Abstract: A suture-securing device includes a first tubular element, shaped to define a first lumen therethrough, and having first and second ends; and a second tubular element, shaped to define a second lumen therethrough, and having first and second ends. The suture-securing device is configured to have (a) an unlocked configuration in which the first end of the second tubular element is disposed closer to the first end of first tubular element than is the second end of the second tubular element, and the sutures are disposable within and slidable through the first and second lumens, and (b) a locking configuration in which the second end of the second tubular element is disposed closer to the first end of first tubular element than is the first end of the second tubular element, and the sutures are inhibited from sliding through the first and second lumens. Other embodiments are also described.

Abstract: A valve-tensioning implant is provided that includes a first venous tissue anchor, a second atrial tissue anchor, and a third atrial tissue anchor. The first venous tissue anchor includes an intraluminal stent that is configured to be implanted in a vein selected from the group of veins consisting of: a superior vena cava, an inferior vena cava, and a coronary sinus. The second atrial tissue anchor includes (a) a tissue-coupling element and (b) a head, which is shaped so as to define an opening. The valve-tensioning implant further includes a tether, which (a) is connected to the first venous tissue anchor and the third atrial tissue anchor, and (b) passes and is moveable through the opening of the head. Other embodiments are also described.

Abstract: A method is provided for repairing the tricuspid valve of a patient using tension. A radially-expandable stent is implanted in a coronary sinus of the patient. A tissue anchor is implanted in tissue in the vicinity of the tricuspid valve. The tricuspid valve is repaired by applying tension between the radially-expandable stent and the tissue anchor using a flexible longitudinal member that connects the radially-expandable stent and the tissue anchor.

Abstract: Apparatus for use with a deployment tool is provided. The apparatus includes a tissue anchor configured to be delivered in a constrained state within the deployment tool. The tissue anchor includes a shaft and a tissue-coupling element, which extends from a distal end of the shaft and is configured to be advanced through an incision in a wall of a cardiac chamber and be coupled to a far outer side of the wall. A spring is disposed proximal to a sealing element, and is configured to distally push the sealing element against an inner side of the wall to seal the incision. Other embodiments are also described.

Abstract: A tissue anchor is provided that is configured to be delivered in a constrained state within a deployment tool. The tissue anchor includes a shaft and a tissue-coupling element, which (a) extends from a distal end of the shaft, and (b) is configured to be advanced through a heart wall and be coupled to a far side of the heart wall. The tissue anchor further includes a sealing element, which is (a) disposed around the shaft, (b) sized and shaped to be disposed entirely within the heart wall, and (c) configured to promote hemostasis. Other embodiments are also described.

Abstract: Apparatus is provided that includes a casing, shaped to define a cavity, and one or more openings in the casing, in which openings one or more sutures are disposable; and a core, disposed in the cavity, and shaped to define a lumen in which the sutures are disposable. The apparatus has an unlocked configuration in which the sutures are disposable within and slidable through the openings and the lumen, and a locking configuration in which the sutures are inhibited from sliding through the openings and the lumen. The apparatus is movable from the unlocked configuration to the locking configuration, and is configured such that, when the sutures are disposed within the openings and the lumen, and the apparatus moves from the unlocked configuration to the locking configuration, the apparatus cuts the sutures at a cutting site, and becomes coupled to the sutures at a coupling site.

Abstract: An expandable tissue anchor is provided that includes an elongate tissue-coupling portion configured to be delivered through a cardiac tissue wall, and a flexible elongate tension member, which is coupled to a portion of the tissue-coupling portion such that a tensile force can be applied to the tissue-coupling portion after it has been expanded. A portion of the tension member is slidably disposed through a passage defined by the anchor. A sleeve encloses a portion of the tension member between the tissue-coupling portion and a distal opening of the passage. The sleeve and the passage are sized and shaped such that the size and shape of the passage prevent proximal movement of the sleeve past the passage upon application of the tensile force to the tension member, thereby limiting compression and deformation of the expanded tissue-coupling portion by the tension member. Other embodiments are also described.

