Polymyositis

Back

Practice Essentials

Polymyositis is an idiopathic inflammatory myopathy characterized by the following[1] :



View Image

MRI of thighs showing increased signal in the quadriceps muscles bilaterally consistent with inflammatory myositis.



View Image

Histopathology of polymyositis showing endomysial mononuclear inflammatory infiltrate and muscle fiber necrosis.

Polymyositis is one of several idiopathic inflammatory myopathies.[2] Clinically similar to polymyositis, dermatomyositis is an idiopathic inflammatory myopathy associated with characteristic dermatologic manifestations.[3] Inclusion body myositis is a slowly progressive, idiopathic, inflammatory myopathy with characteristic pathologic findings that is generally found in older men. Bohan and Peter classified the idiopathic inflammatory myopathies as follows[4] :

Necrotizing autoimmune myopathy (NAM) is a recently recognized form of idiopathic inflammatory myopathy that is identified by finding macrophage-predominant myocyte destruction, with few to no lymphocytes, on muscle biopsy. NAM has been associated with malignancy and statin use.[6]

See Etiology, Presentation, and Workup.

Polymyositis and dermatomyositis have many shared clinical features. Both present as symmetrical muscle weakness that develops over weeks to months. Initial treatment with corticosteroids usually produces a response; however, nonresponders require further treatment. Moreover, both conditions may be associated with malignancies.[5] Despite these similarities, muscle biopsy findings and characteristic skin findings of dermatomyositis reveal each as a distinct clinical entity.

Although classified as an inflammatory myopathy, inclusion body myositis shows minimal evidence of inflammation. This is the most common inflammatory myopathy in patients older than age 50 years. It more commonly presents as asymmetrical, distal weakness and also has distinct biopsy findings. Studies so far have yielded less favorable results than treatment for polymyositis and dermatomyositis. (See Treatment and Medication.)

Patient education

Patients with polymyositis should be educated early about the disease and should be provided with realistic expectations about outcomes. Most patients show significant improvement with treatment.

Stress the need for close follow-up care, continued physical therapy, and long-term therapy with monitoring of several parameters, and warn patients regarding adverse events related to medications. Patients may visit The Myositis Association Web site for more information.

Etiology

Polymyositis is an immune-mediated syndrome secondary to defective cellular immunity that is most commonly associated with other systemic autoimmune diseases. It may be due to diverse causes that occur alone or in association with viral infections, malignancies, or connective-tissue disorders.

Evidence points toward a T-cell–mediated cytotoxic process directed against unidentified muscle antigens. Supporting this conclusion is the involvement of CD8 T cells, which, along with macrophages, initially surround healthy nonnecrotic muscle fibers and eventually invade and destroy them. (See the image below.)



View Image

Close view of muscle biopsy, showing chronic inflammatory infiltrate consisting of T lymphocytes, especially CD8+ T lymphocytes.

The factors triggering a T-cell–mediated process in polymyositis are unclear. Viruses have been implicated; so far, however, the only viruses that have been etiologically connected with the disease are the human retroviruses human immunodeficiency virus (HIV) and human T-cell lymphotrophic virus type I (HTLV-I), the simian retroviruses, and coxsackievirus B. Those viruses may directly invade the muscle tissue, damaging the vascular endothelium and releasing cytokines, which then induce abnormal expression of the major histocompatibility complex (MHC) and render the muscle susceptible to destruction.

An autoimmune response to nuclear and cytoplasmic autoantigens is detected in about 60-80% of patients with polymyositis and dermatomyositis. Some serum autoantibodies are shared with other autoimmune diseases (ie, myositis-associated antibodies [MAAs]), and some are unique to myositis (ie, myositis-specific antibodies [MSAs]). The MSAs are found in approximately 40% of patients with polymyositis or dermatomyositis, whereas MAAs are found in 20-50% of these patients.

Myositis-specific antibodies

The identified MSA targets include the following 3 distinct groups of proteins:

Most of the anti-tRNA synthetase antibodies are directed toward functional and highly conserved domains of the enzyme. As many as 6 of 20 aminoacyl-tRNA synthetases have been described, but anti-histidyl-tRNA synthetase (Jo-1) is most common (20-30%). Autoantibodies directed toward the other synthetases specific for alanine (anti-PL12), glycine (anti-EJ), isoleucine (anti-OJ), threonine (anti-PL7), and asparagine (anti-KS) have been reported in only about 1% of patients.

Anti-Jo-1 autoantibodies were originally described as precipitating autoantibodies in sera of patients with polymyositis. Later, the anti-Jo-1 antibodies were recognized to be specific for patients with polymyositis. The target for the anti-Jo-1 antibodies was the aminoacyl-tRNA synthetases, a family of distinct cellular enzymes.

The Jo-1 antigen is histidyl-tRNA synthetase. This enzyme is partially responsible for attaching tRNA to their cognate ribosomal RNA (rRNA). The Jo-1 antigen migrates as a 53-kd protein on sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS-PAGE).

The presence of autoantibodies against the Jo-1 antigen has been reported in up to 23% of polymyositis patients by immunodiffusion. Anti–Jo-1 antibodies are almost completely specific for myositis and are more common in polymyositis than in dermatomyositis; they are rare in children. The presence of anti-Jo-1 antibodies defines a distinct group of polymyositis patients with interstitial lung disease, arthritis, and fevers. The anti–Jo-1 response appears to be self-antigen driven, having a broad spectrotype over time and undergoing isotype switching. Anti–Jo-1 antibodies also inhibit the function of histidyl-tRNA synthetase in humans more than they do in other species.

Anti-Mi-2 antibodies recognize a major protein of a nuclear complex formed by at least 7 proteins that is involved in the transcription process. Autoantibodies recognizing Mi-2 are considered specific serologic markers of dermatomyositis. They are detected in about 20% of patients with myositis and are associated with relatively acute onset, a good prognosis, and a good response to therapy.

Anti-SRP antibodies are directed toward an RNA-protein complex that consists of 6 proteins and a 300-nucleotide RNA molecule (7SL RNA). Patients with anti-SRP antibodies have acute polymyositis with cardiac involvement, a poor prognosis, and a poor response to therapy.

Myositis-associated antibodies

The MAA are found in the sera of 20-50% of patients and are commonly encountered in other connective tissue diseases. The most important antigenic targets of the MAA are the following:

Anti-PM/Scl autoantibodies are generally found in patients affected by polymyositis overlapping with scleroderma. Anti-Ku antibodies are found in patients with myositis overlapping with other connective tissue diseases.

Antibodies directed against snRNP are frequently found in patients with myositis and in patients with connective tissue–disease overlap syndrome, whereas antibodies toward Ro/SSA 60 kD, Ro/SSA 52 kD, and La/SSB protein components of the RoRNP complex are almost exclusively found in patients with Sjögren syndrome and systemic lupus erythematosus (SLE).

Risk factors

An increased association of myositis has been found with human leukocyte antigen (HLA) haplotypes A1, B8, and DR3, which also increase the risk for autoimmune diseases. Environmental triggers, especially infectious agents, have been suggested as etiologic agents. These include the following:

Many drugs are known to cause myopathy. Most drugs, such as hydroxychloroquine and colchicine, cause a toxic or metabolic myopathy.

