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Publication Date2013, ISBN 0444534970, Volume 116
A variety of noninvasive brain stimulation techniques have been used to study neuronal plasticity. Mostly, noninvasive techniques have been employed, and the...
homeostatic plasticity | quadripulse stimulation | motor learning | plasticity | paired associative stimulation | transcranial magnetic stimulation | theta-burst stimulation | metaplasticity | transcranial direct current stimulation | Transcranial magnetic stimulation | Theta-burst stimulation | Metaplasticity | Paired associative stimulation | Plasticity | Quadripulse stimulation | Homeostatic plasticity | Motor learning | Transcranial direct current stimulation | Transcranial Magnetic Stimulation | Animals | Neuronal Plasticity - physiology | Models, Biological | Humans | Brain - physiology | Electric Stimulation - methods
homeostatic plasticity | quadripulse stimulation | motor learning | plasticity | paired associative stimulation | transcranial magnetic stimulation | theta-burst stimulation | metaplasticity | transcranial direct current stimulation | Transcranial magnetic stimulation | Theta-burst stimulation | Metaplasticity | Paired associative stimulation | Plasticity | Quadripulse stimulation | Homeostatic plasticity | Motor learning | Transcranial direct current stimulation | Transcranial Magnetic Stimulation | Animals | Neuronal Plasticity - physiology | Models, Biological | Humans | Brain - physiology | Electric Stimulation - methods
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Loading RightsCurrent Opinion in Neurobiology, ISSN 0959-4388, 2011, Volume 21, Issue 2, pp. 291 - 298
Research highlights ► Cp-AMPARs are expressed at the early stage of Hebbian and homeostatic synaptic plasticity. ► Cp-AMPARs are replaced with GluA2-containing...
Neurology | Psychiatry | GLUR2 SUBUNIT | SYNAPSES | HIPPOCAMPAL PYRAMIDAL NEURONS | MECHANISMS | LONG-TERM POTENTIATION | HOMEOSTATIC SYNAPTIC PLASTICITY | ACTIVITY-DEPENDENT REGULATION | SUBUNIT COMPOSITION | TNF-ALPHA | EXPRESSION | NEUROSCIENCES | Animals | Neuronal Plasticity - physiology | Synapses - metabolism | Calcium - metabolism | Calcium Signaling - physiology | Humans | Receptors, AMPA - metabolism | Calcium influx
Neurology | Psychiatry | GLUR2 SUBUNIT | SYNAPSES | HIPPOCAMPAL PYRAMIDAL NEURONS | MECHANISMS | LONG-TERM POTENTIATION | HOMEOSTATIC SYNAPTIC PLASTICITY | ACTIVITY-DEPENDENT REGULATION | SUBUNIT COMPOSITION | TNF-ALPHA | EXPRESSION | NEUROSCIENCES | Animals | Neuronal Plasticity - physiology | Synapses - metabolism | Calcium - metabolism | Calcium Signaling - physiology | Humans | Receptors, AMPA - metabolism | Calcium influx
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Loading RightsPhilosophical Transactions of the Royal Society B: Biological Sciences, ISSN 0962-8436, 03/2017, Volume 372, Issue 1715, pp. 20160153 - 20160153
Growing experimental evidence shows that both homeostatic and Hebbian synaptic plasticity can be expressed presynaptically as well as postsynaptically. In this...
