Functional Connectivity and Tuning Curves in Populations of Simultaneously Recorded Neurons

Ian H. Stevenson; Brian M. London; Emily R. Oby; Nicholas A. Sachs; Jacob Reimer; Bernhard Englitz; Stephen V. David; Shihab A. Shamma; Timothy J. Blanche; Kenji Mizuseki; Amin Zandvakili; Nicholas G. Hatsopoulos; Lee E. Miller; Konrad P. Kording

doi:10.1371/journal.pcbi.1002775

Functional Connectivity and Tuning Curves in Populations of Simultaneously Recorded Neurons

Ian H. Stevenson, Brian M. London, Emily R. Oby, Nicholas A. Sachs, Jacob Reimer, Bernhard Englitz, Stephen V. David, Shihab A. Shamma, Timothy J. Blanche, Kenji Mizuseki, Amin Zandvakili, Nicholas G. Hatsopoulos, Lee E. Miller, Konrad P. Kording

Otolaryngology

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Abstract

How interactions between neurons relate to tuned neural responses is a longstanding question in systems neuroscience. Here we use statistical modeling and simultaneous multi-electrode recordings to explore the relationship between these interactions and tuning curves in six different brain areas. We find that, in most cases, functional interactions between neurons provide an explanation of spiking that complements and, in some cases, surpasses the influence of canonical tuning curves. Modeling functional interactions improves both encoding and decoding accuracy by accounting for noise correlations and features of the external world that tuning curves fail to capture. In cortex, modeling coupling alone allows spikes to be predicted more accurately than tuning curve models based on external variables. These results suggest that statistical models of functional interactions between even relatively small numbers of neurons may provide a useful framework for examining neural coding.

Original language	English (US)
Article number	e1002775
Journal	PLoS computational biology
Volume	8
Issue number	11
DOIs	https://doi.org/10.1371/journal.pcbi.1002775
State	Published - Nov 2012

ASJC Scopus subject areas

Ecology, Evolution, Behavior and Systematics
Modeling and Simulation
Ecology
Molecular Biology
Genetics
Cellular and Molecular Neuroscience
Computational Theory and Mathematics

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Stevenson, I. H., London, B. M., Oby, E. R., Sachs, N. A., Reimer, J., Englitz, B., David, S. V., Shamma, S. A., Blanche, T. J., Mizuseki, K., Zandvakili, A., Hatsopoulos, N. G., Miller, L. E., & Kording, K. P. (2012). Functional Connectivity and Tuning Curves in Populations of Simultaneously Recorded Neurons. PLoS computational biology, 8(11), Article e1002775. https://doi.org/10.1371/journal.pcbi.1002775

Stevenson, IH, London, BM, Oby, ER, Sachs, NA, Reimer, J, Englitz, B, David, SV, Shamma, SA, Blanche, TJ, Mizuseki, K, Zandvakili, A, Hatsopoulos, NG, Miller, LE & Kording, KP 2012, 'Functional Connectivity and Tuning Curves in Populations of Simultaneously Recorded Neurons', PLoS computational biology, vol. 8, no. 11, e1002775. https://doi.org/10.1371/journal.pcbi.1002775

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abstract = "How interactions between neurons relate to tuned neural responses is a longstanding question in systems neuroscience. Here we use statistical modeling and simultaneous multi-electrode recordings to explore the relationship between these interactions and tuning curves in six different brain areas. We find that, in most cases, functional interactions between neurons provide an explanation of spiking that complements and, in some cases, surpasses the influence of canonical tuning curves. Modeling functional interactions improves both encoding and decoding accuracy by accounting for noise correlations and features of the external world that tuning curves fail to capture. In cortex, modeling coupling alone allows spikes to be predicted more accurately than tuning curve models based on external variables. These results suggest that statistical models of functional interactions between even relatively small numbers of neurons may provide a useful framework for examining neural coding.",

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Functional Connectivity and Tuning Curves in Populations of Simultaneously Recorded Neurons

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