Categorically distinct types of receptive fields in early visual cortex

In the visual cortex, distinct types of neurons have been identified based on cellular morphology, response to injected current, or expression of specific markers, but neurophysiological studies have revealed visual receptive field (RF) properties that appear to be on a continuum, with only two generally recognized classes: simple and complex. Most previous studies have characterized visual responses of neurons using stereotyped stimuli such as bars, gratings, or white noise and simple system identification approaches (e.g., reverse correlation). Here we estimate visual RF models of cortical neurons using visually rich natural image stimuli and regularized regression system identification methods and characterize their spatial tuning, temporal dynamics, spatiotemporal behavior, and spiking properties. We quantitatively demonstrate the existence of three functionally distinct categories of simple cells, distinguished by their degree of orientation selectivity (isotropic or oriented) and the nature of their output nonlinearity (expansive or compressive). In addition, these three types have differing average values of several other properties. Cells with nonoriented RFs tend to have smaller RFs, shorter response durations, no direction selectivity, and high reliability. Orientation-selective neurons with an expansive output nonlinearity have Gabor-like RFs, lower spontaneous activity and responsivity, and spiking responses with higher sparseness. Oriented RFs with a compressive nonlinearity are spatially nondescript and tend to show longer response latency. Our findings indicate multiple physiologically defined types of RFs beyond the simple/complex dichotomy, suggesting that cortical neurons may have more specialized functional roles rather than lying on a multidimensional continuum.

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Excitatory amino acid transmitters in neuronal circuits of the cat visual cortex

Journal of Neurophysiology ◽

10.1152/jn.1986.55.3.469 ◽

1986 ◽

Vol 55 (3) ◽

pp. 469-483 ◽

Cited By ~ 62

Author(s):

T. Tsumoto ◽

H. Masui ◽

H. Sato

Keyword(s):

Visual Cortex ◽

Amino Acid ◽

Cortical Neurons ◽

Excitatory Amino Acid ◽

Receptive Fields ◽

Great Majority ◽

Suppressive Effect ◽

Kainate Receptors ◽

Visual Responses ◽

Special Complex

To test a possibility that glutamate (Glu) and aspartate (Asp) are transmitters in the visual cortex and to locate their operating sites in the cortical circuitry, we studied effects of microiontophoretic application of Glu/Asp antagonists on visual responses of cortical neurons in the cat. The antagonists tested were kynurenic acid (KYNA), cis-2,3-piperidine dicarboxylic acid, and gamma-D-glutamylglycine. Among these antagonists, KYNA was most effective in blocking visual responses of cortical neurons; it eliminated visual responses in 156 of the 188 cells tested. Usually the maximal suppressive effect appeared 20-30 s after starting KYNA application and recovery of cell's responsiveness 30-60 s after stopping the application. KYNA antagonized excitations induced by ionophoretic application of Glu and Asp but did not block those by acetylcholine, suggesting that KYNA is a selective antagonist of Glu/Asp, and its action is not due to general depressant effects. This suggestion was further supported by the observation that in corticogeniculate cells the latency and probability of invasion of antidromic spikes into the somatodendritic part following electrical stimulation of the lateral geniculate were not changed while visual responses were completely suppressed by KYNA. In terms of actions of the three agonists which give the basis for classifying excitatory amino acid receptors into at least three types, KYNA antagonized excitations by N-methyl-D-aspartic acid (NMDA) and kainate in almost all the cells tested but did not block those by quisqualate in about half of the cells. These results suggest that KYNA reacts more preferentially with NMDA and kainate receptors than with quisqualate receptors. Effectiveness of KYNA was related to types of receptive fields of cells and to their laminar locations. In 79 of the 104 simple cells tested, KYNA completely suppressed their visual responses, while such a complete block was seen in only 18 of the 68 complex and 3 of the 16 special complex cells. The great majority of the cells in layers IVab, IVc and the upper part of layer VI were completely suppressed by KYNA, whereas most of the cells in the other layers were incompletely suppressed or not suppressed at all.(ABSTRACT TRUNCATED AT 400 WORDS)

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Dynamic Predictive Coding with Hypernetworks

10.1101/2021.02.22.432194 ◽

2021 ◽

Author(s):

Linxing Preston Jiang ◽

Dimitrios C. Gklezakos ◽

Rajesh P. N. Rao

Keyword(s):

