Body posture changes in women with migraine with or without temporomandibular disorders

Abstract

Background

Migraine and temporomandibular disorders (TMDs) are reported to be associated. However, there are no reports on the association among migraines, TMDs and changes in body posture.

Objectives

To assess changes in body posture in women suffering migraines with or without TMD compared with a control group.

Method

Sixty-six women with a mean age of 18 to 45 years participated in this study. The groups were composed of 22 volunteers with migraine and TMD (MTMD), 22 volunteers with migraines without TMD (MG) and 22 women in the control group (CG). Static posture was assessed by photogrammetry, and 19 angles were measured.

Results

Postural asymmetry was observed in the face for 4 angles measured on the frontal plane in the MG group and for 4 angles of the trunk in the MG and MTMD groups with respect to CG. However, for comparisons between MTMD and CG, clinical relevance was identified for two angles of the sagittal plane (Cervical and Lumbar Lordosis, Effect Size - ES - moderate: 0.53 and 0.60). For comparisons between the MG and CG, the clinical relevance/potential was verified for three angles with moderate ES (ES>0.42). The clinical relevance when comparing MTMD and CG was identified for four angles of facial symmetry head inclination (ES>0.54) and for two angles between MG and CG (ES>0.48).

Conclusion

The results demonstrated the presence of postural changes compared with a control group in women with migraines with or without TMD, and there were similar clinically relevant postural changes among the patients with migraines with and without TMD.

Introduction

Several methods for assessing static posture have been reported in the literature, including qualitative methods, such as visual observation, and quantitative methods, where images are analyzed using specific software such as photogrammetry^1,2. Prior studies have demonstrated good levels of intra- and interrater reliability for the technique of assessing posture by photogrammetry^3-5.

Body posture changes can be associated with many disorders, including painful syndromes⁶, such as migraines⁷, and musculoskeletal disorders⁸, such as temporomandibular disorders (TMD)^9-13. However, assessments of craniocervical posture have only previously been tested in patients with TMD¹³ and in individuals with migraines⁷.

One possible explanation for the association between changes in craniocervical posture in patients with migraines and TMD is the mechanism of convergence of trigeminal and cervical afferents onto the same neurons in the brainstem¹⁴. This convergence of afferent nerves can lead to the development of cervical pain symptoms in patients with TMD and migraines, resulting in a limited range of motion¹⁵ and changes in head and cervical posture. Changes in body posture may appear as a compensatory mechanism, especially in adjacent body segments.

Migraine is a chronic headache that manifests episodically and is characterized by recurring attacks involving headaches that are typically unilateral, pulsating and of moderate to severe intensity¹⁶. Migraines are more common in women^17,18.

TMD is a disorder of the temporomandibular joints (TMJs) and/or masticatory muscles and associated structures¹⁹ and can cause the following signs and symptoms: pain in the preauricular region, pain in the TMJ and associated structures, restricted mandibular movement, and TMJ noise^20-22. In Brazil, 37.5% of the population may present with one of these symptoms²³.

In addition to the association among TMD, migraines, and changes in body posture, there are published reports of a possible association between migraine and TMD^24-28. One of the described mechanisms is the ability of TMD to aggravate a pre-existing headache or to acting as a risk factor for migraine²⁶.

Despite indications that both conditions are associated with changes in body posture, we could find no published studies that examined the effect of the overlap of these disorders on the development of craniocervical and global posture or studies on the presence of posture changes in individuals with those disorders separately. Therefore, the hypotheses tested in the present study are that there are body posture differences in women with migraines compared with a group of women without migraine and that the presence of both migraines and TMD amplifies such differences.

The present study aimed to detect changes in static body posture in patients with migraine in the presence or absence of TMD when compared to a control group (CG).

Method

This was a cross-sectional case-control study with three groups of 22 female participants aged 18 to 50 years. The groups consisted of patients with migraines and TMD (MTMD), patients with migraines without TMD (MG), and volunteers in the CG. Taking the forward head posture (FHP) as the main variable, a power effect of 0.99 and an effect size of 0.74 (α=0.05) were obtained from a sample size of 66 subjects (22 per group). The GPower® 3.0.10 software (Franz Faut, Universität Kiel Germany, 2008) was used for analyses. No significant differences were found between groups with respect to the anthropometric data of the samples (Table 1).

