scholarly journals The Receptive Fields of Inferior Temporal Cortex Neurons in Natural Scenes

2003 ◽  
Vol 23 (1) ◽  
pp. 339-348 ◽  
Author(s):  
Edmund T. Rolls ◽  
Nicholas C. Aggelopoulos ◽  
Fashan Zheng
Keyword(s):  
Temporal Cortex ◽  
Receptive Fields ◽  
Inferior Temporal Cortex ◽  
Natural Scenes

scholarly journals Object Perception in Natural Scenes: Encoding by Inferior Temporal Cortex Simultaneously Recorded Neurons

2005 ◽  
Vol 93 (3) ◽  
pp. 1342-1357 ◽  
Author(s):  
Nikolaos C. Aggelopoulos ◽  
Leonardo Franco ◽  
Edmund T. Rolls
Keyword(s):  
Alternative Hypothesis ◽  
Temporal Cortex ◽  
Receptive Fields ◽  
Object Perception ◽  
Spike Timing ◽  
Inferior Temporal Cortex ◽  
Natural Scenes ◽  
Small Contribution ◽  
Complex Scene ◽  
Information Encoding

The firing of inferior temporal cortex neurons is tuned to objects and faces, and in a complex scene, their receptive fields are reduced to become similar to the size of an object being fixated. These two properties may underlie how objects in scenes are encoded. An alternative hypothesis suggests that visual perception requires the binding of features of the visual target through spike synchrony in a neuronal assembly. To examine possible contributions of firing synchrony of inferior temporal neurons, we made simultaneous recordings of the activity of several neurons while macaques performed a visual discrimination task. The stimuli were presented in either plain or complex backgrounds. The encoding of information of neurons was analyzed using a decoding algorithm. Ninety-four percent to 99% of the total information was available in the firing rate spike counts, and the contribution of spike timing calculated as stimulus-dependent synchronization (SDS) added only 1–6% of information to the total that was independent of the spike counts in the complex background. Similar results were obtained in the plain background. The quantitatively small contribution of spike timing to the overall information available in spike patterns suggests that information encoding about which stimulus was shown by inferior temporal neurons is achieved mainly by rate coding. Furthermore, it was shown that there was little redundancy (6%) between the information provided by the spike counts of the simultaneously recorded neurons, making spike counts an efficient population code with a high encoding capacity.

scholarly journals Within and between hemifields generalization of repetition suppression in inferior temporal cortex.

2020 ◽  
Author(s):  
Francesco Fabbrini ◽  
Rufin Vogels
Keyword(s):  
Test Stimulus ◽  
Common Property ◽  
Temporal Cortex ◽  
Receptive Fields ◽  
Selective Adaptation ◽  
Inferior Temporal Cortex ◽  
Repetition Suppression ◽  
Repetition Trial ◽  
End Stage ◽  
Spatial Locations

The decrease in response with stimulus repetition is a common property observed in many sensory brain areas. This repetition suppression (RS) is ubiquitous in neurons of macaque inferior temporal (IT) cortex, the end-stage of the ventral visual pathway. The neural mechanisms of RS in IT are still unclear, and one possibility is that it is inherited from areas upstream to IT that show also RS. Since neurons in IT have larger receptive fields compared to earlier visual areas, we examined the inheritance hypothesis by presenting adapter and test stimuli at widely different spatial locations along both vertical and horizontal meridians, and across hemifields. RS was present for distances between adapter and test stimuli up to 22°, and when the two stimuli were presented in different hemifields. Also, we examined the position tolerance of the stimulus selectivity of adaptation by comparing the responses to a test stimulus following the same (repetition trial) or a different adapter (alternation trial) at a different position than the test stimulus. Stimulus-selective adaptation was still present and consistently stronger in the later phase of the response for distances up to 18°. Finally, we observed stimulus-selective adaptation in repetition trials even without a measurable excitatory response to the adapter stimulus. To accommodate these and previous data, we propose that at least part of the stimulus-selective adaptation in IT is based on short-term plasticity mechanisms within IT and/or reflects top-down activity from areas downstream to IT.

