Cardiac valve support structure
Cardiac valve supports and their methods of use.
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This application claims the benefit of U.S. Provisional Application No. 61/379,235, filed Sep. 1, 2010, which is incorporated herein by reference in its entirety.
BACKGROUND OF THE DISCLOSUREHeart valve regurgitation occurs when the heart leaflets do not completely close when the heart contracts. When the heart contracts, blood flows back through the improperly closed leaflets. For example, mitral valve regurgitation occurs when blood flows back through the mitral valve and into the left atrium when the ventricle contracts.
In some instances regurgitation occurs due to disease of the valve leaflets (e.g., primary, or “organic” regurgitation). Regurgitation can also be cause by dilatation of the left ventricle, which can lead to secondary dilatation of the mitral valve annulus. Dilation of the annulus spreads the mitral valve leaflets apart and creates poor tip cooptation and secondary leakage, or so-called “functional regurgitation.”
Currently, primary regurgitation is corrected by attempting to remodel the native leaflets, such as with clips, sutures, hooks, etc., to allow them to close completely when the heart contracts. When the disease is too far advanced, the entire valve needs to be replaced with a prosthesis, either mechanical or biologic. Examples include suture annuloplasty rings all the way to actual valve replacement with leaflets, wherein the suture rings are sutured to the mitral valve annulus. Annuloplasty rings, which are also sutured to the annulus, have also been used to attempt to remodel the annulus, bringing the native leaflets closer together to allow them to properly close.
Based on the success of catheter-based aortic valve replacement there is growing interest in evaluating similar technologies to replace the mitral valve non-invasively using similar types of replacement valves.
Unlike the aortic valve, however, the mitral valve annulus does not provide a good landmark for positioning a replacement mitral valve. In patients needing a replacement aortic valve, the height and width of the aortic annulus are generally increased in the presence of degenerative disease associated with calcium formation. These changes in tissue make it easier to properly secure a replacement aortic valve in place due to the reduced cross-sectional area of the aortic annulus. The degenerative changes typically found in aortic valves are not, however, present in mitral valves experiencing regurgitation, and a mitral valve annulus is therefore generally thinner than the annulus of a diseased aortic valve. The thinner mitral valve annulus makes it relatively more difficult to properly seat a replacement mitral valve in the native mitral valve annulus. The general anatomy of the mitral valve annulus also makes it more difficult to properly anchor a replacement mitral valve in place. The mitral valve annulus provides for a smoother transition from the left atrium to the left ventricle than the transition that the aortic valve annulus provides from the aorta to the left ventricle. The aortic annulus is anatomically more pronounced, providing a larger “bump” to which a replacement aortic valve can more easily be secured in place.
In general, the aortic valve annulus is smaller than the mitral valve annulus. It has been estimated that the mitral valve annulus is about 2.4 cm to about 3.2 cm in diameter, while the aortic valve annulus has been estimated to be about 1.6 cm to about 2.5 cm in diameter.
The larger mitral valve annulus makes it difficult to securely implant current percutaneously delivered valves in the native mitral position. Current replacement aortic valves are limited in the amount of radial expansion they can undergo during deployment and implantation. To provide a replacement aortic valve that has an expanded configuration such that it can be securely anchored in a mitral valve annulus would require that the collapsed delivery profile of the replacement aortic valve be increased. Increasing the collapsed delivery profile, however, would make endovascular delivery more dangerous for the patient and more difficult to navigate the vasculature with a larger diameter delivery system.
Some attempts have been made to deliver and implant a one-piece replacement mitral valve, but it is difficult to provide a device that can be collapsed down to have a sufficiently small delivery profile and still be able to be expanded and secured in place within the mitral valve via a vascular access site.
A valve support structure or anchoring device is needed that can be positioned near or within the native mitral valve and that is adapted to secure a replacement mitral valve in place.
