Abstract: Apparatus is provided for repairing a cardiac valve, the apparatus including a catheter sized for delivery through vasculature of a subject and an elongated and flexible annuloplasty structure having an elongated lumen and an annuloplasty structure axis extending along the lumen. The annuloplasty structure is sized and configured for delivery to a heart of the subject through the catheter substantially along a catheter axis of the catheter while the annuloplasty structure axis is substantially parallel to the catheter axis. The apparatus also includes a plurality of anchors configured for delivery to a region of cardiac tissue from a proximal end of the catheter toward a distal end of the catheter and substantially along the annuloplasty structure axis and the catheter axis while at least a portion of the annuloplasty structure is within a delivery passage of the catheter. Other embodiments are also described.

Abstract: A linking member extends from a first linking site of a longitudinal member to a second linking site of the longitudinal member. An anchor driver is configured to anchor portions of the longitudinal member to tissue using tissue anchors. A distal portion is anchorable to a first tissue location while the first linking site is within a catheter. While the distal portion is anchored to the first location, and the second linking site is within the catheter, a second portion is advanceable distally out of the catheter and is anchorable to a second tissue location. While the second portion is anchored to the second location, the second linking site and a third portion are advanceable distally out of the catheter. After the second linking site has been advanced out of the catheter, the third portion is anchorable to a third tissue location. Other embodiments are also described.

Abstract: An anchor-storage device comprises (i) a housing, shaped to define a channel having an anchor-storage zone and an opening configured to provide access for an anchor driver to the anchor-storage zone; and (ii) a retaining member. A tissue anchor is stored in the anchor-storage zone and is slidable through the channel. The retaining member (a) has a retaining state in which the retaining member is configured to retain the tissue anchor in the anchor-storage zone, and (b) is configured, by moving in response to a proximally-directed force applied to the tissue anchor, to allow the tissue anchor to leave the anchor-storage zone in response to the proximally-directed force. The proximally-directed force is greater than a pre-determined threshold force. Other embodiments are also described.

Abstract: An anchor includes (a) an anchor head; and (b) a tissue-engaging member extending distally away from the anchor head until a distal tip of the tissue-engaging member, and configured to anchor the anchor to tissue. An anchor driver can include (a) a longitudinal shaft, having a flexible distal portion and a distal end; (b) a deployment element at the distal end of the shaft, reversibly lockable to the anchor head, and reversibly movable between (i) a locked state that retains locking between the deployment element and the anchor head, and (ii) an unlocked state that unlocks the deployment element from the anchor head; and (c) a tissue-piercing lance, reversibly movable between (i) an extended state in which the lance extends distally from the shaft past the distal tip of the anchor, and retains the deployment element in the locked state, and (ii) a retracted state in which the deployment element automatically moves into the unlocked state.

Abstract: Apparatus is provided for repairing a cardiac valve, the apparatus can include a flexible annuloplasty structure having a sleeve with an elongated tubular side wall and a distal tip. A first tissue anchor can passing through the distal tip of the sleeve, and a second tissue anchor can pass through a section of the tubular side wall. The first and second tissue anchors can extend in a substantially same direction. A longitudinal portion of the tubular side wall can be disposed between the first and second tissue anchors, and have a first lateral part opposite a second lateral part and closer to the first and second tissue anchors than the second lateral part is to the first and second tissue anchors. The second lateral part can have a degree of tension that is larger than a degree of tension of the first lateral part.

Abstract: An implant that includes a ring, anchors, and adjustment elements is advanced to a subject's heart valve. The ring includes hinges, and struts arranged in a pattern of alternating peaks and troughs. The ring circumscribes a central axis. At least one hinge is disposed at each trough. Each strut has a first end-portion and a second end-portion. Each peak is defined by convergence of adjacent first end-portions. Each trough is defined by convergence of adjacent second end-portions. Each anchor has a longitudinal axis. Within the heart, the longitudinal axis of at least one of the anchors is deflected with respect to the central axis, and each of the anchors is driven along its longitudinal axis with respect to the trough and into tissue of the heart. Subsequently, tissue of the heart is contracted by rotating the plurality of adjustment elements. Other embodiments are also described.

Abstract: A catheter, advanced toward an anatomical site, has a proximal end and a steerable distal end. An anchor is advanced through the catheter. An anchor driver drives the anchor out of the catheter's distal end, anchoring the anchor at the site. A first constraining member engages tissue, and inhibits, after the anchor has been driven out of the catheter and before the anchoring, movement of at least the anchor driver's distal end, on a first axis between the anchor driver's distal end and a site at which the first constraining member engages the tissue. A second constraining member inhibits, after the anchor has been driven out of the catheter and before the anchoring, movement of at least the anchor driver's distal end, on a second axis. Other embodiments are also described.

