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How anatomy shapes dynamics: a semi-analytical study of the brain at rest by a simple spin model

Journal article

G. Deco, M. Senden, Viktor Jirsa
Frontiers in Computational Neuroscience, 2012
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APA   Click to copy
Deco, G., Senden, M., & Jirsa, V. (2012). How anatomy shapes dynamics: a semi-analytical study of the brain at rest by a simple spin model. Frontiers in Computational Neuroscience.

Chicago/Turabian   Click to copy
Deco, G., M. Senden, and Viktor Jirsa. “How Anatomy Shapes Dynamics: a Semi-Analytical Study of the Brain at Rest by a Simple Spin Model.” Frontiers in Computational Neuroscience (2012).

MLA   Click to copy
Deco, G., et al. “How Anatomy Shapes Dynamics: a Semi-Analytical Study of the Brain at Rest by a Simple Spin Model.” Frontiers in Computational Neuroscience, 2012.

BibTeX   Click to copy 

@article{g2012a,
  title = {How anatomy shapes dynamics: a semi-analytical study of the brain at rest by a simple spin model},
  year = {2012},
  journal = {Frontiers in Computational Neuroscience},
  author = {Deco, G. and Senden, M. and Jirsa, Viktor}
}

Abstract

Resting state networks (RSNs) show a surprisingly coherent and robust spatiotemporal organization. Previous theoretical studies demonstrated that these patterns can be understood as emergent on the basis of the underlying neuroanatomical connectivity skeleton. Integrating the biologically realistic DTI/DSI-(Diffusion Tensor Imaging/Diffusion Spectrum Imaging)based neuroanatomical connectivity into a brain model of Ising spin dynamics, we found a system with multiple attractors, which can be studied analytically. The multistable attractor landscape thus defines a functionally meaningful dynamic repertoire of the brain network that is inherently present in the neuroanatomical connectivity. We demonstrate that the more entropy of attractors exists, the richer is the dynamical repertoire and consequently the brain network displays more capabilities of computation. We hypothesize therefore that human brain connectivity developed a scale free type of architecture in order to be able to store a large number of different and flexibly accessible brain functions.