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4/2020
vol. 95
 
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Artykuł oryginalny

Vitamin D status in children with migraine: a case-control study

Aliakbar Momen
1
,
Kourosh Riahi
1
,
Gholamreza Jelodar
1
,
Shahram Nasiri
1
,
Sahar Majidinezjad
1
,
Hamid Nilsaz-Dezfouli
2
,
Reza Azizimalamiri
1

1.
Department of Pediatrics, Golestan Medical, Educational, and Research Center, Ahvaz Jundishapur University of Medical Sciences, Ahvaz, Iran
2.
Department of Industrial Engineering, Islamic Azad University, Mahshahr, Iran
Pediatr Pol 2020; 95 (4): 228–233
DOI: https://doi.org/10.5114/polp.2020.103505
Data publikacji online: 2021/01/30
Plik artykułu:
- Vitamin D status.pdf  [0.14 MB]
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Introduction

Migraine is very common in children and adolescents, affecting about 4-11% of children in elementary schools and 8-23% of adolescents [1]. According to the criteria of the international classification of headache disorders, 3rd edition (ICHD-III), [2] migraine headaches in children are usually characterized by attacks of pulsating and unilateral or bilateral headaches with photo-phonophobia, and nausea or vomiting. These headaches last 2-72 hours and the behaviour of children usually changes during the headaches. Migraine headaches have a huge negative impact on the quality of life in children and their families [1]. Although bio-behavioural measures such as adequate sleep and appropriate and on time meals may help managing headaches, many children with frequent (more than 2 attacks per week) or severe migraine attacks require medications [3]. Medications approved by FDA to administer in children with migraine are limited. A number of different classes of medications have been used including anti-seizure medications (valproate, levetiracetam), calcium channel blockers (flunarizine, cinnarizine, cyproheptadine), beta-blockers (propranolol), and tricyclic anti-depressants (amitriptyline) [3].
In addition to the mentioned medications, a number of dietary supplements such as minerals and vitamins have been suggested to prevent recurrent migraine attacks. Liampas et al. have been conducted 4 important systematic reviews and meta-analyses and provided the evidence for the use of complementary approaches [4–7]. In these studies, the effects of supplemental pyridoxine, folate, cobalamine, and the serum homocysteine in patients with migraine have been evaluated and possible therapeutic roles have been suggested [6, 7]. They also assessed the therapeutic use of exogenous melatonin in migraine [5]. Among the different vitamins, one of the most noted is vitamin D [4, 8]. Vitamin D has a wide range of effects on different systems of the human body including the nervous system [8]. Some observational studies and a few clinical trials tried to show the role of this vitamin in migraine headaches [8–24], however, the results are controversial and prescribing vitamin D in every patient with migraine is not indicated [8]. Vitamin D may influence migraine headaches in a number of ways. Inflammation plays a key role in migraine; hence, the anti-inflammatory role of vitamin D may play an important role in preventing migraine headaches [25]. In addition, vitamin D supplementation can reduce inflammatory factors such as C reactive protein as a strong inflammatory mediator [26]. Other possible pathophysiologic roles of vitamin D in migraine headaches are related to its effects on the possible sensitization of the second and third neurons. These neurons are connected with the stimulation of sensory receptors of the periosteal covering and central sensitization [17, 27]. Vitamin D deficiency could also lead to magnesium deficiency. Magnesium has a central role in inhibiting excessive excitation and studies have shown a strong association between migraine and magnesium deficiency [28]. Nitric oxide (NO) is known as a key mediator in migraine and vitamin D reduces the production of NO [29]. The release of dopamine and serotonin have been shown to be influenced by vitamin D and these factors are known to be connected with the pathogenesis of migraine [30]. Low levels of melatonin have been shown in patients with migraine and vitamin D deficiency could lead to low melatonin levels [31]. All of these suggested mechanisms indicate the importance of vitamin D in the pathophysio­logy of migraine. To our knowledge, no study has been conducted speci­fically in Iran to show the vitamin D status in children with migraine; therefore, we conducted a study to assess the status of vitamin D in children with migraine and comparing them with a healthy age- and sex-matched healthy controls. We also tried the assess the correlation between vitamin D serum levels and the severity and frequency of headaches.

