You are in: eMedicine Specialties > Orthopedic Surgery > SHOULDER Rotator Cuff PathologyArticle Last Updated: Nov 7, 2007AUTHOR AND EDITOR INFORMATIONSection 1 of 10
  Author: Rana Haris Bin Bilal, MBBS, Senior House Officer, Department of Orthopedic Surgery, Nuffield Orthopedic Center, UK Rana Haris Bin Bilal is a member of the following medical societies: British Medical Association Coauthor(s): Patrick J Duffy, MBBCh, FRCS (Trauma and Orth), Consultant Trauma Surgeon, Department of Orthopedic Surgery, Cumberland Infirmary Carlisle, UK; Badar Bin Bilal Shafi, MBBS, MRCP, Specialist Registrar in Clinical Radiology, Royal Liverpool University Hospital, UK; Suhaib Bin Bilal Hafi, MBBS, Foundation 2 House Officer, Department of Psychiatry, University Hospital of Aintree, UK Editors: Cato T Laurencin, MD, PhD, University Professor, Lillian T Pratt Distinguished Professor and Chairman, Department of Orthopaedic Surgery, The University of Virginia; Francisco Talavera, PharmD, PhD, Senior Pharmacy Editor, eMedicine; Pekka A Mooar, MD, Associate Professor, Department of Orthopedic Surgery, Temple University School of Medicine; Dinesh Patel, MD, FACS, Associate Clinical Professor of Orthopedic Surgery, Harvard Medical School; Chief of Arthroscopic Surgery, Department of Orthopedic Surgery, Massachusetts General Hospital; Mary Ann E Keenan, MD, Professor, Vice Chair for Graduate Medical Education, Department of Orthopedic Surgery, University of Pennsylvania School of Medicine; Chief of Neuro-Orthopedics Program, Department of Orthopedic Surgery, Hospital of the University of Pennsylvania Author and Editor Disclosure Synonyms and related keywords: rotator cuff tear, shoulder injury, rotator cuff injury, rotator cuff rupture, frozen shoulder, rotator cuff tendinitis, rotator cuff tendonitis, shoulder tendonitis, shoulder tendinitis INTRODUCTIONSection 2 of 10
  Background Frequency Shoulder pain is the third most common cause of musculoskeletal disorders (MSDs) after low back pain and cervical pain. Estimates of the cumulative annual incidence of shoulder disorders vary from 7-25% in the Western general population. The annual incidence is estimated at 10 cases per 1000 population, peaking at 25 cases per 1000 population in persons aged 42-46 years. In persons aged 70 years or older, 21% of persons have shoulder symptoms, most of which were attributed to the rotator cuff. In cadaver studies, the rate of full thickness tears varies from 18-26%. The rate of partial thickness tears varies from 32-37% after age 40 years. Before age 40 years, tears are rare. In magnetic resonance imaging (MRI) studies, tears have been observed in 34% of asymptomatic individuals of any age. After age 60 years, 26% of patients have partial thickness tears, and 28% demonstrate full-thickness tears. Morbidity and mortality As mentioned, shoulder pain is the third most common cause of MSDs after low back and neck pain. Although considered a benign condition, according to a study on the long-term outcome of rotator cuff tendinitis, 61% of the patients were still symptomatic at 18 months, despite receiving what was considered sufficient conservative treatment. Moreover, 26% of patients rated their symptoms as severe. MSDs are the primary disabling conditions of working adults. The prevalence of rotator cuff tendinitis has been found to be as high as 18% in certain workers who performed heavy manual labor. Webster and Snook estimated that the mean compensation cost per case of upper extremity work-related MSDs was $8070 in 1993; the total US compensable cost for upper extremity, work-related MSDs was $563 million in the 1993 workforce. The compensable cost is limited to the medical expenses and indemnity costs (lost wages). When other expenses (eg, full lost wages, lost production, cost of recruiting and training replacement workers, cost of rehabilitating the affected workers) are considered, the total cost to the national economy becomes much greater.7 The impact of rotator cuff disease on quality of life is even more difficult to assess than its cost. Further studies using valid methods such as the Medical Outcomes Study (MOS) 36-item short-form health survey (SF-36), which measure the impact of the disorder on general health, should help assess this issue. Race, sex, and age No known racial variation associated with rotator cuff disease is cited in the literature. In one study, a predominance of male patients (66%) seeking consultation for rotator disease is reported, but in other studies, the male-to-female ratio is 1:1. Rotator cuff disease is more common after age 40 years. The average age of onset is estimated at 55 years. Anatomy The rotator cuff is composed of 4 muscles—the subscapularis, supraspinatus, infraspinatus, and teres minor—and their musculotendinous attachments. The subscapularis muscle is innervated by the subscapular nerve and originates on the scapula. It inserts on the lesser tuberosity of the humerus. The supraspinatus and infraspinatus are both innervated by the suprascapular nerve, originate in the scapula, and insert on the greater tuberosity. The teres minor is innervated by the axillary nerve, originates on the scapula, and inserts on the greater tuberosity. The subacromial space lies underneath the acromion, the coracoid process, the acromioclavicular joint, and the coracoacromial ligament. A bursa in the subacromial space provides lubrication for the rotator cuff (see Image 3).8, 9 Functional anatomy Understanding the functional anatomy of the rotator cuff assists in understanding its disorders. The rotator cuff is the dynamic stabilizer of the glenohumeral joint. The static stabilizers are the capsule and the labrum complex, including the glenohumeral ligaments. Although the rotator cuff muscles generate torque, they also depress the humeral head. The deltoid abducts the shoulder. Without an intact rotator cuff, particularly during the first 60° of humeral elevation, the unopposed deltoid would cause cephalad migration of the humeral head, with resulting subacromial impingement. PATHOLOGYSection 3 of 10
