Frontiers in Physiology | |
WaSP-ECG: A Wave Segmentation Pretraining Toolkit for Electrocardiogram Analysis | |
David J. McEneaney1  Rob Brisk1  Alicja J. Piadlo1  Raymond R. Bond2  Dewar Finlay2  James A. D. McLaughlin2  | |
[1] Cardiology Department, Craigavon Area Hospital, Craigavon, United Kingdom;Faculty of Computing, Engineering and the Built Environment, Ulster University, Belfast, United Kingdom; | |
关键词: artificial intelligence; electrocardiogram (ECG); machine learning; explainable AI; representation learning; | |
DOI : 10.3389/fphys.2022.760000 | |
来源: DOAJ |
【 摘 要 】
IntroductionRepresentation learning allows artificial intelligence (AI) models to learn useful features from large, unlabelled datasets. This can reduce the need for labelled data across a range of downstream tasks. It was hypothesised that wave segmentation would be a useful form of electrocardiogram (ECG) representation learning. In addition to reducing labelled data requirements, segmentation masks may provide a mechanism for explainable AI. This study details the development and evaluation of a Wave Segmentation Pretraining (WaSP) application.Materials and MethodsPretraining: A non-AI-based ECG signal and image simulator was developed to generate ECGs and wave segmentation masks. U-Net models were trained to segment waves from synthetic ECGs. Dataset: The raw sample files from the PTB-XL dataset were downloaded. Each ECG was also plotted into an image. Fine-tuning and evaluation: A hold-out approach was used with a 60:20:20 training/validation/test set split. The encoder portions of the U-Net models were fine-tuned to classify PTB-XL ECGs for two tasks: sinus rhythm (SR) vs atrial fibrillation (AF), and myocardial infarction (MI) vs normal ECGs. The fine-tuning was repeated without pretraining. Results were compared. Explainable AI: an example pipeline combining AI-derived segmentation masks and a rule-based AF detector was developed and evaluated.ResultsWaSP consistently improved model performance on downstream tasks for both ECG signals and images. The difference between non-pretrained models and models pretrained for wave segmentation was particularly marked for ECG image analysis. A selection of segmentation masks are shown. An AF detection algorithm comprising both AI and rule-based components performed less well than end-to-end AI models but its outputs are proposed to be highly explainable. An example output is shown.ConclusionWaSP using synthetic data and labels allows AI models to learn useful features for downstream ECG analysis with real-world data. Segmentation masks provide an intermediate output that may facilitate confidence calibration in the context of end-to-end AI. It is possible to combine AI-derived segmentation masks and rule-based diagnostic classifiers for explainable ECG analysis.
【 授权许可】
Unknown