層30(ブレード層)の周方向の目開き寸法Wは、図1に示すように、サブチューブ40の外径よりも大きい。第一外層52はワイヤ補強層30とサブチューブ40との間に含浸している。すなわち、メッシュ状に交差する補強ワイヤ32の交差位置(目の位置)とサブチューブ40との位置関係によらず、ワイヤ補強層30のいずれの目開きも、サブチューブ40により完全に遮蔽されることはない。これにより、後述する製造工程において、第一外層52はサブチューブ40の周囲から目開きの内部に含浸して、内層24、ワイヤ補強層30およびサブチューブ40を一体に固着させる。
The blade layer formed by braiding the reinforcing wire 32 is illustrated as the wire reinforcing layer 30 of the present embodiment. As shown in FIG. 1, the opening dimension W in the circumferential direction of the wire reinforcing layer 30 (blade layer) represented by the above formula (2) is larger than the outer diameter of the sub-tube 40. The first outer layer 52 is impregnated between the wire reinforcing layer 30 and the subtube 40. That is, any opening of the wire reinforcing layer 30 is completely shielded by the subtube 40 regardless of the positional relationship between the crossing position (eye position) of the reinforcing wires 32 intersecting in a mesh shape and the subtube 40. There is nothing. Thereby, in the manufacturing process described later, the first outer layer 52 is impregnated from the periphery of the subtube 40 into the inside of the openings, and the inner layer 24, the wire reinforcing layer 30, and the subtube 40 are fixed together.
第二補強層80は、管状本体10のうち操作線60よりも外径側に設けられて第二外層54を保護する保護層である。操作線60の外径側に第二補強層80が存在することで、操作線60が第二外層54および親水層(図示せず)を破断させて管状本体10の外部に露出することを防止する。
第二補強層80は第二補強ワイヤ82をコイル巻回またはメッシュ状に編組してなる。第二補強ワイヤ82には、ワイヤ補強層30の補強ワイヤ32として例示した上記の材料を用いることができる。第二補強ワイヤ82と補強ワイヤ32とは同種の材料でもよく、または異種の材料でもよい。本実施形態では、第二補強ワイヤ82として、補強ワイヤ32と同種の材料(ステンレス鋼)からなる細線をメッシュ状に編組したブレード層を例示する。 The second reinforcinglayer 80 is a protective layer that is provided on the outer diameter side of the operation line 60 in the tubular body 10 and protects the second outer layer 54. The presence of the second reinforcing layer 80 on the outer diameter side of the operation line 60 prevents the operation line 60 from being exposed to the outside of the tubular body 10 by breaking the second outer layer 54 and the hydrophilic layer (not shown). To do.
The second reinforcinglayer 80 is formed by winding the second reinforcing wire 82 into a coil or mesh shape. For the second reinforcing wire 82, the above-described materials exemplified as the reinforcing wire 32 of the wire reinforcing layer 30 can be used. The second reinforcing wire 82 and the reinforcing wire 32 may be made of the same material or different materials. In the present embodiment, as the second reinforcing wire 82, a blade layer in which fine wires made of the same material (stainless steel) as the reinforcing wire 32 are braided in a mesh shape is illustrated.
第二補強層80は第二補強ワイヤ82をコイル巻回またはメッシュ状に編組してなる。第二補強ワイヤ82には、ワイヤ補強層30の補強ワイヤ32として例示した上記の材料を用いることができる。第二補強ワイヤ82と補強ワイヤ32とは同種の材料でもよく、または異種の材料でもよい。本実施形態では、第二補強ワイヤ82として、補強ワイヤ32と同種の材料(ステンレス鋼)からなる細線をメッシュ状に編組したブレード層を例示する。 The second reinforcing
The second reinforcing
第二補強ワイヤ82と補強ワイヤ32との線径は同一でもよく、または異なってもよい。本実施形態では、第二補強ワイヤ82と補強ワイヤ32とは同一の線径である。
また、ワイヤ補強層30を構成する補強ワイヤ32の条数と、第二補強層80を構成する第二補強ワイヤ82の条数との大小も特に限定されないが、本実施形態では同数とする。図1では、ワイヤ補強層30、第二補強層80ともにそれぞれ16条のワイヤ(補強ワイヤ32、第二補強ワイヤ82)からなるブレード層を図示してある。 The wire diameters of the second reinforcingwire 82 and the reinforcing wire 32 may be the same or different. In the present embodiment, the second reinforcing wire 82 and the reinforcing wire 32 have the same wire diameter.
Further, the size of the number of the reinforcingwires 32 constituting the wire reinforcing layer 30 and the number of the second reinforcing wires 82 constituting the second reinforcing layer 80 are not particularly limited, but are the same in this embodiment. In FIG. 1, both of the wire reinforcing layer 30 and the second reinforcing layer 80 are illustrated as blade layers made of 16 wires (reinforcing wires 32 and second reinforcing wires 82).
また、ワイヤ補強層30を構成する補強ワイヤ32の条数と、第二補強層80を構成する第二補強ワイヤ82の条数との大小も特に限定されないが、本実施形態では同数とする。図1では、ワイヤ補強層30、第二補強層80ともにそれぞれ16条のワイヤ(補強ワイヤ32、第二補強ワイヤ82)からなるブレード層を図示してある。 The wire diameters of the second reinforcing
Further, the size of the number of the reinforcing
サブチューブ40は副管腔42を画定する中空管状の部材である。サブチューブ40は外層50(第一外層52)の内部に埋設されている。サブチューブ40は、たとえば熱可塑性ポリマー材料により構成することができる。その熱可塑性ポリマー材料としては、ポリテトラフルオロエチレン(PTFE)、ポリエーテルエーテルケトン(PEEK)、または四フッ化エチレン・六フッ化プロピレン共重合体(FEP)などの低摩擦樹脂材料が挙げられる。
サブチューブ40は、外層50よりも曲げ剛性率および引張弾性率が高い材料で構成されている。 Thesubtube 40 is a hollow tubular member that defines a secondary lumen 42. The subtube 40 is embedded in the outer layer 50 (first outer layer 52). The subtube 40 can be made of, for example, a thermoplastic polymer material. Examples of the thermoplastic polymer material include low friction resin materials such as polytetrafluoroethylene (PTFE), polyetheretherketone (PEEK), or tetrafluoroethylene / hexafluoropropylene copolymer (FEP).
Thesubtube 40 is made of a material having a higher bending rigidity and tensile elastic modulus than the outer layer 50.
サブチューブ40は、外層50よりも曲げ剛性率および引張弾性率が高い材料で構成されている。 The
The
サブチューブ40の外表面には金属ナトリウム処理またはプラズマ処理などのエッチング処理が施されている。これによりサブチューブ40と外層50との密着性を向上している。
The outer surface of the sub-tube 40 is subjected to etching treatment such as metal sodium treatment or plasma treatment. Thereby, the adhesiveness of the subtube 40 and the outer layer 50 is improved.
本実施形態は複数本のサブチューブ40が主管腔20の周囲に対向して配置されている。より具体的には、図1に示すように、ワイヤ補強層30の周囲に90度間隔で互いに対向して4本のサブチューブ40が配置され、そのうち180度対向する2本のサブチューブ40に操作線60がそれぞれ挿通されている。4本のサブチューブ40は、それぞれ管状本体10の軸心方向に対して平行に配置されている。
In this embodiment, a plurality of sub-tubes 40 are arranged facing the periphery of the main lumen 20. More specifically, as shown in FIG. 1, four subtubes 40 are arranged around the wire reinforcing layer 30 so as to face each other at intervals of 90 degrees, of which two subtubes 40 facing each other are 180 degrees. Each operation line 60 is inserted. The four sub tubes 40 are arranged in parallel to the axial direction of the tubular body 10.
すなわち、本実施形態は3本以上のサブチューブ40が主管腔20の周囲に均等に配置されて互いに対向している。図1に示すように、4本のサブチューブ40は主管腔20を取り囲むように、同一の円周上に配置されている。本実施形態に代えて、3本以下または5本以上のサブチューブ40を主管腔20の周囲に等間隔で配置してもよい。3本以上のサブチューブ40を主管腔20の周囲に等間隔で配置することで、管状本体10の屈曲方向によらず管状本体10の曲げ剛性が等しくなる。このため、屈曲状態で管状本体10をトルク回転させた場合に遠位部DEの少なくとも一部の領域を所望の方向に滑らかに指向させることが可能である。
That is, in this embodiment, three or more subtubes 40 are evenly arranged around the main lumen 20 and face each other. As shown in FIG. 1, the four sub tubes 40 are arranged on the same circumference so as to surround the main lumen 20. Instead of this embodiment, three or less or five or more subtubes 40 may be arranged around the main lumen 20 at equal intervals. By arranging three or more sub tubes 40 around the main lumen 20 at equal intervals, the bending rigidity of the tubular body 10 becomes equal regardless of the bending direction of the tubular body 10. For this reason, when the tubular main body 10 is torque-rotated in a bent state, it is possible to smoothly direct at least a part of the distal portion DE in a desired direction.
操作線60は、サブチューブ40に対して摺動可能に遊挿されている。操作線60の先端部は管状本体10の遠位部DEに固定されている。具体的には、本実施形態の操作線60は、後述する第一マーカー14付近に固定されている。操作線60を基端側に牽引することで、管状本体10の軸心に対して偏心した位置に引張力が付与されるため管状本体10は屈曲する。本実施形態の操作線60は極めて細く可撓性が高いため、操作線60を遠位側に押し込んでも、管状本体10の遠位部DEには実質的に押込力は付与されない。
The operation line 60 is slidably inserted in the sub tube 40. The distal end portion of the operation line 60 is fixed to the distal portion DE of the tubular main body 10. Specifically, the operation line 60 of the present embodiment is fixed near the first marker 14 described later. By pulling the operation line 60 to the proximal end side, a tensile force is applied to a position that is eccentric with respect to the axial center of the tubular body 10, so that the tubular body 10 is bent. Since the operation line 60 of the present embodiment is extremely thin and highly flexible, even if the operation line 60 is pushed distally, a pushing force is not substantially applied to the distal portion DE of the tubular body 10.
操作線60は、単一の線材により構成されていてもよいが、複数本の細線を互いに撚りあわせることにより構成された撚り線であってもよい。操作線60の一本の撚り線を構成する細線の本数は特に限定されないが、3本以上であることが好ましい。細線の本数の好適な例は、7本または3本である。
操作線60が単線の素線からなる場合は、その単線の直径を操作線60の線径という。操作線60が複数本の素線を互いに撚り合わせた撚り線である場合は、複数本の素線を包含する外接円の直径を操作線60の線径という。 Theoperation wire 60 may be formed of a single wire, but may be a stranded wire formed by twisting a plurality of thin wires. The number of fine wires constituting one stranded wire of the operation wire 60 is not particularly limited, but is preferably 3 or more. A preferable example of the number of thin wires is seven or three.
When theoperation line 60 is a single wire, the diameter of the single line is referred to as the wire diameter of the operation line 60. When the operation wire 60 is a stranded wire obtained by twisting a plurality of strands, the diameter of a circumscribed circle including the plurality of strands is referred to as the wire diameter of the operation wire 60.
操作線60が単線の素線からなる場合は、その単線の直径を操作線60の線径という。操作線60が複数本の素線を互いに撚り合わせた撚り線である場合は、複数本の素線を包含する外接円の直径を操作線60の線径という。 The
When the
操作線60としては、低炭素鋼(ピアノ線)、ステンレス鋼(SUS)、耐腐食性被覆した鋼鉄線、チタンもしくはチタン合金、またはタングステンなどの金属線を用いることができる。このほか、操作線60としては、ポリビニリデンフルオライド(PVDF)、高密度ポリエチレン(HDPE)、ポリ(パラフェニレンベンゾビスオキサゾール)(PBO)、ポリエーテルエーテルケトン(PEEK)、ポリフェニレンスルフィド(PPS)、ポリブチレンテレフタレート(PBT)、ポリイミド(PI)、ポリテトラフルオロエチレン(PTFE)、またはボロン繊維などの高分子ファイバーを用いることができる。
As the operation wire 60, a low carbon steel (piano wire), stainless steel (SUS), a steel wire coated with corrosion resistance, titanium or a titanium alloy, or a metal wire such as tungsten can be used. In addition, the operation line 60 includes polyvinylidene fluoride (PVDF), high density polyethylene (HDPE), poly (paraphenylenebenzobisoxazole) (PBO), polyetheretherketone (PEEK), polyphenylene sulfide (PPS), Polymer fibers such as polybutylene terephthalate (PBT), polyimide (PI), polytetrafluoroethylene (PTFE), or boron fiber can be used.
保持ワイヤ70は、サブチューブ40とワイヤ補強層30とを共巻きしている、本実施形態に特徴的な部材である。保持ワイヤ70は、サブチューブ40の周囲にコイル巻回またはメッシュ状に編組してなる。このうち、本実施形態の保持ワイヤ70はコイルであり、より具体的には複数本の保持ワイヤ70が多条に巻回されたコイル(多条コイル)である。
The holding wire 70 is a member characteristic of the present embodiment in which the subtube 40 and the wire reinforcing layer 30 are wound together. The holding wire 70 is formed by winding the coil around the subtube 40 or braiding it in a mesh shape. Among these, the holding wire 70 according to the present embodiment is a coil, and more specifically, a coil (multi-coil) in which a plurality of holding wires 70 are wound in multiple lines.
図1に破線で示すように、本実施形態の保持ワイヤ70が巻回してなる保持ワイヤ層の形状は、サブチューブ40をコーナーとする略多角形である。三本以上(N本)のサブチューブ40が主管腔20の周囲に均等に分散配置されている場合、保持ワイヤ70からなる保持ワイヤ層の巻回形状は、各サブチューブ40をコーナーとする角丸N角形である。より具体的には、4本のサブチューブ40が主管腔20の周囲に均等に配置された本実施形態では、保持ワイヤ層の巻回形状は角丸正方形である。保持ワイヤ層は、主管腔20の周囲に均等に配置された複数本のサブチューブ40の外側を保持ワイヤ70が取り囲んで螺旋状に巻回されてなる。保持ワイヤ70に付与する巻張力の作用により、サブチューブ40同士の中間部において保持ワイヤ70は略直線状に張架される。ただし、保持ワイヤ70の曲げ剛性が大きいか、または巻張力が小さい場合、サブチューブ40同士の中間部において保持ワイヤ70は弧状に湾曲してもよい。この場合、保持ワイヤ層の巻回形状は略円形となってもよい。
保持ワイヤ70は、サブチューブ40の外側表面のほか、更にワイヤ補強層30の表面に接してもよい。
保持ワイヤ70は、サブチューブ40の周面、具体的には主管腔20の軸心とは反対側にあたる外側表面に食い込んで嵌入している。これにより保持ワイヤ70とサブチューブ40とが軸心方向に相対移動することが規制されている。
管状本体10が屈曲した際に、屈曲の外側は伸張し、内側は圧縮される。上記のように、サブチューブ40は、外層50よりも曲げ剛性率および引張弾性率が高い材料からなるため、外層50は柔軟に伸張または圧縮されるのに対して、サブチューブ40の伸張または圧縮は小さい。このため管状本体10が屈曲するとサブチューブ40と外層50との界面に剪断力が生じるが、保持ワイヤ70が外層50とサブチューブ40の双方に対して係合するアンカーとして働くとともに、保持ワイヤ70が弾性変形して上記の剪断力を緩和する。これによりサブチューブ40と外層50との界面の剥離(以下、界面剥離という)が防止される。 As shown by a broken line in FIG. 1, the shape of the holding wire layer formed by winding the holdingwire 70 of this embodiment is a substantially polygonal shape with the subtube 40 as a corner. When three or more (N) sub-tubes 40 are uniformly distributed around the main lumen 20, the winding shape of the holding wire layer formed of the holding wires 70 is an angle with each sub-tube 40 as a corner. Round N-gon. More specifically, in the present embodiment in which the four sub tubes 40 are evenly arranged around the main lumen 20, the winding shape of the holding wire layer is a rounded square. The holding wire layer is formed by spirally winding the holding wire 70 so as to surround the outer sides of the plurality of sub tubes 40 arranged evenly around the main lumen 20. Due to the action of the winding tension applied to the holding wire 70, the holding wire 70 is stretched substantially linearly at the intermediate portion between the sub-tubes 40. However, when the bending rigidity of the holding wire 70 is large or the winding tension is small, the holding wire 70 may be curved in an arc shape at an intermediate portion between the sub-tubes 40. In this case, the winding shape of the holding wire layer may be substantially circular.
The holdingwire 70 may be in contact with the surface of the wire reinforcing layer 30 in addition to the outer surface of the subtube 40.
The holdingwire 70 is inserted into the peripheral surface of the subtube 40, specifically, the outer surface on the opposite side to the axis of the main lumen 20. As a result, the relative movement of the holding wire 70 and the subtube 40 in the axial direction is restricted.
When thetubular body 10 bends, the outside of the bend expands and the inside is compressed. As described above, since the subtube 40 is made of a material having a higher bending rigidity and tensile modulus than the outer layer 50, the outer layer 50 is flexibly stretched or compressed, whereas the subtube 40 is stretched or compressed. Is small. For this reason, when the tubular body 10 is bent, a shearing force is generated at the interface between the sub-tube 40 and the outer layer 50, but the holding wire 70 functions as an anchor that engages both the outer layer 50 and the sub-tube 40, and the holding wire 70. Elastically deforms to relieve the above shearing force. Thereby, peeling of the interface between the sub-tube 40 and the outer layer 50 (hereinafter referred to as interface peeling) is prevented.
