1 Volume 21 2022 e228356 Original Article Braz J Oral Sci. 2022;21:e228356http://dx.doi.org/10.20396/bjos.v21i00.8668356 1 Post graduate Program in Human Movement Sciences, Methodist University of Piracicaba - UNIMEP - Piracicaba (SP), Brazil. 2 Post graduate Program of Dental Clinic, concentration area Oral and Maxillofacial Surgery, Piracicaba Dental School, University of Campinas – UNICAMP – Piracicaba (SP), Brazil. Corresponding author: Adriana Pertille Graduate Program in Human Movement Sciences, Methodist University of Piracicaba E-mail address: pertille.adri@gmail. com Editor: Dr. Altair A. Del Bel Cury Received: February 8, 2022 Accepted: April 2, 2022 Strength of scapular elevation in women with TMD and asymptomatic women - a cross-sectional study Lúcio Ferreira dos Santos1, Fabiana Foltran-Mescollotto1 , Ester Moreira de Castro-Carletti1 , Elisa Bizetti Pelai2 , Marcio de Moraes2 , Delaine Rodrigues-Bigaton2 , Adriana Pertille1 Temporomandibular disorder (TMD) is recognized for its high prevalence, presenting characteristic signs and symptoms. Cervical spine pain is present in 70% of diagnosed TMD cases. Aim: To verify if women with TMD present changes in isometric muscle strength in the scapula elevation. Methods: This is an observational, cross-sectional study. Thirty-five women, aged 22.89±2.04 years, were divided into the TMD group (TMDG), diagnosed with TMD according to the DC/TMD, and control group (CG), with asymptomatic individuals. The volunteers accessed a online link by the smartphone in order to answer questions on personal data, the Fonseca Anamnestic Index (FAI), Neck Disability Index (NDI), and Masticatory preference. In all participants, evaluation of the force of the scapula elevation muscles was performed, using a load cell model MM-100 (Kratos® SP, Brazil). Data were analyzed descriptively using the maximum, mean, and standard deviation and a two-way ANCOVA test was applied for all variables. A significance level of 5% was considered. Results: There were no statistically significant differences between the TMDG and CG for the maximal and mean muscle strength of scapular elevation. There were statistically significant differences in FAI (p <0.001*) between the CG and the TMDG. Conclusion: Based on the results, it was not possible to confirm the hypothesis that women diagnosed with TMD present lower isometric strength during scapular elevation (right/left). Keywords: Temporomandibular joint. Isometric contraction. Muscle strength. https://orcid.org/0000-0002-6145-7448 https://orcid.org/0000-0002-0688-165X https://orcid.org/0000-0003-0826-9744 https://orcid.org/0000-0002-5229-5723 https://orcid.org/0000-0002-3423-5575 https://orcid.org/0000-0002-6979-342X 2 Santos et al. Braz J Oral Sci. 2022;21:e228356 Introduction Temporomandibular Disorder (TMD) is recognized by the American Academy of Orofacial Pain (AAOP) as a group of musculoskeletal and neuromuscular conditions involving the temporomandibular joint (TMJ), masticatory muscles1, and all other associated craniocervical structures2,3. The clinical signs and symptoms present in individuals with TMD can be listed as muscle and/or joint pain, TMJ sounds or noises (in cases of disc displacement and/or degenerative dysfunction), restrictions, limitations, and deviations during mouth opening and/or closing2. Moreover, pain in the cervical region is present in 70% of cases of TMD4-6. The prevalence of TMD ranged from 21.1% to 73.3% with the occurrence of painful TMD signs/symptoms varying from 3.4% to 65.7%, and non-painful signs/symptoms between 3.1% and 40.8%7. According to Silveira et al. (2015)5, the presence of signs and symptoms in the cervical region of patients diagnosed with TMD, as well as the presence of painful points in the cervical region, are very common. The presence of signs and symptoms in the cervical region was confirmed on palpation, with 23 to 67% of patients with TMD presenting muscle tenderness (presence of tender points) in the sternocleidomastoid and upper trapezius muscles5. Muscle tension in the cer- vical and mandibular regions is associated with high levels of disability, according to the Neck Disability Index (NDI)8. The cervical spine and TMJ present a neuro-anatomical and functional relationship5,6. In addition, alterations in the cervical posture can be related to patients with TMD