JPH06105798A - Catheter tube - Google Patents

Abstract

PURPOSE:To form a catheter tube so that only its foremost part can be bent certainly by furnishing a coil, in which adjoining turns are attached tightly, in the parts of the tube body except its foremost. CONSTITUTION:A coil 9 is spiraliy wound on a tube body 2 of catheter tube over its length. At the foremost part of the tube body 2, the coil 9 is so formed that gaps 19 are reserved between adjoining turns. and that turns are attached tightly with one another in the part 23 nearer the base end than the foremost 22. When a pulling tool 16 is operated to pull a wire 8 toward the base end of the tube body 2, a force is applied in the longitudinal direction of the catheter tube 1A. Therein the shape of the coil 9 remains unchanged in the tightly wound part 23, so that no bending takes place, but the foremost part 22 solely bends with the foremost of the tightly wound part 23 as the fulcrum.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to, for example, the heart, blood vessels,
Used by inserting into body cavities such as digestive tract, urethra, abdominal cavity,
A catheter tube for observing the insertion site and performing medical procedures,
In particular, it relates to a catheter tube that constitutes an endoscope (fiberscope).

[0002]

2. Description of the Related Art An endoscope can be inserted from the outside of the body to observe the inside of body cavities such as blood vessels and other tubular organs, and medical treatment such as administration of a drug solution to the inner wall and irradiation of a laser beam. Therefore, it has attracted attention in recent years and its development is progressing.

When observing the inside of a body cavity using such an endoscope, it is necessary to bend (bend) the distal end portion of a catheter tube that constitutes the endoscope in order to select a visual field.

A method of bending the distal end portion of the catheter tube (hereinafter referred to as the tube distal end portion) from the external position is to connect the tube distal end portion to a plurality of node rings rotatably and sequentially, and to pull the wire. There is a method of bending the distal end of the tube, but recently, a catheter tube having a structure without a node ring has been proposed in response to a request for reducing the diameter of the endoscope.

In such a device, the tube tip is made more flexible than the other parts, while a wire is inserted into the lumen of the tube body and the tip of the wire is fixed at the eccentric position of the tube tip. There is a catheter tube having a structure in which the distal end of the tube is bent from the external position by pulling the wire at the proximal end side of the wire (JP-A-2-1292).

[0006] In such a catheter tube, it is an important subject to surely bend only the tube tip without increasing the outer diameter of the catheter tube.

In order to solve such a problem, the tube tip portion is made of a flexible material, and for the other portion of the tube, the tube material is selected and the rod-like or tubular rigidity having a large bending elastic modulus is given. If sufficient bending rigidity is provided by arranging the body, it is possible to surely bend the tube distal end without bending other portions of the tube when the wire is pulled. However, in order to provide sufficient bending rigidity without increasing the outer diameter of the catheter tube, a material having a large bending elastic modulus must be used, but in this case, on the contrary, the flexibility becomes poor and the catheter tube is There are drawbacks such that buckling occurs when inserting into a target site in the cavity, the insertion operation becomes difficult, and the lumen is crushed or the optical fiber of the endoscope installed in the lumen is broken.

Therefore, it is desired to develop a catheter tube having a small diameter, which has appropriate rigidity and flexibility, prevents buckling, and can surely bend only the distal end of the tube. ing.

[0009]

SUMMARY OF THE INVENTION An object of the present invention is to maintain a good balance between flexibility and rigidity without increasing the outer diameter of the catheter tube, prevent buckling of the catheter tube, and prevent tube tip. It is to provide a catheter tube capable of reliably bending only a portion.

[0010]

This object is achieved by the present invention described in (1) below. Further, it is preferably (2) to (11).

(1) A tube body, at least one lumen formed over substantially the entire length of the tube body, a coil body arranged in the tube body, and a lumen housed in the lumen, the tip of which is the tube. At least one wire fixed in an eccentric position near the tip of the main body, and a pulling tool capable of pulling the wire in the proximal direction of the tube main body, wherein the coil body is a portion other than the front end portion of the tube main body. The adjacent one winding is in close contact with each other, whereby the distal end portion of the tube body is bent by pulling the wire toward the proximal end direction of the tube body.

(2) The catheter tube according to the above (1), wherein adjacent one turn of the coil body is in contact with a surface having a predetermined area.

(3) The coil body extends to the tip of the tube body, and is arranged with a gap between adjacent ones of the turns at the tip (1) or The catheter tube according to (2).

(4) The catheter tube according to (3), wherein the gap is filled with a flexible substance.

(5) The catheter tube according to any one of (1) to (4), wherein the coil body is arranged along an outer peripheral surface of the tube body.

(6) The catheter tube according to the above (5), which has a holding member for holding the coil body on the outer surface of the coil body so as not to separate from the outer periphery of the tube body.

(7) The catheter tube according to any one of the above (1) to (4), wherein the coil body is housed in a lumen formed in the tube body.

(8) The catheter tube according to any one of the above (1) to (7), wherein a plurality of the wires are provided and the tips of the wires are fixed at different eccentric positions within the cross section of the tube body.

(9) The tube body has a plurality of lumens, one of which has the wire accommodated therein, and the other one has an observation or medical treatment instrument accommodated therein. ) Thru | or the catheter tube in any one of (8).

(10) The catheter tube according to any one of the above (1) to (9), wherein at least one expandable and contractible expander is installed around the outer peripheral wall of the tube body.

(11) The catheter tube according to the above (10), wherein the expander is installed near a tip of a portion where adjacent one turns of the coil body are in close contact with each other or on a base end side of the tip.

