Department of Pediatrics, UT Southwestern Medical Center, 1935 Medical District Dr, Dallas, TX, 75235, USA.
Department of Radiology, UT Southwestern Medical Center, 1935 Medical District Dr, Dallas, TX, 75235, USA.
Pediatr Cardiol. 2021 Mar;42(3):578-589. doi: 10.1007/s00246-020-02518-5. Epub 2021 Jan 4.
Ventricular contouring of cardiac magnetic resonance imaging is the gold standard for volumetric analysis for repaired tetralogy of Fallot (rTOF), but can be time-consuming and subject to variability. A convolutional neural network (CNN) ventricular contouring algorithm was developed to generate contours for mostly structural normal hearts. We aimed to improve this algorithm for use in rTOF and propose a more comprehensive method of evaluating algorithm performance. We evaluated the performance of a ventricular contouring CNN, that was trained on mostly structurally normal hearts, on rTOF patients. We then created an updated CNN by adding rTOF training cases and evaluated the new algorithm's performance generating contours for both the left and right ventricles (LV and RV) on new testing data. Algorithm performance was evaluated with spatial metrics (Dice Similarity Coefficient (DSC), Hausdorff distance, and average Hausdorff distance) and volumetric comparisons (e.g., differences in RV volumes). The original Mostly Structurally Normal (MSN) algorithm was better at contouring the LV than the RV in patients with rTOF. After retraining the algorithm, the new MSN + rTOF algorithm showed improvements for LV epicardial and RV endocardial contours on testing data to which it was naïve (N = 30; e.g., DSC 0.883 vs. 0.905 for LV epicardium at end diastole, p < 0.0001) and improvements in RV end-diastolic volumetrics (median %error 8.1 vs 11.4, p = 0.0022). Even with a small number of cases, CNN-based contouring for rTOF can be improved. This work should be extended to other forms of congenital heart disease with more extreme structural abnormalities. Aspects of this work have already been implemented in clinical practice, representing rapid clinical translation. The combined use of both spatial and volumetric comparisons yielded insights into algorithm errors.
心脏磁共振成像的心室轮廓是修复性法洛四联症(rTOF)容积分析的金标准,但可能耗时且存在变异性。已经开发出卷积神经网络(CNN)心室轮廓算法来生成大多数结构正常心脏的轮廓。我们旨在改进该算法以用于 rTOF,并提出一种更全面的算法性能评估方法。我们评估了一种在结构正常的心脏上训练的心室轮廓 CNN 算法在 rTOF 患者中的性能。然后,我们通过添加 rTOF 训练病例创建了一个更新的 CNN,并在新的测试数据上评估了新算法生成左心室(LV)和右心室(RV)轮廓的性能。算法性能通过空间指标(Dice 相似系数(DSC)、Hausdorff 距离和平均 Hausdorff 距离)和容积比较(例如 RV 容积差异)进行评估。原始的主要结构正常(MSN)算法在 rTOF 患者中更擅长对 LV 进行轮廓勾画,而不是 RV。在重新训练算法后,新的 MSN+rTOF 算法在对其不熟悉的测试数据(N=30;例如,LV 舒张末期心外膜 DSC 0.883 对 0.905,p<0.0001)和 RV 舒张末期容积学方面的 LV 心外膜和 RV 心内膜轮廓均有所改善(中位数%误差 8.1 对 11.4,p=0.0022)。即使使用少量病例,基于 CNN 的 rTOF 轮廓勾画也可以得到改进。这项工作应该扩展到具有更极端结构异常的其他类型的先天性心脏病。这项工作的某些方面已经在临床实践中实施,代表了快速的临床转化。同时使用空间和容积比较可以深入了解算法错误。
