Abstract
Background
Upper crossed syndrome (UCS) refers to specific altered muscle activation and changed movement patterns along with some postural deviations in the upper quarter of the body. This syndrome might contribute to the dysfunction of the cervicothoracic and glenohumeral joints.
Objectives
The present study will aim to investigate the effectiveness of a comprehensive corrective exercises program (CCEP) and subsequent detraining on alignment, muscle activation and movement pattern in men with UCS.
Methods/design
This is a parallel-group randomized controlled trial. Participants will be 22 men aged 18 to 28 years who are suffering from UCS. Participants in the intervention group will conduct CCEP (three times a week for 8 weeks), followed by 4 weeks of detraining. The control group will do their daily activities. Participants will be randomized (1:1) into the intervention or the control group. The primary outcome will be upper trapezius activations. Secondary outcomes consist of electromyography of middle and lower trapezius and serratus anterior muscles, scapular dyskinesis test, forward head and shoulder angles, thoracic kyphosis angle, and neck flexion pattern test.
Discussion
We propose to evaluate the effectiveness of a randomized controlled trial of a CCEP in men with UCS on their alignment, selected muscle activations, and relevant movement patterns. Results from our trial may provide new insights into the effects of exercise not only on the alignment but also on muscle activation and movement patterns that are important outcomes for people with postural malalignments and, if successful, could assist therapists in evidence-based clinical decision-making.
Trial registration
Iranian Registry of Clinical Trials, IRCT20181004041232N1. Registered on 26 October 2018.
Similar content being viewed by others
Background
Most people will see a medical practitioner or another health care provider at least once in their lifetime because of neck, shoulder and back pain [1, 2]. At a societal level, these pains are also responsible for substantial costs, including healthcare expenditure, disability insurance, and work absenteeism [3]. Previous studies showed that these pains might be associated with abnormal alignments [4, 5]. One of these malalignments is the upper crossed syndrome (UCS), which was defined as a muscular imbalance pattern by Vladimir Janda MD (1923–2002) [6]. UCS refers to specific altered muscle activation and movement patterns along with some postural deviations [7]. Alterations in muscle activation include overactivity of the upper trapezius, levator scapula, and pectorals muscles and underactivity of the deep cervical flexors, middle and lower trapezius, and serratus anterior [8]. Due to kinetic and muscular chains, there are altered scapular movement patterns (scapular dyskinesis) and specific postural changes, including forward head and shoulder posture and increased thoracic kyphosis [7, 9]. These changes can lead to reduction in the stability of the glenohumeral joint and to various musculoskeletal symptoms in the head, neck, and shoulder [7, 8, 10].
Over recent decades, therapists have been seeking to design appropriate exercises to correct musculoskeletal malalignments mainly through structural and functional approaches [11,12,13]. In the traditional structural approach, the changes observed in malalignments such as in UCS are attributed to biomechanics and are presumed to lead to adjustments in the length and strength of local muscles [11, 14]. This may account for the stretching of short muscles and strengthening of weakened muscles at the site of the problem in the correction phase, while ignoring other related malalignments [14]. Interestingly, despite the popularity of this method, very little research has been conducted based on this theory [15]. Furthermore, some review studies have questioned the effectiveness of strengthening and stretching exercises to improve postural disorders [16, 17].
In contrast, the functional (neurological) approach to musculoskeletal problems is based on the interaction of the central and peripheral nervous systems, and the involvement of the muscular and skeletal structures in producing and controlling motion [6, 18, 19]. In this functional approach, the musculoskeletal problems are attributed to the role of muscles in motor function; furthermore, changes in the alignment result not only from changes in muscle length and strength but also from more important changes in muscle neuromuscular factors, such as muscle recruitments [13, 20]. In fact, the motor control unit may change the muscle activation strategy for temporary stabilization due to the presence of dysfunction. These changes in motor recruitment will alter the muscular balance, movement patterns, and eventually the motor program [12]. Similarly, Hodges et al. noted that motor control interventions require tailoring to each individual’s posture, muscle activation, and movement pattern [21]. However, this theory has not been tested in practice for the prevention and treatment of musculoskeletal malalignments.
