Lateral inhibition in the somatosensory cortex during and between migraine without aura attacks: Correlations with thalamocortical activity and clinical features

Coppola, G.; Di Lorenzo, C.; Schoenen, Jean; Pierelli, F.

doi:10.1177/0333102415610873

Article (Scientific journals)

Lateral inhibition in the somatosensory cortex during and between migraine without aura attacks: Correlations with thalamocortical activity and clinical features

Coppola, G.; Di Lorenzo, C.; Schoenen, Jean et al.

2015 • In Cephalalgia, 36 (6), p. 568-578

Peer Reviewed verified by ORBi

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https://hdl.handle.net/2268/258675

DOI
10.1177/0333102415610873

PubMed
26442930

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Keywords :

Migraine; Article; Adult; Evoked Potentials, Somatosensory; Female; Humans; Male; Migraine without Aura; Somatosensory Cortex

Abstract :

[en] Background We studied lateral inhibition in the somatosensory cortex of migraineurs during and between attacks, and searched for correlations with thalamocortical activity and clinical features. Participants and methods Somatosensory evoked potentials (SSEP) were obtained by electrical stimulation of the right median (M) or ulnar (U) nerves at the wrist or by simultaneous stimulation of both nerves (MU) in 41 migraine without aura patients, 24 between (MO), 17 during attacks, and in 17 healthy volunteers (HVs). We determined the percentage of lateral inhibition of the N20-P25 component by using the formula [(100)-MU/(M + U)∗100]. We also studied high-frequency oscillations (HFOs) reflecting thalamocortical activation. Results In migraine, both lateral inhibition (MO 27.9% vs HVs 40.2%; p = 0.009) and thalamocortical activity (MO 0.5 vs HVs 0.7; p = 0.02) were reduced between attacks, but not during. In MO patients, the percentage of lateral inhibition negatively correlated with days elapsed since the last migraine attack (r = -0.510, p = 0.01), monthly attack duration (r = -0.469, p = 0.02) and severity (r = -0.443, p = 0.03), but positively with thalamocortical activity (r = -0.463, p = 0.02). Conclusions We hypothesize that abnormal migraine cycle-dependent dynamics of connectivity between subcortical and cortical excitation/inhibition networks may contribute to clinical features of MO and recurrence of attacks. © International Headache Society 2015.

Disciplines :

Neurology

Author, co-author :

Coppola, G.; G.B. Bietti Foundation, IRCCS, Department of Neurophysiology of Vision and Neurophthalmology, Via Livenza 3, Rome, Italy

Di Lorenzo, C.; Fondazione Don Gnocchi, Italy

Schoenen, Jean ; Université de Liège - ULiège > Département des sciences biomédicales et précliniques > Département des sciences biomédicales et précliniques

Pierelli, F.; Sapienza University of Rome Polo Pontino, Department of Medical and Surgical Sciences and Biotechnologies, Italy, INM Neuromed IRCCS, Italy

Language :

English

Title :

Lateral inhibition in the somatosensory cortex during and between migraine without aura attacks: Correlations with thalamocortical activity and clinical features

Publication date :

2015

Journal title :

Cephalalgia

ISSN :

0333-1024

eISSN :

1468-2982

Publisher :

SAGE Publications Ltd

Volume :

Issue :

Pages :

568-578

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBi :

