Neoadjuvant chemotherapy followed by curative-intent surgery for perihilar cholangiocarcinoma based on its anatomical resectability classification and lymph node status

In the localized perihilar cholangiocarcinoma, negative tumor margin resection contributes to get an opportunity for long recurrence free survival. In the past two decades, advances in diagnostic and surgical techniques have improved surgical outcomes and survival rates [1]. However, the prognosis of the resected perihilar cholangiocarcinoma patients with lymph node (LN) metastasis has not been improved. Therefore, we should not only perform negative tumor margin resection, but also establish effective adjuvant and/or neoadjuvant therapy for the localized perihilar cholangiocarcinoma with LN metastasis.

The role of adjuvant chemotherapy (AC) for resected bile duct cancer (BTC) is controversial. Although 3 phase-III randomized trials have been explored in the adjuvant setting for BTC [2‐4], the positive effects of AC were not well defined.

In terms of neoadjuvant chemotherapy (NAC) for localized BTC, there are a few retrospective small reports [5‐7]. They considered that NAC followed by curative-intent surgery might offer downstaging for initially resectable BTC and conversion surgery for initially unresectable BTC, resulted in improving prognosis. Recently, using the large National Cancer Database data, a propensity score matched analysis using resected patients with cholangiocarcinoma indicated that patients who received NAC alone had a superior overall survival compared to those who received AC alone [8]. This study implied the benefit of NAC for selected patients with cholangiocarcinoma as well as other malignancies including pancreatic and breast cancer.

In the field of pancreatic ductal adenocarcinoma (PDAC), localized tumors are anatomically classified as resectable (R), borderline resectable (BR), or locally advanced (LA) based on the likelihood of a positive margin resection. Neoadjuvant chemo and/or radiotherapy is introduced PDAC patients based on its classification. In our institution, neoadjuvant gemcitabine based chemoradiotherapy for advanced PDAC based on its resectability has been introduced since 2005 and its prognosis has been improved [9]. Therefore, we originally established the anatomical resectability classification for localized perihilar cholangiocarcinoma according to surgical points of view from biliary and vascular extension as well as PDAC. As extrahepatic bile duct cancer partly shares embryological, clinical and pathological features with PDAC [10], this favorable effect of gemcitabine prompted to conduct NAC using gemcitabine plus S-1 in patients with perihilar cholangiocarcinoma.

This study aimed to evaluate the feasibility of anatomical resectability classification and the efficacy of NAC followed by curative-intent surgery based on its classification and LN status.

Between September 2010 and August 2018, 72 consecutive patients with localized perihilar cholangiocarcinoma, who were all eligible patients identified by us, had been enrolled for our institutional treatment protocol based on our established resectability classification from surgical points of view. The diagnosis of perihilar cholangiocarcinoma was confirmed by means of cytological analysis of bile juice or histological analysis of biopsy specimens obtained using endoscopic retrograde cholangiography (ERC). Patients were excluded when they showed evident distant metastatic lesions at the time of enrollment. On the basis of our resectability classification mentioned below, the 72 patients were classified into the three groups: R (n = 29), BR (n = 23), and LA (n = 20). Of them, 43 were men and 29 were women, with an average age of 71 years (range 44–87 years).

The clinical and follow-up information was extracted from a prospectively maintained database at the department of hepatobiliary pancreatic and transplant surgery, Mie university hospital, and verified by reviewing patient medical records. The day of final follow-up was March 31, 2019.

In the present study, we proposed anatomical resectability classification for patients with localized perihilar cholangiocarcinoma according to surgical points of view from biliary and vascular factors, and the enrolled 72 patients had been classified into the three groups: R (n = 29), BR (n = 23), and LA (n = 20), respectively. Based on this classification and LN status, NAC using 2 cycles GS followed by curative-intent surgery was administered for the 47 patients, and its completion rate was 91.4% (43/47), which was feasible and tolerable. The resection rate was similar between R (89.7%) and BR (73.9%), but much lower in LA (30%). The 5-year DSS was stratified according to the resectability classification: 50.3% in R, 30.0% in BR, and 16.5% in LA, respectively. The patients with resection had significantly better prognosis compared to those without resection (5-year DSS: 43.8% vs. 5.9%). Interestingly, the patients’ survival did not differ among the three groups when resected. Among the 49 patients with resection, preoperative high CEA levels (more than 8.5 ng/ml) and pT4 were identified as independent poor prognosis factors, and the patients with resection showing high CEA levels or pT4 had very poor prognosis, being comparable to the patients without resection.

