Bone remodelling in humans is load-driven but not lazy

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Christen, Patrik^1,3; Ito, Keita¹; Ellouz, Rafaa²; Boutroy, Stephanie²; Sornay-Rendu, Elisabeth²; Chapurlat, Roland D.²; van Rietbergen, Bert¹

Bone remodelling in humans is load-driven but not lazy

Nat Commun. September 2014;5:4855

©2014 Macmillan Publishers Limited. All rights reserved

Affiliations

¹Orthopaedic Biomechanics, Department of Biomedical Engineering, Eindhoven University of Technology, P.O. Box 513, 5600 MB Eindhoven, The Netherlands

²INSERM UMR 1033, Hôpital Edouard Herriot, Université de Lyon, 69437 Lyon, France

³Present address: Institute for Biomechanics, ETH Zurich, Hönggerbergring 64, 8093 Zurich, Switzerland
Abstract

During bone remodelling, bone cells are thought to add and remove tissue at sites with high and low loading, respectively. To predict remodelling, it was proposed that bone is removed below and added above certain thresholds of tissue loading and within these thresholds, called a ‘lazy zone’, no net change in bone mass occurs. Animal experiments linking mechanical loading with changes in bone density or microstructure support load-adaptive bone remodelling, while in humans the evidence for this relationship at the micro-scale is still lacking. Using new high-resolution CT imaging techniques and computational methods, we quantify microstructural changes and physiological tissue loading in humans. Here, we show that bone remodelling sites in healthy postmenopausal women strongly correlate with tissue loading following a linear relationship without a ‘lazy zone’ providing unbiased evidence for load-driven remodelling in humans. This suggests that human and animal bones both react to loading induced remodelling in a similar fashion.
Links

DOI: 10.1038/ncomms5855

PubMed: 25209333

WoS: 000342929900003
History

Received: 2014-03-05

Accepted: 2014-07-30

Online: 2014-09-11

Cited Works (28)