Several drugs, however, rarely induce an immune-mediated myopathy or myositis. Muscle biopsy shows chronic inflammatory changes consistent with polymyositis. Drugs such as D-penicillamine, hydralazine, procainamide, phenytoin, and angiotensin-converting enzyme (ACE) inhibitors have been associated with this type of inflammatory myopathy. Statins occasionally cause severe muscle inflammation and rhabdomyolysis.

Epidemiology

Frequency

Idiopathic inflammatory myopathies are relatively rare diseases, with an incidence in the United States that ranges from 0.5-8.4 cases per million population. Polymyositis is more common in the United States within the black population, with the estimated black-to-white incidences for polymyositis and dermatomyositis being 5:1 and 3:1, respectively. Internationally, polymyositis is less common among Japanese persons.

Sex- and age-related demographics

Polymyositis and dermatomyositis are more common in women than in men (2:1 ratio), while inclusion body myositis is twice as common in men.

Polymyositis usually affects adults older than 20 years, especially those aged 45-60 years. Polymyositis rarely affects children. The age of onset of polymyositis with another collagen vascular disease is related to the associated condition.

Although dermatomyositis is primarily a disease of adults, it also is observed in children, usually those aged 5-14 years. Eighty percent of patients with inclusion body myositis are older than 50 years at onset.

Prognosis

In most patients, polymyositis responds well to treatment, although residual weakness occurs in approximately 30% of patients. Osteoporosis, a common complication of long-term corticosteroid therapy, may cause significant morbidity. A study from Taiwan determined that the risk of osteoporosis was 2.99 times higher in patients with polymyositis, and that the risk was independent of corticosteroid and immunosuppressant treatment.[7]

Poor prognostic factors include the following:

Morbidity and mortality

Complications of polymyositis may include the following:

Carruthers et al reported that patients with polymyositis are at increased risk for venous thromboembolism (VTE), with hazard ratios of 7.0 for VTE, 6.16 for deep venous thrombosis, and 7.23 for pulmonary embolism. Overall, the highest calculated incidence rate ratios were observed in the first year after diagnosis of polymyositis.[11]

The incidence of lung, bladder, and non-Hodgkin lymphoma may be increased in patients with polymyositis, especially in the first year after diagnosis.

Polymyositis shares pathologic characteristics and immunologic features with  amyotrophic lateral sclerosis (ALS), and a nationwide cohort study from Taiwan found that a diagnosis of polymyositis increased the likelihood of a subsequent diagnosis of ALS (P <0.001). The association was independent of sex, age, and concomitant autoimmune diseases.[12]

Five-year survival rates in polymyositis have been estimated at more than 80%. Mortality is most often related to associated malignancy or pulmonary complications; however, elderly patients with cardiac involvement or dysphagia also have a higher mortality rate.[13]

 

History

Symptoms of polymyositis gradually develop over a period of 3-6 months. Diagnosis is usually delayed, because, unlike in dermatomyositis, no associated rash occurs before the onset of muscle disease. Family history and medication history are important in excluding other causes of myopathy.

The history of patients with polymyositis or dermatomyositis typically includes the following:

Muscular symptoms

Patients with polymyositis usually present with symmetrical, proximal muscle weakness in the upper and lower extremities. Weakness of neck flexors also occurs. Patients with polymyositis may occasionally report muscle pain and tenderness, which may be confused with symptoms of polymyalgia rheumatica. The disease may exist for several months before the patient seeks medical advice, and all of the muscles of the thighs, trunk, shoulders, hips, and upper arms are usually involved. Muscle weakness may fluctuate on different days and at different times. 

Fine motor movements that depend on the strength of distal muscles, such as buttoning a shirt, sewing, knitting, or writing, are affected only late in the disease.

Dysphagia secondary to oropharyngeal and esophageal involvement occurs in about one third of patients with polymyositis and is a poor prognostic sign. Dysphonia is also a poor prognostic sign but is much less common.

Ocular muscles are never involved in generalized polymyositis. However, isolated orbital myositis, an inflammatory disorder involving the extraocular muscles, is well described. Facial and bulbar muscle weakness is extremely rare in individuals with polymyositis.

A family history of neuromuscular disease, endocrinopathy, or exposure to myotoxic drugs or toxins is absent.

Constitutional symptoms

Polymyositis is a systemic disease. Symptoms may include the following:

Pulmonary manifestations

Pharyngeal and esophageal weakness may lead to aspiration pneumonia. Patients with polymyositis may experience exertional dyspnea secondary to weakness of chest wall muscles and diaphragmatic muscles. Patients receiving immunosuppressants are at an increased risk of infection.

Interstitial lung disease occurs in 5-30% of patients with idiopathic inflammatory myopathy (associated with antisynthetase antibodies, especially anti-Jo-1). Patients may be asymptomatic or present with exertional dyspnea, cough, and fever.[14]

Interstitial pneumonitis, bronchiolitis obliterans organizing pneumonia, and pulmonary capillaritis have been described in conjunction with polymyositis.

Cardiac manifestations

Cardiac involvement is unusual and, if present, portends a bad prognosis. Rhythm disturbances, conduction defects, congestive heart failure, pericarditis, pulmonary hypertension, and myocarditis can occur.

Joint involvement

Patients can present with arthralgias or arthritis. Arthritis is usually symmetrical and involves the knees, wrists, and hands (associated with antisynthetase antibodies). A severe, deforming arthropathy without erosions has been reported; erosive changes are very rare.

Overlap syndromes

Polymyositis has been associated with other connective-tissue diseases, including the following:

About 25% of patients with scleroderma have myositis; this phenomenon has been associated with anti-PM/Scl (anti-PM-1) antibody. In Japan, anti-Ku antibody has been described with this condition.

Gastrointestinal manifestations

Symptoms may include the following:

Renal manifestations

Intrinsic renal disease is rare in patients with polymyositis. Occasionally, severe rhabdomyolysis with myoglobinuria can result in acute tubular necrosis.

Cutaneous manifestations

Unlike in dermatomyositis, rash is absent in polymyositis. However, "mechanic's hands" (associated with antisynthetase antibodies), ie, hyperkeratotic eruptions over the finger pads and lateral aspects of the fingers, have been reported.

Raynaud phenomenon has been described in patients with antisynthetase antibodies. Rarely, periorbital edema may occur (best described in dermatomyositis). Calcinosis occurs in approximately 5% of patients with polymyositis (in association with scleroderma like illness). Telangiectasias are uncommon.

Inclusion body myositis

This condition is a slowly progressive, idiopathic, inflammatory myopathy that mostly affects men older than age 50 years. Muscle involvement predominantly includes proximal muscles but may also include distal muscles (50%), and involvement may be asymmetrical. Dysphagia is found in most patients (60%).

Physical Examination

Muscle weakness in polymyositis is symmetric and proximal. It is not painful, although a minority of patients report aches or cramps. On occasion, the muscle may be sore to palpation and may have a nodular and grainy feel.

Sensory examination findings are normal. Ocular and facial muscles remain normal even in advanced, untreated cases. 

