A method, system, or apparatus for stent delivery. Delivering one or more stents with a delivery tool that can include a kinetic transfer of energy to deliver one or more stents. The stents can include a modifiable stent that can change its overall shape and/or dimensions based on pre-configured design parameters. A coil stent that can engage with a vessel that surrounds the modifiable stent forming a dual stent configuration. The coil stent can also include anchor points that allow it to engage with a second vessel securing the first vessel and the second vessel together to aid in the healing process.

A vascular prosthesis for implantation at an aortic arch of a human patient includes major tubular component defining a longitudinal axis and an island graft that has a length parallel to the longitudinal axis that is greater than a width transverse to the longitudinal axis. The vascular prosthesis delivery system includes a vascular prosthesis of the invention. The vascular prosthesis can also be a hybrid vascular prosthesis, including a proximal surgical segment that can be corrugated, an endovascular stent graft segment extending distally from the surgical segment, and a collar interposed between the surgical segment and the endovascular stent graft segment. The island graft can be pleated or corrugated and can be radially raised from a surface of the major tubular component.

A prosthetic heart valve comprises an annular frame comprising a plurality of interconnected struts, wherein the frame is radially compressible and expandable between a radially compressed state and a radially expanded state. A plurality of leaflets are situated within the frame, each leaflet comprising a main body, two opposing commissure tabs arranged on opposite sides of the main body and two opposing sub-commissure tabs arranged on opposite sides of the main body. Each commissure tab of a leaflet is paired with an adjacent commissure tab of an adjacent leaflet to form a commissure that is coupled to the frame. Each sub-commissure tab is paired with an adjacent sub-commissure tab of an adjacent leaflet and connected thereto, wherein each pair of sub-commissure tabs extends radially inwardly relative to the frame.

An assembly can include a prosthetic valve and a delivery apparatus having a handle and a plurality of actuator assemblies extending from the handle. The prosthetic valve can have a plurality of posts one or more of which are configured as actuators having an axially spaced first member and second member, and a threaded rod extending through first and second members. Each actuator assembly can include a first actuation member engaging an outflow end of the prosthetic valve and having first and second support extensions, and a second actuation member extending through the first actuation member and comprising a distal end portion having an engagement portion releasably coupled to the threaded rod. The first and second support extensions can inhibit rotation of the frame relative to the one or more actuator assemblies during expansion of the prosthetic valve.

A gimbal handle assembly including: an inner gimbal and an outer gimbal that are concentrically linked and have pivot axes that are orthogonal relative to each other, a spool coupled to and rotatable around the outer gimbal, and a plurality of draw lines attached to the spool in a circumferential configuration, wherein rotation of the spool and/or rotation of the spool and the outer and inner gimbals increases or reduces tension in the draw lines. Also disclosed are a transcatheter valve delivery assembly that includes the gimbal handle assembly, a multi-lumen catheter, a sleeve attached to a distal end of the multi-lumen catheter, and a transcatheter heart valve including an expandable valve frame. Methods of delivering the transcatheter valve to a subject are described, wherein pitch and yaw orientations of the transcatheter valve can be precisely controlled with enhanced degrees of freedom.

A catheter device for implanting a medical implant includes an actuating element configured to move with a capsule of the catheter device and to be manually operated to bring the actuating element from a first state to a second state. A first and/or second stop is included in the catheter device. The first stop is configured to limit a movement of the actuating element and therewith of the capsule in a first direction, e.g. proximal direction (P), when the actuating element is in the first state. The second stop is configured to limit a movement of the actuating element and therewith of the capsule in a second direction, e.g. distal direction (D), when the actuating element is in the first state, so as to prevent pressing of the capsule against a catheter tip of the catheter device and/or against a capsule stop of the catheter device.

A stent delivery system and a method for mounting a stent (1) are disclosed. The stent delivery system includes a handle, an outer tube (52), a restraining member and delayed-release member (4) and is structurally simple and easy to use. During the release of a stent (1) from the restraining member, a proximal end of the stent (1) is always secured to the delayed-release member (4), avoiding the stent (1) from moving backward under the action of forces from the blood and thus resulting in improved positional accuracy of the release of the stent (1). Additionally, during the release of the stent (1) from the restraining member, a distal end of the stent (1) can be secured to an inner tube (51) by means of a fixed coil (32), and the proximal end of the stent (1) can remain fixed on the delayed-release member (4). This can avoid the stent (1) from moving forward or backward during the release of a middle section of the stent (1), allowing the stent (1) to be released under true accurate positional control.

An apparatus for hydraulic deployment and recapture of an implant includes a hydraulic implant uncovering mechanism and a hydraulic implant re-covering mechanism. The implant uncovering mechanism and the implant re-covering mechanism are independently actuateable with a fluid, and the implant uncovering mechanism is coupled to the implant re-covering mechanism by a flexible elongate tether.

Described are a multipurpose handles that can be incorporated into medical device delivery systems. Also described are medical devices, including medical snare devices, that can incorporate the handles or features thereof. An actuation button of the multipurpose handle can be moved longitudinally to move a device portion (e.g. snare loop) longitudinally, e.g. for deployment or retraction. The actuation button can also be rotated to rotate a device portion (e.g. snare loop). Sealing arrangements can be provided and can provide sealing functions in respect of a controlled medical device structure while the actuation button is moved longitudinally or rotated. Methods of using the handles and medical snare or other devices incorporating them are also described.

A delivery system for prosthetic heart valves are provided. The delivery system includes a flexible shaft, a distal sheath capsule configured to contain the prosthetic heart valve, an inner steerable catheter including an inner distal flex component, and an outer steerable catheter including an outer distal flex component. The inner distal flex component includes a first cut pattern and a second cut pattern distal to the first cut pattern. The outer distal flex component includes a third cut pattern. The inner steerable catheter is rotatable at least 90 degrees relative to the outer steerable catheter when the third cut pattern of the outer distal flex component is disposed over at least a portion of the first cut pattern of the inner distal flex component and each of the inner steerable catheter and the outer steerable catheter is in the flexed configuration.