Abstract
Hip fractures are associated with poor outcomes and high mortality rates of 30%. The current gold standard to measure bone fragility is a Dual-Energy X-ray Absorptiometry (DEXA) scan measuring bone mineral density. Yet DEXA under-diagnoses bone fragility by 50% (1). To combat the burden of bone fragility, this experimental study combined ultrasound (US) with a sophisticated computational algorithm, namely full wave inversion (FWI), to evaluate femoral bone structure.
The aims were to assess the association of bone structure between the proximal femoral diaphysis and femoral neck; secondly to evaluate whether transverse ultrasound could assess bone structure of the proximal femoral diaphysis.
Bone structure of 19 ex vivo human femora was assessed by micro-CT analysis (mean age 88.11 years, male:female 13:6)(Nikon HMXST 225). Using ImageJ/BoneJ, three 10.2mm subsections of proximal diaphysis and femoral neck underwent analysis: the total bone volume fraction, cortical parameters (bone volume fraction, porosity, thickness) and trabecular parameters (porosity, thickness, spacing and connectivity).
A unique US prototype was developed to analyse fifteen femoral diaphyseal subsections using two P4-1 transducers with a novel tomography sequence (Verasonics, Matlab ver R2019a, FWI TRUST protocol). Comparative quantitative analysis of US and Micro-CT measurements was assessed (Graphpad Prism 8.3.1).
Micro-CT analysis of the proximal femoral diaphysis demonstrated low correlation to the femoral neck (Pearson r −0.54 to 0.55). US was able to capture cortical structure, though a wide limit of agreement seen when compared to micro-CT analysis (Bland-Altman range 36–59% difference).
This novel US technique was able to capture cortical bone structure. Improvements in methodology and technology are required to improve the analysis of trabecular bone and overall accuracy. Further evaluation of US and FWI is required to develop the technique and determine its role in clinical practice.
