SOFT EMBOLIC IMPLANT
Soft embolic implants exhibiting secondary shapes are disclosed. Some of the embolic implants exhibit progressively increasing softness from the distal end to the proximal end of the coil. The embolic implants have a primary coil, an optional second coil, a shape wire, and a stretch resistant fiber disposed in the lumen of the primary coil. An optional distal support wire is also disclosed. The embolic implants include a proximal constraint assembly configured to be releaseably retained by a delivery device. Disposed near each end of some of the implants are elliptical hole washers through which the shape wire and the stretch resistant fiber are threaded. The embolic implants have a primary, linear configuration for delivery through an implant tool, and a secondary configuration after deployment from the implant tool. The secondary shape can be J-shaped, helical, spherical, complex, or a combination of shapes.
This application is a continuation-in-part of U.S. patent application Ser. No. 14/154,395, (Attorney Docket No. 41507-716.201), filed Jan. 14, 2014, the entire content of which is incorporated herein by reference.
FIELD OF THE INVENTIONThe present invention relates generally to the field of medical treatment, and more particularly to an embolic implant or embolic coil for occluding an aneurysm or a blood vessel.
BACKGROUND OF THE INVENTIONCoil embolization is a commonly practiced technique for treatment of brain aneurysm, arterio-venous malformation, and other conditions for which vessel occlusion is a desired treatment option, such as, for example, in the occlusion of a tumor “feeder” vessel. A typical occlusion coil is a wire coil having an elongate primary shape with windings coiled around a longitudinal axis. In a typical aneurysm coil embolization procedure, a catheter is introduced into the femoral artery and navigated through the vascular system under fluoroscopic visualization. The coil in its primary shape is positioned within the catheter. The catheter distal end is positioned at the site of an aneurysm within the brain. The coil is passed from the catheter into the aneurysm. Once released from the catheter, the coil assumes a secondary shape selected to optimize filling of the aneurysm cavity. Multiple coils may be introduced into a single aneurysm cavity for optimal filling of the cavity. The deployed coils serve to block blood flow into the aneurysm and reinforce the aneurysm against rupture. While the overall device is commonly referred to as a coil, some of the individual components of the device are also referred to as coils. For clarity, the device herein will most often be referred to as an embolic implant, though it will be understood that the terms embolic coil and embolic implant are interchangeable.
Some embodiments of the invention are described below. For clarity, not all features of each actual implementation are described in this specification. In the development of an actual device, some modifications may be made that result in an embodiment that still falls within the scope of the invention.
Beginning with
Also visible in
As mentioned above, embolic implant 10 is shown in its linear, delivery configuration. Embolic implant 10 may be delivered into the vasculature of a subject via a delivery catheter or comparable implant tool (not pictured), while embolic coil or embolic implant 10 is in its delivery configuration. Once delivered to a treatment site within the vasculature, embolic implant 10 will be released from the delivery system, and will revert to a secondary configuration. A secondary configuration according to the invention may be curved, hooked, J-shaped, spiral, helical, complex, spherical, or any other desirable three dimensional configuration. In the example of embolic implant 10, the secondary configuration is complex. Embolic implant 10 is illustrated in its complex secondary configuration in
Referring now to
In the delivery configuration illustrated in
Disposed at distal end 34 is distal assembly 35. Defining distal assembly 35 are distal tip 38, distal sphere 39, and distal knot 54. Within lumen 44, and extending the length of lumen 44, is fiber 46. In addition to being disposed in lumen 44, fiber 46 is disposed within and through an internal channel or through hole (not visible) of proximal constraint element or proximal constraint sphere 37.
Fiber thus extends proximally through lumen 44, through proximal constraint sphere 37, and out of proximal constraint sphere 37 at proximal end 32. Fiber 46 is knotted to form proximal knot 41. Fiber 46 is thus anchored at the proximal end 32. Proceeding in the opposite direction, fiber 46 extends distally of proximal constraint element 37, through lumen 44, and through distal sphere 39, which has, similar to proximal constraint sphere 37, an internal channel or through hole (not visible in
Distal sphere 39, which also may in the alternative have different shape, is retained by atraumatic distal tip 38. Atraumatic distal tip 38 is formed from a polymeric material such as polyester, an acrylic adhesive, or other suitable material. The material is injected, molded, reflowed, extruded, or otherwise placed around distal sphere 39, fiber 46 and distal knot 54 to securely bond the components one to another and to form an atraumatic distal tip. The embedding or other retention of distal sphere 39 also serves to prevent distal sphere 39 from entering lumen 44. Distal assembly 35, in conjunction with proximal assembly 36, thereby maintains tension upon fiber 46, and helps prevent stretching and distortion of primary coil 40 and inner coil 42.