The pharyngeal and neck flexor muscles are often involved, causing dysphagia and difficulty in holding up the head. When the patient is first seen, many of the muscles of the trunk, shoulders, hips, upper arms, and thighs are usually involved. In restricted forms of the disease, only the neck or paraspinal muscles (camptocormia) are affected.[15]

In advanced cases and rarely in acute cases, respiratory muscles are affected. Severe weakness is almost always associated with muscular wasting. Dysphonia with nasal speech may be noted. Lung examination findings may include evidence of interstitial lung disease, such as dry inspiratory crackles ("Velcro") in the lung bases.

The tendon reflexes are preserved, but they may be absent in severely weakened or atrophied muscles.

Primary cardiac abnormalities due to myocarditis may be present in a few patients. These abnormalities mainly manifest as atrioventricular conduction defects, tachyarrhythmias, low ejection fraction, dilated cardiomyopathy, or congestive heart failure.

General systemic disturbances, such as fever, malaise, weight loss, arthralgia, and Raynaud's phenomenon, may occur when polymyositis is associated with another connective-tissue disorder.

Inclusion body myositis

Inclusion body myositis manifests as severe, proximal muscle weakness with atrophy, often with distal muscle weakness. The weakness may be asymmetrical. Deep tendon reflexes may be impaired or absent if weakness is severe.

Complications

Complications include the following:

Approach Considerations

The following laboratory findings may be present in polymyositis:

Perform age-appropriate evaluation for malignancy. Testing for associated malignancy is based on age and sex and can be performed using imaging techniques such as chest radiography, computed tomography (CT) scanning, mammography, pelvic ultrasonography, upper and lower gastrointestinal endoscopy, and magnetic resonance imaging.

Depending on the clinical presentation, other studies that may be appropriate include the following:

Muscle enzyme levels

Serum creatine kinase (CK) levels are usually elevated in persons with polymyositis, ranging from 5-50 times the reference range. A level greater than 100 times the reference level is rare.

Serum CK levels, along with careful physical examination, may be used to monitor myositis activity. However, serum CK levels may be within reference ranges despite increased disease activity (eg, in cases of chronic and late-stage polymyositis). CK levels are usually minimally elevated or within the reference range in patients with inclusion body myositis. CK levels are within the reference range in patients with corticosteroid-induced myopathy.

Other muscle enzyme levels that may be elevated include the following:

Antibody findings

Antinuclear antibody assays are positive in one third of patients with polymyositis and in only 15% of patients with inclusion body myositis. Myositis-specific antibodies include the following[18] :

Imaging Studies

Muscle-imaging techniques such as magnetic resonance imaging (MRI) and ultrasonography may be useful to document and localize the extent of muscle involvement. MRI scans show signal intensity abnormalities of muscle due to inflammation, edema, or scarring. (See the image below.) Whole-body MRI can also identify associated extramuscular diseases, such as interstitial lung disease and systemic malignancy.[21]



View Image

MRI of thighs showing increased signal in the quadriceps muscles bilaterally consistent with inflammatory myositis.

MRI scans may also be used to guide muscle biopsy and to monitor disease activity.[22] However, many clinicians choose the biopsy site on the basis of findings at electromyography and clinical examination and believe that MRI is not required. Barium swallow studies are helpful for evaluation of dysphagia or dysphonia.

Chest radiography and high-resolution CT scanning of the chest are helpful for the evaluation of interstitial lung disease. CT scanning of the chest, abdomen, and pelvis is considered for screening of associated malignancy. Chest radiography may also reveal evidence of associated malignancy.

Other studies to consider in screening for associated malignancy are as follows:

Electromyography

Electromyographic findings are abnormal in almost all patients (90%) with polymyositis. Various abnormalities consistent with polymyositis may be found, depending on the stage of disease. In patients with inclusion body myositis myopathic and neuropathic changes may be present:

Biopsy

Muscle biopsy (eg, deltoid or quadriceps femoris) is crucial in helping to diagnose polymyositis and in excluding other rare muscle diseases.[23] MRI and EMG can be used to guide the site of biopsy. Avoid biopsy of sites recently studied with EMG by using the contralateral side.

Inflammatory changes are seen on muscle biopsy. Findings occasionally may be normal because of patchy involvement. (See the images below.)



View Image

Hematoxylin and eosin frozen section shows polymyositis. Endomysial chronic inflammation is present among intact myofibers, which are remarkable only ....



View Image

Hematoxylin and eosin paraffin section shows polymyositis. Patient had dense endomysial inflammation that contains an abundance of plasma cells, which....



View Image

Hematoxylin and eosin paraffin section shows polymyositis. Photomicrograph illustrates attack on a nonnecrotic myofiber by autoaggressive T lymphocyte....



View Image

Hematoxylin and eosin paraffin section shows polymyositis. Longitudinal section shows a dense, chronic, endomysial inflammatory infiltrate. Image cour....

Macrophage-predominant myocyte destruction, with few to no lymphocytes, is the histopathologic hallmark of necrotizing autoimmune myopathy (NAM), a recently recognized entity within the spectrum of idiopathic inflammatory myopathies. Patients typically have a history of malignancy or statin use and present with proximal muscle weakness and markedly elevated creatine kinase levels.

Histologic Findings

Muscle biopsy shows muscle fibers in varying stages of inflammation, necrosis, and regeneration. Findings include focal endomysial infiltration by mononuclear cells (consisting of mostly CD8+ T lymphocytes and macrophages), capillary obliteration, endothelial cell damage, and increased amounts of connective tissue. Later in the course of polymyositis, muscle-cell degeneration, fibrosis, and regeneration may be observed. (See the images below.)



View Image

Histopathology of polymyositis showing endomysial mononuclear inflammatory infiltrate and muscle fiber necrosis.



View Image

Close view of muscle biopsy, showing chronic inflammatory infiltrate consisting of T lymphocytes, especially CD8+ T lymphocytes.

Because the inflammatory infiltrates can be small and multifocal, they can be missed in a small muscle-biopsy specimen. Perifascicular atrophy or prominent perivascular infiltrates are not present, and the blood vessels are normal. When the disease becomes chronic, the connective tissue increases. The diagnosis of polymyositis is definite when a patient has subacute, elevated levels of serum CK and findings on muscle biopsy consistent with the histologic features of polymyositis.

Inclusion body myositis is histologically similar to polymyositis, with the additional presence of intracytoplasmic inclusion bodies observed on electron microscopy. Dermatomyositis shows inflammatory changes, predominantly in the perimysial and perivascular regions with CD4+ T and B lymphocytes (see the image below). Corticosteroid-induced myopathy causes no inflammatory changes. Type II fiber atrophy is the characteristic feature.



View Image

Hematoxylin and eosin paraffin shows dermatomyositis. In dermatomyositis, inflammation is characteristically perivascular and perimysial. Vessel orien....

Approach Considerations

Treatment of polymyositis (PM) is empirical because of the rarity of the disease and the paucity of randomized, controlled trials.

Corticosteroids

Prednisone is the first-line treatment of choice for polymyositis. Typically, the dose is 1 mg/kg/day, either as a single or in divided doses. This high dose is usually continued for 4-8 weeks, until the creatine kinase (CK) level returns to reference ranges. Taper prednisone by 5-10 mg on a monthly basis until the lowest dose that controls the disease is reached.

