Release of PACAP-38 in episodic cluster headache patients – an exploratory study
© The Author(s). 2016
Received: 22 May 2016
Accepted: 22 July 2016
Published: 30 July 2016
Activation of the trigeminal-autonomic reflex, involving the trigeminal ganglion, the superior salivatory nucleus and the sphenopalatine ganglion (SPG) is crucial in the pathophysiology of cluster headache (CH). Since pituitary adenylate cyclase-activating polypeptide-38 (PACAP-38) is present both in the SPG and the trigeminal ganglion (TG) and its role in migraine has been described, our aim was to determine the plasma PACAP-38 levels in different phases of episodic CH (ECH).
Peripheral cubital fossa blood samples were taken during the ictal and inter-bout periods of male ECH patients and from age-matched healthy controls (n = 9). Plasma PACAP-38-like immunoreactivity (LI) was measured with specific and sensitive radioimmunoassay.
Significantly lower plasma PACAP-38-LI was detected in the inter-bout period of ECH patients than in healthy controls. However, PACAP-38 was significantly elevated in the plasma during CH attacks as compared to the inter-bout phase in the same subjects (n = 5).
This exploratory study suggests that PACAP-38 may be released during the attacks of ECH. Further patients and long-term follow-up are necessary to reveal its function.
Cluster headache (CH) is a primary, trigeminal-autonomic headache disorder, manifesting in periodically occurring unilateral (supra/orbital, temporal) severe pain attacks in association with intense ipsilateral autonomic symptoms. The trigeminal-autonomic reflex (TAR) and the hypothalamic system (HS) are thought to play important roles in the mechanism of CH . The significance of TAR is based on the structural and functional connections between the trigeminal ganglion (TG), the superior salivatory nucleus being the parasympathetic nucleus of the facial nerve, the sphenopalatine ganglion (SPG) and otic ganglion (OG). CH attacks involve activation of the TG and the SPG resulting in release of neuroactive neuropeptides such as calcitonin gene-related peptide (CGRP) and vasoactive intestinal polypeptide (VIP) . These molecules reach the cranial vessels, the lacrimal glands and the nasal mucosa via the postganglionic fibers, leading to conjunctival injection, eyelid and nasal edema, and rhinorrhea. The circadian and circannual periodicity of the attacks is attributed to the activation of the HS.
Neurochemical studies have revealed that the VIP-related neuropeptide pituitary adenylate cyclase-activating polypeptide-38 (PACAP-38) co-localize  in the SPG and the OG , however some PACAP-38-immunoreactivity was also seen in the TG [5, 6]. It has recently been described that PACAP-38 mediates the activation of the trigeminovascular system (TS), and exerts modulatory function in the sensitization process and migraine headache [7–10]. Human studies have confirmed that intravenously administered PACAP-38 induces migraine-like headache with marked vascular effects in migraine patients without aura [11, 12], and that PACAP-38 concentrations in the systemic circulation are significantly altered depending on the phases of migraine headache [13, 14].
Therefore, PACAP-38 is likely to be an important factor in migraine pathophysiology; however, there is less evidence concerning its function in other primary headache disorders such as CH. It is suggested that PACAP-38 may be involved in the evolution of trigeminal-autonomic cephalalgias, since this peptide was presented in the TS [8, 9, 15, 16], and also in the SPG and OG [17, 18] of humans and rats. Moreover there is a clear increase of both trigeminal (CGRP) and parasympathetic (VIP) neuropeptides during CH attacks which is normalized when the pain was controlled in CH [19, 20], and it appears that activation of the VPAC1 and PAC1 receptors influences the TAR, the parasympathetic cranial outflow [17, 21]. Based on these data, our aim was to determine if CH patients are associated with alterations in plasma PACAP-38-like immunoreactivity (LI) in the inter-bout period and during the attack in patients suffering from ECH in comparison with age- and gender-matched healthy volunteers.
