Corticosteroids

Early and adequate treatment with high-dose oral corticosteroids has been widely accepted as a critical component in the management of JDM. Typically, patients receive prednisone (up to 2 mg/kg/day divided into two to three doses) for 2 months, with close monitoring for resolution of both clinical and laboratory manifestations. With an adequate response evident, corticosteroids are then slowly tapered over a 2-year period. Several studies also suggest that aggressive initial management with intravenous (IV) pulse corticosteroids may result in a more favorable outcome. The proposed rationale is to gain rapid control of inflammation, preventing both acute and chronic complications, and in the long-term, minimizing chronic corticosteroid use and associated toxicity. In addition, early aggressive management may induce earlier disease remission and greatly decrease hospitalizations. Further justification suggests that a likely gastrointestinal vasculopathy in active JDM may impair oral corticosteroid absorption therefore impairing efficacy. In contrast, data reported in a retrospective, propensity score analysis did not support any significant difference in efficacy outcomes between standard therapy with oral prednisone and aggressive management with IV corticosteroids.

Despite significant improvements in prognosis of JDM, calcinosis remains a considerable source of long-term morbidity ( Figs. 19-4 and 19-5 ). It appears that calcinosis is significantly correlated with a longer time to diagnosis and overall longer active disease duration. Retrospective data and observational studies are somewhat inconsistent; however, the majority indicate that early treatment with IV methylprednisolone (30 mg/kg), followed by high-dose oral corticosteroids may be associated with a more rapid normalization of muscle enzymes, earlier clinical remission, and therefore, decreased incidence of calcinosis. Similarly, some studies propose that intermittent IV methylprednisolone pulses given on a weekly to monthly basis many induce remission more rapidly. Retrospective reviews, in which a reduction of calcinosis was not significantly associated with initial management with IV methylprednisolone, noted the likelihood of higher disease severity in these patients and, therefore, the increased risk of long-term complications.

A, Calcinosis circumscripta—superficial plaques of dystrophic calcium deposition in subcutaneous tissue in a patient with juvenile dermatomyositis. B, Tumoral calcinosis (i.e., calcinosis universalis)–nodular calcium deposits into deeper tissue layers.

(Courtesy of Dr. Lisa G. Rider, MD, NIH.)

A, Radiographic evidence of planar calcinosis in the arm of a patient with juvenile dermatomyositis. B, Further delineation of interfascial deposition of calcium in the same patient.

Despite the enormous benefits gained from corticosteroids, long-term use is often associated with undesirable steroid toxicity. Among others, side effects that may limit therapy include significant osteopenia, osteoporosis, avascular necrosis of bone, compression fractures, Cushing’s syndrome, growth retardation, and steroid myopathy. Subsequent management and the institution of additional immunosuppressant medications often aim to reduce corticosteroid dose while maintaining adequate disease control. The addition of calcium and vitamin D appears to be beneficial in the reduction of bone loss; however, they may be insufficient in the management of severe osteoporosis. In contrast, calcitonin and bisphosphonates have been shown to be effective in the treatment of adults with osteoporosis; however, use in children is limited due to unknown long-term effects on growing bone. At present, there is an increasing body of evidence that bisphosphonates are relatively safe in the treatment of osteoporosis in children with rheumatic and metabolic bone disease.

Hydroxychloroquine

Based primarily on anecdotal evidence, hydroxychloroquine (6 mg/kg/day) has been recommended as a steroid-sparing agent, particularly in patients with prominent dermatologic manifestations. In general, hydroxychloroquine is considered a safe, well-tolerated medication. Side effects may include gastrointestinal intolerance, headache, lightheadedness, and skin hyperpigmentation. Rarely, retinal toxicity may occur; therefore, all children should have routine ophthalmologic monitoring assessing for changes in visual acuity, visual fields, color vision, and retinal changes.