Patients’ prognosis with perihilar cholangiocarcinoma depends on complete tumor resection, that is, R0 resection. In the absence of widespread disease, the likelihood of achieving R0 resection requires examination of all factors related to local tumor extent. In 1975, Bismuth et al. [20] reported 4 types of biliary stricture based on intraoperative cholangiography [21, 22], which depended on tumor location and extent within the biliary tree. To determine the likelihood of achieving R0 resection, in other words, to predict tumor resectability, additional factors such as vascular involvement and consequent hepatic lobar atrophy should be addressed. In 1998, Blumgart et al. proposed a preoperative staging system to predict unresectability that accounts for local tumor factors including biliary and portal venous involvement, and lobular atrophy [23], and subsequently they reported that this criteria accurately predicted resectability and correlated with survival [24]. Blumgart criteria for unresectablility of perihilar cholangiocarcinoma was based on patients’ factors, local factors, and distant disease. The local factors were defined by the following five factors: 1) hepatic duct involvement up to secondary radicles bilaterally, 2) encasement or occlusion of the main portal vein proximal to its bifurcation, 3) atrophy of one liver lobe with encasement of contralateral portal vein branch, and 4) atrophy of one liver lobe with contralateral secondary biliary radicle involvement. This criteria, however, did not include arterial involvement because of insufficient accuracy of imaging diagnosis at the time of their writing.

With recent advancement in imaging studies such as thin slice dynamic MDCT, we are able to evaluate tumor involvement precisely including artery invasion. In the most recent 8th UICC staging system (2017), arterial involvement is incorporated into T4 stage: tumor invades the main PV or its branches bilaterally or the common hepatic artery; or unilateral second order biliary radicles with contralateral PV or HA involvement. Recently, the development of surgical techniques has enabled us to perform technically demanding procedures including trisectionectomy, and combined PV and/or HA resection. Therefore, using these technically demanding procedures, the tumors determined as unresectable according to Blumgard criteria, Bismuth IV, or UICC T4 stage are not always unresectable, and actually some of them can undergo negative margin resection.

In terms of survey of distant metastasis, preoperative MRI to evaluate intrahepatic metastases or peritoneal dissemination was not performed routinely. Of 54 laparotomy cases in this study (Fig. 3), 4 cases (7.4%) had intrahepatic small metastases and 3 cases (5.5%) had peritoneal dissemination. Several papers reported the usefulness of Gadolinium ethoxybenzyl diethylenetriamine pentaacetic acid-enhanced MR imaging (EOB-MR imaging) compared with MDCT in detecting liver metastasis from colorectal and pancreatic cancers [25, 26]. It was considered that preoperative EOB-MR imaging was useful in detecting small liver metastases.

Regarding the operative procedure for patients of Bismuth type I or II, although limited hilar bile duct resection without major hepatectomy is occasionally underwent, our institution usually employs right hepatectomy with caudate lobectomy, based on previous studies. Ikeyama et al. reported retrospective study using 31 consecutive patients who underwent resection of these types of tumors [27]. R0 resection and survival rates of patients who underwent right hepatectomy with caudate lobectomy (n = 18) were significantly better than those of patients who underwent other types of resection (n = 13). In that study, most patients did not have invasion of the right hepatic artery, but the distance between the leading edge of the cancer and the outer layer of the hepatic artery was 1 mm in many patients. The authors suggested that the resected margin would have been cancer positive without combined resection of the right hepatic artery. Therefore, they recommend right hepatectomy even when invasion of the right hepatic artery cannot be demonstrated preoperatively by diagnostic imaging. Additionally, 2 small studies also reported that outcomes of limited resection except for those of right hepatectomy with caudate lobectomy were unsatisfactory due to low curative resection rate and survival rate [28, 29]. Further evaluation with larger sample sizes is required to justify right hepatectomy with caudate lobectomy for patients with Bismuth type I or II perihilar cholangiocarcinoma.

In the fields of localized PDAC, the National Comprehensive Cancer Network (NCCN) guidelines for Pancreatic Adenocarcinoma in Version 3. 2019 clearly defines the resectability criteria (R, BR and LA) based on a likelihood of a positive margin resection. The definition of BR-PDAC is a tumor that is at high risk for positive margin resection when surgery is used as an initial treatment. LA-PDAC is defined a tumor not to achieve R0 resection and not to indicate up-front surgery [30]. In the fields of localized perihilar cholangiocarcinoma, however, there is no resectability criteria internationally agreed. Blumgard et al. defined LA (unresectable) perihilar cholangiocarcinoma as mentioned previously. In terms of definition of BR perihilar cholangiocarcinoma, in 2011, Chi et al. firstly reported the anatomical definition of BR perihilar cholangiocarcinoma based on biliary extension alone [31]. They defined that BR perihilar cholangiocarcinoma had a chance of curative resection but an unclear longitudinal tumor extent. In 2017, Matsuyama et al. secondly reported that patients with both regional LN metastasis and vascular invasion were oncologically defined as BR because such patients had dismal outcome [32]. Our new resectability classification is based on PV, HA and biliary involvements according to surgical points of view, and consists of the three categories (R, BR, and LA). This resectability classification is based on the likelihood of an R0 resection.

