Metal Stenting with or without Endobiliary Radiofrequency Ablation for Unresectable Extrahepatic Cholangiocarcinoma ()
1. Introduction
Extrahepatic cholangiocarcinoma (EH-CCA) was reported with the highest incidence in eastern and southeastern Asia. It is linked to liver fluke infestations. EH-CCA is a very aggressive tumor and remains highly resistant to current chemoradiation therapies. Radical resection offers the best outcome [1] -[3] but, despite significant advances in diagnostic modalities, the vast majority of patients present with metastases or with advanced locoregional disease that prevents surgical therapy [2] . Even for patients who undergo surgical treatment, recurrent disease is common. Although the tumor burden is usually lethal, the vast majority of patients with EH-CCA present with malignant biliary obstruction, which leads to cholangitis and liver failure, which is also a cause of death. For this reason, the relief of biliary obstruction is a key palliative treatment option for patients with hilar or distal EH-CCA.
Biliary drainage affected by self-expandable metallic stents (SEMSs), is a desirable method of palliation of malignant biliary obstruction for patients whose life expectancy is greater than 3 months [3] . This process has a median stent patency lasting 6 - 10 months [4] -[8] . The major drawback of this treatment is that the patency of the stent is limited to a median duration of 6 - 8 months in up to 50% of patients. This is mainly due to tumor in- or over-growth, biofilm deposition, biliary sludge, or formation of granulation tissue, all of which may result in ongoing or recurrent biliary obstruction that causes significant morbidity and mortality [9] .
Several methods, such as the use of organic polymers to coat self-expandable metallic stents, substituting alloys like nitinol for stainless steel, or endobiliary photodynamic therapy (PDT), have been proposed to increase the duration of stent patency in malignant biliary obstruction but they have not been proven to be effective by sufficient data [8] [10] -[12] . Rather, they present with increased risks of side effects, such as pancreatitis and cholecystitis due to covered SEMS and cholangitis and photosensitivity due to PDT [8] [11] [12] .
Recently, endobiliary radiofrequency ablation (ERFA) has emerged as a new treatment modality to improve SEMS patency and has been used for unresectable malignant biliary obstruction [13] -[19] . The current work highlights two major advantages of RFA. First, it reduces the tumor load, and thus, delays tumor growth, both of which may prolong stent patency. Second, endobiliary RFA may be suitable for development into a neoadjuvant therapy in unresectable CCA.
Here, the effects of SEMS placement with and without ERFA on stent patency and patient survival for unresectable extrahepatic CCA patients were compared. In this study, qualified patients with EH-CCA were included, and they were treated by stenting alone or in combination after endobiliary RFA. The outcomes (overall survival) of the patients were studied, and multivariate Cox proportional hazards regression analyses were used to identify other significant prognostic factors relevant to overall patient survival.
2. Methods
2.1. Patients Selection
This retrospective study was approved by the institutional review board of the second affiliated hospital of Guangzhou Medical University. Between January 2010 and September 2014, 242 patients with extrahepatic CCA were treated in our hospital. Seventy-six patients were included in this study using the following criteria and the detailed selection process is described in Figure 1.
1) Inclusion criteria: a) Patients with histologically or cytologically confirmed extrahepatic biliary adenocarcinoma but ineligible for curative surgery due to locally advanced or metastatic disease or unfit for/not willing to undergo a major operation; b) patients who successfully underwent SEMS placement with or without ERFA as initial treatment for obstructive jaundice by endoscopic retrograde cholangiopancreatography (ERCP) or percu- taneous transhepatic cholangiography (PTC) approaches if ERCP fails.