Materials and methods
Demographic data and clinical features of CH patients
Mean values and features of ECH patients (n = 9)
Body mass index:
28.5 ± 5.6
Duration of cluster headache disease:
7.0 ± 3.8 years
Frequency of cluster episodes and duration of cluster episode:
2.9 ± 0.8 attack episodes/year
5.0 ± 3.1 weeks
Sessions and seasonality of headache episodes:
in the evenings/at nights (n = 4), at dawns (n = 3) and daytime (n = 2)
in spring and summer (n = 4), in changing seasons (n = 4), in winter (n = 1)
Intensity and characteristic of pain:
very strong (n = 6) and severe (n = 3)
splitting/throbbing (n = 5), sharp/stabbing (n = 4) headache
Localization and side of pain:
orbital, supra/periorbital, temporal
right (n = 6) and left (n = 3) side
conjunctival injection, lacrimation, ptosis and eyelid edema, nasal congestion, rhinorrhea, vasodilation, facial redness and flushing
non (n = 4), medium (n = 2) and excessive (n = 3) smokers, moderate caffeine consumers (n = 9)
Most commonly used treatments of ECH patients in the bout periods:
O2 therapy, sumatriptan, nonsteroidal anti-inflammatory drugs (e.g. indomethacin and diclophenac)
Previous attack episode before the inter-bout blood sampling:
2.8 ± 1.0 months
Beginning of the attack episode during the ictal blood sampling:
6.4 ± 4.6 days
Duration of headache attack until the ictal sampling:
2.3 ± 0.6 h
Headache attack frequency per day in a bout and duration of headache attack:
1.2 ± 0.7 headache attack/day in a bout
2.3 ± 0.7 h
Study design sampling procedures
Detailed data of blood samplings in ECH patients: date and time, concentrations of PACAP-38 and therapyᅟ
Date and time of inter-bout sampling
Inter-bout PACAP-38 plasma level (fmol/ml)
Last previous attacks (months ago)
Date and time of ictal sampling
Ictal PACAP-38 plasma level (fmol/ml)
Beginning of bout period (days) and attacks (hours) before the ictal sampling
06 June 2010 03:30 pm
15 May 2011 07:35 pm
Since 14 days, 3 h
O 2, Sumariptan
13 June 2010 01:15 pm
27 June 2010 07:55 pm
Since 2 days, 1.5 h
11 July 2010 01:15 pm
16 Aug 2010 08:00 am
Since 7 days, 2.5 h
O 2 , Sumatriptan
10 Sept 2010 08:30 am
15 Oct 2010 02:45 pm
Since 5 days, 2.5 h
19 Sept 2010 10:30 am
28 Nov 2010 01:00 pm
12 Jan 2011 10:00 am
29 Jan 2012 12:30 pm
11 Oct 2011 01:20 pm
Since 4 days, 2.0 h
O 2 , Sumatriptan
19 Dec 2011 09:00 am
O 2 , Sumatriptan, NSAIDs
Mean ± SD
24.1 ± 2.3
2.8 ± 1.0
28.4 ± 1.9
6.4 ± 4.6 days 2.3 ± 0.6 h
Analysis of PACAP-38 in plasma and data analysis
Blood collection, centrifugation, storage and PACAP-38 measurement were carried out with specific and sensitive radioimmunoassay (RIA). Briefly, following centrifugation of the plasma samples (2000 rpm at +4 °C for 10 min), the peptide was extracted from the plasma into three volumes of absolute alcohol. After precipitation and a second centrifugation, the samples were dried under a nitrogen flow and resuspended in 300 μl of assay buffer before RIA determination. The assay was prepared in 1 mL 0.05 mol/L (pH 7.4) phosphate buffer containing 0.1 mol/L sodium chloride, 0.25 % (w/v) bovine serum albumin and 0.05 % (w/v) sodium azide. The tracer mono-125I-labeled PACAP24–38 (5000 cpm/tube, 124 Bq/1.72 fmol) was prepared in our laboratory. Ovine PACAP38 was used as a RIA standard ranging from 0 to 1000 fmol/mL. The PACAP-38 antiserum (88111-3, dilution 1:10000 obtained from Abcam UK), the RIA tracer and the standard or unknown samples were measured into polypropylene tubes with the assay buffer. After incubation for 48–72 h at +4 °C, the antibody-bound peptide was separated from the free peptide by the addition of separating solution. Following centrifugation (3000 rpm at +4 °C for 20 min), the contents of the tubes were gently decanted and the radioactivity of the precipitates was measured in a gamma counter (Gamma, type: NZ310). The PACAP-38 concentrations of the unknown samples were read from calibration curves.
Data are expressed as median, interquartile range (IQR), minimum and maximum or individual values on the graphs. The distributions of data populations were checked with the Shapiro-Wilk normality test and the Levene’s test for analysis of the equality of variances was also applied.
