Open AccessMultiscale Autoregressive Identification of Neuroelectrophysiological Systems
Author(s) -
Timothy P. Gilmour,
Thyagarajan Subramanian,
Constantino Lagoa,
W.K. Jenkins
Publication year - 2012
Publication title -
computational and mathematical methods in medicine
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.462
H-Index - 48
eISSN - 1748-6718
pISSN - 1748-670X
DOI - 10.1155/2012/580795
Subject(s) - autoregressive model , predictability , computer science , noise (video) , parametric model , parametric statistics , model selection , identification (biology) , selection (genetic algorithm) , signal (programming language) , pattern recognition (psychology) , artificial intelligence , biological system , mathematics , statistics , biology , image (mathematics) , programming language , botany
Electrical signals between connected neural nuclei are difficult to model because of the complexity and high number of paths within the brain. Simple parametric models are therefore often used. A multiscale version of the autoregressive with exogenous input (MS-ARX) model has recently been developed which allows selection of the optimal amount of filtering and decimation depending on the signal-to-noise ratio and degree of predictability. In this paper, we apply the MS-ARX model to cortical electroencephalograms and subthalamic local field potentials simultaneously recorded from anesthetized rodent brains. We demonstrate that the MS-ARX model produces better predictions than traditional ARX modeling. We also adapt the MS-ARX results to show differences in internuclei predictability between normal rats and rats with 6OHDA-induced parkinsonism, indicating that this method may have broad applicability to other neuroelectrophysiological studies.
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