ENDOVASCULAR PROSTHETIC HEART VALVE REPLACEMENT

Abstract

A prosthetic aortic valve intended for native or valve-in-valve within bioprostheses includes an expandable support scaffold and valve leaflets disposed within an upper leaflet portion of the support scaffold. The valve leaflets within the upper portion may be located within the annulus (intravalvular), above the annulus, or above the native or prosthetic leaflets (supravalvular). The valve within a previously implanted degenerated heart valve such that a base or lower portion of the replacement valve is within the previously implanted valve and the upper portion is expanded within the aorta, the internal area of the valve can be increased and the hemodynamics of the valve improved. Alternatively, the valve may include separate upper and lower portions allowing the portions to be implanted sequentially and the length and other characteristics of the valve to be adjusted based on patient anatomy and condition.

Claims

1-27. (canceled)

28. A prosthetic aortic heart valve comprising: an expandable lower base comprising a first expandable support scaffold; and an upper valve, separate from the lower base, comprising an upper leaflet portion, a second expandable support scaffold, the second expandable support scaffold having an expandable upper leaflet structure that surrounds the upper leaflet portion, and a lower engagement region, wherein the first expandable support scaffold of the lower base portion is adapted to be expanded within a heart valve annulus, and wherein the lower engagement region of the upper valve is adapted to be expanded within the first expandable support scaffold of the lower base such that the lower engagement region securely engages the first expandable support scaffold of the lower base, and wherein the expandable upper leaflet structure is configured to be located above or within the heart valve annulus and be expanded above and outside of the lower base such that the expandable upper leaflet structure, when expanded, is wider than the first expandable support scaffold of the lower base.

29. The valve as in claim 28, wherein the first support scaffold of the lower base is covered with a material that inhibits paravalvular leakage.

30. The valve as in claim 29, wherein the material to prevent paravalvular leakage comprises polyethylene terephthalate (PETE).

31. The valve as in claim 29, wherein the material to prevent paravalvular leakage comprises polytetrafluoroethylene (PTFE) or expanded polytetrafluoroethylene (ePTFE).

32. The valve as in claim 28, wherein the first expandable support scaffold of the lower base has a generally cylindrical geometry wherein at least the lower base is sufficiently deformable to conform to non-circularities in the heart valve annulus.

33. The valve as in claim 28, wherein the upper valve has a greater hoop strength than the lower base to maintain circularity despite non-circular expansion of the lower base.

34. The valve as in claim 28, which has an expanded diameter from 17 mm to 30 mm and an axial length in the range from 20 mm to 80 mm.

35. The valve as in claim 28, wherein the lower base comprises barbs or hooks to support fixation of the first expandable support scaffold to the valve annulus.

36. The valve as in claim 28, wherein the lower engagement region of the upper valve is balloon expandable or self-expandable.

37. The valve as in claim 28, wherein the lower engagement region of the upper valve comprises a cover to inhibit paravalvular leakage.

38. A prosthetic aortic heart valve comprising: an expandable lower base comprising a first expandable support scaffold; and an upper valve, separate from the lower base, comprising an upper leaflet portion, a second expandable support scaffold, the second expandable support scaffold having an expandable upper leaflet structure that surrounds the upper leaflet portion, and a lower engagement region, wherein the first expandable support scaffold of the lower base portion is adapted to be expanded within a heart valve annulus, and wherein the lower engagement region of the upper valve is adapted to be expanded within the first expandable support scaffold of the lower base such that the lower engagement region securely engages the first expandable support scaffold of the lower base, and wherein the expandable upper leaflet structure is configured to be located and expanded above the heart valve annulus and above and outside of the lower base.

39. The valve as in claim 38, wherein the expandable upper leaflet structure, when expanded, is wider than the first expandable support scaffold.

40. The valve as in claim 38, wherein the upper valve has a greater hoop strength than the lower base to maintain circularity despite non-circular expansion of the lower base.

