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Updated: Sep 4, 2025

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Dimensionality reduction of longitudinal 'omics data using modern tensor factorizations.

Uria Mor1,2, Yotam Cohen1, Rafael Valdés-Mas1

  • 1Systems Immunology Department, Weizmann Institute of Science, Rehovot, Israel.

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|July 15, 2022
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Summary
This summary is machine-generated.

This study introduces tcam, a novel unsupervised tensor factorization method designed for analyzing complex longitudinal omics data. Tcam effectively filters noise, revealing biologically relevant signals in feature-rich, sample-limited datasets for precision medicine applications.

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Area of Science:

  • Biomedical data analysis
  • Computational biology
  • Precision medicine

Background:

  • Longitudinal omics data are crucial for precision medicine, capturing individual variations.
  • Biomedical studies often generate high-dimensional, sample-limited datasets, posing analytical challenges.
  • Conventional methods struggle to filter noise and identify true biological signals in complex omics data.

Purpose of the Study:

  • To introduce tcam, a new unsupervised tensor factorization method for multiway data analysis.
  • To address the challenges of analyzing feature-rich and sample-limited longitudinal omics data.
  • To provide a tool for uncovering biologically relevant signals beyond inter-individual variation.

Main Methods:

  • Developed tcam, an unsupervised tensor factorization method based on tensor-tensor algebra.
  • Characterized tcam's mathematical properties, including data trait preservation and out-of-sample extension.
  • Applied tcam to re-analyze real-world human experimental longitudinal omics datasets.

Main Results:

  • Tcam preserves geometric and statistical data traits, enabling discovery beyond inter-individual variation.
  • The method offers natural out-of-sample extension, facilitating integration into machine learning workflows.
  • Re-analyses confirmed tcam's utility and theoretical properties in longitudinal omics data analysis.

Conclusions:

  • Tcam is a powerful new tool for analyzing complex longitudinal omics data in precision medicine.
  • The method enhances the interpretation of high-dimensional biological datasets by filtering noise effectively.
  • Tcam's capabilities support the identification of subtle biological signals crucial for personalized healthcare.