Abstract
Osteoporosis disrupts the healthy remodelling process in bone and affects its mechanical properties. Mechanical loading has been shown to be effective in stimulating bone formation to mitigate initial bone loss. However, no study has investigated the effects of repeated mechanical loading, with a pause of one week in between, in the mouse tibia with oestrogen deficiency. This study uses a combined experimental and computational approach, through longitudinal monitoring with micro-computed tomography, to evaluate the effects of loading on bone adaptation in the tibiae of ovariectomised (OVX) C57BL/6 mice from 14 to 22 weeks of age. Micro-FE models coupled with bone adaptation algorithms were used to estimate changes in local tissue strains due to OVX and mechanical loading, and to quantify the relationship between local strain and remodelling. The first in vivo mechanical loading increased apposition, by 50–150%, while resorption decreased by 50–60%. Both endosteal and periosteal resorption increased despite the second mechanical loading, and periosteal resorption was up to 70% higher than that after the first loading. This was found to correlate with an initial decrease in average strain energy density after the first loading, which was lower and more localised after the second loading. Predictions of bone adaptation showed that between 50 and 90% of the load-induced bone apposition is linearly strain driven at the organ-level, but resorption is more biologically driven at the local level. The results imply that a systematic increase in peak load or loading rate may be required to achieve a similar bone adaptation rate in specific regions of interests.
Highlights
bone mineral content (BMC) increased in wild type (WT) mice from weeks 14–18, but had modest changes in OVX and ML mice, and caused the significant difference in BMC between WT and ML groups at week 14 to become insignificant at weeks 16 and 18 (Fig. 3A)
The second applied load at week 21 countered the effects of OVX despite the pause in loading at week 20, as BMC was significantly different, while bone mineral density (BMD) was tending towards significance between the two groups (p = 0.052)
Using in vivo longitudinal micro-CT imaging to monitor the effects of mechanical loading treatment in OVX tibia, revealed for the first time that the load-induced response was higher during the first set of mechanical loading, and showed an increase in periosteal resorption after the second set of mechanical loading
Summary
Please cite this article as: V.S. Cheong, B.C. Roberts and V. Kadirkamanathan et al, Bone remodelling in the mouse tibia is spatiotemporally modulated by oestrogen deficiency and external mechanical loading: A combined in vivo/in silico study, Acta Biomaterialia, https://doi.org/10.1016/j.actbio.2020.09.011 JID: ACTBIO 2V.S. Cheong, B.C. Roberts and V. Kadirkamanathan et al / Acta Biomaterialia xxx (xxxx) xxx and interventions to treat osteoporosis and other musculoskeletal diseases [2,3,4], in order to lower the socio-economic burden on society.
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