Advertisement

An Investigation of Cervical Spinal Posture in Cervicogenic Headache

  1. Peter K. Farmer,
  2. Suzanne J. Snodgrass,
  3. Anthony J. Buxton and
  4. Darren A. Rivett
  1. P.K. Farmer, BAppSc(Physio), MPhil(Physio), Thrive Physio Health Clinic, Erina, New South Wales, Australia.
  2. S.J. Snodgrass, PT, PhD, MMedSc(Physio), Discipline of Physiotherapy, School of Health Sciences, Faculty of Health and Medicine, Hunter Building, The University of Newcastle, University Drive, Callaghan, New South Wales, Australia 2308.
  3. A.J. Buxton, DipAppSc(Med Rad), MHEd, Discipline of Medical Radiation Science (Diagnostic Radiography), School of Health Sciences, Faculty of Health and Medicine, The University of Newcastle.
  4. D.A. Rivett, PhD, MAppSc(ManipPhty), BAppSc(Phty), Discipline of Physiotherapy, School of Health Sciences, Faculty of Health and Medicine, The University of Newcastle.
  1. Address all correspondence to Dr Snodgrass at: Suzanne.Snodgrass{at}newcastle.edu.au.

Abstract

Background Cervicogenic headache (CGH) is defined as headache symptoms originating from the cervical spine. Cervical dysfunction from abnormal posture has been proposed to aggravate or cause CGH, but there are conflicting reports as to whether there is an association between posture and CGH.

Objective The purpose of this study was to evaluate differences in cervical spinal posture, measured on radiographs, between patients with probable CGH and asymptomatic control participants.

Design A single-blinded comparative measurement design was used.

Methods Differences in postural variables from radiographs between participants with CGH (n=30) and age- and sex-matched asymptomatic control participants (n=30) were determined using paired t tests or the nonparametric equivalent. Postural variables were general cervical lordosis (GCL, Cobb angle C2–C7), upper cervical lordosis (UCL, sagittal alignment C2 compared with C3–C4), and C2 spinous process horizontal deviation. Logistic regression determined postural variables, increasing the likelihood of CGH.

Results There were no significant differences in posture between the CGH and control groups. The mean GCL was 10.97 degrees (SD=7.50) for the CGH group and 7.17 degrees (SD=5.69) for the control group. The mean UCL was 11.86 degrees (SD=6.46) for the CGH group and 9.44 degrees (SD=4.28) for the control group. The mean C2 spinous process horizontal deviation was 3.00 mm (SD=1.66) for the CGH group and 2.86 mm (SD=2.04) for the control group. However, there was a significant association between greater GCL and an increased likelihood of having CGH (odds ratio=1.08; 95% confidence interval=1.001, 1.191).

Limitations The findings are limited to an association between GCL and posture, as cause and effect cannot be determined.

Conclusions The association between greater GCL and increased likelihood of having CGH suggests that GCL might be considered in the treatment of patients with CGH. However, as the data do not support posture as a cause of CGH, it is unknown whether addressing posture would reduce CGH.

Assessment and treatment of abnormal posture is common despite there being very little evidence that altered posture is associated with symptoms or that treatment strategies can improve posture-related symptoms.1,2 The assessment of posture assumes that identifying postures that are different to the “ideal” posture may provide a meaningful clinical sign that may be related to dysfunction or symptoms.3 If abnormal posture is not related to dysfunction or symptoms, the justification of clinical postural assessment is limited. Therefore, research to establish associations between postural variables and symptoms in patients is important for justifying current clinical practices. There are very few postural abnormalities that have been directly related to symptoms.2

Cervicogenic headache (CGH) is a type of secondary headache where the symptoms originate from a dysfunction in the cervical spine.4,5 Cervical dysfunction from abnormal posture is one factor that has been proposed to aggravate or cause CGH.6,7 The proposed association between abnormal cervical posture and headache has been demonstrated in migraine and tension-type headaches,810 but there are conflicting results in CGH.1,1113 Despite this lack of agreement, clinicians routinely assess and treat altered posture for CGH1,2; therefore, it is important to examine possible associations in order to guide treatment.

The craniovertebral angle (between the horizontal line passing through C7 and a line extending from the tragus of the ear to the tip of the C7 spinous process10) as measured from photographs has been used to investigate associations between cervical posture and CGH, with conflicting results. Two studies in adults showed no association11,13 and one study in children aged 6 to 12 years showed an association between a smaller craniovertebral angle (ie, increased forward head posture) and the presence of CGH.14 This conflicting evidence suggests that craniovertebral angle measurements may not isolate the specific postural factors that may be associated with CGH symptoms.15 Therefore, to determine potential posture variations in patients with CGH, radiographic measurements are needed. Only one identified study used radiographs to assess static cervical lordosis posture in patients with headache and showed that decreased cervical lordosis was associated with tension headaches.16 Tension headache is considered a different headache type than CGH; therefore, postural presentations may differ in CGH, requiring investigation.