Rotator cuff pathology can be caused by extrinsic (outside) or intrinsic (from within) causes. Extrinsic examples include a traumatic tear in tendons from a fall or accident. Overuse injuries from repetitive lifting, pushing, pulling, or throwing are also extrinsic in nature. Intrinsic factors include poor blood supply, normal attrition or degeneration with aging, and calcific invasion of tendons.8, 10, 11, 12, 13 Rotator cuff tendinitis is the term used to describe irritation of tendons either from excessive pressure on the acromion or, less commonly, from intrinsic tendon pathology. Irritation of the adjacent bursa is known as subdeltoid or subacromial bursitis. Repetitive overhead activities resulting in irritation of tendons and bursae from repeated contact with the undersurface of the acromion is termed impingement syndrome. Rotator cuff dysfunction is typically a continuum of pathology ranging from tendinitis and bursitis, to partial tearing, to a complete tearing in one or more of the tendons. Although the earlier stages may resolve with conservative care, actual tearing of the tendon can be more problematic. These tears most commonly occur at the tenoperiosteal (tendon-to-bone) junction. Because this area has a relatively poor blood supply, injury to the tendon at this location is very unlikely to actually heal. Additionally, the constant resting tension in the muscle-tendon unit, or muscle tone, pulls any detached fibers away from the bone, preventing their reattachment. Finally, joint fluid from within the shoulder may seep into the tear gap and prevent the normal healing processes from occurring. Possible causes of rotator cuff pathology are as follows:
DIAGNOSISSection 4 of 10
Patients with rotator cuff pathology commonly present with an activity related dull ache in their upper lateral (outer) arm and shoulder. Activity is usually most difficult above shoulder level. Many people have little or no discomfort with below-shoulder-level activities such as golf, bowling, gardening, writing, or typing. Conversely, tennis, baseball/softball, basketball, swimming, and painting are more problematic. HistoryA complete medical history should be obtained to direct the physical examination and make the correct diagnosis. Most of the time, the diagnosis can be made following a systematic history. Relevant history findings, treatments, and test results should complement the history of the present injury. Sometimes, relevant social and family histories are necessary. Patients with degenerative rotator cuff disease are almost always older than 40 years. Fifty percent of patients have a progressive onset of shoulder pain, whereas the other 50% can identify a specific event responsible for the onset of pain. The evolution of rotator cuff disease is characterized by variable episodes of recurrence following more intensive shoulder activities, followed by remission with rest or treatment. As the disease progresses, shoulder pain becomes more constant. Overhead and arm-length activities typically increase the pain. Discomfort and night pain can also be present. With time, the individual can notice some weakness during shoulder elevation. Crepitus can also be noted. With evolution of the disease, shoulder pain can be accompanied by cervical and mid-back pain. The following questions should help the physician assess the patient:
The importance of obtaining a systematic and detailed history cannot be overemphasized. Any attempt to shortcut the process leads to a nonfocused physical examination and an inaccurate diagnosis. Remember that a recent study assessing the interobserver agreement of a diagnostic classification of shoulder disorders based on history and physical examination showed only moderate agreement between experienced observers. Physical examinationA systematic examination of the shoulder region includes careful observation; palpation of the bones and soft tissues; assessment of passive and active ROM; and impingement and topographic tests complemented, as needed, by instability tests, labrum tests, and special tests. The examination is completed by a cervical spine examination, along with neurologic and vascular examination. Observation The observation begins from the moment the patient enters the room. The smoothness and symmetry of the shoulders and the movements of the upper extremities are evaluated, as is the patient's gait. The examiner must be aware of any signs of painful posturing and irregularity of motion of the affected shoulder. Bilateral examination allows for comparison of the affected shoulder with the unaffected one. The patient then must be asked to remove the appropriate amount of clothing to facilitate proper assessment of the bone and soft tissues. The shoulder, cervical region, and entire upper extremity must be assessed. The examiner should assess bones and joints for possible asymmetry or deformities and should assess for soft-tissue changes (eg, swelling, erythema, white shiny skin, loss of hair, atrophy) suggestive of vasomotor abnormalities. Scars and abrasions also must be noted. The observer should assess bony contours first and then soft tissues. Observation of the patient must be completed from the front, side, and back.
