- Review article
- Open access
- Published:
Is there a causal relationship between stress and migraine? Current evidence and implications for management
The Journal of Headache and Pain volume 22, Article number: 155 (2021)
Abstract
Background
The purpose of this narrative review is to examine the literature investigating a causal relationship between stress and migraine and evaluate its implications for managing migraine.
Methods
PubMed, PsycINFO and CINAHL were searched from 1988 to August 2021, identifying 2223 records evaluating the relationship between stress and migraine. Records were systematically screened. All potentially relevant records were thematically categorized into six mechanistic groups. Within each group the most recent reports providing new insights were cited.
Results
First, studies have demonstrated an association of uncertain causality between high stress loads from stressful life events, daily hassles or other sources, and the incidence of new-onset migraine. Second, major stressful life events seem to precede the transformation from episodic to chronic migraine. Third, there is some evidence for changes in levels of stress as a risk factor for migraine attacks. Research also suggests there may be a reversed causality or that stress-trigger patterns are too individually heterogeneous for any generalized causality. Fourth, migraine symptom burden seems to increase in a setting of stress, partially driven by psychiatric comorbidity. Fifth, stress may induce sensitization and altered cortical excitability, partially explaining attack triggering, development of chronic migraine, and increased symptom burden including interictal symptom burden such as allodynia, photophobia or anxiety. Finally, behavioral interventions and forecasting models including stress variables seem to be useful in managing migraine.
Conclusion
The exact causal relationships in which stress causes incidence, chronification, migraine attacks, or increased burden of migraine remains unclear. Several individuals benefit from stress-oriented therapies, and such therapies should be offered as an adjuvant to conventional treatment and to those with a preference. Further understanding the relationship between stress, migraine and effective therapeutic options is likely to be improved by characterizing individual patterns of stress and migraine, and may in turn improve therapeutics.
Background
The definition of stress has varied through the ages and literature, but generally speaking, stress can be defined as an organism’s perception of and response to a perceived stressor. This includes how the body responds, both physiologically and psychosocially, to perceived threats, challenges, or physical or psychological barriers.
The physiological stress response involves the autonomic nervous system, especially the hypothalamic-pituitary-adrenal (HPA) axis, and several other structures which undergo neurobiological changes [1, 2]. Any stressor, both mental and/or physical, can elicit the physiological response resulting in pronounced sympathetic outflow and release of stress hormones such as epinephrine, norepinephrine, and cortisol. Increased activity of these stress systems induces behavioral, cardiovascular, endocrine, and metabolic cascades that enable the individual to fight, flee or freeze, to cope with the stress. The physiological stress response may be quantified in various ways, for example measuring the effector hormones (e.g., cortisol), or measuring the effect they produce (e.g., an increase in heart rate or blood pressure).
In addition to the physiological stress response, stress perception has a subjective side, i.e., how an individual perceives, reacts to, and copes with stress. This is described in the transactional stress model by Lazarus [3] which explains perceived stress as resulting in part from the “imbalance between demands and resources”, or a response where “pressure exceeds one’s perceived ability to cope.” Within this transactional model, stress ocurrs when perceived demands exceed perceived resources [4]. Perceived stress may be quantified using various patient reported outcome measures. A primary focus of cognitive behavioral therapy for migraine and related behavioral therapies involves teaching participants to first recognize the physiological and cognitive stress response, then observe their immediate automatic thoughts and then reappraise or reframe, replacing dysfunctional thoughts with more realistic thoughts [5]. Biofeedback and relaxation therapies also teach participants to recognize physiological and psychological activation and then engage in activities intended to reduce sympathetic activation and engage in mental and physical states of calm and well being [6].
The neuronal and hormonal changes associated with stress and the perceived psychological stress response may have multiple relationship to migraine. Stress may provoke the new-onset of migraine (incidence), it may act as a risk factor for migraine attacks, it may amplify migraine disability and/or burden; and it may contribute to the development of chronic migraine; Moreover, migraine attacks themselves and the resulting disability and impact might be a stressor in itself resulting in a vicious feedback cycle [7]. These relationships are exemplified in a common patient belief that “stress causes migraine.” [8] But, does the conventional belief hold? The aim of this article is to review currently available evidence and hypotheses for a causal relationship between stress and migraine and discuss important implications for management.
Methods
To identify relevant literature for this narrative review, PubMed, PsycINFO and CINAHL databases were searched for available records from 1 January 1988—to include all relevant records after the inception of the International Classification of Headache Disorders 1st edition—and last updated on 10 August 2021. The following search term was used across all three databases: (“stress” AND “migraine”), identifying a total of 3124 records. 743 duplicates were identified automatically in the citation manager EndNote 20 (Clarivate, US). Another 158 duplicates were manually identified. The remaining 2223 records were screened based on title and abstract, identifying 208 records that were deemed relevant to appraise the casual relationship between stress and migraine or its implications for management. These 208 records were reviewed and thematically categorized [9]. Records not available online, not available in English, and commentaries were excluded. From the thematic categorization six mechanistic groups crystallized:
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1.
Is stress a predisposing factor for migraine disease onset (incidence)?
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2.
Is stress a predisposing factor for migraine chronification (new onset of chronic migraine)?
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3.
Is stress a risk factor for migraine attacks?
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4.
Is migraine-related disability and/or burden increased by stress?
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5.
What are the physiological correlates of stress and migraine?
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6.
What are the implications of stress for migraine management?
Figure 1 is a PRISMA flowchart depicting the record selection process, and reasons for exclusion. 146 of the 208 identified records were excluded based upon the exclusion criteria. A total of 62 records from the electronic literature search are cited in this paper. Within each of the six themes, we cite records that provide insights into the causal relationship between stress and migraine, and attempt to use the most recently dated records.
Results
Evidence for a causal relationship between stress and migraine
Stress as a factor in new-onset migraine (incidence)
Stress, in a variety of fashions, seems to be associated with the new-onset of migraine. In a longitudinal analysis of almost 20,000 female employees with no history of migraine at study entry, no association between job strain and migraine was found at follow-up [10]. However, high effort-reward imbalance was associated with a slightly increased risk of migraine at follow-up. The proportion of new migraine cases attributable to high effort-reward imbalance was 6.2%. The association of high effort-reward imbalance to new-onset migraine was again confirmed in a 2020 prospective occupational health study [11]. Similarly, a study from 2019 investigated the association between early-life stressors and new-onset adolescent headache [12]. There was an influence of early life family-level factors on the prospective risk of developing migraine moderated through symptoms of depression and anxiety. Moreover, adverse childhood experiences have been demonstrated to have a stable association with an adult diagnosis of migraine [13,14,15], and the association seems to be mediated through neuroticism [16]. Pain as a neonate, defined as prescribed analgesics during stays at the neonatal intensive care unit, has also shown an association with an earlier onset of migraine [17]. All of these studies suggest that unfavorable allostatic load, contextualized as stress, may contribute to the new onset of migraine. Nevertheless, the associations are moderate, and a direct causal link to stress remains unclear.