SUMMARY OF THE DISCLOSUREOne aspect of the disclosure is a cardiac valve support adapted for endovascular delivery to a cardiac valve, comprising: a first support element with a collapsed delivery configuration and a deployed configuration; a second support element with a collapsed delivery configuration and a deployed configuration; a first bridging member extending from the first support element to the second support element, wherein the first bridging member has a delivery configuration and a deployed configuration; and a second bridging member extending from the first support element to the second support element, wherein the first bridging member has a delivery configuration and a deployed configuration, wherein the first and second bridging members extend radially inward from the first and second support elements in the deployed configurations.
In some embodiments the first and second bridging members extend from first and second discrete locations around the first and second support elements, and can symmetrically extend from the first and second support elements. The first and second bridging members can extend from the first and second support elements about 180 degrees from one another.
In some embodiments at least one of the first and second support elements has an annular shape.
In some embodiments the first and second bridging members each have a replacement valve engagement portion adapted to securely engage a replacement heart valve. The engagements portions can each have anchoring and/or a locking element adapted to securely lock with a portion of a replacement heart valve.
In some embodiments the first and second support elements are adapted to preferentially bend at least one location.
In some embodiments the first and second support elements each have a curved portion in their deployed configurations, wherein the curved portions are adapted to assume a tighter curved configuration in the collapsed delivery configurations.
In some embodiments the first and second bridging members are generally C-shaped in their deployed configurations.
In some embodiments the first support element has at least one coupling element adapted to reversibly couple to a delivery system. The at least one coupling element can be a threaded bore.
In some embodiments the second support element has a dimension in the deployed configuration that is larger than a dimension of the first support element in the deployed configuration with or without one or more fixation elements attached and radially engaging in cardiac tissue when needed.
One aspect of the disclosure is a system adapted for endovascular delivery to replace a mitral valve, comprising: a cardiac valve support comprising a first support element with a collapsed delivery configuration and a deployed configuration; a second support element with a collapsed delivery configuration and a deployed configuration; a first bridging member extending from the first support element to the second support element, wherein the first bridging member has a delivery configuration and a deployed configuration; and a second bridging member extending from the first support element to the second support element, wherein the first bridging member has a delivery configuration and a deployed configuration; wherein the first and second bridging members extend radially inward from the first and second support elements in the deployed configurations; and a replacement heart valve comprising an expandable anchor and a plurality of leaflets adapted to be secured to the cardiac valve support.
In some embodiments the bridging members are adapted to securingly engage the replacement heart valve.
One aspect of the disclosure is a method of replacing a patient's mitral valve, comprising: endovascularly delivering a valve support to a location near a subject's mitral valve, the valve support comprising a first support element, a second support element, and first and second bridging members extending from the first and second support elements; expanding the first support element from a collapsed configuration to a deployed configuration secured against cardiac tissue below the plane of the mitral valve annulus; expanding the bridge members from delivery configurations to deployed configurations positioned in general alignment with the coaptation points of the native mitral valve leaflets; and expanding the second support element from a collapsed configuration to a deployed configuration secured against left atrial tissue above the plane of the mitral valve annulus.
In some embodiments expanding the first support element comprises allowing the first support element to self-expand against cardiac tissue.
In some embodiments expanding each of the bridge members comprises allowing the bridge members to assume a deployed configuration in which they extend radially inward from the first and second support elements.
In some embodiments expanding the second support element against left atrial tissue comprises allowing the second support element to self-expand.
In some embodiments expanding the first support element comprises expanding the first support element towards a generally annularly shaped deployed configuration.
In some embodiments expanding the first support element comprises expanding the first support element secured against papillary muscles and chords attached to the native mitral valve, and can be done without displacing them.
In some embodiments native leaflets continue to function after expanding the second support element.
In some embodiments expanding the first support element occurs before expanding the second support element.
In some embodiments expanding the bridge members comprises allowing the bridge members to symmetrically extend from the first support element to the second support element.
In some embodiments expanding the bridge members comprises allowing the bridge members to extend from the first and second support elements about 180 degrees from one another.
In some embodiments expanding the second support element comprises expanding the second support element to the deployed configuration in which the second support element has a dimension larger than a dimension of the first support element in the deployed configuration. The second support element may have one or more fixation elements adapted to pierce into cardiac tissue.
