1 Gruppo Oncologico Italiano di Ricerca Clinica (GOIRC), Parma; 2 Gruppo Cooperativo Istituto Nazionale per la Ricerca sul Cancro (IST-Genova); 3 Gruppo Oncologico Piemontese Tumori Apparato Digerente (GOPTAD), Torino; 4 Istituto Oncologico Romagnolo (IOR), Forlì; 5 Gruppo Oncologico del Nord-Ovest (GONO), Pisa; 6 Servizio di Epidemiologia Clinica (IST)-Centro Trials (CBA), Genova, Italy
Received 12 November 2002; revised 18 March 2003; accepted 11 April 2003
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Abstract |
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To determine whether the addition of leucovorin to the combination 5-fluorouracil plus levamisole prolongs disease-free survival and overall survival in patients with radically resected colon cancer (Dukes B23 and C).
Patients and methods:
Patients (1703) were accrued between March 1992 and February 1995 in a large-scale clinical trial within five Italian cooperative groups. After stratification for center, patients were randomized as follows: arm A, 5-fluorouracil [450 mg/m2 intravenous (i.v.) bolus on days 15] and levamisole (150 mg orally for 3 days, every 14 days for 6 months) versus arm B, 6-S-leucovorin (100 mg/m2 i.v. bolus on days 15) followed by 5-fluorouracil (370 mg/m2 i.v. bolus on days 15), plus levamisole (as arm A), every 4 weeks for six cycles.
Results:
After a median follow-up of 6.4 years no significant difference was seen for either disease-free survival (58% versus 60%, not significant) or 5-year overall survival (68% versus 71%, not significant), respectively. Gastrointestinal toxicity (World Health Organization grade 3/4) was more frequent in arm B (8% versus 18%, not significant).
Conclusions:
In this trial the schedules used showed no statistically significant differences in terms of disease-free survival or overall survival in the treatment of colorectal cancer.
Key words: adjuvant chemotherapy, colon cancer
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Introduction |
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Patients and methods |
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Randomization and treatment
Eligible patients were centrally randomized within 60 days after surgery at three coordinating data centers in Genova for IST-Genova, GONO and GOPTAD, and in Parma for GOIRC and Forlì for IOR. Randomization lists were generated using permuted blocks of variable length in random sequence so that treatments were balanced within each center. Clinical center was the only stratification factor. The two randomization arms were: arm A, 5-FU [450 mg/m2 intravenous (i.v.) bolus for 5 days, every 28 days] or arm B, 5-FU (370 mg/m2 i.v. bolus for 5 days, every 28 days) plus 6-S-LV (100 mg/m2 i.v. bolus on days 15, every 28 days), for a total of six cycles. In both arms, patients received LEVA (150 mg p.o. over 3 days, every 14 days). Toxicity was defined according to WHO criteria. 5-FU dose modifications were required for hematological and gastrointestinal toxicity. For gastrointestinal toxicities (grade 2/3) a dose reduction of 25% was foreseen. Dose reductions of LV and LEVA were not allowed.
Follow-up
Patient data were collected on standardized trial forms and periodically sent to the Information Management Center. Investigators were required to notify the trial office of any serious unexpected adverse event. Before each course of therapy, patients underwent a physical examination and baseline hematological studies, including red and white blood cell count, renal function tests and serum carcinoembryonic antigen (CEA) measurements. These tests were conducted every 6 months for the first 2 years and then every year for a total of 5 years. During follow-up, colonoscopy or barium enema was recommended every year during the first 5 years. Chest X-ray and hepatic ultrasound or computed tomography scan were performed every 6 months for the first 2 years, then every year until the fifth year. Treatment following relapse was decided by the investigators. Follow-up was continued after 5 years without formal protocol requirement.
