1 Research Centre for Reproductive Medicine, University of Pavia, 2 Department of Obstetrics and Gynaecology, IRCCS San Matteo, University of Pavia, 3 University Centre of Adaptive Disorders and Headache (UCADH), University of Pavia, 4 Headache Centre, IRCCS C.Mondino Foundation, Department of Neurology and 5 Chair of Neurology, University La Sapienza, Rome, Italy
6 To whom correspondence should be addressed at: Dept Ob/Gyn, Policlinico S.Matteo, University of Pavia, Piazzale Golgi 2, 27100 Pavia, Italy. E-mail: renappi{at}tin.it
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Abstract |
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Key words: estradiol/meta-chlorophenylpiperazine test/oral contraception/pill-free interval/status migrainosus
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Introduction |
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The 2nd edition of the International Classification of Headache Disorders (2004) codified that migraine or headache may increase in frequency or newly develop during the regular use of exogenous hormones, typically for contraception or HRT, or be provoked within 5 days after the cessation of a course of exogenous estrogens. The onset of migraine triggered by oral contraception (OC) during the pill-free interval is, indeed, very common in obstetrics and gynaecology practice (Sulak et al., 2000
). Abrupt estrogen withdrawal has been evoked to explain the vulnerability of contraceptive users to migraine occurring during the 7 days free of exogenous estrogens (MacGregor, 2001
). That being so, some hormonal techniques such as tricycling the pill, altering the ratio of estrogens to progestins, inducing medical castration with GnRH analogues, using estrogen supplementation during the pill-free week, etc., have been proposed to relieve menstrually related migraine (Murray and Muse, 1997
; Massiou and MacGregor, 2000
; Sulak et al., 2002
).
Menstrually related attacks may have a typical duration (72 h), but in some cases head pain can last several days and may be extremely severe and poorly responsive to analgesics (status migrainosus) (Granella et al., 2004
). Migraine at menstruation is different in terms of severity from non-menstrual attacks, even within individuals (MacGregor and Hackshaw, 2004
). A similar finding may be evident during the pill-free interval in some women presenting unrelenting headache, lasting >72 h, nausea and vomiting, and showing a lack of responsiveness to conventional non-specific and specific therapy, non-steroid antiflammatory drugs and serotonin (5-HT) receptor subtype agonists, respectively.
However, given the complexity of the neuroendocrine events driving the menstrual cycle, the sex steroid-dependent mechanisms involved in the vulnerability of the menstrual window to migraine are still unknown. Estrogen variations seem to be highly implicated in modulating the threshold to challenges by altering neuronal excitability, cerebral vasoactivity, pain sensitivity, neuroendocrine axes, etc., during the menstrual cycle (Silberstein and Merriam, 1999). Among the possible targets of estrogenic changes, the 5-HT system is crucially involved in neuroendocrine adaptive phenomena controlling pain threshold (Goadsby et al., 2002
) and an impairment of 5-HT function has been described in menstrually related status migrainosus (Nappi et al., 2003
). Indeed, we have recently shown that pituitary release of prolactin, and to an even greater extent cortisol, was significantly blunted in ovulatory women with extremely severe migraine attacks triggered by menstruation following a challenge with meta-chlorophenylpiperazine (m-CPP), a 5-HT agent with a high affinity for several subtypes of 5-HT receptors, especially 1 and 2 (Mueller et al., 1985
), in comparison with women with menstrual migraine with typical duration of attacks (472 h) and controls.
OC is a good model to study the menstrual window vulnerability to severe migraine attacks because the pill-free interval is a well-defined period of abrupt exogenous estrogen withdrawal (MacGregor, 2004) that may eventually represent a major insult to neuroendocrine homeostasis involving 5-HT system.
The aim of the present study was to investigate the involvement of 5-HT1 and 5-HT2 receptor subtypes in the occurrence of status migrainosus triggered by OC discontinuation (OC-SM) by using m-CPP challenge test to elicit prolactin and cortisol response during the pill-free interval. In addition, we tested the neuroendocrine and clinical effects of transdermal estradiol (E2) supplementation, against placebo, during the pill-free interval in a consecutive menstrual cycle.
