Diminished response to in vivo mechanical loading in trabecular and not cortical bone in adulthood of female C57Bl/6 mice coincides with a reduction in deformation to load

wbldb

Willie, Bettina M.¹; Birkhold, Annette I.¹; Razi, Hajar¹; Thiele, Tobias¹; Aido, Marta¹; Kruck, Bettina¹; Schill, Alexander¹; Checa, Sara¹; Main, Russell P.^2,3; Duda, Georg N.^1,4

Diminished response to in vivo mechanical loading in trabecular and not cortical bone in adulthood of female C57Bl/6 mice coincides with a reduction in deformation to load

Bone. August 2013;55(2):335-346

©2013 Elsevier Inc. All rights reserved.

Affiliations

¹Julius Wolff Institut, Charité-Universitätsmedizin Berlin, Germany

²Department of Basic Medical Sciences, College of Veterinary Medicine, Purdue University, West Lafayette, IN, USA

³Weldon School of Biomedical Engineering, Purdue University, West Lafayette, IN, USA

⁴Berlin Brandenburg Center for Regenerative Therapies (BCRT), Charité-Universitätsmedizin Berlin, Germany
Abstract and keywords

Bone loss occurs during adulthood in both women and men and affects trabecular bone more than cortical bone. The mechanism responsible for trabecular bone loss during adulthood remains unexplained, but may be due at least in part to a reduced mechanoresponsiveness. We hypothesized that trabecular and cortical bone would respond anabolically to loading and that the bone response to mechanical loading would be reduced and the onset delayed in adult compared to postpubescent mice. We evaluated the longitudinal adaptive response of trabecular and cortical bone in postpubescent, young (10 week old) and adult (26 week old) female C57Bl/6J mice to axial tibial compression using in vivo microCT (days 0, 5, 10, and 15) and dynamic histomorphometry (day 15). Loading elicited an anabolic response in both trabecular and cortical bone in young and adult mice. As hypothesized, trabecular bone in adult mice exhibited a reduced and delayed response to loading compared to the young mice, apparent in trabecular bone volume fraction and architecture after 10 days. No difference in mechanoresponsiveness of the cortical bone was observed between young and adult mice. Finite element analysis showed that load-induced strain was reduced with age. Our results suggest that trabecular bone loss that occurs in adulthood may in part be due to a reduced mechanoresponsiveness in this tissue and/or a reduction in the induced tissue deformation which occurs during habitual loading. Therapeutic approaches that address the mechanoresponsiveness of the bone tissue may be a promising and alternate strategy to maintain trabecular bone mass during aging.

Keywords: Bone adaptation; Mechanoresponse; Aging; Tibial compression; Mouse
Links

DOI: 10.1016/j.bone.2013.04.023

PubMed: 23643681

WoS: 000320896600010
History

Received: 2012-10-27

Revised: 2013-04-26

Accepted: 2013-04-26

Online: 2013-05-1

Cited Works (46)

