JP2018175768A - Stent system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inner catheter configured to be easily pulled out from a tube stent or a pusher catheter.SOLUTION: A stent system 100 includes fine projections 14, 24, and 34 formed on parts of an outer peripheral surface 12 of an inner catheter 10, an inner peripheral surface 22 of a tube stent 20, or an inner peripheral surface 32 of a pusher catheter 30, so as to prevent the inner catheter 10 and the tube stent 20 or the pusher catheter 30 from being closely fitted to each other. This configuration can reduce friction resistance of the inner catheter 10 with the tube stent 20 or the pusher catheter 30 when the inner catheter 10 is pulled out, so as to smoothly pull out the inner catheter 10.SELECTED DRAWING: Figure 1

Description

  The present invention is a non-expandable stent (hereinafter simply referred to as a "tube stent") which is inserted into a human body (hereinafter simply referred to as the "body") through an endoscope and deployed in a tubular organ such as a bile duct. And a pusher catheter for pushing a tube stent, and a stent system comprising a tube stent and an inner catheter inserted inside the pusher catheter.

  The tube stent is indwelled through the endoscope into, for example, a tubular organ such as a bile duct or a ureteral tube to ensure fluid communication in the tubular organ or to prevent rupture of a aneurysm formed in the tubular organ. Used for purpose. For non-expandable tube stents, for example, plastics such as fluoroplastics and polyethylene are mainly used, and those with or without side holes or flaps, straight type, curve type, pigtail type, etc. There are some variations.

  The tube stent advances in the human body by being pushed by a pusher catheter along a guide wire inserted into the human body and an inner catheter. Then, after the tube stent is pushed to the indwelling position, the indwelling process is completed by pulling out the pusher catheter, the inner catheter, and the guide wire. In order to facilitate the procedure for indwelling, a stent kit has been developed in which an inner catheter is inserted in advance through a tube stent, and examples thereof include the following.

JP, 2015-8862, A

  In Patent Document 1, a tube stent having a stent arc having one end formed of at least a part of an arc and an inner arc having the same shape as the stent arc is formed, and the positions of the inner arc and the stent arc coincide. Thus, a stent kit is disclosed which comprises an inner catheter which is inserted into the inside of a tube stent. Further, in this stent kit, the inner catheter and the stent easily rub, and the resistance when the inner catheter is pulled out from the stent is increased. Therefore, for example, PE (stent) and ETFE (inner catheter) It is said that it is preferable to make the inner catheters slippery to make it easy to withdraw the inner catheter from the stent.

  As described above, the tube stent is inserted into the human body through the endoscope. Here, the distal end of the endoscope is configured to be capable of being bent at an arbitrary angle, and at this time, the inner catheter and the pusher catheter passing through the inside of the endoscope will be similarly bent. In this state, even when trying to withdraw the inner catheter, there is a possibility that the frictional resistance between the inner catheter and the pusher catheter is large, making it difficult to withdraw the inner catheter. In addition, particularly in the case of a curved or pigtail type indwelling stent, a problem may occur in that the frictional resistance between the inner catheter and the indwelling stent is large, making it difficult to withdraw the inner catheter.

  Therefore, in view of the above-mentioned problems, the present invention has an object to provide an inner catheter which can be easily pulled out from a tube stent or a pusher catheter.

The present invention relates to a tubular inner catheter inserted into a tubular tube stent and a pusher catheter, wherein
An inner catheter characterized in that an outer peripheral surface minute convex shape is formed on at least a part of a portion of the outer peripheral surface of the inner catheter which passes through the inside of the tube stent.
Or
A tubular tube stent, in which a tubular inner catheter is inserted.
A tube stent having a micro convex shape formed on the inner peripheral surface of the tube stent on at least a part of the inner peripheral surface of the tube stent,
Or
A tubular pusher catheter, into which a tubular inner catheter is inserted.
The problem is solved by a pusher catheter characterized in that a fine convex shape is formed on the inner peripheral surface of the pusher catheter on at least a part of the inner peripheral surface of the pusher catheter.

  Inner catheters, tube stents, and pusher catheters are mainly made of plastic such as fluorocarbon resin and polyethylene, and are usually manufactured by injection molding, so their inner and outer peripheral surfaces are flat. For this reason, the inner catheter and the tube stent or the pusher catheter tend to be in close contact with each other, which is a cause of great resistance when the inner catheter is pulled out.