Hence, for the assessment of UCS, the alignment and its side effects are often evaluated, such as increase in thoracic kyphosis or forward head angles, while less attention has been paid to the keystone, i.e., the scapulae, and the relevant altered muscle activation and movement patterns [22]. In this regard, many researchers and therapists have only evaluated one of the affected regions, such as head, shoulders, or spine, separately and reported a degree of postural deviation regardless of other relevant malalignments and patterns of the muscle activation and related movement patterns, such as scapulohumeral rhythm or neck flexion [23,24,25]. In addition, the design and implementation of the training protocol are based on the traditional structural approach, in which stretching exercises for short muscles and strengthening exercises for weak muscles are prescribed at the site of malalignment [22, 24], while the neuromuscular factors and related movement patterns may not be considered. To the best of our knowledge, no studies identifying and correcting UCS have considered the three components of alignment, movement pattern, and muscle activity in both assessment and correction processes.
Study objectives
The primary aim of the present study is to evaluate the effectiveness of a comprehensive corrective exercise program (CCEP) in young men with UCS for 8 weeks, as measured by alignment (position of the scapula, head and neck, shoulder, and thoracic spine), electromyography activity of selected muscles (upper, middle and lower trapezius, serratus anterior), and specific movement patterns (scapulohumeral rhythm and neck flexion). A secondary aim is to evaluate the effects of the program after 4 weeks of detraining after the intervention.
Methods/design
Study design
This is a parallel-group randomized controlled trial comparing an intervention group receiving an 8-week CCEP followed by 4 weeks of detraining to a control group who will only do their daily activities. The study will be performed at the Laboratory of Health and Sports Medicine Department, University of Tehran, Tehran, Iran. Initially, participants will take part in the baseline assessment process. They will then receive the intervention for 8 weeks. After the end of the intervention phase, all the measurements will be repeated. Finally, a follow-up assessment will be performed after a 4-week detraining period. The study schedule is presented in Table 1 and a flow diagram is shown in Fig. 1. The study protocol is reported in accordance with the SPIRIT guideline.
Ethical aspects
Before starting the project, all participants will be asked to complete and sign an informed consent form. Ethics approval was obtained on August 28, 2017, from the Ethics Committee on Research at University of Tehran, Iran (IR.UT.REC.1395026). The protocol was approved at the Iranian Registry of Clinical Trials on 2018-10-26 (IRCT20181004041232N1).
Study participants and eligibility criteria
The participants consist of 24 men with UCS aged 18 to 28 years. They will be recruited from the students of the University of Tehran, Iran, through advertisements on bulletin boards. They will be screened primarily by observation for three main factors related to UCS, including altered alignment, muscle activation, and movement patterns. Since the scapulae are the keystone in UCS, participants who have any abnormality in the position and rhythm of the scapula, as measured by the scapular dyskinesis test, will be recruited. In addition, they will be assessed for presenting any postural changes such as forward head (≥ 44°), round shoulder (≥ 49°), or excessive thoracic kyphosis (≥ 42°) as measured by photogrammetry and flexicurve, respectively [15]. Also, to ensure any change in muscle activation is related to postural changes, some confirmatory tests, including muscle length tests for upper trapezius and pectoral muscles as well as muscle strength tests for middle and lower trapezius and deep cervical flexor, will be used. Individuals will be excluded from the research process if they do extra physical activity and sports that may affect the outcomes of the research, have any visible malalignment in the pelvis and lower extremities, have a history of fracture, surgery, or joint diseases in the spine, shoulder and pelvis, have a rotation greater than 5° on the forward bending test because of scoliosis [15], or have a bodyweight outside the normal range (body mass index between 18 and 25) [23].
Randomization
Participants will be randomized using computer-generated block randomization in a 1:1 ratio, followed by a concealed allocation through opening sequentially numbered, opaque and sealed envelopes; a card inside will indicate the group into which the participant will randomly be allocated, i.e., the intervention or the control group. Participants can discontinue the project at any time. However, all efforts will be made to avoid missing data. The specific way to deal with missing data will be determined at a data review meeting before starting statistical analyses.
Comprehensive approach
The comprehensive approach (Fig. 2), which is a new approach to corrective exercises [15], takes advantage of the strengths and weaknesses of traditional approaches to achieve the best outcome in correcting musculoskeletal malalignments. It was initiated in 2014 by Seidi et al., who compared the efficacy of comprehensive and traditional corrective exercise programs on the kyphosis angle [15]. The general purpose of this approach is to pay attention to alignment, muscle activation, and movement pattern simultaneously across the whole body rather than at just a single site during both the assessment and correction phases.
