The role of hypertension in the relationship between leisure screen time, physical activity and migraine: a 2-sample Mendelian randomization study

Background

The relationship between lifestyle and migraine is complex, as it remains uncertain which specific lifestyle factors play the most prominent role in the development of migraine, or which modifiable metabolic traits serve as mediators in establishing causality.

Methods

Independent genetic variants strongly associated with 20 lifestyle factors were selected as instrumental variables from corresponding genome-wide association studies (GWASs). Summary-level data for migraine were obtained from the FinnGen consortium (18,477 cases and 287,837 controls) as a discovery set and the GWAS meta-analysis data (26,052 cases and 487,214 controls) as a replication set. Estimates derived from the two datasets were combined using fixed-effects meta-analysis. Two-step univariable MR (UVMR) and multivariable Mendelian randomization (MVMR) analyses were conducted to evaluate 19 potential mediators of association and determine the proportions of these mediators.

Results

The combined effect of inverse variance weighted revealed that a one standard deviation (SD) increase in genetically predicted Leisure screen time (LST) was associated with a 27.7% increase (95% CI: 1.14–1.44) in migraine risk, while Moderate or/and vigorous physical activity (MVPA) was associated with a 26.9% decrease (95% CI: 0.61–0.87) in migraine risk. The results of the mediation analysis indicated that out of the 19 modifiable metabolic risk factors examined, hypertension explains 24.81% of the relationship between LST and the risk of experiencing migraine. Furthermore, hypertension and diastolic blood pressure (DBP) partially weaken the association between MVPA and migraines, mediating 4.86% and 4.66% respectively.

Conclusion

Our research findings indicated that both LST and MVPA in lifestyle have independent causal effects on migraine. Additionally, we have identified that hypertension and DBP play a mediating role in the causal pathway between these two factors and migraine.

Migraine is a prevalent neurological disorder with a multifaceted etiology [1], remains the second leading cause of disability worldwide [2]. The identification and modification of lifestyle factors associated with migraine can inform research into the pathophysiology of migraine and facilitate the development of appropriate prevention and management strategies. A substantial body of evidence from both preclinical and prospective clinical studies indicates that unhealthy lifestyles, including physical inactivity, sleep disorders, and emotional disorders, smoking, alcohol consumption, may be associated with the development of migraine [3,4,5,6]. Nevertheless, the findings of extant observational studies are somewhat inconsistent.

Physical activity includes physical training, work labor, and daily living. As a modifiable lifestyle, physical training has been recommended as a preventative measure for migraine [7]. The increase in plasma β-endorphins after physical training, accompanied by the inhibition of substance P, may contribute to a reduction in pain pathway transmission [8]. Nevertheless, it has also been demonstrated that routine exercise may exacerbate the symptoms of migraine attacks, leading to a state of resistance to exercise [9]. This may be attributed to the fact that migraine, as a disabling neurological disorder, has an impact on patient’s ability to work and engage in social activities, which in turn reduces their level of physical activity [8]. It is therefore unclear whether migraine directly affects patients’ exercise or vice versa. This potential bidirectional causality is worthy of further investigation. Similarly, sleep and affective disorders are strongly associated with migraine, yet the causal link between the two remains controversial in different studies [10,11,12]. Alcohol, caffeine consumption, and smoking are the most common diet-related triggers associated with increased frequency of migraine attacks [13]. Some of the chemicals present in these lifestyle factors, including biogenic amines (such as histamine, tyramine, and phenylethylamine), caffeine, and nicotine, may play a role in the pathogenesis of migraine by stimulating neural pathways and triggering vascular reactions [14,15,16]. However, other studies have reached contradictory conclusions. Caffeine may attenuate pain perception and augment the analgesic efficacy of migraine headaches via its influence on adenosine receptors [17]. Conversely, studies have not found a correlation between coffee intake and the occurrence of migraine [18]. Additionally, with respect to the relationship between alcohol consumption and migraine, the extant literature indicates a negative correlation between alcohol consumption and migraine, which may be due to the tendency of migraineurs to avoid alcohol, rather than to the protective effect of alcohol itself in relieving migraine [14]. This indicates that the correlation between lifestyle factors and migraine may be more intricate than previously assumed.

The available evidence indicates that blood pressure fluctuations, metabolic and energy supply imbalances may be the key biological mechanisms in the pathogenesis of migraine [19]. Earlier research has indicated a higher prevalence of headaches among individuals with hypertension [20]. It has been shown that hypertension may affect the onset and development of migraine through several mechanisms. For example, hypertension may lead to abnormal vascular function, which in turn affects blood supply and neuromodulation in the brain, increasing the risk of migraine development. In addition, hypertension-induced sympathoexcitation and activation of the renin-angiotensin-aldosterone system may also interact with the pathophysiologic processes of migraine [21]. However, there are also epidemiological studies that suggest a negative correlation between headache occurrence and hypertension [22, 23]. The GWAS has demonstrated that migraine and blood pressure share genetic loci, the cross-trait correlation analyses unveiled potential common biological mechanisms between migraine and blood pressure regulation, involving vascular development, endothelial function, and neurogenic inflammation [24]. The association between blood pressure and migraine is inconsistent, a situation that may shed light on the implications of the existence of reverse causality of blood pressure on migraine in observational studies.

