Inputs from single neurons in the visual cortex affect spike-timing of locally connected neurons but do not modulate their firing rate and sensory tuning curves

Computational studies are challenging the intuitive view that neurons with broad tuning curves are necessarily less discriminative than neurons with sharp tuning curves. In the context of somatosensory processing, broad tuning curves are equivalent to large receptive fields. To clarify the computational role of large receptive fields for cortical processing of somatosensory information, we recorded ensembles of single neurons from the infragranular forelimb/forepaw region of the rat primary somatosensory cortex while tactile stimuli were separately delivered to different locations on the forelimbs/forepaws under light anesthesia. We specifically adopted the perspective of individual columns/segregates receiving inputs from multiple body location. Using single-trial analyses of many single-neuron responses, we obtained two main results. 1) The responses of even small populations of neurons recorded from within the same estimated column/segregate can be used to discriminate between stimuli delivered to different surround locations in the excitatory receptive fields. 2) The temporal precision of surround responses is sufficiently high for spike timing to add information over spike count in the discrimination between surround locations. This surround spike-timing code (i) is particularly informative when spike count is ambiguous, e.g., in the discrimination between close locations or when receptive fields are large, (ii) becomes progressively more informative as the number of neurons increases, (iii) is a first-spike code, and (iv) is not limited by the assumption that the time of stimulus onset is known. These results suggest that even though large receptive fields result in a loss of spatial selectivity of single neurons, they can provide as a counterpart a sophisticated temporal code based on latency differences in large populations of neurons without necessarily sacrificing basic information about stimulus location.

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Sub-Optimality of the Early Visual System Explained Through Biologically Plausible Plasticity

Frontiers in Neuroscience ◽

10.3389/fnins.2021.727448 ◽

2021 ◽

Vol 15 ◽

Author(s):

Tushar Chauhan ◽

Timothée Masquelier ◽

Benoit R. Cottereau

Keyword(s):

Visual Cortex ◽

Primary Visual Cortex ◽

Receptive Fields ◽

Spike Timing ◽

Orientation Tuning ◽

Biologically Relevant ◽

Tuning Curves ◽

Stdp Rule ◽

Early Visual Cortex ◽

Minimisation Problem

The early visual cortex is the site of crucial pre-processing for more complex, biologically relevant computations that drive perception and, ultimately, behaviour. This pre-processing is often studied under the assumption that neural populations are optimised for the most efficient (in terms of energy, information, spikes, etc.) representation of natural statistics. Normative models such as Independent Component Analysis (ICA) and Sparse Coding (SC) consider the phenomenon as a generative, minimisation problem which they assume the early cortical populations have evolved to solve. However, measurements in monkey and cat suggest that receptive fields (RFs) in the primary visual cortex are often noisy, blobby, and symmetrical, making them sub-optimal for operations such as edge-detection. We propose that this suboptimality occurs because the RFs do not emerge through a global minimisation of generative error, but through locally operating biological mechanisms such as spike-timing dependent plasticity (STDP). Using a network endowed with an abstract, rank-based STDP rule, we show that the shape and orientation tuning of the converged units are remarkably close to single-cell measurements in the macaque primary visual cortex. We quantify this similarity using physiological parameters (frequency-normalised spread vectors), information theoretic measures [Kullback–Leibler (KL) divergence and Gini index], as well as simulations of a typical electrophysiology experiment designed to estimate orientation tuning curves. Taken together, our results suggest that compared to purely generative schemes, process-based biophysical models may offer a better description of the suboptimality observed in the early visual cortex.

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Information encoding in short firing rate epochs by single neurons in the primate temporal visual cortex

Visual Cognition ◽

10.1080/13506289508401721 ◽

1995 ◽

Vol 2 (1) ◽

pp. 35-58 ◽

Cited By ~ 57

Author(s):

Martin J. Tovee ◽

Edmund T. Rolls

Keyword(s):

Visual Cortex ◽

Firing Rate ◽

Single Neurons ◽

Information Encoding

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Excitatory Convergence of Y and Non-Y Information Channels on Single Neurons in the PMLS Area, a Motion Area of the Cat Visual Cortex

European Journal of Neuroscience ◽

10.1111/j.1460-9568.1997.tb01443.x ◽

1997 ◽

Vol 9 (5) ◽

pp. 921-933 ◽

Cited By ~ 8

Author(s):

