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Kim, Lee, Chung, Park, Park, Song, and Bang: Bleeding Complications and Clinical Safety of Endoscopic Retrograde Cholangiopancreatography in Patients with Liver Cirrhosis

Abstract

Purpose

Patients with liver cirrhosis are considered to be at risk for additional adverse events during endoscopic retrograde cholangiopancreatography (ERCP). The present study was designed as a propensity-score matched analysis to investigate whether cirrhotic liver increases the risk of bleeding complications in patients undergoing ERCP.

Materials and Methods

In total, 8554 patients who underwent ERCP from January 2005 to December 2015 were retrospectively analyzed. To adjust for the imbalance between patients with and those without liver cirrhosis, 1:3 propensity score matching was performed according to age and sex.

Results

Liver cirrhosis was identified in 264 (3.1%) patients. After propensity score matching, a total of 768 patients were included in each of the cirrhotic (n=192) and non-cirrhotic groups (n=576). Post-procedure bleeding (10.9% vs. 4.7%, p=0.003) was more frequently observed in patients with liver cirrhosis than in those without. In multivariate analyses, liver cirrhosis was identified as an independent risk factor associated with post-ERCP bleeding (p=0.003) after further adjustment for prothrombin time, antiplatelet/coagulant, duration of ERCP, and stent insertion. Child-Pugh (CP) class C was found to be associated with an increased incidence of post-ERCP bleeding in patients with cirrhosis (odds ratio 6.144, 95% confidence interval 1.320–28.606; p=0.021).

Conclusion

The incidence of post-ERCP bleeding in patients with liver cirrhosis was higher than that in patients without liver cirrhosis. In particular, CP class C cirrhosis was significantly associated with post-ERCP bleeding.

INTRODUCTION

Endoscopic retrograde cholangiopancreatography (ERCP) has become the first-choice treatment for common bile duct (CBD) disorders and periampullary disease.12 Compared with other endoscopic examinations, ERCP carries a higher potential for complications, ranging from minor events with prompt resolution, such as mild pancreatitis, to major life-threatening risks, such as hemorrhage and severe pancreatitis.34567 In previous studies, the risk factors for bleeding as a result of ERCP are coagulopathy, liver cirrhosis, renal failure, sphincterotomy, and papillectomy.8910 In particular, patients with liver cirrhosis have been considered to be at high risk for ERCP-related bleeding.1112 Cirrhosis-associated coagulopathy, liver dysfunction, and gastroesophageal varices may increase the risk of procedure- related bleeding in these patients.4
To date, several studies have analyzed the risk of ERCP in patients with liver cirrhosis.11131415 However, previous studies reported limited sample sizes,121516 small portions of therapeutic ERCPs,14 limited information about the type of procedure or degree of cirrhosis, and substantial heterogeneity in the comparison group.1112 Furthermore, the safety of ERCP in liver cirrhosis is still controversial because of limited data.1114 Adler, et al.14 reported that therapeutic ERCP is safe and effective in patients with liver cirrhosis. Meanwhile, however, Inamdar, et al.11 showed that the frequency of ERCP-related bleeding was statistically significant in patients with decompensated liver cirrhosis. Endoscopic sphincterotomy (EST) or balloon dilatation, which means cutting or dilatation of the sphincter muscle that lies at the juncture of the intestine with the bile ducts, is an essential technique in patients who receive ERCP.161718 Prior to those procedures in cirrhotic patients, recognition and understanding of the potential complications of ERCP are important for appropriate patient selection for performing ERCP.
Here, we aimed to investigate the safety of ERCP in patients with liver cirrhosis, focusing on bleeding complications. For the evaluation of bleeding complications of ERCP in patients with cirrhosis, we performed propensity-score matched analysis using a retrospective cohort data.

