The present invention aims to provide a method for producing a microneedle device comprising a coating comprising dexmedetomidine and isoproterenol, in which the stability of isoproterenol during production and after production of the microneedle device is high. A method for producing a microneedle device according to one embodiment of the present invention comprises coating microneedles with a coating liquid to form a coating on the microneedles. The microneedle device comprises a substrate, microneedles disposed on the substrate, and a coating formed on the microneedles. The coating liquid comprises dexmedetomidine or a pharmaceutically acceptable salt thereof, isoproterenol or a pharmaceutically acceptable salt thereof, ethylenediaminetetraacetic acid or a pharmaceutically acceptable salt thereof, and a sulfated polysaccharide.

The present invention aims to provide a method for producing a microneedle device comprising a coating comprising dexmedetomidine and isoproterenol, in which the stability of isoproterenol during production and after production of the microneedle device is high. A method for producing a microneedle device according to one embodiment of the present invention comprises coating microneedles with a coating liquid to form a coating on the microneedles. The microneedle device comprises a substrate, microneedles disposed on the substrate, and a coating formed on the microneedles. The coating liquid comprises dexmedetomidine or a pharmaceutically acceptable salt thereof, isoproterenol or a pharmaceutically acceptable salt thereof, ethylenediaminetetraacetic acid or a pharmaceutically acceptable salt thereof, and a sulfated polysaccharide.

An implantable device comprising a core portion and a capsule encapsulating the core portion, said capsule having an outer surface, wherein at least a portion of the outer surface comprises gold.

Nanostructured surfaces on selected substrates are described which are highly resistant to cell adhesion. Such surfaces on medical implants inhibit fibroblast adhesion particularly on nanorough titanium deposited on smooth silicone surfaces. The nanostructured deposited metal coatings can also be engineered so that several cell types, including endothelial, osteoblast, and fibroblast cells, show little if any tendency to attach to the coated surface in vivo.

The present invention relates to a stent having a functional material coated on a cell space (safe coating space) thereof. The stent of the present invention, as a stent having a space for mounting and coating drugs and other materials for expanding the functions of the stent, is highly feasible as an actual product in consideration of the structure, transfer device, and manufacturing process of the stent as a whole, and secures a coating space (safe coating space) of a functional material in a cell of the stent through quantitative and qualitative modelling. Since an additional increase in volume does not occur even when the stent is press-mounted in a transfer device as a result of mounting a radio marker or a drug in the coating space, the stent of the present invention has excellent radio opacity without obstructing the loading and deployment of the stent, and may stably mount a great amount of a functional drug.

The present invention relates to a stent having a functional material coated on a cell space (safe coating space) thereof. The stent of the present invention, as a stent having a space for mounting and coating drugs and other materials for expanding the functions of the stent, is highly feasible as an actual product in consideration of the structure, transfer device, and manufacturing process of the stent as a whole, and secures a coating space (safe coating space) of a functional material in a cell of the stent through quantitative and qualitative modelling. Since an additional increase in volume does not occur even when the stent is press-mounted in a transfer device as a result of mounting a radio marker or a drug in the coating space, the stent of the present invention has excellent radio opacity without obstructing the loading and deployment of the stent, and may stably mount a great amount of a functional drug.

A medication impregnated bone cement (MIBC) coated intramedullary (IM) nail for fixation of a long bone fracture comprising an IM nail base and medication impregnated bone cement. The bone cement encapsulates at least a portion of the IM nail base and forms an interface between the adjacent surfaces of the IM nail base and the bone cement. The interface between the encapsulating bone cement and the encapsulated IM nail base being enhanced to increase the adhesion of the encapsulating bone cement to the encapsulated IM nail base. The increase in adhesion being sufficient to ensure that the encapsulating bone cement remains adhered to the encapsulated IM nail base when the medication impregnated bone cement coated intramedullary nail is removed from the long bone.

Various aspects of the present disclosure provide compositions including a water-insoluble therapeutic agent and a gallate-containing compound. Other aspects provide methods of using such compositions.

Various aspects of the present disclosure provide compositions including a water-insoluble therapeutic agent and a gallate-containing compound. Other aspects provide methods of using such compositions.

Biodegradable magnesium alloy implantable medical devices are protected to delay onset of corrosion, and thus biodegradability, or to corrode more uniformly. The protection allows for extended effective use of the devices while maintaining biodegradability. Examples of protective coatings include conversion coatings that at least partially remove exposed second phases from a surface of the magnesium alloy and coatings that provide a barrier between water and the surface of the magnesium alloy.