. 2021 Mar 12;6(10):3231–3243. doi: 10.1016/j.bioactmat.2021.02.032

Table 3.

Surface modification methods applied for improvement of mechanical or corrosion properties of Mg or its alloys.

Category	Sub-category	Surface composition	Method	Testing environment	Results (post-treatment vs. pre-treatment)	Shortcomings	References
Physical deposition	Polymer coatings	PCL	Deposition layer by layer by a custom designed spraying device	In vitro	60%–80% decrease in corrosion rate while 50% increase in the remaining compressive strength after 60 days of immersion	Insufficient bonding strength between the substrate and coating layer	[97]
		PLLA, PHB, PHBV, or PLGA	Spin coating	In vitro	Over a half reduction of weight loss for the coated samples after 4-week immersion test		[110]
		Chitosan-based nanofibers with incorporated silver sulfadiazine and carbon nanotubes	Electrospinning technique	In vitro	Two times higher in charge transfer resistance		[111]
		PLLA/AKT-DOXY	Electrospinning method	In vitro	Over 60% reduction in corrosion rate		[112]
	Inorganic or hybrid (polymer + inorganic) coatings	HA	Deposition with Ca chelate compound in solution	In vivo	25% decrease in corrosion rate		[113]
		CeO₂	Sol-gel method on a fluorinated surface	In vitro	Approximate 90% reduction in corrosion current density		[114]
		Fe-substituted tricalcium phosphate	Pulsed laser deposition	In vitro	50% reduction in corrosion current density		[115]
		Si-rich oxide and Si-rich layer	Ion implantation	In vitro	Over 90% reduction in corrosion current density		[116]
		TiO_x or AlO_x film	Plasm vapor deposition	In vitro	Approximate 50% reduction in corrosion current density		[117]
		PCL/bioglass nanoparticle composite	Spin coating	In vitro	Significant reduction in corrosion current density		[98]
	Refinement in microstructure	Homogenous surface	Laser surface melting	In vitro	Over 60% reduction in corrosion current density after treatment and grinding	Residual stress exists after LSM treatment	[100]
		Nano-crystallization	Laser shock processing	In vitro	86% increase in surface hardness	Impairment in corrosion resistance	[99]
		Mesoporous silica	Selective laser melting	In vitro	57% reduction in corrosion rate	Potential inhibition of bioactivity of Mg ions by the inert coating	[118]
		Supra-nano-dual-phase alloy membrane	Mg–Cu–Y alloy	In vitro	Increase in the ultimate yield stress by nearly 8 times	Potential electrochemical reactions between membrane and Mg-based substrate	[101]
Chemical conversion coatings	Alkaline derived layers	Magnesium oxide layers	Alkaline-heat treatment	In vitro	Approximate 85% decrease in corrosion rate	Concerns in long-term corrosion performance caused by porosity and detachment of coatings	[88]
	Acid derived layers	Mg₃(PO₄)₂	Phosphoric acid treatment	In vitro	Over 50% reduction in corrosion rate		[90]
	Fluorinated layers	MgF₂	HF treatment	In vitro	50%–70% reduction in corrosion current density		[89]
	Electrochemical deposition	Ceramic coatings with dense micropores	Micro-arc oxidation	In vitro	Over 80% reduction in corrosion current density		[93]
		Hydroxyapatite	Electrophoresis	In vitro	Slight increase in corrosion resistance depending on thickness		[92]
	Others	DAHP/PEI	Chemical conversion and spin coating	In vitro	Reduction in corrosion current density by five orders of magnitude		[119]
Mechanical treatment	surface mechanical attrition treatment (SMAT)	Gradient nanostructures	Repeated multidirectional impact of flying balls on the surface	In vitro	Approximate 50% increase in tensile strength	Weaker corrosion resistance of alloy caused by high density of crystalline defects	[102]
Mechanical treatment	Combination of SMAT and dual-phase metallic glass film	Hybrid nanostructures	Surface impact by ZrO₂ balls and magnetron sputtering	In vitro	Improvement in both strength and ductility	Potential electrochemical reactions between the two layers for impairment of corrosion resistance	[120]