Chiropractic & Manual Therapies 2021 (Jan 7); 29: 1 ~ FULL TEXT
Susanne Lynge, Kristina Boe Dissing, Werner Vach, Henrik Wulff Christensen, and Lise Hestbaek
Department of Sports Science and Clinical Biomechanics,
University of Southern Denmark,
Campusvej 55, 5230, Odense M, Denmark.
Background: To investigate the effectiveness of chiropractic spinal manipulation versus sham manipulation in children aged 7–14 with recurrent headaches.
Methods: Design: A two-arm, single-blind, superiority randomised controlled trial.
Setting: One chiropractic clinic and one paediatric specialty practice in Denmark, November 2015 to August 2020.
Participants: 199 children aged 7 to 14 years, with at least one episode of headache per week for the previous 6 months and at least one musculoskeletal dysfunction identified.
Interventions: All participants received standard oral and written advice to reduce headaches. In addition, children in the active treatment group received chiropractic spinal manipulation and children in the control group received sham manipulation for a period of 4 months. Number and frequency of treatments were based on the chiropractor's individual evaluation in the active treatment group; the children in the control group received approximately eight visits during the treatment period.
Primary outcome measures: 'Number of days with headache', 'pain intensity' and 'medication' were reported weekly by text messages, and global perceived effect by text message after 4 months. A planned fixed sequence strategy based on an initial outcome data analysis was used to prioritize outcomes. 'Number of days with headache' and 'pain intensity' were chosen as equally important outcomes of highest priority, followed by global perceived effect and medication. The significance level for the first two outcomes was fixed to 0.025 to take multiplicity into account.
Results: Chiropractic spinal manipulation resulted in significantly fewer days with headaches (reduction of 0.81 vs. 0.41, p = 0.019, NNT = 7 for 20% improvement) and better global perceived effect (dichotomized into improved/not improved, OR = 2.8 (95% CI: 1.5–5.3), NNT = 5) compared with a sham manipulation procedure. There was no difference between groups for pain intensity during headache episodes. Due to methodological shortcomings, no conclusions could be drawn about medication use.
Conclusions: Chiropractic spinal manipulation resulted in fewer headaches and higher global perceived effect, with only minor side effects. It did not lower the intensity of the headaches. Since the treatment is easily applicable, of low cost and minor side effects, chiropractic spinal manipulation might be considered as a valuable treatment option for children with recurrent headaches.
Trial registration: ClinicalTrials.gov, identifier NCT02684916, registered 02/18/2016 – retrospectively registered.
Keywords: Adolescents; Children; Chiropractic; Clinical trial; Effectiveness; Manipulation; ?eadache.
From the FULL TEXT Article:
Recurrent paediatric headache is common with annual prevalence rates ranging from approximately 5% among 3–year-olds to more than half of the population around puberty.  Recurrent headaches affect quality of life in children and are known to interfere with school performance [2, 3], social life among peers and family , and participation in play and sports.  Children with recurrent headaches also report higher levels of stress and depression compared with children without headache.  Importantly, suffering from recurrent childhood headache can be a precursor to potentially severe headache syndromes later in life. 
Paediatric headaches can be complex and are often associated with co-morbid conditions [6, 7] and the aetiology is diverse, including familial disposition , psychological factors [9, 10], nutrition , socioeconomic factors [7, 12] and more. Trauma to the head or neck, as well as prolonged static postures, have also been associated with headache in children. [13–15] Thus, a biomechanical element may be involved in the aetiology and therefore, spinal manipulation has been suggested as a treatment for headaches. There is some evidence for the effectiveness of spinal manipulation in adults with chronic headache. [16, 17] Spinal manipulation is not uncommon for children with headache, as it is the presenting symptom for 11–20% of school-aged children and adolescents in chiropractic practice. [18–20] Nevertheless, with the exception of one small study where the children only received a single manipulative treatment , which is not common practice [16, 22], there has not been any formal investigation into the effectiveness of spinal manipulation for children with recurrent headache.
Given the potentially severe consequences of recurrent headaches in childhood and the risk of lifelong trajectories of pain, safe and effective management needs to be identified. Adverse events following spinal manipulation appear to be very rare  and the risk to be less than after taking medication, which is often prescribed for painful conditions.  Therefore, this approach calls for investigation.
The aim of this study is to investigate the effectiveness of chiropractic spinal manipulation versus sham manipulation in children aged 7–14 with recurrent headaches.
This was a two-arm, single-blind, superiority randomized controlled trial. The protocol of the study has been published elsewhere. 