Intervention
An 8-week CCEP will be structured to include three phases. In the initial phase of the exercise program, the participants will become cognizant of the purpose and the quality of the exercises. This is characterized as voluntary control of exercise, requiring cortical regulation of movement and a lot of concentration on the part of the participants [12]. Participants will be asked to focus only on the scapular muscles, i.e., an internal focus [26] while their alignment is corrected passively. So, the exercises will be executed in non-weight bearing positions and the participants only try to contract underactive muscles isometrically and relax overactive muscles around the scapula for normalization of scapular position and motion [27, 28]. The participants will be instructed to reproduce this orientation of scapula actively using auditory (from therapist) and kinesthetic cues such as palpation [28]. Once a participant regains sufficient control over scapular muscles, he will focus externally on it and turn the internal focus of attention to correcting proximal segments through chin tuck, retraction of shoulders, and straightening the upper thoracic spine [29]. Then, he will do the exercises in different weight-bearing positions, and after restoring muscle balance in the static conditions, he will try to add upper extremity movements in various training positions. Also, the respiratory pattern of participants will be controlled during this phase and necessary feedback will be provided [13]. Since the quality of exercises is highly important in this phase, the participants should not feel fatigued while doing the exercises because fatigue may alter optimal muscle activations and movement patterns [30].
Once the participants can contract the appropriate muscles in a correct alignment during the best movement pattern, they should be able to maintain this for a long time. This goal will be addressed in the improvement phase when necessary tissue adaptations occur by increasing the load of exercises [31, 32]. Placing the participants in weight-bearing positions and using some tools such as training balls and Thera-Bands will reinforce their abilities gradually. During this phase, the participants will only focus on the goal of exercises (external focus) [29]. Moreover, because UCS is representative of underlying potential sensorimotor dysfunction, some functional balance exercises will be included [12]. The frequency and intensity of the exercises will increase progressively during the study, provided that participants can demonstrate good-quality movement. In the final phase, i.e., the maintenance phase, the participants will try to maintain the training adaptations [32]. All exercises will be performed under the supervision of a corrective exercise specialist. The participants will not conduct any extra exercises at home. However, they will be asked to avoid sustaining poor posture. More details about the intervention protocol are presented in Appendix 1. The control group will be asked to do their ordinary daily activities and not to participate in any exercise programs. After the study is completed, the control group will undergo the exercise intervention protocol for ethical reasons.
Outcome measures
All outcome measurements will be performed by the main researcher at baseline, 8 weeks (after intervention), and 12 weeks (follow-up). Demographic information (i.e., sex, age, body mass index) will be measured before the intervention.
Outcome measures
Upper trapezius activation (measured with surface electromyography) is the primary outcome measure. Secondary outcomes include electromyography measurements of middle and lower trapezius and serratus anterior muscles, scapular dyskinesis, forward head and shoulder angles, thoracic kyphosis angle, and neck flexion pattern.
Electromyography measurements
Surface electromyography of the scapular stabilizer muscles (including upper, middle, lower trapezius, and serratus anterior) will be performed using an ME-6000 Megawin. The participants will execute humeral abduction without resistance in three phases (concentric, isometric, and eccentric) lasting for 3 s each. They will already have been trained to move correctly and at the right speed so that they can perform the movement five times; rest time is 3 s between movements. Disposable Ag-AgCl electrodes with a diameter of 2 cm and a 2 cm spacing between two poles of electrodes will be used and data will be recorded at a frequency of 1000 Hz. The location of the electrodes will be determined using the SENIAM protocol and based on valid scientific papers [33, 34]. The maximum voluntary isometric contraction (MVIC) will be recorded to normalize the signals. More details about the location of the electrodes and MVIC positions are presented in Appendix 2. The data from the mean square root (RMS) will be used in the process of measuring muscle activation. To determine the onset of muscle activity, only the concentric phase of the motion will be used and it will be based on the onset of the deltoid muscle. Moreover, the onset of the activity will be from the point where the level of muscle activity reaches two standard deviations above the rest of the muscle activity [34].
Scapular dyskinesis
The current recommendation for clinical assessment based on a prior consensus meeting is the use of the dynamic scapular dyskinesis test according to the procedure described by McClure et al. [35]. The position and motion of scapula are characterized by dyskinesis as a “yes” (presence of deviation or dysrhythmia/asymmetry bilaterally) or “no” (no presence). This method has been shown to be reliable among observers and has acceptable clinical utility [35, 36].
