[1, 2] While most people with migraine have a few headache days per month, 2% of Americans have chronic migraine

(CM), a condition in which headaches occur on ≥15 days/month, with full-blown migraine on ≥8 of those days.[3] Although headache is typically find more the most obvious symptom of migraine, migraineurs also have painful hypersensitivities and reduced tolerance to sound, light, odor, and cutaneous stimulation.[4, 5] These painful hypersensitivities and reduced tolerance to environmental stimuli are most prominent during migraine attacks, but often persist with less magnitude between attacks (“interictally”).[5-7] Pain perception is a complex process involving pain-facilitating and pain-inhibiting brain regions that play different

roles in pain check details processing: sensory-discriminative (intensity, location, modality), affective (pain tolerance, self-awareness, fear, anxiety), cognitive (attention, expectation, pain memory), and integration of these different pain aspects with other sensory modalities (multisensory convergence).[8-10] Pain detection thresholds (first instant that a stimulus is detected as painful) are thought to be indicative of sensory-discriminative processing of potentially noxious stimuli, while pain tolerance thresholds (first instant that a person decides they can no longer tolerate the painful stimulus) are considered indicative of affective responses to such stimuli.[11, 12] Migraineurs typically have reduced the tolerance of somatosensory, auditory, visual, and olfactory stimuli, and prior functional magnetic resonance imaging (fMRI) studies suggest atypical affective processing of stimuli by the migraine brain.[13-15] Thus, we focused on investigating the resting-state functional connectivity (rs-fc) of brain regions responsible for affective processing of noxious stimuli. Resting-state functional connectivity magnetic resonance

imaging (rs-fcMRI) is based on the observation that spontaneous, low frequency (<0.1 Hz) blood oxygenation level-dependent (BOLD) signal fluctuations in spatially distant but functionally related these brain regions are temporally correlated at rest.[16] Rs-fcMRI allows for visualization and measurement of the brain’s intrinsic functional architecture.[17, 18] The rs-fc among brain regions may change over time according to usual brain activity and needs.[19] Thus, regions of the brain that are frequently coactivated may, over time, develop a stronger rs-fc even when not being engaged by an external task (during the resting state).[19, 20] Atypical rs-fc among regions of resting-state networks and between established networks has been identified in patients with several different medical disorders.