A method for delivering catheters, and stents composed of soft, compliant polymers through anatomical passages. These devices have a bulbous or enlarged anchorage end with a diameter greater than the rest of the catheter. To facilitate implant and delivery a pusher catheter or sheath with an internal lumen larger than the outer diameter of the catheter but smaller than the outer diameter of the bulbous or enlarged anchorage end is provided. The distal end of pusher catheter or the sheath physically engages the proximal end of the bulbous or enlarged anchorage end and applies an axial force to coaxially advance the catheter over a guidewire through anatomical passages. This method allows a physician to move the catheter to an anatomical site without the device exhibiting buckling due to axial force applied. Similarly, this delivery method will allow more force to be applied to the distal end of the catheter diminishing the likelihood of buckling.

Prosthetic heart valves described herein can be deployed using a transcatheter delivery system and technique to interface and anchor in cooperation with the anatomical structures of a native heart valve. Deployment systems and methods for using the deployment systems described herein facilitate implanting a two-part prosthetic heart valve that is arranged in a nested configuration during the transcatheter delivery and deployment processes.

The invention relates to a method for forming a prosthetic base knit (1) made of two parallel sheets of porous knits, namely a first sheet (2) of porous knit and a second sheet of porous knit, said two parallel sheets being joined together in a discrete manner by a plurality of connecting porous knits (4) spaced apart from each other. The invention further relates to a method for manufacturing H-shaped prostheses for hernia repair from said base knit thus obtained and to the prostheses obtained therefrom.

Systems and methods for treating target tissues within the ears are disclosed. Systems include a device including a cutting edge configured to form an incision in a tympanic membrane, a pressure equalization tube positionable within an interior space of the device in a compressed configuration and configured to expand into an expanded configuration when released from the interior space, and an elongate positioning element configured to release the pressure equalization tube from the interior space such that the pressure equalization tube is deployed in the incision formed in the tympanic membrane.

A cardiac device comprises a first anchoring element configured to be attached to a first side of a tissue wall, a second anchoring element configured to be attached to a second side of the tissue wall, and a cinching device. The cinching device is configured to attach to the first anchoring element and the second anchoring element and apply force to the first anchoring element to move the first anchoring element towards the second anchoring element and at least partially compress the tissue wall.

The present teachings provide a device to change the pressure in a chamber of a heart and methods of making and using thereof. One aspect of the present teachings provides a device comprising a frame (for example, a metallic frame) and a scaffold. The frame of the device has a distal flange portion, a shunt portion, and a proximal flange portion. The distal and proximal flange portions can align with the shunt portion and form an elongated first profile. At least one of the distal and proximal flange portions can bend radially away from the shunt portion to form a flange like profile. The scaffold includes one or more than covering layers and encloses parts of the frame or the entire frame. The covering layer provides a barrier between the biological matter and the frame of the device. The scaffold is designed to control and direct tissue growth, for example, by stimulating an irritation response and inducing cell proliferation around the retention flange and/or discouraging cell proliferation inside the shunt portion.

Mitral valve prolapse and mitral regurgitation can be treating by implanting in the mitral annulus a transvalvular intraannular band. The band has a first end, a first anchoring portion located proximate the first end, a second end, a second anchoring portion located proximate the second end, and a central portion. The central portion is positioned so that it extends transversely across a coaptive edge formed by the closure of the mitral valve leaflets. The band may be implanted via translumenal access or via thoracotomy.

In some embodiments, an apparatus includes a handle, an actuator, a pusher device, and a puncture member. A distal anchor is disposed at a distal end portion of an artificial chorda, or suture, and is in a delivery configuration. The artificial chorda, or suture, is coupled to the actuator and extends through a lumen of the puncture member. The actuator can be actuated to move the puncture member distally a preset distance, and to move the pusher device distally such that at least a portion of the distal anchor is moved distal to the distal end of the puncture member and the distal anchor is moved from its delivery configuration to a deployed configuration.

A method and associated device for constricting fluid flow in vasculature comprising inserting a device into vasculature of a patient. The device comprising a frame defining an inflow portion, an outflow portion, and a center portion between the inflow portion and outflow portion and a fluid impermeable membrane lining at least the center portion, wherein a minimum diameter of the center portion is at least about 33% less than a diameter of the inflow portion, and the patient has deep vein reflux (DVR), chronic venous insufficiency (CVI), or excess shunting through a fistula. The method may further include placing the device within a vein proximally to a refluxing deep vein in a valve free zone.

The present disclosure relates to a medical anchor device and methods of use for providing an improved device for intraluminally directed vascular anastomosis. The anchor device includes a generally tubular graft having a flange disposed at one end thereof, where a portion of the graft extends through the flange. The flange includes a wire frame made of a resilient material and a thin membrane covering or overlaying the wire frame, where the wire frame is self-expanding when deployed within a lumen. The device may be deployed within the lumen at an anastomotic site without a need for sutures, staples, clips, or other mechanical attachment means that may cause further injury.