Abstract
In the three-dimensional reconstruction of the pulmonary artery and the identification of pulmonary embolism, experts find it difficult to accurately estimate the severity of the embolism in the pulmonary artery, due to its irregular shape and complex adjacent tissues. In effect, segmenting the pulmonary artery accurately is the basis for assessing the severity of pulmonary embolism, and it is also a challengeable task. To solve this problem, this study proposes a ResD-Unet architecture for pulmonary artery segmentation. To begin with, the U-Net network is used as the basic structure, which allows efficient information flow and good performance in the absence of a sufficiently large dataset. In what follows, novel Residual-Dense blocks are introduced in the ResD-Unet architecture to refine image segmentation and build a deeper network while improving the gradient circulation of the network. Finally, a novel hybrid loss function is utilized to make full use of the advantages of the binary cross entropy loss, Dice loss and SSIM loss. Equipped with the hybrid loss, the proposed architecture is able to effectively segment the object areas and accurately predict the structures with clear boundaries. The experimental results show that the proposed framework can achieve high segmentation accuracy and efficiency, and the segmentation results are comparable to that of manual segmentation.
Highlights
Pulmonary embolism (PE) refers to the pathological and clinical conditions caused by impacting substances entering the pulmonary artery and blocking the blood supply to the tissues, and its morbidity is only lower than that of coronary heart disease and hypertension
U-Net is one of the most well-known deep learning networks with an encoder-decoder architecture, it is widely used in the field of medical image segmentation
Drawing lessons from residual connection and dense connection, we propose Residual-Dense blocks, which attenuate to a great extent the problem of degradation and vanishing gradients that are present in deep architectures
Summary
Pulmonary embolism (PE) refers to the pathological and clinical conditions caused by impacting substances entering the pulmonary artery and blocking the blood supply to the tissues, and its morbidity is only lower than that of coronary heart disease and hypertension. Early diagnosis and timely treatment are the keys to effectively reduce the risk of death. Contrast-enhanced Computed Tomography (CT) is the most commonly used modality for PE screening [1]. Three-dimensional visualization is a technology that uses two-dimensional image sequence to reconstruct three dimensional model and perform analysis. The 3D construction of lung is achieved by stacking the evolved contours of individual slices over one another [2]. Compared with two-dimensional (2D) images, the 3D visualization of pulmonary artery CT images can provide more information
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