Distal radius fractures:​ mechanisms of injury and strength prediction by bone mineral assessment

Augat, Peter; Iida, Hiroyuki; Jiang, Yebin; Diao, Edward; Genant, Harry K.

Affiliations

¹Osteoporosis and Arthritis Research Group, Department of Radiology, University of California, San Francisco, California, U.S.A

²Hand and Microvascular Research Laboratory, Department of Orthopaedic Surgery, University of California, San Francisco, California, U.S.A

Abstract

The strength of the radius depends on the mechanical properties of cancellous and cortical bone. By assessing both compartments quantitatively with bone densitometry. we tried to identify the specificity of each in predicting the load at which the distal raius will fracture. Twenty human cadaver forearms were scanned for bone mineral and geometric properties with quantitative computed tomography and dual x-ray absorptiometry. In both a neutral loading situation and one in which the wrist was extended 45°, the load distribution was determined with pressure-sensitive films, and a fracture simulating a fall on the hand was produced with a material testing machine. Fractures that occur with the wrist in extension were produced by a central impact of the scaphoid onto the radiocarpal joint, and those that occur under neutral loading conditions were produced by a more commonly distributed loading pattern. The load at fracture was most specifically predicted (r² = 0.74) by bone mineral and geometric measures of the cortex at the shaft of the radius. Bone mineral density measures of trabecular (r² = 0.64) and total (r² = 0.66) bone were less successful in predicting the fracture load. After adjustment for bone size, the geometric and density measures revealed similar specificity. Cortical bone, therefore, contributes significantly to the strength of the distal radius and may play an important role in the prediction of osteoporotic wrist fractures.

Links

DOI: 10.1002/jor.1100160517

PubMed: 24644060

WoS: 000340243900018

History

Accepted: 1998-07-07

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Cited By (20)

Year	Entry
2003	Pistoia W, van Rietbergen B, Rüegsegger P. Mechanical consequences of different scenarios for simulated bone atrophy and recovery in the distal radius. Bone. December 2003;33(6):937-945.
2010	Varga P, Pahr DH, Baumbach S, Zysset PK. HR-pQCT based FE analysis of the most distal radius section provides an improved prediction of Colles' fracture load in vitro. Bone. November 2010;47(5):982-988.
2022	Uppuganti S, Ketsiri T, Zhang Y, Does MD, Nyman JS. HR-pQCT parameters of the distal radius correlate with the bending strength of the radial diaphysis. Bone. August 2022;161:116429.
2013	Ural A, Mischinski S. Multiscale modeling of bone fracture using cohesive finite elements. Eng Fract Mech. May 2013;103:141-152.
2007	Troy KL, Grabiner MD. Off-axis loads cause failure of the distal radius at lower magnitudes than axial loads: a finite element analysis. J Biomech. 2007;40(8):1670-1675.
2009	Varga P, Baumbach S, Pahr D, Zysset PK. Validation of an anatomy specific finite element model of Colles’ fracture. J Biomech. August 7, 2009;42(11):1726-1731.
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2011	Edwards WB, Troy KL. Simulating distal radius fracture strength using biomechanical tests: a modeling study examining the influence of boundary conditions. J Biomech Eng. November 2011;133(11):114501.
2023	Dao T, Robinson DL, Doyle LW, Lee PVS, Olsen J, Kale A, Cheong JLY, Wark JD. Quantifying bone strength deficits in young adults born extremely preterm or extremely low birth weight. J Bone Miner Res. December 2023;38(12):1800-1808.
2008	Engelke K, Adams JE, Armbrecht G, Augat P, Bogado CE, Bouxsein ML, Felsenberg D, Ito M, Prevrhal S, Hans DB, Lewiecki EM. Clinical use of quantitative computed tomography and peripheral quantitative computed tomography in the management of osteoporosis in adults: the 2007 ISCD official positions. J Clin Densitom. January–March 2008;11(1):123-162.
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2006	Ashe MC, Khan KM, Kontulainen SA, Guy P, Liu D, Beck TJ, McKay HA. Accuracy of pQCT for evaluating the aged human radius: an ashing, histomorphometry and failure load investigation. Osteoporos Int. August 2006;17(8):1241-1251.
2007	Schneider P. Ultrastructural Phenotyping of Murine Bone Using Synchrotron Micro- and Nano-Computed Tomography [PhD thesis]. Swiss Federal Institute of Technology Zürich; 2007.
2020	Steinmann N. Development of a Modified Anthropomorphic Test Device for the Quantification of Behind Shield Blunt Impacts [Master's thesis]. Hamilton, ON: McMaster University; August 2020.
2005	George WT. Multiaxial Fracture Characteristics of Aging Human Bone [PhD thesis]. Troy, NY: Rensselaer Polytechnic Institute; April 2005.
2009	Varga P. Prediction of Distal Radius Fracture Load Using HR-PQCT-Based Finite Element Analysis [PhD thesis]. Vienna University of Technology; December 2009.
2005	Ashe MC. Upper Limb Bone Health: Cadaveric, Imaging and Clinical Studies With Special Emphasis on Peripheral Quantitative Computed Tomography [PhD thesis]. Vancouver, BC: University of British Columbia; April 2005.
2018	Hosseinitabatabaei S. High-Resolution Peripheral Quantitative Computed Tomography Based Finite Element Modelling of Distal Radius Strength: Assessing Effect of Heterogeneous Material Properties and Scan Site [Master's thesis]. University of Saskatchewan; October 2018.
2020	Bunyamin ATO. Predicting Off-Axis Bone Strength of the Distal Radius Using High-Resolution Peripheral Quantitative Computed Tomography Based Finite Element Modeling [Master's thesis]. University of Saskatchewan; March 2020.
2013	Reeves JM. Development and Assessment of an Impact Apparatus and High-Speed Camera Motion Tracking System to Quantify the Effect of Static Muscle Loads on Fracture Threshold Measures in the Distal Radius [Master's thesis]. University of Western Ontario; 2013.