[0022]

BEST MODE FOR CARRYING OUT THE INVENTION The catheter tube of the present invention will be described in detail below with reference to the structural examples shown in the accompanying drawings.

FIG. 1 is a plan view showing a constitutional example in which the catheter tube of the present invention is applied to an endoscope, FIG. 2 is an enlarged sectional view taken along line II-II in FIG. 1, and FIG. III in Figure 2
FIG. 4 is a sectional view taken along line III-III, and FIG. 4 is a sectional view taken along line IV-IV in FIG. As shown in FIG. 1, the catheter tube 1
A has a tube body 2 and its base end side (right side in FIG. 1)
An operation unit 11 is formed at 21.

The tube body 2 is made of, for example, polyvinyl chloride, polyurethane, polyethylene, polypropylene, polyamide, polytetrafluoroethylene (Teflon),
It is made of a flexible material such as silicone rubber or ethylene-vinyl acetate copolymer. Particularly, the tip portion 22 of the tube body 2 is made of the above-mentioned material or the tube body 2
The diameter of the wire 8 is appropriately selected so that the wire 8 can be easily bent when the wire 8 is pulled.

The catheter tube 1A of the present invention
Is usually used by being inserted and left in the living body under X-ray fluoroscopy, and therefore it is preferable to impart X-ray contrast property to the catheter tube 1A, that is, the tube body 2 and an expansion body 20 described later. It is preferable to include an X-ray contrast agent in the constituent material. Examples of the X-ray contrast agent include metal compounds such as barium sulfate, bismuth oxide, and tungsten.

The tube body 2 is formed with various lumens having different uses and functions as described below.
As shown in FIGS. 2, 3 and 4, the tube body 2 is formed with four first to fourth lumens 3, 4, 5 and 6 over substantially the entire length thereof.

The first lumen 3 accommodates an optical fiber bundle 7 as an observing instrument (fiberscope) for observing the inside of a body cavity such as a blood vessel or a tubular organ. The optical fiber bundle 7 can also be used for medical treatment such as irradiation of a laser beam to a blood vessel or an inner wall of a tubular organ.

As shown in FIG. 2, the optical fiber bundle 7 is composed of a light transmitting fiber (light guide) 71 and a light receiving fiber (image fiber) 72. These optical fibers are made of, for example, epoxy, acrylic, silicone. It is made into a bundle by being hardened with rubber or the like.
The light-transmitting and light-receiving fibers 71 and 72 are each made of an optical fiber such as quartz, plastic, or multi-component glass.

A lens 73 is attached to the tip of the optical fiber bundle 7, and the lens 73 is attached to the first lumen 3
It is located near the tip opening. Light emitted from a light source (not shown) installed on the proximal end side of the catheter tube is transmitted through the light-sending fiber 71, is irradiated to the observation site from its tip, and the reflected light is passed through the lens 73. The light is taken in from the tip of the light receiving fiber 72, the image is transmitted through the light receiving fiber 72, and is guided to an image receiving portion (not shown) installed on the proximal end side of the catheter tube.

It is preferable that the optical fiber bundle 7 is fixedly installed with respect to the first lumen 3, but the optical fiber bundle 7 is movable in the longitudinal direction of the first lumen 3, and the tip of the optical fiber bundle 7 is the first. It may be freely retractable from the opening of the end of the lumen 3.

The second lumen 4 is opened to the tip of the tube body 2 and is mainly used as a guide wire or an insertion channel for various medical treatment instruments. For example, an optical fiber can be stored in the second lumen 4 to irradiate a blood vessel or an inner wall of a tubular organ with a laser beam, or a probe for calculus crushing can be stored to crush a calculus.

The third lumen 5 can be opened to the tip of the tube body 2, and the fluid can be injected into the blood vessel or the like through the opening, or the fluid can be sucked from the blood vessel or the like. Specifically, the third lumen 5 is the catheter tube 1
It is used to administer a drug solution or the like into a blood vessel in which A is inserted or left in place, or when a blood vessel or the like is observed with an endoscope, a transparent liquid for pushing out blood or the like that hinders the field of view (for example, , Saline, dextrose) is also used as a flash channel.

The fourth lumen 6 is for accommodating the wire 8 for bending the tip portion 22 of the tube body 2. The tip opening of the fourth lumen 6 is sealed by filling with a filling material 61, and the tip of the wire 8 is fixed to the tube body 2 at the tip of the tube body 2 by the filling material 61. The fixed position of the tip of the wire 8 is on the tip side of the tube body 2 with respect to the tip 91 of the tightly wound portion of the coil 9 described later.

Further, the fixed position of the tip of the wire 8 is an eccentric position from the central axis of the tube body 2 in the cross section of the tube body 2, whereby the tip end portion 22 of the tube body 22 is pulled in a fixed direction by pulling the wire 8. It is possible to bend to. Therefore, the fixed position of the tip of the wire 8 is preferably a position sufficiently distant from the center of the cross section, for example, near the outer circumference in the cross section.

Further, the base end of the wire 8 is locked to a pulling tool 16 which will be described later. Such a wire 8 has a tensile strength that does not cause a disconnection due to the pulling operation of the pulling tool 16, and examples of the constituent material thereof include stainless steel, piano wire, Ni-Ti series,
Ni-Ti-Fe-based, superelastic alloys such as Ni-Ti-Co-based, or fine metal wires such as martensitic alloys, single wires or fiber bundles such as aromatic polyamide, aliphatic polyamide, polyarylate, polyester, and polyimide, Carbon fiber etc. can be mentioned.

The suitable diameter of the wire 8 depends on its material, but in the case of a fiber bundle of polyarylate, it is preferably 30 to 500 μm, more preferably 100 to 3 μm.
In the case of a stainless wire, it is preferably about 10 to 200 μm.

