• Users Online: 127
  • Print this page
  • Email this page
  • Email this page
  • Facebook
  • Twitter

 Table of Contents  
Year : 2020  |  Volume : 9  |  Issue : 1  |  Page : 1-6

Revisiting the anatomy of rotator cuff relevant to rotator cuff injury

1 Department of Anatomy, All India Institute of Medical Sciences, Patna, Patna, India
2 Department of Anatomy, All India Institute of Medical Sciences Patna, Patna, India

Date of Web Publication2-Sep-2020

Correspondence Address:
Adil Asghar
Department of Anatomy, All India Institute of Medical Sciences, Patna, Patna, Bihar
Login to access the Email id

Source of Support: None, Conflict of Interest: None

DOI: 10.1055/s-0040-1709029

Rights and Permissions

The rotator cuff is the prime stabilizer of the glenohumeral or shoulder joint. The last decade saw introduction of three components, namely, rotator cable, rotator crescent, and rotator interval of rotator cuff, which were being studied and published in dozen of literatures belonging to clinical specialties of orthopaedics and radiology. At times when these terms have helped the clinician to understand the biomechanics of the rotator cuff while improving the outcome of its repair, the knowledge of the same remains at large for the anatomists. The preoperative assessment of rotator cuff tear has helped surgeons to identify the structure and its functional deficits thereof. The rotator cable is a thick fibrous band that behaves like a suspension bridge. Tears of rotator cable result in partial loss of function or pseudoparalysis of shoulder joint. The rotator interval is a four-layered protective cover of ligaments and the capsule in the rotator cuff. The current knowledge of the rotator interval revealed that the minor underlying ligaments of the shoulder j’oint play a crucial role in maintaining the congruency of the rotator cuff. The rotator cuff inj’ury is often misdiagnosed due to a lack of knowledge and identification of its recently reported components. This review intends to sensitize the anatomists to investigate further about rotator cuff anatomy and biomechanics of the shoulder joint.

Keywords: rotator cable, rotator interval, rotator cuff, rotator crescent, shoulder joint, biomechanics

How to cite this article:
Asghar A, Ghosh SK, Narayan RK. Revisiting the anatomy of rotator cuff relevant to rotator cuff injury. Natl J Clin Anat 2020;9:1-6

How to cite this URL:
Asghar A, Ghosh SK, Narayan RK. Revisiting the anatomy of rotator cuff relevant to rotator cuff injury. Natl J Clin Anat [serial online] 2020 [cited 2020 Nov 28];9:1-6. Available from: http://www.njca.info/text.asp?2020/9/1/1/294269

