Instantaneous movement-unrelated midbrain activity modifies ongoing eye movements

Buonocore, Antimo; Baumann, Matthias P.; Hafed, Ziad M.

doi:10.1101/2020.05.31.126359

Cited by 6 publications

(18 citation statements)

References 93 publications

(194 reference statements)

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“…A further implication of the results of SC inactivation on early cue-influenced microsaccade directions ( Figure 3 ) is that one can now attempt to establish a quantitative link between microsaccade endpoint variability and SC cue-induced visual bursts. Specifically, the timing of early cue-congruent microsaccades in Figures 1 – 3 is consistent with the timing of SC visual bursts ( Buonocore et al, 2017 , 2020b ). If eliminating such visual bursts via SC inactivation diminishes the likelihood of cue-congruent microsaccades ( Figure 3 ; Hafed et al, 2013 ), then this might suggest that these cue-congruent microsaccades reflect readout of the SC map under a very specific simultaneity condition: a microsaccade burst in the direction of the appearing cue in the rostral SC region, and a simultaneous visual burst in the periphery at the site representing the cue’s location ( Figure 5A ).…”

Section: The Superior Colliculus (Sc)supporting

confidence: 70%

“…If eliminating such visual bursts via SC inactivation diminishes the likelihood of cue-congruent microsaccades ( Figure 3 ; Hafed et al, 2013 ), then this might suggest that these cue-congruent microsaccades reflect readout of the SC map under a very specific simultaneity condition: a microsaccade burst in the direction of the appearing cue in the rostral SC region, and a simultaneous visual burst in the periphery at the site representing the cue’s location ( Figure 5A ). If true, then there should be a measurable number of cue-induced visual spikes that are “injected” onto the SC map (when the cue appears) at the same time as the triggering of microsaccades ( Buonocore et al, 2017 , 2020b ). This should “add” to the triggered movements and alter their size.…”

Section: The Superior Colliculus (Sc)mentioning

confidence: 99%

“…Thus, every spike of every active cue-driven SC neuron contributes to microsaccade endpoint variability. Adapted with permission from Buonocore et al (2020b) .…”

Section: The Superior Colliculus (Sc)mentioning

confidence: 99%

“…This idea was validated by measuring early cue-congruent microsaccade metrics: cue-congruent microsaccades were significantly larger in size than other microsaccades ( Hafed and Ignashchenkova, 2013 ; Tian et al, 2016 ; Buonocore et al, 2020b ). Importantly, there was also a quantitatively predictable relationship between the number of cue-induced visual spikes in the peripheral SC and the cue-congruent microsaccade amplitudes.…”

Section: The Superior Colliculus (Sc)mentioning

confidence: 99%

“…Importantly, there was also a quantitatively predictable relationship between the number of cue-induced visual spikes in the peripheral SC and the cue-congruent microsaccade amplitudes. To demonstrate this, Buonocore et al (2020b) counted the number of visual spikes emitted by individually recorded peripheral SC neurons at the time of microsaccade triggering ( Figure 5A ). There was a linear relationship between the number of peripheral “visual” spikes and cue-congruent microsaccade amplitudes ( Figures 5B,C ): every single spike of every single visually-driven neuron contributed to the trajectory of early cue-congruent microsaccades ( Buonocore et al, 2020b ).…”

Section: The Superior Colliculus (Sc)mentioning

confidence: 99%

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Dissociable Cortical and Subcortical Mechanisms for Mediating the Influences of Visual Cues on Microsaccadic Eye Movements

Hafed

Yoshida

Tian

et al. 2021

Front. Neural Circuits

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Visual selection in primates is intricately linked to eye movements, which are generated by a network of cortical and subcortical neural circuits. When visual selection is performed covertly, without foveating eye movements toward the selected targets, a class of fixational eye movements, called microsaccades, is still involved. Microsaccades are small saccades that occur when maintaining precise gaze fixation on a stationary point, and they exhibit robust modulations in peripheral cueing paradigms used to investigate covert visual selection mechanisms. These modulations consist of changes in both microsaccade directions and frequencies after cue onsets. Over the past two decades, the properties and functional implications of these modulations have been heavily studied, revealing a potentially important role for microsaccades in mediating covert visual selection effects. However, the neural mechanisms underlying cueing effects on microsaccades are only beginning to be investigated. Here we review the available causal manipulation evidence for these effects’ cortical and subcortical substrates. In the superior colliculus (SC), activity representing peripheral visual cues strongly influences microsaccade direction, but not frequency, modulations. In the cortical frontal eye fields (FEF), activity only compensates for early reflexive effects of cues on microsaccades. Using evidence from behavior, theoretical modeling, and preliminary lesion data from the primary visual cortex and microstimulation data from the lower brainstem, we argue that the early reflexive microsaccade effects arise subcortically, downstream of the SC. Overall, studying cueing effects on microsaccades in primates represents an important opportunity to link perception, cognition, and action through unaddressed cortical-subcortical neural interactions. These interactions are also likely relevant in other sensory and motor modalities during other active behaviors.