Furthermore, migraine is also closely associated with insulin resistance and metabolic syndrome [25, 26], which may lead to altered neuronal excitability, thereby increasing the susceptibility to cortical spreading depression (CSD) and triggering migraine attacks [27]. Furthermore, an imbalance of lipid metabolism plays an important role in the pathogenesis of migraine. It has been demonstrated that obesity increases the risk of migraine onset, attack frequency, and poorer prognosis. This may be related to the increased sensitivity of the trigeminal vascular system as a result of lipid dysregulation [28]. Additionally, calcitonin-related peptide (CGRP), the main pathogenic peptide associated with migraine, have been shown to play a key role in lipid metabolism and glucose homeostasis, thus affecting the pathogenesis of migraine [29, 30].

Furthermore, vitamins may play an important role in oxidative stress by acting as antioxidants, influencing the progression of migraine. For example, vitamin C can act as a scavenger of reactive oxygen species and ameliorate neuroinflammation in migraine [31]. Vitamin B6 deficiency can result in elevated homocysteine and an increased risk of neurovascular endothelial dysfunction, thus increasing the risk of migraine [32]. Furthermore, vitamin D supplementation has been found to prevent the development of migraine [33], potentially due to its anti-inflammatory, antioxidant, and neuroprotective effects [34]. An individual’s lifestyle is closely related to the body’s metabolic processes. We hypothesized that lifestyle factors may influence physiological indicators such as blood pressure, blood glucose, lipids, and vitamin levels, which in turn affect migraine risk. Determining whether these modifiable metabolic factors mediate lifestyle effects on migraine will provide a new theoretical basis for clinical practice and new avenues for migraine prevention and treatment [35]. Mendelian randomization (MR) is an epidemiological approach that utilizes genetic variation to infer causal relationships between biological factors and disease outcomes. By leveraging the effects of randomly assigned genotypes on phenotypes in natural settings, MR mimics the design of a naturally randomized controlled study, thereby mitigating confounding factors and the influence of reverse causality commonly encountered in observational studies. Multivariate MR (MVMR) extends the MR framework by enabling the incorporation of genetic variants associated with multiple potentially relevant exposures within the analysis, which enables the estimation of the independent impact of each exposure on the outcome while mitigating the influence of confounding bias. Consequently, MVMR can also be employed to estimate mediating effects [36].

This study employed a bidirectional two-sample MR (TSMR) analysis to investigate the independent causal relationships between 20 lifestyle behaviors and the susceptibility to migraine, while also investigating the potential mediating role of metabolic factors between lifestyle and migraine through mediation effect analysis. The aim was to elucidate the underlying biological mechanisms and provide novel evidence for the prevention and therapeutic management of migraine.

Study design

The present MR study included a total of 39 categories of modifiable factors (20 lifestyle and 19 metabolic traits). The study comprised two stages of analyses, as depicted in Fig. 1A for the study design. In the first stage, we evaluated the independent causal effects of each lifestyle category on migraine using TSMR and MVMR. Subsequently, in phase 2, we examined potential mediators for the associations between lifestyle and migraine and conducted a mediation analysis to determine and quantify the impact of the mediator’s effect on the association between lifestyle on migraine (Fig. 1B).

Diagram of the study design. (A) Study design; (B) Selection process for mediating variables. Abbreviations BMI, body mass index; BF%, body fat percentage; TG, total triglyceride; TC, total cholesterol; HDL, high-density lipoprotein; LDL, low-density lipoprotein; T2DM, type 2 diabetes; FG, fasting glucose; FI, fasting insulin; SBP, systolic blood pressure; DBP, diastolic blood pressure; and PP, pulse pressure

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Data sources of lifestyle factors, mediators, and migraine

For the MR analyses, we obtained GWAS datasets from both the Open GWAS and GWAS catalogs. We screened datasets that provided complete summary statistics on European ancestry for each variable. Detailed information on the GWAS datasets, including the number of participants and adjusted covariates, is presented in Table S1. All studies included in the cited GWASs had received approval from a relevant review board, and all participants had provided consent forms. Our study adhered to the scope outlined in the original ethics committee approval.

Lifestyle factors

Lifestyle variables included physical activity, sedentary behaviors, sleep disturbances, smoking, alcohol consumption, coffee intake, and affective disorders (Fig. 2).

Lifestyle variables examined in the study

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Data sources on physical activity (PA) and sedentary behavior

Genetic instruments for PA and sedentary traits were derived from the latest GWAS meta-analysis dataset, including up to 661,399 European individuals from 53 studies with questionnaire-based data [37]. PA was measured using self-reported moderate-to-vigorous physical activity (MVPA). The sedentary behavior phenotype included three self-reported measures: sedentary behavior at work, sedentary commuting, and leisure screen time (LST). PA and sedentary behavior were dichotomized based on self-reported outcomes. To ensure consistency between studies, PA was categorized as “active” and “inactive”. Specifically, subjects were categorized as physically active if they were physically active for an average of 20 min or more per week, and inactive if they did not. The term “MVPA” encompasses aerobic exercise (e.g., jogging, running, cycling, skiing, ball games, etc.) and fitness exercise. It excludes activities that are primarily occupational, such as shoveling or weightlifting, as well as light leisure activities, such as walking or gardening. The definition of sedentary behavior was derived from the subjects’ self-reported sedentary status at work and during commuting time. Accordingly, subjects were classified into two categories: sedentary and non-sedentary behaviors, and LST was quantified as hours per day.

