The present invention relates to a medical device suitable for being inserted into the lumen of an anatomic structure of a subject, said medical device comprising means for administration of TRPC6 inhibitor, wherein said means comprises the TRPC6 inhibitor. The present invention further concerns a method of manufacturing a medical device suitable for being inserted into the lumen of an anatomic structure of a subject. Also, the invention relates to a TRPC6 inhibitor for use in the treatment or prevention of a disease associated with neointimal hyperplasia associated with the migration of smooth muscular cells. The invention also relates to a method of treating or preventing a disease associated with neointimal hyperplasia, said method comprising administering a TRPC6 inhibitor to a subject in need thereof. Also envisaged is a method of inhibiting migration of smooth muscle cells. The invention additionally relates to an in vitro test kit comprising: (a) small muscle cells (SMCs); (b) a surface suitable for SMC cultivation coated with a TRPC6 inhibitor. Also concerned is a pharmaceutical composition comprising a TRPC6 inhibitor and a pharmaceutically acceptable carrier.

The present invention is in the fields of medicinal chemistry, biotechnology and pharmaceuticals. The invention provides compositions comprising one or more collagen mimetic peptides, optionally attached to one or more therapeutic compounds or one or more imaging compounds, for use in methods of treating, preventing, ameliorating, curing and diagnosing certain diseases and physical disorders in humans and veterinary animals, as well as methods of manufacturing such composition. The invention also provides medical devices comprising one or more such compositions of the invention. The invention also provides methods of use of such compositions and devices in treating and diagnosing certain diseases and physical disorders in humans and veterinary animals, including ocular diseases or disorders, skin diseases or disorders, certain cancers, particularly intraluminal cancers, gastrointestinal diseases or disorders, genitourinary tract diseases or disorders, fibrotic diseases/disorders and rheumatic diseases/disorders.

Provided are a flexible tube for an endoscope, the flexible tube having a flexible-tube base that is flexible and tubular and a polyester elastomer layer that covers the flexible-tube base and has a naphthalene structure in a soft segment, an endoscopic medical device having the flexible tube for an endoscope, a method for producing a covering material constituting the flexible tube for an endoscope, and a method for producing the flexible tube for an endoscope.

Provided are a flexible tube for an endoscope, the flexible tube having a flexible-tube base containing metal as a constituent material, a cover layer covering an outer periphery of the flexible-tube base, and a primer layer disposed between the flexible-tube base and the cover layer and including at least one of a specific silane coupling agent, an aluminum alkoxide compound, a zirconium alkoxide compound, or a titanium alkoxide compound, in which the cover layer includes, at least on a side in contact with the primer layer, a polyester having a naphthalene structure, an endoscopic medical device using the flexible tube, a method for producing the flexible tube for an endoscope, and a method for producing the endoscopic medical device.

The present invention relates to methods and compositions for rendering a surface resistant to bio-film formation by a combination of an antimicrobial agent, an organic hydroxy acid, lubricious biomedical polymer and solvent. The invention provides for compositions which may be used to render surfaces bio-film resistant, articles having bio-film resistant surfaces, and methods for their preparation. The present invention may be advantageously applied to medical articles as well as articles used in non-medical contexts, such as child care or food preparation.

A method for treating proliferative diseases by delivering a combination of at least two pharmaceutically active agents to a diseased area or tissue comprising a coating layer of two hydrophobic drugs applied to an exterior surface of a device or a substrate wherein the first pharmaceutically active agent is selected from a group consisting of mTor inhibitors and the second pharmaceutically active agent is selected from a group of consisting of NF-kβ inhibitors. Further a method for treating proliferative diseases by delivering a combination of at least two pharmaceutically active agents to a diseased area or tissue comprising: a coating layer of two hydrophobic drugs applied to an exterior surface of a medical device or substrate and a polymer blend carrier for the pharmaceutically active agents.

A method for treating proliferative diseases by delivering a combination of at least two pharmaceutically active agents to a diseased area or tissue comprising a coating layer of two hydrophobic drugs applied to an exterior surface of a device or a substrate wherein the first pharmaceutically active agent is selected from a group consisting of mTor inhibitors and the second pharmaceutically active agent is selected from a group of consisting of NF-kβ inhibitors. Further a method for treating proliferative diseases by delivering a combination of at least two pharmaceutically active agents to a diseased area or tissue comprising: a coating layer of two hydrophobic drugs applied to an exterior surface of a medical device or substrate and a polymer blend carrier for the pharmaceutically active agents.

The present disclosure is directed toward drug coated balloons, and in particular to drug coated balloons having a microcrystalline structure and techniques for increasing vascular permeability for drug application and retention. Particular aspects may be directed to a medical device including a balloon having an outer surface, and a drug coating layer on the outer surface of the balloon. The drug coating layer includes microcrystals in a haystack orientation having random and a substantial absence of uniformity in placement and/or angle on the outer surface of the balloon.

The present disclosure is directed toward drug coated balloons, and in particular to drug coated balloons having a microcrystalline structure and techniques for increasing vascular permeability for drug application and retention. Particular aspects may be directed to a medical device including a balloon having an outer surface, and a drug coating layer on the outer surface of the balloon. The drug coating layer includes microcrystals in a haystack orientation having random and a substantial absence of uniformity in placement and/or angle on the outer surface of the balloon.

Described herein are medical devices and medical implements with high lubricity to flesh (or biological fluid) and/or inhibited nucleation on its surface. The device has a surface comprising an impregnating liquid and a plurality of micro-scale and/or nano-scale solid features spaced sufficiently close to stably contain the impregnating liquid therebetween. The impregnating liquid fills spaces between said solid features, the surface stably contains the impregnating liquid between the solid features, and the impregnating liquid is substantially held in place between the plurality of solid features regardless of orientation of the surface.