The role of AC for resected BTC is controversial. Recently, 3 phase-III randomized trials have been explored in the adjuvant setting for BTC [2‐4], but a definitive survival advantage has been difficult to prove. However, based on these 3 phase-III randomized trials and 16 retrospective studies, ASCO clinical practice guideline in 2019 presents that patients with resected BTC should be offered adjuvant capecitabine chemotherapy for a duration of 6 months. In contrast, the role of NAC for localized BTC has been explored in several small clinical studies. Jung et al. retrospectively reviewed 57 patients who underwent resection for locally advanced perihilar cholangiocarcinoma, whose definition is compatible to BR or LA according to our resectability classification, and compared the MST between 12 patients with neoadjuvant chemoradiotherapy and 45 without it, showing no significant differences between the two groups (32.9 vs. 27.1 months) [5]. The other retrospective study reviewed 21 patients undergoing down-sizing chemotherapy for locally advanced BTC (ICC in 7, GBC in 6, and ECC in 8), and compared the MST between 8 patients with resection and 13 without resection, showing significant differences between the two groups (19.3 vs. 7.5 months) [7]. However, all of previous studies were retrospective small cohort and lack of a comparable control group, which not allow for a meaningful evaluation of the effects of NAC on prognosis. The reasons for difficulty in establishing valuable effects of NAC are considered that BTC includes cancer of the intrahepatic bile ducts, perihilar and distal cholangiocarcinoma, and the gallbladder, which have different biological characteristics and different effectiveness of chemotherapy. Therefore, a separate study is required for individual type of BTC. Although small number patients with BTC were treated in individual facilities, large-scale clinical studies should be conducted for obtaining the appropriate evidence. In the absence of definitive evidence of NAC for localized BTC, using the large National Cancer Database data, a propensity score matched analysis using resected patients with cholangiocarcinoma indicated that selected 278 patients who received NAC alone had a superior overall survival compared to selected 700 patients who received AC alone (MST: 40.3 vs. 32.8 months) [8]. They implied the benefit of NAC for selected patients with cholangiocarcinoma. However, this study has the problem that about 70% study cohort includes ICC. This is because ICC and ECC in oncologically difference.

It is unclear which patient is most likely to benefit from NAC for perihilar cholangiocarcinoma. Nagino et al. [1] evaluated prognosis factors in the patients who underwent curative-intent surgery for perihilar cholangiocarcinoma and concluded that LN metastasis had the strongest impact on survival among independent prognosis factors such as combined vascular resection and reconstruction. They indicated that the control of LN metastasis was very difficult by surgical treatment alone and that establishment of effective AC was urgently needed. The other study reported that patients with both regional LN metastasis and vascular invasion were candidate for initiating NAC to obtain better outcomes [32]. Therefore, our present study enrolled the patients with clinically obvious LN metastasis, BR, and LA for NAC using GS therapy followed by curative-intent surgery. To the best of our knowledge, our study is the first prospective single arm trial to evaluate NAC for localized perihilar cholangiocarcinoma based on its resectability classification and LN status. As a result, we could demonstrate that curative-intent surgery was an important factor for achieving a good prognosis for perihilar cholangiocarcinoma, even if LA patients. However, multivariate analysis for prognosis factor in the patients with resection identified preoperative high CEA levels (8.5 or more ng/ml) and pT4 as the independent poor prognostic factors. Especially, the patients with resection showing preoperative high CEA levels had very poor prognosis, being comparable to the patients without resection. In these patients, indication of curative-intent surgery should be carefully performed by prolonging preoperative therapy as a watch and wait approach. Additionally, our recent study demonstrated that high tumor budding (TB) can be a novel poor prognostic factor in resected perihilar cholangiocarcinoma regardless of neoadjuvant therapy [33] as well as various type of cancers such as esophageal [34] and pancreas [35]. However, the TB cannot be evaluated before surgery. Therefore, there is an urgent need to identify preoperative predictors of high TB. It is future issue to develop more effective NAC regimen with or without radiotherapy and increase rate of curative-intent surgery in BR and LA patients.

According to the factor analysis for unresectability in 20 LA patients (Tables 6 and 7), 6 patients with resection had either one of the vascular or biliary factor, while none of the 4 patients with both vascular and biliary factors could not undergo resection. LA patients with both biliary and vascular factors are not for the candidate of conversion surgery after neoadjuvant GS therapy.

There are several limitations in this study. Study cohort was small and data were collected from a single Japanese center. To evaluate the efficacy of resectability classification and NAC for localized perihilar cholangiocarcinoma patients, prospective randomized multicenter trials are needed.

NAC based on our resectability classification for patients with localized perihilar cholangiocarcinoma according to surgical points of view from biliary and vascular factors and LN status was feasible and tolerable. NAC enabled the downstaging / downsizing of BR patients and conversion surgery in selected LA patients resulted in improving prognosis.