Year	Entry
2008	MacNeil JA, Boyd SK. Bone strength at the distal radius can be estimated from high-resolution peripheral quantitative computed tomography and the finite element method. Bone. June 2008;42(6):1203-1213.
2011	Lambers FM, Schulte FA, Kuhn G, Webster DJ, Müller R. Mouse tail vertebrae adapt to cyclic mechanical loading by increasing bone formation rate and decreasing bone resorption rate as shown by time-lapsed in vivo imaging of dynamic bone morphometry. Bone. December 2011;49(6):1340-1350.
1987	Rubin CT, Lanyon LE. Osteoregulatory nature of mechanical stimuli: function as a determinant for adaptive remodeling in bone. J Orthop Res. 1987;5(2):300-310.
1892	Wolff J. Das Gesetz der Transformation der Knochen. Berlin: Hirschwald; 1892.
1993	Mori S, Burr DB. Increased intracortical remodeling following fatigue damage. Bone. March–April 1993;14(2):103-109.
1997	Arlot ME, Sornay-Rendu E, Garnero P, Vey-Marty B, Delmas PD. Apparent pre- and postmenopausal bone loss evaluated by DXA at different skeletal sites in women: the OFELY cohort. J Bone Miner Res. April 1997;12(4):683-690.
2005	Boutroy S, Bouxsein ML, Munoz F, Delmas PD. In vivo assessment of trabecular bone microarchitecture by high-resolution peripheral quantitative computed tomography. J Clin Endocrinol Metab. December 2005;90(12):6508-6515.
1991	Bertram JEA, Swartz SM. The "law of bone transformation": a case of crying Wolff? Biol Rev. August 1991;66(3):245-273.
2012	Christen P, van Rietbergen B, Lambers FM, Müller R, Ito K. Bone morphology allows estimation of loading history in a murine model of bone adaptation. Biomech Model Mechanobiol. March 2012;11(3-4):483-492.
1998	Ulrich D, van Rietbergen B, Weinans H, Rüegsegger P. Finite element analysis of trabecular bone structure: a comparison of image-based meshing techniques. J Biomech. December 1998;31(12):1187-1192.
2009	Cardoso L, Herman BC, Verborgt O, Laudier D, Majeska RJ, Schaffler MB. Osteocyte apoptosis controls activation of intracortical resorption in response to bone fatigue. J Bone Miner Res. April 2009;24(4):597-605.
1992	Huiskes R, Weinans H, Van Rietbergen B. The relationship between stress shielding and bone resorption around total hip stems and the effects of flexible materials. Clin Orthop Relat Res. January 1992;274:124-134.
2000	Vico L, Collet P, Guignandon A, Lafage-Proust M-H, Thomas T, Rehailia M, Alexandre C. Effects of long-term microgravity exposure on cancellous and cortical weight-bearing bones of cosmonauts. Lancet. May 6, 2000;355(9215):1607-1611.
1985	Burr DB, Martin RB, Schaffler MB, Radin EL. Bone remodeling in response to in vivo fatigue microdamage. J Biomech. 1985;18(3):189-200.
2014	Ellouz R, Chapurlat R, van Rietbergen B, Christen P, Pialat J-B, Boutroy S. Challenges in longitudinal measurements with HR-pQCT: evaluation of a 3D registration method to improve bone microarchitecture and strength measurement reproducibility. Bone. June 2014;63:147-157.
1964	Frost HM. The Laws of Bone Structure. Springfield, IL: Charles C. Thomas; 1964.
1996	Garnero P, Sornay‐Rendu E, Chapuy M, Delmas PD. Increased bone turnover in late postmenopausal women is a major determinant of osteoporosis. J Bone Miner Res. 1996;11(3):337-349.
2009	Bevill G, Keaveny TM. Trabecular bone strength predictions using finite element analysis of micro-scale images at limited spatial resolution. Bone. April 2009;44(4):579-584.
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.
2011	Barak MM, Lieberman DE, Hublin J-J. A Wolff in sheep's clothing: trabecular bone adaptation in response to changes in joint loading orientation. Bone. December 2011;49(6):1141-1151.
1881	Roux W. Der kampf der theile im organismus: Ein beitrag zur vervollständigung der mechanischen zweckmässigkeitslehre. Leipzig: Verlag von Wilhelm Engelmann; 1881.
2006	Pontzer H, Lieberman DE, Momin E, Devlin MJ, Polk JD, Hallgrímsson B, Cooper DML. Trabecular bone in the bird knee responds with high sensitivity to changes in load orientation. J Exp Biol. January 2006;209(1):57-65.
2010	Sugiyama T, Price JS, Lanyon LE. Functional adaptation to mechanical loading in both cortical and cancellous bone is controlled locally and is confined to the loaded bones. Bone. February 2010;46(2):314-321.
2012	Sugiyama T, Meakin LB, Browne WJ, Galea GL, Price JS, Lanyon LE. Bones' adaptive response to mechanical loading is essentially linear between the low strains associated with disuse and the high strains associated with the lamellar/woven bone transition. J Bone Miner Res. August 2012;27(8):1784-1793.
1995	van Rietbergen B, Weinans H, Huiskes R, Odgaard A. A new method to determine trabecular bone elastic properties and loading using micromechanical finite-element models. J Biomech. January 1995;28(1):69-81.
1987	Cowin SC. Bone remodeling of diaphyseal surfaces by torsional loads: theoretical predictions. J Biomech. 1987;20(11-12):1111-1120.
1987	Huiskes R, Weinans H, Grootenboer HJ, Dalstra M, Fudala B, Slooff TJ. Adaptive bone-remodeling theory applied to prosthetic-design analysis. J Biomech. 1987;20(11-12):1135-1150.
1997	Frost HM. On our age‐related bone loss: insights from a new paradigm. J Bone Miner Res. October 1997;12(10):1539-1546.

