Evidence of an increased neuronal activation-to-resting glucose uptake ratio in the visual cortex of migraine patients: a study comparing 18FDG-PET and visual evoked potentials - 2018
Evidence of an increased neuronal activation-to-resting glucose uptake ratio in the visual cortex of migraine patients: a study comparing 18FDG-PET and visual evoked potentials
[en] Background: Migraine attacks might be triggered by a disruption of cerebral homeostasis. During the interictal period migraine patients are characterized by abnormal sensory information processing, but this functional abnormality may not be sufficient to disrupt the physiological equilibrium of the cortex unless it is accompanied by additional pathological mechanisms, like a reduction in energetic reserves. The aim of this study was to compare resting cerebral glucose uptake (using positron emission tomography (18fluorodeoxyglucose-PET)), and visual cortex activation (using visual evoked potentials (VEP)), between episodic migraine without aura patients in the interictal period and healthy volunteers.
Methods: Twenty episodic migraine without aura patients and twenty healthy volunteers were studied. 18FDG-PET and VEP recordings were performed on separate days. The overall glucose uptake in the visual cortex-to-VEP response ratio was calculated and compared between the groups. Additionally, PET scan comparisons adding area under the VEP curve as a covariate were performed. For case-wise analysis, eigenvalues from a specific region exhibiting significantly different FDG-PET signal in the visual cortex were extracted. Standardized glucose uptake values from this region and VEP values from each subject were then coupled and compared between the groups.
Results: The mean area under the curve of VEP was greater in migraine patients compared to healthy controls. In the same line, patients had an increased neuronal activation-to-resting glucose uptake ratio in the visual cortex. Statistical parametric mapping analysis revealed that cortical FDG-PET signal in relation to VEP area under the curve was significantly reduced in migraineurs in a cluster extending throughout the left visual cortex, from Brodmann’s areas 19 and 18 to area 7. Within this region, case-wise analyses showed that a visual neuronal activation exceeding glucose uptake was present in 90% of migraine patients, but in only 15% of healthy volunteers. Conclusion: This study identifies an area of increased neuronal activation-to-resting glucose uptake ratio in the visual cortex of migraine patients between attacks. Such observation supports the concept that an activity-induced rupture of cerebral metabolic homeostasis may be a cornerstone of migraine pathophysiology. This article has been selected as the winner of the 2018 Enrico Greppi Award. The Enrico Greppi Award is made to an unpublished paper dealing with clinical, epidemiological, genetic, pathophysiological or therapeutic aspects of headache. Italian Society for the Study of Headaches (SISC) sponsors this award, and the award is supported through an educational grant from Teva Neuroscience. This article did not undergo the standard peer review process for The Journal of Headache and Pain. The members of the 2018 Enrico Greppi Award Selection Committee were: Francesco Pierelli, Paolo Martelletti, Lyn Griffiths, Simona Sacco, Andreas Straube and Cenk Ayata.
Disciplines :
Neurology
Author, co-author :
Lisicki Martinez, Marco ✱; Université de Liège - ULiège > Département des sciences cliniques > Gynécologie - Obstétrique
D'Ostilio, Kevin ✱
Coppola, Gianluca
Scholtes, Félix ; Université de Liège - ULiège > Département des sciences biomédicales et précliniques > Neuro-anatomie
Maertens de Noordhout, Alain ; Université de Liège - ULiège > Département des sciences cliniques > Département des sciences cliniques
Parisi, Vicenzo
Schoenen, Jean ; Université de Liège - ULiège > Département des sciences biomédicales et précliniques > Département des sciences biomédicales et précliniques
MAGIS, Delphine ; Centre Hospitalier Universitaire de Liège - CHU > Département de médecine interne > Service de neurologie (CHR)
✱ These authors have contributed equally to this work.