保持ワイヤ70は、サブチューブ40の外側表面のほか、更にワイヤ補強層30の表面に接してもよい。
保持ワイヤ70は、サブチューブ40の周面、具体的には主管腔20の軸心とは反対側にあたる外側表面に食い込んで嵌入している。これにより保持ワイヤ70とサブチューブ40とが軸心方向に相対移動することが規制されている。
管状本体10が屈曲した際に、屈曲の外側は伸張し、内側は圧縮される。上記のように、サブチューブ40は、外層50よりも曲げ剛性率および引張弾性率が高い材料からなるため、外層50は柔軟に伸張または圧縮されるのに対して、サブチューブ40の伸張または圧縮は小さい。このため管状本体10が屈曲するとサブチューブ40と外層50との界面に剪断力が生じるが、保持ワイヤ70が外層50とサブチューブ40の双方に対して係合するアンカーとして働くとともに、保持ワイヤ70が弾性変形して上記の剪断力を緩和する。これによりサブチューブ40と外層50との界面の剥離(以下、界面剥離という)が防止される。 As shown by a broken line in FIG. 1, the shape of the holding wire layer formed by winding the holding
The holding
The holding
When the
ここで、保持ワイヤ70がサブチューブ40の周面に嵌入しているとは、管状本体10の少なくとも一箇所の横断面において、保持ワイヤ70の一部または全部が、サブチューブ40の外周の仮想表面(仮想外形)よりも内側に位置していることをいう。サブチューブ40の外周の仮想表面(仮想外形)とは、保持ワイヤ70が嵌入していなかったとした場合のサブチューブ40の仮想的な外周表面である。サブチューブ40の仮想外形は、サブチューブ40における保持ワイヤ70の嵌入部に対して軸心方向に近接する他の部位の外周表面から求めることができる。
保持ワイヤ70がサブチューブ40の周面に嵌入しているとは、少なくとも以下の2つの状態を含む。
第1の状態は、図5(b)および図6(a)に示すように、保持ワイヤ70の嵌入部位においてサブチューブ40が局所的に薄肉になっている、本実施形態の状態である。本実施形態のサブチューブ40は、円形の横断面形状を維持したまま、その肉厚が局所的に薄くなっている。
第2の状態は、本実施形態に代えて、サブチューブ40の横断面形状が、全周に亘って肉厚が均一なまま全体的に凹形状となっている状態である。言い換えると、第2の状態は、サブチューブ40の横断面形状が凹欠円形や凹欠楕円形(腎臓形または曲玉形)などの凹形状をなしている。この凹欠部に保持ワイヤ70が嵌合している状態も、保持ワイヤ70がサブチューブ40の周面に嵌入しているという。
保持ワイヤ70の嵌入部位の横断面における、サブチューブ40の外周の仮想表面(仮想外形)から保持ワイヤ70の最深部までの距離を、サブチューブ40の周面に対する保持ワイヤ70の嵌入深さDとする(図2を参照)。本実施形態のカテーテル100における嵌入深さDはサブチューブ40の肉厚より小さい。嵌入深さDはサブチューブ40の肉厚と等しくてもよく、またはサブチューブ40の肉厚より大きくてもよい。 Here, that the holdingwire 70 is fitted into the peripheral surface of the subtube 40 means that a part or all of the holding wire 70 is virtually on the outer periphery of the subtube 40 in at least one cross section of the tubular body 10. It is located inside the surface (virtual outline). The virtual surface (virtual outer shape) on the outer periphery of the subtube 40 is a virtual outer peripheral surface of the subtube 40 when the holding wire 70 is not inserted. The virtual outer shape of the subtube 40 can be obtained from the outer peripheral surface of another portion that is close to the insertion portion of the holding wire 70 in the subtube 40 in the axial direction.
The holdingwire 70 being fitted into the peripheral surface of the subtube 40 includes at least the following two states.
The first state is the state of the present embodiment in which thesub-tube 40 is locally thin at the insertion site of the holding wire 70 as shown in FIGS. 5 (b) and 6 (a). The sub-tube 40 of the present embodiment is locally thin while maintaining a circular cross-sectional shape.
The second state is a state in which the cross-sectional shape of the sub-tube 40 is a concave shape as a whole with a uniform thickness over the entire circumference instead of the present embodiment. In other words, in the second state, the cross-sectional shape of the sub-tube 40 is a concave shape such as a concave circular shape or a concave elliptical shape (kidney shape or curved ball shape). The state in which theholding wire 70 is fitted in the recessed portion is also said that the holding wire 70 is fitted in the peripheral surface of the sub-tube 40.
The distance from the virtual surface (virtual outline) of the outer periphery of thesubtube 40 to the deepest part of the holding wire 70 in the cross section of the insertion portion of the holding wire 70 is the insertion depth D of the holding wire 70 with respect to the peripheral surface of the subtube 40. (See FIG. 2). The insertion depth D in the catheter 100 of this embodiment is smaller than the thickness of the subtube 40. The insertion depth D may be equal to the thickness of the subtube 40 or may be larger than the thickness of the subtube 40.
保持ワイヤ70がサブチューブ40の周面に嵌入しているとは、少なくとも以下の2つの状態を含む。
第1の状態は、図5(b)および図6(a)に示すように、保持ワイヤ70の嵌入部位においてサブチューブ40が局所的に薄肉になっている、本実施形態の状態である。本実施形態のサブチューブ40は、円形の横断面形状を維持したまま、その肉厚が局所的に薄くなっている。
第2の状態は、本実施形態に代えて、サブチューブ40の横断面形状が、全周に亘って肉厚が均一なまま全体的に凹形状となっている状態である。言い換えると、第2の状態は、サブチューブ40の横断面形状が凹欠円形や凹欠楕円形(腎臓形または曲玉形)などの凹形状をなしている。この凹欠部に保持ワイヤ70が嵌合している状態も、保持ワイヤ70がサブチューブ40の周面に嵌入しているという。
保持ワイヤ70の嵌入部位の横断面における、サブチューブ40の外周の仮想表面(仮想外形)から保持ワイヤ70の最深部までの距離を、サブチューブ40の周面に対する保持ワイヤ70の嵌入深さDとする(図2を参照)。本実施形態のカテーテル100における嵌入深さDはサブチューブ40の肉厚より小さい。嵌入深さDはサブチューブ40の肉厚と等しくてもよく、またはサブチューブ40の肉厚より大きくてもよい。 Here, that the holding
The holding
The first state is the state of the present embodiment in which the
The second state is a state in which the cross-sectional shape of the sub-tube 40 is a concave shape as a whole with a uniform thickness over the entire circumference instead of the present embodiment. In other words, in the second state, the cross-sectional shape of the sub-tube 40 is a concave shape such as a concave circular shape or a concave elliptical shape (kidney shape or curved ball shape). The state in which the
The distance from the virtual surface (virtual outline) of the outer periphery of the
管状本体10の長手方向にみて、保持ワイヤ70は、サブチューブ40の略全長に亘って巻回されている。これにより、一対のサブチューブ40が、ワイヤ補強層30の表面に沿って管状本体10の軸線方向に平行を保った状態で、保持ワイヤ70によりワイヤ補強層30とサブチューブ40との相対位置が固定されている。
Referring to the longitudinal direction of the tubular body 10, the holding wire 70 is wound over substantially the entire length of the subtube 40. Thereby, in a state where the pair of sub tubes 40 is kept parallel to the axial direction of the tubular main body 10 along the surface of the wire reinforcing layer 30, the relative position between the wire reinforcing layer 30 and the sub tube 40 is set by the holding wire 70. It is fixed.
保持ワイヤ70の材料としては、補強ワイヤ32として使用可能な上記の金属材料または樹脂材料のいずれかを用いることができる。本実施形態では、保持ワイヤ70は補強ワイヤ32と異種の材料からなる。保持ワイヤ70の延性は、補強ワイヤ32の延性よりも高いことが好ましい。具体的には、鈍し材であるオーステナイト系の軟質ステンレス鋼(W1またはW2)や、銅または銅合金を保持ワイヤ70に用いる一方、補強ワイヤ32にはタングステンやステンレスバネ鋼を用いることができる。
保持ワイヤ70に延性の高い材料を用いることで、サブチューブ40の周囲に保持ワイヤ70をコイル巻回またはメッシュ状に編組(本実施形態ではコイル巻回)した際に、保持ワイヤ70が巻き緩むことなく塑性的に伸長変形してサブチューブ40を固定する。一方、ワイヤ補強層30は後述するように管状本体10のキンクの発生を防止する部材であるため、弾性復元力が高いバネ性の材料を用いることが好ましい。 As the material of the holdingwire 70, any of the metal materials and resin materials described above that can be used as the reinforcing wire 32 can be used. In the present embodiment, the holding wire 70 is made of a material different from that of the reinforcing wire 32. The ductility of the holding wire 70 is preferably higher than the ductility of the reinforcing wire 32. Specifically, austenitic soft stainless steel (W1 or W2), which is a dull material, or copper or copper alloy is used for the holding wire 70, while tungsten or stainless spring steel can be used for the reinforcing wire 32. .
By using a highly ductile material for theholding wire 70, the holding wire 70 is loosened when the holding wire 70 is coiled or braided into a mesh shape (coil winding in this embodiment) around the sub-tube 40. The sub-tube 40 is fixed by being stretched and deformed plastically. On the other hand, since the wire reinforcing layer 30 is a member that prevents the occurrence of kinks in the tubular body 10 as described later, it is preferable to use a spring material having a high elastic restoring force.
保持ワイヤ70に延性の高い材料を用いることで、サブチューブ40の周囲に保持ワイヤ70をコイル巻回またはメッシュ状に編組(本実施形態ではコイル巻回)した際に、保持ワイヤ70が巻き緩むことなく塑性的に伸長変形してサブチューブ40を固定する。一方、ワイヤ補強層30は後述するように管状本体10のキンクの発生を防止する部材であるため、弾性復元力が高いバネ性の材料を用いることが好ましい。 As the material of the holding
By using a highly ductile material for the
図4から図6を参照して、本実施形態の保持ワイヤ70がサブチューブ40に嵌入している態様を具体的に説明する。
4 to FIG. 6, the aspect in which the holding wire 70 of this embodiment is fitted in the subtube 40 will be specifically described.
本実施形態のカテーテル100では、第一長さ領域L1と第二長さ領域L2とが管状本体10の軸心方向に並んで存在している。第一長さ領域L1は、サブチューブ40の少なくとも一本に関して、その周面に対する保持ワイヤ70の嵌入深さDが所定の深さである領域である。第二長さ領域L2は、この嵌入深さDが第一長さ領域L1よりも深い領域である(図4を参照)。すなわち、第一のサブチューブ40aに関し、第一長さ領域L1(L1a)は、保持ワイヤ70が比較的浅く嵌入している領域であり(図5(a)を参照)、第二長さ領域L2(L2a)は、保持ワイヤ70が比較的深く嵌入している領域である(図6(a)を参照)。
In the catheter 100 of the present embodiment, the first length region L1 and the second length region L2 exist side by side in the axial direction of the tubular body 10. The first length region L1 is a region where the insertion depth D of the holding wire 70 with respect to the peripheral surface of at least one of the sub tubes 40 is a predetermined depth. The second length region L2 is a region in which the insertion depth D is deeper than the first length region L1 (see FIG. 4). That is, regarding the first subtube 40a, the first length region L1 (L1a) is a region in which the holding wire 70 is relatively shallowly inserted (see FIG. 5A), and the second length region L2 (L2a) is a region in which the holding wire 70 is relatively deeply inserted (see FIG. 6A).
ここで、第二長さ領域L2は保持ワイヤ70がサブチューブ40に食い込んで嵌入していることを要するのに対し、第一長さ領域L1は保持ワイヤ70がサブチューブ40の表面に非嵌入に接していることを許容する。すなわち、第二長さ領域L2に関しては嵌入深さD>0であり、第一長さ領域L1に関しては嵌入深さD≧0である。
Here, the second length region L2 requires that the holding wire 70 is inserted into the subtube 40, whereas the first length region L1 does not fit the holding wire 70 into the surface of the subtube 40. Is allowed to touch. That is, the insertion depth D> 0 for the second length region L2, and the insertion depth D ≧ 0 for the first length region L1.
このように、操作線60が挿通されて牽引力が付与される第一のサブチューブ40aに対して、保持ワイヤ70の嵌入深さDが深い領域と浅い領域とが繰り返して存在している。このため、第一のサブチューブ40aの操作線60を牽引して第一のサブチューブ40aが圧縮力を受けた場合に、第二長さ領域L2aで保持ワイヤ70が第一のサブチューブ40aに強くアンカーする。保持ワイヤ70が全長に亘って均一に第一のサブチューブ40aに嵌入している場合には、外層50と第一のサブチューブ40aとの間に界面剥離が生じたとき、この界面剥離が軸心方向に伸展するおそれがある。これに対し、嵌入深さDが大きい第二長さ領域L2aが部分的に存在することで、界面剥離の伸展が第二長さ領域L2aによってストップする。このため、第一のサブチューブ40aと外層50との界面剥離が良好に防止される。
As described above, a region where the insertion depth D of the holding wire 70 is deep and a region where the retaining wire 70 is deeply exist are repeatedly present with respect to the first subtube 40a through which the operation line 60 is inserted and traction force is applied. For this reason, when the operation line 60 of the first subtube 40a is pulled and the first subtube 40a receives a compressive force, the holding wire 70 is moved to the first subtube 40a in the second length region L2a. Anchor strongly. When the holding wire 70 is fitted into the first subtube 40a uniformly over the entire length, when the interface peeling occurs between the outer layer 50 and the first subtube 40a, this interface peeling is the axis. There is a risk of extending in the direction of the heart. On the other hand, since the second length region L2a having a large insertion depth D is partially present, the extension of the interface peeling is stopped by the second length region L2a. For this reason, the interfacial peeling between the first sub-tube 40a and the outer layer 50 is satisfactorily prevented.
第一のサブチューブ40aに関して、第一長さ領域L1aと第二長さ領域L2aとは管状本体10の軸心方向に複数回繰り返して存在している。このため、上記の剥離が軸心方向のいずれの位置で生じたとしても、近傍の第二長さ領域L2aによってただちに剥離の伸展がストップする。
Regarding the first subtube 40a, the first length region L1a and the second length region L2a are repeatedly present in the axial direction of the tubular body 10 a plurality of times. For this reason, even if said peeling arises in any position of an axial center direction, extension of peeling stops immediately by the 2nd length area | region L2a of the vicinity.
本実施形態では、互いに対向する第一のサブチューブ40aおよび第二のサブチューブ40bに操作線60が挿通されている。これらの第一のサブチューブ40aおよび第二のサブチューブ40bは、それぞれ第一長さ領域L1a、L1bと第二長さ領域L2a、L2bとを有している。具体的には、第二のサブチューブ40bに関し、第一長さ領域L1bは、保持ワイヤ70が比較的浅く嵌入している領域であり(図6(b)を参照)、第二長さ領域L2bは、保持ワイヤ70が比較的深く嵌入している領域である(図5(b)を参照)。
In the present embodiment, the operation line 60 is inserted through the first sub-tube 40a and the second sub-tube 40b facing each other. These first subtube 40a and second subtube 40b have first length regions L1a and L1b and second length regions L2a and L2b, respectively. Specifically, regarding the second subtube 40b, the first length region L1b is a region in which the holding wire 70 is relatively shallowly inserted (see FIG. 6B), and the second length region. L2b is a region in which the holding wire 70 is relatively deeply inserted (see FIG. 5B).
このように、操作線60が挿通されている複数本のサブチューブ40に関して第一長さ領域L1と第二長さ領域L2が存在することで、いずれのサブチューブ40で界面剥離が生じたとしても外層50の内部でサブチューブ40が脱離することがない。
As described above, since the first length region L1 and the second length region L2 exist with respect to the plurality of subtubes 40 through which the operation lines 60 are inserted, interfacial peeling occurs in any of the subtubes 40. However, the subtube 40 is not detached inside the outer layer 50.
第一のサブチューブ40aおよび第二のサブチューブ40bの両方に関して、第一長さ領域L1a、L1bと第二長さ領域L2a、L2bとは軸心方向に複数回繰り返して存在している。このため、任意の操作線60を牽引操作して第一のサブチューブ40aおよび第二のサブチューブ40bのいずれの位置に界面剥離が生じたとしても、その伸展が第二長さ領域L2a、L2bでただちにストップする。
Regarding both the first sub-tube 40a and the second sub-tube 40b, the first length regions L1a and L1b and the second length regions L2a and L2b exist repeatedly in the axial direction. For this reason, even if interface peeling occurs at any position of the first sub-tube 40a and the second sub-tube 40b by pulling the arbitrary operation line 60, the extension is the second length region L2a, L2b. Stop immediately.
第一のサブチューブ40aが有する第一長さ領域L1aと、第二のサブチューブ40bが有する第一長さ領域L1bと、は軸心方向における異なる位置に存在している。すなわち、第一長さ領域L1aとL1bがそれぞれ軸心方向に複数回繰り返して存在している場合、少なくとも一つの第一長さ領域L1aと、管状本体10の周方向に対向して近接する第一長さ領域L1bとが、軸心方向の異なる位置に存在している。
The first length region L1a included in the first subtube 40a and the first length region L1b included in the second subtube 40b are present at different positions in the axial direction. That is, when each of the first length regions L1a and L1b repeats a plurality of times in the axial direction, the first length regions L1a and the first length regions L1a that are adjacent to each other in the circumferential direction of the tubular body 10 are adjacent to each other. One length region L1b exists at a different position in the axial direction.
また、第一のサブチューブ40aが有する第二長さ領域L2aと、第二のサブチューブ40bが有する第二長さ領域L2bと、は軸心方向における異なる位置に存在している。すなわち、第二長さ領域L2aとL2bがそれぞれ軸心方向に複数回繰り返して存在している場合、少なくとも一つの第二長さ領域L2aと、管状本体10の周方向に対向して近接する第二長さ領域L2bとが、軸心方向の異なる位置に存在している。
Also, the second length region L2a of the first subtube 40a and the second length region L2b of the second subtube 40b are present at different positions in the axial direction. That is, when each of the second length regions L2a and L2b is repeatedly provided in the axial direction, the second length regions L2a and the second length regions L2a are adjacent to each other in the circumferential direction of the tubular body 10. The two-length region L2b exists at different positions in the axial direction.
ここで、二つの長さ領域が軸心方向の異なる位置に存在するとは、管状本体10の軸心方向に見た場合に、一方の長さ領域が他方の長さ領域と完全に重複しているか、または包含されていることを排除する趣旨である。すなわち、第一長さ領域L1aとL1bとは、軸心方向に重複なく完全に異なる位置にあってもよく、または一部の長さ領域が重複していてもよい。第二長さ領域L2aとL2bに関しても同様である。
Here, two length regions are present at different positions in the axial direction when one length region completely overlaps the other length region when viewed in the axial direction of the tubular body 10. Or to be included. That is, the first length regions L1a and L1b may be in completely different positions without overlapping in the axial direction, or some length regions may overlap. The same applies to the second length regions L2a and L2b.
このように、管状本体10の周方向に対向する第一のサブチューブ40aと第二のサブチューブ40bに関して、嵌入深さDが小さい第一長さ領域L1aとL1bとが異なる位置にあるか、または嵌入深さDが大きい第二長さ領域L2aとL2bとが異なる位置にある。これにより、界面剥離が軸心方向の同じ位置で第一のサブチューブ40aと第二のサブチューブ40bとに発生することが抑制される。このため、押込剛性の脆弱な長さ領域が管状本体10に発生する虞が低減される。
Thus, regarding the first subtube 40a and the second subtube 40b facing in the circumferential direction of the tubular body 10, are the first length regions L1a and L1b having a small insertion depth D in different positions, Alternatively, the second length regions L2a and L2b having a large insertion depth D are at different positions. Thereby, it is suppressed that interface peeling generate | occur | produces in the 1st subtube 40a and the 2nd subtube 40b in the same position of an axial center direction. For this reason, a possibility that the length area | region where indentation rigidity is weak will generate | occur | produce in the tubular main body 10 is reduced.
第一のサブチューブ40aが有する第一長さ領域L1aと、第二のサブチューブ40bが有する第二長さ領域L2bと、は軸心方向における同じ位置に存在している。また、第一のサブチューブ40aが有する第二長さ領域L2aと、第二のサブチューブ40bが有する第一長さ領域L1bと、は軸心方向における同じ位置に存在している。
The first length region L1a included in the first subtube 40a and the second length region L2b included in the second subtube 40b are present at the same position in the axial direction. Further, the second length region L2a included in the first subtube 40a and the first length region L1b included in the second subtube 40b are present at the same position in the axial direction.
