Patent Application
20170354500
The heart receives oxygenated blood from the pulmonary veins into the left atrium. The left atrium is separated from the left ventricle by the mitral valve (also called the left atrioventricular valve, or the bicuspid valve). During ventricular diastole blood passes through the mitral valve into the left ventricle. During ventricular systole the ventricular muscles contract forcing blood through the aortic valve and out of the heart. The mitral valve must withstand the pressures created during ventricular systole to prevent oxygenated blood from traveling back into the left atrium. The Chordae tendineae prevent prolapse of the mitral valve leaflets by pulling on the leaflets of the mitral valve, holding them in a closed position.
In some instances, for example as a result of disease or trauma, the mitral valve is not able to prevent the backflow of blood from the left ventricle into the left atrium during systole. One cause of mitral regurgitation (MR) is increased leaflet motion, otherwise known as leaflet prolapse. The increased leaflet motion can be due to degeneration of the valve tissue, and/or degeneration or rupture of the chordae tendineae. Leaflet prolapse prevents coaptation of the anterior and posterior leaflet by allowing one or more of the leaflets to extend above the annular plane. A need therefore exists for systems and methods for treating mitral prolapse.
In certain aspects the present disclosure provides unique medical devices that can effectively correct mitral valve prolapse without requiring surgical repair or replacement of the anatomical valve. In accordance with some forms of the invention such medical devices are configured to extend between the leaflets of a valve to provide a leaflet contact surface. Accordingly, in one embodiment the present disclosure provides a cardiac valve implant for preventing leaflet regurgitation in a mitral valve, the implant comprising: a leaflet contact member and a brace member. In certain embodiments the leaflet contact member comprises a frame member having a curved portion that is configured to extend into a ventricle upon implantation and is engageable with at least one of the valve leaflets. In some forms the brace member is attached to the leaflet contact member and is configured to extend into the atrium and contact patient tissue, thus securing the leaflet contact member between the leaflets within the valve. In accordance with certain inventive variants the cardiac valve implant further comprises a compliant material secured to the frame member forming a leaflet contact surface which is configured to be engageable with one or more leaflets.
In another embodiment, the disclosure provides a cardiac valve implant for preventing leaflet prolapse in a mitral valve comprising: a frame member having a curved central portion between a first side portion, and a second side portion, the first side portion having a first attachment region, and the second side portion having a second attachment region. In some forms the first attachment region and the second attachment region are securable to patient tissue. In certain embodiments, the curved central portion is configured to extend into the ventricle and is engageable with at least one of the first leaflet or the second leaflet during ventricular systole. In accordance with certain inventive variants the cardiac valve implant further comprises a compliant material secured to the frame member forming a leaflet contact surface which is configured to be engageable with one or more leaflets.
In another embodiment, the disclosure provides a method for treating a mal-functioning mitral valve. In some forms, the disclosed method comprises implanting a cardiac valve implant between the first leaflet and the second leaflet, the cardiac valve implant comprising a frame member having a curved central portion. In some forms the cardiac valve implant has one or more attachment regions for securement to patient tissue. In some forms the cardiac valve implant has one or more brace members configured to extend into the atrium and contact patient tissue to secure the valve implant between the valve leaflets.
In another embodiment, the disclosure provides a method of forming a cardiac valve implant, the method comprising attaching a compliant material to a frame member, wherein the frame member comprises a generally linear shape-memory material and wherein attachment of the compliant material causes the formation of a curve within the frame member.
Additional embodiments as well as features and advantages of embodiments of the invention, will be apparent from the description herein.
For the purpose of promoting an understanding of the principles of the invention, reference will now be made to the embodiments illustrated in the drawings and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended. Any alterations and further modifications in the described embodiments, and any further applications of the principles of the invention as described herein are contemplated as would normally occur to one skilled in the art to which the invention relates. Though some embodiments of the invention are shown in great detail, it will be apparent to those skilled in the relevant art that some features that are not relevant to the present invention may not be shown for the sake of clarity. Additionally it is to be understood that the drawings are schematic and are not to scale. Instead they are meant to facilitate the understanding of the disclosed invention.