A pulling tool 1 which will be described later is provided with such a wire 8.
By pulling toward the base end of the tube body with 6,
As shown in FIG. 5, the distal end portion 22 of the tube body 2 is bent, and along with this, the optical fiber bundle 7 in the first lumen 3 is bent.
And the tip of a medical treatment instrument (not shown) in the second lumen 4 bends. As a result, it is possible to observe the inner surface of the blood vessel or the tubular trachea into which the catheter tube 1A has been inserted, or perform medical treatment.

In the present specification, "bending" is a concept including that the tube body 2 is bent in one step or in two or more step lines, or is continuously curved.

In the catheter tube of the present invention, the bending rigidity of the tip portion 22 can be made smaller than that of other portions of the tube body 2 so that the tip side 22 can be easily bent. In this case, the tip side 22 may be made of a material having a smaller longitudinal elastic modulus E than the other parts of the tube body 2, and / or the moment of inertia I of the cross section of the tip portion may be made smaller.

As another means for allowing the distal end side 22 to be easily bent, the distal end portion 22 is bent over all or part of the outer circumference of the tube body 2 (for example, near the proximal end of the distal end side 22). You may form the groove part (not shown) which assists in the circumferential direction. Two or more groove portions may be formed in the longitudinal direction of the tube body 2.

In the catheter tube of the present invention, the coil body 9 is arranged in the tube body 2. The "coil body" in the present invention refers to a spirally wound shape as shown in the figure, or a shape in which a plurality of annular members are arranged in the axial direction.

As shown in FIGS. 2 to 4, the coil body 9 is
The tube body 2 is spirally wound and arranged on the outer periphery of the tube body 2 over substantially the entire length of the tube body 2. Then, the coil body 9 in the distal end portion 22 of the tube body 2 has a gap 19 between adjacent turns,
Further, in the portion 23 on the base end side of the tip end portion 22, one adjacent winding is arranged in close contact. In addition,
Hereinafter, the portion where the coil body 9 is arranged in close contact is referred to as the "close contact winding portion 23".

The longitudinal cross-sectional shape of the coil body 9 should be such that, in the close-wound portion 23, adjacent windings can be brought into contact with each other at a surface having a predetermined area in order to exert the effect described later. Is required. Such a shape is not limited to the rectangular shape shown in the figure, and examples thereof include those shown in FIGS. 7 (A) to 7 (E).

The length of the tip portion 22 of the tube body 2 is not particularly limited, but is usually about 10 to 100 mm, preferably about 10 to 50 mm.

As the constituent material of the coil body 9, for example,
Metallic materials such as stainless steel, tungsten, aluminum, brass, superelastic alloys, or polytetrafluoroethylene (Teflon), polyvinyl chloride, polyamide, polyethylene terephthalate, polybutylene terephthalate, polysulfone, polycarbonate, polyarylate, polyacetal, Polyphenylene sulfide,
Examples thereof include polyether ketone, polyether ether ketone, polyimide, and composite materials thereof.

The coil body 9 is not limited to the spiral shape as shown in the figure, but a plurality of annular members are continuously arranged in the longitudinal direction of the tube body 2 in a state where the respective members are in close contact with each other. You may comprise by. The cross-sectional shape, dimensions, and the like of such an annular member are the same as those of the spiral shape shown in the drawing.

The position where the coil body 9 is arranged with respect to the tube body 2 is not limited to the outer peripheral surface of the tube body 2 as shown in the figure. For example, a portion in the lumen of the tube body 2 excluding the tip portion 22. In addition, the coil body 9 in which one adjacent winding is closely attached may be housed (not shown). In this case, the lumen for housing the coil body 9 is not particularly limited, and may be, for example, the fourth lumen 6 for housing the wire or the second lumen 4 for housing the medical device or the like. Also, by setting the outer diameter of the coil body 9 to be the same as or slightly larger than the inner diameter of the lumen,
The inner wall of the lumen and the inner wall of the lumen may be closely contacted with each other so that the coil body 9 is securely fixed to the tube body 2 so as not to slide in the longitudinal direction of the tube body 2.

The preferred cross-sectional shape of the coil body 9 varies depending on its cross-sectional shape and material, but it is preferable that the thickness is relatively thin so that the outer diameter of the catheter tube 1A does not become large. For example, in the case of a rectangular stainless wire whose cross section is as shown, the thickness is 50 μm
The thickness is preferably about 1 mm, more preferably 50 μm or more.
It is about 300 μm. The width of the coil body 9 in the cross-sectional shape is not particularly limited, but is 100 μm to 1 in order to prevent smooth bending of the tube body 2.
It is preferably about 0 mm.

Now, as shown in FIG. 8, these portions of the coil body 9 in which one adjacent winding is in contact with each other with a certain area are subjected to the axial force of the coil body 9 as shown in FIG. One winding of the coil body 9 is not displaced (moved) with respect to each other, and the outer shape of the coil body 9 is maintained. However, the coil body 9
With respect to the force applied in the direction of bending the coil body 9, as shown in FIG. 9, the coil body 9 is bent by mutually displacing (moving) with the end point 92 on the surface where the adjacent turns contact each other as a fulcrum.

In the catheter tube 1A, a force is applied in the longitudinal direction of the catheter tube 1A by pulling the wire 8 toward the proximal end of the tube body 2 by operating the pulling tool 16 described later. At this time, since the shape of the coil body 9 does not change in the close-wound portion 23 due to the above-described action, the coil body 9 does not bend, and as shown in FIG.
Only bends.

