Abstract
Retinal blood vessel morphological abnormalities are generally associated with cardiovascular, cerebrovascular, and systemic diseases, automatic artery/vein (A/V) classification is particularly important for medical image analysis and clinical decision making. However, the current method still has some limitations in A/V classification, especially the blood vessel edge and end error problems caused by the single scale and the blurred boundary of the A/V. To alleviate these problems, in this work, we propose a vessel-constraint network (VC-Net) that utilizes the information of vessel distribution and edge to enhance A/V classification, which is a high-precision A/V classification model based on data fusion. Particularly, the VC-Net introduces a vessel-constraint (VC) module that combines local and global vessel information to generate a weight map to constrain the A/V features, which suppresses the background-prone features and enhances the edge and end features of blood vessels. In addition, the VC-Net employs a multiscale feature (MSF) module to extract blood vessel information with different scales to improve the feature extraction capability and robustness of the model. And the VC-Net can get vessel segmentation results simultaneously. The proposed method is tested on publicly available fundus image datasets with different scales, namely, DRIVE, LES, and HRF, and validated on two newly created multicenter datasets: Tongren and Kailuan. We achieve a balance accuracy of 0.9554 and F1 scores of 0.7616 and 0.7971 for the arteries and veins, respectively, on the DRIVE dataset. The experimental results prove that the proposed model achieves competitive performance in A/V classification and vessel segmentation tasks compared with state-of-the-art methods. Finally, we test the Kailuan dataset with other trained fusion datasets, the results also show good robustness. To promote research in this area, the Tongren dataset and source code will be made publicly available. The dataset and code will be made available at https://github.com/huawang123/VC-Net.
Highlights
Retinal blood vessels have attracted widespread research efforts as these vessels represent the only internal human vascular structures that can be observed noninvasively
In order to alleviate these challenges, in this work, we introduce a novel convolutional neural network for joint A/V classification and vessel segmentation in retinal fundus images, named the vessel-constraint network (VC-Net)
The proposed method was used for vessel segmentation and A/V classification simultaneously; performance indices were calculated
Summary
Retinal blood vessels have attracted widespread research efforts as these vessels represent the only internal human vascular structures that can be observed noninvasively. Retinal vessel abnormalities reflect the cumulative damage caused by chronic diseases such diabetes and hypertension and represent an important risk indicator for many systemic and cardiovascular diseases (Wong et al, 2004). Artery narrowing is mostly associated with arterial hypertension, whereas vein widening is related to increased brain pressure, stroke, and similar cardiovascular diseases. Current clinical methods for retinal vessel segmentation and A/V classification mainly rely on manual segmentation. Due to the high complexity and diversity of vessel structures, manual segmentation brings inevitable shortcomings, including being time-consuming and laborious, having interrater variability and subjectivity, and having lower efficiency and accuracy. Automatic methods for A/V classification and vessel segmentation are highly desirable in clinical settings.
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