Your search keyword '"Fovea Centralis physiology"' showing total 1,243 results

51. Perceptual-driven approach to statically foveated head-mounted displays.

Author

Lyu P and Hua H

Subjects

Equipment Design, Eye Movements physiology, Fovea Centralis physiology, Humans, Normal Distribution, Optical Phenomena, Smart Glasses, Visual Acuity physiology, Wearable Electronic Devices

Abstract

A foveated display is a promising technique to realize displays offering both a large field of view (FOV) and high spatial resolution. Although several prior works have attempted to apply a foveation method to the design of a head-mounted display (HMD) system, the common method is based on a dual-resolution dynamic foveation scheme which is inevitably complex and has a high cost due to the requirements for multiple display sources, a 2D steering mechanism, and eye tracker. In this paper, a new perceptual-driven approach to the design of a statically foveated HMD is proposed with the goal of offering a wide FOV across which the degradation of the perceived image resolution is nearly imperceptible or minimal within regions of frequent eye movements. Compared to a dual-resolution discrete and dynamic foveation approach in the prior art, the static foveation approach will not only maintain resolution continuity but also eliminate the need for a scanning mechanism, multiple display sources, and an eyetracker, and therefore minimize hardware complexity. We present the general approach for creating a static foveation scheme, performance metrics for evaluating the perceived image quality, and the process of optimizing a foveation scheme to meet different requirements. Finally, we experimentally demonstrate and validate the proposed foveation scheme using a testbed system. Overall, we demonstrate a statically foveated scheme is capable of offering a display with a total 160° FOV, a constant resolution of 0.5 or 1 arcminutes per pixel within the ±10° region where frequent eye movements occur, an adequate resolution no less than 45% of peak resolution within the parafovea region of ±30°, and a data sampling efficiency as high as 90%.

Published

2021

52. Fast and nonuniform dynamics of perisaccadic vision in the central fovea.

Author

Intoy J, Mostofi N, and Rucci M

Subjects

Adult, Attention physiology, Eye-Tracking Technology instrumentation, Female, Fixation, Ocular physiology, Fovea Centralis metabolism, Humans, Male, Movement physiology, Photic Stimulation methods, Vision, Ocular physiology, Visual Perception physiology, Fovea Centralis physiology, Saccades physiology, Visual Acuity physiology

Abstract

Humans use rapid eye movements (saccades) to inspect stimuli with the foveola, the region of the retina where receptors are most densely packed. It is well established that visual sensitivity is generally attenuated during these movements, a phenomenon known as saccadic suppression. This effect is commonly studied with large, often peripheral, stimuli presented during instructed saccades. However, little is known about how saccades modulate the foveola and how the resulting dynamics unfold during natural visual exploration. Here we measured the foveal dynamics of saccadic suppression in a naturalistic high-acuity task, a task designed after primates' social grooming, which-like most explorations of fine patterns-primarily elicits minute saccades (microsaccades). Leveraging on recent advances in gaze-contingent display control, we were able to systematically map the perisaccadic time course of sensitivity across the foveola. We show that contrast sensitivity is not uniform across this region and that both the extent and dynamics of saccadic suppression vary within the foveola. Suppression is stronger and faster in the most central portion, where sensitivity is generally higher and selectively rebounds at the onset of a new fixation. These results shed light on the modulations experienced by foveal vision during the saccade-fixation cycle and explain some of the benefits of microsaccades., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021

53. Neural evidence for lexical parafoveal processing.

Author

Pan Y, Frisson S, and Jensen O

Subjects

Eye Movements physiology, Female, Fixation, Ocular physiology, Fovea Centralis physiology, Humans, Male, Models, Neurological, Visual Cortex physiology, Visual Perception physiology, Young Adult, Macula Lutea physiology, Reading

Abstract

In spite of the reduced visual acuity, parafoveal information plays an important role in natural reading. However, competing models on reading disagree on whether words are previewed parafoveally at the lexical level. We find neural evidence for lexical parafoveal processing by combining a rapid invisible frequency tagging (RIFT) approach with magnetoencephalography (MEG) and eye-tracking. In a silent reading task, target words are tagged (flickered) subliminally at 60 Hz. The tagging responses measured when fixating on the pre-target word reflect parafoveal processing of the target word. We observe stronger tagging responses during pre-target fixations when followed by low compared with high lexical frequency targets. Moreover, this lexical parafoveal processing is associated with individual reading speed. Our findings suggest that reading unfolds in the fovea and parafovea simultaneously to support fluent reading., (© 2021. The Author(s).)

Published

2021

54. The Relationship Between Visual Sensitivity and Eccentricity, Cone Density and Outer Segment Length in the Human Foveola.

Author

Domdei N, Reiniger JL, Holz FG, and Harmening WM

Subjects

Adult, Cell Count, Female, Fovea Centralis physiology, Humans, Male, Ophthalmoscopy methods, Retinal Cone Photoreceptor Cells cytology, Fovea Centralis cytology, Retinal Cone Photoreceptor Cells physiology, Rod Cell Outer Segment physiology, Tomography, Optical Coherence methods, Visual Acuity

Abstract

Purpose: The cellular topography of the human foveola, the central 1° diameter of the fovea, is strikingly non-uniform, with a steep increase of cone photoreceptor density and outer segment (OS) length toward its center. Here, we assessed to what extent the specific cellular organization of the foveola of an individual is reflected in visual sensitivity and if sensitivity peaks at the preferred retinal locus of fixation (PRL)., Methods: Increment sensitivity to small-spot, cone-targeted visual stimuli (1 × 1 arcmin, 543-nm light) was recorded psychophysically in four human participants at 17 locations concentric within a 0.2° diameter on and around the PRL with adaptive optics scanning laser ophthalmoscopy-based microstimulation. Sensitivity test spots were aligned with cell-resolved maps of cone density and cone OS length., Results: Peak sensitivity was at neither the PRL nor the topographical center of the cone mosaic. Within the central 0.1° diameter, a plateau-like sensitivity profile was observed. Cone density and maximal OS length differed significantly across participants, correlating with their peak sensitivity. Based on these results, biophysical simulation allowed to develop a model of visual sensitivity in the foveola, with distance from the PRL (eccentricity), cone density, and OS length as parameters., Conclusions: Small-spot sensitivity thresholds in healthy retinas will help to establish the range of normal foveolar function in cell-targeted vision testing. Because of the high reproducibility in replicate testing, threshold variability not explained by our model is assumed to be caused by individual cone and bipolar cell weighting at the specific target locations.

Published

2021

55. Foveal vision.

Author

Tuten WS and Harmening WM

Subjects

Humans, Visual Fields physiology, Fovea Centralis physiology, Vision, Ocular physiology

Abstract

William Tuten and Wolf Harmening introduce the anatomical and functional signatures of foveated vision in humans., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

56. Design of a near-eye display measurement system using an anthropomorphic vision imaging method.

Author

Zhang Q, Song W, Hu X, Hu K, Weng D, Liu Y, and Wang Y

Subjects

Equipment Design, Humans, Optical Devices, Accommodation, Ocular physiology, Fovea Centralis physiology, Optical Imaging instrumentation, Pupil physiology, Vision, Ocular physiology

Abstract

We developed a new near-eye display measurement system using anthropomorphic vision imaging to measure the key parameters of near-eye displays, including field-of-view (FOV), angular resolution, eye box, and virtual image depth. The characteristics of the human eye, such as pupil position, pupil size variation, accommodation function, and the high resolution of the fovea, are imitated by the proposed measurement system. A FOV scanning structure, together with a non-vignetting image-telecentric lens system, captures the virtual image from the near-eye display by imitating human eye function. As a proof-of-concept, a prototype device was used to obtain large-range, high-resolution measurements for key parameters of near-eye displays.

Published

2021

57. Active vision at the foveal scale in the primate superior colliculus.

Author

Hafed ZM, Chen CY, Tian X, Baumann MP, and Zhang T

Subjects

Animals, Behavior, Animal physiology, Eye Movements physiology, Fovea Centralis physiology, Motor Activity physiology, Primates physiology, Psychomotor Performance physiology, Superior Colliculi physiology, Visual Perception physiology

Abstract

The primate superior colliculus (SC) has recently been shown to possess both a large foveal representation as well as a varied visual processing repertoire. This structure is also known to contribute to eye movement generation. Here, we describe our current understanding of how SC visual and movement-related signals interact within the realm of small eye movements associated with the foveal scale of visuomotor behavior. Within the SC's foveal representation, there is a full spectrum of visual, visual-motor, and motor-related discharge for fixational eye movements. Moreover, a substantial number of neurons only emit movement-related discharge when microsaccades are visually guided, but not when similar movements are generated toward a blank. This represents a particularly striking example of integrating vision and action at the foveal scale. Beyond that, SC visual responses themselves are strongly modulated, and in multiple ways, by the occurrence of small eye movements. Intriguingly, this impact can extend to eccentricities well beyond the fovea, causing both sensitivity enhancement and suppression in the periphery. Because of large foveal magnification of neural tissue, such long-range eccentricity effects are neurally warped into smaller differences in anatomical space, providing a structural means for linking peripheral and foveal visual modulations around fixational eye movements. Finally, even the retinal-image visual flows associated with tiny fixational eye movements are signaled fairly faithfully by peripheral SC neurons with relatively large receptive fields. These results demonstrate how studying active vision at the foveal scale represents an opportunity for understanding primate vision during natural behaviors involving ever-present foveating eye movements. NEW & NOTEWORTHY The primate superior colliculus (SC) is ideally suited for active vision at the foveal scale: it enables detailed foveal visual analysis by accurately driving small eye movements, and it also possesses a visual processing machinery that is sensitive to active eye movement behavior. Studying active vision at the foveal scale in the primate SC is informative for broader aspects of active perception, including the overt and covert processing of peripheral extra-foveal visual scene locations.