Abstract: Anchor deployment systems and tools are provided. An anchor deployment tool can include a flexible tube including a distal anchor manipulation portion. The tool can also include a deployment element, which is positionable within the flexible tube, and is configured to, while the distal anchor manipulation portion is proximate an implantable device, (i) engage the anchors in the flexible tube, (ii) advance each of the anchors in a distal direction to the distal anchor manipulation portion, and (iii) anchor the implantable device to tissue of a subject by deploying each of the tissue anchors through the implantable device and into the tissue.

Abstract: Apparatus is provided for adjusting at least one dimension of an implant. The apparatus includes a rotatable structure having a channel extending between first and second openings of the rotatable structure. The channel is configured for passage therethrough of an elongate tool. The rotatable structure has a lower surface that is shaped to define a first coupling. The apparatus includes a mechanical element having a surface coupled to the lower surface of the rotatable structure. The mechanical element is shaped to provide a second coupling configured to engage the first coupling during a resting state of the mechanical element, in a manner that restricts rotation of the rotatable structure. The mechanical element has a depressible portion that is disposed in communication with the second opening, and is configured to disengage the first and second couplings in response to a force applied thereto by the elongate tool.

Abstract: An implant having an implant body, a gripper, an elastic pouch, and an elongate member. The pouch can be coupled to the gripper, can have a first part and a second part, can have a contracted state toward which the pouch is elastically biased, and can be reversibly stretchable into a stretched state. The elongate member can have a first end portion coupled to the implant body, a second end portion fastened to the second part of the pouch, and a mid-portion extending (i) from the second end portion, through the pouch to the first part of the pouch, and (ii) out of the pouch to the first end portion. In at least one state of the gripper, the mid-portion can be slidable through the gripper and into the pouch. Other embodiments are also described.

Abstract: A method is provided, including, during a percutaneous transcatheter procedure, placing an annuloplasty device entirely around an annulus of a mitral valve of a subject in a closed loop. The annuloplasty device includes a flexible sleeve, which is fastened to the annulus by coupling a plurality of tissue anchors to a posterior portion of the annulus, without coupling any tissue anchors to any anterior portion of the annulus between left and right fibrous trigones of the annulus. After (a) placing the annuloplasty device entirely around the annulus in the closed loop and (b) fastening the flexible sleeve to the annulus, a longitudinal portion of the flexible sleeve is longitudinally contracted. Other embodiments are also described.

Abstract: Apparatus is provided including a percutaneously-implantable implant and an adjustment device. The adjustment device can comprise an adjustment mechanism, coupled to the implant, and configured to change a dimension of the implant upon actuation of the adjustment mechanism and a lock. The adjustment device can have a locked state in which the lock inhibits actuation of the adjustment mechanism and an unlocked state in which the adjustment mechanism is actuatable. The adjustment device can be reversibly movable between the locked state and the unlocked state. The apparatus can include a longitudinal guide member and an adapter. An unlocking mechanism can be configured such that, while the adapter is coupled to the adjustment device, actuation of the unlocking mechanism moves the lock between the locked state and the unlocked state. Other applications are also described.

Abstract: A tissue-engaging element has a distal portion configured to engage a portion of tissue of the heart. A guide member is reversibly coupled to the tissue-engaging element. An artificial chorda tendinea has a distal end and a proximal end, at least the distal end being slidably coupled to the guide member. A tool is slidable along the guide member distally toward the tissue-engaging element while (i) the tool is coupled to at least the distal end of the chorda tendinea, and (ii) the guide member is coupled to the tissue-engaging element, such that sliding of the tool along the guide member distally toward the tissue-engaging element while (i) the tool is coupled to at least the distal end of the chorda tendinea, and (ii) the guide member is coupled to the tissue-engaging element, slides at least the distal end of the chorda tendinea toward the tissue-engaging element.

Abstract: Apparatus for facilitating anchoring of an anchor to a papillary muscle of a heart of a subject, the apparatus can include: (1) a housing, percutaneously deliverable to the heart, slidable along a guidewire, and shaped to define at least one opening; (2) a guide member, percutaneously deliverable to the heart, percutaneously removable from the subject, couplable to the housing, and having (a) a distal portion, including a chord-engaging element, configured to be percutaneously slidably coupled to at least one chorda tendinea of the heart, and decouplable from the at least one chorda, and (b) a proximal portion, including a longitudinal element; and (3) a deployment tool, configured (a) to be reversibly coupled to the anchor, (b) to be slidably coupled to the longitudinal element, and (c) to anchor the anchor to the papillary muscle. Other embodiments are also described.

