Apparatus and methods are described for treating a subject with a diseased mitral valve. A docking element is implanted within the subject's left atrium such that no portion of the docking element extends through the subject's mitral valve. The docking element includes a ring having a smaller size than that of the subject's mitral annulus, and which configured to be implanted within 15 mm of the mitral annulus. A frame extends upwardly from the ring, a portion of the frame being configured to be disposed in a vicinity of the mitral annulus and to generate tissue ingrowth from the subject's atrial walls in the vicinity of the mitral annulus. A material disposed between the portion of the frame and the ring is configured to form a seal between atrial walls in the vicinity of the mitral annulus and the ring. Other applications are also described.

Embodiments of the disclosure include methods and compositions related to repair of weakenings or openings in a tissue of an individual, including at least a muscular wall, for example. In specific cases, a mesh comprising phosphate crosslinked poly(vinyl alcohol) polymer (PVA-P) is utilized for such methods, including for hernia repair of any kind. In particular embodiments, one side of the mesh comprises decellularized gel matrix to provide for enhanced tissue healing.

Glaucoma treatment devices are disclosed. In various example, the glaucoma treatment devices include a body and a fluid conduit that are configured to help facilitate evacuation of fluid from a fluid-filled body cavity, and reabsorption of the evacuated aqueous humor by the body through tissue surrounding the glaucoma treatment device. In some examples, the glaucoma treatment device is configured such that a flow resistance through the fluid conduit can be modified post-operatively one or more times.

The present invention relates to a bio-functionalized fibrous structure with a core/shell architecture for partial or total repair of human tendons or ligaments. The architecture based on a core/shell system grants to the fibrous structure a specific physical and mechanical behaviour when it is repeatedly mechanically loaded, as happens with a native tendon or ligament in constant usage in the human body. The core is based on several sub-components, namely braided structures parallelly assembled, which are enclosed by a braided shell. Additionally, a selective bio-functionalization of the two parts of the core/shell structure can be applied in order to selectively improve or avoid the in vivo cell adhesion.

The invention relates to a metallic, nanoporous canister used to encapsulate cellular and/or biotherapeutic agents. The device is biocompatible and functions to wholly isolate a therapeutically active agent and/or cells therein. Their implantation, and survival in vivo, permits the local or systemic diffusion of their encapsulated cellular and/or biomolecular and therapeutics factors with the potential to promote repair of damaged or degenerated tissues in mammalian hosts, primarily humans.

The present disclosure relates generally to stents, systems, and methods for gastrointestinal treatment. In some embodiments, a stent may include a tubular scaffold having a first end opposite a second end, wherein a lumen extends between the first and second ends. The tubular scaffold may include a flared section and a medial section extending from the flared section, wherein a first diameter of the flared section is greater than a second diameter of the medial section. The stent may further include a liner extending partially along a surface of the tubular scaffold, wherein the liner is spaced from an anchoring region of the flared section to promote tissue ingrowth with the flared section.

Disclosed in the present invention are a stent apparatus having a self-pleated skirt, a processing method therefor, a skirt pleating method, and a cardiac valve. The stent apparatus comprises a stent, and is further provided with a flexible skirt. The skirt comprises: an unfolded state, where the skirt extends axially and surrounds the periphery of the stent before release; and a stacked state, where the skirt is driven by deformation during release of the stent, and gathers and is stacked along an axial direction of the released stent to form an annular perivalvular leakage blocking part. The stent apparatus is further provided with a pull-wire which is merely threaded on the skirt, and the pull-wire may react to the radial deformation during the release of the stent to drive the skirt to enter the stacked state. According to the present invention, based on perivalvular leakage prevention technology, an interventional stent is fitted with the lining of the blood vessels, so that the stent will not easily be migrated and is more stable, the scope of the applicable population is expanded, additional surgical risks are lowered, and perivalvular leakage, thrombi and other complications are prevented. Better hemodynamic performance is provided, the coverage function of endothelial cells of the host is enhanced, the probability of occurrence of endocarditis is lowered, and the normal blood supply function of the heart and blood vessels is recovered.

An apparatus is provided for draining aqueous humor from an eye for reducing intraocular pressure. The draining apparatus comprises a tube defining a passage for fluid flow between an inlet end and an outlet end. An outlet assembly contacts the conjunctival layer externally of the eyeball. The outlet assembly comprises a housing in fluid communication with the outlet end of the tube and having an aperture for allowing egress of aqueous humor onto the external ocular surface. A resistive component is disposed in the housing for providing resistance to a flow of aqueous humor. A pair of tabs project outwardly and are adapted to be disposed subconjunctivally for securing the draining apparatus relative to the eyeball.

A sphincter assist device includes a plurality of interconnected and adjacent links which define a ring. Each link includes a body section and a latch cam. The body section includes a first set of side beams and a first set of snap arms. The latch cam includes a post extending from the body section and a cam disposed at an end portion of the post. The cam is engagable with the first set of snap arms of an adjacent link. Translation of the cam displaces the first set of snap arms and the first set of side beams to transition the sphincter assist device between open and closed configurations. The first set of snap arms, in combination with the first set of side beams, exert a positive non-linear force profile on the cam, thus defining a non-linear force profile of the sphincter assist device between the open and closed configurations.

A surgical implant (20) comprises a flexible, areal basic structure (22) having a first face and a second face and being provided with pores (26) extending from the first face to the second face. A barrier layer (24) having a first face and a second face is placed, with its second face, at the first face of the basic structure (2) and attached to the basic structure (22). The barrier layer (24) is deformed into at least part of the pores (26) where it forms, in a respective pore (10), a barrier region (28).