Between November 2015 and August 2019, we recruited participants for this trial through the Danish School Information Network, local newspapers, television, social media and radio. The children had to be 7–14 years old, to have experienced at least one episode of headache per week for the previous 6 months and to have at least one musculoskeletal dysfunction in the spine, pelvis and/or temporomandibular joint, identified by the investigating chiropractor. Exclusion criteria were examination findings requiring immediate referral, contraindications to spinal manipulation, previous treatment for headache within the last 3 months and failure to report pre-randomisation baseline data.
The study took place at two clinics in Northern Denmark: one chiropractic clinic and one paediatric specialty practice. Screenings and treatments were administered in both clinics by the same investigating chiropractor with 34 years of experience in private practice.
Pre-randomisation data collection
Before screening, eligible children and their parents answered three questions each Sunday for 4 weeks via a text message on their cell phone (Short Message System, SMS). The questions regarded number of days with a headache, intensity of headaches and number of pills taken for headache during the previous week. In addition, a pre-treatment questionnaire including the characteristics of the child’s headache problem, lifestyle, previous trauma, previous treatment, family history of headache and general health was completed and returned by mail. Details have been reported in the protocol. 
After a four-week pre-treatment period, verifying at least four episodes of headache, a screening for inclusion/exclusion was done by the investigating chiropractor. This included standard neurologic and orthopaedic examination, as well as examination for biomechanical dysfunctions in the spine, pelvis and temporomandibular joints.
Upon receipt of the signed consent form, participating children were randomised with 1:1 allocation using random block size with the software nQuery Advisor  by the data manager at the Nordic Institute for Chiropractic and Clinical Biomechanics. Group assignment was noted in opaque envelopes and sent to the project clinics.
After completing the four-week pre-treatment period and confirmed as eligible for inclusion at the screening visit, all participants and their parents received oral and written advice believed to be beneficial to headache patients in general, regarding regular sleep, diet and exercise. After this the randomisation envelope was opened by the investigating chiropractor and the trial period of 4 months began.
At all the visits, the participants’ parents were present during a short interview where information about side effects and trauma experienced since the previous visit was collected by the chiropractor. The parents would then leave the room, and after examining the child, either the chiropractic spinal manipulation or the sham manipulation was administered.
The chiropractic spinal manipulation treatment was directed at specific, individually identified dysfunctions of one or more joints in the spine, pelvis and/or temporomandibular joints. A high-velocity, low-amplitude thrust, resulting in an audible cavitation, was given to improve the function of the joint. The treatment has been described in detail in the study protocol.  All treatments were modified to fit the age and size of the child as well as individual spinal characteristics. To reflect daily clinical practice, the number and frequency of treatments, as well as the joints treated, were based on the chiropractor’s individual evaluation at each visit throughout the 4 months treatment period.
The sham manipulation treatment followed a previously validated protocol, developed by Chaibi et al.  Placement of the child was similar to the placement in the chiropractic spinal manipulation group, but low-amplitude, low-velocity gentle pushes in a broad non-specific contact away from the spinal column were given with no resulting cavitation. In addition to the protocol previously established by Chaibi et al., a de-activated activator (www.activator.com)  on the chiropractor’s own arm would produce a click-noise in connection with the cervical treatment to resemble the sound of the audible joint cavitation in the chiropractic spinal manipulation group. The children in this group should receive approximately eight visits with increasing intervals during the 4 months participation period to resemble a common course of care in a chiropractic practice. The ideal schedule was 2 visits the first week, 1 visit/week the following 2 weeks, 1 visit every other week for 4 weeks and finally the last two visits 4 weeks apart, but it could be modified to the parents’ convenience.
Children in the chiropractic spinal manipulation treatment group who reported little or no effect, or a worsening of their headache after treatment were offered a consultation with the paediatrician. Children in the sham manipulation group who reported little or no effect, or a worsening of headache after the trial period were offered free chiropractic care, similar to the care delivered in the spinal manipulation group. After the four-month post-trial treatment period, parents received a final text message, identical to the one they received after participating in the trial regarding the effect of the treatment.
Throughout the study period, the parents together with their participating children answered the same weekly text messages as they had during the pre-randomisation period:
“How many days has had a headache this week?
Choose a number between 0 and 7”.
“How will you rate the pain on a scale from 0–10, where 0 is no pain and 10 is the worst pain you can imagine?”
“How many pills for headache has taken this week?
0: none, 1: 1–4, 2: more than 4 pills.”
The parents sent the answers using the reply function, and the answers were automatically registered and stored in a database. At the end of the 4 months of treatment, all participating families received a final text message including three questions to be answered in collaboration between parents and child:
“How satisfied is with participation in this trial on a scale from 0–10, where 0 is the worst and 10 is the best you can imagine?”
“How has the headache changed since started the treatment at the chiropractor?
