Asymmetries in visual acuity around the visual field

Barbot, Antoine; Xue, Shutian; Carrasco, Marisa

doi:10.31234/osf.io/ruwp9

Cited by 25 publications

(82 citation statements)

References 85 publications

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“…Similarly, performance fields asymmetries for SF sensitivity also weaken with increasing angular distance from the VM (Barbot et al, 2020). Notably, these studies are yet to measure contrastdefined performance fields across different stimulus eccentricities or sizes.…”

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confidence: 92%

“…Likewise, performance is better along the lower vertical meridian (LVM) than the upper vertical meridian (UVM) -a phenomenon termed the Vertical-Meridian Asymmetry (VMA) (Carrasco, Talgar, & Cameron, 2001). Together these asymmetries are called performance fields and have been identified for a range of tasks involving contrast sensitivity (Abrams, Nizam, & Carrasco, 2012;Baldwin et al, 2012;Cameron, Tai, & Carrasco, 2002;Levine & McAnany, 2005;Lundh, Lennerstrand, & Derefeldt, 1983;Pointer & Hess, 1989;Regan & Beverley, 1983;Rijsdijk, Kroon, & van der Wildt, 1980;Robson & Graham, 1981;Silva et al, 2008), contrast appearance (Fuller, Rodriguez, & Carrasco, 2008), spatial resolution (Barbot, Xue, & Carrasco, 2020;Carrasco, Williams, & Yeshurun, 2002;Talgar & Carrasco, 2002), temporal information accrual (Carrasco, Giordano, & McElree, 2004), crowding (Fortenbaugh, Silver, & Robertson, 2015;Greenwood, Szinte, Sayim, & Cavanagh, 2017), visual short term memory (Montaser-Kouhsari & Carrasco, 2009), and motion perception (Fuller & Carrasco, 2009).…”

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confidence: 99%

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Stimulus-dependent contrast sensitivity asymmetries around the visual field

Himmelberg

Winawer

Carrasco

2020

Preprint

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AbstractAsymmetries in visual performance at isoeccentric locations are known as performance fields. At a fixed eccentricity, visual performance is best along the horizontal, intermediate along the lower vertical, and poorest along the upper vertical meridian. These performance fields are pervasive across a range of visual tasks, including those mediated by contrast sensitivity. However, contrast performance fields have not been characterized with a systematic manipulation of stimulus spatial frequency, eccentricity, and size; three parameters that constrain contrast sensitivity. Further, individual differences in performance fields measurements have not been assessed. Here, we use an orientation discrimination task to characterize the pattern of contrast sensitivity across four isoeccentric locations along the cardinal meridians, and to examine whether and how this asymmetry pattern changes with systematic manipulation of stimulus spatial frequency (4 cpd to 8 cpd), eccentricity (4.5° to 9°), and size (3° visual angle to 6° visual angle). Our data demonstrate that contrast sensitivity is highest along the horizontal, intermediate along the lower vertical, and poorest along the upper vertical meridian. This pattern is consistent across stimulus parameter manipulations, even though they cause profound shifts in contrast sensitivity. Eccentricity-dependent decreases in contrast sensitivity can be compensated for by scaling stimulus size alone. Moreover, we find that individual variability in the strength of performance field asymmetries is consistent across conditions. This study is the first to systematically and jointly manipulate, and compare, contrast performance fields across spatial frequency, eccentricity, and size, and to address individual variability in performance fields.

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confidence: 92%

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confidence: 99%

Stimulus-dependent contrast sensitivity asymmetries around the visual field

Himmelberg

Winawer

Carrasco

2020

Preprint

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“…[73]). This nasal-temporal asymmetry, although interesting, is beyond the focus of this paper, as the asymmetries in performance we observe are found in both binocular and monocular experiments [10, 32]. Overall, the greater emphasis on the horizontal is substantially greater in the mRGCs than the cones.…”