Table 1.

Mean values (standard deviations, SD) of the anthropometric data and descriptions of the clinical data of the studied samples.

Variables/Groups	Migraine + TMD (n=22)	Migraine (n=22)	Control (n=22)	P-level*
	Mean (SD)	Mean (SD)	Mean (SD)
Age (years)	30.27 (11.46)	31.72 (9.82)	24.41 (6.95)	NS
Height (m)	1.65 (0.06)	1.65 (0.05)	1.65 (0.08)	NS
Weight (kg)	62.31 (8.15)	66.81 (18.69)	63.64 (10.75)	NS
	Raw values
Time of onset of disease (years)	11.5	14.3	NA
Days of migraine attacks	7.8	8.3	NA
Side of headache complaint
R	8	6	NA
L	3	3	NA
Bilateral/Unilateral	11	13	NA
TMD mixed
Group Ia/IIa**	14	0	0
Group Ib/IIb**	1	0	0
Group Ia/IIc**	4	0	0
Myogenous TMD
Group Ia**	3	0	0

NA = not applicable; NS = not significant

^*ANOVA (p <0.05);

^**Description of RDC/TMD diagnostics subgroups Group I - Myogenous Diagnosis: Ia - Ib and Myofascial Pain - Myofascial pain with limited opening. Group II - Disc Displacement: IIa - disc displacement with reduction; IIb - disc displacement without reduction and with limited opening; and IIIc- disc displacement without reduction and without a limited opening. Group III - Arthralgia, Arthritis and Osteoarthritis: IIIa - Arthralgia; IIIb - IIIc and TMJ Osteoarthritis - Osteoarthritis of the TMJ.

This study was approved by the Research Ethics Committee of the Teaching Hospital at the School of Medicine of Ribeirão Preto, Universidade de São Paulo - HCFMRP-USP, Ribeirão Preto, state of São Paulo-SP, Brazil, under protocol number 4732/2011. All study volunteers signed an informed consent form to participate in the study.

Inclusion and exclusion criteria

Patients with migraines were selected consecutively from the Craniofacial Pain Outpatient Clinic of HCFMRP-USP.

Migraine was diagnosed by neurologists according to the criteria set by the International Classification of Headache Disorders ¹⁶. Patients with a stable clinical condition for at least three months with a frequency of 2-12 days with migraine pain per month were included. Patients were assessed for the presence of TMD according to axis I of the Research Diagnostic Criteria for Temporomandibular Disorders (RDC/TMD)²⁹.

Volunteers with no prior diagnoses or signs or symptoms of migraine or TMD in the last 12 months were accepted to the CG. These volunteers were selected from employees and students at the University of São Paulo Campus. The CG volunteers were selected based on their similar weight, height and age relative to the MTMD and MG groups.

The exclusion criteria were as follows: a diagnosis of any other type of headache (except infrequent episodic tension-type headaches of fewer than three attacks per year), any other chronic pain, diagnosed postural changes (scoliosis/limb length discrepancies/hyperkyphosis/amputations/hemiplegias), acute pain at the time of assessment, previous treatment by postural intervention, and a history of traumas involving clinical repercussions (cranial traumas/bone fractures/cervical whiplash).

Assessment of temporomandibular disorder (TMD)

RDC/TMD axis I²⁹ was applied by a single trained examiner as recommended by the international consortium: http://www.rdc-tmdinternational.org/. The tool consists of a clinical assessment protocol widely used in research²⁹. The RDC/TMD consists of measuring the range of mandibular motion, an assessment of pain on palpation, and observations of clicking and crepitus during motion³⁰.

Assessment of body posture

The patients were assessed using photographic records in the orthostatic position from the anterior, posterior, and lateral views. The volunteers were instructed to look at a fixed point on the wall at a distance of 1 m. After a brief walk around the laboratory, the volunteers were asked to position themselves at the site to be photographed.

