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General surgery
Original paper

Bilateral versus unilateral radioactive stent insertion for hilar cholangiocarcinoma

Yuchao Zhang
1
,
Ping Wang
1
,
Gang Xu
1
,
Maozhen Chen
1

1.
Department of Vascular Surgery, The Affiliated Huaian No. 1 People’s Hospital of Nanjing Medical University, Huaian City, China
Videosurgery Miniinv 2022; 17 (4): 672–679
Online publish date: 2022/08/15
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Introduction

Hilar cholangiocarcinoma (HC) is a prevalent malignant tumor involving the hepato-biliary system [13]. Unfortunately, HC is asymptomatic in the early stages. Therefore, it is mostly diagnosed at a late stage of disease, when the opportunity for surgical resection is lost [4]. Moreover, HC patients typically cannot tolerate chemo- or radiotherapy, due to jaundice, which occurs in the late stage of disease [5]. Given these challenges, stent insertion is the first-line treatment for late stage inoperable HC [5].

However, the stent does not treat the tumor, and, in about 50% of cases, stent re-obstruction occurs, due to tumor growth or biliary epithelial cell proliferation [6]. To reduce the stent re-obstruction rate, many anticancer treatments, including chemotherapy (ChT), photodynamic therapy (PdT), and endobiliary radiofrequency ablation (ERA), are typically used after relieving jaundice [79]. In recent years, many researchers have used a radioactive stent technique to treat HC [1012]. A radioactive stent contains a normal metal stent that is attached to I-125 seeds [1012]. Compared to ChT, PdT, and ERA, the major advantage of the radioactive stent is its persistent brachytherapeutic effect [1012].

Another controversy in treating HC patients is determining whether to use unilateral and bilateral stenting [5]. Although multiple studies have assessed the clinical efficacy of unilateral or bilateral stenting, these assessments were primarily done on the normal metal stent, but not on the recently developed radioactive stent [1315]. Therefore, general knowledge on unilateral and bilateral radioactive stent insertion (RSI) efficacy is still lacking.

Aim

Our goal in this study was to compare the clinical efficacy and long-term prognoses of unilateral and bilateral RSI in the treatment of HC patients.

Material and methods

Study design

This study was based on a retrospective design, and it received ethical approval from our hospital. Owing to our retrospective design, documented informed consent was not necessary for our study.

Between January 2016 and December 2020, all HC patients who received unilateral or bilateral RSI at our hospital were selected for this study. Between January 2016 and December 2018, we employed the unilateral RSI technique. From January 2019 onwards, we employed the bilateral RSI technique.

The inclusion criteria were as follows: (a) HC patients; (b) inoperable cases; (c) patients with obstructive jaundice; and (d) Eastern Cooperative Oncology Group performance status (ECOG PS) of 0-2. The exclusion criteria were as follows: (a) patients who had previously undergone hepatectomy; (b) Bismuth type I patients; and (c) life expectancy < 3 months.

Diagnosis

HC was initially diagnosed via abdominal computed tomography (CT) and magnetic resonance imaging (MRI). The Bismuth types were diagnosed via abdominal CT and MRI. The pathological diagnosis of HC was made via intraductal biopsy.

Radioactive stent

A radioactive stent was combined with a normal metal stent (Micro-Tech, Nanjing, China) and an I-125 seed strand. Each I-125 seed strand was designed by sealing I-125 seeds (Chinese Atomic Energy Science Institution, Beijing, China) onto a 4F catheter (PBN MEDICALS Denmark A/S, Stenlose, Denmark). Each I-125 seed (4.5 mm long, 0.8 mm in diameter) released low-energy 35.5-keV γ-rays, carrying a half-life of 59.6 days. The number of required I-125 seeds in each strand was decided according to the obstruction length: N = length of stent (mm)/4.5 + 4 [10].

Unilateral RSI

The radioactive stent was inserted via the percutaneous trans-hepatic approach. In short, the intrahepatic bile duct was penetrated with a 22-G needle under fluoroscopic and ultrasonic intelligence. Next, a 4F single-curved catheter, with a 0.035-inch loach guide wire, was used to detect the obstruction. The length of the obstruction was measured via cholangiography. Once the catheter and guide wire crossed the obstruction, they were guided into the duodenum, and the loach guide wire was replaced with a 0.035-inch stiff guide wire. Next, a 6F sheath was sent across the obstruction via another guide wire. The stent was deployed at the center of the obstruction using a 0.035-inch stiff guide wire. Subsequently, the I-125 seed strand was placed inside the 6F sheath, and the 6F sheath was removed carefully so that the I-125 seed strand was deposited between the biliary wall and the stent (Photo 1 A).