Palpation Like observation, palpation must be performed in an orderly manner, beginning with the anterior structures and finishing with the posterior structures. Palpation must include bony structures and soft tissues. Irregular joint surfaces, swelling, heat, crepitus, pain, tenderness, and muscle tension and spasms must be sought. Palpation can be performed more conveniently with the patient standing. In this position, the examiner can more easily move around the patient. The examiner should stand behind the patient for the palpation. Beginning with the anterior structures, the examiner palpates the sternoclavicular joint. Superior migration of the medial end of the clavicle is palpated if the joint is dislocated. The examiner must remember that the clavicle is superior to the manubrium. Always compare the affected side with the contralateral side. The sternocleidomastoid muscle also must be palpated, looking for tension and spasms. The muscle contracts to turn the head on the contralateral side. The muscle is easier to identify and palpate in this position. The sternal and clavicular heads of the muscle must be palpated. Hands can be moved medially to palpate the suprasternal notch. The first rib, the costochondral joints, and the sternum also should be assessed. The clavicle should be palpated along its whole length, looking for bumps (suggesting callus formation resulting from fracture), loss of continuity, and crepitus. The acromioclavicular joint is a common site of pain and must be palpated with care. Because the acromioclavicular joint is a superficial joint, swelling, synovial thickening, and/or crepitus can be palpated. Step deformities with superior migration of the lateral end of the clavicle, seen in dislocation or subluxation, are easily palpable. The coracoid process can be palpated approximately 2.5 cm (1 in) inferior and just medial to the acromioclavicular joint. The coracoid process is the site of origin of the short head of the biceps tendon, the coracobrachialis muscle, and the insertion of the pectoralis minor. The pectoralis major and minor also must be palpated. Muscle tension and spasms are commonly associated with shoulder disorders. The acromion and subacromial space are palpated. The subacromiodeltoid bursa can be palpated indirectly in the subacromial space. Because it is overlapped by the deltoid muscle, the bursa cannot be felt under the fingers; however, the examiner, through pressure on the deltoid muscle, applies indirect pressure on the inflamed bursa, causing pain. The examiner follows by palpating the greater tuberosity, the long head of the biceps tendon, and the lesser tuberosity. These structures can be identified easily in a lean patient by an experienced examiner. This identification may be more difficult in an overweight patient or one with abundant muscle mass. By rotating the shoulder medially (eg, by putting the dorsal aspect of the hand on the buttock), the examiner can feel the greater tuberosity on the anterior aspect of the shoulder, just inferior to the acromion. The supraspinatus, infraspinatus, and teres minor tendons all insert into this structure and, when inflamed, can produce pain upon palpation of the greater tuberosity. Keeping the fingers on the greater tuberosity, the examiner rotates the shoulder laterally. The fingers feel the bicipital groove where the long head of the biceps tendon can be palpated. Pain or thickening of the tendon sheet indicates an inflamed tendon, whereas its absence suggests a rupture or dislocation. By rotating the shoulder more laterally, the examiner can palpate the lesser tuberosity. The tendon of the subscapularis inserts on that structure, and when it is inflamed, the tendon is painful to palpation. With the shoulder back to a neutral position, extension of the shoulder allows palpation of the subacromiodeltoid bursae under the anterior edge of the acromion. All of these structures must be palpated gently because they may be tender. Any painful palpation must be compared with the contralateral shoulder. A positive finding is when pain is more significant on the affected side than on the contralateral shoulder. Any excessive pain caused by a vigorous palpation makes the examination less sensitive. The biceps muscle should be palpated, looking for any bulging that indicates a long head of the biceps tendon rupture. The deltoid muscle also must be palpated to look for painful spasm or tension. Tone and atrophy also are assessed. The examination is continued by palpation of the posterior structures. Bony structures can be rapidly assessed because they are rarely a source of pain. The spine of the scapula is palpated, followed by palpation of the superior medial angle of the scapula. The levator scapulae muscle that inserts on this angle is a common site of pain. The medial border of the scapula is then palpated from the superior to the inferior medial angle. The bony palpation is completed by palpation of the spinous processes of the dorsal and cervical spine. Because muscle spasm and tension are frequently associated with a rotator cuff disease, the posterior muscles must be palpated with care to identify and treat those muscles. The superior trapezius is commonly tense and painful and must be palpated from its cervical and occipital origin to its insertion on the spine of the scapula and