Manual Treatment for Cervicogenic Headache and
Active Trigger Point in the Sternocleidomastoid
Muscle: A Pilot Randomized Clinical Trial

This section is compiled by Frank M. Painter, D.C.
Send all comments or additions to:    Frankp@chiro.org

FROM:   J Manipulative Physiol Ther. 2013 (Sep);   36 (7):   403—411 ~ FULL TEXT

Gema Bodes-Pardo, PT, MSc, Daniel Pecos-Martín, PT, PhD,
Tomás Gallego-Izquierdo, PT, PhD, Jaime Salom-Moreno, PT, MSc,
César Fernández-de-las-Peñas, PT, PhD, Ricardo Ortega-Santiago, PT, PhD

Clinician, Clínica Fisioterapia Santiago Vila,
San Fernando de Henares, Spain.

---

OBJECTIVE:   The purpose of this preliminary study was to determine feasibility of a clinical trial to measure the effects of manual therapy on sternocleidomastoid active trigger points (TrPs) in patients with cervicogenic headache (CeH).

METHODS:   Twenty patients, 7 males and 13 females (mean ± SD age, 39 ± 13 years), with a clinical diagnosis of CeH and active TrPs in the sternocleidomastoid muscle were randomly divided into 2 groups. One group received TrP therapy (manual pressure applied to taut bands and passive stretching), and the other group received simulated TrP therapy (after TrP localization no additional pressure was added, and inclusion of longitudinal stroking but no additional stretching). The primary outcome was headache intensity (numeric pain scale) based on the headaches experienced in the preceding week. Secondary outcomes included neck pain intensity, cervical range of motion (CROM), pressure pain thresholds (PPT) over the upper cervical spine joints and deep cervical flexors motor performance. Outcomes were captured at baseline and 1 week after the treatment.

RESULTS:   Patients receiving TrP therapy showed greater reduction in headache and neck pain intensity than those receiving the simulation (P < .001). Patients receiving the TrP therapy experienced greater improvements in motor performance of the deep cervical flexors, active CROM, and PPT (all, P < .001) than those receiving the simulation. Between-groups effect sizes were large (all, standardized mean difference, >0.84).

CONCLUSION:   This study provides preliminary evidence that a trial of this nature is feasible. The preliminary findings show that manual therapy targeted to active TrPs in the sternocleidomastoid muscle may be effective for reducing headache and neck pain intensity and increasing motor performance of the deep cervical flexors, PPT, and active CROM in individuals with CeH showing active TrPs in this muscle. Studies including greater sample sizes and examining long-term effects are needed.

---

From the FULL TEXT Article:

Introduction

Cervicogenic headache (CeH) is a secondary headache, which means “head pain with a cervical source.” [1, 2, 3] It is characterized by unilateral headache with symptoms and signs of neck involvement, for example, pain by movement, by external pressure over the upper cervical, and/or sustained awkward head positions. [2, 3] Prevalence rates for CeH varied in the general population because some studies have not detailed the criteria used to define the headache. Prevalence rates within the general population varied from 0.4% to 2.5%, [4, 5] with a female preponderance (2:1). [6] However, Sjaastad and Bakketeig [7] reported a prevalence of 4.1% with no female preponderance.

Physical therapy is commonly used for the management of individuals with CeH. [8] Previous systematic reviews reported preliminary evidence for the application of upper cervical spine mobilization or mobilization for the management of CeH. [9, 10, 11] A recent systematic review of manual therapies suggests that spinal manipulative might be an effective treatment in the management of CeH patients. [12] A survey study conducted in Australia revealed that upper cervical spine mobilization or manipulation was the most used intervention by physical therapists. [13] The physiologic basis of CeH pain lies in the convergence between trigeminal afferents and afferents from the upper cervical spinal nerves in the trigeminocervical nucleus caudalis. [14, 15] Nociceptive afferent inputs into trigeminocervical nucleus may be originated by spondylosis, disk lesions, or facet arthropathies in the upper cervical spine. [16, 17] Therefore, therapeutic interventions targeted to tissues innervated by the trigeminocervical nucleus caudalis can be effective for the management of individuals with CeH.

