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BMC Cancer logoLink to BMC Cancer
. 2013 Sep 22;13:428. doi: 10.1186/1471-2407-13-428

Intestinal-type of differentiation predicts favourable overall survival: confirmatory clinicopathological analysis of 198 periampullary adenocarcinomas of pancreatic, biliary, ampullary and duodenal origin

Peter Bronsert 1, Ilona Kohler 1, Martin Werner 1, Frank Makowiec 2, Simon Kuesters 2, Jens Hoeppner 2, Ulrich Theodor Hopt 2, Tobias Keck 2,3, Dirk Bausch 2,3, Ulrich Friedrich Wellner 2,3,
PMCID: PMC3849372  PMID: 24053229

Abstract

Background

Periampullary adenocarcinomas comprise pancreatic, distal bile duct, ampullary and duodenal adenocarcinoma. The epithelia of these anatomical structures share a common embryologic origin from the foregut. With steadily increasing numbers of pancreatoduodenectomies over the last decades, pathologists, surgeons and oncologists are more often confronted with the diagnosis of “other than pancreatic” periampullary cancers. The intestinal subtype of ampullary cancer has been shown to correlate with better prognosis.

Methods

Histological subtype and immunohistochemical staining pattern for CK7, CK20 and CDX2 were assessed for n = 198 cases of pancreatic ductal, distal bile duct, ampullary and duodenal adenocarcinoma with clinical follow-up. Routine pathological parameters were included in survival analysis performed with SPSS 20.

Results

In univariate analysis, intestinal subtype was associated with better survival in ampullary, pancreatic ductal and duodenal adenocarcinoma. The intestinal type of pancreatic ductal adenocarcinoma was not associated with intraductal papillary mucinous neoplasm and could not be reliably diagnosed by immunohistochemical staining pattern alone. Intestinal differentiation and lymph node ratio, but not tumor location were independent predictors of survival when all significant predictor variables from univariate analysis (grade, TNM stage, presence of precursor lesions, surgical margin status, perineural, vascular and lymphatic vessel invasion, CK7 and CDX2 staining pattern) were included in a Cox proportional hazards model.

Conclusions

Intestinal type differentiation and lymph node ratio but not tumor location are independent prognostic factors in pooled analysis of periampullary adenocarcinomas. We conclude that differentiation is more important than tumor location for prognostic stratification in periampullary adenocarcinomas.

Background

The present WHO classification of tumors distinguishes between pancreatic ductal (PDAC), extrahepatic (distal) bile duct (DBDAC), ampullary (AMPAC) and small intestinal (including duodenal, DUOAC) adenocarcinoma [1]. A fundamental observation is that survival after resection of adenocarcinoma of periampullary location (pancreatic head, distal bile duct, ampulla, duodenum) differs greatly, with DUOAC and AMPAC displaying a much better survival than pancreatic head PDAC or DBDAC, implying several issues of continued debate [2-4].

First, due to the anatomical complexity of the periampullary region, correct classification with respect to location remains challenging to the pathologist. Usually the origin of a periampullary tumor is defined macroscopically by location of the main tumor mass or eventual precursor lesions and has to be confirmed microscopically [2-4]. There is still considerable debate on how localization of adenocarcinomas and their precursor lesions arising in this region should be assessed [2,5].

Another aspect is the question of the biological basis of the observed differences in survival. A major step was the recognition of the intestinal (INT) versus pancreatobiliary (PB) histopathologic phenotypes of AMPAC by Kimura et al. in 2004 [6]. The INT type proved to be associated with considerably better prognosis than the PB subtype, which has been confirmed by several recent series [3,4,7].

Our study aimed at a detailed analysis of clinical, pathological and immunohistochemical parameters for assessment of tumor biology and identification of prognostic factors after resection of periampullary adenocarcinomas of all four locations.

Methods

Patients and data

For the purpose of this study, periampullary adenocarcinomas were defined as pancreatic head PDAC, DBDAC, AMPAC or DUOAC. Only cases with resection by pancreatoduodenectomy, including conversion to total pancreatectomy due to positive intraoperative pancreatic resection margin were included. Thereby cases of the following WHO tumors [1] were excluded: PDAC not located in the pancreatic head, solid-pseudopapillary, acinar and neuroendocrine neoplasms, benign lesions, pancreatoblastoma, teratoma, mesenchymal tumors, lymphoma and secondary tumors. Patients operated at the Clinic for General and Visceral Surgery, University of Freiburg from 2001 to 2011 were identified and baseline and follow-up data extracted from a prospectively maintained database. All histopathological workup was performed at the Insitute of Pathology, University of Freiburg. Archived hematoxylin & eosin (H&E) stained slides were reevaluated by two experienced pathologists (PB, IK) for accuracy of diagnosis and formalin-fixed and paraffin-embedded tissue (FFPE) blocks were selected for generation of serial tissue slices for immunohistochemistry (IHC). All cases with sufficient available FFPE for IHC were included in the study. The study protocol was approved by the Ethics Committee of the University of Freiburg (Ref 13/11).

Standard pathological assessment

During the study period (2001–2011), a standardized protocol was followed for diagnostic workup of pancreatoduodenectomy specimens: First, resection margins including the closest margin to the tumor and retroperitoneum towards portal vein and superior mesenteric artery were marked intraoperatively by the surgeon. After intraoperative transfer to the institute of pathology, every specimen was examined macroscopically by an experienced pathologist. Identifiable tumor masses or suspect areas were measured in three dimensions. Localization, size and distance of the tumor to the resection margins were documented and lymph node stations were separately evaluated. After formalin fixation and paraffin embedding, tissue slices of 3 μm thickness were H&E stained. The following routine work up was equal in procedure for pylorus preserving pancreatoduodenectomy and the classical Whipple procedure. The number of routine tissue blocks and corresponding tissue slices was at minimum 10 (range 10 to 17). The standardized protocol comprised at least two samples for the enteral (oral and aboral) resection margins, and one sample for each of the following locations: whole circumferential parenchymal pancreas resection margin, tumor in relation to the closest posterior (retroperitoneum and vascular groove) resection margin, resection margin at the common bile duct, tumor in relation to the common bile duct and the main duct of the pancreas, tumor in relation to the duodenum, Papilla vateri. At minimum twelve regional lymph nodes were embedded in at least two routine tissue blocks. In case of portal venous en-bloc resections, one additional tissue sample in relation to the tumor was embedded. Additional tissue biopsies were embedded upon request of the operating surgeon. This standardized protocol was modified for total pancreatectomy as follows. The number of routine tissue blocks and corresponding tissue slices was minimal 11 (range 11 to 19). The resection margin of the splenic artery and vein and one sample of the spleen were embedded additionally, while the whole circumferential parenchymal pancreas resection margin was not embedded.

