1 University Medical Center Nijmegen, Department of Medical Oncology, Nijmegen; 2 Vrije Universiteit Medical Center, Department of Pulmonology, Amsterdam, The Netherlands
Received 4 December 2001; revised 28 February 2002; accepted 26 March 2002
Abstract
Background:
The survival in untreated small-cell lung cancer (SCLC) is <3 months. Prognosis has improved with chemotherapy, but remains poor. One of the issues concerning current chemotherapy is whether there is any benefit of increasing chemotherapy dose or dose intensity (DI).
Design:
In the present review, 20 randomised studies, published in the period 19802001, in which dose or DI of chemotherapy in SCLC were the only variables tested, are analysed. The studies were categorised as follows: (i) number of cycles (treatment duration); (ii) dose per cycle; (iii) interval between cycles (dose densification); and (iv) a combination of these variables.
Results:
(i) With treatment duration reduced to three to six cycles, median survival time (MST) was 2 months shorter, most evident in patients showing a (complete) response to initial chemotherapy. (ii) An improved survival was observed in two out of five high-dose studies. (iii) Survival was increased by 0.6 to 6.2 months in all four densification studies. (iv) Survival was not improved in studies that used dose-escalation and/or -densification in combination with a reduced number of cycles. The sample sizes were too small to be conclusive in most of the individual trials. The median of the MSTs in the 20 trials taken together was 9.8 months for the standard arms and 11.5 months for the intensified arms (i.e. more cycles, higher dose per cycle and/or shorter intervals). After omitting the two trials with reduced number of cycles in the so-called high-dose arm, the median of MSTs was 8.7 and 11.5 months, respectively. There was only a slight improvement (1%) in 2-year survival for all trials taken together. However, when only taking high-dose and dose-densified chemotherapy trials into account, the difference in median 2-year survival became 19% (12% versus 31%).
Conclusions:
The above classification facilitates our understanding about doses of chemotherapy and it makes us appreciate the relevance of the individual determinants. It appears that the number of cycles, dose level, dose density, cumulative dose and DI are all important factors for improving survival. Intensification of chemotherapy still deserves further research in SCLC.
Keywords: chemotherapy, dose, dose intensity, review, small-cell lung cancer
Introduction
Survival in small-cell lung cancer (SCLC) is only 512 weeks without treatment. Prognosis has clearly improved, to a median survival time (MST) ranging from 718 months, with combination chemotherapy, although long-term survival remains poor, with <5% of patients being alive at 5 years [1]. Currently, the most frequently used chemotherapy combinations are CAV (cyclophosphamide, doxorubicin, vincristine), CAE or CDE (cyclophosphamide, doxorubicin, etoposide), (V)-ICE (vincristine, ifosfamide, carboplatin, etoposide) and EP (etoposide, cisplatin). New active drugs against SCLC include the taxanes and topoisomerase I inhibitors. Studies with these new drugs are underway.
In fact, little progress has been made since the introduction of combination chemotherapy. The only clear improvement of treatment outcome in terms of survival benefit that has been achieved since is by the introduction of prophylactic cranial irradiation and consolidation chest irradiation, which increases long-term survival by 5% to 10% for patients with a complete (CR) or partial response (PR), especially in those with limited disease (LD) [2, 3]. For both, a meta-analysis was needed to demonstrate the beneficial role of local treatment added to systemic treatment
One of the continuing debates concerning combination chemotherapy for SCLC is its optimal dose. The importance of dose intensity (DI) was first demonstrated by Hryniuk and Bush [4] for chemotherapy in breast cancer, and since then this concept has been applied to many other tumours. DI is defined as the chemotherapy dose per unit time and is expressed as mg/m2/week. DI is generally used as a relative DI, e.g. the ratio of the DI of an experimental versus a standard regimen or the delivered versus planned DI of a specific regimen. Importantly, the reported DI does not take into account discontinuation of chemotherapy, as it is calculated for only those cycles that are actually delivered. In addition to DI, the cumulative dose may contain valuable information. The cumulative dose is the product of dose per cycle and number of cycles of chemotherapy.