MATERIALS AND METHODS

Patients

A total of 8554 patients had undergone ERCP at an academic tertiary hospital in South Korea between January 2005 and December 2015. Among them, 555 patients were excluded according to the following exclusion criteria: ERCP for bile duct anastomosis site stricture after liver transplantation in the cirrhotic group (n=129); failed cannulation during the procedure (n=269); only cholangiography without insertion of a guidewire during the procedure (n=93); and papillectomy (n=64). Finally, 264 patients with cirrhosis and 7735 patients without cirrhosis remained.
The demographic, clinical, and laboratory data of the study population were collected from medical records. Medical record data, including sex, age at the time of procedure, etiology of cirrhosis, cardiovascular disease, medication related to bleeding tendency, pre-procedure laboratory values, Child-Pugh (CP) scores at the time of the procedure, ERCP indications, procedural details, and procedure-related adverse events, were reviewed. Liver cirrhosis was diagnosed according to laboratory values, liver biopsies, and the results of imaging studies. If liver histologic information was not available, clinically diagnosed liver cirrhosis was based on following criteria: 1) platelet count of <100000/µL and ultrasonographic findings suggestive of cirrhosis, including a blunted, nodular liver edge accompanied by splenomegaly (>12 cm); 2) esophageal or gastric varices; or 3) overt complications of liver cirrhosis, including ascites, variceal bleeding, and hepatic encephalopathy.19 The severity of liver cirrhosis was classified according to CP class. This study was performed in accordance with ethical guidelines of the 1975 Declaration of Helsinki and approved by the Institutional Review Board of Severance Hospital (IRB number: 4-2016-1090).

Propensity score matching

Propensity score matching was introduced to reduce patient selection bias and the potential confounding biases due to differences between the two patient groups. A biostatistician in the Medical Research Collaborating Center matched the group of the patients with liver cirrhosis to the group of those without liver cirrhosis at a 1:3 ratio using the calculated propensity score by optimal matching methods. To eliminate bias caused by different baseline characteristics, we calculated propensity score based on age and sex. After optimal matching, we compared the baseline characteristics. Finally, 768 patients were matched, including 192 patients in the cirrhotic group and 576 patients in the non-cirrhotic group (Fig. 1).

Endoscopic procedure

Patients were sedated with intravenous anesthesia (midazolam and/or propofol), along with continuous monitoring of blood pressure, heart rate, and oxygen saturation. All patients received intravenous cimetropium bromide for inhibiting duodenal spasm. A side-viewing duodenal scope (TJF-260; Olympus, Tokyo, Japan) was used for ERCP. After the papilla had been examined with the endoscope, selective cannulation of either the CBD or the ventral pancreatic duct was performed. Once the chosen duct was selectively cannulated, either a cholangiogram or a pancreatogram was obtained fluoroscopically with injection of contrast medium into the duct. Four hours after the ERCP and at 5 a.m. of the next day of the procedure, blood chemistry, including serum amylase, lipase, and total bilirubin level; chest radiography; and simple abdominal radiography were performed for evaluating post-ERCP pancreatitis (PEP), cholangitis, and bowel perforation. To identify post-ERCP bleeding, hemoglobin level and bleeding history were checked. Most of the patients taking medications related to bleeding tendency (such as aspirin, warfarin, clopidogrel, or a new oral anticoagulant) needed to stop the medications for at least until 3 days before the procedure.

Definition and management of complications

Post-sphincterotomy bleeding was defined as immediate bleeding requiring endoscopic or other intervention within 24 hr or delayed bleeding recognized on the basis of clinical evidence (such as melena, hematochezia, and hematemesis), with a decrease in hemoglobin level >2 g/dL or the need for blood transfusion within 10 days after ERCP.4 Clinically significant bleeding and its severity were classified as follows: mild bleeding was defined as overt bleeding with a decrease of hemoglobin level <3 g/dL, without the need for transfusion; moderate bleeding was defined as blood transfusion of 4 units or less without the need for angiographic intervention or surgery; and severe bleeding was defined as blood transfusion of 5 units or more or the need for angiographic or surgical intervention.20

Statistical analysis

Statistical analyses were performed using SPSS software (version 20.0; IBM Corp., Armonk, NY, USA). Associations involving parametric data were assessed using Student's t-test. Chisquare (χ2) test was used to compare categorical data, and Student's t-test was used to compare continuous data. Statistical analysis was performed with the Jonckheere-Terpstra test to determine whether there was a statistically significant trend among independent samples. All two-tailed p values of <0.05 were considered statistically significant.

