Intracortical Origins of Interocular Suppression in the Visual Cortex

Sengpiel, Frank; Vorobyov, Vasily

doi:10.1523/jneurosci.0862-05.2005

Cited by 74 publications

(122 citation statements)

References 49 publications

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“…Stage 1 can also accommodate masking from within and between the eyes across a range of orientations and spatial frequencies (Baker et al, 2007b;Baker & Meese, 2007). Elsewhere (Baker et al, 2007b), we have suggested that the two routes to suppression might exert their influence at distinct sequential stages (''stage 1a'' and ''stage 1b'') and speculated (Meese & Holmes 2002;Baker et al, 2007b) that the first of these stages is in the LGN (or retina, or layer 4 of visual cortex), for which there is physiological evidence (Freeman et al, 2002;Bonin et al, 2005;Li et al, 2005;Sengpiel & Vorobyov, 2005;Nolt et al, 2007) and for which the excitatory exponent is low (Derrington & Lennie, 1984;Sclar et al, 1990;Felisberti & Derrington, 1999) [though higher exponents (~2) are also found; Sclar et al, 1990;Felisberti & Derrington, 2001].…”

Section: The Excitatory and Suppressive Exponents (P And Q)mentioning

confidence: 94%

“…Models of suppressive contrast gain control have prompted a resurgence of interest in ocular interactions in psychophysics (Meese & Hess, 2004;Maehara & Goryo, 2005;Ding & Sperling, 2006;Meese et al, 2006;Tsuchiya et al, 2006;Medina et al, 2007;Baker et al, 2007aBaker et al, , 2007bWeiler et al, 2007), electrophysiology (Walker et al 1998;Truchard et al, 2000;Li et al, 2005;Sengpiel & Vorobyov, 2005), and functional imaging (Büchert et al, 2002). These studies have driven the development of binocular models of masking, where interocular suppression forms part of the divisive contrast gain control (Walker et al, 1998;Meese & Hess, 2004;Maehara & Goryo, 2005;Meese et al, 2006;Baker et al, 2007a).…”

Section: Gain Control and Ocular Interactionsmentioning

confidence: 99%

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A common contrast pooling rule for suppression within and between the eyes

2008

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Recent work has revealed multiple pathways for cross-orientation suppression in cat and human vision. In particular, ipsiocular and interocular pathways appear to assert their influence before binocular summation in human but have different (1) spatial tuning, (2) temporal dependencies, and (3) adaptation after-effects. Here we use mask components that fall outside the excitatory passband of the detecting mechanism to investigate the rules for pooling multiple mask components within these pathways. We measured psychophysical contrast masking functions for vertical 1 cycle/ deg sine-wave gratings in the presence of left or right oblique (645 deg) 3 cycles/deg mask gratings with contrast C%, or a plaid made from their sum, where each component (i) had contrast 0.5C i %. Masks and targets were presented to two eyes (binocular), one eye (monoptic), or different eyes (dichoptic). Binocular-masking functions superimposed when plotted against C, but in the monoptic and dichoptic conditions, the grating produced slightly more suppression than the plaid when C i $ 16%. We tested contrast gain control models involving two types of contrast combination on the denominator: (1) spatial pooling of the mask after a local nonlinearity (to calculate either root mean square contrast or energy) and (2) ''linear suppression' ' (Holmes & Meese, 2004, Journal of Vision 4, 1080-1089), involving the linear sum of the mask component contrasts. Monoptic and dichoptic masking were typically better fit by the spatial pooling models, but binocular masking was not: it demanded strict linear summation of the Michelson contrast across mask orientation. Another scheme, in which suppressive pooling followed compressive contrast responses to the mask components (e.g., oriented cortical cells), was ruled out by all of our data. We conclude that the different processes that underlie monoptic and dichoptic masking use the same type of contrast pooling within their respective suppressive fields, but the effects do not sum to predict the binocular case.