2) Exclusion criteria: a) Patients with obstructive jaundice caused by other malignant tumors (tumors of the ampulla of Vater, pancreatic tumors, hepatocellular carcinoma with endobiliary tumor thrombus, bile duct compressed by hilar lymph metastases, e.g.), or patients who had developed obstructive jaundice due to recurrent tumors after initial resection of the CCA; b) patients with Bismuth type II, III, or IV hilar CCA [21] [22] ;
Figure 1. Flow diagram of patient selection process. CCA, cholangiocarcinoma; ERFA, endobiliary radiofrequency ablation; SEMS, self-expanding metal stent.
c) patients who underwent unsuccessful SEMS placement with or without ERFA, who underwent other local ablative treatments (PDT) instead of ERFA, or who underwent placement of plastic stents instead of SEMS for obstructive jaundice.
2.2. Patient Evaluation
Pre-treatment assessment of all patients included a complete history and physical examination for general health, laboratory tests and radiologic imaging. A dual-phase contrast-enhanced spiral computed tomography and/or magnetic resonance cholangiopancreatography were performed out on all patients to evaluate biliary tumors and possible vascular involvement. If needed, positron emission tomography with [(18)F]fluoro-2-deoxy-D-glucose (FDG-PET) was used to identify occult metastatic disease. All data were reviewed by a multidisciplinary treatment team of radiologists, surgeons, pathologist and oncologists to select treatment options. For those with unresectable extrahepatic CCA, the option of ERFA before SEMS placement and its potential benefits for prolonging stent patency were discussed with patients, who would make the ultimate decision. Informed consent was obtained from all patients.
2.3. ERFA and/or SEMS Treatment and Follow-Up
All patients received intratracheal general anesthesia. Side viewing endoscopes TJF-160 (Olympus America, Center Valley, PA) were used for all endoscopical procedures. Patients underwent biliary sphincterotomy followed by cholangiogram to confirm stricture location. An endoscopical clamp or cytology brush was use to obtain biopsies for histological analysis. Percutaneous biopsy and cholangiography were performed under real-time US guidance (EUB-2000, HITACHI Medical Systems) for all percutaneous approaches.
For patients who received ERFA, the Habib EndoHPB catheter (EMcision UK, London, United Kingdom) was advanced to the stricture location, and radiofrequency energy was delivered by an RFA generator (1500 RF generator; RITA Medical Systems Inc, Fremont, CA) at 400 kHz at 10 W for 2 min, with a rest period of one min before moving the catheter. Repeat energy was applied to ensure the whole stricture length was covered. An uncovered (Cook Ireland ltd, Limerick, Ireland) or covered SEMS (WallFlex RX RMV, Boston Scientific Corporation, city, MA) was placed after ERFA (Figure 2).
All patients received computed tomography and/or MRI and laboratory blood tests about 30 days after the
(a) (b)
Figure 2. Fluoroscopic imaging of the procedure of ERFA and stent placement. (a) This is a 46 year old male with unresectable Bismuth type I hilar CCA. Habib EndoHPB catheter was deployed to ablate bile duct tumor approached by endoscopic retrograde cholangiopancreatography; (b) after completing ERFA, an uncovered self-expanding metal stent was placed at the bile duct stricture site.
procedure and bile duct stricture improvement was evaluated. Those with obvious bile duct decompression and persistent liver function improvement (total bilirubin and combined bilirubin decreasing) were considered to have full stricture improvement. Partial or no improvement was identified when radiologic images showed that a stricture remained in the previous tumor site and bilirubin did not normalize or bilirubin increased after decreased.
Adjuvant chemotherapy based on practice guidelines of the National Comprehension Cancer Network (NCCN) in hepatobiliary cancers was recommended for patients who recovered from the intervention [20] . All patients were regularly followed up every two months since the last intervention procedure until November 2014. When bile ducts occluded again, the multidisciplinary treatment team met to decide whether a repeat ERFA and/or SEMS placement or percutaneous biliary drainage was appropriate. Major complications were defined as procedure-related complications resulting in an unplanned increase in medical care, prolonged hospitalization, permanent adverse sequelae, or death [21] .