Histopathological reports included diagnosis according to WHO classification, UICC stage, presence or absence of lymphatic, vascular and perineural invasion and assessment of oral, aboral, biliary and posterior (retroperitoneal and vascular groove) resection margin. Additional immunohistochemistry for pancytokeratin was performed when it was felt necessary in difficult cases.

Histologic workup

For the present study, all cases were re-assessed by a surgeon (UFW) and two experienced pathologists (PB, IK) in terms of clinical findings and history, preexisting macro- and histopathologic reports and H&E stained tissue slides, as well as new H&E stained tissue slices to ensure correct diagnosis according to current WHO classification and anatomical tumor location. The site of the main tumor mass and/or eventual precursor lesions (intraductal papillary mucinous neoplasms of the pancreas (IPMN) or adenomatous lesions of duodenum, ampulla or bile duct) was used for definition. For this study, five histological subtypes were defined. Intestinal (INT), pancreatobiliary (PB) and mixed intestinal-pancreatobiliary (MIX), as well as poorly differentiated (POOR) were defined according to Albores-Saavedra et al. [8]. An additional category was added for rare other phenotypes (OTH), as mucinous and adenosquamous adenocarcinomas were found in our collective. According to Albores-Saavedra et al. [8], INT adenocarcinomas are characterized by well-formed tubular to elongate glands, complex cribriformed areas, and solid nests similar to colorectal adenocarcinoma, whereas PB adenocarcinomas show simple or branching glands and small solid nests of cells surrounded by abnormal desmoplastic stroma (Figure 1). Few tumors with both patterns equally distributed were assigned to the MIX type. Poorly differentiated carcinomas (POOR) are composed of solid sheets and nests admixed with densely packed, small irregular glands and individual cells with marked nuclear polymorphism, little or no mucin production and strong mitotic activity (Figure 1).

Figure 1.

Figure 1

Histopathological Subtypes of Periampullary Adenocarcinomas. (a-e) hematoxylin-eosin stained tissue (H&E): (a, b) adenocarcinoma of the pancreatobiliary type with simple branching glands lined by cuboidal columnar tumor cells with rounded nuclei and focally cribriform growth pattern. c adenocarcinoma of the mixed type showing both intestinal and pancreatobiliary growth pattern evenly distributed, d adenocarcinoma of the intestinal type with characteristic branching tubular glands, simple and pseudostratified mucin producing glandular epithelium with elongated hyperchromatic and pseudostratified nuclei, (e) poorly differentiated carcinoma displaying solid insular glandular growth pattern and remarkable nuclear atypia; (f-h) typical immunohistochemical staining patterns for cytokeratin 7 (CK7) in a pancreatobiliary type adenocarcinoma (g), cytokeratin 20 (CK20) (f) and caudal type homeobox 2 (CDX2) (h) in an intestinal type adenocarcinoma, pictures taken at 20-fold magnification.

Tumors containing over 50% of stromal mucin were classified as mucinous, as proposed by the WHO classification [1] of ampullary tumors, while diagnosis of colloid carcinoma of the pancreas requires at least 80% of extracellular mucin pools combined with a characteristic well-differentiated cuboidal to columnar cellular morphology.

Histopathologic assessment was done by two independent pathologists blinded for the respective clinical outcome. For classification of histopathologic subtype and immunohistochemistry, the pathologists were blinded towards tumor location.

Immunohistochemistry

After individual case review, tissue slides of 3 μm were prepared from representative FFPE blocks. Immunohistochemistry was carried out using commercially available ready-to-use antibodies for cytokeratin 7 (CK7, DAKO IR619), cytokeratin 20 (CK20, DAKO IR777), and caudal type homeobox 2 (CDX2, DAKO IR080), LINKER reagent (DAKO K8022) and EnVision™ Flex Visualization system (DAKO K8000) on an autostainer LINK 48 (DAKO, Hamburg, Germany) device according to the manufacturer's instructions. The specimens were counterstained with hematoxylin. Omission of primary antibodies served as negative controls and normal pancreatic and intestinal epithelia as internal positive control.

Representative images of immunohistochemical stains are shown in Figure 1. Immunostaining for CK7 and CK20 was considered positive when appropriate brown staining was seen in the tumor cell cytoplasm and immunostaining for CDX2 when appropriate brown staining was seen in the nucleus. CK7, CK20 and CDX2 expressions were established calculating the percentage of immunoreactive cells in the total number of tumor cells and rounding to decades. Only cases with more than 5% of positive tumor cells were regarded as positive.

Statistics

IBM SPSS Statistics Version 20 (SPSS Inc. Chicago, IL) was used for all statistical calculations. For exploratory and descriptive analysis, scale variables were expressed as median (range) and ordinal or dichotomous variables as absolute and relative frequencies. For assessment of diagnostic consistency, interrater reliability analysis using the Kappa statistic was performed. Survival data was plotted and analyzed according to the Kaplan-Meyer method. For univariate and multivariate statistical testing the following methods were used: Mann–Whitney test, Chi squared test, Spearman rank correlation, binary logistic regression, Logrank test and Cox regression. The significance level was set to p = 0.05 and all statistical tests were performed two-sided.

Results

Clinico-pathological reassessment and baseline data

From a total of 966 surgical patients assessed for eligibility (Figure 2), n = 462 did not have periampullary adenocarcinomas, n = 160 had no tumor resection and in n = 143 cases there was insufficient tissue left for the present study due to use for other studies. Reassessment of clinical and pathological reports as well as histopathologic reexamination of H&E stained tissue slides in 201 cases resulted in correction of data entry errors and thus exclusion of two patients with neuroendocrine neoplasms and one patient with ovarian cancer metastasis to the periampullary region. Furthermore there was a change in diagnosis from PDAC to AMPAC in four patients and from AMPAC to PDAC in two patients. Follow-up survival data was complete due to regular follow-up within the Comprehensive Cancer Center Freiburg. Out of the 198 patients included in the study, about two third had pancreatic cancer (n = 126). The second largest group was ampullary cancer (n = 40), followed by distal bile duct (n = 23) and duodenal cancer (n = 9) (Table 1).

Figure 2.

Figure 2

Flowchart of patient selection and data assessment. Abbreviations: PH-PDAC pancreatic head pancreatic ductal adenocarcinoma, DBDAC distal bile duct adenocarcinoma, AMPAC ampullary adenocarcinoma, DUOAC duodenal adenocarcinoma.

Table 1.