ここで、二つの長さ領域が軸心方向の同じ位置に存在するとは、管状本体10の軸心方向に見た場合に、一方の長さ領域が他方の長さ領域と実質的に重複しているか、または包含されていることをいう。ただし、当該一方または他方の長さ領域の一部が軸心方向に互いに僅かにずれあっていることを排除するものではない。
Here, the two length regions are present at the same position in the axial direction, when viewed in the axial direction of the tubular body 10, one length region substantially overlaps the other length region. Or is included. However, it does not exclude that a part of the one or other length region is slightly shifted in the axial direction.
サブチューブ40に対する保持ワイヤ70の巻張力を周期的に変化させながら保持ワイヤ70を螺旋巻回することにより、本実施形態のように第一長さ領域L1および第二長さ領域L2を形成することができる。具体的な方法は後述する。
The first length region L1 and the second length region L2 are formed as in the present embodiment by spirally winding the holding wire 70 while periodically changing the winding tension of the holding wire 70 with respect to the subtube 40. be able to. A specific method will be described later.
第一長さ領域L1および第二長さ領域L2の軸心方向の長さは、保持ワイヤ70の巻回ピッチと等しいか、または巻回ピッチの1/2の整数倍である。保持ワイヤ層が保持ワイヤ70を多条に巻回してなるコイルである場合、保持ワイヤ70の巻回ピッチとは、各保持ワイヤ70の一本に着目した場合のループ間隔をいう。本実施形態の保持ワイヤ層は二条のコイル素線(保持ワイヤ70)からなる多条コイルである。図4では、第一長さ領域L1および第二長さ領域L2が1.5ループごとに繰り返されている状態を例示している。この場合、第一長さ領域L1および第二長さ領域L2の軸心方向の長さは、保持ワイヤ70を構成するコイル素線の巻回ピッチの1.5倍にあたる。
The length in the axial direction of the first length region L1 and the second length region L2 is equal to the winding pitch of the holding wire 70 or is an integral multiple of 1/2 of the winding pitch. When the holding wire layer is a coil formed by winding the holding wire 70 in multiple lines, the winding pitch of the holding wire 70 refers to a loop interval when attention is paid to one of the holding wires 70. The holding wire layer of this embodiment is a multi-strand coil composed of two coil wires (holding wire 70). FIG. 4 illustrates a state where the first length region L1 and the second length region L2 are repeated every 1.5 loops. In this case, the lengths in the axial direction of the first length region L1 and the second length region L2 are 1.5 times the winding pitch of the coil wire constituting the holding wire 70.
管状本体10は、保持ワイヤ70の外側に、第二補強ワイヤ82を断面円形に巻回してなる第二補強層80を備えている。本実施形態の第二補強層80は金属の細線をメッシュ状に編組したブレード層である。すなわち、本実施形態の管状本体10は、ワイヤ補強層30、保持ワイヤ70および第二補強層80という三層の金属層を備えている。
The tubular main body 10 includes a second reinforcing layer 80 formed by winding a second reinforcing wire 82 in a circular cross section outside the holding wire 70. The second reinforcing layer 80 of the present embodiment is a blade layer in which fine metal wires are braided in a mesh shape. That is, the tubular main body 10 of this embodiment includes three metal layers, that is, a wire reinforcing layer 30, a holding wire 70, and a second reinforcing layer 80.
第二補強層80は、ワイヤ補強層30とともに管状本体10に曲げ弾性を付与する部材である。操作線60の牽引操作により管状本体10の遠位部DEの少なくとも一部領域を屈曲させたのち、操作線60の引張荷重を除去したときに、管状本体10が弾性的に復元することが好ましい。このため、本実施形態の管状本体10は、ワイヤ補強層30(補強ワイヤ32)および第二補強層80(第二補強ワイヤ82)にバネ性の金属材料を用いることが好ましい。したがって、保持ワイヤ70の延性は、補強ワイヤ32および第二補強ワイヤ82のいずれの延性よりも高い。
The second reinforcing layer 80 is a member that imparts bending elasticity to the tubular body 10 together with the wire reinforcing layer 30. It is preferable that the tubular body 10 is elastically restored when the tensile load of the operation line 60 is removed after at least a partial region of the distal portion DE of the tubular body 10 is bent by the pulling operation of the operation line 60. . For this reason, it is preferable that the tubular main body 10 of this embodiment uses a spring metal material for the wire reinforcing layer 30 (reinforcing wire 32) and the second reinforcing layer 80 (second reinforcing wire 82). Therefore, the ductility of the holding wire 70 is higher than any of the ductility of the reinforcing wire 32 and the second reinforcing wire 82.
保持ワイヤ70は、サブチューブ40をワイヤ補強層30の周囲に巻回固定するとともに、サブチューブ40に嵌入して外層50との界面剥離を抑制するための部材である。したがって、保持ワイヤ70は、ワイヤ補強層30および第二補強層80に比べて強度は低くてよい。このため、本実施形態では、図3に示すように、保持ワイヤ70の巻回ピッチ、すなわち隣接する保持ワイヤ70のループ間隔は、ワイヤ補強層30(補強ワイヤ32)および第二補強層80(第二補強ワイヤ82)のピッチ間隔のいずれよりも大きくしている。ここでいうピッチ間隔とは、メッシュのうち同方向に巻回された隣接する補強ワイヤ32同士または第二補強ワイヤ82同士の、管状本体10の軸心方向の間隔をいう。ただし、本実施形態に代えて、隣接する保持ワイヤ70のループ間隔が、ワイヤ補強層30(補強ワイヤ32)および第二補強層80(第二補強ワイヤ82)のピッチ間隔の一方または両方よりも小さくてもよい。これにより、保持ワイヤ70によってサブチューブ40とワイヤ補強層30とを好適に保持することができる。また、隣接する保持ワイヤ70のループ間隔を、ワイヤ補強層30(補強ワイヤ32)のピッチ間隔よりも大きく、かつ、第二補強層80(第二補強ワイヤ82)のピッチ間隔よりも小さくしてもよい。
The holding wire 70 is a member for winding and fixing the subtube 40 around the wire reinforcing layer 30 and for fitting the subtube 40 into the subtube 40 to suppress interfacial peeling from the outer layer 50. Therefore, the holding wire 70 may be lower in strength than the wire reinforcing layer 30 and the second reinforcing layer 80. Therefore, in this embodiment, as shown in FIG. 3, the winding pitch of the holding wires 70, that is, the loop interval between the adjacent holding wires 70, is determined by the wire reinforcing layer 30 (reinforcing wire 32) and the second reinforcing layer 80 ( It is larger than any of the pitch intervals of the second reinforcing wires 82). The pitch interval here refers to an interval in the axial direction of the tubular body 10 between adjacent reinforcing wires 32 or second reinforcing wires 82 wound in the same direction in the mesh. However, instead of this embodiment, the loop interval between adjacent holding wires 70 is greater than one or both of the pitch intervals between the wire reinforcing layer 30 (reinforcing wire 32) and the second reinforcing layer 80 (second reinforcing wire 82). It may be small. Thereby, the subtube 40 and the wire reinforcing layer 30 can be suitably held by the holding wire 70. Further, the loop interval between the adjacent holding wires 70 is set larger than the pitch interval of the wire reinforcing layer 30 (reinforcing wire 32) and smaller than the pitch interval of the second reinforcing layer 80 (second reinforcing wire 82). Also good.
図7は本実施形態の管状本体10の遠位部DEを示す側面図である。
FIG. 7 is a side view showing the distal portion DE of the tubular body 10 of the present embodiment.
管状本体10の遠位部DEには、上述のように放射線不透過材料からなるマーカー部(第一マーカー14)が装備されている。保持ワイヤ70の先端(端点71)は、マーカー部(第一マーカー14)の基端側に対して接着材56により接着固定されている。言い換えると、第一マーカー14は保持ワイヤ70の先端側の端部72よりも遠位側に装備されている。第一マーカー14はワイヤ補強層30(補強ワイヤ32)の外側面に装着されており、保持ワイヤ70と第一マーカー14とは管状本体10の径方向に、少なくとも部分的に重なり合っている。
The distal portion DE of the tubular body 10 is equipped with a marker portion (first marker 14) made of a radiopaque material as described above. The distal end (end point 71) of the holding wire 70 is bonded and fixed to the proximal end side of the marker portion (first marker 14) by an adhesive material 56. In other words, the first marker 14 is provided on the distal side of the end portion 72 on the distal end side of the holding wire 70. The first marker 14 is attached to the outer surface of the wire reinforcing layer 30 (reinforcing wire 32), and the holding wire 70 and the first marker 14 overlap at least partially in the radial direction of the tubular body 10.
図7に示すように、多条のコイル素線(保持ワイヤ)70a、70bの端点71は、第一マーカー14の基端側の端面に押し当てられた状態で接着固定されている。すなわち、コイル素線(保持ワイヤ)70a、70bは第一マーカー14によって巻き緩みが抑制された状態で固定されている。
As shown in FIG. 7, the end points 71 of the multifilamentary coil wires (holding wires) 70 a and 70 b are bonded and fixed in a state of being pressed against the end surface on the proximal end side of the first marker 14. That is, the coil strands (holding wires) 70a and 70b are fixed in a state in which the winding looseness is suppressed by the first marker 14.
具体的には、ワイヤ補強層30の表面にコイル素線(保持ワイヤ)70a、70bを螺旋巻回する。つぎに、螺旋巻回されたコイル素線(保持ワイヤ)70a、70bの上から接着材56を塗布する。これにより、接着材56は補強ワイヤ32の目開きに充填され、かつコイル素線(保持ワイヤ)70a、70bの一部長さを埋包した状態となる。接着材56の乾燥後、コイル素線70a、70bの余剰長さを切断することで、コイル素線70a、70b(保持ワイヤ)の端点71が第一マーカー14の基端側の端面にばらけることなく固定される。これにより、コイル素線70a、70bの端点71が外層50やサブチューブ40を傷つけることがない。
Specifically, coil wires (holding wires) 70 a and 70 b are spirally wound around the surface of the wire reinforcing layer 30. Next, the adhesive 56 is applied on the spirally wound coil strands (holding wires) 70a and 70b. As a result, the adhesive material 56 is filled in the openings of the reinforcing wires 32 and the coil wires (holding wires) 70a and 70b are partially embedded. After the adhesive material 56 is dried, the end points 71 of the coil strands 70a and 70b (holding wires) are separated from the proximal end surface of the first marker 14 by cutting the excess length of the coil strands 70a and 70b. It is fixed without. Thereby, the end points 71 of the coil strands 70a and 70b do not damage the outer layer 50 and the subtube 40.
図7に示すように、ワイヤ補強層30は多条の補強ワイヤ32を編組してなる。互いに交差する多条の補強ワイヤ32は矩形の目開きを構成する。接着材56は、ワイヤ補強層30のうちマーカー部(第一マーカー14)の基端側に隣接する複数の目開きの内側に充填されている。保持ワイヤ70(コイル素線70a、70b)の先端(端点71)は、この接着材56に接着固定されている。
また、ワイヤ補強層30は、接着材56を用いずに、リング状の第一マーカー14により内層24の外周面にかしめ固定されていてもよい。 As shown in FIG. 7, thewire reinforcing layer 30 is formed by braiding a plurality of reinforcing wires 32. The multiple reinforcing wires 32 intersecting each other constitute a rectangular mesh. The adhesive material 56 is filled in a plurality of openings adjacent to the proximal end side of the marker portion (first marker 14) in the wire reinforcing layer 30. The tips (end points 71) of the holding wires 70 ( coil wires 70a and 70b) are bonded and fixed to the adhesive material 56.
Further, thewire reinforcing layer 30 may be caulked and fixed to the outer peripheral surface of the inner layer 24 by the ring-shaped first marker 14 without using the adhesive material 56.
また、ワイヤ補強層30は、接着材56を用いずに、リング状の第一マーカー14により内層24の外周面にかしめ固定されていてもよい。 As shown in FIG. 7, the
Further, the
接着材56は、隣接する複数の目開きに充填されている。接着材56は、第一マーカー14の基端側に沿って全周に設けられていてもよく、または端点71を包含する一部領域のみに設けられていてもよい。本実施形態では、接着材56が充填されたワイヤ補強層30の複数の目開きは、互いに隣接してワイヤ補強層30における非周回領域を構成している。接着材56を周回状ではなく非周回に設けることで、端点71の固着作業が容易であり、また第一マーカー14の基端側における管状本体10の柔軟性を損なうことが防止される。
The adhesive material 56 is filled in a plurality of adjacent openings. The adhesive material 56 may be provided on the entire circumference along the base end side of the first marker 14, or may be provided only in a partial region including the end point 71. In the present embodiment, the plurality of openings of the wire reinforcing layer 30 filled with the adhesive material 56 constitute non-circular regions in the wire reinforcing layer 30 adjacent to each other. By providing the adhesive material 56 in a non-circular shape instead of a circular shape, the fixing work of the end point 71 is easy, and the flexibility of the tubular body 10 on the proximal end side of the first marker 14 is prevented from being impaired.
接着材56には、有機系接着剤または鑞付けを用いることができる。
有機系接着剤としては、常温硬化型接着剤、熱硬化型接着剤、溶液型接着剤またはホットメルト型接着剤を用いることができる。
常温硬化型接着剤としては、シアノアクリレート系接着剤、シリコーン系接着剤、エポキシ樹脂系接着剤またはアクリル樹脂系接着剤などの反応系接着剤のほか、ウレタンアクリレートやエポキシアクリレートなどの紫外線硬化系接着剤を用いることができる。
熱硬化型接着剤としては、エポキシ樹脂系接着剤を用いることができる。
溶液型接着剤としては、アクリル樹脂エマルジョン接着剤、α-オレフィン系接着剤、ウレタン樹脂溶剤系接着剤、エチレン-酢酸ビニル樹脂エマルジョン接着剤、酢酸ビニル樹脂エマルジョン接着剤またはポリ酢酸ビニル樹脂溶液系接着剤を例示することができる。
ホットメルト型接着剤としては、エチレン-酢酸ビニル樹脂ホットメルト接着剤、ポリウレタン樹脂ホットメルト接着剤、ポリオレフィン樹脂ホットメルト接着剤を例示することができる。
鑞付けとしては、ハンダまたは銀鑞を例示することができる。 An organic adhesive or brazing can be used for theadhesive material 56.
As the organic adhesive, a room temperature curable adhesive, a thermosetting adhesive, a solution adhesive, or a hot melt adhesive can be used.
Room temperature curing adhesives include reactive adhesives such as cyanoacrylate adhesives, silicone adhesives, epoxy resin adhesives or acrylic resin adhesives, and UV curable adhesives such as urethane acrylates and epoxy acrylates. An agent can be used.
An epoxy resin adhesive can be used as the thermosetting adhesive.
Solution type adhesives include acrylic resin emulsion adhesives, α-olefin adhesives, urethane resin solvent adhesives, ethylene-vinyl acetate resin emulsion adhesives, vinyl acetate resin emulsion adhesives or polyvinyl acetate resin solution adhesives. Agents can be exemplified.
Examples of the hot melt adhesive include ethylene-vinyl acetate resin hot melt adhesive, polyurethane resin hot melt adhesive, and polyolefin resin hot melt adhesive.
As the brazing, solder or silver candy can be exemplified.
有機系接着剤としては、常温硬化型接着剤、熱硬化型接着剤、溶液型接着剤またはホットメルト型接着剤を用いることができる。
常温硬化型接着剤としては、シアノアクリレート系接着剤、シリコーン系接着剤、エポキシ樹脂系接着剤またはアクリル樹脂系接着剤などの反応系接着剤のほか、ウレタンアクリレートやエポキシアクリレートなどの紫外線硬化系接着剤を用いることができる。
熱硬化型接着剤としては、エポキシ樹脂系接着剤を用いることができる。
溶液型接着剤としては、アクリル樹脂エマルジョン接着剤、α-オレフィン系接着剤、ウレタン樹脂溶剤系接着剤、エチレン-酢酸ビニル樹脂エマルジョン接着剤、酢酸ビニル樹脂エマルジョン接着剤またはポリ酢酸ビニル樹脂溶液系接着剤を例示することができる。
ホットメルト型接着剤としては、エチレン-酢酸ビニル樹脂ホットメルト接着剤、ポリウレタン樹脂ホットメルト接着剤、ポリオレフィン樹脂ホットメルト接着剤を例示することができる。
鑞付けとしては、ハンダまたは銀鑞を例示することができる。 An organic adhesive or brazing can be used for the
As the organic adhesive, a room temperature curable adhesive, a thermosetting adhesive, a solution adhesive, or a hot melt adhesive can be used.
Room temperature curing adhesives include reactive adhesives such as cyanoacrylate adhesives, silicone adhesives, epoxy resin adhesives or acrylic resin adhesives, and UV curable adhesives such as urethane acrylates and epoxy acrylates. An agent can be used.
An epoxy resin adhesive can be used as the thermosetting adhesive.
Solution type adhesives include acrylic resin emulsion adhesives, α-olefin adhesives, urethane resin solvent adhesives, ethylene-vinyl acetate resin emulsion adhesives, vinyl acetate resin emulsion adhesives or polyvinyl acetate resin solution adhesives. Agents can be exemplified.
Examples of the hot melt adhesive include ethylene-vinyl acetate resin hot melt adhesive, polyurethane resin hot melt adhesive, and polyolefin resin hot melt adhesive.
As the brazing, solder or silver candy can be exemplified.
接着材56は、外層50、特に第二外層54よりも融点が高いことが好ましい。これにより、保持ワイヤ70(保持ワイヤ層)の周囲に外層50を熱成形する際にもコイル素線(保持ワイヤ)70a、70bの端点71が固着されているため、端部72が巻き緩むことがない。かかる観点および硬化速度の速さから、シアノアクリレート系の瞬間接着剤である常温硬化型接着剤が好適に用いられる。
The adhesive material 56 preferably has a higher melting point than the outer layer 50, particularly the second outer layer 54. As a result, when the outer layer 50 is thermoformed around the holding wire 70 (holding wire layer), the end points 71 of the coil wires (holding wires) 70a and 70b are fixed, so that the end 72 is loosened. There is no. From this point of view and high curing speed, a room temperature curable adhesive which is a cyanoacrylate-based instantaneous adhesive is preferably used.
保持ワイヤ層は多条のコイル素線(保持ワイヤ)70a、70bを巻回してなる。多条のコイル素線(保持ワイヤ)70a、70bの先端(端点71)は、管状本体10の周方向の略同一の位置で接着材56に接着固定されている。
図7に示すように、本実施形態のコイル素線(保持ワイヤ)70aと70bとは先端(端点71)で束ねられて接着固定されている。ただし、これに代えて、コイル素線(保持ワイヤ)70aと70bとが束ねられておらず、端点71同士が管状本体10の軸心方向に互いに解離していてもよい。なお、コイル素線(保持ワイヤ)70a、70bの端点71同士が管状本体10の周方向の略同一の位置にあるとは、端点71同士が主管腔20を挟んで対向していることを排除する趣旨であり、端点71同士の位置が厳密に一致している状態のほか、端点71同士が主管腔20に対して同一側にあって周方向に僅かにずれている状態を含む。 The holding wire layer is formed by winding a plurality of coil wire (holding wires) 70a and 70b. The tips (end points 71) of the multi-element coil wires (holding wires) 70 a and 70 b are bonded and fixed to the adhesive 56 at substantially the same position in the circumferential direction of thetubular body 10.
