An expandable stent (1) to enhance the supply of blood to downstream tissue which is being supplied with blood through a diseased intracranial artery (100) with a stenosis (102) formed therein by plaque with a bore (103) therethrough. The expandable stent (1) comprises first and second end portions (3,4) joined by a central portion (5). The central portion (5) is configured in the expanded state of the stent (1) to be located in the bore (103) of the stenosis (102) with the first and second end portions (3,4) abutting non-diseased parts (104,106) of the artery (100) adjacent the proximal and distal ends (105,107) of the stenosis (102) for anchoring the stent (1) in the artery (100). The central portion (5) with the stent (1) in the expanded state is configured to apply a radial outward pressure to the stenosis (102) such that the diameter of the bore (103) of the stenosis (102) is maintained at its current diameter or increased to approximately 50% of the non-diseased parts (104,106) of the artery (100).

A vascular graft configured for occluding a vasculature of a patient including a biocompatible polymeric textile structure formed of a plurality of filaments spaced to enable blood flow through spaces between the filaments. The textile structure forms a tubular body having a first longitudinally extending opening. An inner element has a proximal end and a distal end, the inner element composed of an open pitched metal coil having a second longitudinally extending opening and is positioned within the longitudinally extending opening of the textile structure.

A convertible nephroureteral catheter is used in the treatment of urinary system complications, particularly on the need for a single surgically delivered device to treat patients who must be seen by an interventional radiologist (IR). In many current procedures, patients need to return to the operating room to remove a previously delivered nephroureteral catheter to exchange this catheter with a fully implanted ureteral stent delivered though the same access site at the flank. The present convertible nephroureteral catheter reduces the need to return for a second surgical procedure. Two weeks after initial implantation, the proximal portion of the convertible nephroureteral catheter extending out from the body may simply be removed. A simple action at the catheter hub allows this proximal portion to be removed, leaving behind the implanted ureteral stent within the patient's urinary system. Other medical procedures, devices, and technologies may benefit from the described convertible catheter.

This disclosure concerns medical devices, such as catheters and implantable devices, having radially adjustable features. More particularly, the catheters and implantable devices can radially expand and contract to perform various functions within the body. Expansion and contraction can be performed by a radially adjustable structure mounted on the medical device. For example, a medical device can include an body configured for in vivo introduction, a strip attached to the body and rolled into a ring such that layers of the strip radially overlap each other, and at least one motor actuatable by electrical energy to move the radially overlapping layers of the strip relative to one another and change a diameter of the ring and the body.

The present disclosure is directed to methods, compositions, devices and kits which pertain to the attachment of stent-containing medical devices to tissue.

The present disclosure is directed to methods, compositions, devices and kits which pertain to the attachment of stent-containing medical devices to tissue.

A prosthetic implant includes a circumferentially adjustable sealing collar and a rotatable sealer gear. The sealing collar has a central longitudinal axis. The rotatable sealer gear is coupled to and disposed within the sealing collar and configured to adjust the circumference of the sealing collar. The sealer gear is radially offset relative to the central longitudinal axis of the sealing collar. Rotating the sealer gear in a first direction relative to the sealing collar circumferentially expands the sealing collar. Rotating the sealer gear in a second direction relative to the sealing collar circumferentially contracts the sealing collar.

A prosthetic heart valve includes a frame, a valve component, and an actuation mechanism. The frame has a plurality of struts interconnected by a plurality of joints and is movable between expanded and compressed configurations. The valve component is inside the frame and has a plurality of leaflets. The actuation mechanism has a first expansion element coupled to the frame at a first location and a second expansion element coupled to the frame at a second location. The actuation mechanism is configured such that moving the first expansion element and the second expansion element toward each other in a first direction results in the frame moving from the compressed configuration to the expanded configuration, and such that moving the first expansion element and the second expansion element away from each other in a second direction results in the frame moving from the expanded configuration to the compressed configuration.

A prosthetic heart valve includes a frame, a valve component, and an actuation mechanism. The frame has a plurality of struts interconnected by a plurality of joints and is movable between expanded and compressed configurations. The valve component is inside the frame and has a plurality of leaflets. The actuation mechanism has a first expansion element coupled to the frame at a first location and a second expansion element coupled to the frame at a second location. The actuation mechanism is configured such that moving the first expansion element and the second expansion element toward each other in a first direction results in the frame moving from the compressed configuration to the expanded configuration, and such that moving the first expansion element and the second expansion element away from each other in a second direction results in the frame moving from the expanded configuration to the compressed configuration.

An implantable vein frame is contemplated in which two ring members are rigidly joined in spaced axial alignment via one or more interconnecting members. One of the one or more interconnecting members defines a protruding region that acts upon the implant placed within the frame and/or the vein that the vein frame is placed within to define a sinus region. The implant is placed within and scaffolded by the vein frame, and the vein frame is subsequently inserted within a vein via a venotomy, or interposed between two vein segments via vein interposition graft. The vein frame acts to support the structural integrity of the implant, and to scaffold and anchor the implant in place with the vein.