Cervicogenic headache pain has been mostly related to joint, disk, and ligament pain from the upper cervical spine [18]; however, clinicians should consider that the upper cervical spine also receives afferent inputs from muscles. The role of referred pain to the head elicited by muscle tissues has received particular interest in recent years. [19, 20] It has been hypothesized that muscle trigger points (TrPs) can play a relevant role in the genesis of headache. [21] A TrP is usually defined as a hyperirritable spot within a taut band of a skeletal muscle that elicits a referred pain upon examination. [21] From a clinical viewpoint, TrPs can be classified as active or latent. Active TrPs are those which local and referred pain reproduces the pain symptoms, for example, reproduce the headache pattern. [21] Trigger points have been reported to be present in patients with tension type headache, [19] migraine, [22] and cluster headache. [23] In addition, active TrPs have been also related to neck pain, [24, 25] a common symptom experienced by individuals with CeH. [3, 5, 8] However, data related to TrPs in CeH are scarce. An old article reported an association between TrPs and CeH, although it was a case series. [26] Furthermore, there is 1 case report where the referred pain elicited by sternocleidomastoid muscle active TrPs reproduced the headache pain pattern in CeH. [27] In addition, treatment of this active TrP was effective for the management of this patient. [27] It is possible that active TrPs in this muscle can be present in a subgroup of patients with CeH. No studies to date have examined the effectiveness of TrP manual therapy over sternocleidomastoid muscle in patients with CeH exhibiting active TrPs in this muscle. Before conducting a randomized, controlled clinical trial, it is necessary to conduct a pilot study as a first step to determine the potential effects of the intervention and, in the case that no significant results were found, to obtain preliminary data for a potential sample size calculation (if needed). Therefore, the purpose of this study was to conduct a pilot randomized clinical trial to determine if such a study were feasible and to identify the preliminary effects of TrP manual therapy in individuals with CeH with sternocleidomastoid muscle active TrPs.

---

Discussion

This study showed that a pilot trial could be conducted to determine if such a study were feasible. The study found preliminary findings that that manual therapy targeted to active TrPs in the sternocleidomastoid muscle may be effective for reducing headache and neck pain intensity and increasing motor performance of the deep cervical flexors, PPT, and active CROM when compared with simulated therapy in patients with CeH showing active TrPs in this muscle. Between-groups effect sizes were large for all the variables suggesting a clinical relevance of the changes after the treatment. In addition, between-group change scores surpassed the previously reported MCID for pain intensity. These results would support the hypothesis that, in patients with CeH where the referred pain from active TrPs in the sternocleidomastoid muscle reproduces the headache pain pattern, the application of TrP manual therapies can be an effective approach for these patients.

Our study is novel because previous studies investigating manual therapies in patients with CeH have only included joint interventions or exercise, but not TrP therapies. [10, 11, 12] There has only been 1 study where the authors applied TrP manual therapy to the masticatory muscle in individuals with CeH. [43] The results of our study are consistent with a previous case report where management of active TrP in the sternocleidomastoid muscle was effective for the treatment of a patient with CeH showing affectation of this muscle. [27] It should be noted that lower bound estimates of the 95% CIs for between-group changes exclude the MCID for pain intensity, the primary outcome, supporting statistically and clinically meaningful improvements in reduction of pain.

Some authors suggested that the sternocleidomastoid muscle may be a particularly common source of myofascial CeH. [44] Nevertheless, we should consider that not all patients with CeH exhibit active TrPs in the sternocleidomastoid muscle. In our study, at least 12 (24%) of 52 patients with CeH did not have active TrPs in this muscle. It would be interesting to determine the prevalence of active TrPs in the neck and head muscles in individuals with CeH.

