An artificial valve for implantation in a mammal body, in or adjacent to a mammal blood vessel, the artificial valve comprising a casing and a closing mechanism, with at least part of said closing mechanism being a first moving part adapted to make movements relative to said casing. The movements are movements to assume a fully open and a fully closed position for opening and closing, respectively, the blood flow through said blood vessel, as well as at least one position in between said fully open and fully closed positions. The first moving part is adapted to receive energy for at least one of its movements at least in part from an energy device which is also comprised in the artificial valve and arranged to be placed external to said blood vessel.

An artificial valve for implantation in a mammal body, in or adjacent to a mammal blood vessel, the artificial valve comprising a casing and a closing mechanism, with at least part of said closing mechanism being a first moving part adapted to make movements relative to said casing. The movements are movements to assume a fully open and a fully closed position for opening and closing, respectively, the blood flow through said blood vessel, as well as at least one position in between said fully open and fully closed positions. The first moving part is adapted to receive energy for at least one of its movements at least in part from an energy device which is also comprised in the artificial valve and arranged to be placed external to said blood vessel.

A system for replacing a deficient native aortic valve includes an implantable prosthetic valve having a self-expandable frame and a valve assembly formed with three valve leaflets. The self-expandable frame includes three angularly spaced longitudinal bars of fixed length defining respective slots and a plurality of web-like constructions extending between and connected to the longitudinal bars. The valve assembly includes commissures extending outwardly through the slots where they are supported on the outside of the frame. Each leaflet includes an inlet end portion secured to the inside of the frame with stitching extending through the leaflet and around adjacent frame portions. The system also includes a restriction tube adapted for insertion into a patient's body. The prosthetic valve is capable of being crimped for insertion into the restriction tube and capable of self-expansion upon release from the restriction tube for deployment in the deficient native aortic valve.

A prosthetic heart valve includes a frame, a valve component, and a skirt. The frame has first and second end portions, a central longitudinal axis extending between the first and second end portions, and a plurality of struts interconnected by a plurality of joints. The joints comprise a rotational axis perpendicular to the longitudinal axis. The frame is movable between an expanded configuration and a compressed configuration. The struts comprise diagonal struts relative to the longitudinal axis when the frame is in the expanded configuration. The valve component has a plurality of leaflets. Adjacent leaflets are attached together and to the frame at commissures of the frame. The leaflets extend from the commissures in a triangular configuration and are attached to adjacent diagonal struts of the frame. The skirt is configured for reducing paravalvular leakage and attached to the diagonal struts of the frame to which the leaflets are attached.

A buoy system for treating cardiac valve regurgitation comprising a movable plug having atrial and ventricular ends, wherein a through-hole passes from the atrial to the ventricular end, wherein during systole, the plug travels toward a cardiac atrium, wherein during diastole, the plug travels into a cardiac ventricle; a tether having atrial and ventricular ends, wherein the tether passes through the through-hole of the moving plug, wherein the atrial end of the tether projects into an atrium, wherein the atrial end of the tether includes a cap to engage a delivery tool; at least one distal anchor located in the ventricle, wherein the distal anchor is coupled to the ventricular end of the tether, and wherein the system is percutaneously delivered and optionally recaptured via catheter and recapture tool at the cap of the tether, respectively.

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.

An implant system for capturing a regurgitant jet to effect preserving the atrioventricular pressure gradient and ventricular remodeling in a human heart including an expandable implant for positioning in the atrial/ventricular valve of the human heart and at least partially within the atrium and/or the ventricle, the expandable implant defining a first position for at least partially capturing the atrioventricular pressure gradient and regurgitant trans-valvular blood flow and associated driving forces during systole and a second position for steering flow from the atrium to the ventricle to enhance vorticular flow during diastole; a therapeutic apical base plate attachable to the apex of the heart; and a tethering conduit connected between the expandable implant and the therapeutic apical base plate assembly that transducts the energy and/or forces of captured regurgitant trans-valvular blood flow or atrioventricular pressure to the structures of the ventricle and the ventricular wall.

An implant system for improving physiological cardiac flow in a human heart is provided including an inflatable implant for positioning at least partially within an atrium, a ventricle and a atrial/ventricular valve of the human heart and defining a surface for intercepting and redirecting hemodynamic flow into the ventricle, the inflatable implant defining a surface to engage the valve; a therapeutic apical base plate assembly attachable to the apex of the heart; and a tether connected between the inflatable implant and the therapeutic apical base plate assembly. The inflatable implant and the therapeutic apical base plate assembly are configured to reshape the ventricular wall by transducting cardiac force and/or energy generated by the heart during systole and diastole when the inflatable implant is engaged with the valve and of the therapeutic apical base plate assembly is attached to the apex.

The present invention relates to an implantable apparatus and methods of use thereof for treating congestive heart failure. An apparatus of this invention may be anchored by implantation of a section of the apparatus within in a branch pulmonary artery, for example the left pulmonary artery, which then positions and anchors another section, for example a device frame section of the apparatus within the main pulmonary artery. A medical device may be attached to the anchored device frame.

An artificial valve for implantation in a mammal body, in or adjacent to a mammal blood vessel, the artificial valve comprising a casing and a closing mechanism, with at least part of said closing mechanism being a first moving part adapted to make movements relative to said casing . The movements are movements to assume a fully open and a fully closed position for opening and closing, respectively, the blood flow through said blood vessel, as well as at least one position in between said fully open and fully closed positions. The first moving part is adapted to receive energy for at least one of its movements at least in part from an energy device which is also comprised in the artificial valve and arranged to be placed external to said blood vessel.