  According to the present invention, the fine convex shape is formed on the outer peripheral surface of the inner catheter, the inner peripheral surface of the tube stent, or a part of the inner peripheral surface of the pusher catheter. Contact with the inner circumferential surface of the tube stent or the inner circumferential surface of the pusher catheter can prevent the inner catheter and the tube stent or the pusher catheter from adhering to each other. This makes it possible to reduce the frictional resistance between the inner catheter and the tube stent or pusher catheter when the inner catheter is pulled out, and the inner catheter can be pulled out smoothly.

  In addition, part of the outer peripheral surface of the inner catheter and the inner peripheral surface of the tube stent or the inner peripheral surface of the pusher catheter do not engage with each other during relative movement of the inner catheter and the tube stent or pusher catheter in the axial direction By forming the fine convex shape, it is possible to further reduce the frictional resistance between the inner catheter and the tube stent or pusher catheter when the inner catheter is pulled out.

BRIEF DESCRIPTION OF THE DRAWINGS The partial front sectional view which represented a part of stent system of 1st Embodiment of this invention. The principal part enlarged view of FIG. The partial front view of the inner catheter of 2nd Embodiment of this invention. The partial front view of the inner catheter of 3rd Embodiment of this invention. The partial front view of the inner catheter of 4th Embodiment of this invention. The partial front view of the inner catheter of 5th Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS. However, the present invention is not limited to this embodiment.

  FIG. 1 shows a stent system 100 according to a first embodiment of the present invention. The stent system 100 includes a tubular inner catheter 10, a tube stent 20, and a pusher catheter 30, which are made of a plastic such as fluorocarbon resin or polyethylene. The tube stent 20 is a non-expandable type that is placed in a tubular organ such as a bile duct. As the tube stent 20, various types of non-expandable stents such as those with or without flaps, straight type, curve type, pigtail type, etc. can be used.

  The inner catheter 10 comprises an outer diameter that can be inserted inside the tube stent 20 and the pusher catheter 30. On the other hand, the inner diameter and the outer diameter of the tube stent 20 and the pusher catheter 30 are substantially the same. Therefore, in a state where the inner catheter 10 is inserted into the inside of the tube stent 20 and the pusher catheter 30, the tube stent 10 can be pushed by the pusher catheter 30 along the inner catheter 10. In addition, since the process of the procedure for indwelling the tube stent 10 is publicly known, the detailed description thereof is omitted, but a guide wire (not shown) is inserted into the human body through the endoscope and the inner along the guide wire. It is a common practice to insert the catheter 10 and push the tube stent 10 along the inner catheter 10 with the pusher catheter 30.

  The outer peripheral surface fine convex shape 14 is formed on a part of the outer peripheral surface 12 of the inner catheter 10 which passes through the inside of the tube stent 20. As shown in FIG. 2, the outer peripheral surface fine convex shape 14 is configured by portions other than the plurality of multidirectional grooves 16 provided on the outer peripheral surface 12 of the inner catheter 10.

  As described above, since the inner catheter 10 has the outer peripheral surface fine convex shape 14 on the outer peripheral surface 12, when the inner catheter 10 is pulled out from the tube stent 20 and the pusher catheter 30 (see FIG. 1), the outer peripheral surface micro convex shape In the range in which 14 is provided, the inner peripheral surface 22 of the tube stent 20, the inner peripheral surface 32 of the pusher catheter 30, and the outer peripheral surface fine convex shape 14 of the inner catheter 10 are in contact with each other. For this reason, compared with the inner catheter which has a planar outer peripheral surface, the outer peripheral surface 12 of the inner catheter 10 and the inner peripheral surface 22 of the tube stent 20 or the inner peripheral surface 32 of the pusher catheter 30 are prevented from adhering. Since the area of the outer peripheral surface 12 of the inner catheter 10 in contact with the inner peripheral surface 22 of the tube stent 20 and the inner peripheral surface 32 of the pusher catheter 30 can be reduced, the resistance due to friction can be reduced accordingly. it can. Thus, the inner catheter 10 can be pulled out of the tube stent 20 and the pusher catheter 30 smoothly.

  By providing the inner catheter 10 on the outer peripheral surface 12 of the inner catheter 10 corresponding to at least a part of the part of the inner surface of the tube stent 20, the outer peripheral fine convex shape 14 is provided from the tube stent 20 and the pusher catheter 30. Although the frictional resistance at the time of withdrawal can be reduced, the range in which the outer peripheral surface fine convex shape 14 is provided can be arbitrarily determined, and can also be provided over the entire outer peripheral surface 12 of the inner catheter 10.

