A medical implant is adapted to be implantable within a gallbladder in order to limit movement of any gallbladder stones present within the gallbladder. The medical implant includes a resilient body that is adapted to fit within the interior volume of the gallbladder and a plurality of pores that are formed within the resilient body. The pores are adapted to allow bile to flow through the pores.

Implants having symmetry are described. The implant may comprise a biocompatible material and have at least two planes of symmetry, including symmetry about an equator of the implant. The implant may be a body contouring implant, wherein a posterior side of the implant is symmetric about the equator to an anterior side of the implant.

Some embodiments described herein include a heart valve replacement system that may be delivered to a targeted native heart valve site via one or more delivery catheters. In some embodiments, a prosthetic heart valve of the system includes structural features that securely anchor the prosthetic heart valve to the site of the native heart valve. Such structural features can provide robust migration resistance. In particular implementations, the prosthetic heart valves occupy a smaller delivery profile, thereby facilitating a smaller delivery catheter for advancement to the heart.

Systems for mitral valve repair are disclosed where one or more mitral valve interventional devices may be advanced intravascularly into the heart of a patient and deployed upon or along the mitral valve to stabilize the valve leaflets. The interventional device may also facilitate the placement or anchoring of a prosthetic mitral valve implant. The interventional device may generally comprise a distal set of arms pivotably and/or rotating coupled to a proximal set of arms which are also pivotably and/or rotating coupled. The distal set of arms may be advanced past the catheter opening to a subannular position (e.g., below the mitral valve) and reconfigured from a low-profile delivery configuration to a deployed securement configuration. The proximal arm members may then be deployed such that the distal and proximal arm members may grip the leaflets between the two sets of arms to stabilize the leaflets.

A novel single plane tissue repair patch is disclosed. The patch has a base member with an opening therethrough, and a closure member associated with the opening. The mesh may be used in open surgical procedures for hernia repairs and other repairs of body wall defects.

An intravascular emboli capture and retrieval system for intravascular embolism protection and embolism removal or maceration. Guidewire mounted proximally and distally located multiple opening filters are deployed within the vasculature and used to part, divide and macerate embolic debris and to capture such embolic debris within the confines thereof. A deployable flexible preformed memory shaped capture sleeve is alternatively used to collapse one or more filters and embolic debris therein for subsequent proximal withdrawal from the vasculature.

An implantable device includes an adjustable spacer and at least one anchor. The adjustable spacer is configured to be positioned between native heart valve leaflets to reduce regurgitation therebetween. The adjustable spacer can comprise a first side and a second side opposite the first side. Each side can be adjustable between a first width and a second width. Each side can be independently moved between the first width and the second width. The adjustable spacer can be made from a sponge material.

Prosthetic heart devices may be implanted into the heart with a sensor coupled to the device, the sensor being configured to measure physiological data, such as blood pressure, in the heart. Devices that may employ such sensors include prosthetic heart valves and occlusion devices, although sensor systems may be deployed in the heart separate from other implantable devices. The sensors may include a body with different configurations for attaching to the implantable device, such as apertures for sutures or fingers for connecting to structures of the implantable device. The sensors may provide data that allow a determination of aortic regurgitation or other information indicative of function of the implantable device and patient health during and after implantation of the device.

Gluteal implants and gluteal implant systems are described herein, as are methods of manufacturing and implanting the same. In certain embodiments, the gluteal implant includes a body having a convex upper surface, a concave lower surface, and an edge, the edge being formed by the intersection between the convex upper surface and the concave lower surface. The body can take on various shapes, including a truncated ovoid shape, a truncated approximate ovoid shape, a truncated substantially ovoid shape, a truncated ellipsoid shape, a truncated approximate ellipsoid shape, or a truncated substantially ellipsoid shape, among others. In certain embodiments, the gluteal implant system includes first and second gluteal implants that have the same or different shaped bodies. In certain embodiments, the gluteal implants and gluteal implant systems are implanted in a buttock region.

A catheter that includes storage for an embolic protection device in an accessible, out-of-the-way location within the advancing catheter.