Abstract
BackgroundSegmentation of the ulna and radius is a crucial step for the measurement of bone mineral density (BMD) in dual-energy X-ray imaging in patients suspected of having osteoporosis.PurposeThis work aimed to propose a deep learning approach for the accurate automatic segmentation of the ulna and radius in dual-energy X-ray imaging.Methods and materialsWe developed a deep learning model with residual block (Resblock) for the segmentation of the ulna and radius. Three hundred and sixty subjects were included in the study, and five-fold cross-validation was used to evaluate the performance of the proposed network. The Dice coefficient and Jaccard index were calculated to evaluate the results of segmentation in this study.ResultsThe proposed network model had a better segmentation performance than the previous deep learning-based methods with respect to the automatic segmentation of the ulna and radius. The evaluation results suggested that the average Dice coefficients of the ulna and radius were 0.9835 and 0.9874, with average Jaccard indexes of 0.9680 and 0.9751, respectively.ConclusionThe deep learning-based method developed in this study improved the segmentation performance of the ulna and radius in dual-energy X-ray imaging.
Highlights
Segmentation of the ulna and radius is a crucial step for the measurement of bone mineral density (BMD) in dual-energy X-ray imaging in patients suspected of having osteoporosis.Purpose: This work aimed to propose a deep learning approach for the accurate automatic segmentation of the ulna and radius in dual-energy X-ray imaging
The deep learning-based method developed in this study improved the segmentation performance of the ulna and radius in dual-energy X-ray imaging
The World Health Organization considers the BMD obtained by dual-energy X-ray absorptiometry (DEXA) as the goldstandard for the diagnosis of osteoporosis [11]
Summary
Segmentation of the ulna and radius is a crucial step for the measurement of bone mineral density (BMD) in dual-energy X-ray imaging in patients suspected of having osteoporosis.Purpose: This work aimed to propose a deep learning approach for the accurate automatic segmentation of the ulna and radius in dual-energy X-ray imaging. Segmentation of the ulna and radius is a crucial step for the measurement of bone mineral density (BMD) in dual-energy X-ray imaging in patients suspected of having osteoporosis. Osteoporosis has a high incidence rate among middle-aged and elderly people, especially women [2, 3]. The World Health Organization considers the BMD obtained by dual-energy X-ray absorptiometry (DEXA) as the goldstandard for the diagnosis of osteoporosis [11]. Dualenergy X-ray imaging is often applied to the diagnosis of osteoporosis and to predict fracture risk by measuring the BMD of the ulna and radius, lumbar (L1–L4) vertebrae, and femur [12,13,14]. The segmentation of the bone region, followed by the calculation of the BMD according to the principle of DEXA (the energy attenuation intensity of low-energy and high-energy X-ray passing through human tissue is different) [15, 16], is important steps in BMD measurement
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