For the purpose of firmly fusing a low-cost osteosynthetic implant having high osteoconductivity with a bone in a short period of time after implanting without having to perform treatment to restore surface hydrophilicity, a osteosynthetic implant is provided with a substrate that is formed of magnesium or a magnesium alloy and a porous anodic oxide coating that is formed on a surface of the substrate, wherein the anodic oxide coating has an outer surface that, due to the sizes and distribution of pores that are formed when generating the anodic oxide coating by means of anodic oxidation treatment, structurally prevents water from entering the pores while maintaining the hydrophilicity thereof.

A medical needle may include a lumen coating configured to reduce surface energy of the lumen-facing/lumen defining surface, in a manner effective to slow and/or reduce coagulation of biomaterial (particularly blood) that contacts the needle lumen surface. Such a coating may include a hydrophobic coating such as a silane and/or siloxane material on at least the needle lumen surface. The coating reduces a surface energy of coated needle regions below the surface energy of uncoated regions, and particularly reduces the polar component of the surface energy in the coated needle regions. The needle may be a metallic biopsy needle with the coating comprised by at least a distalmost length of sample-collection lumen.

Embodiments of the disclosure include lubricious coatings. In an embodiment the disclosure includes a lubricious coating for a medical device including an acrylic acid polymer, an acrylamide copolymer comprising at least one photoreactive group, and a cross-linking agent comprising at least two photoreactive groups. The coating can be used on a catheter surface to facilitate its movement in the body.

A coated powder composite may include a core particle of Ca or an alloy thereof, or of Mg or an alloy thereof. One or more coating layers may be disposed about the core particle, cladding the core particle. The coated powder composite may be biodegradable.

A magnetic article with a corrosion resistant barrier formed from a poly(tetrafluoro-p-xylene) conformal coating or from a parylene conformal coating having a melting point of at least about 430° C. and a moisture vapor transmission less than about 0.5 g-mm/m.sup.2/day at 90% RH and 37° C., the conformal coating being covered with a polysulfone thermoplastic overlayer.

The invention relates to medical devices and, more in particular, to medical devices suitable for use as stents that contain an antimicrobial coating and, optionally, a drug customized to patients requirements. The invention also relates to methods for obtaining devices having the above features.

A thermoplastic article for orthopaedic application comprising a substrate, the substrate including in the range 57 to 95 wt % of a thermoplastic polymer and in the range 5 to 30 wt % of a wax; wherein, the article is plastic at a temperature in the range 40° C. to 60° C. Together with a method of a thermoplastic article for orthopaedic application comprising a substrate, the substrate including in the range 57 to 95 wt % of a thermoplastic polymer and in the range 5 to 30 wt % of a wax; wherein, the article is plastic at a temperature in the range 40° C. to 60° C. and a use of the article together with a computer readable medium which when executed on a processor allows the article to be made.

The present invention relates to a method for producing biomimetic hydroxyapatite (HAp) and boron-doped HAp (B-HAp) with the support of microwave and a method for coating tissue scaffolds with HAp and/or B-HAp.

Disclosed is a method for preparing a nitric oxide-generating adherent coating, comprising: preparing a buffer solution containing polyphenol compounds, organic selenium or sulfur compounds and soluble copper salts; then contacting a base material with the solution, and washing and drying to obtain a target product. The nitric oxide-generating material prepared by the method can be used for any medical device, such as an intravascular stent, or materials and any complex-shaped base material, and has the capability of scavenging free radicals and catalyzing RSNO to produce nitrogen monoxide, and also has a response function of reduced glutathione (GSH), an antimicrobial function and all the physiological functions possessed by nitrogen monoxide.

A method of manufacturing a coated low-friction medical device, such as low-friction medical tubing, including applying a coating to one or more selected portions of a surface of low-friction medical tubing to indicate at least one marking formed along the surface of the low-friction medical tubing, and simultaneously or substantially simultaneously: (a) curing the applied coating to a designated temperature (which is above the temperature at which the low-friction medical tubing begins to decompose and shrink) to adhere the applied coating to the surface of the low-friction medical tubing, (b) utilizing one or more anti-shrinking devices to counteract or otherwise inhibit the shrinking of the low-friction medical tubing, and (c) exhausting any harmful byproducts resulting from curing the low-friction medical tubing to a temperate above the temperature at which the low-friction medical tubing begins to decompose.