Show Summary Details
- Editorial Advisory Board
- Dedication
- Preface
- Acknowledgments
- Contributors
- Chapter 1 The Next Decade of Research in the Basic Mechanisms of the Epilepsies
- Chapter 2 Herbert H. Jasper and the Basic Mechanisms of the Epilepsies
- Chapter 3 Why—and How—Do We Approach Basic Epilepsy Research?
- Chapter 4 Voltage-Gated Na+ Channels
- Chapter 5 Potassium Channels (Including KCNQ) and Epilepsy
- Chapter 6 Voltage-Gated Calcium Channels in Epilepsy
- Chapter 7 Hyperpolarization-Activated Cyclic Nucleotide-Gated (HCN) Ion Channelopathy in Epilepsy
- Chapter 8 Phasic GABAA-Mediated Inhibition
- Chapter 9 Tonic GABAA Receptor–Mediated Signaling in Epilepsy
- Chapter 10 Glutamatergic Mechanisms Related to Epilepsy
- Chapter 11 Glutamate Receptors in Epilepsy
- Chapter 12 Plasticity of Glutamate Synaptic Mechanisms
- Chapter 13 Neuronal Synchronization and Thalamocortical Rhythms during Sleep, Wake, and Epilepsy
- Chapter 14 Limbic Network Synchronization and Temporal Lobe Epilepsy
- Chapter 15 Imaging of Hippocampal Circuits in Epilepsy
- Chapter 16 Normal and Pathological High-Frequency Oscillations
- Chapter 17 Interictal Epileptiform Discharges in Partial Epilepsy
- Chapter 18 GABAA Receptor Function in Typical Absence Seizures
- Chapter 19 GABAB Receptor and Absence Epilepsy
- Chapter 20 Brainstem Networks
- Chapter 21 On the Basic Mechanisms of Infantile Spasms
- Chapter 22 Fast Oscillations and Synchronization Examined with In Vitro Models of Epileptogenesis
- Chapter 23 Computer Modeling of Epilepsy
- Chapter 24 Traumatic Brain Injury and Posttraumatic Epilepsy
- Chapter 25 Head Trauma and Epilepsy
- Chapter 26 Fever, Febrile Seizures, and Epileptogenesis
- Chapter 27 Role of Blood-Brain Barrier Dysfunction in Epileptogenesis
- Chapter 28 Cell Death and Survival Mechanisms after Single and Repeated Brief Seizures
- Chapter 29 Programmed Necrosis after Status Epilepticus
- Chapter 30 Histopathology of Human Epilepsy
- Chapter 31 The Time Course and Circuit Mechanisms of Acquired Epileptogenesis
- Chapter 32 Mossy Fiber Sprouting in the Dentate Gyrus
- Chapter 33 Kainate and Temporal Lobe Epilepsies
- Chapter 34 Abnormal Dentate Gyrus Network Circuitry in Temporal Lobe Epilepsy
- Chapter 35 Alterations in Synaptic Function in Epilepsy
- Chapter 36 Seizure-Induced Formation of Basal Dendrites on Granule Cells of the Rodent Dentate Gyrus
- Chapter 37 Perturbations of Dendritic Excitability in Epilepsy
- Chapter 38 Neurogenesis and Epilepsy
- Chapter 39 Temporal Lobe Epilepsy and the BDNF Receptor, TrkB
- Chapter 40 Alterations in the Distribution of GABAA Receptors in Epilepsy
- Chapter 41 GABAA Receptor Plasticity during Status Epilepticus
- Chapter 42 Plasticity of GABAA Receptors Relevant to Neurosteroid Actions
- Chapter 43 GABAA Receptor Plasticity in Alcohol Withdrawal
- Chapter 44 Regulation of GABAA Receptor Gene Expression and Epilepsy
- Chapter 45 Chloride Homeostasis and GABA Signaling in Temporal Lobe Epilepsy
- Chapter 46 Astrocytes and Epilepsy
- Chapter 47 Astrocyte Dysfunction in Epilepsy
- Chapter 48 Glia–Neuron Interactions in Ictogenesis and Epileptogenesis
- Chapter 49 Glia–Neuron Interactions
- Chapter 50 Genetic Epidemiology and Gene Discovery in Epilepsy
- Chapter 51 Strategies for Studying the Epilepsy Genome
- Chapter 52 Sodium Channel Mutations and Epilepsy
- Chapter 53 Potassium Channelopathies of Epilepsy
- Chapter 54 The Voltage-Gated Calcium Channel and Absence Epilepsy
- Chapter 55 Mutated GABAA Receptor Subunits in Idiopathic Generalized Epilepsy