Monitor response to therapy based on improvement in muscle strength and muscle endurance and decrease in CK levels. Closely monitor patients with polymyositis for disease activity and adverse effects of corticosteroids, such as weight gain, hypertension, diabetes mellitus, osteopenia, and steroid myopathy.

Corticosteroid myopathy can occur during the course of treatment and must be distinguished from reactivation of muscle disease. The CK level is usually within reference ranges in patients with steroid myopathy. No improvement is observed with raised doses of steroids; rather, the condition worsens if the dose is increased.

Immunosuppressants

Immunosuppressive agents are indicated in patients who do not improve with steroids within a reasonable period (ie, 4 wk) or in whom adverse effects from corticosteroids develop. Patients with poor prognostic indicators, such as dysphagia or dysphonia, are likely to require immunosuppressive agents. Under these circumstances, methotrexate is the second-line agent. Azathioprine, cyclophosphamide, chlorambucil, and cyclosporine have been used with varying success as second-line agents for polymyositis.Patients with inclusion body myositis usually respond poorly to corticosteroids and immunosuppressive agents.

Obtain the following baseline tests before initiating immunosuppressive therapy: liver function tests and pulmonary function, chest x-ray, TB and Hepatitis B, C testing

Other agents

Intravenous immunoglobulin (IVIG) has been used for the short-term treatment of steroid-resistant cases of polymyositis.[24, 25]

The role of newer agents, such as tumor necrosis factor (TNF) inhibitors, remains unclear. Case reports describe successful use of the TNF inhibitor infliximab in refractory cases, but small clinical trials have yielded mixed results, with clinical flares occurring in some patients.[26, 27, 28, 29, 30]  In a randomized controlled trial with crossover, 4 of 12 patients with refractory dermatomyositis and polymyositis responded to infliximab at a dose of 5 or 7.5 mg/kg; infliximab was well tolerated.[31]  

A small trial of the TNF inhibitor etanercept provided encouraging results.[32]

The anti-CD20 monoclonal antibody rituximab may be an approach to therapy for refractory cases. The benefit of rituximab was demonstrated in the Rituximab in Myositis (RIM) study, the largest randomized trial ever completed in myositis. RIM included 200 patients with polymyositis, dermatomyositis, or juvenile dermatomyositis not controlled by corticosteroids and other immunosuppressive agents.[33]

The study had a placebo phase design in which half the patients received two rituximab infusions at baseline, whereas the other half received rituximab 8 weeks later. At a median of approximately 20 weeks, 83% of study subjects receiving rituximab met the International Myositis Assessment and Clinical Studies Group preliminary definition of improvement. Whether rituximab was received early or late made no significant difference in the time to achieve the definition of improvement.[33]

The calcineurin inhibitor tacrolimus appears to be effective, safe, and well tolerated in patients with polymyositis that is refractory to other treatments.[34] In a systematic review, CK levels patients decreased in all patients treated with tacrolimus, the average glucocorticoid dosage was reduced from 33.8 to 11.5 mg/day, and the majoriy of patients showed improvement in muscle strength and physical function status. However, randomized, controlled trials of tacrolimus in poymyositis have yet to be conducted.[35]

Mycophenolate mofetil has been reported in case reports to be effective.[36]

ACTH gel has shown some promise in case series with improvement in muscle as well as skin disease. Further randomized trials are required.[37]  

Diet and Activity

Patients with polymyositis may benefit from a high-protein diet. Monitor patients to avoid excessive weight gain due to corticosteroid use.

Encourage patients with polymyositis to start a supervised exercise program early in the disease course.[38] During the acute stage of polymyositis, patients may benefit from heat therapy, passive range-of-motion exercises, and splints to avoid contractures.

Once acute inflammation is under control, the rehabilitation program should include active range-of-motion exercises and isometric contractions of the muscle groups. With improvement in muscle strength, patients should perform isotonic exercises with light resistance. Encourage patients to do 15-30 minute sessions of aerobic exercise when the disease is inactive.

Consultations

A neurologist or rheumatologist is the primary consultant. Consultation may also be required with the following specialists:

Extramuscular Manifestations of Polymyositis

Treatment of extramuscular manifestations of polymyositis includes the following:

Dysphagia secondary to cricopharyngeal involvement in polymyositis/dermatomyositis is a rare manifestation and usually reflects poor prognosis. Dysphagia responds either slowly or poorly to immunosuppressive therapies or high-dose corticosteroids. A large case series indicated that treatment with IVIG can be effective in patients with steroid-resistant esophageal manifestations of polymyositis/dermatomyositis.[41]

Dysphagia may be severe enough to require enteral feeding through a gastrostomy tube or parenteral nutrition.

Inpatient and Outpatient Care

Inpatient care

Patients with polymyositis should be closely monitored in the hospital while they are taking high-dose corticosteroids. Ideally, skin testing for tuberculosis should be performed before initiation of corticosteroid treatment.

Serial creatine kinase (CK) levels should be monitored to assess improvement. Severe pulmonary or cardiac involvement may require management in an intensive care setting. In patients treated with immunosuppressive agents, regularly monitor CBC, liver function test and renal function. Patients with polymyositis usually need aggressive inpatient physical therapy.

Outpatient care

Patients with polymyositis should be seen every 2-3 weeks initially; if they are stable, they should be seen at monthly intervals thereafter.

Frequently check laboratory tests, including CK, and document muscle strength evaluation results. Check patient's weight during each visit. Routine age-appropriate cancer screening is recommended. Arrange outpatient physical therapy.

Deterrence and Prevention

The following precautions can aid against complications associated with polymyositis or its treatment:

Medication Summary

Therapy for polymyositis is based on immune suppression with steroids. Prednisone is the first-line treatment of choice. Immunosuppressive agents are indicated in patients who do not improve with steroids within a reasonable period (ie, 4 weeks) or who experience adverse effects from corticosteroids. Newer agents such as rituximab are showing promise.[28]

Prednisone

Clinical Context:  Prednisone is an anti-inflammatory and immunosuppressive agent used in the treatment of autoimmune disorders. It may decrease inflammation by reversing increased capillary permeability and suppressing neutrophilic activity. Prednisone also stabilizes the lysosomal membrane and suppresses lymphocytes, reducing cytokine and antibody production.

Corticotropin (Acthar Gel, HP Acthar Gel)

Clinical Context:  Porcine ACTH, stimulates adrenocortical hormone production

Class Summary

These agents inhibit the inflammatory process via multiple mechanisms, including the inhibition of proinflammatory cytokine production, monocyte/macrophage function, and angiogenesis.

Methotrexate (Rheumatrex, Trexall)

Clinical Context:  Methotrexate has an unknown mechanism of action in the treatment of chronic inflammatory diseases. It may affect immune function, including through inhibition of the production of proinflammatory cytokines. Methotrexate ameliorates symptoms of inflammation (eg, pain, swelling, stiffness). Adjust the dose gradually to attain a satisfactory response.

Azathioprine (Imuran, Azasan)

Clinical Context:  Azathioprine is a purine analog that inhibits the synthesis of deoxyribonucleic acid (DNA), RNA, and proteins. It may decrease the proliferation of immune cells, resulting in lower immunologic activity.

