Simulating distal radius fracture strength using biomechanical tests:​ a modeling study examining the influence of boundary conditions

Edwards, W. Brent<sup>1</sup>; Troy, Karen L.<sup>1,2</sup>

Affiliations

¹Department of Kinesiology and Nutrition, University of Illinois at Chicago, Chicago, IL 60612

²Department of Bioengineering, University of Illinois at Chicago, Chicago, IL 60612

Abstract

Distal radius fracture strength has been quantified using in vitro biomechanical testing. These tests are frequently performed using one of two methods: (1) load is applied directly to the embedded isolated radius or (2) load is applied through the hand with the wrist joint intact. Fracture loads established using the isolated radius method are consistently 1.5 to 3 times greater than those for the intact wrist method. To address this discrepancy, a validated finite element modeling procedure was used to predict distal radius fracture strength for 22 female forearms under boundary conditions simulating the isolated radius and intact wrist method. Predicted fracture strength was highly correlated between methods (r = 0.94; p < 0.001); however, intact wrist simulations were characterized by significantly reduced cortical shell load carriage and increased stress and strain concentrations. These changes resulted in fracture strength values less than half those predicted for the isolated radius simulations (2274 ± 824 N for isolated radius, 1124 ± 375 N for intact wrist; p < 0.001). The isolated radius method underestimated the mechanical importance of the trabecular compartment compared to the more physiologically relevant intact wrist scenario. These differences should be borne in mind when interpreting the physiologic importance of mechanical testing and simulation results.

Links

DOI: 10.1115/1.4005428

PubMed: 22168742

WoS: 000298009500010

History

Received: 2011-08-31

Revised: 2011-11-01

Online: 2011-11-18

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Cited By (5)

Year	Entry
2022	Revel M, Bermond F, Duboeuf F, Mitton D, Follet H. Influence of loading conditions in finite element analysis assessed by HR–pQCT on ex vivo fracture prediction. Bone. January 2022;154:116206.
2013	Christen P. Deciphering the Secret Message Within Bone Microstructure [PhD thesis]. Eindhoven University of Technology; 2013.
2016	McDonald MP. Predicting Distal Radius Failure Load During a Fall Using Mechanical Testing and Peripheral Quantitative Computed Tomography [Master's thesis]. University of Saskatchewan; December 2016.
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.
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.