A Canon Rebel EOS-300 digital camera was placed on a tripod, and the tripod center was positioned at a fixed distance of 4 m from the volunteer³². For whole body photographs, the center of the camera lens was fixed at a height corresponding to the individual's midpoint; a 35 mm objective was used^31,32. For facial photographs, the center of the camera lens was positioned on the center of the glabella; a 105 m objective was used³³.

The method for obtaining and recording images has been previously described⁴. Anatomical reference points were defined based on bone palpation by a single examiner who was previously trained on the placement of markers⁴, which demonstrated good levels of experimental reproducibility (Figure 1).

Figure 1.

A) Schematic picture demonstrating the 21 anatomical points considered for postural analysis. B) Illustrative scheme from a sagittal view. forward head posture(FHP), cervical lordosis angle (CLA), thoracic kyphosis angle (TKA), and Lumbar lordosis angle (LLA). Anatomical points considered: 1 - sternoclavicular joints; 2 - anterosuperior iliac spines; 3 - anterior tibial tuberosity; 4 - second toe, metatarsophalangeal joint; 5 - tragus of the ear; 6 - acromion of scapula; 7 - lateral epicondyle of elbow; 8 - metacarpophalangeal joint of the 3rd finger; 9 - greater trochanter; 10 - head of fibula; 11 - malleolus lateral ankle; 12 - occipital protuberance; 13 - third cervical vertebra; 14 - 7th cervical vertebra; 15- seventh thoracic vertebrae; 16 - twelfth thoracic vertebra; 17- third lumbar vertebra; 18- fifth lumbar vertebra; 19 - posterior superior iliac spines; 20 - posterior inferior iliac spines; and 21 - midpoint of poplietal line.

Photographic analysis

The images were analyzed using the application Corporis Pro 3.1 (Data Hominis Tecnologia^®, Uberlândia, Minas Gerais, Brazil) using measurements of the angles formed by the lines traced from the anatomical points.

All images were analyzed by a single examiner blinded to the study groups. Thirteen angles of asymmetry in the frontal plane were obtained from the anterior and posterior views, and six angles were obtained in the sagittal plane.

Nineteen angles previously described in the literature were analyzed^4,5. The way in which these angles were traced during the analyses and the method of interpretation are described in Table 2.

Table 2.

Description of the method of measurement of the 19 angles considered and their benchmarks.

Angle		Acronym	Obtaining/Reference Values (x = angle)
Angles Frontal Plane - Face and Shoulder Girdle / Anterior View / Posterior View
Internal Orbicular Angle		IO
External Orbicular Angle		EO	Measured from left to right and extending forward on the horizontal
Comissura Labiorum Angle		CLA
Acromion-Clavicular joint Angle		AC
Sternoclavicular Joint Angle		SC	X = 180: value measured
Angle of Ear Tragus		AET	Value = 180: absence of asymmetry
Anterior Superior Iliac Spines Angle		AS	Values <180: Suggests tilt to the left
Angle between the Tibial Protuberance		ATP	Values> 180: suggested tilt to right
Inferior Angle of the Scapula		IS
Central Region of Olecranon Angle		OC
Posterior Superior Iliac Spines Angle		PS
Posterior Inferior Iliac spines Angle		PI
Popliteal Line Angle		PL
Sagittal Plane Angles	Method and Reference Values
Forward Head Posture (FHP)	Measured from the tragus of the ear to the spinous process of C7, extending forward on the horizontal line.*
Cervical lordosis (CL)	Angle formed by the straight lines between the occipital protuberance and the spinous process of C7 that intersects the horizontal line between C4 and the true vertical line - plumb line*
Thoracic kyphosis (TKA)	Angle formed by the straight lines between the spinous process of C7 and T12 that intersect the horizontal line between T7 and the true vertical line*
Lumbar lordosis (LLA)	Angle formed by the straight lines between the spinous processes of T12 and L5 that intersect the horizontal line between L3 and the true vertical line*
Knee flexor (KF)	Angle formed by the straight line between the points on the greater trochanter of the femur and the head of the fibula and the straight line that passes through the head of the fibula and extends vertically downwards**
Tibiotarsal angle (TTA)	Angle formed by the straight line between the head of the fibula and the lateral malleolus of the foot and the straight line that joins the lateral malleolus and the head of the fifth metatarsus*

^*No reference values/**EJ>180: suggested knee hyperextension and EJ<180: suggests knee flexion

Reliability

The analysis of intrarater reliability of the tracings was performed by randomly selecting 15 records of study participants. The tracings were initially made and then repeated after a period of seven days. Analyses were always performed by the same previously trained examiner (20 hours of training).