IV Immunoglobulin (Privigen, Hizentra, Octogam, Gammagard)

Clinical Context:  IVIG neutralizes circulating myelin antibodies through anti-idiotypic antibodies. It down-regulates proinflammatory cytokines, including interferon gamma; blocks Fc receptors on macrophages; suppresses helper T and B lymphocytes; and augments suppressor T lymphocytes. IVIG's exact mechanism of action in the treatment of polymyositis is unknown.

Chlorambucil (Leukeran)

Clinical Context:  Chlorambucil alkylates and cross-links strands of DNA, inhibiting DNA replication and RNA transcription.

Cyclophosphamide

Clinical Context:  Cyclophosphamide is chemically related to nitrogen mustards. As an alkylating agent, the mechanism of action of the active metabolites may involve cross-linking of DNA, which may interfere with the growth of normal cells such as lymphocytes and neoplastic cells.

Cyclosporine (Sandimmune, Neoral, Gengraf)

Clinical Context:  Cyclosporine is a cyclic polypeptide that suppresses cell-mediated immune reactions such as delayed hypersensitivity and, to a lesser extent, humoral immunity, allograft rejection, experimental allergic encephalomyelitis, and graft versus host disease for a variety of organs. Cyclosporine selectively inhibits the transcription of interleukin 2, predominantly in helper lymphocytes.

Mycophenolate (CellCept, MMF, Myfortic)

Clinical Context:  Inhibits T- and B-cell proliferation, as well as antibody production

Class Summary

These agents may be of benefit in patients whose condition has not responded to steroids or in patients unable to tolerate prednisone.

Etanercept (Enbrel)

Clinical Context:  Etanercept binds specifically to TNF and blocks its interaction with cell-surface TNF receptors, rendering TNF biologically inactive.

Infliximab (Remicade)

Clinical Context:  Infliximab binds to soluble and transmembranous forms of TNF-alpha, rendering TNF biologically inactive.

Class Summary

These agents may be used in refractory cases of polymyositis that have failed to respond to conventional therapy with steroids.

Rituximab (Rituxan)

Clinical Context:  (Off-label) Rituximab is a humanized monoclonal antibody that binds to CD20 antigen, thereby inducing complement- or antibody-mediated cytolysis. Clinical trials in refractory polymyositis have shown improvement in patients who have failed corticosteroids and other immunosuppressive agents.

Class Summary

Clinical trials with rituximab have shown encouraging results in patients who are refractory to first-line treatment.

How is polymyositis characterized?What are idiopathic inflammatory myopathies?What is necrotizing autoimmune myopathy (NAM)?How are polymyositis and dermatomyositis differentiated?How are polymyositis and inclusion body myositis differentiated?What is included in patient education about polymyositis?What is polymyositis?What is the role of viruses in the etiology of polymyositis?What is the role of autoimmune antibodies in the etiology of polymyositis?Which proteins are targeted by myositis-specific antibodies (MSAs) in the pathogenesis of polymyositis?What are the targets of the anti-tRNA synthetase antibodies in the pathogenesis of polymyositis?What are the targets of the anti-Jo1 antibodies in the pathogenesis of polymyositis?What is the role of the Jo-1 antigen in the etiology of polymyositis?How do autoantibodies against the Jo-1 antigen affect the clinical course of polymyositis?How do Mi-2 antibodies affect the clinical course of polymyositis?How do Anti-SRP antibodies affect the clinical course of polymyositis?Which antigens are targeted by myositis- associated antibodies (MAAs) in the pathogenesis of polymyositis?What does the presence of anti-PM/Scl autoantibodies or Anti-Ku antibodies indicate in polymyositis?What does the presence of antibodies directed against snRNP or RoRNP indicate in patients with polymyositis?What is the role of infection in the etiology of polymyositis?Which drugs may induce polymyositis?What is the incidence of polymyositis?How does the incidence of polymyositis vary by sex?How does the incidence of polymyositis vary by age?What is the prognosis of polymyositis?What are the prognostic factors for polymyositis?What are the possible complications of polymyositis?What is the risk for venous thromboembolism (VTE) in polymyositis?Which malignancies are more common in patients with polymyositis?How does polymyositis affect the risk for amyotrophic lateral sclerosis (ALS)?What mortality rate of polymyositis?Why is there often a delay in the diagnosis of polymyositis?What is focus of history for polymyositis?What are the muscular symptoms of polymyositis?How are fine motor movements affected in patients with polymyositis?What is the prevalence of dysphagia and dysphonia in patients with polymyositis?How are ocular muscles affected by polymyositis?What is the role of family history in the evaluation of polymyositis?What are the systemic symptoms of polymyositis?What are the pharyngeal and esophageal symptoms of polymyositis?What is the prevalence of interstitial lung disease in polymyositis?What are the pulmonary symptoms of polymyositis?What are the cardiac manifestations of polymyositis?What are musculoskeletal symptoms of polymyositis?Which connective-tissue diseases are associated with polymyositis?What is the prevalence of scleroderma in polymyositis?What are the GI symptoms of polymyositis?What are the renal manifestations of polymyositis?What are the cutaneous manifestations of polymyositis?What is inclusion body myositis?How is muscle weakness characterized in polymyositis?Which sensory exam findings are characteristic of polymyositis?Which muscles are typically involved in polymyositis?How does polymyositis affect respiratory muscles?How does polymyositis affect tendon reflexes?Which cardiac abnormalities may be present in polymyositis?Which physical findings indicate polymyositis associated with a connective-tissue disorder?What are the physical findings characteristic of inclusion body myositis?What are the possible complications of polymyositis?Which conditions should be included in the differential diagnoses of polymyositis?What may cause drug-induced myopathy in patients with polymyositis?What are the differential diagnoses for Polymyositis?Which lab studies are performed in the evaluation of polymyositis?How is malignancy assessed in the evaluation of polymyositis?Which studies may be clinically appropriate in the evaluation of polymyositis?How are serum creatine kinase (CK) levels affected in polymyositis?How is myositis activity monitored in polymyositis activity?Which muscle enzyme levels may be elevated in polymyositis?What is the role of antinuclear antibody assays in the evaluation of polymyositis?What is the role of muscle imaging in the evaluation of polymyositis?What is the role of chest radiography and high-resolution computed tomography in the workup of polymyositis?Which studies may be performed to screen for malignancy in polymyositis?What is the role of electromyography in the workup of polymyositis?What is the role of muscle biopsy in the workup of polymyositis?Which histologic findings are characteristic of polymyositis?Why are inflammatory infiltrates missed in a muscle-biopsy specimen for evaluation of polymyositis?Which histologic findings are characteristic of inclusion body myositis?Why is the treatment of polymyositis empirical?What is the first-line treatment of choice for polymyositis?What is included in treatment monitoring for polymyositis?How is corticosteroid myopathy differentiated from reactivation of polymyositis?What is the role of immunosuppressants in the treatment of polymyositis?Which baseline tests should be performed before initiating immunosuppressive therapy for polymyositis?What is the role of IV immunoglobulins (IVIGs) in the treatment of polymyositis?What is the role of tumor necrosis factor (TNF) inhibitors in the treatment of polymyositis?What is the role of rituximab in the treatment of polymyositis?What is the role of tacrolimus in the treatment of polymyositis?What is the role of mycophenolate mofetil in the treatment of polymyositis?What is the role of ACTH gel in the treatment of polymyositis?What is the role of dietary modifications in the treatment of polymyositis?What is the role of exercise in the treatment of polymyositis?What is the role of physical rehabilitation programs in the treatment of polymyositis?Which specialist consultations are beneficial in the treatment of polymyositis?What are the treatment options for extramuscular manifestations of polymyositis?How is dysphagia managed in polymyositis?What testing should be performed prior to initiation of corticosteroids for polymyositis?What is included in inpatient monitoring during treatment of polymyositis?How frequently should patients with stable polymyositis be seen?What is included in long-term monitoring of polymyositis?How can complications of polymyositis be prevented?What is the role of medications in the treatment of polymyositis?Which medications in the drug class Anti-CD20 Monoclonal Antibodies are used in the treatment of Polymyositis?Which medications in the drug class DMARDs, TNF Inhibitors are used in the treatment of Polymyositis?Which medications in the drug class Immunosuppressants are used in the treatment of Polymyositis?Which medications in the drug class Corticosteroids are used in the treatment of Polymyositis?

