Corticosteroid Induced Myopathy (2024)

Continuing Education Activity

Corticosteroid-induced myopathy is an iatrogenic myopathy caused by chronic high to moderate systemic corticosteroid use. This is a common condition that must be differentiated from other iatrogenic and organic causes of myopathy. Diagnosis is based on a high degree of clinical suspicion in patients on chronic steroids; prompt initiation of treatment in the form of corticosteroid withdrawal, if possible, should be initiated to avoid the morbidity associated with the condition. This activity reviews the characteristics, evaluation, and management of corticosteroid-induced myopathy and highlights the role of the interprofessional team in the care of patients with this condition.

Objectives:

• Outline the epidemiology of corticosteroid-induced myopathy.

• Explain the pathophysiology of corticosteroid-induced myopathy.

• Describe the evaluation of corticosteroid-induced myopathy.

• Identify opportunities for improving care coordination within the interprofessional team to improve outcomes for patients affected by corticosteroid-induced myopathy.

Access free multiple choice questions on this topic.

Introduction

Corticosteroid-induced myopathyis a highly prevalent toxic noninflammatorymyopathy that occurs as an adverse effect ofprolongedoral or intravenous glucocorticoid use. It was first described in1932 by Harvey Cushing as part of a constellation of symptoms seen in Cushing syndrome. With the broader use of corticosteroids as therapeutic tools in the 1950s, corticosteroid-induced myopathy became a more well-known entity.[1]This toxic noninflammatory myopathy typically has an indolent presentation and predominantly affects pelvic girdle muscles, and is associated with muscle weakness and atrophy without associated pain. Acute steroid-induced myopathy in the critical care setting is another presentation. Workup typically reveals normal creatine kinase and no other signs of inflammatory disease, with EMG studiesunremarkable and biopsy showing atrophy of type 2b fast-twitch muscle fibers. The diagnosis requires a high index of suspicion and is confirmed when muscle weakness improves after 3 to 4 weeks of tapering steroids, although improvement may take months to a year.Other than steroid withdrawal, other options include switching from fluorinated to nonfluorinated glucocorticoids or alternate day dosing. Additionally, physical therapy in the form of resistance and aerobic exercise has been shown in some studies to prevent and treat steroid-induced myopathy.[2][3]As such, a screening program for steroid-induced myopathy should be implemented in the appropriate patient population, and patients should be prescribed physical therapy as a preventive and treatment modality for this condition.[4]

Etiology

Corticosteroid-induced myopathy is a toxic noninflammatory myopathy caused by exogenous corticosteroid administration. The condition typically develops with doses higher than 10 mg prednisone equivalents/day used for four weeks or longer. However, 2 to 3 weeks of higher doses (such as 40 to 60 mg prednisone/day) have been associated with more acute presentations. Oral and intravenous formulations are most associated with corticosteroid myopathy, although case reports exist regarding steroid myopathy following inhaled corticosteroids and epidural, intramuscular, or intra-articular injection.[1]For patients in the intensive care setting undergoing mechanical ventilation andreceiving curare-like paralytics, doses of methylprednisolone greater than 60 mg/day for 5 to 7 days are also associated with acute steroid myopathy.[5]

Epidemiology

Corticosteroid-induced myopathy is the most common drug-induced myopathy, with an incidence of 50% to 60% among those using corticosteroids for a prolonged period.[6][5]While any individual on chronic corticosteroids can be affected, elderly patients are most at risk due to lower baseline muscle mass, as are patients with oncologic diseases. Additional risk factors for corticosteroid-induced myopathy include patients with prior muscle disease or spinal cord injury, chronic respiratory illness, poor nutritional status, and a sedentary lifestyle.[5]Women are more prone to developing corticosteroid-induced myopathy, although the mechanism of this is unclear.[7]In the acute illness setting, patients on mechanical ventilation who receive neuromuscular blockade with curare-like agents and receive high-dose steroids are also at high risk for developing acute steroid-induced myopathy, which may take weeks to recover.[5]Of note, case reports do exist of nonventilated patients experiencing acute early-onset steroid myopathy (defined as less than 2 weeks from the start of treatment), even with moderate steroid doses and unusual muscle involvement, such as the vocal cords.[8]Thus, the epidemiology of the condition is highly variable.

