Biomaterials and methods and uses for repair or augmentation of tissues are provided. In particular, the invention provides a multi-layered, naturally occurring multi-axial oriented biomaterial comprising predominately type I collagen fibers. The invention further provides methods and uses for repair or augmentation of tissues using biomaterials of the invention.

The present invention relates to a silicone-gel-coated, adhesive layer structure, a method for the production thereof as well as the use thereof. The layer structure comprises a porous backing material, an intermediate layer applied to one side of the porous backing material and an adhesive layer made of a silicone gel applied to the intermediate layer.

The present disclosure is related to inorganic, biocompatible material compositions for bioactivatable devices, devices, and products comprising transition metal chalcogenides, such as molybdenum sulfides, that can be converted in vivo from a non-bioactive state to a bioactive state upon exposure to physiological conditions, wherein the bioactivated transition metal chalcogenide derivatives, such as molybdenum sulfide derivatives, exhibit copper-chelating activities. Various methods for the application of these compositions for enhancing biocompatibility and reducing or modulating copper-dependent biological reactions are provided.

This invention is directed to an anastomosing stent comprising an internal frame and an external casing, and methods of use thereof.

Compositions comprising electrospun fibers and active (e.g. pharmaceutical) agents encapsulated thereto are provided. Further, articles and methods of use of the fibers, including, but not limited to coating of medical tubing, are provided.

A bioartificial device, such as a bioartificial pancreas, for implantation in a patient's vascular system. The bioartificial pancreas includes a scaffold adapted to engage an interior wall of a blood vessel, a cellular complex support by the scaffold and extending longitudinally within the interior cavity of the scaffold so as to be exposed to the blood flow when the scaffold is engaged with the blood vessel, the cellular complex support comprising one or more pockets bordered by thin film; and cellular complex comprising pancreatic islets disposed in the one or more pockets, the thin film being adapted to permit oxygen and glucose to diffuse from flowing blood into the one or more pockets at a rate sufficient to support the viability of the islets. The invention also includes methods of making and using a bioartificial pancreas.

The present invention is directed to medical devices having a first porous substrate layer with at least a surface coating thereon of a first co-reactive component and a second substrate layer with at least a surface coating layer of a second co-reactive component that reacts with the first co-reactive component, and a removable barrier layer positioned between the first substrate layer and second substrate layer and in contact with said first substrate layer and said second substrate layer.

One aspect of the invention provides a method of treating a chronic wound including administering to the wound at least one agent from a delivery system wherein the agent induces sequential conversion of a first population of wound macrophages in the wound to M2A macrophages and a second population of wound macrophages to M2C macrophages. The sequential conversion of the wound macrophages promotes tissue remodeling.

The present disclosure relates to drug eluting stents, methods of making, using, and verifying long-term stability of the drug eluting stents, and methods for predicting long term stent efficacy and patient safety after implantation of a drug eluting stent. In one embodiment, a drug eluting stent may include a stent framework; a drug-containing layer; a drug embedded in the drug-containing layer; and a biocompatible base layer disposed over the stent framework and supporting the drug-containing layer. The drug-containing layer may have an uneven coating thickness. In addition or in alternative, the drug-containing layer may be configured to significantly dissolve/dissipateldisappear between 45 days and 60 days after stent implantation. Stents of the present disclosure may reduce, minimize, or eliminate patient risks associated with the implantation of a stent, including, for example, restenosis, thrombosis, and/or MACE.

Disclosed is a drug eluting balloon for a balloon catheter. The drug eluting balloon comprises a balloon body (100) and a coating (200), and the coating (200) comprises a water-soluble adhesive layer (210), an isolating layer (220) and a drug layer (230) from the inside out. After the drug eluting balloon is pushed to a diseased part, the balloon body (100) is expanded, and the water-soluble adhesive layer (210) dissolves due to scouring by a blood flow, such that the isolating layer (220) and the drug layer (230) are separated from an outer surface of the balloon body (100) and adhere to a blood vessel wall. The provision of the isolating layer (220) can effectively suppress the water-soluble adhesive layer (210) from removing part of the drug layer (230) during dissolution, and after the drug layer (230) adheres to and makes contact with the blood vessel wall, the isolating layer can also reduce the scouring effect on the drug layer (230) by the blood flow, thereby reducing the loss of drugs, allowing the drugs to be taken in by the blood vessel wall to the greatest extent, greatly improving the utilization rate of the drugs and improving the treatment effect while also preventing toxic and side effects brought about by large doses of the drugs. Moreover, the isolating layer (220) can also realize the slow release of the drug layer (230), such that the drug layer (230) can provide treatment for a long time, and a good treatment effect can be obtained.