Published

2021

58. Contrast Sensitivity on 1/f Noise Is More Greatly Impacted by Older Age for the Fovea Than Parafovea.

Author

Srinivasan R, Turpin A, and McKendrick AM

Subjects

Adult, Aged, Female, Humans, Male, Middle Aged, Psychometrics, Sensory Thresholds physiology, Visual Field Tests methods, Visual Fields physiology, Young Adult, Aging physiology, Contrast Sensitivity physiology, Fovea Centralis physiology

Abstract

Significance: Contrast sensitivity changes across the visual field with age and is often measured clinically with various forms of perimetry on plain backgrounds. In daily life, the visual scene is more complicated, and therefore, the standard clinical measures of contrast sensitivity may not predict a patient's visual experience in more natural environments., Purpose: This study aims to determine whether contrast thresholds in older adults are different from younger adults when measured on a 1/f noise background (a nonuniform background whose spatial frequency content is similar to those present in the natural vision environments)., Methods: Twenty younger (age range, 20 to 35 years) and 20 older adults (age range, 61 to 79 years) with normal ocular health were recruited. Contrast thresholds were measured for a Gabor patch of 6 cycles per degree (sine wave grating masked by a Gaussian envelope of standard deviation 0.17°) presented on 1/f noise background (root-mean-square contrast, 0.05 and 0.20) that subtended 15° diameter of the central visual field. The stimulus was presented at four eccentricities (0°, 2°, 4°, and 6°) along the 45° meridian in the noise background, and nine contrast levels were tested at each eccentricity. The proportion of correct responses for detecting the target at each eccentricity was obtained, and psychometric functions were fit to estimate the contrast threshold., Results: Older adults demonstrate increased contrast thresholds compared with younger adults. There was an eccentricity-dependent interaction with age, with the difference between groups being highest in the fovea compared with other eccentricities. Performance was similar for the two noise backgrounds tested., Conclusions: Our results revealed a strong eccentricity dependence in performance between older and younger adults, highlighting age-related differences in the contrast detection mechanisms between fovea and parafovea for stimuli presented on nonuniform backgrounds., Competing Interests: Conflict of Interest Disclosure: Authors AMM and AT receive research support from Haag-Streit AG for work unrelated to the content of this article., (Copyright © 2021 American Academy of Optometry.)

Published

2021

59. Evaluation of 3D Pointing Accuracy in the Fovea and Periphery in Immersive Head-Mounted Display Environments.

Author

Katzakis N, Chen L, Ariza O, Teather RJ, and Steinicke F

Subjects

Adult, Feedback, Sensory physiology, Humans, Young Adult, Fovea Centralis physiology, Hand physiology, Imaging, Three-Dimensional methods, Smart Glasses, Virtual Reality

Abstract

The coupling between perception and action has seldom been explored in sophisticated motor behaviour such as 3D pointing. In this study, we investigated how 3D pointing accuracy, measured by a depth estimation task, could be affected by the target appearing in different visual eccentricities. Specifically, we manipulated the visual eccentricity of the target and its depth in virtual reality. Participants wore a head-mounted-display with an integrated eye-tracker and docked a cursor into a target. We adopted a within-participants factorial design with three variables. The first variable is Eccentricity: the location of the target on one of five horizontal eccentricities (left far periphery, left near periphery, foveal, right near periphery and right far periphery). The second variable is Depth at three levels and the third variable is Feedback Loop with two levels: open/closed. Eccentricity is refactored into Motion Correspondence between the starting location of the cursor and the target location with four levels: periphery to fovea, fovea to periphery, periphery to periphery, fovea to fovea. The results showed that the pointing accuracy is modulated mainly by the target locations rather than the initial locations of the effector (hand). Visible feedback during pointing improved performance.

Published

2021

60. Attention selectively enhances stimulus information for surround over foveal stimulus representations in occipital cortex.

Author

Goddard E and Mullen KT

Subjects

Adult, Brain Mapping methods, Female, Humans, Magnetic Resonance Imaging methods, Male, Occipital Lobe diagnostic imaging, Photic Stimulation, Visual Cortex diagnostic imaging, Visual Fields, Young Adult, Attention physiology, Fovea Centralis physiology, Occipital Lobe physiology, Visual Cortex physiology, Visual Perception physiology

Abstract

By attending to part of a visual scene, we can prioritize processing of the most relevant visual information and so use our limited resources effectively. Previous functional magnetic resonance imaging (fMRI) work has shown that attention can increase overall blood-oxygen-level-dependent (BOLD) signal responsiveness but also enhances the stimulus information in terms of classifier performance. Here, we investigate how these effects vary across the visual field. We compare attention-enhanced fMRI-BOLD amplitude responses and classifier accuracy in fovea and surrounding stimulus regions using a set of four simple stimuli subdivided into a foveal region (1.4° diameter) and a surround region (15° diameter). We found dissociations between the effects of attention on average response and in enhancing stimulus information. In early visual cortex, we found that attention increased the amplitude of responses to both foveal and surround parts of the stimuli and increased classifier performance only for the surround stimulus. Conversely, ventral visual areas showed less change in average response but greater changes in decoding. Unlike for early visual cortex, in the ventral visual cortex attention produced similar changes in decoding for center and surround stimuli.

Published

2021

61. Parafoveal degradation during reading reduces preview costs only when it is not perceptually distinct.

Author

Vasilev MR, Yates M, Prueitt E, and Slattery TJ

Subjects

Adult, Attention, Fixation, Ocular, Humans, Eye Movements physiology, Fovea Centralis physiology, Pattern Recognition, Visual physiology, Perceptual Masking physiology, Reading

Abstract

There is a growing understanding that the parafoveal preview effect during reading may represent a combination of preview benefits and preview costs due to interference from parafoveal masks. It has been suggested that visually degrading the parafoveal masks may reduce their costs, but adult readers were later shown to be highly sensitive to degraded display changes. Four experiments examined how preview benefits and preview costs are influenced by the perception of distinct parafoveal degradation at the target word location. Participants read sentences with four preview types (identity, orthographic, phonological, and letter-mask preview) and two levels of visual degradation (0% vs. 20%). The distinctiveness of the target word degradation was either eliminated by degrading all words in the sentence (Experiments 1a-2a) or remained present, as in previous research (Experiments 1b-2b). Degrading the letter masks resulted in a reduction in preview costs, but only when all words in the sentence were degraded. When degradation at the target word location was perceptually distinct, it induced costs of its own, even for orthographically and phonologically related previews. These results confirm previous reports that traditional parafoveal masks introduce preview costs that overestimate the size of the true benefit. However, they also show that parafoveal degradation has the unintended consequence of introducing additional costs when participants are aware of distinct degradation on the target word. Parafoveal degradation appears to be easily perceived and may temporarily orient attention away from the reading task, thus delaying word processing.

Published

2021

62. Parafoveal pre-processing in children reading English: The importance of external letters.

Author

Milledge SV, Blythe HI, and Liversedge SP

Subjects

Adult, Child, Female, Humans, Male, Young Adult, Fixation, Ocular physiology, Fovea Centralis physiology, Pattern Recognition, Visual physiology, Psycholinguistics, Reading

Abstract

Although previous research has demonstrated that for adults external letters of words are more important than internal letters for lexical processing during reading, no comparable research has been conducted with children. This experiment explored, using the boundary paradigm during silent sentence reading, whether parafoveal pre-processing in English is more affected by the manipulation of external letters or internal letters, and whether this differs between skilled adult and beginner child readers. Six previews were generated: identity (e.g., monkey); external letter manipulations where either the beginning three letters of the word were substituted (e.g., rackey) or the last three letters of the word were substituted (e.g., monhig); internal letter manipulations; e.g., machey, mochiy); and an unrelated control condition (e.g., rachig). Results indicate that both adults and children undertook pre-processing of words in their entirety in the parafovea, and that the manipulation of external letters in preview was more harmful to participants' parafoveal pre-processing than internal letters. The data also suggest developmental change in the time course of pre-processing, with children's pre-processing delayed compared to that of adults. These results not only provide further evidence for the importance of external letters to parafoveal processing and lexical identification for adults, but also demonstrate that such findings can be extended to children.

Published

2021

63. A Comparison of Foveal and Peripheral Contour Interaction and Crowding.

Author

Marten-Ellis SM and Bedell HE

Subjects

Humans, Crowding, Fovea Centralis physiology, Pattern Recognition, Visual physiology, Perceptual Masking physiology, Visual Acuity physiology

Abstract

Significance: Performance on clinical tests of visual acuity can be influenced by the presence of nearby targets. This study compared the influence of neighboring flanking bars and letters on foveal and peripheral letter identification., Purpose: Contour interaction and crowding refer to an impairment of visual resolution or discrimination produced by different types of flanking stimuli. This study compared the impairment of percent correct letter identification that is produced in normal observers when a target letter is surrounded by an array of four flanking bars (contour interaction) or four flanking letters (crowding)., Methods: Performance was measured at the fovea and at eccentricities of 1.25, 2.5, and 5° for photopic (200 cd/m2) and mesopic stimuli (0.5 cd/m2) and a range of target-to-flanker separations., Results: Consistent with previous reports, foveal contour interaction and crowding were more pronounced for photopic than mesopic targets. However, no statistically significant difference existed between foveal contour-interaction and crowding functions at either luminance level. On the other hand, flanking bars produced much less impairment of letter identification than letter flankers at all three peripheral locations, indicating that crowding is more severe than contour interaction in peripheral vision. In contrast to the fovea, peripheral crowding and contour-interaction functions did not differ systematically for targets of photopic and mesopic luminance., Conclusion: The similarity between foveal contour interaction and crowding and the dissimilarity between peripheral contour interaction and crowding suggest the involvement of different mechanisms at different retinal locations., Competing Interests: Conflict of Interest Disclosure: No conflict of interest exists for either author., (Copyright © 2020 American Academy of Optometry.)