  Introduction Top

The rotator cuff is a musculotendinous envelope around the shoulder joint. It includes tendons of supraspinatus, infraspinatus, teres minor, and subscapularis muscles, popularly known as SITS muscles.[1] The subscapularis is a multipennate triangular muscle that arises from subscapular fossa, and its fibers extend up to lesser tuberosity anterior to the shoulder joint. The subscapularis tendon width was reported to be of 15 mm.[2] Some of the tendon’s superficial fibers bridged the bicipital groove and gets attached on the greater tuberosity by merging with the coracohumeral and transverse humeral ligaments. The greater tubercle or tuberosity of the humerus has three facets in the coronal plane: superior, middle, and inferior. The supraspinatus tendon is attached to superior facet and measures 23 mm in width. The thickness of the supraspinatus tendon was mentioned to be approximately of 6 mm.[3],[4] The infraspinatus tendon is attached to middle facet, measures 22 mm in width, and partially overlaps with the posteriormost part of supraspinatus tendon by 10 mm. Supraspinatus, infraspinatus, and teres minor are clubbed as “tendon footprint of greater tubercle.”[1] Rotator cuff injury is a common disorder in day-to-day practice but mostly undiagnosed and inadequately treated. Sometimes it becomes debilitating when the full-thickness tear remains undiag- nosed or missed during radiological examinations. The prevalence of rotator cuff tears was 3 to 39% in cadaveric subjects, but the radiological prevalence is 6 to 23% using magnetic resonance imaging (MRI) or ultrasonography in asymptomatic subjects.[5],[6] The prevalence of full-thickness rotator cuff tears increases with age. The rotator cuff injury is of significant concern to the clinician while dealing with supraspina- tus tendinitis.[7] The uniqueness of rotator cuff anatomy is due to the presence of rotator cable (RC) and crescent. These two terms along with rotator interval are hardly mentioned in a clinical anatomy text. A clear understanding of these three components is required for students and residents to deal with shoulder pain. The RC is a curved ligamentous complex in the musculotendinous cuff, which is tying both ends of the cuff. The RC was recognized by Clark and colleagues in 1990 but illustrated by Burkhart and colleagues in 1993.[8],[9] It is colloquially known as semicircular ligament of the humerus or circular fiber system, subsequently the “transverse band” is renamed as transverse humeral ligament bridging bicip- ital sulcus to contain the long head of biceps.[10] The current review was undertaken to understand the anatomy of RC, interval, and crescent. This article aims to summarize their anatomical, biomechanical, and radiological characteristics. The objective of this review article is to provide awareness to anatomists and clinicians about hitherto unraveled aspect of the rotator cuff.

  The Rotator Cable and Crescent Top

Burkhart et al introduced the term “rotator cable and crescent.” The coracohumeral ligament starts from the lateral border of the coracoid process and blends anteriorly with subscapularis. It consists of two layers: superficial and deep, attached to the lesser and greater tuberosity, respectively.[9],[11] The superficial layer blends with tendons of supraspinatus and infraspinatus muscles. The deep layer is attached to the fibrous capsule of shoulder joint. The RC is a curved extension of coracohumeral ligament, which stretches between lesser tuberosity and the junction of middle and inferior facet of the greater tuberosity [Figure 1] It also blends anteriorly with the subscapularis and sometimes with the anterior part of the supraspinatus tendon.[12] The cable runs from anterior to posterior direction underneath to the supraspinatus and infraspinatus tendons. It finally blends with the posteriormost fibers of infraspinatus tendon or anterior fibers of the tendon of teres minor. The thickened fibers of RC are perpendicular to the tendinous fibers of supraspinatus.[8],[13]
Figure 1: (a and b) The rotator cable extends from lesser tubercle of humerus to greater tubercle. It covers the tendon of long head of biceps (LHB). (Rotator cable marked with yellow color and crescent marked with blue color.)

Click here to view

Interestingly, it binds both the infraspinatus and supra- spinatus to the head of the humerus. Its primary function is to distribute the forces across the rotator cuff complex. The RC helps the rotator cuff to remain functional in the event of partial or full-thickness tears. It forms the suspension bridge between the tendons of subscapularis & infraspinatus. The mean width and thickness of the RC were 12.05 mm and 4.72 mm, respectively. The ratio of cable and crescent thickness is ~2.59 (1.23-5.81).[9],[14]

The rotator crescent is a thin crescent-shaped sheet of the rotator cuff, which consists of lateralmost end of supraspinatus and infraspinatus tendinous sheet. Rotator crescent is an avascular zone of the rotator cuff which tears easily [Figure 2]. The dimensions of the rotator of the crescent as reported by Burkhart et al were 41.35 mm x 14.08 mm, while the mean thickness was 1.82 mm.[14] They reported thick rotator crescent in younger cadaveric specimens as compared with the cable. They categorized the rotator cuff into two types—cable dominant and crescent dominant. RC is thick and the rotator crescent is thin in old subject, but crescent dominant is seen in younger age groups because of a thick crescent.[9],[14] The strength of the superior rotator cuff is more dependent on RC integrity in older patients. Despite these findings, some researchers observed that the RC is more detectable with ultrasound (US) in younger patients.[11] Understanding the type of RC is crucial to making a proper diagnosis and surgical repair.
Figure 2: Rotator cable and crescent in (a) freshly dissected cadaver and (b) dried embalmed cadaver

