Abstract
Despite the state-of-the-art performance for medical image segmentation, deep convolutional neural networks (CNNs) have rarely provided uncertainty estimations regarding their segmentation outputs, e.g., model (epistemic) and image-based (aleatoric) uncertainties. In this work, we analyze these different types of uncertainties for CNN-based 2D and 3D medical image segmentation tasks at both pixel level and structure level. We additionally propose a test-time augmentation-based aleatoric uncertainty to analyze the effect of different transformations of the input image on the segmentation output. Test-time augmentation has been previously used to improve segmentation accuracy, yet not been formulated in a consistent mathematical framework. Hence, we also propose a theoretical formulation of test-time augmentation, where a distribution of the prediction is estimated by Monte Carlo simulation with prior distributions of parameters in an image acquisition model that involves image transformations and noise. We compare and combine our proposed aleatoric uncertainty with model uncertainty. Experiments with segmentation of fetal brains and brain tumors from 2D and 3D Magnetic Resonance Images (MRI) showed that 1) the test-time augmentation-based aleatoric uncertainty provides a better uncertainty estimation than calculating the test-time dropout-based model uncertainty alone and helps to reduce overconfident incorrect predictions, and 2) our test-time augmentation outperforms a single-prediction baseline and dropout-based multiple predictions.
Highlights
Segmentation of medical images is an essential task for many applications such as anatomical structure modeling, tumor growth measurement, surgical planing and treatment assessment (Sharma and Aggarwal, 2010)
We propose a mathematical formulation for test-time augmentation, and analyze its performance for the general aleatoric uncertainty estimation in medical image segmentation tasks
Though the transformations can be in spatial, intensity or feature space, in this work we only study the impact of reversible spatial transformations, which are the most common types of transformations occurring during image acquisition and used for data augmentation purposes
Summary
Segmentation of medical images is an essential task for many applications such as anatomical structure modeling, tumor growth measurement, surgical planing and treatment assessment (Sharma and Aggarwal, 2010). Deep learning with convolutional neural networks (CNN) has achieved the state-of-the-art performance for many medical image segmentation tasks (Milletari et al, 2016; Abdulkadir et al, 2016; Kamnitsas et al, 2017) Despite their impressive performance and the ability of automatic feature learning, these approaches do not by default provide uncertainty estimation for their segmentation results. Current medical image segmentation methods based on deep CNNs use relatively small datasets compared with those for natural image recognition(Russakovsky et al, 2015) This is likely to introduce more uncertain predictions for the segmentation results, and leads to uncertainty of downstream analysis, such as volumetric measurement of the target. Uncertainty estimation is highly desired for deep CNN-based medical image segmentation methods
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