Short-term in vivo precision of BMD and parameters of trabecular architecture at the distal forearm and tibia

wbldb

Engelke, K.^1,2; Stampa, B.¹; Timm, W.¹; Dardzinski, B.³; de Papp, A. E.³; Genant, H. K.⁴; Fuerst, T.⁵

Short-term in vivo precision of BMD and parameters of trabecular architecture at the distal forearm and tibia

Osteoporos Int. August 2012;23(8):2151-2158

©2011 International Osteoporosis Foundation and National Osteoporosis Foundation

Affiliations

¹Synarc Inc., Lübecker Str. 128, 22087 Hamburg, Germany

²Institute of Medical Physics, University of Erlangen, Erlangen, Germany

³Merck Sharp & Dohme Corp., Whitehouse Station, NJ, USA

⁴Department of Radiology, University of California, San Francisco, CA, USA

⁵Synarc Inc., San Francisco, CA, USA
Abstract and keywords

Summary: In vivo hr-pQCT precision was determined in 42 postmenopausal women using double baseline measurements from a multicenter trial of odanacatib. Errors, e.g., at the radius below 1.3% for BMD and below 6.3% for trabecular structure, were comparable to single-center results. Motion artifacts remain a challenge, particularly at the forearm.

Introduction: The short-term in vivo precision of BMD, trabecular bone structure, cortical thickness and porosity of the forearm and tibia was measured by hr-pQCT. Also the effect of image quality on precision was evaluated.

Methods: In 42 postmenopausal women (age 64.4 ± 6.8 years) out of 214 subjects enrolled in a multi center advanced imaging phase III study of odanacatib (DXA spine or hip T-scores between −1.5 and −3.5), double baseline hr-pQCT (XtremeCT) measurements with repositioning were performed. The standard ultradistal location and a second, more proximally located VOI were measured at the radius and tibia to better assess cortical thickness and porosity. Image analysis and quality grading (grades: perfect, slight artifacts, pronounced artifacts, unacceptable) were performed centrally.

Results: At the radius RMS%CV values varied from 0.7% to 1.3% for BMD and BV/TV and from 5.6% to 6.3% for Tb.Sp, Tb.Th, Tb.N, and cortical porosity. Numerically at the tibia, precision errors were approx. 0.5% lower for BMD and 1% to 2% lower for structural parameters although most differences were insignificant. In the radius but not in the tibia, precision errors for cortical thickness were smaller at the distal compared to the ultradistal location (1% versus 2%).

Conclusions: BMD precision errors were lower than those for trabecular architecture and cortical porosity. Motion artifacts remain a challenge, particularly at the forearm. Quality grading remains subjective, and more objective evaluation methods are needed. Precision in the context of a multicenter clinical trial, with centralized training and scan analysis, was comparable to single-center results previously reported.

Keywords: Bone mineral density; High-resolution peripheral QCT; Multicenter study; Short-term in vivo precision; Trabecular structure
Links

DOI: 10.1007/s00198-011-1829-1

PubMed: 22143491

WoS: 000307249200010
History

Received: 2011-05-19

Accepted: 2011-10-17

Online: 2011-12-06

Cited Works (11)

Year	Entry
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.
2008	Kazakia GJ, Hyun B, Burghardt AJ, Krug R, Newitt DC, de Papp AE, Link TM, Majumdar S. In vivo determination of bone structure in postmenopausal women: a comparison of MR‐pQCT and high‐field MR imaging. J Bone Miner Res. 2008;23(4):463-474.
2008	MacNeil JA, Boyd SK. Improved reproducibility of high-resolution peripheral quantitative computed tomography for measurement of bone quality. Med Eng Phys. July 2008;30(6):792-799.
2007	MacNeil JA, Boyd SK. Accuracy of high-resolution peripheral quantitative computed tomography for measurement of bone quality. Med Eng Phys. December 2007;29(10):1096-1105.
1996	Müller R, Hildebrand T, Häuselmann HJ, Rüegsegger P. In vivo reproducibility of three‐dimensional structural properties of noninvasive bone biopsies using 3D‐pQCT. J Bone Miner Res. November 1996;11(11):1745-1750.
2010	Burghardt AJ, Buie HR, Laib A, Majumdar S, Boyd SK. Reproducibility of direct quantitative measures of cortical bone microarchitecture of the distal radius and tibia by HR-pQCT. Bone. September 2010;47(3):519-528.
2009	Mueller TL, Stauber M, Kohler T, Eckstein F, Müller R, van Lenthe GH. Non-invasive bone competence analysis by high-resolution pQCT: an in vitro reproducibility study on structural and mechanical properties at the human radius. Bone. February 2009;44(2):364-371.
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.
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.
2007	Burghardt AJ, Kazakia GJ, Majumdar S. A local adaptive threshold strategy for high resolution peripheral quantitative computed tomography of trabecular bone. Ann Biomed Eng. October 2007;235(10):1678-1686.
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.