Further, the tightly wound portion 23 of the tube body 2
If the coil body 9 is bent, the shape of the coil body 9 can be changed as described above, so that the coil body 9 will not buckle, that is, the catheter tube 1A will not buckle.

Further, as in the illustrated example, in the catheter tube configured to have the gap 19 in the distal end portion 22, the distal end portion 2 obtained by pulling the pulling tool 16 described later is used.
With the bending of No. 2, as shown in FIG. 5, the gap 19 of the coil body 9 is gradually narrowed on the side where the wire is fixed, and conversely, the gap 19 is gradually widened on the opposite side. When the wire is further pulled, some adjacent turns of the coil body 9 come into close contact with each other on the side of the tip 22 where the wire is fixed. And in this state, even if external force is applied by pulling the wire,
Similar to the closely wound portion, the shape of the coil body 9 does not change, so that the tip 22 does not bend further.

As described above, the coil body 9 extends to the tip portion 22 and is arranged in a state where the gap 19 is provided between the adjacent turns, and the gap 19 is set to the tip portion 2.
By setting so that a part of the adjacent windings come into contact with each other when 2 is bent at a desired angle, it is possible to adjust the degree of bending of the tip portion 22 and prevent the bending angle from becoming excessive.

Further, the catheter tube 1A may have a structure (not shown) in which the coil body 9 does not extend to the distal end portion 22 and the coil body 9 is not arranged at the distal end portion 22. In the case of such a configuration, when the wire 8 is pulled, the coil body 9 is rotated with the tip of the tightly wound portion 23 as a fulcrum.
Only the front end portion 22 where is not bent is bent.

As shown in FIGS. 2 to 4, on the outer circumference of the coil body 9, as a holding member for holding the coil body 9 so as not to separate from the outer circumference of the tube body 2, the covered tube 10 is provided.
Is provided.

As the constituent material of the covering tube 10, those having flexibility, especially elasticity are preferable. For example, various rubber materials such as silicone rubber and latex rubber, and polyolefins such as polyethylene and polypropylene, polyurethane, poly Examples of the resin material include vinyl chloride, polyamide, and ethylene-vinyl acetate copolymer. By using such a material, the coil body 9 is prevented from moving along the outer circumference of the tube body 2, and a gap is not created between the coil body 9 and the covering tube 10, so that the catheter tube 1A The outer diameter can be made as small as possible. Furthermore, it is preferable that the coating tube 10 be formed of a heat shrinkable tube made of these materials. As a result, the coil body 9 is attached to the tube body 2
After arranging by spirally winding on the outer circumference of the coil body, covering the outer circumference of the coil body 9 with the heat-shrinkable tube before shrinkage, and then applying warm air to shrink the tube, the coating can be performed easily.

The thickness of the covering tube 10 is relatively thin so that the outer diameter of the catheter tube 1A does not become large, and is preferably about 10 to 500 μm, more preferably about 20 to 200 μm. . The distal end portion 101 of the covering tube 10 is preferably liquid-tightly fixed to the outer peripheral surface of the tube body 2 by fusion bonding, adhesion, or binding with a thread or the like. By providing such a covering tube 10, the surface of the catheter tube 1A becomes smooth, and when inserting the catheter tube 1A into a blood vessel, a tubular organ or the like, it is difficult to damage the inner wall of the blood vessel, the tubular organ or the like.

The holding member for the coil body 9 is not limited to the covering tube 10 as shown in the figure, and for example, a flexible resin material may be directly coated on the arranged coil body 9. Further, a configuration may be used in which a mesh member is wound around the outer circumference of the coil body 9, or a plurality of ring-shaped members may be attached to the outer circumference of the coil body 9 at predetermined intervals in the longitudinal direction of the tube body. In this case, the surface of the catheter tube 1A can be made smooth by coating the resin material having flexibility after providing the mesh-shaped or ring-shaped member. Examples of such a resin material include the same materials as those mentioned as the constituent material of the coated tube 10, low friction materials such as polytetrafluoroethylene (Teflon), and the like.

Alternatively, the coil body 9 may be fixed to the tube body 2 by fusing, bonding or the like without providing the above-mentioned holding member. Also in this case, the surface of the catheter tube 1A can be made smooth by coating the coil body 9 with the above resin material after the fixing.

As shown in FIG. 6, the operation portion 11 formed on the proximal end side of the tube body 2 is in communication with the first lumen 3 and the first connector 12 into which the optical fiber bundle 7 is inserted.
And a second connector 13 communicating with the second lumen 4 for inserting a guide wire or a medical treatment instrument (not shown)
And a third connector 14 that communicates with the third lumen 5 and can connect a liquid injection device such as a syringe to the proximal end thereof, and a fourth lumen 6 that communicates with the fourth lumen 6 and a wire 8. It is composed of a connector 15 and a pulling tool 16 attached to the base end of the fourth connector 15.

FIG. 10 is a vertical sectional view showing a structural example of the pulling tool 16. As shown in the figure, the pulling tool 16 has a substantially cylindrical cylinder 16 at the base end portion of the fourth connector 15.
1 are connected, and a spiral female screw 162 is formed on the inner peripheral surface of the cylinder 161.

On the other hand, on the outer peripheral surface of the head portion 164 of the plunger 163 inserted into the cylinder 161, a male screw 165 which is screwed into the female screw 162 is formed. Further, a flange 166 for gripping the plunger 163 with fingers is formed at the proximal end of the plunger 163.

A through hole 167 having an inner diameter slightly larger than the diameter of the wire 8 is formed inside the plunger 163, and the base end portion of the wire 8 is inserted through the through hole 167 to form the base end surface of the plunger 163. The exposed base end of the wire 8 is rotatably locked to the plunger 163 by a stopper 168.

