Abstract: A medical device and method of providing same, comprises a first stent body and a second stent body wherein the medical device is formed when the at least one first marker portion and the at least one second marker portion of the stent bodies are positioned in a predetermined alignment wherein the first stent body and the second stent body are aligned along substantially the same longitudinal axis and at least a portion of the first end region and at least a portion of the second end region of the respective stent bodies are overlappingly arranged to provide the medical device with a longitudinal length that is less than the sum of the first stent body length and the second stent body length.

Abstract: A radially expandable stent comprising a plurality of spaced band-like elements and intersecting links is disclosed. The band-like elements have a generally serpentine configuration to provide continuous waves of generally sinusoidal character to each band-like element. The waves are characterized by a plurality of peaks and troughs taking a generally longitudinal direction along the cylinder such that the waves in the band-like elements open as the stent is expanded from a first diameter to a second diameter. The intersecting links are substantially U-shaped and terminate in first and second shanks. The first shank of a link emanates from a region between a peak and trough on a band-like element and the second shank of the link emanates from a region between a peak and trough on an adjacent band-like element.

Abstract: A stent for a stent-graft includes: a first ring; a second ring; and spring elements coupling the first ring to the second ring, wherein the first ring, the second ring and the spring elements are integral. During maneuvering of the stent-graft through the tortuous human anatomy, the first ring is bent or flexed relative to the second ring. However, the spring elements are distorted to accommodate this bending. Further, since the stent is integral, a graft material only has to be sewn to the second ring minimizing the delivery profile of the stent-graft.

Abstract: A sewing ring (12) has a diameter commensurate with a diameter of a removed mitral valve. Skirts (44, 46) of mesh or net material extend downward from the sewing ring and line the walls of an associated vessel (58). Basal chordae simulating structures (34, 36) in the form of elongated strips of mesh or netting, rods, or the like extend from the skirt to an underside of each of two valve leaflets (14, 16). Marginal chordae simulating structures (30, 32) extend between each leaflet and the basal chordae simulating structure. The sewing ring (12) is stitched to an open end of a vessel and inner ends of the basal chordae simulating structure are stitched or stapled (50, 52) to associated papillary musculature (54, 56). In this manner, the papillary muscles assist in controlling the timing and control of the mitral valve.

Abstract: A medical device and method for treating a heart valve. In one embodiment, the medical device has a catheter, at least one needle disposed within the catheter, and a nonadjustable fastener ejectable from the needle.

Abstract: A catheter with at least one centering device attached near a distal end of the catheter. The centering device has at least two struts extending between a proximal end and a distal end. The centering device has a variable diameter and tends to center the distal end of the catheter, steering the catheter away from the vessel wall during insertion through the vasculature and toward the treatment site. The centering catheter may facilitate access to tortuous anatomy by preventing the catheter tip from catching on irregularities in the lumenal surface. The centering catheter may also facilitate uniform stent expansion by stabilizing the catheter during stent deployment.

Abstract: The invention is directed to an expandable stent for implantation in a body lumen, such as an artery, and a method for making it from a single length of tubing. The stent consists of a plurality of radially expandable cylindrical elements generally aligned on a common axis and interconnected by one or more interconnective elements. The individual radially expandable cylindrical elements consist of ribbon-like material disposed in an undulating pattern. Portions of the expanded stent project outwardly into engagement with the vessel wall to more securely attach the stent.

Abstract: The present invention provides stents for deploying within tubular organs, blood vessels, or other tubular body lumens. Such stents comprise a stent body comprising an elastic material, the stent body being characterized by a free cylindrical shape having a free diameter. The stent body is at least partially covered with a covering that substantially prevents the stent body from expanding towards its free diameter when the stent body is placed into a diameter smaller than the free diameter. In one embodiment, the covering is a metal coating on the stent body. In another embodiment, the covering is a tube, or multiple tubes, around the stent body. Also provided is a method for deploying the stents of the present invention within tubular organs, blood vessels, or other tubular body lumens.

Abstract: An intraluminal prosthesis composed of a self-expandable stent and a biodegradable constraining element being capable of biodegrading in vivo over a predetermined period of time to permit radial expansion of the stent. The constraining elements are applied to the stent to produce a compressed configuration. Dissolution of the constraining elements in vivo allows for expansion of the stent to an expanded configuration.

Abstract: A stent for dilating an internal lumen includes tubular segments that are arranged side by side in its axial direction. Each of segments expands and contracts in the diametrical direction of the stent, and its axial length is shorter than its expanded-state radius.