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Materials and methods |
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Patients [age: 35.4 ± 1.5 years; body mass index (BMI): 22 ± 0.9 kg/m2] had severe, long-lasting migraine (>72 h) without aura attacks occurring within 48 h of the discontinuation of a monophasic OC containing 30 µg of ethinyl estradiol and 150 µg of desogestrel since at least six menstrual cycles. A retrospective clinical interview revealed that, before assuming OC treatment, each patient was probably already suffering from menstrually related migraine without aura, which has never requested a medical consultation. However, duration and severity of menstrual migraine attacks (disability and analgesic consumption) worsened significantly as soon as OC was started (status migrainosus, OC-SM). In addition, under OC the attack was regularly occurring with the menstruation and no other migraine attacks were present throughout the menstrual cycle.
Six matched healthy women (age: 34.6 ± 1.9 years; BMI: 22.3 ± 1.2 kg/m2) who had been using OC for 6 months and never suffering from menstrually related migraine were recruited at the Department of Obstetrics and Gynaecology, IRCCS San Matteo, University of Pavia, Italy, and served as controls, after they had given informed consent.
The clinical characteristics of migraine attacks with menstruation and the pattern of bleeding were determined upon a headache diary card that patients filled in prospectively for 3 months prior to the study. Control women also filled in the diary. Figure 1 shows a representative example of a migraine diary filled in by a OC-SM patient.
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Study protocol
The study protocol was approved by the Local University Ethical Committee, and the Department of Obstetrics and Gynaecology provided the clinical setting where m-CPP challenges were performed.
Following the 3 month run-in period, each patient with OC-SM and each control woman received oral m-CPP (0.5 mg/kg body weight) challenge test 24 h after the discontinuation of the pill. m-CPP test was performed as previously described (Nappi et al., 2003). Briefly,
45 min after catheter placement into the antecubital vein, an open-label oral dose of m-CPP was administered at 09:00 (0 min). Baseline blood samples were obtained at 30 and 0 min. During the next 210 min, plasma samples were taken every 30 min. Blood samples were centrifuged and serum stored at 20°C until assayed. Side-effects throughout the m-CPP challenge tests were recorded.
In a consecutive menstrual cycle, OC-SM women underwent a single-blinded placebo -controlled treatment with transdermal estradiol (E2) during the pill-free interval. Indeed, five patients were randomly supplemented with 2.0 g of percutaneous E2 gel (Sandrena, NV Organon, The Netherlands), daily for a week, starting the day of discontinuation of OC, while five patients were treated with placebo (dispensed in identical sachets) during the pill-free interval. Women were randomized by a computer-generated number list with odd and even numbers allocating patients to receive blindly transdermal E2 or placebo. m-CPP test was performed in both groups as described above.
A headache diary card was filled by patients under both E2 or placebo treatment in order to investigate any clinical or side-effect due to the pill-free interval supplementation.
Hormone assays
Plasma levels of prolactin (ng/ml) and cortisol (nmol/l) were measured by radioimmunoassay using commercially available kits (Immunotech, Marseille, France); the sensitivity of the assay was 0.5 ng/ml and 10 nmol/l respectively, and the intra- and inter-assay coefficients of variation for prolactin were 2.8 and 6.5% respectively, and for cortisol were 3.4 and 6.7% respectively.
Statistical analysis
Data are expressed as the mean ± SE. Results reported in Table I were analysed by using Students t-test for independent samples. The days with menstrually related migraine in OC-SM, the severity (expressed as no. of hours/attack in which pain intensity was severe and prohibits daily activities; pain intensity was graded hourly on a 3-point scale, where 1 = mild, does not impair daily activities; 2 = moderate, may inhibit, but does not prohibit daily activities; 3 = severe, prohibits daily activities) and the analgesic use (no. of analgesics/attack), as well as the number of days of bleeding were calculated for each subject upon headache diaries over three consecutive menstrual cycles prior to the study and over the menstrual cycle investigated. The presence (no/yes) of nausea, vomiting, photophobia and phonophobia was also recorded and expressed as mean number of episodes for each subject.
