A delivery system (100) for a bifurcated stent (200) is described having a stem (226) and a pair of arms (220, 222), comprising a delivery catheter (110) comprising an elongated first tube (102) having a proximal end (20) and a distal end (30) and a bifurcated part (114) at the distal end (30) configured to accommodate the arms (220, 222), wherein a longitudinal slit (140) disposed on the bifurcated part (114) is configured for releasable passage of the bifurcated stent (200) therethrough. A method for delivery of the bifurcated stent to a site of treatment using the delivery system (100) is also described.

Replacing a defective atrioventricular heart valve, in particular a tricuspid valve, may include stent devices, prosthetic heart valves, delivery systems, and corresponding methods, which provide an improved fixation without distortion of the native anatomy. A stent device for a prosthetic heart valve has an axially extending mesh-shaped body, configured to fit an orifice and defining an inner channel as a passageway from a proximal to a distal end. At least three outer support arms extend from the distal end of the body towards the proximal end. Each support arm has a distal end first support region and a proximal end second support region. The second support region extends radially outwards in the deployed state. Each support arm has a flexible region between the first and second support regions, which is formed as an axially tapered section of the support arm and/or each support arm is tapered towards the proximal end.

Anchors for securing an implant within a body organ and/or reshaping a body organ are provided herein. Anchors are configured for deployment in a body lumen or vasculature of the patient that are curved or conformable to accommodate anatomy of the patient. The invention provides an implant system having multiple anchors, e.g., one or more posterior anchors in combination with one or more anterior anchors. Methods of deploying such anchors, and use of multiple anchors or multiple bridging elements are also provided.

Stent delivery systems and methods for making and using the same are disclosed. An example stent delivery system may include an inner member. A deployment sheath may be disposed about the inner member. A stent may be disposed between the inner member and the deployment sheath. The deployment sheath may include a translucent reinforcing member that allows for visualization of the stent during stent deployment.

A system for repairing a defective heart valve. The system includes a delivery device, a balloon and a prosthetic heart valve. The delivery device includes an inner shaft assembly and a delivery sheath assembly. The delivery sheath assembly provides a capsule terminating at a distal end. The prosthesis includes a stent carrying a prosthetic valve. In a delivery state, the capsule maintains the prosthesis in a collapsed condition over the inner shaft assembly, and the balloon is in a deflated arrangement radially between the prosthetic heart valve and the capsule. In a deployment state, at least a portion of the balloon and at least a portion of the prosthetic heart valve are distal the capsule. Further, the balloon is inflated and surrounds an exterior of at least a portion of the prosthetic heart valve. The balloon controls self-expansion of the prosthetic heart valve.

The vascular prosthesis includes a luminal graft component having at least one fenestration. At least one fenestration ring borders the at least one fenestration and is fixed to the luminal graft component. The fenestration ring includes a main component with two opposing ends and a connecting component. The diameter of the fenestration ring can expand upon insertion of a branch prosthesis through the fenestration ring during implantation at a surgical site. The vascular prosthesis can be implanted in a patient to thereby treat, for example, an arterial aneurysm, spanning a region of an aneurysm that includes at least one arterial branch.

Devices, methods and kits are described for reducing intraocular pressure. The devices include a support that is implantable within Schlemm's canal and that may restore or maintain at least partial patency of the canal without substantially interfering with transmural or transluminal fluid flow across the canal. The devices utilize the natural drainage process of the eye and may be implanted with minimal trauma to the eye. Kits may include a support and an introducer for implanting the support within Schlemm's canal. Methods may include implanting a support within Schlemm's canal, where the support is capable of restoring or maintaining at least partial patency of the canal without substantial interference with transmural or transluminal fluid flow across the canal.

Pinch devices and access systems that can be used to secure a prosthetic heart valve to a heart valve annulus and to treat valvular insufficiency. A pinch device can be a separate expandable element from the prosthetic heart valve that is first advanced to the annulus and deployed, after which an expandable prosthetic heart valve can be advanced to within the annulus and deployed. The two elements can clamp/pinch the heart valve leaflets to hold the prosthetic heart valve in place. The pinch device can have a flexible, expandable annular frame. A combined delivery system can deliver the pinch device and prosthetic heart valve with just a single access point and aid more accurate coaxial deployment. The pinch device can be mounted near distal end of an access sheath, and a catheter for delivering the prosthetic heart valve can be passed through a lumen of the same access sheath.

A stent graft includes a luminal graft component defining at least one fenestration. At least one ligature traverses the fenestration and at least partially defines an opening within the fenestration that secures a branch prosthesis. The stent graft is implanted in a patient to thereby treat an arterial aneurysm, such as an aortic aneurysm in a region of the aorta that includes at least one arterial branch, including juxtarenal and short-neck aortic aneurysms.

A prolapse prevention device formed by a continuous wire-like structure having a first end and a second end disconnected from each other. The continuous wire-like structure of the prolapse prevention device is substantially straight in a delivery configuration. The prolapse prevention device in a deployed configuration includes a centering ring of the continuous wire-like structure configured to seat adjacent to and upstream of an annulus of a heart valve in situ, a vertical support of the continuous wire-like structure which extends from the centering ring and includes an apex configured to seat against a roof of an atrium in situ, and a leaflet backstop of the continuous wire-like structure extending radially inward from the centering ring and configured to contact at least at least a first leaflet of the heart valve in situ to exert a pressure in a downstream direction on the first leaflet to prevent the first leaflet from prolapsing into the atrium.