Response properties of neurons in temporal cortical visual areas of infant monkeys

1993 ◽  
Vol 70 (3) ◽  
pp. 1115-1136 ◽  
Author(s):  
H. R. Rodman ◽  
S. P. Scalaidhe ◽  
C. G. Gross
Keyword(s):  
Nitrous Oxide ◽  
Temporal Cortex ◽  
Receptive Fields ◽  
Stimulus Presentation ◽  
Pattern Perception ◽  
Inferior Temporal Cortex ◽  
Field Size ◽  
Visual Response ◽  
Control Adult ◽  
Oxide Anesthesia

1. Inferior temporal cortex (IT) is a "high-order" region of primate temporal visual cortex implicated in visual pattern perception and recognition. To gain some insight into the development of this area, we compared the properties of single neurons in IT in infant monkeys ranging from 5 wk to 7 mo of age with those of neurons in IT in adult animals. Both anesthetized and awake behaving paradigms were used. 2. In immobilized infant monkeys under nitrous oxide anesthesia, the incidence of visually responsive cells was markedly less than in adult monkeys studied under similar conditions. In infants 4-7 mo of age, only half of IT neurons studied were visually responsive, compared with > 80% in adult monkeys. In monkeys < 4 mo old, even fewer (< 10%) could be visually driven. "Habituation" of IT cells to repeated stimulus presentation appeared more pronounced in infant monkeys under nitrous oxide anesthesia than in adult animals. 3. IT cells in the anesthetized infant monkeys that did respond showed receptive field properties similar to those of responsive adult IT neurons studied under similar conditions. Two thirds of the receptive fields plotted in the anesthetized 4 to 7-mo-old group were bilateral, and median field size did not differ between the infants and comparable adult groups, being approximately 20 degrees on a side in each case. 4. In contrast to the results obtained under anesthesia, most IT cells in alert infant monkeys 5 wk-7 mo of age (80%) were responsive to visual stimuli, and this incidence of visually responsive IT neurons did not differ from that obtained in awake adult macaques. However, response magnitude, measured as spikes per second above baseline rate, was significantly lower in the infant alert sample than in the adult control (5.2 vs. 12.6 spikes/s, mean +/- SE, deviation from spontaneous rate, respectively). 5. In addition to having lower magnitudes of visual response, IT cells in the awake infants also tended to have longer and more variable latencies. The overall mean for the infant cells was 196 ms, compared with an overall mean of 140 ms for IT neurons in the alert control adult. 6. Although the magnitude of response of neurons in alert infant IT cortex was lower overall, the incidence and features of stimulus selectivity shown by alert infant IT neurons were strikingly similar to those of IT cells of both anesthetized and unanesthetized adult monkeys.(ABSTRACT TRUNCATED AT 400 WORDS)

scholarly journals Firing Rate Distributions and Efficiency of Information Transmission of Inferior Temporal Cortex Neurons to Natural Visual Stimuli

1999 ◽  
Vol 11 (3) ◽  
pp. 601-631 ◽  
Author(s):  
Alessandro Treves ◽  
Stefano Panzeri ◽  
Edmund T. Rolls ◽  
Michael Booth ◽  
Edward A. Wakeman
Keyword(s):  
Simple Model ◽  
Information Transmission ◽  
Firing Rate ◽  
Visual Stimulation ◽  
Time Window ◽  
Temporal Cortex ◽  
Exponential Model ◽  
Inferior Temporal Cortex ◽  
Natural Scenes ◽  
Static Images

The distribution of responses of sensory neurons to ecological stimulation has been proposed to be designed to maximize information transmission, which according to a simple model would imply an exponential distribution of spike counts in a given time window. We have used recordings from inferior temporal cortex neurons responding to quasi-natural visual stimulation (presented using a video of everyday lab scenes and a large number of static images of faces and natural scenes) to assess the validity of this exponential model and to develop an alternative simple model of spike count distributions. We find that the exponential model has to be rejected in 84% of cases (at the p < 0.01 level). A new model, which accounts for the firing rate distribution found in terms of slow and fast variability in the inputs that produce neuronal activation, is rejected statistically in only 16% of cases. Finally, we show that the neurons are moderately efficient at transmitting information but not optimally efficient.

