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Open Access, Peer-reviewed
pISSN 1598-2629 eISSN 2092-6685
Indexed in PubMed, Scopus and SCIE
    Immune Netw. 2020 Feb;20(1):e9. English.
    Published online Feb 17, 2020.
    https://doi.org/10.4110/in.2020.20.e9
    Copyright © 2020. The Korean Association of Immunologists
    Review

    Clinical Characteristics and Treatment of Immune-Related Adverse Events of Immune Checkpoint Inhibitors

    Juwhan Choi and Sung Yong Lee
      • Division of Pulmonary, Allergy, and Critical Care Medicine, Department of Internal Medicine, Korea University Guro Hospital, Korea University College of Medicine, Seoul 08308, Korea.
    • Correspondence to Sung Yong Lee. Korea University Guro Hospital, Korea University College of Medicine, 148 Gurodong-ro, Guro-gu, Seoul 08308, Korea. Email: syl0801@korea.ac.kr
    Received November 23, 2019; Revised February 05, 2020; Accepted February 06, 2020.

    This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (https://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

    Abstract

    Immune checkpoint inhibitors (ICIs) have been changing the paradigm of cancer treatment. However, immune-related adverse effects (irAEs) have also increased with the exponential increase in the use of ICIs. ICIs can break up the immunologic homeostasis and reduce T-cell tolerance. Therefore, inhibition of immune checkpoint can lead to the activation of autoreactive T-cells, resulting in various irAEs similar to autoimmune diseases. Gastrointestinal toxicity, endocrine toxicity, and dermatologic toxicity are common side effects. Neurotoxicity, cardiotoxicity, and pulmonary toxicity are relatively rare but can be fatal. ICI-related gastrointestinal toxicity, dermatologic toxicity, and hypophysitis are more common with anti- CTLA-4 agents. ICI-related pulmonary toxicity, thyroid dysfunction, and myasthenia gravis are more common with PD-1/PD-L1 inhibitors. Treatment with systemic steroids is the principal strategy against irAEs. The use of immune-modulatory agents should be considered in case of no response to the steroid therapy. Treatment under the supervision of multidisciplinary specialists is also essential, because the symptoms and treatments of irAEs could involve many organs. Thus, this review focuses on the mechanism, clinical presentation, incidence, and treatment of various irAEs.

    Keywords
    Immune checkpoint inhibitor; Adverse events; Programmed cell death 1

    INTRODUCTION

    Immunotherapy has opened up new horizons for cancer treatment (1). In particular, immune checkpoint inhibitors (ICIs) for CTLA-4 and PD-1/PD-L1 pathways have been used to treat various solid cancers. Currently, Food and Drug Administration approved ICIs include anti-CTLA-4 (ipilimumab), PD-1 inhibitors (pembrolizumab and nivolumab), and PD-L1 inhibitors (atezolizumab, durvalumab, and avelumab). The superiority of the effects of these drugs has been demonstrated, compared to conventional cytotoxic chemotherapy, although various side effects are present. Recently, combination therapy with various ICIs and cytotoxic chemotherapy has been initiated and various side effects are expected (2).

    Frequent immune-related adverse events (irAEs) include gastrointestinal, endocrine, and dermatologic toxicities. Fatal irAEs include neurotoxicity, cardiotoxicity, and pulmonary toxicity (3). The incidence of irAEs is higher in ICI combination therapy than in ICI monotherapy (4). Majorities of clinical trials excluded cancer patients with underlying autoimmune disease or chronic infection (viral or tuberculosis). So, irAEs is expected to increase further when we use immunotherapy in real clinical practice. In addition, some of the symptoms (i.e. cardio or joint toxicity) may be overlooked and confused with the cancer related symptoms of the patients. Thus, the monitoring system for early diagnosis is needed and it can improve treatment of irAEs.

    IrAEs are evaluated and treated using the Common Terminology Criteria for Adverse Events, European Society for Medical Oncology guideline and American Society of Clinical Oncology guideline (Tables 1 and 2) (5, 6, 7). Treatment for grade 1 toxicity is conservative and maintenance of ICIs therapy is considered based on symptoms and involved organs. ‘Hold immunotherapy’ and oral prednisone treatment should be considered in grade 2 toxicity. In grade 3 or 4 toxicity, ICIs should be discontinued, and higher doses of systemic steroids should be considered. If patients do not respond to steroids, immunomodulatory therapy should be initiated. If systemic steroid and immunomodulatory therapy do not improve symptoms, intravenous immunoglobulin or plasmapheresis treatment should be considered in fatal irAEs. Retrying ICIs therapy is not recommended until the irAE has improved to grade 1 or the symptoms have disappeared. In case of fatal irAEs or grade 4 irAEs, retrying ICIs therapy is not recommended. Some irAEs have been reported to be associated with a favorable clinical outcome, but this is still controversial (8). ICIs can be used cautiously in most patients with comorbidities, but it is dangerous for solid-organ transplant patients (9). In this review, we describe the mechanism, clinical presentation, incidence, and treatment based on the organ(s) affected by the irAEs, such as abdomen, endocrine organ, joint and skin, nervous system, and thorax.

    Table 1
    Grading system (Common Terminology Criteria for Adverse Events version 5.0, European Society for Medical Oncology guideline, American Society of Clinical Oncology guideline)

    Table 2
    Management of irAEs (European Society for Medical Oncology guideline, American Society of Clinical Oncology guideline)

    MECHANISM Of irAEs

    ICIs block inhibitory checkpoint and activate T-cell mediated immune response. The precise mechanism of irAEs is still unknown, but several hypotheses are suggested. The key idea is that the use of ICIs breaks up the immunologic homeostasis and reduces T-cell tolerance (10). There is some cross-reactivity of T-cells between tumor cells and normal tissue (11). ICIs can increase levels of preexisting autoantibodies, such as antithyroid Abs (12). ICIs can also increase the level of inflammatory cytokines. In organs that express CTLA-4 or PD-L1 directly to protect normal tissue, such as in normal pituitary cells or cardiomyocytes, ICI can disturb these self-protect system (13, 14). Due to these various reasons, activated T-cells attack healthy tissue, resulting in irAEs with features similar to autoimmune diseases.

    ABDOMEN

    Gastrointestinal tract

    Clinical presentation and diagnosis

    Gastrointestinal toxicity is a common side effect of ICIs. Nausea, vomiting, dysphagia, and epigastric pain may occur when the side effects involve the upper gastrointestinal tract; abdominal pain, hematochezia, and diarrhea may occur when the side effects involve the lower gastrointestinal tract. Lower gastrointestinal tract toxicity occurs more often than upper gastrointestinal tract toxicity. However, asymptomatic or non-specific symptom, which is not related to gastrointestinal symptoms, is also common (Fig. 1A and B). Endoscopy is helpful in diagnosing ICI-induced colitis and the assessment of therapeutic response (15). Stool analysis for bacterial pathogens and clostridium difficile toxin should be considered for differential diagnosis.

    Figure 1
    Enterocolitis related to immune checkpoint inhibitors. (A) Before steroid treatment, axial contrast computed tomography scan shows wall thickening and abnormal enhancement in intestine. (B) After steroid treatment, intestinal wall thickening and abnormal enhancement are reduced.

    Incidence

    Generally, anti-CTLA-4 agents are known to show higher incidence and severity of gastrointestinal side effects than those shown by PD-1/PD-L1 inhibitors (16, 17). The incidence of side effects is higher in ICIs combination therapy than in ICIs monotherapy (4); moreover, the onset of the side effects is faster (18, 19) and occurs 6–8 weeks after the start of ICIs treatment. In the case of anti-CTLA-4 agents, side effects can occur several months after the drug is discontinued. This is because the molecular effects of anti-CTLA-4 agents that are maintained after drug clearance (20).

    Treatment strategies

    The first choice of treatment is a systemic steroid (oral prednisone 0.5–1 mg/kg/day) (21). Infliximab (anti-TNF-α) may be considered for patients that do not respond to systemic steroids (22). Recently, the use of vedolizumab (a humanized monoclonal IgG1 Ab against α4β7 integrin) has also been reported to be effective in some case reports and case series (23). A gastroenterology consultation is needed for toxicities above grade 2. Hydration, electrolyte replacement, and antidiarrheal agents should be considered for conservative care.

    Gut microbiota

    The gut microbiota has been actively studied as a factor affecting gastrointestinal toxicity (24, 25). Particular bacterial populations in the gut have been found to be associated with ICI-induced colitis (26); moreover, repeated antibiotic use is considered a risk factor for ICI-related gastrointestinal toxicity. ICIs can increase gut permeability or damage the gut epithelium. Damage of epithelium can cause the gut microbiota to enter the bloodstream, thereby affecting and changing the immune system (24, 27). Some cases of fecal microbiota transplantation have been reported in patients who did not respond to systemic steroids or infliximab (28).

