Correlated Firing Improves Stimulus Discrimination in a Retinal Model

Synchronous firing limits the amount of information that can be extracted by averaging the firing rates of similarly tuned neurons. Here, we show that the loss of such rate-coded information due to synchronous oscillations between retinal ganglion cells can be overcome by exploiting the information encoded by the correlations themselves. Two very different models, one based on axon-mediated inhibitory feedback and the other on oscillatory common input, were used to generate artificial spike trains whose synchronous oscillations were similar to those measured experimentally. Pooled spike trains were summed into a threshold detector whose output was classified using Bayesian discrimination. For a threshold detector with short summation times, realistic oscillatory input yielded superior discrimination of stimulus intensity compared to rate-matched Poisson controls. Even for summation times too long to resolve synchronous inputs, gamma band oscillations still contributed to improved discrimination by reducing the total spike count variability, or Fano factor. In separate experiments in which neurons were synchronized in a stimulus-dependent manner without attendant oscillations, the Fano factor increased markedly with stimulus intensity, implying that stimulus-dependent oscillations can offset the increased variability due to synchrony alone.

[1]  E. Fetz,et al.  Oscillatory activity in sensorimotor cortex of awake monkeys: synchronization of local field potentials and relation to behavior. , 1996, Journal of neurophysiology.

[2]  M A Freed,et al.  Rate of quantal excitation to a retinal ganglion cell evoked by sensory input. , 2000, Journal of neurophysiology.

[3]  Michael N. Shadlen,et al.  Noise, neural codes and cortical organization , 1994, Current Opinion in Neurobiology.

[4]  D. I. Vaney,et al.  Chapter 2 The mosaic of amacrine cells in the mammalian retina , 1990 .

[5]  E. Fetz,et al.  Synchronization of neurons during local field potential oscillations in sensorimotor cortex of awake monkeys. , 1996, Journal of neurophysiology.

[6]  A Kawana,et al.  Short- and long-range synchronous activities in dimming detectors of the frog retina , 1999, Visual Neuroscience.

[7]  J. Gallant,et al.  Goal-Related Activity in V4 during Free Viewing Visual Search Evidence for a Ventral Stream Visual Salience Map , 2003, Neuron.

[8]  R. Reid,et al.  Synaptic Interactions between Thalamic Inputs to Simple Cells in Cat Visual Cortex , 2000, The Journal of Neuroscience.

[9]  James Theiler,et al.  A model of high-frequency oscillatory potentials in retinal ganglion cells , 2003, Visual Neuroscience.

[10]  M. Verzeano,et al.  Periodic activity in the visual system of the cat. , 1967, Vision research.

[11]  W. Singer,et al.  Stimulus-specific neuronal oscillations in orientation columns of cat visual cortex. , 1989, Proceedings of the National Academy of Sciences of the United States of America.

[12]  M. H. Rowe,et al.  Linear and Nonlinear Contributions to Step Responses in Cat Retinal Ganglion Cells , 1996, Vision Research.

[13]  G. Buzsáki,et al.  Analysis of gamma rhythms in the rat hippocampus in vitro and in vivo. , 1996, The Journal of physiology.

[14]  R. H. Steinberg,et al.  Oscillatory activity in the optic tract of cat and light adaptation. , 1966, Journal of neurophysiology.

[15]  Malvin C. Teich Fractal character of the auditory neural spike train , 1989 .

[16]  Mark C. W. van Rossum,et al.  Effects of noise on the spike timing precision of retinal ganglion cells. , 2003, Journal of neurophysiology.

[17]  W. Singer,et al.  Stimulus-dependent synchronization of neuronal responses in the visual cortex of the awake macaque monkey , 1996, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[18]  D. P. Russell,et al.  Increased Synchronization of Neuromagnetic Responses during Conscious Perception , 1999, The Journal of Neuroscience.

[19]  W. Singer,et al.  Long-range synchronization of oscillatory light responses in the cat retina and lateral geniculate nucleus , 1996, Nature.

[20]  S. Laughlin,et al.  Predictive coding: a fresh view of inhibition in the retina , 1982, Proceedings of the Royal Society of London. Series B. Biological Sciences.