1. almost gone/disappeared; 2. much better; 3. slightly better; 4. same; 5. a little worse; 6. much worse; 7. worse than ever.”
“In this trial there have been two groups. Do you think that was in group 1, who had standard chiropractic treatment or in group 2, that DID NOT have standard chiropractic treatment (please answer 1 or 2)?”
To estimate the effect of the intervention, we considered the average values during the pre-treatment period and the final 4 weeks of the study period (Weeks 14–17) for the three variables based on the weekly SMS questions. The final outcomes were then given by the change scores, i.e. the difference between these average values. A fourth outcome was the global perceived effect (GPE) based on the SMS (question #2) after 4 months.
A sample size calculation was conducted when the data collection was completed for 50 children in each treatment group.  This was based on weekly headache days, and details were reported in the study protocol.  A sample size of 100 children in each group was indicated to detect a difference of 20% in mean change score between groups with a power of 80% and a significance level of 5%. Calculations were performed in nQuery Advisor.  Allowing for a 20% drop-out rate, the aim for inclusion was 240 children. However, as drop out was very rare, inclusion was terminated after 199 children.
Blinding the chiropractor was obviously not possible. Allocation was concealed from the participants and their parents and blinding was further attempted by including a sham manipulation, closely resembling the active treatment, including the clicking sound. At the end of the treatment period, participating children and their parents received a text message asking which group they believed the child had participated in.
Initial outcome analysis
Due to a lack of experience with the four potential outcomes in a population of children suffering from headache and with an SMS-based data collection based on responses from children and their parents, we did not know whether they were measured in a reliable manner and whether they would show a population variation suitable to be used as an outcome in an RCT. For example, we could not exclude that there would be little variation in some of the intended outcomes across children, or that we observed associations with baseline variables which were lower than expected and/or difficult to explain. Such insights were needed to make an informed prioritisation of the outcome variables. Therefore, we conducted an interim outcome data analysis to avoid potential misjudgments. [30, 31]
That interim analysis was performed blinded to intervention status to provide information about the distribution of the four outcome variables in our population and guide the final prioritisation of outcome measures. The results of this analysis were discussed among the authors and the resulting decision report was approved by all authors before analyses of effects were initiated. The statistical report and the final decision report can be found in the Additional File 1.
The following main conclusions were drawn in the report. Since some participants did not follow the instructions to cluster the number of medications in their SMS responses and report the actual number, data on medication use could only be analysed in a reliable manner by identifying the presence/absence of use each week. Consequently, the corresponding primary outcome variable was now the change in the proportion of weeks with medication use. As many children did not report any intake of medication in the pre-treatment phase, the statistical report also suggested a sensitivity analysis, which only included children with at least 2 weeks with medication in the pre-treatment phase.
The vast majority of participants reported a pain intensity of 0 in the weeks with no days of headache, in line with our expectation. However, it turned out that this led to a high variation in pain intensity over time for many children. Hence, the definition of the four-week pain scores was changed for intensity to take only weeks with at least 1 day of headache into account. Rather than illustrating the average intensity, this reflects the intensity of the headaches when present. In addition, two further intensity definitions were suggested to be included in the sensitivity analyses: the original definition and the average over the last available 4 weeks with headache, but maximally going back 7 weeks from the end of the treatment period. Lastly, the statistical report suggested the inclusion of an analysis of lower percentiles of the change scores, instead of means, as a sensitivity analysis to cover the scenario of only a few children benefiting from the intervention.
Based on the above, ‘number of days with headache’ and ‘pain intensity’ were chosen as equally important outcomes of highest priority, followed by GPE and then medication. The significance level for the first two outcomes was fixed to 0.025 to take multiplicity into account within the planned fixed sequence strategy.
All analyses were performed and presented to all authors for interpretation blinded for intervention status and two alternative conclusions were formulated before the concealment was broken. Baseline characteristics are reported as frequencies in each treatment arm for binary and categorical variables, and as means for continuous variables. To illustrate the spread of the data, means are supplemented with 10th and 90th percentiles. With respect to previous examinations, previous treatments and reasons for school absence due to illness, the frequencies for the most common category are reported.
The distribution of the primary outcomes in each treatment group is illustrated by dot plots. Intervention effects are assessed by the difference in mean values between the two intervention groups. They are supplemented by t-test-based 95% confidence intervals, p-values and Cohen’s d (standardized mean difference between groups) as a measure of effect size. In addition, we present adjusted p-values based on a linear regression model with one covariate in addition to treatment. That covariate was the baseline level for each of the change scores, and the number of days with headache at baseline for GPE. According to the protocol, an adjustment for additional baseline characteristics was planned in case they showed a correlation of at least 0.3 with the outcome variable. However, no such characteristic was identified. The multiplicity implied by considering four primary outcomes was taken into account by applying a fixed sequence strategy according to the prioritisation resulting from the initial outcome data analyses. Significance levels of 0.025 for the first two primary outcomes and 0.05 for the two remaining were used and applied to the adjusted p-values.