    Hepatitis

    Clinical presentation and diagnosis

    If aspartate aminotransferase (AST) or alanine aminotransferase (ALT) is more than 2-fold higher than upper limit normal, tests related to hepatitis should be considered (29). Check other medications that cause hepatotoxicity and test for viral hepatitis and autoimmune hepatitis should be performed. Image tests should be undertaken to identify liver metastasis or biliary obstruction. Liver biopsy can be useful in the diagnosis of immune medicated hepatitis (IMH). Liver biopsy shows lobular hepatitis with abundant infiltration by CD3+ or CD8+ T-lymphocytes (30). Fibrin-ring granulomas are not absolute pathognomonic findings but can be estimated by IMH if identified (31).

    Incidence

    The incidence of ICI-associated IMH has been reported to be approximately 2%–15% in clinical trial (32). Anti-CTLA-4 agents are known to show higher incidence of IMH than PD-1/PD-L1 inhibitors. The incidence rates are higher in ICI combination therapy than in ICI monotherapy. Fortunately, the fatal case of IMH is relatively rare (17). Underlying chronic liver disease, such as chronic viral hepatitis or non-alcoholic steatohepatitis, are considered as risk factors (33). Although data are few and not available about antiviral treatment, there is a case report of hepatitis B virus reactivation during the ICI treatment (34).

    Treatment strategies

    Systemic steroid is the basis for the treatment of IMH. If patients do not respond to steroids, tacrolimus, mycophenolate mofetil or azathioprine should be initiated or added. However, infliximab (anti-TNF-α agent) should not be used because it can cause severe liver injury (35).

    Kidney

    Clinical presentation and diagnosis

    Acute interstitial nephritis (AIN) is the most common immune-related nephrotoxicity pattern (36). Most drug-induced AIN is caused by drug hypersensitivity reactions (37). However, immune-related AIN is similar to autoimmune disease (38). Renal biopsies show tubular injury rather than glomerular injury and include features such as edema, interstitial inflammation, and tubulitis. The renal interstitium shows infiltration of CD4+ and CD8+ lymphocytes, in addition to eosinophils and plasma cells. No deposition of specific immunoglobulins or complement fractions is observed. Urine studies often show sterile pyuria and white blood cell casts. Most other ICIs appear as typical tubulointerstitial nephritis, with only ipilimumab sometimes manifesting as nephrotic syndrome (39, 40).

    Incidence

    Acute kidney injury (AKI), abnormal electrolytes, and severe AKI which need dialysis occur in approximately 2%, 1%, and 0.5% of cases, respectively (41). The incidence of AKI in ipilimumab and nivolumab combination therapy has been reported to be approximately 5% (42). However, the incidence rates mentioned above are based on clinical trials; there are case reports and unpublished cohort study data suggesting that approximately 10%–30% may occur in real clinical settings (43).

    Treatment strategies

    The basis of therapy is a systemic steroid in immune-related nephrotoxicity. If AKI occurs, clinicians should check the history of drug use and discontinue any medications that may cause kidney damage. If kidney damage occurs that requires dialysis, ICI should be immediately abrogated.

    Mechanism

    The cause of nephrotoxicity in ICI therapy can be explained by three mechanisms. First, the ICI breaks down peripheral tolerance to self-reactive T-lymphocytes (44). This phenomenon causes an autoimmune variant of interstitial nephritis. Second, the ICI activates drug-specific effector T-cells that are associated with the nephrotoxic drug (45). Several reports show that using proton pump inhibitor (PPI) or non-steroidal anti-inflammatory drug (NSAID) is a risk factor for nephrotoxicity in ICI users. It has also been reported that stopping PPI or NSAID can restore renal function in mild AKI without stopping ICI. There are case reports that PPI or NSAIDs may cause nephrotoxicity, in patients who have used PPI or NSAID for a long time without any nephrotoxicity (46). Thirdly, using ICI increases pro-inflammatory cytokines, which can produce new auto-antibodies that can cause kidney damage (41).

    Kidney transplant patients

    Although data are lacking, the risk of ICI use is emphasized in patients undergoing kidney transplantation (9, 47). In a case report, 30%–60% of kidney rejections were identified in renal transplant patients. Most patients with rejection did not respond to systemic steroids, and transplant kidney damage was progressing or continuing, even despite ICI cancellation. Therefore, ICI should not be used in kidney transplant patients.

    ENDOCRINE ORGANS

    Endocrine toxicity

    Clinical presentation and diagnosis

    Endocrine toxicity is a very common irAE and includes hypophysitis, thyroid dysfunction, primary adrenal insufficiency, hypoparathyroidism, and type 1 diabetes mellitus (48). Hypophysitis and thyroid dysfunction are the most common endocrine toxicities (49). Endocrine toxicity is difficult to diagnose, because most symptoms, such as nausea, vomiting, appetite loss, weight loss, general weakness, fatigue, mild cognitive dysfunction, hypotension, and headache, are nonspecific. Besides, the symptoms are similar to cancer progression or brain metastasis, resulting in delayed diagnosis. Delayed diagnosis can lead to fatal side effects, such as adrenal crisis, thyroid storm, severe hypocalcemia, and diabetic ketoacidosis (50). Endocrine toxicity is often diagnosed by routine laboratory surveillance under asymptomatic conditions. If the symptoms are caused by anti-CTLA-4 therapy, the side effects are dose-dependent (51). Hypophysitis, thyroid dysfunction, and adrenal insufficiency are significantly higher in ICI combination therapy than in ICI monotherapy (52).

    Treatment strategies

    While the treatment of other irAEs is based on systemic steroids, endocrine toxicity is based on the replacement of the deficient hormone. Moreover, other forms of immunomodulatory therapy are not recommended for treatment. Endocrine toxicity is often irreversible compared to other irAEs, because ICIs can cause permanent damage to the endocrine glands (53).

    Hypophysis

    Hypophysitis is more common with anti-CTLA-4 than PD-1/PD-L1 inhibitors (52). Anti-CTLA-4 can cause direct damage to the pituitary gland, because pituitary cells express CTLA-4 (13). Usually, it occurs 4-10 weeks after ICI treatment (54). Toxicity occurs more often in men and older patients (55). Abnormal prolactin levels as well as growth hormone and posterior pituitary hormone deficiency is rare (56). Enlargement of the pituitary gland is rare in cases of ICI-induced hypophysitis (57). Therefore, diagnosis should be based on hormonal evaluation and clinical presentation, not image evaluation (58). Adrenocorticotropic hormone and cortisol tests, performed in the morning, are recommended for diagnosis. If the morning cortisol level is <350 nmol/L, the adrenocorticotropic hormone test should be conducted. If the morning cortisol level is <250 nmol/L or a random cortisol level is <150 nmol/L, hormone replacement therapy should be considered. In the presence of mass effect symptoms, such as a severe headache or visual field impairment, high-doses of glucocorticoids are considered (56).

    Thyroid

    Thyroid dysfunctions include hypothyroidism, hyperthyroidism, and thyroiditis. Thyroid dysfunction is more common with PD-1/PD-L1 inhibitors than with anti-CTLA-4. Moreover, hyperthyroidism is more common with PD-1 inhibitors than PD-L1 inhibitors (59). ICI-related thyroid dysfunctions are more common in females. Thyroglobulin auto-antibodies and/or anti-thyroid peroxidase Abs are reported to be potential biomarkers. Regular monitoring of thyroid-stimulating hormone and free thyroxine is recommended for at least 5–6 cycles of ICI therapy (60). Levothyroxine treatment is recommended when thyroid-stimulating hormone levels are >10 mUI/L (61). Beta-blockers can be useful when symptoms of hyperthyroidism are observed (62).

    HEMATOLOGIC COMPLICATIONS

    Hematologic toxicities are rare irAEs. The risk of hematologic toxicities is lower in ICI than in cytotoxic chemotherapy. In a recent meta-analysis on PD-1 inhibitors, the incidence of all-grade anemia, thrombocytopenia, leukopenia, and neutropenia was 5%, 2%, 2%, and 1%, respectively (63). However, hematologic toxicities are fatal; for example, the mortality rate of immune thrombocytopenic purpura and hemolytic anemia exceeds 10% (64). Anti-CTLA-4 agent causes hematologic toxicity faster than PD-1/PD-L1 inhibitors (65). Systemic steroids are the core of treatment, and transfusion should be performed as supportive care. However, research regarding hematologic complications is still scarce compared to other irAEs.