[21]  W. Singer,et al.  Oscillatory Neuronal Synchronization in Primary Visual Cortex as a Correlate of Stimulus Selection , 2002, The Journal of Neuroscience.

[22]  R. Reid,et al.  Specificity of monosynaptic connections from thalamus to visual cortex , 1995, Nature.

[23]  Walter G. Sannita,et al.  Stimulus- and Frequency-Specific Oscillatory Mass Responses to Visual Stimulation in Man , 2001, Clinical EEG.

[24]  W. Newsome,et al.  The Variable Discharge of Cortical Neurons: Implications for Connectivity, Computation, and Information Coding , 1998, The Journal of Neuroscience.

[25]  M. Shadlen,et al.  Limits to the temporal fidelity of cortical spike rate signals , 2002, Nature Neuroscience.

[26]  W. Singer,et al.  Dynamic predictions: Oscillations and synchrony in top–down processing , 2001, Nature Reviews Neuroscience.

[27]  Michael J. Berry,et al.  The Neural Code of the Retina , 1999, Neuron.

[28]  D. Mastronarde Correlated firing of retinal ganglion cells , 1989, Trends in Neurosciences.

[29]  Reid R. Clay,et al.  Specificity and strength of retinogeniculate connections. , 1999, Journal of neurophysiology.

[30]  David G. Stork,et al.  Pattern Classification , 1973 .

[31]  T. Shibasaki,et al.  Retinal ganglion cells act largely as independent encoders , 2001 .

[32]  Eberhard E. Fetz,et al.  Effects of Firing Synchrony on Signal Propagation in Layered Networks , 1989, NIPS.

[33]  Christoph Kayser,et al.  Effects of Training on Neuronal Activity and Interactions in Primary and Higher Visual Cortices in the Alert Cat , 2004, The Journal of Neuroscience.

[34]  J. Movshon,et al.  Spatial and temporal contrast sensitivity of neurones in areas 17 and 18 of the cat's visual cortex. , 1978, The Journal of physiology.

[35]  R. Reid,et al.  Precisely correlated firing in cells of the lateral geniculate nucleus , 1996, Nature.

[36]  P Sterling,et al.  Convergence and divergence of cones onto bipolar cells in the central area of cat retina. , 1990, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[37]  Yong Li,et al.  Effects of experimental glaucoma in macaques on the multifocal ERG , 2000, Documenta Ophthalmologica.

[38]  W. Singer,et al.  Synchronization of Visual Responses between the Cortex, Lateral Geniculate Nucleus, and Retina in the Anesthetized Cat , 1998, The Journal of Neuroscience.

[39]  W Singer,et al.  Visual feature integration and the temporal correlation hypothesis. , 1995, Annual review of neuroscience.

[40]  J. Dowling,et al.  The oscillatory potentials of the mudpuppy retina. , 1978, Investigative ophthalmology & visual science.

[41]  Eberhard E. Fetz,et al.  A general diffusion model for analyzing the efficacy of synaptic input to threshold neurons , 1992, Biological Cybernetics.

[42]  R. Desimone,et al.  Modulation of Oscillatory Neuronal Synchronization by Selective Visual Attention , 2001, Science.

[43]  Peter Dayan,et al.  The Effect of Correlated Variability on the Accuracy of a Population Code , 1999, Neural Computation.

[44]  M. Ariel,et al.  Rhythmicity in rabbit retinal ganglion cell responses , 1983, Vision Research.

[45]  C. Enroth-Cugell,et al.  Suppression of cat retinal ganglion cell responses by moving patterns. , 1980, The Journal of physiology.

[46]  W. Singer,et al.  Synchronous oscillations in the cat retina , 1999, Vision Research.

[47]  M. Livingstone Oscillatory firing and interneuronal correlations in squirrel monkey striate cortex. , 1996, Journal of neurophysiology.

[48]  B. Sakmann,et al.  Sensitivity distribution and spatial summation within receptive-field center of retinal on-center ganglion cells and transfer function of the retina. , 1970, Journal of neurophysiology.

[49]  W. Singer,et al.  Oscillatory responses in cat visual cortex exhibit inter-columnar synchronization which reflects global stimulus properties , 1989, Nature.