Groups were compared with two sample unpaired and paired t-tests where appropriate via Monte-Carlo permutation (with 10000 random permutations) due to the small number of subjects, the unequal variances and the non-Gaussian distribution of the data of the control group. Correlations were revealed by the Pearson’s test. Statistical analyses were performed using the R software (R Development Core Team, 2002). Significance was accepted at p < 0.05.
Differences in plasma PACAP-38-LI between ECH patients and healthy controls
The level of plasma PACAP-38-LI in the inter-bout phase of ECH patients was significantly lower (n = 9; median = 24.4 fmol/ml, IQR = 2.68) than in age and gender matched healthy volunteers (n = 9; median = 30.5 fmol/ml, IQR = 8.84; p < 0.026).
Positive correlation between inter-bout plasma PACAP-38 concentration and the age of patients
This is the first study investigating alterations in plasma PACAP-38 concentration in CH patients; however limitation of our study is the sample size of ECH patients, especially the sample size of ictal blood samples. Our results agree with observations in plasma samples from migraine patients, obtained in the cubital fossa [11, 13] or the external jugular vein .
The source of PACAP-38 is unclear but two sites are to be discussed, the parasympathetic ganglia SPG and OT, and the TG, because neurons in ether contain PACAP-38. It is difficult to separate these sources of circulation PACAP-38, because they are intermingled. The stimulation of the superior sagittal sinus elicits release of both CGRP from the TG and VIP from the SPG/OT ganglion and the destruction of the trigeminal nerve aborts their release . This shows interplay between the sensory and parasympathetic systems. It has been revealed that PACAP-38 may induce migraine-like attacks while VIP does not [11, 21, 23]. The role of PACAP-38 seems to differ from VIP, but there are similarities concerning theirs effects in the peripheral cutaneous nociception, which may be mediated by VPAC receptors .
Detailed study on distribution revealed that PACAP co-localize with CGRP in dura mater sensory fibers. The supply of parasympathetic innervation of the dura is scant as compared to that of the cerebral circulation . Thus, it is possible that in both migraine and in CH the PACAP-38 release emanates mainly from the trigeminal system.
Our speculation is that the formation of PACAP-38 is depleted during the inter-bout period in certain nerve structures, which results in lower plasma PACAP-38 level outside the attacks of CH. Subsequently the chronically reduced peptide level may be a trigger for sensitization and altered nociception. During the evolution of nociception the concentration of PACAP-38 can increase and it exerts vasodilation, which is an essential trigger in conjunction with other unknown factors to the development of pain. During the attacks the level of PACAP-38 can reach the normal/control level, which may be a compensatory mechanism, but several further investigations are needed to affirm this theory.
It is also evidenced that the meningeal vasculature likely contributes to the propagation of the headache cascade of symptoms, but the vasodilator ability of PACAP-38 in these circumstances is questionable. It was showed that the PACAP-38 has high potency to induce dilation on pressurized rat meningeal arteries , while another study did not find any discernible effect of PACAP-38 on neither rat nor human samples .
Amin et al. have detected significantly elevated plasma PACAP-38 level following the PACAP-38 infusion in those migraine patients without aura, who later experienced migraine-like attack . Although the half-life of this peptide in plasma is short (minutes), it was suggested that the administered PACAP-38 would induce long-lasting extracranial vasodilation and neurogenic inflammation and thereby provoke a migraine attack. The nature of such a mechanism is still unclear. An alternative mechanism might be that low levels of PACAP-38 is entering the CNS and interferes with central sensory mechanisms active in the migraine or CH brain.
Nevertheless, it is important to mention that elevation was detected in the plasma PACAP-38 level both in human migraine studies [11, 14] and experimentally, when the activation of the TS was provoked with electrical or chemical methods [7, 14]. However, these studies could not investigate the difference between the interictal and normal, healthy plasma PACAP-38 levels.
The main factor determining the levels of PACAP-38 in the systemic circulation is unidentified; however, it may originate from endogenous release, damaged elimination, or de novo synthesis . Significant amount of peptide can be released from the peripheral (i.e., cranial meninges) and central branches (i.e., trigeminal caudal nucleus) of the TG and other PACAP-38-containing structures of the nervous system (i.e., SPG/OT) during the beginning of the headache. The activation of TAR is certainly involved in the neuropeptide overflow, which might result in middle meningeal artery vasodilation, mast cell degranulation, and peripheral and central sensitization; concomitantly it contributes to the development of headache [11, 13, 28].