For the three change scores, a responder analysis was conducted, reporting the proportion in each group with 20, 25, 50 and 75% improvement compared with baseline. The number needed to treat (NNT) to reach a 20% improvement is also reported. In order to decide whether to refer the child to a paediatrician after the follow-up period, GPE was dichotomised into ‘improved’ or ‘same or worse’.  The same dichotomisation was used to calculate NNT and this also allowed calculation of an odds ratio.
Side effects and satisfaction with care are analysed as secondary outomes (the latter not mentioned in the study protocol). In addition, course of treatment and the parents’ guess about treatment group are reported by group. Results for the pre-specified secondary outcomes, headache status and GPE after 8 and 12 months, will be presented in a subsequent manuscript.
Aligned with the protocol, sensitivity analyses were performed with missing values imputed based on multiple imputation (described in detail in Additional File 2). In addition, the sensitivity analyses according to the initial outcome data analysis report were performed.
The study is reported according to the CONSORT guidelines  and a CONSORT check list is included as Additional File 3.
STATA v.16.0 (StataCorp, College Station, Tx, USA) was used for all analyses.
All parents were required to give written informed consent allowing their child to participate in this study and they were informed orally and in writing that participation in the trial was voluntary and that parents could withdraw their child from the trial at any time with no negative consequences for the child. All participants were treated according to the Declaration of Helsinki. 
The project was approved by the Regional Committee on Health Research Ethics for The North Denmark Region (#N-20150025) and data were handled according to the General Data Protection Regulations.  The trial was registered with ClinicalTrials.gov (Identifier: NCT02684916). 
Recruitment and dropouts
The inclusion period lasted from November 1st 2015 to September 2nd 2019. Of the 253 children screened, 199 (79%) children were eligible for inclusion. Of these, 99 were randomised to the intervention group, and 100 to the control group. Five children dropped out during the four-month trial period for reasons unrelated to treatment (Figure 1).
In some children, the weekly SMS data were missing for some weeks or single items were missing. Hence the averages used to compute change scores were based on less than 4 weeks for some individuals. Details are given in Additional File 4.
Patient characteristics at baseline
There were more girls (57%) than boys in the cohort and the mean age at baseline was 10.8 years. The mean pain intensity at baseline was 6.0 and the vast majority of children had taken non-prescriptive medicine at some point, most often 1–3 times per month, but only 4% had taken prescriptive medicine. Approximately half of the children had been seen by a general practitioner for their headache, but only one-fifth had received treatment for their headache, most often by a chiropractor. Approximately three-quarters of the children reported previous trauma to the head and/or neck, and headache was by far the primary reason for absence from school due to illness. The majority of the children were physically active during leisure time and had a sufficient amount of sleep. Baseline distribution of age, sex and the outcomes are shown in Table 1 and further details are presented in Additional File 5, Supplementary Table 1.
Headache characteristics at baseline
Approximately half the children had experienced recurrent headaches for 1 to 3 years, most often a few days per week, but 13% suffered from headache almost every day. An episode of headache lasted typically from 2 to 12 h per day and the onset varied over day and night. The typical region of onset varied across children, but headache was often located at the forehead. The most predominant co-occurring symptoms were nausea, dizziness, light and sound sensitivity (53–61%). Neck pain (48%) and the use of computer/tv (51%) were the activities most often thought to cause headache, whereas sleeping was the main activity easing the headache (83%). Further details are presented in Additional File 5, Supplementary Table 2.
Analysis of primary outcomes
Table 2 and Figures 2 and 3 describe the results for the primary outcomes.
Number of days
In both treatment groups, we observed a substantial variation in the change in number of days with a tendency to more substantial improvements in the intervention group (Fig. 2). On average, children reported fewer days with headache after the four-month follow up in both groups compared with baseline, however the mean reduction in number of days with headache was twice as high for children in the intervention group compared with the control group (0.81 vs. 0.41), which was statistically significant (Table 2). The effect size (Cohen’s d) was 0.32. From the responder analysis, illustrated in Fig. 3, it can be seen that about one-third of the children displayed more than a 50% improvement with response being more frequent in the intervention group. The NNT to reach 20% improvement was 7.