Data sources on sleep disturbance

Genetic instruments for sleep disturbances were obtained from the Sleep Disorder Knowledge Portal (SDKP), and sleep phenotypes in this study included sleep chronotype, sleep duration, long/short sleep duration, and insomnia [38,39,40]. Specifically, chronotype data were derived from a single self-report question: “What type of sleeper do you consider yourself to be?” The responses “Definitely a ‘morning’ person” and “More of a ‘morning’ person than a ‘night’ person” were categorized as “morning type”, “More of an ‘evening’ person than ‘morning’” and “Definitely an ‘evening’ person” were categorized as “evening type”, and other responses such as “don’t know or “don’t want to answer” were excluded [38]. Participants reported sleep duration as a continuous variable based on self-reported habitual sleep duration per day, and was also divided into short sleep (6 hours or less), normal sleep (7 or 8 hours), and long sleep (9 hours or more). Participants with extreme sleep duration less than 3 hours or greater than 18 hours, uncertainty, and use of any sleep medication were excluded [39]. Cases of insomnia were determined from self-report to the question, “Do you have trouble falling asleep at night or do you wake up in the middle of the night? " with responses never/rarely, sometimes, usually, prefer not to answer. Subjects who responded “prefer not to answer” were set to missing. One in which insomnia symptoms were dichotomized into controls (“never/rarely”) and cases with any symptoms (“sometimes” and “usually”) [40].

Data sources on bad dietary behaviors

GWAS summary statistics data on smoking and alcohol behavior were obtained from the GWAS & Alcohol and Nicotine Sequencing Consortium (GSCAN). Four sets of genetic instruments were evaluated with smoking behavior, encompassing the age at which individuals began smoking regularly, the quantity of cigarettes consumed daily, the regularity in smoking, and the act of quitting smoking. Smoking initiation phenotypes included age of initiation of regular smoking and a binary phenotype indicating whether an individual had ever smoked regularly. Heaviness of smoking was measured with cigarettes per day. Smoking cessation was a binary variable contrasting current versus former smokers. Smoking phenotypes do not include information on pipe/cigar/chewing or other non-cigarette forms of tobacco use. Alcohol consumption was defined as the average number of drinks a participant reported drinking each week, aggregated across all types of alcohol [41]. The genetic variables related to coffee intake were obtained from the UK Biobank (UKB) cohort. Participants completed a 24-hour recall questionnaire, and their coffee intake was determined based on the average consumption reported in at least two dietary recalls, including decaffeinated coffee [42].

Data sources on affective disorders

GWAS data on Sensitivity to environmental stress and adversity (SESA) cluster were derived from the UKB, and everyone’s phenotype was according to three items of the Eysenck Personality Questionnaire-Revised Short Version (EPQ-RS), including “Are your feelings easily hurt?“, “Do you worry too long after an embarrassing experience?” and “Are you often troubled by feelings of guilt?” Participants with information on all these three questions were included [43].

Genetic instruments for the remaining subclusters of affective disorders selected, including neuroticism, depression, depressed affect, and worry, were derived from a meta-analysis of GWAS data from the UKB cohort, the Genetics of Personality Consortium (GPC) cohort, and the Psychiatric Genetics Consortium (PGC), as reported by Nagel et al. [44]. The UKB measured neuroticism using a 12-item EEPQ-RS [45], and a weighted mean score was calculated as a total score. In the GPC cohort, neuroticism was measured using the 12 five-point scale items of the NEO Five-Factor Personality Inventory (NEO-FFI), and a weighted mean score was also calculated [46]. Depression was assessed in the UKB cohort via two questionnaire items: “How often have you felt down, depressed, or hopeless in the past two weeks?” and “In the past two weeks, how often have you lacked interest or pleasure in doing things?” Response options for each item were “Not at all” (1 point), “A few days” (2 points), “More than half the days” (3 points), and “Almost every day” (4 points). The scores from the two questions were summed to form a “depression index,” which was standardized to have a mean of 0 and a variance of 1. This index was employed to quantify the degree of depression. In the GPC cohort, the depression measure was dichotomous, and depression was diagnosed if there were at least two diagnoses of depression according to the International Classification of Diseases-9th (ICD-9) classification. The PGC categorizes individuals with a lifetime diagnosis of major depressive disorder as cases, which meet the criteria in the Diagnostic and Statistical Manual of Mental Disorders (DSM).