  The outer peripheral surface fine convex shape 14 can be formed by the following steps. First, the tubular inner catheter 10 is formed by injection molding of a plastic material. Then, the outer circumferential surface 12 of the inner catheter 10 corresponding to at least a part of the portion of the inside of the tube stent 20 is scraped in any direction with a wedge member such as sandpaper. The scraping direction may be unidirectional (for example, only in the axial direction or circumferential direction), or may be scraped in multiple directions. The scraped portion forms a groove 16, and the portion other than the groove 16 forms an outer peripheral surface fine convex shape 14.

  On the other hand, as shown in FIG. 1, at least a part of the inner circumferential surface 22 of the tube stent 20 may be provided with a tube stent inner circumferential surface fine convex shape 24 similar to the outer circumferential surface fine convex shape 14. The tube stent inner peripheral surface fine convex shape 24 can be formed by scraping the inner peripheral surface 22 of a tubular tube stent 20 formed by injection molding of a plastic material with a wedge member in any direction. In addition, by providing the tube stent inner peripheral surface fine convex shape 24 on the entire inner peripheral surface 22 of the tube stent 20, the inner catheter 10 can be more easily pulled out from the tube stent 20.

  Further, at least a part of the inner peripheral surface 32 of the pusher catheter 30 may be provided with a pusher catheter inner peripheral fine convex shape 34 similar to the outer peripheral fine convex shape 14. The pusher catheter inner peripheral surface fine convex shape 34 can be formed by scraping the inner peripheral surface 32 of a tubular pusher catheter 30 formed by injection molding of a plastic material with a scissor member in an arbitrary direction. Although the pusher catheter inner peripheral surface fine convex shape 34 can be provided on the entire inner peripheral surface 32 of the pusher catheter 30, it is preferable to provide it on the inner peripheral surface 32 located on the distal end side of the pusher catheter 30.

  FIG. 3 shows an inner catheter 10a having an outer peripheral surface fine convex shape 14a according to another embodiment. As in the inner catheter 10a, the same effect as the outer peripheral surface fine convex shape 14 (see FIG. 1) of the inner catheter 10 can be obtained by providing the outer peripheral surface fine convex shape 14a consisting of a plurality of minute projections on the outer peripheral surface 12a. Can be played. The range in which the outer peripheral surface fine convex shape 14a is provided is the same as that of the outer peripheral surface fine convex shape 14 (see FIG. 1), and thus the description thereof is omitted. Although not shown in the drawings, a protrusion similar to the outer peripheral surface fine convex shape 14a, or at least a part of the inner peripheral surface 22 of the tube stent 20 (see FIG. 1) or the pusher catheter 30 (see FIG. 1) ) Can also be provided on at least a part of the inner circumferential surface 32.

  FIG. 4 shows an inner catheter 10b having an outer peripheral surface fine convex shape 14b of another embodiment. As in the case of the inner catheter 10b, by providing the outer peripheral surface fine convex shape 14b consisting of minute ridges extending in the axial direction of the outer peripheral surface 12b, the outer peripheral surface fine convex shape 14 (see FIG. 1) of the inner catheter 10 Similar effects can be achieved. The ridges of the outer peripheral surface fine convex shape 14b may be discontinuous. The range in which the outer peripheral surface fine convex shape 14 b is provided is the same as that of the outer peripheral surface fine convex shape 14 (see FIG. 1), and thus the description thereof is omitted. Although not shown in the drawings, a ridge similar to the outer peripheral surface fine convex shape 14b may be formed by at least a portion of the inner peripheral surface 22 of the tube stent 20 (see FIG. 1) or the pusher catheter 30 (FIG. 1). It can also be provided on at least a part of the inner circumferential surface 32 of the reference).

  FIG. 5 shows an inner catheter 10c having an outer peripheral surface fine convex shape 14c according to another embodiment. Like the inner catheter 10c, the outer peripheral surface fine convex shape 14c of the inner catheter 10 can also be obtained by providing the outer peripheral surface fine convex shape 14c consisting of a plurality of minute ridges extending in the circumferential direction of the outer peripheral surface 12c. The same effect can be obtained as in The ridges of the outer peripheral surface fine convex shape 14c may be discontinuous. The range in which the outer peripheral surface fine convex shape 14c is provided is the same as that of the outer peripheral surface fine convex shape 14 (see FIG. 1), and thus the description thereof is omitted. The outer peripheral surface fine convex shape 14c can be formed as a curved surface to be corrugated, or can be a continuous spiral ridge. Although not shown in the drawings, a ridge similar to the outer peripheral surface fine convex shape 14c may be formed on at least a portion of the inner peripheral surface 22 of the tube stent 20 (see FIG. 1) or the pusher catheter 30 (FIG. 1). It can also be provided on at least a part of the inner circumferential surface 32 of the reference).