Methotrexate

Second-line medications, including immunosuppressive agents, are typically considered as adjunctive therapy in cases of steroid resistance, steroid dependence or unacceptable steroid toxicity. Of all the immunosuppressive drugs, methotrexate (MTX) is widely used as the preferred agent for refractory JDM (0.35–2 mg/kg/week; max dose = 50 mg). More recently, MTX has also been recommended as a component of initial therapy to additionally improve clinical outcome. Experience from the use of low-dose MTX in other pediatric rheumatologic diseases has proven its safety and limited long-term toxicity. Several small, uncontrolled, retrospective studies have also shown efficacy of MTX in JDM, demonstrating decreased disease activity, decreased calcinosis, as well as a more rapid discontinuation of corticosteroids and therefore decreased steroid toxicity. Initially, MTX is often administered orally, with a change to subcutaneous administration should gastrointestinal side effects evolve. In cases of suspected gastrointestinal vasculopathy with potentially impaired absorption, some authors may propose an earlier change to parenteral administration due to greater bioavailability. Overall, MTX is generally well tolerated, with typical side effects including gastrointestinal intolerance, risk of infection and hepatotoxicity. Although potentially a concern, these effects are often transient and resolve with discontinuation of the drug. In cases of persistent gastrointestinal intolerance, leucovorin (5 mg given 24 hours following the weekly dose of MTX) may be given to reduce potential toxicity.

Cytotoxic Agents

In addition to MTX, other immunosuppressive agents used in refractory JDM include azathioprine (AZA), cyclophosphamide (CYC), cyclosporine, and mycophenolate mofetil (MMF). Of these agents, the greatest amount of published evidence available for the use of these agents in JDM is for cyclosporine therapy (3–5 mg/kg/day); however these data are primarily based on case reports and retrospective reviews. These reports generally reveal favorable outcomes; however, the benefits must be weighed against the risks of side effects, particularly renal impairment, hypertension, and hepatotoxicity. Although few studies exist, some authors suggest AZA (1–3 mg/kg/day) may be as efficacious and a potentially safe steroid-sparing agent should MTX fail. Similarly, CYC (1 mg/kg/day oral or 0.5–1 g/ m /month IV) is seen as a potentially effective medication with minimal evidence of serious toxicity in short-term use, however mixed results have been seen in adult dermatomyositis. Potential side effects of CYC include alopecia, cytopenias, bladder toxicity, gastrointestinal intolerance, and infertility. In addition, there have been some recent reports suggesting the benefits of MMF with generally few side effects.

Intravenous Immunoglobulin

Intravenous immunoglobulin (IVIG) has been shown to be a safe and effective treatment in adults with dermatomyositis. Potential mechanisms of action of IVIG in autoimmune and inflammatory disorders are not fully understood, but data suggest that they involve modulation of expression and/or function of Fc receptors, increased activity of complement or proinflammatory cytokines, idiotype/anti-idiotype interactions, and effects of T, B, and dendritic cells. In a small, double-blinded, placebo-controlled trial, IVIG was shown to result in significant improvement in muscle strength, neuromuscular symptoms and histologic findings on muscle biopsy. In children, however, there are no controlled clinical trials, evidence is therefore based on retrospective reviews and anecdotal reports. These reports concluded that IVIG (1–2 g/kg/month) is beneficial in reducing clinical manifestations and sparing corticosteroid toxicity in cases of severe, refractory JDM. It appears that repeated treatments may be necessary for long-term benefits due to a tendency for relapse after the cessation of IVIG. Administration of IVIG to immunoglobulin A (IgA)–deficient patients may result in anaphylaxis; therefore, IgA levels should be routinely measured before administration, or as soon as possible if immediate use is indicated. In addition, reports suggest that children, particularly those with autoimmune disorders, may have increased incidence of side effects including fever, nausea, and vomiting. This may be related to concentrations of IgA more than 15 µg/mL; therefore, preparations with lower concentrations of IgA are preferred (Gammagard, Baxter, Deerfield, IL; 2.2 µg/mL). Other potential side effects include headache and aseptic meningitis.

Biologic Agents

Tumor necrosis factor-α (TNF-α) has been identified in high levels in patients with JDM, particularly in those with a prolonged disease course or complicated by calcinosis. The use of TNF-α inhibitors, particularly infliximab (6–10 mg/kg via infusions every 4–8 weeks) and etanercept (0.8 mg/kg; max 50 mg/week), appear to show promising results in severe, refractory JDM. Few small clinical trials have been published suggesting clinical benefits, including improved muscle weakness, joint range of motion, and regression of calcinosis. Similarly, rituximab, a monoclonal antibody to B cells, may have clinical benefits; however, clinical trials are still underway. In very severe cases of JDM that are recalcitrant to other therapies, plasmapheresis may also be considered.