The mechanisms why TrP manual therapy can be effective for reducing pain remain speculative. [45] Possible mechanisms include a reduction of TrP activity, restoration of the length of the muscle sarcomeres, reactive hyperemia within the TrP taut band, temporary elongation of the connective tissue, or reduction of sensitization mechanisms associated to TrPs. [45, 46] Another explanation may be that TrP manual treatment results in segmental antinociceptive effects. [47] In agreement with this hypothesis, we found significantly greater increases in PPT over the affected joints in those patients receiving TrP therapy. Again, between-groups differences exhibited large effect sizes, supporting a clinical effect of the intervention over mechanical sensitivity in those joints previously found to be hypersensitive in CeH. [48] The fact that TrP therapy decreases pressure pain sensitivity by increasing PPT is in line with a previous study. [49] Current and previous findings would support the antinociceptive effect of TrP interventions. Nevertheless, it is possible that different mechanisms are involved at the same time in the therapeutic effects of TrP manual treatment. Future studies are needed to determine the mechanisms effects of TrP manual therapies.

We also found that patients with CeH with active TrPs in the sternocleidomastoid muscle receiving TrP manual therapy experienced an increase in motor performance of the CCFT. This finding may be related to the fact that the sternocleidomastoid produces cervical flexion as its primary function. There is evidence associating relative excessive electromyographic activity of this muscle with weak deep cervical flexor activity during the CCFT. [37, 38] It has been found that patients with CeH also exhibit lower motor performance during the CCFT. [36, 50] Therefore, it is further possible that excessive activity of the sternocleidomastoid muscle during the CCFT induces TrP activation as previously suggested. [21, 39, 45] In fact, some studies have demonstrated that TrPs are associated with abnormal movement patterns [51] and increased motor neuron excitability [52] demonstrating the clinical relevance of TrPs in motor performance. In such scenario, manual therapies targeted to TrPs in the sternocleidomastoid muscle can restore the motor control performance of the CCFT.

Finally, we also found an increase in all CROMs after TrP manual therapy suggesting that TrP therapy can relive muscle tension of the taut bands in the sternocleidomastoid muscle. Our results agree with a previous study where patients with chronic neck pain and dizziness also exhibited increase in CROM after the application of ischemic compression over tender neck muscles. [53] In fact, we do not know if restoration of the length of the sarcomeres can be related to improvements in active CROM observed in those patients receiving TrP therapy. Because restricted CROM has been found to discriminate CeH from other headache subtypes, [50] it is expected an improvement of this outcome after a reduction of pain.

---

Limitations

Although a potential strength of the current controlled clinical trial was the inclusion of a simulated therapy group, we should recognize potential limitations. The sample size was small, which was related to the fact that this was a pilot randomized, controlled study. Thus, clinical findings still need to be confirmed with larger studies. We only assessed the effects of TrP manual therapy at 1–week follow-up period, so we cannot be certain if differences remain in the long term. Subject selection was based on CeH clinical criteria and the presence of active TrP in the sternocleidomastoid muscle. Therefore, current results should not be extrapolated to all patients with CeH. As well, it is possible that the simulated TrP treatment could have provided some beneficial effects, although the pressure was minimal. Finally, only 1 therapist provided the treatment in the current study, which may limit the generalizability of the results. Future trials should address these issues and consider including multiple therapists delivering the interventions.

---

Conclusion

This study provides preliminary evidence that a trial of this nature is feasible. The findings of this pilot trial suggests that TrP manual therapy may be effective for reducing headache and neck pain intensity and pressure pain sensitivity and for increasing motor performance of the deep cervical flexors and active CROM in individuals with CeH showing active TrPs in the sternocleidomastoid muscle. Studies including large sample sizes and longer follow-up periods are suggested.

---

Practical Applications

• The application of manual therapy of active TrP in patients with
  CeH improved pressure pain sensitivity, CROM, and deep
  cervical flexors motor performance.
  

• Manual therapy in active TrP point of sternocleidomastoid muscle
  decreased the intensity of neck and head pain in individuals with CeH.
  

• Future randomized controlled trials are necessary to determine the
  validity of these results.