Data analysis

Analysis of variance (ANOVA, p<0.05) was used to compare the mean values of angles measured across the three groups of the present study and the post-hoc Bonferroni test. The Intraclass Correlation Coefficient (ICC) was used to test the reliability of the measurements. The following ranges were considered when rating the reliability: ICC<0.4, poor reliability; 0.4<ICC<0.75, moderate reliability; and ICC>0.75, excellent reliability³⁴. The associations between posture tracings (dependent variables) and the following independent variables were analyzed by multiple linear regression: weight, age, and height. The significance of the final model was tested by the ANOVA F-test, and the goodness of fit was assessed by the adjusted coefficient of determination (adjusted R²). The SPSS, Inc. software version 17 (Chicago IL, USA) was used to perform the statistical analyses.

The following formula was used to analyze the standard error of the measurement: SEM=SD √ICCI(1-ICC)³⁵. The effect size was analyzed using the following formula: ES=(MG1-MG2)/SD polled, where ES= effect size, M=mean, SD pooled = pooled standard deviation (SD pooled = √SD₁² (N₁-1) + SD₂² (N₂-2)/N₁+N₂-2, where N = sample size, SD = standard deviation for each group)³⁶. The effect sizes were classified according to Cohen³⁷: small effect size (SES), 0.20 (0-0.39); medium effect size (MES), 0.50 (0.4-0.79); and large effect size (LES), >0.80.

The Minimal Important Difference (MID) was calculated by multiplying the ES of 0.2 and 0.5 (small and medium ES, respectively, according to Cohen³⁷) by the SD pooled across two groups using the following formulas³⁸: MID₁ = 0.2 x SD pooled and MID₂ = 0.5 x SD pooled.

In the present study, clinically relevant differences were defined as follows: a) a mean difference between the groups greater than the MID³⁸; b) an effect size greater than 0.40; and c) a mean difference between groups greater than the SEM.

Results

The MG and MTMD did not differ in terms of the years since disease onset, laterality of pain, or the number of attacks per month (Table 1). There were no significant differences between the groups with respect to age, weight, or height. Multiple linear regression revealed only a single association between the acromioclavicular joint angle (AC) and the independent variables weight and age, with R²<0.30 and p<0.05.

The TMD diagnostics obtained according to the RDC/TMD are described in Table 1.

Reliability was only classified as moderate for two angles (EO and CLA). Reliability was considered excellent for the remaining angles (17 angles) (Table 3)³⁵. Despite having moderate (EO, CLA) or excellent (SC, ATP, CLA) ICC values, some angles exhibited a wide confidence interval classified as excellent to low (Table 3).

Table 3.

Intraclass Correlation Coefficients (ICC), mean values and confidence intervals (95%) of the 19 measured angles (degrees) in the patients with migraines (MG), patients with migraines and temporomandibular disorders (MTMD), and the control group (CG).

