An endoprosthesis having a length, a first end, a second end, and a longitudinal axis is disclosed herein, where the endoprosthesis is expandable from a compact, delivery configuration to an enlarged, deployed configuration. The endoprosthesis includes a plurality of rows of stent elements along the length of the endoprosthesis, where the plurality of rows include a first row and a second row located adjacent to the first row. The first row of stent elements has a first plurality of alternating apices, and the second row of stent elements has a second plurality of alternating apices. The first and second pluralities of alternating apices define a spaced apart, interlocking arrangement. The endoprosthesis also includes a discontinuous web of material comprising a plurality of web elements spaced from one another and interconnecting the first and second pluralities of alternating apices. The plurality of web elements are arranged along a first, common circumference such that the plurality of web elements restrict torsion and axial compression of the endoprosthesis between the first and second rows of stent elements when the endoprosthesis is in the enlarged, deployed configuration.

An endoluminal stent (100) is described herein. In an embodiment, the endoluminal stent (100) includes a plurality of sinusoidal-shaped expandable ringlets (102) provided in parallel to form a tubular structure of the endoluminal stent (100). Further, adjacent ringlets (102) can be connected to each other by one or more asymmetrical offset connectors (108), the offset connectors (108) being non-linear in structure.

A stent and a preparation method therefor. The stent includes a stent substrate. The stent substrate is provided with at least one radiopaque structure thereon. Each radiopaque structure includes at least one radiopaque unit. A radiopaque material is inlaid in each radiopaque unit, and a ratio of the volume of the radiopaque material to the volume of the radiopaque unit ranges from 1.1 to 1.4. By the stent and the preparation method therefor, the interference fit between the radiopaque material and the radiopaque unit can be better implemented, so that the radiopaque material and the radiopaque unit have strong bonding force therebetween, and the problem of embolism caused by the drop of a radiopaque material is avoided.

A stent comprises a framework that includes a sequence of cells that each occupy a discrete segment of the stent length, and each of the cells includes a plurality of struts with ends connected at respective vertices. In some forms the hollow cylindrical shape of the framework is moveable among a loading diameter that is smaller than a tube diameter, which is smaller than an expanded diameter, and every strut of the framework is oriented parallel to the stent axis when the hollow cylindrical shape is at the tube diameter. In other forms the framework includes T-bars that connect adjacent cells, where the T-bars have a column that has a minimum width perpendicular to the long axis that is wider than a maximum width of each of the struts, and the column defines at least one slot. In still other forms, the framework exhibits geometries that facilitate a high packing density for the framework when the stent is in a compressed tube or loading configuration.

Provided is a segmented covered stent (100), which includes a covering membrane (120) and a support frame (110) fixed to the covering membrane (120). The support frame (110) comprises an annular structure (1200) and a spiral structure (1300), wherein the annular structure (1200) is formed by a plurality of first wave-shaped units (1100) connected end to end; and the spiral structure (1300) is a tubular structure formed by a plurality of second wave-shaped units (1400) connected end to end and arranged in a continuous spiral manner, and the overall extension direction of the spiral structure (1300) is parallel to the support frame (110). A method for preparing the segmented covered stent (100) is further provided.

Stents that are adapted to be balloon-expanded and include a plurality of rings of repeating cells, wherein adjacent rings are connected by s-shaped or omega-shaped crosslink connectors or a combination of both connectors. The configurations, materials, and/or dimensions of these devices, including the unit cells and/or crosslink connectors allow the stents to be expanded to a greater extent (e.g., up to or greater than 12 mm of diameter), and optionally with reduced foreshortening and without increasing the strain on the materials forming the crosslink connectors and unit cells. The biphasic arrangement of trapezoidal unit cells, as well as the configuration and arrangement of the s-shaped connectors, may allow these stents to expand while maintaining their radial compression strength and longitudinal compression strength with minimal recoil and stent foreshortening.

A stent (scaffold) or other luminal prosthesis comprising circumferential structural elements which provide high strength after deployment and allows for scaffold to uncage, and/or allow for scaffold or luminal expansion thereafter. The circumferential scaffold is typically formed from non-degradable material and will be modified to expand and/or uncage after deployment.

A vascular stent assembly includes at least a first and a second strut, each including a thickness and a depth. The assembly includes a pair of end radii, with each of the first and second struts extending from one of the pair of end radii. A thickness of at least one of the first and second struts includes a tapering profile extending from one of the end radii to another of the end radii, the tapering profile following a continuously increasing or decreasing function through at least half a length of the at least one strut.

A vascular graft suitable for implantation, and more particular to a vascular graft having an expandable outflow region for restoring patency of the graft after implantation into a body lumen.

A biodegradable in vivo supporting device is disclosed. In one embodiment, a coated stent device includes a biodegradable metal alloy scaffold made from a magnesium alloy, iron alloy, zinc alloy, or combination thereof, and the metal scaffold comprises a plurality of metal struts. The metal struts are at least partially covered with a biodegradable polymer coating. A method for making and a method for using a biodegradable in vivo supporting device are also disclosed.