An aneurysm bridging device can be placed in the neurovasculature of a patient by advancing the aneurysm bridging device in a small-diameter configuration a delivery catheter to a target region within the neurovasculature and securing the distal region of the aneurysm bridging device to the neurovasculature. While the distal region of the aneurysm bridging device is secured to the neurovasculature, the proximal region of the aneurysm bridging device can be advanced to permit the aneurysm bridging device to expand from the small-diameter configuration and to deform and twist in a central region of the aneurysm bridging device. The proximal region of the aneurysm bridging device can be secured within the neurovasculature to maintain the central region of the aneurysm bridging device in a deformed state.

Methods for securing strand ends of devices configured for insertion into an anatomical structure, and the resulting devices.

Implantable stents that include strips that are each comprised of main struts connected by first connectors, and adjacent strips are connected by second connectors. The strut connectors have a structure, including areas of expanded or reduced width or thickness, to account for venous applications. When used for venous applications, the stents convey benefit from configurations that improve flexibility (due to the greater elasticity of venous applications) while maintaining enough stiffness to resist pressure on the venous structure in selected areas (such as for the May-Thurner syndrome). The stents include particular structural characteristics that are particularly advantageous for (although not limited to) venous applications.

Some embodiments of the invention advantageously leverage the expansion, dilation or by-pass of the Schlemm's canal using adjustable reversible self-expanding eye stents (SES) or eye tension rings (ETRs) of desired sizes to control and improve aqueous flow throughout the range of the uveolymphatic canal. As such, some embodiments include tension ring(s) or cylinders that sits either inside or outside the Schlemm's canal wall and is at least partially within the canal and/or is partially or fully anchored, attached, adhered, or otherwise held in place with respect to the wall and/or elsewhere in the canal. The partial or complete expansion of the canal can be pre-configured based on pre-operative metrology of the Schlemm's canal to a customized and adjustable fit across the various zones within the uveolymphatic canal and based on the patient specific and evolving needs. Additionally, the SES can utilize entry/exit features for by-pass of fluid, varying control of dilation across its shape that may also allow anchoring, repositioning, and retrieval.

An endoluminal device includes a composite yarn with a polymer yarn and an alloy wire. The polymer yarn includes a biodegradable polymer, and the alloy wire includes a biocompatible alloy. An endoluminal device can include a plurality of polymer yarns and at least one alloy wire, in which the polymer yarns include a biodegradable polymer, and the least one alloy wire includes a biocompatible alloy. A surgical system or kit includes an endoluminal device and a delivery instrument.

Methods and devices for relieving stenoses in, or otherwise improving blood flow through, body lumens. Although applicable in a variety of different body lumens, the methods and devices of this invention are specifically useable for relieving stenoses in, or otherwise improving blood flow through, veins which drain blood from the brain for treatment of multiple sclerosis or other neurodegenerative disorders that are caused, triggered or exacerbated by venous occlusion or venous insufficiency.

A medical stent having a first end, a second end, and a central longitudinal axis extending from the first end to the second end, may include a plurality of first filaments each extending in a first helical path around the central longitudinal axis in a first direction and a plurality of second filaments each extending in a second helical path around the central longitudinal axis in a second direction. The plurality of first filaments may be interwoven with the plurality of second filaments. The first helical path of at least one of the plurality of first filaments may include a circumferential offset disposed between the first end and the second end.

The present invention relates to an endoluminal device for implantation in a body lumen, such as a pancreatic duct. The device is provided with a distal end region having greater flexibility than that of a medial region of the device.

The present disclosure relates generally to controlled extension medical stents, and more particularly to controlled extension devices positioned in the body to stent the ureter and facilitate drainage from the kidney to the bladder.

A method for endovascularly replacing a patient's heart valve including the following steps: endovascularly delivering an anchor and a replacement valve supported within the anchor to a vicinity of the heart valve in a collapsed delivery configuration, the anchor having grasping elements adapted to grasp tissue in a vicinity of the heart valve; expanding the anchor, thereby rotating the grasping elements; and grasping the tissue with the rotating grasping elements.