A device for compressing a stent may include a housing extending along a central longitudinal axis, a first threaded member and a second threaded member, a first iris and a second iris, and a compressor element disposed between the second iris and the second threaded member. The first iris includes a first ring extending transverse to the axis and a first plurality of arms extending from the first ring parallel to the axis. The first plurality of arms defines a first central opening and rotation of the first threaded member changes a size of the first central opening. The second iris includes a second ring extending transverse to the axis and a second plurality of arms extending from the second ring parallel to the axis. The second plurality of arms defines a second central opening and rotation of the second threaded member changes a size of the second central opening.

A prosthetic heart valve includes (a) a stent body including a generally tubular annulus region having a tubular wall and a proximal-to-distal axis, the stent body having a radially expanded condition when the stent body is implanted, (b one or more prosthetic valve elements mounted to the stent body and operative to allow blood flow in a distal direction through the annulus region but to substantially block blood flow in a proximal direction through the annulus region, (c) a cuff coupled to the stent body, and (d) one or more biasing elements connected to the stent body and to the cuff, the biasing elements being adapted to bias at least a portion of the cuff outwardly with respect to the stent body.

An anchor for a prosthetic heart valve includes a core, a first cover layer, and a second cover layer. The core includes a plurality of helical turns. One or more outflow turns of the plurality of helical turns has a diameter configured to be disposed on an outflow side of a native valve, and one or more inflow turns of the plurality of helical turns has a diameter configured to be disposed on an inflow side of a native valve. The first cover layer is disposed over and contacts the helical core, and the first cover layer includes a first material. The second cover layer is disposed over and contacts the first cover layer, and the second cover layer includes a second material, which is different than the first material.

A device for loading a prosthesis onto a delivery system includes a first housing having a central bore. One or more actuators on the first housing may be actuated radially inward to selectively compress a discrete portion of the prosthesis disposed in the central bore.

The present invention is directed toward prosthetic heart valves that include an expandable frame and a leaflet assembly mounted therein, wherein the leaflet assembly is coupled to the frame via a plurality of commissure assemblies, formed from tabs of adjacent asymmetrical leaflets secured to each other, wherein at least one of the leaflet tabs includes a vertical tab portion folded over the tab of an adjacent leaflet.

A prosthetic valve delivery apparatus can comprise a handle, a gearbox, an input torque shaft and a plurality of output torque shafts. The input torque shaft can extend distally from the handle and can have a distal end portion operatively connected to the gearbox. The output torque shafts can be operatively connected to and extend distally from the gearbox. Rotation of the input torque shaft can cause rotation of the output torque shafts via the gear box.

The present disclosure relates to implantable, mechanically expandable prosthetic devices, such as prosthetic heart valves, and to assemblies and methods for facilitating change in diameter of such prosthetic devices.

An implant includes a frame comprising a tubular body formed by a plurality of interconnected struts that are manufactured to reduce stresses and strains resulting from component interaction during chronic use. At least a portion of a longitudinal corner of one or more struts of the frame may be chamfered, rounded, or otherwise modified to distribute stresses experienced at the strut corner throughout the strut body. Chamfering and/or rounding corners along at least a portion of a strut of the frame may reduce stresses on the frame caused by interactions between the frame and other components of the implant. The implant may be manufactured by cutting (e.g., laser cutting) a plurality of struts from a tubular metal alloy, polymer, or the like forming the tubular body, and softening at least a portion of an edge of the strut by cutting, grinding, and/or micro-blasting the edges of the corner.

A transcatheter atrio-ventricular valve prosthesis for functional replacement of an atrio-ventricular heart valve in a connection channel, the prosthesis comprising a radially expandable tubular body extending along an axis, and a valve arranged within and attached to the tubular body. The tubular body is provided with an outer circumferential groove which is open to the radial outside of the tubular body, whereby the tubular body is separated by the outer circumferential groove into first and second body sections. The tubular body is provided with a first plurality of projections which extend from the first or second body section in an axial direction of the tubular body and each of which has a free end arranged to overlap the outer circumferential groove. An elongate outer member may be disposed at the exterior of the connection channel wall structure at a level of the circumferential groove.

A prosthesis delivery catheter has an inner distal capsule shaft and a distal capsule configured to house the prosthesis. An anchor catheter with an anchor hub is slidably disposed over the inner distal capsule shaft. An elbow catheter is slidably disposed over the anchor catheter, and a peg plate assembly is adjacent the anchor hub. The peg plate assembly has a plurality of protruding pegs and a plate which form a closed configuration with the pegs abutting the plate, and an open configuration where a gap is between the pegs and plate allowing release of a tether.