The C2 is proposed as the most common cervical level for CGH genesis, with both the C1–2 and C2–3 joints suggested as the dominant motion segment.15,16 The C2–3 motion segment has been reported by some groups to be the most common source of CGH symptoms,5,17,18 with diagnostic blocks suggesting the third occipital nerve located at C2–3 was implicated as the pain source in approximately 53% of 15 patients with CGH.19 Alternatively, C1–2 was reliably palpated by 2 examiners as the symptomatic cervical level in 63% of 60 patients with CGH.20 Two investigations of “unilateral”21 and migraine22 headaches that assessed the position and symmetry of the C2 spinous process using imaging (computed tomography and radiography, respectively) demonstrated that altered C2 spinous process horizontal plane alignment is associated with headaches. However, due to the use of descriptive rather than standardized headache criteria, the participant samples potentially included a mix of headache types, so conclusions about the relationship of C2 spinous process horizontal alignment and CGH cannot be determined.

The aim of this study was to determine if cervical spine posture is altered in patients with CGH compared with age- and sex-matched asymptomatic individuals. This is a first step in determining whether posture is worth considering in larger studies that assess the possible factors contributing to CGH symptoms. Determining whether there is a relationship between CGH and cervical posture may potentially provide clinicians with evidence supporting the assessment and treatment of abnormal posture in this patient group.

Method

A single-blind, age- and sex-matched comparative measurement design was used to evaluate differences in cervical spinal posture, as measured on cervical radiographs, between asymptomatic participants (control group) and participants with CGH. Participants were recruited using flyers placed on noticeboards on the university campus where the study was conducted. Interested participants were first screened by telephone for inclusion. All participants provided written informed consent.

Participants

Participants were healthy adults aged between 18 and 50 years with a primary complaint of headache and no history of significant medical conditions that might be potential contraindications to physical examination of the cervical spine, including known cancer, osteoporosis, nerve root symptoms, inflammatory or infectious diseases affecting the neck, instability of the cervical spine, or reported potential vertebrobasilar insufficiency symptoms.23 This age range was used so that altered upper neck posture associated with different age groups15 was not a confounding factor in the analysis of posture in the symptomatic and asymptomatic groups. Potential participants who were possibly pregnant were excluded, as radiography was to be used in the study. Asymptomatic participants were matched by age and sex with participants with CGH. Participants with a diagnosis of CGH were included if their pattern of symptoms was consistent with the diagnostic criteria of the Cervicogenic Headache International Study Group (CHISG, Appendix).24 These diagnostic criteria have been used widely as the basis for inclusion in CGH studies.13,25,26 The potential participants with CGH were screened by telephone for a pattern of symptoms consistent with the CHISG diagnostic criteria.

To be included in the study, participants had to have: (1) a unilateral headache at least once per week over the previous 2 months (unilaterality consistent on one side, not a headache that swapped sides); (2) neck pain before, during, or following the headache; and (3) pain aggravated by movement or specific postures of the neck. This description of neck pain is consistent with criterion Ia(1) of the CHISG criteria. Individuals who experienced an aura with their headache or who were involved in claiming workers' or third-party compensation or litigation were excluded. Those individuals reporting the required pattern of headache symptoms progressed to a physical assessment to determine study eligibility as long as they also had not received any manual therapy treatment for the previous 2 months, as the potential effect of manual therapy on posture is unknown.

The physical assessment consisted of an experienced physical therapist (with professional qualifications in manual therapy and 16 years of clinical experience) applying pressure over the spinous and articular processes of the cervical spine with the participant in a prone position. The techniques used for this palpation assessment were common cervical spine posteroanterior passive accessory intervertebral movement assessment techniques.25 A potential participant with headache was eligible if he or she met the CHISG criteria for the reproduction of “head pain, similar to the usually occurring one” with palpation.24 The identification of patients with CGH thus required potential participants to meet criteria Ia(1) and Ia(2) and criterion III of the CHISG criteria (Appendix). Participants also may have met criteria Ib and Ic, but potential participants were not excluded if they did not meet these criteria (Appendix). As diagnostic blocks were not used (criterion II, Appendix), participants with CGH were considered to have “probable” CGH, based on the best available diagnostic criteria without the use of invasive techniques. Asymptomatic participants also underwent the physical palpation assessment to maintain consistency between study groups, as the possible effects of this palpation assessment on posture are unknown. The therapist performing the physical assessment was blinded as to the headache status of the potential participant. Asymptomatic participants were eligible as long as they did not report any head pain during the physical assessment.

