Common cortical areas have different neural mechanisms for covert and overt visual pursuits

AbstractAlthough humans can direct their attention to visual targets with or without eye movements, it remains unclear how different brain mechanisms control visual attention and eye movements together and/or separately. Here, we measured MEG and fMRI data during covert/overt visual pursuit tasks and estimated cortical currents using our previously developed extra-dipole, hierarchical Bayesian method. Then, we predicted the time series of target positions and velocities from the estimated cortical currents of each task using a sparse machine-learning algorithm. The predicted target positions/velocities had high temporal correlations with actual visual target kinetics. Additionally, we investigated the generalization ability of predictive models among three conditions: control, covert, and overt pursuit tasks. When training and testing data were the same tasks, the largest reconstructed accuracies were overt, followed by covert and control, in that order. When training and testing data were selected from different tasks, accuracies were in reverse order. These results are well explained by the assumption that predictive models consist of combinations of three computational brain functions: visual information-processing, maintenance of attention, and eye-movement control. Our results indicate that separate subsets of neurons in the same cortical regions control visual attention and eye movements differently.

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The complexity of eye-hand coordination: a perspective on cortico-cerebellar cooperation

Cerebellum & Ataxias ◽

10.1186/s40673-020-00123-z ◽

2020 ◽

Vol 7 (1) ◽

Author(s):

John-Ross Rizzo ◽

Mahya Beheshti ◽

Tahereh Naeimi ◽

Farnia Feiz ◽

Girish Fatterpekar ◽

...

Keyword(s):

Eye Movements ◽

Visual Information ◽

Hand Movement ◽

Movement Control ◽

Hand Movements ◽

General Notion ◽

Cerebellar Stroke ◽

Temporal Prediction ◽

Cortical Stroke ◽

Hand Coordination

Abstract Background Eye–hand coordination (EHC) is a sophisticated act that requires interconnected processes governing synchronization of ocular and manual motor systems. Precise, timely and skillful movements such as reaching for and grasping small objects depend on the acquisition of high-quality visual information about the environment and simultaneous eye and hand control. Multiple areas in the brainstem and cerebellum, as well as some frontal and parietal structures, have critical roles in the control of eye movements and their coordination with the head. Although both cortex and cerebellum contribute critical elements to normal eye-hand function, differences in these contributions suggest that there may be separable deficits following injury. Method As a preliminary assessment for this perspective, we compared eye and hand-movement control in a patient with cortical stroke relative to a patient with cerebellar stroke. Result We found the onset of eye and hand movements to be temporally decoupled, with significant decoupling variance in the patient with cerebellar stroke. In contrast, the patient with cortical stroke displayed increased hand spatial errors and less significant temporal decoupling variance. Increased decoupling variance in the patient with cerebellar stroke was primarily due to unstable timing of rapid eye movements, saccades. Conclusion These findings highlight a perspective in which facets of eye-hand dyscoordination are dependent on lesion location and may or may not cooperate to varying degrees. Broadly speaking, the results corroborate the general notion that the cerebellum is instrumental to the process of temporal prediction for eye and hand movements, while the cortex is instrumental to the process of spatial prediction, both of which are critical aspects of functional movement control.

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Express saccades and visual attention

Behavioral and Brain Sciences ◽

10.1017/s0140525x00031575 ◽

1993 ◽

Vol 16 (3) ◽

pp. 553-567 ◽

Cited By ~ 380

Author(s):

B. Fischer ◽

H. Weber

Keyword(s):

Eye Movements ◽

Visual Attention ◽

Reaction Times ◽

Express Saccades ◽

Research Groups ◽

Express Saccade ◽

Brain Functions ◽

Target Article ◽

Higher Brain Functions ◽

Present Understanding

AbstractOne of the most intriguing and controversial observations in oculomotor research in recent years is the phenomenon of express saccades in monkeys and man. These are saccades with such short reaction times (100 msec in man, 70 msec in monkeys) that some experts on eye movements still regard them as artifacts or as anticipatory reactions that do not need any further explanation. On the other hand, some research groups consider them not only authentic but also a valuable means of investigating the mechanisms of saccade generation, the coordination of vision and eye movements, and the mechanisms of visual attention.This target article puts together pieces of experimental evidence in oculomotor and related research – with special emphasis on the express saccade – to enhance our present understanding of the coordination of vision, visual attention, and the eye movements subserving visual perception and cognition.We hypothesize that an optomotor reflex is responsible for the occurrence of express saccades, one that is controlled by higher brain functions involved in disengaged visual attention and decision making. We propose a neural network as the basis for more elaborate mathematical models or computer simulations of the optomotor system in primates.

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Dopamine and eye movement control in Parkinson’s disease: deficits in corollary discharge signals?

PeerJ ◽

10.7717/peerj.6038 ◽

2018 ◽

Vol 6 ◽

pp. e6038 ◽

Cited By ~ 3

Author(s):

Henry Railo ◽

Henri Olkoniemi ◽

Enni Eeronheimo ◽

Oona Pääkkönen ◽

Juho Joutsa ◽

...

