Image statistics underlying natural texture selectivity of neurons in macaque V4

Okazawa, Gouki; Tajima, Satohiro; Komatsu, Hidehiko

doi:10.1073/pnas.1415146112

Cited by 137 publications

(194 citation statements)

References 57 publications

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“…The importance of cells that extract contours and edges has been recognized since Hubel and Wiesel1; however, extra-striate cells that are selective for specific classes of patterns and textures have only been reported recently2125. Our empirical results and model simulations suggest that cells in pinwheel centres provide suitable inputs for pattern selective cells, whereas cells in iso-orientation domains enhance sensitivity to edges.…”

Section: Discussionmentioning

confidence: 61%

“…Cortical processing of isolated orientations is important for extracting contours and edges1819, three-dimensional shape from shading20 and the direction of local motion1. However, processing multiple orientations simultaneously is essential for more sophisticated visual analyses, such as extracting image patterns21, pattern motion2223, pattern symmetry24, material properties25 and three-dimensional shape from texture262728. Even though processing stimuli with multiple orientations is important, the cortical responses to those stimuli are thought to be strongly suppressed by a neuronal mechanism known as cross-orientation suppression.…”

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confidence: 99%

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Functional implications of orientation maps in primary visual cortex

et al. 2016

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Stimulus orientation in the primary visual cortex of primates and carnivores is mapped as iso-orientation domains radiating from pinwheel centres, where orientation preferences of neighbouring cells change circularly. Whether this orientation map has a function is currently debated, because many mammals, such as rodents, do not have such maps. Here we show that two fundamental properties of visual cortical responses, contrast saturation and cross-orientation suppression, are stronger within cat iso-orientation domains than at pinwheel centres. These differences develop when excitation (not normalization) from neighbouring oriented neurons is applied to different cortical orientation domains and then balanced by inhibition from un-oriented neurons. The functions of the pinwheel mosaic emerge from these local intra-cortical computations: Narrower tuning, greater cross-orientation suppression and higher contrast gain of iso-orientation cells facilitate extraction of object contours from images, whereas broader tuning, greater linearity and less suppression of pinwheel cells generate selectivity for surface patterns and textures.

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Section: Discussionmentioning

confidence: 61%

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confidence: 99%

Functional implications of orientation maps in primary visual cortex

et al. 2016

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“…Thus, most neurons saw only a portion of the stimuli, over which the statistics would not have been fully matched. Finally, recall that the transformation from V1 to V2 is part of a cascade, and it may well be that perception relies more on downstream areas, such as V4, where neurons may show even more selectivity and tolerance for the statistics we used (31,45).…”

Section: Discussionmentioning

confidence: 99%

Selectivity and tolerance for visual texture in macaque V2

Ziemba

Freeman

Movshon

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

105

151

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As information propagates along the ventral visual hierarchy, neuronal responses become both more specific for particular image features and more tolerant of image transformations that preserve those features. Here, we present evidence that neurons in area V2 are selective for local statistics that occur in natural visual textures, and tolerant of manipulations that preserve these statistics. Texture stimuli were generated by sampling from a statistical model, with parameters chosen to match the parameters of a set of visually distinct natural texture images. Stimuli generated with the same statistics are perceptually similar to each other despite differences, arising from the sampling process, in the precise spatial location of features. We assessed the accuracy with which these textures could be classified based on the responses of V1 and V2 neurons recorded individually in anesthetized macaque monkeys. We also assessed the accuracy with which particular samples could be identified, relative to other statistically matched samples. For populations of up to 100 cells, V1 neurons supported better performance in the sample identification task, whereas V2 neurons exhibited better performance in texture classification. Relative to V1, the responses of V2 show greater selectivity and tolerance for the representation of texture statistics. These responses are typically characterized by measuring selectivity for specific visual attributes, such as light intensity or color, and local structural properties, such as spatial position, orientation, and spatial frequency. Stimulus selectivity, along with the complementary notion of "invariance" or "tolerance" to irrelevant variation, provides a de facto language for describing the functional roles and relationships of neurons in visual areas. For example, simple cells in the primary visual cortex, area V1, are selective for orientation (1) and spatial frequency (2-4). Complex cells exhibit similar selectivity, but are also more tolerant to changes in spatial position (1,5,6). Component cells in area MT (or V5) exhibit selectivity for orientation and speed, but (relative to their V1 inputs) are more tolerant of changes in location and spatial frequency, whereas MT pattern cells are tolerant to changes in orientation (and, more generally, spatial structure) (7).Neurons in the inferotemporal visual cortex (IT) are selective for visual images of particular objects, but are tolerant to identitypreserving transformations, such as translation, rotation, or background context (8,9). This tolerance increases from area V4 to IT (10), suggesting that an increase in selectivity is balanced by an increase in tolerance, preserving overall response levels and their distribution across neurons (11). However, the selectivity and tolerance of visual representations in midventral areas, particularly area V2, have been more difficult to establish because we lack knowledge of the relevant visual attributes. V2 neurons receive much of their afferent drive from V1, have receptive fields that are r...

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“…The same is true for V2—knowing that the population of V2 neurons can represent statistical structure in images does not uniquely specify the response properties of individual V2 neurons, and a major challenge for ongoing research will be to create such models. Related work in V4 has explored computations that produce some forms of texture specificity (Okazawa et al 2015), and we have begun to explore models to account for the texture responses of V2 neurons. The structure of the statistical model from which the texture stimuli are generated (Portilla and Simoncelli 2000) provides a starting point.…”

Section: Discussionmentioning

confidence: 99%

Representation of Naturalistic Image Structure in the Primate Visual Cortex

Movshon

Simoncelli

2014

Cold Spring Harb Symp Quant Biol

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The perception of complex visual patterns emerges from neuronal activity in a cascade of areas in the primate cerebral cortex. We have probed the early stages of this cascade with “naturalistic” texture stimuli designed to capture key statistical features of natural images. Humans can recognize and classify these synthetic images and are insensitive to distortions that do not alter the local values of these statistics. The responses of neurons in the primary visual cortex, V1, are relatively insensitive to the statistical information in these textures. However, in the area immediately downstream, V2, cells respond more vigorously to these stimuli than to matched control stimuli. Humans show blood-oxygen-level-dependent functional magnetic resonance imaging (BOLD fMRI responses in V1 and V2) that are consistent with the neuronal measurements in macaque. These fMRI measurements, as well as neurophysiological work by others, show that true natural scenes become a more prominent driving feature of cortex downstream from V2. These results suggest a framework for thinking about how information about elementary visual features is transformed into the specific representations of scenes and objects found in areas higher in the visual pathway.

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Image statistics underlying natural texture selectivity of neurons in macaque V4

Cited by 137 publications

References 57 publications

Functional implications of orientation maps in primary visual cortex

Functional implications of orientation maps in primary visual cortex

Selectivity and tolerance for visual texture in macaque V2

Representation of Naturalistic Image Structure in the Primate Visual Cortex

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