Homoeostatic plasticity | Hebbian plasticity | Long-term potentiation | Synaptic release | Synaptic plasticity | Spiketiming-dependent plasticity | INTRINSIC EXCITABILITY | QUANTAL TRANSMISSION | NEUROTRANSMITTER RELEASE | PRESYNAPTIC RELEASE | homoeostatic plasticity | HOMEOSTATIC PLASTICITY | VISUAL-CORTEX | BIOLOGY | synaptic release | synaptic plasticity | TIMING-DEPENDENT PLASTICITY | NEOCORTICAL PYRAMIDAL NEURONS | spike-timing-dependent plasticity | ACTIVITY DEPRIVATION | long-term potentiation | Sensation | Animals | Neuronal Plasticity | Humans | Memory | Homeostasis | Reaction Time | Models, Neurological | Plasticity (functional) | Plasticity (homeostatic) | Firing pattern | Plasticity (synaptic) | Plasticity (Hebbian) | Plasticity | Sensory perception | Loci | 133 | 1001 | Review
Homoeostatic plasticity | Hebbian plasticity | Long-term potentiation | Synaptic release | Synaptic plasticity | Spiketiming-dependent plasticity | INTRINSIC EXCITABILITY | QUANTAL TRANSMISSION | NEUROTRANSMITTER RELEASE | PRESYNAPTIC RELEASE | homoeostatic plasticity | HOMEOSTATIC PLASTICITY | VISUAL-CORTEX | BIOLOGY | synaptic release | synaptic plasticity | TIMING-DEPENDENT PLASTICITY | NEOCORTICAL PYRAMIDAL NEURONS | spike-timing-dependent plasticity | ACTIVITY DEPRIVATION | long-term potentiation | Sensation | Animals | Neuronal Plasticity | Humans | Memory | Homeostasis | Reaction Time | Models, Neurological | Plasticity (functional) | Plasticity (homeostatic) | Firing pattern | Plasticity (synaptic) | Plasticity (Hebbian) | Plasticity | Sensory perception | Loci | 133 | 1001 | Review
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Loading RightsPhilosophical Transactions of the Royal Society B: Biological Sciences, ISSN 0962-8436, 03/2017, Volume 372, Issue 1715, pp. 20160259 - 20160259
We review a body of theoretical and experimental research on Hebbian and homeostatic plasticity, starting from a puzzling observation: while homeostasis of...
Heterosynaptic plasticity | Homeostasis | Rapid compensatory processes | Synaptic scaling | Hebbian plasticity | Metaplasticity | heterosynaptic plasticity | rapid compensatory processes | HOMEOSTATIC PLASTICITY | homeostasis | NEURAL-NETWORKS | VISUAL-CORTEX | synaptic scaling | TOTAL SYNAPTIC WEIGHT | BIOLOGY | WHISKER MAP PLASTICITY | LONG-TERM POTENTIATION | TIMING-DEPENDENT PLASTICITY | DENTATE GYRUS | metaplasticity | NEUROTRANSMITTER RELEASE PROBABILITY | Learning | Animals | Models, Neurological | Neuronal Plasticity | Memory | Plasticity (homeostatic) | Computer simulation | Circuits | Firing rate | Mental depression | Plasticity (neural) | Plasticity (Hebbian) | Plasticity (synaptic) | Neural networks | Plasticity | Mathematical models | Control stability | Experimental research | Synapses | 133 | 1001 | Review
Heterosynaptic plasticity | Homeostasis | Rapid compensatory processes | Synaptic scaling | Hebbian plasticity | Metaplasticity | heterosynaptic plasticity | rapid compensatory processes | HOMEOSTATIC PLASTICITY | homeostasis | NEURAL-NETWORKS | VISUAL-CORTEX | synaptic scaling | TOTAL SYNAPTIC WEIGHT | BIOLOGY | WHISKER MAP PLASTICITY | LONG-TERM POTENTIATION | TIMING-DEPENDENT PLASTICITY | DENTATE GYRUS | metaplasticity | NEUROTRANSMITTER RELEASE PROBABILITY | Learning | Animals | Models, Neurological | Neuronal Plasticity | Memory | Plasticity (homeostatic) | Computer simulation | Circuits | Firing rate | Mental depression | Plasticity (neural) | Plasticity (Hebbian) | Plasticity (synaptic) | Neural networks | Plasticity | Mathematical models | Control stability | Experimental research | Synapses | 133 | 1001 | Review
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Loading RightsPhilosophical Transactions of the Royal Society B: Biological Sciences, ISSN 0962-8436, 03/2017, Volume 372, Issue 1715, pp. 20160155 - 20160155
Hebbian and homeostatic plasticity are two major forms of plasticity in the nervous system: Hebbian plasticity provides a synaptic basis for associative...
