A filter device has a catheter having a lumen, a shaft extended in the longitudinal direction from the lumen, and a filter capturing an embolus. The filter is connected to the shaft through a slide ring at the distal end thereof. The shaft is inserted into and passed through the ring. The ring is rotatable with respect to the shaft and slidable in the longitudinal direction. When the filter is expanded in a blood vessel, the ring slides on the shaft. The filter is connected to the shaft through another ring on the peripheral edge of an opening. The shaft is inserted into and passed through the ring. The ring is rotatable with respect to the shaft. The ring is held between a pair of stoppers fixed onto the shaft. Therefore, the movement of the ring in the longitudinal direction with respect to the shaft is prevented.

According to one aspect of the present disclosure, a method and technique for manufacturing a stent are disclosed. The stent is a non-metallic stent having a furled small-diameter state and an expanded large-diameter state where the stent, in the furled small-diameter state, includes a plurality of central lobes arranged at spaced-apart intervals and extending longitudinally defining a stent axis, the plurality of central lobes defining a cylindrical plane of the stent. The stent also includes at least one peripheral lobe formed on at least one of the plurality of central lobes, the peripheral lobe oriented along the cylindrical plane.

An interarticular ligament prosthesis is formed from a plurality of high strength high modulus polymeric fibers. The fibers are independent and free from intrinsic inter-fiber shear coupling found in braided or bonded fibers. The ligament prosthesis is installed with tubular, bone screw anchors. The fibers of the ligament prosthesis pass through the central hole of the anchors and are knotted at one end. The exit holes of the anchors include ceramic eyelets with polished edges. The edges are rounded to a defined radius for desired fatigue life of the prosthesis.

The disclosure relates to heart have prostheses with the reduced need of pacemaker implantation and improved means for positioning the replacement heart valve. In one aspect of the present disclosure, the stent scaffold of the valve prosthesis includes axially extending locators. The locators may be positioned within the cusp of the native aortic valve. Placement of the locators within the cusps may prevent further proximal movement of the stent scaffold into the left ventricle. By adjusting the location of the proximal end of the locators with respect to the proximal end of the stent scaffold, infra-annular placement of the stent scaffold in the aortic annulus may be assured. In another aspect, means for visualizing the positioning of replacement heart valves at an implant site inside an individual's body is disclosed.

A radiopaque structure, a stent and a thrombectomy system are disclosed. The radiopaque structure includes: at least one protrusion each for securing, supporting and connecting a radiopaque sleeve (2); at least one radiopaque sleeve (2) disposed over the respective at least one protrusion; and at least one filler (3) filled in a gap between the radiopaque sleeve (2) and the protrusion. Compared with the prior art, the radiopaque mechanism can enhance fluoroscopic visibility of radiopaque dots disposed at a distal end of a laser-cut thrombectomy device and solves the problem that not all metal struts in the laser-cut thrombectomy device can be seen under fluoroscopic imaging. The radiopaque structure can be used in any types of stent and is not limited to being used in a thrombectomy device.

The invention is directed to a medical device, in particular a flow diverter, having a radially self-expandable lattice structure which is tubular at least in some regions and which is composed of a plurality of interwoven individual wires which form meshes of the lattice structure, wherein at least some of the individual wires have an X-ray visible core material and a superelastic mantle material, wherein a plurality of directly adjacent meshes in the circumferential direction of the lattice structure form a mesh ring in a fully self-expanded state, the lattice structure has an expansion diameter D.sub.exp, the mesh ring has a mesh number n, and the core material has a core diameter d.sub.core, and wherein for the core diameter d.sub.core, the following holds:
d.sub.core=f.Math.(D.sub.exp/n)
wherein the following holds for a visibility factor f:
0.08f0.15.