A prosthetic assembly configured for endovascular placement within an aortic arch and method of use thereof. The prosthetic assembly includes a proximal aortic stent-graft prosthesis configured to be positioned within a proximal portion of the aortic arch adjacent to the brachiocephalic artery, a distal aortic stent-graft prosthesis configured to be positioned within a distal portion of the aortic arch adjacent to the left subclavian artery, a first branch stent-graft prosthesis configured to be positioned within the brachiocephalic artery and a second branch stent-graft prosthesis configured to be positioned in one of the left common carotid and the left subclavian artery. When deployed, a proximal end of the first branch stent-graft prosthesis is disposed within a lumen of the proximal aortic stent-graft prosthesis to proximally displace the ostium of the brachiocephalic artery. When deployed, a proximal end of the distal aortic stent-graft prosthesis is disposed within the distal end of the proximal aortic stent-graft prosthesis to form an overlap between the proximal and distal aortic stent-graft prostheses. The overlap is relatively increased by the first branch stent-graft prosthesis proximally displacing the ostium of the brachiocephalic artery.

A scaffold includes a radiopaque marker connected to a strut. The marker is retained within the strut by a head at one or both ends. The marker is attached to the strut by a process that includes forming a rivet from a radiopaque bead and attaching the rivet to the marker including deforming the rivet to enhance resistance to dislodgement during crimping or balloon expansion. The strut has a thickness of about 100 microns.

A growth stent and valve and methods for making and using the same. The growth stent and valve may be delivered to treat early stage congenital lesions, while expanding to adult vessel diameters. In selected embodiments, the growth stent and valve can comprise a frame and may have a covering on some portion to prevent blood flow through a wall of the frame. The growth stent and valve advantageously can maintain radial strength across an entire range of diameters necessary to treat a narrowed lesion from birth and childhood through adulthood as the vessels grow over the lifetime of a patient.

The techniques of this disclosure generally relate to a modular assembly including first and second stent-grafts. The first stent-graft includes a body portion having a first diameter and a waist portion having a second diameter less than the first diameter. The waist portion is at a distal end of the first stent-graft. The second stent-graft includes a captured proximal portion configured to be located within the first stent-graft. The captured proximal portion includes a seated portion configured to be located proximal to the waist portion. The seated portion has a third diameter greater than the second diameter to form a mechanical interlock between the first stent-graft and the second stent-graft.

Devices, systems, and methods for implanting a patient-specific prosthesis at a treatment site in a patient are disclosed herein. In some embodiments, a patient-specific prosthesis includes a tubular graft and a coupling member. A fenestration can be disposed in the tubular graft, the fenestration corresponding to a predicted branch blood vessel location. The coupling member can be disposed about the fenestration. The coupling member can include a coil configured to expand from a first configuration to a second configuration in response to the application of an expanding force. The coil can be configured to contract to a third configuration upon removal of the expanding force.

Embolic material capture catheters and related devices and methods constrain a distal end portion of an embolic material capture element in an insertion configuration. A method of deploying an embolic material capture element in a blood vessel includes constraining a distal end portion of the embolic material capture element in an insertion configuration via engagement with a dilator assembly. The embolic material capture element, in the insertion configuration, is advanced through the blood vessel. A deployment cap of the dilator assembly is distally advanced relative to a dilator sheath of the dilator assembly to release the distal end portion of the embolic material capture element from engagement with the dilator assembly to reconfigure the embolic material capture element from the insertion configuration to a fully deployed configuration via self-expansion of the embolic material capture element.

An implantable heart valve configured for implantation within an existing prosthetic heart valve includes a frame including struts defining a lattice region and a plurality of arches, and a central lumen extending therebetween, a plurality of protrusions extending radially outward from the plurality of struts, and a valve coupled to the frame and positioned within the central lumen.

A device for disrupting tissue in an eye including a distal portion sized and configured for ab interno insertion into an anterior chamber of the eye having an elongate, flexible shaft of super-elastic memory-shape material. A distal end region is shaped into a curve having a radially inner surface connected to a radially outer surface by two lateral sides. The device has a tissue disruptor proximal of a distal-most end formed on at least one of the inner surface and the outer surface. The distal face of the tissue disruptor is a blunt tissue-engaging surface without any cutting element. Related methods and devices are provided.

A closure device for sealing an atrial septal defect is provided. The closure device includes a distal closure portion and a proximal closure portion. The distal closure portion includes a distal membrane covering a plurality of distal fingers that extend in a distal plane. The proximal closure portion includes a proximal membrane covering a plurality of proximal fingers that extend in a proximal plane. The closure device also includes a waist section extending axially between the plurality of distal fingers and the plurality of proximal fingers. The distal closure portion is configured to sealingly engage one of the left or right side of a septal wall, the proximal closure portion is configured to sealingly engage the other of the left or right side of the septal wall, and the waist section is configured to be positioned and centered in an atrial septal defect between the left and the right septal wall.

A prosthetic mitral valve system that comprises a valve dock and a prosthetic mitral valve is disclosed. The valve dock comprises clamp jaws that sandwich the native mitral valve leaflets and the native mitral valve annulus between them anchoring the prosthetic mitral valve system at or adjacent to the native mitral valve annulus. Further, a prosthetic mitral valve comprising atrial and ventricular clamp jaws and which can be implanted at or adjacent to the native mitral valve annulus without a valve dock system is disclosed. Novel methods and systems for treating mitral valve disease or malfunction by percutaneous replacement of the mitral valve (or the tricuspid valve) are disclosed.