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Deep learning–based atherosclerotic coronary plaque segmentation on coronary CT angiography
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Jávorszky, Natasa, Homonnay, Bálint, Gerstenblith, Gary, Bluemke, David, Kiss, Peter, Török, Mihály, Celentano, David, Lai, Hong, Lai, Shenghan and Kolossváry, Márton (2022) Deep learning–based atherosclerotic coronary plaque segmentation on coronary CT angiography. European Radiology, 32 . pp. 7217-7226. doi:10.1007/s00330-022-08801-8 ISSN 1432-1084.
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Official URL: http://dx.doi.org/10.1007/s00330-022-08801-8
Abstract
Objectives
Volumetric evaluation of coronary artery disease (CAD) allows better prediction of cardiac events. However, CAD segmentation is labor intensive. Our objective was to create an open-source deep learning (DL) model to segment coronary plaques on coronary CT angiography (CCTA).
Methods
Three hundred eight individuals’ 894 CCTA scans with 3035 manually segmented plaques by an expert reader (considered as ground truth) were used to train (186/308, 60%), validate (tune, 61/308, 20%), and test (61/308, 20%) a 3D U-net model. We also evaluated the model on an external test set of 50 individuals with vulnerable plaques acquired at a different site. Furthermore, we applied transfer learning on 77 individuals’ data and re-evaluated the model’s performance using intra-class correlation coefficient (ICC).
Results
On the test set, DL outperformed the currently used minimum cost approach method to quantify total: ICC: 0.88 [CI: 0.85–0.91] vs. 0.63 [CI: 0.42–0.76], noncalcified: 0.84 [CI: 0.80–0.88] vs. 0.45 [CI: 0.26–0.59], calcified: 0.99 [CI: 0.98–0.99] vs. 0.96 [CI: 0.94–0.97], and low attenuation noncalcified: 0.25 [CI: 0.13–0.37] vs. −0.01 [CI: −0.13 to 0.11] plaque volumes. On the external dataset, substantial improvement was observed in DL model performance after transfer learning, total: 0.62 [CI: 0.01–0.84] vs. 0.94 [CI: 0.87–0.97], noncalcified: 0.54 [CI: −0.04 to 0.80] vs. 0.93 [CI: 0.86–0.96], calcified: 0.91 [CI:0.85–0.95] vs. 0.95 [CI: 0.91–0.97], and low attenuation noncalcified 0.48 [CI: 0.18–0.69] vs. 0.86 [CI: 0.76–0.92].
Conclusions
Our open-source DL algorithm achieved excellent agreement with expert CAD segmentations. However, transfer learning may be required to achieve accurate segmentations in the case of different plaque characteristics or machinery.
Key Points
• Deep learning 3D U-net model for coronary segmentation achieves comparable results with expert readers’ volumetric plaque quantification.
• Transfer learning may be needed to achieve similar results for other scanner and plaque characteristics.
• The developed deep learning algorithm is open-source and may be implemented in any CT analysis software.
Item Type: | Journal Article | ||||||||||
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Divisions: | Faculty of Science, Engineering and Medicine > Science > Computer Science | ||||||||||
Journal or Publication Title: | European Radiology | ||||||||||
Publisher: | Springer | ||||||||||
ISSN: | 1432-1084 | ||||||||||
Official Date: | October 2022 | ||||||||||
Dates: |
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Volume: | 32 | ||||||||||
Page Range: | pp. 7217-7226 | ||||||||||
DOI: | 10.1007/s00330-022-08801-8 | ||||||||||
Status: | Peer Reviewed | ||||||||||
Publication Status: | Published | ||||||||||
Access rights to Published version: | Restricted or Subscription Access |
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