  FIG. 6 shows an inner catheter 10d having an outer peripheral surface fine convex shape 14d of another embodiment. As in the inner catheter 10d, the same effect as the outer peripheral surface fine convex shape 14 (see FIG. 1) of the inner catheter 10 can be obtained by providing the outer peripheral surface fine convex shape 14d consisting of grid-like ridges on the outer peripheral surface 12d. Can be played. The ridges of the outer peripheral surface fine convex shape 14d may be discontinuous. The range in which the outer peripheral surface fine convex shape 14d is provided is the same as that of the outer peripheral surface fine convex shape 14 (see FIG. 1), and thus the description thereof is omitted. Although not shown in the drawings, a ridge similar to the outer peripheral surface fine convex shape 14d may be formed by at least a portion of the inner peripheral surface 22 of the tube stent 20 (see FIG. 1) or the pusher catheter 30 (FIG. 1). It can also be provided on at least a part of the inner circumferential surface 32 of the reference).

  Conversely, the outer peripheral surfaces 12a to 12d other than the portions corresponding to the outer peripheral surface fine convex shapes 14a to 14d are the inner peripheral surface of the tube stent, with the outer peripheral surface fine convex shapes 14a to 14d described above in a concave shape (groove). By contacting the surface or the inner peripheral surface of the pusher catheter, it is also possible to reduce the frictional resistance when the inner catheters 10a to 10d are withdrawn from the tube stent and the pusher catheter.

  Further, as shown in FIG. 1, the inner catheter 10 and the tube are provided on at least a part of the outer peripheral surface 12 of the inner catheter 10 and at least a part of the inner peripheral surface 22 of the tube stent 20 or the inner peripheral surface 32 of the pusher catheter 30. Forming a micro convex shape (micro convex shape on the outer peripheral surface, micro convex shape on the inner peripheral surface of the tube stent, micro convex shape on the inner peripheral surface of the pusher catheter) which does not engage with each other when the stent 20 or the pusher catheter 30 moves relative to the axial direction. Thus, the frictional resistance between the inner catheter 10 and the tube stent 20 or the pusher catheter 30 when the inner catheter 10 is withdrawn can be further reduced.

  As described above, according to the present invention, since it is possible to reduce the frictional resistance between the inner catheter and the tube stent or pusher catheter when pulling out the inner catheter, it is possible to smoothly pull out the inner catheter. Can provide a stent system that can

10 to 10 d inner catheter 12 outer peripheral surface 14 outer peripheral surface fine convex shape 20 tube stent 22 inner peripheral surface (tube stent)
24 tube stent inner circumferential surface micro convex shape 30 pusher catheter 32 inner circumferential surface (pusher catheter)
34 Pusher catheter inner circumference micro convex shape 100 stent system

The present invention is a stent system comprising a tubular tube stent and a pusher catheter, and a tubular inner catheter inserted inside the tube stent and the pusher catheter,
An outer peripheral surface fine convex shape is formed on at least a part of a portion of the outer peripheral surface of the inner catheter which passes through the inside of the tube stent,
At least a part of the inner peripheral surface of the tube stent is formed with the inner peripheral surface micro convex shape of the tube stent which does not engage with the outer peripheral surface micro convex shape at the time of relative movement of the inner catheter and the tube stent in the axial direction. A stent system characterized by
Or
A stent system comprising a tubular tube stent and a pusher catheter, and a tubular inner catheter inserted inside the tube stent and the pusher catheter,
An outer peripheral surface fine convex shape is formed on at least a part of a portion of the outer peripheral surface of the inner catheter which passes through the inside of the tube stent,
At least a part of the inner peripheral surface of the pusher catheter is formed with a fine convex shape of the inner peripheral surface of the pusher catheter which does not fit with the outer peripheral fine convex shape when the inner catheter and the pusher catheter move relative to each other in the axial direction A stent system characterized by
Or
A stent system comprising a tubular tube stent and a pusher catheter, and a tubular inner catheter inserted inside the tube stent and the pusher catheter,
An outer peripheral surface fine convex shape is formed on at least a part of a portion of the outer peripheral surface of the inner catheter which passes through the inside of the tube stent,
At least a part of the inner circumferential surface of the tube stent is formed with a microconvex shape on the inner circumferential surface of the tube stent that is not fitted with the outer circumferential surface on the outer circumferential surface when relative movement between the inner catheter and the tube stent in the axial direction.
At least a part of the inner peripheral surface of the pusher catheter is formed with a fine convex shape of the inner peripheral surface of the pusher catheter which does not fit with the outer peripheral fine convex shape when the inner catheter and the pusher catheter move relative to each other in the axial direction The above-mentioned problems are solved by a stent system characterized by

