The Resource Cerebellar learning, edited by Narender Ramnani

Cerebellar learning, edited by Narender Ramnani

Label
Cerebellar learning
Title
Cerebellar learning
Statement of responsibility
edited by Narender Ramnani
Subject
Genre
Language
  • eng
  • eng
Summary
Progress in Brain Research is the most acclaimed and accomplished series in neuroscience, firmly established as an extensive documentation of the advances in contemporary brain research. The volumes, some of which are derived from important international symposia, contain authoritative reviews and original articles by invited specialists. The rigorous editing of the volumes assures that they will appeal to all laboratory and clinical brain research workers in the various disciplines: neuroanatomy, neurophysiology, neuropharmacology, neuroendocrinology, neuropathology, basic neurology
Member of
Cataloging source
MiAaPQ
Dewey number
616.3489
Index
index present
Language note
English
LC call number
QP379
LC item number
.C47 2014
Literary form
non fiction
Nature of contents
  • dictionaries
  • bibliography
Series statement
Progress in Brain Research
Series volume
210
http://library.link/vocab/subjectName
Cerebellum
Label
Cerebellar learning, edited by Narender Ramnani
Instantiates
Publication
Copyright
Note
Description based upon print version of record
Bibliography note
Includes bibliographical references and index
Carrier category
online resource
Carrier category code
  • cr
Content category
text
Content type code
  • txt
Contents
  • Front Cover; Cerebellar Learning; Copyright; Contributors; Preface; Contents; Chapter 1: Long-Term Depression as a Model of Cerebellar Plasticity; 1. A Historical Overview of LTD Studies; 1.1. Leading Theories; 1.2. Experimental Approach to LTD and Motor Learning; 1.3. Memory Mechanisms in the Cerebellum; 1.4. Recent Issues; 2. Molecular Mechanisms of LTD; 2.1. Signal Transduction Underlying LTD; 2.2. Constitutive Trafficking of AMPA Receptors; 2.3. Receptor Recycling in LTP; 2.4. Receptor Recycling in LTD; 3. Roles of LTD in Motor Learning; 3.1. Adaptation of HOKR; 3.2. Adaptation of HVOR
  • 3.3. LTD in Fast HOKR Adaptation3.4. Memory Transfer in Slow HOKR Adaptation; 3.5. LTD and Memory Transfer; 3.6. Saccade and Other Reflexes; 3.7. Arm Movement; 4. Significance of LTD in Cerebellar Neural Network; 4.1. Role of Plasticity: Memory Formation Versus Signal Enhancement; 4.2. Induction Mechanism: Climbing-Fiber Specific Changes Versus Nonspecific Changes; 4.3. Learning Principles: Supervised Learning Versus Unsupervised Learning; 4.4. Ideal Location for Memory: Purkinje Cells Versus Other Cells; 4.5. Memory Formation Process: Acquisition Versus Consolidation
  • 4.6. Time at Impairment: Mature Brain Versus Developing Brain5. LTD Versus Learning Mismatch; 5.1. Experimental Gaps in Testing of LTD and Motor Learning; 5.2. Compensation Might Restore Motor Learning; 5.3. Limitations in Testing LTD in Slices; 6. Perspectives; Acknowledgments; References; Chapter 2: The Organization of Plasticity in the Cerebellar Cortex: From Synapses to Control; 1. Introduction; 2. Plasticity in the Granular Layer; 3. Mossy Fiber-Granule Cell LTP and LTD; 3.1. Plasticity in the Granular Layer Inhibitory Circuit; 3.2. Plasticity in the Granular Layer In Vivo
  • 3.3. The Consequences of Granular Layer Plasticity: Geometry, Timing, and Coding3.4. Theoretical Implications; 4. Plasticity in the Molecular Layer; 4.1. Mechanisms of Postsynaptic Parallel Fiber LTP and LTD; 4.2. Mechanisms of Presynaptic Parallel Fiber LTP and LTD; 4.3. Mechanisms of Climbing Fiber LTD; 4.4. Plasticity of Purkinje Cell Intrinsic Excitability; 4.5. Plasticity at Molecular Layer Inhibitory Synapses; 4.6. The Neurophysiological Consequences of Molecular Layer Plasticity; 4.7. The Behavioral Consequences of Molecular Layer Plasticity
  • 5. An Integrated View of Cerebellar Cortical Plasticity5.1. Potentiation of Transmission Channels and Signal-to-Noise Ratio in the Mossy Fiber Pathway; 5.1.1. The NO System of Granule Cells; 5.1.2. The Calcium Control System in Purkinje Cells; 5.2. Contrast Enhancement and Geometrical Organization of Plasticity; 5.3. Coordination of Plasticity During Patterned Circuit Activity; 5.4. Gating of Plasticity by Neuromodulatory Systems; 5.4.1. Neuromodulatory Mechanisms of Gating; 6. Cerebellar Cortical Plasticity and Timing; 7. Integration of Plasticity in the Cerebellar Cortex and Nuclei