Forward head and shoulder angles
The angle of the head and the shoulder will be measured using photogrammetry according to the procedure described by Seidi et al. [15]. The validity and reliability of this method have been established in previous studies [37, 38].
Thoracic kyphosis angle
To measure the static alignment of the thoracic spine, the flexicurve method will be used, which is a well-established, valid, and reliable technique [39, 40]. A detailed description of the procedure can be found in previous studies [15, 23].
Neck flexion pattern test
The participants will lie supine with knees bent. They will then be instructed to lift the head and look at their toes. Normal movement produces a smooth reversal of the normal cervical lordosis, keeping the chin tucked. Abnormal movement is compensated by the tightness of the SCM, producing an early protraction of the chin directly upward at the beginning of the motion [8].
Sample size
The sample size was calculated using the G*Power software (G*Power, version 3.0.10, Germany). It was based on a pilot test of seven participants, and on the assumption that a 10% difference in muscle activity [34] and an 11° difference in kyphosis angle [41] between groups would constitute clinically meaningful differences. It was calculated that a sample consisting of at least 18 participants would suffice to obtain 80% power with d = 0.80 effect size, and a confidence interval of 0.95. It should be noted that the effect size was reported in the previous study which compared scapular muscle activity between the interventions and control groups. Effect sizes ranged from 0.6 to 0.9 for the EMG amplitude and onset [42]. Since a few participants may drop out of the intervention studies, we will include 24 (assuming a drop-out rate of approximately 25%).
Statistical method and analysis
Assessments of statistical procedures will be performed using IBM SPSS version 20 for Windows (SPSS Inc., Chicago, IL, USA). All variables will be reported using the descriptive statistic (mean, standard deviation). Shapiro-Wilk test will be used to assess the normality of data. Repeated measures ANOVA will be used to compare the means. If mean difference is significant, then the Bonferroni-adjusted post-hoc test will be calculated. The independent t-test will also be used for comparison between groups. Finally, the effect size will be calculated for the magnitude of the difference using the Cohen method. The significance level will be set at p < 0.05.
Discussion
We propose to evaluate the effectiveness of a randomized controlled trial of a CCEP in a group of men aged 18 to 28 years with UCS in terms of their alignment, selected muscle activation, and relevant movement patterns.
Clinicians believe that it is important to quantify head, shoulder, scapulae, and spinal posture behavior as they influence and are influenced by many biomechanical, motor control, and performance variables [43]. It has been assumed that exercise can correct postural malalignment, but an earlier review found little evidence to support this assumption [17]. Moreover, despite the widespread inclusion of postural correction in exercise interventions, there are limited empirical data to support its effectiveness and little is known about the most effective exercise interventions [24]. As already mentioned, it seems the most important reason is the adherence to the traditional structural approach in the previous studies. We want to conduct a randomized controlled trial based on the comprehensive approach which is adequately powered and utilizes validated outcome measurements of UCS to investigate the effects of the CCEP on both our primary and secondary outcomes. If the CCEP results in changing the alignment, muscle activation, and movement pattern, or all three, we will examine the pathways of change to determine whether changes in the alignment, muscle activation, or movement pattern can account for the change in the UCS symptoms. Furthermore, if we find out that the CCEP can improve a postural malalignment like in UCS, this evidence could enable practitioners to recommend early intervention for UCS to prevent or delay UCS-associated consequences. Therefore, various experts in the field of corrective exercises and physical therapy, equipped with the knowledge on these changes, can identify people with UCS and also adopt appropriate therapeutic strategies to correct it and prevent the occurrence of secondary consequences.
Our study has some limitations including the recruitment of only men 18 to 28 years of age. Therefore, the results of this study will not be generalizable to all people (e.g., women or men aged ≥ 28 years) with UCS. Another limitation is that this study is not a double-blind design since it is not possible, as is the case with most exercise trials.
The results of our study will be presented at scientific conferences and published in academic journals to ensure that our study will inform therapists in practice and prove beneficial to patient care. Our goal is to conduct a clinical trial that will provide therapists with evidence of the efficacy of the CCEP on the keystone and the side effects of UCS. Previous trials have often used only assessment of the alignment to investigate the improvement of a malalignment. However, we are focusing on alignment, muscle activation, and movement pattern simultaneously based on the comprehensive approach. Therefore, if our exercise intervention proves successful, our approach to improving UCS could represent a fundamental paradigm shift in exercise intervention strategies to improve postural malalignments and their consequences. Results from our trial may provide new insights into the effects of exercise not only on alignment but also on muscle activation and movement pattern, which are important outcomes for people with postural malalignments and, if successful, it could assist practitioners in individualized clinical decision-making. However, our results may have a limited transferability to all people and thus may be valid only for men.