Homeostatic plasticity | Hebbian plasticity | Retinoic acid | Metaplasticity | PRIMARY VISUAL-CORTEX | GTPASE-ACTIVATING PROTEIN | SYNAPTIC PLASTICITY | GLIAL TNF-ALPHA | homeostatic plasticity | retinoic acid | EXPERIENCE-DEPENDENT PLASTICITY | RETINOIC ACID SYNTHESIS | LONG-TERM DEPRESSION | IN-VIVO | BIOLOGY | metaplasticity | OCULAR DOMINANCE PLASTICITY | CRITICAL-PERIOD PLASTICITY | Central Nervous System - physiology | Homeostasis | Animals | Mammals | Neuronal Plasticity | Synapses - physiology | Plasticity (homeostatic) | Molecular modelling | Plasticity (synaptic) | Plasticity (Hebbian) | Central nervous system | Plasticity | Nervous system | Associative learning | Plastic properties | 133 | 1001 | Review
Homeostatic plasticity | Hebbian plasticity | Retinoic acid | Metaplasticity | PRIMARY VISUAL-CORTEX | GTPASE-ACTIVATING PROTEIN | SYNAPTIC PLASTICITY | GLIAL TNF-ALPHA | homeostatic plasticity | retinoic acid | EXPERIENCE-DEPENDENT PLASTICITY | RETINOIC ACID SYNTHESIS | LONG-TERM DEPRESSION | IN-VIVO | BIOLOGY | metaplasticity | OCULAR DOMINANCE PLASTICITY | CRITICAL-PERIOD PLASTICITY | Central Nervous System - physiology | Homeostasis | Animals | Mammals | Neuronal Plasticity | Synapses - physiology | Plasticity (homeostatic) | Molecular modelling | Plasticity (synaptic) | Plasticity (Hebbian) | Central nervous system | Plasticity | Nervous system | Associative learning | Plastic properties | 133 | 1001 | Review
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Loading RightsPhilosophical Transactions of the Royal Society B: Biological Sciences, ISSN 0962-8436, 03/2017, Volume 372, Issue 1715, pp. 20160157 - 20160157
We compare the circuit and cellular mechanisms for homeostatic plasticity that have been discovered in rodent somatosensory (S1) and visual (V1) cortex. Both...
Sensory cortex | Somatosensory cortex | Homeostatic plasticity | Inhibition | Whisker | Firing rate homeostasis | firing rate homeostasis | INHIBITORY SYNAPSES | whisker | inhibition | BARREL CORTEX | sensory cortex | homeostatic plasticity | EXPERIENCE-DEPENDENT PLASTICITY | IN-VIVO | BIOLOGY | WHISKER MAP PLASTICITY | INDUCED SYNAPTIC DEPRESSION | somatosensory cortex | LONG-TERM POTENTIATION | OCULAR DOMINANCE PLASTICITY | CRITICAL-PERIOD PLASTICITY | Somatosensory Cortex - physiology | Animals | Sensory Deprivation | Neuronal Plasticity | Pyramidal Cells - physiology | Homeostasis | Rats | Mice | Visual Cortex - physiology | Plasticity (homeostatic) | Deprivation | Visual pathways | Excitability | Firing rate | Cortex (somatosensory) | Cortex (visual) | Parvalbumin | Sensory deprivation | Plasticity (Hebbian) | Plasticity (synaptic) | Plasticity (visual) | Plasticity | Plasticity (cortical) | Scaling | Plastic foam | 133 | 1001 | Review
Sensory cortex | Somatosensory cortex | Homeostatic plasticity | Inhibition | Whisker | Firing rate homeostasis | firing rate homeostasis | INHIBITORY SYNAPSES | whisker | inhibition | BARREL CORTEX | sensory cortex | homeostatic plasticity | EXPERIENCE-DEPENDENT PLASTICITY | IN-VIVO | BIOLOGY | WHISKER MAP PLASTICITY | INDUCED SYNAPTIC DEPRESSION | somatosensory cortex | LONG-TERM POTENTIATION | OCULAR DOMINANCE PLASTICITY | CRITICAL-PERIOD PLASTICITY | Somatosensory Cortex - physiology | Animals | Sensory Deprivation | Neuronal Plasticity | Pyramidal Cells - physiology | Homeostasis | Rats | Mice | Visual Cortex - physiology | Plasticity (homeostatic) | Deprivation | Visual pathways | Excitability | Firing rate | Cortex (somatosensory) | Cortex (visual) | Parvalbumin | Sensory deprivation | Plasticity (Hebbian) | Plasticity (synaptic) | Plasticity (visual) | Plasticity | Plasticity (cortical) | Scaling | Plastic foam | 133 | 1001 | Review
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Loading RightsJournal of Neurochemistry, ISSN 0022-3042, 10/2016, Volume 139, Issue S2, pp. 179 - 199
This brief review summarizes 60 years of conceptual advances that have demonstrated a role for active changes in neuronal connectivity as a controller of...