Angles	Mean ICC (CI 95%)	MTMD (n=22) Mean (CI 95%)	MG (n=22) M ean (CI 95%)	CG (n=22) Mean (CI 95%)
EO	0.71 (0.90-0.15)	181.71 (182.12-181.30)	182.22 (182.59-181.84)*	181.51 (181.86-181.16)
IO	0.76 (0.80-0.40)	181.24 (181.41-181.07)	182.21 (182.61-181.96)*	181.53 (181.01-181.04)
AC	0.88 (0.96-0.66)	181.07 (181.24-180.91)*	182.29 (182.62-181.96)	182.48 (182.89-182.08)
SC	0.78 (0.92-0.35)	181.64 (181.44-181.03)	182.05 (182.39-181.71)*	181.64 (182.04-181.23)
AET	0.82 (0.84-0.49)	181.11 (181.28-180.94)	181.75 (182.11-181.39)*	181.26 (181.52 - 181)
CLA	0.66 (0.88-0.03)	181.16 (181.36-180.96)	181.55 (181.86-181.25)	181.21 (181.51-180.91)
FHP	0.96 (0.98-0.90)	67.83 (68.89-66.78)	69.88 (71.19-68.58)	73.03 (74.68-71.39)*
CL	0.79 (0.93-0.39)	14.63 (15.04-14.23)	14.99 (15.39-14.59)	16.38 (17.04-15.72)*
TKA	0.97 (0.99-0.93)	40.13 (41.02-39.24)*	42.93 (44.60-41.27)*	47.27 (49.03-45.51)
LLA	0.93 (0.97-0.81)	27.19 (28.18-26.20)*	25.48 (26.47-24.48)*	22.68 (23.32-22.04)
KF	0.99 (1.00-0.99)	181.53 (183.44-179.62)	182.26 (183.80-180.72)	182.02 (184.18-179.86)
TTA	0.98 (0.99-0.96)	100.31 (101.41-99.20)	101.00 (102.18-99.82)	99.47 (101.34-97.60)
IS	0.98 (0.99-0.95)	181.81 (182.49-181.13)	181.29 (181.48-180.09)	179.12 (180.52-177.71)*
OC	0.88 (0.96-0.66)	180.86 (181.49-180.22)	181.03 (181.77-180.29)	180.02 (180.66-179.38)
PS	0.98 (0.99-0.94)	181.84 (182.68-180.59)	181.85 (183.04-180.66)	180.13 (181.34-178.92)
PI	0.96 (0.98-0.89)	183.27 (184.48-182.05)	183.86 (184.97-182.75)	180.58 (183.04-180.13)*
PL	0.95 (0.98-0.87)	182.10 (183.20-181.01)	182.65 (184.97-182.75)	179.89 (180.93-178.85)*
AS	0.86 (0.95-0.60)	184.40 (183.01-181.36)	182.23 (184.21-182.26)	182.95 (184.04-181.85)
ATP	0.76 (0.92-0.31)	181.76 (181.80-180-87)	181.95 (181.26-181.62)	181.48 (181.83-181.13)

^*Difference compared to the other groups - ANOVA, p<0.05 and post-hoc Bonferoni. NS: Not Significant. IO - internal orbicular angle; EO - external orbicular angle; CLA - comissura labiorum angle; AC - acromion-clavicular joint angle; SC - sternoclavicular joint angle; AET - angle of ear tragus; AS - anterior superior iliac spines angle; ATP - angle between tibial protuberance; IS - inferior angle of scapula; OC - central region of olecranon angle; PS - posterior superior iliac spines angle; PI - posterior inferior iliac spines angle; PL - popliteal line angle; FHP - forward head posture; CL - cervical Lordosis; TKA - thoracic kyphosis; LLA - lumbar lordosis; KF - knee flexor; TTA - tibiotarsal angle

From the frontal view, the MG exhibited greater mean values than the MTMD and the CG for the EO and IO values (Table 3). The AC was also significantly smaller in the MTMD. The sternoclavicular joint angle (SC) and the angle of the ear tragus (AET) were significantly greater in the MG than in the MTMD or the CG (Table 3).

However, the differences between the MG and CG were clinically relevant (potential or not) only for EO (ES=0.49; MES), AET (ES=0.44; MES), and AC (ES=1.36; LES); the effect sizes obtained for these measurements were at least moderate, and the mean differences between the groups were greater than the MID (MID 0.2 and 0.5) and the SEM (Table 4). All significant differences found between the MTMD and MG with respect to the angles of facial symmetry/head inclination were clinically relevant, with the exception of the external orbicular angle (EO). The IO, AC, and SC had an ES>0.80 (LES), and the AET and CLA had ESs between 0.40 and 0.80 (MES), with the mean differences between the groups greater than the MID (MID 0.2 and 0.5) and the SEM (Table 4).

Table 4.

Mean difference, standard error of measurement (SEM), effect size and minimal important difference for the 19 measured angles (degrees) compared among patients with migraines (MG), patients with migraines and temporomandibular disorders (MTMD), and the control group (CG).

