Can clinical observation differentiate individuals with and
               without scapular dyskinesis?

Miachiro, Newton Y.; Camarini, Paula M. F.; Tucci, Helga T.; McQuade, Kevin J.; Oliveira, Anamaria S.

doi:10.1590/bjpt-rbf.2014.0025

Abstracts

Background:

Altered scapular rotation and position have been named scapular dyskinesis. Visual dynamic assessment could be applied to classify this alteration based on the clinical observation of the winging of the inferior medial scapular border (Type I) or of the prominence of the entire medial border (Type II), or by the excessive superior translation of the scapula (Type III).

Objective:

The aim of this study was to determine if there were differences in scapular rotations (Type I and II) and position (Type III) between a group of subjects with scapular dyskinesis, diagnosed by the clinical observation of an expert physical therapist, using a group of healthy individuals (Type IV).

Method:

Twenty-six asymptomatic subjects volunteered for this study. After a fatigue protocol for the periscapular muscles, the dynamic scapular dyskinesis tests were conducted to visually classify each scapula into one of the four categories (Type IV dyskinesis-free). The kinematic variables studied were the differences between the maximum rotational dysfunctions and the minimum value that represented both normal function and a small dysfunctional movement.

Results:

Only scapular anterior tilt was significantly greater in the type I dyskinesis group (clinical observation of the posterior projection of the inferior angle of the scapula) when compared to the scapular dyskinesis-free group (p=0.037 scapular and p=0.001 sagittal plane).

Conclusions:

Clinical observation was considered appropriate only in the diagnoses of dyskinesis type I. Considering the lower prevalence and sample sizes for types II and III, further studies are necessary to validate the clinical observation as a tool to diagnose scapular dyskinesis.

biomechanics; shoulder; health evaluation; validation studies; rehabilitation

Contextualização:

A movimentação ou posição alterada da escápula é definida como discinese escapular. O exame visual dinâmico pode ser utilizado para classificá-la de acordo com o julgamento clínico de projeção posterior excessiva da borda inferior medial (tipo I), da borda medial (tipo II) ou ainda translação excessiva no sentido cranial (tipo III).

Objetivo:

Determinar se há diferenças nas rotações escapulares (tipo I e II) e posição (tipo III) entre grupos de discinese e normais (tipo IV), os quais foram diagnosticados visualmente por um fisioterapeuta experiente.

Método:

Vinte e seis participantes assintomáticos foram voluntários neste estudo. Após um protocolo de fadiga periescapular, a avaliação dinâmica da discinese foi conduzida para classificar visualmente cada uma das escápulas em uma das quatro categorias (tipo IV - sem discinese). As variáveis cinemáticas estudadas foram a diferença entre o valor máximo indicativo da disfunção e o mínimo valor correspondente ao padrão normal esperado para o movimento ou o mínimo do próprio movimento disfuncional.

Resultados:

Apenas a inclinação anterior da escápula foi significantemente maior no grupo de discinese tipo I (observação visual de projeção posterior do ângulo inferior da escápula) quando comparada com o grupo sem discinese (p=0,037 plano escapular e p=0,001 plano sagital).

Conclusões:

A avaliação visual foi considerada apropriada apenas para o diagnóstico da discinese do tipo I. Considerando a baixa prevalência e o tamanho amostral dos tipos II e III, mais estudos são necessários para validar completamente a observação clínica como método adequado para o diagnóstico da discinese escapular.

biomecânica; ombro; avaliação de saúde; estudo de validação; reabilitação

Introduction

Previous studies have defined the normal movement of the scapula during arm elevation as a synchronized sequence of superior rotation and posterior tilt¹1. Braman JP, Engel SC, Laprade RF, Ludewig PM. In vivo assessment of scapulohumeral rhythm during unconstrained overhead reaching in asymptomatic subjects. J Shoulder Elbow Surg. 2009;18(6):960-7. PMid:19395283 PMCid:PMC2841046.

2. Ludewig PM, Reynolds JF. The association of scapular kinematics and glenohumeral joint pathologies. J Orthop Sports Phys Ther. 2009;39(2):90-104. PMid:19194022 PMCid:PMC2730194. ^- ³3. Phadke V, Camargo P, Ludewig P. Scapular and rotator cuff muscle activity during arm elevation: A review of normal function and alterations with shoulder impingement. Rev Bras Fisioter. 2009;13(1):1-9. PMid:20411160 PMCid:PMC2857390. with a variable amount of medial-lateral rotation³3. Phadke V, Camargo P, Ludewig P. Scapular and rotator cuff muscle activity during arm elevation: A review of normal function and alterations with shoulder impingement. Rev Bras Fisioter. 2009;13(1):1-9. PMid:20411160 PMCid:PMC2857390.. Variation of this dynamic pattern and of the resting position of the scapula on the thorax has been called 'scapular dyskinesis'⁴4. 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. PMid:23580420. .

The identification of the bony prominences on the scapula at rest and during the dynamics of the scapulothoracic rhythm is challenging for clinicians because of the layers of tissue - in addition to the skin, the subcutaneous fat and muscles that cover the bone⁴4. 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. PMid:23580420. . Additionally, the visual inspection is uniplanar by nature, while the dynamic dysfunction of the scapulothoracic rhythm is three-dimensional (3D)⁴4. 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. PMid:23580420. .