Baseline parameters, basic pathology and immunohistochemical markers for 198 patients with periampullary adenocarcinomas

Parameter
Total
PDAC
DBDAC
AMPAC
DUOAC
p
N 198 126 23 40 9 -
Male : female
102:96
63:63
14:9
22:18
3:6
0.511
Age
67 (30–89)
67 (30–89)
69 (49–83)
65 (36–84)
66 (46–78)
0.137
Distant metastasis (M1)
7 / 4%
4 / 3%
0 / 0%
2 / 5%
1 / 11%
0.448
Neoadjuvant therapy
14 / 7%
13 / 10%
0 / 0%
1 / 3%
0 / 0%
0.126
Resection
PPPD
163
103
19
34
7
0.803
Whipple
23
14
2
5
2
total PE
12
9
2
1
0
PVR
62 / 31%
53 /42%
6 / 26%
2 / 5%
1 / 11%
0.000
Perioperative mortality
7 / 4%
5 / 4%
2 / 9%
0 / 0%
0 / 0%
0.300
Tumor size (mm)
25 (1–320)
27 (1–80)
15 (8–25)
20 (2–320)
40 (22–60)
0.000
Grade G3/4
72 / 37%
48 / 39%
8 / 35%
12 / 31%
4 / 44%
0.785
Stage T3/4
155 / 78%
109 / 87%
18 / 78%
21 / 53%
7 / 78%
0.000
Stage N1/2
132 / 67%
89 / 71%
14 / 61%
24 / 60%
5 / 56%
0.468
Lymph node ratio (LNR)
.09 (0 - .86)
.10 (0 - .86)
.08 (0 - .72)
.07 (0 - .71)
.10 (0 - .28)
0.694
Lymphangiosis (L1)
87 / 44%
60 / 48%
5 / 22%
19 / 48%
3 / 33%
0.116
Hemangiosis (V1)
29 / 15%
22 / 18%
3 / 13%
2 / 5%
2 / 22%
0.237
Perineural invasion (Pn1)
113 / 57%
88 / 70%
12 / 52%
13 / 33%
0 / 0%
0.000
Associated precursor
Adenoma
20 / 10%
1 / 1%
4 / 17%
12 / 30%
3 / 33%
0.000
IPMN
11 / 6%
11 / 9%
0 / 0%
0 / 0%
0 / 0%
0.084
Positive resection margin
51 / 26%
41 / 33%
5 / 22%
3 / 8%
2 / 22%
0.017
Subtype
INT
39 / 20%
11 / 9%
5 / 22%
18 / 45%
5 / 56%
0.000
MIX
12 / 6%
8 / 6%
2 / 9%
2 / 5%
0 / 0%
PB
118 / 16%
89 / 71%
12 / 52%
15 / 38%
2 / 22%
OTH
6 / 3%
5 / 4%
0 / 0%
0 / 0%
1 / 11%
POOR
23 / 12%
13 / 10%
4 / 17%
5 / 13%
1 / 11%
Immunohistochemical Markers
% CK7+
90 (0–100)
90 (0–100)
95 (0–100)
80 (0–100)
0 (0–60)
0.000
% CK20+
0 (0–100)
0 (0–100)
0 (0–100)
10 (0–100)
70 (10–100)
0.000
% nuclear CDX2+ 10 (0–100) 0 (0–100) 0 (0–100) 50 (0–100) 95 (60–100) 0.000

Values are depicted as absolute and percentage of column for categorial and median (range) for scale variables if not otherwise specified. p value derived from two-sided Median test (scale variables), Chi squared test (categorial variables) and from two-sided Spearman rank correlation test (immunohistochemical markers), each for the respective rows.

Abbreviations: PPPD pylorus preserving pancreatoduodenectomy, Whipple classical Whipple procedure, PE pancreatectomy, PVR portal venous resection. INT intestinal, PB pancreatobiliary, MIX mixed intestinal-pancreatobiliary, POOR poorly differentiated carcinoma, OTH other specific subtypes, + positive, CK cytokeratin, PDAC pancreatic ductal adenocarcinoma, DBDAC distal bile duct adenocarcinoma, AMPAC ampullary adenocarcinoma, DUOAC duodenal adenocarcinoma.

Clinical and baseline data are shown in Table 1. No significant differences were found concerning age or gender distribution among the different tumor locations. 14 patients (7%) had received neoadjuvant therapy before resection (13 PDAC and 1 AMPAC). Distant metastasis was very rare among resected patients (4%). The usual resection procedure was pylorus-preserving pancreatoduodenectomy (PPPD, n = 163), with few cases requiring extension to classical Whipple procedure (CWP, n = 23) or total pancreatectomy (TPE, n = 12) for tumor invasion of the pyloric region or intraoperative positive pancreatic resection margin, respectively. PDAC and DBDAC were significantly more often locally advanced as demonstrated by a higher rate of portal venous resections (PVR) due to adhesion to or infiltration of the portal vein or it’s confluence (PDAC/DBDAC 42%/26% vs 5%/11% AMPAC/DUOAC). Perioperative mortality was 4% (n = 7).

Basic pathology and histological subtype analysis

Results of explorative data analysis and statistical testing concerning basic pathology are depicted in Table 1. Several statistically significant differences between the four groups could be noted. DUOAC had the largest median diameter (40 mm) while AMPAC (20 mm) and DBDAC (15 mm) were smaller and PDAC intermediate (27 mm). Only 53% of AMPAC were of stage T3 or T4, compared to 78-87% for the other entities. Likewise, only 8% of AMPAC had positive resection margins, compared to 22-33% for other locations. Adenomatous precursor lesions displayed statistically significant decreasing frequency from DUOAC/AMPAC (33%/30%) to DBDAC/PDAC (17%/1%). Nine percent of PDAC were associated with IPMN precursor lesions. High-grade intraepithelial dysplasia was present in 17 of 20 (85%) associated adenomatous precursor lesions and in 9 of 11 (82%) IPMN.

Results of histological subtype assessment are shown in Table 1. The distribution of subtypes was significantly different among the adenocarcinoma groups. The INT type adenocarcinoma showed decreasing frequency with distance from the duodenum in the order DUOAC – AMPAC - DBDAC - PDAC, ranging from 56% to 9%, while the percentage of PB type increased from 22% to 71%. Of note, two DUOAC were assigned to the PB phenotype by application of the subtype criteria. MIX and OTH types were not frequently encountered (0 - 9% and 0 – 11%). The percentage of poorly differentiated carcinomas was relatively homogenous ranging from 10 to 17%. Rare WHO subtypes designated as OTH were mucinous (2 PDAC and 1 DUOAC) and adenosquamous (3 PDAC). Interrater reliability concerning the five defined histological subtypes was found to be very good (Kappa = 0.920, p = 0.000).