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Section: The Superior Colliculus (Sc)supporting

confidence: 70%

Section: The Superior Colliculus (Sc)mentioning

confidence: 99%

“…Thus, every spike of every active cue-driven SC neuron contributes to microsaccade endpoint variability. Adapted with permission from Buonocore et al (2020b) .…”

Section: The Superior Colliculus (Sc)mentioning

confidence: 99%

Section: The Superior Colliculus (Sc)mentioning

confidence: 99%

Section: The Superior Colliculus (Sc)mentioning

confidence: 99%

See 3 more Smart Citations

Dissociable Cortical and Subcortical Mechanisms for Mediating the Influences of Visual Cues on Microsaccadic Eye Movements

Hafed

Yoshida

Tian

et al. 2021

Front. Neural Circuits

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Saccades along spatial neural circuit discontinuities

Malevich

Hafed

2021

Preprint

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Saccades are realized by six extraocular muscles that define the final reference frame for eyeball rotations. However, upstream of the nuclei innervating the eye muscles, eye movement commands are represented in two-dimensional retinocentric coordinates, as is the case in the superior colliculus (SC). In such spatial coordinates, the horizontal and vertical visual field meridians, relative to the line of sight, are associated with neural tissue discontinuities due to routing of binocular retinal outputs when forming retinotopic sensory-motor maps. At the level of the SC, a functional discontinuity along the horizontal meridian was additionally discovered, beyond the structural vertical discontinuity associated with hemifield lateralization. How do such neural circuit discontinuities influence purely cardinal saccades? Using thousands of saccades from 3 rhesus macaque monkeys and 14 human subjects, we show how the likelihood of purely horizontal or vertical saccades is infinitesimally small, nulling a discontinuity problem. This does not mean that saccades are sloppy. On the contrary, saccades exhibit remarkable direction and amplitude corrections to account for small initial eye position deviations due to fixational variability: “purely” cardinal saccades can deviate, with an orthogonal component of as little as 0.03 deg, to correct for tiny target position deviations from initial eye position. In humans, probing perceptual target localization additionally revealed that saccades show different biases from perception when targets deviate slightly from purely cardinal directions. These results demonstrate a new functional role for fixational eye movements in visually-guided behavior, and they motivate further neurophysiological investigations of saccade trajectory control in the brainstem.New and NoteworthyPurely cardinal saccades are often characterized as being straight. We show how a small amount of curvature is inevitable, alleviating an implementational problem of dealing with neural circuit discontinuities in the representations of the visual meridians. The small curvature functionally corrects for minute variability in initial eye position due to fixational eye movements. Saccades are far from sloppy; they deviate by as little as <1% of the total vector size to adjust their landing position.

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Superior colliculus saccade motor bursts do not dictate movement kinematics

Zhang

Malevich

Baumann

et al. 2021

Preprint

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The primate superior colliculus (SC) contains a topographic map of visual field locations, such that the anatomical location of any given active neuron defines a desired eye movement amplitude and direction. Complementing such a spatial code, SC neurons also exhibit saccade-related bursts that are tightly synchronized with movement onset. Current models suggest that such bursts, and their properties, constitute a temporal rate code that may dictate moment-to-moment movement evolution. However, a recent result demonstrated altered movement properties with minimal changes in SC motor burst strengths (Buonocore, Tian, Khademi, & Hafed, 2021). Here, I support such a dissociation between the SC temporal rate code and instantaneous movement evolution: SC burst strength varies depending on whether saccades are directed towards the upper or lower visual fields, but the movements themselves have similar kinematics. Thus, SC saccade-related motor bursts do not necessarily dictate movement kinematics, motivating investigating other possible functional roles for these bursts.

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Instantaneous movement-unrelated midbrain activity modifies ongoing eye movements

Cited by 6 publications

References 93 publications

Dissociable Cortical and Subcortical Mechanisms for Mediating the Influences of Visual Cues on Microsaccadic Eye Movements

Dissociable Cortical and Subcortical Mechanisms for Mediating the Influences of Visual Cues on Microsaccadic Eye Movements

Saccades along spatial neural circuit discontinuities

Superior colliculus saccade motor bursts do not dictate movement kinematics

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