Stress as a factor in migraine chronification or the new onset of chronic migraine
In a comprehensive systematic review from 2019, risk factors for the new onset of chronic migraine were assessed [18]. The main risk factors for chronification were increased headache day frequency, depression, and certain categories of acute medication overuse. However, major stressful life events were also identified as a risk factor. One of the studies included in the review reported more major stressful life events in the year before or the same year as the onset of chronic daily headache [19]. Similar results were also found in a study by De Benedittis and colleagues, where chronic primary headache patients reported significantly more stressful life events with negative impact in the year before chronic headache onset compared to headache-free controls [20]. More recently, a study investigating the effects of exposure to the 2011 Utøya adolescent summer camp mass shootings found an increased risk of persistent weekly and daily migraine in the months following the terror [21]. Together, this indicates that major stressful events can be associated with the new onset of chronic migraine, although it is unclear if such events directly cause the progression.
Stress as a migraine attack risk factor
Stress is perhaps the most commonly self-reported migraine attack trigger or risk factor [22, 23]. A prospective study of more than twelve hundred consecutive migraine patients found that 76% of patients reported perceived identifiable “triggers”, with stress being the most commonly reported (80%) [24]. Even though stress is reported as the most common self-identified trigger, the literature has produced conflicting findings as to whether stress (both static levels or change in stress) actually causes migraine attacks. One of the main problems is the difficulty of genuinely establishing the causal attack “triggers” [25]. Simply asking patients to recall their usual headache triggers/risk factors or premonitory features retrospectively is limited by recall bias and false attribution. Because different variations and combination of factors may raise the risk of a migraine attack, and these factors have different potencies as risks for a migraine attack both on an interindividual and intraindividual level, we will use the term risk factor rather than trigger to connotate the increased probably of a subsequent attack. Several prospective studies using daily paper or e-diaries report a temporal relationship between stress and migraine that is significant for headache days vs. non-headache days [26,27,28,29,30]. These studies indeed reduce the influence of recall bias and false attribution—yet, fully resolving the temporal association, and influence of static or changing stress levels, is complex.
Let us ponder an example put forth by Lipton and colleagues: [25] Consider a patient that eats chocolate preictally. If chocolate consumption is a precipitant to the attack, then chocolate may be a risk factor. However, if the patient eats chocolate because she or he experiences cravings, the chocolate consumption could be a manifestation of the premonitory migraine phase (Fig. 2a). To distinguish these possibilities, a randomized trial with chocolate and placebo is required. In such a trial, one could administer chocolate or placebo to patients at a selected time and see if there is an increased probability of a migraine attack in the verum group (the group that received chocolate), which would support the notion of chocolate as a risk factor. Alternatively, patients could be randomized to chocolate or placebo when they crave it. If both the verum and the placebo groups have high but equal probabilities of headache, craving chocolate is a premonitory feature. If the verum group has a higher rate of migraine attacks, this suggests chocolate is a risk factor. Remarkably, variants of these studies have been conducted with various perceived triggers or risk factors including both chocolate and stress. In one study, a group of 27 patients with self-perceived triggers was exposed to their personal risk factors (flickering lights or strenuous exercise), and only 3 of 27 patients had a migraine attack after exposure, thus disfavoring the notion of causal risk factors [31]. Along the same lines, a 2021 study demonstrated that there was good agreement for reporting stress as an attack risk factor and experimental nitroglycerin-triggered premonitory mood change, favoring the notion of risk factors a manifestation of the premonitorium [32].
Turner and colleagues conducted a study to explore the conditions necessary to assign causal status to headache risk factors [33]. Based on the Neymar-Rubin causal effects model, the researchers identified three basic assumptions that need to be met to determine causality in headache risk factors: (1) constancy of the individual; (2) constancy of the risk factor effect; and (3) constancy of the risk factor presentation. Houle and Turner attempted to explore the assumption of constancy in risk factor presentation in a real-world natural experiment [34]. They concluded that it is challenging to find days with similar patterns of headache risk factors when relying on natural reliability. This means that the assumption of constancy in risk factors, and thereby causal inference, is likely violated in natural experiments. Thus, the validity of personal uncovering of risk factors is questioned.
A study from 2014 by Lipton and colleagues found that the decline of perceived stress was associated with the onset of migraine attacks. The study reported that static stress levels were not associated with subsequent migraine attacks, but decline in stress from one evening to the next was associated with increased migraine attack onset over the subsequent 6, 12, and 18 hours [26]. The authors offer several explanations as to why a reduction in stress was observed prior to migraine attacks. The findings may be explained by an unmeasured mediator, such as missed medication, skipped meals, or disturbed sleep, that arise as a consequence of stress, but may also be attributed to a reversed causality. During the premonitory phase, there may be a period of increased vulnerability to stress followed by a phase of decreased vulnerability to stress. This is akin to the example proposed earlier with chocolate, i.e., increased stress is a manifestation of an impending attack (Fig. 2b). To date, data are mixed on the “let down pattern” of reductions in stress triggering migraine attacks. Studies both support [35, 36] and disclaim the support of “weekend”, “honeymoon” and “let-down” migraines [28, 37].
However, two recent prospective diary studies adds additional insights [27, 38]. In the first study, a digital health platform was used to prospectively capture stress and headache data and evaluate if the patterns of perceived stress varied through the migraine cycle [38]. Perceived stress was rated once daily on a 0–10 scale. Days were categorized into pre-migraine days, migraine days, post-migraine days and interictal days. Using a cluster analysis, the researchers found three dominant patterns of perceived stress across the migraine cycle: “let down” pattern; “flat pattern”; and “stress as a trigger/symptom” pattern [38]. The majority of headache episodes were assigned to cluster 2 (flat). Approximately one-quarter were assigned to cluster 3 (trigger), and the rest was assigned to cluster 1 (let down). Interestingly, very few patients had more than 90% of their headache episodes in one cluster. No patients had > 90% of episodes in cluster 1 or 3, indicating that there were no exclusively “let-down” or “trigger” pattern patients. The second study suggests that changes in several key variables relative to an individual’s typical habits had the most power as risk factors [27]. Information was collected on daily levels of several commonly perceived attack risk factors including stress (Daily Stress Inventory), number of caffeinated and alcoholic beverages, and mood disturbances. The probability of observing variations in each trigger was used to estimate the “surprisal” of experiencing each trigger. When expressed as units of “surprisal”, the highest odds ratio for an attack was found for stress (1.30; 95% CI 1.14 to 1.46). Together, this illustrates a vast heterogeneity in the manifestation of stress as a migraine attack risk factor, not only between individuals, but also from attack to attack within individuals—hampering the establishment of any simple or generalized causal relationship between stress as a risk factor and migraine.