Published

2021

64. DeepFoveaNet: Deep Fovea Eagle-Eye Bioinspired Model to Detect Moving Objects.

Author

Guzman-Pando A and Chacon-Murguia MI

Subjects

Algorithms, Animals, Databases, Factual, Eagles physiology, Fovea Centralis physiology, Humans, Movement physiology, Video Recording, Image Processing, Computer-Assisted methods, Models, Biological, Neural Networks, Computer, Vision, Binocular physiology

Abstract

Birds of prey especially eagles and hawks have a visual acuity two to five times better than humans. Among the peculiar characteristics of their biological vision are that they have two types of foveae; one shallow fovea used in their binocular vision, and a deep fovea for monocular vision. The deep fovea allows these birds to see objects at long distances and to identify them as possible prey. Inspired by the biological functioning of the deep fovea a model called DeepFoveaNet is proposed in this paper. DeepFoveaNet is a convolutional neural network model to detect moving objects in video sequences. DeepFoveaNet emulates the monocular vision of birds of prey through two Encoder-Decoder convolutional neural network modules. This model combines the capacity of magnification of the deep fovea and the context information of the peripheral vision. Unlike algorithms to detect moving objects, ranked in the first places of the Change Detection database (CDnet14), DeepFoveaNet does not depend on previously trained neural networks, neither on a huge number of training images for its training. Besides, its architecture allows it to learn spatiotemporal information of the video. DeepFoveaNet was evaluated in the CDnet14 database achieving high performance and was ranked as one of the ten best algorithms. The characteristics and results of DeepFoveaNet demonstrated that the model is comparable to the state-of-the-art algorithms to detect moving objects, and it can detect very small moving objects through its deep fovea model that other algorithms cannot detect.

Published

2021

65. Technical Report: The Mechanism of Contour Interaction Differs in the Fovea and Periphery.

Author

Pluháček F, Bedell HE, Siderov J, and Kratkoczká D

Subjects

Adult, Female, Humans, Light, Male, Sensory Thresholds physiology, Visual Fields physiology, Color Vision physiology, Form Perception physiology, Fovea Centralis physiology

Abstract

Significance: Both foveal and peripheral contour interactions are based on, as yet, unexplained neural mechanisms. Our results show that, unlike foveal contour interaction, peripheral contour interaction cannot be explained on the basis of the antagonistic structure of neural receptive fields., Purpose: Foveal contour interaction is markedly reduced for mesopic compared with photopic targets. This finding is consistent with an explanation based on the antagonistic structure of neural receptive fields. However, no reduction was found for low-luminance targets in the periphery, possibly because the luminances used previously remained substantially above peripheral scotopic detection thresholds. In this study, we compared foveal and peripheral contour interactions for long-wavelength photopic and mesopic targets, which would be expected to significantly elevate the peripheral retinal detection threshold., Methods: Five normal observers viewed a randomly selected Sloan letter surrounded by four flanking bars at several edge-to-edge separations (min arc). Photopic and mesopic stimuli were viewed foveally and at 6° peripherally through a selective red filter that ensured that mesopic targets were within 1 log unit of detection threshold at both retinal locations., Results: Whereas the magnitude of foveal contour interaction was substantially less at mesopic compared with photopic luminance (20 vs. 46% reduction of percent correct, on average), no significant difference was observed in peripheral contour interaction, which had average mesopic and photopic magnitudes of 38 and 40%. Moreover, confusion matrices representing photopic and mesopic contour interaction differed in the fovea but not in the periphery. The extent of contour interaction did not change with luminance at either retinal location., Conclusions: Our results indicate that, although the characteristics of foveal contour interaction can be accounted for by the antagonistic structure of neural receptive fields, the same mechanism is not compatible with the characteristics of peripheral contour interaction.

Published

2020

66. Events are perceived earlier in peripheral vision.

Author

Jovanovic L and Mamassian P

Subjects

Female, Fovea Centralis physiology, Humans, Male, Photic Stimulation methods, Reaction Time physiology, Visual Cortex physiology, Visual Fields physiology

Abstract

Visual perception is not instantaneous. It takes a few milliseconds for light to be transduced in photoreceptors and tens of milliseconds more for neuronal spikes to occur at successive levels of the visual hierarchy. Moreover, the latency of responses varies across the visual field and the cortical hierarchy. In peripheral compared to central vision, the impulse response of primates' ganglion cells has a higher peak occurring at shorter latency [1], and yet humans' primary visual cortex is activated later [2]. The diversity of these physiological results makes it difficult to predict when is the perceived present [3], especially when events are presented across the visual field. This question cannot be directly addressed with paradigms traditionally used to investigate perceptual latencies. In particular, response times are not suitable because they are influenced by decisional mechanisms, motor-related processing or compensatory mechanisms [4,5]. Likewise, temporal order judgements between foveal and peripheral stimuli are not suitable because humans overweigh foveal information when making perceptual decisions [6]. Here we explicitly asked participants to estimate when a stimulus is perceived within a fixed duration temporal interval, rather than relative to another stimulus presented in its near temporal proximity. We show that the perceived time of a visual event depends on its position in the visual field. We find a large bias to report events earlier when they were presented in the periphery., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

67. A review of interactions between peripheral and foveal vision.

Author

Stewart EEM, Valsecchi M, and Schütz AC

Subjects

Humans, Visual Cortex physiology, Visual Fields physiology, Fovea Centralis physiology, Vision, Ocular physiology, Visual Perception physiology

Abstract

Visual processing varies dramatically across the visual field. These differences start in the retina and continue all the way to the visual cortex. Despite these differences in processing, the perceptual experience of humans is remarkably stable and continuous across the visual field. Research in the last decade has shown that processing in peripheral and foveal vision is not independent, but is more directly connected than previously thought. We address three core questions on how peripheral and foveal vision interact, and review recent findings on potentially related phenomena that could provide answers to these questions. First, how is the processing of peripheral and foveal signals related during fixation? Peripheral signals seem to be processed in foveal retinotopic areas to facilitate peripheral object recognition, and foveal information seems to be extrapolated toward the periphery to generate a homogeneous representation of the environment. Second, how are peripheral and foveal signals re-calibrated? Transsaccadic changes in object features lead to a reduction in the discrepancy between peripheral and foveal appearance. Third, how is peripheral and foveal information stitched together across saccades? Peripheral and foveal signals are integrated across saccadic eye movements to average percepts and to reduce uncertainty. Together, these findings illustrate that peripheral and foveal processing are closely connected, mastering the compromise between a large peripheral visual field and high resolution at the fovea.

Published

2020

68. Analysis of Parvocellular and Magnocellular Visual Pathways in Human Retina.

Author

Masri RA, Grünert U, and Martin PR

Subjects

Adult, Female, Fovea Centralis physiology, Humans, Male, Middle Aged, Retinal Bipolar Cells physiology, Retinal Cone Photoreceptor Cells physiology, Retinal Ganglion Cells physiology, Visual Acuity, Retina cytology, Retina physiology, Visual Pathways cytology, Visual Pathways physiology

Abstract

Two main subcortical pathways serving conscious visual perception are the midget-parvocellular (P), and the parasol-magnocellular (M) pathways. It is generally accepted that the P pathway serves red-green color vision, but the relative contribution of P and M pathways to spatial vision is a long-standing and unresolved issue. Here, we mapped the spatial sampling properties of P and M pathways across the human retina. Data were obtained from immunolabeled vertical sections of six postmortem male and female human donor retinas and imaged using high-resolution microscopy. Cone photoreceptors, OFF-midget bipolar cells (P pathway), OFF-diffuse bipolar (DB) types DB3a and DB3b (M pathway), and ganglion cells were counted along the temporal horizontal meridian, taking foveal spatial distortions (postreceptoral displacements) into account. We found that the density of OFF-midget bipolar and OFF-midget ganglion cells can support one-to-one connections to 1.05-mm (3.6°) eccentricity. One-to-one connections of cones to OFF-midget bipolar cells are present to at least 10-mm (35°) eccentricity. The OFF-midget ganglion cell array acuity is well-matched to photopic spatial acuity measures throughout the central 35°, but the OFF-parasol array acuity is well below photopic spatial acuity, supporting the view that the P pathway underlies high-acuity spatial vision. Outside the fovea, array acuity of both OFF-midget and OFF-DB cells exceeds psychophysical measures of photopic spatial acuity. We conclude that parasol and midget pathway bipolar cells deliver high-acuity spatial signals to the inner plexiform layer, but outside the fovea, this spatial resolution is lost at the level of ganglion cells. SIGNIFICANCE STATEMENT We make accurate maps of the spatial density and distribution of neurons in the human retina to aid in understanding human spatial vision, interpretation of diagnostic tests, and the implementation of therapies for retinal diseases. Here, we map neurons involved with the midget-parvocellular (P pathway) and parasol-magnocellular (M pathway) through human retina. We find that P-type bipolar cells outnumber M-type bipolar cells at all eccentricities. We show that cone photoreceptors and P-type pathway bipolar cells are tightly connected throughout the retina, but that spatial resolution is lost at the level of the ganglion cells. Overall, the results support the view that the P pathway is specialized to serve both high acuity vision and red-green color vision., (Copyright © 2020 the authors.)

Published

2020

69. Accuracy and precision of small saccades.

Author

Poletti M, Intoy J, and Rucci M

Subjects

Adult, Eye Movements physiology, Female, Fixation, Ocular physiology, Fovea Centralis physiology, Humans, Male, Oculomotor Nerve physiology, Orientation physiology, Young Adult, Saccades physiology

Abstract

Despite recent advances on the mechanisms and purposes of fine oculomotor behavior, a rigorous assessment of the precision and accuracy of the smallest saccades is still lacking. Yet knowledge of how effectively these movements shift gaze is necessary for understanding their functions and is helpful in further elucidating their motor underpinnings. Using a combination of high-resolution eye-tracking and gaze-contingent control, here we examined the accuracy and precision of saccades aimed toward targets ranging from [Formula: see text] to [Formula: see text] eccentricity. We show that even small saccades of just 14-[Formula: see text] are very effective in centering the stimulus on the retina. Furthermore, we show that for a target at any given eccentricity, the probability of eliciting a saccade depends on its efficacy in reducing the foveal offset. The pattern of results reported here is consistent with current knowledge on the motor mechanisms of microsaccade production.

