On null models for temporal small-worldness in brain dynamics

• Published in: Harvard data science review Vol. 8; no. 2; pp. 377 - 394
• Main Authors: Rossi, Aurora, Deslauriers-Gauthier, Samuel, Natale, Emanuele
• Format: Journal Article
• Language: English
• Published: United States MIT Press Journals, The 01.07.2024; MIT Press; The MIT Press
• Subjects: Brain; Brain mapping; Cognitive science; Computer Science; Functional magnetic resonance imaging; Hypotheses; Magnetic resonance imaging; Networks; Neuroimaging; Neuroscience; Small mammals; Statistical models; fMRI; Brain networks; Small-worldness; Null model; Temporal networks; Hyperbolic graph; Hyperbolic Graph; Null Model; Brain Networks; Temporal Networks
• ISSN: 2472-1751; 2472-1751; 2644-2353
• DOI: 10.1162/netn_a_00357

Brain dynamics can be modeled as a temporal brain network starting from the activity of different brain regions in functional magnetic resonance imaging (fMRI) signals. When validating hypotheses about temporal networks, it is important to use an appropriate statistical null model that shares some features with the treated empirical data. The purpose of this work is to contribute to the theory of temporal null models for brain networks by introducing the random temporal hyperbolic (RTH) graph model, an extension of the random hyperbolic (RH) graph, known in the study of complex networks for its ability to reproduce crucial properties of real-world networks. We focus on temporal small-worldness which, in the static case, has been extensively studied in real-world complex networks and has been linked to the ability of brain networks to efficiently exchange information. We compare the RTH graph model with standard null models for temporal networks and show it is the null model that best reproduces the small-worldness of resting brain activity. This ability to reproduce fundamental features of real brain networks, while adding only a single parameter compared with classical models, suggests that the RTH graph model is a promising tool for validating hypotheses about temporal brain networks.