# Unveiling complex patterns: An information-theoretic approach to high-order behaviors in microarray data

**Authors:** Antonio Lacalamita, Alfonso Monaco, Grazia Serino, Daniele Marinazzo, Nicola Amoroso, Loredana Bellantuono, Marianna La Rocca, Tommaso Maggipinto, Ester Pantaleo, Emanuele Piccinno, Viviana Scalavino, Sabina Tangaro, Gianluigi Giannelli, Sebastiano Stramaglia, Roberto Bellotti, Paul Gagniuc, Y-h. Taguchi, Y-h. Taguchi, Y-h. Taguchi, Y-h. Taguchi

PMC · DOI: 10.1371/journal.pone.0336379 · 2025-11-13

## TL;DR

This paper uses an information-theoretic method to uncover complex gene interactions in microarray data from HCC and ASD patients.

## Contribution

The novel application of partial information decomposition (PID) reveals higher-order gene behaviors not captured by traditional methods.

## Key findings

- PID identifies differential genes and enriched functions linked to disease phenotypes.
- Synergy clusters reveal higher-order behaviors not detected by classical correlation methods.

## Abstract

The information-theoretic approach can shed light on the role of groups of correlated elements within a network. While there are already established methods for measuring new information, storage and transmission, the definition and application of methods for measuring information change remains an unresolved challenge. The change of information in a network is associated with redundancy and synergy between systems that share information about a target. Redundancy involves shared information about the target that can be retrieved using the individual source systems, while synergy involves information that can only be obtained by sharing the systems. A more refined approach, called partial information decomposition (PID), separates the unique, redundant and synergetic contributions of the shared information. However, these contributions cannot be directly derived from the classical measures of information theory. In this work, we apply PID approach to publicly available microarray gene expression data from 2 different experiments derived from patients affected by HCC and ASD. By comparing sample and gene synergy clusters with classical correlation clusters, we uncover higher order behaviours, such as differential genes and enriched functions closely linked to diseases phenotype, that emerge with this novel approach. These findings and further applications of this approach to gene expression data could shed light on the genetic aspects related to physiological aspects of complex diseases.

## Linked entities

- **Diseases:** HCC (MONDO:0007256), ASD (MONDO:0006664)

## Full-text entities

- **Diseases:** HCC (MESH:D006528), ASD (MESH:D001321)
- **Species:** Homo sapiens (human, species) [taxon 9606]

## Figures

50 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12614557/full.md

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Source: https://tomesphere.com/paper/PMC12614557