RT Journal Article SR Electronic T1 A Maximum Entropy Model Applied to Spatial and Temporal Correlations from Cortical Networks In Vitro JF The Journal of Neuroscience JO J. Neurosci. FD Society for Neuroscience SP 505 OP 518 DO 10.1523/JNEUROSCI.3359-07.2008 VO 28 IS 2 A1 Aonan Tang A1 David Jackson A1 Jon Hobbs A1 Wei Chen A1 Jodi L. Smith A1 Hema Patel A1 Anita Prieto A1 Dumitru Petrusca A1 Matthew I. Grivich A1 Alexander Sher A1 Pawel Hottowy A1 Wladyslaw Dabrowski A1 Alan M. Litke A1 John M. Beggs YR 2008 UL http://www.jneurosci.org/content/28/2/505.abstract AB Multineuron firing patterns are often observed, yet are predicted to be rare by models that assume independent firing. To explain these correlated network states, two groups recently applied a second-order maximum entropy model that used only observed firing rates and pairwise interactions as parameters (Schneidman et al., 2006; Shlens et al., 2006). Interestingly, with these minimal assumptions they predicted 90–99% of network correlations. If generally applicable, this approach could vastly simplify analyses of complex networks. However, this initial work was done largely on retinal tissue, and its applicability to cortical circuits is mostly unknown. This work also did not address the temporal evolution of correlated states. To investigate these issues, we applied the model to multielectrode data containing spontaneous spikes or local field potentials from cortical slices and cultures. The model worked slightly less well in cortex than in retina, accounting for 88 ± 7% (mean ± SD) of network correlations. In addition, in 8 of 13 preparations, the observed sequences of correlated states were significantly longer than predicted by concatenating states from the model. This suggested that temporal dependencies are a common feature of cortical network activity, and should be considered in future models. We found a significant relationship between strong pairwise temporal correlations and observed sequence length, suggesting that pairwise temporal correlations may allow the model to be extended into the temporal domain. We conclude that although a second-order maximum entropy model successfully predicts correlated states in cortical networks, it should be extended to account for temporal correlations observed between states.