2.4. Statistical Analysis
Demographic data for both groups was compared using the Student’s t test for continuous data and the Chi-squared test for categorical data. The median stent patency was compared by Mann-Whitney test. Overall survival curves from the date of ERFA and/or SEMS were calculated and constructed by the Kaplan-Meier method and compared using the log-rank test. The relative prognostic significance of the variables in predicting overall survival was assessed by multivariate Cox proportional hazards regression analysis. Statistical analyses were performed using SPSS 10.0 statistical software (SPSS Company, Chicago, IL). Continuous data are given as means ± S.D. All statistical tests were two-sided, and a significant difference was considered when P < 0.05.
3. Results
3.1. Patient Groups
Seventy-six patients with indication for SEMS and ERFA were included in this study, among which, 34 patients opted to receive ERFA followed by SEMS placement and 42 patients opted to receive SEMS only. There were no significant differences among the patients in demography (gender, age), tumor grade, and staging, patients’ general health conditions, and liver function parameters (Table 1). Most patients (72/76, 94.7%) had unresecta- ble extrahepatic CCA due to local advanced tumors (n = 65) or metastatic disease (n = 7). Two patients with po- tentially resectable extrahepatic CCA refused tumor resection, and 2 patients were considered unfit for a major operation (one had severe cirrhosis; the other had poor pulmonary function). Histological and/or cytological dia- gnosis of biliary adenocarcinoma was made in 66 patients by ERCP. For those who underwent a PTC approach, 6 patients also had hepatic metastatic tumors and the other 4 patients had Bismuth type I hilar CCA. Percuta- neous biopsy was successfully performed on hepatic metastatic tumors or hilar CCA. There was no difference in
Table 1. General clinical data of the patients.
aAmerican Joint Committee on Cancer (AJCC) TNM Staging (7th edition 2010). 27; bPatients who declined to have major operation; cPatients who were unfit for major operation; dEndobiliary radiofrequency ablation; eSelf-expanding metal stent; fCholangiocarcinoma; gEndoscopic retrograde cholangiopancreatography; hPercutaneous transhepatic cholangiography.
follow-up duration between the two groups (ERFA + SEMS: 12.2 months ± 0.53, range, 6 - 19.5 months; SEMS only: 11.3 months ± 0.34, range, 7 - 16 months) (t-test, P = 0.078).
3.2. Treatment Efficiency and Complications
Thirty-day stent patency was obtained in all patients and the median stent patency in ERFA + SEMS group (9.5 months, range: 4.5 - 14.0 months) was significantly longer than that in the SEMS group (8.35 months, range: 4.9 - 11 months) (Mann-Whitney test, P = 0.024). During follow up, 4 patients in the ERFA + SEMS group received repeated ERFA, but only 2 patients completed the process proposed by Steel and co-workers, which required an ablation of 2 min at 10W [17] . The other two patients failed due to technical issues: a short-circuit produced in the primary stents during the early process, which led to the termination of the repeated ERFA. Four patients received a secondary SEMS placement within the primary stent successfully. Sixty-one patients received percutaneous biliary drainage when biliary obstruction relapsed during the followup. Twenty-three patients refused to have adjuvant therapy either due to costs or anxiety about adverse effects.
There was no treatment procedure-related mortality in the study subjects and no significant difference in treatment complications was observed between the two groups (Table 2). Twelve patients had moderate or severe post-procedure abdominal pain, which required oral or intravenous analgesics for relief of symptoms. Three patients developed cholangitis and one had pyogenic cholecystitis which required percutaneous transhepatic gallbladder drainage. All of these patients recovered fully after antibiotic treatment. Three patients were diagnosed with asymptomatic pancreatitis (serum amylase > 1000 IU/L) and recovered after conservative treatment.
3.3. Survival and Prognosis Analysis
Nine patients survived to the end of the follow-up period in November 2014. Of the patients who died, a detailed list of causes of death is summarized in Table 3. The major causes of death were disease progression (liver failure), bleeding, biliary infection, cachexia, and lung infection. The rates of occurrence of each of these showed no significant differences between the two both groups. None of the patients died from ERFA- or SEMS-related procedures.