Regarding intensity of headache, we can observe a reduction over time for many children in both groups (Fig. 2). The mean reduction was almost equal between the two groups (0.53 vs. 0.52) and the difference was not statistically significant (Table 2). The effect size (Cohen’s d) was 0.01. In the responder analysis illustrated in Fig. 3, less than a third of the children showed an improvement of at least 20%. The difference between the groups was of negligible magnitude. The NNT to reach 20% improvement was 50.
Global perceived effect
As illustrated in Fig. 2, improvement in GPE was more frequent in the intervention group. The mean score was 3.2 in the intervention group and 2.6 in the control group. The difference in mean scoring was significant with a value of 0.61, corresponding to a Cohen’s d of 0.67 (Table 2). When dichotomised, 43.4% reported improvement in the intervention group and 22.0% in the control group, resulting in an odds ratio of 2.8 (95% CI: 1.5–5.3). The number needed to treat was 5.
As illustrated in Fig. 2, intake of medicine went up or down to a similar degree in both groups, resulting in small reductions on average (Table 2). There was no statistically significant difference detected between groups (0.10 vs. 0.03). Cohen’s d was 0.20. In the responder analysis seen in Fig. 3, both groups showed an almost equal improvement, resulting in an NNT of 40 to reach 20% improvement.
In the intervention group, 84% of the children reported side effects following at least one consultation and in the control group it was 75%. Side effects reported were mild in nature, most often soreness, headache and fatigue, and they were typically of short duration (0–2 h). There were no serious side effects reported. Details are reported in Additional File 5, Supplementary Table 3.
As seen in Figure 4, most children were quite satisfied with participation in the trial, but children in the intervention group were on average more satisfied than children in the control group. The difference was statistically significant (p < 0.001) with a mean of 7.9 versus 6.8 for the intervention and the control group, respectively. Cohen’s d was 0.49.
Course of treatment and guessing of treatment group
We intended to expose the children to treatment for 17 weeks and this was achieved in the intervention group, with a median of 16.8 weeks and little variation (10th–90th percentile: 15.7–17.7). The median time was smaller in the control group (15.0) with a more substantial variation (12.3–18.6). There was, however, a distinct difference in the number of consultations, with a median of 11 in the intervention group and 7 in the control group. This reflects a difference in the time scheduling of the consultations. In the control group, we reached the intended gap of 14 days between consultations quite precisely with a median of 14 days, whereas in the intervention group the median was 9 days.
At the four-month follow up, 62% in the intervention group and 59% in the control group guessed the correct randomisation group.
Using different definitions of outcomes – as suggested in the initial outcome data analysis report – did not change the results, except for the case of using the original definition for pain intensity. In this case, the results trended towards those observed for number of days with headache, as we expected from our considerations in the initial outcome data analysis (Additional File 5, Supplementary Table 4). The handling of missing values did not seem to affect the results (Additional File 2, Supplementary Tables 5–6). We did not perform analyses of percentiles, as the analysis of mean values gave a clear picture.
This is the first large-scale randomised clinical trial investigating the effectiveness of chiropractic spinal manipulation in the treatment of recurrent headaches in children. Chiropractic spinal manipulation resulted in significantly fewer days with headaches and better GPE when compared with a validated sham manipulation procedure. There was no difference between groups for pain intensity during headache episodes.
This positive effect is in line with results seen in studies of adult populations for migraine  and cervicogenic headaches [17, 37], whereas the results for tension type headaches are favorable but less conclusive. [16, 17] Also in trials in adults, effects of manual therapy were more pronounced for frequency of headache than for pain intensity. [16, 22]
However, the results presented in this article do not distinguish between headache types in the children. Furthermore, it should be noted, that the effect of placebo is possibly larger for children than adults , and thus larger effects are needed to demonstrate differences between treatment and sham interventions.
Strengths and weaknesses
The use of an adaptive design [29–31] allowing for the prioritisation of the primary outcomes based on an interim analysis might be considered unorthodox. However, due to the uncertainty about the measurement properties of the outcomes included, we believed this step to be necessary in order to avoid misjudgments in the priority of outcomes. Actually, the interim analysis led to a down-grading of the outcome medication, which otherwise would probably have been given a higher priority. The interim analysis was pre-planned, blinded for any information about the treatment status of the participant, and performed by an independent statistician, and thus the scientific standard was not compromised. The process was transparent, and the reports are published in the supplementary material.
This study has several strengths. The good compliance and the large sample size resulted in more precise estimates and can facilitate subsequent hypothesis-generating subgroup analyses; utilising weekly SMS text messages as a headache diary reduces recall bias and has been shown to be an efficient and reliable method to collect frequent data [3*9, 40]; and there has been a structured recording of side effect/adverse event. The blinding appeared to be effective because the observed difference in belief between groups is understandable due to the better outcome in the treatment group likely to have fostered a belief that they received the active treatment. 