Photo 1

Images for unilateral (arrows) (A) and bilateral (arrows) (B) radioactive stent insertion for HC patients

/f/fulltexts/WIITM/47648/WIITM-17-47648-g002_min.jpg

Bilateral RSI

The bilateral RSI was performed via the left and right intrahepatic bile duct approach, and the stents were placed employing the side-by-side technique (Photo 1 B).

Follow-up and definitions

After surgery, all patients were followed up at 1 week; 1, 3, and 6 months; and once every 6 months after that. During these follow-ups, patients underwent abdominal CT, a liver function test, and body examination. The follow-ups lasted either until patients’ death or until 31 December 2021.

Technical success was described as the successful recanalization of the biliary obstruction, with good contrast passage via the stent and into the duodenum [10, 11]. Functional success was described as 20% lowering of the serum total bilirubin (TB) at < 1 week after surgery [16]. Stent patency was defined as the duration between the stent deployment and the first recurrence of jaundice, the most recent follow-up, or death in the absence of jaundice [10, 11]. Overall survival (OS) was defined as the duration between the stent deployment and death [10, 11]. Early complication was defined as a complication occurring within 30 days of stent placement [16].

Statistical analysis

Inter-group continuous variables were analyzed via the Mann-Whitney U test, and the data before and after stent placement were compared via the paired t-test. Categorical data are presented as number and percentage (%), and were analyzed using the χ2 or Fisher’s exact test. The intergroup stent patency and OS were analyzed via Kaplan-Meier curves with the log-rank test. Uni- and multivariate Cox regression analyses were employed to examine the associations between predictors and OS. P < 0.05 was considered significant. All analyses were carried out with the SPSS v16.0 software (SPSS, Inc., Chicago, Illinois, USA).

Results

Patients

Overall, 65 HC patients, who underwent unilateral (n = 33) or bilateral (n = 32) RSI at our hospital, were selected for analysis (Table I). The baseline data were comparable between the two groups. Moreover, a total of 14 and 12 patients underwent ChT after unilateral and bilateral RSI, respectively (p = 0.685).

Table I

Patient characteristics in the 2 groups

ParameterUnilateral groupBilateral groupP-value
Number of patients3332
Age [years]65.563.20.247
Gender (male/female)17/1617/150.897
Tumor stage (II/III/IV)13/11/910/11/110.750
Bismuth type (II/III/IV)12/14/717/10/50.397
Obstruction length [mm]40.237.30.163
ECOG PS (0/1/2)16/11/617/11/40.813
TB [μmol/l]:
 Before230.1181.30.084
 After98.181.00.242
Ca19-9 (≤/> 37 U/l)1/322/300.978

[i] ECOG PS – Eastern Cooperative Oncology Group performance status, TB – total bilirubin.

Treatment effect

The technical success rate was 100% in both groups. No intra-operative complications occurred. The diameter of all stents was 8 mm, and the length of all stents ranged between 50 and 70 mm. A total of 452 (mean 13.7 per patient) and 786 (mean 24.6 per patient) I-125 seeds were utilized in the unilateral and bilateral groups, respectively. The functional success rates were 97.0% (32/33) and 90.6% (29/32) after unilateral and bilateral RSI, respectively, and there was no significant difference between the two groups (p = 0.584). In the unilateral group, the average TB decreased from the preoperative value of 230.1 μmol/l to the postoperative value of 98.1 μmol/l (p < 0.001). In the bilateral group, the average TB decreased from the preoperative value of 181.3 μmol/l to the postoperative value of 81.0 μmol/l (p < 0.001).

Follow-up

No patients were lost to follow-up. Stent re-obstruction was observed in 6 (18.2%) and 9 (28.1%) patients after unilateral and bilateral RSI, respectively (p = 0.341, Table II). All stent re-obstructions were caused by tumor invasion. The median stent patency periods were 214 and 233 days following unilateral and bilateral RSI, respectively (Figure 1 A), and there was no significant difference between the two groups (p = 0.650). In the unilateral group, 6 re-obstruction patients underwent percutaneous transhepatic cholangial drainage (PTCD) (n = 5) or deployment of a second metal stent (n = 1). In the bilateral group, all 9 re-obstruction patients underwent PTCD.