The continuing confusion about the relevance of chemotherapy dose and DI in SCLC is partly due to the fact that the above-mentioned distinction between dose and DI has not always explicitly been considered. This may lead to comparisons of high-dose studies with dose-dense studies [5]. In this review, we analysed whether a higher than standard dose (cumulative or per cycle) and/or higher than standard DI improves survival.
Materials and methods
Studies were searched for by Medline. All publications in the English language between 1980 and September 2001 were examined by the hits small cell, lung cancer, chemotherapy and randomised. In addition, references of relevant articles were reviewed. All studies in which dose or DI of chemotherapy in SCLC were the only variables tested were included. Studies that performed comparisons between different drugs [6] were excluded from this review. Furthermore, studies only evaluating the impact of prophylactic growth factors on febrile complications were excluded.
Studies concerning dose and DI were categorised by number of cycles (treatment duration), dose per cycle, interval between cycles (dose density) and a combination of these variables (Table 1).
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(i) Number of cycles: different treatment durations
Several investigators have attempted to determine the optimal number of cycles of chemotherapy to be delivered as first-line treatment, with respect to survival [714]. In these studies, the same drugs were delivered at the same dose per cycle (apart from one, in which the dose in the maintenance phase was slightly lower [9]) and the same interval between cycles, but for a different number of cycles (Table 2).
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The trial by the Cancer and Leukaemia Group B (CALGB) is difficult to interpret, because three separate randomisations were involved [7]: the first, for the type of chemotherapy, including cyclophosphamide, methotrexate and/or vincristine; the second for with or without cranial irradiation; and the third for maintenance chemotherapy until relapse or observation. In 46 LD patients with a CR, survival was significantly improved with 10 months by maintenance chemotherapy (P = 0.01).
In the trial by the Eastern Cooperative Oncology Group (ECOG), 577 patients with extensive disease (ED) were randomised in a 2 x 2 factorial fashion to assess the impact on survival of standard CAV compared with alternating CAVHEM chemotherapy (CAVhexamethylmelamine, etoposide, methotrexate) [8]. In addition, 86 patients with a CR after six to eight initial cycles of chemotherapy were randomised to maintenance chemotherapy (total treatment duration of 28 cycles) or to observation until progression. Patients without CAV maintenance therapy had shorter time to progression (TTP), whereas patients on CAVHEM with no maintenance therapy survived for longer than those with maintenance therapy.
In four studies, it was shown that five or six cycles was not worse than 12 or 14 cycles, at least not when considering overall and long-term survival [912]. However, TTP and MST appeared to be reduced for the short treatment arm [10, 12]. This latter should be offset against a documented worse quality of life with prolonged treatment [10]. Importantly, in one study it was noted that in the short-treatment arm there was a longer total off-chemotherapy time, taking second-line chemotherapy into account [12]. The Medical Research Council (MRC) reported that for the subgroup who were in CR after initial chemotherapy, there was a suggestion of longer survival, with 12 cycles of chemotherapy (MST 6.9 versus 9.7 months, P < 0.05, log rank test) [10].
The trial reported by Spiro et al. [13] for the Cancer Research Campaign is of particular importance, as it addressed the role of second-line chemotherapy in advance. In this study with a 2 x 2 factorial design, patients were assigned at registration to four or eight cycles, and to second-line chemotherapy or symptomatic therapy in case of progression. Based on the initial randomisation, the overall survival was not significant different (P = 0.085). However, four cycles of chemotherapy alone, without second-line chemotherapy at relapse, gave inferior survival compared with the other three arms, which were equivalent in outcome (MST 6.9 versus 9 months, P < 0.01). Importantly, the policy of second-line chemotherapy was difficult to implement, because patients and physicians were reluctant to restart chemotherapy.
