A method of using an implantable device provides an implantable device including a plurality of links (113, 115, 117, 119), a device closure pin (111), a lock-in unit (103) attached and located between two links, and a quick release unit (105) attached and located between two links. The plurality of links (113, 115, 117, 119), lock-in unit (103) and release unit (105) are constructed in a closed contour. The closed contour of the implantable device, in a rigid state (151), is a figure eight comprised of two arcs (125, 127) and two connected interconnecting sections (131, 133).

A method includes advancing a delivery assembly through a patient's vasculature toward a native heart valve of the patient, wherein the delivery assembly comprises a first catheter assembly and a second catheter assembly extending through a shaft of the first catheter assembly, and wherein a support member is in an uncoiled, elongated configuration within a sheath of the first catheter assembly. The support member is deployed from the sheath by pushing the second catheter assembly distally relative to the first catheter assembly so that the support member is uncovered by the sheath and the support member extends around native chordae tendineae and/or native leaflets of the native heart valve. A prosthetic valve is implanted within the native leaflets of the native heart valve such that the native chordae tendineae and/or native leaflets are frictionally engaged between the support member and the prosthetic valve.

An apparatus for delivery of a device into a hollow organ and a method of delivery are provided. The apparatus includes an elongated tube having proximal and distal openings and being configured for carrying the device on a distal portion thereof. The apparatus further includes a tubular cover for covering at least a portion of the device when mounted on the elongated tube, the tubular cover being radially elastic and axially non-elastic. The tubular cover is retrievable into the elongated tube through the distal opening, such that when the device is mounted on the elongated tube and covered by the tubular cover, retrieval of the tubular cover into the elongated tube uncovers the device for delivery into the hollow organ.

A method of delivering a prosthetic mitral valve includes delivering a distal anchor from a delivery sheath such that the distal anchor self-expands inside a first heart chamber on a first side of the mitral valve annulus, pulling proximally on the distal anchor such that the distal anchor self-aligns within the mitral valve annulus and the distal anchor rests against tissue of the ventricular heart chamber, and delivering a proximal anchor from the delivery sheath to a second heart chamber on a second side of the mitral valve annulus such that the proximal anchor self-expands and moves towards the distal anchor to rest against tissue of the second heart chamber. The self-expansion of the proximal anchor captures tissue of the mitral valve annulus therebetween.

The invention discloses an auxiliary balloon structure for transcatheter aortic valve replacement (TAVR), which comprises a balloon head and a balloon body. When unexpanded, the balloon body has two conical ends and a cylindrical middle part. The conical ends are defined as a front and a rear conical part. The cylindrical middle part is provided with a mastoid structure. The front and rear conical parts are made of a semi-compliant material, while the cylindrical middle part is made of a non-compliant material.

A device includes a balloon and an interface. The balloon has an outer surface and a central lumen aligned on a longitudinal axis. The balloon is configured to receive a compressible fluid. The interface is coupled to the outer surface and has an external surface configured to bond with a tissue.

A surgically implanted occluding assembly comprises an implant body having a longitudinally split generally “C”-shaped cross-section tube circumscribing an anatomical lumen. In one embodiment, the surgically implanted occluding assembly is a male continence device selectively occluding a urethra. In some embodiments an occluding magnet is rigidly affixed with the implant body, and an external selective occlusion control assembly is used to selectively activate the surgically implanted occluding assembly. The external assembly has a magnet, and body supporting the magnet. The external selective occlusion control assembly is configured to be selectively placed and retained adjacent to the surgically implanted occluding assembly. In some embodiments, a bi-stable spring longer than and spanning the longitudinal split in the implant body has a first stable anatomical lumen occluding position curved into an interior of the longitudinal split, and a second stable anatomical lumen open position curved outward exterior of the longitudinally split tube.

The present disclosure describes various embodiments of adjustable implants, particularly permanent breast implants, intended for implantation into a subject, particularly a human subject. In some embodiments, the adjustable implant comprises a shell including a resilient shell membrane, a first reservoir containing a fluid, e.g., a saline, a second reservoir including a resilient second-reservoir membrane, and a pump. The pump may include a first pump actuator, a first pump inlet, and a first pump outlet. The first reservoir and second reservoir may be disposed within the shell and be in fluid communication via the pump. Fluid may be transferred between the two reservoirs to change the profile of the implant.

Features for a restraint to facilitate delivery and deployment of an implantable cardiac device are described. The restraint may include a series of circumferential engagements for securing inwardly corresponding portions of the implant. The restraint may be located inside the implant and provide a radially inward force on the implant. The restraint may include a center shaft having a series of grooves configured to cooperate with corresponding splines of the implant. Distal or proximal advance of the restraint disengages the restraint from the implant. The implant may include a tubular frame configured to contract and be secured by the restraint in a contracted configuration and to expand upon disengagement from the restraint. The restraint may provide for a smaller overall cross-sectional profile of a transcatheter delivery system, for instance by negating the need for a distal delivery sheath.

A method of delivering a prosthetic mitral valve includes delivering a distal anchor from a delivery sheath such that the distal anchor self-expands inside a first heart chamber on a first side of the mitral valve annulus, pulling proximally on the distal anchor such that the distal anchor self-aligns within the mitral valve annulus and the distal anchor rests against tissue of the ventricular heart chamber, and delivering a proximal anchor from the delivery sheath to a second heart chamber on a second side of the mitral valve annulus such that the proximal anchor self-expands and moves towards the distal anchor to rest against tissue of the second heart chamber. The self-expansion of the proximal anchor captures tissue of the mitral valve annulus therebetween.