Abstract
The aim of this study was to investigate the use of de-blooming algorithm in coronary CT angiography (CCTA) for optimal evaluation of calcified plaques. Calcified plaques were simulated on a coronary vessel phantom and a cardiac motion phantom. Two convolution kernels, standard (STND) and high-definition standard (HD STND), were used for imaging reconstruction. A dedicated de-blooming algorithm was used for imaging processing. We found a smaller bias towards measurement of stenosis using the de-blooming algorithm (STND: bias 24.6% vs 15.0%, range 10.2% to 39.0% vs 4.0% to 25.9%; HD STND: bias 17.9% vs 11.0%, range 8.9% to 30.6% vs 0.5% to 21.5%). With use of de-blooming algorithm, specificity for diagnosing significant stenosis increased from 45.8% to 75.0% (STND), from 62.5% to 83.3% (HD STND); while positive predictive value (PPV) increased from 69.8% to 83.3% (STND), from 76.9% to 88.2% (HD STND). In the patient group, reduction in calcification volume was 48.1 ± 10.3%, reduction in coronary diameter stenosis over calcified plaque was 52.4 ± 24.2%. Our results suggest that the novel de-blooming algorithm could effectively decrease the blooming artifacts caused by coronary calcified plaques, and consequently improve diagnostic accuracy of CCTA in assessing coronary stenosis.
Highlights
Our results from phantom experiment and patient study suggest that the new de-blooming algorithm appears to effectively decrease the blooming artifacts caused by coronary calcified plaques, and improve image interpretability and diagnostic accuracy
We found a trend in our analysis that HD reconstruction mode improved coronary artery luminal visualization and results in higher diagnostic accuracy in comparison with standard reconstructions mode
Blooming artifact is caused by limited spatial resolution, which is associated with the design tradeoffs between image noise and resolution, and with the partial volume averaging of different densities within a single voxel
Summary
A total of 375 coronary artery segments from 31 patients were included for evaluation; image quality was comparable with and without use of de-blooming algorithm. Our results from phantom experiment and patient study suggest that the new de-blooming algorithm appears to effectively decrease the blooming artifacts caused by coronary calcified plaques, and improve image interpretability and diagnostic accuracy.
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