Although PACAP-38 has not been previously investigated in CH, the concentrations of CGRP, VIP and substance P (SP) have already been examined. Regarding VIP a clinical study has revealed elevated VIP-like immunoreactivity in saliva of CH patients during attack period as compared with the VIP levels during the interictal phase . Moreover, significantly increased CGRP and VIP levels were found in the plasma obtained from the ipsilateral external jugular vein during spontaneous attacks of ECH patients , and in the extracerebral circulation both during spontaneous and nitroglycerine-induced attack phase of CH [20, 30], whereas lower plasma SP levels were detected during histamine-induced and spontaneously occurring CH attacks when compared with controls . Of note, similar alterations were found considering these neuropeptides in migraineurs, which parallels the concordant changes of PACAP-38-LI observed in migraine and CH disorders.
Additionally, it should be noted that the role of PACAP in CH may also be emphasized by the evidences, which showed that PACAP can modulate the melatonin synthesis, subsequently the circadian and circannual rhythm in animals (including mammals) [32–34]. However, we did not find any correlation between the plasma concentration of PACAP-38 and the date and time of blood sampling.
Moreover, we detected a positive linear correlation between the inter-bout plasma PACAP-38 level and the age of ECH patients, which suggests that older age is associated with smaller decrease in the concentration of PACAP-38 outside of cluster period. Our data can be related to clinical studies, which concluded that the development of chronic CH is much less frequent in older than in younger patients [35, 36], if we consider that a lower inter-bout plasma PACAP-38 concentration can be a triggering factor of attacks. However, it needs further cases and data collection to affirm our hypothesis regarding this association.
Our pilot study provides the first evidence supporting that PACAP-38 may influence the course of CH. Similar changes of this peptide in migraine suggest that PACAP-38 might serve as a marker of primary headache conditions. Further investigations are necessary to determine the exact functions, targets and signaling pathways of PACAP-38.
CGRP, calcitonin gene-related peptide; CH, cluster headache; ECH, episodic cluster headache; EDTA, ethylenediaminetetraacetic acid; HS, hypothalamic system; LI, like immunoreactivity; OG, otic ganglion; PACAP-38, pituitary adenylate cyclase-activating polypeptide-38; RIA, radioimmunoassay; SP, substance P; SPG, sphenopalatine ganglion; TAR, trigeminal-autonomic reflex; TG, trigeminal ganglion; TS, trigeminovascular system; VIP, vasoactive intestinal polypeptide
This work was supported by the project TÁMOP-4.2.2.A-11/1/KONV-2012-0052, EUROHEADPAIN (Grant No. 602633), OTKA (PD 104715), the MTA-SZTE Neuroscience Research Group and the National Brain Research Programs (Grant No. KTIA_13_NAP-A-III/9., Chronic Pain Research Group: Grant No. KTIA_NAP_13-2014-0022; Z. Helyes, 888819). Dr. Árpád Párdutz and Dr. Nikoletta Szabó were supported by the Bolyai Scholarship Programme of the Hungarian Academy of Sciences.
All authors have read the manuscript and agreed with the submission.
All authors declare that there are no conflicts of interest and they have no other relevant affiliations or financial involvement concerning this study.
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- Goadsby PJ (2002) Pathophysiology of cluster headache: a trigeminal autonomic cephalgia. Lancet Neurol 1(4):251–7View ArticlePubMedGoogle Scholar
- Goadsby PJ, Lipton RB (1997) A review of paroxysmal hemicranias, SUNCT syndrome and other short-lasting headaches with autonomic feature, including new cases. Brain 120(Pt 1):193–209View ArticlePubMedGoogle Scholar
- Fahrenkrug J, Hannibal J (2004) Neurotransmitters co-existing with VIP or PACAP. Peptides 25(3):393–401View ArticlePubMedGoogle Scholar