Published

2020

70. Repeatability of binarization thresholding methods for optical coherence tomography angiography image quantification.

Author

Mehta N, Braun PX, Gendelman I, Alibhai AY, Arya M, Duker JS, and Waheed NK

Subjects

Adult, Choroid physiology, Female, Healthy Volunteers, Humans, Image Processing, Computer-Assisted methods, Male, Fovea Centralis physiology, Retinal Vessels physiology, Tomography, Optical Coherence methods

Abstract

Binarization is a critical step in analysis of retinal optical coherence tomography angiography (OCTA) images, but the repeatability of metrics produced from various binarization methods has not been fully assessed. This study set out to examine the repeatability of OCTA quantification metrics produced using different binarization thresholding methods, all of which have been applied in previous studies, across multiple devices and plexuses. Successive 3 × 3 mm foveal OCTA images of 13 healthy eyes were obtained on three different devices. For each image, contrast adjustments, 3 image processing techniques (linear registration, histogram normalization, and contrast-limited adaptive histogram equalization), and 11 binarization thresholding methods were independently applied. Vessel area density (VAD) and vessel length were calculated for retinal vascular images. Choriocapillaris (CC) images were quantified for VAD and flow deficit metrics. Repeatability, measured using the intra-class correlation coefficient, was inconsistent and generally not high (ICC < 0.8) across binarization thresholds, devices, and plexuses. In retinal vascular images, local thresholds tended to incorrectly binarize the foveal avascular zone as white (i.e., wrongly indicating flow). No image processing technique analyzed consistently resulted in highly repeatable metrics. Across contrast changes, retinal vascular images showed the lowest repeatability and CC images showed the highest.

Published

2020

71. Development of global visual processing: From the retina to the perceptive field.

Author

Doron R, Lev M, Wygnanski-Jaffe T, Moroz I, and Polat U

Subjects

Adolescent, Child, Child, Preschool, Contrast Sensitivity physiology, Crowding, Female, Fovea Centralis physiology, Humans, Macular Edema physiopathology, Male, Tomography, Optical Coherence methods, Retina physiology, Visual Acuity physiology, Visual Cortex physiology

Abstract

Young children exhibit poorer visual performance than adults due to immaturity of the fovea and of the fundamental processing of visual functions such as masking and crowding. Recent studies suggest that masking and crowding are closely related to the size of the fundamental processing unit-the perceptive field (PF). However, while it is known that the retina and basic visual functions develop throughout childhood, it is not clear whether and how changes in the size of the PF affect masking and crowding. Furthermore, no retinal and perceptual development data have been collected from the same cohort and time. Here we explored the developmental process of the PF and the basic visual functions. Psychophysical and imaging methods were used to test visual functions and foveal changes in participants ranging from 3-17 years old. Lateral masking, crowding and contrast sensitivity were tested using computerized tasks. Foveal measurements were obtained from spectral-domain optical coherence tomography (OCT). The children patterns below 6 years exhibited high crowding, while the expected facilitation was found only at a larger target-flanker distance than required for children above 6 years, who exhibited the typical adult. Foveal thickness and macular volume for the children below 6 years were significantly lower than for the older group. Significant correlation was found for contrast sensitivity, foveal thickness and macular volume with age and between contrast sensitivity and foveal thickness. Our data suggest that the developmental processes at the retina and visual cortex occur in the same age range. Thus, in parallel to maturation of the PF, which enables reduction in crowding, foveal development contributes to increasing contrast sensitivity., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

72. Parafoveal-on-foveal repetition effects in sentence reading: A co-registered eye-tracking and electroencephalogram study.

Author

Mirault J, Yeaton J, Broqua F, Dufau S, Holcomb PJ, and Grainger J

Subjects

Adolescent, Adult, Comprehension physiology, Electroencephalography, Eye-Tracking Technology, Female, Humans, Male, Young Adult, Evoked Potentials physiology, Fixation, Ocular physiology, Fovea Centralis physiology, Pattern Recognition, Visual, Reading

Abstract

When reading, can the next word in the sentence (word n + 1) influence how you read the word you are currently looking at (word n)? Serial models of sentence reading state that this generally should not be the case, whereas parallel models predict that this should be the case. Here we focus on perhaps the simplest and the strongest Parafoveal-on-Foveal (PoF) manipulation: word n + 1 is either the same as word n or a different word. Participants read sentences for comprehension and when their eyes left word n, the repeated or unrelated word at position n + 1 was swapped for a word that provided a syntactically correct continuation of the sentence. We recorded electroencephalogram and eye-movements, and time-locked the analysis of fixation-related potentials (FRPs) to fixation of word n. We found robust PoF repetition effects on gaze durations on word n, and also on the initial landing position on word n. Most important is that we also observed significant effects in FRPs, reaching significance at 260 ms post-fixation of word n. Repetition of the target word n at position n + 1 caused a widely distributed reduced negativity in the FRPs. Given the timing of this effect, we argue that it is driven by orthographic processing of word n + 1, while readers were still looking at word n, plus the spatial integration of orthographic information extracted from these two words in parallel., (© 2020 The Authors. Psychophysiology published by Wiley Periodicals, Inc. on behalf of Society for Psychophysiological Research.)

Published

2020

73. Interocular asymmetry of foveal avascular zone morphology and parafoveal capillary density in sickle cell retinopathy.

Author

Zhou DB, Scott AW, Linz MO, Han IC, Castanos MV, Lynch G, Andrade Romo JS, Linderman RE, Carroll J, Rosen RB, and Chui TY

Subjects

Adult, Anemia, Sickle Cell complications, Area Under Curve, Case-Control Studies, Cross-Sectional Studies, Eye diagnostic imaging, Female, Fovea Centralis blood supply, Humans, Male, Middle Aged, ROC Curve, Retinal Diseases etiology, Retrospective Studies, Severity of Illness Index, Tomography, Optical Coherence, Young Adult, Anemia, Sickle Cell pathology, Capillaries physiology, Fovea Centralis physiology, Retinal Diseases pathology

Abstract

Objectives: To examine interocular asymmetry of foveal avascular zone (FAZ) and parafoveal capillary density metrics in sickle cell retinopathy (SCR) using optical coherence tomography angiography (OCT-A)., Methods: This cross-sectional, retrospective study evaluated SCR patients and unaffected controls who underwent 3x3mm macular OCT-A imaging using a spectral domain-OCT system. FAZ (area, perimeter, and acircularity index) and parafoveal capillary density metrics were computed for both eyes of each participant. In unaffected controls, interocular difference in FAZ and parafoveal capillary density metrics were evaluated using Bland-Altman plots. SCR patients with interocular difference outside the upper 97.5% and lower 2.5% limits of agreement from controls were defined as having interocular asymmetry. Area under receiver operating characteristic curve (AROC) was also performed to determine the ability of the absolute interocular difference to differentiate between subjects with SCR-including non-proliferative SCR (NP-SCR) and proliferative SCR (P-SCR)-and unaffected controls., Results: Thirty-one patients with SCR (21 NP-SCR and 10 P-SCR) and 14 race-matched and age-matched controls were included for analysis. Interocular asymmetry was seen for all FAZ and parafoveal capillary density metrics in NP-SCR and P-SCR subjects. SCR subjects showed greater disease severity in the left-eye for FAZ and parafoveal capillary density metrics., Conclusions: NP-SCR and P-SCR patients demonstrated quantifiable interocular asymmetry in FAZ and parafoveal capillary density metrics compared to unaffected subjects, with left-eye predominance in disease severity., Competing Interests: AWS: Allergan (Consultant), Novartis (Consultant), Optos (Material Support). RBR: Optovue (Consultant), Boehringer-Ingelheim (Consultant), Astellas (Consultant), Genentech-Roche (Consultant), NanoRetina (Consultant), OD-OS (Consultant), Regeneron (Consultant), Bayer (Consultant), Diopsys (Consultant), Teva (Consultant), Opticology, (Personal Financial Interest), Guardion (Personal Financial Interest), GlaucoHealth (Personal Financial Interest). JC: Optovue (Financial Support), Translational Imaging Innovations (Personal Financial Interest). REL: Optovue (Consultant). These competing interests do not alter our adherence to PLOS ONE policies on sharing data and materials.

Published

2020

74. Investigating face and house discrimination at foveal to parafoveal locations reveals category-specific characteristics.

Author

Kreichman O, Bonneh YS, and Gilaie-Dotan S

Subjects

Adolescent, Adult, Form Perception, Humans, Middle Aged, Visual Acuity, Visual Fields, Visual Pathways, Visual Perception physiology, Young Adult, Facial Recognition physiology, Fovea Centralis physiology, Housing

Abstract

Since perceptual and neural face sensitivity is associated with a foveal bias, and neural place sensitivity is associated with a peripheral bias (integration over space), we hypothesized that face perception ability will decline more with eccentricity than place perception ability. We also wanted to examine whether face perception ability would show a left visual field (LeVF) bias due to earlier reports suggesting right hemisphere dominance for faces, or would show an upper or lower visual field bias. Participants performed foveal and parafoveal face and house discrimination tasks for upright or inverted stimuli (≤4°) while their eye movements were monitored. Low-level visual tasks were also measured. The eccentricity-related accuracy reductions were evident for all categories. Through detailed analyses we found (i) a robust face inversion effect across the parafovea, while for houses an opposite effect was found, (ii) higher eccentricity-related sensitivity for face performance than for house performance (via inverted vs. upright within-category eccentricity-driven reductions), (iii) within-category but not across-category performance associations across eccentricities, and (iv) no hemifield biases. Our central to parafoveal investigations suggest that high-level vision processing may be reflected in behavioural performance.

