Contributions of excitation and suppression in shaping spatial frequency selectivity of V1 neurons as revealed by binocular measurements

Ninomiya, Taihei; Sanada, Takahisa M.; Ohzawa, Izumi

doi:10.1152/jn.00832.2010

Cited by 10 publications

(15 citation statements)

References 37 publications

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“…Instead, these locations could be selective to more complex features and thus not well described by the two distinct parameters representing preferred orientation and preferred SF. This idea is supported by a recent two-photon imaging studies showing a large percentage of unresponsive cells to oriented, drifting gratings close to pinwheels (Ohki et al, 2006). This interpretation recalls the suggestion of Basole et al (2003) that separable cortical maps representing preferred orientation and preferred SF (as well as speed) were not sufficient to predict the preferred orientations within a complex stimulus composed of drifting, oriented textures.…”

Section: Representation Of Spatial Frequency At Orientation Pinwheel supporting

confidence: 83%

“…Finally, the location of the functional "border" between A17 and A18 was estimated based on the difference between the maximal intensity maps at 0.15 and 0.5 cpd (Bonhoeffer et al, 1995;Ohki et al, 2000). The TZ was defined with precision on the basis of the data obtained through GC activation in Figure 11G.…”

Section: Methodsmentioning

confidence: 99%

“…The signal at pinwheel was assumed to be weak. Indeed, a recent twophoton imaging study has shown that neurons located close to pinwheel centers have a weak response strength and that a large proportion of cells are unresponsive to an oriented, drifting grating (Ohki et al, 2006). For simplicity here, the signal at the pinwheel center was assumed to be of equal strength for the two curves.…”

Section: A Spatial Frequency Map In Area 17mentioning

confidence: 99%

“…Figures 6A and 10A show that the SF representation in the TZ exhibits local extrema that reflect the patchy organization present in both A17 and A18. The SF representation in the TZ is additionally constrained by the very different ranges of SFs that activate the respective areas, implying the existence of yet another SF gradient to ensure the continuity between the two areas (Bonhoeffer et al, 1995;Issa et al, 2000;Ohki et al, 2000). But previous approaches did not permit this gradient to be precisely characterized.…”

Section: A Spatial Frequency Map In Area 18mentioning

confidence: 99%

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Organization and Origin of Spatial Frequency Maps in Cat Visual Cortex

et al. 2013

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It remains controversial whether and how spatial frequency (SF) is represented tangentially in cat visual cortex. Several models were proposed, but there is no consensus. Worse still, some data indicate that the SF organization previously revealed by optical imaging techniques simply reflects non-stimulus-specific responses. Instead, stimulus-specific responses arise from the homogeneous distribution of geniculo-cortical afferents representing X and Y pathways. To clarify this, we developed a new imaging method allowing rapid stimulation with a wide range of SFs covering more than 6 octaves with only 0.2 octave resolution. A benefit of this method is to avoid error of high-pass filtering methods which systematically under-represent dominant selectivity features near pinwheel centers. We show unequivocally that SF is organized into maps in cat area 17 (A17) and area 18 (A18). The SF organization in each area displays a global anteroposterior SF gradient and local patches. Its layout is constrained to that of the orientation map, and it is suggested that both maps share a common functional architecture. A17 and A18 are bound at the transition zone by another SF gradient involving the geniculocortical and the callosal pathways. A model based on principal component analysis shows that SF maps integrate three different SFdependent channels. Two of these reflect the segregated excitatory input from X and Y geniculate cells to A17 and A18. The third one conveys a specific combination of excitatory and suppressive inputs to the visual cortex. In a manner coherent with anatomical and electrophysiological data, it is interpreted as originating from a subtype of Y geniculate cells.

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Section: Representation Of Spatial Frequency At Orientation Pinwheel supporting

confidence: 83%

Section: Methodsmentioning

confidence: 99%

Section: A Spatial Frequency Map In Area 17mentioning

confidence: 99%

Section: A Spatial Frequency Map In Area 18mentioning

confidence: 99%

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Organization and Origin of Spatial Frequency Maps in Cat Visual Cortex

et al. 2013

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“…If this suppression occurred monocularly, in a cell where there was an excitatory binocular interaction, it would be compatible with the data of both studies above. When a binocular stimulus is presented, raising responses above baseline, suppressive effects of adding a single frequency to one eye are often seen [36]. It is therefore possible that over the range of stimuli explored in all these studies, the two descriptions are functionally equivalent.…”

Section: Testing the Extended Energy Model: Suppressive Subunits?mentioning

confidence: 99%

Disparity processing in primary visual cortex

Henriksen

Tanabe

Cumming

2016

Phil. Trans. R. Soc. B

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One contribution of 15 to a theme issue 'Vision in our three-dimensional world'. The first step in binocular stereopsis is to match features on the left retina with the correct features on the right retina, discarding 'false' matches. The physiological processing of these signals starts in the primary visual cortex, where the binocular energy model has been a powerful framework for understanding the underlying computation. For this reason, it is often used when thinking about how binocular matching might be performed beyond striate cortex. But this step depends critically on the accuracy of the model, and real V1 neurons show several properties that suggest they may be less sensitive to false matches than the energy model predicts. Several recent studies provide empirical support for an extended version of the energy model, in which the same principles are used, but the responses of single neurons are described as the sum of several subunits, each of which follows the principles of the energy model. These studies have significantly improved our understanding of the role played by striate cortex in the stereo correspondence problem.This article is part of the themed issue 'Vision in our three-dimensional world'.

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Joint coding of shape and blur in area V4

2018

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Edge blur, a prevalent feature of natural images, is believed to facilitate multiple visual processes including segmentation and depth perception. Furthermore, image descriptions that explicitly combine blur and shape information provide complete representations of naturalistic scenes. Here we report the first demonstration of blur encoding in primate visual cortex: neurons in macaque V4 exhibit tuning for both object shape and boundary blur, with observed blur tuning not explained by potential confounds including stimulus size, intensity, or curvature. A descriptive model wherein blur selectivity is cast as a distinct neural process that modulates the gain of shape-selective V4 neurons explains observed data, supporting the hypothesis that shape and blur are fundamental features of a sufficient neural code for natural image representation in V4.

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Contributions of excitation and suppression in shaping spatial frequency selectivity of V1 neurons as revealed by binocular measurements

Cited by 10 publications

References 37 publications

Organization and Origin of Spatial Frequency Maps in Cat Visual Cortex

Organization and Origin of Spatial Frequency Maps in Cat Visual Cortex

Disparity processing in primary visual cortex

Joint coding of shape and blur in area V4

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