Exploring alterations in sensory pathways in migraine

• Published in: Journal of headache and pain Vol. 23; no. 1; p. 5
• Main Authors: Meylakh, Noemi, Henderson, Luke A.
• Format: Journal Article
• Language: English
• Published: Milan Springer Milan 12.01.2022; Springer Nature B.V; BMC
• Subjects: Activity patterns; Brain; Brain mapping; Cortex (olfactory); Functional connectivity; Functional magnetic resonance imaging; Headache; Humans; Information processing; Infra-slow oscillations; Internal Medicine; Magnetic Resonance Imaging; Medicine; Medicine & Public Health; Migraine; Migraine Disorders - complications; Migraine Disorders - diagnostic imaging; Nausea; Neural networks; Neuroimaging; Neurology; Pain; Pain Medicine; Primary Visual Cortex; Research Article; Secondary visual cortex; Sensory integration; Sensory network; Sensory perception; Somatosensory Cortex; Visual cortex; Vomiting; Functional connectivity; Primary visual cortex; Secondary visual cortex; Migraine; Infra-slow oscillations; Sensory network
• ISSN: 1129-2369; 1129-2377
• DOI: 10.1186/s10194-021-01371-y

Background Migraine is a neurological disorder characterized by intense, debilitating headaches, often coupled with nausea, vomiting and sensitivity to light and sound. Whilst changes in sensory processes during a migraine attack have been well-described, there is growing evidence that even between migraine attacks, sensory abilities are disrupted in migraine. Brain imaging studies have investigated altered coupling between areas of the descending pain modulatory pathway but coupling between somatosensory processing regions between migraine attacks has not been properly studied. The aim of this study was to determine if ongoing functional connectivity between visual, auditory, olfactory, gustatory and somatosensory cortices are altered during the interictal phase of migraine. Methods To explore the neural mechanisms underpinning interictal changes in sensory processing, we used functional magnetic resonance imaging to compare resting brain activity patterns and connectivity in migraineurs between migraine attacks ( n  = 32) and in healthy controls ( n  = 71). Significant differences between groups were determined using two-sample random effects procedures ( p  < 0.05, corrected for multiple comparisons, minimum cluster size 10 contiguous voxels, age and gender included as nuisance variables). Results In the migraine group, increases in infra-slow oscillatory activity were detected in the right primary visual cortex (V1), secondary visual cortex (V2) and third visual complex (V3), and left V3. In addition, resting connectivity analysis revealed that migraineurs displayed significantly enhanced connectivity between V1 and V2 with other sensory cortices including the auditory, gustatory, motor and somatosensory cortices. Conclusions These data provide evidence for a dysfunctional sensory network in pain-free migraine patients which may be underlying altered sensory processing between migraine attacks.