since 07 April 2021

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Bibliography

Magis D, Vigano A, Sava S, et al. Pearls and pitfalls: Electrophysiology for primary headaches. Cephalalgia 2013; 33: 526-539.
Bjørk M, Sand T,. Quantitative EEG power and asymmetry increase 36 h before a migraine attack. Cephalalgia 2008; 28: 960-968.
Coppola G, Ambrosini A, Di Clemente L, et al. Interictal abnormalities of gamma band activity in visual evoked responses in migraine: An indication of thalamocortical dysrhythmia? Cephalalgia 2007; 27: 1360-1367.
Coppola G, Iacovelli E, Bracaglia M, et al. Electrophysiological correlates of episodic migraine chronification: Evidence for thalamic involvement. J Headache Pain 2013; 14: 76-76.
Coppola G, Pierelli F, Schoenen J,. Is the cerebral cortex hyperexcitable or hyperresponsive in migraine? Cephalalgia 2007; 27: 1427-1439.
Coppola G, Parisi V, Di Lorenzo C, et al. Lateral inhibition in visual cortex of migraine patients between attacks. J Headache Pain 2013; 14: 20-20.
Curio G,. Linking 600-Hz "spikelike" EEG/MEG wavelets ("sigma-bursts") to cellular substrates: Concepts and caveats. J Clin Neurophysiol 2000; 17: 377-396.
Tinazzi M, Priori A, Bertolasi L, et al. Abnormal central integration of a dual somatosensory input in dystonia. Evidence for sensory overflow. Brain 2000; 123: 42-50.
Friedman R, Chen L, Roe A,. Responses of areas 3b and 1 in anesthetized squirrel monkeys to single- and dual-site stimulation of the digits. J Neurophysiol 2008; 100: 3185-3196.
Helmstaedter M, Sakmann B, Feldmeyer D,. Neuronal correlates of local, lateral, and translaminar inhibition with reference to cortical columns. Cereb Cortex 2009; 19: 926-937.
de Tommaso M, Sciruicchio V, Tota P, et al. Somatosensory evoked potentials in migraine. Funct Neurol 1997; 12: 77-82.
Allison T, McCarthy G, Wood CC, et al. Potentials evoked in human and monkey cerebral cortex by stimulation of the median nerve. A review of scalp and intracranial recordings. Brain 1991; 114 (Pt 6): 2465-2503.
Burke D, Gandevia S, McKeon B, et al. Interactions between cutaneous and muscle afferent projections to cerebral cortex in man. Electroencephalogr Clin Neurophysiol 1982; 53: 349-360.
Hsieh C, Shima F, Tobimatsu S, et al. The interaction of the somatosensory evoked potentials to simultaneous finger stimuli in the human central nervous system. A study using direct recordings. Electroencephalogr Clin Neurophysiol 1995; 96: 135-142.
Brecht M, Roth A, Sakmann B,. Dynamic receptive fields of reconstructed pyramidal cells in layers 3 and 2 of rat somatosensory barrel cortex. J Physiol 2003; 553: 243-265.
Somogyi P, Freund T, Cowey A,. The axo-axonic interneuron in the cerebral cortex of the rat, cat and monkey. Neuroscience 1982; 7: 2577-2607.
Shepherd AJ,. Increased visual after-effects following pattern adaptation in migraine: A lack of intracortical excitation? Brain 2001; 124: 2310-2318.
Shepherd AJ, Palmer JE, Davis G,. Increased visual after-effects in migraine following pattern adaptation extend to simultaneous tilt illusion. Spat Vis 2002; 16: 33-43.
Shepherd A,. Local and global motion after-effects are both enhanced in migraine, and the underlying mechanisms differ across cortical areas. Brain 2006; 129: 1833-1843.
Battista J, Badcock D, McKendrick A,. Migraine increases centre-surround suppression for drifting visual stimuli. PLoS One 2011; 6: e18211-e18211.
Nguyen B, McKendrick A and Vingrys A. Abnormal inhibition-excitation imbalance in migraine. Cephalalgia. Epub ahead of print 18 March 2015. DOI: 10.1177/0333102415576725.
Shepherd A, Wyatt G, Tibber M,. Visual metacontrast masking in migraine. Cephalalgia 2011; 31: 346-356.
Stankewitz A, Aderjan D, Eippert F, et al. Trigeminal nociceptive transmission in migraineurs predicts migraine attacks. J Neurosci 2011; 31: 1937-1943.
Coppola G, Tinelli E, Lepre C, et al. Dynamic changes in thalamic microstructure of migraine without aura patients: A diffusion tensor magnetic resonance imaging study. Eur J Neurol 2014; 21: 287-e13.
Llinás RR, Steriade M,. Bursting of thalamic neurons and states of vigilance. J Neurophysiol 2006; 95: 3297-3308.
Stankewitz A, Schulz E, May A,. Neuronal correlates of impaired habituation in response to repeated trigemino-nociceptive but not to olfactory input in migraineurs: An fMRI study. Cephalalgia 2013; 33: 256-265.
Russo A, Marcelli V, Esposito F, et al. Abnormal thalamic function in patients with vestibular migraine. Neurology 2014; 82: 2120-2126.
Noseda R, Kainz V, Jakubowski M, et al. A neural mechanism for exacerbation of headache by light. Nat Neurosci 2010; 13: 239-245.
Hamel E,. Serotonin and migraine: Biology and clinical implications. Cephalalgia 2007; 27: 1293-1300.
Sprenger T, Borsook D,. Migraine changes the brain: Neuroimaging makes its mark. Curr Opin Neurol 2012; 25: 252-262.
Mesulam MM,. Large-scale neurocognitive networks and distributed processing for attention, language, and memory. Ann Neurol 1990; 28: 597-613.
Sandrini G, Rossi P, Milanov I, et al. Abnormal modulatory influence of diffuse noxious inhibitory controls in migraine and chronic tension-type headache patients. Cephalalgia 2006; 26: 782-789.
Moulton E, Burstein R, Tully S, et al. Interictal dysfunction of a brainstem descending modulatory center in migraine patients. PLoS One 2008; 3: 10-10.
Coppola G, Currà A, Serrao M, et al. Lack of cold pressor test-induced effect on visual-evoked potentials in migraine. J Headache Pain 2010; 11: 115-121.
Afridi SK, Giffin NJ, Kaube H, et al. A positron emission tomographic study in spontaneous migraine. Arch Neurol 2005; 62: 1270-1275.
Restuccia D, Vollono C, Virdis D, et al. Patterns of habituation and clinical fluctuations in migraine. Cephalalgia 2014; 34: 201-210.