Literature DB >> 8765653

A model of the cerebellum in adaptive control of saccadic gain. I. The model and its biological substrate.

N Schweighofer1, M A Arbib, P F Dominey.   

Abstract

We review data showing that the cerebellum is required for adaptation of saccadic gain to repeated presentations of dual-step visual targets and thus, presumably, for providing adaptive corrections for the brainstem saccade generator in response to any error created by the open-loop saccadic system. We model the adaptability of the system in terms of plasticity of synapses from parallel fibers to Purkinje cells in cerebellar cortex, stressing the integration of cerebellar cortex and nuclei in microzones as the units for correction of motor pattern generators. We propose a model of the inferior olive as an error detector, and use a 'window of eligibility' to insure that error signals that elicit a corrective movement are used to adjust the original movement, not the secondary movement. In a companion paper we simulate this large, realistic network of neural-like units to study the complex spatiotemporal behavior of neuronal subpopulations implicated in the control and adaptation of saccades.

Entities:  

Mesh:

Year:  1996        PMID: 8765653     DOI: 10.1007/bf00238736

Source DB:  PubMed          Journal:  Biol Cybern        ISSN: 0340-1200            Impact factor:   2.086


  34 in total

1.  Burst discharges of mossy fibers in the oculomotor vermis of macaque monkeys during saccadic eye movements.

Authors:  K Ohtsuka; H Noda
Journal:  Neurosci Res       Date:  1992-10       Impact factor: 3.304

2.  A cortico-subcortical model for generation of spatially accurate sequential saccades.

Authors:  P F Dominey; M A Arbib
Journal:  Cereb Cortex       Date:  1992 Mar-Apr       Impact factor: 5.357

3.  Purkinje cell activity during motor learning.

Authors:  P F Gilbert; W T Thach
Journal:  Brain Res       Date:  1977-06-10       Impact factor: 3.252

4.  Distributed representation of limb motor programs in arrays of adjustable pattern generators.

Authors:  N E Berthier; S P Singh; A G Barto; J C Houk
Journal:  J Cogn Neurosci       Date:  1993       Impact factor: 3.225

Review 5.  Cerebellar control of saccadic eye movements: its neural mechanisms and pathways.

Authors:  H Noda
Journal:  Jpn J Physiol       Date:  1991

6.  Activation of protein kinase C induces a long-term depression of glutamate sensitivity of cerebellar Purkinje cells. An in vitro study.

Authors:  F Crepel; M Krupa
Journal:  Brain Res       Date:  1988-08-23       Impact factor: 3.252

7.  Role of the caudal fastigial nucleus in saccade generation. I. Neuronal discharge pattern.

Authors:  A F Fuchs; F R Robinson; A Straube
Journal:  J Neurophysiol       Date:  1993-11       Impact factor: 2.714

8.  Toward a modern theory of adaptive networks: expectation and prediction.

Authors:  R S Sutton; A G Barto
Journal:  Psychol Rev       Date:  1981-03       Impact factor: 8.934

9.  Effects of cerebellar lesions on saccadic eye movements.

Authors:  L Ritchie
Journal:  J Neurophysiol       Date:  1976-11       Impact factor: 2.714

10.  The length of cerebellar parallel fibers in chicken and rhesus monkey.

Authors:  E Mugnaini
Journal:  J Comp Neurol       Date:  1983-10-10       Impact factor: 3.215
View more
  14 in total

1.  Synaptic control of spiking in cerebellar Purkinje cells: dynamic current clamp based on model conductances.

Authors:  D Jaeger; J M Bower
Journal:  J Neurosci       Date:  1999-07-15       Impact factor: 6.167

2.  Chaos may enhance information transmission in the inferior olive.

Authors:  Nicolas Schweighofer; Kenji Doya; Hidekazu Fukai; Jean Vianney Chiron; Tetsuya Furukawa; Mitsuo Kawato
Journal:  Proc Natl Acad Sci U S A       Date:  2004-03-22       Impact factor: 11.205

Review 3.  Saccade adaptation as a model of learning in voluntary movements.

Authors:  Yoshiki Iwamoto; Yuki Kaku
Journal:  Exp Brain Res       Date:  2010-06-11       Impact factor: 1.972

4.  Discharge of monkey nucleus reticularis tegmenti pontis neurons changes during saccade adaptation.

Authors:  N Takeichi; C R S Kaneko; A F Fuchs
Journal:  J Neurophysiol       Date:  2005-05-25       Impact factor: 2.714

Review 5.  Evaluating the adaptive-filter model of the cerebellum.

Authors:  Paul Dean; John Porrill
Journal:  J Physiol       Date:  2011-04-18       Impact factor: 5.182

6.  A model of the cerebellum in adaptive control of saccadic gain. II. Simulation results.

Authors:  N Schweighofer; M A Arbib; P F Dominey
Journal:  Biol Cybern       Date:  1996-07       Impact factor: 2.086

7.  Saccadic adaptation to a systematically varying disturbance.

Authors:  Carlos R Cassanello; Sven Ohl; Martin Rolfs
Journal:  J Neurophysiol       Date:  2016-04-20       Impact factor: 2.714

8.  Hierarchical control of two-dimensional gaze saccades.

Authors:  Pierre M Daye; Lance M Optican; Gunnar Blohm; Philippe Lefèvre
Journal:  J Comput Neurosci       Date:  2013-09-06       Impact factor: 1.621

9.  Distributed cerebellar plasticity implements adaptable gain control in a manipulation task: a closed-loop robotic simulation.

Authors:  Jesús A Garrido; Niceto R Luque; Egidio D'Angelo; Eduardo Ros
Journal:  Front Neural Circuits       Date:  2013-10-09       Impact factor: 3.492

10.  Biohybrid Control of General Linear Systems Using the Adaptive Filter Model of Cerebellum.

Authors:  Emma D Wilson; Tareq Assaf; Martin J Pearson; Jonathan M Rossiter; Paul Dean; Sean R Anderson; John Porrill
Journal:  Front Neurorobot       Date:  2015-07-20       Impact factor: 2.650
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.