1 Centre René Gauducheau, Saint Herblain; 2 Centre François Baclesse, Caen; 3 CHU Hotel Dieu, Nantes; 4 CHG Chubert, Vannes; 5 CHG Georges Renon, Niort; 6 Centre Alexis Vautrin, Vandoeuvre-les-Nancy; 7 Centre GF Leclerc, Dijon; 8 CHU Gabriel Montpied, Clermont-Ferrand; 9 CHG André Boulloche, Montbeliard; 10 CHU Pasteur, Nice; 11 CHG, Cholet; 12 CH J Cur, Bourges; 13 Laboratoire Aventis, Paris, France
* Correspondence to: Professor J.-Y. Douillard, Centre René Gauducheau, Boulevard J Monod, 44805 Saint Herblain, France. Tel: +33-2-40-67-99-78; Fax: +33-2-40-67-97-76; Email: jy-douillard{at}nantes.fnclcc.fr
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Abstract |
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Methods: Overall, 115 patients received DC (docetaxel 75 mg/m2 and cisplatin 100 mg/m2 both on day 1, every 3 weeks, arm A1) and 118 VC (vinorelbine 30 mg/m2/week on days 1 and 8 and cisplatin 100 mg/m2 on day 1, every 3 weeks, arm B1) for six cycles, and subsequently maintained by monotherapy with docetaxel (A1) or vinorelbine (B1) with cross-over on disease progression to vinorelbine 30 mg/m2 days 1 and 8 (A2), or docetaxel 100 mg/m2, day 1, both every 3 weeks (B2). The primary end point was overall response rate (ORR).
Results: Patient characteristics were balanced; median follow-up was 8.8 months. First-line response rate was 33.9% with DC and 26.3% with VC (P=0.20). In arms A1 and B1, respectively: duration of response was similar (8.2 versus 8.4 months); median time to progression was 5 months in both; median survival was 8 versus 9 months (P=0.38); 1-, 2- and 3-year survival was 36% versus 35%, 17% versus 10% and 13% versus 6% (P not significant). However, with a low number of long-term survivors, statistical significance was not reached. Overall, almost half of the patients crossed over to second-line therapy; there were no response with vinorelbine and 6 (11.2%) partial responses with docetaxel. Considering the safety profile, the occurrence of febrile neutropenia was 9.6% with DC and 26.3% with VC. Treatment-related mortality was 2.5% with DC and 8.5% with VC.
Conclusions: The trend in favour of the DC arm in ORR, even though statistical significance was not reached, is consistent with previous reports. This study suggests an activity of first-line DC in advanced NSCLC, and that second-line vinorelbine does not provide additional clinical benefit. As already shown in other studies, the use of DC in first-line should provide a better percentage of long-term survivors, despite the absence of efficacy of the second-line in our study.
Key words: chemotherapy, docetaxel, first-line, non-small-cell lung cancer
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Introduction |
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This activity of docetaxel led to numerous phase II studies of the drug as first-line treatment. A pooled analysis of the four main trials with docetaxel (100 mg/m2) showed a 31% response rate, a median survival of 9.2 months and a 1-year survival rate of 37% [6]. In avanced NSCLC, standard first-line chemotherapy includes platinum combination. The recent report by Fossella et al. [7
] has shown that the combinations of docetaxelcisplatin (DC) and vinorelbinecisplatin (VC) are active in the first-line setting. The study provided the results of a comparative phase III study involving 1200 patients, which showed that DC provided a greater benefit in terms of response, overall survival and quality of life compared with VC in the first-line setting [7
]. This new setting in first-line chemotherapy for NSCLC will be responsible for more acute needs for the second-line setting therefore accessible to an increased population. However, in this phase III study, according to the protocol, second-line therapy was at the investigator's discretion. Our randomised, phase II study was designed to evaluate the activity of DC versus VC as first-line therapy in advanced NSCLC, and is the first to look at the effect of cross-over to single-agent docetaxel or vinorelbine at disease progression in NSCLC.
