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Divalent metal ions enhance bone regeneration through modulation of nervous systems and metabolic pathways

Ying Luo, Baoyi Liu, Yashi Qiu, Lichen Li, Fan Yang, Chao Zhang, Jiali Wang

2025Bioactive Materials12 citationsDOIOpen Access PDF

Abstract

levels. Interestingly, the divalent cations alone did not influence osteogenesis and aerobic glycolysis of undifferentiated MSCs. However, once the osteogenic differentiation of MSCs was initiated by neurotransmitters or osteogenic differentiation medium, the osteogenesis of MSCs could be significantly promoted by the divalent cations, which was accompanied by the improved aerobic glycolysis. In terms of indirect effects, the divalent cations significantly upregulated levels of sensory nerve derived CGRP, PNS produced choline acetyltransferase and type H vessels, while significantly tuned down sympathetic activity in the defect zone in rats, thereby contributing to significantly increased bone formation relative to the control group. Together, the divalent cations favor bone regeneration via modulation of sensory-autonomic nervous systems and promotion of aerobic glycolysis-driven osteogenesis of MSCs after osteogenic initiation by neurotransmitters.

Topics & Concepts

Regeneration (biology)DivalentModulation (music)IonMetalMetal ions in aqueous solutionChemistryMaterials scienceBiophysicsCell biologyMetallurgyBiologyPhysicsOrganic chemistryAcousticsImmune responses and vaccinationsTrace Elements in HealthMicroRNA in disease regulation
Divalent metal ions enhance bone regeneration through modulation of nervous systems and metabolic pathways | Litcius