RESULTS

Patients

After propensity score matching, a total of 192 patients with cirrhosis (age 59.4±9.5 years) were included in the analysis. The etiologies of cirrhosis were as follows: hepatitis B (n=106, 59.2%), hepatitis C (n=21, 11.7%), and alcoholic (n=28, 15.6%). Among 192 patients with liver cirrhosis, 92 (47.9%) had CP classification A, 55 (28.6%) had CP classification B, and 45 (23.4%) had CP classification C. The patient demographic and procedure characteristics are summarized in Table 1. The indications for ERCP were as follows: CBD stone with or without acute cholangitis (n=296, 38.5%), bile duct obstruction (n=335, 43.6%), and pancreatitis (n=32, 4.2%).

ERCP-related bleeding complications

A total of 48 patients had post-ERCP bleeding among the enrolled patients, and there was a statistically significantly higher rate of bleeding complication in patients with cirrhosis (10.9% vs. 4.7%; p=0.003). Among the bleeding cases, 32 patients (66.7%) had mild post-ERCP bleeding; 16 patients (33.3%) had moderate post-ERCP bleeding (Table 2). Most bleeding events (n= 32, 66.7%) were mild oozing that occurred during the procedure. No cases of massive bleeding occurred. Thirty-two bleeding episodes were controlled with electrical cauterization with a needle knife and/or hemoclip. No cases needed embolization or surgical management. There was no event of mortality related to bleeding.

Risk factors related to post-ERCP bleeding

Univariate analysis showed liver cirrhosis to be a significant risk factor related to post-ERCP bleeding (p=0.003). Because cirrhosis associated coagulopathy may increase the risk of procedure-related bleeding, we performed additional multivariate analysis. Liver cirrhosis was identified as an independent risk factor related to post-ERCP bleeding after adjustment for prothrombin time and duration of ERCP (p=0.003) (Table 3). Procedure types were not independent risk factors for post-ERCP bleeding.

Bleeding complications according to the CP classification

In subgroup analysis, there was a significant difference in the rate of post-procedure bleeding among patients with different CP classifications (Table 4). In multivariate analysis, CP class C was found to be associated with an increased incidence of post-ERCP bleeding in patients with cirrhosis (odds ratio 6.144, 95% confidence interval 1.320–28.606; p=0.021).

Complications according to procedure type

The patients underwent various therapeutic maneuvers during ERCP, which were individualized based on indications and intraprocedural findings. Among patients with liver cirrhosis, 93 patients (48.4%) underwent EST; however, there was no significant difference in the rate of post-ERCP bleeding in patients who underwent biliary sphincterotomy, compared with those who did not have a sphincterotomy (10.8% vs. 11.1%, p=0.561) (Supplementary Table 1, only online). We further analyzed the events of PEP and cholangitis because a high frequency of adverse events, including PEP and cholangitis, occurred in patients with cirrhosis undergoing ERCP. In the present study, there were no significant differences in the occurrences of PEP and cholangitis (p=0.507 and p=0.489) between the cirrhotic and non-cirrhotic groups (Supplementary Table 2, only online). In multivariate analysis, stent insertion was found to be associated with increased incidences of PEP and cholangitis (p=0.005 and p=0.029) (Supplementary Tables 3 and 4, only online).