Pathophysiology

Corticosteroid-induced myopathy is believed to occur through both catabolic and anti-anabolic mechanisms. In terms of catabolic mechanisms, corticosteroids upregulate proteolytic systems such as the ubiquitin-proteasome system, cathepsins (lysosomes), and calpains (calcium-dependent systems). This increases the proteolysis of myofibrillar proteins by dissociating actin from myosin.[5][6]Corticosteroids also induce myocyte apoptosis throughreceptor-based signaling pathways as well as mitochondrial-based signaling pathways involving cytochrome c and the caspase cascade.[6]In terms of anti-anabolic mechanisms, corticosteroids inhibit amino acid transport into cells, inhibit muscle IGF-I production, and down-regulate differentiation of satellite cells into muscle fibers by blocking the transcription factor called myogenin, thusinhibiting protein synthesis and myogenesis. Additionally, corticosteroids with high mineralocorticoid activity lower serum potassium and phosphate, which may contribute to muscle weakness.[5]

Histopathology

Muscle biopsy, if performed,reveals atrophy of type 2b or fast-twitch muscle fibers, with less impact on type 1 or slow-twitch muscle fibers, with variability in fiber size and centralization of nuclei, without evidence of inflammation or necrosis.[9]The preferential atrophy of type 2b fibers, which have high glycolytic and low oxidative capacity, supports the predominant involvement of extremityskeletal muscles rather than respiratory muscles.[7]

History and Physical

Symptoms of corticosteroid-induced myopathy consist of muscle weakness, typically in a symmetric distribution involving the proximal extremity muscles, with the hip girdle affected more and earlier than the shoulders. It is associated with long-termmuscle atrophy, notably with very minimal or no associated pain.[1][7][10][11]Onset is typically insidious, with the range being weeks to months from initiation of corticosteroids. Patients often complain of difficulty rising from a seated position, climbing stairs, and trouble with overhead activities.[12]History invariably includes ongoing oral or intravenous corticosteroid use, particularly prolonged fluorinated glucocorticoid exposure. It is important to observe that higher doses are more likely to induce clinical myopathy. On physical exam, in one study, up to 20% of patients show objective signs of muscle weakness, although a subjective feeling of weakness occurs in 60%.[13]The remainder of the physical exam can reveal decreased muscle stretch reflexes in the affected extremities. However, there are no sensoryor neurological deficits that would point to a central nervous/spinal cord etiology and no cranial nerve involvement.[7]Patients may have additional sequelaeof chronic glucocorticoid administration, includingCushing syndrome stigmata, such as moon facies and fat redistribution. They may have metabolic complications, including obesity, diabetes, adrenal insufficiency, hyperlipidemia, hypertension, skin, and bone disorders, including osteoporosis and avascular necrosis. Other complications of chronic steroid use include increased susceptibility to infection, gastritis, cataracts, glaucoma, and mood/neurocognitive side effects.[11]Thus, patients may present withseveral complications of chronic steroid use.

Evaluation

Corticosteroid-induced myopathy is a clinical diagnosis that requires a high index of suspicion. Labwork including creatine kinase (CK), aspartate aminotransferase (AST), lactate dehydrogenase (LDH), and aldolase are typically normal, although these may be elevated very early in the disease process or acute steroid myopathy of critically ill patients.[1][12]Muscle biopsy is not required for diagnosis, although, when performed, it may show nonspecific type 2b muscle fiber atrophy without inflammatory infiltrate, with variable fiber size and centrally located nuclei; necrosisis rare.[5]The unremarkable lab and biopsy findings help differentiate corticosteroid-induced myopathy from other inflammatory myopathies. EMG findings are typically normal, with an occasional slight reduction in the amplitude of the motor unit potentials. This occurs asEMG measures both type 1 and type 2 fiber activity and does not differentiate in the preferential atrophy of type 2b muscle fibers.[7]Imaging, including MRI, is rarely performed for corticosteroid-induced myopathy except when evaluating for alternate diagnoses.[1]Sometimes, in patients on steroids for inflammatory myopathy, it is difficult to distinguish the muscle weakness arising from the worsening of the underlying myopathy from the symptoms arising from the newly developing corticosteroid-induced myopathy. The determination of corticosteroid-induced myopathy is ultimately tested and confirmed when symptoms improve with tapering or discontinuing corticosteroids.

