| Literature DB >> 32469053 |
Dominic Standage1, Corson N Areshenkoff2,3, Joseph Y Nashed2, R Matthew Hutchison4, Melina Hutchison5, Dietmar Heinke1, Ravi S Menon6, Stefan Everling6,7, Jason P Gallivan2,3,8.
Abstract
General anesthetics are routinely used to induce unconsciousness, and much is known about their effects on receptor function and single neuron activity. Much less is known about how these local effects are manifest at the whole-brain level nor how they influence network dynamics, especially past the point of induced unconsciousness. Using resting-state functional magnetic resonance imaging (fMRI) with nonhuman primates, we investigated the dose-dependent effects of anesthesia on whole-brain temporal modular structure, following loss of consciousness. We found that higher isoflurane dose was associated with an increase in both the number and isolation of whole-brain modules, as well as an increase in the uncoordinated movement of brain regions between those modules. Conversely, we found that higher dose was associated with a decrease in the cohesive movement of brain regions between modules, as well as a decrease in the proportion of modules in which brain regions participated. Moreover, higher dose was associated with a decrease in the overall integrity of networks derived from the temporal modules, with the exception of a single, sensory-motor network. Together, these findings suggest that anesthesia-induced unconsciousness results from the hierarchical fragmentation of dynamic whole-brain network structure, leading to the discoordination of temporal interactions between cortical modules.Entities:
Keywords: anesthesia; connectivity; consciousness; isoflurane; resting-state functional MRI; unconsciousnesswhole-brain dynamics
Year: 2020 PMID: 32469053 PMCID: PMC7472202 DOI: 10.1093/cercor/bhaa085
Source DB: PubMed Journal: Cereb Cortex ISSN: 1047-3211 Impact factor: 5.357