the acromion. Under this muscle, lying in the supraspinatus fossa, the supraspinatus muscle also should be palpated. The rhomboid muscles, from C7 to T5, run downward to attach on the medial border of the scapula. These muscles, often a source of pain, are difficult to distinguish from the overlying middle trapezius muscle. The rhomboid muscles can be identified by asking the patient to put his or her hand behind the back, with the shoulder internally rotated and the elbow flexed, and to push posteriorly against a resistance. The muscle belly of the rhomboid muscles then becomes palpable. Muscle palpation is completed by assessing the infraspinatus, teres major and minor, and latissimus dorsi muscles. Range of motion Both active and passive ROM must be evaluated. Although some authors suggest that an assessment of passive ROM is not necessary if the patient is able to perform complete active ROM without pain, passive ROM must be assessed systematically. Some patients with glenohumeral ROM restrictions have learned to compensate with increased scapulothoracic mobility and seem to have near-normal active ROM. Movements (with the normal ranges provided) that should be assessed are abduction (70-180°), adduction (30-45°), flexion (160-180°), extension (45-50°), external rotation (80-90°), and internal rotation (90-110°).
Impingement tests Positive impingement tests result from the reproduction of impingement of the rotator cuff tendon by different provocative maneuvers.14 With anterosuperior impingement syndrome, the impingement occurs underneath the coracoacromial arch. With posterosuperior impingement syndrome, the impingement is on the posterosuperior border of the glenoid cavity. Finally, with anterointernal impingement syndrome, the impingement occurs in the subcoracoid space or in the coracohumeral interval. Impingement tests confirm an impingement syndrome; however, they do not determine the location of the rotator cuff lesion. A of cadaveric shoulders has shown that some provocative impingement tests—namely, the Neer and Hawkins-Kennedy tests—appear to elicit contact consistent with impingement.
Topographic tests Using resisted isometric contraction of specific muscles of the rotator cuff, the location of the tendon lesion causing the impingement can be identified. To identify the supraspinatus tendon, use the Jobe test or the full-can test.
To identify the infraspinatus tendon, use the infraspinatus isolation test or, less optimally, the Patte test.
To identify the teres minor tendon, use the same tests used for the infraspinatus tendon. No specific teres minor isolation tests have been developed. To identify the subscapular tendon, use the Gerber lift-off test or the Gerber push-with-force test.
To identify the long head of the biceps tendon, use the Speed palm-up test.
The Yergason test, in this author's opinion, is technically difficult and ineffective; therefore, it is not described. Generally, the topographic tests are sensitive but not specific, except for the Gerber lift-off test. The combination of impingement tests and topographic tests helps determine whether a patient's symptoms are caused by rotator cuff disease. As mentioned, the examination must be completed by instability and labrum tests, special tests (eg, thoracic outlet syndrome tests), a cervicothoracic spine examination, and a neurologic and vascular examination, but it is not the purpose of this section to describe them all. Imaging studiesA wide variety of radiologic examinations are offered to image the rotator cuff. Each of them has advantages and limitations. To prescribe the most useful examination, one must start with a good clinical history and physical examination. Imaging should be used to confirm the anomaly and to describe its extension and the associated findings. The following paragraphs briefly explain the indications, the technique, and the findings for each modality available to image the rotator cuff in radiology.15 Plain film radiography
Arthrography
CT arthrography
Magnetic resonance imaging (Arthrography)
The size and morphologic features of rotator cuff tears may influence treatment selection and affect final outcomes. Magnetic resonance arthrography allows observation of these features and other intra-articular structures. In one series, Toyoda and colleagues19 compared MRI with MRI arthrography. To assess the utility of magnetic resonance imaging in assessing size and morphologic features, the authors did a retrospective analysis of 41 shoulders in 37 consecutive surgically treated patients (mean age, 63.2 years) who had MRI followed by magnetic resonance arthrography. The maximum rotator cuff defect size in the anteroposterior direction defined transverse size, and the maximum rotator cuff defect size in the mediolateral direction defined longitudinal size. Sensitivity for detecting full-thickness rotator cuff tears by MRI was 90.2%, compared with 100% for magnetic resonance arthrography.19 Magnetic resonance arthrography also allowed morphologic classification of the torn tendon as blunt end, tapering end, indistinct end, horizontal tear, and global tear. There was good agreement in classifying torn edges: the imaging findings agreed with findings at surgery. Magnetic resonance arthrography was more accurate in evaluating both rotator cuff tear size and morphologic features than MRI.19 With the aid of fat-suppressed imaging, full thickness and partial cuff tears can be identified with 100% sensitivity and specificity. Fat-suppressed images also showed intratendinous contrast material imbibition in 3 torn cuffs with frayed, friable tendon margins. Fat suppression in MR arthrography is valuable in the differentiation between partial and full-thickness cuff tears and in the detection of small partial tears of the inferior tendon surface. Ultrasonography Ultrasound uses the same principles as radar. The images are created using a high-resolution transducer that first sends a sound signal and then receives the echo produced when the sound hits the different structures at different depths.17, 20
