COIL REINFORCED SUPERELASTIC GUIDEWIRE

Abstract

A guidewire formed from a superelastic material has a proximal section and a distal section. In order to improve torque and pushability in the proximal section, a first wire is wound clockwise onto the proximal section to form a first coil and a second wire is wound counterclockwise onto the first coil to form a second coil.

Claims

1. A guidewire, comprising: an elongated core wire formed from a superelastic material; the elongated core wire having a proximal section and a distal section; a first multifilar wire wound in a clockwise direction onto the proximal section of the elongated core wire to form a first multifilar coil; a second multifilar wire wound in a counterclockwise direction onto the first multifilar coil to form a second multifilar coil; and a polymer cover over the second multifilar coil and the proximal section of the elongated core wire to attach the first multifilar coil and the second multifilar coil to the elongated core wire.

2. The guidewire of claim 1, wherein the proximal section of the elongated core wire has a uniform outer diameter.

3. The guidewire of claim 2, wherein the distal section of the elongated core wire is tapered.

4. The guidewire of claim 1, wherein one of the first multifilar coil or the second multifilar coil has a transverse rectangular shaped cross-section.

5. The guidewire of claim 1, wherein the first multifilar coil and the second multifilar coil have transverse rectangular cross-sections.

6. The guidewire of claim 1, wherein the polymer cover conforms to a shape of the second multifilar coils to form an irregular surface.

7. The guidewire of claim 1, wherein one of the first multifilar coil or the second multifilar coil has a transverse I-beam shaped cross-section.

8. The guidewire of claim 1, wherein the first multifilar coil and the second multifilar coil have a transverse I-beam shaped cross-section.

9. The guidewire of claim 1, wherein the first multifilar coil or the second multifilar coil is formed from a metallic material taken from the group of metallic materials including stainless steel, titanium, cobalt-chromium, tungsten, nitinol, platinum and silver.

10. The guidewire of claim 1, wherein the superelastic material forming the elongated core wire is taken from the group of materials including NiTi, CuZnAl and Co—Cr—N.

11. The guidewire of claim 1, wherein the elongated core wire is formed from a hollow tubing.

12. A guidewire, comprising: an elongated core wire formed from a superelastic material; the elongated core wire having a distal section and a proximal section; a first wire wound in a clockwise direction onto the proximal section to form a first coil and a second wire wound in a counterclockwise direction onto the first coil to form a second coil; and a polymer cover over the second coil and the proximal section of the elongated core wire to attach the first coil and the second coil to the elongated core wire.

13. The guidewire of claim 12, wherein the first wire or the second wire has a transverse cross-sectional shape other than round.

14. The guidewire of claim 12, wherein the proximal section of the elongated core wire has a uniform outer diameter.

15. The guidewire of claim 12, wherein the distal section of the elongated core wire is tapered.

16. The guidewire of claim 12, wherein one of the first wire or the second wire has a transverse rectangular shaped cross-section.

17. The guidewire of claim 12, wherein the first wire and the second wire have a transverse rectangular shaped cross-section.

18. The guidewire of claim 12, wherein the first wire and the second wire have a transverse I-beam shaped cross-section.

19. A guidewire, comprising: an elongated hollow tubing formed from a superelastic material; the elongated hollow tubing having a proximal section and a distal section; a first multifilar wire wound in a clockwise direction onto the proximal section of the elongated hollow tubing to form a first multifilar coil; a second multifilar wire wound in a counterclockwise direction onto the first multifilar coil to form a second multifilar coil; and a polymer cover over the second multifilar coil and the proximal section of the elongated hollow tubing to attach the first multifilar coil and the second multifilar coil to the elongated hollow tubing.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0007] FIG. 1 is an elevational view, partially in section, depicting a guidewire having counter-wound multifilar coils on the proximal section.

[0008] FIG. 2A is an enlarged, partial elevational view of the proximal section of the guidewire of FIG. 1, depicting a first multifilar wire being wound in a clockwise direction onto the proximal section.

[0009] FIG. 2B is an enlarged, partial elevational view of the proximal section of the guidewire of FIG. 2A, depicting the first multifilar wire forming first multifilar coils wound in a clockwise direction onto the proximal section

[0010] FIG. 3 is an enlarged, partial elevational view of the proximal section of FIG. 2B, depicting a second multifilar wire being wound in a counterclockwise direction onto the first multifilar coil to form a second multifilar coil.

[0011] FIG. 4 is an enlarged, partial elevational view of the first multifilar coil and the second multifilar coil being covered by a polymer cover.

[0012] FIG. 5 is an enlarged, partial elevational view, in section, depicting a first wire coil and a second wire coil being covered by a polymer cover.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0013] While navigating a guidewire through tortuous anatomy during intervention procedures there is always a device compromise made to sacrifice push and torque transmission to the distal end to gain navigational and durability traits. Nitinol is often used to aid the physician in navigation and durability, however, the material properties of nitinol are not optimal for torque or push due to the superelastic nature of the material. The concept is to use a single length of superelastic wire or hollow tubing, such as nitinol, and alter the torque transmission, durability, and pushability, by reinforcing the proximal section of the guidewire.