    JOINT AND SKIN

    Joint

    Clinical presentation and diagnosis

    Clinical symptoms include joint swelling, warmth, erythema, or recently experienced joint pain. Erosive joint damage or change can progress rapidly. Evaluating joint erosion through sonography or magnetic resonance imaging may be helpful in diagnosis (Fig. 2). If diagnosis is delayed and joint deformities develop, permanent motion limitation or chronic symptoms may occur. If a suspected symptom occurs, it is vital to early diagnose and treat the disease, in consultation with a rheumatologist. Compared to other irAEs, side effect is chronic and persistent and often requires long-term treatment.

    Figure 2
    Inflammatory arthritis related to immune checkpoint inhibitors on both knees; axial contrast computed tomography scan show moderate joint effusion of both knees (right > left) with associated synovial thickening.

    Incidence

    Representative irAEs associated with the joints are arthralgia, inflammatory arthritis, and tenosynovitis (66). In clinical trials, arthralgia is reported by 3%–7% and inflammatory arthritis by 1% of cases (67, 68). High-risk factors are ICI combination therapy, long-term use of ICI, and previous occurrence of other irAEs. Occurrence of inflammatory arthritis is rare and later than other irAEs. Occasionally, inflammatory arthritis occurs after more than a year of stopping ICI treatment (69). In addition, compared to other symptoms, the diagnosis of inflammatory arthritis is often delayed because patients do not complain unless the doctor asks explicitly about joint pains.

    Treatment strategies

    Like in case of other irAEs, systemic steroids are used for treatment. Non-steroidal anti-inflammatory drugs (NSAIDs) and intra-articular steroid injections may be helpful for supportive management (70). For side effects above grade 3, immunomodulatory therapy, such as disease-modifying antirheumatic drugs, can prevent permanent damage (71). Although detailed studies are still lacking, it has been reported that immunomodulatory therapy does not affect treatment response (72, 73). Moreover, some studies report that persistent arthritis is associated with a better treatment response.

    Skin

    Clinical presentation and diagnosis

    The skin is known to be the most affected by enhanced autoimmunity; thus, dermatologic toxicity is the most common irAEs (74). Common symptoms include rash, pruritus, and vitiligo. Rashes mainly localize to the trunk and extremities and may be combined with pruritus (75). The head, palms, and soles are often affected later, and the rash mostly manifests as erythematous macules, papules, and plaques (Fig. 3). Biopsy of the rash shows perivascular eosinophilic and leukocytic infiltrates (76). In severe cases, toxic epidermal necrolysis, Stevens-Johnson syndrome, vasculitis, and drug reaction with eosinophilia and systemic symptoms may occur (77). Sweet syndrome, cutaneous sarcoidosis, and bullous skin disorders have been reported very rarely (78).

    Figure 3
    Exacerbation of psoriasis under immune checkpoint inhibitors; plaque psoriasis with silvery scales on trunk.

    Incidence

    Dermatologic toxicity occurs faster than other irAEs (79); it is observed approximately 1 month after starting anti-CTLA-4 and approximately 2 months after starting PD-1/PD-L1 inhibitors (80). Dermatologic toxicity and severe toxicity are generally reported to occur in 25% and 2% of cases, respectively (81). Dermatologic toxicity occurs more frequently and severely with anti-CTLA-4 than PD-1/PD-L1 inhibitors. In anti-CTLA-4 therapy, dermatologic toxicity may be dose-dependent. It is more common in ICI combination therapy, and the main symptoms are rash and pruritus. Among the various symptoms of dermatologic toxicity, rash and vitiligo are suspected to be preferable marker for ICI treatment response (8, 82).

    Treatment strategies

    In most cases, dermatologic toxicity is mild and can be treated with topical corticosteroids or antihistamines (grade 1) (83). Gabapentin, a neurokinin 1 receptor antagonist, and doxepin may help at severe pruritus (84). For side effects above grade 2, the use of oral prednisone at 1 mg/kg/day is recommended. If the condition of the patient continues to worsen while using systemic steroids, the use of additional immunomodulatory therapy, such as infliximab, cyclophosphamide, and mycophenolate mofetil, should be considered.

    NERVOUS SYSTEM

    Neurotoxicity

    Clinical presentation and diagnosis

    ICI-related neurotoxicity can be classified into inflammatory (encephalitis, myelitis, vasculitis, and meningitis) and peripheral neuromuscular autoimmune disorders (myasthenia gravis and Guillain-Barre syndrome). If ICI-related neurotoxicity is suspected, prompt work-up should be performed and discontinuation of the ICIs should be considered. Diagnosis must be done to differentiate between spinal cord compression, intra-cerebral metastases, and bacterial meningitis. In order to exclude bacterial meningitis in patients with fever or patients who are immuno-compromised, an urgent lumbar puncture is need. Electromyography and nerve conduction studies help diagnose peripheral neuropathies, and nerve biopsy helps diagnose vasculitis. Neurological history and physical examination may be helpful for diagnosis; therefore, early consultation with a specialized neurologist is necessary (85).

    Incidence

    The incidence of ICI-related neurotoxicity is reported as 1% in the clinical trial, but it is fatal (3). As it is directly related to the quality of life, patients may give up additional chemotherapy if they experience neurological sequelae. ICI-related neurotoxicity mostly occurs within 3 months of drug initiation. Patterns of neurotoxicity are different depending on the ICIs used (86). Neuromuscular junction dysfunction (myasthenia gravis), non-infectious encephalitis, and myelitis occur more commonly with PD-1/PD-L1 inhibitors than anti-CTLA-4 agents. In contrast, Guillain-Barré syndrome and non-infectious meningitis occur more commonly with anti-CTLA-4 agents. It has been reported that adverse effects are more common with ipilimumab–nivolumab combination therapy than with monotherapy (87). Although sufficient data are lacking, some studies have reported that progression-free and overall survival are much longer in patients with ICI-related neurotoxicity (87, 88). The mechanism of neurotoxicity is still unknown, but it is presumed to be caused by sub-perineural edema and inflammation of endoneurial microvessels (89).

    Treatment strategies

    The treatment of choice is a systemic steroid. If the symptoms progress, systemic steroids should be started immediately (90). If steroid therapy has been initiated, the dose should be maintained until an observation of response. It should also be applied if there is a concern about the use of steroids due to other underlying diseases or factors. If respiratory muscles are involved, the intensive care unit and ventilator care may be necessary. In the absence of a steroid response, plasmapheresis, administration of intravenous immunoglobulin, and immune modulators, such as infliximab, mycophenolate, and cyclosporine, may be considered (87).

    Myasthenia gravis

    Myasthenia gravis is the most lethal form of ICI-related neurotoxicity. Unlike other ICI-related neurotoxicities, it occurs within a month of drug use (3). Myasthenia gravis is frequently accompanied by myocarditis and myositis (91). Unlike general myasthenia gravis, the test for acetylcholinesterase receptor Ab is frequently negative in this form of myasthenia gravis (92). Myasthenia gravis may cause an emergency that requires intensive care unit (ICU) treatment. Approximately 20% of patients with myasthenia gravis die, and the fatality rate is increased when the respiratory muscles are affected. High dose corticosteroids, plasma exchange and/or intravenous immunoglobulins are considered in fatal cases (93).

    Cognitive disorders

    ICI-related neurotoxicity has been focused on acute patterns and diseases. However, ICIs therapy is also suspected of being involved in causing the various aspects of chronic neurotoxicity, including cognitive disorders, fatigue, and mood disorders. In preclinical animal studies, ICIs can pass through the blood-brain barrier (94). ICIs can also change microglial activation and the levels of cytokines and chemokines in the brain (95). This change has been mainly demonstrated in the hippocampus, the center of cognitive function. Cognitive function and mood disorders are important factors that are directly linked to quality of life; often, this toxicity is neglected. Thus, further research is needed regarding cognitive disorders, fatigue, and mood disorders (96).

    OCULAR SYSTEM

    Ocular toxicities are known to be rare irAEs, with less than 1% of occurrence (97). The most common ICI-related ocular toxicity is uveitis. Most cases are bilateral and appear as anterior uveitis or pan-uveitis (98). Ocular toxicities occur within 6 months of using ICIs. Anti-CTLA-4 agents showed a higher incidence and severity of ocular toxicity than PD-1/PD-L1 inhibitors. ICIs induce more ocular toxicities than cytotoxic chemotherapy regimens (99). ICI-related ocular toxicity occurs more often in melanoma than other solid cancers. This observation may be explained through the cross-reactivity between malignant melanoma cells and normal choroidal melanocytes (100). Uveitis, especially in Vogt-Koyanagi-Harada like uveitis, is suspected to be a marker for a favor treatment response (101). Several cases have been reported that led to permanent loss of vision. Therefore, ophthalmic evaluation should be considered immediately if symptoms, such as worsening vision, floaters, or conjunctival injection, are detected (102). Uveitis can be easily treated with topical steroids, but systemic steroids should be considered when severity is high.