Nuclear medicine imaging Bone scintigraphy is not used routinely in rotator cuff disease imaging. TREATMENTSection 5 of 10
Conservative therapiesPhysical therapy can be a useful adjunct in the conservative treatment of patients with degenerative rotator cuffs. Although numerous studies have been performed on conservative treatment and surgical approaches of the painful shoulder and, more specifically, the rotator cuff, the conclusion of a review of randomized, controlled trials of interventions for painful shoulder was that little evidence supports or refutes the efficacy of common interventions for shoulder pain.21, 22, 23 Drawing firm conclusions about the efficacy of any of these interventions remains difficult because of, among other reasons, the lack of definition and strict diagnostic criteria for the different painful shoulder conditions, valid randomization procedures, blinding, valid scales for outcome measurement, and heterogeneous populations. In their approach to conservative patient treatment, clinicians must be critical and try to use an evidence-based medicine approach as much as possible. The clinician must also use a combination of experience and intuition to compensate for the lack of scientific evidence supporting the different therapeutic modalities. Conservative treatment of the degenerative rotator cuff involves pain relief; avoidance of painful motions and activities; simple analgesics and NSAIDs; manual physical therapy for the glenohumeral, scapulothoracic, acromioclavicular, and sternoclavicular joints and the parascapular and scapula-stabilizer muscles; subacromial corticosteroid injection; bupivacaine suprascapular nerve block; restoration of motion and normal scapulohumeral rhythm; stretching of the glenohumeral capsule and muscles; and manual therapy of the cervicodorsal spine (often necessary because of its close relationship with the shoulder). Ultrasound Ebenbichler showed in a randomized, doubled-blind, placebo-controlled study that the use of a pulsed ultrasound performed 5 times a week for 15 minutes (0.89 MHz frequency, 2.5 W/cm2, pulsed mode 1:4) significantly resolves calcification of the shoulder, decreases pain, and improves the short-term quality of life.24, 25 Long-term follow-up did not show significant differences; however, in the long term, the symptoms of calcifying tendinitis may be self-limiting and may improve independently from the resolution of the calcium deposit. This theory may explain why the use of ultrasound is only significantly effective in the short term. The short-term efficacy of ultrasound therapy has been demonstrated only in calcifying tendinitis. Its efficacy in other shoulder disorders has not been shown. Extracorporeal shockwave therapy Another modality that looks promising is extracorporeal shockwave therapy. Passing a strong electric current through a flat coil induces a magnetic field and generates shock waves. Shock waves were used first for the treatment of delayed union and nonunion of fractures by stimulating osteogenesis. In an uncontrolled study, shockwave therapy (1500 impulses of 0.28 mJ/mm2) reportedly disintegrated calcium deposits partially or completely in 62% of patients, and 75% had significant improvement in pain, power, ROM, and shoulder function. The authors of the study concluded that a larger-scale, placebo-controlled trial should be conducted to analyze the benefits of this modality. A prospective, randomized, controlled study using a valid functional shoulder scale showed the efficacy of extracorporeal shockwave therapy. At 3-6 months, significant improvement occurred in pain and function. At 6 months, calcium deposits disappeared or disintegrated in up to 77% of patients' radiographs. Comparing different regimens of shockwaves, the authors concluded that the improvement in pain and function and the radiologic disintegration of calcification were dose-dependent.26, 27, 28, 29 Extracorporeal shockwave therapy appears to be a promising treatment for calcifying tendinitis. Similar to ultrasound, its efficacy in other shoulder conditions has not been established. Iontophoresis Randomized, controlled studies have shown the efficacy of topical steroids, NSAIDs, and acetic acid iontophoresis, as compared with placebo, in different MSDs; however, the studies were not specifically on rotator cuff disease. Moreover, a recent trial did not show any difference in outcomes between no treatment and treatment with acetic acid iontophoresis followed immediately by 9 sessions of ultrasound therapy in a constant mode (0.8 W/cm2 at a frequency of 1 MHz for 5 min) over a period of 3 