Instrumentation for implanting a cervical disc replacement device includes cervical disc replacement trials for determining the appropriate size of replacement device to be implanted, an insertion plate for maintaining the elements of the replacement device in fixed relation to one another for simultaneous manipulation, an insertion handle for attachment to the insertion plate for manipulation of the elements, an insertion pusher for releasing the insertion handle from the insertion plate, a drill guide that cooperates with the insertion plate to guide the drilling of tap holes for bone screws to be placed through bone screw holes in the flanges of the replacement device, clips that are applied to the flanges after placement of the bone screws to resist screw backout, and a clip applicator for applying the clips to the flanges.

A system for an anatomical joint includes a first fastener, a second fastener, a prosthetic ligament member, and a biasing member associated with at least one of the first and second fasteners. The first fastener is operable to be connected to a first bone portion. The second fastener is operable to be connected to a second bone portion. The prosthetic ligament member is flexible and is directly coupled to both the first and second fasteners to support the first bone portion and the second bone portion for relative movement. A portion of the prosthetic ligament member extends from the first fastener to the second fastener and has an adjustable length. The biasing member is operable to bias the prosthetic ligament member to thereby maintain tension in the prosthetic ligament member.

An annuloplasty ring including elastic features that make the ring optimal for receiving a subsequent prosthetic valve via a “Valve In Ring Procedure.” The elastic features provide a squeezing force on the native valve annulus that both ensures coaptation of the native valve leaflets and also prevents paravalvular leakage around a subsequently-placed prosthetic valve.

An embolic protection device including a porous deflector screen including a filter, arranged to expand and to conform to a wall of the aortic arch covering entrances to arteries branching from an aorta, an emboli collector including a cylinder arranged to expand and to lie along walls of a descending aorta, pushing against walls of the descending aorta and anchoring the porous deflector screen, and a connecting portion for connecting the porous deflector screen and the emboli collector, arranged to push the porous deflector screen against a wall of the aortic arch while anchoring against the emboli collector. Related apparatus and methods are also described.

A tissue lumen stent is provided with a body having an elongated tubular configuration and a foreshortened configuration. In the foreshortened configuration, downstream and upstream ends of the body expand radially into downstream and upstream flange structures, leaving a generally cylindrical saddle region therebetween. In some embodiments, the flange structures are non-symmetrical with respect to one another. Systems and methods of using the stents are also disclosed.

The invention relates to a transcatheter heart valve replacement (A61F2/2412), and in particular Compression Capable Annular Frames for a side delivered transcatheter prosthetic heart valve having a annular support frame having compressible wire cells that facilitate rolling and folding the valve length-wise, or orthogonally to the central axis of the flow control component, allowing a very large diameter valve to be delivered and deployed to the tricuspid valve from the inferior vena cava or superior vena cava, or trans-atrially to the mitral valve, the valve having a height of about 5-60 mm and a diameter of about 25-80 mm, without requiring an oversized diameter catheter and without requiring delivery and deployment from a catheter at an acute angle of approach.

The present disclosure relates generally to the field of medical devices. In particular, the present disclosure relates to medical devices for facilitating the flow of fluids and materials in a lumen and/or between adjacent body lumens; for example, a stent which maintains an open flow passage between body lumens. In one example, a stent may comprise first and second flanges and an elongate body therebetween. The elongate body may extend outwardly beyond the elongate body such that ends may be doubled back into the respective first and second flanges.

The present disclosure relates generally to the field of medical devices. In particular, the present disclosure relates to medical devices for facilitating the flow of fluids and materials in and/or between adjacent body lumens, for example, a stent which maintains an open flow passage between body lumens. In one example, a stent may have a constrained configuration and an expanded configuration. In the expanded configuration, the stent may have first and second retention members and saddle region extending therebetween. The saddle region may comprise a coil configured to apply a restoring force to tissue surfaces respectively apposed to the first and second retention members.

Annuloplasty implant systems and methods of deployment within a catheter-based procedure are provided herein. Such systems can utilize annuloplasty rings defined by a scaffold of braided wire that is radially expandable and axially collapsible or by annuloplasty rings defined by multiple interconnected concentric loops. The rings can be formed of a memory alloy and expand to an implantation configuration when advanced from the catheter to be secured against the valve annulus with the anchors. Deployment systems can include delivery catheters that deploy multiple anchors about a valve annulus, and advance the annuloplasty ring over multiple torque wires to securely couple the ring with the anchors forming the annuloplasty ring thereby reforming the valve annulus.

An annuloplasty repair segment for heart valve annulus repair and a method for forming. A multi-stranded cable replaces solid core wire for both the tricuspid and mitral valves which allows for greater deployment flexibility for minimally-invasive surgical (MIS) implant, while still maintaining the required strength and similar tensile properties of solid-core wire. The particular shape of the annuloplasty ring is fixed using a heat setting process including heating the flexible core member to a temperature higher than 500° C. and holding it in a desired heat-set saddle shape for a period of time. The core is then rapidly cooled to impart physical properties such that the flexible core member can be straightened, during implantation, to fit through a tubular access device and regain the heat-set saddle shape after exiting the access device and, when attached to the native heart valve, the flexible core member is strong enough to remodel the native heart valve.