A delivery device for percutaneously delivering a stented prosthetic heart includes a sheath, a handle, and adjustment device including a fine adjustment mechanism, and an outer stability shaft. The sheath defines a lumen and is configured to compressively constrain the stented prosthetic heart valve. The handle is coupled to the proximal portion of the sheath and includes an actuator mechanism coupled to a proximal portion of the sheath that is configured to selectively move the sheath relative to the housing to release the stented prosthetic heat valve. The adjustment device is coupled to the handle and includes an adjustment lumen through which the sheath and the handle slidably extend. The outer stability shaft is coupled to the adjustment device. The fine adjustment mechanism is configured to selectively move the handle and the sheath relative to the adjustment device and the outer stability shaft.

A branched graft method includes securing a first end of a branch graft into a first conduit and subsequently moving the second end into a second conduit. The first conduit may be a branch vessel, such as a renal artery and the second conduit may be a main graft that extends over an aortic aneurysm. The branch graft may be deployed starting at an offset distance from the first end, thereby preventing the deployed portion from insertion into the first conduit and predetermining the insertion length into the target vessel. The first end may then be deployed to secure the first end to the first conduit. A branch graft may be a self-expanding stent graft having one or more ripcords, and/or a serpentine ripcord that enables non-linear deployment of the branch graft, or deployment that does not progress from one end to the opposing end.

This disclosure relates to systems and methods for compressing reversibly compressible endovascular devices for loading into delivery catheters prior to deployment in lumen of a vessel.

A stent delivery system includes a stent; a pusher catheter disposed at a proximal-end side thereof; and a collet chuck disposed at the proximal-end side of the pusher catheter. The collet chuck includes a collet disposed along an outer circumference of a guide catheter; and a chuck nut provided to be relatively advanceable and retractable with respect to the collet and into which the guide catheter is insertable, and an inner circumferential surface of the chuck nut facing a center axis of the guide catheter includes a first region tightens the collet to make the collet to approach the center axis as coming into contact with the collet while approaching the collet; and a second region being at an opposite side of the collet with respect to the first region for making an approaching amount of the collet to be smaller than that in the first region.

A braided stent having a plurality of retrieval and/or repositioning levers includes a stent body formed of a plurality of wires interbraided in a braided pattern. The repositioning and/or retrieval levers have a loop portion extending radially away from the stent body and first and second legs extending along the stent body. The levers are configured to be actuated radially inward toward the central longitudinal axis of the stent by a radially inwardly directed force to radially collapse the stent.

A braided stent having a plurality of retrieval and/or repositioning levers includes a stent body formed of a plurality of wires interbraided in a braided pattern. The repositioning and/or retrieval levers have a loop portion extending radially away from the stent body and first and second legs extending along the stent body. The levers are configured to be actuated radially inward toward the central longitudinal axis of the stent by a radially inwardly directed force to radially collapse the stent.

There is provided a system for cardiac electromagnetic/magnetic catheterization for diagnosing and treating blood vessels of a patient. The system having at least one electromagnetic intraluminal capsule able to force its way through a narrowing blood vessel, the capsule carrying a camera allowing visualization of blood vessels of a patient. There is a portable electromagnetic tip, where the tip pulls the electromagnetic capsule by electromagnetic force, and when the magnetic tip moves along a body of a patient and pulls the intraluminal electromagnetic capsule along with it towards a narrowing blood vessel visualized by the camera, so that the capsule then treats the narrowing site and clears the blood vessel from coronary plaque. In addition working capsule can replace diseased valve in any cardiac position for either temporary or permanent needs.

According to an aspect of some embodiments of the invention, there is provided a method of deploying an expandable prosthetic mitral valve in a subject, the method comprising: deploying a first component of the prosthetic mitral valve in a left atrium; deploying a second component of the prosthetic mitral valve in a left ventricle; and approximating the first and the second components so that leaflets of a native mitral valve are trapped between the first and the second components.

Embodiments of the disclosed technology provide flow diverting devices for dialysis vascular access, and methods for use therewith. According to some embodiments of the disclosed technologies, a medical device comprises: a tubular vascular stent; and a flow restrictor disposed within the tubular vascular stent. According to some embodiments of the disclosed technologies, a method comprises: providing a medical device, the medical device comprising: a tubular vascular stent, and a flow restrictor disposed within the tubular vascular stent; and deploying the medical device at a site within a vascular access of a patient. According to some embodiments of the disclosed technologies, a medical device comprises: a tubular vascular stent; one or more anchor struts formed on at least one end of the tubular stent; a flow restrictor disposed within the tubular vascular stent; and a tubular stent cover, wherein the vascular stent is disposed within the tubular stent cover.

Embodiments of the disclosed technology provide flow diverting devices for dialysis vascular access, and methods for use therewith. According to some embodiments of the disclosed technologies, a medical device comprises: a tubular vascular stent; and a flow restrictor disposed within the tubular vascular stent. According to some embodiments of the disclosed technologies, a method comprises: providing a medical device, the medical device comprising: a tubular vascular stent, and a flow restrictor disposed within the tubular vascular stent; and deploying the medical device at a site within a vascular access of a patient. According to some embodiments of the disclosed technologies, a medical device comprises: a tubular vascular stent; one or more anchor struts formed on at least one end of the tubular stent; a flow restrictor disposed within the tubular vascular stent; and a tubular stent cover, wherein the vascular stent is disposed within the tubular stent cover.