When the plunger 163 is gripped and rotated while the cylinder 161 is fixedly supported, the plunger 163 moves in the axial direction with respect to the cylinder 161, and accordingly, the wire 8 moves in the same direction. Moving. For example, when the plunger 163 is rotated counterclockwise and moved to the proximal end side, the wire 8 is pulled toward the proximal end of the tube body 2, and the distal end portion 22 of the tube body 2 bends as shown in FIG. To do. Further, when the plunger 163 is rotated in the opposite direction to the distal end side and returned to the original position, the pulling of the wire 8 is released, and the distal end portion 22 of the tube body 2 is shown in FIGS. 3 and 4. It returns to its original straight line state.

Since the moving distance of the plunger 163 is almost proportional to the rotation amount of the plunger 163, the degree of pulling the wire 8 (distance) can be adjusted by adjusting the rotation amount.
That is, the bending angle of the tip portion 22 can be adjusted to a desired angle.

At the base end of the cylinder 161, a rib 169 protruding inward is formed. This rib 1
69 serves as a stopper that contacts the base end surface of the head portion 164 of the plunger 163 and restricts the movement of the plunger 163 in the base end direction. When the proximal end surface of the head portion 164 of the plunger 163 comes into contact with the rib 169, if the tube body distal end portion 22 is adjusted to bend at a desired angle, the bending angle of the tube body distal end portion 22 becomes excessive. Can be prevented.

In such a pulling tool 16, a scale (not shown) is provided on the cylinder 161 or the plunger 163, and the pulling length of the wire 8, that is, the tip 2
It is also possible to know the bending angle of 2.

In a pulling tool such as the pulling tool 16 which converts a rotary motion into a linear motion, the degree of pulling of the wire 8, that is, the bending angle of the tip portion 22 can be finely adjusted. Excellent operability.

The pulling tool according to the present invention is not limited to the above-mentioned one. For example, the wire 8 may be pulled by a plunger sliding in the cylinder in the axial direction, or the wire 8 may be taken up by a take-up reel. Any structure such as a structure of winding and pulling may be used.

Further, in order to make the surface of the distal end portion 22 of the catheter tube 1A smoother, the gap 19 may be filled with a filler. With such a configuration, it is possible to reduce the unevenness of the surface of the catheter tube 1A between the portion where the coil body 9 exists and the portion where the coil body 9 does not exist, and the surface can be made smoother.

As a material of such a filler, a substance having elasticity is preferable, and for example, various rubber materials such as silicone rubber and latex rubber, polyurethane, polyvinyl chloride, polyamide, ethylene-vinyl acetate copolymer and the like. Resin materials such as Among them, those having flexibility are more preferable.

By constructing the filler with such a material, the wire 8 is pulled to position inside the bend (on the side having the wire 8) as the tip 22 is bent as shown in FIG. The filling material is compressed.

FIG. 11 is a cross-sectional view showing another example of the construction of the catheter tube of the present invention, and FIG. 12 is XI- in FIG.
It is a sectional view taken along line XI. Hereinafter, the configuration of the catheter tube 1B of the present invention will be described based on these drawings, but the description of the same matters as the catheter tube 1A will be omitted.

Tube body 2 of catheter tube 1B
Has the same first to fourth lumens 3, 4, 5 and 6 as described above. The first lumen 3 and the fourth lumen 6 respectively have the same optical fiber bundle 7 as described above.
And the wire 8 is stored.

Further, in the third lumen 5, the coil body 9 in which one adjacent winding is in close contact is accommodated except for the tip portion 22 of the tube body 2. As a result, the shape of the tube body 2 where the coil body 9 is present does not change with respect to the force acting in the longitudinal direction of the tube body 2, and therefore the distal end portion 22 is bent by the pulling operation of the wire 8. At this time, only the distal end portion 22 is surely bent, and the tube body 2 on the proximal end side (closely wound portion 23) of the distal end portion 22 is prevented from being unnecessarily curved.

In this coil body 9 as well, similar to the above, one adjacent winding of the coil body 9 can be displaced (moved) with respect to the end point as a fulcrum as the tube body 2 bends. Therefore, the buckling of the coil body, that is, the buckling of the catheter tube 1B is prevented.

The tip opening of the third lumen 5 is filled with the filler 51.
The liquid is prevented from flowing into the third lumen 5. Further, since the coil body 9 is housed in the third lumen 5, the fluid is injected into the blood vessel or the like, or the fluid is sucked from the blood vessel or the like in the second lumen 4.

Catheter tube 1B having such a configuration
Then, since the coil body 9 and the covering tube 10 such as the catheter tube 1A do not exist on the outer circumference of the tube body 2, the outer diameter of the catheter tube can be further reduced. Further, since it is not necessary to attach the covering tube 10 in manufacturing the catheter tube, the manufacturing of the catheter tube is facilitated and the manufacturing cost is reduced.

The coil body 9 is not limited to being housed in the third lumen 5, but may be housed together with the wire 8 in another lumen, for example, the fourth lumen 6. In this case, the coil body 9 can be arranged in a tubular shape so as to surround the wire 8. Further, similarly, the coil body 9 can be housed in the first lumen 3 together with the optical fiber bundle 7.

In the catheter tube 1B,
As the coil body 9, a plurality of ring-shaped members adhered to each other may be housed in the lumen of the tube body 2.

FIG. 13 is a cross sectional view showing another example of the construction of the catheter tube of the present invention. Hereinafter, the configuration of the catheter tube 1C of the present invention will be described with reference to the same drawing, but the description of the same matters as those of the catheter tubes 1A and 1B will be omitted.

