This application claims priority to Japanese Patent Application No. 2013-118988 which was filed on Jun. 5, 2013, the entire contents of which are incorporated herein by reference.
The disclosed embodiments relate to a medical device. Specifically, the disclosed embodiments relate to a pusher guidewire that delivers a stent housed in a catheter to a target site.
A stent is a medical device that supports the lumens of blood vessels and digestive organs so as to prevent re-constriction of blood vessels and digestive organs expanded by a balloon catheter and the like. Stents are broadly classified into two types: balloon expandable stents that are expanded by a balloon catheter and the like; and self-expandable stents that naturally expand on their own. In recent years, self-expandable stents that do not easily deform even under an external force are often used.
One known method for delivering a self-expandable stent to a target site is to house the stent in a front end portion of a catheter with the stent arranged around the outer circumference of a pusher guidewire, to advance the catheter to the target site, and then to push the pusher guidewire toward the front end so as to deploy the stent from the front end of the catheter at the target site (see, for example, Japanese Patent No. 4498709).
However, with the aforementioned pusher guidewire, if a doctor notices that the deployment position of the stent has shifted away from the target site during deployment of the stent from the front end of the catheter, the doctor can do nothing but pull the pusher guidewire toward the rear end so as to retrieve the stent in the state where the stent is pinched between the pusher guidewire and the catheter. Once a self-expandable stent has been deployed from the front end of a catheter, it cannot be retrieved into the catheter. For this reason, when a doctor attempts to retrieve the deployed stent, there is a risk of damaging the inner wall of a normal blood vessel by the deployed stent.
The disclosed embodiments have been made in view of the above issue. An object is to provide a pusher guidewire in which a coil has a free rear end that is not fixed to a core shaft, thereby allowing a stent that has been partially deployed from the front end of a catheter to be retrieved into the catheter.
The above object is achieved by the means listed below.
According to some aspects of the invention, a pusher guidewire is provided for delivering a stent to a target site, the pusher guidewire including: a core shaft; a coil covering a front end portion of the core shaft; and a joining member joining the front end portion of the core shaft and the coil, wherein a rear end of the coil is a free end that is not fixed to the core shaft.
According to some aspects of the invention, the pusher guidewire is provided in which an outer diameter of the coil is larger from the joining member to the rear end of the coil than from a front end of the coil to the joining member.
According to some aspects of the invention the pusher guidewire is provided in which a wire diameter of a wire constituting the coil is larger from the joining member to the rear end of the coil than from a front end of the coil to the joining member.
According to some aspects of the invention the pusher guidewire is provided in which a winding pitch of the coil is larger from the joining member to the rear end of the coil than from a front end of the coil to the joining member.
According to some aspects of the invention, the pusher guidewire is provided in which the rear end of the coil is provided with a latching member.
In the pusher guidewire according to at least some aspects of the invention, the rear end of the coil is a free end that is not fixed to the core shaft. Therefore, by pulling the core shaft toward the rear end, the free rear end of the coil catches a gap of the partially-deployed stent. By rotating the core shaft in this state, the stent deployed from the front end of the catheter can be wrapped around the outer circumference of the coil. By further pulling the core shaft toward the rear end with the stent thus wrapped, the partially-deployed stent can be retrieved into the catheter. As a result, the inner wall of a normal blood vessel can be prevented from being damaged by the stent.
In the pusher guidewire according at least some aspects of the invention, the outer diameter of the coil is larger from the joining member to the rear end of the coil than from the front end of the coil to the joining member. Reducing the outer diameter of the coil on the front end allows the pusher guidewire to reach blood vessels at more extreme ends. Furthermore, the gaps of the stent are not expandable and hence narrow when the stent is housed in the catheter, but are widened once the stent has been deployed from the front end of the catheter. Therefore, increasing the outer diameter of the coil on the rear end side makes it easy for the rear end of the coil to catch a gap of the stent that is starting to expand. In this way, the partially-deployed stent can be retrieved into the catheter more reliably.