Table II

Post-operative complications and re-obstruction

ParameterUnilateral groupBilateral groupP-value
Total complications4110.033
Cholangitis39
Cholecystitis12
Early/late complications2/28/30.930
Re-obstruction690.341
Figure 1

Comparison of stent patency duration (A) and OS (B) between the 2 groups

/f/fulltexts/WIITM/47648/WIITM-17-47648-g001_min.jpg

All patients expired during follow-up. The median OS periods were 240 and 281 days after the unilateral and bilateral RSI, respectively (Figure 1 B), and there was no significant difference between the two groups (p = 0.068). Our univariate Cox regression analysis revealed that the Bismuth type III HC (p = 0.035) was correlated with reduced OS, while the post-operative ChT (p = 0.012) and bilateral RSI (p = 0.076) were correlated with prolonged OS. We next entered the above significant variables into the multivariate model. We found that the Bismuth type III HC (p = 0.035) was associated with shorter OS, while the post-operative ChT (p = 0.033) was associated with longer OS (Table III).

Table III

Predictors of overall survival

ParameterUnivariate analysisMultivariate analysis
Hazard ratio95% CIP-valueHazard ratio95% CIP-value
Age0.9950.964–1.0260.995
Gender:
 Male1
 Female1.3820.833–2.2930.211
Tumor stage:
 II1
 III0.6950.378–1.2760.695
 IV1.2370.671–2.2790.496
Obstruction length1.0580.806–1.3900.685
ECOG PS1.1630.846–1.5990.352
Bismuth type:
 II11
 III2.5471.422–4.5620.0351.9321.047–3.5640.035
 IV0.9240.459–1.8590.8240.8080.397–1.6440.556
TB before1.0000.997–1.0020.921
TB after1.0040.998–1.0090.192
Ca19-9:
 ≤ 37 U/l1
 > 37 U/l0.9880.566–1.7230.965
Post-operative chemotherapy:
 No1
 Yes0.5200.312–0.8670.0120.5530.320–0.9950.033
Types of stent:
 Unilateral11
 Bilateral0.6320.381–1.0490.0760.6370.376–1.0180.095

[i] ECOG PS – Eastern Cooperative Oncology Group performance status, TB – total bilirubin.

Post-operative complications

The total complication rate was significantly lower among the unilateral RSI-treated patients versus the bilateral RSI-treated patients (12.1% vs. 34.4%, p = 0.033, Table II). In the unilateral RSI-treated patients, cholangitis and cholecystitis were detected in 3 and 1 patients, respectively. In the bilateral RSI-treated patients, cholangitis and cholecystitis were detected in 9 and 2 patients, respectively. Moreover, 2 and 8 patients in the unilateral RSI- and bilateral RSI-treated patients experienced early complications.

Subgroup analyses

We also performed subgroup analyses, based on the different tumor stages and Bismuth types (Table IV). Patient stratification by tumor stages showed no significant differences in stent patency duration. A significantly longer OS period was observed in the bilateral RSI-treated patients only, depending on tumor stage III (p = 0.037). Patient stratification by Bismuth types also showed no significant differences in stent patency or the OS period.

Table IV

Subgroup analyses of patency and OS

ParameterUnilateral groupBilateral groupP-value
Tumor stage II:
 Patency (d)2172300.912
 OS (d)2532530.824
Tumor stage III:
 Patency (d)2112220.935
 OS (d)2343300.037
Tumor stage IV:
 Patency (d)2122440.449
 OS (d)2272570.435
Bismuth type II:
 Patency (d)2282420.678
 OS (d)2653060.106
Bismuth type III:
 Patency (d)1872090.400
 OS (d)2072090.946
Bismuth type IV:
 Patency (d)2422450.685
 OS (d)2613400.298

[i] OS – overall survival.

Discussion

Herein, we evaluated the clinical efficacy and long-term prognoses of unilateral and bilateral RSI in treating HC patients. Compared to previous studies involving RSI insertion for malignant hilar obstruction [10, 11], the advantage of this study was that we only included HC patients. Our results were also quite positive. Based on our analyses, both procedures exhibited high technical and functional success rates. Therefore, both procedures can be effectively used to relieve jaundice in HC patients.