Radiographic Methods

The study used radiographic measurements to quantify posture, as these methods have been demonstrated to allow specific segmental measurements of cervical spine posture.15,27 Two standard views of the cervical spine (one anterior-posterior [AP] open-mouth view and one lateral view, both in a standing position) were used to facilitate generalization to clinical practice. Radiographic examinations were performed by a registered radiographer with 35 years of experience using standardized positioning techniques and participant instructions.28 The radiographic views and instructions were consistent with a standard cervical radiographic series as performed in clinical radiography practice. Participants were asked to stand in a normal comfortable posture with their arms relaxed and to look straight ahead. The images were taken in suspended respiration during normal shallow breathing at rest, with the instruction to “stop breathing now.” Participants were not given any instructions for the timing of inspiration or expiration, as forced voluntary breathing causes thoracic cavity movement and body sway, whereas normal involuntary breathing does not result in excessive movement or blurring of the image.28

Radiographs were performed using a Philips Diagnostic Vertical Bucky Stand attached to a Philips Optimus 50 Medium Frequency Generator and Philips R0 1648 Hi-Speed Rotating Anode X-Ray tube in a Philips ROT 360 X-ray Tube Housing (Philips Healthcare, Best, Holland). Two Fuji Computed Radiography (model DS, Fujifilm Holdings Corp, Tokyo, Japan) imaging cassettes were used: one 18- × 24-cm cassette (for AP open-mouth view) and one 24- × 30-cm cassette (for lateral view). The cassettes contained a standard definition Fuji Digital Image Receptor Plate, Model CR ST-VI (Fujifilm Holdings Corp). All images were obtained using a grid technique (105 lines/inch 12:1 grid). A focal film distance of 178 cm was used for the lateral view radiographic projection, and a focal film distance of 110 cm was used for the AP open-mouth view.

Radiographic Measurements

The radiographic images were obtained digitally and then transferred to Centricity Webpacs V2.1 (GE Medical Systems, Milwaukee, Wisconsin), a software system used to perform measurements. A qualified radiographer experienced in the use of this measurement tool performed all measurements using the same computer and monitor for each participant. A second experienced radiographer repeated the measurements on a subset of 20 randomly selected participants to determine interrater reliability of the on-screen measurement techniques. Both radiographers were blinded to the headache status of each participant and the measurements of the other radiographer. Good reliability has been demonstrated for these methods when they were performed by drawing on hard copies of radiographs15,2931 but is unknown for digitized images using the Centricity Webpacs software.

The posture measurements performed on the lateral radiographic view were general cervical lordosis (GCL) and upper cervical lordosis (UCL). The GCL measurement was based on the Cobb method.29 It was obtained by drawing lines parallel to the inferior end plates of C2 and C7, and then the software package generated perpendicular lines to those drawn. The acute angle formed between these lines was calculated by the software package and recorded as GCL (Fig. 1A). A higher value for GCL indicated a participant had greater cervical lordosis between C2 and C7. The UCL radiographic measurement, based on the technique described by Johnson,15 involved drawing a line between the most superior-posterior point on the odontoid process of C2 and the most inferior-posterior point on the body of C2. A second line was then drawn connecting the most inferior-posterior point on the body of C3 with the most inferior-posterior point on the body of C4. The angle for UCL was determined by measuring the acute angle formed between these 2 lines (Fig. 1B). A higher value for UCL indicated a participant had greater cervical lordosis between C2 and C4. The AP open-mouth radiograph view was used to measure the position of the C2 spinous process relative to the midline (Fig. 2). This procedure involved a measurement of the distance that the C2 spinous process deviated from the midline at the level of the atlas.27 This measurement was determined by drawing 2 vertical lines: one passing through the midpoint of the tip of the odontoid process and one passing through the midpoint of the spinous process of C2. The distance (in millimeters) between these 2 lines determined the C2 spinous process deviation, with greater values for increased deviation.

Figure 1.
Figure 1.

(A) Example of a general cervical lordosis measurement (Cobb C2–C7 measurement). Single asterisk represents the angle (in degrees) used in analysis, with a higher value indicating increased lordosis between C2 and C7. (B) Example of an upper cervical lordosis measurement on a radiograph. Double asterisk represents the angle (in degrees) used in analysis, with a higher value indicating increased lordosis between C2 and C4.

Figure 2.
Figure 2.

Example of a C2 spinous process horizontal deviation measurement on a radiograph. The perpendicular distance (in millimeters) between the 2 lines represents the value used in analysis, with a higher value indicating increased C2 spinous process horizontal deviation.

Data Analysis

Sample size estimations suggested that potentially meaningful differences of 10 and 5 degrees in GCL29 and UCL,15 respectively, between groups could be detected with 80% power with 22 to 24 participants per group. As the variability of C2 spinous process horizontal deviation was unknown, 30 participants per group were recruited. Intraclass correlation coefficients (ICC [2,1]) and 95% confidence intervals (95% CIs) determined the intertester reliability of the radiographic measurements. Data were checked for normality, and nonparametric methods were used where appropriate. Differences in C2 spinous process horizontal deviation and UCL between the CGH group and control group were determined using t tests. The difference in GCL between groups was determined using the Wilcoxon rank sum test.

