Change of mechanical vertebrae properties due to progressive osteoporosis: Combined biomechanical and finite-element analysis within a rat model

Research output: Contribution to journalResearch articleContributedpeer-review



For assessing mechanical properties of osteoporotic bone, biomechanical testing combined with in silico modeling plays a key role. The present study focuses on microscopic mechanical bone properties in a rat model of postmenopausal osteoporosis. Female Sprague-Dawley rats were (1) euthanized without prior interventions, (2) sham-operated, and (3) subjected to ovariectomy combined with a multi-deficiencies diet. Rat vertebrae (corpora vertebrae) were imaged by micro-CT, their stiffness was determined by compression tests, and load-induced stress states as well as property changes due to the treatment were analyzed by finite-element modeling. By comparing vertebra stiffness measurements with finite-element calculations of stiffness, an overall microscopic Young's modulus of the bone was determined. Macroscopic vertebra stiffness as well as the microscopic modulus diminish with progression of osteoporosis by about 70 %. After strong initial changes of bone morphology, further decrease in macroscopic stiffness is largely due to decreasing microscopic Young's modulus. The micromechanical stress calculations reveal particularly loaded vertebra regions prone to failure. Osteoporosis-induced changes of the microscopic Young's modulus alter the fracture behavior of bone, may influence bone remodeling, and should be considered in the design of implant materials.


Original languageEnglish
Pages (from-to)405-414
Number of pages10
Journal Medical & biological engineering & computing : MBEC ; the journal of the International Federation for Medical and Biological Engineering
Issue number4
Publication statusPublished - Apr 2014

External IDs

researchoutputwizard legacy.publication#58248
Scopus 84897108266
PubMed 24518991



  • Biomechanics, Bone histology, Osteoporosis, Rat model, Young's modulus, finite element, analysis