Click here to view

  The Rotator Interval Top

The term “rotator interval” was introduced by Neer et al in 1970.[15] The rotator interval (RI) was presumed to be a semifunctional and relatively empty area in the rotator cuff. There are two different RIs in shoulder anatomy: the anterior and posterior RIs. The anterior RI is a triangular space in the superoanterior part of the shoulder joint.[16] In 2002, Kolts et al identified that the superior, inferior, and medial borders of RI are formed by supraspinatus, sub- scapularis, and base of coracoid process, respectively, in a cadaveric study done on 19 shoulder joints.[17],[18] The joint capsule forms the roof of anterior RI whereas the floor is formed by the articular surface of the humerus. A fibrous capsule envelops the long head of the biceps tendon present on the base of the RI space and has opening for long head of biceps tendon (LHBT). The RI is a relatively small space but includes the extra-articular coracohumeral ligament (CHL), the superior and middle glenohumeral ligaments (SGHL and MGHL, respectively), LHBT, and a thin layer of the capsule that fills the capsular openings in the RI region. The CHL is known as the rotator interval capsule,[17] and it is strengthened by the CHL laterally and by the SGHL medially. Microscopically, the RI has four layers as reported by Jost et al.[19] The first layer includes superficial fiber of CHL, which starts from the coracoid process and attaches to the edge of this triangular space of RI [Figure 3] The second layer has an amalgamation of the CHL and rotator cuff tendons. The third layer includes deep fibers of CHL, and the fourth layer is a combined sheet of the SGHL and capsule.[17],[20] The coracoglenoid ligament (CGL) is another vital component of the RI, which is attached to the anterosuperior ligament complex of CHL and SGHL.[21] It is stretched from the coracoid process to the supraglenoid tubercle, and is extra-articular in location. Its function is still debatable as a stabilizer of the shoulder joint. Wilson et al described the variations of the fibrous capsule of the glenohumeral joint at RI. They identified the capsular opening being superolateral to middle glenohumeral ligament (MHG) in 59% individual.[22] This opening is very close to anteriormost fibers of the supra- spinatus and makes the long head of biceps tendon vulnerable to vulnerable to injury.[16] Harryman et al summarized that the overall function of the RI was to (1) act as a shackle to prevent extreme flexion, extension, adduction, and external rotation; (2) stabilize the humeral head against inferior translation during extreme adduction; and (3) steady the humeral head against posterior translation during extreme flexion or external rotation of abducted shoulder.[23] The posterior rotator interval is located between supraspinatus and infraspinatus. It consists of the glenohumeral capsule fused with supraspinatus tendon medially, and infraspinatus tendons laterally. The reported mean length of the posterior rotator interval was 77.8 mm, which includes the distance from the spinoglenoid notch to the glenoid border of scapula.[24] Release of the posterior rotator interval may be required to realign supraspinatus tendon when retracted or scarred at the posterior end.[25]
Figure 3: (a) A coronal view of the glenohumeral joint that shows the location of the rotator interval (between the black dashed lines) as a triangular structure between the supraspinatus and subscapularis tendons. (Reprinted with permission from Provencher MT, Saldua NS. Operative Techniques in Orthopaedics. Elsevier. copyright 2020) (b) The contents of rotator interval: space between supraspinatus (SSP) and subscapularis (SSC) has long head of biceps (LHB), coracohumeral ligament (CHL), superior glenohumeral ligament (SGHL). It has five layers shown in the image.