The catheter tube 1C has almost the same structure as the catheter tube 1B, but an expandable body (balloon) 17 which can be expanded (expanded) and contracted around the outer peripheral wall of the tube body 2 is installed. Is different.
The expansion body 17 is made of a rubber material such as silicone rubber or latex rubber, or a thin film made of a resin such as polyurethane, polyvinyl chloride, polyamide, or ethylene-vinyl acetate copolymer in a tubular or bag shape. It is molded.

The expansion body 17 in the illustrated structural example is adapted to be in close contact with the inner wall surface of a blood vessel or a tubular organ at the time of expansion, and has a role of fixing the catheter tube 1C to a blood vessel or the like, and the front side of the expansion body 17 At the tip of the tube body), it has a role of eliminating blood that obstructs the field of view and blocking the inflow of blood when replacing it with a transparent liquid.
The use and function of the extension body 17 are not limited to these.

The installation position of the expansion body 17 with respect to the longitudinal direction of the tube body 2 is at the base end side of the close winding portion 23 of the coil body 9 or near the front end 91 so as not to hinder the bending of the front end portion 22. It is preferable that
In addition, it is preferable that such an expansion body 17 radially expands from the center of the tube body 2 during expansion.

The cross-sectional shape of the expansion body 17 may be a circle, an ellipse, or other similar shape, but if it is approximated to the cross-sectional shape of a blood vessel or tubular organ to be inserted or indwelled, it may be a blood vessel or tubular organ. Adhesiveness to is favorable, which is preferable.

The expansion body 17 needs to be attached to the tube body 2 in an airtight or liquid-tight manner. As a method of attaching the extension body 17, for example, another member (a tubular or bag-like member) is attached to the outer peripheral surface of the tube body 2. Etc.), a method of gluing the expansion body 17 at the ends by gluing, fusing or tying with a thread,
Alternatively, a method of integrally molding with the tube body 2 or two-color molding is possible.

Tube body 2 of catheter tube 1C
In addition to the first to fourth lumens, a fifth lumen 18 communicating with the inside of the expansion body 17 is formed in the. Through the fifth lumen 18, the fluid is sent into the expansion body 17 to expand the expansion body 17, and the fluid is discharged to contract the expansion body 17. The fluid for expanding the expansion body 17 may be air, gas such as CO ₂ gas or O ₂ gas, or liquid such as physiological saline or liquid containing X-ray contrast agent. The fifth lumen communicating with the expansion body 17 may also serve as another lumen, for example, the third lumen 5.

In such a catheter tube with an expansion body, a plurality of expansion bodies 17 may be formed along the longitudinal direction of the tube body 2. In this case, it is possible to provide a plurality of fifth lumens that communicate with the inside of each expansion body, or to configure one fifth lumen to communicate with the inside of each expansion body. The installation position when a plurality of expansion bodies are installed is the same as that described above, with the expansion body at the most distal end side of the tube body 2 being closer to the base end side than the distal end 91 of the tightly wound portion 23 of the coil body 9, or The position is preferably near the tip 91.

In such a catheter tube with an expandable body, the coil body 9 may be formed on the outer peripheral surface of the tube body 2. In this case, the fifth lumen 18
The opening 18a communicating with the expansion body of the coil body 9 is formed closer to the tip side than the tip 91 of the tightly wound portion 23 of the coil body 9 or near the tip 91.
7 is also formed in the vicinity of the opening 18a, that is, in the vicinity of the tip 91 or on the tip side thereof. However, for the reasons described above, it is preferable that the expansion body 17 exists near the tip 91.

The above catheter tubes 1A, 1B, 1C
In, the coil body 9 located on the outer peripheral surface of the tube body 2 or in the lumen may be installed so as to be movable in the axial direction. With such a configuration, there are the following advantages.
That is, the bending region of the tip portion 22 is adjusted by preselecting and setting the axial position of the tip 91 of the coil body 9 with respect to the tube body 2, that is, the bending point of the tip portion 22 is arbitrarily set. Can be set.

Further, when applying such a coil body axially movable structure to the catheter tubes 1B, 1C, the coil body can be housed in the fourth lumen 6 together with the wire 8. In this case, as described above, the coil body may be formed in a tubular shape, and the wire 8 may be housed in the inner cavity thereof.

As the operation tool for moving the coil body, the one having the same structure as the pulling tool 16 can be used, and when the coil body and the wire 8 are housed in the same lumen, the wire is used. As the pulling tool of 8, it is possible to use a pulling tool having a function of moving the coil body. Even if the movable coil body 9 is arranged except for the tip portion 22 shown in FIGS. 11 and 13, it is extended to the tip portion 22 as shown in FIGS. Any of those arranged so as to have an interval may be used.

The catheter tubes 1A, 1B, 1C
In the above, in order to bend the distal end portion 22 of the tube body 2 in two or more directions, a plurality of wires 8 can be provided. That is, a plurality of lumens (not shown) are provided at predetermined intervals along the circumferential direction in the cross section of the tube body 2, the wires 8 are housed in these lumens, and the tips of the wires 8 are respectively attached to the tube. If the structure is fixed at different eccentric positions in the cross section of the main body 2, one wire 8 or a part of a plurality of wires 8 is provided.
It is possible to bend the distal end portion 22 of the tube body 2 in a desired direction by pulling at once.

For example, four lumens are provided at equal intervals along the circumferential direction within the cross section of the tube body 2, and the wires 8 are housed in these lumens, respectively.
In a catheter tube having a configuration in which the tip ends of are fixed to the tip ends of the tube main body 2, if each wire 8 is pulled independently, the tip portion 22 will be 4 depending on the pulled wire 8.
It is possible to bend in one direction (up, down, left, right).

