A system including a self-expanding prosthesis configured to foreshorten during deployment thereof and a delivery device configured to percutaneously deliver the self-expanding prosthesis. The delivery device includes a handle having an actuator thereon, an outer sheath including a proximal end coupled to the handle and a pusher shaft slidingly disposed within the outer sheath. The pusher shaft has a proximal end coupled to the handle and a distal end configured to releasably couple to the self-expanding prosthesis such that the self-expanding prosthesis axially moves therewith. The inner shaft has a distal portion of the inner shaft that is configured to receive a self-expanding prosthesis thereon. The outer sheath and the pusher shaft are configured to simultaneously move in opposing axial directions via actuation of the actuator on the handle to compensate for the foreshortening of the self-expanding prosthesis during deployment.

Medical device delivery system including a catheter, handle, lock line handle, and lock line. The catheter includes a proximal end portion and a distal end portion. The handle is coupled to the proximal end portion of the catheter. The lock line handle is releasably coupled to the handle and actuatable between a lock position and an unlock position. The lock line includes a first end portion fixedly coupled to the lock line handle, a second end portion releasably coupled to the lock line handle, and an intermediate portion configured to be releasably coupled to the medical implant disposed proximate the distal end portion of the catheter. Actuating the lock line handle from the lock position toward the unlock position increases tension on the lock line, and actuating the lock line handle from the unlock position toward the lock position decreases tension on the lock line.

A prosthetic heart valve has a plurality of valve leaflets that control directional flow of blood through a heart and a stent structure having a plurality of commissure posts supporting the valve leaflets. The stent structure has a covering over the plurality of commissure posts and has a sewing ring at an inflow end of the stent structure. Each of the plurality of commissure posts has a tip and a suture loop is attached to the covering at a location adjacent to or on the tip of the commissure post. Each suture loop provides a passage for a suture to pass through between the covering and the suture loop.

The present disclosure relates to numerous delivery devices and methods for transcatheter prosthetic heart valve loading, deployment and delivery utilizing at least one suture. Disclosed delivery devices utilize improved suture routing methods and configurations that reduce suture tangling and also provide the ability to adjust the prosthetic heart valve expansion and contraction prior to the final release of the prosthetic heart valve from the delivery device.

A collapsible and expandable prosthetic atrioventricular valve may include an outer stent, an inner stent, and a plurality of prosthetic leaflets mounted within the inner stent. The outer stent may have an atrial disc, a ventricular disc, and a plurality of posts coupling the atrial disc to the ventricular disc. A plurality of connectors may extend between the inner stent and the outer stent to couple the inner stent to the outer stent. The outer stent may be devoid of metal in a space circumferentially extending between adjacent ones of the plurality of posts. The space may extending approximately one half, approximately one third, or approximately one fourth of a circumference of the outer stent.

Delivery devices and methods for delivering a stented prosthesis to a target site are disclosed. Disclosed delivery devices include a handle assembly including an actuator, an inner shaft assembly interconnected to the handle assembly, and are configured to releasably retain the stented prosthesis to the delivery device with at least one elongate tension member. The delivery devices further include a tension management device that is configured to limit the amount of tension that can be applied via the actuator to the at least one tension member. Certain embodiments are configured to apply different tension limits to different tension members that are controlled by a one or more actuators. Other various embodiments include one or more tension adjustors to selectively adjust one or more tension limits.

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 provides a delivery device including an inner shaft assembly including an inner shaft having a proximal end and a distal end and a lumen. The inner shaft further includes a spindle connected to the distal end of the inner shaft and the spindle includes a body and a side lumen offset with respect to a central axis of the spindle. The delivery device further includes a spine wire that can slide within both the lumen of the inner shaft and the side lumen of the spindle. Additional lumens and spine wires can be provided. The disclosure further includes methods of using the delivery devices of the disclosure for delivery a stented prosthesis, for example.

Prosthetic heart valves described herein can be deployed using a transcatheter delivery system and technique to interface and anchor in cooperation with the anatomical structures of a native heart valve. Some embodiments of prosthetic valves described herein include an anchor portion that couples to the anatomy near a native valve, and a valve portion that is mateable with the anchor portion. In some such embodiments, the anchor portion and/or the deployment system includes one or more prosthetic elements that temporarily augment or replace the sealing function of the native valve leaflets.

A prosthetic heart valve has a frame and a valvular structure coupled thereto. The valvular structure has multiple leaflets, with paired tabs from the leaflets forming commissure tab assemblies that couple the valvular structure to the frame. The frame is tapered with its inflow end diameter being smaller than its outflow end diameter. The valvular structure is constructed such that a flow channel formed by the leaflets is also tapered, with the inlet end cross-section being smaller than the outlet end cross-section. The commissure tab assemblies are attached to the frame with leaflet bending axes at or adjacent to the radially-inner surface of the frame. During systole, separation of blood flow induced by the tapered geometry of the flow channel generates an annular back flow region adjacent to the inner surface of the valve at the outflow end, which prevents the free edge of the leaflets from contacting the frame.