The sum of scores on four EPQ-RS items (i.e., “Do you often feel lonely? “, “Do you ever feel “just miserable” for no reason? “) was used to obtain scores for the cluster depressed affect. Similarly, the sum of scores on four other EPQ-RS items (i.e., “Does your mood often go up and down? “, and “Do you often feel “fed up”?“. The GWAS for worry cluster was obtained by summing the score on these four items, “Are you a worried? “, “Do you suffer from nerves? “, “Would you call yourself a nervous person? “, and “Would you call yourself tense or highly strung”) was used to obtain scores for the cluster worry.

Data sources on mediators

We identified 19 candidate mediator variables that may lie within the causal pathway between lifestyle and migraine. The detailed information of epidemiological evidence for the relationship between the studied lifestyle factors and mediators with migraine is provided in Table S2, and Table S3 provides detailed information on GWAS of studied mediators, including vitamin traits (retinol, vitamin B12, vitamin C, 25-(OH)2D, α-tocopherol, γ- tocopherol) [47,48,49,50], adiposity traits (body mass index [BMI] and body fat percentage [BF%]) [51, 52], lipids traits (total triglyceride [TG], total cholesterol [TC], high-density lipoprotein - cholesterol [HDL-C], low-density lipoprotein - cholesterol [LDL-C]) [53], glucose metabolism-related traits (fasting glucose, fasting insulin, type 2 diabetes) [54, 55], and blood pressure traits (hypertension, systolic blood pressure [SBP], diastolic blood pressure [DBP], and pulse pressure [PP]) [55, 56].

Data sources on migraine

A summary-level data set on migraine was collected from two large studies. The data from the Discovery Set study were derived from the FinnGen database and included 18,477 individuals with migraine and 287,837 controls [57]. The cases of migraine were defined according to the International Classification of Diseases-10th (ICD-10) classification code G43 and ICD-9 code 346. The dataset excluded individuals of indeterminate sex, high genotypic deletion rate (> 5%), excessive heterozygosity (± 4 SDs) and individuals of non-Finnish ancestry, and the association test was adjusted for age, sex, genetic ancestry principal components (PCs), and genotyping batches. The largest GWAS dataset of migraine European samples to date from the Genetic Epidemiology Research in Adult Health and Aging (GERA) cohort, the UKB cohort, and pooled data from the International Headache Genetics Consortium (IHGC) of Gormley et al., comprising a total of 26,052 cases, 487,214 controls for replication-stage MR analyses [58]. Migraine cases were defined by code G43 in ICD-10 and code 346 in ICD-9, and some of the UKB cohort cases were self-reported by patients. The UKB data in the replication set excluded individuals of non-European ancestry, closely related individuals (or at least one of a related pair of individuals), individuals with sex chromosome abnormalities, and individuals who withdrew consent from the UKB study. The replication set was adjusted for age, sex, and ancestry PCs.

Genetic instrument selection

Independent single nucleotide polymorphisms (SNPs) associated with these factors were selected from the corresponding GWASs using a significance threshold of P < 5 × 10^− 8. Genetic instrument selection for the MVMR analysis followed the same criteria. The instrumental variables (IVs) were clumped based on the linkage disequilibrium (LD) structure from the 1000 Genomes Project, with a threshold of r² < 0.001 and a clump window of 10,000 kb to remove any correlated variants [59].

Statistical analysis

TSMR and MVMR analyses

We conducted a two-sample bidirectional MR study using genetic proxies to evaluate the causal relationship between modifiable lifestyle and migraine. A forward MR analysis was conducted to assess the impact of genetic predisposition to lifestyle factors on the risk of developing migraine. Additionally, a reverse MR analysis was employed to explore the potential influence of genetic susceptibility to migraines on these lifestyle factors. Subsequent MVMR analyses were performed to evaluate the direct causal impact of a specific lifestyle factor on migraine, while accounting for the influence of other lifestyle factors through adjustment. All MR analyses met three essential assumptions: (i) The instrumental variables exhibited a strong correlation with the exposure variable, satisfying the hypothesis of association; (ii) The instrumental variables were independent of the confounding factors, satisfying the independence assumption; (iii) The instrumental variables were not associated with outcome variables but only with outcome variables through the exposure variables, satisfying the independence assumption, the three hypotheses to be satisfied in this study are depicted in Fig. 1A. The inverse variance weighted (IVW) method was used as our main MR analytical approach. To augment the statistical robustness of the analysis, we combined the IVW estimates of the discovery and replication sets through fixed-effects meta-analysis [60].

Mediation MR analyses

To screen for mediators that regulate the causal pathway between lifestyle and migraine, the following criteria should be applied:

1. (1)

   The effect of lifestyle on the mediator should be unidirectional.

2. (2)

   There should always be a causal relationship between the mediator and migraine with or without lifestyle modification.

3. (3)

   The direction of the lifestyle-to-mediator effect as well as the mediator-to-migraine effect should be consistent.

The flow chart of the process of candidate media screening is shown in Fig. 1B. The TSMR was used to estimate the causal effect of lifestyle factor on migraine in the two GWAS datasets, and the effects were combined to generate a total effect β. Subsequently, the TSMR was conducted to estimate the effect size β1 of lifestyle on the mediator, and ultimately estimated the effect size β2 of the mediator-to-migraine effect after adjusting for lifestyle using multivariate MR. The indirect effect was calculated by multiplying the effect sizes of the two steps (β1 × β2). The mediating effect was calculated using the formula indirect/total effect (β1 × β2/β), and standard errors (se) were inferred using the Delta method utilizing the effect estimates obtained from the two-sample MR analysis.