Diagnostic value of immunohistochemical markers

Results of immunohistochemical marker assessment are presented in Table 1. Cytokeratin 7 (CK7) is a marker of pancreatobiliary epithelia, whereas cytokeratin 20 (CK20) and CDX2 are expressed by intestinal epithelia. Median intestinal marker expression was highest in DUOAC (CK20 and CDX2, 70% and 95%) and decreased for AMPAC (10% and 50%) and negative for DBDAC and PDAC (median expression level 0%). The pancreatobiliary marker CK7 showed the inverse pattern with high median expression level in PDAC / DBDAC (90%/ 95%), decreased with AMPAC (85%) and 0% in DUOAC. These correlations were highly significant (p < 0.001 in two-sided Spearman rank correlation test).

Uni- and multivariate binary logistic regression models were used in the attempt to predict the INT type by means of the immunohistochemical markers CK7, CK20 and CDX2 (details shown in Table 2). However, due to poor performance for prediction of the INT type in PDAC / DBDAC location (0%-13% correct prediction for univariate and 19% for multivariate model), even a multivariate model including all three markers only achieved 51% correct prediction for the INT type when applied to the total patient collective.

Table 2.

Diagnostic value of immunohistochemical markers for intestinal type adenocarcinoma

Location
Marker
% Positive tumor cells
% Correct prediction
p
Median (Range)
    INT NON-INT INT NON-INT  
PDAC / DBDAC
CK7
90 (0–100)
90 (0–100)
0%
100%
0.288
CK20
10 (0–100)
0 (0–100)
0%
100%
0.034
CDX2
45 (0–100)
0 (0–90)
13%
100%
0.000
CK7, CK20, CDX2
-
19%
100%
0.002
multivariate
AMPAC / DUOAC
CK7
20 (0–100)
85 (0–100)
57%
75%
0.024
CK20
80 (0–100)
8 (0–100)
65%
79%
0.002
CDX2
90 (20–100)
30 (0–100)
87%
79%
0.000
CK7, CK20, CDX2
-
87%
75%
0.000
multivariate
ALL
CK7, CK20, CDX2
-
51%
95%
0.000
  multivariate          

Prediction modeled by univariate and multivariate binary logistic regression analysis, p values given for the two-sided overall model omnibus test of the respective row.

Abbreviations: PDAC / DBDAC / AMPAC / DUOAC pancreatic ductal/distal bile duct / ampullary / duodenal adenocarcinoma, INT intestinal, NON-INT non-intestinal, CK cytokeratin, CI confidence interval.

Baseline data and biology of the intestinal subtype

Results of a subgroup analysis of INT adenocarcinomas are shown in Table 3. While median tumor size did not differ between INT and NON-INT type (23 vs 25 mm, p = 0.779), several attributes of lower malignant potential could be demonstrated for INT adenocarcinomas. High tumor grade, high T and N Stage, lymph node ratio (LNR), perineural and vascular invasion were significantly less frequent and expression of intestinal molecular markers CK20 and CDX2 was significantly higher with INT versus non-INT adenocarcinoma. INT adenocarcinomas were more frequently located in the ampulla of Vater or duodenum region than in the pancreas or distal bile duct and margin-free surgical resection was more frequently achieved. There was a statistically significant association of the INT type with adenomatous precursor lesions, but not with IPMN precursor lesions.

Table 3.

Baseline data and biology of the intestinal subtype

Parameter
INT
NON-INT
p
N 39 159 -
Male : female
25:14
77:82
0.079
Age
69 (36–81)
67 (30–89)
0.569
Distant metastasis (M1)
1 (3%)
6 (4%)
0.714
Neoadjuvant therapy
1 (3%)
13 (8%)
0.220
Resection
PPPD
31 (80%)
132 (83%)
0.701
Whipple
6 (15%)
17 (11%)
 
TPE
2 (5%)
10 (6%)
 
PVR
8 (21%)
54 (34%)
0.105
Perioperative mortality
2 (5%)
5 (3%)
0.548
Tumor size (mm)
23 (1–320)
25 (3–70)
0.779
Grade G3/4
6 (15%)
66 (42%)
0.002
pT Stage 3/4
21 (54%)
134 (84%)
0.000
pN Stage 1/2
16 (41%)
116 (73%)
0.000
Lymph node ratio (LNR)
.00 (.00-.58)
.12 (.00-.86)
0.018
Lymphangiosis (L1)
12 (31%)
75 (47%)
0.064
Hemangiosis (V1)
1 (3%)
28 (18%)
0.017
Perineural invasion (Pn1)
13 (33%)
100 (63%)
0.001
Positive resection margin
3 (8%)
48 (30%)
0.004
Location
PDAC / DBDAC
16 (41%)
133 (84%)
0.000
AMPAC / DUOAC
23 (59%)
26 (16%)
 
% CK7
85 (0–100)
90 (0–100)
0.070
% CK20
45 (0–100)
0 (0–100)
0.000
% nuclear CDX2
80 (0–100)
0 (0–100)
0.000
Associated precursor lesion
Adenoma
8 (21%)
12 (8%)
0.016
  IPMN 3 (8%) 8 (5%) 0.516

Values are depicted as absolute and percentage of column for categorial and median (range) for scale variables, p value derived from Mann–Whitney (scale variables) or Chi squared test (categorial variables) for the respective row.

Abbreviations: Whipple / PPPD non / pylorus-preserving pancreatoduodenectomy, TPE total pancreatectomy, PVR portal venous resection, PDAC/DBDAC/AMPAC/DUOAC pancreatic ductal/distal bile duct/ampullary/duodenal adenocarcinoma, NON-/INT non-/intestinal subtype, CK cytokeratin.

Survival analysis for tumor location and histological subtype

Details of survival analysis regarding tumor location and subtype are shown in Table 4 and Figure 3. Perioperative deaths (n = 7) were excluded from survival analysis. Overall median follow-up was 15 months (range 0–116 months). Median survival ranged in ascending order from 23, 29, 64 to 71 months for PDAC, DBDAC, AMPAC to DUOAC. For histological subtypes, median survival was 13, 22, 25 and 30 months for POOR, PB, OTH and MIX subtype, while median survival was not yet reached for the INT subtype. Pairwise comparison by two-sided logrank test among histological subtypes disclosed that significant differences existed only between INT type versus other types. Therefore, non-intestinal types (NON-INT) were assigned to a common group. When survival plots were stratified by tumor location, survival after resection of INT type adenocarcinomas was remarkably favorable for each location, reaching the significance level for PDAC, AMPAC and DUOAC (Table 4 and Figure 3).

Table 4.