As shown in FIG. 7, the coil wires (holding wires) 70a and 70b of the present embodiment are bundled and fixed by bonding at the tips (end points 71). However, instead of this, the coil wires (holding wires) 70 a and 70 b may not be bundled, and the end points 71 may be dissociated from each other in the axial direction of thetubular body 10. Note that the fact that the end points 71 of the coil strands (holding wires) 70a and 70b are at substantially the same position in the circumferential direction of the tubular main body 10 excludes that the end points 71 face each other across the main lumen 20. In addition to the state in which the positions of the end points 71 are exactly matched, the end points 71 are on the same side with respect to the main lumen 20 and are slightly displaced in the circumferential direction.
図7に示すように、本実施形態のコイル素線(保持ワイヤ)70aと70bとは先端(端点71)で束ねられて接着固定されている。ただし、これに代えて、コイル素線(保持ワイヤ)70aと70bとが束ねられておらず、端点71同士が管状本体10の軸心方向に互いに解離していてもよい。なお、コイル素線(保持ワイヤ)70a、70bの端点71同士が管状本体10の周方向の略同一の位置にあるとは、端点71同士が主管腔20を挟んで対向していることを排除する趣旨であり、端点71同士の位置が厳密に一致している状態のほか、端点71同士が主管腔20に対して同一側にあって周方向に僅かにずれている状態を含む。 The holding wire layer is formed by winding a plurality of coil wire (holding wires) 70a and 70b. The tips (end points 71) of the multi-element coil wires (holding wires) 70 a and 70 b are bonded and fixed to the adhesive 56 at substantially the same position in the circumferential direction of the
As shown in FIG. 7, the coil wires (holding wires) 70a and 70b of the present embodiment are bundled and fixed by bonding at the tips (end points 71). However, instead of this, the coil wires (holding wires) 70 a and 70 b may not be bundled, and the end points 71 may be dissociated from each other in the axial direction of the
サブチューブ40の肉厚は保持ワイヤ70および操作線60の線径のいずれよりも小さい。また、保持ワイヤ70の線径は、操作線60の線径よりも小さい。保持ワイヤ70が細径で曲率半径が小さいことにより、保持ワイヤ70を所定の深さでサブチューブ40に嵌入させたときに、保持ワイヤ70のうち嵌入している中心角を大きくすることができる。このため、界面剥離の伸展を良好に防止することができる。
The wall thickness of the sub tube 40 is smaller than both the holding wire 70 and the operation wire 60. Further, the wire diameter of the holding wire 70 is smaller than the wire diameter of the operation wire 60. Since the holding wire 70 has a small diameter and a small radius of curvature, when the holding wire 70 is fitted into the sub-tube 40 at a predetermined depth, the center angle of the holding wire 70 can be increased. . For this reason, extension of interfacial peeling can be prevented satisfactorily.
管状本体10の遠位部DEには、第一マーカー14と、この第一マーカー14よりも近位側に位置する第二マーカー16と、が設けられている。第一マーカー14および第二マーカー16は、白金など、X線等の放射線が不透過の材料からなるリング状の部材である。第一マーカー14および第二マーカー16の2つのマーカーの位置を指標とすることにより、放射線(X線)観察下において体腔(血管)内における管状本体10の先端の位置を視認することができる。これにより、カテーテル100の屈曲操作を行うのに最適なタイミングを容易に判断することができる。
The distal part DE of the tubular main body 10 is provided with a first marker 14 and a second marker 16 located on the proximal side of the first marker 14. The first marker 14 and the second marker 16 are ring-shaped members made of a material that does not transmit radiation such as X-rays such as platinum. By using the positions of the two markers of the first marker 14 and the second marker 16 as an index, the position of the distal end of the tubular body 10 in the body cavity (blood vessel) can be visually confirmed under radiation (X-ray) observation. Thereby, the optimal timing for performing the bending operation of the catheter 100 can be easily determined.
操作線60の先端部は、管状本体10のうち第二マーカー16よりも遠位側の部分に固定されている。操作線60を牽引することで、遠位部DEのうち第二マーカー16よりも遠位側の部分が屈曲する。本実施形態のカテーテル100では、操作線60の先端部は第一マーカー14に固定されている。操作線60を第一マーカー14に固定する態様は特に限定されず、ハンダ接合、熱融着、有機系接着剤による接着、操作線60と第一マーカー14との機械的掛止などを挙げることができる。
The tip of the operation line 60 is fixed to a portion of the tubular main body 10 that is more distal than the second marker 16. By pulling the operation line 60, the distal portion of the distal portion DE with respect to the second marker 16 is bent. In the catheter 100 of this embodiment, the distal end portion of the operation line 60 is fixed to the first marker 14. The mode of fixing the operation line 60 to the first marker 14 is not particularly limited, and examples include solder bonding, thermal fusion, adhesion with an organic adhesive, and mechanical engagement between the operation line 60 and the first marker 14. Can do.
第二マーカー16の内径は、第一マーカー14の内径よりも大きい。第一マーカー14はワイヤ補強層30の外表面に接触しているか、またはほぼ接触するように配置されている。第一マーカー14の内径はワイヤ補強層30の外径よりも大きく、第二補強層80の内径よりも小さい。
第一マーカー14の内壁面および外周表面と、サブチューブ40との径方向の位置関係は特に限定されない。操作線60を第一マーカー14の外周表面に固定する場合は、図3のように、第一マーカー14の外周表面がサブチューブ40の先端の配設位置の内部(内径側)に位置するよう、第一マーカー14の外径を設定することができる。このほか、操作線60を第一マーカー14の基端側の端面に固定する場合は、当該端面がサブチューブ40の先端と径方向に重複するとよい。この場合、第一マーカー14の外周表面がサブチューブ40の先端の配設位置よりも外径側に位置してもよい。
第二マーカー16は、第二補強層80の外表面に接触しているか、またはほぼ接触するように配置されている。第二マーカー16の内径は第二補強層80の外径よりも大きい。 The inner diameter of thesecond marker 16 is larger than the inner diameter of the first marker 14. The first marker 14 is disposed so as to be in contact with or substantially in contact with the outer surface of the wire reinforcing layer 30. The inner diameter of the first marker 14 is larger than the outer diameter of the wire reinforcing layer 30 and smaller than the inner diameter of the second reinforcing layer 80.
The radial positional relationship between the inner wall surface and outer peripheral surface of thefirst marker 14 and the subtube 40 is not particularly limited. When the operation line 60 is fixed to the outer peripheral surface of the first marker 14, the outer peripheral surface of the first marker 14 is positioned inside (inner diameter side) the arrangement position of the tip of the subtube 40 as shown in FIG. 3. The outer diameter of the first marker 14 can be set. In addition, when the operation line 60 is fixed to the end surface on the proximal end side of the first marker 14, the end surface may overlap with the distal end of the subtube 40 in the radial direction. In this case, the outer peripheral surface of the first marker 14 may be located on the outer diameter side with respect to the arrangement position of the tip of the subtube 40.
Thesecond marker 16 is disposed so as to be in contact with or substantially in contact with the outer surface of the second reinforcing layer 80. The inner diameter of the second marker 16 is larger than the outer diameter of the second reinforcing layer 80.
第一マーカー14の内壁面および外周表面と、サブチューブ40との径方向の位置関係は特に限定されない。操作線60を第一マーカー14の外周表面に固定する場合は、図3のように、第一マーカー14の外周表面がサブチューブ40の先端の配設位置の内部(内径側)に位置するよう、第一マーカー14の外径を設定することができる。このほか、操作線60を第一マーカー14の基端側の端面に固定する場合は、当該端面がサブチューブ40の先端と径方向に重複するとよい。この場合、第一マーカー14の外周表面がサブチューブ40の先端の配設位置よりも外径側に位置してもよい。
第二マーカー16は、第二補強層80の外表面に接触しているか、またはほぼ接触するように配置されている。第二マーカー16の内径は第二補強層80の外径よりも大きい。 The inner diameter of the
The radial positional relationship between the inner wall surface and outer peripheral surface of the
The
図3に示すように、ワイヤ補強層30の遠位端は、第一マーカー14の配設領域に達している。第一マーカー14の配設領域とは、管状本体10の軸心方向にみて第一マーカー14が形成されている長さ領域である。第二マーカー16に関しても同様である。ワイヤ補強層30の遠位端は、第一マーカー14の近位端よりも、管状本体10の遠位側に位置している。また、ワイヤ補強層30の遠位端は、第一マーカー14の遠位端の近傍に位置している。このように、ワイヤ補強層30が第一マーカー14の配設領域まで到達していることで、第一マーカー14の近位端における管状本体10の曲げ剛性の不連続性を緩和してキンクの発生を防止している。
As shown in FIG. 3, the distal end of the wire reinforcing layer 30 reaches the region where the first marker 14 is disposed. The arrangement region of the first marker 14 is a length region in which the first marker 14 is formed when viewed in the axial direction of the tubular main body 10. The same applies to the second marker 16. The distal end of the wire reinforcing layer 30 is located on the distal side of the tubular body 10 with respect to the proximal end of the first marker 14. Further, the distal end of the wire reinforcing layer 30 is located in the vicinity of the distal end of the first marker 14. In this way, the wire reinforcing layer 30 reaches the region where the first marker 14 is disposed, so that the discontinuity of the bending rigidity of the tubular body 10 at the proximal end of the first marker 14 is alleviated and the kink Occurrence is prevented.
第二補強層80の遠位端は、第一マーカー14の近位端よりも近位側、かつ第二マーカー16の配設領域の近位端よりも遠位側である。第二補強層80の遠位端は、第二マーカー16の遠位端の近傍に位置している。これにより、第二マーカー16の遠位端において管状本体10の曲げ剛性に不連続性を発生させている。このため、操作線60を牽引操作した場合に、第二マーカー16の僅かに遠位側において管状本体10をシャープに屈曲させることができる。なお、このように管状本体10をシャープに屈曲させても、上記のようにワイヤ補強層30が第一マーカー14の配設領域まで連続的に形成されているため、管状本体10にキンクが生じることがない。言い換えると、ワイヤ補強層30または第二補強層80の一方を管状本体10の遠位端近傍まで連続的に形成してキンクを防止し、他方を遠位部DEの途中で終端させることで管状本体10に曲げ剛性の不連続性を生じさせて屈曲位置を明確に規定している。
The distal end of the second reinforcing layer 80 is more proximal than the proximal end of the first marker 14 and more distal than the proximal end of the region where the second marker 16 is disposed. The distal end of the second reinforcing layer 80 is located in the vicinity of the distal end of the second marker 16. Thereby, a discontinuity is generated in the bending rigidity of the tubular body 10 at the distal end of the second marker 16. For this reason, when the operation line 60 is pulled, the tubular body 10 can be sharply bent slightly on the distal side of the second marker 16. Even if the tubular body 10 is bent sharply in this way, the wire reinforcing layer 30 is continuously formed up to the region where the first marker 14 is disposed as described above, and thus the tubular body 10 is kinked. There is nothing. In other words, one of the wire reinforcing layer 30 and the second reinforcing layer 80 is continuously formed up to the vicinity of the distal end of the tubular body 10 to prevent kinking, and the other is terminated in the middle of the distal portion DE. The bending position is clearly defined by causing a discontinuity of bending rigidity in the main body 10.
ワイヤ補強層30および第二補強層80の近位端は、管状本体10の近位端、すなわち操作部90の内部に位置している。
The proximal ends of the wire reinforcing layer 30 and the second reinforcing layer 80 are located at the proximal end of the tubular body 10, that is, inside the operation unit 90.
内層24の遠位端は、管状本体10の遠位端まで到達していてもよく、または遠位端よりも基端側で終端していてもよい。内層24が終端する位置としては、第一マーカー14の配設領域の内部でもよい。
The distal end of the inner layer 24 may reach the distal end of the tubular body 10 or may terminate on the proximal side of the distal end. The position where the inner layer 24 terminates may be inside the region where the first marker 14 is disposed.
なお、本発明は上記の実施形態に限定されるものではなく、本発明の目的を達成できる範囲での変形、改良等は本発明に含まれるものである。
上記の実施形態では、ワイヤ補強層30がブレード層であって、第一外層52がサブチューブ40の周囲からワイヤ補強層30の目開きの内部に含浸して、内層24、ワイヤ補強層30およびサブチューブ40が一体に固着されていることを例示した。これに代えて、外層50の内側層にあたる第一外層52が、ワイヤ補強層30とサブチューブ40との間に実質的に含浸していなくてもよい。すなわち、上記の数式(2)で表されるワイヤ補強層30の周方向の目開き寸法Wよりもサブチューブ40の外径が大きくてもよい。そして、サブチューブ40の直下の目開きがサブチューブ40により閉止されて、第一外層52が完全には充填されていない空洞部を有する目開きがあってもよい。
また、上記の実施形態では、補強ワイヤ32、保持ワイヤ70、第二補強ワイヤ82がいずれも断面円形の線であるものを例示したが、これらはいずれも断面円形に限られるものではなく、断面楕円形、断面多角形等の線であってもよい。 In addition, this invention is not limited to said embodiment, The deformation | transformation in the range which can achieve the objective of this invention, improvement, etc. are included in this invention.
In the above embodiment, thewire reinforcing layer 30 is a blade layer, and the first outer layer 52 is impregnated from the periphery of the subtube 40 into the inside of the opening of the wire reinforcing layer 30, so that the inner layer 24, the wire reinforcing layer 30, and The sub-tube 40 is exemplified as being integrally fixed. Instead, the first outer layer 52 corresponding to the inner layer of the outer layer 50 may not be substantially impregnated between the wire reinforcing layer 30 and the subtube 40. That is, the outer diameter of the subtube 40 may be larger than the opening dimension W in the circumferential direction of the wire reinforcing layer 30 represented by the above formula (2). And the opening just under the subtube 40 may be closed by the subtube 40, and there may be an opening which has the cavity part which the 1st outer layer 52 is not completely filled.
Further, in the above embodiment, the reinforcingwire 32, the holding wire 70, and the second reinforcing wire 82 are all illustrated as having a circular cross section, but these are not limited to a circular cross section, It may be a line such as an ellipse or a polygon in cross section.
上記の実施形態では、ワイヤ補強層30がブレード層であって、第一外層52がサブチューブ40の周囲からワイヤ補強層30の目開きの内部に含浸して、内層24、ワイヤ補強層30およびサブチューブ40が一体に固着されていることを例示した。これに代えて、外層50の内側層にあたる第一外層52が、ワイヤ補強層30とサブチューブ40との間に実質的に含浸していなくてもよい。すなわち、上記の数式(2)で表されるワイヤ補強層30の周方向の目開き寸法Wよりもサブチューブ40の外径が大きくてもよい。そして、サブチューブ40の直下の目開きがサブチューブ40により閉止されて、第一外層52が完全には充填されていない空洞部を有する目開きがあってもよい。
また、上記の実施形態では、補強ワイヤ32、保持ワイヤ70、第二補強ワイヤ82がいずれも断面円形の線であるものを例示したが、これらはいずれも断面円形に限られるものではなく、断面楕円形、断面多角形等の線であってもよい。 In addition, this invention is not limited to said embodiment, The deformation | transformation in the range which can achieve the objective of this invention, improvement, etc. are included in this invention.
In the above embodiment, the
Further, in the above embodiment, the reinforcing
第二外層54の外表面に形成される親水層(図示せず)は、カテーテル100の最外層を構成する。親水層は、管状本体10の全長に形成されていてもよく、または遠位部DEを含む先端側の一部長さ領域のみに形成されていてもよい。親水層は、たとえば、ポリビニルアルコール(PVA)などの無水マレイン酸系ポリマーやその共重合体、ポリビニルピロリドンなどの親水性の樹脂材料からなる。
A hydrophilic layer (not shown) formed on the outer surface of the second outer layer 54 constitutes the outermost layer of the catheter 100. The hydrophilic layer may be formed over the entire length of the tubular body 10 or may be formed only in a partial length region on the tip side including the distal portion DE. The hydrophilic layer is made of, for example, a maleic anhydride polymer such as polyvinyl alcohol (PVA) or a copolymer thereof, or a hydrophilic resin material such as polyvinyl pyrrolidone.
本実施形態のカテーテル100の構成要素の代表的な寸法について説明する。
主管腔20の直径は400μm~600μm(上限値および下限値を含む。以下同じ。)、内層24の厚さは5μm~30μm、外層50の厚さは10μm~200μmとすることができる。サブチューブ40の肉厚は、内層24よりも薄く、かつ1μm~10μmとすることができる。ワイヤ補強層30の内径は410μm~660μm、ワイヤ補強層30の外径は450μm~740μm、第二補強層80の内径は560μm~920μm、第二補強層80の外径は600μm~940μmとすることができる。
第一マーカー14の内径は450μm~740μm、第一マーカー14の外径は490μm~820μm、第二マーカー16の内径は600μm~940μm、第二マーカー16の外径は640μm~960μmとすることができる。第一マーカー14の幅寸法(管状本体10の長手方向の寸法)は0.3mm~2.0mm、第二マーカー16の幅寸法は0.3mm~2.0mmとすることができる。
カテーテル100の軸心からサブチューブ40の中心までの半径(距離)は300μm~450μm、サブチューブ40の内径(直径)は40μm~100μm、操作線60の太さは25μm~60μmとすることができる。
管状本体10の直径は700μm~980μm、すなわち外径が直径1mm未満であり、腹腔動脈などの血管に挿通可能である。 The typical dimension of the component of thecatheter 100 of this embodiment is demonstrated.
The diameter of themain lumen 20 can be 400 μm to 600 μm (including the upper limit value and the lower limit value; the same applies hereinafter), the inner layer 24 can have a thickness of 5 μm to 30 μm, and the outer layer 50 can have a thickness of 10 μm to 200 μm. The thickness of the sub-tube 40 is thinner than the inner layer 24 and can be 1 μm to 10 μm. The inner diameter of the wire reinforcing layer 30 is 410 μm to 660 μm, the outer diameter of the wire reinforcing layer 30 is 450 μm to 740 μm, the inner diameter of the second reinforcing layer 80 is 560 μm to 920 μm, and the outer diameter of the second reinforcing layer 80 is 600 μm to 940 μm. Can do.
The inner diameter of thefirst marker 14 may be 450 μm to 740 μm, the outer diameter of the first marker 14 may be 490 μm to 820 μm, the inner diameter of the second marker 16 may be 600 μm to 940 μm, and the outer diameter of the second marker 16 may be 640 μm to 960 μm. . The width dimension of the first marker 14 (the dimension in the longitudinal direction of the tubular body 10) can be 0.3 mm to 2.0 mm, and the width dimension of the second marker 16 can be 0.3 mm to 2.0 mm.