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Figure 2 was obtained by using multiple analysis of variance (MANOVA) with repeated measures, with diagnostic group as the between-subject variable (OC-SM and controls) and time-point (baseline and 30, 60, 90, 120, 150, 180, 210 min after m-CPP) as the within-subject variables. Figure 2C and D was obtained by using MANOVA with repeated measures, with treatment group as the between-subject variable (E2 and placebo) and time-point (baseline and 30, 60, 90, 120, 150, 180 and 210 min after m-CPP) as the within-subject variables. Significant differences in plasma hormone levels were analyzed by Duncans post hoc comparisons. Outcome measures were evaluated by one of us (N.G.) who was blind to the treatment regimen.
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Results |
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Figure 2B shows significant effects of diagnosis by time interaction (F = 5.8; P < 0.001) obtained by MANOVA on plasma cortisol levels after m-CPP challenge test. Indeed, Duncans post hoc comparison revealed that cortisol response to m-CPP test was absent in OC-SM as opposed to control women who displayed a cortisol increase starting from 90 to 210 min. Even for MANOVA on plasma cortisol levels following m-CPP, the analysis of covariance for age and BMI did not alter the results. No significant difference was found in baseline plasma cortisol levels between OC-SM and C women.
Clinical effects of m-CPP in OC-SM patients and controls
m-CPP was well tolerated by each patient, without significant side-effects. However, one woman with OC-SM had severe nausea, while one control woman had mild nausea as a consequence of m-CPP administration. No significant difference was found in the duration and severity (disability and analgesic consumption) of migraine attacks (data not shown) occurring after m-CPP test in comparison with the data collected during the 3 months prior to the study. It was interesting to note that patients with OC-SM had prolonged menstrual attacks (4.3 ± 0.7 days), a high number of hours in which pain intensity prohibited daily activity (33.0 ± 2.3), extremely severe episodes of vomiting (2.7 ± 0.2) and a very high consumption of analgesics (5.9 ± 0.7). The duration of bleeding was similar between OC-SM patients (4.2 ± 0.4 days) and control women (4.1 ± 0.3 days). Figure 1 shows the clinical severity of the migraine attack occurring at menstruation in an OC-SM patient.
Neuroendocrine and clinical effects of transdermal E2 supplementation of the pill-free interval in OC-SM
Transdermal E2 treatment during the pill-free interval significantly augmented prolactin response to m-CPP in OC-SM, whereas placebo did not interfere with the pattern of prolactin response. MANOVA identified significant effects of time (F = 6.9; P < 0.001) and treatment (F = 10.2; P < 0.01), and treatment by time interaction (F = 2.8; P < 0.01) after m-CPP administration on plasma prolactin levels (Figure 2C).
Cortisol response to m-CPP was completely restored by transdermal E2 supplementation of the pill-free interval. MANOVA identified significant effects of time (F = 2.6; P < 0.02) and treatment by time interaction (F = 18.9; P < 0.001) after m-CPP administration on plasma cortisol levels (Figure 2D). It was interesting to note that when OC-SM were treated with transdermal E2, basal plasma cortisol levels (at 30, 0 and 30 min following m-CPP administration) were significantly lower (P < 0.001) in comparison to placebo.
Even though the number of OC-SM patients treated with the active drug or placebo was low, it was possible to observe a positive clinical effect of transdermal E2 supplementation of the pill-free interval. Indeed, the duration (P < 0.002), the number of hours in which pain intensity prohibits daily activity (P < 0.001), the episodes of vomiting (P < 0.04) and the consumption of analgesics (P < 0.001) were significantly reduced in comparison with placebo (Table I).
Any relevant side-effect was evident in OC-SM women treated with transdermal E2, apart from a modest increase in the duration of bleeding (4.3 ± 0.5 days) in comparison with placebo (3.7 ± 0.3 days; not significant).