Univariate survival analysis for tumor location and histopathological subtypes in periampullary adenocarcinomas

Location
Type
N
Events
Survival (months)
p
      (Deaths) Median Mean  
 
Comparison of tumor locations versus PDAC
PDAC
ALL
121
64
23
31
-
DBDAC
21
14
29
39
0.430
AMPAC
40
14
64
72
0.000
DUOAC
9
6
71
46
0.169
 
Comparison of tumor subtypes versus INT
ALL
INT
37
8
NR
83
-
MIX
12
8
30
37
0.002
OTH WHO
6
4
25
38
0.017
PB
115
66
22
34
0.000
POOR
21
12
13
28
0.000
NON-INT
154
90
22
35
0.000
 
Comparison INT vs NON-INT stratified for tumor location
PDAC
NON-INT
111
63
20
29
0.034
INT
10
1
39
74
DBDAC
NON-INT
17
12
12
37
0.563
INT
4
2
29
55
AMPAC
NON-INT
22
11
38
56
0.019
INT
18
3
NR
90
DUOAC
NON-INT
4
4
4
10
0.003
  INT 5 2 75 75  

Survival estimates are derived from Kaplan-Meier method, p values from two-sided Logrank test. For Kaplan-Meier plots see Figure 3. Perioperative deaths (n = 7) were excluded from survival analysis.

Abbreviations: INT intestinal, NON-INT non-intestinal, PB pancreatobiliary subtype, MIX mixed subtype, POOR poorly differentiated carcinoma, OTH other subtypes, PDAC pancreatic ductal adenocarcinoma, DBDAC distal bile duct adenocarcinoma, AMPAC ampullary adenocarcinoma, DUOAC duodenal adenocarcinoma, NR not reached.

Figure 3.

Figure 3

Survival plots according to histological subtypes and tumor origin. a: KM plot for all patients with periampullary adenocarcinomas, stratified for histological subtypes. b: KM plot for all patients with periampullary adenocarcinoma, stratified for INT versus non-INT subtype. c-f: KM plots for INT versus non-INT histological subtype divided by respective periampullary adenocarcinoma origin (pancreatic head (PDAC), ampullary (AMPAC), distal bile duct (DBDAC), duodenal (DUOAC). perioperative deaths (n = 7) excluded, p values derived from two-sided Logrank test. For details see also Table 4. Abbreviations: KM Kaplan Meier, INT intestinal type adenocarcinoma, PB pancreatobiliary type adenocarcinoma, MIX mixed type adenocarcinoma, POOR poorly differentiated carcinoma, OTH other WHO types. n.s. not significant.

Univariate and multivariate survival analysis

Results of uni- and multivariate survival analysis are shown in Table 5. Cases with perioperative death (n = 7) were excluded from survival analysis. In univariate analysis, several clinicopathologic parameters were found to be significantly associated with poor survival: necessity of portal venous resection, high tumor grade, T stage, N stage and LNR, lymphatic and blood vessel invasionas well as positive resection margins. Presence of a precursor lesion was significantly associated with better survival. This was however only the cause for adenomatous precursor lesions in non-pancreatic adenocarcinomas (p = 0.017, two-sided Logrank test), as the subgroup of PDAC with associated IPMN did not show significantly better survival than PDAC without associated IPMN (p = 0.538, Logrank test). Both tumor location and histological subtype were highly significant predictors of survival (p < 0.001). Accordingly, high CK7 expression and low CDX2 expression, as characteristic of NON-INT phenotype, were significant predictors of poor survival.

Table 5.

Univariate and multivariate survival analysis for resected periampullary adenocarcinomas

Parameter
Condition
Median survival (months)
Hazard ratio
Univariate
Multivariate
    With condition Without condition (95% CI) p p
All patients (n = 191)
-26-
-
 
 
Gender
Male
30
25
0.953 (0.641–1.417)
0.812
NI
Age (years)1
> 67
26
27
1.050 (0.706–1.561)
0.811
NI
Distant metastasis
Yes
11
27
2.044 (0.892–4.688)
0.091
NI
Neoadjuvant tx
Yes
25
26
1.536 (0.741–3.182)
0.248
NI
PVR
Yes
25
27
1.640 (1.068–2.517)
0.024
0.510
Tumor size (mm)1
> 25
26
26
1.069 (0.699–1.635)
0.759
NI
Tumor grade
G3/4
17
31
1.808 (1.199–2.726)
0.005
0.075
pT stage
pT3/4
23
41
1.938 (1.160–3.238)
0.012
0.905
pN stage
pN1/2
22
52
1.883 (1.198–2.959)
0.006
0.211
LNR1
> 0.09
20
48
2.291 (1.515–3.465)
0.000
0.019
Lymphangiosis
Present
22
30
1.557 (1.035–2.342)
0.033
0.398
Hemangiosis
Present
12
29
1.900 (1.161–3.109)
0.011
0.384
Perineural invasion
Present
25
29
1.322 (0.881–1.984)
0.177
NI
Precursor lesion
Present
NR
25
0.362 (0.175–0.748)
0.006
0.169
Resection margins
Positive
19
37
2.368 (1.551–3.617)
0.000
0.132
Tumor subtype2
See Table 4
1.487 (1.253–1.765)
0.000
0.006
Tumor location2
See Table 4
1.471 (1.175–1.843)
0.001
0.270
CK7 + (%)1
> 90
20
38
1.757 (1.161–2.657)
0.008
0.869
CK20 + (%)1
> 0
29
23
0.311 (0.538–1.218)
0.311
NI
CDX2 + (%)1 > 10 48 20 0.562 (0.368–0.858) 0.008 0.767

Survival estimates are derived from Kaplan-Meyer method, perioperative deaths (n = 7) were excluded, univariate / multivariate p is derived from two-sided Cox regression in a proportional hazards model.

Abbreviations: CK cytokeratin, CI confidence interval, + positive. 1 cut-off at overall median value, 2 defined as ordinal variable according to decreasing median survival as indicated in Table 2, pos positive, tx therapy, PVR portal venous resection, NR not reached.

Parameters found to be significant in univariate analysis were included in a Cox proportional hazards model including all cases with periampullary adenocarcinomas (n = 191 after exclusion of n = 7 cases of perioperative mortality). In this model, only histological subtype (Hazard Ratio 1.5, p = 0.006) and LNR (Hazard Ratio 2.3, p = 0.019) were found to represent independent predictors of survival. This was confirmed by conditional backward elimination of predictive parameters.

Discussion

Only one group has so far systematically extended the INT/PB concept to the whole spectrum of periampullary adenocarcinomas [3,9]. We were able to validate and extend these findings in our study. From a plethora of prognostic markers identified in univariate analysis, including UICC stage, tumor size, resection margin status and even immunohistochemical markers, only histologic subtype and lymph node ratio qualified as independent predictors of survival. Hereby the present study confirms that histopathological differentiation, in contrast to tumor location, is an independent prognostic factor. It also confirms that the lymph node ratio is a stronger independent prognostic marker than N stage, which has been shown for PDAC, AMPAC and DBDAC before [10,11].

