A delivery apparatus comprises a handle portion and at least one rotatable drive shaft. The handle portion has an actuation mechanism and a display. The actuation mechanism includes a motor and one or more actuators. The rotatable drive shaft has a proximal end portion and a distal end portion. The proximal end portion is coupled to the motor, and the distal end portion is configured to be releasably coupled to a prosthetic heart valve. The actuation mechanism is configured to control and monitor expansion of the prosthetic heart valve, and the display is configured to display a diameter of the prosthetic heart valve.

A braided stent system includes a stent body having a lumen formed by a plurality of braided members with interstices formed therebetween and a first expansion ring connected to the lumen of the stent body. The first expansion ring may include a frame defined by a plurality of interconnected support assemblies that are selectively positioned to impart an outwardly expanding radial force to the stent body, each support assembly can include a plurality of legs joined at a first intersection and connected to one of the other interconnected support assemblies at a second intersection opposite the first intersection. Each support assembly can include a claw portion mechanically connected to one or more of the interstices of the stent body so that the frame imparts an outward radial expansion force of the stent to facilitate use and delivery of the stent.

The present invention discloses a rolled up radially self-expanding stent comprising at least one transverse expandable member of non-shape memory alloy sheet or wire loops laminated in a polymer and rolled up in a configuration that stores elastic energy and retains flexibility, arranged on a longitudinal axis used to improve the lumen patency of non-vascular body lumens. The radial expansion of the stent is caused by unrolling of the rolled up transverse expandable member during deployment in the body lumen.

Disclosed are systems and methods relating to an implant configured for reshaping a mitral valve. The implant comprises a plurality of struts with anchors for tissue engagement. The implant is compressible to a first, reduced diameter for transluminal or transapical navigation and delivery to the left atrium of a heart. The implant may then expand to a second, enlarged diameter to embed its anchors to the tissue surrounding and/or including the mitral valve. The size and/or shape of the implant may then be adjusted, pulling mitral annulus tissue radially inwardly, and restrained in the adjusted configuration to improve mitral valve function.

An organ lengthening device comprising a spring-like structure, wherein the surface of the device is covered with micron-size anchors such as hooks, studs or wires made from a biodegradable polymer. The anchors are configured to engage the surface of the organ so that the device will be anchored to the organ. The device, which is inserted into the organ in a compressed position, gradually lengthens over time, thereby lengthening the organ, wherein the anchors are configured to degrade away and eventually allow the device to become disengaged from the organ.

An organ lengthening device comprising a spring-like structure, wherein the surface of the device is covered with micron-size anchors such as hooks, studs or wires made from a biodegradable polymer. The anchors are configured to engage the surface of the organ so that the device will be anchored to the organ. The device, which is inserted into the organ in a compressed position, gradually lengthens over time, thereby lengthening the organ, wherein the anchors are configured to degrade away and eventually allow the device to become disengaged from the organ.

A radially expandable, tubular stent, includes a first section having a first crush resistance force and a second section have a second crush resistance force, wherein the first crush resistance force is less than the second crush resistance force. The first section is connected to the second section to form a tube, connection of the first and second sections extending in an axial direction of the tube.

Excessive dilation of the annulus of a mitral valve may lead to regurgitation of blood during ventricular contraction. This regurgitation may lead to a reduction in cardiac output. Disclosed are systems and methods relating to an implant configured for reshaping a mitral valve. The implant comprises a plurality of struts with anchors for tissue engagement. The implant is compressible to a first, reduced diameter for transluminal navigation and delivery to the left atrium of a heart. The implant may then expand to a second, enlarged diameter to embed its anchors to the tissue surrounding and/or including the mitral valve. The implant may then contract to a third, intermediate diameter, pulling the tissue radially inwardly, thereby reducing the mitral valve and lessening any of the associated symptoms including mitral regurgitation.

Disclosed are devices, systems, and methods for pulmonary vein ostium and pulmonary vein prosthetic implants for creating a region of scar tissue (non-conductive) in or near one or more pulmonary veins and the superior venacava.

Disclosed are devices, systems, and methods for pulmonary vein ostium and pulmonary vein prosthetic implants for creating a region of scar tissue (non-conductive) in or near one or more pulmonary veins and the superior venacava.