An intravascular support device includes a support or reshaper wire, a proximal anchor and a distal anchor. The support wire engages a vessel wall to change the shape of tissue adjacent the vessel in which the intravascular support is placed. The anchors and support wire are designed such that the vessel in which the support is placed remains open and can be accessed by other devices if necessary. The device provides a minimal metal surface area to blood flowing within the vessel to limit the creation of thrombosis. The anchors can be locked in place to secure the support within the vessel.

Implants or systems of implants and methods apply a selected force vector or a selected combination of force vectors within or across the left atrium, which allow mitral valve leaflets to better coapt. The implants or systems of implants and methods make possible rapid deployment, facile endovascular delivery, and full intra-atrial adjustability and retrievability years after implant. The implants or systems of implants and methods also make use of strong fluoroscopic landmarks. The implants or systems of implants and methods make use of an adjustable implant and a fixed length implant. The implants or systems of implants and methods may also utilise an adjustable bridge stop to secure the implant, and the methods of implantation employ various tools.

Apparatus is provided that includes first and second tissue-engaging elements, and first and second flexible longitudinal members, coupled at respective first end portions thereof to the first and the second tissue-engaging elements, respectively. The apparatus further includes a first flexible-longitudinal-member-coupling element coupled to a second end portion of the first flexible longitudinal member, a second flexible-longitudinal-member-coupling element coupled to a second end portion of the second flexible longitudinal member, and a flexible longitudinal guide member reversibly coupled to the first flexible-longitudinal-member-coupling element. The first and second flexible-longitudinal-member-coupling elements are configured to be couplable together to couple together the first and the second flexible longitudinal elements. Other applications are also described.

A device, a kit and a method is presented for permanently augmenting the pump function of the left heart. The mitral valve plane is assisted in a movement along the left ventricular long axis during each heart cycle. The very close relationship between the coronary sinus and the mitral valve is used by various embodiments of a medical device providing this assisted movement. By means of catheter technique an implant is inserted into the coronary sinus, the device is augmenting the up and down movement of the mitral valve and thereby increasing the left ventricular diastolic filling when moving upwards and the piston effect of the closed mitral valve when moving downwards.

Delivery systems, methods and associated devices to facilitate delivery and deployment of a heart implant. Such delivery systems and methods of delivery include use of a pair of magnetic catheters, including an anchor delivery catheter carrying an anchor, which can be stacked with or can be axially offset from the magnetic head. Such systems further include use of a puncturing guidewire advanceable through the magnetic head of the anchor delivery catheter to establish access to a chamber of a heart and which is attached to a bridging element such that continued advancement of the guidewire draws a bridging element attached to the first anchor across the chamber of the heart while the bridging element remains covered by the magnetically coupled catheters. Methods and devices herein also allow for cutting and removal of a bridge element of a deployed heart implant.

A delivery sheath can comprise an elongate tubular member and an anchor on a distal portion of the elongate tubular member, the anchor being configured to engage with the coronary sinus ostium, or both the coronary sinus ostium and a portion of the coronary sinus adjacent to the ostium, so as to provide stable transcatheter access into the coronary sinus. The anchor can be configured to permit blood flow through the ostium while in engagement with the ostium.

A plication lock delivery system that enables a suture lock assembly to be delivered percutaneously. The plication lock delivery system comprises a lock assembly that secures sutures in place, a control assembly that allows a clinician to engage a suture to a suture lock assembly, apply tension to the sutures to cause tissue plication, and deploy the lock assembly, and a catheter assembly. This plication lock delivery system can be used to repair mitral regurgitation percutaneously or in an open-heart surgery.

A mitral cerclage annuloplasty apparatus includes a catheter with a blocking member and a capturing member. The blocking member is in the shape of a pigtail or a balloon, and is configured on the distal portion of the catheter preventing the catheter from traversing through an unsafe zone thereby enabling the catheter to pass through the safe zone. This prevents damage to critical cardiac tissues. The capturing member is adapted for pulling out a RVOT cerclage wire into the IVC, and comprises of an expandable and collapsible mesh so that the RVOT cerclage wire is captured and directed into the IVC through the safe zone. Thus the RVOT cerclage wire is passed through the RV without damaging the heart tissue forming a complete circle around the mitral valvular annulus.

A catheter member for interacting with a circumferential tissue structure includes: an elongate primary catheter having at least one inner lumen and extending along a longitudinal axis; first and second elongate secondary catheters, each having an inner lumen, and each positionable in an inner lumen of the primary catheter to be moveable relatively thereto and exposable therefrom; and a first flexing mechanism to provide a distal end portion of the first and/or second secondary catheter with a tendency to assume a first secondary bent shape. The distal end portion of the first and/or second secondary catheters is provided so as to be able to be flexed by the first flexing mechanism to form an arm portion substantially transverse to the direction of the longitudinal axis of the primary catheter so as to assume the first secondary bent shape when exposed from a distal end portion of the primary catheter.

The present disclosure relates to a device for valve regurgitation surgery and pacemaker lead fixation, and more particularly, to a device for valve regurgitation surgery and pacemaker lead fixation that allows mitral regurgitation surgery, tricuspid regurgitation surgery, and fixation of a pacemaker lead to an interventricular septum to be performed using a single device. The device for valve regurgitation surgery and pacemaker lead fixation according to the present disclosure includes a cerclage wire, a coronary sinus tube which has a lumen formed to insert the cerclage wire thereinto and which is inserted into a coronary sinus, a tricuspid valve tube which has a lumen formed to insert the cerclage wire thereinto and which crosses a tricuspid valve and protects tissues of the tricuspid valve and the interventricular septum, a lead insertion tube which is coupled to the tricuspid valve tube and has an end facing the interventricular septum, and a pacemaker lead which is inserted into the lead insertion tube and has an end inserted into the bundle of His.