Referring to
In certain embodiments, the present disclosure provides a device which may be placed within the mitral valve, for example between the anterior leaflet and the posterior leaflet. In some forms, the device provides a surface configured to increase friction between the two leaflets. In some forms, the device provides a surface configured to create sufficient friction between the surface and one or more leaflets such that the damaged leaflet cannot prolapse into the atria, thus preventing mitral regurgitation (MR). In use, the device is placed within the mitral valve with a central portion of the device extending into the left ventricle; this portion provides a surface for contact with the anterior leaflet and/or the posterior leaflet. In some forms, the device is anchored within the atrium with a portion extending into the ventricle.
In some modes of practicing the invention, the cardiac valve implant comprises a frame member. In certain embodiments, the frame member comprises a central portion between a first side portion and a second side portion. In some forms, the central portion of the cardiac valve implant is curved forming a curvilinear structure such that upon implantation the central portion is configured to extend into the ventricle. In certain embodiments the central portion may comprise a single curve such as the embodiment shown in
In certain beneficial embodiments the frame member is configured to contact the valve leaflet(s) at or near the leaflet edge or periphery. Such a configuration allows for improved coaptation and diminishes stress on the leaflet. It is also envisioned that the frame may be configured to contact the edge of the leaflet at a desired point and a more central portion of the leaflet at another point.
In certain embodiments, the frame member comprises a single piece of material which has been formed into a desired shape. However, it is envisioned that a suitable frame member may be formed from multiple subunits. The frame member may comprise a variety of materials and various percentages and/or combinations of materials. For example, the frame member may comprise a shape memory material such as a nickel titanium alloy such as nitinol. In some forms, the frame member may be compressed into a first condition for loading into a delivery device and is expandable to a second condition suitable for implantation. Other suitable materials for use in constructing the frame member include titanium, stainless steel, tungsten, nitinol, and/or a stiff polymer although any material known to one skilled in the art to be suitable for medical implantation may be used. In some forms, the frame member may be coated with material, for example a drug or bioactive component configured to prevent or promote coagulation or endothelialization after implantation or an electrically insulating material. In embodiments comprising a filament, diameters of about 0.004 inches to about 0.050 inches, more preferably about 0.008 inches to about 0.025 inches.
Frame member size can be variable depending on valve size of the intended application. However, as the disclosed cardiac implant has a certain level of flexibility certain sizes may be designed to fit more than one size of valve, and specific sizing to each individual valve may not be required. Regardless of cardiac implant size, the lengths of first and second side sections should enable center portion and/or leaflet contact surface to be in contact with at least one leaflet after the frame member is implanted inside of a valve.
In accordance with certain inventive variants, the frame member of the present disclosure includes a first attachment region and/or a second attachment region. In certain embodiments, the attachment regions are configured to secure the frame member at or near fibrous tissues surrounding the valve opening, such as valve commissures, valve annulus, and/or trigones. In some forms, first attachment region and or second attachment region is(are) configured to attach directly to the commissure(s), for example the attachment regions may include grasping features such as hooks, barbs, or compression members configured to grasp patient tissue at or near the commissure. In some forms, the attachment regions are configured to accept an anchor member or the like in order to secure the frame member within the valve. Exemplary anchor members include but are not limited to: sutures, staples, and/or surgically implanted posts.
In some forms, the attachment regions are engageable with one or more anchor member(s). The anchor member(s) may be implanted prior to, concurrently, or after introduction of the frame member. In certain embodiments, the anchor members are configured for implantation into fibrous tissues surrounding the valve opening, such as valve commissures, valve annulus, and/or trigones, while also providing an engageable surface for attachment of the frame member. In accordance with certain inventive variants, the anchor members may be attached to a suture as will be described herein.
Anchor members for use in the present disclosure may be comprised of a variety of shapes and materials not limited to those illustrated or described below. In some forms, the anchor members may comprise a wire shaped into a helix, or other formation. In certain embodiments, the anchor member comprises a screw. Alternatively the anchor member may comprise a hook or hooks. In certain embodiments, the anchor member(s) comprise(s) one or more sutures. Some variants of the anchor portion(s) may be combined with a cannula for easier implantation. For example, a cannula can be designed to engage with an anchor member to torque or otherwise manipulate the anchor member. Manipulating the cannula can apply sufficient torque and pressure to anchor member to allow it to penetrate patient tissue at the desired location.