Trial status
This trial was registered on 2018-10-26 (registration number IRCT20181004041232N1, protocol version number 34266, https://en.irct.ir/user/trial/34266/view). The trial is currently in the stage of recruiting patients. The first patient was included on 2019-02-01. To date, ten patients have been included. The recruitment will be completed on approximately 2019-07-01.
Availability of data and materials
The authors aim to make the datasets supporting the results and conclusions of this study available as supplementary files in future published articles.
References
Langenfeld A, Humphreys BK, de Bie RA, Swanenburg J. Effect of manual versus mechanically assisted manipulations of the thoracic spine in neck pain patients: study protocol of a randomized controlled trial. Trials. 2015;16(1):233.
Gaffney BM, Maluf KS, Davidson BS. Evaluation of novel EMG biofeedback for postural correction during computer use. Appl Psychophysiol Biofeedback. 2016;41(2):181–9.
Kamper SJ, Apeldoorn A, Chiarotto A, Smeets R, Ostelo R, Guzman J, et al. Multidisciplinary biopsychosocial rehabilitation for chronic low back pain: Cochrane systematic review and meta-analysis. BMJ. 2015;350:h444.
Yoo W-G, Park S-Y. Effects of posture-related auditory cueing (PAC) program on muscles activities and kinematics of the neck and trunk during computer work. Work. 2015;50(2):187–91.
Barrett E, O'Keeffe M, O'Sullivan K, Lewis J, McCreesh K. Is thoracic spine posture associated with shoulder pain, range of motion and function? A systematic review. Man Ther. 2016;26:38–46.
Morris CE, Greenman PE, Bullock MI, Basmajian JV, Kobesova A. Vladimir Janda, MD, DSc: tribute to a master of rehabilitation. Spine. 2006;31(9):1060–4.
Page P. Shoulder muscle imbalance and subacromial impingement syndrome in overhead athletes. Int J Sports Phys Ther. 2011;6(1):51.
Page P. Cervicogenic headaches: an evidence-led approach to clinical management. Int J Sports Phys Ther. 2011;6(3):254.
Kibler WB, Sciascia A. Current concepts: scapular dyskinesis. Br J Sports Med. 2010;44(5):300–5.
Kang J-H, Park R-Y, Lee S-J, Kim J-Y, Yoon S-R, Jung K-I. The effect of the forward head posture on postural balance in long time computer based worker. Ann Rehabil Med. 2012;36(1):98–104.
Czaprowski D, Stoliński Ł, Tyrakowski M, Kozinoga M, Kotwicki T. Non-structural misalignments of body posture in the sagittal plane. Scoliosis Spinal Disord. 2018;13(1):6.
Page P. Sensorimotor training: a “global” approach for balance training. J Bodyw Mov Ther. 2006;10(1):77–84.
Frank C, Kobesova A, Kolar P. Dynamic neuromuscular stabilization & sports rehabilitation. Int J Sports Phys Ther. 2013;8(1):62.
Sahrmann S, Azevedo DC, Van Dillen L. Diagnosis and treatment of movement system impairment syndromes. Braz J Phys Ther. 2017;21(6):391–9.
Seidi F, Rajabi R, Ebrahimi I, Alizadeh MH, Minoonejad H. The efficiency of corrective exercise interventions on thoracic hyper-kyphosis angle. J Back Musculoskelet Rehabil. 2014;27(1):7–16.
Hrysomallis C. Effectiveness of strengthening and stretching exercises for the postural correction of abducted scapulae: a review. J Strength Cond Res. 2010;24(2):567–74.
Hrysomallis C, Goodman C. A review of resistance exercise and posture realignment. J Strength Cond Res. 2001;15(3):385–90.
Hamill J, van Emmerik RE, Heiderscheit BC, Li L. A dynamical systems approach to lower extremity running injuries. Clin Biomech. 1999;14(5):297–308.
Davids K, Glazier P, Araujo D, Bartlett R. Movement systems as dynamical systems. Sports Med. 2003;33(4):245–60.