In another trial by the MRC, patients were randomised to three or six cycles [14]. Again, TTP was shorter with the reduced number of cycles, and now, as toxicity and quality of life were similar for both arms, the investigators recommended six cycles of chemotherapy as the optimal standard. Furthermore, in the light of the comparison of three versus six cycles, the authors emphasised that with current chemotherapy regimens, almost all of the potential action is achieved during the first three cycles, indicating that these three cycles should be given without interruption or modification.
In conclusion, most of these maintenance trials did not reveal significant survival differences [714], which is reason for a generally rather sceptic view concerning prolonged treatment. However, some studies did show a trend for improved overall survival or showed a significantly improved MST and/or TTP for the maintenance arm. In fact, a significant increase in TTP was observed in all but one of the studies, in which >100 patients were randomised. When pooling the data from the various trials together, it becomes even more obvious that the direction of outcome is quite comparable for all studies. That is, both the TTP and the MST are 2 months longer with prolonged treatment (Figure 1). In other words, more drugs apparently increases efficacy, even despite the use of second-line chemotherapy.
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Ihde et al. [17] evaluated the efficacy of higher doses of etoposide and cisplatin. Patients received the higher doses in the first two cycles, while in the third and fourth cycle all patients received standard dose EP, at 3-weekly intervals. Patients with a CR after four cycles continued on EP, while the remaining received in most instances CAV in cycles 58. Considerable excess toxicities were manifested in patients who received high-dose EP, and again no survival difference was seen.
Arriagada and colleagues [18] reported on a prospective study in 105 LD patients randomised to higher versus lower doses of cisplatin and cyclophosphamide in the first cycle only. All patients received the lower doses of cisplatin and cyclophosphamide, and the same doses of doxorubicin and etoposide from the second through the sixth cycle of chemotherapy at 4-weekly intervals. Enrolment was prematurely closed after a planned interim analysis due to the favourable outcome in the intensified arm: 2-year survival rate 26% versus 43% (P = 0.02).
There is only one randomised trial in which the benefit of high-dose chemotherapy requiring bone marrow transplantation was evaluated [19]. In contrast to the studies mentioned above, this concerns a late intensification study. First, three cycles of standard-dose methotrexate plus CAV were given, followed by two cycles of standard-dose EP. Then, 45 responding fit patients were randomised to a last cycle of cyclophosphamide, etoposide and BCNU at conventional or intensified dose. In the intensified arm the CR rate increased from 39% before to 79% after the high-dose cycle, while in the standard arm the last conventional-dose cycle did not modify the response rate. Despite the clear-cut doseresponse relationship and an improved relapse-free survival (2.3 versus 6.5 months, P = 0.002), median overall survival showed only a trend for improvement (12.7 versus 15.7 months, P = 0.13).
Several limitations of the four early intensification studies are the small number of patients included, and the relative moderate dose increment, ranging from 16% to 68% per cycle for a few number of cycles only. In the light of the three negative studies, the results of the French study are both impressive and surprising. Some have hypothesised that the benefits of high-dose chemotherapy may be restricted to LD patients. The lack of significance of the late intensification trial may be due to the low number of patients randomised, an imbalance at the time of randomisation with more patients in the conventional arm having CR (55% versus 39%), and a high number of toxic deaths in the intensified arm compared with the standard arm (17% versus 0%). Importantly, these studies were all performed before the haematopoietic growth factor era. Despite these drawbacks, an improved overall or relapse-free survival was observed in two out of five high-dose studies, demonstrating the correctness of the concept of dose escalation.
(iii) Interval between cycles: densification of chemotherapy
The impact of shortening chemotherapy intervals on survival has also been tested [2023] (Table 4). In these trials the same drugs were delivered at the same dose per cycle and the same number of cycles, with the only variable being the interval between cycles. Cumulative doses were planned to remain the same, while DI was increased in the experimental arm due to the shorter treatment duration.