Published

2020

75. Modulations of foveal vision associated with microsaccade preparation.

Author

Shelchkova N and Poletti M

Subjects

Adolescent, Adult, Female, Humans, Male, Photic Stimulation, Visual Perception, Young Adult, Attention physiology, Eye Movements physiology, Fovea Centralis physiology, Saccades physiology, Vision, Ocular physiology

Abstract

It is known that attention shifts prior to a saccade to start processing the saccade target before it lands in the foveola, the high-resolution region of the retina. Yet, once the target is foveated, microsaccades, tiny saccades maintaining the fixated object within the fovea, continue to occur. What is the link between these eye movements and attention? There is growing evidence that these eye movements are associated with covert shifts of attention in the visual periphery, when the attended stimuli are presented far from the center of gaze. Yet, microsaccades are primarily used to explore complex foveal stimuli and to optimize fine spatial vision in the foveola, suggesting that the influences of microsaccades on attention may predominantly impact vision at this scale. To address this question we tracked gaze position with high precision and briefly presented high-acuity stimuli at predefined foveal locations right before microsaccade execution. Our results show that visual discrimination changes prior to microsaccade onset. An enhancement occurs at the microsaccade target location. This modulation is highly selective and it is coupled with a drastic impairment at the opposite foveal location, just a few arcminutes away. This effect is strongest when stimuli are presented closer to the eye movement onset time. These findings reveal that the link between attention and microsaccades is deeper than previously thought, exerting its strongest effects within the foveola. As a result, during fixation, foveal vision is constantly being reshaped both in space and in time with the occurrence of microsaccades., Competing Interests: The authors declare no competing interest., (Copyright © 2020 the Author(s). Published by PNAS.)

Published

2020

76. Grouping Effects on Foveal Spatial Interactions in Children.

Author

Waugh SJ and Formankiewicz MA

Subjects

Adolescent, Child, Child, Preschool, Contrast Sensitivity physiology, Crowding, Female, Form Perception physiology, Humans, Male, Pattern Recognition, Visual physiology, Photic Stimulation, Psychometrics, Fovea Centralis physiology, Spatial Processing physiology, Visual Acuity physiology

Abstract

Purpose: Grouping of flankers from the target can modulate crowding in adults. Visual acuity in children is measured clinically using charts with targets and different flankers to enhance spatial interactions. We investigated grouping effects on interactions using visual acuity letters, flanked by contours and letters, in children., Methods: Visual acuity for isolated and flanked letters was measured in 155 three- to 11-year old children and 32 adults. Flankers were one stroke width from the target and were a box or four bars and black or red letters. Magnitudes of interaction were flanked minus isolated logMAR acuities. Psychometric function slopes were also examined., Results: Magnitudes of interaction by contours did not change significantly with age. They were 0.047 ± 0.014 logMAR more with bars than a box. Interaction from flanking letters reduced with age, adults being not different from 9- to 11-year-olds for black and red letter surrounds. It was weaker by 0.033 ± 0.013 logMAR when a black letter was surrounded by red rather than black letters. Psychometric function slopes for visual acuity were steepest for the youngest children (3-5 years)., Conclusions: For contour and letter flankers, grouping effects on interaction magnitude are age independent. Grouping bars into a box forming a single object reduces magnitude of effect. Grouping letter flankers by color and ungrouping them from the target reduce interaction magnitude by ∼8%, suggesting that luminance-defined form dominates. Differently colored letter flankers of high-luminance contrast on acuity charts could draw attention to the target but retain significant interaction strength.

Published

2020

77. Retinotopy of emotion: Perception of negatively valenced stimuli presented at different spatial locations as revealed by event-related potentials.

Author

Carretié L, Méndez-Bértolo C, Bódalo C, Hernández-Lorca M, Fernández-Folgueiras U, Fondevila S, and Giménez-Fernández T

Subjects

Adolescent, Adult, Brain Mapping, Electroencephalography, Female, Fovea Centralis diagnostic imaging, Fovea Centralis physiology, Humans, Magnetic Resonance Imaging, Male, Photic Stimulation, Visual Fields, Visual Pathways diagnostic imaging, Visual Pathways physiology, Young Adult, Emotions physiology, Evoked Potentials physiology, Retina physiology, Visual Perception physiology

Abstract

Scarce previous data on how the location where an emotional stimulus appears in the visual scene modulates its perception suggest that, for functional reasons, a perceptual advantage may exist, vertically, for stimuli presented at the lower visual field (LoVF) and, horizontally, for stimuli presented at the left visual field (LeVF). However, this issue has been explored through a limited number of spatial locations, usually in a single spatial dimension (e.g., horizontal) and invariant eccentricities. Event-related potentials (ERPs) were recorded from 39 participants perceiving brief neutral (wheels) and emotional stimuli (spiders) presented at 17 different locations, one foveal and 16 at different peripheral coordinates. As a secondary scope, we explored the role of the magnocellular (M) and the parvocellular (P) visual pathways by presenting an isoluminant/heterochromatic (P-biased) and a heteroluminant/isochromatic version (M-biased) of each stimulus. Emo > Neu effects were observed in PN1 (120 ms) for stimuli located at fovea, and in PN2 (215 ms) for stimuli located both at fovea and diverse peripheral regions. A factorial approach to these effects further revealed that: (a) emotional stimuli presented in the periphery are efficiently perceived, without evident decrease from para- to perifovea; (b) peripheral Emo > Neu effects are reflected 95 ms later than foveal Emo > Neu effects in ERPs; (c) LoVF is more involved than UVF in these effects; (d) our data fail to support the LeVF advantage previously reported, and (e) Emo > Neu effects were significant for both M and P stimuli., (© 2019 The Authors. Human Brain Mapping published by Wiley Periodicals, Inc.)

Published

2020

78. Foveal scanning based on an optical-phases array.

Author

Cao J, Li Y, Zhou D, Zhang FH, Zhang K, Tang M, Wang X, and Hao Q

Subjects

Humans, Models, Biological, Models, Theoretical, Visual Acuity, Fovea Centralis physiology, Optical Imaging instrumentation, Tomography, Optical Coherence instrumentation

Abstract

We utilize the space-variant structure of the human fovea as a basis for a novel, to the best of our knowledge, foveal approach based on optical-phases array (OPA). This approach can be used to solve issues in 3D imaging and achieve a large field of view and high resolution with real-time application. A foveal scanning model based on the OPA is established. Simulations and experiments are performed to verify the models and illustrate the advantages of foveal scanning compared with traditional raster scanning. Simulations agree well with the theory, and the foveal approach has higher efficiency than traditional raster scanning. These results can serve as a reference for developing biomimetic sensors that mimic the human eye.

Published

2020

79. The impact on emotion classification performance and gaze behavior of foveal versus extrafoveal processing of facial features.

Author

Atkinson AP and Smithson HE

Subjects

Adult, Female, Fixation, Ocular physiology, Fovea Centralis physiology, Humans, Male, Young Adult, Emotions, Eye Movements physiology, Facial Expression, Facial Recognition physiology, Social Perception

Abstract

At normal interpersonal distances all features of a face cannot fall within one's fovea simultaneously. Given that certain facial features are differentially informative of different emotions, does the ability to identify facially expressed emotions vary according to the feature fixated and do saccades preferentially seek diagnostic features? Previous findings are equivocal. We presented faces for a brief time, insufficient for a saccade, at a spatial position that guaranteed that a given feature-an eye, cheek, the central brow, or mouth-fell at the fovea. Across 2 experiments, observers were more accurate and faster at discriminating angry expressions when the high spatial-frequency information of the brow was projected to their fovea than when 1 or other cheek or eye was. Performance in classifying fear and happiness (Experiment 1) was not influenced by whether the most informative features (eyes and mouth, respectively) were projected foveally or extrafoveally. Observers more accurately distinguished between fearful and surprised expressions (Experiment 2) when the mouth was projected to the fovea. Reflexive first saccades tended toward the left and center of the face rather than preferentially targeting emotion-distinguishing features. These results reflect the integration of task-relevant information across the face constrained by the differences between foveal and extrafoveal processing (Peterson & Eckstein, 2012). (PsycINFO Database Record (c) 2020 APA, all rights reserved).

Published

2020

80. Foveal gravity: A robust illusion of color-location misbinding.

Author

Ceja CR, Jardine NL, and Franconeri SL

Subjects

Adolescent, Adult, Attention physiology, Female, Humans, Male, Young Adult, Color Perception physiology, Fovea Centralis physiology, Optical Illusions physiology, Photic Stimulation methods

Abstract

Some types of object features, such as color, shape, or location, can be processed separately within the visual system, requiring that they be correctly "bound" to a single object via attentional selection of a subset of visual information. Forcing selection to spread too widely can cause an illusion where these features misbind to objects, creating illusory objects that were never present. Here, we present a novel display that produces a robust color-location misbinding illusion that we call foveal gravity (viewable at https://osf.io/2bndg/). When observers selected only a set of colored objects, colors were largely perceived in their correct locations. When observers additionally selected objects in the far periphery, colors in the near periphery migrated closer to the fovea on over 35% of trials. We speculate that foveal gravity occurs because locations closer to the fovea are more likely to defeat more peripheral locations in competitive interactions to "win" the task-relevant color.