- Chapter 56 The GABAAγ2(R43Q) Mouse Model of Human Genetic Epilepsy
- Chapter 57 GABAA Receptor Subunit Mutations and Genetic Epilepsies
- Chapter 58 Nicotinic Acetylcholine Receptor Mutations
- Chapter 59 Gene Interactions and Modifiers in Epilepsy
- Chapter 60 Rare Genetic Causes of Lissencephaly May Implicate Microtubule-Based Transport in the Pathogenesis of Cortical Dysplasias
- Chapter 61 The Generation of Cortical Interneurons
- Chapter 62 Genes in Infantile Epileptic Encephalopathies
- Chapter 63 Developing Models of Aristaless-Related Homeobox Mutations
- Chapter 64 Haploinsufficiency of STXBP1 and Ohtahara Syndrome
- Chapter 65 mTOR and Epileptogenesis in Developmental Brain Malformations
- Chapter 66 Major Susceptibility Genes for Common Idiopathic Epilepsies
- Chapter 67 Myoclonin1/EFHC1 in Cell Division, Neuroblast Migration, and Synapse/Dendrite Formation in Juvenile Myoclonic Epilepsy
- Chapter 68 Progressive Myoclonus Epilepsy of Lafora
- Chapter 69 Progressive Myoclonus Epilepsy
- Chapter 70 GABRB3, Epilepsy, and Neurodevelopment
- Chapter 71 Pathophysiology of Epilepsy in Autism Spectrum Disorders
- Chapter 72 Cognitive and Behavioral Comorbidities of Epilepsy
- Chapter 73 Migraine and Epilepsy—Shared Mechanisms within the Family of Episodic Disorders
- Chapter 74 Neurobiology of Depression as a Comorbidity of Epilepsy
- Chapter 75 Calcium Channel α2δ Subunits in Epilepsy and as Targets for Antiepileptic Drugs
- Chapter 76 Targeting SV2A for Discovery of Antiepileptic Drugs
- Chapter 77 Neurosteroids—Endogenous Regulators of Seizure Susceptibility and Role in the Treatment of Epilepsy
- Chapter 78 Mechanisms of Ketogenic Diet Action
- Chapter 79 Deep Brain Stimulation for Epilepsy
- Chapter 80 Animal Models for Evaluating Antiepileptogenesis
- Chapter 81 Strategies for Antiepileptogenesis
- Chapter 82 Neonatal Seizures and Neuronal Transmembrane Ion Transport
- Chapter 83 Antiepileptogenesis, Plasticity of AED Targets, Drug Resistance, and Targeting the Immature Brain
- Chapter 84 Drug Resistance
- Chapter 85 Neural Stem Cell Therapy for Temporal Lobe Epilepsy
- Chapter 86 Embryonic Stem Cell Therapy for Intractable Epilepsy
- Chapter 87 Cell Therapy Using GABAergic Neural Progenitors
- Chapter 88 Reversing Disorders of Neuronal Migration and Differentiation in Animal Models
- Chapter 89 Gene Therapy of Focal-Onset Epilepsy Using Adeno-Associated Virus Vector-Mediated Overexpression of Neuropeptide Y
- Chapter 90 Adenosine Augmentation Therapy
- Index
(p. 122) Glutamatergic Mechanisms Related to Epilepsy: Ionotropic Receptors
(p. 122) Glutamatergic Mechanisms Related to Epilepsy: Ionotropic Receptors
- Chapter:
- (p. 122) Glutamatergic Mechanisms Related to Epilepsy
- Author(s):
Raymond Dingledine
- DOI:
- 10.1093/med/9780199746545.003.0010
The ionotropic glutamate receptors are ligand-gated ion channels that mediate the vast majority of excitatory neurotransmission in the brain. The past 20 years have been a golden age for glutamate receptor research. Even before that time, in the early 1980s the invention of the first selective antagonists for what would come to be known as N-methyl-
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- Editorial Advisory Board
- Dedication
- Preface
- Acknowledgments
- Contributors
- Chapter 1 The Next Decade of Research in the Basic Mechanisms of the Epilepsies
- Chapter 2 Herbert H. Jasper and the Basic Mechanisms of the Epilepsies
- Chapter 3 Why—and How—Do We Approach Basic Epilepsy Research?
