The multiscale hierarchical structure of Heloderma suspectum osteoderms and their mechanical properties
Autor: | Alessandro Olivo, Sergio Bertazzo, Alana C. Sharp, Paul R. Shearing, Yousef Javanmardi, Emad Moeendarbary, Francesco Iacoviello, Alexander Kirby, Susan E. Evans, Elena Tsolaki, Inge K. Herrmann, Jian-Hao Li, Mehran Moazen, Kerda Keevend, Dan J. L. Brett, Murad Shabanli, Matthew J. Hayes |
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Rok vydání: | 2020 |
Předmět: |
Nano architecture
Biomimetic materials Materials science Heloderma 0206 medical engineering Biomedical Engineering 02 engineering and technology Biochemistry Bone and Bones Finite element simulation Biomaterials Animals Osteoderm Molecular Biology biology Atomic force microscopy Lizards Dermis General Medicine 021001 nanoscience & nanotechnology biology.organism_classification 020601 biomedical engineering Characterization (materials science) Evolutionary biology 0210 nano-technology Biotechnology |
Zdroj: | Acta Biomaterialia |
ISSN: | 1742-7061 |
DOI: | 10.1016/j.actbio.2020.02.029 |
Popis: | Osteoderms are hard tissues embedded in the dermis of vertebrates and have been suggested to be formed from several different mineralized regions. However, their nano architecture and micro mechanical properties had not been fully characterized. Here, using electron microscopy, µ-CT, atomic force microscopy and finite element simulation, an in-depth characterization of osteoderms from the lizard Heloderma suspectum, is presented. Results show that osteoderms are made of three different mineralized regions: a dense apex, a fibre-enforced region comprising the majority of the osteoderm, and a bone-like region surrounding the vasculature. The dense apex is stiff, the fibre-enforced region is flexible and the mechanical properties of the bone-like region fall somewhere between the other two regions. Our finite element analyses suggest that when combined into the osteoderm structure, the distinct tissue regions are able to shield the body of the animal by bearing the external forces. These findings reveal the structure-function relationship of the Heloderma suspectum osteoderm in unprecedented detail. STATEMENT OF SIGNIFICANCE: The structures of bone and teeth have been thoroughly investigated. They provide a basis not only for understanding the mechanical properties and functions of these hard tissues, but also for the de novo design of composite materials. Osteoderms, however, are hard tissues that must possess mechanical properties distinct from teeth and bone to function as a protective armour. Here we provide a detailed analysis of the nanostructure of vertebrate osteoderms from Heloderma suspectum, and show that their mechanical properties are determined by their multiscale hierarchical tissue. We believe this study contributes to advance the current knowledge of the structure-function relationship of the hierarchical structures in the Heloderma suspectum osteoderm. This knowledge might in turn provide a source of inspiration for the design of bioinspired and biomimetic materials. |
Databáze: | OpenAIRE |
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