Abstract: A method for stabilizing a cardiac valve annulus is provided. The method includes intravascularly delivering a prosthesis to a region of a cardiac valve, expanding the prosthesis to secure the prosthesis to the region of the cardiac valve, and reducing the inner diameter of the prosthesis to form the region of the cardiac valve into a predefined shape.

Abstract: A method for stabilizing a cardiac valve annulus is provided. The method includes intravascularly delivering a prosthesis to a region of a cardiac valve, expanding the prosthesis to secure the prosthesis to the region of the cardiac valve, and reducing the inner diameter of the prosthesis to form the region of the cardiac valve into a predefined shape.

Abstract: A method for stabilizing a cardiac valve annulus is provided. The method includes intravascularly delivering a prosthesis to a region of a cardiac valve, expanding the prosthesis to secure the prosthesis to the region of the cardiac valve, and reducing the inner diameter of the prosthesis to form the region of the cardiac valve into a predefined shape.

Abstract: A method for stabilizing a cardiac valve annulus is provided. The method includes intravascularly delivering a prosthesis to a region of a cardiac valve, expanding the prosthesis to secure the prosthesis to the region of the cardiac valve, and reducing the inner diameter of the prosthesis to form the region of the cardiac valve into a predefined shape.

Abstract: A method for stabilizing a cardiac valve annulus is provided. The method includes intravascularly delivering a prosthesis to a region of a cardiac valve, expanding the prosthesis to secure the prosthesis to the region of the cardiac valve, and reducing the inner diameter of the prosthesis to form the region of the cardiac valve into a predefined shape.

Abstract: A method for manufacturing a stent includes forming a stent blank from a first material, the stent blank comprising a plurality of struts and a plurality of crowns, each crown connecting at least two struts, and a plurality of slots in at least some of the plurality of struts and/or the plurality of crowns, depositing a second material over outer surfaces of the struts and the crowns and in the slots to encase the stent blank in the second material, creating at least one opening through the second material, and removing the first material to form a stent comprising the second material, the stent having a continuous lumen from one end of the stent to the other end of the stent, the continuous lumen being partitioned in portions corresponding to the locations of the slots in the stent blank. The lumen may then be filled with a therapeutic substance.

Abstract: A method for stabilizing a cardiac valve annulus is provided. The method includes intravascularly delivering a prosthesis to a region of a cardiac valve, expanding the prosthesis to secure the prosthesis to the region of the cardiac valve, and reducing the inner diameter of the prosthesis to form the region of the cardiac valve into a predefined shape.

Abstract: A prosthetic valve delivery system for percutaneously delivering and deploying a prosthetic valve within an existing valve is disclosed. The delivery system includes a stented prosthetic valve having a balloon-expandable stent portion with a prosthetic valve disposed therein and at least one self-expanding stent portion. The delivery system further includes a dual balloon catheter having a first balloon on which the stented prosthetic valve is disposed during delivery and a second balloon. Upon delivery within the existing valve, the self-expanding stent portion contacts the existing valve and the first balloon expands the balloon-expandable stent portion to a first diameter such that the stented prosthetic valve is in a first stage deployment configuration.

Abstract: A method for manufacturing a stent includes forming a stent blank from a first material, the stent blank comprising a plurality of struts and a plurality of crowns, each crown connecting at least two struts, and a plurality of slots in at least some of the plurality of struts and/or the plurality of crowns, depositing a second material over outer surfaces of the struts and the crowns and in the slots to encase the stent blank in the second material, creating at least one opening through the second material, and removing the first material to form a stent comprising the second material, the stent having a continuous lumen from one end of the stent to the other end of the stent, the continuous lumen being partitioned in portions corresponding to the locations of the slots in the stent blank. The lumen may then be filled with a therapeutic substance.

Abstract: A method for stabilizing a cardiac valve annulus is provided. The method includes intravascularly delivering a prosthesis to a region of a cardiac valve, expanding the prosthesis to secure the prosthesis to the region of the cardiac valve, and reducing the inner diameter of the prosthesis to form the region of the cardiac valve into a predefined shape.

Abstract: A catheter based system for treating mitral valve regurgitation includes a reshaping device having a body and a plurality of movable anchoring barbs attached to the body of the device. The reshaping device can be made from a biocompatible material having suitable shape memory properties. The devices of the current invention can be self expandable, balloon expandable, or a combination self expandable and balloon expandable. One embodiment of the invention includes a method for attaching a reshaping device to the annulus of a mitral valve, moving the body of the device from a fully expanded configuration to a resting configuration, and thereby reshaping the mitral valve annulus.

Abstract: A drug eluting implantable device includes an exterior surface on the device and at least one recess formed in the exterior surface. The device further include at least one sidewall protruding from the exterior surface adjacent the at least one recess defining a channel with the recess into which the drug may be loaded, the sidewall including a perpendicular portion substantially perpendicular to the exterior surface and the sidewall further including a parallel portion extending from the perpendicular portion, the parallel portion extending from the perpendicular portion at an angle greater than about 90 degrees as measured with reference to the exterior surface.