Click here to view

  Biomechanics Top

If the rotator cuff is intact, then the humeral head is located in the center and completely congruent during movement. The rotator cable keeps the humeral head centered because of the force coupled between subscapularis and infraspinatus [Figure 4]. The supraspinatus, infraspinatus, and subscapularis are active stabilizers.[8] They prevent depression of humeral head in overhead abduction and superior migration toward the coracoacromial arch in initial abduction. Both tendons provide a force couple to depress the humeral head and restrict it from migrating upward during early abduction. The presence of rotator cuff tear leads to failure of the mechanism as mentioned, thus causing upward displacement of humeral head toward the coracoacromial arch.[5]
Figure 4: (a and b) Force couple maintaining stability and congruency of glenohumeral joint

Click here to view

  The “Suspension Bridge” Model Top

The suspension bridge model was advised by Burkhart et al to explain the rotator cuff tear. They demonstrated that uppermost suspension cable of a bridge transfers the force to towers (located at the ends). Here, the rotator cable (RC) stretches between lesser and greater tubercle, below the middle facet. The RC is ~2.5 times thicker than rotator crescent. The rotator cuff redistributes the stress forces created by supraspinatus tendon. This mechanism prevents the tear of the rotator crescent. The above mechanism is explained by the stress shielding effect of the rotator cuff to the thinner tissue of the rotator crescent [Figure 5][9],[14]
Figure 5: Suspension bridge and stress shielding (superior view). The suspension bridge analogy: the relatively thick rotator cable provides a “stress shielding” effect to the thinner tissue within the crescent by distributing forces across the span of the humeral head (modified). (Source: https://www.sportsinjurybulletin.com/cables-crescents-and-suspension-bridges-the-unique-anatomy-of-the-rotator-cuff-cable/.)

Click here to view

This stress shielding effect is more effective in old individuals than young or in athletic subjects because of thin RC (crescent dominant rotator cuff). So, violent contraction of supraspinatus tendon may lead to tear of RC, causing painful arc syndrome. The rotator crescent is much thinner in the shoulders of old subjects and is damaged even in trivial trauma (cable dominant rotator cuff). The cable is better able to shield the cuff from loads than a crescent.[26] This mechanism explains asymptomatic or minor symptomatic clinical presentation in rotator cuff injury in the older individual, but it may lead to degeneration of rotator crescent. So, RC tears are biomechanically more debilitating than rotator crescent tears. Few authors have suggested some modifications to the suspension bridge model. Namdari et al advocated that the anteriormost junction of the supraspinatus tendon and its cable attachment were the most vulnerable to injury.[27] Adams et al demonstrated that capsular tear of the rotator cuff might lead to failure of suspension bridge mechanism in cadaveric studies.[28]

  Radiological Anatomy of Rotator Cuff Top

The rotator cuff or its components aren’t visible on plain radiographs. MRI or US has been accepted modalities for the screening of rotator cuff anatomy.[29] Arthroscopy is a choice but secondary to MRI or US. Some authors advised that the abduction external rotation (ABER) is the best suitable position for the assessment of the rotator cuff. A routine oblique coronal plane MRI is the right choice because the glenoid cavity is placed 30°anterior from the coronal plane [Figure 6]. The RC could be identified in the fat-suppressed T2 view, where it appears as a 2 to 5 mm broad hypointense region under supraspinatus tendon. The RCs were detectable in 75% subjects because of small diameter in crescent-dominant young subjects.[30],[31] Additionally, it is difficult to differentiate between the RC and a small tear of the anterior supraspina- tus tendon. The axial scanning may help in such cases. On the axial plane, the hypointensity of the RC extends from the greater tubercle (GT) to the inferior facet of GT, similar to its anatomical shape. So, the coronal and axial images help to identify the RC, but confirmation is done in the sagittal plane and ABER position.[31]
Figure 6: MRI, coronal section, T2-weighted image of rotator cable. SS, supraspinatus; RC, rotator cable. Huri et al. 201932; Creative Commons Attribution-Non Commercial 4.0 International (CC BY-NC 4.0) license (https://creativecommons.org/licenses/by-nc/4.0/).

