Correction: Humans adapt their anticipatory eye movements to the volatility of visual motion properties

AbstractAnimal behavior constantly adapts to changes, for example when the statistical properties of the environment change unexpectedly. For an agent that interacts with this volatile setting, it is important to react accurately and as quickly as possible. It has already been shown that when a random sequence of motion ramps of a visual target is biased to one direction (e.g. right or left), human observers adapt their eye movements to accurately anticipate the target’s expected direction. Here, we prove that this ability extends to a volatile environment where the probability bias could change at random switching times. In addition, we also recorded the explicit prediction of the next outcome as reported by observers using a rating scale. Both results were compared to the estimates of a probabilistic agent that is optimal in relation to the assumed generative model. Compared to the classical leaky integrator model, we found a better match between our probabilistic agent and the behavioral responses, both for the anticipatory eye movements and the explicit task. Furthermore, by controlling the level of preference between exploitation and exploration in the model, we were able to fit for each individual’s experimental dataset the most likely level of volatility and analyze inter-individual variability across participants. These results prove that in such an unstable environment, human observers can still represent an internal belief about the environmental contingencies, and use this representation both for sensory-motor control and for explicit judgments. This work offers an innovative approach to more generically test the diversity of human cognitive abilities in uncertain and dynamic environments.Author summaryUnderstanding how humans adapt to changing environments to make judgments or plan motor responses based on time-varying sensory information is crucial for psychology, neuroscience and artificial intelligence. Current theories for how we deal with the environment’s uncertainty, that is, in response to the introduction of some randomness change, mostly rely on the behavior at equilibrium, long after after a change. Here, we show that in the more ecological case where the context switches at random times all along the experiment, an adaptation to this volatility can be performed online. In particular, we show in two behavioral experiments that humans can adapt to such volatility at the early sensorimotor level, through their anticipatory eye movements, but also at a higher cognitive level, through explicit ratings. Our results suggest that humans (and future artificial systems) can use much richer adaptive strategies than previously assumed.

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Role of the Vermal Cerebellum in Visually Guided Eye Movements and Visual Motion Perception

Annual Review of Vision Science ◽

10.1146/annurev-vision-091718-015000 ◽

2019 ◽

Vol 5 (1) ◽

pp. 247-268 ◽

Cited By ~ 1

Author(s):

Peter Thier ◽

Akshay Markanday

Keyword(s):

Eye Movements ◽

Motion Perception ◽

Visual Motion ◽

Cerebellar Nuclei ◽

Visually Guided ◽

Past Performance ◽

Visual Motion Perception ◽

Oculomotor Vermis ◽

Retinal Information

The cerebellar cortex is a crystal-like structure consisting of an almost endless repetition of a canonical microcircuit that applies the same computational principle to different inputs. The output of this transformation is broadcasted to extracerebellar structures by way of the deep cerebellar nuclei. Visually guided eye movements are accommodated by different parts of the cerebellum. This review primarily discusses the role of the oculomotor part of the vermal cerebellum [the oculomotor vermis (OMV)] in the control of visually guided saccades and smooth-pursuit eye movements. Both types of eye movements require the mapping of retinal information onto motor vectors, a transformation that is optimized by the OMV, considering information on past performance. Unlike the role of the OMV in the guidance of eye movements, the contribution of the adjoining vermal cortex to visual motion perception is nonmotor and involves a cerebellar influence on information processing in the cerebral cortex.