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Section: The Excitatory and Suppressive Exponents (P And Q)mentioning

confidence: 94%

Section: Gain Control and Ocular Interactionsmentioning

confidence: 99%

A common contrast pooling rule for suppression within and between the eyes

2008

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“…Early work supposed that XOS is caused by intra-cortical inhibition (Morrone et al, 1987;Heeger, 1992), but recent studies of cat physiology have challenged this view. For example, mask stimuli that drift or flicker too quickly to excite most cortical cells will nevertheless produce XOS, implying precortical involvement (Freeman et al, 2002;Sengpiel and Vorobyov, 2005). Possible origins include suppressive interactions in the lateral geniculate nucleus (LGN) (Levick et al, 1972;Bonin et al, 2005), saturation in the retina or LGN (Li et al, 2006;Priebe and Ferster, 2006;Smith et al, 2006) and depression at the thalamo-cortical synapse (Freeman et al, 2002).…”

mentioning

confidence: 99%

“…The last two accounts are applicable only when the mask and test are presented to the same eye (monoptic presentation) and overlap in space and time. However, in cat at least, XOS is not a purely ipsiocular process because when an oriented grating and crossoriented mask are presented to different eyes (dichoptic presentation), suppression is evident in striate cells (Sengpiel et al, 1995;Walker et al, 1998;Li et al, 2005;Sengpiel and Vorobyov, 2005). Although interocular suppression has been found in the LGN (e.g.…”

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confidence: 99%

Psychophysical evidence for two routes to suppression before binocular summation of signals in human vision

2007

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Abstract-Visual mechanisms in primary visual cortex are suppressed by the superposition of gratings perpendicular to their preferred orientations. A clear picture of this process is needed to (i) inform functional architecture of image-processing models, (ii) identify the pathways available to support binocular rivalry, and (iii) generally advance our understanding of early vision. Here we use monoptic sine-wave gratings and cross-orientation masking (XOM) to reveal two crossoriented suppressive pathways in humans, both of which occur before full binocular summation of signals. One is a within-eye (ipsiocular) pathway that is spatially broadband, immune to contrast adaptation and has a suppressive weight that tends to decrease with stimulus duration. The other pathway operates between the eyes (interocular), is spatially tuned, desensitizes with contrast adaptation and has a suppressive weight that increases with stimulus duration. When cross-oriented masks are presented to both eyes, masking is enhanced or diminished for conditions in which either ipsiocular or interocular pathways dominate masking, respectively. We propose that ipsiocular suppression precedes the influence of interocular suppression and tentatively associate the two effects with the lateral geniculate nucleus (or retina) and the visual cortex respectively. The interocular route is a good candidate for the initial pathway involved in binocular rivalry and predicts that interocular cross-orientation suppression should be found in cortical cells with predominantly ipsiocular drive.

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“…The way in which the human visual system behaves when stimuli are presented independently to each eye (dichoptic presentation) is of interest to researchers investigating the mechanisms underlying visual perception (Baker et al, 2007;Harrad and Hess, 1992;Levi et al, 1979;Li et al, 2005;Macknik and Martinez-Conde, 2004;Meese et al, 2006;Sengpiel, 1997;Sengpiel and Vorobyov, 2005). Functional magnetic resonance imaging (fMRI) can be combined with dichoptic stimulation procedures to explore the neural responses of the human brain under different perceptual states (Tong et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

A dichoptic projection system for visual psychophysics in fMRI scanners

Thompson

Farivar

Hansen

et al. 2008

Journal of Neuroscience Methods

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Here we describe a projection system based on the combination of linear polarizing filters, designed to allow dichoptic presentation of visual stimuli during fMRI experiments. Currently available MRI compatible dichoptic presentation systems are either highly expensive, require degradation of the projected stimulus such as the removal of all but one color or are difficult to deploy in a range of scanner environments. The system described here is relatively low in cost, requires no change in stimulus properties and could be used in many types of scanner facilities. We provide a verification of the system demonstrating minimal cross-talk between the images presented to the two eyes.

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Intracortical Origins of Interocular Suppression in the Visual Cortex

Cited by 74 publications

References 49 publications

A common contrast pooling rule for suppression within and between the eyes

A common contrast pooling rule for suppression within and between the eyes

Psychophysical evidence for two routes to suppression before binocular summation of signals in human vision

A dichoptic projection system for visual psychophysics in fMRI scanners

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