Published

2020

81. Relationship Between Foveal Threshold and Macular Structure/Function/Vessel Density in Glaucoma.

Author

Jeong D, Won HJ, Jo YH, Song MK, Shin JW, and Kook MS

Subjects

Adult, Aged, Cross-Sectional Studies, Female, Fluorescein Angiography, Humans, Intraocular Pressure physiology, Male, Middle Aged, Nerve Fibers pathology, Retinal Ganglion Cells pathology, Retrospective Studies, Sensory Thresholds physiology, Tomography, Optical Coherence methods, Visual Field Tests, Visual Fields physiology, Fovea Centralis physiology, Glaucoma, Open-Angle physiopathology, Macula Lutea physiopathology, Retinal Vessels pathology

Abstract

Purpose: To investigate the hypothesis that macular structure, function, and vessel density (VD) measurements can predict foveal threshold (FT) outcomes in glaucomatous eyes., Materials and Methods: One hundred ninety-five eyes from 195 subjects (134 subjects with early-to-moderate stage open-angle glaucoma and 61 healthy controls) who underwent optical coherence tomography angiography imaging and 24-2 visual field (VF) testing with FT measurements on the same day were retrospectively enrolled in this study. The association of FT with macular structural/functional/VD measurements was evaluated using partial correlation analyses with adjustment for age and linear regression analyses., Results: FT showed significant correlations between the thickness of the macular ganglion cell-inner plexiform layer (mGCIPL) (r=0.330, P<0.001) and the mean sensitivity (MS) of the central 5 and 10 degrees VF points (r=0.448, P<0.001 and r=0.361, P<0.001). Significant correlations were also found between FT and VD measurements at the inferior and superior parafoveal sectors (r=0.455, P<0.001 and r=0.438, P<0.001). In multivariate linear regression analyses controlling the covariates, the thickness of the mGCIPL, central 5 degrees VF MS, and parafoveal VD were significantly associated with FT (all P<0.001). There was also a significant association between FT and logMAR best-corrected visual acuity (β=-5.647, P<0.001)., Conclusions: Macular VD along with mGCIPL thickness and central 5 degrees VF MS independently predict FT outcomes even in the eyes of patients with early-to-moderate stage open-angle glaucoma.

Published

2020

82. Object discrepancy modulates feature prediction across eye movements.

Author

Köller CP, Poth CH, and Herwig A

Subjects

Adolescent, Adult, Female, Humans, Male, Young Adult, Eye Movements physiology, Fovea Centralis physiology, Judgment physiology, Learning physiology, Photic Stimulation, Saccades physiology, Visual Perception physiology

Abstract

Object perception across saccadic eye movements is assumed to result from integrating two information sources: incoming peripheral object information and information from a foveal prediction (Herwig and Schneider, J Exp Psychol Gen 143(5):1903-1922, 2014, Herwig, J Vis 15(16), 7, 2015). Predictions are supposed to be based on transsaccadic associations of peripheral and foveal object information. The main function of these predictions may be to conceal discrepancies in resolution and locations across saccades. Here we ask how predictions are affected by discrepancies between peripheral and foveal objects. Participants learned unfamiliar transsaccadic associations by making saccades to objects whose shape systematically changed during the saccade. Importantly, we manipulated the size of this change between participants to induce different magnitudes of object discrepancy. In a subsequent test, we found that judgment shifts of peripheral shape perception toward the predicted foveal input depended on change size during acquisition. Specifically, the contribution of prediction decreased for large changes but did not reach zero, showing that even for large changes (i.e., square to circle or vice versa) the prediction was not ignored completely. These findings indicate that object discrepancy during learning determines how much the resulting foveal prediction contributes to perception in the periphery.

Published

2020

83. Late disruption of central visual field disrupts peripheral perception of form and color.

Author

Weldon KB, Woolgar A, Rich AN, and Williams MA

Subjects

Adolescent, Adult, Attention physiology, Color, Feedback, Physiological, Female, Fovea Centralis physiology, Humans, Male, Photic Stimulation, Visual Cortex physiology, Color Perception physiology, Pattern Recognition, Visual physiology, Visual Fields physiology

Abstract

Evidence from neuroimaging and brain stimulation studies suggest that visual information about objects in the periphery is fed back to foveal retinotopic cortex in a separate representation that is essential for peripheral perception. The characteristics of this phenomenon have important theoretical implications for the role fovea-specific feedback might play in perception. In this work, we employed a recently developed behavioral paradigm to explore whether late disruption to central visual space impaired perception of color. In the first experiment, participants performed a shape discrimination task on colored novel objects in the periphery while fixating centrally. Consistent with the results from previous work, a visual distractor presented at fixation ~100ms after presentation of the peripheral stimuli impaired sensitivity to differences in peripheral shapes more than a visual distractor presented at other stimulus onset asynchronies. In a second experiment, participants performed a color discrimination task on the same colored objects. In a third experiment, we further tested for this foveal distractor effect with stimuli restricted to a low-level feature by using homogenous color patches. These two latter experiments resulted in a similar pattern of behavior: a central distractor presented at the critical stimulus onset asynchrony impaired sensitivity to peripheral color differences, but, importantly, the magnitude of the effect was stronger when peripheral objects contained complex shape information. These results show a behavioral effect consistent with disrupting feedback to the fovea, in line with the foveal feedback suggested by previous neuroimaging studies., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

84. Gaze direction as equilibrium: more evidence from spatial and temporal aspects of small-saccade triggering in the rhesus macaque monkey.

Author

Hafed ZM and Goffart L

Subjects

Adult, Animals, Behavior, Animal physiology, Eye Movement Measurements, Female, Fovea Centralis physiology, Humans, Macaca mulatta, Male, Memory physiology, Reaction Time physiology, Saccades physiology, Superior Colliculi physiology, Visual Fields physiology, Visual Perception physiology

Abstract

Rigorous behavioral studies made in human subjects have shown that small-eccentricity target displacements are associated with increased saccadic reaction times, but the reasons for this remain unclear. Before characterizing the neurophysiological foundations underlying this relationship between the spatial and temporal aspects of saccades, we tested the triggering of small saccades in the male rhesus macaque monkey. We also compared our results to those obtained in human subjects, both from the existing literature and through our own additional measurements. Using a variety of behavioral tasks exercising visual and nonvisual guidance of small saccades, we found that small saccades consistently require more time than larger saccades to be triggered in the nonhuman primate, even in the absence of any visual guidance and when valid advance information about the saccade landing position is available. We also found a strong asymmetry in the reaction times of small upper versus lower visual field visually guided saccades, a phenomenon that has not been described before for small saccades, even in humans. Following the suggestion that an eye movement is not initiated as long as the visuo-oculomotor system is within a state of balance, in which opposing commands counterbalance each other, we propose that the longer reaction times are a signature of enhanced times needed to create the symmetry-breaking condition that puts downstream premotor neurons into a push-pull regime necessary for rotating the eyeballs. Our results provide an important catalog of nonhuman primate oculomotor capabilities on the miniature scale, allowing concrete predictions on underlying neurophysiological mechanisms. NEW & NOTEWORTHY Leveraging a multitude of neurophysiological investigations in the rhesus macaque monkey, we generated and tested hypotheses about small-saccade latencies in this animal model. We found that small saccades always take longer, on average, than larger saccades to trigger, regardless of visual and cognitive context. Moreover, small downward saccades have the longest latencies overall. Our results provide an important documentation of oculomotor capabilities of an indispensable animal model for neuroscientific research in vision, cognition, and action.

Published

2020

85. Competition between salience and informational value for saccade adaptation.

Author

Wolf C, Wagner I, and Schütz AC

Subjects

Adolescent, Adult, Female, Fovea Centralis physiology, Humans, Male, Photic Stimulation, Probability, Visual Fields, Young Adult, Adaptation, Physiological, Saccades, Space Perception, Visual Perception

Abstract

What we see is influenced by where we look. When confronted with multiple relevant targets, inaccurate saccade target selection can impair perceptual performance. Here we ask whether endpoint selection can be optimized by the mechanism maintaining saccade accuracy: saccade adaptation. Therefore, we introduce a double-target adaptation task, where a presaccadic peripheral stimulus (plaid) splits vertically into its two components (Gabor patches) during horizontal saccades. While both targets were task-relevant, one of them provided more information for the perceptual task, because it could only be identified after the saccade with near-foveal vision. The other target was highly salient and could also be identified in the presaccadic plaid using peripheral vision. This double-target paradigm induced saccade adaptation: Without a perceptual task, participants adapted to the salient target. When both targets were judged sequentially, participants mostly adapted to the target they had to judge first. When targets were judged simultaneously, endpoints were biased toward the informative target but showed no gradual learning and fell short of optimality. We observed gradual adaptation when targets shifted randomly such that a strategic adjustment of endpoints was not possible. Overall, these findings show that when multiple targets compete, our oculomotor system can learn to adjust endpoints in order to maximize information for perception. Yet individual variability and other factors affecting target priority play a crucial role.

Published

2019

86. Parafoveal processing of phonology and semantics during the reading of Korean sentences.

Author

Yan M, Wang A, Song H, and Kliegl R

Subjects

Adult, Female, Fovea Centralis physiology, Humans, Male, Phonetics, Republic of Korea, Semantics, Young Adult, Pattern Recognition, Visual physiology, Psycholinguistics, Reading

Abstract

The present study sets out to address two fundamental questions in the reading of continuous texts: Whether semantic and phonological information from upcoming words can be accessed during natural reading. In the present study we investigated parafoveal processing during the reading of Korean sentences, manipulating semantic and phonological information from parafoveal preview words. In addition to the first evidence for a semantic preview effect in Korean, we found that Korean readers have stronger and more long-lasting phonological than semantic activation from parafoveal words in second-pass reading. The present study provides an example that human mind can flexibly adjust processing priority to different types of information based on the linguistic environment., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2019

87. Contributions of foveal and non-foveal retina to the human eye's focusing response.

Author

Labhishetty V, Cholewiak SA, and Banks MS

Subjects

Adolescent, Adult, Color, Face, Female, Humans, Male, Young Adult, Accommodation, Ocular, Fovea Centralis physiology, Myopia physiopathology, Retina physiology

Abstract

The human eye changes focus-accommodates-to minimize blur in the retinal image. Previous work has shown that stimulation of nonfoveal retina can produce accommodative responses when no competing stimulus is presented to the fovea. In everyday situations it is very common for the fovea and other parts of the retina to be stimulated simultaneously. We examined this situation by asking how nonfoveal retina contributes to accommodation when the fovea is also stimulated. There were three experimental conditions. (a) Real change in which stimuli of different sizes, centered on the fovea, were presented at different optical distances. Accommodation was, as expected, robust because there was no conflicting stimulation of other parts of the retina. (b) Simulated change, no conflict in which stimuli of different sizes, again centered on the fovea, were presented at different simulated distances using rendered chromatic blur. Accommodation was robust in this condition because there was no conflict between the central and peripheral stimuli. (c) Simulated change, conflict in which a central disk (of different diameters) was presented along with an abutting peripheral annulus. The disk and annulus underwent opposite changes in simulated distance. Here we observed a surprisingly consistent effect of the peripheral annulus. For example, when the diameter of the central stimulus was 8° (thereby stimulating the fovea and parafovea), the abutting peripheral annulus had a significant effect on accommodation. We discuss how these results may help us understand other situations in which nonfixated targets affect the ability to focus on a fixated target. We also discuss potential implications for the development of myopia and for foveated rendering.