A matched-pairs binary logistic regression determined whether measurements taken of cervical spinal posture on radiographs (GCL, UCL, and C2 spinous process horizontal deviation) demonstrated an association with the likelihood of experiencing CGH. Analyses were completed using JMP 10 and SAS 9.2 (SAS Institute Inc, Cary, North Carolina).

Results

Approximately 300 potential participants were screened by telephone using the CHISG criteria (Fig. 3). The most common reasons for exclusion were the presence of bilateral headache or an aura. Control participants were only recruited when a participant of the same sex and similar age had already been recruited in the CGH group, so exclusions occurred if matching was not possible. Thirty participants with probable CGH (mean age=31.4 years, SD=10.0; 4 male, 26 female) and 30 age- and sex-matched controls (mean age=29.8 years, SD=9.4; 4 male, 26 female) were recruited. Participants with CGH reported a mean frequency of 1.2 headaches per week (SD=1.8, range=1–7) and a mean duration of 152.4 weeks (SD=311.7, range=2 months–30 years). All potential CGH group participants who met the telephone screening criteria reported reproduction of their familiar headache on palpation and were included in the study. Digital radiographs were technically compromised for 2 participants (one from the CGH group and one from the control group); therefore, radiographic data analyses are from 58 participants. The intertester reliability of the radiographic measurements was good to excellent: UCL (ICC=.75; 95% CI=.47, .89), C2 spinous process horizontal deviation (ICC=.88; 95% CI=.73, .95), and GCL (ICC=.90; 95% CI=.77, .96).

Figure 3.
Figure 3.

Flow diagram of study participants. CGH=cervicogenic headache, CHISG=Cervicogenic Headache International Study Group.

There were no significant differences between the control and CGH groups for the 3 radiographic postural measurements (Tab. 1). Logistic regression demonstrated that as the GCL increased, there was a statistically significant increased likelihood of having CGH (P=.042). The odds ratio of 1.08 (95% CI=1.00, 1.19) suggests that with each degree increase of GCL, there was an approximate 8% increased likelihood of having CGH in this sample. There were no associations between CGH and UCL or C2 spinous process deviation (Tab. 2).

View this table:
Table 1.

Comparisons of Radiographic Postural Variables Between Participants With Cervicogenic Headache (CGH) and Age- and Sex-Matched Asymptomatic Individuals

View this table:
Table 2.

Associations Between the Radiological Measurements of the Cervical Spinal Postural Variables and the Likelihood of Experiencing Cervicogenic Headache

Discussion

This study is the first to investigate the association between posture and CGH using a radiographic analysis of the cervical spine. The results indicate that cervical spine posture, as defined by the radiographic methods used in this study, cannot be used to differentiate between individuals with probable CGH and those who are asymptomatic. However, an increase in GCL was found to be associated with an increased likelihood of experiencing CGH, although UCL and C2 spinous process horizontal deviation were not associated with CGH. The significant variability in cervical spinal posture in the absence of symptoms has been reported to contribute to difficulties in distinguishing postural types between asymptomatic and symptomatic individuals.15,32 This result also is consistent with a previous study in CGH that indicated isolated clinical signs were not sufficient to differentiate individuals with CGH from those who were asymptomatic.33 Although the posture variables measured in this study did not differentiate individuals with CGH from those who were asymptomatic, the association between increased GCL and an increased likelihood of having CGH suggests that GCL may be worth considering in assessment of patients with CGH.

Interpreting the odds ratio for the association between GCL and CGH (1.08), each degree of increased lordosis increases the odds of having CGH by 8% (compared with the control group in this study). However, the 95% CI for the odds ratio (1.0, 1.19) suggests that there is either no association or the odds of having CGH may be as high as 19% per degree increase in GCL. As the 95% CI value for the odds ratio suggests that there may not be an association, the routine assessment of GCL as an isolated clinical sign is not justified. The inability of any single clinical sign or injection procedure to discriminate CGH is consistent with the description of CGH as a syndrome3436 characterized by a combination of movement, joint, and muscle dysfunction.37,38 However, a combination of clinical signs (restricted cervical movement, impairment in the craniocervical flexion test, and palpable upper cervical joint dysfunction) has been demonstrated to reliably identify CGH.33 The results of the current study suggest that further investigation may be warranted to determine if increased GCL may improve the identification of CGH when considered in combination with other clinical signs.

Previous studies have demonstrated an association between decreased cervical lordosis and tension-type headache14 or neck pain.39,40 In contrast, the present study demonstrated an association between CGH and increased cervical lordosis. This finding is consistent with the results of a previous study in children that demonstrated increased forward head posture as measured by craniovertebral angle (which might be expected to be associated with increased cervical lordosis) was associated with having CGH. These results together suggest that increased cervical lordosis may well be unique to CGH and could be associated with the upper cervical muscle dysfunction that is a feature of CGH.33,41 One possible theory explaining the relationship between CGL and CGH may be related to muscle dysfunction,42 as upper cervical flexor muscle dysfunction has been established as a feature of CGH33,41 and treatments to improve muscle function and control have been demonstrated to be effective in patients with CGH.41,4345 However, the effects of improved muscle function on posture in patients with CGH are unknown, as relationships between improved muscle function and posture have been demonstrated only in patients with neck pain46,47 and not CGH.

