An annuloplasty device is disclosed for treating a defective mitral valve having an annulus, comprising a removable and flexible elongate displacement unit for temporary insertion into a coronary sinus (CS) adjacent the valve, wherein the displacement unit has a delivery state for delivery into the CS, and an activated state to which the displacement unit is temporarily and reversibly transferable from said delivery state, the displacement unit comprises a proximal reversibly expandable portion, a distal anchoring portion being movable in relation to the proximal expandable portion in a longitudinal direction of the displacement unit to said activated state in which the shape of the annulus is modified to a modified shape, wherein the proximal expandable portion is reversibly foldable to an expanded state for positioning against a tissue wall at the entrance of the CS.

A method of making an annuloplasty implant includes forming first and second support rings arranged in a coiled configuration around an axial direction and forming at least part of the first and second support ring from a carbon fiber material. The first and second support rings can be formed by 3-D printing according to dimensions of a 3-D reconstruction of a heart valve.

A biomimetic tissue scaffold for repairing an elongated tissue in need of repair can comprise a plurality of coiled flexible polymeric ribbons having a surface on which is formed an array of nanofibers, the ribbons forming a tubular body defining a first open end in which a first end of the elongated tissue is receivable, a second open end in which a second end of the elongated tissue is receivable, and a lumen extending between the first and second open ends.

Apparatus and methods are described including a docking element (20) configured to be implanted within a subject's left atrium such that no portion of the docking element (20) extends through the subject's mitral valve. The docking element (20) includes a ring (40), a frame (24) extending upwardly from the ring (40), and a radial protrusion (50) configured to extend radially outwardly from the frame, to be disposed in a vicinity of the subject's native mitral annulus, and to generate tissue ingrowth to the radial protrusion from walls of the left atrium at least in the vicinity of the subject's native mitral annulus. A bridging material (56), which is disposed between radial protrusion (50) and the ring (40), forms a seal between the radial protrusion (50) and the ring (40). Other applications are also described.

A branched and fenestrated prosthesis may include a main tubular graft body including a proximal end opening, a distal end opening, a lumen, and a sidewall. A branch may extend from the sidewall and may include a first end opening, a second end opening, and a lumen. A fenestration may be disposed in the sidewall and positioned distal of the second end opening of the branch. The branched and fenestrated prosthesis may include a plurality of branches and a plurality of fenestrations.

A catheter device and manufacturing process for manufacturing the catheter device, wherein the catheter device has a halo-shaped coiled portion extending away from a perpendicular stem portion through a swan neck portion. Eyelets on the halo coil portion and swan neck portion facilitate flow out of the bladder through the catheter device vertical to the catheter, rather than perpendicularly as is the case with existing catheters. The catheter device is formed by using a straight catheter tube, heating and cooling it within a formed mold to have the halo coil and swan neck, such that it can be straightened using a pusher and stylet, inserted into the body while straightened, and thereafter return to its coiled shape when the stylet is removed.

Systems and methods for native heart valve repair includes an anchor. The anchor includes an anchor body configured to transition from a first configuration, in which the anchor body is straightened for transvascular delivery to the native heart valve, to a second configuration comprising at least two turns for implanting at the native heart valve. Two or more of the at least two turns in the second configuration have a diameter smaller than a major axis of the native heart valve.

A surgical medical device includes a rod portion and a support portion extending from the rod portion. The support portion has a first stretch segment, a second stretch segment, and a third stretch segment disposed between the first stretch segment and the second stretch segment. The surgical medical device has a control mechanism. The surgical medical device stretches or contracts the first stretch segment, the third stretch segment and the second stretch segment by the control mechanism.

An implantable device includes a conduit, an adjustable membrane element coupled to the conduit near the front end of the conduit for controllable coaptation of a body lumen, such as coaptation of a urethra as treatment for urinary incontinence, and a helix coupled to the front end of the conduit. The helix functions as a fixation mechanism to anchor the implantable device to the tissue. The implantable device can be inserted into tissue using a sheath and can be rotated with the sheath by partially inflating the adjustable membrane element placed in a front end portion of the sheath, and the helix can be turned into the tissue by rotating the sheath.

An implant, system, and method of deployment includes a plurality of anchor housings coupled to one of the proximal end or distal end of an implant frame. Each anchor housing may include an anchor sleeve disposed within a bore of the anchor housing, the anchor sleeve having a lumen extending therethrough including features disposed on an internal wall of the lumen for translatably supporting at least one anchor. Each anchor sleeve may be independently translatable within the bore of the anchor housing to control a distal extent of travel of the at least one anchor through the at least one anchor housing.