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Spatial and Temporal Integration of Visual Motion Signals for Smooth Pursuit Eye Movements in Monkeys

Journal of Neurophysiology ◽

10.1152/jn.00611.2009 ◽

2009 ◽

Vol 102 (4) ◽

pp. 2013-2025 ◽

Cited By ~ 8

Author(s):

Leslie C. Osborne ◽

Stephen G. Lisberger

Keyword(s):

Random Walk ◽

Eye Movements ◽

Smooth Pursuit ◽

Visual Motion ◽

Target Motion ◽

Linear Filter ◽

Smooth Pursuit Eye Movements ◽

Spatial Averaging ◽

Spatial Integration ◽

Pursuit Eye Movements

To probe how the brain integrates visual motion signals to guide behavior, we analyzed the smooth pursuit eye movements evoked by target motion with a stochastic component. When each dot of a texture executed an independent random walk such that speed or direction varied across the spatial extent of the target, pursuit variance increased as a function of the variance of visual pattern motion. Noise in either target direction or speed increased the variance of both eye speed and direction, implying a common neural noise source for estimating target speed and direction. Spatial averaging was inefficient for targets with >20 dots. Together these data suggest that pursuit performance is limited by the properties of spatial averaging across a noisy population of sensory neurons rather than across the physical stimulus. When targets executed a spatially uniform random walk in time around a central direction of motion, an optimized linear filter that describes the transformation of target motion into eye motion accounted for ∼50% of the variance in pursuit. Filters had widths of ∼25 ms, much longer than the impulse response of the eye, and filter shape depended on both the range and correlation time of motion signals, suggesting that filters were products of sensory processing. By quantifying the effects of different levels of stimulus noise on pursuit, we have provided rigorous constraints for understanding sensory population decoding. We have shown how temporal and spatial integration of sensory signals converts noisy population responses into precise motor responses.

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Anticipatory Eye Movements While Watching Continuous Action Across Shots in Video Sequences: A Developmental Study

Child Development ◽

10.1111/cdev.12651 ◽

2016 ◽

Vol 88 (4) ◽

pp. 1284-1301 ◽

Cited By ~ 4

Author(s):

Heather L. Kirkorian ◽

Daniel R. Anderson

Keyword(s):

Eye Movements ◽

Video Sequences ◽

Developmental Study ◽

Continuous Action ◽

Anticipatory Eye Movements

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Pursuit and optokinetic deficits following chemical lesions of cortical areas MT and MST

Journal of Neurophysiology ◽

10.1152/jn.1988.60.3.940 ◽

1988 ◽

Vol 60 (3) ◽

pp. 940-965 ◽

Cited By ~ 213

Author(s):

M. R. Dursteler ◽

R. H. Wurtz

Keyword(s):

Eye Movements ◽

Visual Field ◽

Visual Motion ◽

Ibotenic Acid ◽

Motion Processing ◽

Temporal Area ◽

Target Speed ◽

Pursuit Eye Movements ◽

Medial Superior Temporal ◽

Visual Motion Processing

1. Previous experiments have shown that punctate chemical lesions within the middle temporal area (MT) of the superior temporal sulcus (STS) produce deficits in the initiation and maintenance of pursuit eye movements (10, 34). The present experiments were designed to test the effect of such chemical lesions in an area within the STS to which MT projects, the medial superior temporal area (MST). 2. We injected ibotenic acid into localized regions of MST, and we observed two deficits in pursuit eye movements, a retinotopic deficit and a directional deficit. 3. The retinotopic deficit in pursuit initiation was characterized by the monkey's inability to match eye speed to target speed or to adjust the amplitude of the saccade made to acquire the target to compensate for target motion. This deficit was related to the initiation of pursuit to targets moving in any direction in the visual field contralateral to the side of the brain with the lesion. This deficit was similar to the deficit we found following damage to extrafoveal MT except that the affected area of the visual field frequently extended throughout the entire contralateral visual field tested. 4. The directional deficit in pursuit maintenance was characterized by a failure to match eye speed to target speed once the fovea had been brought near the moving target. This deficit occurred only when the target was moving toward the side of the lesion, regardless of whether the target began to move in the ipsilateral or contralateral visual field. There was no deficit in the amplitude of saccades made to acquire the target, or in the amplitude of the catch-up saccades made to compensate for the slowed pursuit. The directional deficit is similar to the one we described previously following chemical lesions of the foveal representation in the STS. 5. Retinotopic deficits resulted from any of our injections in MST. Directional deficits resulted from lesions limited to subregions within MST, particularly lesions that invaded the floor of the STS and the posterior bank of the STS just lateral to MT. Extensive damage to the densely myelinated area of the anterior bank or to the posterior parietal area on the dorsal lip of the anterior bank produced minimal directional deficits. 6. We conclude that damage to visual motion processing in MST underlies the retinotopic pursuit deficit just as it does in MT. MST appears to be a sequential step in visual motion processing that occurs before all of the visual motion information is transmitted to the brainstem areas related to pursuit.(ABSTRACT TRUNCATED AT 400 WORDS)