The treatment was individualised with attention to any specific biomechanical dysfunction the child might have had, rather than a standardised treatment given to all. This reflects clinical reality and is likely to make potential recommendations easier to translate into common practice.
We regard having the same, highly experienced chiropractor treating both groups as a way to reach similarity of the clinical encounter across groups, with the only exception being the chiropractic spinal manipulation  instead of the sham manipulation. However, we cannot exclude deviations from this optimal scenario due to lack of blinding. Using a highly experienced chiropractor may also question the transferability of results, but using an expertise-based approach can prove to be a strength for the community to subsequently trust and embrace the findings.  Future studies must determine the level of expertise needed to obtain similar results.
On average the control group had nearly the intended number of eight consultations over a 16–week period and the intended gap of 14 days between consultations on average, whereas the active treatment group received on average 11 consultations. This is clearly above our expectations for the active treatment group and is due to the fact, that the treatment was pragmatic, i.e. based on the children’s signs and symptoms at each visit, and therefore these could not be precisely planned and did not follow a predefined protocol. On the other hand, the control children followed the predefined pattern of visits to the extent that the parents’ and the clinician’s schedules allowed. It cannot be excluded that the favorable results for patients in the active treatment group are partially due to obtaining more attention – both in quantity and quality. However, the control group actually received an unusually high level of quantitative attention compared to patients not included in this study, such that the effect of additional attention may be limited.
Unfortunately, medication use could not be evaluated in this study due to difficulties interpreting the responses as described in the decision report. Future studies should attempt better ways to include use of medication since the risk of Medication Overuse Headache increases with age  and the use of over-the-counter painkillers is worryingly high in adolescence, primarily due to headache. 
Considering the significant consequences of paediatric headache and the lack of effective and safe pharmacological treatment [1, 3, 38], non-pharmacological treatments such as spinal manipulation could be attractive alternatives.  The positive results from this study combined with the low risk of adverse events should encourage clinicians and policy-makers to consider spinal manipulation for children with recurrent headaches.
Unanswered questions and future research
The most important next step is investigating of the long-term effect. One-year follow-up is being completed for the present study and will be reported in a later article. The difference in effect of treatment between GPE (NNT = 3) and frequency (NNT = 7), and the lack of effect on intensity, might imply that frequency and pain intensity alone do not adequately capture ‘improvement’ as experienced by the children. This indicates that there are elements of improvement which are not captured by the investigated outcomes. Before future trials of manipulation or other types of treatment for paediatric headaches are initiated, qualitative studies should investigate further which outcomes are important to children.
Furthermore, considering the complexity of childhood headaches and the large individual differences in response to treatment observed in this study, it is important to identify potential treatment effect modifiers to target treatment efficiently.
We found that children with recurrent headaches who received chiropractic spinal manipulation experienced fewer days with headaches compared with children receiving sham manipulation. We could not detect a relevant difference in pain intensity between the groups. Children receiving chiropractic spinal manipulation also reported higher self-rated improvement than children receiving sham manipulation. Unfortunately, medication data were unreliable and therefore no conclusions could be drawn on this.
Consequently, since the treatment is easily applicable, of low cost and with no or only mild side effects, chiropractic spinal manipulation might be considered as a valuable treatment option for children with recurrent headache.
Additional file 1
The results of the initial outcome data analysis and the resulting decision report.(384K, pdf)
Additional file 2
Tables showing results following imputation of data.(266K, pdf)
Additional file 3
Full reporting check list including page numbers.(67K, pdf)
Additional file 4
Flowchart of SMS-reports.(180K, jpg)
Additional file 5
Additional information in tables.(361K, pdf)
GPE = General Perceived Effect
NNT = Numbers Needed to Treat
NRS = Numerical Rating Scale
SMS = Short Message Service
SL and LH conceived the idea; SL, LH and HWC designed the study; SL collected the data; KBD and WV performed the data analyses; SL and LH prepared the draft manuscript; all authors participated in the interpretation of data; all authors read and approved the final manuscript.
The study was primarily funded by the Foundation for Chiropractic Research and Postgraduate Education (Grant no 09/2518). The Danish Migraine and Headache Society also made a financial contribution. The funding bodies did not have any influence on the study design; in the collection, analysis, and interpretation of data; in the writing of the report; or in the decision to submit the article for publication. All authors had full access to all data (including statistical reports and tables) in the study and can take responsibility for the integrity of the data and the accuracy of the data analysis.
Ethics approval and consent to participate
All parents were required to give written informed consent allowing their child to participate in this study and they were informed orally and in writing that participation in the trial was voluntary and that parents could withdraw their child from the trial at any time with no negative consequences for the child. All participants were treated according to the Declaration of Helsinki .