Abstract: A prosthetic valve delivery system for percutaneously delivering and deploying a prosthetic valve within an existing valve is disclosed. The delivery system includes a stented prosthetic valve having a balloon-expandable stent portion with a prosthetic valve disposed therein and at least one self-expanding stent portion. The delivery system further includes a dual balloon catheter having a first balloon on which the stented prosthetic valve is disposed during delivery and a second balloon. Upon delivery within the existing valve, the self-expanding stent portion contacts the existing valve and the first balloon expands the balloon-expandable stent portion to a first diameter such that the stented prosthetic valve is in a first stage deployment configuration.

Abstract: A method for treating a vascular condition is disclosed, the method comprising delivering a stent to a target region of a vessel, the stent including a drug polymer coating including an elution portion and a remaining portion, eluting the elution portion from the delivered stent for an elution period, heating the delivered stent after the elution period; and removing the remaining portion based on the heating.

Abstract: A prosthetic valve delivery system for percutaneously delivering and deploying a prosthetic valve within an existing valve is disclosed. The delivery system includes a stented prosthetic valve having a balloon-expandable stent portion with a prosthetic valve disposed therein and at least one self-expanding stent portion. The delivery system further includes a dual balloon catheter having a first balloon on which the stented prosthetic valve is disposed during delivery and a second balloon. Upon delivery within the existing valve, the self-expanding stent portion contacts the existing valve and the first balloon expands the balloon-expandable stent portion to a first diameter such that the stented prosthetic valve is in a first stage deployment configuration.

Abstract: A prosthetic valve delivery system for percutaneously delivering and deploying a prosthetic valve within an existing valve is disclosed. The delivery system includes a stented prosthetic valve having a balloon-expandable stent portion with a prosthetic valve disposed therein and at least one self-expanding stent portion. The delivery system further includes a dual balloon catheter having a first balloon on which the stented prosthetic valve is disposed during delivery and a second balloon. Upon delivery within the existing valve, the self-expanding stent portion contacts the existing valve and the first balloon expands the balloon-expandable stent portion to a first diameter such that the stented prosthetic valve is in a first stage deployment configuration.

Abstract: A prosthetic valve delivery system for percutaneously delivering and deploying a prosthetic valve within an existing valve is disclosed. The delivery system includes a stented prosthetic valve having a balloon-expandable stent portion with a prosthetic valve disposed therein and at least one self-expanding stent portion. The delivery system further includes a dual balloon catheter having a first balloon on which the stented prosthetic valve is disposed during delivery and a second balloon. Upon delivery within the existing valve, the self-expanding stent portion contacts the existing valve and the first balloon expands the balloon-expandable stent portion to a first diameter such that the stented prosthetic valve is in a first stage deployment configuration.

Abstract: A drug delivery stent is formed by a metallic or polymeric tubular strut which is shaped into a generally cylindrical configuration, the tubular strut having a central lumen for containing a therapeutic substance or drug therein. The tubular strut has a continuous channel extending from the inside surface of the strut to the outside surface of the strut positioned spirally about or in a corkscrew fashion around a circumference of the tubular strut for delivering the therapeutic substance or drug to a stenotic lesion. The spiral or corkscrew channel width may be varied along the length of the strut to control elution rate and/or flexibility of the stent. The pitch of the spiral or corkscrew channel may also be varied along the length of the strut to control flexibility of the stent. The stent may be carried on a balloon of a balloon catheter to a site of a stenotic lesion where the stent is implanted.

Abstract: A prosthetic valve delivery system for percutaneously delivering and deploying a prosthetic valve within an existing valve is disclosed. The delivery system includes a stented prosthetic valve having a balloon-expandable stent portion with a prosthetic valve disposed therein and at least one self-expanding stent portion. The delivery system further includes a dual balloon catheter having a first balloon on which the stented prosthetic valve is disposed during delivery and a second balloon. Upon delivery within the existing valve, the self-expanding stent portion contacts the existing valve and the first balloon expands the balloon-expandable stent portion to a first diameter such that the stented prosthetic valve is in a first stage deployment configuration.

Abstract: A drug delivery stent is formed by a metallic or polymeric tubular strut which is shaped into a generally cylindrical configuration, the tubular strut having a central lumen for containing a therapeutic substance or drug therein. The tubular strut has a continuous channel extending from the inside surface of the strut to the outside surface of the strut positioned spirally about or in a corkscrew fashion around a circumference of the tubular strut for delivering the therapeutic substance or drug to a stenotic lesion. The spiral or corkscrew channel width may be varied along the length of the strut to control elution rate and/or flexibility of the stent. The pitch of the spiral or corkscrew channel may also be varied along the length of the strut to control flexibility of the stent. The stent may be carried on a balloon of a balloon catheter to a site of a stenotic lesion where the stent is implanted.