transcription factor | amygdala | fear conditioning | memory | LTP | learning | neurochemistry | second messenger | neuroepigenetics | cerebellum | epigenetics | protein kinase | homeostatic plasticity | Aplysia | intellectual disabilities | neurodevelopment | back‐propagating action potential | eye‐blink conditioning | operant conditioning | addiction | dendrites | place field | chromatin | consolidation | neuroimaging | neuromodulation | amnesia | AMPA receptor | CaMKII | long‐term potentiation | decision making | synaptic scaling | synaptic facilitation | NMDA receptor | metaplasticity | place cell | gene expression | eye-blink conditioning | back-propagating action potential | long-term potentiation | FREELY-MOVING RAT | DROSOPHILA-MELANOGASTER | HIPPOCAMPAL PYRAMIDAL NEURONS | DEPENDENT PROTEIN-KINASE | SYNAPTIC PLASTICITY | RUBINSTEIN-TAYBI-SYNDROME | MEMORY FORMATION | BIOCHEMISTRY & MOLECULAR BIOLOGY | D-ASPARTATE RECEPTOR | NEUROSCIENCES | COMPLEX-SPIKE CELLS | Learning - physiology | Memory Disorders - psychology | Animals | Neuronal Plasticity - physiology | Humans | Long-Term Potentiation - physiology | Memory Disorders - metabolism | Behavior - physiology | Brain - physiology | Epigenetic inheritance | Chromatin | Genes | Protein biosynthesis | Cellular signal transduction | Genetic transcription | Methylation | Neurophysiology | Neurochemistry | Signal transduction | Genetics | Behavior | Protein synthesis | Neurobiology
transcription factor | amygdala | fear conditioning | memory | LTP | learning | neurochemistry | second messenger | neuroepigenetics | cerebellum | epigenetics | protein kinase | homeostatic plasticity | Aplysia | intellectual disabilities | neurodevelopment | back‐propagating action potential | eye‐blink conditioning | operant conditioning | addiction | dendrites | place field | chromatin | consolidation | neuroimaging | neuromodulation | amnesia | AMPA receptor | CaMKII | long‐term potentiation | decision making | synaptic scaling | synaptic facilitation | NMDA receptor | metaplasticity | place cell | gene expression | eye-blink conditioning | back-propagating action potential | long-term potentiation | FREELY-MOVING RAT | DROSOPHILA-MELANOGASTER | HIPPOCAMPAL PYRAMIDAL NEURONS | DEPENDENT PROTEIN-KINASE | SYNAPTIC PLASTICITY | RUBINSTEIN-TAYBI-SYNDROME | MEMORY FORMATION | BIOCHEMISTRY & MOLECULAR BIOLOGY | D-ASPARTATE RECEPTOR | NEUROSCIENCES | COMPLEX-SPIKE CELLS | Learning - physiology | Memory Disorders - psychology | Animals | Neuronal Plasticity - physiology | Humans | Long-Term Potentiation - physiology | Memory Disorders - metabolism | Behavior - physiology | Brain - physiology | Epigenetic inheritance | Chromatin | Genes | Protein biosynthesis | Cellular signal transduction | Genetic transcription | Methylation | Neurophysiology | Neurochemistry | Signal transduction | Genetics | Behavior | Protein synthesis | Neurobiology
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Loading RightsNature, ISSN 0028-0836, 10/2017, Volume 550, Issue 7674, pp. 109 - 113
Homeostatic signalling systems ensure stable but flexible neural activity and animal behaviour(1-4). Presynaptic homeostatic plasticity is a conserved form of...
