A transcatheter heart valve includes a paravalvular seal that is configured for transfemoral delivery. The valve includes an outer frame and the seal is formed from a plurality of outwardly extending fibers.

Apparatus for progressively dilating the lumen of a narrow natural vessel such as an iliac artery and implanting a tubular device enabling access through the dilated lumen to conduct subsequent procedures via the dilated lumen, includes an inflatable integrated balloon locatable at least partially within the tubular device, the tubular device having a length L1 providing a self-expanding tubular body having at least a portion including stents, so that when the integrated balloon is removed the dilated lumen of the natural vessel remains dilated and supported by the tubular device.

A personalized prosthesis for implantation at a treatment site of a patient includes a self-expanding mesh or membrane having collapsed and expanded configurations. The collapsed configuration is adapted to be delivered to the treatment site, and the expanded configuration engages the personalized prosthesis with the treatment site. The mesh or membrane is personalized to match the treatment site in the expanded configuration, and has an outer surface that substantially matches the treatment site shape and size. The self-expanding mesh or membrane forms a central lumen configured to allow blood or other body fluids to flow therethrough. Methods of manufacturing and delivery of the personalized prosthesis are also disclosed.

Devices, systems, and methods for improving airflow within an airway. One example embodiment includes a method for treating a subject. The method includes (1) placing an expandable object into one or more airways of the bronchial tree of the subject, (2) expanding the expandable object within at least one of the one or more airways such that at least a portion of a wall of the one or more airways is expanded, and (3) placing a stent in the airway such that a portion of the stent is adjacent to the portion of the wall of the one or more expanded airways.

The present disclosure relates to a sheath that is usable with a medical device, particularly to a sheath that is useable with a medical device and which sheath is expandable in the regions that the medical device is positioned in the sheath, and more particularly to a sheath that is useable with a medical device and which sheath is expandable in the regions that the medical device is positioned in the sheath and which sheath reforms to its same or similar size and shape after the medical device has passed through a portion of all of the sheath. The sheath is used to protect the body passageway of a patient as a medical device is inserted into and/or through the body passageway and to a treatment site.

A method and apparatus is provided for creating a modified tissue graft, wherein an anatomical site at which the modified tissue graft is to be placed is identified, desired characteristics for the modified tissue graft are identified based at least upon the anatomical site, one or more types of graft modifications and regions of the tissue graft to be modified are identified to achieve the desired characteristics; and at least a first area and a second area of the exterior surface of the tissue graft are modified by compressing, cutting and/or removing one or more portions thereof to create first designed surface features which cause the tissue graft to have first characteristics in the first area and second designed surface features which cause the tissue graft to have second characteristics in the second area.

A hybrid prosthetic heart valve configured to replace a native heart valve and having a support frame configured to be expanded post implant in order to receive and/or support an expandable prosthetic heart valve therein (a valve-in-valve procedure). The prosthetic heart valve may be configured to have a generally rigid and/or expansion-resistant configuration when initially implanted to replace a native valve (or other prosthetic heart valve), but to assume a generally expanded form when subjected to an outward force such as that provided by a dilation balloon or other mechanical expander. An inflow stent frame is expandable for anchoring the valve in place, and may have an outflow end that is collapsible for delivery and expandable post-implant to facilitate a valve-in-valve procedure.

Stents comprising a first region and a second region are provided, where at least the second region comprises one or more phase transforming cellular materials configured to move the outlet between an open configuration and a closed configuration in response to certain triggers. Such stents can also comprise one or more analog for a shape memory alloy (ASMA) unit cells on an inner surface of the first region such that, in response to resistive forces, the ASMA unit cells exert controllable motion to clear the stent. Methods of treatment of cancer, jaundice, and other diseases are also provided.

In some examples, a medical system including a stent configured to be positioned within a ureter of a patient. The stent includes one or more distal petals and/or one or more proximal petals resiliently biased to deploy radially outwards from a stent body. The stent may be configured to position the distal petals in a kidney of a patient and position the proximal petals in a bladder of the patient. The distal petals and/or proximal petals may be configured to resist a migration of the stent within the ureter. The stent may include suture configured to cause the distal petals and/or proximal petals to substantially to collapse for withdrawal of the stent. The medical system may include a sheath to retain the distal petals and/or proximal petals in a collapsed condition during, for example, implantation in the patient.

Apparatus and methods are provided for flaring a stent deployed within a branch vessel including an ostium communicating with a main vessel, a first end of the stent extending at least partially from the branch. A catheter is provided that includes a balloon having a reinforced region adjacent an unreinforced region. When the balloon is positioned at a desired location, e.g., within a stent, prosthetic valve, or other tubular prosthesis, the balloon may be inflated to a first pressure causing the reinforced and unreinforced regions to expand substantially simultaneously. Upon inflation of the balloon beyond the first pressure, the reinforced region of the balloon remains at the first diameter and the unreinforced region continues to expand, e.g., to flare one or more ends of the prosthesis.