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Case Reviews in Surgery

Colonic Perforation after Dual Ipilimumab and Nivolumab Treatment

Colonic Perforation after Dual Ipilimumab and Nivolumab Treatment

March 4, 2020

Abstract

Background

The advent of immunotherapy is changing treatment paradigms for a number of cancers and an increasing number of patients are being treated with immune checkpoint inhibitors (ICIs). ICI-associated immune-related adverse events (irAEs) are most often mild and can be managed medically; however, 1.0 to 1.5% of patients treated with ICIs experience sever adverse events, including colonic perforation, a life-threatening condition. This case report describes a patient with a history of metastatic melanoma, who had recently been started on combination ipilimumab and nivolumab therapy (two ICIs). Soon after treatment initiation, the patient developed severe colitis with subsequent perforation of her sigmoid colon, necessitating emergent surgical intervention. Surgeons will increasingly be involved in caring for these patients as the prevalence of patients being treated with ICIs continues to rise.

Summary

The patient is a 66-year-old female diagnosed with metastatic melanoma, including metastases to her lungs. Six weeks prior to presenting to the hospital, the patient had received her second treatment with two immune checkpoint inhibitors - the programmed cell death-1 (PD-1) inhibitor nivolumab and the cytotoxic T-lymphocyte associated protein 4 (CTLA4) inhibitor ipilimumab. The patient had been started on a three-week cycle of 100 mg of nivolumab and 3 mg per kilogram of ipilimumab. After the second treatment cycle, the patient experienced abdominal pain, loose stools and hematochezia, and she was started on corticosteroids for management of immune-mediated colitis. Her abdominal pain and hematochezia progressed, prompting her to seek emergency care. Diagnostic workup revealed signs of sigmoid colon perforation, with pneumoperitoneum, free fluid and extraluminal contrast detected on computed tomography (CT). The patient was taken to the operating room for an exploratory laparotomy. Two small perforations were identified in the sigmoid colon, surrounded by moderately inflamed but otherwise grossly healthy appearing bowel. The sigmoid colon was resected, and a Hartmann's procedure was performed. One week post-operatively, the patient developed significant recurrent hematochezia with hemodynamic instability, requiring an emergent completion colectomy with end ileostomy. The patient made a full recovery without further complication after the completion colectomy and is awaiting reversal of the ileostomy.

Conclusion

As the role of immunotherapy continues to expand, the incidence of serious adverse events, including colitis and life-threatening colonic perforation, will continue to rise. This case report highlights a colonic perforation following treatment with combination ipilimumab and nivolumab and the complex decision making inherent in providing surgical care to this patient population.

Key Words

ipilimumab, nivolumab, PD-1, CTLA4, immunotherapy, colon perforation


Case Description

In the past decade, six antibodies targeting immune checkpoints (ipilimumab – CTLA4; pembrolizumab and nivolumab – PD-1; atezolizumab, avelumab and durvalumab – PD-L1) have been approved by the Food and Drug Administration (FDA) for the treatment of several different types of cancer, including metastatic melanoma, renal cell carcinoma, classical Hodgkin's lymphoma, mismatch repair deficient colorectal cancer, bladder cancer, head and neck cancer, and non-small cell lung cancer.1-3 Combination therapy composed of two checkpoint inhibitors (e.g., an anti-PD-1 inhibitor and an anti-CTLA4 inhibitor) has shown enormous promise due to improved response rates and improved overall survival4-6 but has also amplified the incidence of severe immune-related adverse events (irAEs).6-8 Colonic perforation associated with immunotherapy is a rare, but well-documented, irAE that requires emergent surgical intervention.9-13 This monograph describes the case of a 66-year-old woman with a past medical history significant for obesity, COPD, tobacco dependence and malignant melanoma of the right upper extremity, status post wide local excision and sentinel lymph node biopsy in 2013 complicated by metastasis to the lung in 2017. She was started on a three-week cycle of dual immunotherapy treatment with nivolumab and ipilimumab for metastatic melanoma, dosed at 100 mg and 3 mg/kg, respectively. The patient received two cycles of the two checkpoint inhibitors. Treatment was discontinued after the second dose due to signs of immune-mediated colitis with symptoms of diarrhea, hematochezia and abdominal pain. She was started on an outpatient steroid taper regimen to treat the immune-mediated colitis. Importantly, the patient does not have a history of inflammatory bowel disease.

