A self-supervised electrocardiogram foundation model for empowering cardiovascular disease prediction and genetic factor discovery

可解释性 概化理论 机器学习 人工智能 疾病 医学 计算机科学 深度学习 接收机工作特性 全基因组关联研究 人工神经网络 遗传算法 基础(证据) 遗传模型 数据挖掘 预测建模 遗传关联 监督学习 数据科学 精密医学 生物信息学 心电图 心脏病 风险因素 鉴定(生物学) 联想(心理学) 重症监护医学
作者
Siying Lin,Zhaoqi Li,Qifan Wu,Yifeng Chen,Yuedong Yang,Hongyun Zhao
出处
期刊:Nature Communications [Nature Portfolio]
标识
DOI:10.1038/s41467-026-72436-2
摘要

Electrocardiogram (ECG) has been widely used in the diagnosis of cardiovascular disease (CVD). Current deep learning methods for CVD prediction using ECG often lack generalizability and interpretability, resulting in limited performance. Here, we have developed a self-supervised Electrocardiogram Large-scale Foundation Model (ECG-LFM) through pre-training over ten million 12-lead ECGs from multiple ECG datasets. To enhance ECG representation, ECG-LFM integrates contrastive learning with masked language modeling in a self-supervised manner, enabling the model to capture both global contextual information and fine-grained patterns within ECG signals. It was fine-tuned to predict eight types of CVDs and achieved an average area under the receiver operating characteristic curve (AUROC) of 0.930 from multiple datasets, which demonstrates improved performance compared to existing methods. The important ECG-LFM derived features (EDFs) are able to represent known CVD biomarkers, indicating the high interpretability of ECG-LFM. Applications of the EDFs in genome-wide association study identified 24 significant single nucleotide polymorphisms (SNPs) (P-value < 5×10-8, LD r2 < 0.01) associated with ECG, including 8 novel findings. The genetic causal effects of EDFs on the CVDs were evaluated by Mendelian randomization, indicating 2 CVDs and 4 EDFs having causal relationships. Overall, ECG-LFM provides accurate prediction for CVDs and novel genetic insights for ECG. This study presents ECG-LFM, an AI model trained on more than 10 million electrocardiograms to predict cardiovascular diseases and uncover novel genetic markers for heart health.
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