Migraine-related disability, burden, impact and frequency in relation to stress
Even though there is no definite evidence that stress incites the incidence or progression of migraine, or directly triggers migraine attacks, there is a general understanding of a worsening of migraine burden in the setting of stress. A large prospective study with more than 5000 participants found that stress intensity was associated with headaches for individuals with tension-type headache, migraine and, coexisting tension-type headache and migraine [39]. They found a 4.3% increase in headache days for each 10-point stress increase on a 0–100 visual analog scale. Correlation analyses were adjusted for sex, age, abortive drug consumption, drinking, smoking, body mass index, and education, meaning that higher levels of stress are associated with a higher migraine symptom burden. Similarly, several observational studies demonstrate an association between stress and migraine symptom burden. Higher migraine frequency is associated with higher levels of perceived stress [40]. High job strain, resulting in lack of time for personal care and leisure, is associated with an increased odds of migraine [41, 42]. Twenty-four hour shifts among medical residents increases migraine-related disability [43]. Among women, high levels of stress contribute to and increase the negative effects obesity has on migraine [44]. Stress facilitates the negative consequences poor sleep has on migraine occurrence [45, 46]. Stress is associated with poorer response to acute treatment in chronic migraine patients [47]. Interestingly, minor life events, or daily hassles, seems to be more associated with migraine-related disability than major life events [48].
On the other hand, a case-control study from 2017 with 227 patients found that episodic migraine patients had no more perceived stress than controls after adjusting for depression and anxiety [49]. This indicates that migraine itself does not necessarily result in perceived stress. Remarkably, the chronic migraine patients had significantly more stress after adjusting for depression and anxiety, suggesting that chronic migraine appears to be a specific factor for perceived stress. If the total migraine symptom burden affects levels of perceived stress, one should consider the option that the migraine—in itself—is an essential factor driving stress. In fact, several studies have shown that individuals with severe headaches appraise events more negatively, which may contribute to increased stress [50]. This plausible collateral causality between stress and migraine means that stress indeed is a part of a vicious reinforcing feedback cycle involving stress and migraine [51].
Finally, it is interesting to mention changes in migraine symptom burden during the SARS-CoV-2 lockdowns, viewed in light of the stress caused by the COVID-19 pandemic and isolation. Several recent studies have produced conflicting findings [52]. As an example, one survey from Italy found an overall reduction in headache frequency and intensity during the quarantine compared to pre-quarantine [53]. On the other hand, a study from Spain found worsening of the usual pain during lockdown [54]. It may be that the perception of the pandemic of the individual combined with individual circumstances, resources and demands may lead to profoundly different impacts for different individuals. Future reports summarizing these findings will likely provide a better understanding of how global pandemics, cautionary measures such as lockdowns and mask mandates and their repercussions affects the migraine population.
Physiological measures of stress and migraine
The studies mentioned above have chiefly assessed the relationship between perceived stress and migraine—but how does this correlate to physiological measures? Herein we will briefly review the physiological changes corresponding to stress and migraine.
Stress induces a series of neurophysiological changes that may aid in understanding the stress-related triggering of migraine attacks. In a laboratory study of knock-in S218L familial hemiplegic migraine mutation mice, relief after chronic stress led to a lower cortical spreading depression threshold [55]. This model may, in part, explain why some patients experience “let down” migraine. Another laboratory study found that patients who did not report stress as a risk factor displayed deficient habituation to visual evoked potentials, suggesting that stress-sensitive patients lack this altered cortical excitability threshold [56]. Moreover, recall the idea that migraine risk factors may be a case of reversed causality, e.g., identifying chocolate as a risk factor may be the manifestation of a premonitory craving. Neuroimaging studies demonstrate that stress may be a manifestation of premonitory activation of pain processing regions, including the hippocampus [57, 58], indicating that perceived stress is a manifestation of the impending attack.
Next, stress leads to central sensitization and hyperalgesia, which may concomitantly contribute to the debilitating characteristics of the migraine attack. Animal models show that both acute and chronic stress may enhance nociceptive responses [59]. Both peripheral and central sensitization seem to be important pathophysiological factors, contributing to many of the clinical characteristics of migraine including throbbing pain, motion sensitivity, hyperalgesia and allodynia [60] which may be exaggerated by stress. A recent study by Avona and colleagues [61] demonstrated that stress induced in mice produced a migraine-like state of hyperalgesia with increased response to the artificial migraine trigger sodium nitroprusside and subsequent blocking by calcitonin gene related peptide monoclonal antibodies. Similarly, allodynia exerts some effect on migraine-related disability, independent of the pain itself, and the relationship is partially driven by stress [62]. Moreover, emerging research has elucidated the role of NMDA receptors and microRNA in stress-related conditions such as major depressive disorder. Accumulated research suggests that chronic stress leads to an upregulation of NMDA receptor activation [2]. Glutamatergic medications acting as NMDA antagonists have shown an antidepressant and stabilizing effect in several brain circuits in animal models. Likewise, at the molecular level, dysregulation of microRNA seems to play a role in both acute and chronic stress and neuropsychiatric and affective disorders associated with stress [63]. It is conceivable that similar mechanisms apply to migraine in which stress seems to play a role.
Finally, the autonomic nervous system and HPA axis is worth mentioning. A body of research has traditionally focused on cardiovascular alterations among individuals with migraine [64], but there is now a trend toward the interactions of migraine and stress on the autonomic nervous system and HPA axis function. Yet, there are conflicting findings. Both lower and higher baseline sympathetic tone have been demonstrated in migraine patients [65,66,67]. Migraine patients also display significantly higher pain responses and sympathetic activation to stress than controls [68, 69]. In total, there seems to be a sympathetic impairment interictally with increased sympathetic responsiveness during the migraine attack [70]. One possible explanation of this phenomenon might be that the constant stress by repeated headaches results in a sympathetic downregulation with a paradoxical hyperactivation during subsequent headaches. Studies of HPA activation have also produced conflicting findings. A systematic review found conflicting findings on the levels of corticotropic hormones in migraine patients, and the authors concluded that corticotropic hormones, at least as a direct causal link, seem to be irrelevant in the pathophysiology of migraine [71].
