The invention relates to a device for use in the transcatheter treatment of mitral valve regurgitation, specifically a coaptation assistance devices for implantation across the valve; a system including the coaptation enhancement element and anchors for implantation; a system including the coaptation enhancement element, and one or more of the following: transseptal sheath, anchor delivery catheter, implant delivery catheter, and clip delivery catheter; and methods for transcatheter implantation of a coaptation element across a heart valve.

A radiopaque frame is transluminally advanced to an atrium of a heart of a subject. The frame is expanded within a valve adjacent the atrium such that part of the frame remains disposed in the atrium. While the frame remains expanded within the valve, progressive portions of an annuloplasty structure are progressively positioned and anchored around the annulus using multiple anchors by, for each of the anchors sequentially (i) while fluoroscopically imaging the frame and a distal end of a delivery tool, and facilitated by mechanical guidance from the frame, positioning the distal end of the delivery tool between the frame and a wall of the atrium; and (ii) driving the anchor into the annulus laterally from the frame. Subsequently, the frame is contracted and withdrawn from the subject while leaving the annuloplasty structure anchored around the annulus. Other embodiments are also described.

A method for treating a native heart valve of a patient includes anchoring a plurality of anchors of an implant into tissue around an annulus of the valve. At the annulus, a force-distribution element is incorporated into the implant such that the force-distribution element extends along a longitudinal portion of the elongate contracting member. The method can also include circumferentially tightening the annulus by pulling the plurality of anchors closer together, such as by actuating a contracting mechanism of a contracting system, such that (i) the contracting mechanism, coupled to an elongate contracting member of the implant, applies a longitudinal tensioning force to the elongate contracting member, and (ii) the force-distributing element distributes the longitudinal tensioning force over at least two of the anchors. Other embodiments are also described.

A delivery system for delivering a plurality of helical tissue anchors to repair a wall defect. Coaxially contained within the outer sheath are inner tubular members. The first inner tubular member designed to deploy a first helical tissue anchor, a second inner tubular member designed to deploy a second helical tissue anchor, and a centered inner tubular member contains a cinching mechanism. The two helical tissue anchors are connected to a suture or strap that pull the two helical tissue anchors together to close a tissue defect. A cinching mechanism holds the anchors and tissue defect together and cut the suture or strap.

The disclosure provides systems and related methods for delivering a prosthesis to a target location. The system includes a tether delivery catheter and a prosthesis delivery catheter, and also can include a lock delivery catheter or knot pusher, as desired. Various embodiments of useful valve prostheses are also disclosed.

Devices and methods for deploying self-cinching surgical clips. A device can access at least two layers of tissue or material from only one side of the tissue or material and puncture through the two layers of tissue or material. The various configurations of clips disclosed herein can be made of a superelastic material such as Nitinol, and have a constrained and a relaxed state, and no sharp edges or tips so as to reduce tissue irritation following deployment. The clip can be disposed within the housing of the delivery device and held in a constrained state until deployment wherein the clip assumes its relaxed state, where the ends of the clip can be brought into close approximation, thereby securing the layers of tissue or material together.

A surgical fastener applying device for releasable connection to an end effector is provided. The surgical fastener applying device includes an elongated body portion having an outer tube and an inner shaft assembly. The inner shaft assembly defines a non-circular bore in a distal end thereof. The inner shaft assembly is longitudinally movable through the outer tube. The outer tube and the inner shaft assembly define corresponding openings extending radially therethrough. The surgical fastener applying device includes a detent movable within the openings of the elongated body portion. The detent floats between the end effector and the elongated body portion to enable selective connection between the end effector and the elongated body portion.

Disclosed are embodiments of a method for occluding a left atrial appendage (LAA) and other cavities or openings within a body. Some embodiments of the method can include an implant configured to be deployed within the LAA or other cavity, configured to be expanded or moved against a wall portion of the LAA or other cavity, and configured to twist at least a portion of the LAA or other cavity when the implant is rotated. Thereafter, one or more securing elements, staples, sutures, or other fasteners can be implanted in the gathered tissue to hold the tissue in the gathered state, thereby occluding the opening of the LAA or other cavity. In some embodiments, the opening of the LAA or other cavity can be occluded by elongating or otherwise reshaping the opening using an implant device, and securing the opening in the occluded state.

Methods and devices that prevent stasis in the LAA by either increasing the flow through the LAA or by closing off or sealing the LAA. Increasing the flow is accomplished through shunts, flow diverters, agitators, or by increasing the size of the ostium. Closing off the LAA is accomplished using seals or by cinching the LAA.

Solutions for reducing irritation and/or trauma which may result upon contact of an implanted implantable device with tissue surrounding or adjacent to the implantable device. Various embodiments include features which allow a tangential or otherwise atraumatic contact of the implantable device with the tissue, in contrast with a sharper contact which may occur with prior art implantable devices. The broad principles are applicable to annuloplasty devices, and have other broader applications as well.