    THORAX

    Heart

    Clinical presentation and diagnosis

    ICI-related cardiotoxicity is relatively rare. However, it is life-threatening and fatal (3). ICI-related cardiotoxicity includes myocarditis, arrhythmias, conduction disease, acute coronary syndrome, congestive heart failure, and pericardial disease. The most common ICI-related cardiotoxicity is myocarditis. Diagnosis is based on clinical symptoms, laboratory findings and image tool, such as cardiac enzymes (troponin and creatinine kinases), echocardiogram, and electrocardiogram (103). Several studies report the usefulness of cardiac magnetic resonance imaging, although it is still controversial (104). Endomyocardial biopsy may be helpful for diagnosis, but it is an invasive procedure (105). Histologically, CD8+ T-cell and CD68+ macrophage, but not B-cell, infiltration is observed (106). Many cases are asymptomatic, and the clinician's awareness about cardiotoxicity is low (107). Therefore, attention to cardiotoxicity and efforts in cardiovascular monitoring are needed (108).

    Incidence

    The incidence of ICI-related myocarditis is known to be 0.09%–2.4% (109, 110). However, the fatality rate is approximately 27%–60%, making ICI-related myocarditis the most dangerous irAE (91, 111). The incidence and fatality rates are higher in ICI combination therapy than in ICI monotherapy (110). For example, ipilimumab–nivolumab combination therapy reported a fatality rate of 60% in myocarditis. In addition, a combination trial of ICIs and antiangiogenic agents, such as vascular endothelial growth factor (tyrosine kinase) inhibitors, has recently attracted attention, so cardiotoxicity has been increasingly an issue of concern. The time of occurrence varies, but fatal myocarditis usually occurs within a month of the first cycle of ICI infusion (109).

    Treatment strategies

    Cardiotoxicity has a significantly higher mortality rate than other irAEs, and it is recommended that ICIs are discontinued if cardiotoxicity is suspected. Systemic steroids are recommended for initial therapy, and 1 g per day of intravenous therapy should be considered if hemodynamic impairments are present (104). In steroid-refractory myocarditis, mycophenolate mofetil or tacrolimus should be considered (35, 112). Recently, antithymocyte globulin, abatacept (CTLA-4 agonist), and alemtuzumab (anti-CD52 Ab) have been used for the treatment of steroid-refractory myocarditis (113, 114). If the left ventricular ejection fraction is less than 50%, angiotensin-converting-enzyme inhibitors may be useful (115). Unlike other side effects, the re-initiation of ICIs is reported to be extremely dangerous (116).

    Mechanism

    The mechanism of cardiotoxicity is unknown. The presumed mechanism is that the PD-L1 and CTLA-4 pathways have a cardioprotective mechanism (especially T-cell-mediated inflammation), and ICIs disrupt immune tolerance in the heart (117). This hypothesis is based on the observation that PD-L1 expression in cardiomyocytes is upregulated in cardiac disease or injury (14). Postmortem analysis in ICI-related fatal myocarditis cases showed an increase in cytotoxic T-cells and macrophages. Dilated cardiomyopathy or autoimmune myocarditis has been observed in PD-1 knockout mouse models (118, 119). Moreover, severe myocarditis with cytotoxic T-lymphocyte infiltration has been reported in a CTLA-4 knockout mouse models (120). In contrast, some reports suggest that cardiotoxicity occurs because of shared Ags and epitopes among the heart, muscle, and tumor cells (109).

    Lung

    Clinical presentation and diagnosis

    Symptoms involving the lungs are very diverse and nonspecific, and some patients do not experience respiratory symptoms (121). It is crucial to exclude infections in diagnosis; thus, bronchoscopy or bronchoalveolar lavage may be helpful for differential diagnosis. However, no specific histologic findings are available yet. In addition, chest imaging and computed tomography are essential for diagnosis and detection. ICI-related pneumonitis exhibits a variety of imaging patterns, such as organizing pneumonia, nonspecific interstitial pneumonia, hypersensitivity pneumonitis, acute interstitial pneumonia, acute respiratory distress syndrome, bronchiolitis, and radiation recall (122). The dominant radiologic pattern is organizing pneumonia.

    Incidence

    ICI-related pneumonitis is rarer than other irAEs, but it is the most fatal irAE associated with PD-1/PD-L1 inhibitor therapy. ICI-related pneumonitis accounts for 35% of deaths due to PD-1 / PD-L1 inhibitor monotherapy (3). The overall incidence rate of ICI-related pneumonitis observed in clinical trials with ICI monotherapy is 2.5%–5.0%, and that with ICI combination therapy ranges 7%–10% (121). As clinical trials target healthy patients who have no underlying lung disease or autoimmune disease, the incidence in real world data ranges from 7%–19% (123). Moreover, the incidence of ICI-related pneumonitis is higher in non-small cell lung cancer than in other tumors (124). Further, PD-1/PD-L1 inhibitors showed a higher incidence and severity of pulmonary toxicity than that shown by anti-CTLA-4 agents (15), and PD-1 inhibitors show a higher incidence and severity of pulmonary toxicity than do PD-L1 inhibitors (125). Underlying lung disease (interstitial lung disease, asthma, and chronic obstructive pulmonary disease) and prior thoracic radiation are considered risk factors for ICI-related pneumonitis (126, 127). The mean duration of onset is approximately 3 months (128).

    Treatment strategies

    The framework of treatment is similar to drug-related hypersensitivity pneumonitis. The basis of treatment is ICI cessation, systemic steroids, and immunosuppressive medications (129). It has been reported that, if ICIs are restarted, ICI-related pneumonitis can recur in 20% of cases (130). Moreover, even after accomplishment of systemic steroid treatment and absence of retrying ICI therapy, some patients experience recurrent pneumonitis (131).

    CONCLUSION

    ICIs can cause a variety of unexpected side effects throughout the whole body. IrAEs are sometimes nonspecific or ambiguous, such as cardiotoxicity and endocrine toxicity. An important point in the treatment of irAEs is early detection and diagnosis. It should be noted that all new symptoms after ICI initiation could be irAEs. Regular checkups, such as thyroid function tests or cardiac enzymes, need to be performed. The basis of most irAE treatments is the use of systemic steroids. However, an immune modulator may be used in the absence of steroid response. Multidisciplinary treatments under the supervision of specialists are essential, because the symptoms and treatment of irAEs may involve multiple organs.

    Notes

    Conflict of Interest:The authors declare no potential conflicts of interest.

    Author Contributions:

    • Conceptualization: Choi J, Lee SY.

    • Supervision: Lee SY.

    • Writing - original draft: Choi J, Lee SY.

    • Writing - review & editing: Choi J, Lee SY.

    Abbreviations

    AIN acute interstitial nephritis
    ALT alanine aminotransferase
    AKI acute kidney injury
    AST aspartate aminotransferase
    ICI immune checkpoint inhibitor
    IMH immune medicated hepatitis
    irAE immune-related adverse effect
    NSAID non-steroidal anti-inflammatory drug
    PPI proton pump inhibitor