Published

2019

88. Misperception of motion in depth originates from an incomplete transformation of retinal signals.

Author

Murdison TS, Leclercq G, Lefèvre P, and Blohm G

Subjects

Cues, Equipment Design, Female, Fovea Centralis physiology, Humans, Imaging, Three-Dimensional, Male, Reproducibility of Results, Vision, Binocular, Young Adult, Depth Perception, Eye Movements, Motion Perception, Retina physiology, Vision Disparity

Abstract

Depth perception requires the use of an internal model of the eye-head geometry to infer distance from binocular retinal images and extraretinal 3D eye-head information, particularly ocular vergence. Similarly, for motion in depth perception, gaze angle is required to correctly interpret the spatial direction of motion from retinal images; however, it is unknown whether the brain can make adequate use of extraretinal version and vergence information to correctly transform binocular retinal motion into 3D spatial coordinates. Here we tested this hypothesis by asking participants to reconstruct the spatial trajectory of an isolated disparity stimulus moving in depth either peri-foveally or peripherally while participants' gaze was oriented at different vergence and version angles. We found large systematic errors in the perceived motion trajectory that reflected an intermediate reference frame between a purely retinal interpretation of binocular retinal motion (not accounting for veridical vergence and version) and the spatially correct motion. We quantify these errors with a 3D reference frame model accounting for target, eye, and head position upon motion percept encoding. This model could capture the behavior well, revealing that participants tended to underestimate their version by up to 17%, overestimate their vergence by up to 22%, and underestimate the overall change in retinal disparity by up to 64%, and that the use of extraretinal information depended on retinal eccentricity. Since such large perceptual errors are not observed in everyday viewing, we suggest that both monocular retinal cues and binocular extraretinal signals are required for accurate real-world motion in depth perception.

Published

2019

89. A primarily serial, foveal accumulator underlies approximate numerical estimation.

Author

Cheyette SJ and Piantadosi ST

Subjects

Female, Humans, Male, Mathematics, Eye Movements physiology, Fovea Centralis physiology, Models, Neurological, Vision, Ocular physiology

Abstract

The approximate number system (ANS) has attracted broad interest due to its potential importance in early mathematical development and the fact that it is conserved across species. Models of the ANS and behavioral measures of ANS acuity both assume that quantity estimation is computed rapidly and in parallel across an entire view of the visual scene. We present evidence instead that ANS estimates are largely the product of a serial accumulation mechanism operating across visual fixations. We used an eye-tracker to collect data on participants' visual fixations while they performed quantity-estimation and -discrimination tasks. We were able to predict participants' numerical estimates using their visual fixation data: As the number of dots fixated increased, mean estimates also increased, and estimation error decreased. A detailed model-based analysis shows that fixated dots contribute twice as much as peripheral dots to estimated quantities; people do not "double count" multiply fixated dots; and they do not adjust for the proportion of area in the scene that they have fixated. The accumulation mechanism we propose explains reported effects of display time on estimation and earlier findings of a bias to underestimate quantities., Competing Interests: The authors declare no conflict of interest.

Published

2019

90. Averaging sets of expressive faces is modulated by eccentricity.

Author

To MPS, Carvey KM, Carvey RJ, and Liu CH

Subjects

Adult, Analysis of Variance, Emotions physiology, Female, Fixation, Ocular physiology, Fovea Centralis physiology, Humans, Male, Models, Biological, Orientation physiology, Young Adult, Facial Expression, Facial Recognition physiology

Abstract

Research has shown that participants can extract the average facial expression from a set of faces when these were presented at fixation. In this study, we investigated whether this performance would be modulated by eccentricity given that neural resources are limited outside the foveal region. We also examined whether or not there would be compulsory averaging in the parafovea as has been previously reported for the orientation of Gabor patches by Parkes, Lund, Angelucci, Solomon, and Morgan (2001). Participants were presented with expressive faces (alone or in sets of nine, at fixation or at 3° to the left or right) and were asked to identify the expression of the central target face or to estimate the average expression of the set. Our results revealed that, although participants were able to extract average facial expressions in central and parafoveal conditions, their performance was superior in the parafovea, suggesting facilitated averaging outside the fovea by peripheral mechanisms. Furthermore, regardless of whether the task was to judge the expression of the central target or set average, participants had a tendency to identify central targets' expressions in the fovea but were compelled to average in the parafovea, a finding consistent with compulsory averaging. The data also supported averaging over substitution models of crowding. We conclude that the ability to extract average expressions in sets of faces and identify single targets' facial expressions is influenced by eccentricity.

Published

2019

91. The upper disparity limit increases gradually with eccentricity.

Author

Ghahghaei S, McKee S, and Verghese P

Subjects

Fixation, Ocular physiology, Fovea Centralis physiology, Humans, Photic Stimulation, Psychomotor Performance physiology, Vision, Binocular physiology, Visual Acuity physiology, Depth Perception physiology, Vision Disparity physiology, Vision, Ocular physiology

Abstract

Stereopsis is important for tasks of daily living such as eye-hand coordination. It is best in central vision but is also mediated by the periphery. Previously we have shown that individuals with central-field loss who have residual stereopsis in the periphery perform better at an eye-hand-coordination task when they perform the task binocularly rather than monocularly. Here we seek to determine what sets the limit of stereopsis, defined as the largest disparity that supports the sustained appearance of depth, in the near periphery in healthy individuals. While stereoacuity thresholds increase sharply with eccentricity, Panum's area increases much more slowly. We used a rigorous method to determine the uppermost limit of disparity. At long durations, the two half-images that define a large disparity appear as two isolated targets in the same flat plane; small incremental changes in disparity produce changes in the separation between the half-images, and disparity magnitude can be judged on the basis of separation, like a monocular width judgment. The disparity limit is the point at which the threshold for judging dichoptic separation between the half-images is equal to the monocular width-discrimination threshold. The disparity limit at 10° was a factor of 2-4 times larger than the fovea, regardless of the meridian tested. The increase in the disparity limit with eccentricity was shallow, similar to that of Panum's area. Within this disparity limit, disparity increment thresholds were comparable for foveal and peripheral targets, illustrating the significance and utility of peripheral stereopsis, especially in the absence of foveal stereopsis.

Published

2019

92. Lateral effects in pattern vision.

Author

Foley JM

Subjects

Discrimination, Psychological physiology, Humans, Sensory Thresholds physiology, Contrast Sensitivity physiology, Fovea Centralis physiology, Pattern Recognition, Visual physiology

Abstract

There is a large literature on lateral effects in pattern vision but no consensus about them or comprehensive model of them. This paper reviews the literature with a focus on the effects of parallel context in the central fovea. It describes seven experiments that measure detection and discrimination thresholds in annular and Gabor-pattern contexts at different separations. It presents a model of these effects, which is an elaboration of Foley's (1994) model. The model describes the results well, and it shows that lateral context affects the response to the target by both multiplicative excitation and additive inhibition. Both lateral effects extend for several wavelengths beyond the target. They vary in relative strength, producing near suppression and far enhancement of the response to the target. The model describes the detection and discrimination results well, and it also describes the results of experiments on lateral effects on perceived contrast. The model is consistent with the physiology of V1 cells.

Published

2019

93. The effects of parafoveal word frequency and segmentation on saccade targeting during Chinese reading.

Author

Liu Y, Yu L, Fu L, Li W, Duan Z, and Reichle ED

Subjects

Adult, Asian People, China, Female, Fixation, Ocular physiology, Humans, Male, Young Adult, Fovea Centralis physiology, Pattern Recognition, Visual physiology, Reading, Saccades physiology

Abstract

Two eye-movement experiments are reported in which a boundary paradigm was used to manipulate the presence versus absence of boundaries for high-frequency and low-frequency target words in the parafovea. In Experiment 1, this was done by introducing a blank space after the target words, whereas in Experiment 2 this was done by rendering the target words in red. In both experiments, higher frequency targets engendered longer saccades, whereas the presence of parafoveal word boundaries engendered shorter saccades. This pattern suggests the operation of two countermanding saccade-targeting mechanisms: one that uses parafoveal processing difficulty to adjust saccade lengths and a second that uses word boundaries to direct the eyes toward specific saccade targets. The implications of these findings for models of eye-movement control during reading are discussed, as are suggestions for integrating dynamic-adjustment and default-targeting accounts.

Published

2019

94. Object categorization in visual periphery is modulated by delayed foveal noise.

Author

Ramezani F, Kheradpisheh SR, Thorpe SJ, and Ghodrati M

Subjects

Adult, Discrimination, Psychological, Female, Humans, Male, Form Perception physiology, Fovea Centralis physiology, Pattern Recognition, Visual physiology, Visual Fields physiology

Abstract

Behavioral studies in humans indicate that peripheral vision can do object recognition to some extent. Moreover, recent studies have shown that some information from brain regions retinotopic to visual periphery is somehow fed back to regions retinotopic to the fovea and disrupting this feedback impairs object recognition in human. However, it is unclear to what extent the information in visual periphery contributes to human object categorization. Here, we designed two series of rapid object categorization tasks to first investigate the performance of human peripheral vision in categorizing natural object images at different eccentricities and abstraction levels (superordinate, basic, and subordinate). Then, using a delayed foveal noise mask, we studied how modulating the foveal representation impacts peripheral object categorization at any of the abstraction levels. We found that peripheral vision can quickly and accurately accomplish superordinate categorization, while its performance in finer categorization levels dramatically drops as the object presents further in the periphery. Also, we found that a 300-ms delayed foveal noise mask can significantly disturb categorization performance in basic and subordinate levels, while it has no effect on the superordinate level. Our results suggest that human peripheral vision can easily process objects at high abstraction levels, and the information is fed back to foveal vision to prime foveal cortex for finer categorizations when a saccade is made toward the target object.

