A Morphospace of Functional Configuration to Assess Configural Breadth Based on Brain Functional Networks

Overview

Journal Netw Neurosci

Publisher MIT Press

Specialty Neurology

Date 2021 Nov 8

PMID 34746622

Citations 7

Authors

Duy Duong-Tran

Kausar Abbas

Enrico Amico

Bernat Corominas-Murtra

Mario Dzemidzic

David Kareken

Mario Ventresca

Joaquin Goni

Affiliations

Soon will be listed here.

Abstract

The quantification of human brain functional (re)configurations across varying cognitive demands remains an unresolved topic. We propose that such functional configurations may be categorized into three different types: (a) network configural breadth, (b) task-to task transitional reconfiguration, and (c) within-task reconfiguration. Such functional reconfigurations are rather subtle at the whole-brain level. Hence, we propose a mesoscopic framework focused on functional networks (FNs) or communities to quantify functional (re)configurations. To do so, we introduce a 2D network morphospace that relies on two novel mesoscopic metrics, trapping efficiency (TE) and exit entropy (EE), which capture topology and integration of information within and between a reference set of FNs. We use this framework to quantify the network configural breadth across different tasks. We show that the metrics defining this morphospace can differentiate FNs, cognitive tasks, and subjects. We also show that network configural breadth significantly predicts behavioral measures, such as episodic memory, verbal episodic memory, fluid intelligence, and general intelligence. In essence, we put forth a framework to explore the cognitive space in a comprehensive manner, for each individual separately, and at different levels of granularity. This tool that can also quantify the FN reconfigurations that result from the brain switching between mental states.

Citing Articles

Volume-optimal persistence homological scaffolds of hemodynamic networks covary with MEG theta-alpha aperiodic dynamics.

Nguyen N, Hou T, Amico E, Zheng J, Huang H, Kaplan A Med Image Comput Comput Assist Interv. 2025; 15003:519-529.

PMID: 39949393 PMC: 11816146. DOI: 10.1007/978-3-031-72384-1_49.

Causality-based Subject and Task Fingerprints using fMRI Time-series Data.

Song D, Shen L, Duong-Tran D, Wang X ACM BCB. 2025; 2024.

PMID: 39897336 PMC: 11786950. DOI: 10.1145/3698587.3701342.

PRESERVING HUMAN LARGE-SCALE BRAIN CONNECTIVITY FINGERPRINT IDENTIFIABILITY WITH RANDOM PROJECTIONS.

Duong-Tran D, Magsino M, Goni J, Shen L Proc IEEE Int Symp Biomed Imaging. 2024; 2024.

PMID: 39371470 PMC: 11452154. DOI: 10.1109/isbi56570.2024.10635372.

Volume-optimal persistence homological scaffolds of hemodynamic networks covary with MEG theta-alpha aperiodic dynamics.

Nguyen N, Hou T, Amico E, Zheng J, Huang H, Kaplan A ArXiv. 2024; .

PMID: 39108288 PMC: 11302673.

Tangent space functional reconfigurations in individuals at risk for alcohol use disorder.

Moghaddam M, Dzemidzic M, Guerrero D, Liu M, Alessi J, Plawecki M ArXiv. 2024; .

PMID: 38827458 PMC: 11142326.

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