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Patients and methods |
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Previous radiotherapy was allowed if it involved <25% of bone marrow and was completed 4 weeks before study entry. Previously irradiated or clinically asymptomatic brain metastases and any weight loss during the last 6 months were admitted. Exclusion criteria were: stages IIIB (including wet T4); National Cancer Institute Common Toxicity Criteria (NCI CTC) peripheral neuropathy grade >1; prior chemotherapy or biological therapy for metastases; lymphangitis carcinomatosa, ascites or pleural effusion as the only target. This trial was approved by a local ethics committee and all patients provided written informed consent.
Treatment administration
Patients were randomised to one of two treatment arms: A (A1 + A2) and B (B1 + B2). Patients in arm A received as first-line (A1): docetaxel 75 mg/m2 as a 1-h intravenous (i.v.) infusion followed by cisplatin 100 mg/m2 as a 1-h infusion on day 1. Patients randomised to arm B received as first-line (B1): cisplatin 100 mg/m2 as a 1-h infusion on day 1 followed by vinorelbine 30 mg/m2 as a 15-min infusion on days 1 and 8. For both arms, cycles were administered every 3 weeks for up to six cycles. In the event of a complete response (CR), treatment was stopped until progressive disease (PD) occurred. When a partial response (PR) or stable disease (SD) was reported, cisplatin was stopped after six cycles and chemotherapy was continued with docetaxel in arm A1 and vinorelbine in arm B1 at the same dose until PD, unacceptable toxicity or patient's request to halt treatment. When PD had been documented, patients crossed over to the alternative monotherapy as second-line treatment: (A2) vinorelbine 30 mg/m2 on days 1 and 8, or (B2) docetaxel 100 mg/m2 every 3 weeks until PD (Figure 1). A docetaxel dose of 100 mg/m2 in second-line was chosen at the time of the trial conception, when data from Shepherd et al. [4] and Fossella et al. [5
] were not available.
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Dose adjustment
During treatment, patients underwent weekly complete blood cell count, white blood cell differential and platelet counts. Before treatment, patients were required to have an absolute neutrophil count of 1.5 x 109/l and a platelet count
100 x 109/l. Dose-adjustment criteria were based mainly on haematological measurements or clinical assessments, and were maintained for all subsequent cycles of treatment. The minimal dose reductions were 60 mg/m2 (docetaxel), 80 mg/m2 (cisplatin) and 25 mg/m2 (vinorelbine). Docetaxel doses were reduced by 20% in cases of liver transaminase levels between 2.5x and 5x ULN values, and were interrupted in cases of transaminases >5x ULN and abnormal bilirubin. If patients experienced several toxicities, the most conservative dose adjustment was adopted. If a cisplatin-related toxicity occurred, either docetaxel or vinorelbine was continued as monotherapy until PD was assessed. In the case of NCI CTC (version 1) grade 3 toxicities (except alopecia, anaemia and asthenia), study treatment could be delayed for up to 2 weeks to allow recovery until grade
1 levels were monitored.
Study assessments
Pretreatment assessments included a complete medical history and physical examination; complete blood cell count with differential and platelets, standard biochemical profile, aspartate aminotransaminase, alanine aminotransferase, total bilirubin, creatinine, albumin and 1-acid glycoprotein; electrocardiogram; chest X-ray; CT scan of the chest, abdomen and brain; and radionuclide total body scan. Tumour assessments were performed every three cycles. All lesions were followed and all measurable disease recorded. However, in cases of multiple lesions, up to four measurable target lesions representative of all organs involved were selected, giving the priority to bidimensionally measurable lesions. Response had to be confirmed at a minimum of 4-weekly interval. Radiological documentation of first-line treatment was reviewed by an external review committee to assess the best response and date of possible progression. Criteria of response were assessed according to WHO response criteria. Toxicity was evaluated according to the NCI CTC (version 1) when possible. Otherwise, the severity was assessed and graded as mild, moderate, severe or life-threatening.