The project was approved by the Regional Committee on Health Research Ethics for the Region of Northern Denmark (#N-20150025) and data were handled according to the General Data Protection Regulations . The trial was registered with ClinicalTrials.gov (Identifier: NCT02684916) .
LH, WV and HWC are supported partly by the Foundation for Chiropractic Research and Postgraduate Education; SL, HWC and KBD are in private practice, treating the patients in question. No other relationships or activities that could appear to have influenced the submitted work.
Singhi S, Jacobs H, Gladstein J.
Pediatric headache: where have we been and where do we need to be.
Powers SW, Patton SR, Hommel KA, Hershey AD.
Quality of life in childhood migraines: clinical impact and comparison to other chronic illnesses.
Pediatrics. 2003;112(1 Pt 1):e1–e5
Termine C, Ozge A, Antonaci F, Natriashvili S, Guidetti V, Wober-Bingol C.
Overview of diagnosis and management of paediatric headache. Part II: therapeutic management.
J Headache Pain. 2011;12(1):25–34
Bektas O, Ugur C, Gencturk ZB, Aysev A, Sireli O, Deda G.
Relationship of childhood headaches with preferences in leisure time activities, depression, anxiety
and eating habits: a population-based, cross-sectional study.
Recurrent pediatric headache: a comprehensive review.
Child Health Care. 2003;32(3):153–189.
Pediatric headache: update on recent research.
Lateef TM, Merikangas KR, He J, Kalaydjian A, Khoromi S, Knight E, Nelson KB.
Headache in a National Sample of American Children: Prevalence and Comorbidity
J Child Neurol 2009 (May); 24 (5): 536–543
Kroner-Herwig B, Heinrich M, Morris L.
Headache in German children and adolescents: a population-based epidemiological study.
Nelson S, Coakley R.
The pivotal role of pediatric psychology in chronic pain: opportunities for informing and
promoting new research and intervention in a shifting healthcare landscape.
Curr Pain Headache Rep. 2018;22(11):76
Hetlevik O, Bjorna CH, Lundring IT, Gjesdal S.
Adolescents consulting general practitioners for psychological problems-a nationwide, register-based study in Norway.
Fam Pract. 2019;36(1):77–83
Erlichman J, Hall A, Dean A, Godwin B, Mascarenhas M.
Integrative nutrition for pediatrics.
Curr Probl Pediatr Adolesc Health Care. 2016;46(6):165–171
Anttila P, Metsahonkala L, Aromaa M, Sourander A, Salminen J.
Determinants of tension-type headache in children.
Headache Classification Committee of the International Headache S
The international classification of headache disorders, 3rd edition (beta version)
Wilson MC, Krolczyk SJ.
Pediatric post-traumatic headache.
Curr Pain Headache Rep. 2006;10(5):387–390
Weber Hellstenius SA (2009)
Recurrent Neck Pain and Headaches in Preadolescents Associated with Mechanical Dysfunction
he Cervical Spine: A Cross-Sectional Observational Study With 131 Students
J Manipulative Physiol Ther 2009 (Oct); 32 (8): 625—634
Posadzki P, Ernst E.
Spinal manipulations for tension-type headaches: a systematic review of randomized controlled trials.
Complement Ther Med. 2012;20(4):232–239
Clar C, Tsertsvadze A, Court R, Hundt G, Clarke A, Sutcliffe P.
Clinical Effectiveness of Manual Therapy for the Management of Musculoskeletal and
Non-Musculoskeletal Conditions: Systematic Review and Update of UK Evidence Report
Chiropractic & Manual Therapies 2014 (Mar 28); 22 (1): 12
Hestbaek L, Jorgensen A, Hartvigsen J.
A description of children and adolescents in Danish chiropractic practice: results from a nationwide survey.
J Manipulative Physiol Ther. 2009;32(8):607–615
Chiropractic Care of Children from Birth to Adolescence and Classification
of Chiropractic Care Reported Conditions: An Internet Cross-Sectional
Survey of 956 European Chiropractors
J Manipulative Physiol Ther. 2012 (Jun); 35 (5): 372–380
State of Victoria A,
Safer Care Victoria, October 2019,
ISBN 978-1-76069-066-3: Safer Care Victoria.
Chiropractic spinal manipulation of children under 12. Independent review.
In. State of Victoria, Australia; 2019.
Borusiak P, Biedermann H, Bosserhoff S, Opp J.
Lack of efficacy of manual therapy in children and adolescents with suspected cervicogenic headache:
results of a prospective, randomized, placebo-controlled, and blinded trial.
Haas M, Bronfort G, Evans R, Schulz C, Vavrek D, Takaki L, Hanson L, Leininger B, Neradilek MB.