MR sensitivity analyses

In sensitivity analyses, other MR methods such as MR-Egger, Weighted median were performed to correct any potential violations of the assumptions. To check the consistency of results and horizontal pleiotropy, sensitivity analyses were performed using weighted median, MR-Egger regression, and MR-Pleiotropy RESidual Sum and Outlier (MR-PRESSO). The weighted median method produces consistent causal estimates if more than half of the instrumental variables used are valid. MR-Egger regression detects horizontal pleiotropy by the p-value of its intercept test. MR-PRESSO to identify horizontal pleiotropic and identify and discard influential outlier predictors from the IVW test. Additionally, if any pleiotropic SNP was found through the PhennoScanner analysis for causality associated pairs, we removed each possible variant separately and conducted the primary method of IVW again. Cochran Q analysis to assess heterogeneity and considered the fixed-effects IVW approach as the main approach if P-values were higher than 0.05 without evidence of heterogeneity. The random-effects IVW approach was utilized if there was substantial heterogeneity (P < 0.05). The leave-one-out sensitivity analysis was used to assess the effect of individual SNPs on causal estimates by removing each SNP alternatively. The F statistic was calculated to assess the strength of IVs, an F-statistic of > 10 indicated that there was no obvious weak instrument bias.

In TSMR analyses associated with genetic susceptibility to migraine, correlations with p-values less than 0.001 (0.05/39 exposures) were deemed a significant association, and the association with the P-value ≥ 0.001 and ≤ 0.05 were regarded as a suggestive association. The P-value for TSMR associated with LST was set at 0.003 (0.05/19 exposures). IVW estimates were considered causally related only if they were in the same direction and statistically significant as at least one of the sensitivity analyses and showed no evidence of pleiotropy. All statistical tests were two-sided and performed using the TwoSampleMR, Mendelian Randomization and MRPRESSO packages in RStudio 6.0.421.

Lifestyle factors and migraine

Among the 20 lifestyle phenotypes, it was found that genetic susceptibility of five phenotypes was associated with an increased risk of migraine, while two phenotypes were associated with a decreased risk of migraine (Fig. 3). The combined of IVW analysis indicated that the genetically predicted depression (OR, 2.63; 95%CI, 1.66–4.2), neuroticism (OR, 1.36; 95%CI, 1.19–1.56), SESA (OR, 1.69; 95%CI, 1.26–2.27), insomnia (OR, 1.94; 95%CI, 1.40–2.70), and LST (OR, 1.28; 95%CI, 1.14–1.44) were all associated with an increased risk of migraine. However, a genetically predicted 50% increase of coffee intake was found to be associated with a 43.3% reduction in the risk of migraine (OR, 0.57; 95%CI, 0.44–0.73), MVPA was linked to a 26.9% decrease in the risk of migraine (OR, 0.73; 95%CI, 0.61–0.87), the comprehensive findings of discovery and validation analyses are shown in Table S4. In the reverse MR analysis, an observed correlation was found between genetic predisposition to migraine and a decrease in coffee consumption, as well as an evaluated likelihood of morning chronotype and insomnia (Table S5). It is worth noting that all utilized genetic instrumental variables did not exhibit pleiotropy with the outcome, although certain genetic instrumental variables displayed heterogeneity (Table S4 and Table S5).

UVMR estimates of the casual association of each lifestyle factors with migraine. Blue, yellow, and red colors represent the causal effects of the genetically predicted lifestyle with migraine for the discovery set, replication set, and merged set, respectively, estimated using the IVW statistical method. Abbreviations: PA, physical activity; MVPA, moderate or/and vigorous physical activity; LST, leisure screen time; SESA, sensitivity to environmental stress and adversity

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Subsequently, the MVMR approach was employed to concurrently assess the causal relationship between each phenotype and migraine. Following adjustment for genetic instrumental variables pertaining to two other mental disorders, including neuroticism and SESA, the causal effect of depression on migraine remained (OR, 1.89; 95%CI, 1.03–3.45). Furthermore, upon accounting for PA and sedentary behavior, both genetically predicted MVPA and LST exhibited causal associations with migraine (OR, 0.68; 95%CI, 0.58–0.81 for MVPA, OR, 1.16; 95%CI, 1.07–1.26 for LST, respectively). However, upon controlling for all relevant variables that exerted a causal influence on migraine, the causal association of depression with migraine was no longer statistically significant. Instead, only MVPA and LST exhibited distinct and independent causal effects on genetical prediction of migraine, as illustrated in Fig. 4.