Six weeks later, the patient presented to the hospital with acute worsening of abdominal pain and hematochezia. On physical examination, she was febrile with a temperature of 39.2°C, hemodynamically normal, and had significant abdominal tenderness. Pertinent laboratory values included a white blood cell count of 19,600 cells/μL, hemoglobin of 8.6 g/dL, creatinine of 0.84 mg/dL and lactate of 0.8 mmol/L. She was given two units of blood, intravenous fluids and empiric antibiotics. Abdominal and pelvic CT evaluation with PO and IV contrast showed free air in the abdomen and complex ascites with extraluminal contrast, consistent with bowel perforation of the sigmoid colon. Marked thickening of the descending and rectosigmoid colon with pericolonic stranding was also identified (Figure 1). The decision was made to take her to the operating room for exploratory laparotomy.

Figure 1. Pre-operative CT imaging. A. Complex free fluid with evidence of extraluminal contrast (red arrow), consistent with bowel perforation.B. Sigmoid colonic thickening (red arrow) with pericolonic fat stranding and complex pelvic ascites.
Figure 1. Pre-operative CT imaging. A. Complex free fluid with evidence of extraluminal contrast (red arrow), consistent with bowel perforation.B. Sigmoid colonic thickening (red arrow) with pericolonic fat stranding and complex pelvic ascites.

Figure 1. Pre-operative CT imaging. A. Complex free fluid with evidence of extraluminal contrast (red arrow), consistent with bowel perforation.B. Sigmoid colonic thickening (red arrow) with pericolonic fat stranding and complex pelvic ascites.

Intraoperatively, succus and purulent matter was encountered immediately upon exploration. Inspection of the bowel reveled two perforations on the anti-mesenteric aspect of the mid-sigmoid colon; the remaining bowel appeared grossly normal. The sigmoid colon was removed given the significant inflammation with perforation. An anorectal stump was created, and an end colostomy was formed. Subsequent pathological analysis of the sigmoid colon specimen demonstrated extensive mucosal and focal transmural ulceration and necrosis (Figure 2A) without evidence of lymphocytic colitis. The patient tested negative for cytomegalovirus (CMV), Clostridium difficile, herpes simplex virus, hepatitis B virus (HBV), and hepatitis C virus and stool cultures were negative for growth of any bacteria or yeast.

Figure 2. Pathologic analysis indicates immune-mediated colitis. A. Path Low power hematoxylin and eosin (H&E) image showing sigmoid colon with extensive ulceration and full-thickness necrosis extending from the mucosa (arrow) into the muscularis propria (star). B. Medium power hematoxylin and eosin (H&E) image showing colonic glands with acute inflammation, crypt abscesses (arrows), scattered enterocyte apoptosis, and mild lymphoplasmacytic expansion of the lamina propria (star).
Figure 2. Pathologic analysis indicates immune-mediated colitis. A. Path Low power hematoxylin and eosin (H&E) image showing sigmoid colon with extensive ulceration and full-thickness necrosis extending from the mucosa (arrow) into the muscularis propria (star). B. Medium power hematoxylin and eosin (H&E) image showing colonic glands with acute inflammation, crypt abscesses (arrows), scattered enterocyte apoptosis, and mild lymphoplasmacytic expansion of the lamina propria (star).

Figure 2. Pathologic analysis indicates immune-mediated colitis. A. Path Low power hematoxylin and eosin (H&E) image showing sigmoid colon with extensive ulceration and full-thickness necrosis extending from the mucosa (arrow) into the muscularis propria (star). B. Medium power hematoxylin and eosin (H&E) image showing colonic glands with acute inflammation, crypt abscesses (arrows), scattered enterocyte apoptosis, and mild lymphoplasmacytic expansion of the lamina propria (star).

Initially, the patient recovered appropriately. She was extubated and had return of bowel function. Immunosuppressive therapy was not continued in the immediate post-operative period due to a concern for impairment in wound healing. However, on post-operative day eight, the patient developed significant hematochezia from her colostomy, had an incomplete response to blood transfusion, and developed hemodynamic instability. She was subsequently taken back to the operating room emergently and underwent completion colectomy to ensure that further complications due to colitis were eliminated. Intra-operatively, an EGD and ileoscopy via enterotomy of the terminal ileum demonstrated normal stomach and small bowel mucosa without evidence of bleeding. Surgical pathology of the removed colon again demonstrated acute inflammation, crypt abscesses and enterocyte apoptosis (Figure 2B). These findings suggest that during the initial operation, more aggressive resection may have been preferable. Post-operatively, the patient had a prolonged hospital course with respiratory failure requiring tracheostomy, extended ventilator management, and she was discharged to a rehabilitation facility. The patient was last seen in surgical clinic at six-month follow-up doing well, having functionally returned to her baseline, and her six-month imaging demonstrated reduction in the size of her largest lung nodules, stable smaller nodules, and no evidence of new lung of abdominal metastases.

