Main

The advent of targeted therapy (TT) has dramatically changed the treatment paradigm and prognosis of metastatic renal cell carcinoma (mRCC). Seven agents are now approved or available for use in North America and Europe, and more are awaiting phase III results (Figlin et al, 2012; ClinicalTrials.gov Identifier: NCT01030783, NCT00664326, NCT01865747, NCT01136733, NCT00303862, NCT01472081, NCT01582672). In the last 10 years, the standard of care for a patient with mRCC has undergone multiple revisions, mainly due to the rapidity of emerging data from prospective trials. There is a growing need for benchmark survival data from real-life patients exposed to one or more of the contemporary targeted therapies. Such data can provide guidance for future prospective trials and set expectations for outcomes that new therapies should exceed.

A number of retrospective studies have examined different aspects of clinical experience with targeted therapies. The most studied agents are anti-vascular endothelial growth factor (VEGF) inhibitors, sunitinib and sorafenib, usually in the setting of sequential therapy or following immunotherapy (Buchler et al, 2012; Harrison et al, 2013; Wahlgren et al, 2013). Retrospective studies have been completed to investigate the optimal sequence of TKIs and other second-line therapies such as mammalian target of rapamycin (mTOR) inhibitors, as well as the timing of cytoreductive nephrectomy (Buchler et al, 2012; Giuliani and Drudi, 2012; Stenner et al, 2012; Stroup et al, 2013). A multicentre Swedish study has previously found that in 2753 patients treated from 2002 to 2008, the median overall survival (OS) was 9.6 months from 2002 to 2006, vs 12.4 months from 2006 to 2008 (Wahlgren et al, 2013). Given that the first targeted agent, sunitinib, was approved in 2006, the clinical experience with TT in this database had not matured, with a limited number of exposures to multiple lines of contemporary agents. Another large cohort study found the median OS of 18.8 months among those who were treated with first-line VEGF-targeted treatment, although the outcomes were reported in the context of prognostic model validation (Heng et al, 2013).

The objectives of the study were two-fold: first, to compare the survival outcomes of mRCC patients in the International mRCC Database Consortium (IMDC) cohort who were treated with first, second, third, or more lines of TT; second, to benchmark survival outcomes based on the different inclusion criteria for selected phase III trials of novel targeted agents. Our study evaluated the largest multicentre retrospective database of patients who have mRCC and have received one or more VEGF inhibitors or mTOR inhibitors over a 9-year period. We also examined OS and progression-free survival (PFS) of patients using inclusion criteria simulated from large phase III trials, both published and recently reported studies.

Materials and methods

Twenty international cancer centres in Canada, the United States, Japan, South Korea, Singapore, and Denmark provided data on consecutive patients with mRCC. All patients were treated with anti-VEGF TT for mRCC (sunitinib, sorafenib, bevacizumab, pazopanib, and axitinib) and/or mTOR inhibitors (temsirolimus and everolimus) between January 2004 and December 2012, either per standard of care or as part of clinical trials. Patients were allowed to have undergone previous immunotherapy, but only targeted therapies were counted as lines of therapy used in each patient. Patient lists were obtained in a consecutive fashion from pharmacy or registry data in each centre, which included every mRCC patient who received TT. Using uniform data templates, we collected baseline patient characteristics and survival data from medical chart reviews and publically available records. All centres obtained local institutional ethics approval before including data in the cohort.

We assessed the survival outcomes of patients who received only one line of TT, who received two lines of targeted therapies, and who received three or more targeted therapies. We then extracted data and analysed survival outcomes for the following six sub-groups based on recent large prospective trials of TT:

  • All patients who received at least one TT;

  • Patients who received first-line TT with an intermediate or poor risk disease and whose diagnosis to treatment interval was less than 1 year, similar to those enrolled in Phase 3 Trial of Autologous Dendritic Cell Immunotherapy (AGS-003) Plus Standard Treatment of Advanced Renal Cell Carcinoma (ADAPT; ClinicalTrials.gov Identifier: NCT01582672);

  • Patients who received first-line TT and previously underwent nephrectomy, similar to those enrolled in A Study to Compare Tivozanib (AV-951) to Sorafenib in Subjects With Advanced Renal Cell Carcinoma (TIVO-1; ClinicalTrials.gov Identifier: NCT01030783);

  • Patients who received second-line TT after at least one other VEGF- TT, similar to those enrolled in Temsirolimus Vs Sorafenib As Second-Line Therapy In Patients With Advanced RCC Who Have Failed First-Line Sunitinib (INTORSECT; ClinicalTrials.gov Identifier: NCT00474786);

  • All patients who received third-line therapy;

  • Patients who received third-line TT and were previously exposed to one VEGF inhibitor and one mTOR inhibitor, similar to those enrolled in Study of Dovitinib Vs Sorafenib in Patients With Metastatic Renal Cell Carcinoma (GOLD; ClinicalTrials.gov Identifier: NCT01223027).