    References

      1. Topalian SL, Hodi FS, Brahmer JR, Gettinger SN, Smith DC, McDermott DF, Powderly JD, Carvajal RD, Sosman JA, Atkins MB, et al. Safety, activity, and immune correlates of anti-PD-1 antibody in cancer. N Engl J Med 2012;366:2443–2454.
      1. Tang J, Yu JX, Hubbard-Lucey VM, Neftelinov ST, Hodge JP, Lin Y. Trial watch: The clinical trial landscape for PD1/PDL1 immune checkpoint inhibitors. Nat Rev Drug Discov 2018;17:854–855.
      1. Wang DY, Salem JE, Cohen JV, Chandra S, Menzer C, Ye F, Zhao S, Das S, Beckermann KE, Ha L, et al. Fatal toxic effects associated with immune checkpoint inhibitors: a systematic review and meta-analysis. JAMA Oncol 2018;4:1721–1728.
      1. Wolchok JD, Chiarion-Sileni V, Gonzalez R, Rutkowski P, Grob JJ, Cowey CL, Lao CD, Wagstaff J, Schadendorf D, Ferrucci PF, et al. Overall survival with combined nivolumab and ipilimumab in advanced melanoma. N Engl J Med 2017;377:1345–1356.
      1. Yu Y, Ruddy KJ, Tsuji S, Hong N, Liu H, Shah N, Jiang G. Coverage evaluation of CTCAE for capturing the immune-related adverse events leveraging text mining technologies. AMIA Jt Summits Transl Sci Proc 2019;2019:771–778.
      1. Brahmer JR, Lacchetti C, Schneider BJ, Atkins MB, Brassil KJ, Caterino JM, Chau I, Ernstoff MS, Gardner JM, Ginex P, et al. Management of immune-related adverse events in patients treated with immune checkpoint inhibitor therapy: American Society of Clinical Oncology Clinical Practice Guideline. J Clin Oncol 2018;36:1714–1768.
      1. Haanen JB, Carbonnel F, Robert C, Kerr KM, Peters S, Larkin J, Jordan K. ESMO Guidelines Committee. Management of toxicities from immunotherapy: ESMO Clinical Practice Guidelines for diagnosis, treatment and follow-up. Ann Oncol 2018;29:iv264–iv266.
      1. Teulings HE, Limpens J, Jansen SN, Zwinderman AH, Reitsma JB, Spuls PI, Luiten RM. Vitiligo-like depigmentation in patients with stage III-IV melanoma receiving immunotherapy and its association with survival: a systematic review and meta-analysis. J Clin Oncol 2015;33:773–781.
      1. Deltombe C, Garandeau C, Renaudin K, Hourmant M. Severe allograft rejection and autoimmune hemolytic anemia after anti-PD1 therapy in a kidney transplanted patient. Transplantation 2017;101:e291
      1. Postow MA, Sidlow R, Hellmann MD. Immune-related adverse events associated with immune checkpoint blockade. N Engl J Med 2018;378:158–168.
      1. Byrne EH, Fisher DE. Immune and molecular correlates in melanoma treated with immune checkpoint blockade. Cancer 2017;123:2143–2153.
      1. Kimbara S, Fujiwara Y, Iwama S, Ohashi K, Kuchiba A, Arima H, Yamazaki N, Kitano S, Yamamoto N, Ohe Y. Association of antithyroglobulin antibodies with the development of thyroid dysfunction induced by nivolumab. Cancer Sci 2018;109:3583–3590.
      1. Iwama S, De Remigis A, Callahan MK, Slovin SF, Wolchok JD, Caturegli P. Pituitary expression of CTLA-4 mediates hypophysitis secondary to administration of CTLA-4 blocking antibody. Sci Transl Med 2014;6:230ra45
      1. Baban B, Liu JY, Qin X, Weintraub NL, Mozaffari MS. Upregulation of programmed death-1 and its ligand in cardiac injury models: interaction with GADD153. PLoS One 2015;10:e0124059
      1. Haanen JB, Carbonnel F, Robert C, Kerr KM, Peters S, Larkin J, Jordan K. ESMO Guidelines Committee. Management of toxicities from immunotherapy: ESMO Clinical Practice Guidelines for diagnosis, treatment and follow-up. Ann Oncol 2017;28:iv119–iv142.
      1. Robert C, Schachter J, Long GV, Arance A, Grob JJ, Mortier L, Daud A, Carlino MS, McNeil C, Lotem M, et al. Pembrolizumab versus ipilimumab in advanced melanoma. N Engl J Med 2015;372:2521–2532.
      1. Schachter J, Ribas A, Long GV, Arance A, Grob JJ, Mortier L, Daud A, Carlino MS, McNeil C, Lotem M, et al. Pembrolizumab versus ipilimumab for advanced melanoma: final overall survival results of a multicentre, randomised, open-label phase 3 study (KEYNOTE-006). Lancet 2017;390:1853–1862.
      1. de Malet A, Antoni G, Collins M, Soularue E, Marthey L, Vaysse T, Coutzac C, Chaput N, Mateus C, Robert C, et al. Evolution and recurrence of gastrointestinal immune-related adverse events induced by immune checkpoint inhibitors. Eur J Cancer 2019;106:106–114.
      1. Geukes Foppen MH, Rozeman EA, van Wilpe S, Postma C, Snaebjornsson P, van Thienen JV, van Leerdam ME, van den Heuvel M, Blank CU, van Dieren J, et al. Immune checkpoint inhibition-related colitis: symptoms, endoscopic features, histology and response to management. ESMO Open 2018;3:e000278
      1. Gupta A, De Felice KM, Loftus EV Jr, Khanna S. Systematic review: colitis associated with anti-CTLA-4 therapy. Aliment Pharmacol Ther 2015;42:406–417.
      1. Samaan MA, Pavlidis P, Papa S, Powell N, Irving PM. Gastrointestinal toxicity of immune checkpoint inhibitors: from mechanisms to management. Nat Rev Gastroenterol Hepatol 2018;15:222–234.
      1. Beniwal-Patel P, Matkowskyj K, Caldera F. Infliximab therapy for corticosteroid-resistant ipilimumab-induced colitis. J Gastrointestin Liver Dis 2015;24:274.
      1. Hsieh AH, Ferman M, Brown MP, Andrews JM. Vedolizumab: a novel treatment for ipilimumab-induced colitis. BMJ Case Rep 2016;2016:bcr2016216641
      1. Gong J, Chehrazi-Raffle A, Placencio-Hickok V, Guan M, Hendifar A, Salgia R. The gut microbiome and response to immune checkpoint inhibitors: preclinical and clinical strategies. Clin Transl Med 2019;8:9.
      1. Roy S, Trinchieri G. Microbiota: a key orchestrator of cancer therapy. Nat Rev Cancer 2017;17:271–285.
      1. Dubin K, Callahan MK, Ren B, Khanin R, Viale A, Ling L, No D, Gobourne A, Littmann E, Huttenhower C, et al. Intestinal microbiome analyses identify melanoma patients at risk for checkpoint-blockade-induced colitis. Nat Commun 2016;7:10391.
      1. Pezo RC, Wong M, Martin A. Impact of the gut microbiota on immune checkpoint inhibitor-associated toxicities. Therap Adv Gastroenterol 2019;12:1756284819870911
      1. Wang Y, Wiesnoski DH, Helmink BA, Gopalakrishnan V, Choi K, DuPont HL, Jiang ZD, Abu-Sbeih H, Sanchez CA, Chang CC, et al. Fecal microbiota transplantation for refractory immune checkpoint inhibitor-associated colitis. Nat Med 2018;24:1804–1808.
      1. Jennings JJ, Mandaliya R, Nakshabandi A, Lewis JH. Hepatotoxicity induced by immune checkpoint inhibitors: a comprehensive review including current and alternative management strategies. Expert Opin Drug Metab Toxicol 2019;15:231–244.
      1. Zen Y, Yeh MM. Hepatotoxicity of immune checkpoint inhibitors: a histology study of seven cases in comparison with autoimmune hepatitis and idiosyncratic drug-induced liver injury. Mod Pathol 2018;31:965–973.
      1. De Martin E, Michot JM, Papouin B, Champiat S, Mateus C, Lambotte O, Roche B, Antonini TM, Coilly A, Laghouati S, et al. Characterization of liver injury induced by cancer immunotherapy using immune checkpoint inhibitors. J Hepatol 2018;68:1181–1190.
      1. Wang W, Lie P, Guo M, He J. Risk of hepatotoxicity in cancer patients treated with immune checkpoint inhibitors: a systematic review and meta-analysis of published data. Int J Cancer 2017;141:1018–1028.
      1. Kim KW, Ramaiya NH, Krajewski KM, Jagannathan JP, Tirumani SH, Srivastava A, Ibrahim N. Ipilimumab associated hepatitis: imaging and clinicopathologic findings. Invest New Drugs 2013;31:1071–1077.