DISCUSSION

In this study, we analyzed our data after propensity score matching according to identified variables including sex and age. We confirmed that patients with liver cirrhosis face a greater risk of experiencing post-ERCP bleeding: liver cirrhosis was an independent risk factor associated with post-ERCP bleeding. These results were not changed after further adjustment for duration of ERCP, procedure type, and prothrombin time.
Patients with liver cirrhosis are predisposed to developing underlying coagulopathy. Because of poor hepatic synthetic function, these patients have coagulation disorders and low platelet counts, which are risk factors of post-procedure bleeding. Zhang, et al.15 reported that post-ERCP bleeding was increased in patients with Model for End-stage Liver Disease (MELD) scores >11.5. Similar to previous studies, patients with CP class C cirrhosis experienced significantly more bleeding than those with CP class A or B in this study.
ERCP with sphincterotomy has been considered to pose a higher risk for post-procedure bleeding.4 In a previous study, complications of EST occur in about 10% of patients, and 2–3% may have a prolonged hospital stay.20 The presence of varices, which can develop in the duodenum in patients with cirrhosis, may increase the risk of bleeding after sphincterotomy. However, in this study, bleeding risk after sphincterotomy did not show any statistically significant difference from the patients with cirrhosis, compared to those without cirrhosis. Regardless of the sphincterotomy, due to a tendency for patients with cirrhosis to bleed, bleeding complications of ERCP are considered to occur. Accordingly, the rate of bleeding was higher in patients with cirrhosis in this study.
Mariante-Neto, et al.21 and Romano, et al.22 reported that lower levels of creatinine may influence the low prognostic value of MELD score, which is associated post-ERCP bleeding, and suggested that sex may have an impact on the prognostic value of both MELD and CP scores. Herein, we matched all patients by age and sex. We analyzed the impact of liver cirrhosis on post-ERCP bleeding both without adjustment for platelet/prothrombin time and with it. After all of this, regardless of platelet/prothrombin time, liver cirrhosis was a significant risk factor in this study.
Our study has several limitations. First, the retrospective nature may lead to an inherent selection bias. To overcome this limitation, we performed propensity score matching. This study is based on a cohort from large representative tertiary referral hospitals. Further, we performed additional adjustment for platelet, albumin, and prothrombin time to reduce the selection bias. After matching, more than 50% of therapeutic ERCPs was performed in this study, and degree of cirrhosis was analyzed. Second, the definition of bleeding events has not been standardized in previous studies.111314152324 The number of post-ERCP bleedings may depend on the definition of bleeding associated with a procedure. In this study, we categorized the bleeding grade according to the clinical and laboratory findings to find the effect of ERCP in patients with cirrhosis.
In conclusion, the incidence of post-ERCP bleeding in patients with liver cirrhosis is remarkably high after diagnostic and therapeutic ERCP. CP classification can be a valuable predictive factor for ERCP-related adverse events, especially in terms of bleeding. Bleeding problems may be related to the formation of a powerful collateral vascular bed in the area of the duodenum due to portal hypertension. In this regard, therapeutic ERCP in patients with liver cirrhosis should be used according to absolute indications and with high caution. For diagnostic purposes, minimally invasive methods, such as magnetic resonance cholangiopancreatography, endoscopic ultrasound, etc., may be more appropriate.

ACKNOWLEDGEMENTS

Pray for the bliss of dead of Ji Yeon Kim.

Notes

The authors have no potential conflicts of interest to disclose.

AUTHOR CONTRIBUTIONS: Ji Yeon Kim, Hee Seung Lee: data collection, data analysis, study conception, and manuscript preparation. Moon Jae Chung: critical revision of manuscript, data quality review. Jeong Youp Park: critical revision of manuscript, data quality review. Seung Woo Park: critical revision of manuscript, data quality review. Si Young Song: critical revision of manuscript, data quality review. Seungmin Bang: study conception, critical revision of manuscript, overall study supervision. All authors approved the final manuscript.

References

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SUPPLEMENTARY MATERIALS

Supplementary Table 1

Comparison of Adverse Events of ERCP Among Patients with Liver Cirrhosis Who Underwent EST, EPBD, and Stent Insertion (ERBD)
ymj-60-440-s001.pdf

Supplementary Table 2

Comparison of Adverse Events in ERCP between Patients with Cirrhosis and Those without Cirrhosis
ymj-60-440-s002.pdf

Supplementary Table 3

Univariate and Multivariate Analysis of Risk Factors for Post-ERCP Pancreatitis
ymj-60-440-s003.pdf

Supplementary Table 4

Univariate and Multivariate Analysis of Risk Factors for Post-ERCP Cholangitis
ymj-60-440-s004.pdf
Fig. 1

Flow diagram of patient selection. ERCP, endoscopic retrograde cholangiopancreatography.

