Litcius/Paper detail

Pulsed electromagnetic fields mediate sensory nerve regulation for bone formation in aging models

Tiantian Wang, Zejun Liang, Changyi Wang, Jiehao Chen, Yaru Ma, Sihan Chen, Dong Zhou, Zhen Hong

2025Nature Communications6 citationsDOIOpen Access PDF

Abstract

Pulsed electromagnetic fields (PEMFs) enhance bone formation to combat osteoporosis, yet the mechanisms by which they promote bone health during aging remain unclear. This study shows PEMFs enhance new bone formation and innervation, promoting osteogenesis and reducing adipogenesis in mesenchymal stem cells (MSCs) in aging male mice. PEMF-induced osteogenesis is impaired by sensory nerve dysfunction in this model. Mechanistically, PEMFs stimulate sensory nerves to secrete semaphorin 3A (Sema3A), and depleting these nerves or knocking out Sema3a eliminates PEMFs' bone-forming effects. Sema3A interacts with neuropilin-1 (Nrp1) in MSCs that express the leptin receptor, aiding osteogenesis and inhibiting adipogenesis in aging male mice. The activation of the "Sema3A-Nrp1" pathway is central for the anti-senescence effects of PEMFs on MSCs, and knocking out Nrp1 in MSCs that express the leptin receptor negates PEMFs' benefits. Overall, PEMFs stimulate sensory nerves to produce Sema3A, which promotes osteogenesis, inhibits adipogenesis, and counters MSC senescence. This underscores their therapeutic potential for treating osteoporosis in aging males.

Topics & Concepts

SemaphorinMesenchymal stem cellAdipogenesisOsteoporosisSensory systemCell biologyNeuroscienceBone formationChemistrySensory nerveSEMA3ALeptinMechanotransductionStromal cellMedicineReceptorCortical boneOsteoblastSecretionNeuropilin 1BiologyBone healingEndocrinologyNerve growth factorCancer researchInternal medicineStem cellBone remodelingElectromagnetic Fields and Biological EffectsSpaceflight effects on biologyBiofield Effects and Biophysics
Pulsed electromagnetic fields mediate sensory nerve regulation for bone formation in aging models | Litcius