weeks. Some authors could not show any effect of iontophoresis on steroid migration through in vivo and in vitro studies, whereas others did. Thus, no conclusions can be made regarding the efficacy of iontophoresis in the treatment of rotator cuff disease. Subacromial corticosteroid injection As with NSAID therapy, many of the studies on the efficacy of corticosteroid injection for various shoulder conditions are of poor methodological quality. Green, van Der Heijden, and Sibilia performed a systematic review of all the randomized clinical trials on corticosteroid injection. Although the trials selected were essentially the same in the 3 studies, their conclusions differ because of the different assessment methods. Two of these articles suggested that corticosteroid injection may be superior to placebo in the short-term treatment of rotator cuff tendinitis, whereas one suggested that no conclusive evidence was found regarding the efficacy of corticosteroid injection.30, 31, 32, 33 Subacromial corticosteroid and local anesthetic agent injection also appear to be more effective than an injection of a local anesthetic alone, although some authors disagree. Corticosteroid injection also appears to be significantly more effective than NSAIDs. Therefore, subacromial corticosteroid injection appears indicated when pain persists after simple analgesics and NSAIDs have been used.34 Because some authors have reported poorer surgical outcome in patients who have had 3 or more corticosteroid injections, the recommendation is that no more than 2 injections be given. No trials have compared the different routes of corticosteroid injection; thus, the physician should select his or her preferred route. Additionally, no trial has compared the efficacy of different corticosteroids. Triamcinolone acetonide is the agent most frequently studied. The action mechanism is inhibition of prostaglandin formation by selective cyclooxygenase (COX)–2 activity. The optimal dose has not been evaluated. Recommended doses vary from 20-80 mg in the different trials. This author recommends 20-40 mg of triamcinolone acetonide. Adverse effects can be local or systemic. Although systemic adverse effects can occur following a subacromial injection, only local adverse effects are discussed here. Possible adverse effects include dermal atrophy, necrosis and loss of pigmentation, synovitis, septic arthritis, hemarthroses, cartilage damage and degeneration, tendon rupture, and Charcot arthropathy. Bupivacaine suprascapular nerve block The bupivacaine suprascapular nerve block is a relatively unknown, although effective, method to treat different painful shoulder disorders. A few randomized controlled trials have demonstrated its efficacy for painful shoulder associated with rheumatoid arthritis, for chronic rotator cuff disease, and for frozen shoulder. Preliminary data of a study on chronic impingement syndrome conducted at the Montreal Rehabilitation Institute show its efficacy compared with placebo. At 3 months, a significant improvement in pain and function, measured by a valid functional shoulder scale, was observed. The efficacy of this procedure is supported by randomized controlled studies, and it appears to be a very promising new approach in the treatment of rotator cuff disease.35 The technique for nerve block is very inexpensive, simple, and safe. It consists of injecting 10 mL of bupivacaine 0.5% in the supraspinatus fossa of the scapula to produce an indirect suprascapular nerve block. In rotator cuff disease, 2 injections are administered 4 weeks apart Surgical treatmentPatients with more advanced rotator cuff disease or a more significant injury may not respond to conservative therapies. If the patient believes that his or her quality of life is being significantly impacted by the shoulder dysfunction, then surgical intervention is a reasonable consideration. In some cases, simple debridement of a frayed or partially torn cuff tendon, along with smoothing of the undersurface of the acromion (acromioplasty) above the tendon, may be all that is needed. More significant partial tearing (>50% of tendon thickness) and complete tears require reattachment of the tendon ends back to the humeral head.36, 37, 38 Open surgery Rotator cuff repair is most commonly performed using an open surgical procedure, which typically requires a 2- to 4-in incision at the top of the shoulder. The deltoid muscle is split, and the undersurface of the acromion is smoothed. Strong stitches are placed in the torn ends of the rotator cuff tendons, and they are attached back to the bone of the humerus through specially created tunnels or commercially available suture anchors. Because the entire shoulder cannot be visualized through the open approach, many surgeons perform an initial diagnostic arthroscopy of the shoulder at the time of the repair to be sure no other coexisting problems are present within the shoulder that could also be addressed at the open procedure. This technique may be performed in an inpatient setting or in an outpatient surgery facility, providing that the patient is comfortable enough to return home the same day. Standard tendon repair techniques combined with anterior acromioplasty, postoperative limb protection, and monitored physiotherapy can produce consistent and lasting pain relief and improvement in range of