Angles	Mean Difference (MTMD-CG)	Mean Difference (MG-CG)	Mean Difference (MTMD-MG)	SEM	ES** (MTMD vs. CG)	ES** (MG vs. CG)	ES** (MTMD vs. MG)	MID 0.2/0.5 (MTMD vs. CG)	MID 0.2/0.5 (MG vs. CG)	MID 0.2/0.5 (MTMD vs. MG)
EO	0.20	0.71*	–0.50*	0.45	–0.13 = SES	–0.49=MES	–0.30 = SES	0.31/0.79	0.29/0.72 - PCR	0.34/0.84
IO	–0.28	0.68*	–0.97*	0.57	0.20 = SES	–0.31=SES	–0.92 = LES	0.29/0.73	0.44/1.09	0.21/0.53- CR
AC	–1.41*	–0.20	–1.21*	0.34	1.36 = LEF	0.13=SES	–1.63 = LES	0.21/0.52 - CR	0.30/0.75	0.15/0.37 - CR
SC	–0.40	0.41*	–0.82*	0.56	0.36 = SES	–0.27=SES	–0.95= LES	0.23/0.56	0.30/0.75	0.17/0.43 - CR
AET	–0.15	0.48*	–0.64*	0.30	0.28 = SES	–0.44=MES	–0.73= LES	0.11/0.27	0.22/0.55 - PCR	0.17/0.43 - CR
CLA	–0.05	0.34	–0.40	0.25	0.07 = SES	–0.34=SES	–0.54 = MES	0.14/0.35	0.20/0.50	0.15/0.37 - CR
FHP	–5.20*	–3.15*	–2.05	0.79	0.25 = SES	0.13=SES	–0.13 = SES	4.17/10.44	4.81/12.04	3.08/7.71
CLA	–1.75*	–1.38*	–0.36	0.73	0.53 = MES	0.42=MES	–0.20 = SES	0.66/1.65 - CR	0.66/1.64 - CR	0.35/0.89
TKA	–7.14*	–4.34*	–2.81	0.73	0.34 = SES	0.14=SES	–0.14 = SES	4.24/10.61	6.39/15.99	3.88/9.70
LLA	4.51*	2.79*	1.71	0.31	–0.60=MES	–0.37= SES	0.16=SES	1.51/3.79 - CR	1.53/3.82	2.15/5.37
KF	–0.49	0.24	–0.73	1.04	0.01=SES	–0.01=SES	–0.02=SES	9.10/22.76	7.71/19.28	6.59/16.47
TTA	0.84	1.53	–0.69	0.90	–0.03=SES	–0.06=SES	–0.05=SES	5.16/12.90	5.36/13.39	2.86/7.14
IS	2.69	2.17	0.52	0.48	–0.20=SES	–0.12=SES	0.05=SES	2.67/6.68	3.73/9.33	2.07/5.18
OC	0.84	1.01	–0.18	0.53	–0.19=SES	–0.19=SES	–0.03=SES	0.89/2.23	1.05/2.62	1.05/2.61
PS	1.51	1.72	–0.21	0.41	–0.11=SES	–0.11=SES	–0.02=SES	2.79/6.98	3.14/7.85	2.73/6.84
PI	1.68	2.28	–0.59	0.70	–0.09=SES	–0.12=SES	–0.04=SES	3.92/9.81	3.67/9.18	2.96/7.40
PL	2.22	2.76	–0.54	0.56	–0.18=SES	–0.21=SES	–0.04=SES	2.48/6.21	2.61/6.53	2.74/6.85
AS	–0.76	0.29	–1.05	0.98	0.07=SES	–0.04=SES	–0.12=SES	2.06/5.15	1.32/3.30	1.79/4.46
ATP	–0.14	0.47	–0.62	0.41	0.08=SES	–0.71= MES	–0.35=SES	0.37/0.92	0.13/0.34 - CR	0.35/0.88