The radius (distance) from the axis of thecatheter 100 to the center of the subtube 40 can be 300 μm to 450 μm, the inner diameter (diameter) of the subtube 40 can be 40 μm to 100 μm, and the thickness of the operation line 60 can be 25 μm to 60 μm. .
Thetubular body 10 has a diameter of 700 μm to 980 μm, that is, an outer diameter of less than 1 mm, and can be inserted into a blood vessel such as a celiac artery.
主管腔20の直径は400μm~600μm(上限値および下限値を含む。以下同じ。)、内層24の厚さは5μm~30μm、外層50の厚さは10μm~200μmとすることができる。サブチューブ40の肉厚は、内層24よりも薄く、かつ1μm~10μmとすることができる。ワイヤ補強層30の内径は410μm~660μm、ワイヤ補強層30の外径は450μm~740μm、第二補強層80の内径は560μm~920μm、第二補強層80の外径は600μm~940μmとすることができる。
第一マーカー14の内径は450μm~740μm、第一マーカー14の外径は490μm~820μm、第二マーカー16の内径は600μm~940μm、第二マーカー16の外径は640μm~960μmとすることができる。第一マーカー14の幅寸法(管状本体10の長手方向の寸法)は0.3mm~2.0mm、第二マーカー16の幅寸法は0.3mm~2.0mmとすることができる。
カテーテル100の軸心からサブチューブ40の中心までの半径(距離)は300μm~450μm、サブチューブ40の内径(直径)は40μm~100μm、操作線60の太さは25μm~60μmとすることができる。
管状本体10の直径は700μm~980μm、すなわち外径が直径1mm未満であり、腹腔動脈などの血管に挿通可能である。 The typical dimension of the component of the
The diameter of the
The inner diameter of the
The radius (distance) from the axis of the
The
図8(a)は、本実施形態のカテーテル100の全体側面図である。図8(b)は、ホイール操作部92を一方向(同図における時計回り)に操作した状態を示すカテーテル100の全体側面図である。図8(c)は、ホイール操作部92を他方向(同図における反時計回り)に操作した状態を示すカテーテル100の全体側面図である。
FIG. 8 (a) is an overall side view of the catheter 100 of the present embodiment. FIG. 8B is an overall side view of the catheter 100 showing a state in which the wheel operation unit 92 is operated in one direction (clockwise in FIG. 8). FIG. 8C is an overall side view of the catheter 100 showing a state in which the wheel operation unit 92 is operated in the other direction (counterclockwise in FIG. 8).
カテーテル100は、管状本体10の基端部に設けられて複数本の操作線60(図1から図3を参照)を個別に牽引する操作部90を有している。操作部90は、使用者が手で把持する本体ケース94と、この本体ケース94に対して回転可能に設けられたホイール操作部92と、を有している。管状本体10の基端部は、本体ケース94の内部に導入されている。操作線60が挿通された二本のサブチューブ40(図1から図3を参照)は、本体ケース94の前端部の内部において管状本体10から分岐している。これらのサブチューブ40からそれぞれ引き出された操作線60の基端部はホイール操作部92に連結されている。ホイール操作部92を何れかの方向に回転操作することにより、一方の操作線60を基端側に牽引して張力を与え、他方を緩めることができる。これにより、牽引された操作線60がカテーテル100の遠位部DEの少なくとも一部領域を屈曲させる(図8(b)、図8(c)を参照)。ここで、管状本体10が屈曲するとは、管状本体10が「くの字」状に折れ曲がる態様と、弓なりに湾曲する態様とを含む。
The catheter 100 has an operation unit 90 that is provided at the proximal end of the tubular main body 10 and that individually pulls a plurality of operation lines 60 (see FIGS. 1 to 3). The operation unit 90 includes a main body case 94 that is gripped by the user's hand, and a wheel operation unit 92 that is provided so as to be rotatable with respect to the main body case 94. The proximal end portion of the tubular main body 10 is introduced into the main body case 94. The two sub tubes 40 (see FIGS. 1 to 3) through which the operation line 60 is inserted branch from the tubular main body 10 inside the front end portion of the main body case 94. The base end portion of the operation line 60 drawn from each of the sub tubes 40 is connected to the wheel operation portion 92. By rotating the wheel operation unit 92 in either direction, one operation line 60 can be pulled to the proximal end side to apply tension, and the other can be loosened. Accordingly, the pulled operation line 60 bends at least a partial region of the distal portion DE of the catheter 100 (see FIGS. 8B and 8C). Here, the bending of the tubular body 10 includes an aspect in which the tubular body 10 is bent in a “shape” and an aspect in which the tubular body 10 is curved in a bow shape.
このように、操作部90のホイール操作部92に対する操作によって、2本の操作線60を選択的に牽引することにより、カテーテル100の遠位部DEの少なくとも一部領域を、互いに同一平面に含まれる第一または第二の方向に選択的に屈曲させることができる。
As described above, by selectively pulling the two operation lines 60 by the operation of the operation unit 90 with respect to the wheel operation unit 92, at least a partial region of the distal portion DE of the catheter 100 is included in the same plane. Can be selectively bent in the first or second direction.
ホイール操作部92の周面には凹凸係合部が形成されている。本実施形態では、波形の縦目ローレットを例示する。本体ケース94には、ホイール操作部92に接する位置に凹部95が形成されている。凹部95には、ホイール操作部92に向かって進退自在に摺動するスライダ98が設けられている。スライダ98のうちホイール操作部92に向く先端部には突起99が形成されている。突起99は、ホイール操作部92の周面の凹凸係合部(縦目ローレット)の開口幅よりも小さい。スライダ98をホイール操作部92に向けて摺動させると、突起99がホイール操作部92の周面に掛止されてホイール操作部92の回転を規制する。これにより、カテーテル100の遠位部DEの一部領域が屈曲した状態でホイール操作部92の回転を規制することで、カテーテル100の屈曲状態を維持することができる。図8(a)はスライダ98の突起99とホイール操作部92とが非係合でホイール操作部92が回転可能な状態を示す。図8(b)および図8(c)は、スライダ98の突起99とホイール操作部92とが係合してホイール操作部92が回転規制され、遠位部DEの屈曲状態が保持されている状態を示す。
An uneven engagement portion is formed on the peripheral surface of the wheel operation portion 92. In the present embodiment, a vertical knurled waveform is illustrated. A recess 95 is formed in the main body case 94 at a position in contact with the wheel operation unit 92. The concave portion 95 is provided with a slider 98 that slides forward and backward toward the wheel operation portion 92. A protrusion 99 is formed at the tip of the slider 98 facing the wheel operation unit 92. The protrusion 99 is smaller than the opening width of the concave-convex engaging portion (vertical knurling) on the peripheral surface of the wheel operating portion 92. When the slider 98 is slid toward the wheel operation unit 92, the protrusion 99 is hooked on the peripheral surface of the wheel operation unit 92 to restrict the rotation of the wheel operation unit 92. Thereby, the bent state of the catheter 100 can be maintained by restricting the rotation of the wheel operation unit 92 in a state where a partial region of the distal portion DE of the catheter 100 is bent. FIG. 8A shows a state in which the protrusion 99 of the slider 98 and the wheel operation unit 92 are not engaged and the wheel operation unit 92 can rotate. 8B and 8C, the protrusion 99 of the slider 98 and the wheel operation portion 92 are engaged to restrict the rotation of the wheel operation portion 92, and the bent state of the distal portion DE is maintained. Indicates the state.
操作部90を管状本体10の軸回りに回転させることで、管状本体10の遠位部DEを所定の角度でトルク回転させることができる。ホイール操作部92の操作と操作部90の全体の軸回転とを組み合わせて行うことにより、カテーテル100の遠位部DEの向きを自在に制御することが可能となる。
Rotating the operation unit 90 about the axis of the tubular body 10 allows the distal portion DE of the tubular body 10 to be torque-rotated at a predetermined angle. By combining the operation of the wheel operation unit 92 and the entire shaft rotation of the operation unit 90, the direction of the distal portion DE of the catheter 100 can be freely controlled.
カテーテル100は、管状本体10の主管腔20と連通して設けられたハブ96を備えている。ハブ96にはシリンジ(図示せず)が装着される。ハブ96は本体ケース94の後端部に設けられており、ハブ96の後方(図8(a)の右方)からシリンジが装着される。シリンジによってハブ96内に薬液等を注入することにより、主管腔20を介して薬液等を患者の体腔内へ供給することができる。薬液等としては、造影剤、液体抗ガン剤、生理食塩水、瞬間接着剤として用いられるNBCA(n-butyl-2-cianoacrylate)を例示することができる。このほか、液体に限らず、塞栓コイルやビーズ(塞栓球状物質)等の医療用デバイスを薬液等として挙げることができる。
The catheter 100 includes a hub 96 provided in communication with the main lumen 20 of the tubular body 10. A syringe (not shown) is attached to the hub 96. The hub 96 is provided at the rear end of the main body case 94, and a syringe is mounted from the rear of the hub 96 (right side in FIG. 8A). By injecting a drug solution or the like into the hub 96 with a syringe, the drug solution or the like can be supplied into the body cavity of the patient via the main lumen 20. Examples of the chemical solution include a contrast agent, a liquid anticancer agent, physiological saline, and NBCA (n-butyl-2-cyanoacrylate) used as an instantaneous adhesive. In addition, medical devices such as embolization coils and beads (emboli globular material) are not limited to liquids.
〔製造方法〕
次に、図9~図12を参照して、本実施形態のカテーテル100の製造方法について説明する。図9は、主芯線22の周囲に内層24およびワイヤ補強層30を形成した内側構造体26の縦断面図である。図10は、副芯線44の周囲にサブチューブ40を形成した有芯チューブ46の側面図である。図11は、保持ワイヤ70の巻回工程を模式的に示す斜視図である。図12は、サブチューブ40の周囲に第二補強ワイヤ82を巻回した状態を示す側面図である。 〔Production method〕
Next, a method for manufacturing thecatheter 100 of the present embodiment will be described with reference to FIGS. FIG. 9 is a longitudinal sectional view of the inner structure 26 in which the inner layer 24 and the wire reinforcing layer 30 are formed around the main core wire 22. FIG. 10 is a side view of the cored tube 46 in which the subtube 40 is formed around the subcore wire 44. FIG. 11 is a perspective view schematically showing the winding process of the holding wire 70. FIG. 12 is a side view showing a state in which the second reinforcing wire 82 is wound around the sub-tube 40.
次に、図9~図12を参照して、本実施形態のカテーテル100の製造方法について説明する。図9は、主芯線22の周囲に内層24およびワイヤ補強層30を形成した内側構造体26の縦断面図である。図10は、副芯線44の周囲にサブチューブ40を形成した有芯チューブ46の側面図である。図11は、保持ワイヤ70の巻回工程を模式的に示す斜視図である。図12は、サブチューブ40の周囲に第二補強ワイヤ82を巻回した状態を示す側面図である。 〔Production method〕
Next, a method for manufacturing the
はじめに、本実施形態の医療用機器であるカテーテル100の製造方法(以下、本製造方法という場合がある)の概要について説明する。
First, an outline of a method for manufacturing the catheter 100, which is the medical device of the present embodiment (hereinafter sometimes referred to as the present manufacturing method), will be described.
本製造方法は、内側構造体準備工程、サブチューブ保持工程、本体形成工程、副芯線抜去工程および主芯線抜去工程を含む。
内側構造体準備工程は、主芯線22と、この主芯線22の周囲に補強ワイヤ32を巻回したワイヤ補強層30と、を含む内側構造体26を準備する工程である。
サブチューブ保持工程は、樹脂製のサブチューブ40で被覆された副芯線44を主芯線22に沿ってワイヤ補強層30の外周表面に配置し、保持ワイヤ70をサブチューブ40の表面に押圧して食い込ませながらサブチューブ40とワイヤ補強層30とを保持ワイヤ70で共巻きする工程である。
本体形成工程は、共巻きされたサブチューブ40およびワイヤ補強層30ならびに保持ワイヤ70を内包するように管状本体10を形成する工程である。
副芯線抜去工程は、副芯線44を伸張および縮径させてサブチューブ40から剥離させて副管腔42を形成する工程である。
主芯線抜去工程は、主芯線22を管状本体10から抜去して主管腔20を形成する工程である。 This manufacturing method includes an inner structure preparation step, a sub tube holding step, a main body forming step, a sub core wire extraction step, and a main core wire extraction step.
The inner structure preparation step is a step of preparing theinner structure 26 including the main core wire 22 and the wire reinforcing layer 30 in which the reinforcing wire 32 is wound around the main core wire 22.
In the sub-tube holding step, thesub-core wire 44 covered with the resin sub-tube 40 is disposed on the outer peripheral surface of the wire reinforcing layer 30 along the main core wire 22, and the holding wire 70 is pressed against the surface of the sub-tube 40. In this step, the sub-tube 40 and the wire reinforcing layer 30 are wound together by the holding wire 70 while being bitten.
The main body forming step is a step of forming the tubularmain body 10 so as to include the sub-tube 40, the wire reinforcing layer 30, and the holding wire 70 that are wound together.
The sub-core wire extracting step is a step of forming the sub-lumen 42 by extending and reducing the diameter of thesub-core wire 44 and separating it from the sub-tube 40.
The main core wire extraction step is a step of forming themain lumen 20 by extracting the main core wire 22 from the tubular body 10.
内側構造体準備工程は、主芯線22と、この主芯線22の周囲に補強ワイヤ32を巻回したワイヤ補強層30と、を含む内側構造体26を準備する工程である。
サブチューブ保持工程は、樹脂製のサブチューブ40で被覆された副芯線44を主芯線22に沿ってワイヤ補強層30の外周表面に配置し、保持ワイヤ70をサブチューブ40の表面に押圧して食い込ませながらサブチューブ40とワイヤ補強層30とを保持ワイヤ70で共巻きする工程である。
本体形成工程は、共巻きされたサブチューブ40およびワイヤ補強層30ならびに保持ワイヤ70を内包するように管状本体10を形成する工程である。
副芯線抜去工程は、副芯線44を伸張および縮径させてサブチューブ40から剥離させて副管腔42を形成する工程である。
主芯線抜去工程は、主芯線22を管状本体10から抜去して主管腔20を形成する工程である。 This manufacturing method includes an inner structure preparation step, a sub tube holding step, a main body forming step, a sub core wire extraction step, and a main core wire extraction step.
The inner structure preparation step is a step of preparing the
In the sub-tube holding step, the
The main body forming step is a step of forming the tubular
The sub-core wire extracting step is a step of forming the sub-lumen 42 by extending and reducing the diameter of the
The main core wire extraction step is a step of forming the
以下、本製造方法を詳細に説明する。
Hereinafter, this production method will be described in detail.
内側構造体準備工程では、はじめに、主芯線22の周囲に内層24を形成する。主芯線22はマンドレル(芯材)であり、主管腔20を画定する断面円形の線材である。主芯線22の材料は特に限定されないが、銀メッキが施された銅または銅合金の線材を用いることができる。このほか、主芯線22の材料としてステンレス鋼を用いることもできる。内層24は、ポリテトラフルオロエチレン(PTFE)などのフッ素系ポリマーを溶剤に分散させたコーティング液に主芯線22をディッピングしたうえで乾燥させて形成することができる。
つぎに、多条の補強ワイヤ32を内層24の外表面でメッシュ状に編組してワイヤ補強層30を形成する。
図9に示すように、補強ワイヤ32の先端部の周囲にリング状の第一マーカー14をカシメ固定したうえで、第一マーカー14の遠位側で補強ワイヤ32を切除する。
以上により内側構造体26が作製される。 In the inner structure preparation step, first, theinner layer 24 is formed around the main core wire 22. The main core wire 22 is a mandrel (core material), and is a wire material having a circular cross section that defines the main lumen 20. The material of the main core wire 22 is not particularly limited, but a copper or copper alloy wire material plated with silver can be used. In addition, stainless steel can be used as the material of the main core wire 22. The inner layer 24 can be formed by dipping the main core wire 22 in a coating liquid in which a fluorine-based polymer such as polytetrafluoroethylene (PTFE) is dispersed in a solvent and then drying.
Next, a multi-strand reinforcingwire 32 is braided into a mesh shape on the outer surface of the inner layer 24 to form the wire reinforcing layer 30.
As shown in FIG. 9, the ring-shapedfirst marker 14 is caulked and fixed around the tip of the reinforcing wire 32, and then the reinforcing wire 32 is excised on the distal side of the first marker 14.
Thus, theinner structure 26 is produced.
つぎに、多条の補強ワイヤ32を内層24の外表面でメッシュ状に編組してワイヤ補強層30を形成する。
図9に示すように、補強ワイヤ32の先端部の周囲にリング状の第一マーカー14をカシメ固定したうえで、第一マーカー14の遠位側で補強ワイヤ32を切除する。
以上により内側構造体26が作製される。 In the inner structure preparation step, first, the
Next, a multi-strand reinforcing
As shown in FIG. 9, the ring-shaped
Thus, the
内側構造体準備工程と同時に、または内側構造体準備工程と前後して、図10に示す有芯チューブ46を作製する。内側構造体準備工程では、副芯線44の周面にサブチューブ40を形成する。副芯線44は副管腔42を画定する断面円形の線材である。副芯線44の材料は特に限定されないが、主芯線22よりも高強度の金属材料、たとえばステンレス鋼を用いることができる。副芯線44は主芯線22よりも細径である。副芯線44として主芯線22よりも高強度の金属材料を用いることで、副芯線抜去工程において副芯線44を破断させることなく伸張および縮径させてサブチューブ40から好適に剥離させることができる。サブチューブ40の肉厚は内層24よりも薄いことが好ましい。サブチューブ40をポリテトラフルオロエチレン(PTFE)などのフッ素系ポリマーで作製する場合は、当該ポリマーを溶剤に分散させたコーティング液に副芯線44をディッピングしたうえで乾燥させて形成することができる。
このほか、副芯線44の外径よりもサブチューブ40の内径が大径となるようにチューブ状に引き落とし成形したうえで、これ副芯線44の周囲に被覆して有芯チューブ46を作製してもよい。 The coredtube 46 shown in FIG. 10 is manufactured simultaneously with the inner structure preparation step or before and after the inner structure preparation step. In the inner structure preparation step, the sub tube 40 is formed on the peripheral surface of the sub core wire 44. The secondary core wire 44 is a wire having a circular cross section that defines the secondary lumen 42. The material of the sub-core wire 44 is not particularly limited, but a metal material having a higher strength than the main core wire 22, such as stainless steel, can be used. The sub-core wire 44 has a smaller diameter than the main core wire 22. By using a metal material having a strength higher than that of the main core wire 22 as the sub-core wire 44, the sub-core wire 44 can be suitably peeled off from the sub-tube 40 by extending and reducing the diameter without breaking the sub-core wire 44 in the sub-core wire removing step. The wall thickness of the subtube 40 is preferably thinner than the inner layer 24. In the case where the subtube 40 is made of a fluorine-based polymer such as polytetrafluoroethylene (PTFE), the subtube 40 can be formed by dipping the subcore wire 44 in a coating liquid in which the polymer is dispersed in a solvent and then drying it.