41. A method for implanting a prosthetic aortic valve in a native aortic valve annulus, said method comprising: providing a replacement aortic prosthetic valve comprising: a lower base comprising a first expandable support scaffold; and an upper valve, separate from the lower base, comprising an upper leaflet portion and a second expandable support scaffold, the second expandable support scaffold having an expandable upper leaflet structure that surrounds the upper leaflet portion, and a lower engagement region; positioning the replacement aortic prosthetic valve in the native aortic valve annulus so that the lower base is located within the native aortic valve annulus and the lower engagement region of the upper valve is located within the first expandable support scaffold of the lower base such that the upper valve is located within or above the native aortic valve annulus; expanding the first expandable support scaffold of the lower base such that the lower base securely engages the native aortic valve annulus; expanding the lower engagement region of the upper valve such that the lower engagement region securely engages the first expandable support scaffold of the lower base; and expanding the expandable upper leaflet structure of the upper valve, with the upper leaflet structure positioned above the native aortic valve annulus and above and outside of the lower base, such that the expandable upper leaflet structure, when expanded, is wider than the first expandable support scaffold of the lower base to increase luminal area of the replacement aortic valve.

42. The method as in claim 41, wherein the lower engagement region of the upper valve is covered to inhibit paravalvular leakage.

43. The method as in claim 41, wherein expanding the expandable upper leaflet structure of the upper valve comprises inflating a deployment balloon within the upper valve.

44. The method as in claim 41, wherein the lower base has a self-expanding tubular wall, wherein the lower base is constrained while being delivered and releases from constraint to expand and conform to the valve annulus.

45. The method as in claim 44, wherein the tubular wall comprises anchors on its outer surface which penetrate the annulus upon expansion.

46. The method as in claim 44, wherein the tubular wall comprises a superelastic metal scaffold covered with a material that inhibits paravalvular leakage.

47. The method as in claim 44, wherein the lower engagement region of the upper valve is positioned within the lower base, wherein the upper leaflet portion is balloon expandable and the lower engagement region is balloon expandable or self-expandable.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0026] FIGS. 1A and 1B illustrate a prototype replacement prosthetic valve constructed in accordance with the principles of the present invention.

[0027] FIG. 2 is a schematic illustration of the prosthetic aortic valve of FIG. 1 implanted within a degenerated prosthetic heart valve.

[0028] FIGS. 3 and 4 illustrate an implantation protocol of a replacement prosthetic heart valve in accordance with the principles of the methods of the present invention.

[0029] FIG. 5 illustrates a second embodiment of a prosthetic aortic valve constructed in accordance with the present invention comprising a lower base portion and a separate upper valve portion, where the lower base portion comprises inner and outer tubular members.

[0030] FIGS. 6A through 6D illustrate implantation of the prosthetic aortic valve of FIG. 5 in a native valve annulus after the native valve has been removed.

DETAILED DESCRIPTION OF THE INVENTION

[0031] Referring to FIGS. 1A and 1B, a replacement prosthetic valve 10 constructed in accordance with the principles of the present invention comprises a stainless steel cylindrical scaffold (stent) 12 comprising six zig-zag rings joined by aligned axial struts having prosthetic valve leaflets secured in its upper end. The scaffold design allows the support to be radially expanded and contracted without foreshortening. Thus, the length of the scaffold will remain the same throughout an implantation procedure. An exemplary length is 30 mm and the exemplary, expanded diameter is 23 mm. Leaflets and an internal Dacron sheet are secured within the scaffold and the valve commissures anchored at the top of the scaffold with stitches. Thus, the scaffold has an upper portion 14 which houses the leaflets and a lower base portion 16 which is generally free from internal structure other than the Dacron sheet lining.

[0032] Referring now to FIG. 2, positioning of the prosthetic replacement valve 10 within a degenerated prosthetic aortic valve 20 is schematically illustrated. The replacement valve 10 will be positioned such that the upper leaflet portion 14 of the valve 10 is above the upper extent of the degenerated prosthetic valve 20. Note that “upper” generally refers to the direction from the left ventricle into the aorta. The base portion 16 of the scaffold 12 is positioned within the interior of the degenerated prosthetic heart valve 20.