Discussion

The advent of immune checkpoint inhibitors has caused a paradigm shift in the treatment approaches for several types of cancer,1,9,14 including lung cancer,15-17 head and neck cancers,18,19 colon cancer,20 renal cell carcinoma,21 urothelial carcinoma,3 and metastatic melanoma.4,6 The combination of a PD-1 and a CTLA4 inhibitor – as used for the patient described in this report – to treat metastatic melanoma has been studied in several large clinical trials.4,6,22 Early trials of monotherapy for advanced melanoma showed that checkpoint inhibitors yielded 3-year survival rates of 20% to 26%,23-28 a significant improvement for a disease with a median survival of eight months and a 5-year survival rate of 10%.29 Subsequent studies of dual-therapy reported that combinations of PD-1 and CTLA4 inhibitors appear superior in terms of overall survival to monotherapy.4-6,30 The outcomes of these clinical trials have been encouraging; however, as the number of patients treated with these agents increases, it is to be expected that the number of patients experiencing severe irAEs will rise accordingly.4,6,31

The incidence of all irAEs has been reported to be 65% and higher for checkpoint inhibitor monotherapy.9,30 This rate is amplified when therapeutics are combined, with rates for adverse events approaching 96% for patients treated with combined nivolumab and ipilimumab compared to 86% for either agent given as monotherapy; severe adverse events of grade 3 or 4 were reported to be 59% for combination therapy, 28% for patients treated with ipilimumab, and 21% for nivolumab treated patients.6 Based on several large clinical trials, the most frequently encountered adverse events include rash, pruritus, fatigue, nausea, and diarrhea, with more severe events such as colitis, pneumonitis, neutropenia, and myelitis occurring much less commonly.4-6,9,12 Most adverse events are minor and can be managed medically. One of the most severe irAEs, colonic perforation, is a rare but well document event and life-threatening in nature.6,31,32

Immune-mediated colitis has been reported to occur in 0.3 to 7% of patients treated with immune checkpoint inhibitors.31 Immune checkpoint-associated colitis most commonly, but not exclusively, affects the rectum and sigmoid colon.8,33,34 When colitis is suspected, immunomodulator treatment should be discontinued immediately, and alternative causes of colitis, such as CMV, IBD, HBV, celiac disease, and Clostridium difficile infection must be excluded.31 The extent of involved colon should be confirmed via flexible sigmoidoscopy or colonoscopy, and biopsies are recommended.8 Immune checkpoint inhibitor-associated colitis tends to differ from inflammatory bowel disease (IBD) in that patients present with acute focal or patchy colitis with infiltrating neutrophils and eosinophils and with crypt abscesses.8 In severe cases, treatment with immune checkpoint inhibitors must be discontinued in perpetuity;.8 in less severe cases, treatment can recommence once symptoms subside: in ipilimumab and nivolumab treated melanoma patients, response rate was not affected by brief periods of treatment discontinuation.31

Medical management for immune-related adverse GI events includes treatment with steroids: corticosteroids given at a fixed dose of 1 mg/kg/day and up to 2 mg/kg/day in refractory or severe cases, followed by a 1-2-month taper once symptoms have improved, has shown good efficacy. Systemic steroid treatment does not seem to negate the anti-tumor activity of checkpoint inhibitors,22,35 but current available data is not entirely conclusive.36 In case of clinical deterioration despite corticosteroid treatment (i.e., no improvement after several days of treatment), infliximab (TNF-α) treatment with a single dose of 5 mg/kg is recommended.31 A second dose of 5 mg/kg of infliximab two weeks after the initial dose should be given if the patient remains symptomatic.

Colon perforation has been estimated to occur in 1.0% to 1.5% of melanoma patients treated with ipilimumab and up to 6% of ipilimumab treated patients with renal cell carcinoma.8,33 There are currently no established molecular markers or host factors to predict adverse events from immunotherapy; although, IL-17, eosinophil levels, neutrophil infiltrates, and other factors are being actively investigated.37 In the case of suspected perforation, CT studies should be completed if the patient is hemodynamically stable; however, in the unstable patient, surgery should not be delayed and exploratory laparotomy is indicated.8 It has not been determined if re-initiation of immunotherapeutic therapy is advisable after surgical treatment.