Kibler et al.⁵5. Kibler WB, Uhl TL, Maddux JW, Brooks PV, Zeller B, McMullen J. Qualitative clinical evaluation of scapular dysfunction: A reliability study. J Shoulder Elbow Surg. 2002;11(6):550-6. PMid:12469078.'s classification, derived from observing the dynamics of the scapular dyskinesis combined with the rest position of the scapula, resulted in three dysfunctional patterns⁵5. Kibler WB, Uhl TL, Maddux JW, Brooks PV, Zeller B, McMullen J. Qualitative clinical evaluation of scapular dysfunction: A reliability study. J Shoulder Elbow Surg. 2002;11(6):550-6. PMid:12469078.. Type I was characterized, at rest, by the posteriorly displaced or winging of the inferior medial scapular border, and during arm elevation, by the posterior winging of the inferior angle of the scapula. Type II was characterized by the projection of the entire medial border of the scapula at rest and in motion. Finally, type III was characterized by excessive superior translation, with elevation and some anterior displacement of the superior border of the scapula on the thorax. A symmetrical pattern and the normal scapulothoracic rhythm were classified as type IV.

Other patterns of dynamic classification for scapular dyskinesis have been recently proposed in the literature, with acceptable values of intra- and inter-rater reliability⁶6. Uhl TL, Kibler WB, Gecewich B, Tripp BL. Evaluation of clinical assessment methods for scapular dyskinesis. Arthroscopy. 2009;25(11):1240-8. PMid:19896045. ^, ⁷7. 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. PMid:19295960 PMCid:PMC2657031.. Uhl et al.⁶6. Uhl TL, Kibler WB, Gecewich B, Tripp BL. Evaluation of clinical assessment methods for scapular dyskinesis. Arthroscopy. 2009;25(11):1240-8. PMid:19896045. proposed a nominal dichotomous classification in which "NO" represents the absence of dyskinesis, and "YES" a positive diagnosis, if the clinician could observe any of the three dysfunctional patterns previously described by Kibler et al.⁵5. Kibler WB, Uhl TL, Maddux JW, Brooks PV, Zeller B, McMullen J. Qualitative clinical evaluation of scapular dysfunction: A reliability study. J Shoulder Elbow Surg. 2002;11(6):550-6. PMid:12469078.. McClure et al.⁷7. 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. PMid:19295960 PMCid:PMC2657031. classified the presence of dyskinesis as "subtle" or as an "obvious abnormality", according to the subjective perception of the examiner on the dysrhythmia or on the scapular winging. While a dorsal displacement was determined by winging of the medial border and / or the inferior angle of the scapula posteriorly, the dysrhythmia included premature or excessive elevation or protraction, irregularity (non-smooth) or judder (stuttering) during arm elevation or lowering, or a fast scapular inferior rotation during arm lowering. The criteria idealized by McClure et at.7, therefore, eliminated the necessity of a judgment based on observation of the specific direction of rotations or mal-positioning of the scapula. McClure patterns are qualitative (subtle or obvious), which created extra difficulty for its validation.

Although these patterns of classification have shown values ranging from poor to moderate⁵5. Kibler WB, Uhl TL, Maddux JW, Brooks PV, Zeller B, McMullen J. Qualitative clinical evaluation of scapular dysfunction: A reliability study. J Shoulder Elbow Surg. 2002;11(6):550-6. PMid:12469078. ^, ⁶6. Uhl TL, Kibler WB, Gecewich B, Tripp BL. Evaluation of clinical assessment methods for scapular dyskinesis. Arthroscopy. 2009;25(11):1240-8. PMid:19896045. or moderate⁷7. 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. PMid:19295960 PMCid:PMC2657031. for the inter-rater agreement, and moderate for the intra-rater agreement⁵5. Kibler WB, Uhl TL, Maddux JW, Brooks PV, Zeller B, McMullen J. Qualitative clinical evaluation of scapular dysfunction: A reliability study. J Shoulder Elbow Surg. 2002;11(6):550-6. PMid:12469078., the only attempt to validate, by comparing three-dimensional (3D) kinematic data with the four diagnostic patterns described, showed that the asymmetries were common in both symptomatic and asymptomatic volunteers⁶6. Uhl TL, Kibler WB, Gecewich B, Tripp BL. Evaluation of clinical assessment methods for scapular dyskinesis. Arthroscopy. 2009;25(11):1240-8. PMid:19896045..

Scapular dyskinesis has been associated with a variety of shoulder pain conditions³3. Phadke V, Camargo P, Ludewig P. Scapular and rotator cuff muscle activity during arm elevation: A review of normal function and alterations with shoulder impingement. Rev Bras Fisioter. 2009;13(1):1-9. PMid:20411160 PMCid:PMC2857390. ^, ⁸8. Kibler WB, Sciascia A, Wilkes T. Scapular dyskinesis and its relation to shoulder injury. J Am Acad Orthop Surg. 2012;20(6):364-72. PMid:22661566. . However, the sample sizes and the designs of the studies were insufficient to support the idea that the dysfunctions of the scapulothoracic rhythm were risk factors for the development or perpetuation of the symptoms. Recently, a study⁹9. Tate AR, McClure P, Kareha S, Irwin D, Barbe MF. A clinical method for identifying scapular dyskinesis, part 2: validity. J Athl Train. 2009;44(2):165-73. PMid:19295961 PMCid:PMC2657032. conducted on 62 athletes involved in overhead sports, with 31subjects classified with obvious dyskinesis and 31subjects classified as normal⁷7. 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. PMid:19295960 PMCid:PMC2657031., showed a scapulothoracic rhythm pattern with decreased upward rotation and elevation and increased clavicular protraction for the diagnostic of the dysfunction. However, the observational diagnosis of scapular dyskinesis was not correlated to with the presence of shoulder pain⁹9. Tate AR, McClure P, Kareha S, Irwin D, Barbe MF. A clinical method for identifying scapular dyskinesis, part 2: validity. J Athl Train. 2009;44(2):165-73. PMid:19295961 PMCid:PMC2657032..