Material and methods

Study design, location, and participants

We conducted a prospective case-control study. The study was performed at Golestan Hospital, a University-affiliated referral hospital in Ahvaz, Southwest of Iran. The study began on June 1, 2018, and continued until November 30, 2019. Eligible children were those who aged 6-14 years that according to the international classification of headache disorders, 3rd edition (ICHD-III) criteria had migraine (with and without aura) [2]. A child neurologist confirmed the migraine diagnosis and all the children in the migraine group had headaches at least more than 6 months. To rule out other causes of headaches, a detailed history was taken and thorough systemic and neurologic examinations were conducted. Brain imaging (MRI) was conducted in doubtful cases. After obtaining written informed consent, participants were consecutively enrolled to the migraine or control group. Participants in the control group composed of healthy children who were referred for growth and development monitoring. All the children in the control group were healthy without any history of migraine headaches or other primary headache disorders. To increase the betweengroups comparability, we recruited them from the same schools and living areas as the migraine group.

Inclusion and exclusion criteria

Included children (6-14 years) were those with migraine (with and without aura) and a group of sex- and age-matched healthy children as a control group. Those who did not give consent, either themselves or their parents, were excluded. We also excluded all those who had major comorbidities such as diabetes mellitus, renal failure, epilepsy, congenital heart disease, malignancy, rheumatologic disorders, gastrointestinal diseases, and those with clinical manifestations of rickets or osteomalacia and those who were taking supplemental vitamin D or any medication that could change the metabolism of vitamin D and calcium. All of these conditions may have a direct or indirect effect on vitamin D status.

Sampling

We referred all the participants to the central laboratory of the centre for blood sampling from 8:00 to 10:00 A.M. every day except Friday. In each participant, a 5-ml blood sample was collected under standard aseptic condition. The samples immediately were centrifuged then serums of the samples were frozen and kept at –70°C. Plasma levels of 25(OH)D were measured using a chemiluminescent immunoassay kit [“25(OH)D total assay, Diasorin Liaison”] by LIAISON analyser. The best way of defining vitamin D status in a person is measuring the prohormone 25(OH)D, which is an indicator of supply rather than function [32]. Vitamin D status was classified as Optimal (> 20 ng/ml), insufficient (11–20 ng/ml), and deficient (≤ 10 ng/ml) [32]. In children with migraine the frequency, duration, and severity of headaches were registered. We asked all the children with migraine and their parents to record the frequency (per month), severity (using the scale), and duration (in hours) of headaches in previously prepared charts during the next month after enrolment. To assess the severity of headaches, we used the Wong-Baker FACES Pain Rating Scale [33, 34]. Wong-Baker FACES Pain Rating Scale ranges from 0 to 10. On this scale, 0 equals no pain, 1–3 equals mild pain, 4–6 equals moderate pain, and 7–10 equals severe pain. According to the literature, the frequency of headaches could be categorized; fewer than seven headache days per month (low-frequency episodic migraine), 7–14 days per month (high-frequency episodic migraine), and 15 or more days per month (chronic migraine)[35].

Statistical analysis

According to the previous studies [12, 15, 23] and based on the type I error α = 0.05 and power of 80% we needed at least 30 children in each group to detect differences between the serum vitamin D levels of the two groups. The Kolmogorov–Smirnov test was used to define the normality of the data. We used independent sample t-test and analysis of variance (ANOVA) to analysed continuous data. Categorical variables were analysed using the 2 test. We used Pearson correlation test to assess the correlation of vitamin D serum levels and the severity and frequency of headaches. The p-values < 0.05 was considered significant.

Ethics

The study design and its protocol have been assessed and approved by the ethics committee of the centre and Ahvaz Jundishapur University of Medical Sciences (D/3265) and we performed the study in accordance with the ethical standards as laid down in the 1964 Declaration of Helsinki and its later amendments. All the parents and their children read and signed written informed consent before enrolment. Verbal consent was obtained from children who could not sign our forms.

