Various embodiments of the present invention comprise a single-chamber collapsible and expandable prosthetic valve implant device with an elevated valve section and comprising the following capabilities: (1) preservation of native valve functionality; (2) initial preservation of native valve functionality with subsequent full replacement of native valve functionality; (3) full replacement of native valve functionality; and/or (4) mitigation of the prolapsing distance of the dysfunctional leaflets by preventing the anterior excursion of the prolapsing leaflets above the upper annular surface and into the left atrial chamber in order to preserve native leaflet functionality for as long as possible. The expanded and implanted device does not extend beyond the boundaries of the subject heart chamber, e.g., the left atrium, thereby enabling the preservation of any remaining native valve functionality with subsequent full replacement of native valve functionality if and when needed.

Provided is a foldable one-way valve prosthesis has an open state allowing a fluid to pass therethrough, and a closed state, preventing or at least reducing a reverse fluid flow therethrough. Leaflets are attached to each other along their common side edges with a possibility of pivoting relative to each other about the common side edge when the leaflets are folded along their folding lines causing the short section of the downstream edge to be angled with respect to the long section thereof, so as to bring the valve prosthesis into the closed state.

A heart valve prosthesis delivery system can include a first sheath, a second sheath, a check valve, a check valve control lines, and a heart valve prosthesis carried within the first sheath or the second sheath. The check valve can be carried within the first sheath or the second sheath. The check valve has a check valve frame and a cover component, and the check valve control lines can be coupled to the check valve frame and configured to be manipulated by a physician to control release of the check valve. In use, the check valve can be configured to be deployed within the native valve structure for minimizing back flow of blood during placement of the valve prosthesis when the native valve leaflets are rendered non-functional by the presence of the delivery system.

An implant comprises a leaflet-augmentation patch, a patch anchor, and a cord. The patch comprises a flexible sheet, and a frame that supports the flexible sheet. The frame defines a spring configured to tension the cord. The cord couples the patch anchor to the patch in a manner in which anchoring the patch anchor to a first leaflet of a heart valve of a subject positions the patch to coapt with a second leaflet of the valve during ventricular systole. Other embodiments are also described.

Devices for assisting with the functioning of a tricuspid valve of a heart include a shaft, a flow optimizer, and an anchoring mechanism. A tilting mechanism can be configured to tilt the shaft relative to a central axis of the anchoring mechanism. Leaflets (e.g., multi-layer leaflets) of the flow optimizer can include a membrane and a rim, and the rim can have a higher stiffness than the membrane.

A percutaneous transseptal surgical implantation method for replacing a defective atrioventricular (AV) valve with a conical shaped prosthetic valve formed from extracellular matrix (ECM) tissue. When the method is employed to replace a native mitral valve, the method positions the prosthetic tissue valve in the mitral valve region, whereby the valve does not obstruct the outflow tract of the aortic valve and prevents the leaflets of the aortic valve from coapting.

A prosthetic heart valve includes a frame, a valve component, and an actuation mechanism. The frame has a plurality of struts interconnected by a plurality of joints and is movable between expanded and compressed configurations. The valve component is inside the frame and has a plurality of leaflets. The actuation mechanism has a first expansion element coupled to the frame at a first location and a second expansion element coupled to the frame at a second location. The actuation mechanism is configured such that moving the first expansion element and the second expansion element toward each other in a first direction results in the frame moving from the compressed configuration to the expanded configuration, and such that moving the first expansion element and the second expansion element away from each other in a second direction results in the frame moving from the expanded configuration to the compressed configuration.

A stent-valve for transcatheter implantation to replace a cardiac valve, the stent valve being compressible to a compressed state for delivery, and expandable to an operative state for implantation, the stent-valve comprising a stent, a plurality of leaflets for defining a prosthetic valve, an inner skirt, an outer skirt, and a paravalve seal for sealing against surrounding tissue. In some embodiments, the paravalve seal comprises material that swells in response to contact with blood. In some embodiments, the seal comprises a flap or pocket that is distensible in response to backpressure and/or paravalve back-flow of blood.

A prosthetic heart valve having an inflow end and an outflow end includes a collapsible and expandable stent having a plurality of commissure features, a plurality of first struts and a plurality of second struts. The plurality of first struts define a substantially cylindrical portion and the plurality of second struts have first ends attached to the cylindrical portion and free ends projecting radially outward from the cylindrical portion and configured to couple to adjacent heart tissue to anchor the stent. A collapsible and expandable valve assembly disposed within the stent has a plurality of leaflets coupled to the commissure features.

Devices for assisting with the functioning of a tricuspid valve of a heart include a shaft, a flow optimizer, and an anchoring mechanism. A tilting mechanism can be configured to tilt the shaft relative to a central axis of the anchoring mechanism. Leaflets (e.g., multi-layer leaflets) of the flow optimizer can include a membrane and a rim, and the rim can have a higher stiffness than the membrane.