Kaplan-Meier plots for ERFA + SEMS and SEMS groups associated with patient survival are shown in Figure 3. The log-rank test demonstrated that the overall survival in the ERFA + SEMS group (n = 34) was significantly longer than that in the SEMS group (n = 42) (P = 0.036), as shown in Figure 3(a). Further subgroup analysis excluded patients with metastatic disease (n = 7), or unfit (n = 2) or declined surgery (n = 2). The
Table 2. Complications after treatments.
aEndobiliary radiofrequency ablation; bSelf-expanding metal stent.
Table 3. Causes of death after treatment.
aEndobiliary radiofrequency ablation; bSelf-expanding metal stent.
log-rank test demonstrated that the overall survival for patients with local advanced extrahepatic CCA in the ERFA + SEMS group (n = 30) was significantly longer than in the SEMS group (n = 35) (P = 0.034), as shown in Figure 3(b). If patients with covered metal stents (n = 10) were excluded from the study, the overall survival in the ERFA + SEMS group was longer than in the SEMS group, but the difference was not significant (log-rank test, P = 0.084) as in Figure 3(c). Similarly, no significant differences were found between the two treatments with respect to unresectable Bismuth type I hilar CCA (log-rank test, P = 0.116) as in Figure 3(d); or unresectable distal CCA (log-rank test, P = 0.214) as in Figure 3(e).
Multivariate Cox proportional hazards regression analyses showed that ERFA, tumor AJCC stage, extrahepatic CCA type, serum albumin and adjuvant chemotherapy were prognostic factors for overall patient survival (Table 4).
4. Discussion
ERFA was first introduced by Steel and co-workers in 2011 as a palliative treatment modality for malignant obstructive jaundice [17] . Since then, several studies have reported the outcomes of ERFA in the treatment of malignant biliary obstruction [13] -[16] [18] [19] . In these studies, the safety of ERFA was confirmed. As in those cases, very few complications were here found to be associated with endobiliary RFA combined with SEMS, and no procedure-related mortality was observed. Cholangitis was observed in only one case and asymptomatic pancreatitis in 2 cases in the ERFA + SEMS group, but all of them fully recovered after conservative treatment. No bile duct perforation or vessel thrombus was observed. Since the introduction of the ERFA catheter in 2011, thermal injury to adjacent structures around the bile duct was a main concern [14] [17] . However, such concern seems to be unnecessary. Unlike traditional RFA electrodes for solid tumors, the bipolar Habib EndoHPB RFA catheter seems confined to ablation of small necrotic zones. Even in ex-vivo pig livers, this catheter could only ablate a semidiameter of 4.5 mm under energy output of 10 W in 60 - 90 s [13] . This may be much more confined in vivo when flow of blood of the adjacent structure serve as cooling stream which could take away much heat based in the experience in ablation of solid tumors [22] . RFA is in-situ ablative technique and tissue structure remains structurally intact immediately after RFA. Furthermore, SEMS placement leads to immediate decompression within the bile duct, which could prevent bile duct perforation. The vessel around the ablation could be preserved against thrombus formation by blood flow cooling.
We report that ERFA can prolong stent patency and was associated with an improved overall patient survival for unresectable extrahepatic CCA with biliary obstruction. The current study was stronger and more clinically significant than previous studies [13] -[16] [18] [19] . First, there was a larger sample size (n = 34 in the ERFA +
Table 4. Multivariate analysis of prognostic factors to predict overall survival after treatment.
aCholangiocarcinoma; bAmerican Joint Committee on Cancer; cEndoscopic retrograde cholangiopancreatography; dPercutaneous transhepatic cholangiography; eSelf-expanding metal stent.