The three-dimensional measurements of the shoulder joint complex yields a relatively precise description of the position and orientation of the joint¹1. Braman JP, Engel SC, Laprade RF, Ludewig PM. In vivo assessment of scapulohumeral rhythm during unconstrained overhead reaching in asymptomatic subjects. J Shoulder Elbow Surg. 2009;18(6):960-7. PMid:19395283 PMCid:PMC2841046. ^, ¹⁰10. Hamming D, Braman JP, Phadke V, LaPrade RF, Ludewig PM. The accuracy of measuring glenohumeral motion with a surface humeral cuff. J Biomech. 2012;45(7):1161-8. PMid:22387119 PMCid:PMC3327809. . However, the cost of the equipment and procedures involved in data collection hampers the development of epidemiological (transverse or longitudinal) studies based on these data. Thus, the validation of the clinical observation method in the diagnosis of scapular dyskinesis is a challenge but would contribute to any investigations of how this dysfunction influenced pain in the shoulder joint complex.

The present study aimed to compare the differences in the rotations (types I and II) and position (type III) of the scapula between two groups, those with and those without scapular dyskinesis, that were classified by an experienced physical therapist through clinical observation, in accordance with the criteria proposed by Kibler et al.⁵5. Kibler WB, Uhl TL, Maddux JW, Brooks PV, Zeller B, McMullen J. Qualitative clinical evaluation of scapular dysfunction: A reliability study. J Shoulder Elbow Surg. 2002;11(6):550-6. PMid:12469078.. Our hypothesis was that individuals classified with scapular dyskinesis, when compared to the group without dyskinesis, would present increased anterior tilt of the scapula when clinically classified as type I, increased medial rotation as type II and increased superior translation as type III, as outlined by the protocol proposed for this study.

Method

Participants

A total of 26 volunteer subjects, 15 men and 11 women, with a mean age of 22.8 (±3.4) years and body mass index of 21.9 (±2.8) kg/m², were evaluated. According to the history and physical assessment, the subjects in the study had full and painless glenohumeral range of motion, absence of cervical spine and upper limb dysfunctions and would be classified as "sedentary"¹¹11. Matsudo S, Araujo T, Matsudo V, Andrade D, Andrade E, Oliveira LC, et al. Questionário internacional de atividade física (IPAQ): estudo de validade e reprodutibilidade no Brasil. Rev Bras Ativ Fís Saúde. 2001;6(2):5-18. or those who "practice irregular physical activity"¹¹11. Matsudo S, Araujo T, Matsudo V, Andrade D, Andrade E, Oliveira LC, et al. Questionário internacional de atividade física (IPAQ): estudo de validade e reprodutibilidade no Brasil. Rev Bras Ativ Fís Saúde. 2001;6(2):5-18. that did not involve the upper limbs. Subjects who reported any systemic conditions, history of trauma, surgery to the trunk, neck or upper limb, deformities of the spine or positive signs of orthopedic and neurological tests of the shoulder (except dyskinesis), elbow, wrist, hand and cervical spine, were excluded from the study.

All subjects were informed of the objectives and procedures involved in the study and signed a formal informed consent approved by the Ethics Research Committee of the Hospital das Clínicas, Ribeirão Preto Medical School, University of São Paulo (USP-HCFMRP), Ribeirão Preto, SP, Brazil, protocol No. 13032/2011.

Procedures

The subjects were initially informed of the procedures and were able to familiarize themselves with the movement of elevating and lowering the arm in the sagittal and scapular planes. To assist the subjects in keeping the movement of the arms in the scapular and sagittal planes, a guide made of two PVC tubes were placed vertically in front of the volunteers at a distance that would orient the plane of arm elevation without the subjects touching the guide. The tubes were placed at an angle of 90º and 40º anterior to the frontal plane to guide arm elevation and lowering in the sagittal and scapular planes, respectively.

The 3SPACE Liberty (Polhemus. Inc, Colchester, VT) apparatus was integrated with (Innovative Sports Programs, Chicago, IL) The Motion Monitor software for collection of the 3D kinematics at a sampling frequency of 120 Hz. The electromagnetic sensors were firmly attached using adhesive tape and Velcron(r). Five acquisition sensors were positioned on either side of the body of the subjects as follows: two on the flat surface of the acromion of each scapula, to prevent movement produced by the adjacent soft tissue; two positioned on the humerus, just below the insertion of the deltoid muscle; and one placed on the sternum, just below the jugular notch. Each sensor provided information on position and angular orientation of the body segments with 0.08 cm RMS accuracy for position and 0.15º RMS accuracy for orientation, according to the manufacturer. The validity of the 3D kinematic measurements with the electromagnetic system was previously tested¹²12. Karduna AR, McClure PW, Michener LA, Sennett B. Dynamic measurements of three-dimensional scapular kinematics: a validation study. J Biomech Eng. 2001;123(2):184-90. PMid:11340880. and the reliability of the intra-section was determined prior to the beginning of the study and was considered excellent¹³13. Fleiss RL. The design and analysis of clinical experiments. New York: John Wiley and Sons; 1996. (95% confidence intervals of the values of the intraclass correlation coefficient_2,k ranging from 0.94-1.00) for assessing the rotations and translations of the scapula on the dominant and non-dominant limbs.

