Abstract: A method for manufacturing an implantable medical device, the method including the steps of: (a) providing in a vapor deposition chamber a substrate including a substrate material, an anodic source made of an anodic material, and a cathodic source made of a cathodic material, the anodic and cathodic materials forming a galvanic couple; (b) operating the vapor deposition chamber to vaporize simultaneously the anodic and cathodic materials from the anodic and cathodic sources and depositing the vaporized cathodic and anodic materials on the substrate to produce a coated substrate including the substrate material coated by a bioresorbable coating; and (c) obtaining the implantable medical device from the coated substrate. Also, a stent, a medical device and a bioresorbable material obtained with vapor deposition of materials forming a galvanic couple.

Abstract: The present describes an oxygen functionalized nanoflake (O-GNF), a stable nanofluid in which the graphene nanoflakes remain dispersed or in suspension free of surfactants, and the method of making the oxygen-functionalized nanoflake. The oxygen-functionalized graphene nanoflake (O-GNF and/or O—N-GNF) comprises a single-crystal graphene nanoflake of 5-20 atomic planes comprising a surface oxygen-functionalization, wherein the O-GNF comprise a degree of oxygen functionalization from about 6 to about 25 at. % oxygen by weight of the GNF with a preferred oxygen functionalization of about 14 at. % oxygen.

Abstract: A method for manufacturing an implantable medical device, the method including the steps of: (a) providing in a vapor deposition chamber a substrate including a substrate material, an anodic source made of an anodic material, and a cathodic source made of a cathodic material, the anodic and cathodic materials forming a galvanic couple; (b) operating the vapor deposition chamber to vaporize simultaneously the anodic and cathodic materials from the anodic and cathodic sources and depositing the vaporized cathodic and anodic materials on the substrate to produce a coated substrate including the substrate material coated by a bioresorbable coating; and (c) obtaining the implantable medical device from the coated substrate. Also, a stent, a medical device and a bioresorbable material obtained with vapor deposition of materials forming a galvanic couple.

Abstract: The present describes an oxygen functionalized nanoflake (O-GNF), a stable nanofluid in which the graphene nanoflakes remain dispersed or in suspension free of surfactants, and the method of making the oxygen-functionalized nanoflake. The oxygen-functionalized graphene nanoflake (O-GNF and/or O—N-GNF) comprises a single-crystal graphene nanoflake of 5-20 atomic planes comprising a surface oxygen-functionalization, wherein the O-GNF comprise a degree of oxygen functionalization from about 6 to about 25 at. % oxygen by weight of the GNF with a preferred oxygen functionalization of about 14 at. % oxygen.

Abstract: A method for manufacturing a bioresorbable device, said method comprising: providing an anodic material; providing a cathodic material, said anodic and cathodic materials forming a galvanic couple; vapor depositing simultaneously said anodic and cathodic materials on a substrate to obtain a bioresorbable material; and processing said bioresorbable material to form said bioresorbable device. Said vapor deposition of said anodic and cathodic materials is performed under conditions such that bioresorption of said device is promoted by galvanic corrosion between said anodic and cathodic materials.

Abstract: A pure and crystalline single-crystal nitrogen-functionalized graphene nano-flake powder comprising from 2 atomic % to at least 35 atomic % of total functionalized nitrogen within the graphene nano-flakes is disclosed. As well, the method of producing the nano-flakes that comprises injecting a carbon source into a thermal plasma system, dissociating the carbon source into carbon atomic species, transporting the carbon atomic species through a controlled nucleation zone to produce a crystalline graphene nano-flake structure, injecting the nitrogen source into the thermal plasma system dissociating the nitrogen source into nitrogen active species, and transporting the nitrogen atomic species to contact the crystalline graphene nano-flakes to produce the crystalline nitrogen-functionalized graphene nano-flakes is also disclosed. Finally, a multilayer composite comprising a carbon substrate and a layer of crystalline nitrogen-functionalized graphene nano-flakes is also described.