---

References:

1. Headache Classification Subcommittee of the International Headache Society.
   The International Classification of Headache Disorders, 2nd edition.
   Cephalalgia. 2004; 24: 9–160

2. Bendtsen, L and Jensen, R.
   Epidemiology of tension-type headache, migraine and cervicogenic headache.
   in: C Fernández-de-las-Peñas, L Arendt-Nielsen, R Gerwin (Eds.)
   Tension type and cervicogenic headache: Patho-Physiology, Diagnosis and treatment.
   Jones and Bartlett Publishers, Baltimore; 2010: 7–13

3. Sjaastad, O, Fredriksen, TA, and Pfaffenrath, V.
   Cervicogenic headache: diagnostic criteria.
   Headache. 1998; 38: 442–445

4. Nilsson N.
   The Prevalence of Cervicogenic Headache in a Random Population Sample of 20-59 Year Olds
   Spine (Phila Pa 1976) 1995 (Sep 1); 20 (17): 1884–1888

5. Sjaastad, O and Fredriksen, TA.
   Cervicogenic headache: criteria, classification and epidemiology.
   Clin Exp Rheumatol. 2000; 18: S3–S6

6. Knackstedt H, Bansevicius D, Aaseth K, Grande RB, Lundqvist C, Russell MB.
   Cervicogenic Headache in the General Population:
   The Akershus Study of Chronic Headache
   Cephalalgia. 2010 (Dec); 30 (12): 1468–1476

7. Sjaastad, O and Bakketeig, LS.
   Prevalence of cervicogenic headache: Vaga study of headache epidemiology.
   Acta Neurol Scand. 2008; 117: 173–180

8. Pollmann, W, Keidel, M, and Pfaffenrath, V.
   Headache and the cervical spine: a critical review.
   Cephalalgia. 1997; 17: 801–816

9. Bryans R, Descarreaux M, Duranleau M, Marcoux H, Potter B, Ruegg R.
   Evidence-Based Guidelines for the Chiropractic Treatment
   of Adults With Headache
   J Manipulative Physiol Ther. 2011 (Jun); 34 (5): 274–289

10. Vernon, H, McDermaid, C, and Hagino, C.
    Systematic Review of Randomized Clinical Trials of Complementary/Alternative Therapies
    in the Treatment of Tension-type and Cervicogenic Headache
    Complementary Therapies in Medicine 1999 (Sep); 7 (3): 142—155

11. Fernández-de-las-Peñas, C, Alonso, C, Cuadrado, ML, and Pareja, JA.
    Spinal Manipulative Therapy in the Management of Cervicogenic Headache
    Headache. 2005 (Oct); 45 (9): 1260—1263

12. Chaibi, A and Russell, MB.
    Manual Therapies for Cervicogenic Headache: A Systematic Review
    J Headache Pain. 2012 (Jul); 13 (5): 351–359

13. Jull, G.
    Use of high and low velocity cervical manipulative therapy procedures by Australian manipulative physiotherapists.
    Austr J Physiother. 2002; 48: 189–193

14. Goadsby, PJ and Bartsch, T.
    The anatomy and physiology of the trigemino-cervical complex.
    in: C Fernández-de-las-Peñas, L Arendt-Nielsen, R Gerwin (Eds.)
    Tension type and cervicogenic headache: patho-physiology, diagnosis and treatment.
    Jones and Bartlett Publishers, Baltimore; 2010: 109–117

15. Bogduk, N.
    Cervicogenic headache: anatomical basis and patho-physiological mechanisms.
    Curr Pain Headache Rep. 2001; 5: 382–386

16. Bovim, G, Berg, R, and Dale, LG.
    Cervicogenic headache: anesthetic blockades of cervical nerves (C2-C5) and facet joint (C2/3).
    Pain. 1992; 49: 315–320

17. Meloche, JP, Bergeron, Y, Bellavance, A, Morand, M, Huot, J, and Belzile, G.
    Painful inter-vertebral dysfunction: Robert Maigne's original contribution to headache of cervical origin.
    Headache. 1993; 33: 328–334

18. Bogduk, N and Govind, J.
    Cervicogenic Headache: An Assessment of the Evidence on Clinical Diagnosis,
    Invasive Tests, and Treatment
    Lancet Neurol. 2009 (Oct); 8 (10): 959–968

