In one embodiment, a method of repairing a heart valve accesses an interior of a patient's beating heart minimally invasively and inserts one or more sutures into each of a plurality of heart valve leaflets with a suturing instrument. The suture ends of the sutures are divided into suture pairs, with each pair including one suture end from a suture inserted into a first valve leaflet and one suture end from a suture inserted into a second valve leaflet. One or more tourniquet tubes is advanced over the suture pairs to the leaflets to draw the sutures together to coapt the leaflets and then the sutures are secured in that position.

A method is provided that includes implanting a first tissue-engaging element in a first portion of tissue in a vicinity of a heart valve. A second tissue-engaging element, which is connected to a third tissue-engaging element by a longitudinal sub-member, is implanted in a second portion of tissue of an annulus, and the third tissue-engaging element is implanted in a third portion of tissue of the annulus. A fourth tissue-engaging element is implanted in a portion of a blood vessel that is in contact with an atrium. While the longitudinal sub-member engages the longitudinal member at a junction therebetween, at least a first leaflet of the heart valve is drawn toward at least a second leaflet of the heart valve by adjusting a distance between the portion of the blood vessel and the first portion of tissue in the vicinity of the heart valve. Other embodiments are also described.

A method of reducing tricuspid valve regurgitation is provided, including implanting first, second, and third tissue anchors at respective different first, second, and third implantation sites in cardiac tissue in the vicinity of the tricuspid valve of the patient. The geometry of the tricuspid valve is altered by drawing the leaflets of the tricuspid valve toward one another by applying tension between the first, the second, and the third tissue anchors by rotating a spool that (a) winds therewithin respective portions of first, second, and third longitudinal members coupled to the first, the second, and the third tissue anchors, respectively, and (b) is suspended along the first, the second, and the third longitudinal members hovering over the tricuspid valve away from the annulus of the tricuspid valve. Other embodiments are also described.

Apparatus is provided, including an implant including a tissue-adjusting member including a longitudinal member, and a tissue anchor coupled to the tissue-adjusting member and configured to be anchored into the tissue of the patient. A tissue-coupling element is coupled to the longitudinal member. A delivery tool is reversibly couplable to the implant and is configured to deliver the implant to the tissue of the patient. The delivery tool includes an elongate shaft, a tissue-coupling-element holder coupled to a portion of the elongate shaft, the tissue-coupling-element holder being configured to hold the tissue-coupling element during delivery of the implant to the tissue of the patient, and an actuating element configured to rotate the tissue anchor so as to facilitate anchoring of the tissue anchor into the tissue of the patient while not rotating the tissue-coupling-element holder with respect to the shaft.

Systems, devices and methods for securing tissue including the annulus of a mitral valve. The systems, devices and methods may employ catheter based techniques and devices to plicate tissue and perform an annuloplasty.

Synthetic chord devices and methods for using the same for connecting tissues are provided. Aspects of the synthetic chord device include a flexible cord having an attachment element at both a first and a second end, wherein each attachment element includes a piercing member coupled to a securing member that attaches the flexible cord to a first tissue. At least a portion of the flexible cord can be configured to be secured to a second tissue. Aspects of the invention also include sets of the synthetic chord device with pre-measured flexible cords. The devices and methods of the invention find use in a variety of applications, such as in applications in which it is desired to repair a heart valve.

Implants, implant systems, and methods for treatment of mitral valve regurgitation and other valve diseases generally include a coaptation assist body which remains within the blood flow path as the leaflets of the valve move, the valve bodies often being relatively thin, elongate (along the blood flow path), and/or conformable structures which extend laterally from commissure to commissure, allowing the native leaflets to engage and seal against the large, opposed surfaces on either side of the valve body during the heart cycle phase when the ventricle contracts to empty that chamber of blood, and allows blood to pass around the valve body so that blood flows from the atrium to the ventricle during the filling phase of the heart cycle. Separate deployment of independent anchors near each of the commissures may facilitate positioning and support of an exemplary triangular valve body, with a third anchor being deployed in the ventricle. An outer surface of the valve body may accommodate tissue ingrowth or endothelialization, while a fluid-absorbing matrix can swell after introduction into the heart. The valve body shape may be selected after an anchor has been deployed, and catheter-based deployment systems may have a desirable low profile.

This invention relates to the design and function of a single-tether compressible valve replacement prosthesis which can be deployed into a beating heart without extracorporeal circulation using a transcatheter delivery system. The design as discussed combats the process of wear on anchoring tethers over time by using a plurality of stent-attached, centering tethers, which are themselves attached to a single anchoring tether, which extends through the ventricle and is anchored to a securing device located on the epicardium.

Implants, implant systems, and methods for treatment of mitral valve regurgitation and other valve diseases generally include a coaptation assist body which remains within the blood flow path as the leaflets of the valve move, the valve bodies often being relatively thin, elongate (along the blood flow path), and/or conformable structures which extend laterally from commissure to commissure, allowing the native leaflets to engage and seal against the large, opposed surfaces on either side of the valve body during the heart cycle phase when the ventricle contracts to empty that chamber of blood, and allows blood to pass around the valve body so that blood flows from the atrium to the ventricle during the filling phase of the heart cycle. Separate deployment of independent anchors near each of the commissures may facilitate positioning and support of an exemplary triangular valve body, with a third anchor being deployed in the ventricle. An outer surface of the valve body may accommodate tissue ingrowth or endothelialization, while a fluid-absorbing matrix can swell after introduction into the heart. The valve body shape may be selected after an anchor has been deployed, and catheter-based deployment systems may have a desirable low profile.

Devices, systems, and methods for treating a heart of a patient may make use of one or more implant structures which limit a size of a chamber of the heart, such as by deploying a tensile member to bring a wall of the heart toward (optionally into contact with) a septum of the heart.