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2021	Zhang J, Wang Y, Cheng K-l, Cheuk K, Lam T-p, Hung ALH, Cheng JCY, Qiu Y, Müller R, Christen P, Lee WYW. Association of higher bone turnover with risk of curve progression in adolescent idiopathic scoliosis. Bone. February 2021;143:115655.
2021	Whittier DE, Burt LA, Boyd SK. A new approach for quantifying localized bone loss by measuring void spaces. Bone. February 2021;143:115785.
2021	García-Aznar JM, Nasello G, Hervas-Raluy S, Pérez MÁ, Gómez-Benito MJ. Multiscale modeling of bone tissue mechanobiology. Bone. October 2021;151:116032.
2023	Walle M, Whittier DE, Schenk D, Atkins PR, Blauth M, Zysset P, Lippuner K, Müller R, Collins CJ. Precision of bone mechanoregulation assessment in humans using longitudinal high-resolution peripheral quantitative computed tomography in vivo. Bone. July 2023;172:116780.
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2023	Kerberger R, Brunello G, Drescher D, van Rietbergen B, Becker K. Micro finite element analysis of continuously loaded mini-implants: a micro-CT study in the rat tail model. Bone. December 2023;177:116912.
2024	Cramer EEA, de Wildt BWM, Hendriks JGE, Ito K, Hofmann S. Integration of osteoclastogenesis through addition of PBMCs in human osteochondral explants cultured ex vivo. Bone. January 2024;178:116935.
2020	Lerebours C, Weinkamer R, Roschger A, Buenzli PR. Mineral density differences between femoral cortical bone and trabecular bone are not explained by turnover rate alone. Bone Rep. December 1, 2020;13:100731.
2021	Peyroteo MMA, Belinha J, Natal Jorge RM. A mathematical biomechanical model for bone remodeling integrated with a radial point interpolating meshless method. Comput Biol Med. February 2021;129:104170.
2015	van Rietbergen B, Ito K. A survey of micro-finite element analysis for clinical assessment of bone strength: the first decade. J Biomech. March 18, 2015;48(5):832-841.
2020	Mancuso ME, Troy KL. Relating bone strain to local changes in radius microstructure following 12 months of axial forearm loading in women. J Biomech Eng. November 2020;142(11):111014.
2017	Sandino C, McErlain DD, Schipilow J, Boyd SK. Mechanical stimuli of trabecular bone in osteoporosis: a numerical simulation by finite element analysis of microarchitecture. J Mech Behav Biomed Mater. February 2017;66:19-27.
2021	Du J, Li S, Silberschmidt VV. Remodelling of trabecular bone in human distal tibia: a model based on an in-vivo HR-pQCT study. J Mech Behav Biomed Mater. July 2021;119:104506.
2021	Du J, Hartley C, Brooke-Wavell K, Paggiosi MA, Walsh JS, Li S, Silberschmidt VV. High-impact exercise stimulated localised adaptation of microarchitecture across distal tibia in postmenopausal women. Osteoporos Int. May 2021;32(5):907-919.
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.
2017	Saers JPP. Ontogeny and Functional Adaptation of Trabecular Bone in the Human Foot [PhD thesis]. Cambridge, UK: University of Cambridge; July 2017.
2020	Robinson ST. Bone Mechanobiology of Modeling and Remodeling and the Effect of Hematopoietic Lineage Cells [PhD thesis]. Columbia University; 2020.
2017	Matheny JB. Interactions Between Bone Remodeling and Microdamage in Cancellous Bone [PhD thesis]. Ithaca, NY: Cornell University; August 2017.
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.
2022	Goff E. Osteocyte Lacunar Biomarkers in Human Rare Bone Diseases [PhD thesis]. Swiss Federal Institute of Technology Zürich; 2022.
2020	Lewandowski K. Numerical Investigation of Bone Adaptation to Exercise and Fracture in Thoroughbred Racehorses [PhD thesis]. Glasgow, UK: University of Glasgow; February 2020.
2019	Du J. Mechanical Adaptation of Human Trabecular Bone: Experimental and Computational Study [PhD thesis]. Loughborough University; 2019.
2018	Synek A. Predicting Habitual Activities from Bone Architecture Using a Biomechanical Approach [PhD thesis]. Vienna University of Technology; 2018.
2019	Brunet SC. Using Advanced Medical Imaging to Study Bone and Joint Changes in Rheumatoid Arthritis [Master's thesis]. Calgary, AB: University of Calgary; June 2019.
2021	Kemp TD. An Inverse Interface Evolution Problem to Identify Participant-Specific Bone Microarchitecture Adaptation [Master's thesis]. Calgary, AB: University of Calgary; May 2021.
2021	Whittier DEW. The Assessment of Fragility Fracture Risk Using HR-PQCT as a Novel Tool for Diagnosis of Osteoporosis [PhD thesis]. Calgary, AB: University of Calgary; August 2021.
2022	Mielczarek CB. An Investigation of Local Microarchitecture Topology Changes in Long-Duration Spaceflight [Master's thesis]. Calgary, AB: University of Calgary; November 2022.
2023	Kaketsis D. Investigating Bone Remodelling in Knee Osteoarthritis Using HR-PQCT Imaging [Master's thesis]. Calgary, AB: University of Calgary; May 2023.
2020	Bonnheim N. Fundamental Mechanisms of Load Transfer in the Human Vertebral Body Following Lumbar Total Disc Arthroplasty [PhD thesis]. Berkeley, CA: Berkeley, University of California; 2020.
2023	Tits A. Attaching Soft to Hard: A Multimodal Correlative Investigation of the Tendon-Bone Interface [PhD thesis]. Liège, Belgique: Université de Liège; 2023.
2023	Austermann K. Effects of Nutritive Antioxidants on Bone During Immobility [PhD thesis]. Rheinische Friedrich-Wilhelms-Universität Bonn; 2023.
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.