Search results for "Spontaneous recovery"

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Effects of post-extinction l-DOPA administration on the spontaneous recovery and reinstatement of fear in a human fMRI study

2015

Relapse is a pertinent problem in the treatment of anxiety disorders. In the laboratory, relapse is modeled as return of conditioned fear responses after successful fear extinction and is explained by insufficient retrieval and/or expression of the fear-inhibitory extinction memory that is generated during extinction learning. We have shown in mice and humans that return of fear can be prevented by administration of a single dose of the dopamine precursor l-3,4-dihydroxyphenylalanine (l-DOPA) immediately after extinction. In mice, this effect could be attributed to an enhancement of extinction memory consolidation. In our human study, we could not exclude that l-DOPA might have acted by int…

AdultMalemedicine.medical_treatmentDopamine AgentsSpontaneous recoveryExposure therapyVentromedial prefrontal cortexAmygdalaFear-potentiated startleExtinction PsychologicalDevelopmental psychologyLevodopaRandom AllocationDouble-Blind MethodConditioning PsychologicalmedicineHumansPharmacology (medical)Fear conditioningBiological PsychiatryMemory ConsolidationPharmacologyFear processing in the brainBrain MappingPsychotropic DrugsBrainFearGalvanic Skin Responsesocial sciencesExtinction (psychology)Magnetic Resonance ImaginghumanitiesPsychiatry and Mental healthmedicine.anatomical_structureNeurologyVisual PerceptionNeurology (clinical)CuesPsychologyNeuroscienceEuropean Neuropsychopharmacology
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Blocking NMDA-receptors in the pigeon's "prefrontal" caudal nidopallium impairs appetitive extinction learning in a sign-tracking paradigm

2015

Extinction learning provides the ability to flexibly adapt to new contingencies by learning to inhibit previously acquired associations in a context-dependent manner. The neural networks underlying extinction learning were mostly studied in rodents using fear extinction paradigms. To uncover invariant properties of the neural basis of extinction learning, we employ pigeons as a model system. Since the prefrontal cortex of mammals is a key structure for extinction learning, we assessed the role of N-methyl-D-aspartate receptors (NMDARs) in the nidopallium caudolaterale, the avian functional equivalent of mammalian prefrontal cortex. Since NMDARs in prefrontal cortex have been shown to be rel…

Cognitive NeuroscienceSpontaneous recoveryStimulus (physiology)contextlcsh:RC321-571Behavioral NeuroscienceSign-trackingmedicinePrefrontal cortexretrievallcsh:Neurosciences. Biological psychiatry. NeuropsychiatryOriginal ResearchrenewalArtificial neural networkExtinction (psychology)social sciencesmusculoskeletal systemhumanitiesNeuropsychology and Physiological Psychologynervous systemDisinhibitionNidopalliumNMDA receptorAPVmedicine.symptomPsychologyNeurosciencegeographic locationsNeuroscience
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