Also disposed in lumen 44 is shape wire 48. Shape wire 48 is anchored in and extends from proximal bond 52, through lumen 44, and to distal tip 38. Wire 48 is formed from Nitinol or another suitable shape memory material. Wire 48 confers the desired complex secondary configuration on embolic coil 30. The proximal end of shape wire 48 is retained by proximal bond 52. The distal end of shape wire 48 is anchored to or secured by atraumatic distal tip 38. Because shape wire 48 is constructed of Nitinol, it is highly kink resistant, and confers softness on embolic implant 30, while at the same time reliably conferring a desired secondary shape on embolic implant 30. In the alternative, a relatively thin platinum wire may be used to construct primary coil 40, also conferring softness on embolic implant 30, enhancing the safety of the device.
In an alternative embodiment (not pictured), shape wire 48 may be ground or otherwise formed so that it is of a smaller diameter at its proximal end relative to its distal end. The diameter of shape wire 48 may increase gradually or incrementally from proximal end 32 to distal end 34. The resulting embolic coil would be of a more robust or a stiffer secondary shape at the distal end and a softer coil near the proximal end. The largest shape wire diameter would be a diameter based upon the level of robustness desired at the distal end of the device.
Alternative embodiments of the invention described above are illustrated in
The embodiment illustrated in
Also secured by or anchored to proximal bond 85, and extending distally through lumen 69, is shape wire 76. Wire 76 is embedded in or otherwise bonded to proximal bond 85 near proximal end 62. Shape wire 76 is processed to impart a secondary shape on embolic implant 60. The profile of shape wire 76 may be altered to exhibit either a consistent or varied profile along its length. A larger profile shape wire will exhibit a more robust shape, and a smaller profile shape wire will exhibit a softer coil. Shape wire 76 extends distally and is anchored to distal bond 86. Distal bond 86 may be formed using similar techniques as those used to form proximal bond 85. However, in the implant 60, distal bond 86 defines a more ring-like structure than proximal bond 85. Distal bond 86 surrounds the distal end of primary coil 66.
Fiber 73 also extends distally, through lumen 69, and through a through hole of distal sphere 72. Fiber 73 is knotted to form distal knot 84 near distal end 64. Distal bond 86 prevents distal sphere 72 from entering lumen 69 at distal end 64. Both proximal bond 85 and distal bond 86 serve to maintain tension in stretch resistant member 73, and to prevent stretching and potential elongation of primary coil 66 and inner coil 68.
As mentioned above, prior to assembly of embolic implant 60, a secondary configuration is conferred upon wire 76. However, embolic implant 60 and wire 76 are constrained in a generally linear, or delivery configuration by a delivery catheter or comparable device so that embolic coil 60 may be delivered intravascularly. After delivery of embolic implant 60 to a vessel or within an aneurysm of a subject, wire 76 will revert from its linear delivery configuration to its secondary configuration (not pictured). Consequently, embolic implant 60 will also revert to its secondary configuration, such as, for example, the configuration illustrated in
Embolic implant 200 is shown in cross section in
Also extending through lumen 203 is primary shape wire 206. Each end of primary shape wire 206 extends through an elliptical hole washer 212, via apertures 213. Further, each end of primary shape wire 206 is optionally flattened or affixed to a broadened element 211 to prevent primary shape wire 206 from passing back through apertures 213. Primary shape wire 206 is most advantageously constructed from Nitinol. Primary shape wire 206 is shape set to confer a secondary shape on embolic implant 200. Coupled to primary shape wire 206 is distal support wire 208. Distal support wire 208 is linked to shape wire 206 towards the distal end 201 of embolic implant 200. In the example of
Also disposed at each end of primary coil 202 are weld joints 221. In the example of
Turning for now to proximal end 205, elliptical hole washer 212 prevents proximal constraint assembly 207 from entering lumen 203. Proximal constraint assembly accordingly helps maintain tension on fiber 204. Several structures define proximal constraint assembly 207. These structures include fiber loop 217, proximal constraint element or proximal constraint sphere 216, adhesive 218, and proximal wire 220. Fiber loop 217 is threaded through a hole in proximal constraint sphere 216. Proximal wire 220 is in turn threaded through the proximal end of loop 217. Loop 217 thereby links proximal constraint sphere 216 and proximal wire 220, and forms a mechanical lock of fiber 204 at proximal end 205. Adhesive 218 is molded or applied to secure proximal wire 220, loop 217, and proximal constraint sphere 216.
Returning now to distal end 201, fiber 204 is threaded distally through embolic implant lumen 203 and then through aperture 209 of washer 212 disposed at distal end 201. Fiber 204 is tied, knotted, or otherwise linked to distal peg 222. Distal peg 222 can be formed from stainless steel, platinum, or other similarly rigid material. Distal peg 222 and fiber 204 are embedded or otherwise anchored or bonded to the distal atraumatic tip 214, forming a mechanical lock adjacent to distal elliptical hole washer 212. Together, proximal constraint assembly 207 and distal peg 222 maintain tension on fiber 204, which thereby enables embolic implant 200 to resist stretching and elongation.
