Automated biventricular quantification in patients with repaired tetralogy of Fallot using a 3D deep learning segmentation model.

IF 4.2 1区医学 Q1 CARDIAC & CARDIOVASCULAR SYSTEMS

Journal of Cardiovascular Magnetic Resonance Pub Date : 2024-09-11 DOI:10.1016/j.jocmr.2024.101092

Sofie Tilborghs,Tiffany Liang,Stavroula Raptis,Ayako Ishikita,Werner Budts,Tom Dresselaers,Jan Bogaert,Frederik Maes,Rachel M Wald,Alexander Van De Bruaene

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引用次数: 0

Abstract

BACKGROUND Deep learning is the state-of-the-art approach for automated segmentation of the left ventricle (LV) and right ventricle (RV) in cardiac magnetic resonance (CMR) images. However, these models have been mostly trained and validated using CMR datasets of structurally normal hearts or cases with acquired cardiac disease, and are therefore not well-suited to handle cases with congenital cardiac disease such as tetralogy of Fallot (TOF). We aimed to develop and validate a dedicated model with improved performance for LV and RV cavity and myocardium quantification in patients with repaired TOF. METHODS We trained a 3D convolutional neural network (CNN) with 5-fold cross-validation using manually delineated end-diastolic (ED) and end-systolic (ES) short-axis image stacks obtained from either a public dataset containing patients with no or acquired cardiac pathology (n=100), an institutional dataset of TOF patients (n=96), or both datasets mixed. Our method allows for missing labels in the training images to accommodate for different ED and ES phases for LV and RV as is commonly the case in TOF. The best performing model was applied to all frames of a separate test set of TOF cases (n=36) and ED and ES phases were automatically determined for LV and RV separately. The model was evaluated against the performance of a commercial software (suiteHEART®, NeoSoft, Pewaukee, Wisconsin, US). RESULTS Training on the mixture of both datasets yielded the best agreement with the manual ground truth for the TOF cases, achieving a median DICE similarity coefficient of (93.8%, 89.8%) for LV cavity and of (92.9%, 90.9%) for RV cavity at (ED, ES) respectively, and of 80.9% and 61.8% for LV and RV myocardium at ED. The offset in automated ED and ES frame selection was 0.56 and 0.89 frames on average for LV and RV respectively. No statistically significant differences were found between our model and the commercial software for LV quantification (two-sided Wilcoxon signed rank test, p<5%), while RV quantification was significantly improved with our model achieving a mean absolute error of 12ml for RV cavity compared to 36ml for the commercial software. CONCLUSION We developed and validated a fully automatic segmentation and quantification approach for LV and RV, including RV mass, in patients with repaired TOF. Compared to a commercial software, our approach is superior for RV quantification indicating its potential in clinical practice.

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利用三维深度学习分割模型自动量化法洛氏四联症修复患者的双心室。

背景深度学习是在心脏磁共振（CMR）图像中自动分割左心室（LV）和右心室（RV）的最先进方法。然而，这些模型大多是使用结构正常的心脏或后天性心脏病病例的 CMR 数据集进行训练和验证的，因此不太适合处理法洛氏四联症（TOF）等先天性心脏病病例。我们的目的是开发并验证一种专用模型，该模型在对修复过的 TOF 患者进行左心室和左心室腔及心肌定量分析时性能更佳。方法：我们使用手动绘制的舒张末期（ED）和收缩末期（ES）短轴图像堆栈，对三维卷积神经网络（CNN）进行了 5 次交叉验证训练，这些图像堆栈分别取自包含无或获得性心脏病理学患者的公共数据集（n=100）、TOF 患者的机构数据集（n=96）或两个数据集的混合数据集。我们的方法允许训练图像中的缺失标签，以适应左心室和左心室不同的 ED 和 ES 阶段，这在 TOF 中很常见。将性能最好的模型应用于 TOF 病例（n=36）单独测试集的所有帧，并分别自动确定左心室和右心室的 ED 和 ES 阶段。结果在两个数据集的混合物上进行训练后，TOF 病例与人工基本真相的一致性最佳，LV 和 RV 的中位 DICE 相似系数分别为（93.8%、89.8%）。8%，89.8%），在（ED，ES）的左心室腔和左心室腔的相似系数中位数分别为（92.9%，90.9%），在ED的左心室和左心室心肌的相似系数中位数分别为80.9%和61.8%。对左心室和右心室而言，ED 和 ES 自动帧选择的偏移量平均分别为 0.56 帧和 0.89 帧。在 LV 定量方面，我们的模型与商业软件之间没有发现明显的统计学差异（双侧 Wilcoxon 符号秩检验，P<5%），而 RV 定量则有明显改善，我们的模型对 RV 腔的平均绝对误差为 12 毫升，而商业软件为 36 毫升。与商业软件相比，我们的方法在 RV 定量方面更胜一筹，显示了其在临床实践中的潜力。

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来源期刊

Journal of Cardiovascular Magnetic Resonance 医学-核医学

CiteScore

10.90

自引率

12.50%

发文量

审稿时长

6-12 weeks

期刊介绍： Journal of Cardiovascular Magnetic Resonance (JCMR) publishes high-quality articles on all aspects of basic, translational and clinical research on the design, development, manufacture, and evaluation of cardiovascular magnetic resonance (CMR) methods applied to the cardiovascular system. Topical areas include, but are not limited to: New applications of magnetic resonance to improve the diagnostic strategies, risk stratification, characterization and management of diseases affecting the cardiovascular system. New methods to enhance or accelerate image acquisition and data analysis. Results of multicenter, or larger single-center studies that provide insight into the utility of CMR. Basic biological perceptions derived by CMR methods.