Decoding heart failure subtypes with neural networks via differential explanation analysis.

Ruz Jurado, Mariano; Dimmeler, Stefanie; Schulz, Marcel H; Rodriguez Morales, David; Genetzakis, Elijah; Ardakani, Fatemeh Behjati; Fischer, Ariane; John, David; Zanders, Lukas; Buettner, Florian

doi:10.1093/bib/bbaf581

Journal Article

DKFZ-2025-02419

Decoding heart failure subtypes with neural networks via differential explanation analysis.

Ruz Jurado, M. ; Rodriguez Morales, D. ; Genetzakis, E. ; Ardakani, F. B. ; Zanders, L. ; Fischer, A. ; Buettner, F.DKFZ* ; Schulz, M. H. ; Dimmeler, S. ; John, D.

2025
Oxford University Press Oxford [u.a.]

Briefings in bioinformatics 26(6), bbaf581 (2025) [10.1093/bib/bbaf581]

Abstract: Single-cell transcriptomics offers critical insights into the molecular mechanisms of heart failure (HF) with reduced or preserved ejection fraction. However, understanding these mechanisms is hindered by the growing complexity of single-cell data and the difficulty in unmasking meaningful differential gene signatures among HF types. Machine learning, particularly deep neural networks (NNs), address these challenges by learning transcriptional patterns, reconstructing expression profiles and effectively classifying cells but often lacks interpretability. Recent advances in explainable AI (XAI) offer tools to clarify model decisions. Yet pinpointing differentially regulated genes with these tools remains challenging. We introduce a novel method to identify differentially explained genes (DXGs) based on importance scores derived from custom-built NNs. We highlight the superiority of DXGs in identifying HF subtypes-specific pathways that provide new insights into different types of HF. Offering a robust foundation for future research and therapeutic exploration in expanding transcriptome atlases.

Keyword(s): Heart Failure: genetics (MeSH) ; Heart Failure: classification (MeSH) ; Heart Failure: metabolism (MeSH) ; Humans (MeSH) ; Neural Networks, Computer (MeSH) ; Transcriptome (MeSH) ; Gene Expression Profiling (MeSH) ; Machine Learning (MeSH) ; Computational Biology: methods (MeSH) ; deep neural networks ; differential gene expression ; explainable artificial intelligence ; heart failure subtypes

Classification:

ddc:004

Contributing Institute(s):

DKTK Koordinierungsstelle Frankfurt (FM01)

Research Program(s):

899 - ohne Topic (POF4-899) (POF4-899)

Appears in the scientific report 2025

Database coverage:
Medline

;

; BIOSIS Previews ; Biological Abstracts ; Clarivate Analytics Master Journal List ; Current Contents - Life Sciences ; Ebsco Academic Search ; Essential Science Indicators ; Nationallizenz

; SCOPUS ; Science Citation Index Expanded ; Web of Science Core Collection

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Record created 2025-11-14, last modified 2026-03-12

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