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3D-printed conductive hydrogel scaffolds for bone regeneration: Electromechanical coupling, neurovascular integration, and immunomodulatory strategies

Yumiao Liu, Longhui Li, Xiaoyu Zhan, Susu Hong, Shaopeng Chang, Gan Huang, Gan Huang, Shu-Ting Pan, Shu-Ting Pan, Yang Liu, Lei Li, Xiaowei Zhan, Soon‐Ku Hong, Shu‐Wei Chang, Guocheng Huang, Guocheng Huang, Shuting Pan, Shuting Pan

2025Biomaterials Advances7 citationsDOI

Topics & Concepts

Self-healing hydrogelsRegeneration (biology)Materials scienceNanotechnologyElectrical conductorBiomedical engineeringTissue engineeringRegenerative medicineBiomimeticsNeurogenesisBiocompatible materialNeural tissue engineeringNeuroscienceStimulationBiocompatibilityBrain stimulationMicrofabricationBiofabricationParacrine signallingBench to bedsideAxon guidanceBone Tissue Engineering Materials3D Printing in Biomedical ResearchTissue Engineering and Regenerative Medicine
3D-printed conductive hydrogel scaffolds for bone regeneration: Electromechanical coupling, neurovascular integration, and immunomodulatory strategies | Litcius