In further embodiments, the anchor portion(s) can have at least one region that has a greater width than the opening in the corresponding embodiments of attachment regions. In some aspects, a region with a relatively greater width can help prevent attachment region from dislodging from the valve.
To aid with placement of anchor portions inside of the valve some embodiments of the disclosed device can also comprise one or more receiving sutures. In some forms, a distal end of a suture can be attached to an attachment region, with a proximal end of the suture extending into a deployment catheter. Such a configuration can be utilized to allow anchor portion to be correctly positioned with attachment region. For example, in some forms the suture may be used as a guide for placing one or more anchor members at or near the attachment region(s). In some forms the anchor members may be configured with a suture receiving portion, for example a cannula configured to receive the suture, such that the anchor member can pass over the suture towards the attachment region. In an alternative embodiment the anchor portion(s) and attachment region(s) are not separate prior to implantation. For example the attachment region may comprise a threaded portion already engaged with a corresponding anchor member. In some forms, the anchor portion may contain an adaptation for preventing separation from the attachment region during implantation.
In some forms the attachment regions and/or anchor members are configured to promote tissue growth at the attachment site. For example, in certain embodiments the attachment region may further comprise a coating or section of material intended to promote tissue growth around the attachment region following implantation. The material may include but is not limited to: a metallic mesh, or extracellular matrix material (ECM), for example small intestinal submucosa (SIS). In addition, the material section, the attachment region, and/or the anchor member can a have a rough surface adapted to encourage endothelialization. In some forms the material section, the attachment region, and/or the anchor member may be coated with a bioactive substance, for example a growth factor or drug. The material section may be attached to the device in any suitable manner.
In certain embodiments, the device of the present disclosure comprises a resilient frame member. In some forms the resilient frame member is constrained when implanted within a valve such that the resilient force of the frame member secures the frame member within the valve opening. For example, as described herein the frame member of the present disclosure may be formed of shape-memory materials. In certain embodiments, upon implantation the device of the present disclosure may impart a radial force of between about 0.02 to about 1.00 lbs. The radial force of the frame member should be such that the frame member is secured within the valve opening without causing harm to surrounding tissues.
In accordance with certain inventive variants, the cardiac valve implant of the present disclosure may also include one or more brace members. As described herein a brace member is a portion of the cardiac valve implant configured to extend into the atria upon implantation and prevent dislodgement of the cardiac valve implant. In some forms a brace member is configured to prevent retrograde motion of the implant. For example, in certain embodiments one or more brace members are configured to contact patient tissue within the atrium in order to resist fluid pressure and secure the cardiac valve implant within the valve opening. In some forms the brace members are configured to conform with patient anatomy, for example to avoid entering the pulmonary veins. In certain embodiments, brace members are configured to extend into a pulmonary vein. In certain embodiments one or more brace members are configured to extend as a loop from the frame member forming an opening having a length of about 2 mm to about 50 mm, preferably about 15 mm to about 30 mm, and a width of about 2 mm to about 30 mm, preferably about 4 mm to about 20 mm.
In some forms, the entirety of the frame member, including any attachment regions and/or brace members, can be formed of single length of wire. In accordance with certain embodiments the attachment region(s) and/or brace member(s) may comprise a different material from the frame member. In other embodiments, the attachment region(s) and/or brace member(s) are formed from the same material as the rest of the frame member. In some forms, the ends of the wire forming the frame member can be shaped so as to form an attachment region and/or a brace member. For example, in some embodiments a first side of the wire can be bent into a circular loop creating a first attachment region and/or first brace member. In some modes, the first attachment region or first brace member can be bent away from the center portion at an angle to the frame member so as to allow for tissue contact at a desired location (e.g. commissure, trigone, annulus, etc.). In some embodiments a second side of the wire can be bent into a circular loop creating a second attachment region and/or second brace member. In some modes the second attachment region or second brace member can be bent away from the center portion at an angle to the frame member so as to allow for tissue contact at a desired location (e.g. commissure, trigone, annulus, etc.). In some forms, the attachment region(s) and/or brace member(s) may comprise, for example a hook, a flattened portion, or an aperture within the frame material. The second attachment region can be formed substantially similar to the first attachment region, or in certain embodiments the second attachment region may differ from the first attachment region. Similarly, additional brace member(s) can be formed substantially similar to a first brace member, or in certain embodiments the additional brace member(s) may differ from the first brace member. For example, in some forms it may be advantageous to bend the first attachment region and/or brace member differently from the second attachment region and/or brace member so as to allow for tissue contact at desired sites and or to avoid pulmonary veins. Additional configurations of the attachment regions will be apparent to one skilled in the art.