We were able to demonstrate a significantly better survival of the INT subtype not only for AMPAC but also in the subgroups of DUOAC and PDAC, which has not been demonstrated before due to insufficient case numbers [3,9]. Probably due to its relatively rare occurrence (around 10% of PDAC), INT type PDAC has only recently been recognized [12].

The concept of INT and PB differentiation has recently been extended to IPMN. It has been suggested that INT type IPMN can develop into colloid carcinoma (CAC) [13,14], which is associated with better survival [15,16]. We show that in ampullary and duodenal location, INT phenotype is associated with adenomatous precursor lesions, but this is not the case in PDAC, validating its existence as a separate entity apart from colloid carcinoma or invasive IPMN. In addition, one recent study shows no association of intraductal papillary neoplasms of the bile duct (IPNB) with INT type cholangiocarcinoma [17,18]. It may therefore be suggested that an “intestinal pathway” of carcinogenesis is possible via the INT type of IPMN to colloid carcinoma, and duodenal or ampullary adenoma to DUOAC and AMPAC, but also without papillary precursor lesions to INT type PDAC and DBDAC.

On the other hand, blinded application of the INT/PB classification scheme resulted in assignment of two DUOAC to the PB group. One might speculate that if INT type adenocarcinoma can arise in the pancreas, vice versa PB type adenocarcinoma may arise in rare instances in the duodenum due to common embryologic origin, but further evaluation is currently not possible given the exceeding rarity of DUOAC.

As CK7, CK20 and CDX2 are known to be fairly specific markers for the discrimination of INT and PB subtypes in AMPAC and IPMN [14,19-22], it was surprising that this was not the case for PDAC and DBDAC in our study. This finding is noteworthy as it shows that careful morphological assessment by an experienced pathologist outperforms immunohistochemical markers in this respect.

This study has several limitations that have to be mentioned. First, although data was obtained from a prospectively maintained database, all data was analyzed retrospectively. There was a relatively high number of cases assessed for eligibility from which insufficient amounts of tissue were available for the present study due to use for other studies. A selection bias by exclusion of small tumors with few tissue can thus not totally be ruled out. Furthermore we note a relatively high rate of PDAC in our series compared to other recent studies [2,4] on this subject. This may be explained in several ways: first, selection bias excluding small tumors may favor the inclusion of PDAC which are usually larger than AMPAC; furthermore assignment to tumor location was not performed according to the most recent detailed protocols [2,4] and could only be reassessed in a retrospective manner. Misclassification of origin especially in large tumors cannot totally be ruled out. Nevertheless pathologists and surgeons at our institution since long have been aware of this complex issue and extensive surgical and pathological experience exists. We believe that by primary assessment in a standardized protocol as well as detailed re-assessment in the scope of this study, risk of misclassification was reduced to a minimum.

Another current issue concerns resection margin status in PDAC. Some recent studies demonstrated by extensive resection margin workup that the majority of PDAC resections were in fact margin positive (R1) [23-25]. Margin assessment in our standardized protocol was very detailed but not as extensive as in some of the aforementioned studies, thus a number of R0 might in fact have been R1 resections. Nevertheless our data is validated by the fact that margin status was a prognostic factor. More detailed analysis of this issue was not within the scope of this study but will have to be addressed in future studies.

The most important aspect of pathological diagnostic is clinical decision making on the basis of prognostic factors. With respect to the findings of this study, several aspects warrant consideration.

Based on favorable survival, surgical treatment of metastasis may be indicated in INT type AMPAC, as already suggested by others [26]. Given the fact that tumor location is less relevant than subtype, this concept may be extended to PDAC, DBDAC and DUOAC. Especially since criteria for the rarely performed resection of metastatic PDAC are poorly defined [27], subtype might be a valuable adjunct in decision making.

Furthermore, there is still no consensus regarding the indication and regimen for adjuvant therapy in non-pancreatic periampullary adenocarcinomas [28-33]. In clinical practice, treatment regimen for AMPAC, DUOAC or DBDAC are usually extrapolated from PDAC. Limited data suggests that patients with node positive and margin-negative AMPAC benefit from adjuvant therapy [28,30,33]. However, these studies did not report on subtype. Regarding the results of our study, a more differentiated approach based on subtype may be suggested for future trials.

It has been shown that survival figures of series reporting outcome of resected pancreatic head cancer have been biased by inclusion of ampullary cancers [23,34]. In consequence, more thorough examination of tumor origin has been demanded by some authors [2]. However given the results of our study, the biologically valid and logistically preferable approach would be to distinguish between INT and PB differentiation rather than tumor location. This is emphasized by the fact that for larger tumors with involvement of all periampullary structures, assessment of primary location is very difficult or impossible.

Conclusion

In summary, our study demonstrates that histopathological subtype and lymph node ratio are the most important prognostic factors in periampullary adenocarcinomas, outperforming all other parameters. As tumor location becomes irrelevant with correct microscopical phenotype classification, this may obviate the need for time-intensive macroscopical and microscopical workup of tumor location in pancreatoduodenectomy specimen. It must be recommended that studies and trials on outcome and therapy of periampullary adenocarcinomas stratify for intestinal and pancreatobiliary differentiation.

Competing interests

The authors have no competing interests to declare.

Authors’ contributions

PB, IK and MW performed the pathological assessment and critically revised the manuscript. DB, SK and JH collected clinical data and performed the operations. TK and UTH performed the operations and critically revised the manuscript. UFW and FM collected the data, performed statistical analysis and drafted the manuscript. All authors read and approved the final manuscript.

Pre-publication history

The pre-publication history for this paper can be accessed here:

http://www.biomedcentral.com/1471-2407/13/428/prepub

Contributor Information

Peter Bronsert, Email: peter.bronsert@uniklinik-freiburg.de.

Ilona Kohler, Email: ilona.kohler@uniklinik-freiburg.de.

Martin Werner, Email: martin.werner@uniklinik-freiburg.de.

Frank Makowiec, Email: frank.makowiec@uniklinik-freiburg.de.

Simon Kuesters, Email: simon.kuesters@uniklinik-freiburg.de.

Jens Hoeppner, Email: jens.hoeppner@uniklinik-freiburg.de.

Ulrich Theodor Hopt, Email: ulrich.hopt@uniklinik-freiburg.de.

Tobias Keck, Email: tobias.keck@uksh.de.

Dirk Bausch, Email: dirk.bausch@uksh.de.

Ulrich Friedrich Wellner, Email: dr.ulrich.wellner@gmail.com.