Implications for management
Behavioral interventions
Behavioral treatments with evidence for migraine prevention include stress management, relaxation therapy, cognitive behavioral therapy, biofeedback, mindfulness-based therapies and acceptance and commitment therapy [72,73,74,75,76]. The US headache consortium has given relaxation therapy, cognitive behavioral therapy, and biofeedback Grade A evidence for migraine prevention [77]. Most, if not all, of these behavioral treatments include improvements in stress management as well as adjusting expectations and perceptions as therapeutic targets. However, in many of the studies of behavioral interventions, it has been illustrated that the reduction in headache frequency is not a function of the intended beneficial target organ response [51, 78,79,80]. For example, in biofeedback training, improvement of circulation through hand warming does not necessarily translate to improvements in migraine outcomes. Thus, improvement in migraine and headache outcomes may be a consequence of non-specific effects, self-efficacy and the learned ability to cope with stressors combined with benefits of relaxation training to the nervous system—rather than stress reduction alone [80]. Moreover, trials of behavioral interventions have methodological challenges when using traditional pharmacological clinical trial standards, such as managing blinding and creating ideal control groups, which further hamper establishing causal effects. Even though the exact causal mechanisms of how stress management leads to improved migraine symptomatology are unclear, stress is a negative prognostic factor for migraine management and quality of life, clinical trial data and real-world experience show that many individuals have preventive benefits from established therapies, and some individuals prefer behavioral interventions. Therefore attention to individual management of stress is warranted and important [72, 77, 81].
A long-standing tradition in migraine management has been to advise patients to avoid headache risk factors, including increased stress. This strategy is traditionally implemented alongside general lifestyle measures such as good sleep hygiene, routine meal schedules, and regular exercise. Even though specific programs for identifying risk factors have been developed [82], some researchers suggest that complete avoidance of risk factors may have detrimental effects, in part driven by trigger sensitization [83, 84]. From this, the new behavioral management strategy termed “Learning to Cope with Triggers” emerged [85]. Therapist and patient would identify triggers and decide what strategy to use with them. Three main strategies were employed: exposure to find out if the trigger resulted in a migraine attack; exposure to achieve desensitization/habituation; and exposure to enable practicing coping skills. A randomized controlled trial with 127 participants found that “Learning to Cope with Triggers” was superior to both waiting-list and avoidance for the outcomes headache frequency and abortive drug consumption [85]. Of note, the study merged both migraine and tension-type headache.
One promising behavioral intervention that directly targets stress management and perception is mindfulness-based stress reduction (MBSR). A meta-analysis from 2018, including five small sample studies of migraine and tension-type headache, found no benefit for MBSR in treating chronic headache [86]. In more recent randomized controlled trials, MBSR has been found to be superior to simple stress management with regards to headache frequency reduction [87]; superior to headache education with regards to reduction in disability and improvements in quality of life [88]; and superior to progressive muscle relaxation with regards to adaptive coping strategies, self-efficacy and reduced pain perception [89]. Of note, the two latter studies failed the primary clinical outcome of improvement in migraine frequency. In addition to the MBSR studies mentioned above, mindfulness-based cognitive therapy for migraine has demonstrated efficacy to reduce headache-related disability and attack level disability, and is another promising emerging treatment option [74]. Overall, there is no unambiguous evidence that mindfulness-based therapies is better than traditional guideline recommended behavioral interventions for migraine prevention and management in terms of headache day reduction; however, it is a promising emerging treatment for addressing migraine-related disability as well as other important outcomes.
Pharmacological interventions
Although pharmacotherapy alone is improbable to be paramount in managing migraine in a context of stress, behavioral interventions can be combined with pharmacotherapy to enhance the effects. Combining drugs and behavioral treatment seems to be more effective than betablockers alone or behavioral treatment alone [90]. In a four-armed randomized controlled trial, 232 migraine patients were randomized to placebo, betablockers, behavioral treatment and placebo or behavioral treatment and betablocker [90]. The combination of betablockers and behavioral treatments improved treatment outcomes and outcomes of acute treatment. The same benefits of combining drugs and behavioral treatments has been observed in a trial children and adolescents, in which amitriptyline plus cognitive behavioral therapy was superior to amitriptyline alone [91]. The study did not evaluate cognitive behavioral therapy alone, or placebo alone, making it unclear if it’s the behavioral therapy or the medications that is most efficient in the pediatric population.
Predictive models
A promising and emerging topic of research is the use of risk factor and premonitory features, including stress, in predictive models and forecasting models [92]. One very promising study by Houle and colleagues [93] looked into predicting headaches based on self-reported perceived stress. To the best of our knowledge, this is the first study investigating if self-reported stress may be used to forecast headaches. In the study, a low-dimensional model using today’s level of stress combined with the presence or absence of headache could predict headache tomorrow with an out-of-sample area under the curve precision of 0.65. Such predictive models can likely further improve the management of migraine for several reasons. Reducing the unpredictability of attacks might, in turn, lead to breaking the vicious circle of stress-migraine-stress. Predicting attacks increases self-efficacy among patients and allows for tailored stress management and management of factors that indeed predict attacks. Forecasting enables so-called preemptive treatment (or mini-prophylaxis) in which medication is focused on days with an increased probability of attacks. However, preemptive drug treatment based on forecasting models should only be utilized if future predictive models are highly accurate due to the increased risk of medication overuse in patients with higher frequency migraine. Another recent study examined changes in several potential risk factors to forecast migraine attacks [94]. In the study, a decrease in caffeine consumption, higher self-predicted probability of headache, and a higher level of stress were observed within the two days preceding a migraine attack. However, the multivariable model predicted migraine risk only slightly better than chance with a within-person C-statistic of 0.56. Both studies emphasize that the use of an electronic diary to capture data is effective but results in missed data and measurement errors which may compromise the validity and precision of the forecasting models. Still, we are likely far from the plausible biological roof for forecasting migraine attacks. If there are underlying neurobiological differences that explain the vast heterogeneity of observed risk factors and premonitory factors, including stress, identifying these, and incorporating them into predictive models could result in high forecasting accuracy.
Conclusion
Undoubtedly, there is a relationship between stress and migraine. The exact causal relationships in which stress causes incidence, chronification, migraine attacks, or increased burden of migraine remains unclear. Likely, the underlying neurobiology and pathophysiology is too complex, and the phenotype is too finely granulated to enable a generalized causal framework of migraine pathophysiology and treatment based on unitary stress biomarkers. However, actively engaging in how stress patterns unfold in each migraine patient could help the clinician in understanding why some patients transform to chronic migraine, how stress contributes as an attack risk factor, how stress may increase migraine symptom burden, and how to choose optimal therapy. Several individuals seem to benefit from stress management-oriented behavioral therapies, and such therapies should be offered as a adjuvant to pharmacological treatment or to those with a preference. Future studies should characterize large migraine cohorts to identify and exploit individual differences in treatment responsiveness of stress management-oriented therapies; and utilize all available data including triggers/ risk factors, premonitory features, and detailed facets of the physiological and psychosocial stress response, to create high-validity forecasting models.
Availability of data and materials
The literature database is available upon reasonable request to the authors.