The interpretation of the results of the present study should be made in the light of the results of previous studies investigating cervical lordosis. No previous studies were identified assessing general GCL in patients with CGH using the radiographic C2–C7 Cobb angle measurement, and few studies in patients with cervical dysfunction were identified. C2–C7 Cobb angles have been reported for patients with neck pain39 and asymptomatic individuals.48 Using measurement methods similar to those of the current study, Harrison et al39 found greater lordosis in people with neck pain compared with asymptomatic controls. Harrison et al reported Cobb angles (X̅=12.7°, SD=12.5°) in their chronic pain group (neck pain symptoms >12 weeks) that were comparable to those of the current study (X̅=11.0°, SD=7.5°). Conversely, Matsumoto et al49 found no difference in the prevalence of lordotic curvature versus nonlordotic curvature in patients with acute whiplash compared with asymptomatic controls; however, these findings were based on observation rather than measurements. The GCL values in asymptomatic participants in the current study (X̅=7.1, SD=5.7) are consistent with C2–C7 Cobb angles reported by Park et al48 for their asymptomatic younger group (mean age=9.0 years, SD=11.0, range=20–29) but much lower than values reported for asymptomatic participants in the study by Harrison et al (X̅=26.8, SD=9.7). Harrison et al excluded participants with excessive head protrusion (perpendicular distance from C2 to C7 >25.4 mm for their pain groups and >10 mm for their control group), partially explaining the differences. Harrison et al also had a lower proportion of female participants (50%) compared with the current study (86%), and women have been shown to have greater cervical lordosis than men (demonstrated using different radiographic assessment methods).16,50 These findings suggest that increased GCL may be a factor in both neck pain and headache, but further research is needed to confirm this conclusion.

The lack of statistically significant associations between the 2 investigated upper cervical spinal postural variables and CGH suggests that despite the upper cervical region being considered the predominant region for the generation of CGH,5153 symptoms may not be associated with upper cervical postural variations. As increased UCL is one of the components of forward head posture, these results support the findings of previous investigations that concluded there is no association between forward head posture and CGH.11,13 However, these results contrast with the findings of a study by Budelmann et al14 showing forward head posture was greater in children with CGH. The current study findings of no association between CGH and C2 spinous process horizontal deviation concur with a previous study reporting that deviation of the C2 spinous process in patients with headache may be coincidental.54 These findings potentially mean that other impairments in the upper cervical region (eg, muscular dysfunction) may instead be contributing to symptoms, rather than localized postural characteristics. Furthermore, the association of GCL with CGH despite expectations that the UCL would more likely be involved is consistent with a previous case study that showed improvements in CGH following treatment to improve general posture.55 One hypothesis may be that altered general posture contributes to the likelihood of CGH due to the effects on larger muscle groups (eg, levator scapulae) that attach to the upper cervical levels.

Limitations

The participants in this study were recruited via advertisements rather than patients presenting at a clinic, which may bias the results. However, strict selection criteria were used, based on the CHISG major criteria for CGH diagnosis.24 The CHISG recommends the use of diagnostic anesthetic blockades to provide a definitive CGH diagnosis,24 which this study did not utilize. Previous studies also did not use diagnostic anesthetic blockades, as they are considered invasive and associated with unjustifiable risk in the research setting with volunteer participants.13,43 Moreover, diagnostic anesthetic blockades abolish other types of headaches56 and, therefore, do not establish an unequivocal CGH diagnosis. They also rely on the participant presenting for assessment at the time he or she is experiencing symptoms. Participants were included in the current study if they regularly experienced CGH, rather than if they had a presenting headache, and the presence or absence of CGH symptoms at the time the radiograph was taken was not recorded. As CGH is typically an intermittent headache that does not occur in a predictable cycle and that patients often present in the clinical setting during symptom-free periods, it was considered important to investigate posture regardless of participants' symptoms at the time of assessment. Furthermore, although the reproduction of a participant's familiar headache was used as one assessment component to identify patients with CGH as recommended in the CHISG diagnostic criteria, it is acknowledged that pain on palpation of the cervical spine also may occur in patients with other types of headaches, suggesting this criterion is not specific to CGH.57 The reproduction of familiar headache by palpation was used in addition to the descriptors consistent with CGH as described in the CHISG criteria as an additional component supporting the likelihood of a participant's headache being cervical in origin, as in a previous study.58

In terms of the possible confounders of the posture measurements, the radiographs in this study were not assessed for pathology, so other possible contributors to the presenting postures cannot be determined. Furthermore, the palpation assessment may have been a confounding factor, as the effect of palpation on posture is unknown. To minimize the potential for confounding, the palpation assessment was performed on all participants using the same method and in the same sequence regardless of the participants' headache status. Lastly, as this study used a comparative study design, only an association between posture and CGH can be demonstrated, and it is unknown whether increased GCL posture causes CGH or having CGH leads to an increase in GCL. Additional factors that may contribute to symptoms, such as psychosocial variables, were not explored in this study; therefore, the interpretation of the results is limited to the possible association of posture to symptoms.

