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Main Authors: Nguyen, Phu X., Kontras, Konstantinos, Dai, Wei, Phan, Huy, Chatzichristos, Christos, Liang, Paul Pu, Vandenberk, Bert, De Vos, Maarten
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.27583
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author Nguyen, Phu X.
Kontras, Konstantinos
Dai, Wei
Phan, Huy
Chatzichristos, Christos
Liang, Paul Pu
Vandenberk, Bert
De Vos, Maarten
author_facet Nguyen, Phu X.
Kontras, Konstantinos
Dai, Wei
Phan, Huy
Chatzichristos, Christos
Liang, Paul Pu
Vandenberk, Bert
De Vos, Maarten
contents Electrocardiograms (ECGs) are widely used non-invasive measurements of cardiac activity and play a central role in clinical diagnosis. Recent multimodal approaches align ECG signals with clinical reports to incorporate diagnostic semantics, but clinical reports often fail to preserve the rich physiological structure of ECG waveforms, particularly across multiple levels of abstraction ranging from coarse diagnostic categories to fine-grained morphology. To address this limitation, we formulate ECG representation learning from an information-theoretic perspective and derive a tractable objective that jointly preserves signal structure and integrates clinical semantics. Based on this principle, we propose \textbf{MERIT} (Multimodal ECG Representation via Information Theory), a dual-branch pretraining framework combining masked ECG modeling with ECG--text contrastive alignment. Extensive experiments on PTB-XL and additional benchmarks demonstrate consistent improvements over prior methods, including gains exceeding $3%$ F1 on PTB-XL All and $5%$ F1 on SubClass classification. In zero-shot evaluation, MERIT further improves performance by up to $ +2.66\%$ AUC and $ +2.11\%$ F1 on PTB-XL SubClass, while also demonstrating robustness under multiple distribution-shift settings. Moreover, leveraging the learned ECG representations for ECG-conditioned clinical text generation with large language models improves text quality across several metrics, including ROUGE and METEOR. Together, these results demonstrate that MERIT learns more informative and clinically meaningful ECG representations, particularly for fine-grained clinical applications.
format Preprint
id arxiv_https___arxiv_org_abs_2605_27583
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Information-theoretic Multimodal Representation Learning for Electrocardiogram Signals
Nguyen, Phu X.
Kontras, Konstantinos
Dai, Wei
Phan, Huy
Chatzichristos, Christos
Liang, Paul Pu
Vandenberk, Bert
De Vos, Maarten
Machine Learning
Electrocardiograms (ECGs) are widely used non-invasive measurements of cardiac activity and play a central role in clinical diagnosis. Recent multimodal approaches align ECG signals with clinical reports to incorporate diagnostic semantics, but clinical reports often fail to preserve the rich physiological structure of ECG waveforms, particularly across multiple levels of abstraction ranging from coarse diagnostic categories to fine-grained morphology. To address this limitation, we formulate ECG representation learning from an information-theoretic perspective and derive a tractable objective that jointly preserves signal structure and integrates clinical semantics. Based on this principle, we propose \textbf{MERIT} (Multimodal ECG Representation via Information Theory), a dual-branch pretraining framework combining masked ECG modeling with ECG--text contrastive alignment. Extensive experiments on PTB-XL and additional benchmarks demonstrate consistent improvements over prior methods, including gains exceeding $3%$ F1 on PTB-XL All and $5%$ F1 on SubClass classification. In zero-shot evaluation, MERIT further improves performance by up to $ +2.66\%$ AUC and $ +2.11\%$ F1 on PTB-XL SubClass, while also demonstrating robustness under multiple distribution-shift settings. Moreover, leveraging the learned ECG representations for ECG-conditioned clinical text generation with large language models improves text quality across several metrics, including ROUGE and METEOR. Together, these results demonstrate that MERIT learns more informative and clinically meaningful ECG representations, particularly for fine-grained clinical applications.
title Information-theoretic Multimodal Representation Learning for Electrocardiogram Signals
topic Machine Learning
url https://arxiv.org/abs/2605.27583