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Lookup NU author(s): Professor Marcus Kaiser
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The study of dynamical systems defined on complex networks provides a natural framework with which to investigate myriad features of neural dynamics and has been widely undertaken. Typically, however, networks employed in theoretical studies bear little relation to the spatial embedding or connectivity of the neural networks that they attempt to replicate. Here, we employ detailed neuroimaging data to define a network whose spatial embedding represents accurately the folded structure of the cortical surface of a rat brain and investigate the propagation of activity over this network under simple spreading and connectivity rules. By comparison with standard network models with the same coarse statistics, we show that the cortical geometry influences profoundly the speed of propagation of activation through the network. Our conclusions are of high relevance to the theoretical modelling of epileptic seizure events and indicate that such studies which omit physiological network structure risk simplifying the dynamics in a potentially significant way.
Author(s): O'Dea R, Crofts JJ, Kaiser M
Publication type: Article
Publication status: Published
Journal: Journal of the Royal Society Interface
Year: 2013
Volume: 10
Issue: 81
Print publication date: 13/02/2013
ISSN (print): 1742-5689
ISSN (electronic): 1742-5662
Publisher: The Royal Society Publishing
URL: http://dx.doi.org/10.1098/rsif.2013.0016
DOI: 10.1098/rsif.2013.0016
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