If two adjacent wires 8 are simultaneously pulled, the pulling wires 8 can be bent in four directions each forming an angle of 45 ° from the above four directions, and a total of eight directions can be obtained. The tip 22 can be bent. Furthermore, if the pulling force of each of the two adjacent wires 8 is changed and operated, the tip portion 22
Can be bent in any direction.

Thus, the tip portion 22 of the tube body 2 is
If it can be flexibly bent in many directions, the field of view of the blood vessel or tubular organ and the area where medical treatment can be performed will expand, and when changing the direction of the visual field of observation or the site of medical treatment. In addition, the operation can be performed easily and in a short time without performing an operation such as rotating the tube body 2.

Further, the catheter tubes 1A to 1
In C, in order to minimize the sliding resistance between adjacent turns of the coil body 9 or between the coil body 9 and the inner surface of the lumen that houses them, a surface where the adjacent turns of the coil body 9 are in contact with each other. Or the outer surface of the coil body 9,
The inner surface of the lumen that houses the coil body 9 may be subjected to the same treatment for reducing the friction coefficient as described above.

In the catheter tube of the present invention,
The present invention is not limited to having all of the illustrated first to fourth lumens, and one or more other lumens may be formed in addition to these lumens. The lumen is used, for example, for expanding the expansion body when a plurality of expansion bodies are provided, storing each wire when a plurality of wires is provided, and injecting a liquid different from the transparent liquid. , Blood suction, etc.

In the above description, an endoscope for observing the inside of a blood vessel or the like with an optical fiber has been described, but the use of the catheter tube of the present invention is not limited to this, and for example, administration of a medicinal solution or through an optical fiber. Laser beam irradiation, tip guidance when inserting into the target site, etc.
It can be applied to a wide range of fields.

The site for inserting and indwelling the catheter tube is not limited to blood vessels, but may be, for example, tubular organs such as the trachea, esophagus, stomach, intestine, ureter, bladder, biliary tract, pancreatic duct, abdominal cavity, or the heart. It can also be used for the inside of organs and the like.

Next, specific examples of the catheter tube of the present invention will be described. Example 1 An endoscope catheter tube having a structure shown in FIGS. 1 to 4 was manufactured. The conditions of this catheter tube are as follows.

<Tube Body> Material: Polyurethane (containing tungsten) Outer diameter: 2.5 mm Overall length: 500 mm Lumen: 4 lumen Lumen for storing fiberscope, 1 (inner diameter: 1.
0mm) Lumen for storing medical treatment tools, 1 (inner diameter: 1.0mm) Lumen for ejecting transparent liquid, 1 (inner diameter: 0.4mm) Lumen for storing wires, 1 (inner diameter: 0.3mm)

<Fiberscope> Image Fiber bundle (Approximately 2000 quartz fibers with a diameter of 2-3 μm
A bundle of books and a light guide fiber (diameter about 5)
50 pieces of 0 μm quartz fiber) were integrated into one fiber scope having an outer diameter of about 0.8 mmφ. Also,
A convex lens was attached to the tip surface of the image fiber bundle, and the light emitted from the light guide fiber was received to bind the subject image to the tip surface of the image fiber bundle.

<Coil> Material: Stainless steel Outer diameter: 2.9 mm Vertical cross-sectional shape: Flat plate (rectangular) Flat plate thickness: 0.15 mm Flat plate width: 1.0 mm Arrangement: 50 mm adjacent to the tube body tip 450 turns left so that one turn has a gap (number of turns: 30)
mm is arranged along the outer peripheral surface of the tube body so as to be in close contact (number of windings: 450)

<Coated tube> Material: Polyolefin heat shrinkable tube Inner diameter before shrinkage: about 3 mm Inner diameter after shrinkage: about 2.3 mm Thickness after shrinkage: About 100 μm The tube body was fixed to the tube body by adhesion.

<Wire> Material: Polyarylate Thickness: 100 denier Tip fixing position: Position 1 mm eccentric from the center of the cross section of the tube body, and 1 mm from the tip of the tube body to the base end side.

<Extended body> None

<Proximal End of Catheter Tube> 1. The pulling tool had the structure shown in FIG. Maximum travel distance of the tensioner: 10 mm

2. An eyepiece was attached to the base end of the image fiber bundle to enable direct observation. An optical connector was attached to the base end of the light guide, and this was connected to a xenon lamp.

3. At the base end of the transparent liquid ejection lumen,
A stopcock with a luer taper port was attached through a connector, and a syringe was connected to this to enable physiological saline to be supplied to a transparent liquid ejection lumen.

[Evaluation] A bent tube (bending radius: about 150 mm) made of a plastic tube having an inner diameter of 8 mm was manufactured,
The catheter tube of Example 1 was inserted into the bent tube (insertion length: about 200 mm). In this insert operation,
The tube body did not buckle, and the insertion operation was extremely smooth.

Next, the plunger of the pulling tool was manually operated, and the wire connected to the plunger was pulled to the proximal end side of the catheter tube by a moving distance of 5 mm to bend the distal end of the tube body. As a result, the tip of the fiberscope is also bent, and the average tilt angle is about 30 °.
Met.

In this state, the eyepiece was removed, and the inner surface of the bent tube was observed on a video monitor screen. As a result, good observation could be made. Moreover, when the inclination angle of the tip portion was adjusted by changing the degree (distance) of wire pulling in the range of 0 to 10 mm, a change in the visual field direction was confirmed through the monitor image.

The pulling operation of the wire and the releasing operation thereof could be smoothly performed without any trouble. The bending of the tube body occurred only at the tip portion, and the bending of the tube body due to the pulling of the wire did not occur in the portion where the rigidity imparting body was present.

