Abstract
Arterial calcification is an independent predictor of cardiovascular disease (CVD) events whereas thoracic aorta calcium (TAC) detection might anticipate extracoronary outcomes. In this work, we trained six convolutional neural networks (CNNs) to detect aortic calcifications and to automate the TAC score assessment in intermediate CVD risk patients. Cardiac computed tomography images from 1415 patients were analyzed together with their aortic geometry previously assessed. Orthogonal patches centered in each aortic candidate lesion were reconstructed and a dataset with 19,790 images (61% positives) was built. Three single-input 2D CNNs were trained using axial, coronal and sagittal patches together with two multi-input 2.5D CNNs combining the orthogonal patches and identifying their best regional combination (BRC) in terms of lesion location. Aortic calcifications were concentrated in the descending (66%) and aortic arch (26%) portions. The BRC of axial patches to detect ascending or aortic arch lesions and sagittal images for the descending portion had the best performance: 0.954 F1-Score, 98.4% sensitivity, 87% of the subjects correctly classified in their TAC category and an average false positive TAC score per patient of 30. A CNN that combined axial and sagittal patches depending on the candidate aortic location ensured an accurate TAC score prediction.
Highlights
Arterial calcification is an independent predictor of cardiovascular disease (CVD)events, morbidity and mortality [1]
All images were reconstructed with a thickness of 2.5 mm and analyzed using custom software designed in our laboratory to detect, label and calculate the size and position of calcifications in the thoracic aorta (TA) [6]
The main evaluation metric employed to compare the performance of the different architectures was the F1-Score value weighted by Thoracic aorta calcium (TAC) in a lesion-by-lesion scheme
Summary
Arterial calcification is an independent predictor of cardiovascular disease (CVD)events, morbidity and mortality [1]. Calcium deposits can be observed in several vascular beds [2], but coronary artery calcium (CAC) is probably the most studied biomarker of calcium burden. It is generally quantified using the Agatston score [3] which is calculated detecting calcified lesions in non-enhanced computed tomography (CT) axial images, accumulating their size and weighting them by density [4]. Thoracic aorta calcium (TAC), generally detected in the ascending and descending portions of the aorta during coronary examinations, was associated with CVD events and death [5]. The relationship between presence and extent of aortic calcium and the occurrence of stroke [7]
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