Litcius/Paper detail

Osteoporosis After Menopause and After Drug Therapy: The Molecular Mechanism of Bone Loss and Its Treatment

Kelly I-Rong Lee, Jie-Hong Chen, Kuo-Hu Chen

2026International Journal of Molecular Sciences10 citationsDOIOpen Access PDF

Abstract

Osteoporosis is a prevalent skeletal disorder characterized by reduced bone mass and microarchitectural deterioration, leading to increased fracture risk, particularly in aging populations. Postmenopausal osteoporosis (PMOP) remains the most common primary form and results from abrupt estrogen deficiency after menopause, which disrupts bone remodeling by accelerating the receptor activator of nuclear factor-κB ligand (RANKL)-mediated osteoclastogenesis, suppressing Wnt/β-catenin signaling, and promoting inflammatory cytokine production. In contrast, drug-induced osteoporosis (DIOP) encompasses a heterogeneous group of secondary bone disorders arising from pharmacologic exposures. Glucocorticoids suppress osteoblastogenesis, enhance osteoclast activity, and increase reactive oxygen species; long-term bisphosphonate therapy may oversuppress bone turnover, resulting in microdamage accumulation; denosumab withdrawal triggers a unique rebound surge in RANKL activity, often leading to rapid bone loss and multiple vertebral fractures. Medications including aromatase inhibitors, SSRIs, proton pump inhibitors, heparin, and antiepileptic drugs impair bone quality through diverse mechanisms. Standard antiresorptive agents remain first-line therapies, while anabolic agents such as teriparatide, abaloparatide, and romosozumab provide enhanced benefits in high-risk or drug-suppressed bone states. Transitional bisphosphonate therapy is essential when discontinuing denosumab, and individualized treatment plans-including drug holidays, lifestyle interventions, and monitoring vulnerable patients-are critical for optimizing outcomes. Emerging approaches such as small interfering RNA (siRNA)-based therapeutics, anti-sclerostin agents, digital monitoring technologies, and regenerative strategies show promise for future precision medicine management. Understanding the distinct and overlapping molecular mechanisms of osteoporosis is essential for improving fracture prevention and long-term skeletal health.

Topics & Concepts

OsteoporosisMedicineDenosumabBone remodelingOsteoclastRANKLBisphosphonateAnabolic AgentsOsteoprotegerinBioinformaticsBone resorptionAromataseInternal medicineEndocrinologyBone Density Conservation AgentsMenopauseBone diseaseDrugBone densityPharmacologySelective estrogen receptor modulatorSenile osteoporosisOsteoblastEstrogenRANK LigandOsteopeniaZoledronic acidStrontium ranelateTolerabilityOncologyHormone replacement therapy (female-to-male)RaloxifeneSkeletal disorderPeak bone massBone health and osteoporosis researchBone Metabolism and DiseasesBone health and treatments