Dose-Response and Efficacy of Spinal Manipulation for Care of
A Dual-Center Randomized Controlled Trial
Spine J. 2018 (Oct); 18 (10): 1741–1754
Vohra, S, Johnston, BC, Cramer, K, and Humphreys, K.
Adverse Events Associated with Pediatric Spinal Manipulation: A Systematic Review
Pediatrics. 2007 (Jan); 119 (1): e275–e283
Carnes D, Mars TS, Mullinger B, Froud R, Underwood M.
Adverse events and manual therapy: a systematic review.
Man Ther. 2010;15(4):355–363
Lynge S, Hartvigsen J, Christensen HW, Vach W, Hestbaek L.
Effectiveness of chiropractic manipulation versus sham manipulation on recurrent headaches
in children aged 7-14 years, Protocol for a randomized clinical trial.
Chiropr Man Ther. 2019;27:40
Powering Sample Size
Chaibi A, Saltyte Benth J, Bjorn Russell M.
Validation of placebo in a manual therapy randomized controlled trial.
Sci Rep. 2015;5:11774
Osterbauer PJ, Fuhr AW, Hildebrandt RW.
Mechanical force, manually assisted short lever chiropractic adjustment.
J Manipulative Physiol Ther. 1992;15(5):309–317
Bauer P, Kohne K.
Evaluation of experiments with adaptive interim analyses.
Pallmann P, Bedding AW, Choodari-Oskooei B, Dimairo M, Flight L, Hampson LV, et al.
Adaptive designs in clinical trials: why use them, and how to run and report them.
BMC Med. 2018;16(1):29
Committee for medicinal products for human use (CHMP) EMA.
Reflection paper on methodological issues in confirmatory clinical trials planned with an adaptive design.
London: European Medicines Agency; 2007.
Schulz KF, Altman DG, Moher D,
Group C CONSORT 2010 statement: updated guidelines for reporting parallel group randomised trials.
A World medical association declaration of Helsinki: ethical principles for medical research involving human subjects.
General Data Protection Regulation
Rist PM, Hernandez A, Bernstein C, et al.
The Impact of Spinal Manipulation on Migraine Pain and Disability:
A Systematic Review and Meta-Analysis
Headache: The Journal of Head and Face Pain. 2019 (Apr); 59 (4): 532–542
Varatharajan S, Ferguson B, Chrobak K, Shergill Y, Cote P, Wong JJ, Yu H, Shearer HM, Southerst D, Sutton D, et al. Are non-invasive interventions effective for the management of headaches associated with neck pain? An update of the Bone and Joint Decade Task Force on Neck Pain and Its Associated Disorders by the Ontario Protocol for Traffic Injury Management (OPTIMa) Collaboration. Eur Spine J. 2016;25(7):1971–1999
Papetti L, Ursitti F, Moavero R, Ferilli MAN, Sforza G, Tarantino S, Vigevano F, Valeriani M.
Prophylactic treatment of pediatric migraine: is there anything new in the last decade?
Front Neurol. 2019;10:771
Johansen B, Wedderkopp N.
Comparison between data obtained through real-time data capture by SMS and a retrospective telephone interview.
Chiropr Osteopat. 2010;18:10
Axen I, Bodin L, Bergstrom G, Halasz L, Lange F, Lovgren PW, Rosenbaum A, Leboeuf-Yde C, Jensen I.
The use of weekly text messaging over 6 months was a feasible method for monitoring the clinical
course of low back pain in patients seeking chiropractic care.
J Clin Epidemiol. 2012;65(4):454–461
Commentary: measuring the success of blinding in RCTs: don't, must, can't or needn't?
Int J Epidemiol. 2007;36(3):664–665
Rossettini G, Carlino E, Testa M.
Clinical relevance of contextual factors as triggers of placebo and nocebo effects in musculoskeletal pain.
BMC Musculoskelet Disord. 2018;19(1):27
Cook JA, McCulloch P, Blazeby JM, Beard DJ, Marinac-Dabic D, Sedrakyan A, Group I
IDEAL framework for surgical innovation 3: randomised controlled trials in the assessment stage
and evaluations in the long term study stage.
Hansen EH, Holstein BE, Due P, Currie CE.
International survey of self-reported medicine use among adolescents.
Ann Pharmacother. 2003;37(3):361–366
Locher C, Kossowsky J, Koechlin H, Lam TL, Barthel J, Berde CB, Gaab J, Schwarzer G, Linde K, Meissner K.
Efficacy, safety, and acceptability of pharmacologic treatments for pediatric migraine prophylaxis:
a systematic review and network meta-analysis.
JAMA Pediatr. 2020;174(4):341–9.
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