Statistical analysis
The primary end point was the overall response rate (ORR) after first-line treatment as evaluated by the external review committee. Secondary objectives for both first- and second-line treatment were duration of response, time to progression (TTP), survival, toxicity and quality of life. The sample size estimation was based on the assumption that the response rate should be 35% in each arm of the treated population after first-line treatment. With a precision of ±10% of the 95% confidence interval (CI), 88 patients per arm were required. For the analysis of secondary end points, 100 patients per arm were included. Statistical tests were only allowed for exploratory purposes.
Analyses were performed using SAS software (version 6.12; SAS Institute, Cary, NC, USA) on all patients who had received at least one infusion (evaluable population). Median, minimum and maximum values were used to summarise continuous data. Time-dependent parameters were analysed using the KaplanMeier method. All patients who received at least three cycles of treatment were assessable for response. Patients who received less than three cycles were assessable for toxicity and for response if clinical progression occurred >8 days after the first treatment infusion. Patients who had PD with combination therapy were considered as refractory to platinum.
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Results |
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Efficacy
Response rate was 33.9% with DC (A1) and 26.3% with VC (B1) (Table 2) (P=0.203). In A1, there was one (0.9%) CR and 38 (33.0%) PRs. In B1, there was no CR but 31 (26.3%) PRs. SD was similar in both arms: 34 (29.6%) in A1 and 41 (34.7%) in B1, and PD occurred in over one-quarter of patients in each arm, 29 (25.2%) in A1 and 26 (22%) in B1. Overall response rates were similar between the two arms. In descriptive histological subtypes, among patients with squamous cell carcinoma (38 each arm), 12 in A1 and seven in B1 had a PR. Among patients with large cell histological subtype (12 in A1 and 16 in B1), PR occurred in 6 and 1 patient, respectively. There was no difference between treatments in terms of median duration of response: 8.2 months (95% CI 6.710.7) in A1 and 8.4 months (95% CI 7.911) in B1. The median TTP was 5 months in both arms.
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By the cut-off date, 101 patients (88%) had died in arm A and 111 in arm B (94%). In arm A (A1 + A2), 86 patients (85.1%) died due to PD and 10 patients (9.9%) due to other reasons. Five deaths (4.9%) were treatment-related: 3 patients died during first-line treatment (A1) and 2 in second-line (A2). Similarly in arm B, 86 deaths (77.5%) occurred due to PD and 15 (13.5%) from other reasons. Ten deaths (9%) were treatment-related, all occurring in the first-line phase (B1).
Toxicity
Toxicity was assessed at every cycle in all patients who received at least 1 cycle of treatment (Table 4). During first-line bitherapy, a similar percentage of patients experienced at least one treatment-related grade 34 adverse event in arms A1 (42.8%) and B1 (49.2%). However, twice as many patients in B1 had serious treatment-related adverse events (50%) than did patients in A1 (24.3%). Grade 34 anaemia was seen in 17 patients (14.8% in A1) (grade 3 only) and 41 patients (35.1% in B1) (Table 4). Grade 34 neutropenia was observed in 74 patients (64.3%) in arm A1 versus 98 (83.7%) in B1. Among them, febrile neutropenia occurred in <10% of patients (n=11) receiving DC compared with 26% (n=31) receiving VC. Use of granulocyte colony-stimulating factor was rare, occurring only in 2.4% of 1063 cycles. However, the incidence of grade 34 thrombocytopenia was similar for both arms: four (3.4%) and six (5.1%) patients in arm A1 and B1, respectively. Only one patient (0.9%) experienced grade 34 infection in the DC arm (A1) compared with four (3.4%) in the VC arm (B1). As expected, alopecia occurred in more patients receiving DC (86 patients, 74.8%) than with VC (44 patients, 37.3%) (Table 4). Nail disorders occurred in 13 patients (11.3%) in DC versus one patient (<1%) in VC. Digestive toxicities were in accordance with the known toxicity profile of each agent. Grade 3 and 4 nausea and vomiting occurred in A1 [21 (18.3%) and 18 (15.7%) patients, respectively] and in B1 [eight (6.7%) and 12 (10.1%) patients, respectively]. Grade 3 asthenia was experienced by the same percentage of patients in both arms. Grade 3 peripheral neurotoxicity was experienced only by two (1.7%) patients in B1.