Abbreviations
- HPA:
-
Hypothalamic-pituitary-adrenal
- MBSR:
-
Mindfulness-based stress reduction
References
Charmandari E, Tsigos C, Chrousos G (2005) Endocrinology of the stress response. Annu Rev Physiol 67(1):259–284. https://doi.org/10.1146/annurev.physiol.67.040403.120816
Serafini G, Pompili M, Innamorati M, Dwivedi Y, Brahmachari G, Girardi P (2013) Pharmacological properties of glutamatergic drugs targeting NMDA receptors and their application in major depression. Curr Pharm Des 19(10):1898–1922. https://doi.org/10.2174/13816128113199990293
Lazarus RS, Folkman S (1984) Stress, appraisal, and coping. New York: Springer publishing company
Steptoe A. Psychobiological processes in the etiology of disease. Oxford: Pergamon Press; 1991.
Beck AT (1979) Cognitive therapy of depression. New York: Guilford press
Pérez-Muñoz A, Buse DC, Andrasik F (2019) Behavioral interventions for migraine. Neurol Clin 37(4):789–813. https://doi.org/10.1016/j.ncl.2019.07.003
Sauro KM, Becker WJ (2009) The stress and migraine interaction. Headache 49(9):1378–1386. https://doi.org/10.1111/j.1526-4610.2009.01486.x
Wöber C, Holzhammer J, Zeitlhofer J, Wessely P, Wöber-Bingöl Ç (2006) Trigger factors of migraine and tension-type headache: experience and knowledge of the patients. J Headache Pain 7(4):188–195. https://doi.org/10.1007/s10194-006-0305-3
Thomas J, Harden A (2008) Methods for the thematic synthesis of qualitative research in systematic reviews. BMC Med Res Methodol 8(1):1–10. https://doi.org/10.1186/1471-2288-8-45
Mäki K, Vahtera J, Virtanen M, Elovainio M, Keltikangas-Järvinen L, Kivimäki M (2008) Work stress and new-onset migraine in a female employee population. Cephalalgia 28(1):18–25. https://doi.org/10.1111/j.1468-2982.2007.01462.x
Leineweber C, Eib C, Bernhard-Oettel C, Nyberg A (2020) Trajectories of effort-reward imbalance in Swedish workers: differences in demographic and work-related factors and associations with health. Work Stress 34(3):238–258. https://doi.org/10.1080/02678373.2019.1666434
Hammond NG, Orr SL, Colman I (2019) Early life stress in adolescent migraine and the mediational influence of symptoms of depression and anxiety in a Canadian cohort. Headache 59(10):1687–1699. https://doi.org/10.1111/head.13644
Fuller-Thomson E, Baker TM, Brennenstuhl S (2010) Investigating the association between childhood physical abuse and migraine. Headache 50(5):749–760. https://doi.org/10.1111/j.1526-4610.2010.01626.x
Tietjen GE, Brandes JL, Peterlin BL, Eloff A, Dafer RM, Stein MR, Drexler E, Martin VT, Hutchinson S, Aurora SK, Recober A, Herial NA, Utley C, White L, Khuder SA (2010) Childhood maltreatment and migraine (part I). Prevalence and adult revictimization: a multicenter headache clinic survey. Headache 50(1):20–31. https://doi.org/10.1111/j.1526-4610.2009.01556.x
Tietjen GE, Brandes JL, Peterlin BL, Eloff A, Dafer RM, Stein MR, Drexler E, Martin VT, Hutchinson S, Aurora SK, Recober A, Herial NA, Utley C, White L, Khuder SA (2010) Childhood maltreatment and migraine (part II). Emotional abuse as a risk factor for headache chronification. Headache 50(1):32–41. https://doi.org/10.1111/j.1526-4610.2009.01557.x
Karmakar M, Elhai JD, Amialchuk AA, Tietjen GE (2018) Do personality traits mediate the relationship between childhood abuse and migraine? An exploration of the relationships in young adults using the add health dataset. Headache 58(2):243–259. https://doi.org/10.1111/head.13206
Maneyapanda SB, Venkatasubramanian A (2005) Relationship between significant perinatal events and migraine severity. Pediatrics 116(4):e555–e558. https://doi.org/10.1542/peds.2005-0454
Buse DC, Greisman JD, Baigi K, Lipton RB (2019) Migraine progression: a systematic review. Headache 59(3):306–338. https://doi.org/10.1111/head.13459
Scher A, Stewart W, Buse D, Krantz DS, Lipton RB (2008) Major life changes before and after the onset of chronic daily headache: a population-based study. Cephalalgia 28(8):868–876. https://doi.org/10.1111/j.1468-2982.2008.01634.x
De Benedittis G, Lorenzetti A, Fieri A (1990) The role of stressful life events in the onset of chronic primary headache. Pain 40(1):65–75. https://doi.org/10.1016/0304-3959(90)91052-K
Stensland S, Zwart JA, Wentzel-Larsen T et al (2018) The headache of terror: a matched cohort study of adolescents from the Utøya and the HUNT study. Neurology 90(2):e111–e118. https://doi.org/10.1212/wnl.0000000000004805
Marmura MJ (2018) Triggers, protectors, and predictors in episodic migraine. Curr Pain Headache Rep 22(12):81. https://doi.org/10.1007/s11916-018-0734-0
Pellegrino ABW, Davis-Martin RE, Houle TT, Turner DP, Smitherman TA (2018) Perceived triggers of primary headache disorders: a meta-analysis. Cephalalgia 38(6):1188–1198. https://doi.org/10.1177/0333102417727535
Kelman L (2007) The triggers or precipitants of the acute migraine attack. Cephalalgia 27(5):394–402. https://doi.org/10.1111/j.1468-2982.2007.01303.x
Lipton RB, Pavlovic JM, Haut SR, Grosberg BM, Buse DC (2014) Methodological issues in studying trigger factors and premonitory features of migraine. Headache: J Head Face Pain 54(10):1661–1669. https://doi.org/10.1111/head.12464
Lipton RB, Buse DC, Hall CB, Tennen H, DeFreitas TA, Borkowski TM, Grosberg BM, Haut SR (2014) Reduction in perceived stress as a migraine trigger: testing the “let-down headache” hypothesis. Neurology 82(16):1395–1401. https://doi.org/10.1212/wnl.0000000000000332
Turner DP, Lebowitz AD, Chtay I, Houle TT (2019) Headache triggers as surprise. Headache 59(4):495–508. https://doi.org/10.1111/head.13507
Wöber C, Brannath W, Schmidt K, Kapitan M, Rudel E, Wessely P, Wöber-Bingöl C, PAMINA Study Group (2007) Prospective analysis of factors related to migraine attacks: the PAMINA study. Cephalalgia 27(4):304–314. https://doi.org/10.1111/j.1468-2982.2007.01279.x
Hashizume M, Yamada U, Sato A, Hayashi K, Amano Y, Makino M, Yoshiuchi K, Tsuboi K (2008) Stress and psychological factors before a migraine attack: a time-based analysis. Biopsychosoc Med 2(1):14. https://doi.org/10.1186/1751-0759-2-14