In addition, after drawing into a tube shape so that the inner diameter of the sub-tube 40 is larger than the outer diameter of thesub-core wire 44, the core tube 46 is produced by covering the periphery of the sub-core wire 44. Also good.
このほか、副芯線44の外径よりもサブチューブ40の内径が大径となるようにチューブ状に引き落とし成形したうえで、これ副芯線44の周囲に被覆して有芯チューブ46を作製してもよい。 The cored
In addition, after drawing into a tube shape so that the inner diameter of the sub-tube 40 is larger than the outer diameter of the
サブチューブ保持工程では、副芯線44を主芯線22に沿ってワイヤ補強層30の外周表面に配置して保持ワイヤ70で共巻きする。本製造方法では、副芯線44を主芯線22に沿って配置するタイミングと、保持ワイヤ70で副芯線44と主芯線22とを共巻きするタイミングとはほぼ同時である。図11に示すように、挿通治具110の通孔112を通じて複数本(本製造方法では4本)の有芯チューブ46を内側構造体26に沿って送り出しながら、その周囲でワインダ装置120の複数個のボビンヘッド122を同方向に回転させる。ボビンヘッド122には保持ワイヤ70が巻き付けられている。挿通治具110には、内側構造体26を挿通する主通孔114が形成されている。主通孔114の周囲には等間隔で4個の通孔112が形成されている。
In the sub-tube holding step, the sub-core wire 44 is disposed on the outer peripheral surface of the wire reinforcing layer 30 along the main core wire 22 and is wound together with the holding wire 70. In this manufacturing method, the timing at which the sub-core wire 44 is arranged along the main core wire 22 and the timing at which the sub-core wire 44 and the main core wire 22 are wound together by the holding wire 70 are substantially the same. As shown in FIG. 11, a plurality of (four in the present manufacturing method) cored tubes 46 are sent out along the inner structure 26 through the through holes 112 of the insertion jig 110, and a plurality of winder devices 120 are disposed around the cored tubes 46. The bobbin heads 122 are rotated in the same direction. A holding wire 70 is wound around the bobbin head 122. The insertion jig 110 is formed with a main through hole 114 through which the inner structure 26 is inserted. Four through holes 112 are formed at regular intervals around the main through hole 114.
内側構造体26の先端に露出した主芯線22と、複数本(本製造方法では4本)の有芯チューブ46の先端にそれぞれ露出した副芯線44とは、治具(図示せず)により一体に固定されている。この状態で、第一マーカー14を先端側(図11の上方)に向けて、所定の送り速度で内側構造体26および有芯チューブ46を押し出しながらボビンヘッド122を回転させる。これにより、ワイヤ補強層30およびサブチューブ40の周囲に保持ワイヤ70がコイル状に巻回される。内側構造体26および有芯チューブ46の送り速度とボビンヘッド122の回転速度を調整することで、保持ワイヤ70の巻回ピッチを増減させることができる。
The main core wire 22 exposed at the front end of the inner structure 26 and the sub core wires 44 exposed at the front ends of a plurality of (four in the present manufacturing method) cored tubes 46 are integrated by a jig (not shown). It is fixed to. In this state, the bobbin head 122 is rotated while pushing the inner structure 26 and the cored tube 46 at a predetermined feed speed with the first marker 14 facing the tip side (upward in FIG. 11). As a result, the holding wire 70 is wound around the wire reinforcing layer 30 and the subtube 40 in a coil shape. By adjusting the feed speed of the inner structure 26 and the cored tube 46 and the rotational speed of the bobbin head 122, the winding pitch of the holding wire 70 can be increased or decreased.
本製造方法では、サブチューブ40に対する保持ワイヤ70の巻張力を周期的に変化させながら保持ワイヤ70を螺旋巻回する。保持ワイヤ70の巻張力を周期的に変化させる方法は一つに限られない。ここでは、複数個のボビンヘッド122を内側構造体26の周囲に均等配置したうえで、内側構造体26を外力により周期的に偏心させる第一方法と、複数個のボビンヘッド122を内側構造体26の周囲に偏心配置する第二方法を例示する。
In this manufacturing method, the holding wire 70 is spirally wound while periodically changing the winding tension of the holding wire 70 with respect to the subtube 40. The method for periodically changing the winding tension of the holding wire 70 is not limited to one. Here, a plurality of bobbin heads 122 are evenly arranged around the inner structure 26 and then the inner structure 26 is periodically eccentric by an external force, and the plurality of bobbin heads 122 are connected to the inner structure. A second method of eccentrically arranging around 26 is illustrated.
第一方法は、保持ワイヤ70を共巻きするサブチューブ保持工程において、内側構造体26を副芯線44に対して径方向に相対的に偏心させながら保持ワイヤ70で共巻きすることを特徴とする。
The first method is characterized in that, in the sub-tube holding step in which the holding wire 70 is wound together, the inner structure 26 is wound together with the holding wire 70 while being eccentric relative to the sub-core wire 44 in the radial direction. .
図11に示すように、本製造方法では、4本の副芯線44をワイヤ補強層30の周囲に90度間隔で互いに対向して配置する。なお、3本の副芯線44を配置する場合は、120度対向させるとよい。本製造方法では多条(二条)の保持ワイヤ70の巻点74がワイヤ補強層30の周囲で回転対称位置となるように、複数個(二個)のボビンヘッド122の位置を選択する。これにより、多条の保持ワイヤ70の個別の巻張力が相殺される。
この状態で内側構造体26を強制的に偏心させて多条の保持ワイヤ70の嵌入深さDを互いに相違させる。 As shown in FIG. 11, in this manufacturing method, the foursub-core wires 44 are arranged around the wire reinforcing layer 30 so as to face each other at intervals of 90 degrees. In addition, when arrange | positioning the three subcore wires 44, it is good to make it face 120 degree | times. In this manufacturing method, the positions of the plural (two) bobbin heads 122 are selected so that the winding points 74 of the multiple (two) holding wires 70 are rotationally symmetrical around the wire reinforcing layer 30. Thereby, the individual winding tension of the multiple holding wires 70 is offset.
In this state, theinner structure 26 is forcibly decentered to make the insertion depths D of the multiple holding wires 70 different from each other.
この状態で内側構造体26を強制的に偏心させて多条の保持ワイヤ70の嵌入深さDを互いに相違させる。 As shown in FIG. 11, in this manufacturing method, the four
In this state, the
図11に示すように、内側構造体26の周囲には把持具126が装着されている。把持具126は、主通孔114を通じて所定の送り速度で押し出される内側構造体26を摺動可能に挟持する。把持具126と挿通治具110との一方または両方は、駆動部(図示せず)により、内側構造体26の半径方向に相対移動するように駆動される。なお、図11では把持具126が挿通治具110に対して内側構造体26の送り方向に離間して設けられている状態を例示しているが、把持具126は挿通治具110と一体に設けられてもよい。
As shown in FIG. 11, a gripping tool 126 is mounted around the inner structure 26. The gripping tool 126 slidably holds the inner structure 26 that is pushed out at a predetermined feed speed through the main through hole 114. One or both of the gripping tool 126 and the insertion jig 110 is driven so as to relatively move in the radial direction of the inner structure 26 by a driving unit (not shown). 11 illustrates a state in which the gripping tool 126 is provided apart from the insertion jig 110 in the feeding direction of the inner structure 26, the gripping tool 126 is integrated with the insertion jig 110. It may be provided.
より具体的には、第一方法において駆動部(図示せず)は、180度対向する一対のサブチューブ40を結ぶ方向に把持具126を往復揺動させる。揺動周期は、ボビンヘッド122の回転周期と異なるか、または回転周期の整数倍に設定されている。揺動周期は可変であってもよい。
把持具126が内側構造体26を強制的に偏心させることで、保持ワイヤ70がサブチューブ40に付与する巻張力は、この揺動周期で周期的に変化する。これにより、サブチューブ40に第一長さ領域L1および第二長さ領域L2が形成される(図4を参照)。具体的には、把持具126が内側構造体26を、一方のサブチューブ40(第一のサブチューブ40a)に向かって押しつける方向に偏心させているとき、この第一のサブチューブ40aにおける保持ワイヤ70の巻点74にボビンヘッド122が付与する巻張力は大きくなる。これにより、第一のサブチューブ40aには嵌入深さDが大きい第二長さ領域L2aが形成される。このとき、軸心方向の同じ位置において、第一のサブチューブ40aと180°対向して配置された第二のサブチューブ40bにおける保持ワイヤ70の巻点74に他方のボビンヘッド122が付与する巻張力は小さくなる。これにより、第二のサブチューブ40bには嵌入深さDが小さい第一長さ領域L1bが形成される。
把持具126が周期的に揺動して内側構造体26が第二のサブチューブ40bに向かって偏心すると、第二のサブチューブ40bには嵌入深さDが大きい第二長さ領域L2bが形成される。そして、軸心方向の同じ位置において、第一のサブチューブ40aには嵌入深さDが小さい第一長さ領域L1aが形成される。 More specifically, in the first method, the drive unit (not shown) reciprocally swings thegripping tool 126 in a direction connecting the pair of sub tubes 40 facing each other by 180 degrees. The swing cycle is set different from the rotation cycle of the bobbin head 122 or an integral multiple of the rotation cycle. The oscillation cycle may be variable.
When thegripper 126 forcibly decenters the inner structure 26, the winding tension applied to the sub-tube 40 by the holding wire 70 periodically changes in this oscillation cycle. Thereby, the 1st length area | region L1 and the 2nd length area | region L2 are formed in the subtube 40 (refer FIG. 4). Specifically, when the gripper 126 is decentering in a direction in which the inner structure 26 is pressed toward one of the sub tubes 40 (first sub tube 40a), the holding wire in the first sub tube 40a. The winding tension applied by the bobbin head 122 to the winding point 74 of 70 increases. Thereby, the 2nd length area | region L2a with large insertion depth D is formed in the 1st subtube 40a. At this time, at the same position in the axial direction, the winding provided by the other bobbin head 122 to the winding point 74 of the holding wire 70 in the second sub-tube 40b arranged to face the first sub-tube 40a by 180 °. The tension is reduced. Thereby, the 1st length area | region L1b with small insertion depth D is formed in the 2nd subtube 40b.
When thegripping tool 126 is periodically swung and the inner structure 26 is eccentric toward the second sub-tube 40b, a second length region L2b having a large insertion depth D is formed in the second sub-tube 40b. Is done. And the 1st length area | region L1a with small insertion depth D is formed in the 1st subtube 40a in the same position of an axial center direction.
把持具126が内側構造体26を強制的に偏心させることで、保持ワイヤ70がサブチューブ40に付与する巻張力は、この揺動周期で周期的に変化する。これにより、サブチューブ40に第一長さ領域L1および第二長さ領域L2が形成される(図4を参照)。具体的には、把持具126が内側構造体26を、一方のサブチューブ40(第一のサブチューブ40a)に向かって押しつける方向に偏心させているとき、この第一のサブチューブ40aにおける保持ワイヤ70の巻点74にボビンヘッド122が付与する巻張力は大きくなる。これにより、第一のサブチューブ40aには嵌入深さDが大きい第二長さ領域L2aが形成される。このとき、軸心方向の同じ位置において、第一のサブチューブ40aと180°対向して配置された第二のサブチューブ40bにおける保持ワイヤ70の巻点74に他方のボビンヘッド122が付与する巻張力は小さくなる。これにより、第二のサブチューブ40bには嵌入深さDが小さい第一長さ領域L1bが形成される。
把持具126が周期的に揺動して内側構造体26が第二のサブチューブ40bに向かって偏心すると、第二のサブチューブ40bには嵌入深さDが大きい第二長さ領域L2bが形成される。そして、軸心方向の同じ位置において、第一のサブチューブ40aには嵌入深さDが小さい第一長さ領域L1aが形成される。 More specifically, in the first method, the drive unit (not shown) reciprocally swings the
When the
When the
なお、上記の第一方法では内側構造体26を往復揺動させることを例示したが、本発明はこれに限られない。主通孔114の周囲に沿って内側構造体26を回転揺動させてもよい。すなわち、内側構造体26(主芯線22)の軸心が主通孔114よりも小さな円を描くように、偏心させた内側構造体26を回転させてもよい。これにより、すべて(本製造方法では4本)のサブチューブ40に対して等しく第一長さ領域L1と第二長さ領域L2を形成することができる。
In the first method, the inner structure 26 is reciprocally swung, but the present invention is not limited to this. The inner structure 26 may be rotated and oscillated along the periphery of the main through hole 114. That is, the eccentric inner structure 26 may be rotated so that the axis of the inner structure 26 (main core wire 22) draws a circle smaller than the main through hole 114. Thereby, the first length region L1 and the second length region L2 can be formed equally for all the subtubes 40 (four in this manufacturing method).
第二方法では、多条の保持ワイヤ70を巻回する複数個のボビンヘッド122を内側構造体26の周囲に非対称に配置した状態で回転させる(図示せず)。二個のボビンヘッド122を用いて二条の保持ワイヤ70を巻回する場合、二個のボビンヘッド122の位置関係は、内側構造体26を中心とする中心角で120度以上180度未満とすることができる。ボビンヘッド122が近接しすぎると巻張力の合力が内側構造体26を過度に偏心させるところ、上記の角度範囲であればボビンヘッド122の回転周期と等しいか、または回転周期の整数倍にて内側構造体26を周期的に偏心させることができる。
In the second method, the plurality of bobbin heads 122 around which the multiple holding wires 70 are wound are rotated in a state where they are arranged asymmetrically around the inner structure 26 (not shown). When the two holding wires 70 are wound using the two bobbin heads 122, the positional relationship between the two bobbin heads 122 is 120 degrees or more and less than 180 degrees at the central angle with the inner structure 26 as the center. be able to. When the bobbin head 122 is too close, the resultant force of the winding tension causes the inner structure 26 to be excessively decentered. The structure 26 can be periodically eccentric.
なお、第一方法および第二方法で、一本の管状本体10において内側構造体26の揺動周期を変化させてもよい。これにより、繰り返される第一長さ領域L1および第二長さ領域L2の長さを、管状本体10の先端からの距離に応じて変化させることができる。一例として、遠位部DEでは第一長さ領域L1および第二長さ領域L2の長さを短くし、中間部や近位部では第一長さ領域L1および第二長さ領域L2の長さを長くするとよい。これにより、操作線60を牽引した場合に顕著に屈曲する遠位部DEにおけるサブチューブ40と外層50との密着性を良好に高めることができる。
Note that the oscillation period of the inner structure 26 may be changed in one tubular body 10 by the first method and the second method. Thereby, the length of the 1st length area | region L1 and the 2nd length area | region L2 which are repeated can be changed according to the distance from the front-end | tip of the tubular main body 10. FIG. As an example, the length of the first length region L1 and the second length region L2 is shortened in the distal portion DE, and the length of the first length region L1 and the second length region L2 is shortened in the middle portion and the proximal portion. It is good to lengthen the length. Thereby, the adhesiveness of the subtube 40 and the outer layer 50 in the distal part DE which bends notably when the operation line 60 is pulled can be improved favorably.
なお、本製造方法では副芯線44を送り出しながら主芯線22に対して共巻きすることを説明したが、本発明は上記に限られない。副芯線44の略全長を主芯線22に対して予め治具等で仮固定したあとで、保持ワイヤ70によって副芯線44と主芯線22とを共巻きしてもよい。
In the present manufacturing method, it has been described that the sub-core wire 44 is wound around the main core wire 22 while being sent out, but the present invention is not limited to the above. The sub-core wire 44 and the main core wire 22 may be wound together by the holding wire 70 after the substantially entire length of the sub-core wire 44 is temporarily fixed to the main core wire 22 with a jig or the like in advance.
本体形成工程では、内側構造体26、有芯チューブ46および保持ワイヤ70(以下、構造体)を内包するように外層を形成し、管状本体10とする。はじめに、構造体の周囲に第一外層52を形成する。第一外層52は、溶融した樹脂材料を構造体の表面に塗工形成するコーティング押出により形成してもよい。または、予め環状や管状に形成された樹脂リングや樹脂管を構造体の周囲に装着したうえで熱収縮チューブ等を用いて熱賦形してもよい。第一外層52は、サブチューブ40およびこれに嵌入した保持ワイヤ70を包埋する。これにより保持ワイヤ70は第一外層52とサブチューブ40との双方にアンカーする。
In the main body forming step, an outer layer is formed so as to enclose the inner structure 26, the cored tube 46, and the holding wire 70 (hereinafter, “structure”), and the tubular main body 10 is formed. First, the first outer layer 52 is formed around the structure. The first outer layer 52 may be formed by coating extrusion in which a molten resin material is applied to the surface of the structure. Alternatively, a resin ring or resin tube formed in an annular shape or a tubular shape in advance may be attached around the structure, and then heat-formed using a heat-shrinkable tube or the like. The first outer layer 52 embeds the subtube 40 and the holding wire 70 fitted therein. As a result, the holding wire 70 anchors both the first outer layer 52 and the subtube 40.
つぎに、第一外層52に埋設されたサブチューブ40の周囲に第二補強ワイヤ82を編組して第二補強層80を形成する(図12を参照)。第二補強層80の先端部の周囲に第二マーカー16をカシメ固定したうえで、第二マーカー16の遠位側で第二補強ワイヤ82を切除する。
さらに、第二補強層80および第二マーカー16を覆うように第二外層54(図1を参照)を形成する。第二外層54は、溶融した樹脂材料を第二補強層80の表面に塗工形成するコーティング押出により形成してもよく、または予め環状や管状に形成された樹脂リングや樹脂管を構造体の周囲に装着したうえで熱賦形してもよい。 Next, the2nd reinforcement wire 82 is braided around the subtube 40 embed | buried under the 1st outer layer 52, and the 2nd reinforcement layer 80 is formed (refer FIG. 12). After the second marker 16 is caulked and fixed around the tip of the second reinforcing layer 80, the second reinforcing wire 82 is excised on the distal side of the second marker 16.
Further, a second outer layer 54 (see FIG. 1) is formed so as to cover the second reinforcinglayer 80 and the second marker 16. The second outer layer 54 may be formed by coating extrusion in which a molten resin material is applied and formed on the surface of the second reinforcing layer 80, or a resin ring or resin tube previously formed in an annular shape or a tubular shape is used as the structure. You may heat-shape after mounting around.