The digitalization of the anatomical landmarks for defining local coordinates of the scapula, humerus and thorax was performed in accordance with the recommendations from the International Society of Biomechanics (ISB) for the upper extremity¹⁴14. Wu G, Van der Helm FC, Veeger HE, Makhsous M, Van Roy P, Anglin C, et al. ISB recommendation on definitions of joint coordinate systems of various joints for the reporting of human joint motion--Part II: shoulder, elbow, wrist and hand. J Biomech. 2005;38(5):981-92. PMid:15844264. . The axes YX'Z'' represented the movements of medial/lateral and superior/inferior rotations, and anterior/posterior tilt of the scapula.

Before the clinical assessment and collection of the 3D kinematics, the subjects carried out a protocol performed to fatigue (fatigue protocol) of the peripheral scapular muscles, in which the subjects received a verbal encouragement. The fatigue protocol consisted of two parts: 1) an isometric contraction in the push-up plus position¹⁵15. Borstad JD, Szucs K, Navalgund A. Scapula kinematic alterations following a modified push-up plus task. Hum Mov Sci. 2009;28(6):738-51. PMid:19683822. ^, ¹⁶16. Szucs K, Navalgund A, Borstad JD. Scapular muscle activation and co-activation following a fatigue task. Med Biol Eng Comput. 2009;47(5):487-95. PMid:19387715. (maximum scapular protaction) (Figure 1A) holded as long as the volunteer stand, and 2) repetitions of bilateral, active, weighted arm elevation (Figure 1B). Load for active arm elevation was defined by body weigth as in McClure et al.⁷7. 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. PMid:19295960 PMCid:PMC2657031.. The protocol was interrupted only after the subject reported an inability to continue the exercise combined with the observation of the following compensations: decreased scapular protraction or loss of trunk alignment at the push up plus position (for position 1) and inability to elevate the arm with full elbow extension without changing the plane of motion or during shoulder abduction with load (for position 2). The protocol was performed before the assessments because it had previously been demonstrated that peripheral muscle fatigue could alter scapulothoracic rhythm¹⁷17. McQuade KJ, Dawson J, Smidt GL. Scapulothoracic muscle fatigue associated with alterations in scapulohumeral rhythm kinematics during maximum resistive shoulder elevation. J Orthop Sports Phys Ther. 1998;28(2):74-80. PMid:9699156. . In addition, other functional tests also contribute to muscle fatigue and could exacerbate movement disorders¹⁸18. Geiser CF, O'Connor KM, Earl JE. Effects of isolated hip abductor fatigue on frontal plane knee mechanics. Med Sci Sports Exerc. 2010;42(3):535-45. PMid:19952814. ^, ¹⁹19. Gribble PA, Hertel J. Effect of lower-extremity muscle fatigue on postural control. Arch Phys Med Rehabil. 2004;85(4):589-92.. The subjects completed the Borg Scale of Perceived Exertion²⁰20. Borg G. Escalas de Borg para a dor e o esforço percebido. São Paulo: Manole; 2000. before and immediately after the fatigue protocol.

Figure 1
Fatigue exercise protocol of the periscapular muscles performed before the clinical observation of the scapulothoracic rhythm: (A) Position 1: isometric contractions in the push-up plus (maximal scapular protraction) position, and (B) Position 2: resisted standing scaption.

Figure 2
Box-plot showing the first to third quartile (vertical lines), the median, (vertical line inside the box) and the maximum and minimum values (horizontal lines) of the differences between the maximum and minimum anterior-posterior tilt (n=18), anterior-posterior internal-external rotation (n=9), superior translation of the scapula (T-C7) (n=6), and from the dyskinesis-free group (n=18), during the scapular dyskinesis testing (Type I: first; Type II; second and Type III: third line) performed in the scapular (left) and sagittal (right) planes.(¥)p=0.037; *p=0.0018 from non-paired t-test.

The clinical diagnosis and the 3D kinematic assessment were performed in a random sequence defined by lottery.

The clinical diagnosis was given by a physical therapy specialist in the area who had five years clinical experience working with disorders of the shoulder and upper extremity, and who was also a member of a research group on the shoulder joint complex. Prior to the study, this professional was trained to use the classification system proposed by Kibler et al.⁵5. Kibler WB, Uhl TL, Maddux JW, Brooks PV, Zeller B, McMullen J. Qualitative clinical evaluation of scapular dysfunction: A reliability study. J Shoulder Elbow Surg. 2002;11(6):550-6. PMid:12469078. of the four types (type IV = normal) of dyskinesis, and provided with supplementary definitions. In addition to this material, pictures of the subjects with scapular dyskinesis were provided.

The clinical evaluation included a posterior and lateral view of each subject at rest with the arms along the trunk, and also during repeated arm elevation and lowering with the elbows extended, in the sagittal and scapular planes. The clinician diagnosed each scapula separately and asked each subject to hold the isometric position or to perform as many repetitions as deemed necessary for a conclusive diagnosis. The maximal number of repetions for test position 2 was 8.

The acquisition of the movements using the 3D kinematic sensors was obtained with the subjects' arms at rest and during elevation and lowering of the arm in the sagittal and scapular planes. The cycle of arm elevation and lowering in the sagittal (90º anterior to the frontal plane) and scapular planes (40º anterior to the frontal plane) were collected between the starting position and at the subject's maximum elevation point. The starting position was defined with the arms extended along the trunk, with palms of the hands facing the sagittal plane and thumbs pointing ahead⁶6. Uhl TL, Kibler WB, Gecewich B, Tripp BL. Evaluation of clinical assessment methods for scapular dyskinesis. Arthroscopy. 2009;25(11):1240-8. PMid:19896045.. Three sets of movements were collected in each plane, and the duration of each repetition was approximately four seconds or 90º per second. Visual feedback was not available for the participant during data collection. The data on the resting position of the scapula were extracted from records of the starting position and were collected after elevation and lowering movements of the arms.