Future Research

Future investigations could aim to determine if the postural association identified in the current study is a causative factor for CGH or instead a response to symptoms and if changing the GCL has an effect on symptoms. Additionally, a larger multifactorial study may investigate posture with other possible factors (eg, psychosocial factors) influencing the development of symptoms. Further research into cervical posture using radiographs in other headache types may help determine whether posture could be useful for diagnostic differentiation of headache types. Research also may focus on the potential relationships between upper cervical muscle dysfunction and posture, which might direct future treatment strategies in CGH.

In conclusion, the present study showed that 3 components of static cervical spinal posture commonly used clinically cannot be used to discriminate participants with CGH from asymptomatic individuals. However, increased GCL was associated with an increased likelihood of having CGH. Therefore, clinicians may consider GCL when assessing or treating patients with CGH. It should be noted that the results of this study suggest the degree of GCL cannot identify a patient with CGH, so the routine assessment of GCL in all patients with CGH is not supported.

The Bottom Line

What do we already know about this topic?

Clinicians often consider abnormal cervical spine posture to be associated with cervicogenic headache (CGH); however, researchers have disagreed about whether altered posture is actually linked to CGH.

What new information does this study offer?

This study compared a population of patients with CGH with age- and sex-matched control participants. The researchers found that individuals with increased general cervical lordosis had an increased likelihood of experiencing CGH.

If you're a patient or a caregiver, what might these findings mean for you?

Your physical therapist may need to address general cervical lordotic posture to reduce your likelihood of experiencing CGH.

Appendix.

Appendix.
Appendix.

Major criteria for cervicogenic headache diagnosis recommended by the Cervicogenic Headache International Study Groupa

a Major criteria as described by Sjaastad et al.24 Criterion II was not used in the current study.

Footnotes

  • All authors provided concept/idea/research design, writing, and data collection. Mr Farmer, Dr Snodgrass, and Mr Buxton provided data analysis. Mr Farmer and Dr Rivett provided project management. Dr Snodgrass and Mr Buxton provided facilities/equipment. Dr Snodgrass, Mr Buxton, and Dr Rivett provided consultation (including review of the manuscript before submission). The authors acknowledge John Tessier for his assistance with data collection.

  • The study protocol was approved by the University of Newcastle's Human Research Ethics Committee.

  • An abstract of the study was presented at the Musculoskeletal Physiotherapy Australia 16th Biennial Conference; October 1–5, 2009; Sydney, Australia.

  • Received February 24, 2014.
  • Accepted October 2, 2014.