Acknowledgements

This study was funded by a research grant of the German Research Foundation to Ulrich Friedrich Wellner (grant number DFG WE 5085/1-1).

References

  1. Bosman FT, Carneiro F, Hruban RH, Theise ND. WHO classification of tumors of the digestive system. 4. Lyon: International Agency for Research in Cancer; 2010. [Google Scholar]
  2. Adsay V, Ohike N, Tajiri T, Kim GE, Krasinskas A, Balci S, Bagci P, Basturk O, Bandyopadhyay S, Jang K-T, Kooby DA, Maithel SK, Sarmiento J, Staley CA, Gonzalez RS, Kong SY, Goodman M. Ampullary region carcinomas: definition and site specific classification with delineation of four clinicopathologically and prognostically distinct subsets in an analysis of 249 cases. Pathol: Am J Surg; 2012. [DOI] [PubMed] [Google Scholar]
  3. Westgaard A, Tafjord S, Farstad IN, Cvancarova M, Eide TJ, Mathisen O, Clausen OPF, Gladhaug IP. Pancreatobiliary versus intestinal histologic type of differentiation is an independent prognostic factor in resected periampullary adenocarcinoma. BMC Cancer. 2008;8:170. doi: 10.1186/1471-2407-8-170. [DOI] [PMC free article] [PubMed] [Google Scholar]
  4. Pomianowska E, Grzyb K, Westgaard A, Clausen OPF, Gladhaug IP. Reclassification of tumour origin in resected periampullary adenocarcinomas reveals underestimation of distal bile duct cancer. Eur J Surg Oncol. 2012;38:1043. doi: 10.1016/j.ejso.2012.07.113. [DOI] [PubMed] [Google Scholar]
  5. Ohike N, Kim GE, Tajiri T, Krasinskas A, Basturk O, Coban I, Bandyopadhyay S, Morohoshi T, Goodman M, Kooby DA, Sarmiento JM, Adsay NV. Intra-ampullary papillary-tubular neoplasm (IAPN): characterization of tumoral intraepithelial neoplasia occurring within the ampulla: a clinicopathologic analysis of 82 cases. Am J Surg Pathol. 2010;34:1731–1748. doi: 10.1097/PAS.0b013e3181f8ff05. [DOI] [PMC free article] [PubMed] [Google Scholar]
  6. Kimura W, Futakawa N, Zhao B. Neoplastic diseases of the papilla of Vater. J Hepatobiliary Pancreat Surg. 2004;11:223–231. doi: 10.1007/s00534-004-0894-7. [DOI] [PubMed] [Google Scholar]
  7. Morini S, Perrone G, Borzomati D, Vincenzi B, Rabitti C, Righi D, Castri F, Manazza AD, Santini D, Tonini G, Coppola R, Onetti Muda A. Carcinoma of the Ampulla of Vater: Morphological and Immunophenotypical Classification Predicts Overall Survival. Pancreas. 2012;42:60–66. doi: 10.1097/MPA.0b013e318258fda8. [DOI] [PubMed] [Google Scholar]
  8. Albores-Saavedra J, Henson DE, Klimstra DS. Atlas of Tumor Pathology. Washington DC: Armed Forces Institute of Pathology; 2000. Tumors of the gallbladder, extrahempatic bile duct and ampulla of Vater. Fascile 27. [Google Scholar]
  9. Westgaard A, Pomianowska E, Clausen OPF, Gladhaug IP. Intestinal-type and pancreatobiliary-type adenocarcinomas: how does ampullary carcinoma differ from other periampullary malignancies? Ann Surg Oncol. 2013;20:430–439. doi: 10.1245/s10434-012-2603-0. [DOI] [PubMed] [Google Scholar]
  10. Pomianowska E, Westgaard A, Mathisen O, Clausen OPF, Gladhaug IP. Prognostic relevance of number and ratio of metastatic lymph nodes in resected pancreatic, ampullary, and distal bile duct carcinomas. Oncol: Ann. Surg; 2012. [DOI] [PubMed] [Google Scholar]
  11. Riediger H, Keck T, Wellner U, zur Hausen A, Adam U, Hopt UT, Makowiec F. The lymph node ratio is the strongest prognostic factor after resection of pancreatic cancer. J Gastrointest Surg. 2009;13:1337–44. doi: 10.1007/s11605-009-0919-2. [DOI] [PubMed] [Google Scholar]
  12. Albores-Saavedra J, Simpson K, Dancer Y-J, Hruban R. Intestinal type adenocarcinoma: a previously unrecognized histologic variant of ductal carcinoma of the pancreas. Ann Diagn Pathol. 2007;11:3–9. doi: 10.1016/j.anndiagpath.2006.06.008. [DOI] [PubMed] [Google Scholar]
  13. Adsay NV, Pierson C, Sarkar F, Abrams J, Weaver D, Conlon KC, Brennan MF, Klimstra DS. Colloid (mucinous noncystic) carcinoma of the pancreas. Am J Surg Pathol. 2001;25:26–42. doi: 10.1097/00000478-200101000-00003. [DOI] [PubMed] [Google Scholar]
  14. Adsay NV, Merati K, Basturk O, Iacobuzio-Donahue C, Levi E, Cheng JD, Sarkar FH, Hruban RH, Klimstra DS. Pathologically and biologically distinct types of epithelium in intraductal papillary mucinous neoplasms: delineation of an “intestinal” pathway of carcinogenesis in the pancreas. Am J Surg Pathol. 2004;28:839–848. doi: 10.1097/00000478-200407000-00001. [DOI] [PubMed] [Google Scholar]
  15. Yopp AC, Katabi N, Janakos M, Klimstra DS, D’Angelica MI, DeMatteo RP, Fong Y, Brennan MF, Jarnagin WR, Allen PJ. Invasive carcinoma arising in intraductal papillary mucinous neoplasms of the pancreas: a matched control study with conventional pancreatic ductal adenocarcinoma. Ann Surg. 2011;253:968–974. doi: 10.1097/SLA.0b013e318214bcb4. [DOI] [PubMed] [Google Scholar]
  16. Waters JA, Schnelldorfer T, Aguilar-Saavedra JR, Chen J-H, Yiannoutsos CT, Lillemoe KD, Farnell MB, Sarr MG, Schmidt CM. Survival after resection for invasive intraductal papillary mucinous neoplasm and for pancreatic adenocarcinoma: a multi-institutional comparison according to American Joint Committee on Cancer Stage. J Am Coll Surg. 2011;213:275–283. doi: 10.1016/j.jamcollsurg.2011.04.003. [DOI] [PubMed] [Google Scholar]