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Recasting the Smooth Pursuit Eye Movement System

Journal of Neurophysiology ◽

10.1152/jn.00801.2003 ◽

2004 ◽

Vol 91 (2) ◽

pp. 591-603 ◽

Cited By ~ 285

Author(s):

Richard J. Krauzlis

Keyword(s):

Eye Movements ◽

Brain Stem ◽

Smooth Pursuit ◽

Visual Motion ◽

Saccadic Eye Movements ◽

Extrastriate Cortex ◽

High Acuity ◽

Voluntary Eye Movements ◽

New Perspective ◽

The Brain

Primates use a combination of smooth pursuit and saccadic eye movements to stabilize the retinal image of selected objects within the high-acuity region near the fovea. Pursuit has traditionally been viewed as a relatively automatic behavior, driven by visual motion signals and mediated by pathways that connect visual areas in the cerebral cortex to motor regions in the cerebellum. However, recent findings indicate that this view needs to be reconsidered. Rather than being controlled primarily by areas in extrastriate cortex specialized for processing visual motion, pursuit involves an extended network of cortical areas, and, of these, the pursuit-related region in the frontal eye fields appears to exert the most direct influence. The traditional pathways through the cerebellum are important, but there are also newly identified routes involving structures previously associated with the control of saccades, including the basal ganglia, the superior colliculus, and nuclei in the brain stem reticular formation. These recent findings suggest that the pursuit system has a functional architecture very similar to that of the saccadic system. This viewpoint provides a new perspective on the processing steps that occur as descending control signals interact with circuits in the brain stem and cerebellum responsible for gating and executing voluntary eye movements. Although the traditional view describes pursuit and saccades as two distinct neural systems, it may be more accurate to consider the two movements as different outcomes from a shared cascade of sensory–motor functions.

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MST Neuronal Responses to Heading Direction During Pursuit Eye Movements

Journal of Neurophysiology ◽

10.1152/jn.1999.81.2.596 ◽

1999 ◽

Vol 81 (2) ◽

pp. 596-610 ◽

Cited By ~ 66

Author(s):

William K. Page ◽

Charles J. Duffy

Keyword(s):

Eye Movements ◽

Smooth Pursuit ◽

Visual Motion ◽

Neuronal Population ◽

Smooth Pursuit Eye Movements ◽

Neuronal Responses ◽

Temporal Area ◽

Pursuit Eye Movements ◽

Heading Direction ◽

Monkey Visual Cortex

MST neuronal responses to heading direction during pursuit eye movements. As you move through the environment, you see a radial pattern of visual motion with a focus of expansion (FOE) that indicates your heading direction. When self-movement is combined with smooth pursuit eye movements, the turning of the eye distorts the retinal image of the FOE but somehow you still can perceive heading. We studied neurons in the medial superior temporal area (MST) of monkey visual cortex, recording responses to FOE stimuli presented during fixation and smooth pursuit eye movements. Almost all neurons showed significant changes in their FOE selective responses during pursuit eye movements. However, the vector average of all the neuronal responses indicated the direction of the FOE during both fixation and pursuit. Furthermore, the amplitude of the net vector increased with increasing FOE eccentricity. We conclude that neuronal population encoding in MST might contribute to pursuit-tolerant heading perception.

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