Interaction information along lifespan of the resting brain dynamics reveals a major redundant role of the default mode network

Borja Camino-Pontes; Ibai Diez; Antonio Jimenez-Marin; Javier Rasero; Asier Erramuzpe; Paolo Bonifazi; Sebastiano Stramaglia; Stephan Swinnen; Jesus M. Cortes

doi:10.3390/e20100786

Interaction information along lifespan of the resting brain dynamics reveals a major redundant role of the default mode network

Borja Camino-Pontes
, Ibai Diez
, Antonio Jimenez-Marin
, Javier Rasero
, Asier Erramuzpe
, Paolo Bonifazi
, Sebastiano Stramaglia
, Stephan Swinnen
, Jesus M. Cortes^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

18 Citations (Scopus)

Abstract

Interaction Information (II) generalizes the univariate Shannon entropy to triplets of variables, allowing the detection of redundant (R) or synergetic (S) interactions in dynamical networks. Here, we calculated II from functional magnetic resonance imaging data and asked whether R or S vary across brain regions and along lifespan. Preserved along lifespan, we found high overlapping between the pattern of high R and the default mode network, whereas high values of S were overlapping with different cognitive domains, such as spatial and temporal memory, emotion processing and motor skills. Moreover, we have found a robust balance between R and S among different age intervals, indicating informational compensatory mechanisms in brain networks.

Original language	English
Article number	742
Journal	Entropy
Volume	20
Issue number	10
DOIs	https://doi.org/10.3390/e20100786
Publication status	Published - 1 Oct 2018
Externally published	Yes

Keywords

Default mode network
Interaction information
Lifespan
Redundancy
Resting state
Synergy

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10.3390/e20100786

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abstract = "Interaction Information (II) generalizes the univariate Shannon entropy to triplets of variables, allowing the detection of redundant (R) or synergetic (S) interactions in dynamical networks. Here, we calculated II from functional magnetic resonance imaging data and asked whether R or S vary across brain regions and along lifespan. Preserved along lifespan, we found high overlapping between the pattern of high R and the default mode network, whereas high values of S were overlapping with different cognitive domains, such as spatial and temporal memory, emotion processing and motor skills. Moreover, we have found a robust balance between R and S among different age intervals, indicating informational compensatory mechanisms in brain networks.",

keywords = "Default mode network, Interaction information, Lifespan, Redundancy, Resting state, Synergy",

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T1 - Interaction information along lifespan of the resting brain dynamics reveals a major redundant role of the default mode network

AU - Camino-Pontes, Borja

AU - Diez, Ibai

AU - Jimenez-Marin, Antonio

AU - Rasero, Javier

AU - Erramuzpe, Asier

AU - Bonifazi, Paolo

AU - Stramaglia, Sebastiano

AU - Swinnen, Stephan

AU - Cortes, Jesus M.

PY - 2018/10/1

Y1 - 2018/10/1

N2 - Interaction Information (II) generalizes the univariate Shannon entropy to triplets of variables, allowing the detection of redundant (R) or synergetic (S) interactions in dynamical networks. Here, we calculated II from functional magnetic resonance imaging data and asked whether R or S vary across brain regions and along lifespan. Preserved along lifespan, we found high overlapping between the pattern of high R and the default mode network, whereas high values of S were overlapping with different cognitive domains, such as spatial and temporal memory, emotion processing and motor skills. Moreover, we have found a robust balance between R and S among different age intervals, indicating informational compensatory mechanisms in brain networks.

AB - Interaction Information (II) generalizes the univariate Shannon entropy to triplets of variables, allowing the detection of redundant (R) or synergetic (S) interactions in dynamical networks. Here, we calculated II from functional magnetic resonance imaging data and asked whether R or S vary across brain regions and along lifespan. Preserved along lifespan, we found high overlapping between the pattern of high R and the default mode network, whereas high values of S were overlapping with different cognitive domains, such as spatial and temporal memory, emotion processing and motor skills. Moreover, we have found a robust balance between R and S among different age intervals, indicating informational compensatory mechanisms in brain networks.

KW - Default mode network

KW - Interaction information

KW - Lifespan

KW - Redundancy

KW - Resting state

KW - Synergy

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DO - 10.3390/e20100786

M3 - Article

AN - SCOPUS:85055679004

SN - 1099-4300

VL - 20

JO - Entropy

JF - Entropy

IS - 10

M1 - 742

ER -

Interaction information along lifespan of the resting brain dynamics reveals a major redundant role of the default mode network

Abstract

Keywords

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