In some embodiments the method further comprises securing a replacement mitral valve to the valve support. Securing the replacement mitral valve to the valve support can include comprise expanding the replacement mitral valve from a collapsed delivery configuration to an expanded configuration. Expanding the replacement mitral valve can include expanding the replacement mitral valve with a balloon and/or allowing the replacement mitral valve to self-expand. Securing a replacement mitral valve to the valve support can comprise securing the replacement mitral valve radially within the valve support. Securing a replacement mitral valve to the valve support can comprise locking a replacement mitral valve element with a valve support element to lock the replacement mitral valve to the valve support. The bridge members can each comprise a bridge lock element and the replacement mitral valve can comprise a plurality of lock elements such that the locking step comprises locking one of the plurality of lock elements with one of the bridge lock elements and locking a second of the plurality of lock elements with the other of the bridge lock elements.
INCORPORATION BY REFERENCEAll publications and patent applications mentioned in this specification are herein incorporated by reference to the same extent as if each individual publication or patent application was specifically and individually indicated to be incorporated by reference.
The novel features of the disclosure are set forth with particularity in the appended claims. A better understanding of the features and advantages of the present disclosure will be obtained by reference to the following detailed description that sets forth illustrative embodiments, in which the principles of the disclosure are utilized, and the accompanying drawings of which:
The disclosure is generally related to cardiac valve support structures that are adapted to be implanted near or within a native cardiac valve or native valve annulus and are adapted to provide support for a replacement heart valve. The support structures are adapted to interact with a replacement heart valve to secure it in an implanted position near or within the native valve or native valve annulus. In some embodiments the support structure is adapted to be positioned near or within the mitral valve annulus, and is adapted to interact with a subsequently delivered replacement mitral valve to secure the replacement mitral valve in place to replace the function of the native mitral valve.
The disclosure also provides for two-step endovascular implantation procedures for replacing a patient's native mitral valve. In general, a support structure is first positioned near or within a mitral valve annulus and secured in place. A replacement mitral valve is subsequently secured to the support structure, securing the replacement valve in place near or within the annulus. By implanting the support structure and replacement mitral valve in two steps, the replacement mitral valve can have a lower delivery profile because it does not have to expand as much to contact native tissue due to the presence of the support structure. This eliminates the need to have a large delivery profile replacement valve as would be required if attempting to position an aortic valve in the native mitral valve, or if attempting to position a one-piece mitral valve implant (i.e., an implant not assembled in-vivo) within the native mitral valve.
In some embodiments the first support element and the second support element are generally annular in shape in their expanded configurations (see, for example,
In the embodiment in
In the embodiment in
In some embodiments the first and second support elements and the bridge members are made from a resilient material that can be deformed into a delivery configuration yet are adapted to self-expand to an expanded configuration, with optional additional expansion of one or more components by balloon dilation. For example, the support can be made from Nitinol, relying on its superelastic properties. In some embodiments the valve support is made from a material with shape memory properties, such as nitinol, and is adapted to return to an expanded memory configuration after being heated above its transition temperature. In some embodiments in which the valve support is made from a material such as nitinol, the shape memory properties and the superelastic properties are utilized. In the embodiment in
Once the support structure is expanded and secured in place within the native mitral valve, a replacement mitral valve in a collapsed delivery configuration is advanced through the first support structure and positioned within the bridge members. Expansion of the replacement mitral valve (e.g., balloon expansion, self-expansion, etc.) not only expands the replacement mitral valve, but applies an expanding force on the bridge members, expanding them further radially outward towards the native annulus. Expansion of the replacement mitral valve causes the replacement valve to engage the bridge members and secure the replacement mitral valve to the valve support. Because the bridge members are biased towards a configuration in which they extend generally radially inward, the bridge members apply a radially inward force on the replacement mitral valve, helping to secure the replacement mitral valve in place. Further details of exemplary deployment procedures are described below.
