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MultiGEOmics: Graph-Based Integration of Multi-Omics via Biological Information Flows.

Bizhan Alipour Pijani1,2,3, Jubair Ibn Malik Rifat1,2,3, Serdar Bozdag1,2,3,4

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MultiGEOmics integrates multi-omics data by modeling cross-omics regulatory signals, improving machine learning for biology and medicine. This framework maintains robust performance even with missing data, aiding complex cellular process analysis.

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Area of Science:

  • Computational Biology
  • Bioinformatics
  • Machine Learning in Medicine

Background:

  • Multi-omics datasets offer comprehensive biological insights but are challenging to integrate.
  • Current graph-based methods often ignore crucial cross-omics regulatory signals and struggle with missing data.
  • Existing approaches often fail to model interdependencies between different omics layers effectively.

Purpose of the Study:

  • To introduce MultiGEOmics, a novel graph integration framework for multi-omics data.
  • To explicitly model cross-omics regulatory signals and dependencies for improved biological insights.
  • To develop a method robust to missing omics data for reliable machine learning applications.

Main Methods:

  • Developed MultiGEOmics, an intermediate-level graph integration framework.
  • Incorporated explicit cross-omics regulatory signals into graph representation learning.
  • Modeled both omics-specific and cross-omics dependencies using biologically inspired approaches.

Main Results:

  • MultiGEOmics learns robust cross-omics embeddings, performing well even with partially missing data.
  • Evaluated on eleven datasets across cancer and Alzheimer's disease, showing consistent strong predictive performance under various missing-data scenarios.
  • Demonstrated interpretability by identifying key omics types and features driving predictions.

Conclusions:

  • MultiGEOmics effectively integrates multi-omics data, overcoming limitations of existing methods.
  • The framework provides reliable and interpretable predictions, even with incomplete datasets.
  • Enables advanced machine learning applications in biology and medicine by leveraging integrated omics information.