Abstract: An apparatus can include: (1) a steerable tube, having a proximal section, a distal section, and a central longitudinal axis, the tube defining a primary lumen and two secondary lumens; (2) two wires, each extending from the distal section proximally through a respective secondary lumen; (3) a handle, coupled to the proximal section, and including a steering knob that is coupled to the wires such that rotation of the knob adjusts a degree of tension in the wires; (4) a pull ring coupled to the distal section of the tube such that the pull ring circumscribes the longitudinal axis at the distal section of the tube, and defining two recesses, a distal end portion of each wire being disposed in a respective one of the recesses; and (5) at least one cap, bridging the recesses and the distal end portion of the wires. Other embodiments are also described.

Abstract: A method for treating a heart valve of a patient includes inserting into a heart and in contact with a valve surface, an implant including an elongate element and a locking mechanism coupled to the elongate element. The locking mechanism has a resting position that provides a locked state preventing movement of the elongate element with respect to the locking mechanism. The heart valve is treated by facilitating movement of the elongate element with respect to the locking mechanism by maintaining application of a force to the locking mechanism using a tool, and thereby maintaining the locking mechanism in an unlocked state during the facilitating of the movement of the elongate element with respect to the locking mechanism. Subsequently, the locking mechanism is transitioned to the resting position by decoupling the tool from the locking mechanism.

Abstract: An implant structure includes a contracting mechanism, including a rotatable structure for contracting the implant structure, and a locking mechanism. A rotation tool is configured to engage and rotate the rotatable structure. A longitudinal guide member is removably coupled to the contracting mechanism, configured to guide the rotation tool to the rotatable structure, and includes a distal force applicator. The rotation tool is axially moveable with respect to the guide member. The contracting mechanism is arranged such that the locking mechanism is (a) unlocked when the guide member is coupled to the contracting mechanism in a first state, thereby allowing the rotatable structure to rotate, and (b) locked when (i) the guide member is coupled to the contracting mechanism in a second state, thereby restricting the rotation of the rotatable structure, and (ii) the guide member is not coupled to the contracting mechanism, thereby restricting the rotation of the rotatable structure.

Abstract: Apparatus includes a tube and an implant moveable at least in part through a lumen of the tube. The implant includes a longitudinal member and a locking mechanism coupled to the longitudinal member. The locking mechanism has (i) an unlocked state in which the locking mechanism is configured to facilitate adjustment of tension of the longitudinal member, and (ii) a locked state in which the locking mechanism is configured to restrict adjustment of the tension of the longitudinal member. A tool maintains the locking mechanism in the unlocked state via contact of the tool with the locking mechanism in the heart, and moves the locking mechanism into the locked state. The locking mechanism is disposed distally to the distal end of the tube while the longitudinal member is disposed entirely within the tube. Other applications are also described.

Abstract: A method is provided including inserting into a heart a tissue-adjusting member selected from the group consisting of: one or more artificial chordae tendineae and an annuloplasty ring structure. An adjusting mechanism of the tissue-adjusting member adjusts tension of the tissue-adjusting member. The adjusting mechanism: (a) includes a locking mechanism configured to restrict adjusting of the tissue-adjusting member by the adjusting mechanism, and (b) is shaped to define a first coupling. The method further includes, using a tool reversibly coupled to the adjusting mechanism, restricting the adjusting of the tissue-adjusting member by the adjusting mechanism, by facilitating movement of the locking mechanism into a locked state. The tool is shaped to define a second coupling that mates with the first coupling of the adjusting mechanism. The first and second couplings are coupled together and remain mated during the restricting of the adjusting of the tissue-adjusting member.

Abstract: During a percutaneous procedure, a flexible sleeve of an annuloplasty structure is introduced into an atrium and arranged completely around an annulus as a closed loop, such that none of one or more longitudinal contracting members thereof is positioned along an anterior portion of the annulus between fibrous trigones of the valve. The annuloplasty structure is fastened to the annulus. At least a portion of a posterior portion of the annulus is tightened, while preserving a length of an anterior portion of the annulus between fibrous trigones of the valve, by contracting, using the one or more longitudinal contracting members, a longitudinal portion of the sleeve not positioned along the anterior portion of the annulus between the fibrous trigones of the valve. Thereafter, the one or more longitudinal contracting members are locked.