Treatment / Management

Corticosteroid-induced myopathy isan often overlooked diagnosis, as symptoms are occasionally attributed to the primary illness that the corticosteroid is treating. This prolongs the time to diagnosis and increases morbidity. Thus, a high index of suspicion must be maintained when patients present with muscle weakness in any muscle group (with particular emphasis on pelvic girdle)withany dose, route, or duration of steroids.[8]Reduction or, ideally, discontinuation of the corticosteroid is the mainstay of treatment, with close monitoring for adrenal insufficiency and exacerbation of the primary illness during the discontinuation process. For patients unable to taper off steroids, replacement of fluorinated glucocorticoids with non-fluorinated glucocorticoids, such as dexamethasone with prednisone or hydrocortisone, should be considered. Although the mechanism is unclear, fluorinated glucocorticoids are known to bemuch more potent than non-fluorinated glucocorticoids, which may contribute to their higher toxicity.[12]For patients with primary brain tumors on the fluorinated glucocorticoid dexamethasone, the anticonvulsant phenytoin has been usedwith dexamethasone to reduce the risk of developing corticosteroid-induced myopathy, as phenytoin is thought to help facilitate hepatic dexamethasone metabolism.[14]Other options include non-daily dosing regimens.[7]However, steroid-sparing treatments should be prioritized whenever possible.Diagnosis is confirmed when muscle strength improves within 3 to 4 weeks of tapering steroids, although recovery may take months to a year.[9][12]In addition to steroid withdrawal, supportive management with an emphasis on physical therapy should be considered for both prevention and treatment. Physical therapy with aerobic and resistance exercises is effective at modulating muscle atrophy in patients who have corticosteroid-induced myopathy.[5]Even for patients unable to taper off steroids, in a study of heart transplant recipients on chronic glucocorticoids (approximately 10 mg prednisone/daily), a 6-month regimen of monitored resistance training (with a focus on low back and whole-body resistance exercises) successfully reversed corticosteroid-induced muscle atrophyand improved skeletal muscle strength 400% to 600% in the treatment versus the control group.[2]Experimental agents such as exogenousIGF-I, branched-chain amino acids, creatine, androgens (testosterone, DHEA), and glutamine have been investigatedin animal models. However, they have not been conclusivelyevaluated in humans and are not currently recommended.[7]

Differential Diagnosis

Other medications known to cause drug-induced myopathy include colchicine, antimalarials, and antiretrovirals. Drug-induced myopathy should beconsidered mainly for patients taking two myopathic agents, such as hydroxychloroquine and glucocorticoids, for inflammatory disorders.[7][11][15]Statins have been known to cause a myopathy, which typically presents with myalgias and evidence of muscle inflammation on labwork; an autoimmune necrotic myopathy in the setting of statin use has been reported in the literature.[16]Other toxic substances, such as alcohol and cocaine,can also cause myopathy.[17]Organic causes of myopathy should be ruled out and include inflammatory diseases such as polymyositis and dermatomyositis.

In contrast tocorticosteroid-induced myopathy, these present with elevated muscle enzymes, worsening muscle weakness with discontinuation of steroids, systemic signs of muscle breakdown and inflammation, and characteristic"early recruitment" findings on EMG.[7]On biopsy, inflammatory myopathies show endomysial or perivascular inflammation and perifascicular atrophy, whereas corticosteroid-induced myopathy shows predominantly type 2b muscle fiber atrophy without inflammation.

