TY - JOUR
T1 - Adaptive frequency-based modeling of whole-brain oscillations
T2 - Predicting regional vulnerability and hazardousness rates
AU - Kaboodvand, Neda
AU - van den Heuvel, Martijn P.
AU - Fransson, Peter
PY - 2019/10
Y1 - 2019/10
N2 - Whole-brain computational modeling based on structural connectivity has shown great promise in successfully simulating fMRI BOLD signals with temporal coactivation patterns that are highly similar to empirical functional connectivity patterns during resting state. Importantly, previous studies have shown that spontaneous fluctuations in coactivation patterns of distributed brain regions have an inherent dynamic nature with regard to the frequency spectrum of intrinsic brain oscillations. In this modeling study, we introduced frequency dynamics into a system of coupled oscillators, where each oscillator represents the local mean-field model of a brain region. We first showed that the collective behavior of interacting oscillators reproduces previously shown features of brain dynamics. Second, we examined the effect of simulated lesions in gray matter by applying an in silico perturbation protocol to the brain model. We present a new approach to map the effects of vulnerability in brain networks and introduce a measure of regional hazardousness based on mapping of the degree of divergence in a feature space.
AB - Whole-brain computational modeling based on structural connectivity has shown great promise in successfully simulating fMRI BOLD signals with temporal coactivation patterns that are highly similar to empirical functional connectivity patterns during resting state. Importantly, previous studies have shown that spontaneous fluctuations in coactivation patterns of distributed brain regions have an inherent dynamic nature with regard to the frequency spectrum of intrinsic brain oscillations. In this modeling study, we introduced frequency dynamics into a system of coupled oscillators, where each oscillator represents the local mean-field model of a brain region. We first showed that the collective behavior of interacting oscillators reproduces previously shown features of brain dynamics. Second, we examined the effect of simulated lesions in gray matter by applying an in silico perturbation protocol to the brain model. We present a new approach to map the effects of vulnerability in brain networks and introduce a measure of regional hazardousness based on mapping of the degree of divergence in a feature space.
KW - Adaptive frequency
KW - Dynamical systems
KW - In silico perturbation
KW - Resting-state fMRI
KW - Vulnerability
KW - Whole-brain network modeling
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UR - https://www.ncbi.nlm.nih.gov/pubmed/31637340
U2 - https://doi.org/10.1162/netn_a_00104
DO - https://doi.org/10.1162/netn_a_00104
M3 - Article
C2 - 31637340
SN - 2472-1751
VL - 3
SP - 1094
EP - 1120
JO - Network Neuroscience
JF - Network Neuroscience
IS - 4
ER -