19. Fernández-de-las-Peñas, C, Cuadrado, ML, Arendt-Nielsen, L, Simona, DG, and Pareja, JA.
    Myofascial trigger points and sensitisation: an updated pain model for tension type headache.
    Cephalalgia. 2007; 27: 383–393

20. Fernández-de-las-Peñas, C and Schoenen, J.
    Chronic tension type headache: what's new?.
    Current Opin Neurol. 2009; 22: 254–261

21. Simons, DG, Travell, J, and Simons, LS.
    Myofascial pain and dysfunction. The trigger point manual. Vol. 1. 2 ed.
    Williams & Wilkins, Baltimore; 1999

22. Fernández-de-las-Peñas, C, Cuadrado, ML, and Pareja, JA.
    Myofascial trigger points, neck mobility and forward head posture in unilateral migraine.
    Cephalalgia. 2006; 26: 1061–1070

23. Calandre, EP, Hidalgo, J, Garcia-Leiva, JM, Rico-Villademoros, F, and Delgado-Rodriguez, A.
    Myofascial trigger points in cluster headache patients: a case series.
    Head Face Med. 2008; 4: 32

24. De-la-Llave-Rincon, AI, Alonso-Blanco, C, Gil-Crujera, A, Ambite-Quesada, S.
    Myofascial trigger points in the masticatory muscles in patients with and without chronic mechanical neck pain.
    J Manipulative Physiol Ther. 2012; 35: 678–684

25. Muñoz-Muñoz, S, Muñoz-García, MT, Alburquerque-Sendín, F, Arroyo-Morales, M.
    Myofascial Trigger Points, Pain, Disability, and Sleep Quality in Individuals With
    Mechanical Neck Pain
    J Manipulative Physiol Ther. 2012 (Oct); 35 (8): 608–613

26. Jaeger, B.
    Are cervicogenic headaches due to myofascial pain or cervical spine dysfunction?.
    Cephalalgia. 1989; 9: 157–164

27. Roth, JK, Roth, RS, Weintraub, JR, and Simons, DG.
    Cervicogenic headache caused by myofascial trigger points in the sternocleidomastoid: a case report.
    Cephalalgia. 2007; 27: 375–380

28. Van Suijlekom, JA, de Vet, HCW, van den Berg, SGM, and Weber, WE.
    Inter-observer reliability of diagnostic criteria for cervicogenic headache.
    Cephalalgia. 1999; 19: 817–823

29. Gerwin, RD, Shanon, S, Hong, CZ, Hubbard, D, and Gevirtz, R.
    Interrater reliability in myofascial trigger point examination.
    Pain. 1997; 69: 65–67

30. Lucas, N, Macaskill, P, Irwig, L, Moran, R, and Bogbuk, N.
    Reliability of physical examination for diagnosis of myofascial trigger points: a systematic review of the literature.
    Clin J Pain. 2009; 25: 80–89

31. Jensen, MP, Turner, JA, Romano, JM, and Fisher, L.
    Comparative reliability and validity of chronic pain intensity measures.
    Pain. 1999; 83: 157–162

32. Cleland, JA, Childs, JD, and Whitman, JM.
    Psychometric properties of the Neck Disability Index and Numeric Pain Rating Scale in patients with mechanical neck pain.
    Arch Phys Med Rehabil. 2008; 89: 69–74

33. Fletcher, JP and Bandy, WD.
    Intra-rater reliability of CROM measurement of cervical spine active range of motion in persons with and without neck pain.
    J Orthop Sports Phys Ther. 2008; 38: 640–645

34. Vanderweeen, L, Oostendorp, RB, Vaes, P, and Duquet, W.
    Pressure algometry in manual therapy.
    Man Ther. 1996; 1: 258–265

35. Chesterson, LS, Sim, J, Wright, CC, and Foster, NE.
    Inter-rater reliability of algometry in measuring pressure pain thresholds in healthy humans, using multiple raters.
    Clin J Pain. 2007; 23: 760–766

36. Jull, G, Barrett, C, Magee, R, and Ho, P.
    Further clinical clarification of the muscle dysfunction in cervical headache.
    Cephalalgia. 1999; 19: 179–185