References

    1. Christensen ST,
    2. Hartvigsen J
    . Spinal curves and health: a systematic critical review of the epidemiological literature dealing with associations between sagittal spinal curves and health. J Manipulative Physiol Ther. 2008;31:690714.
    1. Refshauge K,
    2. Gass E
    . Musculoskeletal Physiotherapy: Clinical Science and Evidence-Based Practice. 2nd ed. Oxford, United Kingdom: Butterworth Heinemann; 2004.
    1. Troyanovich SJ,
    2. Harrison DE,
    3. Harrison DD
    . Structural rehabilitation of the spine and posture: rationale for treatment beyond the resolution of symptoms. J Manipulative Physiol Ther. 1998;21:3750.
    1. Antonaci F,
    2. Sjaastad O
    . Cervicogenic headache: a real headache. Curr Neurol Neurosci Rep. 2011;11:149155.
    1. Bogduk N,
    2. Govind J
    . Cervicogenic headache: an assessment of the evidence on clinical diagnosis, invasive tests, and treatment. Lancet Neurol. 2009;8:959968.
    1. Richardson CJ
    . Treatment of cervicogenic headaches using Mulligan “SNAGS” and postural re-education: a case report. Orthopaedic Physical Therapy Practice. 2009;21:3338.
    1. Jull G
    . Management of cervical headache. Man Ther. 1997;2:182190.
    1. Fernández-de-las-Peñas C,
    2. Alonso-Blanco C,
    3. Cuadrado ML,
    4. Pareja JA
    . Forward head posture and neck mobility in chronic tension-type headache: a blinded, controlled study. Cephalalgia. 2005;26:314319.
    1. Fernández-de-las-Peñas C,
    2. Cuadrado ML,
    3. Pareja JA
    . Myofascial trigger points, neck mobility and forward head posture in unilateral migraine. Cephalalgia. 2006;26:10611070.
    1. Fernández-de-las-Peñas C,
    2. Cuadrado ML,
    3. Pareja JA
    . Myofascial trigger points, neck mobility, and forward head posture in episodic tension-type headache. Headache. 2007;47:662672.
    1. Dumas JP,
    2. Arsenault AB,
    3. Boudreau G,
    4. et al
    . Physical impairments in cervicogenic headache: traumatic vs. nontraumatic onset. Cephalalgia. 2001;21:884893.
    1. Watson DH,
    2. Trott PH
    . Cervical headache: an investigation of natural head posture and upper cervical flexor muscle performance. Cephalalgia. 1993;13:272284.
    1. Zito G,
    2. Jull G,
    3. Story I
    . Clinical tests of musculoskeletal dysfunction in the diagnosis of cervicogenic headache. Man Ther. 2006;11:118129.
    1. Budelmann K,
    2. von Piekartz H,
    3. Hall T
    . Is there a difference in head posture and cervical spine movement in children with and without pediatric headache? Eur J Pediatr. 2013;172:13491356.
    1. Johnson GM
    . The correlation between surface measurement of head and neck posture and the anatomic position of the upper cervical vertebrae. Spine (Phila Pa 1976). 1998;23:921927.
    1. Nagasawa A,
    2. Sakakibara T,
    3. Takahashi A
    . Roentgenographic findings of the cervical spine in tension-type headache. Headache. 1993;33:9095.
    1. Cooper G,
    2. Bailey B,
    3. Bogduk N
    . Cervical zygapophysial joint pain maps. Pain Med. 2007;8:344353.
    1. Jull G
    . Manual diagnosis of C2/3 headache. Cephalalgia. 1985;5:308309.
    1. Lord SM,
    2. Barnsley L,
    3. Wallis BJ,
    4. Bogduk N
    . Third occipital nerve headache: a prevalence study. J Neurol Neurosurg Psychiatry. 1994;57:11871190.
    1. Hall T,
    2. Briffa K,
    3. Hopper D,
    4. Robinson K
    . Reliability of manual examination and frequency of symptomatic cervical motion segment dysfunction in cervicogenic headache. Man Ther. 2010;15:542546.
    1. Rose FC
    1. Boquet J,
    2. Moore N,
    3. Payennville G,
    4. et al
    . Use of CT scans in the study of the upper cervical vertebrae in strictly lateralised migrainous headache (and other intermittent headache?) In: Rose FC, ed. New Advances in Headache Research. London, United Kingdom: Smith-Gordon and Company; 1989:4548.
    1. Boquet J,
    2. Biosmare F,
    3. Payenneville G,
    4. et al
    . Lateralization of headache: possible role of upper cervical trigger point. Cephalalgia. 1989;9:1524.
    1. Murtagh JE,
    2. Kenna CJ
    . Back Pain & Spinal Manipulation. 2nd ed. Oxford, United Kingdom: Butterworth Heinemann; 2001.
    1. Sjaastad O,
    2. Fredriksen TA,
    3. Pfaffenrath V
    ; for The Cervicogenic Headache International Study Group. Cervicogenic headache: diagnostic criteria. Headache. 1998;38:442445.
    1. Stanton WR,
    2. Jull GA
    . Cervicogenic headache: locus of control and success of treatment. Headache. 2003;43:956961.
    1. Martelletti P,
    2. van Suijlekom H
    . Cervicogenic headache: practical approaches to therapy. CNS Drugs. 2004;18:793805.
    1. Gradl G,
    2. Maier-Bosse T,
    3. Penning R,
    4. Stabler A
    . Quantification of C2 cervical spine rotatory fixation by X-ray, MRI and CT. Eur Radiol. 2005;15:376382.
    1. Bontrager KL
    . Textbook of Radiographic Positioning and Related Anatomy. 7th ed. St Louis, Mo: Mosby; 2010.
    1. Cote P,
    2. Cassidy JD,
    3. Yong-Hing K,
    4. et al
    . Apophysial joint degeneration, disc degeneration, and sagittal curve of the cervical spine: can they be measured reliably on radiographs? Spine (Phila Pa 1976). 1997;22:859864.
    1. Harrison DE,