For each subgroup, we obtained the median OS and PFS, calculated from the line of therapy under consideration unless otherwise specified. We defined OS as the period between TT initiation and date of death, unless it was censored on the day of the last follow-up visit. We defined PFS as the period between treatment initiation and progression, drug cessation, or death, unless it was censored at the last follow-up visit. Progression was assessed radiologically using the Response Evaluation Criteria in Solid Tumors (RECIST), or clinically when continuation of treatment was deemed futile (Eisenhauer et al, 2009).

Statistical analysis

Baseline patient and disease characteristics were summarised using descriptive analysis. Overall survival and PFS were estimated for each sub-cohort with a 95% confidence interval (CI), and differences among the sub-cohorts were adjusted by the known independent predictors of poorer OS (KPS <80%, diagnosis to treatment interval <1 year, hypercalcemia, anemia, thrombocytosis, neutrophilia) using proportional hazards regression (Heng et al, 2009). The statistical analyses were performed using SAS version 9 (SAS Institute, Cary, NC, USA), and P<0.05 (two-sided) was considered statistically significant.

Results

Patient and treatment characteristics

In total, 2705 patients were included in the study cohort with a median follow-up period of 37 months. Their baseline patient characteristics and therapies are summarised in Table 1. One thousand five hundred and thirty three patients (57%) received or are still receiving 1TT. The most frequently used first-line therapy was sunitinib, used in 1959 patients (72%). This was followed by sorafenib in 474 patients (18%) and bevacizumab in 109 patients (4%). Other first-line choices included temsirolimus, pazopanib, everolimus, and axitinib. In total, 734 patients (27%) received a total of two lines of therapy, whereas only 438 patients (16%) received three or more lines of therapy.

Table 1 Baseline patient characteristics

Survival outcomes in the IMDC cohort

The median OS in patients who received only one TT was 14.9 months from the time of first-line therapy initiation (95% CI, 13.2–16.7 months), with PFS of 6.7 months (95% CI, 5.9–7.5 months). In contrast, the median OS in patients who received two lines of therapy was 21.0 months, measured from the time of first-line therapy initiation (95% CI, 19.1–23.5 months), with PFS of 3.4 months, measured from the time of second-line therapy initiation (95% CI, 3.0–3.9 months). Patients who received three or more lines of TT had an OS of 39.2 months, measured from the time of first-line initiation (95% CI, 36.3–41.9 months), with PFS of 4 months, measured from the time of third-line therapy initiation (95% CI, 3.4–4.5 months). On multivariable analysis, adjusting for the IMDC prognostic criteria, receiving second-line or third-line therapy was independently associated with better OS (HR=0.738, 95% CI 0.663–0.821; HR=0.626, 95% CI 0.541–0.724, respectively, both P<0.0001).

Table 2 summarises the survival outcomes of the six subgroups, as described above.

Table 2 OS and PFS in the specified sub-cohorts using data from the IMDC (see Materials and Methods)

Discussion

Survival benchmark studies provide context when designing and interpreting new clinical trials. Outcomes from real-life cohorts treated with current standard therapies serve as comparators for future clinical trials, with the expectation that newer therapies will perform better than the standard therapies. The benchmarked outcomes can also allow for future statistical considerations such as sample size for new prospective trials. Prior benchmark studies in mRCC were limited to patients who received cytokine immunotherapy (Belldegrun et al, 2008). Since the initial Food and Drug Administration (FDA) approval of sorafenib in 2005, contemporary targeted therapies have now largely replaced immunotherapy as the new standard of care. This study is, to the authors’ knowledge, the first and largest multi-national benchmarking study to date of mRCC patients treated with at least one line of TT.