Visual Cortex ◽

Cortical Neurons ◽

Predictive Coding ◽

Receptive Fields ◽

Natural Image ◽

Prediction Errors ◽

Time Varying ◽

Transition Matrices ◽

Time Step ◽

Transition Dynamics

AbstractThe original predictive coding model of Rao & Ballard [1] focused on spatial prediction to explain spatial receptive fields and contextual effects in the visual cortex. Here, we introduce a new dynamic predictive coding model that achieves spatiotemporal prediction of complex natural image sequences using time-varying transition matrices. We overcome the limitations of static linear transition models (as in, e.g., Kalman filters) using a hypernetwork to adjust the transition matrix dynamically for every time step, allowing the model to predict using a time-varying mixture of possible transition dynamics. We developed a single level model with recurrent modulation of transition weights by a hypernetwork and a two-level hierarchical model with top-down modulation based on a hypernetwork. At each time step, the model predicts the next input and estimates a sparse neural code by minimizing prediction error. When exposed to natural movies, the model learned localized, oriented spatial filters as well as both separable and inseparable (direction-selective) space-time receptive fields at the first level, similar to those found in the primary visual cortex (V1). Longer timescale responses and stability at the second level also emerged naturally from minimizing prediction errors for the first level dynamics. Our results suggest that the multiscale temporal response properties of cortical neurons could be the result of the cortex learning a hierarchical generative model of the visual world with higher order areas predicting the transition dynamics of lower order areas.

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Impact of acute visual experience on development of LGN receptive fields in the ferret

10.1101/2021.07.16.452697 ◽

2021 ◽

Author(s):

Andrea K Stacy ◽

Nathan A Schneider ◽

Noah K Gilman ◽

Stephen D Van Hooser

Keyword(s):

Visual Cortex ◽

Cortical Neurons ◽

Visual Experience ◽

Receptive Fields ◽

Direction Selectivity ◽

In Vivo Electrophysiology ◽

Primate Visual Cortex ◽

Before And After ◽

Visual Cortical

Selectivity for direction of motion is a key feature of primary visual cortical neurons. Visual experience is required for direction selectivity in carnivore and primate visual cortex, but the circuit mechanisms of its formation remain incompletely understood. Here we examined how developing lateral geniculate nucleus (LGN) neurons may contribute to cortical direction selectivity. Using in vivo electrophysiology techniques, we examined LGN receptive field properties of visually naive female ferrets before and after exposure to 6 hours of motion stimuli in order to assess the effect of acute visual experience on LGN cell development. We found that acute experience with motion stimuli did not significantly affect the weak orientation or direction selectivity of LGN neurons. In addition, we found that neither latency nor sustainedness or transience of LGN neurons significantly changed with acute experience. These results suggest that the direction selectivity that emerges in cortex after acute experience is computed in cortex and cannot be explained by changes in LGN cells.

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Emerging feed-forward inhibition allows the robust formation of direction selectivity in the developing ferret visual cortex

Journal of Neurophysiology ◽

10.1152/jn.00891.2013 ◽

2014 ◽

Vol 111 (11) ◽

pp. 2355-2373 ◽

Cited By ~ 13

Author(s):

Stephen D. Van Hooser ◽

Gina M. Escobar ◽

Arianna Maffei ◽

Paul Miller

Keyword(s):

Visual Cortex ◽

Cortical Neurons ◽

Initial Conditions ◽

Receptive Fields ◽

Long Term Potentiation ◽

Direction Selectivity ◽

Feed Forward ◽

Synaptic Competition ◽

Eye Opening ◽

Feed Forward Inhibition

The computation of direction selectivity requires that a cell respond to joint spatial and temporal characteristics of the stimulus that cannot be separated into independent components. Direction selectivity in ferret visual cortex is not present at the time of eye opening but instead develops in the days and weeks following eye opening in a process that requires visual experience with moving stimuli. Classic Hebbian or spike timing-dependent modification of excitatory feed-forward synaptic inputs is unable to produce direction-selective cells from unselective or weakly directionally biased initial conditions because inputs eventually grow so strong that they can independently drive cortical neurons, violating the joint spatial-temporal activation requirement. Furthermore, without some form of synaptic competition, cells cannot develop direction selectivity in response to training with bidirectional stimulation, as cells in ferret visual cortex do. We show that imposing a maximum lateral geniculate nucleus (LGN)-to-cortex synaptic weight allows neurons to develop direction-selective responses that maintain the requirement for joint spatial and temporal activation. We demonstrate that a novel form of inhibitory plasticity, postsynaptic activity-dependent long-term potentiation of inhibition (POSD-LTPi), which operates in the developing cortex at the time of eye opening, can provide synaptic competition and enables robust development of direction-selective receptive fields with unidirectional or bidirectional stimulation. We propose a general model of the development of spatiotemporal receptive fields that consists of two phases: an experience-independent establishment of initial biases, followed by an experience-dependent amplification or modification of these biases via correlation-based plasticity of excitatory inputs that compete against gradually increasing feed-forward inhibition.