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In first-line therapy, there were three treatment-related deaths (2.6%) in DC (one due to respiratory distress, one septic shock, one unknown cause) and 10 in VC (8.5%) (seven due to sepsis with febrile neutropenia, one pneumonia, one infection and one unknown cause despite autopsy). In second-line treatment, two patients died due to sepsis with febrile neutropenia in the vinorelbine arm (A2). No deaths due to toxicity were observed in the docetaxel arm.
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Discussion |
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A previous phase III study [12] demonstrated the superiority of the combination vinorelbinecisplatin compared with vindesinecisplatin or vinorelbine alone. VC has shown higher median survival, particularly among patients with good performance status (PS) [13
]. Recently, an additional Japanese trial compared DC with vindesinecisplatin [14
]. The aim of the present French study was to assess efficacy and toxicity of DC compared with VC. Then, based on previous phase II results for this new combination in NSCLC [15
18
], we aimed to determine the effect of cross-over to second-line monotherapy on progression. Based on previous experience with weekly vinorelbine in VC, the treatment schedule was modified, with vinorelbine 30 mg/m2/day given on days 1 and 8 only. The two arms had the same cisplatin dosage (100 mg/m2) and 3-weekly schedule in first-line. We report here the results of a strategy involving two treatment sequences: first-line cisplatin-based combination therapy with DC (arm A1) or VC (arm B1), followed by maintenance monotherapy with either docetaxel or vinorelbine until evidence of PD. Thereafter, patients crossed over to receive second-line monotherapy with either vinorelbine (arm A2) or docetaxel (arm B2). When this study began, the inefficacy of maintenance chemotherapy had not been published. Results of efficacy gave an ORR of 33.9% in the first-line DC arm that was consistent with other phase II and III trials using the same dosage of cisplatin [10
, 11
, 16
] and with the pivotal study by Fossella et al. [7
] in which patients received both cisplatin and docetaxel at 75 mg/m2 every 3 weeks or 25 mg/m2 weekly vinorelbine and 100 mg/m2 of cisplatin every 4 weeks. Similarly, Kubota et al. [14
] reported a response rate of 37% using only 60 mg/m2 of docetaxel and 80 mg/m2 of cisplatin. The ORRs from four phase II studies ranged from 33% to 45%, with a median survival of 811 months and 1-year survival of nearly 35% [15
, 18
]. Only one Greek study reported a 1-year survival of 48%, probably due to the higher proportion of stage IIIB patients at inclusion [15
].
In contrast to most other phase III studies comparing the combination VC with alternative combinations, we accrued unselected patients, including poor-prognosis patients with low PS (15% of patients in each arm had PS 2), metastatic disease (all patients had stage IV disease at inclusion) and brain metastases. In other published studies, at least 10% of the patients had stage IIIB disease, good PS of 0 or 1 and no brain metastases [7, 14
, 19
22
]. In the current study, more favourable responses to first-line DC versus VC are suggested, respectively, in patients aged
60 years (20 of 40 patients versus 12 of 52) and those with squamous cell carcinoma (12 of 38 patients versus seven of 38 patients), and in large cell histological subtypes (six of 12 patients versus 1 of 16 patients) and those with PS 2 (six of 18 patients versus three of 17 patients). The ORR for with first-line DC is consistent with published results according to disease stage and PS. Unlike the Greek study [23
], adenocarcinoma histological subtype was not a prognostic factor for response. Amongst other efficacy parameters, TTP, median overall survival and 1-year survival were similar in both arms, consistent with other phase III trials [11
, 13
]. There was no statistical difference in first-line response rate, survival or treatment discontinuations due to toxicity.