The physical therapy specialist and those who participated in the data collection and processing of the data were instructed not to communicate with each other or to express their opinions on the diagnoses or results.

Data analysis and statistics

The Motion Monitor (Innovative Sports Programs, Chicago, IL) was used to process the kinematic data. In this analysis, the variables that characterized each type of scapular dyskinesis were determined for comparison with the corresponding values obtained from the group classified as type IV (normal). Thus, the anterior tilt (medial-lateral axis) was used to define the diagnosis of type I; the medial rotation (longitudinal axis) of type II; and the superior translation of the scapula (frontal or scapular plane) of type III.

Data analyses were conducted on 51 scapulae, since kinematic data from one scapula was lost. Thus, the 26 subjects who participated in the study were divided into the following groups: type I (n=9, 18 scapulae), type II (n=5, 9 scapulae), type III (n=3, 6 scapulae) and type IV (n=9, 18 scapulae) based on the assessment following the fatigue protocol.

The values of the rotations of the scapulae, relative to the trunk around the medial-lateral and longitudinal axes, were extracted during the lowering phase (or eccentric phase) of arm elevation, according to the Euler angles sequence of rotation YX'Z'', as recommended by the ISB¹⁴14. Wu G, Van der Helm FC, Veeger HE, Makhsous M, Van Roy P, Anglin C, et al. ISB recommendation on definitions of joint coordinate systems of various joints for the reporting of human joint motion--Part II: shoulder, elbow, wrist and hand. J Biomech. 2005;38(5):981-92. PMid:15844264. . The values of scapular translation were extracted from the concentric phase of the arm elevation and corresponded to the linear distance between the trigonum spinae scapulae (root of the spine of the scapula) and the spinous process of the seventh cervical vertebra (T-C7).

Given that the clinical decision was determined by the observation of an excessive movement along the range of motion, the kinematic variables analyzed in this study corresponded to the difference between the maximum and the minimum value of the dysfunction. This corresponded to the normal pattern expected for the movement or the minimum value of the dysfunctional movement that occurred throughout the phase of movement assessed. The parameters of the interval used for analysis was established while considering the visual identification of changes in the direction of the curve for the kinematic variable of interest. In addition, the duration of the change in the direction recorded should be at least of 0.28 seconds(s). The longer the change in the movement direction, the easier it was for the clinician to indentify the dysfunction. In this case, 0.28 seconds, in addition to the peak value of the change in direction, was the minimum amount of time required to visually and cognitively diagnose dyskinesis²¹21. Carreiro LRR, Haddad H, Baldo MVC. Componentes sensoriais e atencionais do tempo de reação: efeitos do tamanho, excentricidade e previsibilidade de estímulos visuais. Psic Teor Pesq. 2012;28(2):133-40. . Thus, even if the change in direction occurred more than once or if it was over the entire movement examined, such as the position of the scapula in medial rotation throughout the eccentric phase of the movement, the maximum value was included in the analysis.

The average values of the three measurements for each subject of the differences between maximum and minimum anterior-posterior tilt (type I), medial-lateral rotation (type II) and translation of the scapula (T-C7), were compared with the corresponding average values obtained from the subjects classified as normal (type IV). For this analysis, Students' unpaired t test was used with Welch's corrections applied where appropriate. GraphPad Prism(r) program (GraphPad Software, Inc., La Jolla, CA) version 6.0 was used considering a statistical significance level of 0.05. The effect size of the comparisons was estimated by Cohen's d. The magnitude of the effect was interpreted as small when the value was 0.2; moderate at 0.5; and large when equal to or greater than 0.8²²22. Cohen J. The concepts of power analysis. In: Cohen J, editor. Statistical power analysis for the behavioral sciences. Hillsdale: Academic Press, Inc; 1988. p. 1-17..

The levels of effort perceived were presented as a percentage of the change in the related categories, since the variable is nominal.

Results

The average time determined for the muscle fatigue was 86 s (±37.2 s). For males, the average time was 114 s (±40.5 s) while for females, it was 67 s (±18.5 s). After the fatigue protocol, the subjects noted their level of perceived exertion, either between light and heavy (22.23%) or between intense and very intense (77.77%).

Only the comparison of the mean difference between maximum and minimum anterior-posterior tilt (type I) with the average values obtained from subjects classified as normal (type IV) was statistically significant, both in the scapular (p=0.0037, Cohen's d=0.778) and sagittal planes (p=0.0018, Cohen's d=1.128), indicanting a greater anterior tilt of the scapula for those with type I diagnoses (Figure 2). For the non-significant comparisons, the magnitude of the effects was small, with Cohen's d values ranging from 0.06 to 0.493.

Discussion

The objective of this study was to compare the kinematic data indicative of scapulothoracic rhythm dysfunction between subjects with and without a diagnosis of scapular dyskinesis, using the classification proposed by Kibler et al.⁵5. Kibler WB, Uhl TL, Maddux JW, Brooks PV, Zeller B, McMullen J. Qualitative clinical evaluation of scapular dysfunction: A reliability study. J Shoulder Elbow Surg. 2002;11(6):550-6. PMid:12469078.. Our results showed that, independent of the plane of motion in which the test was performed, the difference between the maximum and minimum anterior tilt of the scapula was greater in the group of subjects identified with dyskinesis type I, characterized by the dorsal prominent of the inferior medial border of the scapula, compared to the values of the group diagnosed as normal.

Regardless of the plane in which arm elevation and lowering was performed, the variables indicative of dyskinesis, characterized by prominent of the medial border of the scapula or superior translation of the scapula, showed no significant differences when compared to the normal group. Although the results may indicate a lack of validity in the diagnosis of dyskinesis type II and III conducted by the physical therapy specialist, it is important to highlight that the sample size of these groups does not support this conclusion.

