Assessment of carotid artery atherosclerosis through ultrasound and magnetic resonance imaging

Atherosclerosis is a chronic progressive disease. Although being segmental, atherosclerosis is systemic and attacks carotid arteries, propitiating a greater risk of cerebral vascular accident. In this assessment, we have applied two diagnostic imaging methods such as gray-scale B-mode ultrasound (US) in association with color flow Doppler (CFD-US) and T1 and T2-weighted magnetic resonance imaging (MRI) sequences, using black-blood (T1-BB and T2-BB) and black-blood with fat saturation (T1-FSBB and T2-FSBB) techniques, and magnetic resonance angiography (MRA) with and without paramagnetic contrast agent (three-dimensional time-of-flight, 3D TOF). Our objective was the identification of carotid atheromas in patients with coronary artery disease - as confirmed by cardiac catheterism, and referred to cardiac surgery. The degree of stenosis of the internal carotid arteries was estimated by CFD-US and by MRA, and the results from both methods were compared. The echogenicity of carotid plaques as seen by US and the signal intensity of MR images were also compared. Evaluation of image quality and inter-rater reliability of evaluation of MR images were also performed. There was a high incidence of carotid atherosclerosis in the patient population under study. From a total of one hundred (100) carotid artery segments analyzed by CFD-US for stenosis degree estimation, 81% showed some degree of stenosis, with a predominance of mild grade (grade II), which was detected in 59.0% of the cases. We have evaluated the association between the degree of stenosis visualized by CFD-US and by MRA with and without contrast agent and there was a marginal reproducibility between these methods. It was observed changes in artery wall signal intensity of 71% to 72%, in the T1-BB, T1-FSBB, T2-BB and T2-FSBB sequences of the MRI examinations. Increases in signal intensity were predominant. Among 72 plaques with echogenicity type 4, the signal intensity has increased 13.9% in 3D TOF, 59.7% inT1-BB, 65.3% in T1-FSBB, 62.5% in T2-BB and 66.7% in T2-FSBB. Among plaques with echogenicity type 2, the signal intensity has increased 42.9% in 3D TOF, 71.4% in T1-BB and T1-FSBB, 85.7% in T2-BB and 71.4% in T2-FSBB. Plaques with echogenicity type 1, showed signal intensity increase of 50.0% in the 3D TOF, T1 and T2 weighted MRI sequences. In 19 carotid artery segments, CFD-US was considered normal. When the same segments were evaluated by MRI, it was noted an increase of the image signal intensity in 21.1% in 3D TOF, 47.4% in T1-BB, 57.9% in T1-FSBB, 52.6% in T2-BB and T2-FSBB. There was no correlation between the types of plaque echogenicities seen by the CFD-US with the changes of signal intensity seen by MRI. The image quality and interobserver reliability of MR examinations were evaluated. The image quality of the T1 and T2-weighted axial MR images was considered excellent and for 3D TOF images, the quality was considered very good. The quality of the MRA images with and without paramagnetic contrast agent was considered excellent. It was noted an excellent interobserver reproducibility with values of Kappa index greater than 0.71 (AU)