Coding of time-varying signals in spike trains of linear and half-wave rectifying neurons

1. The coding of time-varying electric fields in the weakly electric fish, Eigenmannia, was investigated in a quantitative manner. The activity of single P-type electroreceptor afferents was recorded while the amplitude of an externally applied sinusoidal electric field was stochastically modulated. The amplitude modulation waveform (i.e., the stimulus) was reconstructed from the spike trains by mean square estimation. 2. From the stimulus and the reconstructions we calculated the following: 1) the signal-to-noise ratio and thus an effective temporal bandwidth of the units; 2) the coding fraction, i.e., a measure of the fraction of the time-varying stimulus encoded in single spike trains; and 3) the mutual information provided by the reconstructions about the stimulus. 3. Signal-to-noise ratios as high as 7:1 were observed and the bandwidth ranged from 0 up to 200 Hz, consistent with the limit imposed by the sampling theorem. Reducing the cutoff frequency of the stimulus increased the signal-to-noise ratio at low frequencies, indicating a nonlinearity in the receptors' response. 4. The coding fraction and the rate of mutual information transmission increased in parallel with the standard deviation (i.e., the contrast) of the stimulus as well as the mean firing rate of the units. Significant encoding occurred 20-40 Hz above the spontaneous discharge of a unit. 5. When the temporal cutoff frequency of the stimulus was increased between 80 and 400 Hz, 1) the coding fraction decreased, 2) the rate of mutual information transmission remained constant over the same frequency range, and 3) the reconstructed filter changed. This is in agreement with predictions obtained in a simplified neuronal model. 6. Our results suggest that 1) the information transmitted by single spike trains of primary electrosensory afferents to higherorder neurons in the fish brain depends on the contrast and the cutoff frequency of the stimulus as well as on the mean firing rate of the units; and 2) under optimal conditions, more than half of the information about a Gaussian stimulus that can in principle be encoded is carried in single spike trains of P-type afferents at rates up to 200 bits per second.

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Propagation of Electromagnetic Waves Excited by Half-Wave Dipole Antenna in Time-Varying Media

2005 IEEE International Symposium on Microwave, Antenna, Propagation and EMC Technologies for Wireless Communications ◽

10.1109/mape.2005.1617913 ◽

2006 ◽

Author(s):

Ying Zhang ◽

Bing-kang Chen ◽

Ben-qing Gao

Keyword(s):

Electromagnetic Waves ◽

Dipole Antenna ◽

Time Varying ◽

Half Wave

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Modeling Population Spike Trains with Specified Time-Varying Spike Rates, Trial-to-Trial Variability, and Pairwise Signal and Noise Correlations

Frontiers in Computational Neuroscience ◽

10.3389/fncom.2010.00144 ◽

2010 ◽

Vol 4 ◽

Cited By ~ 7

Author(s):

Dmitry R. Lyamzin ◽

Jakob H. Macke ◽

Nicholas A. Lesica

Keyword(s):

Spike Trains ◽

Population Spike ◽

Time Varying

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Spike Train Probability Models for Stimulus-Driven Leaky Integrate-and-Fire Neurons

Neural Computation ◽

10.1162/neco.2008.06-07-540 ◽

2008 ◽

Vol 20 (7) ◽

pp. 1776-1795 ◽

Cited By ~ 12

Author(s):

Shinsuke Koyama ◽

Robert E. Kass

Keyword(s):

Spike Train ◽

Point Process ◽

Renewal Process ◽

Spike Trains ◽

Process Models ◽

Time Varying ◽

Integrate And Fire ◽

Lack Of Fit ◽

Point Process Models ◽

Spike Train Data

Mathematical models of neurons are widely used to improve understanding of neuronal spiking behavior. These models can produce artificial spike trains that resemble actual spike train data in important ways, but they are not very easy to apply to the analysis of spike train data. Instead, statistical methods based on point process models of spike trains provide a wide range of data-analytical techniques. Two simplified point process models have been introduced in the literature: the time-rescaled renewal process (TRRP) and the multiplicative inhomogeneous Markov interval (m-IMI) model. In this letter we investigate the extent to which the TRRP and m-IMI models are able to fit spike trains produced by stimulus-driven leaky integrate-and-fire (LIF) neurons. With a constant stimulus, the LIF spike train is a renewal process, and the m-IMI and TRRP models will describe accurately the LIF spike train variability. With a time-varying stimulus, the probability of spiking under all three of these models depends on both the experimental clock time relative to the stimulus and the time since the previous spike, but it does so differently for the LIF, m-IMI, and TRRP models. We assessed the distance between the LIF model and each of the two empirical models in the presence of a time-varying stimulus. We found that while lack of fit of a Poisson model to LIF spike train data can be evident even in small samples, the m-IMI and TRRP models tend to fit well, and much larger samples are required before there is statistical evidence of lack of fit of the m-IMI or TRRP models. We also found that when the mean of the stimulus varies across time, the m-IMI model provides a better fit to the LIF data than the TRRP, and when the variance of the stimulus varies across time, the TRRP provides the better fit.