Year	Entry
2011	Lynch ME, Main RP, Xu Q, Schmicker TL, Schaffler MB, Wright TM, van der Meulen MCH. Tibial compression is anabolic in the adult mouse skeleton despite reduced responsiveness with aging. Bone. September 2011;49(3):439-446.
2013	Weatherholt AM, Fuchs RK, Warden SJ. Cortical and trabecular bone adaptation to incremental load magnitudes using the mouse tibial axial compression loading model. Bone. January 2013;52(1):372-379.
1997	Kohrt WM, Ehsani AA, Birge SJ. Effects of exercise involving predominantly either joint-reaction or ground-reaction forces on bone mineral density in older women. J Bone Miner Res. August 1997;12(8):1253-1261.
2007	Taddei F, Schileo E, Helgason B, Cristofolini L, Viceconti M. The material mapping strategy influences the accuracy of ct-based finite element models of bones: an evaluation against experimental measurements. Med Eng Phys. 2007;29(9):973-979.
2003	Kontulainen S, Sievänen H, Kannus P, Pasanen M, Vuori I. Effect of long-term impact-loading on mass, size, and estimated strength of humerus and radius of female racquet-sports players: a peripheral quantitative computed tomography study between young and old starters and controls. J Bone Miner Res. February 2003;18(2):352-359.
2001	Lanyon L, Skerry T. Postmenopausal osteoporosis as a failure of bone's adaptation to functional loading: a hypothesis. J Bone Miner Res. November 2001;16(11):1937-1947.
2012	Silva MJ, Brodt MD, Lynch MA, Stephens AL, Wood DJ, Civitelli R. Tibial loading increases osteogenic gene expression and cortical bone volume in mature and middle-aged mice. PLoS One. April 2012;7(4):e34980.
1999	Brodt MD, Ellis CB, Silva MJ. Growing C57Bl/6 mice increase whole bone mechanical properties by increasing geometric and material properties. J Bone Miner Res. December 1999;14(12):2159-2166.
1986	Riggs BL, Wahner HW, Melton LJ III, Richelson LS, Judd HL, Offord KP. Rates of bone loss in the appendicular and axial skeletons of women: evidence of substantial vertebral bone loss before menopause. J Clin Invest. May 1986;77(5):1487-1491.
1992	Rubin CT, Bain SD, McLeod KJ. Suppression of the osteogenic response in the aging skeleton. Calcif Tiss Int. April 1992;50(4):306-313.
1990	Foldes J, Shih M-S, Parfitt AM. Frequency distributions of tetracycline-based measurements: implications for the interpretation of bone formation indices in the absence of double-labeled surfaces. J Bone Miner Res. October 1990;5(10):1063-1067.
1998	Bassey EJ, Rothwell MC, Littlewood JJ, Pye DW. Pre- and postmenopausal women have different bone mineral density responses to the same high-impact exercise. J Bone Miner Res. December 1998;13(12):1805-1813.
2008	Buie HR, Moore CP, Boyd SK. Postpubertal architectural developmental patterns differ between the l3 vertebra and proximal tibia in three inbred strains of mice. J Bone Miner Res. 2008;23(12):2048-2059.
2003	Lee K, Jessop H, Suswillo R, Zaman G, Lanyon L. Bone adaptation requires oestrogen receptor-α. Nature. July 24, 2003;424(6947):389.
2005	Fritton JC, Myers ER, Wright TM, van der Meulen MCH. Loading induces site-specific increases in mineral content assessed by microcomputed tomography of the mouse tibia. Bone. June 2005;36(6):1030-1038.
1996	Kerr D, Morton A, Dick I, Prince R. Exercise effects on bone mass in postmenopausal women are site-specific and load-dependent. J Bone Miner Res. February 1996;11(2):218-225.
1995	Turner CH, Takano Y, Owan I. Aging changes mechanical loading thresholds for bone formation in rats. J Bone Miner Res. October 1995;10(10):1544-1549.
1995	Turner CH, Owan I, Takano Y. Mechanotransduction in bone: role of strain rate. Am J Physiol Endocrinol Metab. September 1995;269(3):E438-E442.
2008	Sugiyama T, Saxon LK, Zaman G, Moustafa A, Sunters A, Price JS, Lanyon LE. Mechanical loading enhances the anabolic effects of intermittent parathyroid hormone (1–34) on trabecular and cortical bone in mice. Bone. August 2008;43(2):238-248.
2005	De Souza RL, Matsuura M, Eckstein F, Rawlinson SCF, Lanyon LE, Pitsillides AA. Non-invasive axial loading of mouse tibiae increases cortical bone formation and modifies trabecular organization: a new model to study cortical and cancellous compartments in a single loaded element. Bone. December 2005;37(6):810-818.
2010	Lynch ME, Main RP, Xu Q, Walsh DJ, Schaffler MB, Wright TM, van der Meulen MCH. Cancellous bone adaptation to tibial compression is not sex dependent in growing mice. J Appl Physiol. September 2010;109(3):685-691.
