A medical member includes a base material that is permeable to light; and a polymer layer having a phosphorylcholine group and located at least at a part of an inner surface of the base material. The part of the inner surface includes a first area irradiated with light of an intensity capable of forming the polymer layer when irradiated with light of a predetermined intensity from an outer surface side of the base material. Another medical member includes a base material that is permeable to light; and a polymer layer having a phosphorylcholine group and located at least at a part of an inner surface of the base material. The inner surface of the base material is irradiated with light of a light intensity of 3 mW/cm.sup.2 or less when light of a light intensity of 15 mW/cm.sup.2 or less enters from an outer surface side of the base material.

A medical member includes a base material that is permeable to light; and a polymer layer having a phosphorylcholine group and located at least at a part of an inner surface of the base material. The part of the inner surface includes a first area irradiated with light of an intensity capable of forming the polymer layer when irradiated with light of a predetermined intensity from an outer surface side of the base material. Another medical member includes a base material that is permeable to light; and a polymer layer having a phosphorylcholine group and located at least at a part of an inner surface of the base material. The inner surface of the base material is irradiated with light of a light intensity of 3 mW/cm.sup.2 or less when light of a light intensity of 15 mW/cm.sup.2 or less enters from an outer surface side of the base material.

Embodiments herein relate to thromboresistant coatings, coated devices, and related methods. In an embodiment, a thromboresistant implantable, partially implantable, or wearable medical device is included having a substrate, a non-fouling basecoat layer, and a lubricious topcoat layer. The non-fouling basecoat layer can include a hydrophilic component and a hydrophobic component. The non-fouling basecoat layer is disposed over the substrate. The lubricious topcoat layer can include a photo-reactive polyvinylpyrrolidone compound and a cross-linking agent. The lubricious topcoat layer can be disposed over the non-fouling basecoat layer. Other embodiments are also included herein.

Embodiments herein relate to thromboresistant coatings, coated devices, and related methods. In an embodiment, a thromboresistant implantable, partially implantable, or wearable medical device is included having a substrate, a non-fouling basecoat layer, and a lubricious topcoat layer. The non-fouling basecoat layer can include a hydrophilic component and a hydrophobic component. The non-fouling basecoat layer is disposed over the substrate. The lubricious topcoat layer can include a photo-reactive polyvinylpyrrolidone compound and a cross-linking agent. The lubricious topcoat layer can be disposed over the non-fouling basecoat layer. Other embodiments are also included herein.

Antimicrobial and antithrombogenic polymer or polymeric blend, compounds, coatings, and materials containing the same, as well as articles made with, or coated with the same, and methods of making the same exhibiting improved antimicrobial properties and reduced platelet adhesion. Embodiments include polymers with antimicrobial and antithrombogenic groups bound to a single polymer backbone, an antimicrobial polymer blended with an antithrombogenic polymer, and medical devices coated with the antimicrobial and antithrombogenic polymer or polymeric blend.

Provided is a method for producing an antithrombotic coating material in which a high molecular weight polymer can be obtained by a solution polymerization using a radical polymerization initiator. The above-mentioned task is achieved by a method for producing an antithrombotic coating material, including steps of: preparing a methanol solution containing a monomer represented by formula (1): ##STR00001##
wherein in formula (1), R.sup.1, R.sup.2, and R.sup.3 are the same as those described in the specification, respectively; adding a radical polymerization initiator having a 10-hour half-life temperature of 60° C. or less to the methanol solution to prepare a polymerization reaction liquid; and polymerizing the monomer.

Methods for forming an expandable tubular body having a plurality of braided filaments including a first filament including platinum or platinum alloy and a second filament including cobalt-chromium alloy. The methods include applying a first phosphorylcholine material directly on the platinum or platinum alloy of the first filament and applying a silane material on the second filament followed by a second phosphorylcholine material on the silane material on the second filament. The first and second phosphorylcholine materials each define a thickness of less than 100 nanometers.

High strength biomedical materials and processes for making the same are disclosed. Included in the disclosure are nanoporous hydrophilic solids that can be extruded with a high aspect ratio to make high strength medical catheters and other devices with lubricious and biocompatible surfaces.

There is provided herein a method of coating a polyurethane surface of an insertable medical device, the method comprising obtaining an insertable medical device or a part thereof comprising a polyurethane surface; performing a direct thiolization of the polyurethane surface to produce thiolated polyurethane surface comprising free thiol groups, the direct thiolization comprises a direct reaction between a secondary amine of the polyurethane surface and ethylene sulphide (ES) to form a covalent bond between the amine and the free thiol group; and reacting the thiolated polyurethane surface with a therapeutic/antithrombogenic compound having a vinyl/methacrylate functional group through thiol-ene click reaction, to produce an insertable medical device coated with a therapeutic/antithrombogenic and abrasion (delamination)-resistant coating.

There is provided herein a method of coating a polyurethane surface of an insertable medical device, the method comprising obtaining an insertable medical device or a part thereof comprising a polyurethane surface; performing a direct thiolization of the polyurethane surface to produce thiolated polyurethane surface comprising free thiol groups, the direct thiolization comprises a direct reaction between a secondary amine of the polyurethane surface and ethylene sulphide (ES) to form a covalent bond between the amine and the free thiol group; and reacting the thiolated polyurethane surface with a therapeutic/antithrombogenic compound having a vinyl/methacrylate functional group through thiol-ene click reaction, to produce an insertable medical device coated with a therapeutic/antithrombogenic and abrasion (delamination)-resistant coating.