Results

Baseline characteristics

In this study, 50 children with migraine and 45 healthy control were eligible to enrol. However, in the migraine group, 10 children did not give consent, 8 children had no cooperation to record the requested data, and 2 were lost to follow up. In the control group, 15 children did not give consent. Sequentially, we enrolled 60 children with confirmed eligibility (30 children in each group) into the study and the data from all of them were analysed. The baseline characteristics of the participants are summarized in Table 1 (migraine group) and Table 2 (control group). The age range of the participants was between 6–14 years and the median age in both groups was 9 years. Migraine characteristics such as frequency, duration, and severity of headaches are shown in Table 1. Migraine accompaniments also are shown in Table 1. In terms of age, gender, and body mass index, no statistically significant differences were found between groups (Table 3). None of the children from both groups showed the signs and symptoms of vitamin deficiency or insufficiency. Table 3 compares groups regarding age, gender, and weight.

Vitamin D status in the participants, and its correlation with headache severity and frequency

The mean ± SD of vitamin D serum levels (ng/ml) was (15.9 ±5.4) in migraine group and (17.4 ±11.3) in healthy controls. Independent sample t-test showed no significant difference between groups (two tailed independent sample t-test, p-value = 0.509). As shown in Table 4, in the migraine group five patients (3 girls and 2 boys) had optimal levels of vitamin D, 20 (10 girls and 10 boys) had insufficiency, and five (4 girls and 1 boy) were deficient. In the control group, six patients (4 girls and 2 boys) had optimal levels of vitamin D, 19 (8 girls and 11 boys) had insufficiency, and five (4 girls and 1 boy) were deficient. Vitamin D status had no significant difference between both groups (2, p = 0.943). We could not find any correlation between vitamin D status and severity (Pearson correlation, p = 0.513) and frequency (Pearson correlation, p = 0.422) of migraine attacks. Table 5 shows the vitamin D serum levels (ng/ml) and compares it between groups regarding gender, age groups, the presence of aura, and severity and frequency of headaches. As shown in Table 5, no statistically significant difference in serum vitamin D levels was found between groups regarding age groups and gender. In addition, the serum vitamin D levels was not significantly different in migraine groups regarding presence or absence of aura, and the frequency and severity of headaches.

