Bioactivity and corrosion properties of novel coatings containing strontium by micro-arc oxidation

“…Hence, inorganic irons such as strontium [81][82][83][84][85][86], manganese [87], copper [88][89][90] have been considered to be promising agents to enhance the positive effect coatings on osteointegration and bone regeneration. Because the apatite structure is very tolerant to ionic substitutions (F, Mg, Sr, etc.…”

“…Lee et al [81,83] investigated that the MAO coatings in electrolytes with different strontium content did not change the physicochemical characteristic but had an effect on cell response. The cell proliferation on the coatings containing 1% or 5% strontium was higher than that without strontium content after 14 days culture.…”

Review of the biocompatibility of micro-arc oxidation coated titanium alloys

“…Hence, inorganic irons such as strontium [81][82][83][84][85][86], manganese [87], copper [88][89][90] have been considered to be promising agents to enhance the positive effect coatings on osteointegration and bone regeneration. Because the apatite structure is very tolerant to ionic substitutions (F, Mg, Sr, etc.…”

“…Lee et al [81,83] investigated that the MAO coatings in electrolytes with different strontium content did not change the physicochemical characteristic but had an effect on cell response. The cell proliferation on the coatings containing 1% or 5% strontium was higher than that without strontium content after 14 days culture.…”

Review of the biocompatibility of micro-arc oxidation coated titanium alloys

“…But the poor wear and corrosion resistances of magnesium and its alloy restricted their large-scale applications in industries [3,4]. This makes protective surface treatments an essential part of the manufacturing process for further application of magnesium alloys, which can provide a way of allowing the excellent properties of the substrate material to be maintained while protecting them against wear or corrosion [5][6][7][8][9][10].…”

Preparation and characterization of Ni–P–nanoTiN electroless composite coatings

“…Studies have shown that Ag, Sr, Ca, Si and other elements introduced by surface modification can effectively improve the biological activity of the implant. In view of the broad-spectrum antibacterial activity of Ag and the excellent structure of our nanotube coating prepared by anodic oxidation technology, we assume that Ag is introduced onto the surface of the titanium implant and Ag + is slowly released, exhibiting its antibacterial effect [22][23][24] . …”

Antibacterial and Microstructure Properties of Titanium Surfaces Modified with Ag-Incorporated Nanotube Arrays