Study end points and statistical methods
INTACC aimed to recruit 725 patients per arm, which would give a >80% chance that the study could detect a 20% proportional difference in 5-year overall mortality between the two regimens (e.g. 60% versus 67%), based on a reported 3.5-year OS of 71% [3]. The final analysis was set when a total of 570 events had been observed. The primary end point was OS. Secondary end points included DFS and toxicity. Statistical analyses were based on the intention-to-treat principle. An interim analysis was planned and executed 2 years after recruiting the last patient to monitor study progression. A cut-off date of follow-up was set for 30 June 2000 to minimize the effect of potential bias in the reporting of events. KaplanMeier estimates were used to describe the time course of events in the treatment groups and the log-rank test was used for comparisons. Cox regression analysis was used to assess the relationship of the study end points to treatment after adjusting for a set of independent clinical variables, including ECOG performance status, histological grading, TNM (tumornodemetastasis) stage of disease, gender and site of disease. Age, in 10-year intervals, was used as a stratification factor. The final models were obtained by means of a backward procedure based on the likelihood ratio test (P <0.05 for inclusion and 0.10 for elimination). The presence of significant interactions between treatment and prognostic factors was assessed by including the appropriate interaction terms in the model. Estimates were derived from a multivariate Coxs model, with all prognostic factors included as covariates. From the total population of 1703 patients, 28 with missing information for one or more of the above factors were excluded. The P-value for heterogeneity of the hazard ratios was estimated by including interaction factors in the model. The proportional hazard assumptions were graphically checked with the log [log (survival function)]. SPSS 9.0 statistical package was used for the statistical procedures. For all tests, a two-sided P-value of <0.05 was regarded as significant.
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Results |
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Clinical outcomes
At 6.4 years [95% confidence interval (CI) 6.36.5] of median follow-up, a total of 571 of 1703 study patients had died. A similar number of deaths was seen in the two arms [296 (35%) versus 275 (32%)] (Table 1). Distribution of deaths by cause showed slightly more toxic deaths in arm A [5 (2.2%) versus 1 (0.4%)]. The most frequent causes of death were severe gastrointestinal toxicity (diarrhea, vomiting) associated with severe neutropenia, septic fever and other systemic compliances. The number of recurrences was similar in arm A (304, 36%) and arm B (284, 33%). The most common site of recurrence was the liver: 23% in both arms. The risk of a second primary tumor was similar in both arms (7% versus 8%). The most frequent second tumors were breast cancer (arm A versus arm B: eight versus two patients), colon cancer (arm A versus arm B: three versus six patients), gastric cancer (arm A versus arm B: two versus four patients) and myeloma (arm A versus arm B: two versus one patient). By KaplanMeier analysis, 5-year OS was not dissimilar between arms A (68%) and B (71%) (log-rank test, not significant). DFS at 5 years was 58% in arm A and 60% in arm B, respectively (Figure 1). In a subanalysis of both end points between treatments in patients stratified by disease stage (Dukes B23 versus C), no remarkable differences were seen. Multivariate Cox regression analysis did not show a significant association between treatment and either OS or DFS (Figure 2). Treatment B was associated with a non-significant reduction of 5% in the relative risk of death (hazard ratio 0.95; 95% CI 0.801.13; P = 0.57) and of 3% in the relative risk of relapse, second tumor or death (hazard ratio 0.97; 95% CI 0.831.13; P = 0.66). No significant interaction was seen between treatment and age, sex, the number of positive lymph nodes and tumor location, indicating the lack of any subgroup-specific treatment effect.
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Discussion |
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Both tested regimens were associated with a satisfactory clinical outcome in terms of DFS (58% versus 60%) and OS (68% versus 71%), rates that are comparable with results from the literature. Although 5-FU plus LV is currently accepted as standard treatment for colon cancer, the enigma concerning the value of LEVA in combination with 5-FU, or the value of 5-FU alone, remains unresolved. Some hypotheses can be proposed to explain the reasons for the equal activity of both regimens in this trial.