(Embodiment 2) The longitudinal cross-sectional shape is the same as that of Embodiment 1, and a tightly wound coil body having an outer diameter of 0.95 mm and a total length of 450 cm (the number of windings: 450) is placed in the medical treatment instrument accommodating lumen. A catheter tube similar to that in Example 1 was manufactured except that it was housed and the covering tube was omitted (configuration shown in FIGS. 10 and 11). When this catheter tube was evaluated in the same manner as in Example 1, similar results were obtained.

(Embodiment 3) The following expansion body is installed around the outer peripheral wall of the tube body, and an expansion body expansion lumen (inner diameter: 0.
3 mm) was provided (configuration shown in FIG. 12), and the second embodiment
A catheter tube similar to the above was manufactured. An expansion liquid injection syringe was connected to the proximal end of the expansion body expansion lumen through a valve having a luer taper receptacle so that the expansion liquid (physiological saline) could be injected into the expansion body.

<Expansion body> Material: Latex rubber Thickness: Approximately 150 μm Shape: Cylindrical effective length: 7 mm Expanded diameter: 6 mm Tip position: Position 30 mm from tube body tip to base end side

[Evaluation] The femoral artery was secured to the experimental animal by the Seldinger method, and under fluoroscopy, the catheter tube of Example 4 was gradually inserted into the blood vessel having an inner diameter of about 5 mm to the target site (insertion). Length: about 100 mm). In this insertion operation, buckling of the tube body did not occur, and the insertion operation could be performed extremely smoothly.

Next, the expansion liquid injection syringe was operated to expand the expansion body, fixing the catheter tube to the blood vessel and blocking the blood flow. Next, the syringe for jetting the transparent liquid was operated, and physiological saline was continuously injected into the blood vessel through the lumen for jetting the transparent liquid to eliminate blood.

Next, the plunger of the pulling tool was manually operated, and the wire connected to the plunger was pulled to the proximal end side of the catheter tube by a moving distance of 5 mm to bend the distal end of the tube body. As a result, the tip of the fiberscope was also bent. When confirmed by X-ray fluoroscopy, the inclination angle was about 30 °.

In this state, the eyepiece was removed and the blood vessel inner wall surface was observed on a video monitor screen. As a result, clear observation was possible without the inflow of blood into the observed portion. Also, the degree of pulling the wire (distance)
When the tilt angle was adjusted by changing in the range of 0 to 10 mm, a change in the visual field direction was confirmed through the monitor image.

The pulling operation of the wire and the releasing operation thereof could be smoothly performed without any trouble. The bending of the tube body occurred only at the tip portion, and the bending of the tube body due to the pulling of the wire did not occur in the portion where the rigidity imparting body was present.

[0123]

As described above, according to the catheter tube of the present invention, a relatively small diameter can be obtained by the simple construction in which the adjacent coil is closely attached except the distal end of the tube body. Also in the catheter tube, the tip portion of the catheter tube can be reliably bent.

The catheter tube of the present invention is
Since the coil body can bend along with the tube body,
Buckling is unlikely to occur, so that the catheter tube can be easily inserted and inserted. Further, since the diameter of the catheter tube can be reduced, it can be applied to more peripheral blood vessels and thin tubular organs.

[Brief description of drawings]

FIG. 1 is a plan view showing a configuration example of a catheter tube of the present invention.

FIG. 2 is a sectional view taken along line II-II in FIG.

FIG. 3 is a sectional view taken along line III-III in FIG.

FIG. 4 is a sectional view taken along line IV-IV in FIG.

5 is a vertical cross-sectional view showing the configuration of the catheter tube shown in FIG. 1 in a state where the distal end portion is bent.

FIG. 6 is a vertical sectional view schematically showing a configuration example of a pulling tool according to the present invention.

FIG. 7 is a cross-sectional view showing another configuration example of the vertical cross-sectional shape of the coil body according to the present invention.

FIG. 8 is a diagram for explaining the action of the coil body in the present invention.

FIG. 9 is a diagram for explaining the action of the coil body in the present invention.

FIG. 10 is a plan view showing another configuration example of the catheter tube of the present invention.

11 is a sectional view taken along line XI-XI in FIG.

FIG. 12 is a vertical cross-sectional view showing a configuration example of a catheter tube with an expandable body of the present invention.

[Explanation of symbols]

 1A, 1B, 1C Catheter tube 2 Tube body 21 Base end side 22 Tip part 22a Tip end side 22b Base end side 23 Adhesive winding part 3 1st lumen 4 2nd lumen 5 3rd lumen 6 4th lumen 51, 61 Filler 7 Optical fiber bundle 71 Light-transmitting fiber 72 Light-receiving fiber 73 Lens 8 Wire 9 Coil body 91 Tip 92 End point 10 Cover tube 101 Tip part 11 Operating part 12 First connector 13 Second connector 14 Third connector 15 Fourth connector 16 Tensioner 161 Cylinder 162 Female Thread 163 Plunger 164 Head 165 Male Thread 166 Flange 167 Through Hole 168 Stopper 169 Rib 17 Expansion Body 18 Fifth Lumen 19 Gap

Claims (1)

[Claims] 1. A flexible tube body, at least one lumen formed over substantially the entire length of the tube body, a coil body arranged in the tube body, and housed in the lumen, The distal end of the tube body has at least one wire fixed at an eccentric position near the distal end of the tube body, and a pulling tool capable of pulling the wire in the proximal direction of the tube body. In a portion excluding, the adjacent ones are closely attached to each other, whereby the distal end of the tube body is bent by pulling the wire in the proximal direction of the tube body. tube.