Bone morphology allows estimation of loading history in a murine model of bone adaptation

Christen, Patrik<sup>1</sup>; van Rietbergen, Bert<sup>1</sup>; Lambers, Floor M.<sup>2</sup>; Müller, Ralph<sup>2</sup>; Ito, Keita<sup>1</sup>

Affiliations

¹Orthopaedic Biomechanics, Department of Biomedical Engineering, Eindhoven University of Technology, PO Box 513, WH 4.11, 5600 MB, Eindhoven, The Netherlands

²Institute for Biomechanics, ETH Zurich, HCI E 357.2, Wolfgang-Pauli-Str. 10, 8093 Zurich, Switzerland

Abstract and keywords

Bone adapts its morphology (density/microarchitecture) in response to the local loading conditions in such away that a uniform tissue loading is achieved (‘Wolff’s law’). This paradigm has been used as a basis for bone remodeling simulations to predict the formation and adaptation of trabecular bone. However, in order to predict bone architectural changes in patients, the physiological external loading conditions, to which the bone was adapted, need to be determined. In the present study, we developed a novel bone loading estimation method to predict such external loading conditions by calculating the loading history that produces the most uniform bone tissue loading.We applied this method to murine caudal vertebrae of two groups that were in vivo loaded by either 0 or 8 N, respectively. Plausible load cases were sequentially applied to micro-finite element models of the mice vertebrae, and scaling factors were calculated for each load case to derive the most uniform tissue strainenergy density when all scaled load cases are applied simultaneously. The bone loading estimation method was able to predict the difference in loading history of the two groups and the correct load magnitude for the loaded group. This result suggests that the bone loading history can be estimated from its morphology and that such a method could be useful for predicting the loading history for bone remodeling studies or at sites where measurements are difficult, as in bone in vivo or fossil bones.

Keywords: Bone loading estimation; Bone adaptation; Micro-finite element analysis; Bone remodeling algorithm; Murine caudal vertebra

Links

DOI: 10.1007/s10237-011-0327-x

PubMed: 21735242

WoS: 000300518000017

History

Received: 2011-01-30

Accepted: 2011-06-20

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Cited By (10)

Year	Entry
2019	Wood Z, Lynn L, Nguyen JT, Black MA, Patel M, Barak MM. Are we crying wolff? 3D printed replicas of trabecular bone structure demonstrate higher stiffness and strength during off-axis loading. Bone. October 2019;127:635-645.
2014	Christen P, Ito K, Ellouz R, Boutroy S, Sornay-Rendu E, Chapurlat RD, van Rietbergen B. Bone remodelling in humans is load-driven but not lazy. Nat Commun. September 2014;5:4855.
2013	Schulte FA, Ruffoni D, Lambers FM, Christen D, Webster DJ, Kuhn G, Müller R. Local mechanical stimuli regulate bone formation and resorption in mice at the tissue level. PLoS One. April 2013;8(4):e62172.
2021	Malhotra A, Walle M, Paul GR, Kuhn GA, Müller R. Application of subject-specific adaptive mechanical loading for bone healing in a mouse tail vertebral defect. Sci Rep. January 22, 2021;11:1861.
2020	Aggleton J. First-Hand Experience: A Methodology for Exploring Bone Architecture [PhD thesis]. Bristol, UK: University of Bristol; January 2020.
2016	Li Z. Time-Lapsed in Vivo Bone Response to Implantation in a Mouse Model of Disease and Treatment [PhD thesis]. Swiss Federal Institute of Technology Zürich; 2016.
2019	Tourolle D. A Micro-Scale Multiphysics Framework for Fracture Healing and Bone Remodelling [PhD thesis]. Swiss Federal Institute of Technology Zürich; 2019.
2013	Christen P. Deciphering the Secret Message Within Bone Microstructure [PhD thesis]. Eindhoven University of Technology; 2013.
2018	Synek A. Predicting Habitual Activities from Bone Architecture Using a Biomechanical Approach [PhD thesis]. Vienna University of Technology; 2018.
2020	Mancuso ME. Defining the Multiscale Relationship Between Subject-Specific Bone Strain and Structural Adaptation in the Distal Radius of Women [PhD thesis]. Worcester, MA: Worcester Polytechnic Institute; July 2020.