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Mechanisms of Direction Selectivity in Cat Primary Visual Cortex as Revealed by Visual Adaptation

Journal of Neurophysiology ◽

10.1152/jn.00241.2010 ◽

2010 ◽

Vol 104 (5) ◽

pp. 2615-2623 ◽

Cited By ~ 12

Author(s):

Nicholas J. Priebe ◽

Ilan Lampl ◽

David Ferster

Keyword(s):

Visual Cortex ◽

Primary Visual Cortex ◽

Cortical Neurons ◽

Visual Stimulation ◽

Direction Selectivity ◽

Dependent Manner ◽

Visual Responses ◽

Null Direction ◽

Simple Cells ◽

Complex Cells

In contrast to neurons of the lateral geniculate nucleus (LGN), neurons in the primary visual cortex (V1) are selective for the direction of visual motion. Cortical direction selectivity could emerge from the spatiotemporal configuration of inputs from thalamic cells, from intracortical inhibitory interactions, or from a combination of thalamic and intracortical interactions. To distinguish between these possibilities, we studied the effect of adaptation (prolonged visual stimulation) on the direction selectivity of intracellularly recorded cortical neurons. It is known that adaptation selectively reduces the responses of cortical neurons, while largely sparing the afferent LGN input. Adaptation can therefore be used as a tool to dissect the relative contribution of afferent and intracortical interactions to the generation of direction selectivity. In both simple and complex cells, adaptation caused a hyperpolarization of the resting membrane potential (−2.5 mV, simple cells, −0.95 mV complex cells). In simple cells, adaptation in either direction only slightly reduced the visually evoked depolarization; this reduction was similar for preferred and null directions. In complex cells, adaptation strongly reduced visual responses in a direction-dependent manner: the reduction was largest when the stimulus direction matched that of the adapting motion. As a result, adaptation caused changes in the direction selectivity of complex cells: direction selectivity was reduced after preferred direction adaptation and increased after null direction adaptation. Because adaptation in the null direction enhanced direction selectivity rather than reduced it, it seems unlikely that inhibition from the null direction is the primary mechanism for creating direction selectivity.

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Pure tones modulate the representation of orientation and direction in the primary visual cortex

Journal of Neurophysiology ◽

10.1152/jn.00069.2019 ◽

2019 ◽

Vol 121 (6) ◽

pp. 2202-2214 ◽

Cited By ~ 5

Author(s):

John P. McClure ◽

Pierre-Olivier Polack

Keyword(s):

Visual Cortex ◽

Primary Visual Cortex ◽

Visual Stimulus ◽

Visual Stimuli ◽

Direction Selectivity ◽

Multimodal Integration ◽

Visual Responses ◽

V1 Neurons ◽

Pure Tones ◽

The Impact

Multimodal sensory integration facilitates the generation of a unified and coherent perception of the environment. It is now well established that unimodal sensory perceptions, such as vision, are improved in multisensory contexts. Whereas multimodal integration is primarily performed by dedicated multisensory brain regions such as the association cortices or the superior colliculus, recent studies have shown that multisensory interactions also occur in primary sensory cortices. In particular, sounds were shown to modulate the responses of neurons located in layers 2/3 (L2/3) of the mouse primary visual cortex (V1). Yet, the net effect of sound modulation at the V1 population level remained unclear. In the present study, we performed two-photon calcium imaging in awake mice to compare the representation of the orientation and the direction of drifting gratings by V1 L2/3 neurons in unimodal (visual only) or multimodal (audiovisual) conditions. We found that sound modulation depended on the tuning properties (orientation and direction selectivity) and response amplitudes of V1 L2/3 neurons. Sounds potentiated the responses of neurons that were highly tuned to the cue’s orientation and direction but weakly active in the unimodal context, following the principle of inverse effectiveness of multimodal integration. Moreover, sound suppressed the responses of neurons untuned for the orientation and/or the direction of the visual cue. Altogether, sound modulation improved the representation of the orientation and direction of the visual stimulus in V1 L2/3. Namely, visual stimuli presented with auditory stimuli recruited a neuronal population better tuned to the visual stimulus orientation and direction than when presented alone. NEW & NOTEWORTHY The primary visual cortex (V1) receives direct inputs from the primary auditory cortex. Yet, the impact of sounds on visual processing in V1 remains controverted. We show that the modulation by pure tones of V1 visual responses depends on the orientation selectivity, direction selectivity, and response amplitudes of V1 neurons. Hence, audiovisual stimuli recruit a population of V1 neurons better tuned to the orientation and direction of the visual stimulus than unimodal visual stimuli.