Numerous investigators have suggested that the DI of 5-FU may be important in determining the activity of adjuvant chemotherapy in colon cancer [15]. Zalcberg et al. [16] evaluating the DI of 5-FU in adjuvant treatment, showed that the benefit associated with the use of 5-FU and LEVA in Dukes C colon cancer is directly related to the planned total dose of 5-FU administered. This benefit was greater in trials where the largest dose of 5-FU was combined with LEVA compared with other 5-FU regimens. The conclusion of Zalcberg et al.s retrospective analysis suggests two hypotheses: first, the planned dosage of 5-FU is directly related to the results, when combined with LEVA; and secondly, the contribution of LEVA may not have had significant impact [16]. According to the Zalcberg hypothesis, the results of our trial can depend on the planned dose of 5-FU in arm A compared with that in arm B. It is possible that the effect of LV modulation was not evident due to counterbalancing by the 5-FU dose reduction in the experimental arm. A recent trial evaluated an adequate dose of 5-FU versus 5-FU plus LEVA and showed that 5-FU alone was as active as in combination with LEVA in prolonging survival in stage III colon cancer patients [17]. Recently, Tepper et al. [18] reported a large trial in patients with high-risk rectal cancer treated with adjuvant radiotherapy combined with 5-FU alone, 5-FU plus LEVA, 5-FU plus LV, and 5-FU plus LEVA and LV. No statistically significant advantage to any of the treatment regimens was found and data suggest that 5-FU is the only really effective agent in the adjuvant therapy [18]. In our trial, 5-FU was combined with LV in the experimental arm using the Machover schedule (the standard treatment in Europe), and we administered LEVA in both arms because at the onset of the trial it was not ethical to treat patients without 5-FU plus LEVA. In both arms, we administered chemotherapy for 6 months with the objective to increase the compliance of patients and to reduce the costs. Recent trials evaluating the duration of treatment (6 versus 12 months) have reported that 6 months treatment with 5-FU plus LV did not appear to be inferior to 12 months of treatment [10]. Haller et al. [19] (INT-0089) demonstrated that 6 months of 5-FU plus LV administered by weekly and monthly schedule is equal to 5-FU/LEVA for 12 months, and supported that 6 months of 5-FU plus LV is a better treatment and the value of LEVA is irrelevant [19]. Wolmark et al.s (NSABP-C04) [20] trial compared six cycles of 5-FU plus LV (Roswell Park schedule) to standard 5-FU plus LEVA (Moertels schedule) and double modulation of 5-FU plus LV and LEVA. The results did not reveal significant differences among the regimens. In 1992, in the INTACC trials, we used high doses of LV, but the optimal dose of LV is still under question. In particular, in an attempt to solve the question of LV dose and the role of LEVA, the Quick and Simple and Reliable (QUASAR) group designed a factorial (2 x 2) large-scale trial where the patients were randomly assigned either high-dose (175 mg fixed dose) or low-dose (25 mg fixed dose) LV, and either LEVA or placebo combined with 5-FU (370 mg/m2 for 5 days). The randomized comparison in the QUASAR group suggests that there are no survival differences between high- and low-dose LV or between LEVA and placebo [21]. Moreover, in a non-randomized trial, the QUASAR group evaluated the comparison between weekly and 4-weekly treatment schedules. The weekly regimen is less toxic than the 4-weekly regime, but there is no apparent difference in recurrence rates or OS [22]. In our trial, using the monthly schedule with LV plus 5-FU plus LEVA, the overall gastrointestinal toxicity, in particular diarrhea, stomatitis and vomiting, was statistically greater (32% versus 79%, arm A versus arm B; P <0.0000). Six patients died due to severe toxicity in the 5-FU plus LEVA arm, while one toxic death was related to the LV-combination treatment arm. In conclusion, our trial fails to demonstrate that the addition of LV to 5-FU plus LEVA is superior to 5-FU plus LEVA, both administered for 6 months. At this time, 5-FU plus LV is considered the standard adjuvant chemotherapy for colon cancer, although the new results that have emerged from advanced colon cancer treatment with CPT-11, oxaliplatin and oral fluoropyrimidine, justify new trials to increase and improve these results.
