The present invention provides a bileaflet heart valve that has a central flow hemodynamic configuration similar to the human aortic valve. Further, the present invention provides a bileaflet heart valve that successfully removes the incidence of thrombosis. This design minimizes the mechanical resistance against leaflet movement and allows for a greater washing effect to minimize thrombosis.

Various temporary or removable valve devices having an expandable frame comprising a flexible material and a membrane attached to the expandable frame, wherein the temporary valve device is movable into an expanded configuration for deployment of the device in a target vascular area and further is movable into a collapsed configuration for both delivery of the device to the target vascular area and for removal of the device from the target vascular area.

A prosthetic heart valve including a valve housing configured to be positioned adjacent to a heart valve annulus, one or more flaps moveably coupled to the valve housing, a passage defined by an inner surface of at least one of the valve housing and the one or more flaps, wherein the passage is configured to facilitate blood flow therethrough along a longitudinal axis thereof, from an inflow side to an outflow side of the valve, one or more openings through the inner surface located such that at an open position of the heart valve, a portion of the blood flow flowing along the longitudinal axis of the passage is redirected from the passage through the one or more openings, wherein the direction of the redirected blood flow has a component that is normal to the longitudinal axis of the passage, thereby mitigating stagnation of the blood flow and thus mitigating a risk of blood clots formation.

An implantable prosthetic device such as might be used to treat poor function of a diseased heart valve in a medical patient includes a body portion and an anchor portion including a plurality of paddles. Clasps attached to the paddles include fixed arms and moveable arms operable to secure the device to the patient's native valve leaflets.

Described herein is a prosthetic valve device having an optimized valve component for durability and functionality of the collapsible leaflets. Specially designed commissures contribute to the optimization along with identified parameters. In other embodiments, the invention is a frame formed from a unique cutting pattern.

An implantable prosthetic device such as might be used to treat poor function of a diseased heart valve in a medical patient includes a body portion and an anchor portion including a plurality of paddles. Clasps attached to the paddles include fixed arms and moveable arms operable to secure the device to the patient's native valve leaflets.

A prosthetic venous valve device is disclosed and described, having a valve base including a cylindrical shape with a lumen configured for axial blood flow, the valve base further including an anterograde end and a retrograde end, a pair of flexure pivots coupled to opposite sides of the valve base at the anterograde end, and a pair of leaflets opposingly positioned with respect to one another and each pivotally coupled to one of the pair of flexure pivots, the pair of leaflets being separated from one another in a default open position, wherein the pair of leaflets are structurally configured to pivot from the default open position toward one another to close the prosthetic venous valve to limit retrograde venous blood flow under normal physiologic venous conditions.

A mechanical prosthetic heart valve having a ring, multiple hinges, and multiple leaflets. The hinges are attached to the ring and are evenly spaced from one another along the inner circumference of the ring. Each leaflet is rotably attached to a hinge by an opening located in the center of the lower portion of the leaflets. The ring can include multiple protrusions located along the inner circumference of the ring. The protrusions of the ring limit the opening angle of the leaflets. By limiting the opening angle of the leaflets, wear and tear of the hinges and leaflets, as well as the probability of malfunction of the mechanical prosthetic heart valve are reduced. In addition, limiting the opening angle of the leaflets may increase the opening and closing speed of the leaflets, thus improving performance of the mechanical prosthetic heart valve when the patient is experiencing an elevated cardiac frequency.

Prosthetic heart valve devices for percutaneous replacement of native heart valves and associated systems and method are disclosed herein. A prosthetic heart valve device configured in accordance with a particular embodiment of the present technology can include an expandable support having an outer surface and configured for placement between leaflets of the native valve. The device can also include a plurality of asymmetrically arranged arms coupled to the expandable support and configured to receive the leaflets of the native valve between the arms and the outer surface. In some embodiments, the arms can include tip portions for engaging a subannular surface of the native valve.

A method for implanting a replacement heart valve within a diseased valve includes accessing a patient's heart by piercing a myocardium, advancing a guidewire into the patient's heart, and installing an access device in a wall of the heart. The access device preferably has at least one valve mechanism. A valve delivery device is advanced over the guidewire and through the access device. The valve delivery device has a replacement heart valve disposed along a distal end portion thereof. The replacement heart valve preferably includes an outer support structure and a leaflet valve disposed within the outer support structure. The replacement heart valve is radially expanded within the diseased valve. During implantation, the outer support structure conforms to a diameter of the diseased valve and the leaflet valve expands to a fixed size having a diameter smaller than the diameter of the diseased valve.