and vice versa. High rates are reported for the coexistence of TMD and cervical spine abnormalities. According to Armijo-Olivo et al.9, the prevalence of neck pain in their sample of subjects with TMD was high; approximately 88% of subjects with mixed TMD had self-reported neck pain. Several studies demonstrate correlations and associations between TMD and signs and symptoms of cervical dysfunctions and despite increasing evidence, this is still explained by the intimate anatomical connections10,11, neurophysiological mecha- nisms that connect these two regions12-14, and pain15. The work of Truong Quang Dang et al.16, investigated the relationship between den- tal occlusion and arm strength; in particular, jaw imbalance could cause a loss or decrease in upper limb strength. During functioning, mechanical loads on the scapula are transferred to the shoulder and cervical spine, through the double orientation of the musculature (upper trapezius and scapular elevation)17-19, and this may be altered in patients with cervical dysfunction20, in addition to being frequently cited for involve- ment in myofascial neck pain21. Based on the literature cited above, the current study hypothesized that women with TMD would present decreased isometric strength generation of scapular ele- vation in the orthostatic position when compared with asymptomatic women. Mea- surements of the function and strength of scapular elevation were not found in the existing literature, especially when related to patients with TMD. This informa- 3 Santos et al. Braz J Oral Sci. 2022;21:e228356 tion may help to elucidate the functionality of this structure in patients with TMD, using an inexpensive, simple, and objective evaluation method. The possibility of correlations between muscle strength in scapula elevation and subjects with TMD could bring elements that are easy to access for the clinical evaluation of these subjects in the future. Thus, the current study aimed to verify if there is a difference in developing the strength of scapular elevation between women with TMD and asymptomatic women. Methods Study design This is an observational, cross-sectional study. The study was approved by the Research Ethics Committee of the University (CAAE 65444417.1.0000.5507) and led by LARET (Therapeutic Resources Laboratory) from UNIMEP (Methodist University of Piracicaba). Sample size A sample size calculation was performed, based on a pilot study comparing the groups, composed of 6 volunteers in each group. The measure used was the move- ment of scapular elevation strength. The mean and standard deviation values of the Control Group (CG) and the Temporomandibular Disorder Group (TMDG) were, respectively, 23.23±6.38 Kgf and 43.98±6.91 Kgf. According to the variables, for an effect size of 0.32, power of 80%, and 20% alpha, following the analysis of the results, 15 volunteers were required per group. The sample size calculation was performed using GPower® software, version 3.1.9.2. Inclusion criteria For inclusion in the TMDG, volunteers were required to be female university stu- dents, aged between 18 and 40 years, with a body mass index (BMI) ≤25kg/m², and a diagnosis of TMD according to the Diagnostic Criteria for Temporomandib- ular Disorders (DC/TMD)22. The diagnoses accepted in this study were myalgia, local myalgia, myofascial pain with spreading, myofascial pain with referral, disc displacement with reduction, disc displacement with reduction and with intermit- tent locking, disc displacement without reduction and with a limited opening, disc displacement without reduction and limited opening, degenerative joint disease, and arthralgia. For inclusion in the CG, the subjects were required to be female university students aged between 18 and 40 years, with a BMI<25kg/m², and no diagnosis of TMD according to the DC/TMD. Exclusion criteria In the TMD group, volunteers that did not present a TMD diagnosis or presented a diagnosis of degenerative joint diseases in the TMJ were excluded. For both groups (TMD and Control) the following exclusion criteria were considered; volun- teers that were under physiotherapeutic or pharmacological treatment (analgesic, 4 Santos et al. Braz J Oral Sci. 2022;21:e228356 anti-inflammatory, and muscle relaxant), presented tooth loss, using a full or partial dental prosthesis, history of trauma