Supportive Measures

In addition to the therapies listed earlier, supportive measures including skin care for ulcerations, nutritional assessments for risk of aspiration and malnutrition, psychological support and education, and physical therapy are essential in the management of patients with JDM. Despite active inflammation, physical therapy should be initiated at the time of diagnosis with passive range-of-motion exercises to prevent decreased range of motion. Once acute inflammation has subsided; active, muscle-strengthening exercises should be gradually introduced to minimize muscle atrophy and contractures.

One of the major aims of treatment in JDM is to avoid long-term complications, including calcinosis and lipodystrophy ( Fig. 19-6 ). Once these complications develop, there are no treatments that have proven to be consistently effective. Case reports and anecdotal evidence suggest that therapies including colchicine, warfarin, bisphosphonates, probenecid, diltiazem, and aluminum hydroxide may offer variable responses in the management of calcinosis. The authors have had some success with treatment with colchicine, especially when superficial calcinosis lesions cause ulceration and crystal-induced cellulitis. It should also be noted that calcinosis is often complicated by concurrent infection, and appropriate antibiotic administration can be critical. In addition, there is generalized consensus that early aggressive control of active disease inflammation; using corticosteroids, MTX, IVIG, and cytotoxic agents have a preventative role in the formation and progression of calcinosis. In some cases, calcinosis may spontaneously regress; however, depending on location, in rare cases surgical excision may be required ( Fig. 19-7 ). In addition, careful monitoring must be performed in the prevention of serious infections potentially associated with calcinosis and ulceration.

A, Six-year-old boy who was ultimately diagnosed with juvenile dermatomyositis. B, Same patient, 2 years later (age 8) showing significant facial lipodystrophy. Note absence of subcutaneous fat in the malar areas. Similar loss of fat was present in the extremities.

Skin grafting after excision of large tumoral calcinosis lesions in the axillae and antecubital fossae of an adolescent boy with juvenile dermatomyositis.

Nonsteroidal Anti-Inflammatory Drugs

Nonsteroidal anti-inflammatory drugs (NSAIDs) are primarily used in pediatric SLE for fever and mild musculoskeletal manifestations, including arthritis, myalgias, and arthralgias. Aspirin (ASA), another potential therapeutic option in these scenarios, is less commonly used in children due to the potential for hepatotoxicity and Reye’s syndrome. Toxicity from NSAIDs is limited; however, risks most often include gastritis, decreased glomerular filtration rate, and rarely aseptic meningitis. Pseudoporphyria has also been described in children using naproxen.

Antimalarials

Hydroxychloroquine (6 mg/kg/day, max 400 mg/day) is routinely used at the onset of disease in children and adolescents with SLE to reduce symptoms of fatigue, mucocutaneous manifestations, and alopecia, as well as a steroid toxicity–sparing agent. Efficacy of antimalarials in SLE has been demonstrated in clinically stable adults, with removal of the drug, resulting in increased incidence of disease activity. Although typically well tolerated, the primary concern in the use of hydroxychloroquine is the rare incidence of retinal toxicity; therefore, yearly ophthalmologic monitoring is indicated.

Corticosteroids

The introduction of corticosteroids as the mainstay of treatment has greatly improved the prognosis in children with SLE, allowing for a more rapid control of acute manifestations and increased overall life expectancy. Depending on initial presentation, high-dose oral corticosteroids (prednisone 1–2 mg/kg/day, divided into two doses to maximize anti-inflammatory effects) are often initiated, particularly in cases of major organ involvement including renal, central nervous system (CNS), pulmonary and hematologic manifestations. In cases of severe CNS or renal involvement, IV methylprednisolone (30 mg/kg/day for 3 consecutive days) may be indicated to achieve a more rapid resolution of symptoms. In addition, intermittent monthly doses of intravenous methylprednisolone may aid in the long-term management of these patients while decreasing overall corticosteroid use and associated toxicity.