SEMS group), representing the largest sample for this type of study to our knowledge. The follow-up period was longer than in previous studies. It was used to monitor the long-term outcomes, which showed the actual impact of RFA on both stent patency and overall survival to be lacking. For example, Steel et al. [17] performed endoscopic RF ablation in 6 unresectable CCA patients followed by SEMS placement. However, that study only included a 90-day follow-up regarding biliary patency. Second, stricter selection criteria were used. Here, only patients with unresectable Bismuth type I hilar or distal biliary adenocarcinoma were included. Patients with malignant biliary obstruction caused by other tumors or other Bismuth type of hilar CCAs were excluded, which reduced confounding bias when comparing overall survival rates. Furthermore, we focused on stent patency improvement and survival benefit of ERFA for patients who received SEMS. Patients who received plastic or nasobiliary drainage instead of SEMS shortly after ERFA were excluded which reduced bias when comparing the effectiveness of ERFA because SEMS itself was superior to plastic stent for malignant obstruction jaundice relief [7] [8] . A comprehensive analysis of overall survival was performed. This analysis indicated that when potential prognosis factors (e.g. metastatic disease, covered SEMS) were includedin overall survival analysis, the survival benefit of ERFA for unresectable extrahepatic CCA was confirmed.
Repeat ERFA using a bipolar catheter within the previous metal stent is not always feasible due to technical issues. Based on this study, the metal stent would prevent the bipolar RFA catheter from contacting and ablating the bile duct tumor when performing repeat ERFA [23] . Furthermore, direct contact with the bipolar RFA catheter with the uncovered metal stent could produce a short-circuit, making it impossible for a repeat endobiliary RFA.
In this study, multivariate Cox proportional hazards regression analysis indicated that ERFA, tumor AJCC stage, extrahepatic type, serum albumin and adjuvant chemotherapy were significant prognostic factors for overall patient survival. We attribute this benefit to the fact that ERFA can significantly prolong metal stent patency, which can improve patient comfort by relieving jaundice and chemotherapeutic toxicity both of which contribute to overall survival. As a prognostic factor, survival benefits for bile tract cancer with adjuvant chemotherapy, especially in combination with cisplatin and gemcitabine, is well documented [24] . It is understandable that patients with earlier AJCC extrahepatic CCA or normal serum albumin indicating better hepatic function, had better survival outcomes. We found that distal CCA ostensibly had better outcomes than Bismuth type I hilar CCA patients who received ERFA and/or SEMS but why this occurred is unclear. Nonetheless, even without statistical significance, patients treated with ERCP or those with covered SEMS had better outcomes than those who received the PTC approach (p = 0.112) and those with an uncovered SEMS (P = 0.091), respectively. The PTC approach was used for more advanced stage CCA patients with metastatic disease (6/7, 85.7%) than those patients treated with the ERCP approach, which may change outcomes. Covered SEMS coated with an organic polymer had longer stent patency than uncovered SEMS likely due to polymer-inhibited tumor ingrowth. Thus, SEMS may also be prognostic although no statistically significant results were observed likely due to the small sample size of patients with covered SEMS (10/76, 13.2%) were included in this analysis.
The present study has an important weakness: its retrospective nature. Additional clinical studies such as prospective randomized trials are needed to confirm this observation. It is still not possible to claim that endobiliary RFA + SEMS is superior to other methods. However, the present study is meant as a pilot study aiming to investigate the safety and the feasibility of endobiliary RFA.
5. Conclusion
Overall, ERFA is safe and effective and it may improve metal stent patency and patient overall survival for EH-CCA with biliary obstruction, and should therefore be incorporated into the treatment algorithm of any center treating patients with EH-CCA.
Disclosures
No conflict of interest.
Fund
This work was supported by Pearl River S&T Nova Program of Guangzhou (2011J2200004) and the grant of Sciences and Technology Committee of Guangdong Province (2011B031800072 and 2013B021800300), China.
NOTES
*Corresponding author.