in the face and/or TMJ, and history of dislocation and/or subluxation of the TMJ. Assessment tools Diagnostic Criteria of Temporomandibular Disorder (DC/TMD) The DC/TMD is a validated biaxial questionnaire for myogenic TMD diagnosis23. Axis I of the DC/TMD includes a physical evaluation and considers recurrent factors in the patient’s daily life, while Axis II considers the previous history, including the beginning and perpetuating factors of the dysfunction22-24. The evaluator was trained and cali- brated to use this tool. Fonseca Anamnestic Index (FAI) The FAI is a scale developed in Portuguese that assesses the severity of the myogenic temporomandibular disorder. The Short-Form Fonseca Anamnestic Index (SFAI) demonstrates a high level of diagnostic accuracy and may be used as a new version of the index for the diagnosis of myogenous TMD25. The FAI also presents multidi- mensionality, with dimension one (primary) consisting of five reliable and well fitting items for the composition of its structure26. The high degree of diagnostic accuracy demonstrates that the FAI can be employed for the identification of myogenous TMD in women27. This instrument consists of ten self-answered questions, which include information on difficulty opening the mouth and moving the jaw sideways; tiredness and/or mus- cle pain when chewing; frequent headaches; neck pain and/or a stiff neck; ear or joint pain in the face; noises in the joint when opening the mouth or chewing; if the teeth are well articulated; and whether a person is tense/nervous and has the habit of teeth clenching or grinding. The scale presents three possible answers: “yes” with a score of 10, “sometimes” with a score of 5, and “no” with a score of 0. Neck Disability Index (NDI) The NDI measures the extent to which neck pain affects activities of daily living such as personal care, lifting, reading, headaches, concentration, work, driving, and sleep- ing. The NDI is a relatively short validated, reliable, and responsive questionnaire that is easy to administer8,28. The 10 items produce a score from zero to 50. The level of neck disability for the NDI was determined as follows: 0–4 points: ‘no disability’, 5–14 points: ‘mild disability’, 15–24 points: ‘moderate disability’, 25–34 points: ‘severe disability’, and >35 points: ‘complete disability’. The total score on the ques- tionnaire was used for statistical purposes. Maximal Voluntary Isometric Contraction (MVC) To evaluate the muscle strength of the right and left scapular elevations, a model MM-100 (Kratos ®, São Paulo, SP, Brazil) load cell was used. The volunteers remained standing, on an eight-centimeter-high platform, to better accommodate the load cell. One end of the load cell was fixed to the ground by a metal hook and chain, and the 5 Santos et al. Braz J Oral Sci. 2022;21:e228356 other end was held by the volunteer to pull; the load cell did not allow movement, only isometric contraction. All subjects were asked to perform a unilateral shoulder elevation (shoulder blade) to keep the shoulder blade muscles in voluntary isometric contraction. The volunteers were instructed not to perform elbow flexion and/or trunk inclination, and to avoid possible postural compensations. A therapist observed the data collection to prevent any compensations (Figure 1). Two interspersed measure- ments of ten seconds were performed for each side, that is, two attempts for the right and two for the left. A two-minute interval was given between each attempt to avoid interference of muscle fatigue in the results. The choice of the right or left side was randomized. Procedures At the beginning of the evaluation, all volunteers signed the consent form agree- ing to participate of the study. The volunteers were instructed to answer an online questionnaire regarding personal and anthropometric data (body mass, height, age, sex), dominant hand, side preference for chewing, the FAI, and NDI. Next, the volun- teers underwent the DC/TMD evaluation, and were divided into the control and TMD groups. Finally, the volunteers performed the MVC of the scapular elevation. Data from the MVC were obtained through EMG 830C signal acquisition module (EMG System do Brasil, São José dos Campos, Brazil) software. Data on the mean and maximum values of each attempt made using the load cell were extracted from this software