1977	Carter DR, Hayes WC. The compressive behavior of bone as a two-phase porous structure. J Bone Joint Surg. 1977;59A(7):954-962.
2004	Somerville JM, Aspden RM, Armour KE, Armour KJ, Reid DM. Growth of C57Bl/6 mice and the material and mechanical properties of cortical bone from the tibia. Calcif Tiss Int. May 2004;74(5):469-475.
2007	Schileo E, Taddei F, Malandrino A, Cristofolini L, Viceconti M. Subject-specific finite element models can accurately predict strain levels in long bones. J Biomech. 2007;40(13):2982-2989.
1997	Burr DB. Muscle strength, bone mass, and age‐related bone loss. J Bone Miner Res. 1997;12(10):1547-1551.
2010	Bouxsein ML, Boyd SK, Christiansen BA, Guldberg RE, Jepsen KJ, Müller R. Guidelines for assessment of bone microstructure in rodents using micro-computed tomography. J Bone Miner Res. July 2010;25(7):1468-1486.
1987	Parfitt AM, Drezner MK, Glorieux FH, Kanis JA, Malluche H, Meunier PJ, Ott SM, Recker RR. Bone histomorphometry: standardization of nomenclature, symbols, and units: report of the ASBMR histomorphometry nomenclature committee. J Bone Miner Res. December 1987;2(6):595-610.
2000	Haapasalo H, Kontulainen S, Sievänen H, Kannus P, Järvinen M, Vuori I. Exercise-induced bone gain is due to enlargement in bone size without a change in volumetric bone density: a peripheral quantitative computed tomography study of the upper arms of male tennis players. Bone. September 2000;27(3):351-357.
2010	Main RP, Lynch ME, van der Meulen MCH. In vivo tibial stiffness is maintained by whole bone morphology and cross-sectional geometry in growing female mice. J Biomech. October 19, 2010;43(14):2689-2694.
2001	Fuchs RK, Bauer JJ, Snow CM. Jumping improves hip and lumbar spine bone mass in prepubescent children: a randomized controlled trial. J Bone Miner Res. January 2001;16(1):148-156.
2000	Robling AG, Burr DB, Turner CH. Partitioning a daily mechanical stimulus into discrete loading bouts improves the osteogenic response to loading. J Bone Miner Res. August 2000;15(8):1596-1602.
1984	Rubin CT, Lanyon LE. Regulation of bone formation by applied dynamic loads. J Bone Joint Surg. March 1984;66A(3):397-402.
2007	Glatt V, Canalis E, Stadmeyer L, Bouxsein ML. Age‐related changes in trabecular architecture differ in female and male C57BL/6J mice. J Bone Miner Res. August 2007;22(8):1197-1207.
2010	Brodt MD, Silva MJ. Aged mice have enhanced endocortical response and normal periosteal response compared with young-adult mice following 1 week of axial tibial compression. J Bone Miner Res. September 2010;25(9):2006-2015.
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.
2002	Ehrlich PJ, Lanyon LE. Mechanical strain and bone cell function: a review. Osteoporos Int. September 2002;13(9):688-700.
2003	Srinivasan S, Agans SC, King KA, Moy NY, Poliachik SL, Gross TS. Enabling bone formation in the aged skeleton via rest-inserted mechanical loading. Bone. December 2003;33(6):946-955.
1977	Jones HH, Priest JD, Hayes WC, Tichenor CC, Nagel DA. Humeral hypertrophy in response to exercise. J Bone Joint Surg. March 1977;59A(2):204-208.
2004	Akkus O, Adar F, Schaffler MB. Age-related changes in physicochemical properties of mineral crystals are related to impaired mechanical function of cortical bone. Bone. March 2004;34(4):443-453.
2008	Klinck RJ, Campbell GM, Boyd SK. Radiation effects on bone architecture in mice and rats resulting from in vivo micro-computed tomography scanning. Med Eng Phys. September 2008;30(7):888-895.
2006	Seeman E, Delmas PD. Bone quality: the material and structural basis of bone strength and fragility. NEJM. May 25, 2006;354(21):2250-2261.
1998	Mosley JR, Lanyon LE. Strain rate as a controlling influence on adaptive modeling in response to dynamic loading of the ulna in growing male rats. Bone. October 1998;23(4):313-318.
2002	Lee KCL, Maxwell A, Lanyon LE. Validation of a technique for studying functional adaptation of the mouse ulna in response to mechanical loading. Bone. September 2002;31(3):407-412.
2012	Moustafa A, Sugiyama T, Prasad J, Zaman G, Gross TS, Lanyon LE, Price JS. Mechanical loading-related changes in osteocyte sclerostin expression in mice are more closely associated with the subsequent osteogenic response than the peak strains engendered. Osteoporos Int. April 2012;23(4):1225-1234.
2008	Riggs BL, Melton LJ, Robb RA, Camp JJ, Atkinson EJ, McDaniel L, Amin S, Rouleau PA, Khosla S. A population‐based assessment of rates of bone loss at multiple skeletal sites: evidence for substantial trabecular bone loss in young adult women and men. J Bone Miner Res. February 2008;23(2):205-214.

