Magnesium ion implantation enhances the osseointegration and vascularization of 3D-Printed CoCrMo alloy scaffolds for load-bearing orthopedic applications.
Ziyang Dong, Chenyuan Gao, Xinguang Wang, Ti Zhang, Xiao Geng, Jiazheng Chen, Junhao Feng, Yuhang Zheng, Yipu Zhang, Zhencan Han, Hao Wang, Ji Tan, Xianming Zhang, Yang Li, Zijian Li
Abstract
Open AccessTotal knee arthroplasty (TKA) remains the gold-standard treatment for end-stage osteoarthritis, yet persistent challenges in prosthetic material performance limit its long-term clinical efficacy. CoCrMo alloy is commonly used material of femoral component in TKA due to its excellent mechanical durability. However, two critical limitations persist: (1) substantial elastic modulus mismatch inducing stress-shielding effects, and (2) bioinert surface impairing osseointegration. To address these dual challenges, we developed a synergistic surface engineering strategy combining 3D-printed porous architecture with Mg2+ functionalization via plasma immersion ion implantation (PIII). The porous structure significantly reduced the elastic modulus and achieve biomimetic mechanical compatibility. Mg2+-implanted scaffolds (CoCrMo-Mg) demonstrated multifunctional bioactivity through synergistic physicochemical interactions. Surface topography modification via 3D printing generated micro-scale features that enhanced osteoblast adhesion through mechanotransduction pathways, while the release of Mg2+ exerted immunomodulatory, pro-angiogenic and osteogenic effects. Mg2+-mediated downregulation of pro-inflammatory cytokines, established an anti-inflammatory microenvironment conducive to bone regeneration, while Mg2+ stimulation promoted substantial neovascularization - collectively creating an osteogenic niche favoring coupled angiogenesis-osteogenesis process. These findings were further validated in vivo, where the CoCrMo-Mg scaffolds showed improved anti-inflammation, neovascularization and bone ingrowth capacities, along with favorable biomechanical integration. Overall, this dual-modality approach combining structural optimization with bioactive ion engineering establishes a paradigm for developing mechanically compliant and biologically active orthopedic implants, with particular translational relevance for cementless TKA applications.