- Edvinsson L, Elsas T, Suzuki N, Shimizu T, Lee TJ (2001) Origin and Co-localization of nitric oxide synthase, CGRP, PACAP, and VIP in the cerebral circulation of the rat. Microsc Res Tech 53(3):221–8View ArticlePubMedGoogle Scholar
- Moller K, Zhang YZ, Hakanson R, Luts A, Sjolund B, Uddman R, Sundler F (1993) Pituitary adenylate cyclase activating peptide is a sensory neuropeptide: immunocytochemical and immunochemical evidence. Neuroscience 57(3):725–32View ArticlePubMedGoogle Scholar
- Tajti J, Uddman R, Moller S, Sundler F, Edvinsson L (1999) Messenger molecules and receptor mRNA in the human trigeminal ganglion. J Auton Nerv Syst 76(2-3):176–83View ArticlePubMedGoogle Scholar
- Tuka B, Helyes Z, Markovics A, Bagoly T, Nemeth J, Mark L, Brubel R, Reglodi D, Pardutz A, Szolcsanyi J, Vecsei L, Tajti J (2012) Peripheral and central alterations of pituitary adenylate cyclase activating polypeptide-like immunoreactivity in the rat in response to activation of the trigeminovascular system. Peptides 33(2):307–16View ArticlePubMedGoogle Scholar
- Eftekhari S, Salvatore CA, Johansson S, Chen TB, Zeng Z, Edvinsson L (2015) Localization of CGRP, CGRP receptor, PACAP and glutamate in trigeminal ganglion. Relation to the blood-brain barrier. Brain Res 1600:93–109View ArticlePubMedGoogle Scholar
- Palkovits M, Somogyvari-Vigh A, Arimura A (1995) Concentrations of pituitary adenylate cyclase activating polypeptide (PACAP) in human brain nuclei. Brain Res 699(1):116–20View ArticlePubMedGoogle Scholar
- Zagami AS, Goadsby PJ, Edvinsson L (1990) Stimulation of the superior sagittal sinus in the cat causes release of vasoactive peptides. Neuropeptides 16(2):69–75View ArticlePubMedGoogle Scholar
- Amin FM, Hougaard A, Schytz HW, Asghar MS, Lundholm E, Parvaiz AI, de Koning PJ, Andersen MR, Larsson HB, Fahrenkrug J, Olesen J, Ashina M (2014) Investigation of the pathophysiological mechanisms of migraine attacks induced by pituitary adenylate cyclase-activating polypeptide-38. Brain 137(Pt 3):779–94View ArticlePubMedGoogle Scholar
- Schytz HW, Birk S, Wienecke T, Kruuse C, Olesen J, Ashina M (2009) PACAP38 induces migraine-like attacks in patients with migraine without aura. Brain 132(Pt 1):16–25PubMedGoogle Scholar
- Tuka B, Helyes Z, Markovics A, Bagoly T, Szolcsanyi J, Szabo N, Toth E, Kincses ZT, Vecsei L, Tajti J (2013) Alterations in PACAP-38-like immunoreactivity in the plasma during ictal and interictal periods of migraine patients. Cephalalgia 33(13):1085–95View ArticlePubMedGoogle Scholar
- Zagami AS, Edvinsson L, Goadsby PJ (2014) Pituitary adenylate cyclase activating polypeptide and migraine. Ann Clin Transl Neurol 1(12):1036–40View ArticlePubMedPubMed CentralGoogle Scholar
- Mulder H, Uddman R, Moller K, Zhang YZ, Ekblad E, Alumets J, Sundler F (1994) Pituitary adenylate cyclase activating polypeptide expression in sensory neurons. Neuroscience 63(1):307–12View ArticlePubMedGoogle Scholar
- Tajti J, Uddman R, Edvinsson L (2001) Neuropeptide localization in the “migraine generator” region of the human brainstem. Cephalalgia 21(2):96–101View ArticlePubMedGoogle Scholar
- Csati A, Tajti J, Kuris A, Tuka B, Edvinsson L, Warfvinge K (2012) Distribution of vasoactive intestinal peptide, pituitary adenylate cyclase-activating peptide, nitric oxide synthase, and their receptors in human and rat sphenopalatine ganglion. Neuroscience 202:158–68View ArticlePubMedGoogle Scholar
- Uddman R, Tajti J, Moller S, Sundler F, Edvinsson L (1999) Neuronal messengers and peptide receptors in the human sphenopalatine and otic ganglia. Brain Res 826(2):193–9View ArticlePubMedGoogle Scholar
- Goadsby PJ, Edvinsson L (1994) Human in vivo evidence for trigeminovascular activation in cluster headache. Neuropeptide changes and effects of acute attacks therapies. Brain 117(Pt 3):427–34View ArticlePubMedGoogle Scholar