C. Wang ◽

B. Dreher ◽

K. R. Huxlin ◽

W. Burke

Keyword(s):

Visual Cortex ◽

Single Neurons ◽

Cat Visual Cortex ◽

Information Channels

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Single neurons are differently involved in stimulus-specific oscillations in cat visual cortex

Experimental Brain Research ◽

10.1007/bf00229667 ◽

1993 ◽

Vol 95 (1) ◽

Cited By ~ 47

Author(s):

R. Eckhorn ◽

A. Obermueller

Keyword(s):

Visual Cortex ◽

Single Neurons ◽

Cat Visual Cortex

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A model for the estimate of local image velocity by cells in the visual cortex

Proceedings of the Royal Society of London Series B Biological Sciences ◽

10.1098/rspb.1990.0012 ◽

1990 ◽

Vol 239 (1295) ◽

pp. 129-161 ◽

Cited By ~ 129

Keyword(s):

Visual Cortex ◽

Primary Visual Cortex ◽

Frequency Tuning ◽

Temporal Frequency ◽

Spatial Integration ◽

Temporal Area ◽

Image Velocity ◽

Tuning Curves ◽

Spatio Temporal ◽

Local Image

Some computational theories of motion perception assume that the first stage en route to this perception is the local estimate of image velocity. However, this assumption is not supported by data from the primary visual cortex. Its motion sensitive cells are not selective to velocity, but rather are directionally selective and tuned to spatio-temporal frequencies. Accordingly, physiologically based theories start with filters selective to oriented spatio-temporal frequencies. This paper shows that computational and physiological theories do not necessarily conflict, because such filters may, as a population, compute velocity locally. To prove this point, we show how to combine the outputs of a class of frequency tuned filters to detect local image velocity. Furthermore, we show that the combination of filters may simulate ‘Pattern’ cells in the middle temporal area (MT), whereas each filter simulates primary visual cortex cells. These simulations include three properties of the primary cortex. First, the spatio-temporal frequency tuning curves of the individual filters display approximate space-time separability. Secondly, their direction-of-motion tuning curves depend on the distribution of orientations of the components of the Fourier decomposition and speed of the stimulus. Thirdly, the filters show facilitation and suppression for responses to apparent motions in the preferred and null directions, respectively. It is suggested that the MT’s role is not to solve the aperture problem, but to estimate velocities from primary cortex information. The spatial integration that accounts for motion coherence may be postponed to a later cortical stage.

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Effect of longer periods of dark rearing on NMDA receptors in cat visual cortex

Journal of Neurophysiology ◽

10.1152/jn.1994.72.3.1220 ◽

1994 ◽

Vol 72 (3) ◽

pp. 1220-1226 ◽

Cited By ~ 21

Author(s):

D. Czepita ◽

S. N. Reid ◽

N. W. Daw

Keyword(s):

Visual Cortex ◽

Nmda Receptor ◽

Firing Rate ◽

Spontaneous Activity ◽

Visual Response ◽

Visual Responses ◽

Level Of Activity ◽

Direction Of Movement ◽

Excitatory Drive ◽

Dark Rearing

1. Cats were reared in the dark to 3, 5, and 11 mo. We studied the N-methyl-D-aspartate (NMDA) receptor contribution to the visual response in the cortex, defined as the percentage reduction in visual response after application of 2-amino-5-phosphonovaleric acid (APV). We also studied the firing rate in response to the optimal visual stimulus and the spontaneous activity. We made comparisons of all these properties between light-reared and dark-reared animals. 2. The NMDA receptor contribution to the visual response in layers IV, V, and VI of dark-reared animals was substantially above that in light-reared animals at all ages tested. 3. The specificity of receptive field properties in dark-reared animals showed some degeneration between 6 wk and 3 mo of age. At > or = 3 mo, almost no cells were specific for orientation and direction of movement. 4. Firing rate was lower in dark-reared animals at all ages, suggesting a decrease in excitatory drive to the visual cortex. 5. Spontaneous activity was equal in dark- and light-reared animals, suggesting that the overall level of activity (including visual responses as well as spontaneous activity) in light-reared animals is higher than in dark-reared animals. This should tend to upregulate glutamate receptors in general in dark-reared animals.

