Bone micro-architecture and determinants of strength in the radius and tibia: age-related changes in a population-based study of normal adults measured with high-resolution pQCT

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Dalzell, N.^1,2,3; Kaptoge, S.^1,2; Morris, N.⁴; Berthier, A.⁵; Koller, B.⁶; Braak, L.⁵; van Rietbergen, B.⁷; Reeve, J.^1,2

Bone micro-architecture and determinants of strength in the radius and tibia: age-related changes in a population-based study of normal adults measured with high-resolution pQCT

Osteoporos Int. October 2009;20(10):1683-1694

©2009 International Osteoporosis Foundation and National Osteoporosis Foundation

Affiliations

¹Department of Public Health and Primary Care, University of Cambridge, Strangeways Research Laboratory, Wort’s Causeway, Cambridge CB1 8RN, UK

²Department of Medicine, University of Cambridge Cambridge, UK

³Department of Clinical Gerontology, University of Cambridge, Cambridge, UK

⁴Hethersett Surgery, Norfolk, UK

⁵MEDES, Toulouse, France

⁶Scanco, Brüttisellen, Switzerland

⁷Eindhoven University of Technology, Eindhoven, Netherlands
Abstract and keywords

Summary: We recruited a population-based sample of 58 males and 74 females aged 20–79 from a primary care medical practice to provide normative and descriptive data for high-resolution peripheral quantitative computed tomography (pQCT) parameters. Important effects of ageing and contrasts in the effects of sex on the micro-architecture and strength of upper and lower limb bones were revealed.

Introduction: The advent of high-resolution pQCT scanners has permitted non-invasive assessment of structural data on cortical and trabecular bone.

Methods: We investigated age-related changes in pQCT and finite element (FE) modelling parameters at the distal radius and distal tibia in a population-based cross-sectional study of 58 males and 74 females aged 20–79 years. Linear regression models including quadratic terms for age were used for inference.

Results: Age-related changes and sex differences were generally similar for pQCT parameters at the radius and tibia. At each site, mean values for bone density, cortical thickness and trabecular micro-architecture (number, separation and thickness) were lower (trabecular separation higher) in women than men. Changes with age were most apparent for bone density and cortical thickness, which declined with age, in contrast to trabecular micro-architecture parameters which were not significantly associated with age (p > 0.05) in either sex. Cortical bone density and thickness declined faster in women than men after age 50 and trabecular bone density was consistently lower in women. FE-analysis predicted failure load decreased with age and percentage of load carried by trabecular bone increased (p < 0.05).

Conclusions: These data show contrasts in the effects of sex on the micro-architecture and strength of upper and lower limb bones with ageing. The faster decline in cortical bone thickness and density in women than men after age 50 and consistently lower trabecular bone density in women have implications for the excess risks of wrist and hip fractures in women.

Keywords: Bone quality; Bone structure; Finite element analysis; Micro-architecture ; Normal ranges; Osteoporosis; pQCT; XtremeCT
Links

DOI: 10.1007/s00198-008-0833-6

PubMed: 19152051

WoS: 000269914700005
History

Received: 2008-04-04

Accepted: 2008-12-12

Online: 2009-01-17

Cited Works (17)

