Continuous extraction of coronary artery centerline from cardiac CTA images using a regression-based method

Coronary artery centerline extraction in cardiac computed tomography angiography (CTA) is an effectively non-invasive method to diagnose and evaluate coronary artery disease (CAD). The traditional method of manual centerline extraction is time-consuming and tedious. In this study, we propose a deep learning algorithm that continuously extracts coronary artery centerlines from CTA images using a regression method. In the proposed method, a CNN module is trained to extract the features of CTA images, and then the branch classifier and direction predictor are designed to predict the most possible direction and lumen radius at the given centerline point. Besides, a new loss function is developed for associating the direction vector with the lumen radius. The whole process starts from a point manually placed at the coronary artery ostia, and terminates until tracking the vessel endpoint. The network was trained using a training set consisting of 12 CTA images and the evaluation was performed using a testing set consisting of 6 CTA images. The extracted centerlines had an average overlap (OV) of 89.19%, overlap until first error (OF) of 82.30%, and overlap with clinically relevant vessel (OT) of 91.42% with manually annotated reference. Our proposed method can efficiently deal with multi-branch problems and accurately detect distal coronary arteries, thereby providing potential help in assisting CAD diagnosis.

Automated summary

This study proposes a deep learning algorithm for continuous extraction of coronary artery centerlines from cardiac computed tomography angiography (CTA) images. The algorithm uses a regression method and a CNN module to extract features, and includes a branch classifier and direction predictor for direction and lumen radius prediction. A new loss function is developed to associate the direction vector with the lumen radius. The method achieves high accuracy in centerline extraction, making it useful for assisting in the diagnosis of coronary artery disease (CAD).