In the pusher guidewire according at least some aspects of the invention, the wire diameter of the wire constituting the coil is larger from the joining member to the rear end of the coil than from the front end of the coil to the joining member. Reducing the wire diameter of the wire constituting the coil on the front end reduces the outer diameter of the coil on the front end, thereby allowing the pusher guidewire to reach blood vessels at more extreme ends. Furthermore, increasing the wire diameter of the wire constituting the coil on the rear end increases the force by which the coil on the rear end restrains the stent, thereby making it easy to wrap the stent deployed from the front end of the catheter around the outer circumference of the coil. In this way, the partially-deployed stent can be retrieved into the catheter more reliably.
In the pusher guidewire according to at least some aspects of the invention, the winding pitch of the coil is larger from the joining member to the rear end of the coil than from the front end of the coil to the joining member. By narrowing the winding pitch of the coil on the front end, rotation of the core shaft can be transmitted to the front end of the coil via the joining member. On the other hand, by widening the winding pitch of the coil on the rear end, the flexibility of the free rear end of the coil can be increased, and a clearance can be provided between portions of the wire constituting the coil. As a result, the flexibility is improved, and the rear end of the coil, in which the clearance is provided between portions of the wire, easily catches a gap of the stent. In this way, the partially-deployed stent can be retrieved into the catheter more reliably.
In the pusher guidewire according to at least some aspects of the invention, the rear end of the coil is provided with a latching member. The latching member has a hook-like shape or a bulged shape. This can reduce the risk that the rear end of the coil that caught a gap of the stent slips off the gap of the stent when the core shaft is rotated.
A pusher guidewire 1 according to one embodiment will now be described with reference to
First, as shown in
A catheter 2 has a tubular body 20 into which the pusher guidewire 1 can be inserted. The pusher guidewire 1, around which the stent 10 is arranged between the front end coil 14 and the rear end coil 18, can be inserted from a rear end opening 22 of the catheter 2. A description of the catheter 2 is omitted as a conventional catheter can be used as the catheter 2.
As shown in
A pusher 40, which is joined to the second front end portion 12b of the core shaft 12, is provided between the stent 10 and the rear end coil 18. The pusher 40 is constituted by a tubular body made of metal such as stainless steel, and is used to deploy the stent 10 from a front end opening 24 of the catheter 2 when the doctor pushes the core shaft 12 toward the front end (the left side of
As shown in
Once the catheter 2 has been advanced to the target site, the doctor pushes the core shaft 12 toward the front end (the direction of arrow 50) so as to deploy the stent 10 housed in the catheter 2 at the target site (see
The catheter 2 is fixed such that it does not move when the stent 10 is deployed at the target site. However, in the case where the target site is in a curved peripheral blood vessel and hence a front end portion of the catheter 2 is curved, if the core shaft 12 is forcefully pushed toward the front end (the left side of
In the pusher guidewire 1 according to the present embodiment, the rear end 14a of the front end coil 14 is a free end that is not fixed to the first front end portion 12a of the core shaft 12, and therefore pulling the core shaft 12 toward the rear end (the direction of arrow 60) allows the rear end 14a of the front end coil 14 to catch a gap 10a of the stent 10 (see
By rotating the core shaft 12 in the circumferential direction (the direction of arrow 70) with the rear end 14a of the front end coil 14 catching the gap 10a of the stent 10, the front end portion 11 of the stent 10 deployed from the front end opening 24 of the catheter 2 can be wrapped around the outer circumference of the front end coil 14 (see
By further pulling the core shaft 12 toward the rear end (the direction of arrow 80) with the front end portion 11 of the stent 10 wrapped around the outer circumference of the front end coil 14, the partially-deployed stent 10 can be retrieved into the catheter 2 (see
By using the free rear end 14a of the front end coil 14 in the above manner, the stent 10 deployed from the front end opening 24 of the catheter 2 can be retrieved into the catheter 2. Therefore, when the doctor attempts to retrieve the stent 10 after noticing the shift of the deployment position of the stent 10 away from the target site, a blood vessel can be prevented from being damaged by the stent 10 deployed from the front end opening 24 of the catheter 2.