In the embodiment shown in
In some embodiments the height of the valve support, measured from the base of the first support to the top of the second support, is about 1 cm to about 50 cm to be able to accommodate the height of the replacement heart valve, such as a stented heart valve. In some embodiments the height is greater than 50 cm. In some embodiments the height of the valve support is between about 10 cm and about 25 cm. For example, a stented heart valve in an expanded configuration can have a height of about 17.5 mm. In some embodiments, however, the height of the valve support is less than the height of the replacement heart valve. These numbers are merely exemplary and are not limiting. Additionally, the two annular support elements can have different dimensions. For example, the two support elements, if generally annular-shaped, can have different diameters. In some embodiments the first support element has a larger diameter than the second support element because the anatomical position in which it is to be placed is larger than the anatomical position in which the second support element is to be placed. In the embodiment shown in
In the embodiments described herein the support elements do not have a covering element. In some embodiments, however, one or more support elements can have a covering element such as a sealing skirt to enhance the sealing of blood flow in and around the support structure and replacement heart valve. The covering element can be any type of material that surrounds the support elements and provides the enhanced sealing functionality.
In some embodiments one or more of support structures is covered in a material such as a polyester fabric (e.g., Dacron). Alternatively or in addition to, one or more of the bridge members can be covered in a polyester fabric such as Dacron.
In the embodiments in
Access to the mitral valve or other atrioventricular valve will preferably be accomplished through the patient's vasculature percutaneously (access through the skin). Percutaneous access to a remote vasculature location is well-known in the art. Depending on the point of vascular access, the approach to the mitral valve can be antegrade and require entry into the left atrium by crossing the interatrial septum. Alternatively, approach to the mitral valve may be retrograde where the left ventricle is entered through the aortic valve. Alternatively, the mitral valve can be accessed transapically, a procedure known in the art. Additional details of an exemplary antegrade approach through the interatrial septum and other suitable access approaches can be found in the art, such as in U.S. Pat. No. 7,753,923, filed Aug. 25, 2004, the contents of which are incorporated herein by reference.
While the support structures herein are generally described as a support for replacement mitral valves, they can be delivered to a desired location to support other replacement cardiac valves, such as replacement tricuspid valves, replacement pulmonic valves, and replacement aortic valves.
In
As shown in
Referring back to
As shown in
The locations on support element 62 (and support element 58) from which bridge members 60 extend are roughly 180 degrees apart from one another, similar to the roughly 180 separation of the native leaflet coaptation points. In the expanded configuration shown in
While the support structures herein are generally described as including two bridging elements, the support structures can be have more than two bridging elements disposed in any configuration around the support structures.
Next, guiding member 56 is retracted from the patient, leaving guidewire 52, guide catheter 50, and elongate body 55 in place, as shown in
As shown in
After the replacement valve has been expanded and secured in place, balloon 70 is deflated and withdrawn, along with the guidewire, from the patient, as is shown in
While a balloon expandable replacement heart valve has been shown, the replacement heart valve can be self-expanding as well.
Once the replacement valve is secured in place within the valve support, coupling members 64 are disengaged from support element 62. In this exemplary embodiment the distal ends of coupling members 64 have threads which adapted to engage threaded bores within support element 62. Rotation of coupling members 64 causes the coupling members 64 to be unscrewed from support element 62, thereby uncoupling the coupling members 64 from support 62. Guide catheter 50 is then removed from the patient, leaving the implant in place, as shown in
As set forth above, the mitral valve can be accessed via a transapical approach, or though the apex of the heart. In such an approach, coupling members 64 would be secured to inferior support element 58 rather than superior support element 62, as shown in the embodiments herein. The coupling members 64 could still be actuated in the same manner as described herein.
In
As shown in
Once the valve support is determined to be positioned in place, guiding lumen 92 can be removed to allow for a replacement heart valve to be positioned within the valve support, an example of which is shown in
When deployed, in some embodiments the flaps are disposed above the annulus and over the side of the superior support element, which may not be extending all the way to the atrial wall. This can extend coverage of the valve support system for a few millimeters, reducing para-valvular leakage. Alternatively, in some embodiments in which the support element is larger, the flaps are urged against the atrial tissue. In this use, the flaps act as an additional seal when the valve support system is in place. The one or more flaps can therefore be a component of the valve support system that reduces para-valvular leakage and/or acts as an additional seal.
