Abstract
IntroductionDeep learning-based algorithms have demonstrated enormous performance in segmentation of medical images. We collected a dataset of multiparametric MRI and contour data acquired for use in radiosurgery, to evaluate the performance of deep convolutional neural networks (DCNN) in automatic segmentation of brain metastases (BM).MethodsA conventional U-Net (cU-Net), a modified U-Net (moU-Net) and a U-Net trained only on BM smaller than 0.4 ml (sU-Net) were implemented. Performance was assessed on a separate test set employing sensitivity, specificity, average false positive rate (AFPR), the dice similarity coefficient (DSC), Bland-Altman analysis and the concordance correlation coefficient (CCC).ResultsA dataset of 509 patients (1223 BM) was split into a training set (469 pts) and a test set (40 pts). A combination of all trained networks was the most sensitive (0.82) while maintaining a specificity 0.83. The same model achieved a sensitivity of 0.97 and a specificity of 0.94 when considering only lesions larger than 0.06 ml (75% of all lesions). Type of primary cancer had no significant influence on the mean DSC per lesion (p = 0.60). Agreement between manually and automatically assessed tumor volumes as quantified by a CCC of 0.87 (95% CI, 0.77–0.93), was excellent.ConclusionUsing a dataset which properly captured the variation in imaging appearance observed in clinical practice, we were able to conclude that DCNNs reach clinically relevant performance for most lesions. Clinical applicability is currently limited by the size of the target lesion. Further studies should address if small targets are accurately represented in the test data.
Highlights
Deep learning-based algorithms have demonstrated enormous performance in segmentation of medical images
Performance of the algorithm depends on the size of the target lesion
A dataset of 509 patients (1223 brain metastases) with the required T1-weighted contrast-enhanced MRI (T1c), T2 and Fluid-attenuated inversion recovery (FLAIR) images and contour data was used for this study (Table 1)
Summary
Deep learning-based algorithms have demonstrated enormous performance in segmentation of medical images. We collected a dataset of multiparametric MRI and contour data acquired for use in radiosurgery, to evaluate the performance of deep convolutional neural networks (DCNN) in automatic segmentation of brain metastases (BM). Contouring of planning CT and MR images generates a large amount of clinically representative imaging and contour data This data can be used to train deep convolutional neural networks (DCNNs) which have been applied to various tasks in medical imaging including segmentation in the recent years [3]. Dikici et al identified this problem and developed an algorithm which was trained and performed well only on small BM (mean volume of 160 mm3) [7], which suggests that a single model is unlikely to solve the segmentation problem for metastases of arbitrary size
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