Vives-Mestres M, Casanova A, Hershey AD, Orr SL (2021) Perceived stress and pain severity in individuals with chronic migraine: a longitudinal cohort study using daily prospective diary data. Headache 61(8):1245–1254. https://doi.org/10.1111/head.14199
Hougaard A, Amin F, Hauge AW, Ashina M, Olesen J (2013) Provocation of migraine with aura using natural trigger factors. Neurology 80(5):428–431. https://doi.org/10.1212/WNL.0b013e31827f0f10
Karsan N, Bose P, Newman J, Goadsby PJ (2021) Are some patient-perceived migraine triggers simply early manifestations of the attack. J Neurol 268(5):1885–1893. https://doi.org/10.1007/s00415-020-10344-1
Turner DP, Smitherman TA, Martin VT, Penzien DB, Houle TT (2013) Causality and headache triggers. Headache: J Head Face Pain 53(4):628–635. https://doi.org/10.1111/head.12076
Houle TT, Turner DP (2013) Natural experimentation is a challenging method for identifying headache triggers. Headache: J Head Face Pain 53(4):636–643. https://doi.org/10.1111/head.12075
Torelli P, Cologno D, Manzoni GC (1999) Weekend headache: a retrospective study in migraine without aura and episodic tension-type headache. Headache: J Head Face Pain 39(1):11–20. https://doi.org/10.1046/j.1526-4610.1999.3901011.x
Vaitl D, Propson N, Stark R, Walter B, Schienle A (2001) Headache and sferics. Headache: J Head Face Pain 41(9):845–853. https://doi.org/10.1111/j.1526-4610.2001.01155.x
Morrison D (1990) Occupational stress in migraine is weekend headache a myth or reality. Cephalalgia 10(4):189–193. https://doi.org/10.1046/j.1468-2982.1990.1004189.x
Vives-Mestres M, Casanova A, Buse DC, Donoghue S, Houle TT, Lipton RB, Mian A, Shulman KJ, Orr SL (2020) Patterns of perceived stress throughout the migraine cycle: a longitudinal cohort study using daily prospective diary data. Headache 61(1):90–102. https://doi.org/10.1111/head.13943
Schramm SH, Moebus S, Lehmann N, Galli U, Obermann M, Bock E, Yoon MS, Diener HC, Katsarava Z (2015) The association between stress and headache: a longitudinal population-based study. Cephalalgia 35(10):853–863. https://doi.org/10.1177/0333102414563087
An YC, Liang CS, Lee JT, Lee MS, Chen SJ, Tsai CL, Lin GY, Lin YK, Yang FC (2019) Effect of sex and adaptation on migraine frequency and perceived stress: a cross-sectional case-control study. Front Neurol 10:598. https://doi.org/10.3389/fneur.2019.00598
Griep RH, Toivanen S, Santos IS, Rotenberg L, Juvanhol LL, Goulart AC, Aquino EM, Benseñor I (2016) Work-family conflict, lack of time for personal care and leisure, and job strain in migraine: results of the Brazilian longitudinal study of adult health (ELSA-Brasil). Am J Ind Med 59(11):987–1000. https://doi.org/10.1002/ajim.22620
Santos IS, Griep RH, Alves MG et al (2014) Job stress is associated with migraine in current workers: the Brazilian Longitudinal Study of Adult Health (ELSA-Brasil). Eur J Pain (London, England) 18:1290–1297. https://doi.org/10.1002/j.1532-2149.2014.489.x
Navarro-Pérez MP, Suller-Marti A, Bellosta-Diago E, Roche-Bueno JC, Santos-Lasaosa S (2020) Impact of 24-hour on-call shifts on headache in medical residents: a cohort study. Headache 60(7):1427–1431. https://doi.org/10.1111/head.13861
Andreeva VA, Fezeu LK, Hercberg S, Galan P (2018) Obesity and migraine: effect modification by gender and perceived stress. Neuroepidemiology 51(1-2):25–32. https://doi.org/10.1159/000489663
Vgontzas A, Li W, Mostofsky E, Mittleman MA, Bertisch SM (2021) Baseline sleep quality, stress, and depressive symptoms, and subsequent headache occurrence in a six-week prospective cohort study of patients with episodic migraine. Headache 61(5):727–733. https://doi.org/10.1111/head.14105
Dikmen PY, Yavuz BG, Aydinlar EI (2015) The relationships between migraine, depression, anxiety, stress, and sleep disturbances. Acta Neurol Belg 115:117–122. https://doi.org/10.1007/s13760-014-0312-0
Cha MJ, Kim BK, Moon HS, Ahn JY, Oh K, Kim JY, Kim BS, Sohn JH, Chung JM, Song TJ, Kim J, Seo JG, Chu MK, Cho SJ (2018) Stress is associated with poor outcome of acute treatment for chronic migraine: a multicenter study. Pain Med 19(9):1832–1838. https://doi.org/10.1093/pm/pnx269
De Benedittis G, Lorenzetti A (1992) The role of stressful life events in the persistence of primary headache: major events vs. daily hassles. Pain 51(1):35–42. https://doi.org/10.1016/0304-3959(92)90006-w
Moon H-J, Seo J-G, Park S-P (2017) Perceived stress in patients with migraine: a case-control study. J Headache Pain 18(1):73. https://doi.org/10.1186/s10194-017-0780-8
Vladetić M, Jančuljak D, Butković Soldo S, Kralik K, Buljan K (2017) Health-related quality of life and ways of coping with stress in patients with migraine. Neurol Sci: Off J Ital Neurol Soc Ital Soc Clin Neurophysiol 38(2):295–301. https://doi.org/10.1007/s10072-016-2759-7
Martin PR (2016) Stress and primary headache: review of the research and clinical management. Curr Pain Headache Rep 20(7):45. https://doi.org/10.1007/s11916-016-0576-6
Buse D, Gerstein M, Wirth R et al (2021) Impact of the COVID-19 pandemic on people living with migraine: results of the MICOAS qualitative study. Headache:65–66
Delussi M, Gentile E, Coppola G, Prudenzano AMP, Rainero I, Sances G, Abagnale C, Caponnetto V, de Cesaris F, Frattale I, Guaschino E, Marcinnò A, Ornello R, Pistoia F, Putortì A, Roca ME, Roveta F, Lupi C, Trojano M, Pierelli F, Geppetti P, Sacco S, de Tommaso M (2020) Investigating the effects of COVID-19 quarantine in migraine: An observational cross-sectional study from the Italian National Headache Registry (RICe). Front Neurol 11:597881. https://doi.org/10.3389/fneur.2020.597881
Gonzalez-Martinez A, Planchuelo-Gómez Á, Guerrero ÁL, García-Azorín D, Santos-Lasaosa S, Navarro-Pérez MP, Odriozola-González P, Irurtia MJ, Quintas S, de Luis-García R, Gago-Veiga AB (2021) Evaluation of the impact of the COVID-19 lockdown in the clinical course of migraine. Pain Med 22(9):2079–2091. https://doi.org/10.1093/pm/pnaa449
Balkaya M, Seidel JL, Sadeghian H, Qin T, Chung DY, Eikermann-Haerter K, van den Maagdenberg AMJM, Ferrari MD, Ayata C (2019) Relief following chronic stress augments spreading depolarization susceptibility in familial hemiplegic migraine mice. Neuroscience 415:1–9. https://doi.org/10.1016/j.neuroscience.2019.07.006
