3D patient-specific finite element models of the proximal femur based on DXA towards the classification of fracture and non-fracture cases

Wills, Carlos Ruiz; Olivares, Andy Luis; Tassani, Simone; Ceresa, Mario; Zimmer, Veronika; González Ballester, Miguel A.; Del Río, Luis Miguel; Humbert, Ludovic; Noailly, Jérôme

doi:10.1016/j.bone.2019.01.001

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3D patient-specific finite element models of the proximal femur based on DXA towards the classification of fracture and non-fracture cases
Citation	Wills CR, Olivares AL, Tassani S, Ceresa M, Zimmer V, González Ballester MA, Del Río LM, Humbert L, Noailly J. Bone 2019; 121: 89-99.
Affiliation	BCN MedTech, Universitat Pompeu Fabra (UPF), Barcelona, Spain.
Copyright	(Copyright © 2019, Elsevier Publishing)
DOI	10.1016/j.bone.2019.01.001
PMID	30611923
Abstract	Osteoporotic bone fractures reduce quality of life and drastically increase mortality. Minimally irradiating imaging techniques such as dual-energy X-ray absorptiometry (DXA) allow assessment of bone loss through the use of bone mineral density (BMD) as descriptor. Yet, the accuracy of fracture risk predictions remains limited. Recently, DXA-based 3D modelling algorithms were proposed to analyse the geometry and BMD spatial distribution of the proximal femur. This study hypothesizes that such approaches can benefit from finite element (FE)-based biomechanical analyses to improve fracture risk prediction. One hundred and eleven subjects were included in this study and stratified in two groups: (a) 62 fracture cases, and (b) 49 non-fracture controls. Side fall was simulated using a static peak load that depended on patient mass and height. Local mechanical fields were calculated based on relationships between tissue stiffness and BMD. The area under the curve (AUC) of the receiver operating characteristic method evaluated the ability of calculated biomechanical descriptors to discriminate fracture and control cases. The results showed that the major principal stress was better discriminator (AUC > 0.80) than the volumetric BMD (AUC ≤ 0.70). High discrimination capacity was achieved when the analysis was performed by bone type, zone of fracture and gender/sex (AUC of 0.91 for women, trabecular bone and trochanter area), and outcomes suggested that the trabecular bone is critical for fracture discrimination. In conclusion, 3D FE models derived from DXA scans might significantly improve the prediction of hip fracture risk; providing a new insight for clinicians to use FE simulations in clinical practice for osteoporosis management. Copyright © 2018. Published by Elsevier Inc. Language: en
Keywords	3D finite element analysis; DXA; Fracture discrimination; Hip fracture