Additionally, myositis may present as a manifestationof systemic lupus erythematosus, Sjögren syndrome, scleroderma, and rheumatoid arthritis; these organic causes of myopathy should beconsidered when diagnosing corticosteroid-induced myopathy.[17]Given the increased risk for malignancy in dermatomyositis, paraneoplastic syndromes can be on the differential.[18]More broadly, endocrine disorders (thyroid, adrenals, or pituitary), electrolyte abnormalities (potassium, calcium), and nutrient deficiencies (such as low vitamin D) can cause muscle weakness. Metabolic myopathies related to carbohydrate, lipid, and purine metabolism and congenital myopathies are rare causes of muscle weakness and have distinct presentation patterns.[17]Thus, a broad differentialexists,and each patient should be evaluated in their clinical context.

Prognosis

Corticosteroid-induced myopathy is almost always reversible, with improvement in myopathy within 3 to 4 weeks of tapering corticosteroids, although recovery can take months to a year.[4][9]Other than withdrawing corticosteroids, there are no known pharmacotherapies to accelerate recovery. Switching from fluorinated glucocorticoids like dexamethasone to nonfluorinated glucocorticoids like prednisone can sometimes help. It should be recognized that many of the patients on chronic steroid therapy would need to be weaned off slowly from their steroid regimen to avoid adrenal insufficiency or exacerbation of the disease process for which they have been on long-term steroids. Physical therapy, with both resistance and endurance exercise, taking into account baseline functional status, is recommended to help prevent and treat glucocorticoid-induced myopathy.[3][19]

Complications

Complications of corticosteroid-induced myopathy include the morbidity and subsequent mortality associated with chronic muscle weakness. Patients experience decreased quality of life through the inability to perform activities of daily livingand are at increased risk for falls and injury.[7]In patients with treatment-resistant asthma on chronic corticosteroids, corticosteroid-induced myopathy should be entertained as a contributing factor to uncontrolled asthma and chronic respiratory failure.[20]

Deterrence and Patient Education

Patients should routinely be educated on the risk versus benefit profile of corticosteroids, including the risk of corticosteroid-induced myopathy. Patients should be advised tocontact their provider if they notice weakness developing. Patients should be informed that physical activity can help prevent and mitigate the effects of corticosteroid-induced myopathy and should be prescribed physical therapy as part of a preventive and treatment regimen.

Enhancing Healthcare Team Outcomes

Given the high incidence of corticosteroid-induced myopathy in patients receiving glucocorticoid therapy fora wide range of clinical indications, an interprofessional team should implement systematic clinical screening for corticosteroid-induced myopathyin the appropriate patient populations. Since primary care clinicians are the most frequently and consistently involved specialty in taking care of such patients, they should maintain a high degree of suspicion for this diagnosis. Providers and team members should also systematically recommend and prescribe physicaltherapyto prevent and treat corticosteroid-induced myopathy.[2][4]

Review Questions

• Access free multiple choice questions on this topic.

• Comment on this article.

References

1.

Pereira RM, Freire de Carvalho J. Glucocorticoid-induced myopathy. Joint Bone Spine. 2011 Jan;78(1):41-4. [PubMed: 20471889]

2.

Braith RW, Welsch MA, Mills RM, Keller JW, Pollock ML. Resistance exercise prevents glucocorticoid-induced myopathy in heart transplant recipients. Med Sci Sports Exerc. 1998 Apr;30(4):483-9. [PubMed: 9565927]

3.

Horber FF, Scheidegger JR, Grünig BE, Frey FJ. Evidence that prednisone-induced myopathy is reversed by physical training. J Clin Endocrinol Metab. 1985 Jul;61(1):83-8. [PubMed: 3998075]

4.

Fardet L, Kassar A, Cabane J, Flahault A. Corticosteroid-induced adverse events in adults: frequency, screening and prevention. Drug Saf. 2007;30(10):861-81. [PubMed: 17867724]

5.