Language :
English
Title :
Evidence of an increased neuronal activation-to-resting glucose uptake ratio in the visual cortex of migraine patients: a study comparing 18FDG-PET and visual evoked potentials
Publication date :
July 2018
Journal title :
Journal of Headache and Pain
ISSN :
1129-2369
eISSN :
1129-2377
Publisher :
Springer, New York, United States - New York
Peer reviewed :
Peer Reviewed verified by ORBi
European Projects :
FP7 - 602633 - EUROHEADPAIN - Mechanisms and Treatment of Migraine and its Chronification
Goadsby, P.J., Holland, P.R., Martins-Oliveira, M., Pathophysiology of migraine: a disorder of sensory processing (2017) Physiol Rev, 97, pp. 553-622
Magis, D., Vigano, A., Sava, S., Pearls and pitfalls: electrophysiology for primary headaches (2013) Cephalalgia, 33, pp. 526-539
Lisicki, M., Ruiz-Romagnoli, E., D’Ostilio, K., Familial history of migraine influences habituation of visual evoked potentials (2017) Cephalalgia, 37. , https://doi.org/10.1177/0333102416673207, et al
Schoenen, J., Deficient habituation of evoked cortical potentials in migraine: a link between brain biology, behavior and trigeminovascular activation? (1996) Biomed Pharmacother, 50, pp. 71-78
Schoenen, J., Pathogenesis of migraine: the biobehavioural and hypoxia theories reconciled (1994) Acta Neurol Belg, 94, pp. 79-86. , PID: 8036881
Schoenen, J., Hypoxia, a turning point in migraine pathogenesis? (2016) Brain, 139, pp. 644-647
Reyngoudt, H., Paemeleire, K., Descamps, B., 31P-MRS demonstrates a reduction in high-energy phosphates in the occipital lobe of migraine without aura patients (2011) Cephalalgia, 31, pp. 1243-1253
Montagna, P., Cortelli, P., Monari, L., 31P-magnetic resonance spectroscopy in migraine without aura (1994) Neurology, 44, pp. 666-669. , PID: 8164822
Lodi, R., Montagna, P., Soriani, S., Deficit of brain and skeletal muscle bioenergetics and low brain magnesium in juvenile migraine: an in vivo 31P magnetic resonance spectroscopy Interictal study (1997) Pediatr Res, 42, pp. 866-871
Gantenbein, A.R., Sandor, P.S., Fritschy, J., Sensory information processing may be neuroenergetically more demanding in migraine patients (2013) Neuroreport, 24, pp. 202-205
Schoenen, J., Jacquy, J., Lenaerts, M., Effectiveness of high-dose riboflavin in migraine prophylaxis. A randomized controlled trial (1998) Neurology, 50, pp. 466-470. , PID: 9484373
Di Lorenzo, C., Coppola, G., Sirianni, G., Migraine improvement during short lasting ketogenesis: a proof-of-concept study (2015) Eur J Neurol, 22, pp. 170-177
Strahlman, R.S., Can ketosis help migraine sufferers? A case report (2006) Headache, 46, p. 182
Kim, J.H., Kim, S., Suh, S.I., Interictal metabolic changes in episodic migraine: a voxel-based FDG-PET study (2010) Cephalalgia, 30, pp. 53-61
Magis, D., D’Ostilio, K., Thibaut, A., Cerebral metabolism before and after external trigeminal nerve stimulation in episodic migraine (2017) Cephalalgia, 37, pp. 881-891
Kassab, M., Bakhtar, O., Wack, D., Bednarczyk, E., Resting brain glucose uptake in headache-free migraineurs (2009) Headache, 49, pp. 90-97
The international classification of headache disorders, 3rd edition (beta version) (2013) Cephalalgia, 53, pp. 137-146
Delorme, A., Makeig, S., EEGLAB: an open source toolbox for analysis of single-trial EEG dynamics including independent component analysis (2004) J Neurosci Methods, 134, pp. 9-21
Makeig, S., Debener, S., Onton, J., Delorme, A., Mining event-related brain dynamics (2004) Trends Cogn Sci, 8, pp. 204-210
de Tommaso, M., Ambrosini, A., Brighina, F., Altered processing of sensory stimuli in patients with migraine (2014) Nat Rev Neurol, 10, pp. 144-155
Loder, E., What is the evolutionary advantage of migraine? (2002) Cephalalgia, 22, pp. 624-632. , PID: 12383059
Wong-Riley, M., Energy metabolism of the visual system (2010) Eye Brain, p. 99. , https://doi.org/10.2147/EB.S9078
Paemeleire, K., Schoenen, J., (31) P-MRS in migraine: fallen through the cracks (2013) Headache, 53, pp. 676-678
Zhang, X., Levy, D., Kainz, V., Activation of central trigeminovascular neurons by cortical spreading depression (2011) Ann Neurol, 69, pp. 855-865
Kilic, K., Karatas, H., Dönmez-Demir, B., Inadequate brain glycogen or sleep increases spreading depression susceptibility (2018) Ann Neurol, 83, pp. 61-73
Karatas, H., Erdener, S.E., Gursoy-Ozdemir, Y., Spreading depression triggers headache by activating neuronal Panx1 channels (2013) Science, 339, pp. 1092-1095
Pietrobon, D., Moskowitz, M.A., Chaos and commotion in the wake of cortical spreading depression and spreading depolarizations (2014) Nat Rev Neurosci, 15, pp. 379-393
Lisicki, M., Ruiz-Romagnoli, E., Piedrabuena, R., Migraine triggers and habituation of visual evoked potentials (2017) Cephalalgia, , https://doi.org/10.1177/0333102417720217, 333102417720217
