Microscale compressive behavior of hydrated lamellar bone at high strain rates

Research output: Contribution to journalResearch articleContributedpeer-review


  • Cinzia Peruzzi - (Author)
  • Rajaprakash Ramachandramoorthy - (Author)
  • Alexander Groetsch - (Author)
  • Daniele Casari - (Author)
  • Philippe Gronquist - (Author)
  • Markus Rueggeberg - , Chair of Forest Utilization (Author)
  • Johann Michler - (Author)
  • Jakob Schwiedrzik - (Author)


The increased risk of fracture in the elderly associated with metabolic conditions like osteoporosis poses a significant strain on health care systems worldwide. Due to bone's hierarchical nature, it is necessary to study its mechanical properties and failure mechanisms at several length scales. We conducted micropillar compression experiments on ovine cortical bone to assess the anisotropic mechanical response at the lamellar scale over a wide range of strain rates (10−4 to 8·102 s−1). At the microscale, lamellar bone exhibits a strain rate sensitivity similar to what is reported at the macroscale suggesting that it is an intrinsic property of the extracellular matrix. Significant shear band thickening was observed at high strain rates by HRSEM and STEM imaging. This is likely caused by the material's inability to accommodate the imposed deformation by propagation of thin kink bands and shear cracks at high strain rates, leading to shear band thickening and nucleation. The post-yield behavior is strain rate and direction dependent: hardening was observed for transverse oriented micropillars and hardening modulus increases with strain rate by a factor of almost 2, while axially oriented micropillars showed strain softening and an increase of the softening peak width and work to ultimate stress as a function of strain rate. This suggests that for compression at the micrometer scale, energy absorption in bone increases with strain rate. This study highlights the importance of investigating bone strength and post-yield behavior at lower length scales, under hydrated conditions and at clinically relevant strain rates.


Original languageEnglish
Pages (from-to)403-414
JournalActa biomaterialia
Issue number131
Publication statusPublished - 1 Sep 2021

External IDs

Scopus 85111533180



  • Bone, Micropillar compression, High strain rate, Strain rate sensitivity, Deformation and failure mechanisms