In this study, 2-year survival was higher in DC followed by vinorelbine than in VC followed by docetaxel (17% versus 10%), which is in agreement with the survival obtained with the other phase III trial using DC [7, 14
]. Moreover, 3-year survival was also twice as high (13% versus 6%) with first-line DC followed by second-line vinorelbine compared with VC followed by docetaxel, although because of the low number of long-term survivors, statistical significance was not reached. This result suggests a long-term survival benefit with a sequential regimen involving DC as first-line followed by a second-line therapy in patients with NSCLC, including those with metastatic disease. Clinical trials will be developed including second-line treatment with further drugs to improve the results of the sequence.
Despite its better activity in second-line treatment compared with vinorelbine, docetaxel was unable to compensate for the lower efficacy of VC that had been used as first-line treatment in arm B. Docetaxel is better tolerated than vinorelbine as both a single agent and in combination with cisplatin. For example, the percentage of discontinuation due to adverse events was lower with DC (14.3% versus 18.3%), and with docetaxel monotherapy in first-line (29.4% in A1 versus 38.1% in B1) or second-line (9.6% in B2 versus 19.6% in A2) therapy. Similarly, a greater percentage of patients experienced at least one serious treatment-related adverse event with VC (50.8%) than with DC (24.3%). Haematological toxicity, such as neutropenia, anaemia and thrombocytopenia, occurred more frequently in arm B1. In particular, more patients experienced febrile neutropenia with VC (26.3%) than with DC (9.6%). This incidence was higher than the results of a phase III study in which, for each arm, only 4% of patients experienced febrile neutropenia [7]. A possible explanation for the difference in the incidence of febrile neutropenia may be the different doses of vinorelbine and cisplatin used in the Fossella et al. [7
] trial (25 versus 30 mg/m2 and 75 versus 100 mg/m2, respectively), or that the patient population showed more advanced disease and had worse PS in our study.
Treatment-related deaths were twice as high overall with VC followed by docetaxel (9% of patients) as with DC followed by vinorelbine (4.9%), and this was mostly due to febrile neutropenia. This also includes second-line therapy, in which no treatment-related deaths occurred during treatment with docetaxel and two occurred with vinorelbine.
In our study, a low percentage of patients experienced neurotoxicity leading to combination treatment discontinuation in both arms: four (3.4%) patients in arm A1 and three (2.6%) in arm B1. These results are similar to those reported by the TAX 326 study (3.6% of patients) [7]. Therefore, in terms of neurotoxicity, DC is equivalent to VC. Moreover, compliance with treatment was similar in both arms for the median number of cycles administered. Nevertheless, despite the modified vinorelbine schedule used in this study, the number of complete combination cycles administered was greater in arm A1 (98.3%) than in B1 (94.6%). Similarly, more cycles were delayed with vinorelbine administered as combination therapy or monotherapy than with docetaxel.
The efficacy and safety of DC in our study is consistent with that reported by the TAX 326 study [7]. Despite similar response rates, the benefitrisk ratio seems to favour DC in first-line followed by second-line vinorelbine, regarding 2- and 3-year survivals as well as a manageable toxicity profile. There were more long-term survivors when DC was used in first-line. In our study, the second-line therapy did not seem to impact on overall survival, and alternative and more effective drugs are sought for second-line treatment. Despite a higher response rate in second-line, our data suggest that docetaxel gives a better response rate in both lines, but is not able to compensate for the reduced impact on survival of VC as first-line therapy. The benefit for 2- and 3-year survivals seems to be attributable to DC as first-line.
In conclusion, the trend in favour of the DC arm in terms of ORR, even though statistical significance was not reached, is consistent with previous reports. This study suggests an activity of first-line DC in advanced NSCLC, and that second-line vinorelbine does not provide additional clinical benefit. As already shown in other studies, the use of DC in first-line should provide a better percentage of long-term survivors, despite the absence of efficacy of the second-line in our study.
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Acknowledgements |
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Received for publication April 8, 2004. Revision received July 14, 2004. Accepted for publication August 9, 2004.
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