Abstract
We developed a fully automated, two-step deep learning approach for characterizing coronary calcified plaque in intravascular optical coherence tomography (IVOCT) images. First, major calcification lesions were detected from an entire pullback using a 3D convolutional neural network (CNN). Second, a SegNet deep learning model with the Tversky loss function was used to segment calcified plaques in the major calcification lesions. The fully connected conditional random field and the frame interpolation of the missing calcification frames were used to reduce classification errors. We trained/tested the networks on a large dataset comprising 8,231 clinical images from 68 patients with 68 vessels and 4,320 ex vivo cadaveric images from 4 hearts with 4 vessels. The 3D CNN model detected major calcifications with high sensitivity (97.7%), specificity (87.7%), and F1 score (0.922). Compared to the standard one-step approach, our two-step deep learning approach significantly improved sensitivity (from 77.5% to 86.2%), precision (from 73.5% to 75.8%), and F1 score (from 0.749 to 0.781). We investigated segmentation performance for varying numbers of training samples; at least 3,900 images were required to obtain stable segmentation results. We also found very small differences in calcification attributes (e.g., angle, thickness, and depth) and identical calcium scores on repetitive pullbacks, indicating excellent reproducibility. Applied to new clinical pullbacks, our method has implications for real-time treatment planning and imaging research.
Highlights
Coronary calcified plaque (CCP) is an important marker of early atherosclerosis
The severity of CCP is strongly associated with the degree of atherosclerosis, and the extent of CCP distribution is linked to higher rates of complications and worse outcomes during or after percutaneous coronary intervention (PCI), the most widely performed intervention for coronary heart disease [3]
We compared the performance of our 3D convolutional neural network (CNN) model to various 2D models for identifying major calcification lesions
Summary
CCP is highly prevalent in patients with coronary heart disease and leads to reduced vascular compliance, abnormal vasomotor responses, and impaired myocardial perfusion [1], [2]. The severity of CCP is strongly associated with the degree of atherosclerosis, and the extent of CCP distribution is linked to higher rates of complications and worse outcomes during or after percutaneous coronary intervention (PCI), the most widely performed intervention for coronary heart disease [3]. Intravascular optical coherence tomography (IVOCT) is a high contrast, high-resolution imaging modality that produces cross-sectional images of coronary arteries using a near-infrared light. Compared to intravascular ultrasound (IVUS), IVOCT provides better penetration depth for detection of calcifications and relatively high axial (12-18 μm vs 150-250 μm from IVUS) and lateral (20-90 μm vs 150300 μm from IVUS) resolution [4].
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