and tabulated for later analysis. Figure 1. Muscle strength evaluation model of scapular elevation. a): anterior view; b): posterior view. A B 6 Santos et al. Braz J Oral Sci. 2022;21:e228356 Statistical analysis Data were initially analyzed descriptively (means and standard deviations). Data nor- mality was assessed by the Shapiro-Wilk test, which indicated normal data distribution. To verify if there was a difference in the maximum muscle strength of right and left scapular elevations, and to compare the values of the NDI and FAI between the TMDG and CG, the t-test for independent samples was performed. To compare the MVC of right and left scapular elevations between groups, and sides of masticatory preference, a two-way ANCOVA was used. The analysis was adjusted for age. Data analysis was performed using SPSS software, version 13.0. It was considered statistically significant when the p-value was less than 5%. Results Figure 2 presents a flow chart of the recruitment and assignment to the groups. Table 1 presents the characterization of the sample, highlighting the mean age of the volunteers of 22.89 ± 2.04 years, and chewing and manual preference on the right side. Table 1. Sample characterization presented as mean and standard deviation for age, weight, height, and presented as the frequency of occurrence for chewing and manual preference (right/left) for the total sample, TMDG, and CG (n=35). N = 35 TMDG = 17 CG = 18 Age (years) 22.8±2.0 22.5±3.6 23.0±1.9 Weight (Kg) 61.6±7.2 61.8±11.5 62.5±6.5 Height (cm) 160.9±10.3 163.7±6.3 166.7±4.9 Chewing Preference (Right/Left) 30/5 13/4 17/1 Manual preference (Right/Left) 31/4 13/4 18/0 N: total sample; TMDG: Temporomandibular disorder group; GC: control group. Figure 2. Volunteer recruitment flowchart. Individuals recruited for research (n = 38) Not elegible (n = 3) Elegible volunteers (n = 35) TMDG (n = 17) CG (n = 18) 7 Santos et al. Braz J Oral Sci. 2022;21:e228356 Table 2 presents the classification according to the DC/TMD for all volunteers. The maximum strength values and means found for right and left scapular elevations for each of the groups are presented in Table 3. No statistically significant differences were found between the TMDG and CG for the MVC of the right and left scapula elevations. There was a statistically significant difference (p=0.001*) in FAI scores between the TMDG (71.76±11.71) and CG (36.94±22.89). However, there was no dif- ference between groups in relation to the NDI. Table 4 shows the analysis of mean and standard deviation of maximal strength of scapular elevations, right and left sides, and masticatory preference between the TMDG and CG, using a two-way ANCOVA test. A t-test for independent groups was applied. All outcomes were grouped and none of the differences found were statisti- cally significant. Table 2. Diagnosis of volunteers according to the DC/TMD, presented as frequency of occurrence (n=35). Diagnosis Control Group 18 Myalgia 16 Myofascial pain 16 Disc displacement with reduction, with intermittent locking (R/L) 9 (7/6) Disc displacement without reduction, with limited opening (R/L) 1(1/1) Disc displacement without reduction, without limited opening (R/L) 1 (1/1) Arthralgia 14 (12/11) DC/TMD (Diagnostic Criteria for Temporomandibular Disorders)R/L= Right/Left. Table 3. Maximum and mean of strength measures for the variables (M.S.S.L.), total NDI and FAI scores for the TMDG and CG (n=35). TMDG (Mean±SD) CG (Mean±SD) p value M.S.S.L. right (Kgf) maximum 33.1±10.9 27.3±7.2 0.059 M.S.S.L. right (Kgf) mean 28.7±9.7 23.0±6.7 0.053 M.S.S.L. left (Kgf) maximum 33.4±10.9 27.9±7,3 0.090 M.S.S.L. left (Kgf) mean 29.0±9.5 23.6±6.8 0.059 NDI 8.5±3.8 5.7±3.3 0.270 FAI 71.7±11.7 36.9±22.8 0.001* SD: Standard Deviation; M.S.S.L.: Maximal strength of the scapular elevations; TMDG: Temporomandibular disorder group; CG: control group; NDI: Neck Disability Index; FAI: Fonseca Anamnestic Index. *Statistically significant difference between groups (p<0.05). A t-test was applied. 