Gupta A, Gupta Y. Glucocorticoid-induced myopathy: Pathophysiology, diagnosis, and treatment. Indian J Endocrinol Metab. 2013 Sep;17(5):913-6. [PMC free article: PMC3784879] [PubMed: 24083177]

6.

Dirks-Naylor AJ, Griffiths CL. Glucocorticoid-induced apoptosis and cellular mechanisms of myopathy. J Steroid Biochem Mol Biol. 2009 Oct;117(1-3):1-7. [PubMed: 19520160]

7.

Minetto MA, Lanfranco F, Motta G, Allasia S, Arvat E, D'Antona G. Steroid myopathy: some unresolved issues. J Endocrinol Invest. 2011 May;34(5):370-5. [PubMed: 21677507]

8.

Haran M, Schattner A, Kozak N, Mate A, Berrebi A, Shvidel L. Acute steroid myopathy: a highly overlooked entity. QJM. 2018 May 01;111(5):307-311. [PubMed: 29462474]

9.

Owczarek J, Jasińska M, Orszulak-Michalak D. Drug-induced myopathies. An overview of the possible mechanisms. Pharmacol Rep. 2005 Jan-Feb;57(1):23-34. [PubMed: 15849374]

10.

Perrot S, Le Jeunne C. [Steroid-induced myopathy]. Presse Med. 2012 Apr;41(4):422-6. [PubMed: 22326665]

11.

Caplan A, Fett N, Rosenbach M, Werth VP, Micheletti RG. Prevention and management of glucocorticoid-induced side effects: A comprehensive review: Ocular, cardiovascular, muscular, and psychiatric side effects and issues unique to pediatric patients. J Am Acad Dermatol. 2017 Feb;76(2):201-207. [PubMed: 28088991]

12.

Bodine SC, Furlow JD. Glucocorticoids and Skeletal Muscle. Adv Exp Med Biol. 2015;872:145-76. [PubMed: 26215994]

13.

Levin OS, Polunina AG, Demyanova MA, Isaev FV. Steroid myopathy in patients with chronic respiratory diseases. J Neurol Sci. 2014 Mar 15;338(1-2):96-101. [PubMed: 24380687]

14.

Dropcho EJ, Soong SJ. Steroid-induced weakness in patients with primary brain tumors. Neurology. 1991 Aug;41(8):1235-9. [PubMed: 1866012]

15.

Guemara R, Lazarou I, Guerne IA. [Drug-induced myopathies]. 2017 Mai 10Rev Med Suisse. 13(562):1013-1017. [PubMed: 28627846]

16.

Mammen AL. Statin-Associated Autoimmune Myopathy. N Engl J Med. 2016 Feb 18;374(7):664-9. [PubMed: 26886523]

17.

Silver EM, Ochoa W. Glucocorticoid-Induced Myopathy in a Patient with Systemic Lupus Erythematosus (SLE): A Case Report and Review of the Literature. Am J Case Rep. 2018 Mar 11;19:277-283. [PMC free article: PMC5865408] [PubMed: 29525810]

18.

Dias LP, Faria AL, Scandiuzzi MM, Inhaia CL, Shida JY, Gebrim LH. A rare case of severe myositis as paraneoplastic syndrome on breast cancer. World J Surg Oncol. 2015 Apr 01;13:134. [PMC free article: PMC4397703] [PubMed: 25890160]

19.

LaPier TK. Glucocorticoid-induced muscle atrophy. The role of exercise in treatment and prevention. J Cardiopulm Rehabil. 1997 Mar-Apr;17(2):76-84. [PubMed: 9101384]

20.

Yamaguchi M, Niimi A, Minakuchi M, Matsumoto H, Shimizu K, Chin K, Mishima M. Corticosteroid-induced myopathy mimicking therapy-resistant asthma. Ann Allergy Asthma Immunol. 2007 Oct;99(4):371-4. [PubMed: 17941287]

Disclosure: Natalya Surmachevska declares no relevant financial relationships with ineligible companies.

Disclosure: Vivekanand Tiwari declares no relevant financial relationships with ineligible companies.