Discussion

The results of this study indicate that vitamin D insufficiency and deficiency in children with migraine are as common as in healthy children. Our results did not indicate any correlation between vitamin D serum values and the severity and frequency of headaches in children. These results may be inclined by small sample size of the study. We know that to define delicate differences we need large sample sizes. Previous studies of vitamin D status in patients with migraine had controversial results. A number of case-control studies proposed an inverse correlation between the vitamin D serum levels and the severity of headaches [12, 23]. However, these studies could not indicate plausible pathophysiologic evidence for their claims that vitamin D insufficiency or deficiency essentially worsens migraine headaches. Like observational studies, clinical trials of vitamin D supplementation in patients with migraine had controversial results [10, 11, 13, 14, 16]. A few clinical trials showed the positive effect of vitamin D supplementation on the frequency and severity of headaches while other experimental studies showed no effect of administering vitamin D. Among these trials, the study conducted by Knutsen et al. did not show any significant difference between vitamin supplementation and the placebo effect on the occurrence, anatomical localization, and degree of pain or headache [16]. In contrast, studies conducted by Ghorbani et al., Gazerani et al., and Buettner et al. showed the efficacy of supplemental vitamin D in patients with migraine [10, 13, 14].
Among previous studies, Hancı et al. conducted a case-control study in children with primary headaches [15]. The age range in their study (5–17 years) was almost similar to the age range of ours. Interestingly, their results are comparable to our results. Like us, they did not find any difference in vitamin D status between children with migraine and healthy controls. In contrast to our results, the results of a case-control study in children that was conducted by Donmez et al. indicated that vitamin D levels in children with migraine were significantly lower than the healthy control group [12]. Another case-control study conducted by Tozzi et al. indicated a high incidence of vitamin D deficiency in the paediatric population with headache (56%), particularly in migraineurs without aura [23]. All the remaining observational studies were conducted in young adults. Although these studies in the adults had controversial results, a recent meta-analysis conducted by Liampas et al. showed interesting results. This study pooled the data from the nine eligible studies. Serum levels of 25(OH)D were determined significantly lower in migraine patients (n = 952) in comparison with healthy controls (n = 8013) (eight studies, PQ < 0.1, I2 = 94%, RE model MD = –4.11, 95% CI : –6.48 to –1.74). The authors indicated that investigation of the effect of vitamin D supplementation in patients suffering from migraine is warranted [4].
The pathophysiology of migraine is complex and until now the main involved mechanisms in this condition have not been fully elucidated. A number of studies proposed possible role of calcium in the pathophysiology of migraine. These studies have been suggested the possible role of hypercalcemia in migraine headaches and proposed that genetically elevated serum calcium over lifetime appears to increase risk for migraine [36]. Moreover, investigators have had attempted to explain a number of pathophysiologic mechanisms of vitamin D and its deficiency in patients with migraine [8]. Among these mechanisms, anti-inflammatory effects of calcitriol, controlling T helper cells, acting as a neuroactive steroid, inhibiting nitric oxide, and suppressing prostaglandin E2 are the most proposed mechanisms [8]. In addition, clinical trials of supplemental vitamin D in patients with migraine headaches have shown controversial results, and supplementing with vitamin D is not indicated in all patients with migraine. By the way, a highly selected group of patients with migraine and vitamin D deficiency might benefit from supplemental vitamin D [8].
Jazayeri et al. conducted a meta-analysis and studied the prevalence of vitamin deficiency and insufficiency in Iranian children [37]. They pooled the data from the 11 studies from all over the country. The prevalence of vitamin D deficiency in Iranian boys and girls were 35% (95% CI: 34–37) and 61% (95% CI: 60–63), respectively. The prevalence of vitamin D insufficiency in Iranian children and adolescents was 31% (95% CI: 30–31). Although the results of our study are somewhat different from the results of this meta-analysis but when we compared our results with the individual studies from Iran, we found that our results are close to the results of the study conducted by Mellati et al. [38]. Iran is a vast country and the exposure of people to sunlight is different over the country. Our province, Khuzestan, is sunny and people are exposed to sunlight more than other areas of the country, however, dietary insufficiency of vitamin D supplements could result in insufficient production of vitamin D after exposure to sunlight but could prevent from severe deficiency. It seems that the results of our study could represent the vitamin D status from this part of our country. The results of our study should be interpreted in the face of certain limits. The sample size of our study was small. Our patients were from the Southwest of Iran; therefore, our results should not be generalized to other provinces of Iran. In addition, studies showed that the prevalence of vitamin D insufficiency and deficiency in Iran is high [37]; therefore, any study of assessing vitamin D status in any population from Iran could be affected by this high prevalence.

Conclusions

Vitamin D insufficiency and deficiency are common in children and it seems that its prevalence is similar in children with migraine and healthy controls. To determine the role of vitamin D in the pathophysiology of migraine or its management, we need well-designed clinical trials of supplementing vitamin D in children with migraine who suffer from vitamin D deficiency or insufficiency.

Acknowledgements

This paper is from the thesis of Sahar Majidinezjad, M.D. The Research Deputy of Ahvaz Jundishapur University of Medical Sciences provided financial and logistic support for this study (grant number: U-96159), but had no role in study design; data collection, analysis, or interpretation; writing the report; or in the decision to submit the article for publication. The authors are grateful to all parents and patients for their participation in this study. We are extremely indebted to the authorities of the Research Deputy of Ahvaz Jundishapur University of Medical Sciences for their financial and logistic support. 

Disclosure

The authors declare no conflict of interest.
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