motion. Open rotator cuff repair has been known to have excellent outcomes and patient satisfaction since the early 80s. Romeo and colleagues have reported 94% patient satisfaction 4 years after open rotator cuff repair, with lasting relief of pain and improved function.39 In another series, Baysal has reported that 96% of patients were satisfied or very satisfied with the results of their repair; 78% of patients who were working before surgery returned to work without modification by 1 year postoperatively. For the most part, patient age and size of tear did not influence postoperative range of motion or health-related quality of life.40 Arthroscopy Arthroscopic surgery involves the use of a special camera attached to a long, narrow surgical telescope to visualize the inside of a joint. Working through small incisions about the size of dress-shirt buttonholes, the surgeon can use specially created instruments to repair damaged cartilage, capsule, tendon, and other tissues. The camera transmits the signal to a video monitor for improved visualization and to allow photographic and videographic documentation of the surgical findings and the procedure. In orthopedic surgery, arthroscopy was first used to treat conditions of the knee. With new technology and refined techniques, arthroscopic surgery has become quite common for treating many knee, shoulder, elbow, wrist, hip, ankle, and foot problems.41, 42, 43 Arthroscopic treatment of rotator cuff disease initially consisted of rotator cuff inspection and debridement and arthroscopic acromioplasty. If a repairable rotator cuff tear was discovered, an open or mini–open repair of the tendon was then performed. As surgeons' skills improved and more specialized instrumentation was developed, it became possible to fix relatively small tears using arthroscopic techniques to insert anchors, pass sutures, and tie knots. In current practice, surgeons can now perform shoulder arthroscopy to repair even large rotator cuff tears using these techniques. Arthroscopic rotator cuff repair is a technically challenging procedure (see Images 5-12) that requires advanced arthroscopic surgical skills, careful preoperative planning, and a step-wise, systematic approach. The procedure may be performed with the patient in a "beach chair" (sitting) or a lateral decubitus (side-lying) position. Usually, the patient is under general anesthesia. Small (5-mm) incisions are created in the back, side, and front of the shoulder, and the arthroscope and instruments may be switched between each of these positions as necessary. A complete diagnostic arthroscopy and bursoscopy (inspection of bursa) is initially performed. Care is taken to inspect the biceps tendon within the shoulder, the fibrous ring or labrum that surrounds the glenoid, the capsule and ligaments, the cartilage surfaces of the head and glenoid, and the rotator cuff tendons. Any pathology is addressed only after a complete inspection, so as not to miss any significant findings. Careful preoperative radiographic evaluation of the shape and size of the acromion, along with a notation of any spurs, serves as a guide for the extent of any acromioplasty (undersurface smoothing) necessary. Because the arthroscope magnifies the structures seen, irregularities in the surface of less than 1 mm can be seen and are removed. The goal is to smooth and flatten the undersurface of the acromion to provide more room for the repair and to relieve pressure from the healing tendon. An overly aggressive acromioplasty must be avoided because excessive removal of the anterior acromion can result in the humeral head sliding forward, up, and out of the socket (anterosuperior subluxation). The rotator cuff tear is then visualized through the lateral (side) portal from the "50-yard-line view." The size and pattern of the tear are assessed. Any thin or fragmented portions are removed, and the area where the tendon will be reattached to the bone is lightly debrided to encourage new blood vessel ingrowth for healing. The sutures are once again passed through the tendon and systematically tied. The sutures pull the tendon down to the prepared bone surface, closing the defect. This completes the repair. At the completion of the procedure, the shoulder is injected with a long-acting local anesthetic to assist with postoperative pain management. Each portal incision is closed with a single nylon stitch and covered with a sterile bandage tape, followed by a dry, sterile dressing. A cryotherapeutic shoulder pad (Cryocuff) is applied to provide postoperative cold therapy. This assists in management of pain and swelling. Finally, a sling (Don Joy UltraSling II) is applied for immobilization and protection. The patient is then taken to the recovery room. Arthroscopic rotator cuff repair has achieved good-to-excellent results in a large percentage of patients (95% reported in one series), with the results being independent of tear size. U-shaped tears repaired by margin convergence have been shown to have results comparable to those of crescent-shaped tears repaired directly by a tendon-to-bone technique. There is a rapid return to full overhead function after arthroscopic rotator cuff repair (average, 4 months for all tear sizes). A delay between the time of injury and the time of diagnosis, even of several years, is not a contraindication for arthroscopic rotator cuff repair. Prosthetic implants (tissue engineering) Tissue-engineering techniques are being used to develop therapies for tendon reconstruction. Biologic and synthetic scaffolds can both repair tendon defects and improve healing by allowing for the regeneration of the tendon's natural biologic composition to restore its mechanical capacity. This process can be further enhanced through augmentation methods such as cell seeding, growth factor implantation, and gene therapy. There are many engineered prosthetic materials being used, but there is no widely accepted treatment for massive irreparable rotator cuff tears. Allografts have been used for repair of large defects but with very little success. MEDICATIONSSection 6 of 10