  17. Zen Y, Quaglia A, Heaton N, Rela M, Portmann B. Two distinct pathways of carcinogenesis in primary sclerosing cholangitis. Histopathology. 2011;59:1100–1110. doi: 10.1111/j.1365-2559.2011.04048.x. [DOI] [PubMed] [Google Scholar]
  18. Rocha FG, Lee H, Katabi N, Dematteo RP, Fong Y, D’Angelica MI, Allen PJ, Klimstra DS, Jarnagin WR. Intraductal papillary neoplasm of the bile duct: a biliary equivalent to intraductal papillary mucinous neoplasm of the pancreas? Hepatology. 2012;56:1352–1360. doi: 10.1002/hep.25786. [DOI] [PubMed] [Google Scholar]
  19. Kohler I, Jacob D, Budzies J, Lehmann A, Weichert W, Schulz S, Neuhaus P, Röcken C. Phenotypic and genotypic characterization of carcinomas of the papilla of Vater has prognostic and putative therapeutic implications. Am J Clin Pathol. 2011;135:202–211. doi: 10.1309/AJCPCTCUQSYI89YT. [DOI] [PubMed] [Google Scholar]
  20. Fischer H-P, Zhou H. Pathogenesis of carcinoma of the papilla of Vater. J Hepatobiliary Pancreat Surg. 2004;11:301–309. doi: 10.1007/s00534-004-0898-3. [DOI] [PubMed] [Google Scholar]
  21. Fischer H-P, Zhou H. Pathogenesis and histomorphology of ampullary carcinomas and their precursor lesions. Review and individual findings. Pathologe. 2003;24:196–203. doi: 10.1007/s00292-003-0617-x. [DOI] [PubMed] [Google Scholar]
  22. Gassler N, Knüchel R. Tumors of Vater’s ampulla. Pathologe. 2012;33:17–23. doi: 10.1007/s00292-011-1546-8. [DOI] [PubMed] [Google Scholar]
  23. Verbeke CS, Gladhaug IP. Resection margin involvement and tumour origin in pancreatic head cancer. Br J Surg. 2012;99:1036–1049. doi: 10.1002/bjs.8734. [DOI] [PubMed] [Google Scholar]
  24. Esposito I, Kleeff J, Bergmann F, Reiser C, Herpel E, Friess H, Schirmacher P, Buchler MW. Most pancreatic cancer resections are R1 resections. Ann Surg Oncol. 2008;15:1651–60. doi: 10.1245/s10434-008-9839-8. [DOI] [PubMed] [Google Scholar]
  25. Menon KV, Gomez D, Smith AM, Anthoney A, Verbeke CS. Impact of margin status on survival following pancreatoduodenectomy for cancer: the Leeds Pathology Protocol (LEEPP) HPB (Oxford) 2009;11:18–24. doi: 10.1111/j.1477-2574.2008.00013.x. [DOI] [PMC free article] [PubMed] [Google Scholar]
  26. De Jong MC, Tsai S, Cameron JL, Wolfgang CL, Hirose K, van Vledder MG, Eckhauser F, Herman JM, Edil BH, Choti MA, Schulick RD, Pawlik TM. Safety and efficacy of curative intent surgery for peri-ampullary liver metastasis. J Surg Oncol. 2010;102:256–263. doi: 10.1002/jso.21610. [DOI] [PubMed] [Google Scholar]
  27. Michalski CW, Erkan M, Hüser N, Müller MW, Hartel M, Friess H, Kleeff J. Resection of primary pancreatic cancer and liver metastasis: a systematic review. Dig Surg. 2008;25:473–480. doi: 10.1159/000184739. [DOI] [PubMed] [Google Scholar]
  28. Kang SP, Saif MW. Ampullary and periampullary tumors: translational efforts to meet a challenge in diagnosis and treatment. Highlights from the “2011 ASCO Gastrointestinal Cancers Symposium”. San Francisco, CA, USA. January 20–22, 2011. JOP. 2011;12:123–125. [PubMed] [Google Scholar]
  29. Neoptolemos JP, Moore MJ, Cox TF, Valle JW, Palmer DH, McDonald AC, Carter R, Tebbutt NC, Dervenis C, Smith D, Glimelius B, Charnley RM, Lacaine F, Scarfe AG, Middleton MR, Anthoney A, Ghaneh P, Halloran CM, Lerch MM, Oláh A, Rawcliffe CL, Verbeke CS, Campbell F, Büchler MW. Effect of adjuvant chemotherapy with fluorouracil plus folinic acid or gemcitabine vs observation on survival in patients with resected periampullary adenocarcinoma: the ESPAC-3 periampullary cancer randomized trial. JAMA. 2012;308:147–156. doi: 10.1001/jama.2012.7352. [DOI] [PubMed] [Google Scholar]
  30. Narang AK, Miller RC, Hsu CC, Bhatia S, Pawlik TM, Laheru D, Hruban RH, Zhou J, Winter JM, Haddock MG, Donohue JH, Schulick RD, Wolfgang CL, Cameron JL, Herman JM. Evaluation of adjuvant chemoradiation therapy for ampullary adenocarcinoma: the Johns Hopkins Hospital-Mayo Clinic collaborative study. Radiat Oncol. 2011;6:126. doi: 10.1186/1748-717X-6-126. [DOI] [PMC free article] [PubMed] [Google Scholar]
  31. Palta M, Patel P, Broadwater G, Willett C, Pepek J, Tyler D, Zafar SY, Uronis H, Hurwitz H, White R, Czito B. Carcinoma of the ampulla of Vater: patterns of failure following resection and benefit of chemoradiotherapy. Ann Surg Oncol. 2012;19:1535–1540. doi: 10.1245/s10434-011-2117-1. [DOI] [PMC free article] [PubMed] [Google Scholar]
  32. Neoptolemos J. European Study Group for Pancreatic Cancer. Ampullary cancer ESPAC-3 (v2) trial: a multicenter, international, open-label, randomized controlled phase III trial of adjuvant chemotherapy versus observation in patients with adenocarcinoma of the ampulla of vater. J Clin Oncol. 2011;29(Suppl) LBA4006. [Google Scholar]
  33. Kim R, Chabot J, Saif MW. Adjuvant treatment for ampullary cancer. Highlights from the “2011 ASCO Annual Meeting”. Chicago, IL, USA; June 3–7, 2011. JOP. 2011;12:362–363. [PubMed] [Google Scholar]
  34. Carpelan-Holmstrom M, Nordling S, Pukkala E, Sankila R, Luttges J, Kloppel G, Haglund C. Does anyone survive pancreatic ductal adenocarcinoma? A nationwide study re-evaluating the data of the Finnish Cancer Registry. Gut. 2005;54:385–7. doi: 10.1136/gut.2004.047191. [DOI] [PMC free article] [PubMed] [Google Scholar]

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