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Bioinspired porous core-shell microspheres with spatiotemporal delivery coordinate immunomodulatory-osteogenic coupling via NF-κB/P-STAT6 and Rho/MAPK signaling for enhanced calvarial regeneration

Jiahe Zheng, Chengrun Li, Qingxia Zhang, Ou Tao, Linlong Li, Pengfei Yu, Shujuan Wei, Gui‐Ge Hou, Huanhuan Yan

2025Bioactive Materials6 citationsDOIOpen Access PDF

Abstract

Critical-sized calvarial defects remain a formidable clinical challenge due to dyssynchronous immunomodulation-osteogenesis coupling and unregulated growth factor release. Here, a bioinspired porous core-shell microsphere system (GCI@HPPS) is developed, integrating hydroxyapatite (HA)-loaded shell, surface-immobilized SDF-1α, and IGF-1-encapsulated cores to immunomodulate osteoimmune microenvironment and osteogenesis promotion. The hierarchical architecture achieved spatiotemporally programmed release: HA degradation-dependent mineralization, SDF-1α-mediated BMSC chemotaxis, and sustained IGF-1 delivery, mimicking natural bone repair cascades. Dual covalent/guest-host crosslinking (GelMA/Ac-β-CD) enhanced compressive strength, while polydopamine functionalization of microspheres conferred electroactivity, hydrophilicity, ROS/RNS scavenging (97.29 % ABTS•+ elimination), antibacterial efficacy (>99.8 %) and hemostasis. In vitro , GCI@HPPS mitigates oxidative stress, induces M2 macrophage polarization, and suppresses inflammatory cascades while concomitantly enhancing endogenous BMSC recruitment, proliferation, and osteogenic differentiation. Proteomics revealed a tetradic anti-inflammatory mechanisms of GCI@HPPS: NF-κB/P-JNK suppression, pro-inflammatory cytokines downregulation, mitochondrial oxidative modulation, and STAT6-driven M2 polarization. In vivo , GCI@HPPS achieved calvarial defect closure at 8 weeks through porous matrix-guided cellular infiltration, and SDF-1α/IGF-1-mediated chemotaxis, Rho/MAPK signaling pathway activation balancing osteoclast-osteoblast dynamics, stage-specific osteogenic induction and AGE-RAGE/VEGF-coupled angiogenesis-osteogenesis. This work pioneers a spatiotemporal delivery paradigm that coordinates inflammation modulation, stem cell recruitment, osteogenic differentiation, and mineralization phases, offering a promising approach for complex cranial reconstruction. Bioinspired porous core-shell microsphere (GCI@HPPS) is designed for sequential therapeutic factors delivery to synchronize immunomodulation and osteogenic regeneration. The anti-inflammatory mechanisms of GCI@HPPS are NF-κB/P-JNK suppression, pro-inflammatory cytokine downregulation, mitochondrial oxidative modulation, and STAT6-driven M2 polarization. GC@HPPS achieves cranial reconstruction by SDF-1α/IGF-1-mediated chemotaxis, Rho/MAPK signaling pathway activation balancing osteoclast-osteoblast dynamics, stage-specific osteogenic induction (OSX/Runx2-BMP-2/Col-I/ALP/OPN-OCN/calcium deposition) and AGE-RAGE/VEGF-coupled angiogenesis-osteogenesis. • Core-shell porous microsphere (GCI@HPPS) enables spatiotemporal delivery of immunomodulatory-osteogenic factors. • GCI@HPPS mitigates oxidative stress, induces M2 macrophage polarization, and suppresses inflammatory cascades. • GCI@HPPS enhances endogenous BMSC recruitment, proliferation, and osteogenic differentiation. • GCI@HPPS immunomodulates osteoimmune microenvironment and osteogenesis promotion.

Topics & Concepts

Materials scienceMicrosphereRegeneration (biology)Shell (structure)Coupling (piping)PorosityBiophysicsNanotechnologyCell biologyChemical engineeringComposite materialBiologyEngineeringBone Tissue Engineering MaterialsMesenchymal stem cell researchGraphene and Nanomaterials Applications
Bioinspired porous core-shell microspheres with spatiotemporal delivery coordinate immunomodulatory-osteogenic coupling via NF-κB/P-STAT6 and Rho/MAPK signaling for enhanced calvarial regeneration | Litcius