Cited By (30)

Year	Entry
2019	Zenzes M, Bortel EL, Fratzl P, Mundlos S, Schuetz M, Schmidt H, Duda GN, Witte F, Zaslansky P. Normal trabecular vertebral bone is formed via rapid transformation of mineralized spicules: a high-resolution 3D ex-vivo murine study. Acta Biomater. March 1, 2019;86:429-440.
2020	Mulder B, Stock JT, Saers JPP, Inskip SA, Cessford C, Robb JE. Intrapopulation variation in lower limb trabecular architecture. Am J Phys Anthropol. September 2020;173(1):112-129.
2014	Birkhold AI, Razi H, Duda GN, Weinkamer R, Checa S, Willie BM. The influence of age on adaptive bone formation and bone resorption. Biomaterials. November 2014;35(34):9290-9301.
2014	Holguin N, Brodt MD, Sanchez ME, Silva MJ. Aging diminishes lamellar and woven bone formation induced by tibial compression in adult C57BL/6. Bone. August 2014;65:83-91.
2020	Willie BM, Zimmermann EA, Vitienes I, Main RP, Komarova SV. Bone adaptation: safety factors and load predictability in shaping skeletal form. Bone. February 2020;131:115114.
2021	Kistler-Fischbacher M, Weeks BK, Beck BR. The effect of exercise intensity on bone in postmenopausal women (part 2): a meta-analysis. Bone. February 2021;143:115697.
2022	Bouchard AL, Dsouza C, Julien C, Rummler M, Gaumond M-H, Cermakian N, Willie BM. Bone adaptation to mechanical loading in mice is affected by circadian rhythms. Bone. January 2022;154:116218.
2022	Wang H, Du T, Li R, Main RP, Yang H. Interactive effects of various loading parameters on the fluid dynamics within the lacunar-canalicular system for a single osteocyte. Bone. May 2022;158:116367.
2022	Young SAE, Rummler M, Taïeb HM, Garske DS, Ellinghaus A, Duda GN, Willie BM, Cipitria A. In vivo microCT-based time-lapse morphometry reveals anatomical site-specific differences in bone (re)modeling serving as baseline parameters to detect early pathological events. Bone. August 2022;161:116432.
2022	Meslier QA, DiMauro N, Somanchi P, Nano S, Shefelbine SJ. Manipulating load-induced fluid flow in vivo to promote bone adaptation. Bone. December 2022;165:116547.
2020	Albiol L, Büttner A, Pflanz D, Mikolajewicz N, Birkhold AI, Kramer I, Kneissel M, Duda GN, Checa S, Willie BM. Effects of long-term sclerostin deficiency on trabecular bone mass and adaption to limb loading differ in male and female mice. Calcif Tiss Int. April 2020;106(4):415-430.
2020	Pepe V, Oliviero S, Cristofolini L, Dall’Ara E. Regional nanoindentation properties in different locations on the mouse tibia from C57BL/6 and Balb/C female mice. Front Bioeng Biotechnol. May 15, 2020;8:478.
2014	Patel TK, Brodt MD, Silva MJ. Experimental and finite element analysis of strains induced by axial tibial compression in young-adult and old female C57Bl/6 mice. J Biomech. January 22, 2014;47(2):451-457.
