Literature DB >> 1756806

Frontal eye field lesions impair predictive and visually-guided pursuit eye movements.

E G Keating1.   

Abstract

The study initially explored the frontal eye field's (FEF) control of predictive eye movements, i.e., eye movements driven by previous rather than current sensory signals. Five monkeys were trained to pursue horizontal target motion, including sinusoidal targets and "random-walk" targets which sometimes deviated from a sine motion. Some subjects also tracked other target trajectories and optokinetic motion. FEF ablations or cold lesions impaired predictive pursuit, but also degraded visually guided foveal pursuit of all targets. Unilateral lesions impaired pursuit of targets moving in both horizontal orbital fields and in both directions of movement. Saccadic estimates of target motion were generally accurate. The slow-phase velocity of optokinetic pursuit (collected after 54 s of OKN) also appeared normal. Pursuit recovered over 1-3 weeks after surgery but the deficits were then reinstated by removal of FEF in the other hemisphere. Thereafter, a slight deficit persisted for up to 10 weeks of observation in two subjects. The pattern of symptoms suggests that FEF lies subsequent to parietal area MST and prior to the pontine nuclei in controlling pursuit eye movements.

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Mesh:

Year:  1991        PMID: 1756806     DOI: 10.1007/bf00228954

Source DB:  PubMed          Journal:  Exp Brain Res        ISSN: 0014-4819            Impact factor:   1.972


  31 in total

1.  Pursuit eye movements and their neural control in the monkey.

Authors:  R Eckmiller; M Mackeben
Journal:  Pflugers Arch       Date:  1978-10-18       Impact factor: 3.657

2.  Cerebral Integration of Ocular Movements.

Authors:  G Holmes
Journal:  Br Med J       Date:  1938-07-16

3.  Saccadic disorders caused by cooling the superior colliculus or the frontal eye field, or from combined lesions of both structures.

Authors:  E G Keating; S G Gooley
Journal:  Brain Res       Date:  1988-01-12       Impact factor: 3.252

4.  Frontal eye field efferents in the macaque monkey: II. Topography of terminal fields in midbrain and pons.

Authors:  G B Stanton; M E Goldberg; C J Bruce
Journal:  J Comp Neurol       Date:  1988-05-22       Impact factor: 3.215

5.  Effects of occipital lobectomy upon eye movements in primate.

Authors:  D S Zee; R J Tusa; S J Herdman; P H Butler; G Gücer
Journal:  J Neurophysiol       Date:  1987-10       Impact factor: 2.714

6.  Primate frontal eye fields. I. Single neurons discharging before saccades.

Authors:  C J Bruce; M E Goldberg
Journal:  J Neurophysiol       Date:  1985-03       Impact factor: 2.714

7.  The frontal eye field and attention.

Authors:  D P Crowne
Journal:  Psychol Bull       Date:  1983-03       Impact factor: 17.737

8.  Relationship between eye acceleration and retinal image velocity during foveal smooth pursuit in man and monkey.

Authors:  S G Lisberger; C Evinger; G W Johanson; A F Fuchs
Journal:  J Neurophysiol       Date:  1981-08       Impact factor: 2.714

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

Authors:  M R Dürsteler; R H Wurtz
Journal:  J Neurophysiol       Date:  1988-09       Impact factor: 2.714

10.  Model emulates human smooth pursuit system producing zero-latency target tracking.

Authors:  A T Bahill; J D McDonald
Journal:  Biol Cybern       Date:  1983       Impact factor: 2.086
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  44 in total

1.  Cortical visuomotor integration during eye pursuit and eye-finger pursuit.

Authors:  N Nishitani; K Uutela; H Shibasaki; R Hari
Journal:  J Neurosci       Date:  1999-04-01       Impact factor: 6.167

2.  Supplementary eye field activity reflects a decision rule governing smooth pursuit but not the decision.

Authors:  Shun-nan Yang; Helen Hwang; Joel Ford; Stephen Heinen
Journal:  J Neurophysiol       Date:  2010-02-17       Impact factor: 2.714

3.  Cortical afferents to the smooth-pursuit region of the macaque monkey's frontal eye field.

Authors:  Gregory B Stanton; Harriet R Friedman; Elisa C Dias; Charles J Bruce
Journal:  Exp Brain Res       Date:  2005-06-07       Impact factor: 1.972

Review 4.  The vestibular-related frontal cortex and its role in smooth-pursuit eye movements and vestibular-pursuit interactions.

Authors:  Junko Fukushima; Teppei Akao; Sergei Kurkin; Chris R S Kaneko; Kikuro Fukushima
Journal:  J Vestib Res       Date:  2006       Impact factor: 2.435

5.  Neural activity in the frontal pursuit area does not underlie pursuit target selection.

Authors:  Shaun Mahaffy; Richard J Krauzlis
Journal:  Vision Res       Date:  2010-10-21       Impact factor: 1.886

6.  An fMRI study on smooth pursuit and fixation suppression of the optokinetic reflex using similar visual stimulation.

Authors:  Caroline K L Schraa-Tam; Aad van der Lugt; Maarten A Frens; Marion Smits; P C A van Broekhoven; Josef N van der Geest
Journal:  Exp Brain Res       Date:  2007-10-26       Impact factor: 1.972

7.  Discharge of pursuit-related neurons in the caudal part of the frontal eye fields in juvenile monkeys with up-down pursuit asymmetry.

Authors:  Sergei Kurkin; Teppei Akao; Junko Fukushima; Kikuro Fukushima
Journal:  Exp Brain Res       Date:  2008-10-21       Impact factor: 1.972

8.  Gaze pursuit responses in nucleus reticularis tegmenti pontis of head-unrestrained macaques.

Authors:  David A Suzuki; Kathleen F Betelak; Robert D Yee
Journal:  J Neurophysiol       Date:  2008-11-05       Impact factor: 2.714

9.  A theory of the dual pathways for smooth pursuit based on dynamic gain control.

Authors:  Ulrich Nuding; Seiji Ono; Michael J Mustari; Ulrich Büttner; Stefan Glasauer
Journal:  J Neurophysiol       Date:  2008-04-02       Impact factor: 2.714

10.  A model of visually-guided smooth pursuit eye movements based on behavioral observations.

Authors:  R J Krauzlis; S G Lisberger
Journal:  J Comput Neurosci       Date:  1994-12       Impact factor: 1.621
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