Effects of hydration and mineralization on the deformation mechanisms of collagen fibrils in bone at the nanoscale
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Bone is a biomaterial with a structural load-bearing function. Investigating the biomechanics of bone at the nanoscale is important in application to tissue engineering, the development of bioinspired materials, and for characterizing factors such as age, trauma, or disease. At the nanoscale, bone is composed of fibrils that are primarily a composite of collagen, apatite crystals (mineral), and water. Though several studies have been done characterizing the mechanics of fibrils, the effects of variation and distribution of water and mineral content in fibril gap and overlap regions are unexplored. We investigate how the deformation mechanisms of collagen fibrils change as a function of mineral and water content. We use molecular dynamics to study the mechanics of collagen fibrils of 0 wt%, 20 wt%, and 40 wt% mineralization and 0 wt%, 2 wt%, and 4 wt% hydration under applied tensile stresses. We observe that the stress–strain behavior becomes more nonlinear with an increase in hydration, and an increase in mineral content for hydrated fibrils under tensile stress reduces the nonlinear stress versus strain behavior caused by hydration. The Young’s modulus of both non-mineralized and mineralized fibrils decreases as the water content increases. As the water content increases, the gap/overlap ratio increases by approximately 40% for the non-mineralized cases and 16% for the highly mineralized cases. Our results indicate that variations in mineral and water content change the distribution of water in collagen fibrils and that the water distribution changes the deformation of gap and overlap regions under tensile loading.
KeywordsMineralization in bone Mechanisms of deformation Molecular modeling of bone Collagen fibrils
MF and AKN would like to thank the support from Department of Mechanical Engineering, University of Arkansas, and also the Arkansas High Performance Computing Center (AHPCC). Authors also acknowledge the support in part by the National Science Foundation (NSF) under the Grants ARI#0963249, MRI#0959124, and EPS#0918970, and a grant from Arkansas Science and Technology Authority, managed by Arkansas High Performance Computing Center. We also acknowledge partial support from NSF Grant IIA 1457888.
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Conflict of interest
Authors declare no conflict of interest.
- Ahsan AS (2017) Effect of intrafibrillar mineralization on the mechanical properties of osteogenesisimperfecta bone using a cohesive finite element approach. The University of Texas, SanAntonioGoogle Scholar
- Bevington P, Robinson DK (2003) Data reduction and error analysis for the physical sciences. McGraw-Hill EducationGoogle Scholar
- Currey JD (2002) Bones: structure and mechanics. Princeton University Press, PrincetonGoogle Scholar
- Wess TJ, Hammersley A, Wess L, Miller A (1995) Type-I collagen packing, conformation of the triclinic unit-cell. J Mol Biol 248:487–493Google Scholar