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

Hafed, Ziad M.; Goffart, Laurent

doi:10.1152/jn.00588.2019

Cited by 21 publications

(55 citation statements)

References 54 publications

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“…While the time bins in that study were too coarse to explore the short latency responses that we saw, these human results are, at least, consistent with our observation that image onsets can rapidly modulate ocular drifts. Other oculomotor phenomena are also very well preserved between monkeys and humans: some notable examples from our own prior work include ocular following responses ( Chen and Hafed, 2013 ) as well as saccade-related implications of SC visual field asymmetries ( Grujic et al, 2018 ; Hafed and Chen, 2016 ; Hafed and Goffart, 2020 ) and SC foveal magnification ( Chen et al, 2019 ; Hafed and Goffart, 2020 ; Willeke et al, 2019 ).…”

Section: Discussionmentioning

confidence: 98%

Rapid stimulus-driven modulation of slow ocular position drifts

Malevich

Buonocore

Hafed

2020

eLife

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The eyes are never still during maintained gaze fixation. When microsaccades are not occurring, ocular position exhibits continuous slow changes, often referred to as drifts. Unlike microsaccades, drifts remain to be viewed as largely random eye movements. Here we found that ocular position drifts can, instead, be very systematically stimulus-driven, and with very short latencies. We used highly precise eye tracking in three well trained macaque monkeys and found that even fleeting (~8 ms duration) stimulus presentations can robustly trigger transient and stimulus-specific modulations of ocular position drifts, and with only approximately 60 ms latency. Such drift responses are binocular, and they are most effectively elicited with large stimuli of low spatial frequency. Intriguingly, the drift responses exhibit some image pattern selectivity, and they are not explained by convergence responses, pupil constrictions, head movements, or starting eye positions. Ocular position drifts have very rapid access to exogenous visual information.

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Section: Discussionmentioning

confidence: 98%

Rapid stimulus-driven modulation of slow ocular position drifts

Malevich

Buonocore

Hafed

2020

eLife

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“…While the time bins in that study were too coarse to explore the short latency responses that we saw, these human results are, at least, consistent with our observation that image onsets can rapidly modulate ocular drifts. Other oculomotor phenomena are also very well preserved between monkeys and humans: some notable examples from our own prior work include ocular following responses (Chen & Hafed, 2013) as well as saccade-related implications of SC visual field asymmetries (Grujic, Brehm, Gloge, Zhuo, & Hafed, 2018; Hafed & Chen, 2016; Hafed & Goffart, 2020) and SC foveal magnification (Chen et al, 2019; Hafed & Goffart, 2020; Willeke et al, 2019).…”

Section: Discussionmentioning

confidence: 98%

Rapid stimulus-driven modulation of slow ocular position drifts

Malevich¹,

Buonocore²,

Hafed³

2020

Preprint

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We analyzed microsaccade-free fixation after a visual transient. In a first experiment, 53 each monkey fixated a white spot over a gray background spanning approximately 54 +/-15 deg horizontally and +/-11 deg vertically. At a random time, the display 55 changed: one entire half (right or left) became black (split view stimulus); and a half-56 circle of 0.74-deg radius around the fixated position remained gray, in order to 57 maintain view of the stable fixation spot (Methods). In trials without microsaccades (-58 100 to 200 ms from stimulus onset), a highly repeatable short-latency drift response 59 occurred. This drift response is illustrated in Fig. 1A, B for monkey A, in which we 60 tracked the left eye using the precise scleral search coil technique [36, 37]; the 61 response measured in the two other monkeys, in which we measured right eye 62 position, is shown in Fig. S1. Regardless of the tracked eye, and regardless of the 63 steady-state stereotypical drift direction exhibited individually by a given monkey, 64there was always a robust upward position drift after stimulus onset. Importantly, it 65 was clearly visible at the individual trial level (Figs. 1C, S1C, I). In one monkey (N), 66 this upward drift response was sometimes initiated first by a much more short-lived 67 and downward shift of eye position (of very small magnitude) before the flip to the 68 upward drift (Fig. S1G-L). 69 70We statistically assessed the onset and duration of the drift response in each monkey 71 by computing 95% confidence intervals (Methods) around the average eye velocity 72 traces. When the 95% confidence intervals between the stimulus and control velocity 73 traces did not overlap for at least 20 consecutive milliseconds, we deemed the 74 velocity response to be significant. In monkey A, the upward velocity pulse started at 75 ~80 ms and lasted for ~60 ms (Fig. 1B). These values were ~60 ms and ~90 ms, 76

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“…Interestingly, a different strategy appeared with size changes. When viewing small sized images, the visual system decreased the ROI sampling rate (consistent with [ 58 ]) while maintaining Sp and thus increasing Xp ( Fig 5 , Table on top ). A sequential open-loop scheme, in which the visual input affects Rs and Rs affects the drifts variables, is ruled out here; the mean values of Rs did not systematically change along with either Sp or Xp , and the pause-by-pause correlations between each Sp or Xp and its preceding instantaneous Rs (i.e., the inverse of the inter-saccadic-interval) were negligible (R 2 < 0.06).…”

Section: Resultsmentioning

confidence: 62%

Section: Plos Onementioning

confidence: 84%

“…The dynamics of closed-loop systems are limited by the loop delay, that is, the time it takes for the effect of a signal to travel along the loop. In the drift system this delay can be estimated as < 50 ms [58]. Accordingly, drift oscillations around 10 Hz [61] may reflect fluctuating loop dynamics and may point to the characteristic limit cycle of the loop.…”

Section: Plos Onementioning

confidence: 99%

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Closed loop motor-sensory dynamics in human vision

Gruber

Ahissar

2020

PLoS ONE

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Vision is obtained with a continuous motion of the eyes. The kinematic analysis of eye motion, during any visual or ocular task, typically reveals two (kinematic) components: saccades, which quickly replace the visual content in the retinal fovea, and drifts, which slowly scan the image after each saccade. While the saccadic exchange of regions of interest (ROIs) is commonly considered to be included in motor-sensory closed-loops, it is commonly assumed that drifts function in an open-loop manner, that is, independent of the concurrent visual input. Accordingly, visual perception is assumed to be based on a sequence of open-loop processes, each initiated by a saccade-triggered retinal snapshot. Here we directly challenged this assumption by testing the dependency of drift kinematics on concurrent visual inputs using real-time gaze-contingent-display. Our results demonstrate a dependency of the trajectory on the concurrent visual input, convergence of speed to conditionspecific values and maintenance of selected drift-related motor-sensory controlled variables, all strongly indicative of drifts being included in a closed-loop brain-world process, and thus suggesting that vision is inherently a closed-loop process.

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

Cited by 21 publications

References 54 publications

Rapid stimulus-driven modulation of slow ocular position drifts

Rapid stimulus-driven modulation of slow ocular position drifts

Rapid stimulus-driven modulation of slow ocular position drifts

Closed loop motor-sensory dynamics in human vision

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