Embodiments of a leaflet clip device and method of reducing regurgitation through a native heart valve are disclosed. A leaflet clip device can include an elongated clipping member having a first end portion and a second end portion and a tensioning mechanism coupled to the clipping member. The leaflet clip device can further include one or more tensioning members disposed within a lumen of the clipping member, wherein the one or more tensioning members are operatively connected to the tensioning mechanism to transform the clipping member from a delivery configuration to an implantation configuration.

Devices and methods are disclosed for the treatment or repair of regurgitant cardiac valves, such as a mitral valve. An annuloplasty device can be placed in the coronary sinus to reshape the mitral valve and reduce mitral valve regurgitation. A protective device can be placed between the annuloplasty device and an underlying coronary artery to inhibit compression of the underlying coronary artery by the annuloplasty device in the coronary sinus. In addition, the protective device can inhibit compression of the coronary artery from inside the heart, such as from a prosthetic mitral valve that exerts radially outward pressure toward the coronary artery. The annuloplasty device can also create an artificial inner ridge or retaining feature projecting into the native mitral valve region to help secure a prosthetic mitral valve.

Methods of delivering a prosthetic aortic heart valve are disclosed. The disclosed methods include loading a prosthetic aortic valve in a collapsed configuration into a delivery sheath so that a selected point on the prosthetic valve is rotationally aligned relative to a long axis of the delivery sheath with a selected radiopaque marker on the delivery sheath, while under fluoroscopic imaging, rotating the delivery sheath about its long axis to align a selected radiopaque marker on the delivery sheath with the selected point on the native aortic valve in a fluoroscopic imaging plane, thereby establishing a desired orientation of the prosthetic aortic valve with respect to the native aortic valve in which the prosthetic valve commissures are rotationally aligned with commissures of the native aortic valve, further advancing the delivery sheath along its long axis until the prosthetic aortic valve is disposed inside the native aortic valve, and deploying the prosthetic aortic valve into an implanted state inside the native aortic valve with the prosthetic aortic valve aligned in the desired orientation with respect to the native aortic valve.

An illustrative stent may comprise an elongated tubular member having a first end and a second end and an intermediate region disposed therebetween. The elongated tubular member configured to move between a collapsed configuration and an expanded configuration. The elongated tubular member may comprise at least one twisted filament, such as a knitted filament having a plurality of twisted knit stitches with intermediate rung portions extending between adjacent twisted knit stitches, or a plurality of helical filaments twisted with a plurality of longitudinal filaments.

A surgical prosthetic heart valve has a supporting structure and a plurality of leaflets, the supporting structure generally having an annular shape with a blood flow channel defined in the annular shape and having opposite inflow and outflow sides along an axial direction of the annular shape, the plurality of leaflets connected to the supporting structure to control the blood flow channel to open or close. The supporting structure includes a first annular band and a second annular band, both of which are provided with deformable sections spaced from each other in the circumferential direction for allowing diameter expansion of the respective annular bands. The surgical heart valve achieves the diameter expansion of the annular bands through the deformable sections, thereby addressing the problem of postoperative variation in a valve-in-valve operations.

An exemplary valve repair device for repairing a native valve of a patient includes a coaption element, a pair of paddles, and barb portions. The barb portions extend directly from at least one of the coaption element and the pair of paddles.

Methods of delivering a prosthetic aortic heart valve are disclosed. The disclosed methods include loading a prosthetic aortic valve in a collapsed configuration into a delivery sheath so that a selected point on the prosthetic valve is rotationally aligned relative to a long axis of the delivery sheath with a selected radiopaque marker on the delivery sheath, while under fluoroscopic imaging, rotating the delivery sheath about its long axis to align a selected radiopaque marker on the delivery sheath with the selected point on the native aortic valve in a fluoroscopic imaging plane, thereby establishing a desired orientation of the prosthetic aortic valve with respect to the native aortic valve in which the prosthetic valve commissures are rotationally aligned with commissures of the native aortic valve, further advancing the delivery sheath along its long axis until the prosthetic aortic valve is disposed inside the native aortic valve, and deploying the prosthetic aortic valve into an implanted state inside the native aortic valve with the prosthetic aortic valve aligned in the desired orientation with respect to the native aortic valve.

A stented valve having at least one leaflet made of pericardium or other material having a relatively thin profile at the annulus. The leaflets are attached via chords to a stent frame, where the chords are positioned to mimic the native valve anatomy and functionality. In particular, the valves of one exemplary embodiment of the invention are sized to replace a mitral valve and therefore the chords are arranged to prevent prolapse of the leaflets into the atrium. The stented valve has a relatively short height at its annulus due to the positioning of the chords. In addition, the stented valve is capable of being crimped to a small enough size that it can be delivered to the implantation site via transcatheter delivery systems and methods.

An implantable device includes an adjustable spacer and at least one anchor. The adjustable spacer is configured to be positioned between native heart valve leaflets to reduce regurgitation therebetween. The adjustable spacer can comprise a first side and a second side opposite the first side. Each side can be adjustable between a first width and a second width. Each side can be independently moved between the first width and the second width. The adjustable spacer can be made from a sponge material.

Methods of delivering a prosthetic aortic heart valve are disclosed. The disclosed methods include loading a prosthetic aortic valve in a collapsed configuration into a delivery sheath so that a selected point on the prosthetic valve is rotationally aligned relative to a long axis of the delivery sheath with a selected radiopaque marker on the delivery sheath, while under fluoroscopic imaging, rotating the delivery sheath about its long axis to align a selected radiopaque marker on the delivery sheath with the selected point on the native aortic valve in a fluoroscopic imaging plane, thereby establishing a desired orientation of the prosthetic aortic valve with respect to the native aortic valve in which the prosthetic valve commissures are rotationally aligned with commissures of the native aortic valve, further advancing the delivery sheath along its long axis until the prosthetic aortic valve is disposed inside the native aortic valve, and deploying the prosthetic aortic valve into an implanted state inside the native aortic valve with the prosthetic aortic valve aligned in the desired orientation with respect to the native aortic valve.