- Chapter 4 Voltage-Gated Na+ Channels
- Chapter 5 Potassium Channels (Including KCNQ) and Epilepsy
- Chapter 6 Voltage-Gated Calcium Channels in Epilepsy
- Chapter 7 Hyperpolarization-Activated Cyclic Nucleotide-Gated (HCN) Ion Channelopathy in Epilepsy
- Chapter 8 Phasic GABAA-Mediated Inhibition
- Chapter 9 Tonic GABAA Receptor–Mediated Signaling in Epilepsy
- Chapter 10 Glutamatergic Mechanisms Related to Epilepsy
- Chapter 11 Glutamate Receptors in Epilepsy
- Chapter 12 Plasticity of Glutamate Synaptic Mechanisms
- Chapter 13 Neuronal Synchronization and Thalamocortical Rhythms during Sleep, Wake, and Epilepsy
- Chapter 14 Limbic Network Synchronization and Temporal Lobe Epilepsy
- Chapter 15 Imaging of Hippocampal Circuits in Epilepsy
- Chapter 16 Normal and Pathological High-Frequency Oscillations
- Chapter 17 Interictal Epileptiform Discharges in Partial Epilepsy
- Chapter 18 GABAA Receptor Function in Typical Absence Seizures
- Chapter 19 GABAB Receptor and Absence Epilepsy
- Chapter 20 Brainstem Networks
- Chapter 21 On the Basic Mechanisms of Infantile Spasms
- Chapter 22 Fast Oscillations and Synchronization Examined with In Vitro Models of Epileptogenesis
- Chapter 23 Computer Modeling of Epilepsy
- Chapter 24 Traumatic Brain Injury and Posttraumatic Epilepsy
- Chapter 25 Head Trauma and Epilepsy
- Chapter 26 Fever, Febrile Seizures, and Epileptogenesis
- Chapter 27 Role of Blood-Brain Barrier Dysfunction in Epileptogenesis
- Chapter 28 Cell Death and Survival Mechanisms after Single and Repeated Brief Seizures
- Chapter 29 Programmed Necrosis after Status Epilepticus
- Chapter 30 Histopathology of Human Epilepsy
- Chapter 31 The Time Course and Circuit Mechanisms of Acquired Epileptogenesis
- Chapter 32 Mossy Fiber Sprouting in the Dentate Gyrus
- Chapter 33 Kainate and Temporal Lobe Epilepsies
- Chapter 34 Abnormal Dentate Gyrus Network Circuitry in Temporal Lobe Epilepsy
- Chapter 35 Alterations in Synaptic Function in Epilepsy
- Chapter 36 Seizure-Induced Formation of Basal Dendrites on Granule Cells of the Rodent Dentate Gyrus
- Chapter 37 Perturbations of Dendritic Excitability in Epilepsy
- Chapter 38 Neurogenesis and Epilepsy
- Chapter 39 Temporal Lobe Epilepsy and the BDNF Receptor, TrkB
- Chapter 40 Alterations in the Distribution of GABAA Receptors in Epilepsy
- Chapter 41 GABAA Receptor Plasticity during Status Epilepticus
- Chapter 42 Plasticity of GABAA Receptors Relevant to Neurosteroid Actions
- Chapter 43 GABAA Receptor Plasticity in Alcohol Withdrawal
- Chapter 44 Regulation of GABAA Receptor Gene Expression and Epilepsy
- Chapter 45 Chloride Homeostasis and GABA Signaling in Temporal Lobe Epilepsy
- Chapter 46 Astrocytes and Epilepsy
- Chapter 47 Astrocyte Dysfunction in Epilepsy
- Chapter 48 Glia–Neuron Interactions in Ictogenesis and Epileptogenesis
- Chapter 49 Glia–Neuron Interactions