Judit, A., Sándor, P.S., Schoenen, J., Habituation of visual and intensity dependence of auditory evoked cortical potentials tends to normalize just before and during the migraine attack (2000) Cephalalgia, 20, pp. 714-719. , PID: 11167900
Zaletel, M., Strucl, M., Bajrovic, F.F., Pogacnik, T., Coupling between visual evoked cerebral blood flow velocity responses and visual evoked potentials in migraneurs (2005) Cephalalgia, 25, pp. 567-574
Hougaard, A., Amin, F., Hauge, A.W., Provocation of migraine with aura using natural trigger factors (2013) Neurology, 80, pp. 428-431
Martin, P.R., Seneviratne, H.M., Effects of food deprivation and a stressor on head pain (1997) Health Psychol, 16, pp. 310-318
Cao, Y., Aurora, S.K., Nagesh, V., Functional MRI-BOLD of brainstem structures during visually triggered migraine (2002) Neurology, 59, pp. 72-78. , PID: 12105310
Cao, Y., Welch, K.M., Aurora, S., Vikingstad, E.M., Functional MRI-BOLD of visually triggered headache in patients with migraine (1999) Arch Neurol, 56, pp. 548-554. , PID: 10328249
Kelman, L., The triggers or precipitants of the acute migraine attack (2007) Cephalalgia, 27, pp. 394-402
Schoonman, G., Sándor, P., Agosti, R., Normobaric hypoxia and nitroglycerin as trigger factors for migraine (2006) Cephalalgia, 26, pp. 816-819
Arngrim, N., Schytz, H.W., Britze, J., Migraine induced by hypoxia: an MRI spectroscopy and angiography study (2016) Brain, 139, pp. 723-737
Welch, K.M., Levine, S.R., D’Andrea, G., Preliminary observations on brain energy metabolism in migraine studied by in vivo phosphorus 31 NMR spectroscopy (1989) Neurology, 39, pp. 538-541. , PID: 2927679
Welch, K.M., Levine, S.R., D’Andrea, G., Helpern, J.A., Brain pH in migraine: an in vivo phosphorus-31 magnetic resonance spectroscopy study (1988) Cephalalgia, 8, pp. 273-277
Ramadan, N.M., Halvorson, H., Vande-Linde, A., Low brain magnesium in migraine (1989) Headache, 29, pp. 590-593. , PID: 2584000
Cosentino, G., Fierro, B., Vigneri, S., Cyclical changes of cortical excitability and metaplasticity in migraine: evidence from a repetitive transcranial magnetic stimulation study (2014) Pain, 155, pp. 1070-1078
Bélanger, M., Allaman, I., Magistretti, P.J., Brain energy metabolism: focus on astrocyte-neuron metabolic cooperation (2011) Cell Metab, 14, pp. 724-738. , PID: 22152301
Zimmer, E.R., Parent, M.J., Souza, D.G., [18F]FDG PET signal is driven by astroglial glutamate transport (2017) Nat Neurosci, 20, pp. 393-395
Figley, C.R., Stroman, P.W., The role(s) of astrocytes and astrocyte activity in neurometabolism, neurovascular coupling, and the production of functional neuroimaging signals (2011) Eur J Neurosci, 33, pp. 577-588
Anderson, C.M., Swanson, R.A., Astrocyte glutamate transport: review of properties, regulation, and physiological functions (2000) Glia, 32, pp. 1-14. , PID: 10975906
Kimelberg, H.K., Nedergaard, M., Functions of astrocytes and their potential as therapeutic targets (2010) Neurotherapeutics, 7, pp. 338-353
Gordon, G.R.J., Choi, H.B., Rungta, R.L., Brain metabolism dictates the polarity of astrocyte control over arterioles (2008) Nature, 456, pp. 745-749
Araque, A., Parpura, V., Sanzgiri, R.P., Haydon, P.G., Tripartite synapses: glia, the unacknowledged partner (1999) Trends Neurosci, 22, pp. 208-215
Capuani, C., Melone, M., Tottene, A., Defective glutamate and K+ clearance by cortical astrocytes in familial hemiplegic migraine type 2 (2016) EMBO Mol Med, , https://doi.org/10.15252/emmm.201505944
Eising, E., de Leeuw, C., Min, J.L., Involvement of astrocyte and oligodendrocyte gene sets in migraine, , https://doi.org/10.1177/0333102415618614
Renthal, W., Localization of migraine susceptibility genes in human brain by single-cell RNA sequencing, , https://doi.org/10.1177/0333102418762476
Lauritzen, M., Dreier, J.P., Fabricius, M., Clinical relevance of cortical spreading depression in neurological disorders: migraine, malignant stroke, subarachnoid and intracranial hemorrhage, and traumatic brain injury (2011) J Cereb Blood Flow Metab, 31, pp. 17-35
Hadjikhani, N., Sanchez Del Rio, M., Wu, O., Mechanisms of migraine aura revealed by functional MRI in human visual cortex (2001) Proc Natl Acad Sci U S A, 98, pp. 4687-4692
Lashley, K.S., Patterns of cerebral integration indicated by the scotomas of migraine (1941) Arch Neurol Psychiatr, 46, pp. 331-339
Lauritzen, M., Olesen, J., Regional cerebral blood flow during migraine attacks by Xenon-133 inhalation and emission tomography (1984) Brain, 107, pp. 447-461. , PID: 6609739
Granziera, C., DaSilva, A.F.M., Snyder, J., Anatomical alterations of the visual motion processing network in migraine with and without Aura (2006) PLoS Med, 3
Schulte, L.H., May, A., The migraine generator revisited: continuous scanning of the migraine cycle over 30 days and three spontaneous attacks (2016) Brain, 139, pp. 1987-1993