Author

Mythili Seetharaman, MD, Consultant Rheumatologist, OAA, St Luke's University Hospital, St Christopher's Hospital for Children

Disclosure: Nothing to disclose.

Chief Editor

Herbert S Diamond, MD, Visiting Professor of Medicine, Division of Rheumatology, State University of New York Downstate Medical Center; Chairman Emeritus, Department of Internal Medicine, Western Pennsylvania Hospital

Disclosure: Nothing to disclose.

Acknowledgements

Michael S Beeson, MD, MBA, FACEP, Professor of Emergency Medicine, Northeastern Ohio Universities College of Medicine and Pharmacy; Attending Faculty, Akron General Medical Center

Michael S Beeson, MD, MBA, FACEP is a member of the following medical societies: American College of Emergency Physicians, Council of Emergency Medicine Residency Directors, National Association of EMS Physicians, and Society for Academic Emergency Medicine

Disclosure: Nothing to disclose.

Thomas H Brannagan III, MD, Associate Professor of Clinical Neurology and Director, Peripheral Neuropathy Center, Columbia University, College of Physicians and Surgeons; Co-Director, EMG Laboratory, New York-Presbyterian Hospital, Columbia Campus, New York

Thomas H Brannagan III, MD is a member of the following medical societies: American Academy of Neurology, American Association of Neuromuscular and Electrodiagnostic Medicine, and Peripheral Nerve Society

Disclosure: Nothing to disclose.

Lawrence H Brent, MD, Associate Professor of Medicine, Jefferson Medical College of Thomas Jefferson University; Chair, Program Director, Department of Medicine, Division of Rheumatology, Albert Einstein Medical Center

Lawrence H Brent, MD is a member of the following medical societies: American Association for the Advancement of Science, American Association of Immunologists, American College of Physicians, and American College of Rheumatology

Disclosure: Genentech Honoraria Speaking and teaching; Genentech Grant/research funds Other; Amgen Honoraria Speaking and teaching; Pfizer Honoraria Speaking and teaching; Abbott Immunology Honoraria Speaking and teaching; Takeda Honoraria Speaking and teaching; UCB Speaking and teaching; Omnicare Consulting fee Consulting; Centocor Consulting fee Consulting

Zaineb Daud, MD, Consulting Staff, Department of Neurology, Medical College of Pennsylvania Hahnemann University

Disclosure: None

Gino A Farina, MD, FACEP, FAAEM, Associate Professor of Clinical Emergency Medicine, Albert Einstein College of Medicine; Program Director, Department of Emergency Medicine, Long Island Jewish Medical Center

Gino A Farina, MD, FACEP, FAAEM is a member of the following medical societies: American Academy of Emergency Medicine, American College of Emergency Physicians, and Society for Academic Emergency Medicine

Disclosure: Nothing to disclose.

Francisco de Assis Aquino Gondim, MD, MSc, PhD, Associate Professor of Neurology, Department of Neurology and Psychiatry, St Louis University School of Medicine

Francisco de Assis Aquino Gondim, MD, MSc, PhD is a member of the following medical societies: American Academy of Neurology, American Association of Neuromuscular and Electrodiagnostic Medicine, and Movement Disorders Society

Disclosure: Nothing to disclose.

Aamir Hashmat, MD, Consulting Staff, Neurology and Neurodiagnostics Lab, Department of Neurology, Jeff Anderson Regional Medical Center

Aamir Hashmat, MD is a member of the following medical societies: American Academy of Neurology, American Epilepsy Society; American Medical Association, AO Foundation

Disclosure: None

Milind J Kothari, DO, Professor and Vice-Chair, Department of Neurology, Pennsylvania State University College of Medicine; Consulting Staff, Department of Neurology, Penn State Milton S Hershey Medical Center

Milind J Kothari, DO is a member of the following medical societies: American Academy of Neurology, American Association of Neuromuscular and Electrodiagnostic Medicine, and American Neurological Association

Disclosure: Nothing to disclose.

Kristine M Lohr, MD, MS, Professor, Department of Internal Medicine, Center for the Advancement of Women's Health and Division of Rheumatology, Director, Rheumatology Training Program, University of Kentucky College of Medicine

Kristine M Lohr, MD, MS is a member of the following medical societies: American College of Physicians, American College of Rheumatology, and American Medical Women's Association

Disclosure: Nothing to disclose.

Glenn Lopate, MD, Associate Professor, Department of Neurology, Division of Neuromuscular Diseases, Washington University School of Medicine; Director of Neurology Clinic, St Louis ConnectCare; Consulting Staff, Department of Neurology, Barnes-Jewish Hospital

Glenn Lopate, MD is a member of the following medical societies: American Academy of Neurology, American Association of Neuromuscular and Electrodiagnostic Medicine, and Phi Beta Kappa

Disclosure: Nothing to disclose.

Nicholas Lorenzo, MD, Consulting Staff, Neurology Specialists and Consultants

Nicholas Lorenzo, MD is a member of the following medical societies: Alpha Omega Alpha and American Academy of Neurology

Disclosure: Nothing to disclose.

Henry Rosenkranz, MD, FAAEM, FACEP, Department of Emergency Medicine, Norwood Hospital

Henry Rosenkranz, MD, FAAEM, FACEP is a member of the following medical societies: American Academy of Emergency Medicine and American College of Emergency Physicians

Disclosure: Nothing to disclose.

