ZnO and Cu/ZnO-modified Magnesium orthopedic implant with improved osteoblast cellular activity: An in-vitro study

Abstract

Mg-based biomaterials, due to their desirable mechanical integrity, natural bioabsorbability, and osteopromotive characteristics, are promising candidates for both orthopedic applications, such as the surgical fixation of injured musculoskeletal tissues, and cardiovascular applications like coronary artery stents. In the present study, nano- and micro-sized ZnO and Cu/ZnO bioactive particles were used to fabricate Mg-based biocomposites using friction stir processing (FSP). FSP resulted in significant microstructural modification in terms of grain refinement, uniform redistribution of secondary phase particles and homogenous dispersion of bioactive particles. Long-term biodegradation results through H2 evolution method illustrated that biodegradation rate of the bioabsorbable WE43 alloy was significantly reduced by addition of bioactive particles. In addition, fabricated biocomposites with addition of nano-sized particles resulted in lower biodegradation rate in comparison to those with micro-sized particles. Furthermore, uniform dispersion of bioactive particles resulted in superior in-vitro biocompatibility in contact with MC3T3-E1 mouse osteoblast cells. Mg–ZnO–N and Mg–Cu/ZnO–N biocomposites showed improved cell adhesion with elongated and spread morphology of MC3T3-E1 osteoblast cells. Live/dead staining and MTT assay indicated that number of healthy cells and cell viability after 24 h of incubation increased by uniform distribution of bioactive particles. Moreover, fabricated biocomposites with homogenous distribution of Zn2+ and Cu2+ ions showed higher ALP activity. Our findings propose that Mg–ZnO and Mg–Cu/ZnO biocomposites with homogenous dispersion of bioactive particles can be promising candidates for bone tissue regeneration applications.