Turning now to
Embolic implant 250 has a proximal end 251 and a distal end 253. Elliptical hole washer 261 is disposed at proximal end 251 and elliptical hole washer 262 is disposed at distal end 253. Embolic implant 250 includes a primary coil 252 that is shape set during the manufacturing process to impart a secondary, deployed configuration on embolic implant 250. Primary coil 252 surrounds lumen 254. Disposed within lumen 254 is fiber 258. In a fashion similar to that described in relation to
Also disposed within lumen 254 is distal support wire 256. Distal support wire 256 renders the secondary configuration of embolic implant 250 more robust in the distal region in which distal support wire 256 lies. (Embolic implant 250 is more softly shaped near its proximal end 251.) Distal support wire 256 is attached to fiber 258 at bond 260. Distal support wire 256 extends at its distal end through aperture 263 of elliptical hole washer 262. The distal end of distal support wire 256 is optionally flattened to form a broadened element 280, or attached to a broadened element 280, to mechanically lock distal support wire 256 to elliptical hole washer 262.
Weld joint 264 is constructed at proximal end 251 in a fashion similar to that described above, and atraumatic tip 275 is formed from reflowed or molded polymer, adhesive, or a combination thereof. Weld joint 264 anchors primary coil 252 and elliptical hole washer 261 at proximal end 251. At distal end 253, weld joint 267 similarly bonds primary coil 252 and elliptical hole washer 262. A molded or reflowed polymer, adhesive or comparable material forms atraumatic tip 277.
Proximal constraint assembly 265 is similar to the proximal constraint assembly described above in relation to
As mentioned above, embolic implant 250 can be shape set to revert to a secondary configuration such as the configuration illustrated in
Turning now to
Proximal segment 302 has a secondary (or deployed) configuration, outside of a vessel that is helical. Alternatively, a proximal segment may have a secondary configuration that is complex, similar to the secondary configuration of distal segment 304, described in more detail below. In yet another alternative embodiment, a proximal segment according to the invention may have a straight or linear configuration. Though a wide range of outer diameters of the helix of proximal segment 302 are within the scope of the invention, in the example illustrated here, the outer diameter of proximal segment 302 is approximately 2-30 mm. In a preferable embodiment, the outer diameter of proximal segment 302 is less than the outer diameter of distal segment 304, when both proximal segment 302 and distal segment 304 are in their secondary configurations. Techniques for forming the secondary configuration of proximal segment 302 are known in the art, and include, for example, wrapping the shape wire disposed within proximal segment 302 around a mandrel and heat treating the segment so that it will return via shape memory behavior to the helical shape. Alternative techniques for achieving the shape memory objective are within the scope of the invention.
Implant 300 also has a distal segment 304, as mentioned above. Distal segment 304 also includes, disposed within its interior and therefore not visible in
In addition, as can be viewed in
In addition to having a very different secondary shape than proximal segment 302, distal segment 304 also has a larger outside profile or outer diameter than proximal segment 302. For example, in the embodiment illustrated in
The combination of both this larger outer diameter, the concentration of material at the outer edges of the shape, and the stiffer internal wire of distal segment 304 cause distal segment 304 to function much like an “anchor” for implant 300 within a vessel. In other words, distal segment 304 exerts some outward radial force against a vessel wall when implant 300 is deployed within a vessel. And, when deployed within a blood vessel of a subject, blood flow may carry proximal segment into the “interior” or distal segment 304, filling distal segment 304, and effectively preventing further blood flow through implant 300. In this respect, implant 300 effectively has an “anchor” segment and a “filler” segment, resulting in a soft, well packed embolic implant.
Turning now to
Embolic implant 400 is shown in cross section in
As mentioned above, primary shape wire 406 extends essentially the length of embolic implant 400. Each end of shape wire 406 extends through an elliptical hole washer 412, via apertures 413. Elliptical hole washers 412 are disposed at each end of primary coil 402. Also disposed at each end of primary coil 402 is a molded polymer or adhesive 421, each of which secures elliptical hole washers 412 to primary coil 402 and fiber 404, and forms atraumatic tips 414. Both proximal end 405 and distal end 401 have atraumatic tips 414.
Several structures define proximal constraint assembly 407. As mentioned above, fiber 404 extends beyond proximal end 405. Fiber 404 is looped back onto itself to form loop 417. After forming loop 417, fiber 404 extends back into lumen 403, and is secured to itself via knot 415. Loop 417 links proximal constraint sphere 416 and proximal wire 420. Adhesive 418 is molded or applied to secure proximal wire 420, loop 417, and proximal constraint sphere 416. Elliptical hole washer 412 and adhesive 421 prevent proximal constraint sphere 416 from entering lumen 403.