    2. Harrison DD,
    3. Cailliet R,
    4. et al
    . Cobb method or Harrison posterior tangent method: which to choose for lateral cervical radiographic analysis. Spine (Phila Pa 1976). 2000;25:20722078.
    1. Rochester RP
    . Inter and intra-examiner reliability of the upper cervical X-ray marking system: a third and expanded look. CRJ: Chiropractic Research Journal. 1994;3:2331.
    1. Szeto GPY,
    2. Straker L,
    3. Raine S
    . A field comparison of neck and shoulder postures in symptomatic and asymptomatic office workers. Appl Ergon. 2002;33:7584.
    1. Jull G,
    2. Amiri M,
    3. Bullock-Saxton J,
    4. et al
    . Cervical musculoskeletal impairment in frequent intermittent headache, part 1: subjects with single headaches. Cephalalgia. 2007;27:793802.
    1. Antonaci F
    . Physical therapy and exercise in headache. Cephalalgia. 2008;28(suppl 1):35.
    1. Coskun O,
    2. Ucler S,
    3. Karakurum B,
    4. et al
    . Magnetic resonance imaging of patients with cervicogenic headache. Cephalalgia. 2003;23:842845.
    1. Sjaastad O,
    2. Bakketeig LS
    . Prevalence of cervicogenic headache: Vågå study of headache epidemiology. Acta Neurol Scand. 2008;117:173180.
    1. Jull G,
    2. O'Leary S,
    3. Falla D
    . Clinical assessment of the deep cervical flexor muscles: the craniocervical flexion test. J Manipulative Physiol Ther. 2008;31:525533.
    1. Moore MK
    . Upper crossed syndrome and its relationship to cervicogenic headache. J Manipulative Physiol Ther. 2004;27:414420.
    1. Harrison DD,
    2. Harrison DE,
    3. Janik TJ,
    4. et al
    . Modeling of the sagittal cervical spine as a method to discriminate hypolordosis: results of elliptical and circular modeling in 72 asymptomatic subjects, 52 acute neck pain subjects, and 70 chronic neck pain subjects. Spine (Phila Pa 1976). 2004;29:24852492.
    1. McAviney J,
    2. Schulz D,
    3. Bock R,
    4. et al
    . Determining the relationship between cervical lordosis and neck complaints. J Manipulative Physiol Ther. 2005;28:187193.
    1. Jull G,
    2. Trott P,
    3. Potter H,
    4. et al
    . A randomized controlled trial of exercise and manipulative therapy for cervicogenic headache. Spine (Phila Pa 1976). 2002;27:18351843.
    1. Mayoux-Benhamou MA,
    2. Revel M,
    3. Vallee C,
    4. et al
    . Longus colli has a postural function on cervical curvature. Surg Radiol Anat. 1994;16:367371.
    1. Jull G,
    2. Sterling M,
    3. Falla D,
    4. Treleaven J,
    5. O'Leary S
    . Whiplash, Headache and Neck Pain. Edinburgh, Scotland: Churchill Livingstone; 2008.
    1. Chaibi A,
    2. Russell MB
    . Manual therapies for cervicogenic headache: a systematic review. J Headache Pain. 2012;13:351359.
    1. Ylinen J,
    2. Nikander R,
    3. Nykänen M,
    4. et al
    . Effect of neck exercises on cervicogenic headache: a randomized controlled trial. J Rehabil Med. 2010;42:344349.
    1. Beer A,
    2. Treleaven J,
    3. Jull G
    . Can a functional postural exercise improve performance in the cranio-cervical flexion test? a preliminary study. Man Ther. 2012;17:219224.
    1. Falla D,
    2. Jull G,
    3. Russell T,
    4. et al
    . Effect of neck exercise on sitting posture in patients with chronic neck pain. Phys Ther. 2007;87:408417.
    1. Park MS,
    2. Moon SH,
    3. Lee HM,
    4. et al
    . The effect of age on cervical sagittal alignment: normative data on 100 asymptomatic subjects. Spine (Phila Pa 1976). 2013;38:E458E463.
    1. Matsumoto M,
    2. Fujimura Y,
    3. Suzuki N,
    4. et al
    . Cervical curvature in acute whiplash injuries: prospective comparative study with asymptomatic subjects. Injury. 1998;29:775778.
    1. Helliwell PS,
    2. Evans PF,
    3. Wright V
    . The straight cervical spine: does it indicate muscle spasm? J Bone Joint Surg Br. 1994;76:103106.
    1. Bogduk N
    . Cervicogenic headache: anatomic basis and pathophysiologic mechanisms. Curr Pain Headache Rep. 2001;5:382386.
    1. Ward TN,
    2. Levin M
    . Case reports: headache caused by a spinal cord stimulator in the upper cervical spine. Headache. 2000;40:689691.
    1. Narouze SN,
    2. Casanova J,
    3. Mekhail N
    . The longitudinal effectiveness of lateral atlantoaxial intra-articular steroid injection in the treatment of cervicogenic headache. Pain Med. 2007;8:184188.
    1. Macpherson BCM,
    2. Campbell C
    . C2 rotation and spinous process deviation in migraine: cause or effect or coincidence? Neuroradiology. 1991;33:475477.
    1. McDonnell MK,
    2. Sahrmann SA,
    3. Van Dillen L
    . A specific exercise program and modification of postural alignment for treatment of cervicogenic headache: a case report. J Orthop Sports Phys Ther. 2005;35:315.
    1. Goadsby P,
    2. Lipton RB,
    3. Ferrari MD
    . Migraine: current understanding and treatment. N Engl J Med. 2002;346:257270.
    1. Watson DH,
    2. Drummond PD
    . Head pain referral during examination of the neck in migraine and tension-type headache. Headache. 2012;52:12261235.
    1. Antonaci F,
    2. Ghirmai S,
    3. Bono G,
    4. et al
    . Cervicogenic headache: evaluation of the original diagnostic criteria. Cephalalgia. 2001;21:573583.