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Microstructure, Spectroscopic Studies and Nanomechanical Properties of Human Cortical Bone with Osteogenesis Imperfecta
Published online by Cambridge University Press: 11 March 2014
Abstract
Bone is a natural protein (collagen)-mineral (hydroxyapatite) nanocomposite with hierarchically organized structure. Our previous work has demonstrated orientational differences in stoichiometry of hydroxyapatite resulting from orientationally dependent collagen-mineral interactions in bone. The nature of these interactions has been investigated both through molecular dynamics simulations as well as nanomechanical and infrared spectroscopic experiments. In this study, we report experimental studies on human cortical bone with osteogenesis imperfecta (OI), a disease characterized by fragility of bones and other tissues rich in type I collagen. About 90% of OI cases result from causative variant in one of the two structural genes (COL1A1 or COL1A2) for type I procollagens. OI provides an interesting platform for investigating how alterations of collagen at the molecular level cause changes in structure and mechanics of bone. Fourier transform spectroscopy, electron microscopy (SEM), and nanomechanical experiments describe the structural and molecular differences in bone ultrastructure due to presence of diseases. Photoacoustic-Fourier transform infrared spectroscopy (PA-FTIR) experiments have been conducted to investigate the orientational differences in molecular structure of OI bone, which is also compared with that of healthy human cortical bone. Further, in situ SEM static nanomechanical testing is conducted in the transverse and longitudinal directions in the OI bone. Microstructural defects and abnormities of OI bone were ascertained using scanning electron microscopies. These results provide an insight into molecular basis of deformation and mechanical behavior of healthy human bone and OI bone.
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- Copyright © Materials Research Society 2014
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REFERENCES
Boyde, A., Travers, R., Glorieux, F. H. and Jones, S. J., Calcified Tissue International
64(3), 185–190 (1999).CrossRefGoogle Scholar
Fratzl, P., Paris, O., Klaushofer, K. and Landis, W. J., Journal of Clinical Investigation
97(2), 396–402 (1996).CrossRefGoogle Scholar
Camacho, N. P., Landis, W. J. and Boskey, A. L., Connective Tissue Research
35 (1-4), 259–265 (1996).CrossRefGoogle Scholar
Vanleene, M., Porter, A., Guillot, P. V., Boyde, A., Oyen, M. and Shefelbine, S., Bone
50(6), 1317–1323 (2012).CrossRefGoogle ScholarPubMed
Gu, C., Katti, D. R. and Katti, K. S., Spectrochimica acta Part A
103, 25–37 (2013).CrossRefGoogle Scholar
Pradhan, S. M., Katti, K. S. and Katti, D. R., Journal of engineering mechanics (2012).Google Scholar
Katti, D. R., Pradhan, S. M. and Katti, K. S., Journal of Biomechanics
43(9), 1723–1730 (2010).CrossRefGoogle Scholar
Bhowmik, R., Katti, K. S. and Katti, D. R., Journal of Materials Science
42(21), 8795–8803 (2007).CrossRefGoogle Scholar
Pradhan, S. M., Katti, D. R. and Katti, K. S., Journal of nanomechanics and micromechanics
1(3), 104–110 (2011).CrossRefGoogle Scholar
Traub, W., Arad, T., Vetter, U. and Weiner, S., Matrix Biology
14(4), 337–345 (1994).CrossRefGoogle Scholar
Socrates, G., Infrared and Raman Characteristic group frequencies: tables and charts, 3rd ed. (John Wiley & Sons, Chichester, 2004).Google Scholar
van Dijk, F. S., Byers, P. H., Dalgleish, R., Malfait, F., Maugeri, A., Rohrbach, M., Symoens, S., Sistermans, E. A. and Pals, G., European Journal of Human Genetics
20(1), 11–19 (2012).CrossRefGoogle Scholar
Farlay, D., Panczer, G., Rey, C., Delmas, P. D. and Boivin, G., Journal of Bone and Mineral Metabolism
28(4), 433–445 (2010).CrossRefGoogle Scholar
Katti, K. S., Mohanty, B. and Katti, D. R., Journal of Materials Research
21(5), 1237–1242 (2006).CrossRefGoogle Scholar