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Estimating Local Tissue Expansion in Thoracic Computed Tomography Images Using Convolutional Neural Networks
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Estimating Local Tissue Expansion in Thoracic Computed Tomography Images Using Convolutional Neural Networks
Registration of lungs in thoracic computed tomography (CT) images produces a dense correspondence which can be analyzed to estimate local tissue expansion. However, the validity of this local expansion estimate is dependent on the accuracy of the image registration. In this work, a convolutional neural network (CNN) model is used to directly estimate the local tissue expansion between lungs imaged at two lung volumes, without requiring image registration. The network was trained with 5705 subjects from COPDGene with varying degrees of disease severity. The CNN-based model was evaluated with 3046 subjects from COPDGene. At the global scale, the mean lung expansion estimated from the CNN-based and registration-based models were highly correlated (rs = 0.945). At the local scale, the proposed method achieved a voxelwise Spearman correlation of 0.871 ? 0.080. At the regional scale, Dice coefficient for high and low func- tioning regions was 0.806 ? 0.065 and 0.805 ? 0.066, respectively. The results indicate the CNN-based model was able to reproduce image registration derived tissue expansion images without explicitly estimating the correspondence.
Registration of lungs in thoracic computed tomography (CT) images produces a dense correspondence which can be analyzed to estimate local tissue expansion. However, the validity of this local expansion estimate is dependent on the accuracy of the image registration. In this work, a convolutional neural network (CNN) model is used to directly estimate the local tissue expansion between lungs imaged at two lung volumes, without requiring image registration. The network was trained with 5705 subjects from COPDGene with varying degrees of disease severity. The CNN-based model was evaluated with 3046 subjects from COPDGene. At the global scale, the mean lung expansion estimated from the CNN-based and registration-based models were highly correlated (rs = 0.945). At the local scale, the proposed method achieved a voxelwise Spearman correlation of 0.871 ? 0.080. At the regional scale, Dice coefficient for high and low func- tioning regions was 0.806 ? 0.065 and 0.805 ? 0.066, respectively. The results indicate the CNN-based model was able to reproduce image registration derived tissue expansion images without explicitly estimating the correspondence.