- Chapter 50 Genetic Epidemiology and Gene Discovery in Epilepsy
- Chapter 51 Strategies for Studying the Epilepsy Genome
- Chapter 52 Sodium Channel Mutations and Epilepsy
- Chapter 53 Potassium Channelopathies of Epilepsy
- Chapter 54 The Voltage-Gated Calcium Channel and Absence Epilepsy
- Chapter 55 Mutated GABAA Receptor Subunits in Idiopathic Generalized Epilepsy
- Chapter 56 The GABAAγ2(R43Q) Mouse Model of Human Genetic Epilepsy
- Chapter 57 GABAA Receptor Subunit Mutations and Genetic Epilepsies
- Chapter 58 Nicotinic Acetylcholine Receptor Mutations
- Chapter 59 Gene Interactions and Modifiers in Epilepsy
- Chapter 60 Rare Genetic Causes of Lissencephaly May Implicate Microtubule-Based Transport in the Pathogenesis of Cortical Dysplasias
- Chapter 61 The Generation of Cortical Interneurons
- Chapter 62 Genes in Infantile Epileptic Encephalopathies
- Chapter 63 Developing Models of Aristaless-Related Homeobox Mutations
- Chapter 64 Haploinsufficiency of STXBP1 and Ohtahara Syndrome
- Chapter 65 mTOR and Epileptogenesis in Developmental Brain Malformations
- Chapter 66 Major Susceptibility Genes for Common Idiopathic Epilepsies
- Chapter 67 Myoclonin1/EFHC1 in Cell Division, Neuroblast Migration, and Synapse/Dendrite Formation in Juvenile Myoclonic Epilepsy
- Chapter 68 Progressive Myoclonus Epilepsy of Lafora
- Chapter 69 Progressive Myoclonus Epilepsy
- Chapter 70 GABRB3, Epilepsy, and Neurodevelopment
- Chapter 71 Pathophysiology of Epilepsy in Autism Spectrum Disorders
- Chapter 72 Cognitive and Behavioral Comorbidities of Epilepsy
- Chapter 73 Migraine and Epilepsy—Shared Mechanisms within the Family of Episodic Disorders
- Chapter 74 Neurobiology of Depression as a Comorbidity of Epilepsy
- Chapter 75 Calcium Channel α2δ Subunits in Epilepsy and as Targets for Antiepileptic Drugs
- Chapter 76 Targeting SV2A for Discovery of Antiepileptic Drugs
- Chapter 77 Neurosteroids—Endogenous Regulators of Seizure Susceptibility and Role in the Treatment of Epilepsy
- Chapter 78 Mechanisms of Ketogenic Diet Action
- Chapter 79 Deep Brain Stimulation for Epilepsy
- Chapter 80 Animal Models for Evaluating Antiepileptogenesis
- Chapter 81 Strategies for Antiepileptogenesis
- Chapter 82 Neonatal Seizures and Neuronal Transmembrane Ion Transport
- Chapter 83 Antiepileptogenesis, Plasticity of AED Targets, Drug Resistance, and Targeting the Immature Brain
- Chapter 84 Drug Resistance
- Chapter 85 Neural Stem Cell Therapy for Temporal Lobe Epilepsy
- Chapter 86 Embryonic Stem Cell Therapy for Intractable Epilepsy
- Chapter 87 Cell Therapy Using GABAergic Neural Progenitors
- Chapter 88 Reversing Disorders of Neuronal Migration and Differentiation in Animal Models
- Chapter 89 Gene Therapy of Focal-Onset Epilepsy Using Adeno-Associated Virus Vector-Mediated Overexpression of Neuropeptide Y
- Chapter 90 Adenosine Augmentation Therapy
- Index