Erik D Schraga, MD, Staff Physician, Department of Emergency Medicine, Mills-Peninsula Emergency Medical Associates

Francisco Talavera, PharmD, PhD, Adjunct Assistant Professor, University of Nebraska Medical Center College of Pharmacy; Editor-in-Chief, Medscape Drug Reference

Disclosure: Medscape Reference Salary Employment

References

  1. Milisenda JC, Selva-O'Callaghan A, Grau JM. The diagnosis and classification of polymyositis. J Autoimmun. 2014 Feb-Mar. 48-49:118-21. [View Abstract]
  2. Malik A, Hayat G, Kalia JS, Guzman MA. Idiopathic Inflammatory Myopathies: Clinical Approach and Management. Front Neurol. 2016 May 20. 7:64. [View Abstract]
  3. Na SJ, Kim SM, Sunwoo IN, Choi YC. Clinical characteristics and outcomes of juvenile and adult dermatomyositis. J Korean Med Sci. 2009 Aug. 24(4):715-21. [View Abstract]
  4. Bohan A. History and classification of polymyositis and dermatomyositis. Clin Dermatol. 1988 Apr-Jun. 6(2):3-8. [View Abstract]
  5. Zampieri S, Valente M, Adami N, et al. Polymyositis, dermatomyositis and malignancy: a further intriguing link. Autoimmun Rev. 2010 Apr. 9(6):449-53. [View Abstract]
  6. Carroll MB, Newkirk MR, Sumner NS. Necrotizing Autoimmune Myopathy: A Unique Subset of Idiopathic Inflammatory Myopathy. J Clin Rheumatol. 2016 Oct. 22 (7):376-80. [View Abstract]
  7. Lee CW, Muo CH, Liang JA, Sung FC, Hsu CY, Kao CH. Increased osteoporosis risk in dermatomyositis or polymyositis independent of the treatments: a population-based cohort study with propensity score. Endocrine. 2015 Oct 1. [View Abstract]
  8. Marie I, Hachulla E, Chérin P, et al. Opportunistic infections in polymyositis and dermatomyositis. Arthritis Rheum. 2005 Apr 15. 53(2):155-65. [View Abstract]
  9. Rai SK, Choi HK, Sayre EC, Aviña-Zubieta JA. Risk of myocardial infarction and ischaemic stroke in adults with polymyositis and dermatomyositis: a general population-based study. Rheumatology (Oxford). 2015 Sep 30. [View Abstract]
  10. Yang Z, Lin F, Qin B, Liang Y, Zhong R. Polymyositis/dermatomyositis and malignancy risk: a metaanalysis study. J Rheumatol. 2015 Feb. 42 (2):282-91. [View Abstract]
  11. Carruthers EC, Choi HK, Sayre EC, Aviña-Zubieta JA. Risk of deep venous thrombosis and pulmonary embolism in individuals with polymyositis and dermatomyositis: a general population-based study. Ann Rheum Dis. 2014 Sep 5. [View Abstract]
  12. Tseng CC, Chang SJ, Tsai WC, Ou TT, Wu CC, Sung WY, et al. Increased Incidence of Amyotrophic Lateral Sclerosis in Polymyositis: A Nationwide Cohort Study. Arthritis Care Res (Hoboken). 2017 Aug. 69 (8):1231-1237. [View Abstract]
  13. Bronner IM, van der Meulen MF, de Visser M, Kalmijn S, van Venrooij WJ, Voskuyl AE, et al. Long-term outcome in polymyositis and dermatomyositis. Ann Rheum Dis. 2006 Nov. 65(11):1456-61. [View Abstract]
  14. Schnabel A, Hellmich B, Gross WL. Interstitial lung disease in polymyositis and dermatomyositis. Curr Rheumatol Rep. 2005 Apr. 7(2):99-105. [View Abstract]
  15. Kuo SH, Vullaganti M, Jimenez-Shahed J, Kwan JY. Camptocormia as a presentation of generalized inflammatory myopathy. Muscle Nerve. 2009 Dec. 40(6):1059-63. [View Abstract]
  16. Fathi M, Lundberg IE, Tornling G. Pulmonary complications of polymyositis and dermatomyositis. Semin Respir Crit Care Med. 2007 Aug. 28 (4):451-8. [View Abstract]
  17. Jakubaszek M, Kwiatkowska B, Maślińska M. Polymyositis and dermatomyositis as a risk of developing cancer. Reumatologia. 2015. 53 (2):101-5. [View Abstract]
  18. Satoh M, Tanaka S, Ceribelli A, Calise SJ, Chan EK. A Comprehensive Overview on Myositis-Specific Antibodies: New and Old Biomarkers in Idiopathic Inflammatory Myopathy. Clin Rev Allergy Immunol. 2017 Feb. 52 (1):1-19. [View Abstract]
  19. Mammen AL. Statin-Associated Autoimmune Myopathy. N Engl J Med. 2016 Feb 18. 374 (7):664-9. [View Abstract]
  20. Satoh M, Tanaka S, Ceribelli A, Calise SJ, Chan EK. A Comprehensive Overview on Myositis-Specific Antibodies: New and Old Biomarkers in Idiopathic Inflammatory Myopathy. Clin Rev Allergy Immunol. 2017 Feb. 52 (1):1-19. [View Abstract]
  21. Huang ZG, Gao BX, Chen H, Yang MX, Chen XL, Yan R, et al. An efficacy analysis of whole-body magnetic resonance imaging in the diagnosis and follow-up of polymyositis and dermatomyositis. PLoS One. 2017. 12 (7):e0181069. [View Abstract]
  22. Elessawy SS, Abdelsalam EM, Abdel Razek E, Tharwat S. Whole-body MRI for full assessment and characterization of diffuse inflammatory myopathy. Acta Radiol Open. 2016 Sep 21. 5 (9):2058460116668216. [View Abstract]
  23. Chahin N, Engel AG. Correlation of muscle biopsy, clinical course, and outcome in PM and sporadic IBM. Neurology. 2008 Feb 5. 70(6):418-24. [View Abstract]
  24. Cherin P, Pelletier S, Teixeira A, et al. Results and long-term followup of intravenous immunoglobulin infusions in chronic, refractory polymyositis: an open study with thirty-five adult patients. Arthritis Rheum. 2002 Feb. 46(2):467-74. [View Abstract]
  25. Kumar A, Teuber SS, Gershwin ME. Intravenous immunoglobulin: striving for appropriate use. Int Arch Allergy Immunol. 2006. 140(3):185-98. [View Abstract]
  26. Hengstman GJ, van den Hoogen FH, Barrera P, Netea MG, Pieterse A, van de Putte LB, et al. Successful treatment of dermatomyositis and polymyositis with anti-tumor-necrosis-factor-alpha: preliminary observations. Eur Neurol. 2003. 50(1):10-5. [View Abstract]
  27. Anandacoomarasamy A, Howe G, Manolios N. Advanced refractory polymyositis responding to infliximab. Rheumatology (Oxford). 2005 Apr. 44(4):562-3. [View Abstract]
  28. Aggarwal R, Oddis CV. Therapeutic advances in myositis. Curr Opin Rheumatol. 2012 Nov. 24(6):635-41. [View Abstract]
  29. Dastmalchi M, Grundtman C, Alexanderson H, Mavragani CP, Einarsdottir H, Helmers SB, et al. A high incidence of disease flares in an open pilot study of infliximab in patients with refractory inflammatory myopathies. Ann Rheum Dis. 2008 Dec. 67(12):1670-7. [View Abstract]
  30. Uthman I, El-Sayad J. Refractory polymyositis responding to infliximab. Rheumatology (Oxford). 2004 Sep. 43(9):1198-9. [View Abstract]
  31. Schiffenbauer A, Garg M, Castro C, Pokrovnichka A, Joe G, Shrader J, et al. A randomized, double-blind, placebo-controlled trial of infliximab in refractory polymyositis and dermatomyositis. Semin Arthritis Rheum. 2017 Oct 16. [View Abstract]
  32. Tjärnlund A, Tang Q, Wick C, Dastmalchi M, Mann H, Tomasová Studýnková J, et al. Abatacept in the treatment of adult dermatomyositis and polymyositis: a randomised, phase IIb treatment delayed-start trial. Ann Rheum Dis. 2017 Oct 9. [View Abstract]
  33. Oddis CV, Reed AM, Aggarwal R, Rider LG, Ascherman DP, Levesque MC, et al. Rituximab in the treatment of refractory adult and juvenile dermatomyositis and adult polymyositis: a randomized, placebo-phase trial. Arthritis Rheum. 2013 Feb. 65(2):314-24. [View Abstract]
  34. Ueno KI, Shimojima Y, Kishida D, Sekijima Y, Ikeda SI. Advantage of administering tacrolimus for improving prognosis of patients with polymyositis and dermatomyositis. Int J Rheum Dis. 2016 Jul 26. [View Abstract]
  35. Ge Y, Zhou H, Shi J, Ye B, Peng Q, Lu X, et al. The efficacy of tacrolimus in patients with refractory dermatomyositis/polymyositis: a systematic review. Clin Rheumatol. 2015 Sep 2. [View Abstract]
  36. Caramaschi P, Volpe A, Carletto A, Bambara LM, Biasi D. Long-standing refractory polymyositis responding to mycophenolate mofetil: a case report and review of the literature. Clin Rheumatol. 2007 Oct. 26 (10):1795-6. [View Abstract]
  37. Levine T. Treating refractory dermatomyositis or polymyositis with adrenocorticotropic hormone gel: a retrospective case series. Drug Des Devel Ther. 2012. 6:133-9. [View Abstract]
  38. Alexanderson H. Exercise: an important component of treatment in the idiopathic inflammatory myopathies. Curr Rheumatol Rep. 2005 Apr. 7(2):115-24. [View Abstract]
  39. Shimojima Y, Ishii W, Matsuda M, Kishida D, Ikeda SI. Effective Use of Calcineurin Inhibitor in Combination Therapy for Interstitial Lung Disease in Patients With Dermatomyositis and Polymyositis. J Clin Rheumatol. 2017 Mar. 23 (2):87-93. [View Abstract]
  40. Chen D, Wang XB, Zhou Y, Zhu XC. Efficacy of infliximab in the treatment for dermatomyositis with acute interstitial pneumonia: a study of fourteen cases and literature review. Rheumatol Int. 2013 Oct. 33(10):2455-8. [View Abstract]
  41. Marie I, Menard JF, Hatron PY, et al. Intravenous immunoglobulins for steroid-refractory esophageal involvement related to polymyositis and dermatomyositis: a series of 73 patients. Arthritis Care Res (Hoboken). 2010 Dec. 62(12):1748-55. [View Abstract]

