Trabecular bone remodeling in the ageing mouse: a micro-multiphysics agent-based<i>in silico</i>model using single-cell mechanomics

Boaretti, Daniele; Marques, F. C.; Ledoux, Charles; Singh, Amit; Kendall, Jack J.; Wehrle, Esther; Kuhn, Gisela; Bansod, Yogesh Deepak; Schulte, Friederike A.; Müller, Ralph

doi:10.1101/2022.11.16.516723

Cited by 3 publications

(5 citation statements)

References 85 publications

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“…Eventually, these factors were vital to producing relatively smooth RmV curves and enabling consistent and plausible piecewise linear, and hyperbola fits. In any case, as previous work has focused on group average results both in vivo (Schulte et al 2013, Razi et al 2015, San Cheong et al 2020) and in silico (Levchuk et al 2014, San Cheong et al 2020, Boaretti et al 2023), our analysis still aligns with such standard practices. Second, contrasting with conditional probability-based approaches, (re)modeling events are no longer characterized separately since our approach yields a single curve representing the average RmV describing the net effect of (re)modeling events for a given mechanical signal.…”

Section: Discussionsupporting

confidence: 62%

“…Furthermore, the decreased anabolic response observed in the RmV curves for high strains may also be linked to a decrease in mechanosensitivity resulting from increased cell stiffness, as previously reported for such high strain values (Nawaz et al 2012). Therefore, the trends estimated with the mechanostat remodeling velocity curves could be leveraged by in silico simulations that also rely on time-lapsed in vivo micro-CT data as input, such as novel agent-based models that simulate individual cell populations in 3D (Tourolle 2019, Boaretti et al 2022) and with that, improve the accuracy of their predictions with respect to in vivo data. In this regard, our results demonstrating that several parameters estimated from the mechanostat also follow a logarithmic relationship with loading frequency can help to calibrate such models and investigate loading frequency-dependent responses in silico .…”

Section: Discussionmentioning

confidence: 99%

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Mechanostat parameters estimated from time-lapsedin vivomicro-computed tomography data of mechanically driven bone adaptation are logarithmically dependent on loading frequency

Marques

Boaretti

Walle

et al. 2023

Preprint

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Mechanical loading is a key factor governing bone remodeling and adaptation. Both preclinical and clinical studies have demonstrated its effects on bone tissue, which were also notably predicted in the mechanostat theory. Indeed, existing methods to quantify bone mechanoregulation have successfully associated the frequency of remodeling events with local mechanical signals, combining time-lapsed in vivo micro-computed tomography (micro-CT) imaging and micro-finite element (micro-FE) analysis. However, a correlation between the local surface velocity of remodeling events and mechanical signals has not been shown. As many degenerative bone diseases have also been linked to impaired bone remodeling, this relationship could provide an advantage in detecting the effects of such conditions and advance our understanding of the underlying mechanisms. Therefore, in this study, we introduce a novel method to estimate remodeling velocity (RmV) curves from time-lapsed in vivo mouse caudal vertebrae data under static and cyclic mechanical loading. These curves can be fitted with piecewise linear functions as proposed in the mechanostat theory. Accordingly, new remodeling parameters can be derived from such data, including formation saturation levels (FSL), resorption velocity modulus (RVM), and remodeling thresholds (RmT). Our results revealed that the norm of the gradient of strain energy density (gradSED) yielded the highest accuracy to quantify mechanoregulation data using micro-FE analysis with homogeneous material properties, while effective strain was the best predictor for micro-FE analysis with heterogeneous material properties. Furthermore, RmV curves could be accurately described with piecewise linear and hyperbola functions (root mean square error below 0.2 um/day for weekly analysis) and several remodeling parameters determined from these curves followed a logarithmic relationship with loading frequency, especially FSL and RmT values for both weekly and four-weekly analysis. Crucially, RmV curves and derived parameters could detect differences in mechanically driven bone adaptation, which complemented previous results showing a logarithmic relationship between loading frequency and net change in bone volume fraction over four weeks. Together, we expect this data to support the calibration of in silico models of bone adaptation and the characterization of the effects of mechanical loading and pharmaceutical treatment interventions in vivo.

show abstract

Section: Discussionsupporting

confidence: 62%

Section: Discussionmentioning

confidence: 99%

Mechanostat parameters estimated from time-lapsedin vivomicro-computed tomography data of mechanically driven bone adaptation are logarithmically dependent on loading frequency

Marques

Boaretti

Walle

et al. 2023

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…Eventually, these factors were vital to producing relatively smooth RmV curves and enabling consistent and plausible piecewise linear, and hyperbola fits. In any case, as previous work has focused on group average results both in vivo ( Schulte et al, 2013 ; Razi et al, 2015 ; San Cheong et al, 2020a ) and in silico ( Levchuk et al, 2014 ; San Cheong et al, 2020a ; Boaretti et al, 2023 ), our analysis still aligns with such standard practices. Second, contrasting with conditional probability-based approaches, (re)modeling events are no longer characterized separately since our approach yields a single curve representing the average RmV describing the net effect of (re)modeling events for a given mechanical signal.…”