[0014] In one embodiment, as shown in FIGS. 1-4, a guidewire 10 includes an elongated core wire 12 formed from a superelastic material. The elongated core wire 12 has a proximal section 14 and a distal section 16. A first multifilar wire 18 is wound in a clockwise direction 19 onto the proximal section 14 of the elongated core wire 12 to form a first multifilar coil 20 (FIG. 2A), and a second multifilar wire 22 is wound in a counterclockwise direction 23 onto the first multifilar coil 20 to form a second multifilar coil 24 (FIG. 3). As shown in FIG. 4, a polymer cover 26 is placed over the second multifilar coil 24 and the proximal section 14 of the elongated core wire 12 to attach the first multifilar coil 20 and the second multifilar coil 24 to the elongated core wire 12. The polymer cover 26 can be applied by means of dip coating, coextruding, or a shrink tube placed over the coils 20, 24 and secured in place. Counter winding the coils 20, 24 will provide optimal torque in both the clockwise 19 and counterclockwise 23 directions. The transverse cross-section of the multifilar wires 18, 22 can also be a specific profile, such as round, rectangular, I-beam shaped, helical hollow strand, or stranded coil element/filament to optimize mechanical properties and torque transmission. Utilizing counter-wound coils 20, 24 on the guidewire proximal section 14 increases torquability in the proximal section 14 while allowing a more compliant and flexible distal section 16 for navigating tortuous vessels. Utilization of the multifilar coils over the proximal section also allows the polymer cover 26, once applied, to mimic the profile of the underlying structure (the multifilar coils 20, 24) providing an uneven surface which would both minimize surface contact (due to a decrease in resistance while in a tortuous bend) and potentially aid the physician in gripping and torqueing the device while navigating the guidewire into position. As an alternative to winding the first multifilar wire 18 and the second multifilar wire 22 onto the proximal section 14, the multifilar coils 20, 24 can be formed as subassemblies and advanced over the proximal section 14 and then secured in place by the polymer cover 26. The multifilar wires 18, 22 can be formed from a metallic material including stainless steel, titanium, cobalt chromium, tungsten, nitinol, platinum and silver.

[0015] In another embodiment, as shown in FIG. 5, a guidewire 10 includes an elongated core wire 12 formed from a superelastic material similar to that shown in FIG. 1. The elongated core wire 12 has a proximal section 14 and a distal section not shown. A first wire 30 is wound in a clockwise direction 32 onto the proximal section 14 of the elongated core wire 12 to form a first coil 34, and a second wire 36 is wound in a counterclockwise direction 37 onto the first coil 34 to form a second coil 40. A polymer cover 26 is placed over the second coil 40 and the proximal section 14 of the elongated core wire 12 to attach the first coil 34 and the second coil 40 to the elongated core wire 12. The polymer cover 26 can be applied by means of dip coating, coextruding, or a shrink tube placed over the coils 34, 40 and secured in place. Counter winding the coils 34, 40 will provide optimal torque in both the clockwise 32 and counterclockwise 37 directions. The transverse cross-section of the first wire 30 and the second wire 36 can also be a specific profile, such as round, rectangular, I-beam shaped, or other known cross-sectional shapes, to optimize mechanical properties and torque transmission. Utilizing counter-rotated coils 34, 40 on the guidewire proximal section 14 increases torquability in the proximal section 14 while allowing a more compliant and flexible distal section for navigating tortuous vessels. Utilization of a single wire coil such as second coil 40 over the core material also allows the polymer cover 26, once applied, to mimic the profile of the underlying structure providing an uneven surface which would both minimize surface contact (due to a decrease in resistance while in a tortuous bend) and potentially aid the physician in gripping and torqueing the device while navigating the guidewire into position.

[0016] In all of the embodiments disclosed herein, a portion of or all of the elongated core wire 12 can be formed from a hollow tubing. The hollow tubing can improve guidewire performance, especially the torque and pushability performance. Application of the coils disclosed herein is the same for the hollow tubing as that described for the elongated core wire 12.

[0017] Guidewire lengths are well known in the art and can range from 180 cm to 300 cm for coronary artery applications, to much shorter lengths for other applications. Importantly, the proximal section 14 may be substantially longer than the distal section 16 of the elongated core wire 14. For example, for a standard 180 cm long guidewire 10, the proximal section can range from 95 cm to 180 cm, and preferably range from 165 cm to 175 cm.

[0018] The guidewire 10 preferably is formed from any superelastic material known in the art, and more preferably formed from nitinol. Guidewire 10 can be formed from other metal alloys including stainless steel, titanium, and cobalt chromium.

[0019] The polymer cover 26 can be formed by any polymer well known in the art for use with guidewire, catheters, and stents.