Section: Resultsmentioning

confidence: 57%

“…The asymmetries gradually fall-off with angular distance from the meridians [74]. This gradual decrease in radial asymmetry in cortex parallels the gradual decrease in contrast sensitivity [10, 25, 26] and spatial frequency sensitivity [32] with angular distance from the cardinal meridians. Measurements of cone density and retinal ganglion cell density have emphasized the meridians, so there is less information regarding how the asymmetries vary with angular distance from the meridians.…”

Section: Discussionmentioning

confidence: 96%

“…At iso-eccentric locations, performance is better along the horizontal than vertical meridian (horizontal-vertical anisotropy or “HVA” e.g., [9–12]) and better along the lower than upper vertical meridian (vertical-meridian asymmetry or “VMA” [10–14]). These radial asymmetries are observed in many different visual tasks, such as those mediated by contrast sensitivity [10–12, 15–28] and spatial resolution [9, 13, 15, 16, 29–32], contrast appearance [33], visual search [34–42], crowding [14, 42–45], and tasks that are thought to recruit higher visual areas such as visual working memory [31].…”

Section: Introductionmentioning

confidence: 99%

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Asymmetries around the visual field: From retina to cortex to behavior

Kupers

Benson

Carrasco

et al. 2020

Preprint

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Visual performance varies around the visual field. It is best near the fovea compared to the periphery, and at iso-eccentric locations it is best on the horizontal, intermediate on the lower, and poorest on the upper meridian. The fovea-to-periphery performance decline is linked to the decreases in cone density, retinal ganglion cell (RGC) density, and V1 cortical magnification factor (CMF) as eccentricity increases. The origins of radial asymmetries are not well understood. Optical quality and cone density vary across the retina, but recent computational modeling has shown that these factors can only account for a small percentage of behavior. Here, we investigate how visual processing beyond the cones contributes to radial asymmetries in performance. First, we quantify the extent of asymmetries in cone density, midget RGC density, and V1-V2 CMF. We find that both radial asymmetries and eccentricity gradients are amplified from cones to mRGCs, and from mRGCs to cortex. Second, we extend our previously published computational observer model to quantify the contribution of spatial filtering by mRGCs to behavioral asymmetries. Starting with photons emitted by a visual display, the model simulates the effect of human optics, fixational eye movements, cone isomerizations and mRGC spatial filtering. The model performs a forced choice orientation discrimination task on mRGC responses using a linear support vector machine classifier. The model shows radial asymmetries in performance that are larger than those from a model operating on the cone outputs, but considerably smaller than those observed from human performance. We conclude that spatial filtering properties of mRGCs contribute to radial performance differences, but that a full account of these differences will entail a large contribution from cortical representations.

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Seeing and extrapolating motion trajectories share common informative activation patterns in primary visual cortex

Agostino

Merkel

Ball

et al. 2022

Human Brain Mapping

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The natural environment is dynamic and moving objects become constantly occluded, engaging the brain in a challenging completion process to estimate where and when the object might reappear. Although motion extrapolation is critical in daily life—imagine crossing the street while an approaching car is occluded by a larger standing vehicle—its neural underpinnings are still not well understood. While the engagement of low‐level visual cortex during dynamic occlusion has been postulated, most of the previous group‐level fMRI‐studies failed to find evidence for an involvement of low‐level visual areas during occlusion. In this fMRI‐study, we therefore used individually defined retinotopic maps and multivariate pattern analysis to characterize the neural basis of visible and occluded changes in motion direction in humans. To this end, participants learned velocity‐direction change pairings (slow motion‐upwards; fast motion‐downwards or vice versa) during a training phase without occlusion and judged the change in stimulus direction, based on its velocity, during a following test phase with occlusion. We find that occluded motion direction can be predicted from the activity patterns during visible motion within low‐level visual areas, supporting the notion of a mental representation of motion trajectory in these regions during occlusion.

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Asymmetries in visual acuity around the visual field

Cited by 25 publications

References 85 publications

Stimulus-dependent contrast sensitivity asymmetries around the visual field

Stimulus-dependent contrast sensitivity asymmetries around the visual field

Asymmetries around the visual field: From retina to cortex to behavior

Seeing and extrapolating motion trajectories share common informative activation patterns in primary visual cortex

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