Janda V. On the concept of postural muscles and posture in man. Aust J Physiother. 1983;29(3):83–4.
Hodges P, Paul W, Van Dieën JH, Cholewicki J. Time to reflect on the role of motor control in low back pain. Alexandria: JOSPT Inc.; 2019.
Bae WS, Lee HO, Shin JW, Lee KC. The effect of middle and lower trapezius strength exercises and levator scapulae and upper trapezius stretching exercises in upper crossed syndrome. J Phys Ther Sci. 2016;28(5):1636–9.
Vaughn DW, Brown EW. The influence of an in-home based therapeutic exercise program on thoracic kyphosis angles. J Back Musculoskelet Rehabil. 2007;20(4):155–65.
Harman K, Hubley-Kozey CL, Butler H. Effectiveness of an exercise program to improve forward head posture in normal adults: a randomized, controlled 10-week trial. J Man Manipulative Ther. 2005;13(3):163–76.
Hajihosseini E, Norasteh A, Shamsi A, Daneshmandi H. The effects of strengthening, stretching and comprehensive exercises on forward shoulder posture correction. Phys Treat Specif Phys Ther J. 2014;4(3):123–32.
Cools AM, Struyf F, De Mey K, Maenhout A, Castelein B, Cagnie B. Rehabilitation of scapular dyskinesis: from the office worker to the elite overhead athlete. Br J Sports Med. 2013. https://doi.org/10.1136/bjsports-2013-092148.
Kibler WB, Sciascia AD, Uhl TL, Tambay N, Cunningham T. Electromyographic analysis of specific exercises for scapular control in early phases of shoulder rehabilitation. Am J Sports Med. 2008;36(9):1789–98.
Worsley P, Warner M, Mottram S, Gadola S, Veeger H, Hermens H, et al. Motor control retraining exercises for shoulder impingement: effects on function, muscle activation, and biomechanics in young adults. J Shoulder Elb Surg. 2013;22(4):e11–e9.
Lederman E. The myth of core stability. J Bodyw Mov Ther. 2010;14(1):84–98.
Tsai N-T, McClure PW, Karduna AR. Effects of muscle fatigue on 3-dimensional scapular kinematics1. Arch Phys Med Rehabil. 2003;84(7):1000–5.
Brody LT. Effective therapeutic exercise prescription: the right exercise at the right dose. J Hand Ther. 2012;25(2):220–32.
Garber CE, Blissmer B, Deschenes MR, Franklin BA, Lamonte MJ, Lee I-M, et al. American College of Sports Medicine position stand. Quantity and quality of exercise for developing and maintaining cardiorespiratory, musculoskeletal, and neuromotor fitness in apparently healthy adults: guidance for prescribing exercise. Med Sci Sports Exerc. 2011;43(7):1334–59.
Hermens HJ, Freriks B, Disselhorst-Klug C, Rau G. Development of recommendations for SEMG sensors and sensor placement procedures. J Electromyogr Kinesiol. 2000;10(5):361–74.
De Mey K, Danneels L, Cagnie B, Cools AM. Scapular muscle rehabilitation exercises in overhead athletes with impingement symptoms effect of a 6-week training program on muscle recruitment and functional outcome. Am J Sports Med. 2012;40(8):1906–15.
McClure P, Tate AR, Kareha S, Irwin D, Zlupko E. A clinical method for identifying scapular dyskinesis, part 1: reliability. J Athl Train. 2009;44(2):160–4.
Kibler WB, Ludewig PM, McClure PW, Michener LA, Bak K, Sciascia AD. Clinical implications of scapular dyskinesis in shoulder injury: the 2013 consensus statement from the ‘Scapular Summit’. Br J Sports Med. 2013;47(14):877–85.
Gadotti IC, Armijo-Olivo S, Silveira A, Magee D. Reliability of the craniocervical posture assessment: visual and angular measurements using photographs and radiographs. J Manip Physiol Ther. 2013;36(9):619–25.
Ruivo RM, Pezarat-Correia P, Carita AI. Intrarater and interrater reliability of photographic measurement of upper-body standing posture of adolescents. J Manip Physiol Ther. 2015;38(1):74–80.
Greendale G, Nili N, Huang M-H, Seeger L, Karlamangla A. The reliability and validity of three non-radiological measures of thoracic kyphosis and their relations to the standing radiological Cobb angle. Osteoporos Int. 2011;22(6):1897–905.
