A novel numerical model for the prediction of patient-dependent bone density loss in microgravity based on micro-CT images

The deterioration of the musculoskeletal system is a serious health concern for long-term space missions. The accumulated information over the past decades of space flights showed that microgravity impacts significantly the musculoskeletal system with muscle atrophy and bone loss. Until now, it has...

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Bibliographic Details
Published in:Continuum mechanics and thermodynamics 2020-05, Vol.32 (3), p.927-943
Main Authors: Bagherian, A., Baghani, M., George, D., RĂ©mond, Y., Chappard, C., Patlazhan, S., Baniassadi, M.
Format: Article
Language:English
Subjects:
Algorithms
Analysis
Atrophy
Biocompatibility
Biomedical materials
Bone density
Bones
Classical and Continuum Physics
Computed tomography
CT imaging
Degradation
Density
Engineering Thermodynamics
Health care reform
Heat and Mass Transfer
Mathematical models
Mathematical optimization
Mechanics
Microgravity
Microstructure
Muscles
Musculoskeletal system
Optimization
Original Article
Osteoporosis
Physics
Physics and Astronomy
Space missions
Structural Materials
Theoretical and Applied Mechanics
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Summary:The deterioration of the musculoskeletal system is a serious health concern for long-term space missions. The accumulated information over the past decades of space flights showed that microgravity impacts significantly the musculoskeletal system with muscle atrophy and bone loss. Until now, it has been difficult to make reasonable predictions of the bone loss for prolonged space missions due to the lack of in-space experimental data and weak understanding of the mechanobiological bone mechanisms. On earth, the healthy musculoskeletal degradation is mainly age related with osteoporosis and delayed fracture healing. A better understanding of the bone mechanobiological functions could help us improve our model predictions of the musculoskeletal health system during long-term space missions. We develop a numerical model able to predict the bone loss at the mesoscopic scale (bone trabecula) in microgravity. The model is able to correlate the calculated bone degradation mechanism with data available in the literature showing the effective bone density loss measured experimentally. An optimization algorithm is used for an average bone microstructure distribution and long-term prediction. Extrapolation is made to link the local bone loss at the structural scale with the corresponding effective bone strength. The first part of the paper details the extraction of the bone microstructure using micro-CT images and numerical model development. Next, the degradation and optimization schemes are detailed. Finally, some results are presented for long-term degradation.
ISSN:0935-1175
1432-0959
DOI:10.1007/s00161-019-00798-8