Visuomotor integration

Kathleen Cullen

doi:10.1007/978-1-4939-3474-4_25

Visuomotor integration

Research output: Chapter in Book/Report/Conference proceeding › Chapter

Abstract

The term “visuomotor integration” refers to the computations preformed by the brain that underlie the visual control of movements. Over the past 40 years, neurophysiological studies performed in alert animals have provided considerable insight into the actual mechanisms responsible for visuomotor integration. In particular, to date, we have a particularly refined understanding of the neural control and pathways that govern eye movements. Notably, pioneering studies have provided key insights regarding how the activities of small clusters of neurons effectively shape the motor commands required to produce accurate eye movement. As a result, our understanding of the brainstem mechanisms that underlie the premotor and motor control of eye movements is now remarkably precise. In turn, this strong foundation has proven to be an advantage for neuroscientists in search of improving our understanding of the neural encoding of higher-level processes that link sensation and action, such as attention, perception, and decision-making. As a result, investigators have most recently taken on fundamental questions such as: (1) How does the brain accumulate information to arrive at the decision to make an eye movement? (2) How does the brain strike a balance between optimizing behavioral accuracy and currently available rewards when making eye movements? and (3) What is the linkage between the specific deficits observed in patients and deficits in the underlying neural circuits that control eye movements?.

Original language	English (US)
Title of host publication	Neuroscience in the 21st Century: From Basic to Clinical, Second Edition
Publisher	Springer New York
Pages	961-1005
Number of pages	45
ISBN (Electronic)	9781493934744
ISBN (Print)	9781493934737
DOIs	https://doi.org/10.1007/978-1-4939-3474-4_25
State	Published - Jan 1 2016
Externally published	Yes

Keywords

Accessory optic system (AOS)
Anterior internuclear ophthalmoplegia
Antisaccade task
Conjugate vs. disconjugate eye movements
Double-step saccade paradigm
Extraocular eye muscles
Eye movement
Gaze shift
Gaze shifts
Inhibition of return phenomenon
Jurgens model of the brainstem saccade generator
Mesencephalic reticular formation (MRF)
Motor control
Motor learning
Neurophysiological studies
Optokinetic reflex
Paramedian pontine reticular formation (PPRF)
Robinson model of the brainstem saccade generator
Saccadic eye movement
Single-unit recording experiments
Smooth pursuit eye movements
Superior colliculus (SC)
Vergence eye movements
Vestibuloocular reflex (VOR)
Viscosity

ASJC Scopus subject areas

Medicine(all)
Neuroscience(all)
Agricultural and Biological Sciences(all)

Access to Document

10.1007/978-1-4939-3474-4_25

Cite this

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title = "Visuomotor integration",

abstract = "The term “visuomotor integration” refers to the computations preformed by the brain that underlie the visual control of movements. Over the past 40 years, neurophysiological studies performed in alert animals have provided considerable insight into the actual mechanisms responsible for visuomotor integration. In particular, to date, we have a particularly refined understanding of the neural control and pathways that govern eye movements. Notably, pioneering studies have provided key insights regarding how the activities of small clusters of neurons effectively shape the motor commands required to produce accurate eye movement. As a result, our understanding of the brainstem mechanisms that underlie the premotor and motor control of eye movements is now remarkably precise. In turn, this strong foundation has proven to be an advantage for neuroscientists in search of improving our understanding of the neural encoding of higher-level processes that link sensation and action, such as attention, perception, and decision-making. As a result, investigators have most recently taken on fundamental questions such as: (1) How does the brain accumulate information to arrive at the decision to make an eye movement? (2) How does the brain strike a balance between optimizing behavioral accuracy and currently available rewards when making eye movements? and (3) What is the linkage between the specific deficits observed in patients and deficits in the underlying neural circuits that control eye movements?.",

keywords = "Accessory optic system (AOS), Anterior internuclear ophthalmoplegia, Antisaccade task, Conjugate vs. disconjugate eye movements, Double-step saccade paradigm, Extraocular eye muscles, Eye movement, Gaze shift, Gaze shifts, Inhibition of return phenomenon, Jurgens model of the brainstem saccade generator, Mesencephalic reticular formation (MRF), Motor control, Motor learning, Neurophysiological studies, Optokinetic reflex, Paramedian pontine reticular formation (PPRF), Robinson model of the brainstem saccade generator, Saccadic eye movement, Single-unit recording experiments, Smooth pursuit eye movements, Superior colliculus (SC), Vergence eye movements, Vestibuloocular reflex (VOR), Viscosity",

author = "Kathleen Cullen",

year = "2016",

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doi = "10.1007/978-1-4939-3474-4_25",

language = "English (US)",

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AB - The term “visuomotor integration” refers to the computations preformed by the brain that underlie the visual control of movements. Over the past 40 years, neurophysiological studies performed in alert animals have provided considerable insight into the actual mechanisms responsible for visuomotor integration. In particular, to date, we have a particularly refined understanding of the neural control and pathways that govern eye movements. Notably, pioneering studies have provided key insights regarding how the activities of small clusters of neurons effectively shape the motor commands required to produce accurate eye movement. As a result, our understanding of the brainstem mechanisms that underlie the premotor and motor control of eye movements is now remarkably precise. In turn, this strong foundation has proven to be an advantage for neuroscientists in search of improving our understanding of the neural encoding of higher-level processes that link sensation and action, such as attention, perception, and decision-making. As a result, investigators have most recently taken on fundamental questions such as: (1) How does the brain accumulate information to arrive at the decision to make an eye movement? (2) How does the brain strike a balance between optimizing behavioral accuracy and currently available rewards when making eye movements? and (3) What is the linkage between the specific deficits observed in patients and deficits in the underlying neural circuits that control eye movements?.

KW - Accessory optic system (AOS)

KW - Anterior internuclear ophthalmoplegia

KW - Antisaccade task

KW - Conjugate vs. disconjugate eye movements

KW - Double-step saccade paradigm

KW - Extraocular eye muscles

KW - Eye movement

KW - Gaze shift

KW - Gaze shifts

KW - Inhibition of return phenomenon

KW - Jurgens model of the brainstem saccade generator

KW - Mesencephalic reticular formation (MRF)

KW - Motor control

KW - Motor learning

KW - Neurophysiological studies

KW - Optokinetic reflex

KW - Paramedian pontine reticular formation (PPRF)

KW - Robinson model of the brainstem saccade generator

KW - Saccadic eye movement

KW - Single-unit recording experiments

KW - Smooth pursuit eye movements

KW - Superior colliculus (SC)

KW - Vergence eye movements

KW - Vestibuloocular reflex (VOR)

KW - Viscosity

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U2 - 10.1007/978-1-4939-3474-4_25

DO - 10.1007/978-1-4939-3474-4_25

M3 - Chapter

AN - SCOPUS:85018861887

SN - 9781493934737

SP - 961

EP - 1005

BT - Neuroscience in the 21st Century: From Basic to Clinical, Second Edition

PB - Springer New York

ER -

Visuomotor integration

Abstract

Keywords

ASJC Scopus subject areas

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