Published

2019

95. Foveal Sparing in Central Retinal Dystrophies.

Author

Bax NM, Valkenburg D, Lambertus S, Klevering BJ, Boon CJF, Holz FG, Cremers FPM, Fleckenstein M, Hoyng CB, and Lindner M

Subjects

Disease Progression, Electroretinography, Female, Fluorescein Angiography methods, Fovea Centralis diagnostic imaging, Humans, Male, Middle Aged, Retinal Dystrophies physiopathology, Retrospective Studies, Tomography, Optical Coherence methods, Visual Acuity physiology, Fovea Centralis physiology, Retinal Dystrophies diagnosis

Abstract

Purpose: To describe foveal sparing (FS) in central retinal dystrophies (RD)., Methods: Participants for this retrospective study were identified from the retinal dystrophy database of the Department of Ophthalmology at Radboud University Medical Center. FS was defined as an intact foveal structure surrounded by at least 180° of chorioretinal atrophy, and a best-corrected visual acuity (BCVA) of <1.0 logMAR (>20/200 Snellen). Eligible eyes were identified using fundus autofluorescence (FAF) images, and FS was confirmed using near-infrared reflectance (NIR) imaging and spectral-domain optical coherence tomography when available. Clinical and demographic data were extracted from medical records. We performed quantification of FS and chorioretinal atrophic areas using semiautomated software on fundus autofluorescence and NIR images. We calculated the chronologic change using eye-wise linear regression., Results: We identified 36 patients (56 eyes) with FS. RDs included: Stargardt disease (STGD1;20 patients), central areolar choroidal dystrophy (CACD; 7 patients), mitochondrial retinal dystrophy (MRD; 6 patients), pseudo-Stargardt pattern dystrophy (PSPD; 3 patients). Median age at first presentation was 60 (interquartile range [IQR] 54-63) years. Median BCVA at first presentation ranged from 20/25 Snellen in STGD1, to 20/38 Snellen in MRD. Progression of the chorioretinal atrophic area ranged from 0.26 (0.25-0.28) mm/year in PSPD, to 0.14 (0.11-0.22) in CACD. Change in FS area over time was similar between the different dystrophies., Conclusions: The presence of FS in different RDs suggests a disease-independent mechanism that prolongs the survival of the fovea. The associated preservation of BCVA is important for the individual prognosis and has implications for the design of therapeutic trials for RDs.

Published

2019

96. The Foveal Visual Representation of the Primate Superior Colliculus.

Author

Chen CY, Hoffmann KP, Distler C, and Hafed ZM

Subjects

Animals, Eye Movements, Male, Fovea Centralis physiology, Macaca mulatta physiology, Superior Colliculi physiology, Visual Perception physiology

Abstract

A defining feature of the primate visual system is its foveated nature. Processing of foveal retinal input is important not only for high-quality visual scene analysis but also for ensuring precise, albeit tiny, gaze shifts during high-acuity visual tasks. The representations of foveal retinal input in the primate lateral geniculate nucleus and early visual cortices have been characterized. However, how such representations translate into precise eye movements remains unclear. Here, we document functional and structural properties of the foveal visual representation of the midbrain superior colliculus. We show that the superior colliculus, classically associated with extra-foveal spatial representations needed for gaze shifts, is highly sensitive to visual input impinging on the fovea. The superior colliculus also represents such input in an orderly and very specific manner, and it magnifies the representation of foveal images in neural tissue as much as the primary visual cortex does. The primate superior colliculus contains a high-fidelity visual representation, with large foveal magnification, perfectly suited for active visuomotor control and perception., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

97. Comparison of macular retinal sensitivity and its contribution to the foveal sensitivity between diabetic and non-diabetic patients with normal visual acuity.

Author

Somilleda-Ventura SA, Ceballos-Reyes GM, and Lima-Gómez V

Subjects

Adult, Aged, Cross-Sectional Studies, Female, Humans, Male, Middle Aged, Prospective Studies, Regression Analysis, Diabetes Mellitus, Type 2 physiopathology, Diabetic Retinopathy physiopathology, Fovea Centralis physiology, Macula Lutea physiopathology, Visual Acuity physiology, Visual Fields physiology

Abstract

Purpose: To compare the retinal sensitivity and evaluate its contribution to the foveal sensitivity in patients with and without diabetes who maintain normal visual acuity., Methods: Observational, descriptive, cross-sectional and prospective study in 20 subjects without diabetes (group 1) and 23 with type 2 diabetes mellitus (group 2) that had no ocular abnormalities. Retinal sensitivity was measured with the macular threshold test by the Humphrey's computerized perimeter. The mean sensitivity in each of the 16 points and the foveal sensitivity were compared between groups using the Mann-Whitney's U test; the correlation between retinal sensitivity and foveal sensitivity was analyzed by the Spearman's test and the contribution of each point to the foveal sensitivity was identified by multiple regression., Results: Sixty eyes were evaluated, 30 in group 1 and 30 in group 2; the mean foveal sensitivity was 34.77±0.5dB in group 1 and 32.87±0.6 in group 2. The highest sensitivity of the temporal visual field had an inferior paracentral location (point 3) in both groups. In the linear regression analysis, points which contributed to the foveal sensitivity were 1 in group 1 and points 7 and 15 in group 2., Conclusions: Subjects without diabetes have a significantly higher sensitivity in the temporal retina compared with those with diabetes; points with highest mean retinal sensitivity do not correspond to the central four. The reduced sensitivity in point 1 decreases the mean foveal sensitivity in subjects with diabetes, because this variable correlates with lower perimetry points., (Copyright © 2018 Spanish General Council of Optometry. Published by Elsevier España, S.L.U. All rights reserved.)

Published

2019

98. Modulation of parafoveal word processing by cognitive load during modified visual search tasks.

Author

Dampuré J, Benraiss A, and Vibert N

Subjects

Adult, Attention, Electroencephalography methods, Female, Fovea Centralis physiology, Humans, Male, Memory, Short-Term, Semantics, Task Performance and Analysis, Evoked Potentials, Visual, Eye Movements, Pattern Recognition, Visual, Reaction Time, Reading

Abstract

During visual search for simple items, the amount of information that can be processed in parafoveal vision depends on the cognitive resources that are available. However, whether this applies to the semantic processing of words remains controversial. This work was designed to manipulate simultaneously two sources of cognitive load to study their impact on the depth of parafoveal word processing during a modified visual search task. The participants had to search for target words among parafoveally presented semantic, orthographic or target-unrelated distractor words while their electroencephalogram was recorded. The task-related load was manipulated by either giving target words in advance (literal task) or giving only a semantic clue to define them (categorical task). The foveal load was manipulated by displaying either a word or hash symbols at the centre of the screen. Parafoveal orthographic and semantic distractors had an impact on the early event-related potential component P2a only in the literal task and when hash symbols were displayed at the fovea, i.e., when both the task-related and foveal loads were low. The data show that all sources of cognitive load must be considered to understand how parafoveal words are processed in visual search contexts.

Published

2019

99. Spill the load: Mixed evidence for a foveal load effect, reliable evidence for a spillover effect in eye-movement control during reading.

Author

Findelsberger E, Hutzler F, and Hawelka S

Subjects

Adult, Female, Fixation, Ocular, Humans, Male, Young Adult, Eye Movements physiology, Fovea Centralis physiology, Reading

Abstract

It has been hypothesized that the processing difficulty of the fixated word (i.e., "foveal load") modulates the amount of parafoveal preprocessing of the next word. Evidence for the hypothesis has been provided by the application of parafoveal masks within the boundary paradigm. Other studies that applied alternative means of manipulating the parafoveal preview (i.e., visual degradation) could not replicate the effect of foveal load. The present study examined the effect of foveal load by directly comparing the application of parafoveal masks (Exp. 1) with the alternative manipulation of visually degrading the parafoveal preview (Exp. 2) in adult readers. Contrary to expectation, we did not find the foveal-load interaction in the first experiment with traditional letter masks. We did, however, find the expected interaction in the second experiment with visually degraded previews. Both experiments revealed a spillover effect indicating that the processing of a word is not (always) fully completed when the reader already fixates the next word (i.e., processing "spills over" to the next word). The implications for models of eye-movement control in reading are discussed.

Published

2019

100. The parallel mechanism of semantic context influences and parafoveal word identification.

Author

Zhang W, Zhen A, Liang B, and Mo L

Subjects

Female, Humans, Male, Photic Stimulation, Reaction Time, Reading, Young Adult, Comprehension, Evoked Potentials, Fovea Centralis physiology, Recognition, Psychology, Semantics

Abstract

Previous event-related potential (ERP) studies have shown that the N400 effect tracks with the isolation point of a word in spoken language comprehension. These results suggested the semantic context of a sentence influences word processing before word identification. However, this delayed effect of N400 latency is not often the case in written language comprehension. The present study combined ERP with a rapid serial visual presentation with flanker (RSVP-flanker) method to examine this issue when words were presented in the parafovea. We manipulated three kinds of critical words: expected (EXP), semantically violated (VIO) and semantically cohort violated (COH-VIO). The ERP results showed that the parafoveal N400 effect was delayed in the contrast of COH-VIO vs. EXP than the contrast of VIO vs. EXP. These results suggested that the semantic context influences parafoveal word processing before word identification in written language comprehension., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2019