Abstract: A method is described for use with a heart of a subject, the heart having a valve and an atrium upstream of the valve. The method includes transluminally advancing multiple tissue anchors to the atrium; and securing an elongate contraction member at least partly around an annulus of the valve by anchoring the tissue anchors to the annulus, such that the tissue anchors are distributed along the elongate contraction member. The method further includes subsequently contracting the annulus by applying tension the elongate contraction member, such that a radiopaque indicator that is disposed within the heart and that is coupled to the contraction member undergoes a conformational change in response to the tension. The conformational change of the radiopaque indicator within the heart is observed, and the tension is adjusted responsively to the observed conformational change. 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 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: 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: Apparatus is provided, including: (A) a valve body (204) including a first frame (206) shaped to define a lumen therethrough, and a valve member (205) disposed within the lumen, (B) an upstream support (210), configured to be placed against an upstream surface of a native heart valve, and (C) a flexible sheet (214) that couples the upstream support to the valve body. The valve body has a compressed state in which the first frame has a first diameter, and an expanded state in which the first frame has a second diameter that is greater than the first diameter. The support includes a second frame (212) that has a compressed state, and an expanded state in which the second frame is annular, has an inner perimeter that defines an opening through the second frame, and has an outer perimeter. 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 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: A first catheter has a first lumen therealong, a first-catheter proximal portion, and a steerable first-catheter distal portion that is transluminally advanceable to the heart. A second catheter has second lumen therealong, a second-catheter proximal portion, and a steerable second-catheter distal portion. The second catheter extends through the first lumen, such that the second-catheter proximal portion extends proximally out from the first-catheter proximal portion, the second-catheter distal portion extends distally out from the first-catheter distal portion, and within at least the first-catheter proximal portion, the first lumen and the second lumen are coaxial on a longitudinal axis. A first handle is coupled to the first-catheter proximal portion, and extends obliquely away from the first-catheter proximal portion at a nonzero angle with respect to the longitudinal axis. A second handle is coupled to the second-catheter proximal portion, and is disposed proximally from the first handle.

Abstract: A prosthetic valve comprises a valve body, comprising a tubular frame and a plurality of leaflets; an upstream support, comprising a second frame; and a flexible sheet that couples the upstream support to the valve body. The prosthetic valve is compressible into a delivery tool such that the prosthetic valve is in a compressed state in which the second frame and the tubular frame are arranged in series within the tool, and the valve body has a compressed body-diameter. The prosthetic valve is deployable from the tool such that the prosthetic valve automatically expands into an expanded state. In the expanded state, the second frame defines an inner perimeter, the sheet extends inwardly from the inner perimeter to the valve body, and the prosthetic valve defines a conduit through the upstream support and the valve body. Other embodiments are also described.

Abstract: 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.

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 prosthetic valve includes a tubular valve body, snares, and an upstream support. A native valve of a heart of a subject is disposed between an atrium and a ventricle of the heart, and has an annulus and leaflets. The prosthetic valve is advanced to the heart while in a compressed state. The prosthetic valve is positioned within the heart such that the snares are disposed upstream of the annulus and leaflets. The snares are expanded radially outwardly upstream of the leaflets. Subsequently, the prosthetic valve is moved in a downstream direction such that the snares become disposed downstream of the leaflets. While the snares remain downstream of the leaflets, the upstream support is expanded within the atrium, and the upstream support is placed against an upstream surface of the annulus. Other embodiments are also described.

Abstract: An annuloplasty implant is provided for treating a native atrioventricular valve of a patient, the annuloplasty implant including a plurality of tissue anchors, which are configured to anchor the annuloplasty implant around at least a portion of a valve annulus of the native atrioventricular valve. The annuloplasty further includes a contracting assembly, which includes an elongate contracting member; and a contracting mechanism, which is coupled to the elongate contracting member, and which is configured, upon actuation thereof, to apply a longitudinal contracting force to the elongate contracting member that longitudinally contracts at least a portion of the annuloplasty implant, thereby circumferentially tightening the valve annulus. The annuloplasty further includes a force-distributing element, which includes a longitudinally-non-compressible tightly-coiled element, and which is configured to distribute the longitudinal contracting force over at least two of the tissue anchors.

Abstract: A rod (508) is transfemorally advanceable to the heart. An implant (460) comprises (i) a first frame (462), compressed around a first longitudinal site of a distal portion of the rod, (ii) a second frame (464), compressed around a third longitudinal site of the distal portion, (iii) a valve member (50), disposed within the second frame, and (iv) a flexible sheet (466), coupling the first frame to the second frame, and disposed around a second longitudinal site of the distal portion, the second longitudinal site being between the first longitudinal site and the third longitudinal site. An extracorporeal controller (569) is coupled to a proximal portion of the rod, and is operably coupled to the distal portion of the rod. Operating the controller bends the distal portion of the rod causing articulation between the frames. Other embodiments are also described.

Abstract: A prosthetic valve is advanced to a heart of a subject while the prosthetic valve is in a compressed state thereof, the prosthetic valve including a plurality of snares coupled to a tubular valve body. The prosthetic valve is positioned within the heart such that the plurality of snares is disposed upstream of the leaflets, and the plurality of snares is expanded upstream of the leaflets. Subsequently the prosthetic valve is moved in a downstream direction such that the plurality of snares is disposed downstream of the leaflets. Subsequently, the prosthetic valve is secured at the native valve while the plurality of snares remains disposed downstream of the leaflets.

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.

Abstract: An example anchor-manipulation tool includes (i) at a distal portion of the tool, an anchor-engaging element and an actuator, (ii) at an extracorporeal proximal portion of the tool, a controller, and (iii) a flexible longitudinal member extending between the proximal portion and the distal portion. The distal portion of the tool can be transluminally advanced to an anchor that is intracorporeally implanted in a subject. Subsequently, the anchor-engaging element can be engaged with an eyelet defined by a head of the anchor. Subsequently, the controller can be used to transition the tool into an articulatably-coupled state in which: (i) the eyelet at least in part inhibits movement of the anchor-engaging element away from the anchor, and (ii) the distal portion of the anchor-manipulation tool is deflectable with respect to the anchor. Subsequently, the anchor can be de-anchored by using the anchor-manipulation tool to apply a de-anchoring force to the eyelet.

Abstract: A first element (91) includes a first arm (92) and a second arm coupled thereto and having a concavity (103) facing the first arm and defining a space (96). In an open state, a tissue anchor portion (46) moves into the space through a gap between distal portions (94) of the first and second arms. In the closed state, the anchor portion is not movable through the gap. A second element (82) is movable with respect to the first element, such that, while the portion (46) of the anchor (40) is within the space, and the first element is in the closed state, in a first position of the second element, the portion of the anchor is movable within the space, and in a second position of the second element, the second element applies torque to the anchor by rotating the second element. 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.