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Spatial Distribution of Contextual Interactions in Primary Visual Cortex and in Visual Perception

Journal of Neurophysiology ◽

10.1152/jn.2000.84.4.2048 ◽

2000 ◽

Vol 84 (4) ◽

pp. 2048-2062 ◽

Cited By ~ 198

Author(s):

Mitesh K. Kapadia ◽

Gerald Westheimer ◽

Charles D. Gilbert

Keyword(s):

Spatial Distribution ◽

Visual Cortex ◽

Primary Visual Cortex ◽

Cortical Neurons ◽

Receptive Fields ◽

Human Perception ◽

Spatial Arrangement ◽

Orthogonal Axis ◽

V1 Neurons ◽

Contextual Interactions

To examine the role of primary visual cortex in visuospatial integration, we studied the spatial arrangement of contextual interactions in the response properties of neurons in primary visual cortex of alert monkeys and in human perception. We found a spatial segregation of opposing contextual interactions. At the level of cortical neurons, excitatory interactions were located along the ends of receptive fields, while inhibitory interactions were strongest along the orthogonal axis. Parallel psychophysical studies in human observers showed opposing contextual interactions surrounding a target line with a similar spatial distribution. The results suggest that V1 neurons can participate in multiple perceptual processes via spatially segregated and functionally distinct components of their receptive fields.

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Orientation Tuning, But Not Direction Selectivity, Is Invariant to Temporal Frequency in Primary Visual Cortex

Journal of Neurophysiology ◽

10.1152/jn.01224.2004 ◽

2005 ◽

Vol 94 (2) ◽

pp. 1336-1345 ◽

Cited By ~ 21

Author(s):

Bartlett D. Moore ◽

Henry J. Alitto ◽

W. Martin Usrey

Keyword(s):

Visual Cortex ◽

Primary Visual Cortex ◽

Visual Stimulus ◽

Visual Processing ◽

Cortical Neurons ◽

Temporal Frequency ◽

Direction Selectivity ◽

Orientation Tuning ◽

Orientation Contrast ◽

Wide Range

The activity of neurons in primary visual cortex is influenced by the orientation, contrast, and temporal frequency of a visual stimulus. This raises the question of how these stimulus properties interact to shape neuronal responses. While past studies have shown that the bandwidth of orientation tuning is invariant to stimulus contrast, the influence of temporal frequency on orientation-tuning bandwidth is unknown. Here, we investigate the influence of temporal frequency on orientation tuning and direction selectivity in area 17 of ferret visual cortex. For both simple cells and complex cells, measures of orientation-tuning bandwidth (half-width at half-maximum response) are ∼20–25° across a wide range of temporal frequencies. Thus cortical neurons display temporal-frequency invariant orientation tuning. In contrast, direction selectivity is typically reduced, and occasionally reverses, at nonpreferred temporal frequencies. These results show that the mechanisms contributing to the generation of orientation tuning and direction selectivity are differentially affected by the temporal frequency of a visual stimulus and support the notion that stability of orientation tuning is an important aspect of visual processing.

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Orientation Selectivity Is Reduced by Monocular Deprivation in Combination With PKA Inhibitors

Journal of Neurophysiology ◽

10.1152/jn.2002.88.4.1933 ◽

2002 ◽

Vol 88 (4) ◽

pp. 1933-1940 ◽

Cited By ~ 6

Author(s):

Chris J. Beaver ◽

Quentin S. Fischer ◽

Qinghua Ji ◽

Nigel W. Daw

Keyword(s):