Abstract: An implant is provided that includes first and second tissue anchors, which include (a) first and second tissue-coupling elements, respectively, and (b) first and second heads, respectively, which include first and second tether interfaces; and one or more tethers, which are connected to the first tether interface, and coupled to the second tether interface. The first and second tissue anchors are removably positioned in a catheter shaft of a multiple-anchor delivery tool at first and second longitudinal locations, respectively, the first longitudinal location more distal than the second longitudinal location. First and second torque cables of the delivery tool (a) are removably coupled to the first and second heads, respectively, (b) extend within the catheter shaft proximally from the first and second heads, respectively, and (c) transmit torque when rotated. A portion of the first torque cable is removably positioned alongside the second tissue anchor in the catheter shaft.

Abstract: A method of treating a heart of a patient is provided, including implanting a first tissue anchor in cardiac tissue of the patient, the first tissue anchor attached to one or more tethers that are fixed to a coupling element. A second tissue anchor is implanted in the patient. The coupling element is coupled to a first coupling site of the second tissue anchor, thereby coupling the first tissue anchor to the second tissue anchor via the one or more tethers. Thereafter, after allowing at least 24 hours for tissue growth on the first tissue anchor to strengthen anchoring of the first tissue anchor in the cardiac tissue, tension is increased between the first and the second tissue anchors by decoupling the coupling element from the first coupling site and coupling the coupling element to a second coupling site of the second tissue anchor. Other embodiments are also described.

Abstract: A method is provided for reducing tricuspid valve regurgitation of a patient. The method includes implanting a first tissue anchor at a first implantation site in cardiac tissue in the vicinity of the tricuspid valve of the patient, and implanting a second tissue anchor at a second implantation site in cardiac tissue of the patient opposite the first implantation site across the tricuspid valve. Using a spool that winds therewithin at least a portion of a longitudinal member that couples the first and the second tissue anchors together, tension is applied between the first and the second tissue anchors to alter the geometry of the tricuspid valve by rotating the spool.

Abstract: A method is provided that includes implanting (a) a venous first tissue anchor in a vein selected from the group of veins consisting of: a superior vena cava and an inferior vena cava, (b) an atrial second tissue anchor at an atrial site selected from the group of sites consisting of: an annulus of a tricuspid valve, and a wall of a right atrium of a heart above the annulus of the tricuspid valve, (c) a venous third tissue anchor in a coronary sinus, and (d) one or more tethers, which connect the venous first tissue anchor, the atrial second tissue anchor, and the venous third tissue anchor. A size of a tricuspid orifice is reduced by tensioning the one or more tethers. Other embodiments are also described.

Abstract: A method of treating a heart of a patient is provided. The method includes implanting a first tissue anchor in cardiac tissue of the patient and a second tissue anchor in the patient, such that the first and the second tissue anchors are coupled together by one or more tethers. Thereafter, after allowing at least 24 hours for tissue growth on the first tissue anchor to strengthen anchoring of the first tissue anchor in the cardiac tissue, tension is applied between the first and the second tissue anchors using at least a longitudinal portion of the one or more tethers. Other embodiments are also described.

Abstract: A method is provided that includes implanting (a) a first venous tissue anchor in a superior vena cava, an inferior vena cava, or a coronary sinus, (b) exactly two atrial tissue anchors, which consist of second and third atrial tissue anchors, at respective different atrial sites, each of which sites is selected from: an annulus of a tricuspid valve, and a wall of a right atrium of a heart above the annulus, and (c) a pulley system, which includes (i) a pulley, which is connected to the second atrial tissue anchor, and (ii) a tether, which (A) is connected to the first venous tissue anchor and the third atrial tissue anchor, (B) is moveable through the pulley, and (C) has a length, measured between the first venous and the third atrial tissue anchors, of at least 30 mm. A size of a tricuspid orifice is reduced by tensioning the tether.