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Acknowledgements |
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INTACC investigators are listed below. GOIRC: V. Silingardi, A. Frassoldati, S. Zironi, Divisione di Oncologia Medica Ospedale Policlinico, Modena; C. Modonesi, II Divisione di Medicina Generale, Sez. Aggregata di Oncologia Medica, Arcispedale S. Anna, Ferrara; E. Corgna, Divisione di Oncologia Medica, Policlinico Monteluce, Perugia; L. Giustini, L. Acito, Servizio di Oncologia, Ospedale Civile, Fermo; A. Contu, N. Olmeo, G. Baldino, A. Pazzola, Oncologia Medica ASL N.1 Ospedale Civile, Sassari; A. Lalli, F. Fabbri, Servizio di Oncologia Presidio Ospedaliero, Giulianova; S. Barni, A. Ardizzoia, U. O. di Radioterapia e Oncologia, Monza; C. Rodinò, Servizio di Oncologia Ospedale Civile, Piacenza; V. Pieroni, G. Giacomini, U. Oncologia ASL 5, Jesi; G. De Signoribus, F. Giorgi, Servizio di Oncologia, Ospedale Civile, San Benedetto del Tronto; F. Pucci, F. Leopardi, R. Camisa, Oncologia Ospedale Maggiore, Parma; M. Lombardo, P. Di Stefano, Dipartimento di Oncologia ed Ematologia, Unità Operativa di Chemioimmunoterapia, Pescara; F. Recchia, S. De Filippis, Divisione di Medicina Oncologia, Ospedale Civile, Avezzano; F. Bassan, A. RosaBian, Servizio Autonomo di Oncologia Medica, Presidio Ospedaliero, Tiene; F. Cavicchi, M. Alessio, M. Sisani, Istituto di Medicina Interna e Scienze Oncologiche Policlinico Monteluce, Perugia; L. Di Lullo, Medicina Generale, Ambulatorio di Oncologia, Ospedale Civile, Isernia. Genova: C. Pucetti, M. Giusto, Servizio Oncologia Medica, Osp. Civile, Belluno; S. Monfardini, D. Crivellari, U.O. Oncologia Medica, Azienda Ospedale, Aviano; G. Accarpio, M. Mari, E. Paganini, G. Becchi, Sez. Aggregata Oncologia Pad. 5/3, A. O. Villa Scassi, Genova; S. Mammoliti, U.O. Oncologia Medica I, Istituto Nazionale per la Ricerca sul Cancro, Genova; A. Lavarello, Servizio Oncologia, USL 18-Ospedale, Genova; F. Brema, G. Pastorino, Servizio Oncologia, Ospedale S. Paolo, Savona; G. Bottero, V. Fusco, Divisione Oncologia, Ospedale S. Antonio, Alessandria; G. Orsi, D. Cocchis, Ospedale Civile, Fossano; A. Guglielmi, U.O. Oncologia Medica, Ospedale S. Martino, Genova. GONO: P. Pronzato, Divisione Oncologia Medica, La Spezia; G. Barsanti, M. Battistoni, Divisione Oncologia Medica, Lucca; P. Grezzi, M. Rinaldini, Divisione Oncologia Medica, Arezzo; R. Taviani, Divisione Oncologia Medica, Empoli; M. Aglietta, C. Volta, Divisione Clinica Medica, Novara; R. Algeri, Divisione Oncologia Medica, Grosseto; P. De Gennaro, Divisione Chirurgia, Bibbiena; I. Spinelli, Divisione Oncologia Medica, Massa-Carrara; M. Filidei, Divisione Medicina, Pontedera; G. Arcabasso, Divisione Medicina, Cecina; A. Carli, Divisione Chirurgia, Siena. GOPTAD: R. Antonacci, Oncologia Medica Università di Torino, Osp. San Luigi, Orbassano; C. Bumma, R. Berardo, Oncologia Medica, Osp. S. Giovanni Antica Sede, Torino; A. Boglione, Oncologia Medica, Osp. Gradenigo, Torino; A. Di Napoli, Medicina Interna, Osp. Molinette sede San Vito, Torino; M. Merlano, G. Grecchi, Oncologia Medica, Osp. S. Croce & Carle, Cuneo; G. Porcile, M. Destefanis, Oncologia Medica, Osp. San Lazzaro, Alba; O. Alabiso, R. Buosi, Oncologia Medica Università del Piemonte Orientale, Osp. Maggiore della Carità, Novara; M. Botta, B. Castagneto, Oncologia Medica, Osp. Santo Spirito, Casale Monferrato; V. M. Zampaglione, P. Sozzi, Medicina A, Osp. Degli Infermi, Biella; V. Sidoti, Oncologia Medica, Osp. Agnelli, Pinerolo; S. Di Prima, Oncologia Medica, Osp. Santa Croce, Moncalieri. IOR: D. Amadori, O. Nanni, P. Rosetti, Dipartimento di Oncologia Ospedale Pierantoni, Forlì; M. Marangolo, F. Zumaglini, Dipartimento di Oncologia Ospedale Civile, Ravenna; D. Tassinari, E. Pasquini, Divisione di Oncologia Medica Ospedale Infermi, Rimini; F. Artioli, M. Cesari, Unità Operativa di Oncologia Medica Ospedale Ramazzini Carpi; A. Gambi, L. Amaducci, Divisione di Oncologia Ospedale Civile per gli Infermi, Faenza; P. Alessandrini, G. Catalano, Unità Operativa di Oncologia Medica Azienda Ospedaliera S. Salvatore, Pesaro.
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Footnotes |
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References |
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