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Tissue strain amplification at the osteocyte lacuna: A microstructural finite element analysis
- Source :
- Journal of Biomechanics. 40:2199-2206
- Publication Year :
- 2007
- Publisher :
- Elsevier BV, 2007.
-
Abstract
- A parametric finite element model of an osteocyte lacuna was developed to predict the microstructural response of the lacuna to imposed macroscopic strains. The model is composed of an osteocyte lacuna, a region of perilacunar tissue, canaliculi, and the surrounding bone tissue. A total of 45 different simulations were modeled with varying canalicular diameters, perilacunar tissue material moduli, and perilacunar tissue thicknesses. Maximum strain increased with a decrease in perilacunar tissue modulus and decreased with an increase in perilacunar tissue modulus, regardless of the thickness of the perilacunar region. An increase in the predicted maximum strain was observed with an increase in canalicular diameter from 0.362 to 0.421 microm. In response to the macroscopic application of strain, canalicular diameters increased 0.8% to over 1.0% depending on the perilacunar tissue modulus. Strain magnification factors of over 3 were predicted. However, varying the size of the perilacunar tissue region had no effect on the predicted perilacunar tissue strain. These results indicate that the application of average macroscopic strains similar to strain levels measured in vivo can result in significantly greater perilacunar tissue strains and canaliculi deformations. A decrease in the perilacunar tissue modulus amplifies the perilacunar tissue strain and canaliculi deformation while an increase in the local perilacunar tissue modulus attenuates this effect.
- Subjects :
- Materials science
Biomedical Engineering
Biophysics
Modulus
Bone canaliculus
Bone tissue
Models, Biological
Osteocytes
Bone and Bones
Article
Weight-Bearing
medicine
Animals
Humans
Computer Simulation
Orthopedics and Sports Medicine
Composite material
Strain (chemistry)
Rehabilitation
Anatomy
Adaptation, Physiological
Finite element method
medicine.anatomical_structure
Osteocyte
Stress, Mechanical
Deformation (engineering)
Lacuna
Subjects
Details
- ISSN :
- 00219290
- Volume :
- 40
- Database :
- OpenAIRE
- Journal :
- Journal of Biomechanics
- Accession number :
- edsair.doi.dedup.....1e284182d1ef17fc124e9806116bc059