Click here to view

The MR arthrogram is used to identify the intra-articular RI capsule with the help of a synovial fluid [Figure 7] The oblique sagittal plane of MRI is most helpful for the evaluation of RI. The RI capsule is localized over the biceps pulley as a hypointense band. Tracing the scans of the medial side is helpful in delineating the CHL whereas he SGHL is hardly visible.[32] Chung et al identified CHL in 60% of subjects, while SGHL remained invisible. Similarly, the identification of coracoglenoid ligament (superoanterior capsule-ligamentous complex) needs a trained eye.[16]
Figure 7: MRI, coronal section, T2-weighted image of the rotator interval. SS, supraspinatus tendon; IS, infraspinatus tendon; LHBT, long head of the biceps tendon; RI, rotator interval. Huri et al. 201932 Creative Commons Attribution-Non Commercial 4.0 International (CC BY-NC 4.0) license (https://creativecommons.org/licenses/by-nc/4.0/).

Click here to view

US is another screening tool to assess RC and RI. Some authors were able to identify RI by US in 77 to 99% subjects which is better than MRI.[29] Sconfienza et al advised that the RC was more easily detectable in older subjects (cable-dominant anatomy) and this finding was consistent with observation of Burkhart et al. The sub- clinical tendinosis also help in identification of RC in old subjects.[33]

Tamborrini et al advocated that musculoskeletal US (high resolution) is superior for visualization of the RI and RC and their pathologies (e.g., tendinosis, tears, and capsulitis). The only limiting factor is the presence of acromion, which compromises visualization of underneath soft tissue, for example, RC and RI.[34]

Anatomical proximity of the anterior RC and RI presents with “superoanterior lesions.” This distinct type of rotator cuff tear involves the subscapularis and anterior portion of the supra- spinatus tendon and adjacent RI structures, for example, SGHL, CHL, and biceps tendon.[14] Case-control clinical studies and further investigation are needed to define the clinical importance of this new concept.

  Summary Top

The rotator cuff integrates an exceptional anatomical feature known as the rotator cable. The RC binds the tendons of the rotator cuff muscles, and this cable provides a stress shield effect across both tuberosities of humerus like a suspension bridge. The location of tears in the rotator cuff tendons is more important than the size of the tear. The tear of RC is debilitating, so debridement or conservative treatment would not be helpful and hence requires surgical repair. Therefore, the prognosis of rotator cuff injuries may depend upon more on the location of the tear than the size of the tear. Besides RC and RI, the role of coracoglenoid ligament needs to be investigated further in the suspension bridge model.

  Key Messages Top

  • The rotator cable (RC) is important element of glenohumeral biomechanics.
  • Tear of RC may lead to significant joint translation and instability.
  • RC and crescent form stress shield “suspension bridge model.”
  • Rotator crescent is avascular and rotator cuff injury involving crescent heals slowly.
  • The rotator interval (RI) anatomy is also disturbed during rotator cuff injury.

Funding Support


Conflict of Interest

None declared.