Section: Discussionsupporting

confidence: 62%

“…In agreement with these studies and with potential relevance for future in silico models, we chose to also focus our analysis on velocity rather than change in bone mass, spatially resolving the displacement of surface voxels between time-points. In fact, recent advances in the context of in silico single-cell mechanomics ( Boaretti et al, 2023 ) have associated positive and negative velocities with the activity of osteoblasts and osteoclasts, respectively. Still, converting the output to other units of interest, including a change in bone volume as originally proposed, is equally possible.…”

Section: Discussionmentioning

confidence: 99%

“…Furthermore, the decreased anabolic response observed in the RmV curves for high strains may also be linked to a decrease in mechanosensitivity resulting from increased cell stiffness, as previously reported for such high strain values ( Nawaz et al, 2012 ). Therefore, the trends estimated with the mechanostat (re)modeling velocity curves could be leveraged by in silico simulations that also rely on time-lapsed in vivo micro-CT data as input, such as novel agent-based models that simulate individual cell populations in 3D ( Tourolle, 2019 ; Boaretti et al, 2023 ) and, with that, improve the accuracy of their predictions with respect to in vivo data. For this reason, we chose to express RmV curves using effective strain, as this signal has already been implemented successfully in such in silico models.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Mechanostat parameters estimated from time-lapsed in vivo micro-computed tomography data of mechanically driven bone adaptation are logarithmically dependent on loading frequency

Marques

Boaretti

Walle

et al. 2023

Front. Bioeng. Biotechnol.

Self Cite

View full text Add to dashboard Cite

Mechanical loading is a key factor governing bone adaptation. Both preclinical and clinical studies have demonstrated its effects on bone tissue, which were also notably predicted in the mechanostat theory. Indeed, existing methods to quantify bone mechanoregulation have successfully associated the frequency of (re)modeling events with local mechanical signals, combining time-lapsed in vivo micro-computed tomography (micro-CT) imaging and micro-finite element (micro-FE) analysis. However, a correlation between the local surface velocity of (re)modeling events and mechanical signals has not been shown. As many degenerative bone diseases have also been linked to impaired bone (re)modeling, this relationship could provide an advantage in detecting the effects of such conditions and advance our understanding of the underlying mechanisms. Therefore, in this study, we introduce a novel method to estimate (re)modeling velocity curves from time-lapsed in vivo mouse caudal vertebrae data under static and cyclic mechanical loading. These curves can be fitted with piecewise linear functions as proposed in the mechanostat theory. Accordingly, new (re)modeling parameters can be derived from such data, including formation saturation levels, resorption velocity moduli, and (re)modeling thresholds. Our results revealed that the norm of the gradient of strain energy density yielded the highest accuracy in quantifying mechanoregulation data using micro-finite element analysis with homogeneous material properties, while effective strain was the best predictor for micro-finite element analysis with heterogeneous material properties. Furthermore, (re)modeling velocity curves could be accurately described with piecewise linear and hyperbola functions (root mean square error below 0.2 µm/day for weekly analysis), and several (re)modeling parameters determined from these curves followed a logarithmic relationship with loading frequency. Crucially, (re)modeling velocity curves and derived parameters could detect differences in mechanically driven bone adaptation, which complemented previous results showing a logarithmic relationship between loading frequency and net change in bone volume fraction over 4 weeks. Together, we expect this data to support the calibration of in silico models of bone adaptation and the characterization of the effects of mechanical loading and pharmaceutical treatment interventions in vivo.

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Mechanoregulation analysis of bone formation in tissue engineered constructs requires a volumetric method using time-lapsed micro-computed tomography

Griesbach,

Schulte,

Schädli

et al. 2024

Acta Biomaterialia

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Trabecular bone remodeling in the ageing mouse: a micro-multiphysics agent-basedin silicomodel using single-cell mechanomics

Cited by 3 publications

References 85 publications

Mechanostat parameters estimated from time-lapsedin vivomicro-computed tomography data of mechanically driven bone adaptation are logarithmically dependent on loading frequency

Mechanostat parameters estimated from time-lapsedin vivomicro-computed tomography data of mechanically driven bone adaptation are logarithmically dependent on loading frequency

Mechanostat parameters estimated from time-lapsed in vivo micro-computed tomography data of mechanically driven bone adaptation are logarithmically dependent on loading frequency

Mechanoregulation analysis of bone formation in tissue engineered constructs requires a volumetric method using time-lapsed micro-computed tomography

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