2019	Yang H, Xu X, Bullock W, Main RP. Adaptive changes in micromechanical environments of cancellous and cortical bone in response to in vivo loading and disuse. J Biomech. May 24, 2019;89:85-94.
2020	Chermside-Scabbo CJ, Harris TL, Brodt MD, Braenne I, Zhang B, Farber CR, Silva MJ. Old mice have less transcriptional activation but similar periosteal cell proliferation compared to young‐adult mice in response to in vivo mechanical loading. J Bone Miner Res. September 2020;35(9):1751-1764.
2022	Harrison KD, Sales E, Hiebert BD, Panahifar A, Zhu N, Arnason T, Swekla KJ, Pivonka P, Chapman LD, Cooper DML. Direct assessment of rabbit cortical bone basic multicellular unit longitudinal erosion rate: a 4D synchrotron-based approach. J Bone Miner Res. November 2022;37(11):2244-2258.
2019	Oliviero S, Giorgi M, Laud PJ, Dall’Ara E. Effect of repeated in vivo microCT imaging on the properties of the mouse tibia. PLoS One. November 21, 2019;14(11):e0225127.
2020	Scheuren AC, Kuhn GA, Müller R. Effects of long-term in vivo micro-CT imaging on hallmarks of osteopenia and frailty in aging mice. PLoS One. September 23, 2020;15(9):e0239534.
2020	Rooney A. Interactions Among Estrogen Receptor-Alpha, Parathyroid Hormone, and Mechanical Loading in Skeletal Health [PhD thesis]. Ithaca, NY: Cornell University; December 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.
2015	Weatherholt AM. Translational Studies Into the Effects of Exercise on Estimated Bone Strength [PhD thesis]. Indianapolis, IN: Indiana University; September 2015.
2018	Mikolajewicz N. Purinergic Mechanotransduction in Bone [PhD thesis]. McGill University; December 2018.
2019	Piet J. Restoring Mechano-Adaptation in Aged Murine Bone [PhD thesis]. Northeastern University; March 2019.
2019	Mustafy T. The Short and Long Term Effects of in Vivo Cyclic Axial Compression Applied During Puberty on Bone Growth, Morphometry and Biomechanics [PhD thesis]. École polytechnique de Montréal; July 2019.
2015	Clauser CA. In Vivo Tibial Loading of Healthy and Osteolathrytic Mice [Master's thesis]. Indianapolis, IN: Purdue University; May 2015.
2016	Berman AG. Influence of Mechanical Stimulation on the Quantity and Quality of Bone During Modeling [Master's thesis]. Purdue University; August 2016.
2018	Samvelyan H. The Effect of Timing of Feeding on Bone's Adaptive Response to Mechanical Loading [PhD thesis]. University of Sheffield; March 2018.
2019	Oliviero S. Non-Invasive Prediction of Bone Mechanical Properties of the Mouse Tibia in Longitudinal Preclinical Studies [PhD thesis]. University of Sheffield; January 2019.
2016	Heffner MA. Bone Adaptation in a Mouse Model of Reduced Sensory Nerve Function [PhD thesis]. Davis, University of California; 2016.
2021	Harrison KD. A Novel in Vivo Synchrotron Radiation Micro-CT Imaging Platform for the Direct Tracking of Remodeling Events in Cortical Bone [PhD thesis]. University of Saskatchewan; December 2021.