A replacement heart valve system and a method of implanting a replacement heart valve in a patient. The replacement heart valve system includes a radially self-expandable tubular body and a valve including a plurality of leaflets coupled to the tubular body. The tubular body includes interconnected struts defining circumferential rows of cells, and has an outflow end and an inflow end that flares radially outward so as to have a larger outer diameter than that of the outflow end. A first row of proximal-most cells formed at the inflow end includes circumferentially adjacent cells that are disconnected from each other so as to be spaced from each other in the circumferential direction. A method of implanting the replacement heart valve includes delivering from a delivery catheter the tubular body, and expanding the tubular body such that the proximal-most cells are disposed against the native heart valve annulus.

A locking mechanism for a transcatheter delivery system is disclosed. As one example, the locking mechanism may comprise a first fixing member configured to be coupled to an introducer sheath, a second fixing member configured to be coupled to a handle of a delivery apparatus, and a locking arm configured to be removably coupled at a first end to one of the first fixing member and the second fixing member and fixedly or removably coupled at a second end to another one of the first fixing member and the second fixing member, wherein the locking arm is moveable between a first position where an axial position of the second fixing member is not fixed relative to the first fixing member via the locking arm and a second position where the axial position of the second fixing member is fixed relative to the first fixing member via the locking arm.

An implantable prosthetic device can include a radially expandable and compressible frame including an inflow end portion and an outflow end portion. The frame including a plurality of struts, and at least one expansion and locking mechanism having a first member, a second member extending at least partially into the first member, and a third member. The third member can include an engagement portion. The plurality of struts can include a first strut and a second strut pivotably coupled to one another to form an apex, the first strut having a first flange and the second strut having a second flange. When the frame is expanded, distal advancement of the third member can position the engagement member between the first and second flanges such that they engage the engagement member to resist pivoting of the first and second struts relative to one another to resist compression of the frame.

A stented valve including a stent structure including a generally tubular body portion having a first end, a second end, an interior area, a longitudinal axis, and a plurality of vertical wires extending generally parallel to the longitudinal axis around a periphery of the body portion, wherein the plurality of vertical wires includes multiple commissure wires and at least one structural wire positioned between adjacent commissure wires, and a plurality of V-shaped wire structures having a first end, a second end, and a peak between the first and second ends, wherein a first end of each V-shaped structure extends from a first vertical wire and a second end of each V-shaped structure extends from a second vertical wire that is adjacent to the first vertical wire, wherein each V-shaped structure is oriented so that its peak is facing in the same direction relative to the first and second ends of the body portion, and a valve structure including a plurality of leaflets attached to the stent structure within the tubular body portion.

A heart valve prosthesis that can be quickly and easily implanted during a surgical procedure is provided. The prosthetic valve has a base stent that is deployed at a treatment site, and a valve component configured to quickly connect to the base stent. The base stent may take the form of a self- or balloon-expandable stent that expands outward against the native valve with or without leaflet excision. The valve component has a non-expandable prosthetic valve and a self- or balloon-expandable coupling stent for attachment to the base stent, thereby fixing the position of the valve component relative to the base stent. The prosthetic valve may be a commercially available to valve with a sewing ring and the coupling stent attaches to the sewing ring. The system is particularly suited for rapid deployment of heart valves in a conventional open-heart surgical environment. A catheter-based system and method for deployment is provided.

A mitral valve system comprising a first docking component and a second valvular component that are delivered via a single delivery catheter. The first component is located distal to the second component and provides a detachable rail to allow the second component to accurately position and lock with the first component. The first component has fixation members that are activated by either by a torus balloon or via fiber that does not restrict blood flow during delivery or during fixation member activation.

A cardiac valve prosthesis including an armature for anchorage of the valve prosthesis at an implantation site. The armature defining a lumen for the passage of the blood flow and having a longitudinal axis, and a set of prosthetic valve leaflets supported by said armature and configured to move, under the action of blood flow, in a radially divaricated condition to enable the flow of blood through said lumen in a first direction, and in a radially contracted condition, in which said valve leaflets co-operate with one another and block the flow of blood through the prosthesis in the direction opposite said first direction. The armature including an annular part and a pattern of arches struts carried by said annular part, said pattern of arched struts having proximal ends connected to said annular part, and distal ends spaced axially from the proximal ends and opposite said annular part, a plurality of sets of anchoring formations configured to protrude radially outwardly of said annular part, each set being supported by a least one of said annular part and a corresponding arched strut, and a plurality of support posts, each support post being supported by adjacent arched struts, wherein the sets of anchoring formations alternate with the support posts around said longitudinal axis.

A system for fracturing a frame of a deployed prosthesis with ultrasonic vibration includes a shaft, a tip assembly, an ultrasonic electric generator, and an ultrasonic transducer. The shaft includes a proximal portion and a distal portion. The tip assembly is coupled to the distal portion of the shaft. The tip assembly includes a cutting edge. The ultrasonic transducer is electrically coupled to the ultrasonic generator. Ultrasonic vibration generated by the ultrasonic transducer is translated to the tip assembly. The cutting edge of the tip assembly is configured to focus the vibration of the tip assembly onto a frame of a deployed prosthesis to fracture the frame of the prosthesis. The ultrasonic transducer may be coupled to the proximal portion or the distal portion of the shaft.

A venous valve replacement device includes a stent with a blood flow channel and two leaflets connected to the stent, wherein one side of each leaflet is configured as a fixed edge connected with the stent, and the other side is configured as a movable edge, and wherein the movable edges of the two leaflets cooperates with each other to open or close the blood flow channel, and the movable edges of the two leaflets are provided with flaps that attach to each other in a closed configuration.

A prosthetic mitral valve system that comprises a valve dock and a prosthetic mitral valve is disclosed. The valve dock comprises clamp jaws that sandwich the native mitral valve leaflets and the native mitral valve annulus between them anchoring the prosthetic mitral valve system at or adjacent to the native mitral valve annulus. Further, a prosthetic mitral valve comprising atrial and ventricular clamp jaws and which can be implanted at or adjacent to the native mitral valve annulus without a valve dock system is disclosed. Novel methods and systems for treating mitral valve disease or malfunction by percutaneous replacement of the mitral valve (or the tricuspid valve) are disclosed.