A previous study has shown a standard deviation for the scapulothoracic motion to be 10º. Considering an effect size of 5% for the differences between the variables, a power of 80% and an alpha of 5%, the estimated sample size calculated was 12²³23. Portney LG, Watkins MP. Foundations of clinical research: Applications to practice. Upper Saddle River: Prentice Hall; 2000.. Thus, the group diagnosed with dyskinesis type II had 75% of the minimum sample size, while the group with type III had only 42%. The interpretation of the Cohen's d, for the magnitude of the effect size of the differences found in the anterior tilt of the scapula in the scapular and sagittal planes, indicated moderate and large effects, respectively. The low prevalence of asymptomatic subjects types II and II in the sample did not allow us to reach magnitudes of appropriate effect to validate the clinical observation of these dysfunctions.

Only one study⁶6. Uhl TL, Kibler WB, Gecewich B, Tripp BL. Evaluation of clinical assessment methods for scapular dyskinesis. Arthroscopy. 2009;25(11):1240-8. PMid:19896045. attempted to validate the criteria of dyskinesis proposed by Kibler et al.⁵5. Kibler WB, Uhl TL, Maddux JW, Brooks PV, Zeller B, McMullen J. Qualitative clinical evaluation of scapular dysfunction: A reliability study. J Shoulder Elbow Surg. 2002;11(6):550-6. PMid:12469078., albeit with little success, due to the high prevalence of asymmetry in both groups with and without a diagnosis of dyskinesia. Uhl et al.⁶6. Uhl TL, Kibler WB, Gecewich B, Tripp BL. Evaluation of clinical assessment methods for scapular dyskinesis. Arthroscopy. 2009;25(11):1240-8. PMid:19896045. compared the 3D kinematics of volunteers assessed by clinicians using Kibler et al.⁵5. Kibler WB, Uhl TL, Maddux JW, Brooks PV, Zeller B, McMullen J. Qualitative clinical evaluation of scapular dysfunction: A reliability study. J Shoulder Elbow Surg. 2002;11(6):550-6. PMid:12469078.'s four type classification and the method "YES" (either type I, II and III) and "NO" (type IV), with reference values reported in a pilot study. These reference values were obtained from the resting position of the scapula of eight healthy subjects with no clinical diagnosis of dyskinesis, assessed by the clinicians. These values were calculated as the difference between the right and left medial-lateral rotation, and from the anterior-posterior tilt and vertical translation of the spine of the scapula with respect the spinous process of the twelfth thoracic vertebra (T12). In the present study, we proposed the new variable maximum - minimum to analyze the displacement in the position of the scapula. This variable eliminated using data from both scapulae, as bilateral comparison in static test²⁴24. American College of Sports Medicine. ACSM's Resource Manual for Guidelines for Exercise Testing and Prescription 7th ed. [Kindle Edition].. Indianapolis: Lippincott, Williams & Wilkins; 2013. was previously questioned⁴4. 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. PMid:23580420. in the literature, since the dysfunction could affect the scapula position bilaterally. Besides the individual evaluation for each scapula, our 3D variable favors key components of the clinical diagnosis. Data arises from scapular in motion and adds the judgment of excessive motion (maximum value) and the expected or minor dysfunctional motion (minimum value) within a time compatible to the cognitive interpretation²¹21. Carreiro LRR, Haddad H, Baldo MVC. Componentes sensoriais e atencionais do tempo de reação: efeitos do tamanho, excentricidade e previsibilidade de estímulos visuais. Psic Teor Pesq. 2012;28(2):133-40. of the examiner.

In the present study, a fatigue protocol was performed by the subjects prior to the dynamic examination of dyskinesis. Previous studies have shown that the effect of muscle fatigue on the kinematics and postural control of the lower limb worsens the muscular dysfunction¹⁸18. Geiser CF, O'Connor KM, Earl JE. Effects of isolated hip abductor fatigue on frontal plane knee mechanics. Med Sci Sports Exerc. 2010;42(3):535-45. PMid:19952814. ^, ¹⁹19. Gribble PA, Hertel J. Effect of lower-extremity muscle fatigue on postural control. Arch Phys Med Rehabil. 2004;85(4):589-92.. Similarly, to facilitate the identification of the dysfunction, repetitions of arm elevation with submaximal loads and in the push-up plus position were performed until fatigue was apparent, since the coordination of the movement and much of the stability of the scapula on the thorax is given by the dynamic participation of the axioscapular and scapulohumeral muscles⁸8. Kibler WB, Sciascia A, Wilkes T. Scapular dyskinesis and its relation to shoulder injury. J Am Acad Orthop Surg. 2012;20(6):364-72. PMid:22661566. . It is also necessary to know whether symptomatic volunteers will be able to perform the fatigue protocol proposed, and if it is more efficient than the use of loads along the arc⁷7. 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. PMid:19295960 PMCid:PMC2657031. of movement, since the fatigue protocol could be a condition of increased demand²⁴24. American College of Sports Medicine. ACSM's Resource Manual for Guidelines for Exercise Testing and Prescription 7th ed. [Kindle Edition].. Indianapolis: Lippincott, Williams & Wilkins; 2013. compared to the demand provided by using loads that vary during the movement.

Therefore, the limitation of the study was the inability to confirm the clinical observation diagnosis of the four types of scapular dyskinesis due to the low prevalence of types II and III in the sample evaluated. Future studies should determine the validity of these categories in order to make the clinical observation test acceptable for the diagnosis of scapulothoracic rhythm dysfunction. It should also include asymptomatic subjects and the estimates of sensitivity, specificity and accuracy.