In certain embodiments, the attachment regions and/or brace members are offset from the frame member such that the attachment regions and/or brace members are in a different plane from the curvature of the frame member. In certain forms, the first attachment region and/or first brace member can be in alignment with left valve commissure and the second attachment region and/or second brace member can be in alignment with right valve commissure.
In certain inventive variants, the central portion of the frame member provides sufficient surface area so as to coapt with one or more leaflets. Modifications are envisioned to increase the surface area of the frame member available for leaflet contact. Examples of such modifications include: a serpentine central portion, a material covering, and/or varied thickness of frame member.
In some forms, the cardiac valve implant of the present disclosure further comprises a compliant material attached to the frame member. In some forms the compliant material comprises a biocompatible compliant material. In certain embodiments, a compliant material covers at least the central portion of the frame member so as to create a leaflet contact surface on the central portion of the cardiac valve implant. In certain embodiments, this compliant material is substantially two-dimensional. Suitable constructs for forming the leaflet contact surface may comprise some combination or percentage of the following: a mesh, a film, a fabric, a weave, a knit, a matrix, or a non-woven material.
Examples of materials for the compliant material are polyesters, polyethers, polyolefins, polyurethanes, fluoropolymers, polyamides, elastomers, metals, and/or biologics. In preferred embodiments the compliant material is blood-permeable. Additional materials that can be attached to frame member, will be apparent to one skilled in the art.
In accordance with certain inventive variants the compliant material is configured to restrain a resilient frame member. For example, in some forms the frame member comprises a substantially straight wire comprised of a shape memory material as discussed herein. In some forms attachment of the compliant material causes the resilient frame member to bend, creating a degree of resilient tension within the device. In certain embodiments the device is configured so that upon implantation the frame member is further constrained thus creating slack within the compliant material. As used herein the term “slack” refers to amount of constraint placed upon the compliant material. In certain embodiments the compliant material has a starting width when unconstrained, and a constrained width when deployed within a valve. The slack of the compliant material refers to the percentage difference between the starting width and the constrained width of the compliant material, e.g. (starting width-constrained width)/(starting width) %. In some forms the slack of the compliant material is between about 5 to about 50%, in more preferred forms the slack of the compliant material is between about 15%% to about 35%.
In certain embodiments, the compliant material comprises a naturally derived material. Suitable compliant materials can be provided by collagenous extracellular matrix (ECM) materials possessing biotropic properties. For example, suitable collagenous materials include ECM materials such as those comprising submucosa, renal capsule membrane, dermal collagen, dura mater, pericardium, fascia lata, serosa, peritoneum or basement membrane layers, including liver basement membrane. Suitable submucosa materials for these purposes include, for instance, intestinal submucosa including small intestinal submucosa, stomach submucosa, urinary bladder submucosa, and uterine submucosa. Collagenous matrices comprising submucosa (potentially along with other associated tissues) useful in the present invention can be obtained by harvesting such tissue sources and delaminating the submucosa-containing matrix from smooth muscle layers, mucosal layers, and/or other layers occurring in the tissue source. For additional information as to some of the materials useful in the present invention, and their isolation and treatment, reference can be made, for example, to U.S. Pat. Nos. 4,902,508, 5,554,389, 5,993,844, 6,206,931, and 6,099,567.