- Fanciullacci M, Alessandri M, Figini M, Geppetti P, Michelacci S (1995) Increase in plasma calcitonin gene-related peptide from the extracerebral circulation during nitroglycerin-induced cluster headache attack. Pain 60(2):119–23View ArticlePubMedGoogle Scholar
- Rahmann A, Wienecke T, Hansen JM, Fahrenkrug J, Olesen J, Ashina M (2008) Vasoactive intestinal peptide causes marked cephalic vasodilation, but does not induce migraine. Cephalalgia 28(3):226–36View ArticlePubMedGoogle Scholar
- Headache Classification Committee of the International Headache, S (2013) The International Classification of Headache Disorders, 3rd edition (beta version). Cephalalgia 33(9):629–808View ArticleGoogle Scholar
- Amin FM, Hougaard A, Magon S, Asghar MS, Ahmad NN, Rostrup E, Sprenger T, Ashina M (2016) Change in brain network connectivity during PACAP38-induced migraine attacks: A resting-state functional MRI study. Neurology 86(2):180–7View ArticlePubMedGoogle Scholar
- Schytz HW, Holst H, Arendt-Nielsen L, Olesen J, Ashina M (2010) Cutaneous nociception and neurogenic inflammation evoked by PACAP38 and VIP. J Headache Pain 11(4):309–16View ArticlePubMedPubMed CentralGoogle Scholar
- Eftekhari S, Warfvinge K, Blixt FW, Edvinsson L (2013) Differentiation of nerve fibers storing CGRP and CGRP receptors in the peripheral trigeminovascular system. J Pain 14(11):1289–303View ArticlePubMedGoogle Scholar
- Syed AU, Koide M, Braas KM, May V, Wellman GC (2012) Pituitary adenylate cyclase-activating polypeptide (PACAP) potently dilates middle meningeal arteries: implications for migraine. J Mol Neurosci 48(3):574–83View ArticlePubMedPubMed CentralGoogle Scholar
- Grande G, Labruijere S, Haanes KA, MaassenVanDenBrink A, Edvinsson L (2014) Comparison of the vasodilator responses of isolated human and rat middle meningeal arteries to migraine related compounds. J Headache Pain 15:22View ArticlePubMedPubMed CentralGoogle Scholar
- Vecsei L, Tuka B, Tajti J (2014) Role of PACAP in migraine headaches. Brain 137(Pt 3):650–1View ArticlePubMedGoogle Scholar
- Nicolodi M, Del Bianco E (1990) Sensory neuropeptides (substance P, calcitonin gene-related peptide) and vasoactive intestinal polypeptide in human saliva: their pattern in migraine and cluster headache. Cephalalgia 10(1):39–50View ArticlePubMedGoogle Scholar
- Fanciullacci M, Alessandri M, Sicuteri R, Marabini S (1997) Responsiveness of the trigeminovascular system to nitroglycerine in cluster headache patients. Brain 120(Pt 2):283–8View ArticlePubMedGoogle Scholar
- Sicuteri F, Fanciullacci M, Geppetti P, Renzi D, Caleri D, Spillantini MG (1985) Substance P mechanism in cluster headache: evaluation in plasma and cerebrospinal fluid. Cephalalgia 5(3):143–9View ArticlePubMedGoogle Scholar
- Schwartz C, Andrews MT (2013) Circannual transitions in gene expression: lessons from seasonal adaptations. Curr Top Dev Biol 105:247–73View ArticlePubMedPubMed CentralGoogle Scholar
- Hannibal J, Ding JM, Chen D, Fahrenkrug J, Larsen PJ, Gillette MU, Mikkelsen JD (1997) Pituitary adenylate cyclase-activating peptide (PACAP) in the retinohypothalamic tract: a potential daytime regulator of the biological clock. J Neurosci 17(7):2637–44PubMedGoogle Scholar
- Simonneaux V, Ouichou A, Pevet P (1993) Pituitary adenylate cyclase-activating polypeptide (PACAP) stimulates melatonin synthesis from rat pineal gland. Brain Res 603(1):148–52View ArticlePubMedGoogle Scholar
- Donnet A, Lanteri-Minet M, Guegan-Massardier E, Mick G, Fabre N, Geraud G, Lucas C, Navez M, Valade D, C. Societe Francaise d’Etude des Migraines et (2007) Chronic cluster headache: a French clinical descriptive study. J Neurol Neurosurg Psychiatry 78(12):1354–8View ArticlePubMedPubMed CentralGoogle Scholar
- Dong Z, Di H, Dai W, Pan M, Li Z, Liang J, Zhang M, Zhou Z, Liu R, Yu S (2013) Clinical profile of cluster headaches in China - a clinic-based study. J Headache Pain 14(1):27View ArticlePubMedPubMed CentralGoogle Scholar