An antithrombogenic metallic material includes a metallic material whose surface is coated with a coating material, the coating material containing: a phosphonic acid derivative or a catechol derivative; a polymer containing, as a constituent monomer, a compound selected from the group consisting of alkyleneimines, vinylamines, allylamines, lysine, protamine, and diallyldimethylammonium chloride; and an anionic compound containing a sulfur atom and having anticoagulant activity; the polymer being covalently bound to the phosphonic acid derivative or the catechol derivative, the phosphonic acid derivative or the catechol derivative being bound to the metallic material through a phosphonic acid group or a catechol group thereof, wherein the abundance ratio of nitrogen atoms to the abundance of total atoms as measured by X-ray photoelectron spectroscopy (XPS) on the surface is 4.0 to 13.0 atomic percent.

An antithrombogenic metallic material includes a metallic material whose surface is coated with a coating material, the coating material containing: a phosphonic acid derivative or a catechol derivative; a polymer containing, as a constituent monomer, a compound selected from the group consisting of alkyleneimines, vinylamines, allylamines, lysine, protamine, and diallyldimethylammonium chloride; and an anionic compound containing a sulfur atom and having anticoagulant activity; the polymer being covalently bound to the phosphonic acid derivative or the catechol derivative, the phosphonic acid derivative or the catechol derivative being bound to the metallic material through a phosphonic acid group or a catechol group thereof, wherein the abundance ratio of nitrogen atoms to the abundance of total atoms as measured by X-ray photoelectron spectroscopy (XPS) on the surface is 4.0 to 13.0 atomic percent.

A medical device substrate with a coating including a functional layer located on the substrate, with the functional layer including at least one sugar alcohol and being bonded to the substrate directly or indirectly via a functionalization of the sugar alcohol. Alternatively, the functional layer may also include other saccharides, in which case it is essential that polymerization of the saccharides takes place only upon bonding to the substrate. The inventive medical device exhibits reduced platelet adhesion and aggregation.

A medical device substrate with a coating including a functional layer located on the substrate, with the functional layer including at least one sugar alcohol and being bonded to the substrate directly or indirectly via a functionalization of the sugar alcohol. Alternatively, the functional layer may also include other saccharides, in which case it is essential that polymerization of the saccharides takes place only upon bonding to the substrate. The inventive medical device exhibits reduced platelet adhesion and aggregation.

The present invention discloses a compound heparin anticoagulant coating liquid, a microsphere for coating and its preparation methods and applications. In the present invention, the combination of curcumin and heparin can enhance the anticoagulation functions of heparin coating, and further enhance the stability using the properties of PLA-PEG-PLA drug-loaded sustained-release microspheres, achieving the functions of anti-tissue proliferation and anti-inflammatory reactions that cannot be achieved by coatings alone such as heparin or protein, which is very important for implanted devices such as artificial blood vessels, vascular stents and vascular patches to reduce thrombosis in the human body, lower postoperative complications and improve product lifespan.

The present invention discloses a compound heparin anticoagulant coating liquid, a microsphere for coating and its preparation methods and applications. In the present invention, the combination of curcumin and heparin can enhance the anticoagulation functions of heparin coating, and further enhance the stability using the properties of PLA-PEG-PLA drug-loaded sustained-release microspheres, achieving the functions of anti-tissue proliferation and anti-inflammatory reactions that cannot be achieved by coatings alone such as heparin or protein, which is very important for implanted devices such as artificial blood vessels, vascular stents and vascular patches to reduce thrombosis in the human body, lower postoperative complications and improve product lifespan.

A liquid excipient is added to a lock solution formulation containing a lower alcohol and an anti-coagulant, antibiotic, and/or anti-microbial, such as the ethanol and tri-sodium citrate lock solution formulation, to prevent citrate from crystallizing in catheters made from silicone. The locking solution could include a liquid excipient, such as glycerol, polysorbate-20, or polyethylene glycol (PEG)-400, along with a lower alcohol, such as ethanol, and an anti-coagulant, such as tri-sodium citrate, antibiotic, and/or anti-microbial.

A liquid excipient is added to a lock solution formulation containing a lower alcohol and an anti-coagulant, antibiotic, and/or anti-microbial, such as the ethanol and tri-sodium citrate lock solution formulation, to prevent citrate from crystallizing in catheters made from silicone. The locking solution could include a liquid excipient, such as glycerol, polysorbate-20, or polyethylene glycol (PEG)-400, along with a lower alcohol, such as ethanol, and an anti-coagulant, such as tri-sodium citrate, antibiotic, and/or anti-microbial.

Described herein are coating compositions having unique mechanical and physical properties. The coating compositions are composed of zinc oxide nanoparticles, copper nanoparticles, a perfluorolkylsiloxane, and an organic solvent. The coating compositions can be applied to any article or any surface of an article where it is desirable to reduce surface wettability or prevent the growth of bacteria.

Described herein are coating compositions having unique mechanical and physical properties. The coating compositions are composed of zinc oxide nanoparticles, copper nanoparticles, a perfluorolkylsiloxane, and an organic solvent. The coating compositions can be applied to any article or any surface of an article where it is desirable to reduce surface wettability or prevent the growth of bacteria.