One of the limitations in our methodology is its retrospective patient recruitment. Patients included in our cohort were not selected on a certain criteria or hand-picked by each centre; rather, they were derived from consecutive patient lists in pharmacy or registry data. This strategy was employed to minimise inherent selection bias, to reflect clinical practice as closely as possible, and to include all patients receiving TT as part of standard-of-care or clinical trials. The denominator for patients who received one line of TT is unknown and may vary across centres. However, the denominator for patients who received two lines of TT is, by definition, patients who received one line of TT, and the denominator for patients who received three lines of TT is patients who received two lines of TT; this allows us to assess and compare outcomes in sub-groups within our patient cohorts.

The study compares real-life retrospective survival outcomes with those reported in prospective trials. Since the era of immunotherapy, the median OS of patients in our study cohort, from the time of first-line agent use, has doubled (Belldegrun et al, 2008). The outcomes are slightly inferior to, but still comparable with, those reported in the updated sunitinib phase III study, in the pazopanib phase III study, or those reported in TIVO-1 (summarised in Table 3) (Motzer et al, 2009; Sternberg et al, 2013). This type of comparison is exploratory in nature. The small difference is likely due to the difference in patient inclusion criteria, with non-clear cell histology and patients with poor functional status, brain metastases, and comorbidities in the real-life cohort, who would have otherwise been excluded in clinical trials. The results in our study, therefore, not only confirm and support the findings in prospective trials, but are also generalisable to a wider, more heterogeneous range of patients and clinical practices across the centres.

Table 3 Survival outcomes from phase III studies of first-, second-, and third-line targeted therapies against an approved agent or placebo

In regards to the survival from the initiation of the second-line therapy, the outcomes for patients who received second-line TT in our cohort are comparable to the outcomes from the INTORSECT and RECORD-1 trials, and only slightly inferior to the AXIS trial (summarised in Table 3) (Motzer et al, 2008; Rini et al, 2011). The outcomes for patients in our study who have received a third-line TT after a TKI and an mTOR inhibitor, have exceeded the median survival outcome of GOLD trial, for both the study and control arms (summarised in Table 3). Trials for other novel therapies, including lenvatinib, regorafenib, cediranib, AGS-003, cabozantinib, and nivolumab, are ongoing or have preliminary results. The survival outcomes in our study will serve as benchmark for these studies.

In our study, sunitinib was the most popular first-line therapy, but the diversity of first-line and second-line therapy choices indicates that the sequence of TT prescription may be practice-dependent. In addition, until recently, data from head-to-head trial that tested the comparative effectiveness between front-line TKIs were limited. The recently published COMPARZ study shows that pazopanib was not inferior to sunitinib in terms of PFS as a first-line option in mRCC (Motzer et al, 2013). Thus, the survival advantage may be more associated with increasing lines of targeted therapies given, rather than their sequence, which corresponds with what was shown in prior studies (Motzer et al, 2008; Kirchner et al, 2010).

Reflecting the above observation, patients in our study who received more lines of therapy lived longer with longer PFS, adjusting for prognostic factors. This finding is comparable with results from randomised prospective second-line TT trials, which demonstrated an increased PFS with the use of TT compared with placebo (Motzer et al, 2008). Only 16% of the patients in our study were exposed to three or more lines of TT. This is partly explained by the 9-year study period that encompasses evolving treatment paradigms. Some early years saw targeted therapies offered only as trial drugs, and less than three targeted therapies were approved or available in most participating centres until at least 2008. Our study included a diverse range of patients many of whom would have been excluded from clinical trials, and therefore may not have had the opportunity to receive more lines of therapy on a trial. On the other hand, the survival advantage likely also stems from the inherent selection bias in a retrospective cohort. Even with the currently approved regimens, many patients die or become too ill to receive more than one or two lines of therapy, especially if their diseases had unfavourable prognostic indicators.

Conclusion

The current management of mRCC involves an evolving algorithm with a goal to optimise the outcome for each individual patient with as many lines of TT as the patient may benefit from. We present long-term, multicentre data to provide an understanding of survival outcomes achievable with available therapeutic agents. We demonstrate a prolonged survival with one or more TT comparable with that of previous prospective trials. The results can serve as a benchmark to compare the outcomes of emerging treatment options and help shape the design of future trials with realistic expectations of outcomes such as PFS.