      1. Koksal AS, Toka B, Eminler AT, Hacibekiroglu I, Uslan MI, Parlak E. HBV-related acute hepatitis due to immune checkpoint inhibitors in a patient with malignant melanoma. Ann Oncol 2017;28:3103–3104.
      1. Brahmer JR, Lacchetti C, Thompson JA. Management of immune-related adverse events in patients treated with immune checkpoint inhibitor therapy: American Society of Clinical Oncology Clinical Practice Guideline summary. J Oncol Pract 2018;14:247–249.
      1. Perazella MA, Shirali AC. Nephrotoxicity of cancer immunotherapies: past, present and future. J Am Soc Nephrol 2018;29:2039–2052.
      1. Paueksakon P, Fogo AB. Drug-induced nephropathies. Histopathology 2017;70:94–108.
      1. Marco T, Anna P, Annalisa T, Francesco M, Stefania SL, Stella D, Michele R, Marco T, Loreto G, Franco S. The mechanisms of acute interstitial nephritis in the era of immune checkpoint inhibitors in melanoma. Ther Adv Med Oncol 2019;11:1758835919875549
      1. Mamlouk O, Selamet U, Machado S, Abdelrahim M, Glass WF, Tchakarov A, Gaber L, Lahoti A, Workeneh B, Chen S, et al. Nephrotoxicity of immune checkpoint inhibitors beyond tubulointerstitial nephritis: single-center experience. J Immunother Cancer 2019;7:2.
      1. Izzedine H, Gueutin V, Gharbi C, Mateus C, Robert C, Routier E, Thomas M, Baumelou A, Rouvier P. Kidney injuries related to ipilimumab. Invest New Drugs 2014;32:769–773.
      1. Manohar S, Kompotiatis P, Thongprayoon C, Cheungpasitporn W, Herrmann J, Herrmann SM. Programmed cell death protein 1 inhibitor treatment is associated with acute kidney injury and hypocalcemia: meta-analysis. Nephrol Dial Transplant 2019;34:108–117.
      1. Cortazar FB, Marrone KA, Troxell ML, Ralto KM, Hoenig MP, Brahmer JR, Le DT, Lipson EJ, Glezerman IG, Wolchok J, et al. Clinicopathological features of acute kidney injury associated with immune checkpoint inhibitors. Kidney Int 2016;90:638–647.
      1. Wanchoo R, Karam S, Uppal NN, Barta VS, Deray G, Devoe C, Launay-Vacher V, Jhaveri KD. Cancer and Kidney International Network Workgroup on Immune Checkpoint Inhibitors. Adverse renal effects of immune checkpoint inhibitors: a narrative review. Am J Nephrol 2017;45:160–169.
      1. Hughes J, Vudattu N, Sznol M, Gettinger S, Kluger H, Lupsa B, Herold KC. Precipitation of autoimmune diabetes with anti-PD-1 immunotherapy. Diabetes Care 2015;38:e55–e57.
      1. Shirali AC, Perazella MA, Gettinger S. Association of acute interstitial nephritis with programmed cell death 1 inhibitor therapy in lung cancer patients. Am J Kidney Dis 2016;68:287–291.
      1. Koda R, Watanabe H, Tsuchida M, Iino N, Suzuki K, Hasegawa G, Imai N, Narita I. Immune checkpoint inhibitor (nivolumab)-associated kidney injury and the importance of recognizing concomitant medications known to cause acute tubulointerstitial nephritis: a case report. BMC Nephrol 2018;19:48.
      1. Maggiore U, Pascual J. The bad and the good news on cancer immunotherapy: Implications for organ transplant recipients. Adv Chronic Kidney Dis 2016;23:312–316.
      1. Chang LS, Barroso-Sousa R, Tolaney SM, Hodi FS, Kaiser UB, Min L. Endocrine toxicity of cancer immunotherapy targeting immune checkpoints. Endocr Rev 2019;40:17–65.
      1. Hodi FS, O'Day SJ, McDermott DF, Weber RW, Sosman JA, Haanen JB, Gonzalez R, Robert C, Schadendorf D, Hassel JC, et al. Improved survival with ipilimumab in patients with metastatic melanoma. N Engl J Med 2010;363:711–723.
      1. González-Rodríguez E, Rodríguez-Abreu D. Spanish Group for Cancer Immuno-Biotherapy (GETICA). Immune checkpoint inhibitors: Review and management of endocrine adverse events. Oncologist 2016;21:804–816.
      1. Boasberg P, Hamid O, O'Day S. Ipilimumab: unleashing the power of the immune system through CTLA-4 blockade. Semin Oncol 2010;37:440–449.
      1. de Filette J, Andreescu CE, Cools F, Bravenboer B, Velkeniers B. A systematic review and meta-analysis of endocrine-related adverse events associated with immune checkpoint inhibitors. Horm Metab Res 2019;51:145–156.
      1. Sznol M, Postow MA, Davies MJ, Pavlick AC, Plimack ER, Shaheen M, Veloski C, Robert C. Endocrine-related adverse events associated with immune checkpoint blockade and expert insights on their management. Cancer Treat Rev 2017;58:70–76.
      1. Caturegli P, Di Dalmazi G, Lombardi M, Grosso F, Larman HB, Larman T, Taverna G, Cosottini M, Lupi I. Hypophysitis secondary to cytotoxic t-lymphocyte-associated protein 4 blockade: Insights into pathogenesis from an autopsy series. Am J Pathol 2016;186:3225–3235.
      1. Faje AT, Sullivan R, Lawrence D, Tritos NA, Fadden R, Klibanski A, Nachtigall L. Ipilimumab-induced hypophysitis: a detailed longitudinal analysis in a large cohort of patients with metastatic melanoma. J Clin Endocrinol Metab 2014;99:4078–4085.
      1. Dillard T, Yedinak CG, Alumkal J, Fleseriu M. Anti-CTLA-4 antibody therapy associated autoimmune hypophysitis: serious immune related adverse events across a spectrum of cancer subtypes. Pituitary 2010;13:29–38.
      1. Blansfield JA, Beck KE, Tran K, Yang JC, Hughes MS, Kammula US, Royal RE, Topalian SL, Haworth LR, Levy C, et al. Cytotoxic T-lymphocyte-associated antigen-4 blockage can induce autoimmune hypophysitis in patients with metastatic melanoma and renal cancer. J Immunother 2005;28:593–598.
      1. Ntali G, Kassi E, Alevizaki M. Endocrine sequelae of immune checkpoint inhibitors. Hormones (Athens) 2017;16:341–350.
      1. Barroso-Sousa R, Barry WT, Garrido-Castro AC, Hodi FS, Min L, Krop IE, Tolaney SM. Incidence of endocrine dysfunction following the use of different immune checkpoint inhibitor regimens: a systematic review and meta-analysis. JAMA Oncol 2018;4:173–182.
      1. Barroso-Sousa R, Ott PA, Hodi FS, Kaiser UB, Tolaney SM, Min L. Endocrine dysfunction induced by immune checkpoint inhibitors: Practical recommendations for diagnosis and clinical management. Cancer 2018;124:1111–1121.
      1. Illouz F, Briet C, Cloix L, Le Corre Y, Baize N, Urban T, Martin L, Rodien P. Endocrine toxicity of immune checkpoint inhibitors: essential crosstalk between endocrinologists and oncologists. Cancer Med 2017;6:1923–1929.
      1. de Filette J, Jansen Y, Schreuer M, Everaert H, Velkeniers B, Neyns B, Bravenboer B. Incidence of thyroid-related adverse events in melanoma patients treated with pembrolizumab. J Clin Endocrinol Metab 2016;101:4431–4439.
      1. Sui JD, Wang Y, Wan Y, Wu YZ. Risk of hematologic toxicities with programmed cell death-1 inhibitors in cancer patients: a meta-analysis of current studies. Drug Des Devel Ther 2018;12:1645–1657.
      1. Calvo R. Hematological side effects of immune checkpoint inhibitors: the example of immune-related thrombocytopenia. Front Pharmacol 2019;10:454.
      1. Davis EJ, Salem JE, Young A, Green JR, Ferrell PB, Ancell KK, Lebrun-Vignes B, Moslehi JJ, Johnson DB. Hematologic complications of immune checkpoint inhibitors. Oncologist 2019;24:584–588.
      1. Jagpal A, Choudhary G, Chokr J. Severe arthritis and tenosynovitis caused by immune checkpoint blockade therapy with pembrolizumab (anti-PD-1 antibody). Proc Bayl Univ Med Cent 2019;32:419–421.
      1. Ribas A, Puzanov I, Dummer R, Schadendorf D, Hamid O, Robert C, Hodi FS, Schachter J, Pavlick AC, Lewis KD, et al. Pembrolizumab versus investigator-choice chemotherapy for ipilimumab-refractory melanoma (KEYNOTE-002): a randomised, controlled, phase 2 trial. Lancet Oncol 2015;16:908–918.
