Time Course of Cerebral Perfusion Changes in Children with Migraine with Aura Mimicking Stroke

Discussion

Information has been published on the use of various MR imaging sequences to characterize the time course of perfusion changes in migraine. Several case series on the use of noncontrast MR imaging in migraine have demonstrated prominent cerebral vasculature in the affected hemisphere on SWI sequences in the evaluation of the acute phase of migraine.^7⇓⇓–10 ASL is an increasingly more popular, available, and noninvasive MR imaging perfusion sequence that can provide insight into the pathophysiology of pediatric brain attacks, including pediatric migraine and stroke.¹⁰ The presence of decreased relative cerebral perfusion on ASL in a DWI sequence with normal findings supports the simultaneous use of these sequences as the best MR imaging diagnostic tool for differentiating hemiplegic migraine from stroke. This combination was noted in 8 patients in this case series. ASL asymmetries in stroke or TIA would be localized to a specific vascular territory, while in our patients, migraine-with-aura asymmetries are seen throughout the affected hemisphere in multiple vascular territories. Moreover, lack of restricted diffusion while the patient is clinically symptomatic suggests migraine with aura over stroke.

Many studies have suggested the implementation of ASL in the evaluation of children presenting with focal neurologic symptoms, each with the finding of initial hypoperfusion followed by delayed hyperperfusion.^{11⇓⇓–14} Boulouis et al¹¹ published a case series exploring the use of the ASL MR imaging sequence in children, which demonstrated decreased regional cerebral blood flow when obtained <14 hours after symptom onset and increased regional cerebral blood flow when obtained >17 hours after symptom onset. Lehman et al¹² demonstrated decreased pulsed ASL signal in 11 children who all had increased prominence of cortical or medullary veins on SWI, suggesting increased venous deoxyhemoglobin. In the Lehman et al study, ASL hypoperfusion persisted as long as 16.25 hours. Iizaku et al¹³ also evaluated the changes in perfusion in 3 adult patients with focal neurologic symptoms and migraine whose MR imaging demonstrated initial hypoperfusion and delayed hyperperfusion on ASL >18–24 hours after symptom onset. Pollock et al¹⁴ similarly looked at a case series of 3 adults with migraine and noted cerebral hyperperfusion on ASL imaging >6 hours after the onset of neurologic symptoms.

Our results demonstrate a clear link between brain perfusion changes and the time course of migraine with aura. We observed a wide variation in the duration of perfusion changes, lasting up to at least 11 hours, the longest time to scan from symptom onset in this case series. Three patients in this series demonstrated increased perfusion on ASL within this time window, indicating the transition to hyperperfusion by 11, 5.5, and 7.5 hours. This is earlier than described in other studies.^11⇓–13 Each technique reviewed in this study provided data supporting the following pattern: apparent constriction of distal vessels on MRA, the presence of deoxygenated blood in cerebral veins on SWI, and initial hypoperfusion followed by a rebound hyperperfusion on ASL in the affected hemisphere. Patient 10 in this series demonstrated normal SWI and MRA findings and an ASL sequence with rCBF of only −0.4 at 4 hours, which may represent near-resolution of MR imaging perfusion changes or the transition from hypoperfusion to pseudonormalization during this patient's migraine. Most interesting, patient 7 in this series demonstrated discordance between the MR imaging sequences with a normal SWI signal and decreased vessel caliber on MRA but increased rCBF on pseudocontinuous ASL 5.5 hours from symptom onset. The discordance between pseudocontinuous ASL and SWI could indicate that ASL is more sensitive than SWI sequences in detecting imaging changes related to hemiplegic migraine. It could also indicate that the transition from hypoperfusion to hyperperfusion may be occurring sooner in the progression of migraine than previously thought, as observed in other case reports.¹⁴ The decreased vessel caliber on MRA with increased rCBF on ASL highlights the variability in neurovascular coupling and recovery characteristics with migraine. Migraine leads to reversible disturbances in neurovascular coupling that will affect the timing of ASL hyperperfusion and normalization of perfusion.¹⁶

Current models of migraine suggest that cortical spreading depression is a likely cause of the migraine aura. Spreading depression is a neurovascular phenomenon in which a self-propagating wave of depolarization results in spreading cortical hypoactivity and resultant vasoconstriction. Our data support this model through 2 observations: First, the distribution of changes across all sequences (ASL, SWI, MRA) cross vascular territories but respect the hemispheric boundary. Second, ASL findings demonstrate a trend of initial hemispheric hypoperfusion followed by remote rebound hyperperfusion hours later. In our imaging studies, the spatial resolution of ASL was not sufficient to allow more detailed analysis correlating symptoms and spreading depression localization.⁵ The decreased caliber in the posterior and/or anterior circulation observed in 4 of 12 patients in the present study confirms that multiple vascular territories are affected during migraine with aura.¹⁶

One limitation of this series is the lack of standardized documentation detailing the time course of each patient's clinical symptoms, including aura/headache onset and duration. This may explain some of the variability in rCBF findings. This discordance also emphasizes the value of obtaining multiple imaging sequences to assist in interpreting the patient's symptoms. An additional limitation of this study is that brain MR imaging was performed at only 1 time point rather than ≥2 time points during the brain attack. Multiple samples of imaging data would allow more effective characterization of the evolution of perfusion changes during the migraine attack. Another limitation of this study is that for many of these patients, this was the first or only known attack of migraine with focal neurologic symptoms, which would not fulfill the International Classification of Headache Disorders, 3rd edition, criteria for migraine with aura or hemiplegic migraine.²

The management and disposition of migraine with aura differs remarkably from the entities in the differential diagnosis. Given the history and imaging findings, more than half of the patients in the series were not admitted to the hospital for a work-up and monitoring as would be typical for TIA; they were, instead, referred to the outpatient neurology clinic to establish headache care. Most patients were offered migraine prophylaxis treatment options (daily magnesium, riboflavin, tricyclic antidepressant, or antiepileptic). Given this difference, continuing to define criteria (both clinical and imaging) to identify and separate migraine from ischemic stroke in children by implementing noninvasive neuroimaging protocols in the emergency departments would be highly beneficial. This case series supports the addition of an ASL sequence in the evaluation of pediatric patients presenting with an acute brain attack.