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A Stereoscopic Look at Visual Cortex

Journal of Neurophysiology ◽

10.1152/jn.01068.2004 ◽

2005 ◽

Vol 93 (4) ◽

pp. 1823-1826 ◽

Cited By ~ 48

Author(s):

Peter Neri

Keyword(s):

Visual Cortex ◽

Perceptual Experience ◽

Binocular Disparity ◽

Advanced Stage ◽

Single Neurons ◽

Previous Evidence ◽

Mt Neurons ◽

Visual Areas ◽

V4 Neurons ◽

New Framework

Three recent studies offer new insights into the way visual cortex handles binocular disparity signals. Two of these studies recorded from single neurons in two different visual areas of the monkey brain, one (V5/MT) in dorsal and one (V4) in ventral cortex. While V5/MT neurons respond similarly to neurons in primary visual cortex (V1), V4 neurons appear to reflect a more advanced stage in the analysis of retinal disparity, closer to the perceptual experience of stereoscopic depth. Both studies are consistent with a third study using fMRI to address similar questions in humans. Together with previous evidence, these results suggest a new framework for understanding stereoscopic processing based on the separation between ventral and dorsal streams in visual cortex.

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Neurons in the mouse brain correlate with cryptocurrency price: a cautionary tale

10.31234/osf.io/fa4wz ◽

2021 ◽

Author(s):

Guido Meijer

Keyword(s):

Firing Rate ◽

False Positive ◽

False Positive Rate ◽

Multiple Comparisons ◽

Single Neurons ◽

Bonferroni Correction ◽

Cautionary Tale ◽

Neural Correlate ◽

Positive Rate ◽

Over Time

In this paper I report the discovery of neurons which showed a neural correlate with ongoing fluctuations of Bitcoin and Ethereum prices at the time of the recording. I used the publicly available dataset of Neuropixel recordings by the Allen Institute to correlate the firing rate of single neurons with cryptocurrency price. Out of ~40.000 recorded single neurons, ~70% showed a significant correlation with Bitcoin or Ethereum prices. Even when using the conservative Bonferroni correction for multiple comparisons, ~35% of neurons showed a significant correlation, which is well above the expected false positive rate of 5%. These results were due to "nonsense correlations": when correlating two signals which both evolve slowly over time, the chances of finding a significant correlation between the two are much higher than when comparing signals which lack this property.

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A Computational Model as Neurodecoder Based on Synchronous Oscillation in the Visual Cortex

Neural Computation ◽

10.1162/089976603322362419 ◽

2003 ◽

Vol 15 (10) ◽

pp. 2399-2418 ◽

Cited By ~ 5

Author(s):

Zhao Songnian ◽

Xiong Xiaoyun ◽

Yao Guozheng ◽

Fu Zhi

Keyword(s):

Visual Cortex ◽

Computational Model ◽

Visual Information ◽

Spike Trains ◽

Spike Timing ◽

Contour Detection ◽

System Level ◽

Neuronal Spike ◽

Neuronal Spike Trains ◽

External Stimuli

Based on synchronized responses of neuronal populations in the visual cortex to external stimuli, we proposed a computational model consisting primarily of a neuronal phase-locked loop (NPLL) and multiscaled operator. The former reveals the function of synchronous oscillations in the visual cortex. Regardless of which of these patterns of the spike trains may be an average firing-rate code, a spike-timing code, or a rate-time code, the NPLL can decode original visual information from neuronal spike trains modulated with patterns of external stimuli, because a voltage-controlled oscillator (VCO), which is included in the NPLL, can precisely track neuronal spike trains and instantaneous variations, that is, VCO can make a copy of an external stimulus pattern. The latter, however, describes multi-scaled properties of visual information processing, but not merely edge and contour detection. In this study, in which we combined NPLL with a multiscaled operator and maximum likelihood estimation, we proved that the model, as a neurodecoder, implements optimum algorithm decoding visual information from neuronal spike trains at the system level. At the same time, the model also obtains increasingly important supports, which come from a series of experimental results of neurobiology on stimulus-specific neuronal oscillations or synchronized responses of the neuronal population in the visual cortex. In addition, the problem of how to describe visual acuity and multiresolution of vision by wavelet transform is also discussed. The results indicate that the model provides a deeper understanding of the role of synchronized responses in decoding visual information.

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