Lisicki M, Ruiz-Romagnoli E, Piedrabuena R, Giobellina R, Schoenen J, Magis D (2018) Migraine triggers and habituation of visual evoked potentials. Cephalalgia 38(5):988–992. https://doi.org/10.1177/0333102417720217
Schwedt TJ, Chong CD, Chiang C-C, Baxter L, Schlaggar BL, Dodick DW (2014) Enhanced pain-induced activity of pain-processing regions in a case-control study of episodic migraine. Cephalalgia 34(12):947–958. https://doi.org/10.1177/0333102414526069
Schulte LH, Peng KP (2019) Current understanding of premonitory networks in migraine: a window to attack generation. Cephalalgia 39(13):1720–1727. https://doi.org/10.1177/0333102419883375
Kaufmann D, Brennan KC (2018) The effects of chronic stress on migraine relevant phenotypes in male mice. Front Cell Neurosci 12:294. https://doi.org/10.3389/fncel.2018.00294
Burstein R (2001) Deconstructing migraine headache into peripheral and central sensitization. Pain 89(2):107–110. https://doi.org/10.1016/S0304-3959(00)00478-4
Avona A, Mason BN, Lackovic J, Wajahat N, Motina M, Quigley L, Burgos-Vega C, Moldovan Loomis C, Garcia-Martinez LF, Akopian AN, Price TJ, Dussor G (2020) Repetitive stress in mice causes migraine-like behaviors and calcitonin gene-related peptide-dependent hyperalgesic priming to a migraine trigger. Pain 161(11):2539–2550. https://doi.org/10.1097/j.pain.0000000000001953
Polk AN, Protti TA, Smitherman TA (2020) Allodynia and disability in migraine: the mediating role of stress. Headache 60(10):2281–2290. https://doi.org/10.1111/head.14012
Serafini G, Pompili M, Innamorati M, Giordano G, Montebovi F, Sher L, Dwivedi Y, Girardi P (2012) The role of microRNAs in synaptic plasticity, major affective disorders and suicidal behavior. Neurosci Res 73(3):179–190. https://doi.org/10.1016/j.neures.2012.04.001
Domingues RB, Fonseca KB, Ziviane LF, Domingues SA, Vassalo D (2010) Altered cardiovascular reactivity to mental stress but not to cold pressure test in migraine. Headache 50(1):133–137. https://doi.org/10.1111/j.1526-4610.2009.01567.x
Leistad RB, Stovner LJ, White LR, Nilsen KB, Westgaard RH, Sand T (2007) Noradrenaline and cortisol changes in response to low-grade cognitive stress differ in migraine and tension-type headache. J Headache Pain 8(3):157–166. https://doi.org/10.1007/s10194-007-0384-9
Gass JJ, Glaros AG (2013) Autonomic dysregulation in headache patients. Appl Psychophysiol Biofeedback 38(4):257–263. https://doi.org/10.1007/s10484-013-9231-8
Mamontov OV, Babayan L, Amelin AV, Giniatullin R, Kamshilin AA (2016) Autonomous control of cardiovascular reactivity in patients with episodic and chronic forms of migraine. J Headache Pain 17(1):52. https://doi.org/10.1186/s10194-016-0645-6
Leistad R, Sand T, Westgaard R, Nilsen KB, Stovner LJ (2006) Stress-induced pain and muscle activity in patients with migraine and tension-type headache. Cephalalgia 26(1):64–73. https://doi.org/10.1111/j.1468-2982.2005.00997.x
Rauschel V, Straube A, Süß F, Ruscheweyh R (2015) Responsiveness of the autonomic nervous system during paced breathing and mental stress in migraine patients. J Headache Pain 16(1):82. https://doi.org/10.1186/s10194-015-0567-8
Miglis MG (2018) Migraine and autonomic dysfunction: which is the horse and which is the jockey. Curr Pain Headache Rep 22(3):19. https://doi.org/10.1007/s11916-018-0671-y
Lippi G, Mattiuzzi C (2017) Cortisol and migraine: a systematic literature review. Agri 29(3):95–99. https://doi.org/10.5505/agri.2017.25348
Penzien DB, Irby MB, Smitherman TA, Rains JC, Houle TT (2015) Well-established and empirically supported behavioral treatments for migraine. Curr Pain Headache Rep 19(7):34. https://doi.org/10.1007/s11916-015-0500-5
Ailani J, Burch RC, Robbins MS, the Board of Directors of the American Headache Society (2021) The American headache Society consensus statement: update on integrating new migraine treatments into clinical practice. Headache: J Head Face Pain 61(7):1021–1039. https://doi.org/10.1111/head.14153
Seng EK, Singer AB, Metts C, Grinberg AS, Patel ZS, Marzouk M, Rosenberg L, Day M, Minen MT, Lipton RB, Buse DC (2019) Does mindfulness-based cognitive therapy for migraine reduce migraine-related disability in people with episodic and chronic migraine? A phase 2b pilot randomized clinical trial. Headache: J Head Face Pain 59(9):1448–1467. https://doi.org/10.1111/head.13657
Grazzi L, Andrasik F, Rizzoli P et al (2021) Acceptance and commitment therapy for high frequency episodic migraine without aura: findings from a randomized pilot investigation. Headache: J Head Face Pain 61(6):895–905
Grazzi L, Rizzoli P, Andrasik F (2020) Effectiveness of mindfulness by smartphone, for patients with chronic migraine and medication overuse during the Covid-19 emergency. Neurol Sci 41(S2):461–462. https://doi.org/10.1007/s10072-020-04659-0
Society AH (2019) The American headache Society position statement on integrating new migraine treatments into clinical practice. Headache: J Head Face Pain 59:1–18
Hermann C, Blanchard EB (2002) Biofeedback in the treatment of headache and other childhood pain. Appl Psychophysiol Biofeedback 27(2):143–162. https://doi.org/10.1023/A:1016295727345
Morrill B, Blanchard EB (1989) Two studies of the potential mechanisms of action in the thermal biofeedback treatment of vascular headache. Headache: J Head Face Pain 29(3):169–176. https://doi.org/10.1111/j.1526-4610.1989.hed2903169.x
Holroyd KA, Penzien DB, Hursey KG, Tobin DL, Rogers L, Holm JE, Marcille PJ, Hall JR, Chila AG (1984) Change mechanisms in EMG biofeedback training: cognitive changes underlying improvements in tension headache. J Consult Clin Psychol 52(6):1039–1053. https://doi.org/10.1037/0022-006X.52.6.1039
Probyn K, Bowers H, Caldwell F, Mistry D, Underwood M, Matharu M, Pincus T, On behalf of the CHESS Team (2017) Prognostic factors for chronic headache: a systematic review. Neurology 89(3):291–301. https://doi.org/10.1212/wnl.0000000000004112
Caroli A, Klan T, Gaul C, Kubik SU, Martin PR, Witthöft M (2020) Types of triggers in migraine - factor structure of the headache triggers sensitivity and avoidance questionnaire and development of a new short form (HTSAQ-SF). Headache 60(9):1920–1929. https://doi.org/10.1111/head.13896
