Methods, devices and systems for anchoring and/or sealing a heart valve prosthesis and, in particular, a mitral valve prosthesis (202). Inflatable elements (204, 206) are used to seal and anchor the mitral valve prosthesis (202) and/or other elements associated with repairing a native mitral valve.

Embodiments of a modulable absorption light adjustable lens (MALAL) comprise a light adjustable lens that is capable of changing its optical properties upon an adjusting irradiation, including a photo-modifiable material; and a modulable absorption front protection layer, including a modulable absorption compound whose absorption properties can be modulated with a modulating stimulus. Other embodiments include a method of adjusting an optical property of a modulable absorption light adjustable lens, the method comprising: reducing an absorption of a modulable absorption compound of a modulable absorption front protection layer of the MALAL by a modulating stimulus, the MALAL having been previously implanted into an eye; and changing an optical property of a light adjustable lens of the MALAL by applying an adjusting irradiation.

An implantable prosthesis and a method of attaching the prosthesis to a tissue structure disclosed. The prosthesis includes a body having a first side arranged to face the tissue structure having a defect and second side opposite the first side. One or more adhesive-filled pods are disposed on the first side of the body and selectively openable to supply an adhesive in between the tissue structure and the first side of the prosthesis body after the prosthesis body is positioned relative to the defect. The pods may be pierced, punctured, broken, and/or ruptured to supply the adhesive. A deployment device having a piercer may be used to puncture the pods.

A suction stent for introduction into a hollow organ of the human or animal body, preferably into the gastrointestinal tract, in particular the intestine, includes a tubular hollow body which is open in the longitudinal direction and made of biocompatible material. The tubular hollow body has a fixed diameter at least in its central portion. A porous shapeable material, preferably a sponge material, which is biocompatible and shapeable in the radial direction, radially sheaths the tubular hollow body at least in a section of the tubular hollow body. A method for sealing a leakage, especially an anastomosis, of the hollow organ utilizes the stent.

Additive manufacturing techniques are used to form an artificial intra-ocular lens (IOL) directly inside the human eye. Small openings are formed in the cornea and lens capsule of the eye, and the crystalline lens is broken up and removed through the openings; then, a material is injected into the lens capsule through the openings, and the focal spot of a pulse laser beam is scanned in a defined pattern in the lens capsule, to transform the material in the vicinity of the lase focal spot to form the IOL in a layer-by-layer manner. In one embodiment, stereolithography techniques are used where a pulse UV laser source is used to photosolidify a photopolymer resin. The liquefied resin is injected into the eye through the openings, after which only part of the resin, having the shape of the desired IOL, is selectively cured with the UV laser beam, via progressive layer formation.

Some implementations of the described invention relate to systems and methods for applying a total contact cast to a patient for treatment of a wound on an appendage, such as a leg or foot. While the cast system can comprise any suitable component, in some cases, it includes a clam-shell cast, a foot support defining (or customizable to define) an offloading hole, and a cast underlayment (such as a compression sock, a padding sock, and/or additional padding). In some implementations, a first length of the clam-shell cast is applied to a patient's calf, a second length of the cast is applied to across a patient's foot, and a third length is folded up over the patient's foot to extend up a portion of the patient's calf. In some cases, a strap or wing is used to attach the first and the third lengths together. Other implementations are also described.

Spinal tissue distraction devices that include a member which has a pre-deployed configuration for insertion between tissue layers and a deployed configuration in which the member, by change of configuration, forms a support structure for separating and supporting layers of spinal tissue.

An inter-vertebral disc prosthesis intended for percutaneous deployment comprises an expandable annular enclosure and an expandable nuclear enclosure. The expandable annular enclosure incorporates a reinforcing annular band along its periphery and is filled with in-situ curable rubber. The expandable nuclear enclosure is filled with a gas. The nuclear prosthesis further incorporates a novel, integrally molded sealing valve assembly and is stretchable and collapsible into a minimal profile for ease of insertion into a specially designed delivery cannula, and is inflation-assisted expandable into an inter-vertebral disc in which complete percutaneous nuclectomy has been performed.

A tissue insertion prosthesis system includes an expansible, multi-chambered implant for use in a tissue prosthesis receiving cavity, such that the implant includes an expansible envelope having a plurality of chambers. The system also includes a method of determining a size of a cavity at a site to be filled by a tissue prosthesis. Finally, the system includes a method to facilitate a removal of a biomaterial delivery device from an inflatable member that has been inserted into a cavity formed by the removal of a portion of a nuclear material from an intervertebral disc and to be filled by a tissue prosthesis.

A method for treating hyperopia or presbyopia in a patient, the method comprising making a cut deep in the patient's cornea to create a two-dimensional slit adjacent to and generally parallel to an anterior surface of the cornea and injecting a liquid or semi-solid transparent filler material into the deep cut in an amount sufficient to flatten the posterior surface of the cornea to increase the refractive power of the cornea by a predetermined correction of up to about 5 diopters due to the physical flattening of the posterior surface of the cornea, wherein the transparent filler material comprises a refractive index of about 1.3 to about 1.6, and forms a corneal implant with a lenticular shape within the cornea.