MRI of thighs showing increased signal in the quadriceps muscles bilaterally consistent with inflammatory myositis.

Histopathology of polymyositis showing endomysial mononuclear inflammatory infiltrate and muscle fiber necrosis.

Close view of muscle biopsy, showing chronic inflammatory infiltrate consisting of T lymphocytes, especially CD8+ T lymphocytes.

MRI of thighs showing increased signal in the quadriceps muscles bilaterally consistent with inflammatory myositis.

Hematoxylin and eosin frozen section shows polymyositis. Endomysial chronic inflammation is present among intact myofibers, which are remarkable only for increased variability of fiber size. Image courtesy of Roberta J. Seidman, MD.

Hematoxylin and eosin paraffin section shows polymyositis. Patient had dense endomysial inflammation that contains an abundance of plasma cells, which can be observed in patients with chronic polymyositis. Two necrotic myofibers, characterized by dense eosinophilic staining, are observed. Focal fatty infiltration of the muscle is present in the lower left quadrant of the photomicrograph. Image courtesy of Roberta J. Seidman, MD.

Hematoxylin and eosin paraffin section shows polymyositis. Photomicrograph illustrates attack on a nonnecrotic myofiber by autoaggressive T lymphocytes. On the left, the central myofiber is intact. On the right, it is obliterated by a segmental inflammatory attack. If immunohistochemistry were performed, expected findings would include an admixture of CD8 T lymphocytes and macrophages in the inflammatory process. Image courtesy of Roberta J. Seidman, MD.

Hematoxylin and eosin paraffin section shows polymyositis. Longitudinal section shows a dense, chronic, endomysial inflammatory infiltrate. Image courtesy of Roberta J. Seidman, MD.

Histopathology of polymyositis showing endomysial mononuclear inflammatory infiltrate and muscle fiber necrosis.

Close view of muscle biopsy, showing chronic inflammatory infiltrate consisting of T lymphocytes, especially CD8+ T lymphocytes.

Hematoxylin and eosin paraffin shows dermatomyositis. In dermatomyositis, inflammation is characteristically perivascular and perimysial. Vessel oriented approximately vertically in the center has a mild perivascular chronic inflammatory infiltrate. The endothelium is plump. The wall is not necrotic. A few lymphocytes in the wall of the vessel are probably in transit from the lumen to the external aspect of the vessel. Some observers may interpret this finding as vasculitis, but it is certainly neither necrotizing vasculitis nor arteritis. Image courtesy of Roberta J. Seidman, MD.

MRI of thighs showing increased signal in the quadriceps muscles bilaterally consistent with inflammatory myositis.

Histopathology of polymyositis showing endomysial mononuclear inflammatory infiltrate and muscle fiber necrosis.

Close view of muscle biopsy, showing chronic inflammatory infiltrate consisting of T lymphocytes, especially CD8+ T lymphocytes.

Hematoxylin and eosin frozen section shows polymyositis. Endomysial chronic inflammation is present among intact myofibers, which are remarkable only for increased variability of fiber size. Image courtesy of Roberta J. Seidman, MD.

Hematoxylin and eosin paraffin section shows polymyositis. Patient had dense endomysial inflammation that contains an abundance of plasma cells, which can be observed in patients with chronic polymyositis. Two necrotic myofibers, characterized by dense eosinophilic staining, are observed. Focal fatty infiltration of the muscle is present in the lower left quadrant of the photomicrograph. Image courtesy of Roberta J. Seidman, MD.

Hematoxylin and eosin paraffin section shows polymyositis. Photomicrograph illustrates attack on a nonnecrotic myofiber by autoaggressive T lymphocytes. On the left, the central myofiber is intact. On the right, it is obliterated by a segmental inflammatory attack. If immunohistochemistry were performed, expected findings would include an admixture of CD8 T lymphocytes and macrophages in the inflammatory process. Image courtesy of Roberta J. Seidman, MD.

Hematoxylin and eosin paraffin shows dermatomyositis. In dermatomyositis, inflammation is characteristically perivascular and perimysial. Vessel oriented approximately vertically in the center has a mild perivascular chronic inflammatory infiltrate. The endothelium is plump. The wall is not necrotic. A few lymphocytes in the wall of the vessel are probably in transit from the lumen to the external aspect of the vessel. Some observers may interpret this finding as vasculitis, but it is certainly neither necrotizing vasculitis nor arteritis. Image courtesy of Roberta J. Seidman, MD.

Hematoxylin and eosin paraffin section shows polymyositis. Longitudinal section shows a dense, chronic, endomysial inflammatory infiltrate. Image courtesy of Roberta J. Seidman, MD.