8 Santos et al. Braz J Oral Sci. 2022;21:e228356 Discussion The present results did not confirm the hypothesis that women with TMD present decreased isometric strength generation of scapular elevation in the orthostatic position when compared with asymptomatic women. No statistically significant dif- ferences were found between groups. Statistically significant differences were only found in FAI (p <0.001*) between the CG and the TMDG. In the current study, the FAI presents significantly higher values in the TMD group, reaching a severe index, and the CG, unexpectedly showed a level that was between mild and moderate. No statistically significant differences were found between groups for the mean and maximum MVC test, respectively. Indeed, when the MVC values were adjusted by age and compared considering the masticatory preference, no statically significant differences were found between mean and maximum in the MVC test. However, even without significance, the TMDG showed greater (28.7±9.71right; 29.07±9.56 left) development of isometric strength (mean) than the CG (23.03±6.79 right; 23.60±6.88 left). For the NDI, the groups were not statistically significantly dif- ference and showed a mild disability index. The result presented by the TMDG in the measurement of strength may be related to the low values found in the NDI. The level of cervical disability was mild. Thus, we could suggest that the cervical musculature (upper trapezius and scapular elevation)17,29, even with dysfunction, can still generate Table 4. Maximum and mean of strength measures (Kilogram force) for the variables (M.S.S.L.) in the comparison between masticatory preference, and TMG and CG (n=35). Muscle group Masticatory preference Mean±SD p value M.S.S.L. Right Mean TMDG Right 30.8±8.1 0.46 Left 21.8±12.3 Control Right 23.4±7.0 Left 21.6±0.0 M.S.S.L. Right Max TMDG Right 35.1±9.2 0.54 Left 26.6±14.9 Control Right 27.4±7.4 Left 25.3±0.0 M.S.S.L. Left Mean TMDG Right 30.9±9.1 0.34 Left 22.8±9.3 Control Right 23.9±7.1 Left 24.7±0.0 M.S.S.L. Left Max TMDG Right 35.0±9.8 0.52 Left 28.2±14.2 Control Right 28.3±7.6 Left 28.1±0.0 M.S.S.L.: Maximal strength of the scapular elevations; Max: maximum; TMDG: Temporomandibular disorder group; CG: control group; SD: standard deviation. An ANCOVA test was applied. *Statistically significant difference between variables (p<0.05). 9 Santos et al. Braz J Oral Sci. 2022;21:e228356 isometric strength normally. In addition, the FAI results showed severe levels in the TMDG and mild to moderate levels in the CG, yet despite this significant difference between the groups, the levels of isometric strength were similar. Some studies in the literature which also investigated the MVC of scapular elevation, evaluated women workers with self-reported neck/shoulder pain. The findings showed that the group with pain generated significantly lower force during maximal scapula elevation com- pared to healthy controls30-32. It is proposed that pain may impair the activation of the painful muscles. However, the same findings were not confirmed by the present study. This could occur due to the different population evaluated in this study, as well as the similar values in the NDI for both groups, showing that the control and TMD groups presented mild neck disability and, therefore, both groups presented pain, which could interfere in the strength measures. Another study33 that compared an asymptomatic group with a group presenting myo- fascial trigger points (MTP) and measuring the MVC of the scapular elevation, for both sides at the same time without trunk motion for 5 seconds, did not find a sta- tistically significant difference between the groups. These findings agree with those in the present study since no difference was found between the groups. In addition, the authors reported that when scapular elevation was restricted, shoulder abduc- tor strength was significantly lower in the MTP group than in the non-MTP group, suggesting that overuse of the upper trapezius can cause MTP by compensatory movements in shoulder abduction33. However, the present study did not evaluate the presence of myofascial trigger points or scapular restriction, therefore, this cannot be confirmed by our findings. The current study also did not find significant differences when grouping and relating the masticatory preference with the mean and maximum forces of the control and TMD groups. The TMDG showed higher values of mean and maximum force, with the highest values predominating on the right side (p=0.46 and 0.54), but without statis- tical significance. These high values on the right side could be explained by the right hand and right chewing side