37. Falla, D, Campbell, CD, Fagan, AE, Thompson, DC, and Jull, G.
    Relationship between cranio-cervical flexion range of motion and pressure change during the cranio-cervical flexion test.
    Man Ther. 2003; 8: 92–96

38. Falla, D, Jull, G, Dall'Alba, P, Rainoldi, A, and Merletti, R.
    An electromyographic analysis of the deep cervical flexor muscles in performance of cranio-cervical flexion.
    Phys Ther. 2003; 83: 899–906

39. Fernandez-de-las-Peñas, C, Perez-de-Heredia-Torres, M, Molero-Sanches, A.
    Performance of the craniocervical flexion test, forward head posture, and headache clinical parameters in patients with chronic tension-type headache: a pilot study.
    J Orthop Sports Phys Ther. 2007; 37: 33–39

40. Dommerholt, J and McEvoy, J.
    Myofascial trigger point release approach.
    in: CH Wise (Ed.) Orthopaedic manual physical therapy: from art to evidence.
    FA Davis, Philadelphia; 2010: 114–135

41. Vernon, H and Schneider, M.
    Chiropractic Management of Myofascial Trigger Points and Myofascial Pain Syndrome:
    A Systematic Review of the Literature
    J Manipulative Physiol Ther. 2009 (Jan); 32 (1): 14–24

42. Lewit, K.
    Manipulative therapy in rehabilitation of the locomotor system. 3nd ed.
    Butterworth Heinemann, Oxford; 1999

43. Von Piekartz, H and Ludtke, K.
    Effect of treatment of temporomandibular disorders in patients with cervicogenic headache: a single-blind, randomized, controlled study.
    Cranio. 2011; 29: 43–56

44. Cibulka, MT.
    Sternocleidomastoid muscle imbalance in a patient with recurrent headache.
    Man Ther. 2006; 11: 78–82

45. Simons, DG.
    Understanding effective treatments of myofascial trigger points.
    J Bodywork Mov Ther. 2002; 6: 81–88

46. Hou, CR, Tsai, LC, Cheng, KF, Chung, KC, and Hong, CZ.
    Immediate effects of various physical therapeutic modalities on cervical myofascial pain and trigger-point sensitivity.
    Arch Phys Med Rehabil. 2002; 83: 1406–1414

47. Srbely, JZ.
    New trends in the treatment and management of myofascial pain syndrome.
    Curr Pain Headache Rep. 2010; 14: 346–352

48. Bovim, G.
    Cervicogenic headache, migraine, and tension-type headache. Pressure-pain threshold measurements.
    Pain. 1992; 51: 169–173

49. Renan-Ordine, R, Alburquerque-Sendín, F, Rodrígues-de-Souza, D, Cleland, JA.
    Effectiveness of myofascial trigger point manual therapy combined with a self-stretching protocol for the management of plantar heel pain: a randomized controlled trial.
    J Orthop Sports Phys Ther. 2011; 41: 43–50

50. Jull G, Amiri M, Bullock-Saxton J, Darnell R, Lander C.
    Cervical Musculoskeletal Impairment in Frequent Intermittent Headache.
    Part 1: Subjects with Single Headaches
    Cephalalgia 2007 (Jul); 27 (7): 793–802

51. Lucas, KR, Rich, PA, and Polus, BI.
    Muscle activation patterns in the scapular positioning muscles during loaded scapular plane elevation: the effects of latent myofascial trigger points.
    Clin Biomech. 2010; 25: 765–770

52. Ge, HY, Zhang, Y, Boudreau, S, Yue, SW, and Arendt-Nielsen, L.
    Induction of muscle cramps by nociceptive stimulation of latent myofascial trigger points.
    Exp Brain Res. 2008; 187: 623–629

53. Lin, YC, Lai, CH, Chang, WH, Tu, LW, Lin, JC, and Chou, SW.
    Immediate effects of ischemic compression on neck function in patients with cervicogenic cephalic syndrome.
    J Manipulative Physiol Ther. 2012; 35: 301–307

Return to CERVICOGENIC HEADACHE

Return to MYOFASCIAL TRIGGER POINTS

Since 9–30–2013