Migraine and serotonin: The quest for the Holy Grail goes on

Abstract

Serotonin has been thought to be pivotal in migraine pathogenesis since the early days of headache research. Sicuteri (1) and Lance (2) were pioneers in unraveling that serotonin metabolism was disturbed in migraine, and their findings were confirmed with refined methods by Ferrari and Bruyn (3). Those data pointed toward a cycling profile of 5-HT metabolism: a decreased disposition and enhanced metabolism leading to serotonergic receptor supersensitivity between attacks, contrasting with serotonin release and transiently decreased turnover during attacks. The major shortcomings of these early studies are that they chiefly explored systemic 5-HT metabolism in blood and urine and assumed that the same changes would occur in brain 5-HT metabolism. The development by Diksic and collaborators (4) of a method that measures trapping by the brain of the radio-labeled precursor of 5-HT synthesis, a-[C] methyl-L tryptophan (C-AMT), to evaluate central 5-HT synthesis was a major advance for pathogenic studies in migraine and other brain disorders. Surprisingly, since the development of this method 35 years ago, only three studies have been performed in migraine: one by Chugani et al. (5), and two by Sakai et al., including the one published in this issue of Cephalalgia on the effect of eletriptan on C-AMT brain uptake (6). The results are only partly concordant, even in the studies coming from the same group. In the article published in this issue, Sakai et al. (6) report that the PET-detected brain trapping of C-AMT, expressed as the K complex (K*) and thought to reflect 5-HT synthesis capacity in the brain, is significantly decreased ( 20%) 1 hour after 40mg eletriptan p.o. in six female migraineurs studied interictally, whereas there is a mild non-significant increase in six healthy control participants. The eletriptan-induced decrease predominates in the upper dorsal brainstem, superior parietal, parahippocampal and occipital cortices. Sakai et al. (6) explain their findings by an increased sensitivity of 5-HT1A and 5-HT1B autoreceptors caused by a chronic interictal hyposerotonergic state. It is known that activation of these autoreceptors decreases 5-HT release and synthesis, and there is indirect evidence for interictal low, but ictally heightened, 5-HT neurotransmission in migraine (review in 7). The effects of eletriptan are in line with those published by the same authors (8) showing that sumatriptan injected during an attack produces a 33% reduction of C-AMT uptake. The increase of the latter found after preventive treatment with beta-blockers in migraine patients (5) could be the counterpart, as beta-blockers are able to antagonize 5-HT1A receptors (see 5). That 5-HT receptors/transporter can be upregulated interictally in migraine was evidenced by two PET studies showing increased 5-HT1A receptor (9) and 5-HT transporter (10) availabilities in brain and brainstem, respectively. Nonetheless, to confirm that the eletriptan effect is caused by hypersensitivity of 5-HT1A/B autoreceptors, studies using specific receptor agonists/antagonists would be necessary. Sakai et al. (6) found no significant difference in C-AMT uptake between migraine patients interictally (K*: 5.7 ml/g/min) and healthy control participants (K*: 5.0). This is somewhat surprising as the same authors reported K*values previously of 4.71 in migraineurs between attacks (8) and 7.7 and 6.6 in healthy females and males (11), which would suggest reduced 5-HT synthesis in migraine and fit the authors’ hypothesis of a low serotonergic state with receptor upregulation. The finding by Chugani et al. (5) that K* values were clearly greater in 11 migraine patients interictally (7.75) than in healthy control participants (5.46), is in line with the trend for a regionally more marked increase of 5-HT synthesis in migraine reported in this issue (6). Sakai et al. (6) explain the apparent paradox by similar proximal rate limiting mechanisms in migraine and in control subject participants but different distal feedback mechanisms including autoreceptor sensitization.