Keyword(s):

Parkinson’S Disease ◽

Parkinson's Disease ◽

Eye Movements ◽

Eye Movement ◽

Visual Information ◽

Early Stage ◽

Movement Control ◽

Saccadic Eye Movements ◽

Corollary Discharge ◽

Motor Deficits

Movement in Parkinson’s disease (PD) is fragmented, and the patients depend on visual information in their behavior. This suggests that the patients may have deficits in internally monitoring their own movements. Internal monitoring of movements is assumed to rely on corollary discharge signals that enable the brain to predict the sensory consequences of actions. We studied early-stage PD patients (N = 14), and age-matched healthy control participants (N = 14) to examine whether PD patients reveal deficits in updating their sensory representations after eye movements. The participants performed a double-saccade task where, in order to accurately fixate a second target, the participant must correct for the displacement caused by the first saccade. In line with previous reports, the patients had difficulties in fixating the second target when the eye movement was performed without visual guidance. Furthermore, the patients had difficulties in taking into account the error in the first saccade when making a saccade toward the second target, especially when eye movements were made toward the side with dominant motor symptoms. Across PD patients, the impairments in saccadic eye movements correlated with the integrity of the dopaminergic system as measured with [123I]FP-CIT SPECT: Patients with lower striatal (caudate, anterior putamen, and posterior putamen) dopamine transporter binding made larger errors in saccades. This effect was strongest when patients made memory-guided saccades toward the second target. Our results provide tentative evidence that the motor deficits in PD may be partly due to deficits in internal monitoring of movements.

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Dopamine and eye movement control in Parkinson’s disease: deficits in corollary discharge signals?

10.1101/245381 ◽

2018 ◽

Author(s):

Henry Railo ◽

Henri Olkoniemi ◽

Enni Eeronheimo ◽

Oona Pääkkonen ◽

Juho Joutsa ◽

...

Keyword(s):

Parkinson’S Disease ◽

Parkinson's Disease ◽

Eye Movements ◽

Eye Movement ◽

Visual Information ◽

Early Stage ◽

Movement Control ◽

Saccadic Eye Movements ◽

Corollary Discharge ◽

Motor Deficits

Movement in Parkinson’s disease (PD) is fragmented, and the patients depend on visual information in their behavior. This suggests that the patients may have deficits in internally monitoring their own movements. Internal monitoring of movements is assumed to rely on corollary discharge signals that enable the brain to predict the sensory consequences of actions. We studied early-stage PD patients (N=14), and age-matched healthy control participants (N=14) to examine whether PD patients reveal deficits in updating their sensory representations after eye movements. The participants performed a double-saccade task where, in order to accurately fixate a second target, the participant must correct for the displacement caused by the first saccade. In line with previous reports, the patients had difficulties in fixating the second target when the eye movement was performed without visual guidance. Furthermore, the patients had difficulties in taking into account the error in the first saccade when making a saccade towards the second target, especially when eye movements were made towards the side with dominant motor symptoms. Across PD patients, the impairments in saccadic eye movements correlated with the integrity of the dopaminergic system as measured with [123I]FP-CIT SPECT: Patients with lower striatal (caudate, anterior putamen and posterior putamen) dopamine transporter binding made larger errors in saccades. This effect was strongest when patients made memory-guided saccades towards the second target. Our results provide tentative evidence that the motor deficits in PD may be partly accounted by deficits in internal monitoring of movements.

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Eye movements in sports research and practice: Immersive technologies as optimal environments for the study of gaze behaviour

10.31234/osf.io/fbwvk ◽

2020 ◽

Author(s):

David Harris ◽

Mark Wilson ◽

Tim Holmes ◽

Toby de Burgh ◽

Samuel James Vine

Keyword(s):

Virtual Reality ◽

Eye Movements ◽

Eye Tracking ◽

Visual Information ◽

Successful Performance ◽

Experimental Control ◽

Research And Practice ◽

Gaze Behaviour ◽

Immersive Technologies

Head-mounted eye tracking has been fundamental for developing an understanding of sporting expertise, as the way in which performers sample visual information from the environment is a major determinant of successful performance. There is, however, a long running tension between the desire to study realistic, in-situ gaze behaviour and the difficulties of acquiring accurate ocular measurements in dynamic and fast-moving sporting tasks. Here, we describe how immersive technologies, such as virtual reality, offer an increasingly compelling approach for conducting eye movement research in sport. The possibility of studying gaze behaviour in representative and realistic environments, but with high levels of experimental control, could enable significant strides forward for eye tracking in sport and improve understanding of how eye movements underpin sporting skills. By providing a rationale for virtual reality as an optimal environment for eye tracking research, as well as outlining practical considerations related to hardware, software and data analysis, we hope to guide researchers and practitioners in the use of this approach.

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