さらに、第二補強層80および第二マーカー16を覆うように第二外層54(図1を参照)を形成する。第二外層54は、溶融した樹脂材料を第二補強層80の表面に塗工形成するコーティング押出により形成してもよく、または予め環状や管状に形成された樹脂リングや樹脂管を構造体の周囲に装着したうえで熱賦形してもよい。 Next, the
Further, a second outer layer 54 (see FIG. 1) is formed so as to cover the second reinforcing
副芯線抜去工程では、副芯線44を伸張させることにより縮径させてサブチューブ40から剥離させる。縮径した副芯線44をサブチューブ40から抜去したうえ、複数本のうち一部または全部のサブチューブ40に操作線60を挿入する。本実施形態では、180度対向する一対の第一のサブチューブ40a、第二のサブチューブ40bにのみ操作線60を挿入し、他の二本のサブチューブ40には操作線60を挿入しない。なお、縮径した副芯線44をサブチューブ40から抜去することなく操作線60として使用してもよいが、サブチューブ40の内径に比して十分に小径の操作線60を用いる場合は、副芯線44を抜去したうえ、これと異なる操作線60をサブチューブ40に挿入するとよい。
In the sub-core wire extracting step, the sub-core wire 44 is stretched to be reduced in diameter and peeled off from the sub-tube 40. After the diameter-reduced sub-core wire 44 is removed from the sub-tube 40, the operation line 60 is inserted into some or all of the sub-tubes 40 out of the plurality. In the present embodiment, the operation line 60 is inserted only into the pair of first sub-tube 40a and second sub-tube 40b facing each other by 180 degrees, and the operation line 60 is not inserted into the other two sub-tubes 40. The sub core wire 44 having a reduced diameter may be used as the operation line 60 without being removed from the sub tube 40. However, when the operation line 60 having a sufficiently small diameter compared to the inner diameter of the sub tube 40 is used, After the core wire 44 is removed, a different operation line 60 may be inserted into the sub-tube 40.
主芯線抜去工程は、主芯線22を管状本体10から抜去して主管腔20を形成する。副芯線抜去工程と主芯線抜去工程とを同時に行ってもよく、または副芯線抜去工程を先に行った後に主芯線抜去工程を行ってもよい。後者の場合、主芯線22が主管腔20に挿入されていることで管状本体10の伸張変形が抑制されるため、副芯線抜去工程において副芯線44を伸張させたときに、副芯線44に追随してサブチューブ40が伸びてしまうことがない。このため、主芯線22に比して細径で破断しやすい副芯線44を良好にサブチューブ40から抜去することができる。
In the main core wire extracting step, the main core wire 22 is extracted from the tubular body 10 to form the main lumen 20. The sub core wire extraction step and the main core wire extraction step may be performed simultaneously, or the main core wire extraction step may be performed after the sub core wire extraction step is performed first. In the latter case, because the main core wire 22 is inserted into the main lumen 20, expansion deformation of the tubular body 10 is suppressed. Therefore, when the sub core wire 44 is extended in the sub core wire extraction process, the sub core wire 44 follows. And the subtube 40 does not extend. For this reason, the sub-core wire 44 which is smaller in diameter than the main core wire 22 and easily breaks can be satisfactorily extracted from the sub-tube 40.
本製造方法においては、さらに第二外層54の表面に親水層(図示せず)を形成したうえ、管状本体10の基端部に操作部90を取り付ける。以上により、カテーテル100を得ることができる。
In the present manufacturing method, a hydrophilic layer (not shown) is further formed on the surface of the second outer layer 54, and the operation unit 90 is attached to the proximal end portion of the tubular main body 10. As described above, the catheter 100 can be obtained.
なお、本発明の各種の構成要素は、個々に独立した存在である必要はなく、複数の構成要素が一個の部材として形成されていること、一つの構成要素が複数の部材で形成されていること、ある構成要素が他の構成要素の一部であること、ある構成要素の一部と他の構成要素の一部とが重複していること、等を許容する。
Note that the various components of the present invention do not have to be individually independent, that a plurality of components are formed as one member, and one 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.
また、本製造方法は、複数の工程を順番に記載してあるが、その記載の順番は複数の工程を実行する順番やタイミングを限定するものではない。このため、本製造方法を実施するときには、その複数の工程の順番は内容的に支障のない範囲で変更することができ、また複数の工程の実行タイミングの一部または全部が互いに重複していてもよい。
Moreover, although this manufacturing method has described several process in order, the order of the description does not limit the order and timing which perform several processes. For this reason, when carrying out this manufacturing method, the order of the plurality of steps can be changed within a range that does not hinder the contents, and some or all of the execution timings of the plurality of steps overlap each other. Also good.
本実施形態および本製造方法は以下の技術思想を包含する。
(1)主管腔を画定する長尺の内層と、前記内層の周囲に補強ワイヤを巻回してなるワイヤ補強層と、前記ワイヤ補強層の外側に前記主管腔の長手方向に沿って延在するように配置され、前記主管腔よりも小径の副管腔を画定する樹脂製の長尺なサブチューブと、前記ワイヤ補強層および前記サブチューブを内包する樹脂製の外層と、を含む長尺の管状本体と、前記副管腔の内部に移動可能に挿通され先端が前記管状本体の遠位部に接続された操作線と、前記操作線を牽引操作して前記管状本体の前記遠位部を屈曲させる操作部と、を備え、前記管状本体がさらに、前記外層に内包され前記サブチューブと前記ワイヤ補強層とを共巻きする保持ワイヤを含み、前記保持ワイヤが前記サブチューブの外径側の周面に嵌入していることを特徴とする医療用機器。
(2)前記サブチューブの周面に対する前記保持ワイヤの嵌入深さが所定の深さである第一長さ領域と、前記嵌入深さが前記第一長さ領域よりも深い第二長さ領域と、が前記管状本体の軸心方向に並んで存在している上記(1)に記載の医療用機器。
(3)複数本の前記サブチューブが前記主管腔の周囲に対向して配置されている上記(2)に記載の医療用機器。
(4)3本以上の前記サブチューブが前記主管腔の周囲に均等に配置されて互いに対向している上記(3)に記載の医療用機器。
(5)互いに対向する第一の前記サブチューブおよび第二の前記サブチューブに前記操作線が挿通されており、第一の前記サブチューブおよび第二の前記サブチューブが、それぞれ前記第一長さ領域と前記第二長さ領域とを有している上記(3)または(4)に記載の医療用機器。
(6)第一の前記サブチューブが有する前記第一長さ領域と、第二の前記サブチューブが有する前記第一長さ領域と、が前記軸心方向における異なる位置に存在している上記(5)に記載の医療用機器。
(7)第一の前記サブチューブが有する前記第二長さ領域と、第二の前記サブチューブが有する前記第二長さ領域と、が前記軸心方向における異なる位置に存在している上記(5)または(6)に記載の医療用機器。
(8)第一の前記サブチューブが有する前記第一長さ領域と、第二の前記サブチューブが有する前記第二長さ領域と、が前記軸心方向における同じ位置に存在し、第一の前記サブチューブが有する前記第二長さ領域と、第二の前記サブチューブが有する前記第一長さ領域と、が前記軸心方向における同じ位置に存在している上記(6)または(7)に記載の医療用機器。
(9)前記第一長さ領域と前記第二長さ領域とが前記軸心方向に複数回繰り返して存在している上記(2)から(8)のいずれか一項に記載の医療用機器。
(10)前記保持ワイヤは、コイル素線が多条に巻回された多条コイルである上記(2)から(9)のいずれか一項に記載の医療用機器。
(11)前記第一長さ領域および前記第二長さ領域の前記軸心方向の長さが、前記コイル素線の巻回ピッチと等しいか、または前記巻回ピッチの整数倍である上記(10)に記載の医療用機器。
(12)前記保持ワイヤの外側に、第二補強ワイヤを断面円形に巻回してなる第二補強層を更に備える上記(1)から(11)のいずれか一項に記載の医療用機器。
(13)前記保持ワイヤの延性が前記補強ワイヤおよび前記第二補強ワイヤのいずれの延性よりも高い上記(12)に記載の医療用機器。
(14)前記管状本体の遠位部に放射線不透過材料からなるマーカー部が装備されており、前記保持ワイヤの先端が前記マーカー部の基端側に対して接着材により接着固定されている上記(1)から(13)のいずれか一項に記載の医療用機器。
(15)前記ワイヤ補強層は多条の前記補強ワイヤを編組してなり、前記ワイヤ補強層のうち前記マーカー部の基端側に隣接する複数の目開きの内側に前記接着材が充填されており、前記保持ワイヤの先端が前記接着材に接着固定されている上記(14)に記載の医療用機器。
(16)前記保持ワイヤが多条のコイル素線を巻回してなり、多条の前記コイル素線の先端が前記管状本体の周方向の略同一の位置で前記接着材に接着固定されている上記(15)に記載の医療用機器。
(17)前記複数の目開きが互いに隣接して前記ワイヤ補強層における非周回領域を構成する上記(15)または(16)に記載の医療用機器。
(18)前記主管腔と連通して設けられてシリンジが装着されるハブを更に備えるカテーテルである上記(1)から(13)のいずれか一項に記載の医療用機器。
(19)長尺の主芯線と、前記主芯線の周囲に補強ワイヤを巻回したワイヤ補強層と、を含む内側構造体を準備する工程と、樹脂製のサブチューブで被覆された長尺の副芯線を前記主芯線に沿って前記ワイヤ補強層の外周表面に配置し、保持ワイヤを前記サブチューブの表面に押圧して食い込ませながら前記サブチューブと前記ワイヤ補強層とを前記保持ワイヤで共巻きする工程と、共巻きされた前記サブチューブおよび前記ワイヤ補強層ならびに前記保持ワイヤを内包するように外層を形成し、管状本体とする工程と、前記副芯線を伸張および縮径させて前記サブチューブから剥離させて副管腔を形成する工程と、前記主芯線を前記管状本体から抜去して主管腔を形成する工程と、を含む医療用機器の製造方法。
(20)共巻きする前記工程において、前記内側構造体を前記副芯線に対して径方向に相対的に偏心させながら前記保持ワイヤで共巻きすることを特徴とする上記(19)に記載の医療用機器の製造方法。 This embodiment and this manufacturing method include the following technical ideas.
(1) A long inner layer defining a main lumen, a wire reinforcing layer formed by winding a reinforcing wire around the inner layer, and extending outside the wire reinforcing layer along the longitudinal direction of the main lumen. A long resin-made subtube defining a sub-lumen having a smaller diameter than the main lumen, and a resin-made outer layer containing the wire reinforcing layer and the subtube. A tubular body, an operation line that is movably inserted into the sub-lumen and has a tip connected to a distal portion of the tubular body, and pulling the operation line to move the distal portion of the tubular body An operation portion to be bent, and the tubular main body further includes a holding wire that is enclosed in the outer layer and winds the subtube and the wire reinforcing layer together, and the holding wire is disposed on the outer diameter side of the subtube. It is characterized by being fitted on the peripheral surface Medical equipment.
(2) A first length region in which the insertion depth of the holding wire with respect to the peripheral surface of the subtube is a predetermined depth, and a second length region in which the insertion depth is deeper than the first length region. And the medical device according to the above (1), which is arranged side by side in the axial direction of the tubular main body.
(3) The medical device according to (2), wherein the plurality of sub-tubes are arranged to face the periphery of the main lumen.
(4) The medical device according to (3), wherein the three or more sub-tubes are arranged uniformly around the main lumen and face each other.
(5) The operation line is inserted through the first sub-tube and the second sub-tube opposed to each other, and the first sub-tube and the second sub-tube each have the first length. The medical device according to (3) or (4), wherein the medical device has a region and the second length region.
(6) The first length region included in the first subtube and the first length region included in the second subtube are present at different positions in the axial direction. The medical device as described in 5).
(7) The above (2), wherein the second length region of the first subtube and the second length region of the second subtube are present at different positions in the axial direction. The medical device according to 5) or (6).
(8) The first length region of the first subtube and the second length region of the second subtube are present at the same position in the axial direction, The above (6) or (7), wherein the second length region of the subtube and the first length region of the second subtube are present at the same position in the axial direction. Medical equipment described in 1.
(9) The medical device according to any one of (2) to (8), wherein the first length region and the second length region are repeatedly present in the axial direction a plurality of times. .
(10) The medical device according to any one of (2) to (9), wherein the holding wire is a multi-strand coil in which a coil wire is wound in a multi-strand.
(11) The length in the axial direction of the first length region and the second length region is equal to a winding pitch of the coil element wire or is an integral multiple of the winding pitch. The medical device as described in 10).
(12) The medical device according to any one of (1) to (11), further including a second reinforcing layer formed by winding a second reinforcing wire in a circular cross section outside the holding wire.
(13) The medical device according to (12), wherein the ductility of the holding wire is higher than any of the ductility of the reinforcing wire and the second reinforcing wire.
(14) The marker portion made of a radiopaque material is provided at the distal portion of the tubular body, and the distal end of the holding wire is bonded and fixed to the proximal end side of the marker portion with an adhesive. The medical device according to any one of (1) to (13).
(15) The wire reinforcing layer is formed by braiding a plurality of reinforcing wires, and the adhesive is filled inside a plurality of openings adjacent to the proximal end side of the marker portion in the wire reinforcing layer. The medical device according to (14), wherein a tip of the holding wire is bonded and fixed to the adhesive.
(16) The holding wire is formed by winding a plurality of coil strands, and the tips of the plurality of coil strands are bonded and fixed to the adhesive at substantially the same position in the circumferential direction of the tubular body. The medical device according to (15) above.
(17) The medical device according to (15) or (16), wherein the plurality of openings are adjacent to each other to form a non-circular region in the wire reinforcing layer.
(18) The medical device according to any one of (1) to (13), wherein the medical device further includes a hub provided in communication with the main lumen and to which a syringe is attached.
(19) A step of preparing an inner structure including a long main core wire, and a wire reinforcing layer in which a reinforcing wire is wound around the main core wire, and a long length covered with a resin subtube A sub core wire is arranged on the outer peripheral surface of the wire reinforcing layer along the main core wire, and the holding tube is pressed against the surface of the sub tube and the sub tube and the wire reinforcing layer are shared by the holding wire. A step of winding, a step of forming an outer layer so as to enclose the sub-tube and the wire reinforcing layer and the holding wire, which are co-wound, and forming a tubular body; and extending and reducing the diameter of the sub-core wire to form the sub-tube A method for manufacturing a medical device, comprising: a step of separating from a tube to form a secondary lumen; and a step of removing the main core wire from the tubular body to form a main lumen.
(20) The medical treatment according to (19), wherein in the step of co-winding, the inner structure is co-wound with the holding wire while being relatively eccentric in the radial direction with respect to the sub-core wire. Method of manufacturing equipment.
(1)主管腔を画定する長尺の内層と、前記内層の周囲に補強ワイヤを巻回してなるワイヤ補強層と、前記ワイヤ補強層の外側に前記主管腔の長手方向に沿って延在するように配置され、前記主管腔よりも小径の副管腔を画定する樹脂製の長尺なサブチューブと、前記ワイヤ補強層および前記サブチューブを内包する樹脂製の外層と、を含む長尺の管状本体と、前記副管腔の内部に移動可能に挿通され先端が前記管状本体の遠位部に接続された操作線と、前記操作線を牽引操作して前記管状本体の前記遠位部を屈曲させる操作部と、を備え、前記管状本体がさらに、前記外層に内包され前記サブチューブと前記ワイヤ補強層とを共巻きする保持ワイヤを含み、前記保持ワイヤが前記サブチューブの外径側の周面に嵌入していることを特徴とする医療用機器。
(2)前記サブチューブの周面に対する前記保持ワイヤの嵌入深さが所定の深さである第一長さ領域と、前記嵌入深さが前記第一長さ領域よりも深い第二長さ領域と、が前記管状本体の軸心方向に並んで存在している上記(1)に記載の医療用機器。
(3)複数本の前記サブチューブが前記主管腔の周囲に対向して配置されている上記(2)に記載の医療用機器。
(4)3本以上の前記サブチューブが前記主管腔の周囲に均等に配置されて互いに対向している上記(3)に記載の医療用機器。
(5)互いに対向する第一の前記サブチューブおよび第二の前記サブチューブに前記操作線が挿通されており、第一の前記サブチューブおよび第二の前記サブチューブが、それぞれ前記第一長さ領域と前記第二長さ領域とを有している上記(3)または(4)に記載の医療用機器。
(6)第一の前記サブチューブが有する前記第一長さ領域と、第二の前記サブチューブが有する前記第一長さ領域と、が前記軸心方向における異なる位置に存在している上記(5)に記載の医療用機器。
(7)第一の前記サブチューブが有する前記第二長さ領域と、第二の前記サブチューブが有する前記第二長さ領域と、が前記軸心方向における異なる位置に存在している上記(5)または(6)に記載の医療用機器。
(8)第一の前記サブチューブが有する前記第一長さ領域と、第二の前記サブチューブが有する前記第二長さ領域と、が前記軸心方向における同じ位置に存在し、第一の前記サブチューブが有する前記第二長さ領域と、第二の前記サブチューブが有する前記第一長さ領域と、が前記軸心方向における同じ位置に存在している上記(6)または(7)に記載の医療用機器。
(9)前記第一長さ領域と前記第二長さ領域とが前記軸心方向に複数回繰り返して存在している上記(2)から(8)のいずれか一項に記載の医療用機器。
(10)前記保持ワイヤは、コイル素線が多条に巻回された多条コイルである上記(2)から(9)のいずれか一項に記載の医療用機器。
(11)前記第一長さ領域および前記第二長さ領域の前記軸心方向の長さが、前記コイル素線の巻回ピッチと等しいか、または前記巻回ピッチの整数倍である上記(10)に記載の医療用機器。
(12)前記保持ワイヤの外側に、第二補強ワイヤを断面円形に巻回してなる第二補強層を更に備える上記(1)から(11)のいずれか一項に記載の医療用機器。
(13)前記保持ワイヤの延性が前記補強ワイヤおよび前記第二補強ワイヤのいずれの延性よりも高い上記(12)に記載の医療用機器。
(14)前記管状本体の遠位部に放射線不透過材料からなるマーカー部が装備されており、前記保持ワイヤの先端が前記マーカー部の基端側に対して接着材により接着固定されている上記(1)から(13)のいずれか一項に記載の医療用機器。
(15)前記ワイヤ補強層は多条の前記補強ワイヤを編組してなり、前記ワイヤ補強層のうち前記マーカー部の基端側に隣接する複数の目開きの内側に前記接着材が充填されており、前記保持ワイヤの先端が前記接着材に接着固定されている上記(14)に記載の医療用機器。
(16)前記保持ワイヤが多条のコイル素線を巻回してなり、多条の前記コイル素線の先端が前記管状本体の周方向の略同一の位置で前記接着材に接着固定されている上記(15)に記載の医療用機器。
(17)前記複数の目開きが互いに隣接して前記ワイヤ補強層における非周回領域を構成する上記(15)または(16)に記載の医療用機器。
(18)前記主管腔と連通して設けられてシリンジが装着されるハブを更に備えるカテーテルである上記(1)から(13)のいずれか一項に記載の医療用機器。
(19)長尺の主芯線と、前記主芯線の周囲に補強ワイヤを巻回したワイヤ補強層と、を含む内側構造体を準備する工程と、樹脂製のサブチューブで被覆された長尺の副芯線を前記主芯線に沿って前記ワイヤ補強層の外周表面に配置し、保持ワイヤを前記サブチューブの表面に押圧して食い込ませながら前記サブチューブと前記ワイヤ補強層とを前記保持ワイヤで共巻きする工程と、共巻きされた前記サブチューブおよび前記ワイヤ補強層ならびに前記保持ワイヤを内包するように外層を形成し、管状本体とする工程と、前記副芯線を伸張および縮径させて前記サブチューブから剥離させて副管腔を形成する工程と、前記主芯線を前記管状本体から抜去して主管腔を形成する工程と、を含む医療用機器の製造方法。
(20)共巻きする前記工程において、前記内側構造体を前記副芯線に対して径方向に相対的に偏心させながら前記保持ワイヤで共巻きすることを特徴とする上記(19)に記載の医療用機器の製造方法。 This embodiment and this manufacturing method include the following technical ideas.