The IVW analysis method in the MVMR estimated the relationship between genetically predicted lifestyle factors and migraine after adjusting for other factors

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LST, MVPA and mediators

Bidirectional mediation analysis was employed to examine the potential impacts of LST or MVPA in relation to mediating factors. The forward MR findings revealed significant correlations between BMI and hypertension with LST, as well as between hypertension, SBP, and DBP with MVPA (Table S6). A 1-standard deviation increase in LST was found to be associated with a significant increase in BMI of 0.18 kg/m² (95% CI, 1.13–1.23; P = 7.96 e-14), as well as a substantial 27.9% increase in the risk of hypertension (95% CI, 1.20–1.36; P = 7.95e-15). Furthermore, engaging in MVPA was found to be associated with the 34% decrease in hypertension risk (95% CI, 0.56–0.78; P = 4.17e-07), a significant 94% decrease in SBP (95% CI, 0.002-0.20; P = 4.99e-06), and an 80% decrease in DBP (95% CI, 0.11–0.34; P = 2.62e-09). The results of the reverse MR analysis revealed a positive relationship between BMI and the genetic prediction of the likelihood of LST, while a negative relationship was observed between BMI and MVPA (Table S7). No evidence was found for directional pleiotropy, as indicated by the non-significant MR-Egger intercepts. Additionally, no relationships were found between the other mediators examined, including BF%, T2DM, FG, FI, TG, TC, HDL, LDL, PP, with LST or MVPA.

Mediating effects of mediators in the association between MVPA, LST and migraine

Finally, we utilized MVMR and mediation analyses to examine the potential impact of blood pressure variables on the relationship between LST or MVPA and migraine. The UVMR findings revealed that genetically predicted hypertension was linked to a 9% higher risk of migraine (OR, 1.09; 95%CI, 1.06–1.13), and that genetically predicted migraine risk increased by 1.8% for each 1-mm Hg increase in DBP (OR, 1.02; 95%CI, 1.01–1.03), without any evidence of directional pleiotropy. However, no significant association was observed between genetic susceptibility to SBP and migraine (Table S8). Reverse MR analysis did not find a causal association between genetically predicted migraine and blood pressure variables (Table S9). Out of the 19 candidate mediators, only two modifiable risk factors that met the screening criteria were included in the mediated MR analysis of MVPA or LST with migraine. Upon adjusting for genetic susceptibility to hypertension, the associations between both MVPA and LST and migraine were attenuated, with genetic susceptibility to hypertension mediated 4.86% and 24.81% of the effects of MVPA and LST on migraine risk, respectively. Furthermore, the genetic prediction of DBP accounted for 4.66% of the effect of MVPA to migraine (Fig. 5).

MR estimates of proportions mediated by mediators in the causal relationship between MVPA/LST and migraine. (A) Causal effects between MVPA, hypertension and migraine. (B) Causal effects between MVPA, DBP and migraine. (C) Causal effects between LST, hypertension and migraine

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Migraine is a debilitating disease that severely affects the quality of life and work ability of patients, with high rates of social morbidity and disability [61]. Thus, it is crucial to identify effective prevention strategies for migraine to enhance public health. Recent research indicates that embracing a healthy lifestyle may diminish the likelihood of experiencing migraine [7]. Nonetheless, given that the available evidence primarily stems from observational studies, the causality of the association between lifestyle and migraines remains uncertain. Consequently, while advising against unfavorable lifestyles may prove advantageous for overall health, its specific impact on migraines remains inconclusive. We conducted bidirectional univariable and multivariable MR analyses using extensive genome-wide association discovery set and replication set datasets to exam potential causal associations between lifestyle, metabolic traits, and the likelihood of developing migraine. Our findings revealed that engaging in MVPA and coffee consumption were casually linked to a reduced risk of migraine. Conversely, factors such as LST, insomnia, depression, neuroticism, and SESA were identified as potential detrimental contributors to migraine susceptibility. There was evidence to suggest that migraine could alter sleep patterns to favor morning chronotypes and decrease alcohol consumption. Furthermore, a reciprocal causal relationship between migraine and insomnia was observed. Our study utilizing MR provided novel evidence for the causal connection between MVPA and LST on migraine, even after accounting for other aspects of lifestyle. Intriguingly, the enduring causal impact of other lifestyle factors on migraine was not evident after adjusting for confounding variables, suggesting that their effects on migraine is largely influenced by additional lifestyle factors.

