The invention relates to a stent and a system for putting in place a stent. Said stent is used especially for splinting a vein and consists of a braided, tubular supporting member (2) that has a minimum length of 60 mm. The supporting member is braided from one or more wires in such a way that portions of the wire or wires, resp., delimit rhombuses. The disclosed stent is characterized in that in the unloaded state of the stent, the longitudinal size of most of the rhombuses (7) in the longitudinal direction (15) of the stent (1) is not shorter than the transversal size of the rhombuses.

A replacement heart valve implant includes an expandable framework configured to shift between radially collapsed and radially expanded configurations, and a plurality of valve leaflets secured to the framework. The framework includes a tubular wall defining inflow and outflow ends. The inflow end includes an attachment tab extending radially inward from the tubular wall. A replacement heart valve system includes the implant and a delivery system including a shaft assembly extending distally from a handle. A method of loading the implant includes positioning the implant adjacent an implant holding portion of the delivery system in the collapsed configuration; positioning a distal sheath of the delivery system at least partially over a groove formed in an outer surface of a stent holder of the delivery system; inserting the attachment tab into the groove; and rotating the implant relative to the delivery system.

Stent delivery systems and methods for making and using stent delivery systems are disclosed. An example stent delivery system may include an inner member having a stent receiving region, a stent disposed along the stent receiving region, a deployment sheath axially slidable relative to the inner member, the deployment sheath having a proximal end region, a handle coupled to the deployment sheath, a rod coupled to the handle, the rod having a distal end region, a proximal end region and a first threaded portion extending from the distal end region to the proximal end region and a coupling member configured to couple the rod to the deployment sheath, the coupling member having an engagement portion. Additionally, the first threaded portion of the rod is designed to engage the engagement portion of coupling member and rotation of the rod is designed to translate the coupling member along the rod.

A placement device 1 is a placement device for placing a stent graft 50 in a biological lumen, the placement device including: a sheath 11 in which the stent graft is accommodated; string-like converting means 14 that causes at least a portion of the stent graft in an axial direction to be maintained in a contracted state in a state in which the stent graft is released from the sheath and is able to convert the portion from the contracted state to an expanded state; and operating means 20 operated to place the stent graft in the biological lumen. The operating means has a first operating portion 20A for releasing the stent graft from the sheath, and a second operating portion 20B for releasing restraint of the portion of the stent graft by the converting means.

A delivery and release device for stent-graft includes a guiding head and a central tube connected thereto, an outer tube sleeving on the outside of the central tube, a positioning tube sheathed between the central tube and the outer tube, a front fixator, a back fixator and a positioner successively sheathed between the positioning tube and the outer tube. The stent-graft is placed between the back fixator and the positioner. A metal bar is connected to the guiding head along its axial direction with a ring suture being connected to the front fixator. The ring suture sleeves onto the metal bar after passing through the stent-graft. During the release process, the metal bar moves forward in the axial direction to detach from the ring suture, thereby the stent-graft is released.

A delivery catheter for a prosthetic heart valve, the valve expandable from a collapsed condition for delivery to an expanded condition for implantation, the delivery catheter comprising: a holder for engaging the valve in the collapsed state of the valve, the holder configured such that (i) in response to a radial compression force exerted thereon, the holder has a first shape defining an exposed engagement region for engaging at least a portion of the collapsed prosthetic heart valve for restraining axial displacement of the prosthetic valve in at least one axial direction of the catheter, and (ii) in response to removal of the radial compression force upon expansion of the valve, at least a portion of the holder transitions to a second shape

An endoluminal delivery device assembly is disclosed. The assembly comprises: an introducer including a seal housing assembly, housing a seal, and an sheath extending proximally therefrom; a delivery device including a handle body and a pusher catheter extending from the body, the pusher catheter having a pusher catheter external surface, the pusher catheter extending through the introducer such that the external surface slideably engages with the seal; a guide wire catheter extending through the body and through the pusher, the guide wire catheter being affixed at a proximal end thereof to a tip assembly; and a linking portion for linking the body and the seal housing assembly together, the linking portion having an unlinked condition and a linked condition. In the linked condition, sliding movement between the pusher catheter and the seal is limited such that disengagement between the pusher catheter external surface and the seal is prevented.

A flow diversion device for treating branch point aneurysms that includes a wire stent frame comprising a plurality of wire elements, the wire stent comprising a proximal limb and two distal limbs, wherein the proximal limb and the two distal limbs converge at a crotch of the wire stent frame. The plurality of wire elements may be braided together. The flow diversion device may have a substantially Y-shape or T-shape. The flow diversion device may be manufactured by using two tubular flow diversion devices to make a Y-shaped flow diversion device.

A delivery system for delivering an endovascular graft within a blood vessel. The delivery system includes a tip assembly including a tip and a sleeve having a proximal end. The delivery system includes a tip capture mechanism. The tip assembly is configured to move axially relative to the tip capture mechanism and between a delivery position and a release position. The tip capture mechanism includes a landing zone. The delivery system includes a travel limiter configured to align the proximal end with the landing zone when the tip assembly is in the release position to facilitate removal of the delivery system from the blood vessel.

The present invention relates to a deployment handle for a prosthesis delivery device and to a delivery device including such a handle. The handle assembly facilitates the controlled release of a prosthesis from the delivery device, while ensuring that various deployment steps are performed in a particular sequential order. The handle assembly comprises a main handle and a second handle which is rotatably and/or longitudinally moveable relative to the main handle. The second handle has an initial position on the main handle such that it prevents access to, and premature manipulation of, a proximal stent release mechanism, until the stent graft has been at least partially unsheathed.