      1. Baxi S, Yang A, Gennarelli RL, Khan N, Wang Z, Boyce L, Korenstein D. Immune-related adverse events for anti-PD-1 and anti-PD-L1 drugs: systematic review and meta-analysis. BMJ 2018;360:k793.
      1. Cappelli LC, Naidoo J, Bingham CO 3rd, Shah AA. Inflammatory arthritis due to immune checkpoint inhibitors: challenges in diagnosis and treatment. Immunotherapy 2017;9:5–8.
      1. Naidoo J, Cappelli LC, Forde PM, Marrone KA, Lipson EJ, Hammers HJ, Sharfman WH, Le DT, Baer AN, Shah AA, et al. Inflammatory arthritis: a newly recognized adverse event of immune checkpoint blockade. Oncologist 2017;22:627–630.
      1. Puzanov I, Diab A, Abdallah K, Bingham CO 3rd, Brogdon C, Dadu R, Hamad L, Kim S, Lacouture ME, LeBoeuf NR, et al. Managing toxicities associated with immune checkpoint inhibitors: consensus recommendations from the Society for Immunotherapy of Cancer (SITC) Toxicity Management Working Group. J Immunother Cancer 2017;5:95.
      1. Braaten TJ, Brahmer JR, Forde PM, Le D, Lipson EJ, Naidoo J, Schollenberger M, Zheng L, Bingham Rd CO, Shah AA, et al. Immune checkpoint inhibitor-induced inflammatory arthritis persists after immunotherapy cessation. Ann Rheum Dis. 2019
      1. Horvat TZ, Adel NG, Dang TO, Momtaz P, Postow MA, Callahan MK, Carvajal RD, Dickson MA, D'Angelo SP, Woo KM, et al. Immune-related adverse events, need for systemic immunosuppression, and effects on survival and time to treatment failure in patients with melanoma treated with ipilimumab at Memorial Sloan Kettering Cancer Center. J Clin Oncol 2015;33:3193–3198.
      1. Jaber SH, Cowen EW, Haworth LR, Booher SL, Berman DM, Rosenberg SA, Hwang ST. Skin reactions in a subset of patients with stage IV melanoma treated with anti-cytotoxic T-lymphocyte antigen 4 monoclonal antibody as a single agent. Arch Dermatol 2006;142:166–172.
      1. Belum VR, Benhuri B, Postow MA, Hellmann MD, Lesokhin AM, Segal NH, Motzer RJ, Wu S, Busam KJ, Wolchok JD, et al. Characterisation and management of dermatologic adverse events to agents targeting the PD-1 receptor. Eur J Cancer 2016;60:12–25.
      1. Lacouture ME, Wolchok JD, Yosipovitch G, Kähler KC, Busam KJ, Hauschild A. Ipilimumab in patients with cancer and the management of dermatologic adverse events. J Am Acad Dermatol 2014;71:161–169.
      1. Voskens CJ, Goldinger SM, Loquai C, Robert C, Kaehler KC, Berking C, Bergmann T, Bockmeyer CL, Eigentler T, Fluck M, et al. The price of tumor control: an analysis of rare side effects of anti-CTLA-4 therapy in metastatic melanoma from the ipilimumab network. PLoS One 2013;8:e53745
      1. Naidoo J, Schindler K, Querfeld C, Busam K, Cunningham J, Page DB, Postow MA, Weinstein A, Lucas AS, Ciccolini KT, et al. Autoimmune bullous skin disorders with immune checkpoint inhibitors targeting PD-1 and PD-L1. Cancer Immunol Res 2016;4:383–389.
      1. Curry JL, Tetzlaff MT, Nagarajan P, Drucker C, Diab A, Hymes SR, Duvic M, Hwu WJ, Wargo JA, Torres-Cabala CA, et al. Diverse types of dermatologic toxicities from immune checkpoint blockade therapy. J Cutan Pathol 2017;44:158–176.
      1. Tarhini A. Immune-mediated adverse events associated with ipilimumab CTLA-4 blockade therapy: the underlying mechanisms and clinical management. Scientifica (Cairo) 2013;2013:857519
      1. Minkis K, Garden BC, Wu S, Pulitzer MP, Lacouture ME. The risk of rash associated with ipilimumab in patients with cancer: a systematic review of the literature and meta-analysis. J Am Acad Dermatol 2013;69:e121–e128.
      1. Freeman-Keller M, Kim Y, Cronin H, Richards A, Gibney G, Weber JS. Nivolumab in resected and unresectable metastatic melanoma: characteristics of immune-related adverse events and association with outcomes. Clin Cancer Res 2016;22:886–894.
      1. Zimmer L, Vaubel J, Livingstone E, Schadendorf D. Side effects of systemic oncological therapies in dermatology. J Dtsch Dermatol Ges 2012;10:475–486.
      1. Collins LK, Chapman MS, Carter JB, Samie FH. Cutaneous adverse effects of the immune checkpoint inhibitors. Curr Probl Cancer 2017;41:125–128.
      1. Spain L, Tippu Z, Larkin JM, Carr A, Turajlic S. How we treat neurological toxicity from immune checkpoint inhibitors. ESMO Open 2019;4:e000540
      1. Johnson DB, Manouchehri A, Haugh AM, Quach HT, Balko JM, Lebrun-Vignes B, Mammen A, Moslehi JJ, Salem JE. Neurologic toxicity associated with immune checkpoint inhibitors: a pharmacovigilance study. J Immunother Cancer 2019;7:134.
      1. Spain L, Walls G, Julve M, O'Meara K, Schmid T, Kalaitzaki E, Turajlic S, Gore M, Rees J, Larkin J. Neurotoxicity from immune-checkpoint inhibition in the treatment of melanoma: a single centre experience and review of the literature. Ann Oncol 2017;28:377–385.
      1. Cuzzubbo S, Javeri F, Tissier M, Roumi A, Barlog C, Doridam J, Lebbe C, Belin C, Ursu R, Carpentier AF. Neurological adverse events associated with immune checkpoint inhibitors: review of the literature. Eur J Cancer 2017;73:1–8.
      1. Manousakis G, Koch J, Sommerville RB, El-Dokla A, Harms MB, Al-Lozi MT, Schmidt RE, Pestronk A. Multifocal radiculoneuropathy during ipilimumab treatment of melanoma. Muscle Nerve 2013;48:440–444.
      1. Touat M, Talmasov D, Ricard D, Psimaras D. Neurological toxicities associated with immune-checkpoint inhibitors. Curr Opin Neurol 2017;30:659–668.
      1. Moslehi JJ, Salem JE, Sosman JA, Lebrun-Vignes B, Johnson DB. Increased reporting of fatal immune checkpoint inhibitor-associated myocarditis. Lancet 2018;391:933.
      1. Anquetil C, Salem JE, Lebrun-Vignes B, Johnson DB, Mammen AL, Stenzel W, Léonard-Louis S, Benveniste O, Moslehi JJ, Allenbach Y. Immune checkpoint inhibitor-associated myositis. Circulation 2018;138:743–745.
      1. Becquart O, Lacotte J, Malissart P, Nadal J, Lesage C, Guillot B, Du Thanh A. Myasthenia gravis induced by immune checkpoint inhibitors. J Immunother 2019;42:309–312.
      1. Reardon DA, Gokhale PC, Klein SR, Ligon KL, Rodig SJ, Ramkissoon SH, Jones KL, Conway AS, Liao X, Zhou J, et al. Glioblastoma eradication following immune checkpoint blockade in an orthotopic, immunocompetent model. Cancer Immunol Res 2016;4:124–135.
      1. McGinnis GJ, Friedman D, Young KH, Torres ER, Thomas CR Jr, Gough MJ, Raber J. Neuroinflammatory and cognitive consequences of combined radiation and immunotherapy in a novel preclinical model. Oncotarget 2017;8:9155–9173.
      1. McGinnis GJ, Raber J. CNS side effects of immune checkpoint inhibitors: preclinical models, genetics and multimodality therapy. Immunotherapy 2017;9:929–941.
      1. Antoun J, Titah C, Cochereau I. Ocular and orbital side-effects of checkpoint inhibitors: a review article. Curr Opin Oncol 2016;28:288–294.
      1. Sun MM, Levinson RD, Filipowicz A, Anesi S, Kaplan HJ, Wang W, Goldstein DA, Gangaputra S, Swan RT, Sen HN, et al. Uveitis in patients treated with CTLA-4 and PD-1 checkpoint blockade inhibition. Ocul Immunol Inflamm. 2019
      1. Abdel-Rahman O, Oweira H, Petrausch U, Helbling D, Schmidt J, Mannhart M, Mehrabi A, Schöb O, Giryes A. Immune-related ocular toxicities in solid tumor patients treated with immune checkpoint inhibitors: a systematic review. Expert Rev Anticancer Ther 2017;17:387–394.
