TY - JOUR
T1 - Perturbation of whole-brain dynamics in silico reveals mechanistic differences between brain states
AU - Deco, Gustavo
AU - Cabral, Joana
AU - Saenger, Victor M.
AU - Boly, Melanie
AU - Tagliazucchi, Enzo
AU - Laufs, Helmut
AU - Van Someren, Eus
AU - Jobst, Beatrice
AU - Stevner, Angus
AU - Kringelbach, Morten L.
N1 - Publisher Copyright:
© 2017
PY - 2018/4/1
Y1 - 2018/4/1
N2 - Human neuroimaging research has revealed that wakefulness and sleep involve very different activity patterns. Yet, it is not clear why brain states differ in their dynamical complexity, e.g. in the level of integration and segregation across brain networks over time. Here, we investigate the mechanisms underlying the dynamical stability of brain states using a novel off-line in silico perturbation protocol. We first adjust a whole-brain computational model to the basal dynamics of wakefulness and deep sleep recorded with fMRI in two independent human fMRI datasets. Then, the models of sleep and awake brain states are perturbed using two distinct multifocal protocols either promoting or disrupting synchronization in randomly selected brain areas. Once perturbation is halted, we use a novel measure, the Perturbative Integration Latency Index (PILI), to evaluate the recovery back to baseline. We find a clear distinction between models, consistently showing larger PILI in wakefulness than in deep sleep, corroborating previous experimental findings. In the models, larger recoveries are associated to a critical slowing down induced by a shift in the model's operation point, indicating that the awake brain operates further from a stable equilibrium than deep sleep. This novel approach opens up for a new level of artificial perturbative studies unconstrained by ethical limitations allowing for a deeper investigation of the dynamical properties of different brain states.
AB - Human neuroimaging research has revealed that wakefulness and sleep involve very different activity patterns. Yet, it is not clear why brain states differ in their dynamical complexity, e.g. in the level of integration and segregation across brain networks over time. Here, we investigate the mechanisms underlying the dynamical stability of brain states using a novel off-line in silico perturbation protocol. We first adjust a whole-brain computational model to the basal dynamics of wakefulness and deep sleep recorded with fMRI in two independent human fMRI datasets. Then, the models of sleep and awake brain states are perturbed using two distinct multifocal protocols either promoting or disrupting synchronization in randomly selected brain areas. Once perturbation is halted, we use a novel measure, the Perturbative Integration Latency Index (PILI), to evaluate the recovery back to baseline. We find a clear distinction between models, consistently showing larger PILI in wakefulness than in deep sleep, corroborating previous experimental findings. In the models, larger recoveries are associated to a critical slowing down induced by a shift in the model's operation point, indicating that the awake brain operates further from a stable equilibrium than deep sleep. This novel approach opens up for a new level of artificial perturbative studies unconstrained by ethical limitations allowing for a deeper investigation of the dynamical properties of different brain states.
KW - Brain state
KW - Perturbation
KW - Sleep
KW - Whole brain modeling
UR - http://www.scopus.com/inward/record.url?scp=85037692961&partnerID=8YFLogxK
U2 - 10.1016/j.neuroimage.2017.12.009
DO - 10.1016/j.neuroimage.2017.12.009
M3 - Article
C2 - 29225066
AN - SCOPUS:85037692961
SN - 1053-8119
VL - 169
SP - 46
EP - 56
JO - NeuroImage
JF - NeuroImage
ER -