ymj-60-440-g001
Table 1

Patient Baseline Characteristics

ymj-60-440-i001
Variables Total (n=768) Cirrhotic (n=192) Non-cirrhotic (n=576) p value
Patient related variables
 Male 592 (77.1) 148 (77.1) 444 (77.1) 1.000
 Age (yr) 59.4±9.5 59.4±9.5 59.4±9.5 1.000
 Body mass index 22.6±3.5 22.6±3.5 22.7±3.5 0.702
 Prothrombin time (INR) 1.01±0.21 1.08±0.23 0.98±0.20 0.001
 Platelet (×103/µL) 210.8±96.8 147.4±77.4 231.9±93.3 0.001
 Cardiovascular disease 52 (6.8) 11 (5.7) 41 (7.1) 0.619
 CKD 29 (3.8) 17 (8.9) 12 (2.1) 0.001
 Anticoagulant drug 89 (11.6) 27 (14.1) 62 (10.8) 0.241
Procedure related variables
 Indication of ERCP
  CBD stone 296 (38.5) 71 (37.0) 225 (39.1) 0.669
  Bile duct obstruction 335 (43.6) 98 (51.0) 237 (41.1) 0.019
  Pancreatitis 32 (4.2) 3 (1.6) 29 (5.0) 0.037
 Procedure type
  Stent insertion ERBD 250 (32.6) 63 (32.8) 187 (32.5) 0.929
  EST 350 (45.6) 93 (48.4) 257 (44.6) 0.359
  Ballooning (EPBD) 52 (6.8) 14 (7.3) 38 (6.6) 0.741

ERCP, endoscopic retrograde cholangiopancreatography; ERBD, endoscopic retrograde biliary drainage; EST, endoscopic sphincterotomy; EPBD, endoscopic papillary balloon dilation; INR, international normalized ratio; CKD, chronic kidney disease; CBD, common bile duct.

Variables are expressed as mean±standard deviation or n (%).

Table 2

Comparison of Post-ERCP Bleeding between Patients with Cirrhosis and Those without Cirrhosis

ymj-60-440-i002
Adverse event Total (n=768) Cirrhotic (n=192) Non-cirrhotic (n=576) p value
Bleeding 48 (6.3) 21 (10.9) 27 (4.7) 0.003
Severity 0.555
 Mild 32 (66.7) 13 (61.9) 19 (70.4)
 Moderate 16 (33.3) 8 (38.1) 8 (29.6)
 Severe 0 (0.0) 0 (0.0) 0 (0.0)
Time of bleeding 0.712
 Immediate 39 (81.3) 18 (85.7) 21 (77.8)
 Delayed 9 (18.8) 3 (14.3) 6 (22.2)
Treatment modality 0.758
 Conservative 16 (33.3) 6 (28.6) 10 (37.0)
 Endoscopic 32 (66.7) 15 (71.4) 17 (63.0)

ERCP, endoscopic retrograde cholangiopancreatography.

Variables are expressed as n (%).

Table 3

Univariate and Multivariate Analysis of Risk Factors for Post-ERCP Bleeding

ymj-60-440-i003
Variables Univariate Multivariate
p value Adjusted OR 95% CI p value
Liver cirrhosis 0.003 2.497 1.377–4.530 0.003
Prothrombin time (INR) 0.800 1.198 0.298–4.819 0.799
EST 0.871
EPBD 0.316
Antiplatelet/coagulant 0.399
Duration of ERCP 0.158 1.013 0.997–1.029 0.103
Stent insertion 0.293

ERCP, endoscopic retrograde cholangiopancreatography; OR, odds ratio; CI, confidence interval; INR, international normalized ratio; EST, endoscopic sphincterotomy; EPBD, endoscopic papillary balloon dilatation.

Table 4

Multivariate Analysis of Risk Factors for Post-ERCP Bleeding in Cirrhotic Patients

ymj-60-440-i004
Variables Multivariate
Adjusted OR 95% CI p value
Child-Pugh class
 A 1
 B 2.533 0.704–9.112 0.155
 C 6.144 1.320–28.606 0.021
Albumin 0.539 0.156–1.867 0.330
Platelet 0.987 0.976–0.999 0.032
CKD 4.757 0.525–43.109 0.165
Anticoagulant drugs 1.690 0.257–11.116 0.585
EST 1.760 0.533–5.817 0.354
EPBD 0.552 0.052–5.889 0.623

ERCP, endoscopic retrograde cholangiopancreatography; OR, odds ratio; CI, confidence interval; CKD, chronic kidney disease; EST, endoscopic sphincterotomy; EPBD, endoscopic papillary balloon dilatation.

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