Although many children will respond to treatment with corticosteroids, complications often arise with prolonged use, including adrenal suppression, hypertension, hyperglycemia, cataracts, avascular necrosis, myopathy, CNS disturbances, immunosuppression, and dislipoproteinemia. Among the most concerning toxicities in children is the risk of significant osteopenia, osteoporosis, and growth retardation. In addition, alterations in emotional liability and physical appearance due to cushingoid facies, obesity, hirsuitism, and acne, may have significant impact on adolescent psychosocial well-being. Therefore, early introduction of a slow, gradual taper of corticosteroids while maintaining adequate disease control is critical. Steroid toxicity–sparing strategies may also include consolidation to a single morning dose initially and eventual reduction to alternate-day therapy.

Immunosuppressive Agents

The addition of an immunosuppressive or cytotoxic agent is often indicated in cases of proliferative glomerulonephritis, CNS involvement ( Fig. 19-10 ), and pulmonary hemorrhage; as well as with evidence of steroid dependence or unacceptable steroid toxicity. Common immunosuppressive agents currently used in pediatric SLE are CYC, AZA, cyclosporine, MMF, and MTX.

A, Magnetic resonance imaging scan with increased signal abnormality in the left cerebellar white matter in a 14-year-old patient with systemic lupus erythematosus and focal dysmetria. B, Evidence of bilateral signal abnormality in the basal ganglia of the same patient.

CYC has been considered the adjunctive therapy of choice for the most severe manifestations of SLE, particularly severe proliferative lupus nephritis and CNS disease, often resulting in reduced disease activity, preservation of renal and neurological function and overall reduction in corticosteroid dose. Although there have been no randomized, controlled trials in children, several case series and comparative studies have similarly reported efficacy and superiority over AZA or prednisone alone. Significant toxicity limits use in less severe cases, and caution must be taken in monitoring for bone marrow suppression, infection, alopecia, nausea, vomiting, and hemorrhagic cystitis. The incidence of alopecia, a potentially distressing complication in adolescents, may be reduced with the use of scalp-cooling techniques including cryogel packs, cold air circulation, and specialized caps with liquid coolant circulation. Long-term risks including secondary malignancy may be higher than that in adults; whereas permanent gonadal damage has been reported to be lower in the pediatric population. Although data are limited in children, semen cryopreservation and gonadotropin-releaseing hormone (GnRH)–analogs may provide additional protection in adolescents receiving CYC. Typically IV CYC (0.5–1 g/m ² /month), given in an induction phase of seven monthly doses, followed by a maintenance phase of one dose every 3 months for 2 years, is preferred over oral CYC to reduce overall cumulative toxicity.

In cases of mild to moderate organ involvement other, less toxic, immunosuppressive agents may be necessary to obtain better disease control and reduced corticosteroid dosing. AZA (1–2 mg/kg/day, max 150 mg/day), has been used most frequently in pediatric SLE as an effective steroid-sparing agent with limited toxicity, including potential hematologic and gastrointestinal side effects. Controversy exists regarding efficacy in proliferative SLE nephritis; however, some reports suggest sustained disease remission with decreased long-term toxicity when used as maintenance therapy following CYC induction. Similarly, cyclosporine (3–5 mg/kg/day) may be an effective therapy in steroid-resistant or steroid-dependent children with SLE; however, its role in severe lupus nephritis is still undetermined. Potential for hypertension and nephrotoxicity with cyclosporine may further limit use in these cases. Recent experience with MMF (1–3 g/day) in pediatric SLE has shown promising results, particularly in cases of class V membranous glomerulonephritis and as maintenance therapy following CYC induction in cases of proliferative glomerulonephritis. Further reports suggest that MMF may be as effective as CYC with significantly less toxicity in adults with proliferative lupus nephritis; however, long-term data regarding risks and benefits, and use in pediatric SLE are still to be determined. Finally, the use of MTX has been suggested in the management of persistent arthritis and skin disease; however, sole use may be insufficient to control disease flare in cases of major organ system involvement.