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Harmonics added to a flickering light can upset the balance between ON and OFF pathways to produce illusory colors

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1717356115 ◽

2018 ◽

Vol 115 (17) ◽

pp. E4081-E4090 ◽

Cited By ~ 2

Author(s):

Andrew T. Rider ◽

G. Bruce Henning ◽

Rhea T. Eskew ◽

Andrew Stockman

Keyword(s):

Visual Pathways ◽

Human Vision ◽

Perceptual Quality ◽

Time Varying ◽

Neural Signals ◽

Color Processing ◽

Retinal Photoreceptor ◽

Half Wave ◽

On And Off Pathways ◽

The Brain

The neural signals generated by the light-sensitive photoreceptors in the human eye are substantially processed and recoded in the retina before being transmitted to the brain via the optic nerve. A key aspect of this recoding is the splitting of the signals within the two major cone-driven visual pathways into distinct ON and OFF branches that transmit information about increases and decreases in the neural signal around its mean level. While this separation is clearly important physiologically, its effect on perception is unclear. We have developed a model of the ON and OFF pathways in early color processing. Using this model as a guide, we can produce imbalances in the ON and OFF pathways by changing the shapes of time-varying stimulus waveforms and thus make reliable and predictable alterations to the perceived average color of the stimulus—although the physical mean of the waveforms does not change. The key components in the model are the early half-wave rectifying synapses that split retinal photoreceptor outputs into the ON and OFF pathways and later sigmoidal nonlinearities in each pathway. The ability to systematically vary the waveforms to change a perceptual quality by changing the balance of signals between the ON and OFF visual pathways provides a powerful psychophysical tool for disentangling and investigating the neural workings of human vision.

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Response variability and information transfer in directional neurons of the mammalian horizontal optokinetic system

Visual Neuroscience ◽

10.1017/s0952523800172037 ◽

2000 ◽

Vol 17 (2) ◽

pp. 207-215 ◽

Cited By ~ 6

Author(s):

COLIN W.G. CLIFFORD ◽

MICHAEL R. IBBOTSON

Keyword(s):

Refractory Period ◽

Information Transfer ◽

Visual Motion ◽

Optic Tract ◽

Poisson Model ◽

Spike Trains ◽

Response Variability ◽

Time Varying ◽

Neuronal Responses ◽

Optokinetic System

This study is concerned with how information about the direction of visual motion is encoded by motion-sensitive neurons. Motion-sensitive neurons are usually studied using stimuli unchanging in speed and direction over several seconds. Recently, it has been suggested that neuronal responses to more naturalistic stimuli cannot be understood on the basis of experiments with constant-motion stimuli (de Ruyter van Steveninck et al., 1997). We measured the variability and information content of spike trains recorded from directional neurons in the nucleus of the optic tract (NOT) of the wallaby, Macropus eugenii, in response to constant and time-varying motion. While the NOT forms part of the mammalian optokinetic system, we have shown previously that the responses of its directional neurons resemble those of insect H1 in many respects (Ibbotson et al., 1994). We find that directional neurons in the wallaby NOT respond with lower variability and higher rates of information transmission to time-varying stimuli than to constant motion. The difference in response variability is predicted by an inhomogeneous Poisson model of neuronal spiking incorporating an absolute refractory period of 2 ms during which no subsequent spike can be fired. Refractoriness imposes structure on the spike train, reducing variability (de Ruyter van Steveninck & Bialek, 1988; Berry & Meister, 1998). A given refractory period has a greater impact when firing rates are high, as for the responses of NOT neurons to time-varying stimuli. It is in just these cases that variability in experimentally observed spike trains is lowest. Thus, differences in response variability do not necessarily imply that different models are required to predict neuronal responses to constant- and time-varying motion stimuli.

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