Abstract: A tether-securing device is provided that includes a tubular element, which is shaped so as define a lateral wall that surrounds a lumen. The lateral wall is shaped so as to define a one-way locking opening. The tether-securing device further includes at least one tether, which (a) has at least a first tether end portion, and (b) passes through the lumen and the one-way locking opening. The tether-securing device additionally includes first and second tissue anchors. The first tissue anchor is connected to the first tether end portion. The one-way locking opening is configured to (a) allow sliding of the at least one tether in a first direction through the one-way locking opening, and (b) inhibit sliding of the at least one tether in a second direction opposite the first direction. Other embodiments are also described.

Abstract: A radially-expandable stent is shaped so as to define a plurality of tether interfaces, a plurality of lower-securement portions, and a plurality of higher-securement portions. The lower-securement portions extend (a) along at least respective contiguous lower-securement axial segments of the stent and (b) circumferentially around respective contiguous lower-securement circumferential portions of the stent, which lower-securement axial segments and lower-securement circumferential portions include one or more of the tether interfaces. The higher-securement portions extend (a) along at least respective contiguous higher-securement axial segments of the stent and (b) circumferentially around respective higher-securement circumferential portions of the stent, collectively at all circumferential locations other than those of the lower-securement circumferential portions. The lower- and the higher-securement portions alternate around the stent.

Abstract: A torque-delivery tool includes a cable and a distal coupling element. A tissue anchor includes an anchor head, which includes a shaft having a proximal coupling element. The distal and proximal coupling elements are shaped so as to define corresponding interlocking surfaces. An outer tether-securing element of the anchor is shaped so as to define a lateral opening through which a tether is disposed, and at least partially radially surrounds the shaft and a spring. In an unlocked state, a distal spring depressor restrains the spring in an axially-compressed state. In a locked state, the distal and proximal coupling elements are not coupled with one another, the distal spring depressor does not restrain the spring in the axially-compressed state, and the spring is in an axially-expanded state, in which the spring inhibits the sliding of the tether through the lateral opening by pressing the tether against the outer tether-securing element.

Abstract: 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 N 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.

Abstract: A radially-expandable stent (20) is shaped so as to define one or more tether interfaces (50), a lower-securement portion (56), and a higher-securement portion (64). The lower-securement portion (56) extends (a) along at least a contiguous lower-securement axial segment (58) of the stent (20) and (b) circumferentially around a contiguous lower-securement circumferential portion (60) of the stent (20), which lower-securement axial segment (58) and lower-securement circumferential portion (60) include the one or more tether interfaces (50). The higher-securement portion (64) extends (a) along at least a contiguous higher-securement axial segment (65) of the stent (20) and (b) circumferentially around between 215 and 330 degrees of a circumference (C), at all circumferential locations other than those of the lower-securement circumferential portion (60).

Abstract: A method is provided including making an opening (300) through an atrial septum (302) at a septal site (304) at least 5 mm from a fossa ovalis (330). A first tissue anchor (204) is endovascularly advanced to a left-atrial site (306) on an annulus of a mitral valve (310) or a wall of a left atrium (308) above the annulus. The first tissue anchor (204) is implanted at the left-atrial site (306). A second tissue anchor (24) is endovascularly advanced to a right-atrial site (320) on an annulus of a tricuspid valve (207) or a wall of a right atrium (200) above the annulus. The second tissue (24) anchor is implanted at the right-atrial site (320). The left-atrial site (306) and the right-atrial site (320) are approximated by tensioning a tether (22) that passes through the opening (300) of the atrial septum (302) and connects the first and the second tissue anchors (204, 24). Other embodiments are also described.

Abstract: A system for repairing an atrioventricular valve of a patient is provided. First and second tissue-engaging elements are configured for implantation at first and second implantation sites of the patient, respectively. First and second flexible longitudinal members are coupled at respective first end portions thereof to the first and the second tissue-engaging elements, respective. Each of the first and the second flexible longitudinal members comprises a braided polyester suture or a plurality of wires that are intertwined to form a rope structure. First and second flexible-longitudinal-member-coupling elements are coupled to respective second end portions of the first and the second flexible longitudinal members. The first and the second flexible-longitudinal-member-coupling elements are configured to be couplable together during an implantation procedure to couple together the first and the second flexible longitudinal elements.