  References Top

Curtis AS, Burbank KM, Tierney JJ, Scheller AD, Curran AR. The insertional footprint of the rotator cuff: an anatomic study. Arthroscopy 2006;22(6):609.e1  Back to cited text no. 1
Arai R, Mochizuki T, Yamaguchi K, et al. Functional anatomy of the superior glenohumeral and coracohumeral ligaments and the subscapularis tendon in view of stabilization of the long head of the biceps tendon. J Shoulder Elbow Surg 2010;19(1):58-64  Back to cited text no. 2
Fallon J, Blevins FT, Vogel K, Trotter J. Functional morphology of the supraspinatus tendon. J Orthop Res 2002;20(5):920-926  Back to cited text no. 3
Minagawa H, Itoi E, Konno N, et al. Humeral attachment of the supraspinatus and infraspinatus tendons: an anatomic study. Arthroscopy 1998;14(3):302-306  Back to cited text no. 4
Yamamoto A, Takagishi K, Osawa T, et al. Prevalence and risk factors of a rotator cuff tear in the general population. J Shoulder Elbow Surg 2010;19(1):116-120  Back to cited text no. 5
Cho NS, Moon SC, Hong SJ, Bae SH, Rhee YG. Comparison of clinical and radiological results in the arthroscopic repair of full-thickness rotator cuff tears with and without the anterior attachment of the rotator cable. Am J Sports Med 2017;45(11):2532-2539  Back to cited text no. 6
Codman E. Rupture of the supraspinatus tendon and other lesions in or about the subacromial bursa. The Shoulder 1934  Back to cited text no. 7
Clark JM, Harryman DT II. Tendons, ligaments, and capsule of the rotator cuff. Gross and microscopic anatomy. J Bone Joint Surg Am 1992;74(5):713-725  Back to cited text no. 8
Petersen W, Esch JC, Jolson RS. Re: The rotator crescent and rotator cable: an anatomic description of the shoulder’s “suspension bridge”. Arthroscopy 2010;26(2):256-257  Back to cited text no. 9
Kask K, Kolts I, Lubienski A, Russlies M, Leibecke T, Busch LC. Magnetic resonance imaging and correlative gross anatomy of the ligamentum semicirculare humeri (rotator cable). Clin Anat 2008;21(5):420-426  Back to cited text no. 10
Bureau NJ, Blain-Pare E, Tetreault P, Rouleau DM, Hagemeister N. Sonographic visualization of the rotator cable in patients with symptomatic full-thickness rotator cuff tears: correlation with tear size, muscular fatty infiltration and atrophy, and functional outcome. J Ultrasound Med 2016;35(9):1899-1905  Back to cited text no. 11
Denard PJ, Koo SS, Murena L, Burkhart SS. Pseudoparalysis: the importance of rotator cable integrity. Orthopedics 2012;35(9):e1353-e1357  Back to cited text no. 12
Mochizuki T, Sugaya H, Uomizu M, et al. Humeral insertion of the supraspinatus and infraspinatus. New anatomical findings regarding the footprint of the rotator cuff. J Bone Joint Surg Am 2008;90(5):962-969  Back to cited text no. 13
Burkhart SS, Esch JC, Jolson RS. The rotator crescent and rotator cable: an anatomic description of the shoulder’s “suspension bridge”. Arthroscopy 1993;9(6):611-616  Back to cited text no. 14
Bigoni BJ, Chung CB. MR imaging of the rotator cuff interval. Radiol Clin North Am 2006;44(4):525-536, viii  Back to cited text no. 15
Chung CB, Dwek JR, Cho GJ, Lektrakul N, Trudell D, Resnick D. Rotator cuff interval: evaluation with MR imaging and MR arthrography of the shoulder in 32 cadavers. J Comput Assist Tomogr 2000;24(5):738-743  Back to cited text no. 16
Kolts I, Busch LC, Tomusk H, et al. Macroscopical anatomy of the so-called “rotator interval”. A cadaver study on 19 shoulder joints. Ann Anat 2002;184(1):9-14  Back to cited text no. 17
Frank RM, Taylor D, Verma NN, Romeo AA, Mologne TS, Provencher MT. The rotator interval of the shoulder: Implications in the treatment of shoulder instability. Orthop J Sports Med 2015;3(12):2325967115621494  Back to cited text no. 18
