The present invention relates to a method for preparation of a functionalized surface comprising the steps: a) coating of a carrier with a least one polymer selected from a polyanionic or polycationic polymer, b) addition of at least one compound to the coated carrier of step a), c) exposing the at least one polyanionic or polycationic polymer on the coated carrier of step b) to an organic solvent, resulting in compaction of the at least one polyanionic or polycationic polymer and thereby encapsulating the at least one compound, d) reversible cross-linking of the at least one polyanionic or polycationic polymer of step c) with at least one cross-linker; e) removal of the organic solvent. Furthermore, the invention relates to a functionalized surface, a functionalized surface for use in medicine and a method for releasing a compound ex vivo.

Articles and systems configured for treating GI motility disorders are generally provided. In some embodiments, an article comprising one or more electrodes (with both sensing and stimulating capabilities) may be configured to stimulate one or more tissues in the GI tract, electrically and/or chemically, to modulate peristalsis and/or allow neuromodulation. In some embodiments, a system comprises a controller that allows for close-loop operation of the article, e.g., such that the article may stimulate (e.g., via a feedback loop) the one or more organs in the GI tract upon receiving sensed parameters in the GI tract. In some embodiments, an implantation tool comprising a sensor may allow for submucosal or intramuscular implantation of an article. The implantation tool and the article may be useful for, for example, as a general platform for delivery of treating GI motility disorders and/or neuromodulation of the GI tract.

Articles and systems configured for treating GI motility disorders are generally provided. In some embodiments, an article comprising one or more electrodes (with both sensing and stimulating capabilities) may be configured to stimulate one or more tissues in the GI tract, electrically and/or chemically, to modulate peristalsis and/or allow neuromodulation. In some embodiments, a system comprises a controller that allows for close-loop operation of the article, e.g., such that the article may stimulate (e.g., via a feedback loop) the one or more organs in the GI tract upon receiving sensed parameters in the GI tract. In some embodiments, an implantation tool comprising a sensor may allow for submucosal or intramuscular implantation of an article. The implantation tool and the article may be useful for, for example, as a general platform for delivery of treating GI motility disorders and/or neuromodulation of the GI tract.

Low profile, self-expanding endovascular prostheses having a Ni-Ti alloy stent structure that is particularly well-suited for accessing and traversing narrow anatomical passageways and providing physiologically acceptable radial or hoop strength and longitudinal flexibility.

Low profile, self-expanding endovascular prostheses having a Ni-Ti alloy stent structure that is particularly well-suited for accessing and traversing narrow anatomical passageways and providing physiologically acceptable radial or hoop strength and longitudinal flexibility.

A method of producing a medical device having a substrate and a hydrophilic polymer layer, including the steps of: pretreating the substrate by placing the substrate in an alkali solution and heating the substrate at a temperature ranging from 50° C. to 100° C.; and heating a solution containing the pretreated substrate, a hydrophilic polymer having an acidic group and a hydroxyalkyl group, and an organic acid at a temperature ranging from 50° C. to 100° C. Provided is a simple method of producing a medical device imparted with hydrophilicity excellent in durability.

A method of producing a medical device having a substrate and a hydrophilic polymer layer, including the steps of: pretreating the substrate by placing the substrate in an alkali solution and heating the substrate at a temperature ranging from 50° C. to 100° C.; and heating a solution containing the pretreated substrate, a hydrophilic polymer having an acidic group and a hydroxyalkyl group, and an organic acid at a temperature ranging from 50° C. to 100° C. Provided is a simple method of producing a medical device imparted with hydrophilicity excellent in durability.

In an embodiment, a method of producing a radiopaque stent graft is provided. The method may include functionalizing a surface of a coating layer of a stent graft to produce a functionalized surface; disposing a tie layer over the functionalized exterior surface of the stent graft; disposing an adherent layer over the tie layer; etching a slot into the adherent layer; functionalizing the slot; and positioning a radiopaque marker in the slot to produce a filled slot and thereby produce the radiopaque stent graft.

In an embodiment, a method of producing a radiopaque stent graft is provided. The method may include functionalizing a surface of a coating layer of a stent graft to produce a functionalized surface; disposing a tie layer over the functionalized exterior surface of the stent graft; disposing an adherent layer over the tie layer; etching a slot into the adherent layer; functionalizing the slot; and positioning a radiopaque marker in the slot to produce a filled slot and thereby produce the radiopaque stent graft.

Medical devices as wells as methods for making and using medical devices are disclosed. An example medical device may include a left atrial appendage device. The left atrial appendage device may include an expandable frame configured to shift between a first configuration and an expanded configuration. A fabric mesh may be disposed along at least a portion of the expandable frame. An anti-thrombogenic coating may be disposed along the fabric mesh.