The term MVPA in this study includes both aerobic exercise and strength training. Several clinical trials have confirmed the efficacy of exercise interventions for the treatment of migraineur [62, 63]. Whether it is aerobic exercise (high-intensity aerobic, moderate-intensity aerobic), strength training, or even multimodal exercise training, it is effective in reducing migraine burden [64, 65]. The impact of exercise on the clinical progression of migraine has been explored through various explanatory mechanisms. On the one hand, studies have shown that exercise reduces pain perception by activating the endogenous cannabinoid system and the endogenous opioid system [66]. Concurrently, exercise can also increase the release of various neurotrophic factors, including brain-derived neurotrophic factor (BDNF), insulin-like growth factor (IGF-1), and vascular endothelial growth factor (VEGF), which promote neuronal plasticity and angiogenesis, as well as improve cerebral blood flow and perfusion [64, 67]. However, the above mechanisms remain speculative. Our results revealed that MVPA exerted a protective influence on migraine risk by mitigating the likelihood of developing hypertension. Persistent hypertension leads to fibrosis of the blood vessel wall and damage to the vascular endothelium. Several studies have demonstrated that moderate- to high-intensity physical training has a beneficial effect on vascular endothelial function [68, 69]. Meanwhile, the cross-trait correlation analyses have unveiled potential common biological mechanisms between migraine and blood pressure regulation, involving vascular development, endothelial function, and neurogenic inflammation [70]. This suggests that vascular endothelial function may play a critically important role in the triad between exercise, hypertension, and migraine. Specifically, during exercise, increased blood flow shear stress stimulates endothelial cells and promotes the upregulation of endothelial nitric oxide synthase (eNOS) and VEGF expression [71]. These changes contribute to the enhancement of endothelium-dependent vasodilatation while inducing neovascularization, thereby improving systemic vascular endothelial function [68]. This positive modulation of endothelial function contributes to the eventual reduction of blood pressure levels. Conversely, sustained hypertension can additionally impair vascular endothelial function, resulting in a reduction in endothelium-dependent vasodilation, which in turn exacerbates vascular wall fibrosis and inflammation [72]. Endothelial dysfunction-induced vasoconstriction, microcirculatory disorders, and neurogenic inflammation may represent a pivotal mechanism in the pathogenesis of migraine attacks [73]. Engaging in MVPA during leisure time has been demonstrated to reduce the burden of migraine headaches when compared to the effects of physical activity undertaken for commuting or work [8]. As a lifestyle-based intervention, regular exercise has been demonstrated to not only reduce the frequency of migraine attacks but also to exert a beneficial effect on blood pressure control.

The amount of research on the relationship between screen time and headache is remarkably small, but the existing studies have indicated that in healthy children, adolescents, and young adults, headaches are more prevalent with increased screen time [74, 75]. This is consistent with our findings that recreational screen time increases the risk of migraine after controlling for other lifestyles. Two potential hypotheses have been proposed to explain how screen time interacts with migraine pathophysiology. The first hypothesis suggests that the brightness or frequency of light in the screen band may directly trigger a migraine attack. The second hypothesis proposes that increased screen time exposure may lower the threshold for migraine cascade and then be induced by other factors [76]. Studies have shown that increased screen time raises body fat levels and the risk of developing metabolic syndrome [77, 78], including some of the metabolic triggering factors that result in migraine attacks, such as insulin resistance, high blood pressure, and dyslipidemia [79, 80]. However, our study did not find an association between lipid and glucose metabolism and genetic susceptibility to migraine. We revealed that LST increases the risk of developing hypertension, which in turn increases susceptibility to migraine. Previous studies have indicated that prolonged television viewing was associated with higher SBP and DBP, whereas increased physical activity was primarily associated with lower DBP [81]. Consequently, interventions aimed at reducing blood pressure levels among individuals who are physically inactive or spend prolonged time in front of screens may effectively diminish the occurrence of migraine.

Surprisingly, in our study, certain mediators supported by observational studies performed no mediating role in the relationship between lifestyle to migraine [82, 83]. Our TSMR findings showed a suggestive causal association between some indices of glucose and lipid metabolism with LST or MVPA. Specifically, LST showed a potential causal association with triglycerides, LDL, and fasting insulin, while MVPA showed a potential causal association with HDL and 25(OH)D. Additionally, there was bidirectional causality existed between genetically predicted BMI and LST, hence, it was excluded from our mediation analyses. Significant causal links were discovered between MVPA and type 2 diabetes, but not between type 2 diabetes and migraine, suggesting that the significant associations observed in observational studies may be partially influenced by residual confounders.

Our research provides a comprehensive analysis of the causal connections between different lifestyles and migraines. Unlike prior MR studies that solely investigated the relationships between a singular lifestyle factor and migraine, we employed MVMR analysis to independently evaluate the effects of each variable and ascertain the causal mediators that underlie their respective pathways. Our study on migraine utilized two GWAS data sets. The FinnGen study was chosen for its minimal overlap with exposure or mediator GWAS, thereby minimizing false-positive results. Additionally, the meta dataset of GWAS from Choquet et al. was employed to improve the statistical power for replicating and validating the findings of the FinnGen study, given its substantial sample size. The IVW estimates showed consistency with the results obtained from multiple sensitivity analyses. Moreover, our study rigorously established screening criteria for mediators to mitigate the influence of reverse causation between variables, thus providing compelling evidence to construct explanatory mediation effect models.