Post-surgical care of patients that present with colonic perforation after treatment with immunotherapy has not been clearly delineated. Steroid treatment and treatment with infliximab should be considered as options. High-dose corticosteroid administration for less than ten days has not been found to have a significant effect on wound healing; however, chronic corticosteroid use for at least 30 days before surgery increased the risk of complications two to five times.38 Perioperative corticosteroid use or infliximab use for cases of elective surgery for Crohn's disease did not increase rates of early postoperative complications.39 Several additional studies of post-operative use of steroids or infliximab for cases of IBD have shown a small but significant increase in complications, particularly in the rate of infection (intra-abdominal and wound dehiscence).38-40 Despite the small increase in complications, the use of steroids and infliximab may well yield a benefit; in the context of immunosuppression with steroids and/or infliximab, the use of prophylactic measures to reduce the risk of infection requires further investigation.

The case described in this report highlights some of the challenges likely to be encountered by surgeons with increasing frequency as the number of patients receiving treatment with checkpoint inhibitors continues to rise. In the described case, it would have potentially been preferable to perform a colonoscopy intra-operatively to visualize the extent and severity of the inflammation at the initial operation, to determine if the patient would have benefited from a total initial colectomy and/or implement more aggressive treatment with steroids and infliximab post-operatively. Specifics regarding pre- and post-operative management strategies for patients receiving immunotherapy should be explored in future studies.

Conclusion

This case describes one of the most severe adverse events associated with immunotherapy - colon perforation - and discusses the management thereof from a surgical perspective. The enormous success of immune checkpoint inhibitors for the treatment of several different types of cancer is resulting in a steady increase in the number of patients with adverse events requiring surgical intervention. The possibility of colonic perforation should be suspected in patients treated with immunotherapy, aggressive treatment promptly initiated, and early surgical consultation strongly recommended. Further studies are needed to define the cause and optimal treatment paradigm for this complication in this patient population.

Lessons Learned

As the number of cancer patients treated with ICIs increases, the number of patients that experience colonic perforation is expected to escalate as well. It is critical that surgeons are aware of this expanding patient population and of the most appropriate treatment: likely a combination of surgery, steroids and immunosuppression.

Authors

Tim N. Beck, MD, PhD
Digestive Disease & Surgery Institute
Cleveland Clinic
Cleveland, OH
Program in Molecular Therapeutics
Fox Chase Cancer Center
Philadelphia, PA

Yanis Boumber, MD, PhD
Department of Hematology/Oncology
Fox Chase Cancer Center
Philadelphia, PA
Kazan Federal University
Kazan, Russian Federation

Alexander Y. Deneka, MD, PhD
Program in Molecular Therapeutics
Fox Chase Cancer Center
Philadelphia, PA
Kazan Federal University
Kazan, Russian Federation

Emily S. Reardon, MD
Acute Care and Emergency Surgery
University of Maryland Medical Center
Baltimore, MD

Natalie A. O'Neill, MD
Acute Care and Emergency Surgery
University of Maryland Medical Center
Baltimore, MD

Alison O. Flentje, MD
Acute Care and Emergency Surgery
University of Maryland Medical Center
Baltimore, MD

Megan Quintana, MD
Acute Care and Emergency Surgery
University of Maryland Medical Center
Baltimore, MD

Stephanie Richards, MD
Department of Pathology
University of Maryland Medical Center
Baltimore, MD

Brandon R. Bruns, MD, FACS
Acute Care and Emergency Surgery
University of Maryland Medical Center
Baltimore, MD

Paulesh Shah, MD, FACS
Acute Care and Emergency Surgery
University of Maryland Medical Center
Baltimore, MD

Correspondence Author

Tim N. Beck, MD, PhD
Digestive Disease & Surgery Institute
Cleveland Clinic
9500 Euclid Avenue
Cleveland, Ohio 44195
Phone: 216-645-9460
Email: Beckt2@ccf.org

Disclosure Statement

Dr. Boumber has served on advisory boards of Astra Zeneca, Boehringer Ingelheim, Bristol-Meyers Squibb, Caris Life Sciences, Novartis, and Takeda. The authors have no other conflicts to disclose. The authors were supported by the Ruth L. Kirschstein National Research Service Award F30 fellowship (F30 CA180607 [Dr. Beck]) and R01 A218802-01A1 [Dr. Boumber]). Drs. Boumber and Beck were supported by the NCI Core Grant P30 CA006927 (to Fox Chase Cancer Center).

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