Conclusion

According to this study, the clinical observational assessment of the scapulothoracic rhythm was considered appropriate only for the diagnosis of dyskinesis type I, characterized by excessive dorsal projection of the inferior medial border of the scapula. Considering the low prevalence and sample size of types II and III, further studies are needed to validate the clinical observation method as appropriate for the diagnosis of scapular dyskinesis.

Acknowledgements

The São Paulo Research Foundation (FAPESP), Brazil, by the Research Grant (2008/51456-6) for acquisition of the three-dimensional electromagnetic system, and to the University of São Paulo, Ribeirão Preto, SP, Brazil for Scientific Initiation Scholarship.

References

¹
Braman JP, Engel SC, Laprade RF, Ludewig PM. In vivo assessment of scapulohumeral rhythm during unconstrained overhead reaching in asymptomatic subjects. J Shoulder Elbow Surg. 2009;18(6):960-7. PMid:19395283 PMCid:PMC2841046.
²
Ludewig PM, Reynolds JF. The association of scapular kinematics and glenohumeral joint pathologies. J Orthop Sports Phys Ther. 2009;39(2):90-104. PMid:19194022 PMCid:PMC2730194.
³
Phadke V, Camargo P, Ludewig P. Scapular and rotator cuff muscle activity during arm elevation: A review of normal function and alterations with shoulder impingement. Rev Bras Fisioter. 2009;13(1):1-9. PMid:20411160 PMCid:PMC2857390.
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. PMid:23580420.
⁵
Kibler WB, Uhl TL, Maddux JW, Brooks PV, Zeller B, McMullen J. Qualitative clinical evaluation of scapular dysfunction: A reliability study. J Shoulder Elbow Surg. 2002;11(6):550-6. PMid:12469078.
⁶
Uhl TL, Kibler WB, Gecewich B, Tripp BL. Evaluation of clinical assessment methods for scapular dyskinesis. Arthroscopy. 2009;25(11):1240-8. PMid:19896045.
⁷
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. PMid:19295960 PMCid:PMC2657031.
⁸
Kibler WB, Sciascia A, Wilkes T. Scapular dyskinesis and its relation to shoulder injury. J Am Acad Orthop Surg. 2012;20(6):364-72. PMid:22661566.
⁹
Tate AR, McClure P, Kareha S, Irwin D, Barbe MF. A clinical method for identifying scapular dyskinesis, part 2: validity. J Athl Train. 2009;44(2):165-73. PMid:19295961 PMCid:PMC2657032.
¹⁰
Hamming D, Braman JP, Phadke V, LaPrade RF, Ludewig PM. The accuracy of measuring glenohumeral motion with a surface humeral cuff. J Biomech. 2012;45(7):1161-8. PMid:22387119 PMCid:PMC3327809.
¹¹
Matsudo S, Araujo T, Matsudo V, Andrade D, Andrade E, Oliveira LC, et al. Questionário internacional de atividade física (IPAQ): estudo de validade e reprodutibilidade no Brasil. Rev Bras Ativ Fís Saúde. 2001;6(2):5-18.
¹²
Karduna AR, McClure PW, Michener LA, Sennett B. Dynamic measurements of three-dimensional scapular kinematics: a validation study. J Biomech Eng. 2001;123(2):184-90. PMid:11340880.
¹³
Fleiss RL. The design and analysis of clinical experiments. New York: John Wiley and Sons; 1996.
¹⁴
Wu G, Van der Helm FC, Veeger HE, Makhsous M, Van Roy P, Anglin C, et al. ISB recommendation on definitions of joint coordinate systems of various joints for the reporting of human joint motion--Part II: shoulder, elbow, wrist and hand. J Biomech. 2005;38(5):981-92. PMid:15844264.
¹⁵
Borstad JD, Szucs K, Navalgund A. Scapula kinematic alterations following a modified push-up plus task. Hum Mov Sci. 2009;28(6):738-51. PMid:19683822.
¹⁶
Szucs K, Navalgund A, Borstad JD. Scapular muscle activation and co-activation following a fatigue task. Med Biol Eng Comput. 2009;47(5):487-95. PMid:19387715.
¹⁷
McQuade KJ, Dawson J, Smidt GL. Scapulothoracic muscle fatigue associated with alterations in scapulohumeral rhythm kinematics during maximum resistive shoulder elevation. J Orthop Sports Phys Ther. 1998;28(2):74-80. PMid:9699156.
¹⁸
Geiser CF, O'Connor KM, Earl JE. Effects of isolated hip abductor fatigue on frontal plane knee mechanics. Med Sci Sports Exerc. 2010;42(3):535-45. PMid:19952814.
¹⁹
Gribble PA, Hertel J. Effect of lower-extremity muscle fatigue on postural control. Arch Phys Med Rehabil. 2004;85(4):589-92.
²⁰
Borg G. Escalas de Borg para a dor e o esforço percebido. São Paulo: Manole; 2000.
²¹
Carreiro LRR, Haddad H, Baldo MVC. Componentes sensoriais e atencionais do tempo de reação: efeitos do tamanho, excentricidade e previsibilidade de estímulos visuais. Psic Teor Pesq. 2012;28(2):133-40.
²²
Cohen J. The concepts of power analysis. In: Cohen J, editor. Statistical power analysis for the behavioral sciences. Hillsdale: Academic Press, Inc; 1988. p. 1-17.
²³
Portney LG, Watkins MP. Foundations of clinical research: Applications to practice. Upper Saddle River: Prentice Hall; 2000.
²⁴
American College of Sports Medicine. ACSM's Resource Manual for Guidelines for Exercise Testing and Prescription 7th ed. [Kindle Edition].. Indianapolis: Lippincott, Williams & Wilkins; 2013.