      1. Lavezzo MM, Sakata VM, Morita C, Rodriguez EE, Abdallah SF, da Silva FT, Hirata CE, Yamamoto JH. Vogt-Koyanagi-Harada disease: review of a rare autoimmune disease targeting antigens of melanocytes. Orphanet J Rare Dis 2016;11:29.
      1. Diem S, Keller F, Rüesch R, Maillard SA, Speiser DE, Dummer R, Siano M, Urner-Bloch U, Goldinger SM, Flatz L. Pembrolizumab-triggered uveitis: An additional surrogate marker for responders in melanoma immunotherapy? J Immunother 2016;39:379–382.
      1. Conrady CD, Larochelle M, Pecen P, Palestine A, Shakoor A, Singh A. Checkpoint inhibitor-induced uveitis: a case series. Graefes Arch Clin Exp Ophthalmol 2018;256:187–191.
      1. Michel L, Rassaf T, Totzeck M. Cardiotoxicity from immune checkpoint inhibitors. Int J Cardiol Heart Vasc 2019;25:100420
      1. Ganatra S, Neilan TG. Immune checkpoint inhibitor-associated myocarditis. Oncologist 2018;23:879–886.
      1. Bonaca MP, Olenchock BA, Salem JE, Wiviott SD, Ederhy S, Cohen A, Stewart GC, Choueiri TK, Di Carli M, Allenbach Y, et al. Myocarditis in the setting of cancer therapeutics: Proposed case definitions for emerging clinical syndromes in cardio-oncology. Circulation 2019;140:80–91.
      1. Yang S, Asnani A. Cardiotoxicities associated with immune checkpoint inhibitors. Curr Probl Cancer 2018;42:422–432.
      1. Neilan TG, Rothenberg ML, Amiri-Kordestani L, Sullivan RJ, Steingart RM, Gregory W, Hariharan S, Hammad TA, Lindenfeld J, Murphy MJ, et al. Myocarditis associated with immune checkpoint inhibitors: an expert consensus on data gaps and a call to action. Oncologist 2018;23:874–878.
      1. Totzeck M, Schuler M, Stuschke M, Heusch G, Rassaf T. Cardio-oncology - strategies for management of cancer-therapy related cardiovascular disease. Int J Cardiol 2019;280:163–175.
      1. Johnson DB, Balko JM, Compton ML, Chalkias S, Gorham J, Xu Y, Hicks M, Puzanov I, Alexander MR, Bloomer TL, et al. Fulminant myocarditis with combination immune checkpoint blockade. N Engl J Med 2016;375:1749–1755.
      1. Mahmood SS, Fradley MG, Cohen JV, Nohria A, Reynolds KL, Heinzerling LM, Sullivan RJ, Damrongwatanasuk R, Chen CL, Gupta D, et al. Myocarditis in patients treated with immune checkpoint inhibitors. J Am Coll Cardiol 2018;71:1755–1764.
      1. Escudier M, Cautela J, Malissen N, Ancedy Y, Orabona M, Pinto J, Monestier S, Grob JJ, Scemama U, Jacquier A, et al. Clinical features, management, and outcomes of immune checkpoint inhibitor-related cardiotoxicity. Circulation 2017;136:2085–2087.
      1. Arangalage D, Delyon J, Lermuzeaux M, Ekpe K, Ederhy S, Pages C, Lebbé C. Survival after fulminant myocarditis induced by immune-checkpoint inhibitors. Ann Intern Med 2017;167:683–684.
      1. Salem JE, Allenbach Y, Vozy A, Brechot N, Johnson DB, Moslehi JJ, Kerneis M. Abatacept for severe immune checkpoint inhibitor-associated myocarditis. N Engl J Med 2019;380:2377–2379.
      1. Esfahani K, Buhlaiga N, Thébault P, Lapointe R, Johnson NA, Miller WH Jr. Alemtuzumab for immune-related myocarditis due to PD-1 therapy. N Engl J Med 2019;380:2375–2376.
      1. Lyon AR, Yousaf N, Battisti NM, Moslehi J, Larkin J. Immune checkpoint inhibitors and cardiovascular toxicity. Lancet Oncol 2018;19:e447–e458.
      1. Tajmir-Riahi A, Bergmann T, Schmid M, Agaimy A, Schuler G, Heinzerling L. Life-threatening autoimmune cardiomyopathy reproducibly induced in a patient by checkpoint inhibitor therapy. J Immunother 2018;41:35–38.
      1. Tajiri K, Ieda M. Cardiac complications in immune checkpoint inhibition therapy. Front Cardiovasc Med 2019;6:3.
      1. Wang J, Okazaki IM, Yoshida T, Chikuma S, Kato Y, Nakaki F, Hiai H, Honjo T, Okazaki T. PD-1 deficiency results in the development of fatal myocarditis in MRL mice. Int Immunol 2010;22:443–452.
      1. Nishimura H, Okazaki T, Tanaka Y, Nakatani K, Hara M, Matsumori A, Sasayama S, Mizoguchi A, Hiai H, Minato N, et al. Autoimmune dilated cardiomyopathy in PD-1 receptor-deficient mice. Science 2001;291:319–322.
      1. Waterhouse P, Penninger JM, Timms E, Wakeham A, Shahinian A, Lee KP, Thompson CB, Griesser H, Mak TW. Lymphoproliferative disorders with early lethality in mice deficient in Ctla-4 . Science 1995;270:985–988.
      1. Naidoo J, Wang X, Woo KM, Iyriboz T, Halpenny D, Cunningham J, Chaft JE, Segal NH, Callahan MK, Lesokhin AM, et al. Pneumonitis in patients treated with anti-programmed death-1/programmed death ligand 1 therapy. J Clin Oncol 2017;35:709–717.
      1. Kalisz KR, Ramaiya NH, Laukamp KR, Gupta A. Immune checkpoint inhibitor therapy-related pneumonitis: patterns and management. Radiographics 2019;39:1923–1937.
      1. Suresh K, Naidoo J, Lin CT, Danoff S. Immune checkpoint immunotherapy for non-small cell lung cancer: benefits and pulmonary toxicities. Chest 2018;154:1416–1423.
      1. Ma K, Lu Y, Jiang S, Tang J, Li X, Zhang Y. The relative risk and incidence of immune checkpoint inhibitors related pneumonitis in patients with advanced cancer: a meta-analysis. Front Pharmacol 2018;9:1430.
      1. Sternschein R, Moll M, Ng J, D'Ambrosio C. Immune checkpoint inhibitor-related pneumonitis. Incidence, risk factors, and clinical and radiographic features. Am J Respir Crit Care Med 2018;198:951–953.
      1. Cho JY, Kim J, Lee JS, Kim YJ, Kim SH, Lee YJ, Cho YJ, Yoon HI, Lee JH, Lee CT, et al. Characteristics, incidence, and risk factors of immune checkpoint inhibitor-related pneumonitis in patients with non-small cell lung cancer. Lung Cancer 2018;125:150–156.
      1. Shaverdian N, Lisberg AE, Bornazyan K, Veruttipong D, Goldman JW, Formenti SC, Garon EB, Lee P. Previous radiotherapy and the clinical activity and toxicity of pembrolizumab in the treatment of non-small-cell lung cancer: a secondary analysis of the KEYNOTE-001 phase 1 trial. Lancet Oncol 2017;18:895–903.
      1. Nishino M, Ramaiya NH, Awad MM, Sholl LM, Maattala JA, Taibi M, Hatabu H, Ott PA, Armand PF, Hodi FS. PD-1 inhibitor-related pneumonitis in advanced cancer patients: Radiographic patterns and clinical course. Clin Cancer Res 2016;22:6051–6060.
      1. Sears CR, Peikert T, Possick JD, Naidoo J, Nishino M, Patel SP, Camus P, Gaga M, Garon EB, Gould MK, et al. Knowledge gaps and research priorities in immune checkpoint inhibitor-related pneumonitis. An official American Thoracic Society research statement. Am J Respir Crit Care Med 2019;200:e31–e43.
      1. Delaunay M, Cadranel J, Lusque A, Meyer N, Gounant V, Moro-Sibilot D, Michot JM, Raimbourg J, Girard N, Guisier F, et al. Immune-checkpoint inhibitors associated with interstitial lung disease in cancer patients. Eur Respir J 2017;50:1700050
      1. Nishino M, Chambers ES, Chong CR, Ramaiya NH, Gray SW, Marcoux JP, Hatabu H, Jänne PA, Hodi FS, Awad MM. Anti-PD-1 inhibitor-related pneumonitis in non-small cell lung cancer. Cancer Immunol Res 2016;4:289–293.
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    Publication Types
    Review
    MeSH Terms
    Autoimmune Diseases
    Cardiotoxicity
    Homeostasis
    Hypophysitis
    Immune Checkpoint Inhibitors
    Immune Checkpoint Inhibitors*
    Incidence
    Myasthenia Gravis
    Organization and Administration
    Specialization
    Steroids
    T-Lymphocytes
    Thyroid Gland
    Metrics
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