(1) A long inner layer defining a main lumen, a wire reinforcing layer formed by winding a reinforcing wire around the inner layer, and extending outside the wire reinforcing layer along the longitudinal direction of the main lumen. A long resin-made subtube defining a sub-lumen having a smaller diameter than the main lumen, and a resin-made outer layer containing the wire reinforcing layer and the subtube. A tubular body, an operation line that is movably inserted into the sub-lumen and has a tip connected to a distal portion of the tubular body, and pulling the operation line to move the distal portion of the tubular body An operation portion to be bent, and the tubular main body further includes a holding wire that is enclosed in the outer layer and winds the subtube and the wire reinforcing layer together, and the holding wire is disposed on the outer diameter side of the subtube. It is characterized by being fitted on the peripheral surface Medical equipment.
(2) A first length region in which the insertion depth of the holding wire with respect to the peripheral surface of the subtube is a predetermined depth, and a second length region in which the insertion depth is deeper than the first length region. And the medical device according to the above (1), which is arranged side by side in the axial direction of the tubular main body.
(3) The medical device according to (2), wherein the plurality of sub-tubes are arranged to face the periphery of the main lumen.
(4) The medical device according to (3), wherein the three or more sub-tubes are arranged uniformly around the main lumen and face each other.
(5) The operation line is inserted through the first sub-tube and the second sub-tube opposed to each other, and the first sub-tube and the second sub-tube each have the first length. The medical device according to (3) or (4), wherein the medical device has a region and the second length region.
(6) The first length region included in the first subtube and the first length region included in the second subtube are present at different positions in the axial direction. The medical device as described in 5).
(7) The above (2), wherein the second length region of the first subtube and the second length region of the second subtube are present at different positions in the axial direction. The medical device according to 5) or (6).
(8) The first length region of the first subtube and the second length region of the second subtube are present at the same position in the axial direction, The above (6) or (7), wherein the second length region of the subtube and the first length region of the second subtube are present at the same position in the axial direction. Medical equipment described in 1.
(9) The medical device according to any one of (2) to (8), wherein the first length region and the second length region are repeatedly present in the axial direction a plurality of times. .
(10) The medical device according to any one of (2) to (9), wherein the holding wire is a multi-strand coil in which a coil wire is wound in a multi-strand.
(11) The length in the axial direction of the first length region and the second length region is equal to a winding pitch of the coil element wire or is an integral multiple of the winding pitch. The medical device as described in 10).
(12) The medical device according to any one of (1) to (11), further including a second reinforcing layer formed by winding a second reinforcing wire in a circular cross section outside the holding wire.
(13) The medical device according to (12), wherein the ductility of the holding wire is higher than any of the ductility of the reinforcing wire and the second reinforcing wire.
(14) The marker portion made of a radiopaque material is provided at the distal portion of the tubular body, and the distal end of the holding wire is bonded and fixed to the proximal end side of the marker portion with an adhesive. The medical device according to any one of (1) to (13).
(15) The wire reinforcing layer is formed by braiding a plurality of reinforcing wires, and the adhesive is filled inside a plurality of openings adjacent to the proximal end side of the marker portion in the wire reinforcing layer. The medical device according to (14), wherein a tip of the holding wire is bonded and fixed to the adhesive.
(16) The holding wire is formed by winding a plurality of coil strands, and the tips of the plurality of coil strands are bonded and fixed to the adhesive at substantially the same position in the circumferential direction of the tubular body. The medical device according to (15) above.
(17) The medical device according to (15) or (16), wherein the plurality of openings are adjacent to each other to form a non-circular region in the wire reinforcing layer.
(18) The medical device according to any one of (1) to (13), wherein the medical device further includes a hub provided in communication with the main lumen and to which a syringe is attached.
(19) A step of preparing an inner structure including a long main core wire, and a wire reinforcing layer in which a reinforcing wire is wound around the main core wire, and a long length covered with a resin subtube A sub core wire is arranged on the outer peripheral surface of the wire reinforcing layer along the main core wire, and the holding tube is pressed against the surface of the sub tube and the sub tube and the wire reinforcing layer are shared by the holding wire. A step of winding, a step of forming an outer layer so as to enclose the sub-tube and the wire reinforcing layer and the holding wire, which are co-wound, and forming a tubular body; and extending and reducing the diameter of the sub-core wire to form the sub-tube A method for manufacturing a medical device, comprising: a step of separating from a tube to form a secondary lumen; and a step of removing the main core wire from the tubular body to form a main lumen.
(20) The medical treatment according to (19), wherein in the step of co-winding, the inner structure is co-wound with the holding wire while being relatively eccentric in the radial direction with respect to the sub-core wire. Method of manufacturing equipment.
10 管状本体
14 第一マーカー
16 第二マーカー
20 主管腔
22 主芯線
24 内層
26 内側構造体
30 ワイヤ補強層
32 補強ワイヤ
40,40a,40b サブチューブ
42 副管腔
44 副芯線
46 有芯チューブ
50 外層
52 第一外層
54 第二外層
56 接着材
60 操作線
70 保持ワイヤ
70a,70b コイル素線(保持ワイヤ)
71 端点
72 端部
74 巻点
80 第二補強層
82 第二補強ワイヤ
90 操作部
92 ホイール操作部
94 本体ケース
95 凹部
96 ハブ
98 スライダ
99 突起
100 カテーテル
110 挿通治具
112 通孔
114 主通孔
120 ワインダ装置
122 ボビンヘッド
126 把持具
L1,L1a,L1b 第一長さ領域
L2,L2a,L2b 第二長さ領域
D 嵌入深さ
DE 遠位部
W 周方向の目開き寸法 DESCRIPTION OFSYMBOLS 10 Tubular main body 14 1st marker 16 2nd marker 20 Main lumen 22 Main core wire 24 Inner layer 26 Inner structure 30 Wire reinforcement layer 32 Reinforcement wires 40, 40a, 40b Sub tube 42 Sub lumen 44 Sub core wire 46 Core tube 50 Outer layer 52 1st outer layer 54 2nd outer layer 56 Adhesive material 60 Operation line 70 Holding wire 70a, 70b Coil strand (holding wire)
71End point 72 End portion 74 Winding point 80 Second reinforcing layer 82 Second reinforcing wire 90 Operation portion 92 Wheel operation portion 94 Main body case 95 Recess 96 Hub 98 Slider 99 Protrusion 100 Catheter 110 Insertion jig 112 Through hole 114 Main through hole 120 Winder device 122 Bobbin head 126 Grip tools L1, L1a, L1b First length region L2, L2a, L2b Second length region D Insertion depth DE Distal portion W Opening dimension in the circumferential direction
14 第一マーカー
16 第二マーカー
20 主管腔
22 主芯線
24 内層
26 内側構造体
30 ワイヤ補強層
32 補強ワイヤ
40,40a,40b サブチューブ
42 副管腔
44 副芯線
46 有芯チューブ
50 外層
52 第一外層
54 第二外層
56 接着材
60 操作線
70 保持ワイヤ
70a,70b コイル素線(保持ワイヤ)
71 端点
72 端部
74 巻点
80 第二補強層
82 第二補強ワイヤ
90 操作部
92 ホイール操作部
94 本体ケース
95 凹部
96 ハブ
98 スライダ
99 突起
100 カテーテル
110 挿通治具
112 通孔
114 主通孔
120 ワインダ装置
122 ボビンヘッド
126 把持具
L1,L1a,L1b 第一長さ領域
L2,L2a,L2b 第二長さ領域
D 嵌入深さ
DE 遠位部
W 周方向の目開き寸法 DESCRIPTION OF
71
Claims (20)
- 主管腔を画定する長尺の内層と、前記内層の周囲に補強ワイヤを巻回してなるワイヤ補強層と、前記ワイヤ補強層の外側に前記主管腔の長手方向に沿って延在するように配置され、前記主管腔よりも小径の副管腔を画定する樹脂製の長尺なサブチューブと、前記ワイヤ補強層および前記サブチューブを内包する樹脂製の外層と、を含む長尺の管状本体と、
前記副管腔の内部に移動可能に挿通され先端が前記管状本体の遠位部に接続された操作線と、
前記操作線を牽引操作して前記管状本体の前記遠位部を屈曲させる操作部と、を備え、
前記管状本体がさらに、前記外層に内包され前記サブチューブと前記ワイヤ補強層とを共巻きする保持ワイヤを含み、
前記保持ワイヤが前記サブチューブの外径側の周面に嵌入していることを特徴とする医療用機器。 A long inner layer defining a main lumen, a wire reinforcing layer formed by winding a reinforcing wire around the inner layer, and an outer side of the wire reinforcing layer so as to extend along the longitudinal direction of the main lumen A long tubular body comprising a resin-made long subtube defining a sub-lumen having a smaller diameter than the main lumen; and a resin outer layer containing the wire reinforcing layer and the subtube; ,
An operation line that is movably inserted into the sub-lumen and has a tip connected to a distal portion of the tubular body;
An operation portion that pulls the operation line to bend the distal portion of the tubular body, and
The tubular body further includes a holding wire enclosed in the outer layer and co-winding the sub-tube and the wire reinforcing layer;
The medical device, wherein the holding wire is fitted into a peripheral surface on the outer diameter side of the sub-tube. - 前記サブチューブの周面に対する前記保持ワイヤの嵌入深さが所定の深さである第一長さ領域と、前記嵌入深さが前記第一長さ領域よりも深い第二長さ領域と、が前記管状本体の軸心方向に並んで存在している請求項1に記載の医療用機器。 A first length region in which the insertion depth of the holding wire with respect to the peripheral surface of the subtube is a predetermined depth; and a second length region in which the insertion depth is deeper than the first length region. The medical device according to claim 1, wherein the medical device exists side by side in an axial direction of the tubular main body.
- 複数本の前記サブチューブが前記主管腔の周囲に対向して配置されている請求項2に記載の医療用機器。 3. The medical device according to claim 2, wherein a plurality of the sub-tubes are arranged facing the periphery of the main lumen.
- 3本以上の前記サブチューブが前記主管腔の周囲に均等に配置されて互いに対向している請求項3に記載の医療用機器。 The medical device according to claim 3, wherein the three or more sub-tubes are arranged evenly around the main lumen and face each other.
- 互いに対向する第一の前記サブチューブおよび第二の前記サブチューブに前記操作線が挿通されており、第一の前記サブチューブおよび第二の前記サブチューブが、それぞれ前記第一長さ領域と前記第二長さ領域とを有している請求項3または4に記載の医療用機器。 The operation line is inserted through the first sub-tube and the second sub-tube facing each other, and the first sub-tube and the second sub-tube are respectively connected to the first length region and the second sub-tube. The medical device according to claim 3, further comprising a second length region.
- 第一の前記サブチューブが有する前記第一長さ領域と、第二の前記サブチューブが有する前記第一長さ領域と、が前記軸心方向における異なる位置に存在している請求項5に記載の医療用機器。 The first length region of the first subtube and the first length region of the second subtube are present at different positions in the axial direction. Medical equipment.
- 第一の前記サブチューブが有する前記第二長さ領域と、第二の前記サブチューブが有する前記第二長さ領域と、が前記軸心方向における異なる位置に存在している請求項5または6に記載の医療用機器。 The second length region of the first sub-tube and the second length region of the second sub-tube are present at different positions in the axial direction. Medical equipment described in 1.
- 第一の前記サブチューブが有する前記第一長さ領域と、第二の前記サブチューブが有する前記第二長さ領域と、が前記軸心方向における同じ位置に存在し、
第一の前記サブチューブが有する前記第二長さ領域と、第二の前記サブチューブが有する前記第一長さ領域と、が前記軸心方向における同じ位置に存在している請求項6または7に記載の医療用機器。 The first length region of the first subtube and the second length region of the second subtube are present at the same position in the axial direction;
The second length region of the first sub tube and the first length region of the second sub tube are present at the same position in the axial direction. Medical equipment described in 1. - 前記第一長さ領域と前記第二長さ領域とが前記軸心方向に複数回繰り返して存在している請求項2から8のいずれか一項に記載の医療用機器。 The medical device according to any one of claims 2 to 8, wherein the first length region and the second length region are repeatedly present in the axial direction multiple times.
- 前記保持ワイヤは、コイル素線が多条に巻回された多条コイルである請求項2から9のいずれか一項に記載の医療用機器。 The medical device according to any one of claims 2 to 9, wherein the holding wire is a multi-strand coil in which a coil wire is wound in a multi-strand.
- 前記第一長さ領域および前記第二長さ領域の前記軸心方向の長さが、前記コイル素線の巻回ピッチと等しいか、または前記巻回ピッチの整数倍である請求項10に記載の医療用機器。 The length in the axial direction of the first length region and the second length region is equal to a winding pitch of the coil element wire or an integral multiple of the winding pitch. Medical equipment.
- 前記保持ワイヤの外側に、第二補強ワイヤを断面円形に巻回してなる第二補強層を更に備える請求項1から11のいずれか一項に記載の医療用機器。 The medical device according to any one of claims 1 to 11, further comprising a second reinforcing layer formed by winding a second reinforcing wire in a circular cross section outside the holding wire.
- 前記保持ワイヤの延性が前記補強ワイヤおよび前記第二補強ワイヤのいずれの延性よりも高い請求項12に記載の医療用機器。 The medical device according to claim 12, wherein the ductility of the holding wire is higher than any of the ductility of the reinforcing wire and the second reinforcing wire.
- 前記管状本体の遠位部に放射線不透過材料からなるマーカー部が装備されており、前記保持ワイヤの先端が前記マーカー部の基端側に対して接着材により接着固定されている請求項1から13のいずれか一項に記載の医療用機器。 The distal end portion of the tubular body is equipped with a marker portion made of a radiopaque material, and the distal end of the holding wire is bonded and fixed to the proximal end side of the marker portion with an adhesive. 14. The medical device according to any one of 13.
- 前記ワイヤ補強層は多条の前記補強ワイヤを編組してなり、前記ワイヤ補強層のうち前記マーカー部の基端側に隣接する複数の目開きの内側に前記接着材が充填されており、前記保持ワイヤの先端が前記接着材に接着固定されている請求項14に記載の医療用機器。 The wire reinforcing layer is formed by braiding a plurality of reinforcing wires, and the adhesive is filled inside a plurality of openings adjacent to the proximal end side of the marker portion in the wire reinforcing layer, The medical device according to claim 14, wherein a distal end of the holding wire is bonded and fixed to the adhesive.
- 前記保持ワイヤが多条のコイル素線を巻回してなり、多条の前記コイル素線の先端が前記管状本体の周方向の略同一の位置で前記接着材に接着固定されている請求項15に記載の医療用機器。 The said holding | maintenance wire winds the multi-strand coil strand, The front-end | tip of the multi-strand coil strand is bonded and fixed to the said adhesive material in the substantially the same position of the circumferential direction of the said tubular main body. Medical equipment described in 1.
- 前記複数の目開きが互いに隣接して前記ワイヤ補強層における非周回領域を構成する請求項15または16に記載の医療用機器。 The medical device according to claim 15 or 16, wherein the plurality of openings are adjacent to each other to form a non-circular region in the wire reinforcing layer.
- 前記主管腔と連通して設けられてシリンジが装着されるハブを更に備えるカテーテルである請求項1から13のいずれか一項に記載の医療用機器。 The medical device according to any one of claims 1 to 13, which is a catheter further provided with a hub provided in communication with the main lumen and to which a syringe is attached.
- 長尺の主芯線と、前記主芯線の周囲に補強ワイヤを巻回したワイヤ補強層と、を含む内側構造体を準備する工程と、
樹脂製のサブチューブで被覆された長尺の副芯線を前記主芯線に沿って前記ワイヤ補強層の外周表面に配置し、保持ワイヤを前記サブチューブの表面に押圧して食い込ませながら前記サブチューブと前記ワイヤ補強層とを前記保持ワイヤで共巻きする工程と、
共巻きされた前記サブチューブおよび前記ワイヤ補強層ならびに前記保持ワイヤを内包するように外層を形成し、管状本体とする工程と、
前記副芯線を伸張および縮径させて前記サブチューブから剥離させて副管腔を形成する工程と、
前記主芯線を前記管状本体から抜去して主管腔を形成する工程と、
を含む医療用機器の製造方法。 Preparing an inner structure including a long main core wire and a wire reinforcing layer in which a reinforcing wire is wound around the main core wire;
A long sub-core wire covered with a resin sub-tube is arranged on the outer peripheral surface of the wire reinforcing layer along the main core wire, and the holding tube is pressed against the surface of the sub-tube and bites into the sub-tube. And the step of co-winding the wire reinforcing layer with the holding wire,
A step of forming an outer layer so as to enclose the sub-tube and the wire reinforcing layer and the holding wire which are wound together to form a tubular body;
Extending and reducing the diameter of the sub-core wire and separating from the sub-tube to form a sub-lumen;
Removing the main core wire from the tubular body to form a main lumen;
A method of manufacturing a medical device including: - 共巻きする前記工程において、前記内側構造体を前記副芯線に対して径方向に相対的に偏心させながら前記保持ワイヤで共巻きすることを特徴とする請求項19に記載の医療用機器の製造方法。 20. The manufacturing of the medical device according to claim 19, wherein in the step of co-winding, the inner structure is co-wound with the holding wire while being relatively eccentric in the radial direction with respect to the sub-core wire. Method.
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JP6570123B2 (en) * | 2016-02-29 | 2019-09-04 | 日本ライフライン株式会社 | Intracardiac defibrillation catheter |
TWI767960B (en) * | 2016-11-25 | 2022-06-21 | 日商住友電木股份有限公司 | Medical device |
WO2022091372A1 (en) * | 2020-10-30 | 2022-05-05 | 朝日インテック株式会社 | Catheter and production method therefor |
CN117504089A (en) * | 2022-07-28 | 2024-02-06 | 微创神通医疗科技(上海)有限公司 | medical catheter |
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JP2007515259A (en) * | 2003-12-22 | 2007-06-14 | ボストン サイエンティフィック リミテッド | Medical device with a structure for limiting the pressing force |
US20100059173A1 (en) * | 2006-01-12 | 2010-03-11 | Pacesetter, Inc. | Method of making a tubular body for a catheter, sheath or lead |
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Also Published As
Publication number | Publication date |
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JP2014188211A (en) | 2014-10-06 |
TW201442752A (en) | 2014-11-16 |
JP6201367B2 (en) | 2017-09-27 |
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