Publication Dates

Publication in this collection
May-Jun 2014

History

Received
14 Oct 2013
Reviewed
02 Feb 2014
Accepted
10 Feb 2014

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Braman JP, Engel SC, Laprade RF, Ludewig PM. In vivo assessment of scapulohumeral rhythm during unconstrained overhead reaching in asymptomatic subjects. J Shoulder Elbow Surg. 2009;18(6):960-7. PMid:19395283 PMCid:PMC2841046.

[2] ²
Ludewig PM, Reynolds JF. The association of scapular kinematics and glenohumeral joint pathologies. J Orthop Sports Phys Ther. 2009;39(2):90-104. PMid:19194022 PMCid:PMC2730194.

[3] ³
Phadke V, Camargo P, Ludewig P. Scapular and rotator cuff muscle activity during arm elevation: A review of normal function and alterations with shoulder impingement. Rev Bras Fisioter. 2009;13(1):1-9. PMid:20411160 PMCid:PMC2857390.

[4] 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. PMid:23580420.

[5] ⁵
Kibler WB, Uhl TL, Maddux JW, Brooks PV, Zeller B, McMullen J. Qualitative clinical evaluation of scapular dysfunction: A reliability study. J Shoulder Elbow Surg. 2002;11(6):550-6. PMid:12469078.

[6] ⁶
Uhl TL, Kibler WB, Gecewich B, Tripp BL. Evaluation of clinical assessment methods for scapular dyskinesis. Arthroscopy. 2009;25(11):1240-8. PMid:19896045.

[7] ⁷
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. PMid:19295960 PMCid:PMC2657031.

[8] ⁸
Kibler WB, Sciascia A, Wilkes T. Scapular dyskinesis and its relation to shoulder injury. J Am Acad Orthop Surg. 2012;20(6):364-72. PMid:22661566.

[9] ⁹
Tate AR, McClure P, Kareha S, Irwin D, Barbe MF. A clinical method for identifying scapular dyskinesis, part 2: validity. J Athl Train. 2009;44(2):165-73. PMid:19295961 PMCid:PMC2657032.

[10] ¹⁰
Hamming D, Braman JP, Phadke V, LaPrade RF, Ludewig PM. The accuracy of measuring glenohumeral motion with a surface humeral cuff. J Biomech. 2012;45(7):1161-8. PMid:22387119 PMCid:PMC3327809.

[11] ¹¹
Matsudo S, Araujo T, Matsudo V, Andrade D, Andrade E, Oliveira LC, et al. Questionário internacional de atividade física (IPAQ): estudo de validade e reprodutibilidade no Brasil. Rev Bras Ativ Fís Saúde. 2001;6(2):5-18.

[12] ¹²
Karduna AR, McClure PW, Michener LA, Sennett B. Dynamic measurements of three-dimensional scapular kinematics: a validation study. J Biomech Eng. 2001;123(2):184-90. PMid:11340880.

[13] ¹³
Fleiss RL. The design and analysis of clinical experiments. New York: John Wiley and Sons; 1996.

[14] ¹⁴
Wu G, Van der Helm FC, Veeger HE, Makhsous M, Van Roy P, Anglin C, et al. ISB recommendation on definitions of joint coordinate systems of various joints for the reporting of human joint motion--Part II: shoulder, elbow, wrist and hand. J Biomech. 2005;38(5):981-92. PMid:15844264.

[15] ¹⁵
Borstad JD, Szucs K, Navalgund A. Scapula kinematic alterations following a modified push-up plus task. Hum Mov Sci. 2009;28(6):738-51. PMid:19683822.

[16] ¹⁶
Szucs K, Navalgund A, Borstad JD. Scapular muscle activation and co-activation following a fatigue task. Med Biol Eng Comput. 2009;47(5):487-95. PMid:19387715.

[17] ¹⁷
McQuade KJ, Dawson J, Smidt GL. Scapulothoracic muscle fatigue associated with alterations in scapulohumeral rhythm kinematics during maximum resistive shoulder elevation. J Orthop Sports Phys Ther. 1998;28(2):74-80. PMid:9699156.

[18] ¹⁸
Geiser CF, O'Connor KM, Earl JE. Effects of isolated hip abductor fatigue on frontal plane knee mechanics. Med Sci Sports Exerc. 2010;42(3):535-45. PMid:19952814.

[19] ¹⁹
Gribble PA, Hertel J. Effect of lower-extremity muscle fatigue on postural control. Arch Phys Med Rehabil. 2004;85(4):589-92.

[20] ²⁰
Borg G. Escalas de Borg para a dor e o esforço percebido. São Paulo: Manole; 2000.

[21] ²¹
Carreiro LRR, Haddad H, Baldo MVC. Componentes sensoriais e atencionais do tempo de reação: efeitos do tamanho, excentricidade e previsibilidade de estímulos visuais. Psic Teor Pesq. 2012;28(2):133-40.

[22] ²²
Cohen J. The concepts of power analysis. In: Cohen J, editor. Statistical power analysis for the behavioral sciences. Hillsdale: Academic Press, Inc; 1988. p. 1-17.

[23] ²³
Portney LG, Watkins MP. Foundations of clinical research: Applications to practice. Upper Saddle River: Prentice Hall; 2000.

[24] ²⁴
American College of Sports Medicine. ACSM's Resource Manual for Guidelines for Exercise Testing and Prescription 7th ed. [Kindle Edition].. Indianapolis: Lippincott, Williams & Wilkins; 2013.

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