Validation of prognostic scores for survival in cancer patients beyond first-line therapy

Prediction of survival for patients with advanced cancer who have already received first-line treatment is critical to decision making regarding subsequent treatments. Models allowing accurate estimation of life expectancy are needed to make a more informed treatment decision, in particular to guide decisions about chemotherapy in vulnerable patients. Doctors' survival predictions for palliative patients are often optimistic [1, 2]. The Research Network of the European Association for Palliative Care (EAPC) has provided evidence-based clinical recommendations for prognosis in patients with advanced cancer [3]. One of the six key recommendations is that physicians should systematically use prognostic scores to stratify patients into groups with different survival times. One of the prognostic tools specifically considered by the working group was the Palliative Prognostic (PaP)score based on Performance Status (PS), the presence or absence of dyspnea and anorexia, white blood cell counts, and the clinician's prediction of survival. It has been validated successfully in patients admitted to the oncology ward of a university teaching hospital [4]. However, the PaP score may be limited in that it was developed in the 1990 s for patients with far-advanced cancer referred to community hospitals.

We aimed to develop a novel prognostic scoring system for patients undergoing chemotherapy. Predictive models for survival integrating combinations of clinical and biological factors have been reported [5‐10]. Biological characteristics such as lactate dehydrogenase (LDH) level [6], lymphocyte count [5, 7], interleukin 6 (IL-6) level [8, 9], or vascular endothelial growth factor (VEGF) level [10] have been correlated with poor outcome. The primary endpoint of this study was the validation of two prognostic scores that we have previously shown to be correlated with survival in a Cox proportional hazards regression model. These scores were based on PS plus LDH level (score A) or PS plus lymphocyte count (score B). Both scores have been shown to stratify patients into groups with significantly different survival prognosis [6, 7]. We also aimed to investigate a third model including additional clinical and biological characteristics and thus potentially allowing for more accurate prognostication.

This was a prospective, observational, single-centre study.

In this prospective study, both score A (PS plus LDH level) and score B (PS plus lymphocyte count) were validated as suitable for identifying distinct risk groups with different durations of survival. Furthermore, we showed that the combination of PS and biological covariates such as LDH, lymphocyte and platelet counts, serum albumin and IL-6 levels is an effective strategy to predict survival for patients with advanced or metastatic cancer receiving further treatment after the first-line. Our third model including all six parameters was successfully validated according to the different methods used. Notably, the bias-corrected C index that was used as an alternative for external validation confirmed the good performance of the model. However, this validation study has several limitations. The percentage of colorectal cancer patients in our population study is low (3.7%), which may represent a selection bias. Also, there are several missing biochemical parameters, especially CRP (25%). Furthermore, regarding the CRP cutoff, we have tested it at 10 mg/L, which may appear to be low for advanced cancer patients, and may explain why CRP was not statistically significant in our multivariate analysis. However, several studies have already reported data on cancer patients with this cutoff [11‐13].

The decision to stop chemotherapy is one of the hardest challenges in oncology practice. Chemotherapy remains widely prescribed for terminally ill patients despite side effects and poor efficacy [18, 19]. We aimed to develop prognostic scores that would help clinicians estimate patients' survival regardless of initial tumor site. Therefore, we validated our prognostic scores in different cancer patient populations (Figure 2A and 2B). We acknowledge that, although cancer treatment is known to be cancer-type dependent, we did not include in our analysis prognostic factors specific to each cancer type. However, our scores are of importance and of potential clinical relevance since they may help the physicians discuss palliative treatment options with the patients and their families. Prognostication is not simply prediction of response to therapy, and some prognostic factors, such as PS or lymphocyte count, are useful across different tumor types, as we and others have already shown [4, 10, 15, 20, 21]. Furthermore, clinical or pathological data such as tumor grade or node involvement can reasonably be used as prognostic factors in early-stage disease. After first-line treatment failure, these data do not seem suitable for predicting short-term prognosis [22, 23].

Several clinical signs have been shown to be prognostically important in terminally ill cancer patients. For example, dyspnea, constipation, dizziness, pain, anxiety or depression are individually related to life expectancy, but their prognostic value has rarely been confirmed in multivariate analyses [20, 24, 25]. Therefore, our group developed 2 different PS-based prognostic scores using unbiased biological variables (scores A and B). Score B, described by Ray-Coquard et al [7], uses lymphopenia as a predictor of early death after chemotherapy. The threshold level of 700 lymphocytes per μl was chosen because it predicts hematological toxicity in patients who receive chemotherapy, as demonstrated in previous studies [5, 7, 26, 27]. We recently showed that lymphopenia, with a lymphocyte count of <1000/μl, is also an independent prognostic factor for overall and progression-free survival in several cancers [21]. Score A was published by Bachelot et al [6]. Their study included 154 patients with solid tumors enrolled in phase I clinical trials. PS >1 and high serum LDH level (> 600 U/L) were identified as independent prognostic factors for OS. Several studies have shown that elevated LDH is significantly associated with survival in patients with terminal cancer [28‐31]. Bozcuk et al and Suh et al have set the threshold for high LDH level at 378 U/L and 313 U/L, respectively [29, 31]. However, reasons for patient admission in Bozcuk's study included life-threatening situations, whereas Suh's study included only patients who had been admitted to the palliative care unit.

Most studies show that PS (assessed by the Karnofsky Performance Scale or by the ECOG scale) correlates with duration of survival [3, 6, 7, 20, 24, 25]. Recently, Kikuchi et al. have shown the benefit of adding biological markers such as serum albumin, LDH level, platelet and lymphocyte count to predict survival in terminally-ill cancer patients [32]. Serum albumin concentration is a well-known independent predictor of mortality risk [33]. In the current study, we also confirmed the prognostic value of the pro-inflammatory cytokine IL-6 [8, 9, 34]. However, IL-6 level is not clinically available and the usefulness of routine IL-6 assessment should be further investigated. Also, in our study we decided to use dichotomous variables that make clinical interpretation easier (the risk is either present or absent). However, we acknowledge that strong prognostic marker could be better included as linear parameter to take advantage of its prognostic information over the whole range of potential cutoffs. This might have enabled the calculation of a potentially more powerful prognostic algorithm.

In conclusion, we have validated two prognostic scores (score A: PS plus LDH level, and score B: PS plus lymphocyte count) and confirmed that combination of PS and biological covariates such as serum albumin concentration, LDH level, lymphocyte count, thrombocytopenia and IL-6 level is an effective strategy to predict survival for patients with advanced or metastatic cancer receiving further treatment after first-line failure. Because prediction of survival is variable among physicians, adding more objective measures would improve the accuracy of the score and facilitate treatment decision making in metastatic cancer patients, regardless of initial tumor site.