Year	Entry
2006	Khosla S, Riggs BL, Atkinson EJ, Oberg AL, McDaniel LJ, Holets M, .Peterson JM, Melton LJ III. Effects of sex and age on bone microstructure at the ultradistal radius: a population-based noninvasive in vivo assessment. J Bone Miner Res. January 2006;21(1):124-131.
1998	Chiu J, Robinovitch SN. Prediction of upper extremity impact forces during falls on the outstretched hand. J Biomech. December 1998;31(12):1169-1176.
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.
2004	Pistoia W, van Rietbergen B, Lochmüller E-M, Lill CA, Eckstein F, Rüegsegger P. Image-based micro-finite-element modeling for improved distal radius strength diagnosis: moving from "bench" to "bedside". J Clin Densitom. Summer 2004;7(2):153-160.
2007	Sievänen H, Kannus P, Järvinen TLN. Bone quality: an empty term. PLoS Med. March 2007;4(3):e27.
2008	Boutroy S, Van Rietbergen B, Sornay-Rendu E, Munoz F, Bouxsein ML, Delmas PD. Finite element analysis based on in vivo HR-pQCT images of the distal radius is associated with wrist fracture in postmenopausal women. J Bone Miner Res. March 2008;23(3):392-399.
1998	Laib A, Häuselmann HJ, Rüegsegger P. In vivo high resolution 3D-QCT of the human forearm. Technol Health Care. 1998;6(5-6):329-337.
2008	Vico L, Zouch M, Amirouche A, Frère D, Laroche N, Koller B, Laib A, Thomas T, Alexandre C. High‐resolution pQCT analysis at the distal radius and tibia discriminates patients with recent wrist and femoral neck fractures. J Bone Miner Res. November 2008;23(11):1741-1750.
1988	Currey JD. The effect of porosity and mineral content on the Young's modulus of elasticity of compact bone. J Biomech. 1988;21(2):131-139.
2002	Pistoia W, van Rietbergen B, Lochmüller E-M, Lill CA, Eckstein F, Rüegsegger P. Estimation of distal radius failure load with micro-finite element analysis models based on three-dimensional peripheral quantitative computed tomography images. Bone. June 2002;30(6):842-848.
1999	Bell KL, Loveridge N, Power J, Garrahan N, Stanton M, Lunt M, Meggitt BF, Reeve J. Structure of the femoral neck in hip fracture: cortical bone loss in the inferoanterior to superoposterior axis. J Bone Miner Res. January 1999;14(1):111-119.
2007	Buie HR, Campbell GM, Klinck RJ, MacNeil JA, Boyd SK. Automatic segmentation of cortical and trabecular compartments based on a dual threshold technique for in vivo micro-CT bone analysis. Bone. October 2007;41(4):505-515.
2005	Mayhew PM, Thomas CD, Clement JG, Loveridge N, Beck TJ, Bonfield W, Burgoyne CJ, Reeve J. Relation between age, femoral neck cortical stability, and hip fracture risk. Lancet. July 9, 2005;366(9480):129-135.
2008	Keaveny TM, Bouxsein ML. Theoretical implications of the biomechanical fracture threshold. J Bone Miner Res. October 2008;23(10):1541-1547.
2006	Riggs BL, Melton LJ III, Robb RA, Camp JJ, Atkinson EJ, Oberg AL, Rouleau PA, McCollough CH, Khosla S, Bouxsein ML. Population-based analysis of the relationship of whole bone strength indices and fall-related loads to age- and sex-specific patterns of hip and wrist fractures. J Bone Miner Res. February 2006;21(2):315-323.
2004	Riggs BL, Melton LJ III, Robb RA, Camp JJ, Atkinson EJ, Peterson JM, Rouleau PA, McCollough CH, Bouxsein ML, Khosla S. Population-based study of age and sex differences in bone volumetricdensity, size, geometry, and structure at different skeletal sites. J Bone Miner Res. December 2004;19(12):1945-1954.
2007	Melton LJ, Riggs BL, van Lenthe GH, Achenbach SJ, Müller R, Bouxsein ML, Amin S, Atkinson EJ, Khosla S. Contribution of in vivo structural measurements and load/strength ratios to the determination of forearm fracture risk in postmenopausal women. J Bone Miner Res. September 2007;22(9):1442-1448.

Cited By (46)

