Expandable devices are disclosed herein. Several of the embodiments are directed towards an expandable device comprising a stent configured to be expanded within a body conduit of a human patient. The stent may comprise a tubular sidewall having first portions and second portions. Radial expansion of the stent may cause the first portions to bow outwardly and out of radial alignment with the second portions.

Disclosed are an artificial prosthesis and a method for manufacturing same. The artificial prosthesis includes a surface having a pattern formed thereon, the pattern comprising straight line shapes aligned in parallel with each other, and has the effect of reducing inflammation in a region implanted with the prosthesis, and effectively reducing capsular contracture side effects.

A stent delivery system can include a core member having a distal portion, where the distal portion is configured to be positioned within a lumen of the stent; a cover having a first end portion coupled to the distal portion of the core member and a free second end portion, the cover having (a) a first position in which the second end portion of the cover is configured to at least partially surround a proximal end portion of the stent while the stent is positioned over the core member in a compressed state, and (b) a second position in which the second end portion of the cover is uncoupled from the stent; and a shoulder coupled to the distal portion of the core member at a location distal to the first end portion of the cover, the shoulder configured to abut the proximal end portion of the stent.

The present invention relates to the diagnosis and treatment of joint-related diseases, in particular osteoarthritis. Based on the analysis of the microarchitecture, such as microchannels, of the subchondral bone, the present invention provides methods for evaluating the health state of a joint as well as determining whether a joint is prone to develop or has already developed a disease correlated to joint and cartilage destruction. The invention further provides for membranes and other implants mimicking healthy subchondral bone structure suitable for promoting regeneration of joint structure and function.

A hair implant includes: (a) a hair strand anchor including: an anchor body; at least one hair chamber disposed within the anchor body; and at least one tunnel through the anchor body, where the tunnel is free of a hair; and (b) at least one hair strand having a portion thereof retained in the at least one of the hair chamber; wherein the tunnel is configured to support collagen ligature growth after subcutaneous implantation by receiving and retaining collagen ligatures that anchor the hair implant to a hair implant recipient. Also disclosed is a hair implant including an anchor with first and second anchor bodies and at least one bridge connecting the anchor bodies and bridging at least one void between the anchor bodies, wherein the bridge supports and retains collagen ligature growth. One-piece implants are also disclosed, as are anchors, hair restoration and manufacturing methods.

Methods of forming topographical features on an article, for example on a medical devices that has a surface configured to promote the migration of cells onto the surface of the medical device. In particular, the resulting surface of the medical device has a noncontiguous pattern of topographical features formed therein or thereon.

Methods of delivering a prosthetic aortic heart valve are disclosed. The disclosed methods include loading a prosthetic aortic valve in a collapsed configuration into a delivery sheath so that a selected point on the prosthetic valve is rotationally aligned relative to a long axis of the delivery sheath with a selected radiopaque marker on the delivery sheath, while under fluoroscopic imaging, rotating the delivery sheath about its long axis to align a selected radiopaque marker on the delivery sheath with the selected point on the native aortic valve in a fluoroscopic imaging plane, thereby establishing a desired orientation of the prosthetic aortic valve with respect to the native aortic valve in which the prosthetic valve commissures are rotationally aligned with commissures of the native aortic valve, further advancing the delivery sheath along its long axis until the prosthetic aortic valve is disposed inside the native aortic valve, and deploying the prosthetic aortic valve into an implanted state inside the native aortic valve with the prosthetic aortic valve aligned in the desired orientation with respect to the native aortic valve.

The Nucleo-reticular Multi-cell Dual-system Eye Implant consists of a spherical structure with calculated and variable axial length depending on the needs required by the orbital eye socket, composed of a cell mesh with alternative designs that in turn, makes up the MMM System, in which suturing is provided in any technique, either in cases of evisceration or enucleation. Thanks to its multi-cell structural design, it favors its placement and reduces the risk of migration, extrusion, exposure and extraction. As it is an arrangement with structural holes, it provides a higher percentage of the volume for its vascularization; it also houses inside a Reticular Fibrovascular Core System, which has a structure based on multilevels equipped with micro-reticular tissue and an intra-level communication based on filaments; with the capacity to contain medicines and/or technology by presenting a dual-system of two screw-on pieces, being able to manufacture in different structural designs and biocompatible materials. The C100 model made of polylactic acid (PLA), an ideal material for implants, consists of 100 oval cells. Since it is a light eye implant, it prevents depressure due to settlement or gravity and it can be manufactured in any size.

This disclosure relates generally to prosthetic valves and methods and systems for deploying, positioning, and recapturing the same. A prosthetic valve includes one or more support structures. At least one of the one or more support structures defines an elongate central passageway of the prosthetic valve. The prosthetic valve can also include a plurality of leaflet elements attached to at least one of the one or more support structures and disposed within the elongate central passageway for control of fluid flow through the elongate central passageway. At least one of the one or more support structures is configured to biodynamically fix the prosthetic valve within a native valve such as, for example, a native tricuspid valve of a heart.

A composite scaffold having a highly porous interior with increased surface area and void volume is surrounded by a flexible support structure that substantially maintains its three-dimensional shape under tension and provides mechanical reinforcement during repair or reconstruction of soft tissue while simultaneously facilitating regeneration of functional tissue.