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3D-printed PCL scaffolds combined with injectable sodium alginate/magnesium-doped mesoporous bioactive glass nanosphere hydrogel for meniscus regeneration: In vitro, In vivo, and multiomics-based therapeutic analyses

Hao Li, Yongkang Yang, Tianze Gao, Runmeng Li, Chao Wang, Xue Wang, Tianyuan Zhao, Qinyu Tian, Zhi-xing Zhang, Ruiyang Zhang, Quanyi Guo, Zhiguo Yuan, Peifu Tang

2025Bioactive Materials15 citationsDOIOpen Access PDF

Abstract

Meniscal injury presents a formidable challenge and often leads to functional impairment and osteoarthritic progression. Meniscus tissue engineering (MTE) is a promising solution, as conventional strategies for modulating local immune responses and generating a conducive microenvironment for effective tissue repair are lacking. Recently, magnesium-containing bioactive glass nanospheres (Mg-BGNs) have shown promise in tissue regeneration. However, few studies have explored the ability of Mg-BGNs to promote meniscal regeneration. First, we verified the anti-inflammatory and fibrochondrogenic abilities of Mg-BGNs in vitro. A comprehensive in vivo evaluation of a rabbit critical-size meniscectomy model revealed that Mg-BGNs have multiple effects on meniscal reconstruction and effectively promote fibrochondrogenesis, collagen deposition, and cartilage protection. Multiomics analysis was subsequently performed to further explore the mechanism by which Mg-BGNs regulate the regenerative microenvironment. Mechanistically, Mg-BGNs first activate the TRPM7 ion channel through the PI3K/AKT signaling pathway to promote the cellular function of synovium-derived mesenchymal stem cells and then activate the PPARγ/NF-κB axis to modulate macrophage polarization and inflammatory reactions. We demonstrated that Mg 2+ is critical for the crosstalk among biomaterials, immune cells, and effector cells in Mg-BGN-mediated tissue regeneration. This study provides a theoretical basis for the application of Mg-BGNs as nanomedicines to achieve in situ tissue regeneration in complex intrajoint pathological microenvironments. • Developing Mg incorporating mesoporous bioactive glass (Mg-BGNs) to regulate stem cells and macrophages emerges as a promising treatment for inducing the regeneration of injured meniscus. • Multiomics-based therapeutic analysis to illustrate the regulating mechanisms of Mg-BGNs for regulating the crosstalk between macrophage polarization and endogenous regenerative process. • The Mg-BGNs significantly activate the TRPM7 channel and subsequently trigger the activation of PPARγ/NF-κB pathways of macrophages and PI3K/Akt pathway of MSCs.

Topics & Concepts

In vivoMaterials scienceBioactive glassRegeneration (biology)Mesoporous materialMagnesiumMeniscusIn vitroBiomedical engineeringSelf-healing hydrogelsChemistryComposite materialPolymer chemistryMetallurgyBiochemistryCatalysisBiotechnologyPhysicsCell biologyIncidence (geometry)MedicineOpticsBiologyKnee injuries and reconstruction techniquesTendon Structure and TreatmentTribology and Wear Analysis
3D-printed PCL scaffolds combined with injectable sodium alginate/magnesium-doped mesoporous bioactive glass nanosphere hydrogel for meniscus regeneration: In vitro, In vivo, and multiomics-based therapeutic analyses | Litcius