REFINEMENT | TRANSMITTER | ACTIN | MULTIDISCIPLINARY SCIENCES | NEURONS | RECEPTOR | MECHANISMS | GUIDANCE | EXPRESSION | BRAIN | MODULATION | Synaptic Vesicles - metabolism | Signal Transduction | Neuromuscular Junction - metabolism | Actins - metabolism | Homeostasis | Receptors, Cell Surface - metabolism | Male | Semaphorins - metabolism | Drosophila Proteins - metabolism | Synaptic Transmission | Receptors, Presynaptic - metabolism | DNA-Binding Proteins - metabolism | Drosophila melanogaster - metabolism | Nerve Tissue Proteins - metabolism | Animals | Neuromuscular Junction - secretion | Neuronal Plasticity | Female | Presynaptic Terminals - secretion | Neurotransmitter Agents - secretion | Plasticity (homeostatic) | Brain | Mental disorders | Genes | Nervous system | Plasticity (neural) | Proteins | Morphogenesis | Signal transduction | Receptors | Synaptic transmission | Actin | Plasticity | Neurotransmitter release | Neurons | Axonogenesis | Drosophila | Plasticity (presynaptic) | Signalling systems | Molecular modelling | Plasticity (synaptic) | Semaphorins | Ligands | Mutation | Axon guidance
REFINEMENT | TRANSMITTER | ACTIN | MULTIDISCIPLINARY SCIENCES | NEURONS | RECEPTOR | MECHANISMS | GUIDANCE | EXPRESSION | BRAIN | MODULATION | Synaptic Vesicles - metabolism | Signal Transduction | Neuromuscular Junction - metabolism | Actins - metabolism | Homeostasis | Receptors, Cell Surface - metabolism | Male | Semaphorins - metabolism | Drosophila Proteins - metabolism | Synaptic Transmission | Receptors, Presynaptic - metabolism | DNA-Binding Proteins - metabolism | Drosophila melanogaster - metabolism | Nerve Tissue Proteins - metabolism | Animals | Neuromuscular Junction - secretion | Neuronal Plasticity | Female | Presynaptic Terminals - secretion | Neurotransmitter Agents - secretion | Plasticity (homeostatic) | Brain | Mental disorders | Genes | Nervous system | Plasticity (neural) | Proteins | Morphogenesis | Signal transduction | Receptors | Synaptic transmission | Actin | Plasticity | Neurotransmitter release | Neurons | Axonogenesis | Drosophila | Plasticity (presynaptic) | Signalling systems | Molecular modelling | Plasticity (synaptic) | Semaphorins | Ligands | Mutation | Axon guidance
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Loading RightsPharmacology and Therapeutics, ISSN 0163-7258, 2006, Volume 112, Issue 3, pp. 810 - 832
A number of neuronal functions, including synaptic plasticity, depend on proper regulation of synaptic proteins, many of which can be rapidly regulated by...
Postsynaptic | Homeostatic plasticity | Phosphoproteins | Long-term depression | Long-term potentiation | phosphoproteins | PROTEIN-KINASE-C | ACTIVITY-DEPENDENT PHOSPHORYLATION | long-term depression | METABOTROPIC GLUTAMATE RECEPTORS | postsynaptic | NR2B-CONTAINING NMDA-RECEPTORS | D-ASPARTATE RECEPTOR | HIPPOCAMPAL CA1 REGION | homeostatic plasticity | CALMODULIN-BINDING PROTEIN | POSTSYNAPTIC DENSITY PROTEIN | PHARMACOLOGY & PHARMACY | THETA FREQUENCY STIMULATION | long-term potentiation | Calcium-Calmodulin-Dependent Protein Kinases - physiology | Phosphorylation | Receptors, AMPA - physiology | Synapses - physiology | Humans | Neurogranin - physiology | Phosphoprotein Phosphatases - physiology | Receptors, N-Methyl-D-Aspartate - physiology | Animals | Neuronal Plasticity - physiology | Protein Kinases - physiology | Phosphoproteins - physiology | Calcium-Calmodulin-Dependent Protein Kinase Type 2 | Receptors, Glutamate - physiology | Tyrosine | Methyl aspartate | Phosphatases | Casein | Depression, Mental | Propionates | Glutamate | Protein kinases | Blood proteins
Postsynaptic | Homeostatic plasticity | Phosphoproteins | Long-term depression | Long-term potentiation | phosphoproteins | PROTEIN-KINASE-C | ACTIVITY-DEPENDENT PHOSPHORYLATION | long-term depression | METABOTROPIC GLUTAMATE RECEPTORS | postsynaptic | NR2B-CONTAINING NMDA-RECEPTORS | D-ASPARTATE RECEPTOR | HIPPOCAMPAL CA1 REGION | homeostatic plasticity | CALMODULIN-BINDING PROTEIN | POSTSYNAPTIC DENSITY PROTEIN | PHARMACOLOGY & PHARMACY | THETA FREQUENCY STIMULATION | long-term potentiation | Calcium-Calmodulin-Dependent Protein Kinases - physiology | Phosphorylation | Receptors, AMPA - physiology | Synapses - physiology | Humans | Neurogranin - physiology | Phosphoprotein Phosphatases - physiology | Receptors, N-Methyl-D-Aspartate - physiology | Animals | Neuronal Plasticity - physiology | Protein Kinases - physiology | Phosphoproteins - physiology | Calcium-Calmodulin-Dependent Protein Kinase Type 2 | Receptors, Glutamate - physiology | Tyrosine | Methyl aspartate | Phosphatases | Casein | Depression, Mental | Propionates | Glutamate | Protein kinases | Blood proteins
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