Cited By (15)

Year	Entry
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.
2021	Yeni YN, Oravec D, Drost J, Bevins N, Morrison C, Flynn MJ. Bone health assessment via digital wrist tomosynthesis in the mammography setting. Bone. March 2021;144:115804.
2021	Mikolajewicz N, Zimmermann EA, Rummler M, Hosseinitabatabaei S, Julien C, Glorieux FH, Rauch F, Willie BM. Multisite longitudinal calibration of HR-pQCT scanners and precision in osteogenesis imperfecta. Bone. June 2021;147:115880.
2023	Walle M, Eggemann D, Atkins PR, Kendall JJ, Stock K, Müller R, Collins CJ. Motion grading of high-resolution quantitative computed tomography supported by deep convolutional neural networks. Bone. January 2023;166:116607.
2023	Whittier DE, Walle M, Schenk D, Atkins PR, Collins CJ, Zysset P, Lippuner K, Müller R. A multi-stack registration technique to improve measurement accuracy and precision across longitudinal HR-pQCT scans. Bone. November 2023;176:116893.
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.
2020	Mikolajewicz N, Bishop N, Burghardt AJ, Folkestad L, Hall A, Kozloff KM, Lukey PT, Molloy‐Bland M, Morin SN, Offiah AC, Shapiro J, van Rietbergen B, Wager K, Willie BM, Komarova SV, Glorieux FH. HR‐pQCT measures of bone microarchitecture predict fracture: systematic review and meta‐analysis. J Bone Miner Res. March 2020;35(3):446-459.
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.
2021	Vilaca T, Paggiosi M, Walsh JS, Selvarajah D, Eastell R. The effects of type 1 diabetes and diabetic peripheral neuropathy on the musculoskeletal system: a case–control study. J Bone Miner Res. June 2021;36(6):1048-1059.
2022	Hosseinitabatabaei S, Mikolajewicz N, Zimmermann EA, Rummler M, Steyn B, Julien C, Rauch F, Willie BM. 3D image registration marginally improves the precision of HR-pQCT measurements compared to cross-sectional-area registration in adults with osteogenesis imperfecta. J Bone Miner Res. May 2022;37(5):908-924.
2018	Chiba K, Okazaki N, Kurogi A, Isobe Y, Yonekura A, Tomita M, Osaki M. Precision of second-generation high-resolution peripheral quantitative computed tomography: intra- and intertester reproducibilities and factors involved in the reproducibility of cortical porosity. J Clin Densitom. April–June 2018;21(2):295-302.
2020	Whittier DE, Boyd SK, Burghardt AJ, Paccou J, Ghasem-Zadeh A, Chapurlat R, Engelke K, Bouxsein ML. Guidelines for the assessment of bone density and microarchitecture in vivo using high-resolution peripheral quantitative computed tomography. Osteoporos Int. September 2020;31(9):1607-1627.
2018	Metcalf LM. HR-PQCT Scanning of the Human Calcaneus: Early Development and Validation of Assessment of Calcaneal Trabecular Microstructure [PhD thesis]. University of Sheffield; March 2018.
2018	George JK. Using Finite Element Models Under Multiple Loading Conditions to Improve the Association Between Radius and Tibia Microarchitecture and Prevalent Osteoporotic Vertebral Fracture [Master's thesis]. Calgary, AB: University of Calgary; May 2018.
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.