The compliant material may further comprise a material which is at least partially permeable to blood flow. In some forms, the compliant material is secured to the frame member and forms a planar or luminal leaflet contact surface that is engageable with at least one valve leaflet. In some embodiments, the compliant material can have sufficient flexibility to expand with the movement of the valve leaflets. Alternatively, the compliant material may provide a certain amount slack to allow the anterior leaflet to coapt with the posterior leaflet while also catching the damaged leaflet to prevent leaflet prolapse.
The compliant material may be attached to the frame member in any suitable fashion. In some modes, the compliant material is attached using a biocompatible adhesive or is heat sealed to the frame member. In certain embodiments, the compliant material is sewn to the frame member. It is also envisioned that the compliant material may comprise perforations or holes of sufficient size so as to allow the frame member to pass therethrough. Such materials include meshes and net-type materials. A similar attachment technique includes creating holes in the compliant material so as to allow the frame member to pass therethrough. In a further embodiment the frame member can have a recess that extends at least though the center portion, and can also extend through sections of first side section and/or second side section, the compliant material surface is securable inside of the recess. The recess need not be continuous around frame member, although in some forms the recess is continuous around the frame member.
The compliant material for use with the present disclosure may comprise one or more layers of material. In certain embodiments, a material with multiple layers is configured to form a pocket which can be secured around the frame member. Further, the compliant material may be secured to the frame member using a combination of any of the techniques described herein. Additional forms of attachment not expressly described will be apparent to one skilled in the art. In certain embodiments the compliant material has a height extending from a lowermost edge to an uppermost edge when attached to the frame member. In some forms the height of the compliant material is between about 5 mm to about 70 mm, preferably between about 15 mm to about 60 mm, and most preferably between about 25 mm to about 55 mm. In certain embodiments the compliant material has a width extending from a first lateral edge to a second lateral edge. In some forms the width of the compliant material is between about 5 mm to about 70 mm, preferably between about 15 mm to about 60 mm, and most preferably between about 20 mm to about 50 mm.
Turning now to a discussion of the illustrated embodiments,
The embodiment illustrated in
The embodiment illustrated in
Turning now to
In certain embodiments, the frame member has an overall arc shape similar to that of the coaptation region between the anterior and posterior leaflets of the mitral valve.
It is envisioned that cardiac valve implants as presently disclosed be sized and shaped to fit within a cardiac valve between a first and second leaflet. In some forms a cardiac valve implant may have a width, extending from a first side portion to a second side portion that is greater than the intercommisural distance. As used herein the term “intercommisural distance” refers to the linear distance between the left commissure and the right commissure. In certain embodiments the cardiac valve implant width is 5-50% larger than the intercommisural distance. In some embodiments the cardiac valve implant width is 10-30% larger than the intercommisural distance. The width of the cardiac valve implant depends on various factors including the frame material and/or the attachment of a compliant material to constrain the frame member. In some forms the width of the cardiac valve implant may be adjustable in situ, for example by adding slack or tension to the compliant material.
In order to prevent migration of the device into the ventricle during diastole, the ratio of the drag force of blood on the implant to the anchoring force of the implant must be less than 1. This securement is achieved by a balance of the drag force to the radial force of the implant. The radial force is dependent on the shape, thickness, and material of the frame member and/or brace or anchor members. The drag force is dependent on the porosity and slack of the compliant material.
In accordance with certain inventive variants a cardiac valve implant may comprise a plurality of brace members, each configured to contact patient tissue and support the leaflet contact member within the valve. For example the embodiment illustrates in
In accordance with certain embodiments the brace member and/or leaflet contact member may comprise different materials. In certain inventive variant the brace member may comprise a frame member having an increased diameter relative to that of the leaflet contact member. For example in certain embodiments the brace member may comprise a material having increased resiliency relative to the material of the leaflet contact member. Such a configuration may be desirable to secure the device within the valve while allowing for increased mobility of the leaflet contact member.