The following describes the materials of the constituent elements of the pusher guidewire 1 according to the present embodiment. It should be noted, however, that these constituent elements are not particularly limited to being made of the following materials.
The core shaft 12 may be formed by stainless steel (e.g., SUS 304 and SUS 316) or by a superelastic alloy such as Ni—Ti alloy.
The front end coil 14 and the rear end coil 18 may be formed by radiopaque wires. Such wires are made of, for example, gold, platinum, tungsten, or an alloy containing these chemical elements. With the front end coil 14 and the rear end coil 18 formed by radiopaque wires, the operator can determine the positions of the front end coil 14 and the rear end coil 18 on radiographic images.
The front end coil 14 and the rear end coil 18 may each be formed by a single wire or by a strand made by stranding a plurality of wires. Preferably, the front end coil 14 and the rear end coil 18 are each formed by a strand as it has superior characteristics compared to a single wire in terms of flexibility and resilience.
The front end tip 16 may be formed by a radiopaque material, such as gold, platinum, tungsten, or an alloy containing these chemical elements, so that the position of the front end of the pusher guidewire 1 can be acknowledged on radiographic images.
The joining members 30, 32 may be formed by a brazing filler material (e.g., aluminum alloy, silver, and gold), metal solder (e.g., Au—Sn alloy), and the like.
Similarly to the core shaft 12, the pusher 40 may be formed by stainless steel (e.g., SUS 304 and SUS 316) or by a superelastic alloy such as Ni—Ti alloy.
A pusher guidewire 1a according to a second embodiment will now be described with reference to
The pusher guidewire 1a is different from the pusher guidewire 1 shown in
A pusher guidewire 1b according to a third embodiment will now be described with reference to
The pusher guidewire lb is different from the pusher guidewire 1 shown in
The wire diameter D3 in the front of the front end coil 74 may be reduced as follows: after forming the front end coil 74 by winding a wire having the large wire diameter D4 around the outer circumference of the first front end portion 12a of the core shaft 12, electropolishing is applied to the front end coil 74 between the front end thereof and the joining member 30 so as to transform the wire diameter of the front end coil 74 on the front end side from the large wire diameter D4 to the small wire diameter D3. Alternatively, after forming the front end coil 74 on the front end side by winding a wire having the small wire diameter D3 around the outer circumference of the first front end portion 12a of the core shaft 12, a separate wire having the wire diameter D4, which is larger than the wire diameter D3 of the front end coil 74 on the front end side, may be wound so as to form the front end coil 74 on the rear end side.
A pusher guidewire 1c according to a fourth embodiment will now be described with reference to
The pusher guidewire 1c is different from the pusher guidewire 1 shown in
Finally, a pusher guidewire 1d according to a fifth embodiment will be described with reference to
The pusher guidewire 1d is different from the pusher guidewire 1 shown in
When positioning the front end opening 24 of the catheter 2 at the target site, the catheter 2 and the pusher guidewire 1, 1a, 1b, 1c, 1d may be delivered together with the pusher guidewire 1, 1a, 1b, 1c, 1d inserted into the catheter 2 in advance (the state of
As described above, in the pusher guidewire 1, 1a, 1b, 1c, 1d, the rear end 14a, 64a, 74a, 84a, 94a of the front end coil 14, 64, 74, 84, 94 is a free end that is not fixed to the first front end portion 12a of the core shaft 12. Therefore, by pulling the core shaft 12 toward the rear end, the free rear end 14a, 64a, 74a, 84a, 94a of the front end coil 14, 64, 74, 84, 94 catches a gap 10a of the partially-deployed stent 10. By rotating the core shaft 12 in this state, the front end portion 11 of the stent 10 deployed from the front end opening 24 of the catheter 2 can be wrapped around the outer circumference of the front end coil 14, 64, 74, 84, 94. By further pulling the core shaft 12 toward the rear end with the stent 10 thus wrapped, the partially-deployed stent 10 can be retrieved into the catheter 2. As a result, the inner wall of a normal blood vessel can be prevented from being damaged by the stent 10.
Number | Date | Country | Kind |
---|---|---|---|
2013-118988 | Jun 2013 | JP | national |