Extending distally through lumen 403, fiber 404 is tied, knotted, or otherwise linked to distal peg 422. Distal peg 422 and fiber 404 are embedded or otherwise anchored to the distal atraumatic tip 414. Together, proximal constraint assembly 407 and distal peg 422 maintain tension on fiber 404, which thereby enables embolic implant 400 to resist stretching and plastic deformation.
Unlike the embodiment of
The foregoing examples are not intended to limit the scope of the invention. All modifications, equivalents and alternatives are within the scope of the invention. As an example, a proximal constraint element or a distal constraint element according to the invention need not be a sphere, but may be a disc, a block, a tear drop, or of any suitable alternative shape.
Claims
1-39. (canceled)
40. An embolic implant comprising:
- a proximal end and a distal end;
- a primary coil configured to occlude blood flow in an implanted state, the primary coil comprising a lumen extending through said primary coil;
- a proximal constraint assembly disposed at said proximal end; and
- a distal assembly disposed at said distal end;
- a stretch resistant fiber disposed in said lumen and coupled to the proximal constraint assembly and the distal assembly to prevent elongation of the primary coil; and
- a shape memory filament extending through the lumen, wherein said shape memory filament comprises a first, constrained linear configuration and a second configuration that imparts a complex shape on the embolic implant.
41. The embolic implant according to claim 40, wherein said implant further comprises a jacket over the primary coil.
42. The embolic implant according to claim 41, wherein the jacket wraps or encases over the primary coil.
43. The embolic implant according to claim 42, wherein the jacket is constructed from a thrombogenic material.
44. The embolic implant according to claim 43, wherein the thrombogenic material comprises of polyester, polypropylene, or silk.
45. The embolic implant according to claim 43, wherein the thrombogenic material comprises of a monofilament fiber or multi-filament fibers.
46. The embolic implant according to claim 45, wherein the jacket is constructed by wrapping, winding, braiding, threading, or arranging the monofilament fiber or multi-filament fibers in engagement with the primary coil.
47. The embolic implant according to claim 41, wherein the jacket is a sleeve-like structure that is placed or applied directly over the primary coil.
48. The embolic implant according claim 40, wherein said implant further comprises a second coil disposed in said lumen.
49. The embolic implant according to claim 48, wherein said second coil comprises shape memory material, and said second coil comprises a first, constrained linear configuration and a second configuration that is helical, J-shaped, spherical, complex, or a segmented combination of shapes.
50. The embolic implant according to claim 40, said implant further comprising a proximal bond disposed at the proximal end, wherein said proximal bond is affixed to said primary coil, said shape memory filament, or both.
51. The embolic implant according to claim 40, wherein said implant further comprises an annular distal bond affixed to the distal end of said primary coil.
52. The embolic implant according to claim 40, wherein said stretch resistant fiber comprises a first proximal knot, said proximal constraint assembly includes a proximal constraint element configured to be releaseably retained by a delivery device, wherein said proximal constraint element comprises a through hole and said stretch resistant fiber is disposed through said through hole.
53. The embolic implant according to claim 40, the implant further comprising a distal tip disposed at the distal end of the primary coil.
54. The embolic implant according to claim 53, wherein said distal tip comprises a polymer, or an adhesive, or both, said stretch resistant fiber is knotted to form a distal knot, and said distal knot is embedded in said polymer or said adhesive or both.
55. The embolic implant according to claim 54, said implant further comprising a tube segment having a lumen and disposed at said distal end, wherein said stretch resistant fiber is disposed through said lumen, said distal knot is disposed distal to said tube segment, and said tube segment and said distal knot are embedded in said polymer or said adhesive or both.
56. The embolic implant according to claim 40, said implant further comprising a distal tip disposed at the distal end of said primary coil, wherein said distal tip comprises a polymer, or an adhesive or both, said stretch resistant fiber is knotted to form a distal knot, and said distal knot and a distal constraint element are embedded in said polymer or said adhesive or both.
57. The embolic implant according to claim 40 wherein said proximal constraint assembly comprises a proximal constraint element having a distal aperture, said stretch resistant fiber engages said distal aperture.
58. The embolic implant according to claim 40 wherein said shape memory filament comprises a proximal end, a distal end and a variable diameter, and said variable diameter varies from a lesser diameter near said proximal end to a greater diameter near said distal end.
Type: Application
Filed: Dec 6, 2021
Publication Date: Mar 24, 2022
Inventors: Alexander Plagge Rabkin (San Francisco, CA), Stephen Pons (Alameda, CA), Delilah Hui (American Canyon, CA)
Application Number: 17/543,179