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3D-printed magnesium/strontium-co-doped calcium silicate scaffolds promote angiogenesis and bone regeneration through synergistic bioactive ion stimulation

Chia‐Che Ho, Tuan-Ti Hsu, Yung‐Cheng Chiu, Yen-Hong Lin, Pei-Cheng Xie, Chen‐Ying Wang

2025Journal of Biological Engineering17 citationsDOIOpen Access PDF

Abstract

Bone defects resulting from trauma, infection, or surgical resection require biomaterials that support osteogenesis and vascularization for effective regeneration. In this study, we developed a 3D-printed magnesium- and strontium-co-doped calcium silicate (MSCS) scaffold using direct ink writing to optimize its bioactivity and structural integrity. X-ray diffraction confirmed the successful incorporation of Sr and Mg, leading to phase modifications that influenced ion release and degradation. Wettability and mechanical testing showed that Sr improved the stability, while Mg accelerated degradation, with M5S5 co-doping exhibiting a balanced degradation profile. In vitro, Wharton's jelly mesenchymal stromal cells cultured on M5S5 scaffolds displayed enhanced proliferation, cytoskeletal organization, and osteogenic differentiation, as evidenced by increased alkaline phosphatase activity and bone matrix protein expression. Angiogenesis assays using human umbilical vein endothelial cells revealed that Sr and Mg co-doping synergistically enhanced vascular endothelial growth factor and angiopoietin-1 secretion, thereby promoting endothelial tube formation. In vivo micro-computed tomography and histological analysis of a rabbit femoral defect model confirmed that M5S5 facilitated extensive new bone formation, exhibiting superior trabecular architecture and mineralization. These findings highlight MSCS scaffolds as promising biomaterials for bone tissue engineering applications.

Topics & Concepts

Mesenchymal stem cellAngiogenesisBone morphogenetic protein 2Biomedical engineeringBone healingCell biologyChemistryVascular endothelial growth factorMaterials scienceAlkaline phosphataseCalcium silicateUmbilical veinAnatomyIn vitroBiochemistryCancer researchBiologyMedicineComposite materialEnzymeVEGF receptorsBone Tissue Engineering MaterialsCalcium Carbonate Crystallization and InhibitionBone Metabolism and Diseases
3D-printed magnesium/strontium-co-doped calcium silicate scaffolds promote angiogenesis and bone regeneration through synergistic bioactive ion stimulation | Litcius