[0033] Referring now to FIGS. 3 and 4, a patient heart H initially has the degenerated prosthetic heart valve 20 implanted within the native aortic valve annulus AA as illustrated in FIG. 3. The degenerated prosthetic heart valve 20 typically has a limited length, typically about 1 cm, so that it does not extend significantly into the lumen of the aorta A.

[0034] Referring now to FIG. 4, the replacement prosthetic valve 10 of the present invention is introduced into the interior of the degenerated prosthetic valve 20, typically via a percutaneous route, either through the femoral, axillary, subclavian artery to the aorta or via a minimally invasive route via a trans-septal or more commonly transapical approach. Such protocols for delivering aortic valves are well described in the patent and medical literature.

[0035] Once the replacement prosthetic valve 10 has been positioned within the degenerated valve 20, the replacement valve 10 will be expanded so that the base portion 16 engages and anchors within the interior of the degenerated valve 20. The upper leaflet portion 14 will be expanded so that it opens to a greater cross-sectional area within the aorta above the degenerated prosthetic valve 20. In this way, the effective open or luminal area provided by the replacement heart prosthetic valve 10 is increased to provide improved hemodynamic performance.

[0036] A two-component prosthetic aortic valve 50 comprising two physically separate components constructed in accordance with the principles of the present invention is illustrated in FIG. 5. The prosthetic valve 50 comprises both a lower body portion 52 and a separate upper valve portion 54. The lower base portion 52 includes an inner tubular wall 56 and an outer tubular wall 58. Both the inner tubular wall and the outer tubular wall are typically in the form of expandable metal scaffolds, where the inner tubular wall 56 is balloon-expandable, i.e., is formed from a malleable material which can be expanded and reconfigured by application of an internal force of pressure, typically using a balloon similar to a stent delivery balloon. The outer tubular wall 58 is also typically in the form of a metal scaffold, but the scaffold of the outer tubular wall will typically be formed from a highly elastic material, such as a super elastic alloy, e.g., Nitinol™. The inner and outer tubes will be coupled to each other, typically being connected along their lower edges (toward the bottom of FIG. 5). The outer tubular wall 58 will typically be covered with a generally impermeable material, such as any of the graft materials listed earlier in this application. The cover will help the outer tubular wall 58 seal against the valve annulus when the prosthetic aortic valve is deployed as described below with respect to FIG. 6A through 6D. The inner tubular wall 56 will also be typically covered with a generally impermeable material, such as any of the graft materials listed earlier in this application. The lower outer tubular wall also preferably include a plurality of barbs 62 or other anchors, such as hooks, which help fix the lower tubular wall in the annulus after the wall expands therein.

[0037] The combination of a self-expanding outer wall and balloon expandable inner wall provides a number of advantages. The self-expanding outer tubular wall is particularly well suited for conforming to irregular annular geometries, such as within bicuspid aortic valves which have irregular orifice shapes. While it is particularly suited for adapting and conforming to irregular shapes, it will also be perfectly well suited for expansion within valves and valve annulus having regular geometries.

[0038] The dimensions of the lower base portion 52 can be selected to conform to different patient anatomies and for different implantation schemes. For example, the height of the inner wall of the base portion maybe made longer when supravalvular placement of the upper valve portion 54 is desired. In contrast, if intravalvular placement is desired the inner tubular wall 56 can be made much shorter. In some instances, such as for treatment of acute dissections, aortic aneurysms, or other conditions present in the ascending aorta, the length of the inner wall 56 can be made quite long.