^*Significant difference - ANOVA, p<0.05 and post-hoc Bonferoni. Scoring criteria: When the effect size (ES) and the mean difference between the groups were higher than the minimal important difference (MID), the difference was considered clinically relevant (CR). If the ES is moderate and the mean difference between the groups is greater than the MID, then the measure was classified as potentially clinically relevant (PCR). If the ES is small / moderate and the average difference between the groups is greater than both MIDs, the measurement is classified as PCR. If the ES is small and the average difference between the groups is greater than the MID, the measure cannot be termed clinically relevant. If the ES is small and the average difference between the groups is smaller than the MID, the measure is classified as not clinically relevant. Rating

^**The effect sizes followed the recommendation of Cohen37 - small ES (SES): 0:20 (0-0.39); moderate Effect Size: 0.50 (0.4-0.79); large ES:>0.80, ES: effect size, MID: minimal important difference, PCR: Potentially clinically relevant, CR: clinically relevant, SES: small effect size, MES: moderate effect size, LEF: large effect size.

In the sagittal plane, smaller angles were observed in the MG and MTMD compared to the CG for forward head posture (FHP), cervical lordosis (CL) and thoracic kyphosis (TKA). The mean lumbar lordosis angle (LLA) was significantly greater in the MG and MTMD than in the CG. The MG and MTMD differed significantly with respect to TKA and LLA (smaller TKA and greater LLA in the MTMD) (Table 3). Only the significant differences for CLA (ES=0.53 and 0.42, both MES) and LLA (ES=0.60, LES) were clinically relevant; the ESs were moderate, and the mean differences between the groups were greater than MID 0.2, MID 0.5, and the SEM (Table 4).

In the frontal plane posterior view, the inferior angle of the scapula (IS), the posterior inferior iliac spines (PI), and the central angle of the popliteal line (PL) were significantly smaller in the CG compared with the MG and MTMD (Table 3). However, none of these angles exhibited clinically relevant differences (Table 4).

Discussion

The main objectives of the present study were to test for differences in postural patterns between women with migraine with or without TMD compared with a CG and to test whether the presence of migraine and TMD can exacerbate such differences. The hypothesis tested was partly proved because body postural changes were detected in women with migraine with and without TMD relative to the CG; however, the analysis of clinical relevance revealed that the posture changes were similar in the MG and MTMD. Thus, this analysis demonstrated that some of the significant differences observed should be interpreted cautiously.

Regarding the instrument for posture analysis used in the present study, there was excellent intrarater reliability for most of the postural recordings. The ICC exhibited a wide confidence interval for five angles (EO, SC, CLA, ATP and CL), ranging from excellent to low ICCs. However, of these angles, only CL and SC were statistically significant and clinically relevant, and the lower bounds of the confidence intervals were very near the value considered moderate (0.39 and 0.35, respectively). These findings suggest low variability for the measurements used and low examiner error for the preparation of the angle tracings (SEM between 0.25 and 1.04). Prior studies have used the same method for assessing posture and reported moderate to excellent intra- and inter-examiner reliability^4,5.

The results of the present study revealed significant differences in the postural angles between groups, and the main results were as follows: a) there were clinically relevant differences between the MG and MTMD relative to the CG for only two angles in the sagittal plane and one angle of asymmetry of the shoulder girdle, with potentially clinical differences in two angles of facial asymmetry; b) there was no intensification of posture changes in women with migraine with TMD compared with those suffering only migraines, as it was not possible to assign clinical relevance to the differences between the MG and MTMD; and c) asymmetries were more often found in the MG than in MTMD.

Migraine patients with or without TMD exhibited smaller angles of forward head posture, cervical lordosis, and thoracic kyphosis and a greater angle of lumbar lordosis compared with the CG. However, the only clinically relevant findings were the cervical lordosis angle in the MG and MTMD compared with the CG and the lumbar lordosis angle in the MTMD. Thus, the remaining differences can be considered statistically significant but clinically irrelevant.

