nips nips2008 nips2008-45 nips2008-45-reference knowledge-graph by maker-knowledge-mining

45 nips-2008-Characterizing neural dependencies with copula models


Source: pdf

Author: Pietro Berkes, Frank Wood, Jonathan W. Pillow

Abstract: The coding of information by neural populations depends critically on the statistical dependencies between neuronal responses. However, there is no simple model that can simultaneously account for (1) marginal distributions over single-neuron spike counts that are discrete and non-negative; and (2) joint distributions over the responses of multiple neurons that are often strongly dependent. Here, we show that both marginal and joint properties of neural responses can be captured using copula models. Copulas are joint distributions that allow random variables with arbitrary marginals to be combined while incorporating arbitrary dependencies between them. Different copulas capture different kinds of dependencies, allowing for a richer and more detailed description of dependencies than traditional summary statistics, such as correlation coefficients. We explore a variety of copula models for joint neural response distributions, and derive an efficient maximum likelihood procedure for estimating them. We apply these models to neuronal data collected in macaque pre-motor cortex, and quantify the improvement in coding accuracy afforded by incorporating the dependency structure between pairs of neurons. We find that more than one third of neuron pairs shows dependency concentrated in the lower or upper tails for their firing rate distribution. 1


reference text

[1] R. Zemel, P. Dayan, and A. Pouget. Probabilistic interpretation of population codes. Neural Computation, 10:403–430, 1998.

[2] A. Pouget, K. Zhang, S. Deneve, and P.E. Latham. Statistically efficient estimation using population coding. Neural Computation, 10(2):373–401, 1998.

[3] L. Abbott and P. Dayan. The effect of correlated variability on the accuracy of a population code. Neural Computation, 11:91–101, 1999.

[4] E. Maynard, N. Hatsopoulos, C. Ojakangas, B. Acuna, J. Sanes, R. Normann, and J. Donoghue. Neuronal interactions improve cortical population coding of movement direction. Journal of Neuroscience, 19:8083–8093, 1999.

[5] E. Chornoboy, L. Schramm, and A. Karr. Maximum likelihood identification of neural point process systems. Biological Cybernetics, 59:265–275, 1988.

[6] W. Truccolo, U. T. Eden, M. R. Fellows, J. P. Donoghue, and E. N. Brown. A point process framework for relating neural spiking activity to spiking history, neural ensemble and extrinsic covariate effects. J. Neurophysiol, 93(2):1074–1089, 2004.

[7] M. Okatan, M. Wilson, and E. Brown. Analyzing functional connectivity using a network likelihood model of ensemble neural spiking activity. Neural Computation, 17:1927–1961, 2005.

[8] S. Gerwinn, J.H. Macke, M. Seeger, and M. Bethge. Bayesian inference for spiking neuron models with a sparsity prior. Advances in Neural Information Processing Systems, 2008.

[9] J. W. Pillow, J. Shlens, L. Paninski, A. Sher, A. M. Litke, and E. P. Chichilnisky, E. J. Simoncelli. Spatiotemporal correlations and visual signaling in a complete neuronal population. Nature, 454(7206):995– 999, 2008.

[10] E. Schneidman, M. Berry, R. Segev, and W. Bialek. Weak pairwise correlations imply strongly correlated network states in a neural population. Nature, 440:1007–1012, 2006.

[11] J. Shlens, G. Field, J. Gauthier, M. Grivich, D. Petrusca, A. Sher, Litke A. M., and E. J. Chichilnisky. The structure of multi-neuron firing patterns in primate retina. J Neurosci, 26:8254–8266, 2006.

[12] J.H. Macke, P. Berens, A.S. Ecker, A.S. Tolias, and M. Bethge. Generating spike trains with specified correlation coefficients. Neural Computation, 21(2), 2009.

[13] H. Joe. Multivariate models and dependence concepts. Chapman & Hall, London, 1997.

[14] R.B. Nelsen. An introduction to copulas. Springer, New York, 2nd edition, 2006.

[15] A. Sklar. Fonctions de répartition à n dimensions et leurs marges. Publ. Inst. Statist. Univ. Paris, 8:229– 231, 1959.

[16] R.L. Jenison and R.A. Reale. The shape of neural dependence. Neural Computation, 16(4):665–672, 2004.

[17] C. Genest and J. Neslehova. A primer on copulas for count data. Astin Bulletin, 37(2):475–515, 2007.

[18] M. Serruya, N. Hatsopoulos, L. Paninski, M. Fellows, and J. Donoghue. Instant neural control of a movement signal. Nature, 416:141–142, 2002.

[19] S. Suner, MR Fellows, C. Vargas-Irwin, GK Nakata, and JP Donoghue. Reliability of signals from a chronically implanted, silicon-based electrode array in non-human primate primary motor cortex. Neural Systems and Rehabilitation Engineering, IEEE Transactions on, 13(4):524–541, 2005.

[20] S. Kirshner. Learning with tree-averaged densities and distributions. NIPS, 20, 2008.

[21] E. P. Simoncelli, L. Paninski, J. Pillow, and O. Schwartz. Characterization of neural responses with stochastic stimuli. In M. Gazzaniga, editor, The Cognitive Neurosciences, pages 327–338. MIT Press, 3rd edition, 2004. 8