Simple analgesicsAcetaminophen is recommended as initial treatment because of the toxicity associated with NSAIDs, the need for an analgesic rather than anti-inflammatory effect, the lower cost of a simple analgesic, and the chronicity of degenerative rotator cuff disease, . While NSAIDs are known to be effective in reducing pain and improving function and ROM, they may exert their effect through their analgesic rather than their anti-inflammatory properties. One study with poor methodologic quality showed no short-term superiority of NSAIDs over acetaminophen in the treatment of painful shoulder syndrome. Long- and short-term studies comparing the efficacy of NSAIDs with that of acetaminophen for osteoarthritis of the knee have shown similar efficacy for the 2 agents. Moreover, even the presence of inflammatory signs did not predict a better response to treatment with NSAIDs, suggesting that improvements are not necessarily dependent on an anti-inflammatory effect. Ibuprofen (Ibuprin, Advil, Motrin) If the patient has no contraindications to the use of ibuprofen, it is usually the drug of choice for the treatment of mild to moderate pain. It inhibits inflammatory reactions and pain by decreasing prostaglandin synthesis.
Acetaminophen (Tylenol, Feverall, Aspirin-Free Anacin) The analgesic effect of acetaminophen is mediated by prostaglandin inhibition.
Nonsteroidal anti-inflammatory drugsNumerous studies on the efficacy of NSAIDs for different shoulder conditions have been published, but because most of them have poor methodologic quality, no conclusions can be drawn about the efficacy of NSAIDs. Recent review articles, using strict inclusion criteria based on the quality of the methodology, concluded that the trials with the best methodology show a superior short-term efficacy (2 wk) of NSAIDs compared with placebo; however, at 4 weeks, results did not show any statistical differences. Therefore, a short course (10-14 d) of NSAIDs is indicated as a second-line treatment. No evidence supports longer use. In case of persistent pain, other therapeutic modalities should be sought. A comparison between different types of NSAIDs did not show evidence of the superiority of 1 NSAID with respect to efficacy. Therefore, an NSAID with the fewest adverse effects, such as the newer COX-2 selective molecules or an NSAID with a combination of prostaglandin E1 analogue (diclofenac/misoprostol), should be the drug of choice. In an aging population taking additional medication that may interact with NSAIDs, drug interactions must be avoided. From 40-60% of drugs consumed are over-the-counter medications, most often analgesics and NSAIDs, increasing the risk of potential adverse gastrointestinal side effects. The patient should be asked whether he or she is taking any medications concomitantly, such as anticoagulants (hemorrhage), corticosteroids (peptic ulcer), diuretics and antihypertensives (decreased blood pressure control), ACE inhibitors (acute renal failure), high-dose methotrexate (increased methotrexate toxicity), lithium, digoxin, aminoglycosides (decreased renal clearance), phenytoin (decreased albumin binding), and antacids (decreased NSAID levels). NSAIDs should be avoided, if possible, in elderly patients with congestive heart failure or renal or hepatic dysfunction and who are taking other medications. Celecoxib (Celebrex) Celecoxib primarily inhibits COX-2, which is considered an inducible isoenzyme—that is, it is induced during pain and inflammatory stimuli. Inhibition of COX-1 may contribute to NSAID gastrointestinal toxicity, but at therapeutic concentrations, celecoxib does not inhibit the COX-isoenzyme; therefore, gastrointestinal toxicity may be decreased. The lowest dose of celecoxib should be sought for each patient.
Ketoprofen (Orudis, Actron, Oruvail) Ketoprofen is used for relief of mild to moderate pain and inflammation. Small initial dosages are indicated in small and elderly patients and in persons with renal or liver disease. Doses of more than 75 mg do not increase therapeutic effects. Administer high doses with caution and closely observe patients for response.
DIFFERENTIAL DIAGNOSISSection 7 of 10
Adhesive capsulitis Biceps rupture Bicipital tendinitis Cervical disk disease Cervical myofascial pain Cervical spondylosis Cervical sprain and strain Complex regional pain syndromes Fibromyalgia Myofascial pain Osteoarthritis Rheumatoid arthritis Rotator cuff disease Shoulder and hemiplegia Thoracic outlet syndrome FOLLOW-UPSection 8 of 10
MULTIMEDIASection 9 of 10
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