Year	Entry
2019	Hunter RL, Briley K, Agnew AM. Sex differences in human tibia cortical bone morphometrics from computed tomography (CT). In: Proceedings of the 2019 International IRCOBI Conference on the Biomechanics of Injury. September 11-13, 2019; Florence, Italy.436-445.
2021	Hunter RL, Haverfield Z, Agnew AM. Investigation of sex-specific effects on variation in cortical bone morphometrics of the radius. In: Proceedings of the 2021 International IRCOBI Conference on the Biomechanics of Injury. September 8-10, 2021; Online.268-307.
2009	Mueller TL, van Lenthe GH, Stauber M, Gratzke C, Eckstein F, Müller R. Regional, age and gender differences in architectural measures of bone quality and their correlation to bone mechanical competence in the human radius of an elderly population. Bone. November 2009;45(5):882-891.
2010	Sode M, Burghardt AJ, Kazakia GJ, Link TM, Majumdar S. Regional variations of gender-specific and age-related differences in trabecular bone structure of the distal radius and tibia. Bone. June 2010;46(6):1652-1660.
2011	Sode M, Burghardt AJ, Pialat J-B, Link TM, Majumdar S. Quantitative characterization of subject motion in HR-pQCT images of the distal radius and tibia. Bone. June 1, 2011;48(6):1291-1297.
2012	Pauchard Y, Liphardt A-M, Macdonald HM, Hanley DA, Boyd SK. Quality control for bone quality parameters affected by subject motion in high-resolution peripheral quantitative computed tomography. Bone. June 2012;50(6):1304-1310.
2015	Manske SL, Zhu Y, Sandino C, Boyd SK. Human trabecular bone microarchitecture can be assessed independently of density with second generation HR-pQCT. Bone. October 2015;79:213-221.
2020	Iori G, Schneider J, Reisinger A, Heyer F, Peralta L, Wyers C, Glüer CC, van den Bergh JP, Pahr D, Raum K. Cortical thinning and accumulation of large cortical pores in the tibia reflect local structural deterioration of the femoral neck. Bone. August 2020;137:115446.
2014	Hansen S, Shanbhogue V, Folkestad L, Nielsen MMF, Brixen K. Bone microarchitecture and estimated strength in 499 adult Danish women and men: a cross-sectional, population-based high-resolution peripheral quantitative computed tomographic study on peak bone structure. Calcif Tiss Int. March 2014;94(3):269-281.
2011	Burghardt AJ, Link TM, Majumdar S. High-resolution computed tomography for clinical imaging of bone microarchitecture. Clin Orthop Relat Res. August 2011;469:2179-2193.
2013	Cheung AM, Adachi JD, Hanley DA, Kendler DL, Davison KS, Josse R, Brown JP, Ste-Marie L-G, Kremer R, Erlandson MC, Dian L, Burghardt AJ, Boyd SK. High-resolution peripheral quantitative computed tomography for the assessment of bone strength and structure: a review by the Canadian Bone Strength Working Group. Curr Osteoporos Rep. June 2013;11(2):136-146.
2013	Nishiyama KK, Shane E. Clinical imaging of bone microarchitecture with HR-pQCT. Curr Osteoporos Rep. June 2013;11(2):147-155.
2013	Chen H, Zhou X, Fujita H, Onozuka M, Kubo K-Y. Age-related changes in trabecular and cortical bone microstructure. Int J Endocrinol. March 18, 2013;2013:213234.
2011	Feng L, Jasiuk I. Multi-scale characterization of swine femoral cortical bone. J Biomech. January 11, 2011;44(2):313-320.
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.
2010	Nishiyama KK, Macdonald HM, Buie HR, Hanley DA, Boyd SK. Postmenopausal women with osteopenia have higher cortical porosity and thinner cortices at the distal radius and tibia than women with normal aBMD: an in vivo HR-pQCT study. J Bone Miner Res. April 2010;25(4):882-890.
2010	Burghardt AJ, Kazakia GJ, Ramachandran S, Link TM, Majumdar S. Age- and gender-related differences in the geometric properties and biomechanical significance of intracortical porosity in the distal radius and tibia. J Bone Miner Res. May 2010;25(5):983-993.
2010	Burghardt AJ, Kazakia GJ, Sode M, de Papp AE, Link TM, Majumdar S. A longitudinal HR-pQCT study of alendronate treatment in postmenopausal women with low bone density: relations among density, cortical and trabecular microarchitecture, biomechanics, and bone turnover. J Bone Miner Res. December 2010;25(12):2558-2571.
2011	Macdonald HM, Nishiyama KK, Kang J, Hanley DA, Boyd SK. Age‐related patterns of trabecular and cortical bone loss differ between sexes and skeletal sites: a population‐based HT‐pQCT study. J Bone Miner Res. January 2011;26(1):50-62.
2013	Patsch JM, Burghardt AJ, Yap SP, Baum T, Schwartz AV, Joseph GB, Link TM. Increased cortical porosity in type 2 diabetic postmenopausal women with fragility fractures. J Bone Miner Res. February 2013;28(2):313-324.
2016	Burt LA, Liang Z, Sajobi TT, Hanley DA, Boyd SK. Sex‐ and site‐specific normative data curves for HR‐pQCT. J Bone Miner Res. 2016;31(11):2041-2047.