Jost B, Koch PP, Gerber C. Anatomy and functional aspects of the rotator interval. J Shoulder Elbow Surg 2000;9(4):336-341  Back to cited text no. 19
Kolts I, Busch LC, Tomusk H, et al. Anatomy of the coraco- humeral and coracoglenoidal ligaments. Ann Anat 2000;182(6):563-566  Back to cited text no. 20
Zappia M, Castagna A, Barile A, Chianca V, Brunese L, Pouliart N. Imaging of the coracoglenoid ligament: a third ligament in the rotator interval of the shoulder. Skeletal Radiol 2017;46(8):1101-1111  Back to cited text no. 21
Wilson WR, Magnussen RA, Irribarra LA, Taylor DC. Variability of the capsular anatomy in the rotator interval region of the shoulder. J Shoulder Elbow Surg 2013;22(6):856-861  Back to cited text no. 22
Harryman DT II, Sidles JA, Harris SL, Matsen FA III. The role of the rotator interval capsule in passive motion and stability of the shoulder. J Bone Joint Surg Am 1992;74(1):53-66  Back to cited text no. 23
Miller SL, Gladstone JN, Cleeman E, Klein MJ, Chiang AS, Flatow EL. Anatomy of the posterior rotator interval: implications for cuff mobilization. Clin Orthop Relat Res 2003; (408):152-156  Back to cited text no. 24
Mologne TS, Zhao K, Hongo M, Romeo AA, An K-N, Provencher MT. The addition of rotator interval closure after arthroscopic repair of either anterior or posterior shoulder instability: effect on glenohumeral translation and range of motion. Am J Sports Med 2008;36(6):1123-1131  Back to cited text no. 25
Delserro S. Stress Shielding of the Rotator Cable in the Lateral Rotator Cuff (Master’s dissertation). University of Pittsburgh; 2019. Available from: http://d-scholarship.pitt.edu/36296/1Z delserrosm_etdPitt2019.pdf  Back to cited text no. 26
Namdari S, Donegan RP, Chamberlain AM, Galatz LM, Yamaguchi K, Keener JD. Factors affecting outcome after structural failure of repaired rotator cuff tears. J Bone Joint Surg Am 2014;96(2):99-105  Back to cited text no. 27
Adams CR, DeMartino AM, Rego G, Denard PJ, Burkhart SS. The rotator cuff and the superior capsule: why we need both. Arthroscopy 2016;32(12):2628-2637 10.1016/j. arthro.2016.08.011  Back to cited text no. 28
Martinoli C, Bianchi S, Prato N, et al. US of the shoulder: non-rotator cuff disorders. Radiographics 2003;23(2): 381-401, quiz 534  Back to cited text no. 29
Gyftopoulos S, Bencardino J, Nevsky G, et al. Rotator cable: MRI study of its appearance in the intact rotator cuff with anatomic and histologic correlation. AJR Am J Roentgenol 2013;200(5):1101-1105  Back to cited text no. 30
Iyengar JJ, Burnett KR, Nottage WM, Harwin SF. The abduction external rotation (ABER) view for MRI of the shoulder. Orthopedics 2010;33(8):562-565  Back to cited text no. 31
Huri G, Kaymakoglu M, Garbis N. Rotator cable and rotator interval: anatomy, biomechanics and clinical importance. EFORT Open Rev 2019;4(2):56-62  Back to cited text no. 32
Sconfienza LM, Orlandi D, Fabbro E, et al. Ultrasound assessment of the rotator cuff cable: comparison between young and elderly asymptomatic volunteers and interobserver reproduc- ibility. Ultrasound Med Biol 2012;38(1):35-41  Back to cited text no. 33
Tamborrini G, Moller I, Bong D, et al. The rotator interval-a link between anatomy and ultrasound. Ultrasound Int Open 2017;3(3):E107-E116  Back to cited text no. 34


  [Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5], [Figure 6], [Figure 7]


Similar in PUBMED
   Search Pubmed for
   Search in Google Scholar for
 Related articles
Access Statistics
Email Alert *
Add to My List *
* Registration required (free)

  In this article
The Rotator Cabl...
The Rotator Interval
The “Suspe...
Radiological Ana...
Key Messages
Article Figures

 Article Access Statistics
    PDF Downloaded27    
    Comments [Add]    

Recommend this journal