Varkey E, Linde M, Henoch I (2013) “It’sa balance between letting it influence life completely and not letting it influence life at all”–a qualitative study of migraine prevention from patients’ perspective. Disabil Rehabil 35(10):835–844. https://doi.org/10.3109/09638288.2012.709304
Martin PR (2010) Behavioral management of migraine headache triggers: learning to cope with triggers. Curr Pain Headache Rep 14(3):221–227. https://doi.org/10.1007/s11916-010-0112-z
Martin PR, Reece J, Callan M, MacLeod C, Kaur A, Gregg K, Goadsby PJ (2014) Behavioral management of the triggers of recurrent headache: a randomized controlled trial. Behav Res Ther 61:1–11. https://doi.org/10.1016/j.brat.2014.07.002
Anheyer D, Leach MJ, Klose P, Dobos G, Cramer H (2019) Mindfulness-based stress reduction for treating chronic headache: a systematic review and meta-analysis. Cephalalgia 39(4):544–555. https://doi.org/10.1177/0333102418781795
Seminowicz DA, Burrowes SAB, Kearson A, Zhang J, Krimmel SR, Samawi L, Furman AJ, Keaser ML, Gould NF, Magyari T, White L, Goloubeva O, Goyal M, Peterlin BL, Haythornthwaite JA (2020) Enhanced mindfulness-based stress reduction in episodic migraine: a randomized clinical trial with magnetic resonance imaging outcomes. Pain 161(8):1837–1846. https://doi.org/10.1097/j.pain.0000000000001860
Wells RE, O’Connell N, Pierce CR et al (2021) Effectiveness of mindfulness meditation vs headache education for adults with migraine: a randomized clinical trial. JAMA Intern Med 181(3):317–328. https://doi.org/10.1001/jamainternmed.2020.7090
Simshäuser K, Lüking M, Kaube H, Schultz C, Schmidt S (2020) Is mindfulness-based stress reduction a promising and feasible intervention for patients suffering from migraine? A randomized controlled pilot trial. Complement Med Res 27(1):19–30. https://doi.org/10.1159/000501425
Holroyd KA, Cottrell CK, O’Donnell FJ et al (2010) Effect of preventive (β blocker) treatment, behavioural migraine management, or their combination on outcomes of optimised acute treatment in frequent migraine: randomised controlled trial. BMJ (Clinical research ed) 341:c4871
Powers SW, Kashikar-Zuck SM, Allen JR, LeCates SL, Slater SK, Zafar M, Kabbouche MA, O’Brien HL, Shenk CE, Rausch JR, Hershey AD (2013) Cognitive behavioral therapy plus amitriptyline for chronic migraine in children and adolescents: a randomized clinical trial. Jama 310(24):2622–2630. https://doi.org/10.1001/jama.2013.282533
Buse DC, McGinley JS, Lipton RB. Predicting the Future of Migraine Attack Prediction. Headache. 2020;60(10):2125–2128. https://doi.org/10.1111/head.14025.
Houle TT, Turner DP, Golding AN, Porter JAH, Martin VT, Penzien DB, Tegeler CH (2017) Forecasting individual headache attacks using perceived stress: development of a multivariable prediction model for persons with episodic migraine. Headache: J Head Face Pain 57(7):1041–1050. https://doi.org/10.1111/head.13137
Holsteen KK, Hittle M, Barad M, Nelson LM (2020) Development and internal validation of a multivariable prediction model for individual episodic migraine attacks based on daily trigger exposures. Headache 60(10):2364–2379. https://doi.org/10.1111/head.13960
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This paper is based on the trial lecture by Anker Stubberud at his PhD defense December 10th, 2020.
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AS designed the review, wrote the initial manuscript draft, revised it for important intellectual content, and read and approved the final manuscript. DCB conceived and contributed to the design of the review, revised the manuscript for important intellectual content, and read and approved the final manuscript. ESK conceived and contributed to the design of the review, revised the manuscript for important intellectual content, and read and approved the final manuscript. ML designed the review, revised the manuscript for important intellectual content, and read and approved the final manuscript. ET designed the review, revised the manuscript for important intellectual content, and read and approved the final manuscript.
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AS is a part-time employee and shareholder of Nordic Brain Tech AS, a company developing a mHealth behavioral migraine intervention; and has a patent mHealth Biofeedback treatment concept for episodic migraine pending and may benefit financially from a license agreement between Nordic Brain Tech AS and NTNU Norwegian University of Science and Technology.
DCB has grants from Amgen, the National Headache Foundation and the FDA. She has been a consultant for Amgen/Novartis, Allergan/Abbvie, Lilly, Lundbeck, and Teva. She is on the editorial board of Current Pain and Headache Reports.
ESK reports no competing interest.
ML is a shareholder of Nordic Brain Tech AS, a company developing a mHealth behavioral migraine intervention; has a patent mHealth Biofeedback treatment concept for episodic migraine pending and may benefit financially from a license agreement between Nordic Brain Tech AS and NTNU Norwegian University of Science and Technology of the same concept.
ET is a shareholder of Nordic Brain Tech AS, a company developing a mHealth behavioral migraine intervention; has a patent mHealth Biofeedback treatment concept for episodic migraine pending and may benefit financially from a license agreement between Nordic Brain Tech AS and NTNU Norwegian University of Science and Technology of the same concept. ET has received personal fees for lectures and advisory boards from Lundbeck, Allergan/Abbvie, Roche, TEVA, Novartis, Amgen, Eli-Lilly. He is board member and shareholder of Palion Medical AS.
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Stubberud, A., Buse, D.C., Kristoffersen, E.S. et al. Is there a causal relationship between stress and migraine? Current evidence and implications for management. J Headache Pain 22, 155 (2021). https://doi.org/10.1186/s10194-021-01369-6
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DOI: https://doi.org/10.1186/s10194-021-01369-6