There are also some limitations to consider. First, while we concentrated on the most prevalent and modifiable metabolic risk factors as potential mediators to enhance clinical practice, the mediating function linking lifestyle and migraine remained incompletely explicated in this investigation. It is worth noting that the MVPA in this study did not completely differentiate between the two different types of aerobic exercise and strength training, which may affect the analysis and interpretation of the effects of specific exercise interventions. Future studies should further refine the measures of exercise, as well as explore the individual effects of aerobic exercise and strength training and their interactions, to provide more targeted exercise treatment programs. Furthermore, there may be interdependent mediating effects between different aspects of lifestyle. For example, prolonged LST is usually accompanied by negative mental health and behavioral changes that could potentially increase the likelihood of depression or the impact of coffee intake, while MVPA has a contrasting effect on both. It is challenging to distinguish between mediating and multiple effects in our MVMR outcomes. Therefore, these findings could also partially clarify the augmented risk of migraine. Secondly, the limitations of this study need to be considered as it only included participants of European ancestry, therefore caution should be taken before generalizing the findings to other ethnic groups with diverse lifestyles and cultural backgrounds. Third, an individual’s likelihood to report a phenotype to a physician can influence many phenotypes. For example, some of the migraine cases in this study were self-reported, which implies that more research is necessary to establish the generalizability of our findings to a broader spectrum of migraine symptoms.

In conclusion, the present MR study offers genetic evidence supporting the detrimental impact of lifestyle LST on migraine and the beneficial impact of MVPA on migraine. Additionally, the study identifies hypertension as a mediator in the relationship between LST, MVPA, and migraine. The study provides causal evidence for the understanding of migraine etiology and offers prevention and intervention targets to reduce migraine prevalence and related disease burden.

No datasets were generated or analysed during the current study.

GWAS:

Genome-Wide Association Study

UVMR:

Univariable Mendelian Randomization

MVMR:

Multivariable Mendelian Randomization

SD:

Standard Deviation

LST:

Leisure Screen Time

MVPA:

Moderate or/and Vigorous Physical Activity

DBP:

Diastolic Blood Pressure

CSD:

Cortical Spreading Depression

CGRP:

Calcitonin-Related Peptide

MR:

Mendelian Randomization

MVMR:

Multivariate Mendelian Randomization

TSMR:

Two-Sample Mendelian Randomization

PA:

Physical Activity

SDKP:

Sleep Disorder Knowledge Portal

GSCAN:

GWAS & Alcohol and Nicotine Sequencing Consortium

UKB:

UK Biobank

SESA:

Sensitivity to Environmental Stress and Adversity

EPQ-RS:

Eysenck Personality Questionnaire-Revised Short Form

GPC:

Genetics of Personality Consortium

PGC:

Psychiatric Genetics Consortium

NEO-FFI:

NEO Five-Factor Personality Inventory

ICD-9:

The International Classification of Diseases-9th classification

ICD-10:

International Classification of Diseases-10th

DSM:

The Diagnostic and Statistical Manual of Mental Disorders

BFI:

Big Five Inventory

BMI:

Body Mass Index

BF%:

Body Fat Percentage

TG:

Total Triglyceride

TC:

Total Cholesterol

HDL-C:

High-Density Lipoprotein – Cholesterol

LDL-C:

Low-Density Lipoprotein – Cholesterol

SBP:

Systolic Blood Pressure

PP:

Pulse Pressure

PCs:

Principal Components

GERA:

Genetic Epidemiology Research in Adult Health and Aging

IHGC:

International Headache Genetics Consortium

SNPs:

Single Nucleotide Polymorphisms

IVs:

Instrumental Variables

LD:

Linkage Disequilibrium

IVW:

Inverse Variance Weighted

MR-PRESSO:

MR-Pleiotropy RESidual Sum and Outlier

BDNF:

Brain-Derived Neurotrophic Factor

IGF-1:

Insulin-like Growth Factor-1

VEGF:

Vascular Endothelial Growth Factor

eNOS:

endothelial Nitric Oxide Synthase

We acknowledge the participants and investigators of the SDKP, GSCAN, GPC, PGC, GERA, IHGC, FinnGen, and UKB studies.

This work was supported by Grants from the National Natural Science Foundation of China (81971055, 81471133, 82101292), the Interdisciplinary Innovative Talents Foundation from Renmin Hospital of Wuhan University (JCRCYG-2022-006), and the Medical Education Research Project of Wuhan University (2024YB08).

Authors and Affiliations

1. Department of Neurology, Renmin Hospital of Wuhan University, Wuhan, Hubei, 430060, China

   Quan Gan, Lily Zhang, Yanjie Zhou, Lintao Wang, Zhengming Shan, Jingjing Liang, Shanghua Fan, Songqing Pan & Zheman Xiao

2. Department of Traditional Chinese Medicine, Renmin Hospital of Wuhan University, Wuhan, Hubei, 430060, China

   Enfeng Song

3. Department of Neurology, Dongzhimen Hospital, Beijing University of Chinese Medicine, Beijing, 100700, China

   Kegang Cao

4. Department of Encephalopathy in Traditional Chinese Medicine, Renmin Hospital of Wuhan University, Wuhan, Hubei, 430060, China

   Zheman Xiao

Contributions

QG performed data acquisition, analysis, drawing, article writing and revision. EFS and LLZ revised the manuscript. YJZ, LTW, and ZMS drawing. JJL, SHF, and SQP collected data. KGC and ZMX contributed to the conception and design of the study. All authors reviewed the manuscript.

Corresponding authors

Correspondence to Kegang Cao or Zheman Xiao.

Ethics approval and consent to participate

Not applicable.

Consent for publication

All authors contributed to the article and approved the submitted version.

Competing interests

The authors declare no competing interests.

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