Elucidating failure mechanisms in human femurs during a fall to the side using bilateral digital image correlation

Grassi, Lorenzo<sup>1</sup>; Kok, Joeri<sup>1</sup>; Gustafsson, Anna<sup>1</sup>; Zheng, Yi<sup>2</sup>; Väänänen, Sami P.<sup>3,4</sup>; Jurvelin, Jukka S.<sup>3</sup>; Isaksson, Hanna<sup>1</sup>

Affiliations

¹Department of Biomedical Engineering, Lund University, Sweden

²Department of Physics, Technical University of Denmark, Denmark

³Department of Applied Physics, University of Eastern Finland, Finland

⁴Department of Radiology, Diagnostic Imaging Center, Kuopio University Hospital, Finland

Abstract and keywords

An improved understanding of the mechanical properties of human femurs is a milestone towards a more accurate assessment of fracture risk. Digital image correlation (DIC) has recently been adopted to provide full-field strain measurements during mechanical testing of femurs. However, it has typically been used to measure strains on the anterior side of the femur, whereas in both single-leg-stance and sideways fall loading conditions, the highest deformations result on the medial and lateral sides of the femoral neck. The goal of this study was to measure full-field deformations simultaneously on the medial and lateral side of the femoral neck in a configuration resembling a fall to the side. Twelve female cadaver femurs were prepared for DIC measurements and tested in sideways fall at 5 mm/s displacement rate. Two pairs of cameras recorded the medial and lateral side of the femoral neck, and deformations were calculated using DIC. The samples exhibited a two-stage failure: first, a compressive collapse on the superolateral side of the femoral neck in conjunction with peak force, followed by complete femoral neck fracture at the force drop following the post-elastic phase. DIC measurements corroborated this observation by reporting no tensile strains above yield limit for the medial side of the neck up to peak force. DIC measurements registered onto the bone micro-architecture showed strain localizations in proximity of cortical pores due to, for instance, blood vessels. This could explain previously reported discrepancies between simulations and experiments in regions rich with large pores, like the superolateral femoral neck.

Keywords: Digital image correlation; Femurs; Sideways fall; Strain distribution; Direction of principal strain; Hip fractures; Mechanical testing

Links

DOI: 10.1016/j.jbiomech.2020.109826

PubMed: 32517988

WoS: 000539433900014

History

Accepted: 2020-05-04

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Cited By (6)

Year	Entry
2022	Abe S, Kouhia R, Nikander R, Narra N, Hyttinen J, Sievänen H. Effect of fall direction on the lower hip fracture risk in athletes with different loading histories: a finite element modeling study in multiple sideways fall configurations. Bone. May 2022;158:116351.
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.
2023	Grassi L, Väänänen SP, Jehpsson L, Ljunggren Ö, Rosengren BE, Karlsson MK, Isaksson H. 3D finite element models reconstructed from 2D dual-energy x-ray absorptiometry (DXA) images improve hip fracture prediction compared to areal BMD in osteoporotic fractures in men (MrOS) Sweden cohort. J Bone Miner Res. September 2023;38(9):1258-1267.
2021	Gustafsson A, Tognini M, Bengtsson F, Gasser TC, Isaksson H, Grassi L. Subject-specific FE models of the human femur predict fracture path and bone strength under single-leg-stance loading. J Mech Behav Biomed Mater. January 2021;113:104118.
2021	Nyberg N. Dynamic Finite Element Modelling of a Fall on the Hip [Master's thesis]. Lund, Sweden: Lund University; 2021.
2022	Khakpour S. Multi-Component Finite Element Analysis of Low- Energy Acetabular Fracture: Computational Study of Pelvic Girdle Fracture Mechanism [PhD thesis]. University of Oulu; 2022.