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Discussion |
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Headaches are among the most common hormone withdrawal symptoms in OC users, and the course of migraine, in particular, may be affected by the use of exogenous hormones (Sulak et al., 2000, 2002
). However, apart from selected circumstances, especially migraine with aura, in which OC should be used with caution to avoid the increased risk of stroke (Curtis et al., 2002
), the clinical management of women with migraine under OC is quite controversial (Bousser et al., 2000
; MacGregor, 2004
). Gynaecologists tried some empirical approaches to manage the recurrence of migraine attacks during the pill-free interval (Murray and Muse, 1997
; Massiou and MacGregor, 2000
; Sulak et al, 2002
), but little is known about the pathophysiological mechanisms involved in the occurrence of migraine triggered by OC free-interval at the time of menstruation. Moreover, data corroborating the E2 withdrawal theory (Sommerville, 1975
) are also lacking in the literature because of a poor bidirectional flow of information between headache centres and reproductive clinics. Martin et al. (2003)
have shown that addition of transdermal E2 to existing GnRH agonist therapy provides a modest preventive benefit in women who are pre-menopausal with migraine, suggesting the importance of minimizing hormonal fluctuations.
5-HT receptors are heterogeneous within the central nervous system and some of them are most relevant to migraine both for prevention and treatment (Goadsby et al., 2002). Sex steroid changes during the menstrual cycle clearly modulate the 5-HT system at various levels, having an impact on pain, mood, cognition and numerous other neuroendocrine and autonomic functions (McEwen, 2002
).
Women with menstrually related migraine display peculiar neuroendocrine responses during the luteal phase in comparison with controls (Fioroni et al., 1995) reflecting a vulnerability of the menstrual window to external or internal stimuli influencing migraine threshold when sex steroids are falling. The 5-HT system is highly involved, since platelet monoamine oxidase B activity, a good indicator of central 5-HT, is significantly increased in the luteal phase of menstrual migraine sufferers in comparison with asymptomatic controls (Fioroni et al., 1996
).
Our results, showing a significant imbalance of prolactin and cortisol in response to a 5-HT challenge in OC-SM women which is very similar to that already reported in fertile women with very severe menstrually related attacks (Nappi et al., 2003), are in line with the evidence that OC use and discontinuation eventually represent a trigger factor for severe migraine attacks in those women who display a vulnerable neuroendocrine homeostasis involving the 5-HT system. In this context, it is relevant to note that alterations in 5-HT metabolism are related to depression in susceptible women taking OC (Shaarawy et al., 1982
), whereas borderline personality disorders significantly worse during OC are predicted by circulating E2 levels (DeSoto et al., 2003
). In addition, women using OC who experienced high levels of stress displayed an altered uptake of tryptophan in the brain during the pill-free period that may be responsible for mood changes (Tuiten et al., 1995
). On the other hand, contraceptive pills may stimulate the production of vasodilatory markers, including serotonin, an effect which can be attributed most likely to the estrogenic component (Seeger et al., 2000
).
In addition, our data on the ability of transdermal E2 in restoring neuroendocrine responses by exerting a concomitant positive clinical effect on the severity of OC-SM against placebo further support the notion that E2 drop disrupts 5-HT-mediated adaptive capacities implicated in the inhibition of pain. Such a mechanism may be operating not only in hormonally induced severe migraine attacks but even in naturally occurring peri-menstrual migraine. The potent interaction of the 5-HT system and even short-term E2 treatment has been recently uncovered in women suffering from depressive symptoms at menopause (Schmidt et al., 2000) and may be a reliable explanation for the improvement of OC-SM in terms of duration and severity (disability and analgesic consumption) during E2 supplementation. This result was beyond the scope of our study, which has been mainly focused on neuroendocrine features involving the activation of 5-HT2 and 5-HT1 receptors, but it deserves further attention in larger clinical samples. Dennerstein et al. (1988)
showed in a double-blind trial that percutaneous E2 administration for 7 days encompassing menstruation induced a significant reduction in the frequency of migraine and in the amount of pain-killers. In addition, women significantly appreciated the E2 treatment and expressed the preference for continuing it, without reporting any relevant side-effects similarly to our present experience.
In conclusion, abnormalities in the neuroendocrine response to m-CPP test during the pill-free period are related to extremely severe OC-SM attacks. E2 supplementation by restoring modulatory pain pathways involving 5-HT2 and 5-HT1 receptors may be a useful approach to a periodically disabling condition induced or aggravated by OC use. In perspective, we believe that E2 use may have some value in the design of preventive and/or therapeutic strategies for menstrually related migraine, especially with drugs that block or enhance 5-HT release.
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Acknowledgements |
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References |
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Submitted on April 28, 2005; resubmitted on July 4, 2005; accepted on July 18, 2005.
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