Visual properties of neurons in area V4 of the macaque: sensitivity to stimulus form

1987 ◽  
Vol 57 (3) ◽  
pp. 835-868 ◽  
Author(s):  
R. Desimone ◽  
S. J. Schein
Keyword(s):  
Receptive Field ◽  
Temporal Cortex ◽  
Receptive Fields ◽  
Inferior Temporal Cortex ◽  
Field Size ◽  
Lower Visual Field ◽  
Stimulus Form ◽  
Area V4 ◽  
Prestriate Cortex ◽  
Length Width

Area V4, a visuotopically organized area in prestriate cortex of the macaque, is the major source of visual input to the inferior temporal cortex, known to be crucial for object recognition. To examine the selectivity of cells in V4 for stimulus form, we quantitatively measured the responses of 322 cells to bars varying in length, width, orientation, and polarity of contrast, and sinusoidal gratings varying in spatial frequency, phase, orientation, and overall size. All of the cells recorded in V4 were located on the lower portion of the prelunate gyrus. Receptive fields were located almost exclusively within the representation of the central 5 degrees of the lower visual field, and receptive field size, in linear dimension, was 4-7 times greater than that in the corresponding representation of striate cortex (V1). Nearly all receptive fields consisted of overlapping dark and light zones, like “classic” complex fields in V1, but the relative strengths of the dark and light zones often differed. A few cells responded exclusively to light or dark stimuli. Many cells in V4 were selective for stimulus orientation, and a few were selective for direction of motion as well. Although the median orientation bandwidth of the orientation-selective cells (52 degrees) was wider than that reported for oriented cells in V1, approximately 8% of the oriented cells had bandwidths of less than 30 degrees, which is nearly as narrow as the most narrowly tuned cells in V1. The proportion of cells selective for direction of motion (13%) was not markedly different from that reported in V1. The large majority of V4 cells were tuned to the length and width of bars, and the “shape” of the optimal bar varied from cell to cell, as has been reported for cells in the dorsolateral visual area (DL) of the owl monkey, a possible homologue of V4 in the macaque. Preferred lengths and widths varied independently from approximately 0.05 to 6 degrees, with the smallest preferred bars about the size of the smallest receptive fields in V1 and the largest preferred bars larger than any fields in V1. The relationship between the size of the optimal bar and the size of the receptive field varied from cell to cell. Some cells, for example, responded best to bars much narrower or shorter than the field, whereas other cells responded best to bars that filled (but did not extend beyond) the excitatory field in the length, width, or both dimensions.(ABSTRACT TRUNCATED AT 400 WORDS)

scholarly journals Imaging object-scene integration in visible and invisible natural scenes

2017 ◽  
Author(s):  
Nathan Faivre ◽  
Julien Dubois ◽  
Naama Schwartz ◽  
Liad Mudrik
Keyword(s):  
Visual Masking ◽  
Brain Activity ◽  
Temporal Cortex ◽  
Task Demands ◽  
Inferior Temporal Cortex ◽  
Natural Scenes ◽  
Lateral Occipital Complex ◽  
Parahippocampal Cortex ◽  
Visual Scenes ◽  
Context Integration

AbstractIntegrating objects with their context is a key step in the interpretation of complex visual scenes. Humans can do this very quickly, yet the brain mechanisms that mediate this ability are not yet understood. Here, we used functional Magnetic Resonance Imaging (fMRI) to measure brain activity while participants viewed visual scenes depicting a person performing an action with an object that was either congruent or incongruent with the scene. Univariate and multivariate analyses revealed different activity for congruent compared to incongruent scenes in the lateral occipital complex, inferior temporal cortex, parahippocampal cortex, and prefrontal cortex, in line with existing models of scene processing. Importantly, and in contrast to previous studies, these activations could not be explained by task-induced conflicts. A secondary goal of this study was to examine whether object-context integration could occur in the absence of awareness, by comparing brain activity elicited by congruent vs. incongruent scenes that were suppressed from awareness using visual masking. We found no evidence for brain activity differentiating between congruent and incongruent invisible scenes. Overall, our results provide novel support for the roles of PHC and PFC in conscious object-context integration which cannot be explained by either low-level differences or task demands. Yet they further suggest that activity in these regions is decreased by visual masking to the point of becoming undetectable with our fMRI protocol.

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