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Biodegradable Mg-based medical devices: From passive support to active modulation

Lin Mao, Zhongxin Hu, Chengli Song

2025Journal of Magnesium and Alloys12 citationsDOIOpen Access PDF

Abstract

• Paradigm shift from passive to active implants. Mg-based biodegradable medical devices have evolved from traditional passive structural supports to advanced active systems capable of modulating physiological processes, marking a fundamental shift in implantable medical technology. • Integration of Bio-active/Electro-active functions. Modern Mg-based implants not only promote tissue regeneration and exhibit antibacterial, anti-inflammatory, and osteogenic effects through their degradation products, but also incorporate electrical conductivity for biosensing, real-time monitoring, and therapeutic stimulation, enabling intelligent and responsive medical interventions. • Key technologies and future directions. The future of Mg-based medical devices focuses on precise control of mechanical properties and degradation rates, multifunctional integration of bio-active/electro-active features, and the development of intelligent, personalized, and programmable implants—driving the next generation of active, smart, and biodegradable medical devices. Biodegradable magnesium (Mg)-based medical devices have revolutionized medical implants by uniquely combining biocompatibility and mechanical strength. Fully degradable Mg-based implants have been developed to provide temporary structural support and serve as a dynamic scaffold for tissue repair and restructuring. Additionally, Mg-based devices can respond to physiological signals, and their integration with electrical currents or pulses has been explored to enhance tissue healing and functional recovery. This review provides a comprehensive overview of the development and application of Mg-based medical devices, highlighting their evolution from traditional orthopedic, vascular, and dental uses to advanced systems that actively modulate physiological processes—a shift from passive support to active modulation. The application range of Mg-based devices has expanded from early vascular sutures, bone screws, and stents to multiple clinical fields including porous bone repair scaffolds, anastomotic staples, bioactive devices, and electro-active systems. Bioactive Mg devices demonstrate therapeutic properties including antibacterial, anti-inflammatory, anti-tumor, and osteogenic functions through their degradation products, while electro-active devices utilize the electrical properties of Mg for sensing, monitoring, and therapeutic stimulation. Finally, this review highlights current challenges, including maintaining mechanical support performance, optimizing control of biochemical reactions, and balancing electro-regulatory functions, and identifies future research directions aimed at enhancing the clinical application of biodegradable Mg-based implants, thereby contributing to the significant advancement in the biomedical field. Summary of the most recent applications of Mg alloys in passive and active implants

Topics & Concepts

BiocompatibilityMaterials scienceMedical deviceScaffoldBiomedical engineeringNanotechnologyTissue repairComputer scienceBiocompatible materialRegeneration (biology)Degradation (telecommunications)Smart materialTissue engineeringSystem integrationImplantMedical practiceElectrical currentMedical treatmentMagnesium Alloys: Properties and ApplicationsHydrogen Storage and MaterialsMagnesium in Health and Disease