The present disclosure also contemplates methods of treatment of a patient suffering from a mal functioning cardiac valve. In some forms, the method comprises implanting a cardiac valve implant as described herein. In certain embodiments, the cardiac valve implant is delivered surgically. In accordance with certain inventive variants, the cardiac valve implant is compressed to a first state for introduction into a cannulated delivery device (e.g. catheter), and expandable to a second deployed state for insertion into the cardiac valve. In some forms, the cardiac valve implant is self-expanding. In some forms, the cardiac valve implant is manually expanded, for example by using a balloon or forceps. In some forms, the methods of treatment described herein include the step of introducing a cannulated delivery device to the atrium of the target valve. Such introduction can be accomplished for example via transseptal access gaining access to the left atrium via the right atrium, via transapical access, or the left ventricle via the aorta.
In one method of implantation cardiac valve implant can be compressed for deployment, and put inside of a catheter or other delivery device that can enter the heart. After the delivery device has entered the atrium, for example via transseptal access gaining access to the left atrium via the right atrium, the cardiac valve implant can be deployable near or in the valve annulus. In embodiments in which the cardiac valve is self-expanding the cardiac valve will return to its first uncompressed configuration without any assistance. In embodiments which are not self-expanding the valve implant can be manually expanded using an expansion member such as a balloon or forceps. An operator may further move the implant, such that first attachment region and second attachment region are near or each valve commissure respectively. Certain inventive variant include the step of implanting one or more anchor members prior to or in conjunction with placement of the cardiac valve implant. In some modes, after implantation the cardiac valve implant is anchored within the atrium with the first side section and second side section extending through the valve and into the ventricle. One embodiment of a method of implantation is illustrated in
In another illustrative embodiment, the frame member is at least partially formed of a non-shape memory metal. Here cardiac implant is compressed to a reduced profile and placed in a catheter or other deployment device. After, gaining access to the left atrium the device is deployed in or near the valve opening. After deployment, the cardiac implant is expanded to a formation that will fit correctly in the valve. Expansion device and techniques include but are not limited to, using forceps, an inflatable object like a balloon, or having sutures that can be manipulated by the operator outside of the body. Other methods of expanding the frame should be apparent to one skilled in the art.
In one exemplary embodiment first attachment region is connected to the first anchor member via a suture, the delivery device is configure to allow an operator to implant the first anchor member at a desired location. In some forms, the second attachment region is also connected to a second anchor portion via a second suture, the delivery device configured to allow an operator to implant the second anchor member at a desired location. With one or more anchor members implanted the cardiac valve implant may be introduced and delivered into position. In some forms the anchor portion(s) is(are) slidably associated with the suture(s) so as to allow the sutures to guide the cardiac valve implant into place within the valve. In a further embodiment a cannula is engaged with said first anchor portion, and a second cannula is engaged with second anchor portion. First cannula and second cannula are connected to first and second sutures respectively such that operator by manipulated suture can torque, and/or apply force to first and second anchor portions.
In certain embodiments, the cardiac valve device may be contained in a sterile packaging prior to use. Sterilization of the packaging may be achieved, for example, by irradiation, ethylene oxide gas, or any other suitable sterilization technique. The device of the present disclosure may also be present as part of a kit which may include the delivery catheter, and/or the expansion member.
1. A cardiac valve implant for preventing regurgitation in a mitral valve, the mitral valve having a fibrous annulus and leaflets including a first leaflet, and a second leaflet, the leaflets defining a coaptation region between an atrium and a ventricle, said cardiac valve implant comprising:
2. The valve implant of embodiment 1, wherein said curved central portion is configured to be engageable with at least one of the first leaflet or the second leaflet during ventricular systole
3. The valve implant of embodiment 1, wherein a compliant material is secured to the frame member forming a leaflet contact surface, said leaflet contact surface configured such that said leaflet contact surface is engageable with one or more valve leaflets.
4. The valve implant of embodiment 3, wherein said compliant material is secured to said frame member at said curved central portion.
5. The valve implant of any one of embodiments 1-4, wherein said frame member comprises a shape memory alloy, and said valve implant has a first state with a reduced profile for implantation, and a second deployed state with a larger width.
6. The valve implant of any one of embodiments 2-5, wherein said compliant material comprises a mesh, a film, a fabric, a weave, a knit, a matrix, or a non-woven material
7. The valve implant of embodiment 1, wherein said first side portion comprises a first loop and said second side portion comprises a second loop.