Barrett E, McCreesh K, Lewis J. Reliability and validity of non-radiographic methods of thoracic kyphosis measurement: a systematic review. Man Ther. 2014;19(1):10–7.
Carman D, Browne R, Birch J. Measurement of scoliosis and kyphosis radiographs. Intraobserver and interobserver variation. J Bone Joint Surg Am. 1990;72(3):328–33.
Derakhshani A, Letafatkar A, Khosrokiani Z. Comparing the effects of SUREE programs on people with scapular downward rotation syndrome: a randomized clinical trial. J Sport Rehabil. 2018;28(8):787–95.
Claus AP, Hides JA, Moseley GL, Hodges PW. Thoracic and lumbar posture behaviour in sitting tasks and standing: Progressing the biomechanics from observations to measurements. Appl Ergon. 2016;53:161–8.
Acknowledgments
We are thankful to the participants for their participation. We also acknowledge the dedicated research professionals who contribute to the intervention and assessment of the participants in this study.
Dissemination
The study results will be published in peer-reviewed journals.
Funding
The authors state no external or internal funding involved.
Author information
Authors and Affiliations
Contributions
MBT and FS designed the trial. MBT, FS, and HM participated in trial registration, evaluation, and monitoring. MBT performed the exercises. LLA and PP have contributed to drafting the manuscript and revising it critically for important intellectual content. MBT, HM, LLA, and PP participated in the design of the statistical analysis. All authors contributed to the refinement of the study protocol and approved the final manuscript.
Corresponding author
Ethics declarations
Ethics approval and consent to participate
Ethics approval was obtained on August 28, 2017, from the Ethics Committee on Research in University of Tehran, Iran (IR.UT.REC.1395026). Before starting the project, all participants will be asked to complete the written consent form.
Consent for publication
Written informed consent was obtained from the person for publication of his accompanying images in this manuscript.
Competing interests
The authors declare that they have no competing interests.
Additional information
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Appendices
Appendix 1
Comprehensive corrective exercise program
The duration of the exercise protocol is 8 weeks, with three sessions per week, and each session will be about an hour. Each exercise session begins with 10 min of warm-up activity and ends with 5 min of cool-down. Selected exercises are designed in three phases: initial, improvement, and maintenance [35].
Initial phase exercises
The initial phase exercises (Fig. 3) include laying supine on a foam roll in three different arm abduction angles (exercise 1A–C), side-lying external rotation (exercise 2), side-lying forward flexion (exercise 3), standing diagonal flexion (exercise 4), and military press (exercise 5). Participants with less ability can do exercises 4 and 5 in a sitting position. Once a participant regains muscle balance in the static conditions, he will try to add upper extremity movements in exercise positions. Exercises progress in frequency and intensity during this phase, as long as participants are able to demonstrate good quality movement. The initial phase duration is 2 weeks and the exercises will be performed for seven sets of 10-s hold to ten sets of 15-s hold.
Improvement phase exercises
The goal of the improvement phase is to create the necessary tissue adaptations in the participant. Therefore, during this phase Thera-Bands, weights, and training balls will be used. Improvement phase exercises (Fig. 4) include side-lying external rotation with a dumbbell (exercise 6), side-lying forward flexion with a dumbbell (exercise 7), standing diagonal flexion with a dumbbell (exercise 8), standing external rotation with Thera-band (exercise 9), standing diagonal flexion with Thera-band (exercise 10), abduction in sitting on a training ball (exercise 11), lying prone V, T, and W exercises (exercise 12), and abduction in standing on a balance board (exercise 13). Exercises are progressed by considering individual characteristics of each participant and by observing the overload principle and the progression in the number of repetitions of each set during the 4 weeks of the improvement phase. The exercises will be performed from five sets of ten repetitions to six sets of 15 repetitions.
Maintenance phase exercises: The exercises are the same as in the improvement phase without any progression in intensity and frequency. The maintenance phase duration is 2 weeks.
Appendix 2
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.
About this article
Cite this article
Bayattork, M., Seidi, F., Minoonejad, H. et al. The effectiveness of a comprehensive corrective exercises program and subsequent detraining on alignment, muscle activation, and movement pattern in men with upper crossed syndrome: protocol for a parallel-group randomized controlled trial. Trials 21, 255 (2020). https://doi.org/10.1186/s13063-020-4159-9
Received:
Accepted:
Published:
DOI: https://doi.org/10.1186/s13063-020-4159-9