A prognostic index model to predict the clinical outcomes for advanced pancreatic cancer patients following palliative chemotherapy

The incidence of pancreatic cancer has gradually increased in developing countries in recent years (Ma et al. 2013). Several clinical trials confirmed that gemcitabine- or S-1-containing palliative chemotherapy possess similar efficacy and safety for patients with APC; nevertheless, the prognosis of APC patients remains dismal (Stathis and Moore 2010; Burris et al. 1997; Heinemann et al. 2008; Okusaka et al. 2008; Ueno et al. 2013; Michl and Gress 2013). It is clinically relevant to identify the prognostic factors for APC patients in determination of the treatment strategy.

Previous studies have reported several prognostic factors related to poor outcomes for APC patients, including elevated pretreatment levels of CA19-9 (Saad et al. 2002; Reni et al. 2009), CRP (Haas et al. 2010; Wang et al. 2012; Pine et al. 2009), and LDH (Haas et al. 2010; Tas et al. 2001), increased ratio of neutrophil to lymphocyte (Xue et al. 2014), poor performance status (Tas et al. 2013), and status of initial unresectable disease (Xue et al. 2014). However, the prognostic factors reported were different in various studies. In the current study, we devised a convenient prognostic index model by retrospectively analyzing various clinicopathological factors and pretreatment parameters in APC patients receiving palliative chemotherapy. Three factors, including ECOG score of 2, CA19-9 levels of ≥1000 U/mL, and CRP levels ≥5 mg/L, were identified as independent adverse prognostic factors for OS in APC patients in our cohort. Creating a prognostic index model with these three factors, patients classified as low risk with this model showed significant survival benefit from gemcitabine- or S-1-based chemotherapy, with a median survival duration of 9.9 months and 1-year survival rate of 40.5 %, which was much better than the patients categorized as high risk, with median survival duration of 5.3 months and a 1-year survival rate of 5.9 %. Based on these values, palliative chemotherapy of gemcitabine- or S-1-containing regimen showed no significant survival benefit for the patients in high-risk group. As to the low-risk group of patients, it should be noted that those who have fewer poor prognostic factors may do well even without chemotherapy. Nevertheless, this prognostic index model would help oncologists to avoid excessive medical treatment for APC patients in high-risk group; meanwhile, it is urgent to develop novel therapeutical strategies for these intractable high-risk groups of APC patients.

Previous studies have proposed various prognostic models for APC patients (details in Table 4). Hamada et al. (2014) recently designed a nomogram derived from analysis of their prospectively collected 531 patients with inoperable pancreatic cancer receiving palliative chemotherapy, which contained six potential prognostic factors of age, sex, ECOG PS score, tumor size, regional lymph node metastasis, and distant metastasis status. This nomogram provided improved ability to predict clinical outcome for each patient with APC. Yi et al. (2011) devised a risk-stratified prognostic model derived from 298 APC patients who received gemcitabine-based chemotherapy, which consists of four prognostic factors, including serum CRP levels, albumin levels, metastasis to liver, and ascites dissemination. The survival outcomes differed remarkably according to the prognostic model stratification. However, only 84.9 % patients in their study had definite pathological diagnosis of ductal adenocarcinoma. Maréchal et al. (2007) also reported a prognostic index consists of three variables of KPS, weight loss, and AST for APC patients who received gemcitabine-containing chemotherapy. Using this index model, patients were categorized into three groups with significantly different survival time. By contrast, three variables of ECOG score, CA19-9 levels, and CRP levels identified in our prognostic index model represent the general condition, tumor burden, and systemic inflammatory reaction of patient, respectively, making our result more close to clinical practice. Consistently, previous study has demonstrated that these three prognostic factors are significantly associated with the survival of a cohort of 103 consecutive patients with APC (Ueno et al. 2000). The median OS of this cohort was 3.2 months in contrast to 8.8 months in this study, and about 30 % of the patients had died within 2 months from the beginning of systemic chemotherapy. This may be because patients with locally advanced APC were excluded from this study. Additionally, the chemotherapeutic regimen used in this cohort varied among patients, having only a few patients treated with gemcitabine monotherapy which is not consistent to current clinical practice. Because of the disparity of categorization criteria for the continuous parameters, such as CA19-9 and CRP, between studies (Yi et al. 2011; Maréchal et al. 2007; Ueno et al. 2000), universally accepted cutoff values of these parameters have yet established. This underscores the importance of conducting further study to elucidate this issue. Our data suggests that the cutoff value defined in this study based on previous studies and our clinical practice could be utilized successfully to predict prognosis for APC patients. Obvious limitations should be addressed that the sample size of the current study is relatively small compared with other previous studies. Furthermore, the reliability of the predictive model developed in retrospectively single center should be externally validated using another independent cohort data.

In this study, all the APC patients have received either gemcitabine- or S-1-based chemotherapy. Although the chemotherapy regimens differed among patients in our study, it is unlikely that the treatment regimens would influence the prognosis of patients. Ueno et al. (2013) demonstrated in GEST study that efficacy of gemcitabine, S-1, or gemcitabine/S-1 combination therapy for patients with APC were not statistically different. In addition, previous meta-analysis studies (Heinemann et al. 2008) showed no significant improvement in OS for gemcitabine-based combinations over gemcitabine monotherapy. Furthermore, in our results of univariate analysis for different treatment regimens, the prognosis of patients received gemcitabine- or S-1-containing regimens showed no statistical difference (HR 1.55; 95 % CI 0.74–3.26; P = 0.245).

In conclusion, our study identified three independent adverse prognostic factors, ECOG, CA19-9, and CRP, in patients with APC who had received palliative chemotherapy. A prognostic index model calculated based on these factors was developed to stratify patients with low and high risk of poor prognosis. These readily accessible pretreatment parameters of patients and prognostic index model could assist clinicians to identify high-risk patients and propose individualized therapeutic approach to APC patients in clinical practice.