An implantable prosthetic device for repairing a native valve includes a first clip, a second clip, a first cord, and a second cord. The first clip has a first arm and a second arm and is moveable between an open position and a closed position. The second clip has a third arm and a fourth arm and is moveable between an open position and a closed position. The first cord is operatively coupled to the first clip for moving the first clip between the open and closed position. The second cord is operatively coupled to the second clip for moving the second clip between the open and closed position. The device is configured to clamp a first leaflet of the native mitral valve between the first arm and the second arm and to clamp a second leaflet of the native mitral valve between the third arm and the fourth arm.

A hemostatic tissue anchor (120, 220, 320, 420, 520) is provided which is configured to be anchored to a cardiac tissue wall. The hemostatic tissue anchor (120, 220, 320, 420, 520) includes an anchor portion (130) supported by releasably positioned at a distal end of a generally elongate anchor shaft (132). The anchor portion (130) is expandable from a first generally elongate configuration to a second expanded configuration such that in the second expanded configuration it can be drawn tightly against the cardiac tissue wall when a tensile force is applied to the anchor portion (130). One or more discs (126, 226, 326) surround the anchor shaft (132). Once the one or more discs (126, 226, 326) are implanted entirely within the cardiac tissue wall, the one or more discs (126, 226, 326) act as a hemostatic seal of an opening through the cardiac tissue wall, through which opening the elongate anchor shaft (132) is disposed. Other applications are also described.

A deployment system includes a sheath, a torque able shaft having a handle positioned at its proximal end, a detachable helical first suture anchor positioned at the shafts distal end and an elongate suture fixedly coupled to the suture anchor. The deployment system can be positioned at a first tissue, and the shaft rotated to advance the helical first suture anchor into engagement with the first tissue. The shaft is detached from the first suture anchor thereby deploying it at the first tissue location. Then, the deployment system is removed from the patient, and a second suture anchor is coupled to the distal end of the shaft. The deployment system is re-inserted into the patient and the distal end of the system is moved adjacent a second tissue location, and the process is repeated for a second suture anchor at the second tissue location. A suture extends between the first and second fasteners, and tension is applied to the suture to draw the first and second tissues toward each other to reconfigure the tissue.

Methods for reconstructing a joint include fixating at least one suture inside a joint space, retrieving the at least one suture from inside the joint space, passing the at least one suture through a graft at a location external to the joint space, shuttling the graft into the joint space, and fixating the graft to bone using the at least one suture.

A coupling system includes an applicator tool and an attachment ring mounted on the applicator tool. Clips are contained within the applicator tool and are deployed through the attachment ring in order to anchor the attachment ring to biological tissue. When deployed, tips of the clips follow a curved trajectory through an annular cuff of the attachment ring and through the underlying tissue. The tips loop back out of the tissue and to a location where they are later trapped or clamped by the attachment ring. While the tips are trapped or clamped, the applicator tool cinches the clips by pulling rear segments of the clips. Thereafter, the applicator tool disconnects from the attachment ring which remains anchored to the tissue and serves as a coupling for a cannula. The cannula can have movable lock members that secure it to the attachment ring.

A tissue anchor is provided that includes a head connected to a shaft, and a tissue-coupling element extending from the shaft. The shaft includes a seal that is configured to form a blood-tight seal between the shaft and a heart wall, and to promote hemostasis. When the tissue anchor is unconstrained, the head is coaxial with an axis of the shaft, and the tissue-coupling element is generally orthogonal to the axis and is shaped such that if the tissue-coupling element were to be projected onto a plane that is perpendicular to the axis, at least 80% of an area of a projection of the tissue-coupling element on the plane would fall within a first angle of 180 degrees in the plane having a vertex at the axis. Other embodiments are also described.

The present disclosure relates generally to the field of medical devices. In particular, the present disclosure relates to medical devices, systems, and methods for tightening, fastening, or anchoring in tissue. In one example, a system for tightening, fastening, or anchoring in tissue, may comprise a spring coil having a distal end, a stressed configuration, and an unstressed configuration; and a restraining tube having a lumen extending along a length of the tube. The spring coil may be removably receivable within the lumen to restrain the spring coil in the stressed configuration. Other embodiments are contemplated.

The present invention provides methods and devices for grasping, and optional repositioning and fixation of the valve leaflets to treat cardiac valve regurgitation, particularly mitral valve regurgitation. Such grasping will typically be atraumatic providing a number of benefits. For example, atraumatic grasping may allow repositioning of the devices relative to the leaflets and repositioning of the leaflets themselves without damage to the leaflets. However, in some cases it may be necessary or desired to include grasping which pierces or otherwise permanently affects the leaflets. In some of these cases, the grasping step includes fixation.

The invention relates to a device for use in the transcatheter treatment of mitral valve regurgitation, specifically a coaptation enhancement element for implantation across the valve; a system including the coaptation enhancement element and anchors for implantation; a system including the coaptation enhancement element, catheter and driver; and a method for transcatheter implantation of a coaptation element across a heart valve.

A tissue anchor (200, 258, 300) includes a shaft (122), a tissue-coupling element (128), and a flexible elongate tension member (202). The tissue-coupling element (128) includes a wire (150), which is shaped as an open loop (154) having more than one turn when the tissue anchor (200, 258, 300) is unconstrained. The tension member (202) includes a distal portion (204) that is fixed to a site (206) on the open loop (154), a proximal portion (208), which has a longitudinal segment (209) that runs alongside at least a portion (210) of the shaft (122), and a crossing portion (212), which (i) is disposed between the distal and the proximal portions (204, 208) along the tension member (202), and (ii) crosses at least a portion of the open loop (154) when the tissue anchor (200, 258, 300) is unconstrained. The tissue anchor (200, 258, 300) is configured to allow relative axial motion between the at least a portion (210) of the shaft (122) and the longitudinal segment (209) of the proximal portion (208) of the tension member (202) when the tissue anchor (200, 258, 300) is unconstrained.