dominance. In addition, Bech et al.34 (2017) found that individuals with neck/shoulder pain compared with healthy subjects presented lower values in the MVC of scapula elevation, even after the data were adjusted for sex, which would confirm less capacity to generate MVC in muscles with pain or disability. However, when comparing the methodologies and resources used for the assess- ment with the current study, many differences stand out, such as self-assessment of pain and measurement of strength, in addition, of course, to the fact that the symp- tomatic group did not perform the TMD assessment34. It is well known that individuals with TMD present higher NDI scores than control groups14. According to the current literature, the prevalence of self-reported cervical pain ranges from 75 to 87.8% in individuals with TMD, and on average they present an NDI score 7.9 points greater than asymptomatic individuals3. This was partially found in the present study (TMDG: 8.59±3.82, CG: 5.78±3.37), however, although the TMD presented higher values than the control, no significant difference was found between the groups, and the scores of both groups can be classified as mild disabil- ity. Although this fact may influence cervical dysfunction, the focus of the study was the difference in strength between TMDG and CG individuals. 10 Santos et al. Braz J Oral Sci. 2022;21:e228356 The FAI has been used as a complementary tool in the evaluation of TMD, due to its simplicity and the fact that it does not require specific pre-training for use in research, clinical practice, and in characterizing the severity of TMD. Accord- ing to the study by Berni et al.27 (2015) in the FAI accuracy assessment, a cut-off point was found, which determines the absence or presence of TMD, with a score between 0 and 45 and 50 to 100, respectively. This fact was demonstrated by the results of the FAI in the present study (TMDG: 71.76±11.71, CG: 36.94±22.89), with a statistically significant difference. The contributions of this study are related to daily clinical practice and the belief that regions of dysfunction or muscles with local pain have less capacity to gener- ate isometric strength. This fact reaffirms the importance of individualized assess- ment, independent of the diagnosis, to treat not only the pathology but also its causes and compensations. This study proved to be innovative in the method of evaluation used and the meth- odological care taken, considering the muscle group evaluation, and the use of valid and reliable tools. In addition, a sample calculation was performed. The lim- itations include the small sample size, age range of the participants, absence of analysis of antagonist muscle strength, which could serve as a parameter for com- parison. Other criteria for evaluating the cervical spine, such as range of motion, could provide further evidence of the relationship between the structures evaluated, especially regarding the functionality of both structures. Both groups presented a mild disability score on the NDI, which could interfere in the findings of the pres- ent study. Finally, it is known that young adult women can easily use adaptation and compensation mechanisms in presence of mild TMD, which can interfere with the results. It is suggested that future studies using EMG evaluation be performed, as this tool could provide clarifications about the specific behavior of each muscle (scap- ula elevator, upper trapezius) and its antagonists (cervical flexors and sternoclei- domastoid). It is also suggested that future studies evaluate a larger sample and men volunteers. In conclusion, it was not possible to confirm the hypothesis that women diagnosed with TMD present lower isometric strength (mean and maximum) during scapular elevation (right /left). The results of the other comparisons and analyses between the groups also did not show statistically significant results, except for the results of the FAI. Acknowledgments The authors would like to thank all the subjects who participated in the study. This study was financed in part by the Coordination of Superior Level Staff Improvement - Brazil (CAPES) - Finance Code 001. Data availability Datasets related to this article will be available upon request to the corresponding author. 11 Santos et al. 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