[0039] The upper valve portion 54 comprises a single expandable scaffold 64, typically being balloon-expandable, having an upper end which holds the tricuspid valve 66 and a lower end which is surrounded by a cover 68. The balloon-expandable scaffold is desirable to maintain the circular geometry of the upper valve portion 54 as the scaffold is expanded. Moreover, the lower portion of the scaffold 64 maybe expanded by balloon simultaneously with the inner wall 56 of the lower base portion 52, allowing those two portions to be fit together very closely. However, the lower portion of the scaffold 64 may also be made of self-expanding scaffold to fit into 56 as desired. The length of the lower portion of the scaffold 64 and the cover 68 can be selected so that it can overlap with the cover 56 on the lower base portion 52. In this way, good sealing and anchorage of the valve can be achieved.

[0040] The use of the two components allows great adaptability in assembling the prosthetic aortic valve 50 for patients having different conditions and anatomies. Usually, the valve components maybe selected to provide a relatively short valve for replacement of native valves, may have an intermediate length for the repair of the previously implanted prosthetic valve, and maybe quite long when the valve is being placed for the treatment of aortic aneurysms and dissections.

[0041] The two component stent designs also allow for selection between supravalvular positioning, i.e., positioning of the valve above the native valve leaflets and/or a previously implanted prosthetic valve, or intravalvular positioning, i.e., positioning within the native valve annulus, typically for native valve replacement or above the native annulus (supra-annular).

[0042] In addition to the adaptability provided by the two-component prosthetic aortic valves of the present invention at the time of implantation, they further facilitate valve repair should they become damaged or their performance degenerate in any way. In particular, it will often be possible to remove the upper valve portion 54 from the lower base portion 52 in a valve 50 which has been implanted in a patient, even after a substantial period of time has passed. Since the outer wall portion 58 of the lower base portion 52 of the valve is firmly implanted in the valve annulus and will be anchored by tissue overgrowth over time while other portions of the valve are less firmly implanted due to stent to stent overlap and lack of tissue overgrowth, it will be possible to remove the upper portion and replace it with a new upper valve portions and procedures which are far easier than removing the entire implanted prosthetic valve.

[0043] Referring now to FIG. 6A through 6D, an exemplary protocol for delivering a two-component prosthetic aortic valve 50 into a native valve annulus NA will be described. While this description refers to the native valve annulus without presence of the valve leaflets, it will be appreciated that the implantation procedure could be performed either after excision of the native valve leaflets or with the native valve leaflets left in place.

[0044] The valve maybe initially introduced using a constraining sheath 70 which maybe introduced over the aortic arch using a conventional femoral approach, subclavian/axiallary approach or transapical approach. Transapical approach is not illustrated but functions in principle in the opposite direction from ventricular apex to aorta. A pusher 72 maybe employed to eject the prosthetic aortic valve 50 to the desired location within the native annulus NA, as shown in FIG. 6B. The self-expanding outer tubular wall 58 of the valve 50 will open upon release from constraint and engage the barb 62 into the wall of the annulus. The inner tubular wall 56 will remain less expanded (since it is a balloon expandable element) and available for mating with the upper valve portion 54, as illustrated in FIG. 6C.

[0045] The upper valve portion 54 maybe delivered in its unexpanded configuration to the previously implanted lower base portion 52, as illustrated in FIG. 6C. The lower end of the expansible scaffold 68 will be introduced through the inner tubular wall 56 until the desired axial alignment of the two portions is achieved. Note that the stent portions will typically have radiopaque markers which permit viewing an alignment of the portions under fluoroscopy in a conventional manner.

[0046] After the proper alignment of the upper valve portion 54 with the lower base portion 52 is achieved, a balloon 72 carried by catheter 74 maybe expanded to open both the scaffold portion which carries the inner valve 66 and the lower portion of the scaffold including cover 68, as illustrated in FIG. 6D. Alternatively, the lower end of the upper valve portion 68 may be released as a self expanding scaffold within the inner tubular wall 56, followed by balloon expansion of the valve portion 54. The catheter is now fully implanted and the tricuspid valve 66 capable of functioning.

[0047] While the above is a complete description of the preferred embodiments of the invention, various alternatives, modifications, and equivalents may be used. Therefore, the above description should not be taken as limiting the scope of the invention which is defined by the appended claims.