2017	Manske SL, Davison EM, Burt LA, Raymond DA, Boyd SK. The estimation of second-generation HR-pQCT from first-generation -pQCT using in vivo cross-calibration. J Bone Miner Res. July 2017;32(7):1514-1524.
2020	Cusano NE, Rubin MR, Williams JM, Agarwal S, Tabacco G, Tay D, Majeed R, Omeragic B, Bilezikian JP. Changes in skeletal microstructure through four continuous years of rhPTH(1–84) therapy in hypoparathyroidism. J Bone Miner Res. July 2020;35(7):1274-1281.
2020	Yu F, Xu Y, Hou Y, Lin Y, Jiajue R, Jiang Y, Wang O, Li M, Xing X, Zhang L, Qin L, Hsieh E, Xia W. Age‐, site‐, and sex‐specific normative centile curves for HR‐pQCT‐derived microarchitectural and bone strength parameters in a Chinese mainland population. J Bone Miner Res. November 2020;35(11):2159-2170.
2023	Sadoughi S, Subramanian A, Ramil G, Burghardt AJ, Kazakia GJ. A Laplace–Hamming binarization approach for second-generation HR-pQCT rescues fine feature segmentation. J Bone Miner Res. July 2023;38(7):1006-1014.
2010	Burghardt AJ, Issever AS, Schwartz AV, Davis KA, Masharani U, Majumdar S, Link TM. High-resolution peripheral quantitative computed tomographic imaging of cortical and trabecular bone microarchitecture in patients with type 2 diabetes mellitus. J Clin Endocrinol Metab. 2010;95(11):5045-5055.
2014	Kawalilak CE, Johnston JD, Olszynski WP, Kontulainen SA. Characterizing microarchitectural changes at the distal radius and tibia in postmenopausal women using HR-pQCT. Osteoporos Int. August 2014;25(8):2057-2066.
2017	Bonaretti S, Majumdar S, Lang TF, Khosla S, Burghardt AJ. The comparability of HR-pQCT bone measurements is improved by scanning anatomically standardized regions. Osteoporos Int. July 2017;28(7):2115-2128.
2020	Whittier DE, Mudryk AN, Vandergaag ID, Burt LA, Boyd SK. Optimizing HR-pQCT workflow: a comparison of bias and precision error for quantitative bone analysis. Osteoporos Int. March 2020;31(3):567-576.
2020	Stuck AK, Schenk D, Zysset P, Bütikofer L, Mathis A, Lippuner K. Reference values and clinical predictors of bone strength for HR-pQCT-based distal radius and tibia strength assessments in women and men. Osteoporos Int. October 2020;31(10):1913-1923.
2020	Kemp TD, de Bakker CMJ, Gabel L, Hanley DA, Billington EO, Burt LA, Boyd SK. Longitudinal bone microarchitectural changes are best detected using image registration. Osteoporos Int. October 2020;31(10):1995-2005.
2019	Ó Breasail M. The Quantification of Pregnancy-Induced Bone Mineral Mobilisation in the Maternal Appendicular Skeleton With Novel Peripheral Quantitative Computed Tomography (pQCT) Techniques [PhD thesis]. Cambridge, UK: University of Cambridge; 2019.
2010	Müller T. Bioimaging and Biomechanics of Bone Competence and Implant Stability [PhD thesis]. Swiss Federal Institute of Technology Zürich; 2010.
2010	Feng L. Multi-Scale Characterization of Swine Femoral Cortical Bone and Long Bone Defect Repair by Regeneration [PhD thesis]. University of Illinois at Urbana-Champaign; 2010.
2019	Du J. Mechanical Adaptation of Human Trabecular Bone: Experimental and Computational Study [PhD thesis]. Loughborough University; 2019.
2013	Wong AKO. A Tri-Modality Comparison of Volumetric Bone Measure Quantification Using 1.0 Tesla Peripheral Magnetic Resonance Imaging, Peripheral Quantitative Computed Tomography and Highresolution-Peripheral Quantitative Computed Tomography Images [PhD thesis]. Hamilton, ON: McMaster University; October 2013.
2015	Hunter RL. Variation in Cortical Osteocyte Lacunar Density and Distribution: Implications for Bone Quality Assessment [PhD thesis]. The Ohio State University; 2015.
2009	Varga P. Prediction of Distal Radius Fracture Load Using HR-PQCT-Based Finite Element Analysis [PhD thesis]. Vienna University of Technology; December 2009.
2018	Bachmann S. Age, Sex and Treatment Related Changes of Bone Mineral Density Based on Ct Data [Master's thesis]. Vienna University of Technology; October 2018.
2018	Alousaimi H. A Study of Bone Quality in Femoral Neck of Osteoarthritis [Master's thesis]. Vancouver, BC: University of British Columbia; August 2018.
2012	Nishiyama KKS. In Vivo Assessment of Bone Microarchitecture and Estimated Bone Strength [PhD thesis]. Calgary, AB: University of Calgary; October 2012.
2012	Pauchard Y. In Vivo Monitoring of Longitudinal Changes in Bone Micro-Architecture Using High-Resolution Peripheral Computed Tomography [PhD thesis]. Calgary, AB: University of Calgary; February 2012.
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.
2012	Wilkerson LT. Finite Element Analysis of Cancellous Bone [Master's thesis]. University of Kentucky; 2012.
2016	Meyer LA. Testing and Modeling Mechanical Properties of Ex Vivo Trabecular Bone [PhD thesis]. University of Wisconsin – Madison; 2016.