The postural pattern of forward head posture has been observed in patients with headache. Watson and Trott³⁹ and Fernández-de-las-Peñas et al.⁴⁰ reported a smaller craniovertebral angle (FHP) in patients with cervicogenic and tension-type headaches, respectively. In another study, Fernández-de-las-Peñas et al.⁷ also reported a smaller craniovertebral angle in migraine patients compared with a CG (suggesting greater forward head posture in the migraine group). Shifting the head forward may represent an antalgic posture used to reduce pain. Although a significant reduction in the craniovertebral angle was observed in migraine patients with or without TMD in the present study, this finding was not clinically relevant. Our results demonstrate that the MID for this measurement was at least 10.5º (considering a moderate effect size of 0.5), but the observed mean differences between the groups were 5.20º and 3.15º for the MG and MTMD, respectively, relative to the CG (Table 4).

Published reports disagree on the presence of TMD and forward head posture. Visscher et al.⁴¹ and Iunes et al.⁴² did not observe differences in forward head posture between patients with TMD and healthy controls. In contrast, Lee et al.⁴³ reported greater forward head posture in patients with TMD compared with a CG. None of the aforementioned studies analyzed clinical relevance. Armijo-Olivo et al.⁴⁴ analyzed clinical relevance to investigate craniocervical posture parameters in patients with TMD compared with a CG. The authors identified a statistically significant but clinically irrelevant difference in only one of the posture parameters analyzed (eye-tragus-horizontal angle); the mean difference between the TMD and control groups (2.6º) was less than the MID (2.7º) for an effect size of 0.5.

It is important to highlight the clinical relevance of two angles analyzed in the present study, the cervical lordosis and lumbar lordosis angles. The increase in the cervical lordosis angle was clinically relevant for migraine patients with and without TMD. The decrease in lumbar lordosis (greater lumbar lordosis angle) was clinically relevant for MTMD. Based on these findings, it is possible to suggest that body posture changes in migraine patients without TMD are restricted specifically to the cranial segment, whereas compensatory changes at other levels of the spine can occur in migraine patients with TMD. These data call attention to the importance of assessing body posture in migraine patients.

The angles of facial symmetry/head inclination were greater in the MG, suggesting that migraine without TMD is more related to postural changes in the frontal plane of the face. Of the six angles of facial symmetry/head inclination and shoulder girdle analyzed in the present study, four angles (EO, SC, AET, CLA) exhibited significant and clinically relevant differences (ES>0.5) between patients in the MG and those in the MTMD, and two angles (EO and AET) were potentially clinically relevant based on the mean difference between the MG and CG.

It is possible that such changes are related to facial asymmetry or head and cervical inclination in the frontal plane because there was a tendency for tilt to one side (value greater than 180º - tilt to the right). These findings are possibly explained by the more frequent occurrence of headache on one side. Prior studies correlating the side most commonly afflicted with migraine to possible musculoskeletal changes reported a greater presence of active trigger points ipsilateral to the pain⁷, which could lead to the development of compensatory antalgic posture on the same side.

The shoulder girdle symmetry angle (AC) was significantly smaller in the MG and MTMD than in the CG. It should be noted that the greater weight of migraine patients and lower age of the controls could have affected these results because multiple regression analysis revealed a weak association between the variables. Therefore, the observed differences cannot be attributed exclusively to the presence of migraine and/or TMD.

These findings are novel, and there are no prior published reports involving the study of postural changes in migraine patients and the association between migraine and TMD. One limitation of the present study was the lack of a group with TMD without migraine. Longitudinal studies are required to test the causal relationships between migraine/TMD and posture and to confirm the present findings. Knowledge of these factors will be important for guiding decision-making regarding physiotherapeutic interventions for these patients and may help to select a more global therapeutic approach.

Conclusion

The results of the present study demonstrated body posture changes in women with migraine with or without TMD compared with a CG. Such posture changes were similar between the MG and MTMD. Clinically relevant differences were observed between the MG and MTMD compared with the control group for two angles in the sagittal plane in the spinal region. Potentially clinically relevant differences were observed for the angles of facial asymmetry/head inclination for the MG relative to MTMD and CG. These findings call attention to the importance of assessing craniocervical posture in migraine patients and more comprehensive body posture assessment in migraine patients with TMD.

Funding Statement

We would like to thank the São Paulo Research Foundation (FAPESP) for financial support (Process 2009/17580-4 and 2010/15034-0).