The observed high technical success rates (both 100%) in our study may be attributed to the percutaneous trans-hepatic stenting approach. At present, endoscopic biliary stent insertion is still employed in patients with malignant obstructive jaundice [17, 18]. The main advantages of the endoscopic approach are the physiological drainage of the biliary tract into the intestine and the avoidance of liver puncture. However, endoscopic biliary stenting was usually used for patients with distal biliary or Bismuth type I/II hilar obstruction [1721]. In Bismuth type III and IV HC, the obstruction pattern is more complex because it is tighter, longer, and more tortuous, and it involves more liver segments. Endoscopic biliary stenting is not suitable for Bismuth type III and IV HC because the endoscopic approach has only one retrograde direction and manipulation of devices is more difficult through the long channel [21]. Percutaneous trans-hepatic stenting is used over endoscopic biliary stenting in advanced HC because the precise lobe can be selected for drainage [21]. In the case of HC patients, the percutaneous stenting approach achieves both higher technical (100% vs. 72.4%) and functional (92.7% vs. 77.3%) success rates, as compared to the endoscopic stenting approach [20, 21]. Therefore, percutaneous stenting is the obvious rescue procedure after a failed endoscopic stenting attempt [20].

In this study, bilateral RSI did not show any superiority in terms of the functional success over unilateral RSI. In fact, it was previously demonstrated that unilateral RSI also effectively relieves jaundice in HC patients by draining more than 25% of the liver bile, thereby achieving functional success [22].

A recent meta-analysis also demonstrated that the side-by-side stent technique achieves a significantly reduced stent re-obstruction rate, compared to the unilateral stent insertion technique [14]. However, our analysis did not detect any marked differences in stent re-obstruction rates or stent patency duration. These results may be attributed to the fact that we employed the radioactive stent, which can also inhibit tumor growth [6]. Our re-obstruction rate (18.2%) after unilateral RSI was lower, compared to the 26.0% in the previous meta-analysis that employed normal unilateral stent insertion to treat HC patients [14]. Nevertheless, the dose of each I-125 seed strand was not calculated by the treatment plan system (TPS) because TPS may not be suitable for luminal cancers [23]. Furthermore, the main purpose of RSI is to decrease the re-obstruction rate and prolong the stent patency duration [10, 11]. We did not expect that RSI usage would cure HC. Therefore, we calculated the number of I-125 seeds in each strand using the formula: N = length of stent (mm)/4.5 + 4 [10].

The OS duration was also comparable between the unilateral and bilateral RSI patient populations. This result may be attributed to the comparable stent patency duration between the two groups. While bilateral RSI resulted in the insertion of two I-125 seed strands, such brachytherapy only inhibited regional tumor growth. However, in patients with stage III and IV tumors, such brachytherapy is unable to influence distant or lymph node metastases [24]. Furthermore, we observed that the post-operative ChT was associated with longer OS. This corroborated some previous studies involving stent insertion in HC patients [11, 25]. In such cases, post-operative ChT was shown to play an essential role in treating distant or lymph node metastases. However, in this study, the post-operative ChT was performed based on patient consent and condition; therefore, the effectiveness of the post-operative ChT should be further confirmed by prospective clinical trials.

The total complication rate was significantly reduced in our unilateral RSI patient population. It is possible that, with the use of side-by-side stenting, the placement of two stents into the common biliary tract may promote a rise in the biliary wall compressive stress. This, in turn, can potentially increase the risk of cholangitis [14, 26].

Furthermore, we conducted subgroup analyses, based on distinct tumor stages and Bismuth types. Our results revealed that bilateral RSI significantly prolonged OS duration in patients with stage III tumors. However, this result may not be very reliable since we did not compare the baseline data among stage III tumor patients. Additionally, our subgroup analyses were performed based on a subset of patients with limited sample size.

At present, transarterial radio-embolization (TARE) using yttrium-90 (Y90) is widely employed in treating inoperable intra-hepatic cholangiocarcinoma [27]. Compared to transarterial chemoembolization, TARE provides similar good outcomes with significantly reduced adverse event rates in patients with intra-hepatic cholangiocarcinoma [27]. However, TARE is usually used for mass-like intra-hepatic cholangiocarcinoma. In this study, the HCs were presented as the luminal cancer and TARE was not suitable.

Our research has certain limitations. First, the major limitation was the retrospective nature of the study. Second, the analyzed groups of patients were from different time intervals. Nevertheless, the unique cancer type and comparable baseline data may reduce the risk of bias. Third, the number of I-125 seeds was decided by the length of obstruction, without any treatment planning dedicated to the luminal organs. Under this condition, the radioactive dosimetry may not be able to accurately assess each patient. Fourth, the post-operative ChT was conducted based on patient consent and condition. This may also have introduced selection bias. Nevertheless, the comparable ratio of patients with post-operative ChT between the two groups may have potentially reduced the risk of bias.

Conclusions

Our results revealed that unilateral and bilateral RSI can provide comparable clinical efficacy and long-term prognoses when treating HC patients. However, unilateral RSI is associated with a markedly lower complication rate.

Conflict of interest

The authors declare no conflict of interest.

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