8. The valve implant of embodiment 1, wherein said first side portion comprises a first attachment region securable to patient tissue, and wherein said second side portion comprises a second attachment region securable to patient tissue.
9. The valve implant of embodiment 7, wherein said first loop and said second loop each have a width between 2 mm and 30 mm.
10. The valve implant of embodiment 7, wherein said first loop and said second loop each have a height between 2 mm and 50 mm.
11. The valve implant of embodiment 8, wherein said first attachment region is configured to engage a first anchor member, and said second attachment region is configured to engage a second anchor member.
12. The valve implant of embodiment 1, wherein a section of said frame member comprises a serpentine shape.
13. The valve implant of embodiment 7, wherein said first loop is formed from a first end of said frame member, and wherein said second loop is formed from a second end of said frame member.
14. The valve implant of embodiment 3, wherein said compliant material is blood permeable.
15. The valve implant of embodiment 3, wherein said compliant material has multiple layers.
16. A method for treating a mal-functioning mitral valve, the mitral valve having at least an annulus, a first leaflet, and a second leaflet, defining a coaptation region between an atrium and a ventricle, said method comprising;
17. The method of embodiment 16, further comprising the step of providing a cardiac valve implant within a cannulated delivery device, the cardiac valve implant being expandable from a first compressed state when within the delivery device to a second deployed state when outside of the delivery device.
18. The method of embodiment 17, further comprising the step of introducing the cannulated delivery device into the atrium of the patient.
19. A cardiac valve implant for preventing leaflet regurgitation in a mitral valve, the mitral valve having a fibrous annulus and leaflets including a first leaflet, and a second leaflet, the leaflets defining a coaptation region between an atrium and a ventricle, said cardiac valve implant comprising:
20. The valve implant of embodiment 19, wherein a compliant material is secured to the frame member forming a leaflet contact surface, said leaflet contact surface configured such that said leaflet contact surface is engageable with one or more valve leaflets.
21. The valve implant of any one of embodiments 1-15, 19, or 20 wherein the valve to implant is configured such that the ratio of the drag force of blood on the implant to the anchoring force of the implant is less than 1.
22. The valve implant of embodiment 20, wherein the compliant material is selected from the group consisting of: a mesh, a film, a fabric, a weave, a knit, a matrix, or a non-woven material.
23. The valve implant of embodiment 20, wherein said compliant material comprises polyesters, polyethers, polyolefins, polyurethanes, fluoropolymers, polyamides, elastomers, metals, and/or biologics.
24. The valve implant of embodiment 19, wherein said frame member has a first state with a reduced profile for implantation, and a second expanded state with a larger width.
25. The valve implant of embodiment 19, wherein said brace member comprises a first loop extending from the first side portion of said frame member and a second loop extending from the second side portion.
26. The valve implant of embodiment 25, wherein said first loop and said second loop each have a width between 2 mm and 30 mm.
27. The valve implant of embodiment 25, wherein said first loop and said second loop each have a height between 2 mm and 50 mm.
28. The valve implant of embodiment 19, wherein the frame member comprises a shape memory material.
29. A method for treating a mal-functioning mitral valve, the mitral valve having at least an annulus, a first leaflet, and second leaflet, defining a coaptation region between an atrium and a ventricle, said method comprising;
30. The method of embodiment 29, further comprising the step of providing a cardiac valve implant within a cannulated delivery device, the cardiac valve implant being expandable from a first compressed state to a second deployed state.
31. The method of embodiment 30, further comprising the step of introducing the cannulated delivery device into the atrium of the patient.
32. A method of forming a cardiac valve implant, the method comprising:
33. The method of embodiment 32, wherein the frame member comprises a wire.
34. The method of embodiment 33, wherein the wire has a diameter of between 0.004 inches to 0.050 inches.
35. The valve implant of any one of embodiments 1-15, or 19-28 wherein said frame member comprises a wire.
36. The valve implant of embodiment 35 wherein said wire has a diameter of between 0.004 inches to 0.050 inches.
37. The valve implant of embodiment 36 wherein said wire material comprises nitinol.
| Number | Date | Country | |
|---|---|---|---|
| 62347224 | Jun 2016 | US |
