Abstract
BACKGROUND: Carotid artery disease (CAD) is a serious disease caused by atherosclerosis, resulting in reduced cerebral blood flow and an increased risk of stroke. Traditionally, CAD diagnosis involves manual segmentation of computed tomography angiography (CTA) images, a time-consuming and complex process. This study aimed to address the need for an automated and accurate method for three-dimensional (3D) carotid artery segmentation using deep learning (DL) techniques. METHODS: A total of 214 CTA images from patients at the Affiliated Hospital of Nantong University and Nantong First People's Hospital were collected. The data were annotated using 3Dslicer software and calibrated by experienced radiologists. Preprocessing and augmentation of the CTA images were conducted using a novel window/level (W/L) adjustment method to enhance vascular imaging. The segmentation is performed using the Multi-Flux-Swin-Deepsup-UNet (MFSD-UNet) model, which incorporates multi-scale deep supervision and multi-flux fusion architecture. Performance was evaluated based on accuracy, dice coefficient, sensitivity, and specificity, and compared with state-of-the-art models. Ablation studies were conducted, removing the Swin transformer and deep supervision components to demonstrate the superiority of our method. RESULTS: The proposed model showed excellent performance, achieving an average dice coefficient of 0.9119 and an accuracy of 0.9819, outperforming the average dice coefficients of 0.8770 and 0.8910 for the two state-of-the-art models. Furthermore, it demonstrated high stability across various segmentation categories. Ablation studies revealed that removing the Swin transformer and deep supervision components resulted in a decrease in the dice coefficient to 0.8630 and 0.8371. Significant differences were observed when comparing these four models with MFSD-UNet (P<0.05), and seven-fold cross-validations were performed on MFSD-UNet to demonstrate its robustness. CONCLUSIONS: This study introduced a novel DL-based method for automatic 3D carotid artery segmentation from CTA images. The integration of Swin transformers, deep supervision mechanisms, and innovative data augmentation techniques significantly enhanced the accuracy and robustness of segmentation. This method offers valuable support for the clinical diagnosis and treatment of CAD and exhibits great potential for future medical image segmentation.