Claims (9)

A tubular inner catheter, which is inserted inside a tubular tube stent and a pusher catheter, comprising:
An outer peripheral surface fine convex shape is formed on at least a part of a portion of the outer peripheral surface of the inner catheter which passes through the inside of the tube stent.
Inner catheter. A tubular tube stent, in which a tubular inner catheter is inserted.
The tube stent inner circumferential surface micro convex shape is formed on at least a part of the inner circumferential surface of the tube stent.
Tube stent. A tubular pusher catheter, into which a tubular inner catheter is inserted.
The inner peripheral surface of the pusher catheter is characterized in that a fine convex shape is formed on the inner peripheral surface of the pusher catheter,
Pusher catheter. A stent system comprising a tubular tube stent and a pusher catheter, and a tubular inner catheter inserted inside the tube stent and the pusher catheter,
An outer peripheral surface fine convex shape is formed on at least a part of a portion of the outer peripheral surface of the inner catheter which passes through the inside of the tube stent,
At least a part of the inner peripheral surface of the tube stent is formed with the inner peripheral surface micro convex shape of the tube stent which does not engage with the outer peripheral surface micro convex shape at the time of relative movement of the inner catheter and the tube stent in the axial direction. It is characterized by
Stent system. A stent system comprising a tubular tube stent and a pusher catheter, and a tubular inner catheter inserted inside the tube stent and the pusher catheter,
An outer peripheral surface fine convex shape is formed on at least a part of a portion of the outer peripheral surface of the inner catheter which passes through the inside of the tube stent,
At least a part of the inner peripheral surface of the pusher catheter is formed with a fine convex shape of the inner peripheral surface of the pusher catheter which does not fit with the outer peripheral fine convex shape when the inner catheter and the pusher catheter move relative to each other in the axial direction Are characterized by
Stent system. A stent system comprising a tubular tube stent and a pusher catheter, and a tubular inner catheter inserted inside the tube stent and the pusher catheter,
An outer peripheral surface fine convex shape is formed on at least a part of a portion of the outer peripheral surface of the inner catheter which passes through the inside of the tube stent,
At least a part of the inner circumferential surface of the tube stent is formed with a microconvex shape on the inner circumferential surface of the tube stent that is not fitted with the outer circumferential surface on the outer circumferential surface when relative movement of the inner catheter and the tube stent in the axial direction is performed.
At least a part of the inner peripheral surface of the pusher catheter is formed with a fine convex shape of the inner peripheral surface of the pusher catheter which does not fit with the outer peripheral fine convex shape when the inner catheter and the pusher catheter move relative to each other in the axial direction Are characterized by
Stent system. A method of manufacturing a tubular inner catheter, which is inserted into a tubular tube stent and a pusher catheter, comprising:
Forming the inner catheter by injection molding;
The outer peripheral surface of the inner catheter, which corresponds to at least a part of a portion of the inside of the tube stent, is scraped in an arbitrary direction by a wedge member to form an outer peripheral surface fine convex shape.
Method of manufacturing an inner catheter. A method of manufacturing a tubular tube stent, wherein a tubular inner catheter is inserted inside the tube.
Forming the tube stent by injection molding;
At least a part of the inner peripheral surface of the tube stent is scraped in any direction by a wedge member to form a micro convex shape on the inner peripheral surface of the tube stent,
Method of manufacturing a tube stent. A method of manufacturing a tubular pusher catheter, wherein a tubular inner catheter is inserted inside the tube.
Forming the pusher-catheter by injection molding;
At least a part of the inner circumferential surface of the pusher catheter is scraped in any direction by a wedge member to form a fine convex shape on the inner circumferential surface of the pusher catheter,
Method of manufacturing a pusher catheter.