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RESEARCH PRODUCT

Migraine as a Cortical Brain Disorder

Gabriella EgeoMarcello SilvestroFilippo BrighinaAntonio RussoVincenzo Di StefanoPiero Barbanti

subject

Sensory processingmedicine.medical_treatmentMigraine DisordersAmygdala03 medical and health sciences0302 clinical medicineNeuroimagingmedicineHumansIctalmigraine030212 general & internal medicinepathophysiologyneuroimagingbusiness.industryTrigeminovascular systemmedicine.diseasemedicine.anatomical_structureNeurologyMigraineCerebral cortexCortical Excitabilitycerebral cortexSettore MED/26 - NeurologiaNeurology (clinical)BrainstemNerve NetneurophysiologybusinessNeuroscience030217 neurology & neurosurgery

description

Purpose Migraine is an exclusively human chronic disorder with ictal manifestations characterized by a multifaceted clinical complexity pointing to a cerebral cortical involvement. The present review is aimed to cover the clinical, neuroimaging, and neurophysiological literature on the role of the cerebral cortex in migraine pathophysiology. Overview Converging clinical scenarios, advanced neuroimaging data, and experimental neurophysiological findings, indicate that fluctuating excitability, plasticity, and metabolism of cortical neurons represent the pathophysiological substrate of the migraine cycle. Abnormal cortical responsivity and sensory processing coupled to a mismatch between the brain's energy reserve and workload may ignite the trigeminovascular system, leading to the migraine attack through the activation of subcortical brain trigeminal and extra-trigeminal structures, and driving its propagation and maintenance. Discussion The brain cortex emerges as the crucial player in migraine, a disorder lying at the intersection between neuroscience and daily life. Migraine disorder stems from an imbalance in inhibitory/excitatory cortical circuits, responsible for functional changes in the activity of different cortical brain regions encompassing the neurolimbic-pain network, and secondarily allowing a demodulation of subcortical areas, such as hypothalamus, amygdala, and brainstem nuclei, in a continuous mutual crosstalk.

yearjournalcountryeditionlanguage
2020-07-25
10.1111/head.13935http://hdl.handle.net/10447/520477