Visual Cortex ◽

Protein Kinase ◽

Critical Period ◽

Ocular Dominance ◽

Receptive Fields ◽

Direction Selectivity ◽

Orientation Selectivity ◽

Monocular Deprivation ◽

Ocular Dominance Plasticity ◽

Kinase A

We have previously shown that the protein kinase A (PKA) inhibitor, 8-chloroadenosine-3′,5′–monophosphorothioate (Rp-8-Cl-cAMPS), abolishes ocular dominance plasticity in the cat visual cortex. Here we investigate the effect of this inhibitor on orientation selectivity. The inhibitor reduces orientation selectivity in monocularly deprived animals but not in normal animals. In other words, PKA inhibitors by themselves do not affect orientation selectivity, nor does monocular deprivation by itself, but monocular deprivation in combination with a PKA inhibitor does affect orientation selectivity. This result is found for the receptive fields in both deprived and nondeprived eyes. Although there is a tendency for the orientation selectivity in the nondeprived eye to be higher than the orientation selectivity in the deprived eye, the orientation selectivity in both eyes is considerably less than normal. The result is striking in animals at 4 wk of age. The effect of the monocular deprivation on orientation selectivity is reduced at 6 wk of age and absent at 9 wk of age, while the effect on ocular dominance shifts is less changed in agreement with previous results showing that the critical period for orientation/direction selectivity ends earlier than the critical period for ocular dominance. We conclude that closure of one eye in combination with inhibition of PKA reduces orientation selectivity during the period that orientation selectivity is still mutable and that the reduction in orientation selectivity is transferred to the nondeprived eye.

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Corticogeniculate neurons, corticotectal neurons, and suspected interneurons in visual cortex of awake rabbits: receptive-field properties, axonal properties, and effects of EEG arousal

Journal of Neurophysiology ◽

10.1152/jn.1987.57.4.977 ◽

1987 ◽

Vol 57 (4) ◽

pp. 977-1001 ◽

Cited By ~ 45

Author(s):

H. A. Swadlow ◽

T. G. Weyand

Keyword(s):

Electrical Stimulation ◽

Visual Cortex ◽

Receptive Field ◽

Receptive Fields ◽

Spontaneous Firing ◽

Visual Responses ◽

Firing Rates ◽

Axonal Conduction ◽

Conduction Velocities ◽

Stimulation Of

The intrinsic stability of the rabbit eye was exploited to enable receptive-field analysis of antidromically identified corticotectal (CT) neurons (n = 101) and corticogeniculate (CG) neurons (n = 124) in visual area I of awake rabbits. Eye position was monitored to within 1/5 degrees. We also studied the receptive-field properties of neurons synaptically activated via electrical stimulation of the dorsal lateral geniculate nucleus (LGNd). Whereas most CT neurons had either complex (59%) or motion/uniform (15%) receptive fields, we also found CT neurons with simple (9%) and concentric (4%) receptive fields. Most complex CT cells were broadly tuned to both stimulus orientation and velocity, but only 41% of these cells were directionally selective. We could elicit no visual responses from 6% of CT cells, and these cells had significantly lower conduction velocities than visually responsive CT cells. The median spontaneous firing rates for all classes of CT neurons were 4-8 spikes/s. CG neurons had primarily simple (60%) and concentric (9%) receptive fields, and none of these cells had complex receptive fields. CG simple cells were more narrowly tuned to both stimulus orientation and velocity than were complex CT cells, and most (85%) were directionally selective. Axonal conduction velocities of CG neurons (mean = 1.2 m/s) were much lower than those of CT neurons (mean = 6.4 m/s), and CG neurons that were visually unresponsive (23%) had lower axonal conduction velocities than did visually responsive CG neurons. Some visually unresponsive CG neurons (14%) responded with saccadic eye movements. The median spontaneous firing rates for all classes of CG neurons were less than 1 spike/s. All neurons synaptically activated via LGNd stimulation at latencies of less than 2.0 ms had receptive fields that were not orientation selective (89% motion/uniform, 11% concentric), whereas most cells with orientation-selective receptive fields had considerably longer synaptic latencies. Most short-latency motion/uniform neurons responded to electrical stimulation of the LGNd (and visual area II) with a high-frequency burst (500-900 Hz) of three or more spikes. Action potentials of these neurons were of short duration, thresholds of synaptic activation were low, and spontaneous firing rates were the highest seen in rabbit visual cortex. These properties are similar to those reported for interneurons in several regions in mammalian central nervous system. Nonvisual sensory stimuli that resulted in electroencephalographic arousal (hippocampal theta activity) had a profound effect on the visual responses of many visual cortical neurons.(ABSTRACT TRUNCATED AT 400 WORDS)

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