  • 7.1. Plasticity in the Deep Cerebellar Nuclei
Dimensions
unknown
Extent
1 online resource (312 p.)
Form of item
online
Isbn
9780444634269
Media category
computer
Media type code
  • c
Specific material designation
remote
System control number
  • (EBL)1710538
  • (SSID)ssj0001305584
  • (PQKBManifestationID)11725499
  • (PQKBTitleCode)TC0001305584
  • (PQKBWorkID)11273576
  • (PQKB)11536770
  • (MiAaPQ)EBC1710538
  • (EXLCZ)993710000000128121
Label
Cerebellar learning, edited by Narender Ramnani
Publication
Copyright
Note
Description based upon print version of record
Bibliography note
Includes bibliographical references and index
Carrier category
online resource
Carrier category code
  • cr
Content category
text
Content type code
  • txt
Contents
  • Front Cover; Cerebellar Learning; Copyright; Contributors; Preface; Contents; Chapter 1: Long-Term Depression as a Model of Cerebellar Plasticity; 1. A Historical Overview of LTD Studies; 1.1. Leading Theories; 1.2. Experimental Approach to LTD and Motor Learning; 1.3. Memory Mechanisms in the Cerebellum; 1.4. Recent Issues; 2. Molecular Mechanisms of LTD; 2.1. Signal Transduction Underlying LTD; 2.2. Constitutive Trafficking of AMPA Receptors; 2.3. Receptor Recycling in LTP; 2.4. Receptor Recycling in LTD; 3. Roles of LTD in Motor Learning; 3.1. Adaptation of HOKR; 3.2. Adaptation of HVOR
  • 3.3. LTD in Fast HOKR Adaptation3.4. Memory Transfer in Slow HOKR Adaptation; 3.5. LTD and Memory Transfer; 3.6. Saccade and Other Reflexes; 3.7. Arm Movement; 4. Significance of LTD in Cerebellar Neural Network; 4.1. Role of Plasticity: Memory Formation Versus Signal Enhancement; 4.2. Induction Mechanism: Climbing-Fiber Specific Changes Versus Nonspecific Changes; 4.3. Learning Principles: Supervised Learning Versus Unsupervised Learning; 4.4. Ideal Location for Memory: Purkinje Cells Versus Other Cells; 4.5. Memory Formation Process: Acquisition Versus Consolidation
  • 4.6. Time at Impairment: Mature Brain Versus Developing Brain5. LTD Versus Learning Mismatch; 5.1. Experimental Gaps in Testing of LTD and Motor Learning; 5.2. Compensation Might Restore Motor Learning; 5.3. Limitations in Testing LTD in Slices; 6. Perspectives; Acknowledgments; References; Chapter 2: The Organization of Plasticity in the Cerebellar Cortex: From Synapses to Control; 1. Introduction; 2. Plasticity in the Granular Layer; 3. Mossy Fiber-Granule Cell LTP and LTD; 3.1. Plasticity in the Granular Layer Inhibitory Circuit; 3.2. Plasticity in the Granular Layer In Vivo
  • 3.3. The Consequences of Granular Layer Plasticity: Geometry, Timing, and Coding3.4. Theoretical Implications; 4. Plasticity in the Molecular Layer; 4.1. Mechanisms of Postsynaptic Parallel Fiber LTP and LTD; 4.2. Mechanisms of Presynaptic Parallel Fiber LTP and LTD; 4.3. Mechanisms of Climbing Fiber LTD; 4.4. Plasticity of Purkinje Cell Intrinsic Excitability; 4.5. Plasticity at Molecular Layer Inhibitory Synapses; 4.6. The Neurophysiological Consequences of Molecular Layer Plasticity; 4.7. The Behavioral Consequences of Molecular Layer Plasticity
  • 5. An Integrated View of Cerebellar Cortical Plasticity5.1. Potentiation of Transmission Channels and Signal-to-Noise Ratio in the Mossy Fiber Pathway; 5.1.1. The NO System of Granule Cells; 5.1.2. The Calcium Control System in Purkinje Cells; 5.2. Contrast Enhancement and Geometrical Organization of Plasticity; 5.3. Coordination of Plasticity During Patterned Circuit Activity; 5.4. Gating of Plasticity by Neuromodulatory Systems; 5.4.1. Neuromodulatory Mechanisms of Gating; 6. Cerebellar Cortical Plasticity and Timing; 7. Integration of Plasticity in the Cerebellar Cortex and Nuclei
  • 7.1. Plasticity in the Deep Cerebellar Nuclei
Dimensions
unknown
Extent
1 online resource (312 p.)
Form of item
online
Isbn
9780444634269
Media category
computer
Media type code
  • c
Specific material designation
remote
System control number
  • (EBL)1710538
  • (SSID)ssj0001305584
  • (PQKBManifestationID)11725499
  • (PQKBTitleCode)TC0001305584
  • (PQKBWorkID)11273576
  • (PQKB)11536770
  • (MiAaPQ)EBC1710538
  • (EXLCZ)993710000000128121

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