While some embodiments have been shown and described herein, it will be obvious to those skilled in the art that such embodiments are provided by way of example only. Numerous variations, changes, and substitutions will now occur to those skilled in the art without departing from the disclosure. It should be understood that various alternatives to the embodiments of the disclosure described herein may be employed in practicing the disclosure.
Claims
1. A two-step method of replacing a patient's mitral valve, comprising:
- endovascularly delivering a valve support to a location near a subject′s mitral valve, the valve support comprising a first support element, a second support element, and first and second bridging members extending from the first and second support elements, wherein said valve support is configured to have a collapsed delivery configuration and an expanded deployed configuration;
- expanding the first support element from a collapsed first support delivery configuration to a deployed first support configuration secured against cardiac tissue below the plane of the mitral valve annulus;
- expanding the bridge members from collapsed bridge delivery configurations to expanded bridge deployed configurations positioned in general alignment with the coaptation points of the native mitral valve leaflets; and
- expanding the second support element from a collapsed second support delivery configuration to an expanded second support deployed configuration secured against left atrial tissue above the plane of the mitral valve annulus;
- wherein the native valve leaflets function after said expansion of said second support element;
- and subsequently delivering a replacement mitral valve and securing said replacement mitral valve to the valve support.
2. The method of claim 1, wherein expanding the first support element comprises allowing the first support element to self-expand against cardiac tissue.
3. The method of claim 1, wherein expanding each of the bridge members comprises allowing the bridge members to assume the expanded deployed bridge configuration in which the bridge members extend radially inward from the first and second support elements.
4. The method of claim 1, wherein expanding the second support element against left atrial tissue comprises allowing the second support element to self-expand.
5. The method of claim 1, wherein expanding the first support element comprises expanding the first support element to the expanded first support deployed configuration having a generally annular shape.
6. The method of claim 1, wherein expanding the first support element comprises expanding the first support element secured against papillary tendons.
7. The method of claim 6, wherein expanding the first support element comprises expanding the first support element secured against papillary tendons without displacing the papillary tendons.
8. The method of claim 1, wherein expanding the first support element occurs before expanding the second support element.
9. The method of claim 1, wherein expanding the bridge members comprises allowing the bridge members to symmetrically extend from the first support element to the second support element.
10. The method of claim 1, wherein expanding the bridge members comprises allowing the bridge members to extend from the first and second support elements about 180 degrees from one another.
11. The method of claim 1, wherein expanding the second support element comprises expanding the second support element to the expanded second support deployed configuration in which the second support element has a dimension larger than a dimension of the first support element in the expanded first support deployed configuration.
12. The method of claim 1, wherein securing the replacement mitral valve to the valve support comprises expanding the replacement mitral valve from a collapsed valve delivery configuration to an expanded valve deployed configuration.
13. The method of claim 12, wherein expanding the replacement mitral valve comprises expanding the replacement mitral valve with a balloon.
14. The method of claim 12, wherein expanding the replacement mitral valve comprises allowing the replacement mitral valve to self-expand.
15. The method of claim 1, wherein securing the replacement mitral valve to the valve support comprises securing the replacement mitral valve radially within the valve support.
16. The method of claim 1, wherein securing the replacement mitral valve to the valve support comprises locking a replacement mitral valve element with a valve support element to lock the replacement mitral valve to the valve support.
17. The method of claim 16, wherein the bridge members each comprise a bridge lock element and the replacement mitral valve comprises a plurality of lock elements, and the locking step comprises locking one of the plurality of lock elements with one of the bridge lock elements and locking a second of the plurality of lock elements with the other of the bridge lock elements.
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Type: Grant
Filed: Sep 1, 2011
Date of Patent: Feb 23, 2016
Patent Publication Number: 20120059458
Assignee: MVALVE TECHNOLOGIES LTD. (Herzliya)
Inventors: Maurice Buchbinder (San Diego, CA), Julie A. Logan (La Jolla, CA)
Primary Examiner: Yashita Sharma
Assistant Examiner: Rebecca Preston
Application Number: 13/224,124
International Classification: A61F 2/24 (20060101);