Biologic Agents

Many biologic agents are currently being evaluated in adults with refractory SLE; however, data in pediatrics remain limited. Rituximab, an anti-CD20 monoclonal antibody (375–500 mg/m ² /dose IV for two doses given 2 weeks apart) may be effective in treatment of severe autoimmune cytopenia and potentially as an adjunct to therapy in refractory nephritis. Interpretation of this data is difficult owing to the use of other immunosuppressive agents simultaneously with rituximab. Other agents, such as IVIG, B-cell modulators (LJP 394), anti-interleukin 10 monoclonal antibodies, and therapies targeted against CD-40/CD-40 ligand and CTLA4-Ig are currently being investigated.

Other Considerations

Children with SLE often show signs of dyslipoproteinemia, with evidence of elevated triglycerides and decreased high-density lipoproteins (HDLs), which may predispose them to early atherosclerosis and early cardiovascular sequelae. Therefore, routine screening is indicated, with early intervention with diet and exercise if levels are abnormal. In some cases. pharmacologic intervention with statins and bile acid sequestrants may be necessary. In addition, hydroxychloroquine may have some beneficial lipid-lowering effects.

Differential Diagnosis

The differential diagnosis of KD, at the onset of disease, includes a wide spectrum of illnesses commonly associated with fever and mucocutaneous manifestations. The differential diagnosis includes, but is not limited to, viral infections, toxin-mediated illnesses, immune reactions and other rheumatologic diseases. Viral illnesses, including measles, EBV, and adenovirus may have similar mucocutaneous manifestations; however, these illnesses generally lack extremity and cardiac involvement. In contrast, toxin-mediated illnesses, particularly group A streptococcal infections such as scarlet fever and toxic shock syndrome, may have significant signs of inflammation and major organ involvement. These illnesses, however, often lack the ocular and articular involvement seen in KD. Other infections, such as Rocky Mountain spotted fever, differ due to a predominance of headaches and gastrointestinal complaints. Finally, immune reactions such as Stevens-Johnson syndrome, serum sickness, and rheumatologic diseases including systemic-onset juvenile idiopathic arthritis, can mimic KD; however, subtle differences are seen in ocular and mucosal manifestations.

Treatment

KD is an acute, self-limited illness, which often resolves spontaneously in less than 2 weeks without therapy. However, persistent vascular inflammation may result in the development of coronary artery aneurysms with the potential to cause severe complications and significant long-term morbidity and mortality. In general, goals of therapy include control of acute inflammation, resolution of symptoms and prevention of long-term sequelae. The American Academy of Pediatrics and the American Heart Association currently recommend that first-line therapy of KD should include high-dose ASA and IVIG given within the first 10 days of illness. In cases of suspected incomplete KD, algorithms developed by consensus, have been proposed to aid in clinical management ( Fig. 19-15 ).

Proposed algorithm for diagnosis and management of incomplete Kawasaki’s disease. (1) This algorithm represents the informed opinion of the expert committee. (2) Infants 6 months old on day 7 of fever without other explanation should undergo laboratory testing +/– echocardiogram. (3) Characteristics suggesting disease other than KD include exudative conjunctivitis, exudative pharyngitis, discrete intraoral lesions, bullous or vesicular rash, or generalized adenopathy. (4) Supplemental laboratory criteria: albumin 3.0 g/dL, anemia for age, elevation of alanine amino-transferase, platelets after 7 days 450,000/ mm ³ , white blood cell count 15,000/ mm ³ , and urine 10 white blood cells/high-power field. (5) Can treat before echocardiogram. (6) Echocardiogram is considered positive for purposes of this algorithm if any of 3 conditions are met: z score of LAD or RCA 2.5, coronary arteries meet Japanese Ministry of Health criteria for aneurysms, or 3 other suggestive features exist, including perivascular brightness, lack of tapering, decreased LV function, mitral regurgitation, pericardial effusion, or z scores in LAD or RCA of 2–2.5. (7) If the echocardiogram is positive, treatment should be given to children within 10 days of fever onset and those beyond day 10 with clinical and laboratory signs (CRP, ESR) of ongoing inflammation. (8) Typical peeling begins under nail bed of fingers and then toes.

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