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In the first trial, 65 patients were randomised to six cycles of V-ICE alone or with G-CSF [20]. Prophylactic cranial irradiation was given after cycle 1 and thoracic irradiation after cycle 3. There was no fixed dose interval: in both arms re-treatment was given as soon as blood counts had recovered. Thus, in both arms the chemotherapy had to be administered at the shortest possible interval to ensure that the difference in DI would be attributable to G-CSF only. Dose reductions were not permitted. DI was expressed relative to standard 4-week V-ICE. The G-CSF arm received a small but significantly higher DI than the control group (1.18 versus 1.25 over all cycles, P = 0.03). Despite the small difference in DI, i.e. a relative increase of 6%, the 2-year survival was increased for the G-CSF arm (15% versus 32%, P < 0.05).
In a trial using weekly chemotherapy, 63 patients with ED SCLC were randomised to CODE (cyclophosphamide, vincristine, doxorubicin, etoposide) alone or with G-CSF [21]. Treatment was delayed for 1 week or more if white blood cell counts were <1 x 109/l or if platelet counts were <30 x 109/l. Dose reductions were not permitted. With G-CSF, chemotherapy could be delivered more at the time the next cycle was planned, resulting in an increased delivered DI over all cycles (72% versus 84% of the planned DI, P = 0.03) with a significant improvement in 2-year survival of 7% versus 31% (P = 0.0004), including in the multivariate analysis (P = 0.03).
In sharp contrast, in another trial with a comparable design, but using a different chemotherapy regimen, the addition of G-CSF did not result in an increase in delivered DI [24]. For this reason, this trial is not included in Table 4.
In the trial by Steward et al. [22], patients were randomised to six cycles of V-ICE at fixed intervals, either every 3 weeks or every 4 weeks. A second randomisation (2 x 2 factorial) was made to granulocytemacrophage CSF (GM-CSF) (days 417) or placebo. The primary objective was to determine whether GM-CSF could reduce the incidence of febrile neutropenia. Survival was a secondary endpoint. Patients with CR were offered prophylactic cranial and/or thoracic radiotherapy at the end of chemotherapy. In total, 299 patients were assessable. Importantly, the feasibility of 3-weekly chemotherapy was not dependent on the use of GM-CSF. The change in policy to deliver 3- instead of 4-weekly chemotherapy caused an increase in actually delivered DI of 26%. There was no significant difference in the total dose of chemotherapy delivered in the two arms. The densified treatment resulted in an improvement of 15% in 2-year survival rate and of 3 months in median survival (P = 0.0014). This difference remained significant after adjusting for additional prognostic variables in a Cox regression analysis, and the magnitude of the difference was comparable for LD and ED patients.
The MRC has recently also reported a large randomised trial in which the impact of shortened therapy interval on survival was assessed [23]. In total, 403 patients were randomised to six cycles of CAE chemotherapy given over 3 days at 2-week intervals with the addition of G-CSF, or to the same chemotherapy but at the standard 3-week intervals and without G-CSF. Patients with LD were offered thoracic radiotherapy after chemotherapy. The actually received DI was 34% higher in the intensified arm, while the total amount of chemotherapy delivered was similar in the two arms. CR rates were 40% versus 28%, in favour for the densified arm (P = 0.02). There was a survival benefit for the densified arm with an increase in survival at 1 year of 8%, at 2 years of 5% and in median survival of 0.6 months (P = 0.04). Subgroup analysis showed that the survival advantage for ED patients was as large as for LD patients.
In conclusion, median and 2-year survival was improved in all studies that used densification as the only variable [2023].
(iv) Combination of variables: chemotherapy for different number of cycles at different dosages and/or at different treatment intervals
Three trials fit into this category, each with a different study design (Table 5).
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In the randomised trial by Pujol et al. [26], the impact of an increased dose per cycle for a reduced total number of cycles delivered at the same interval was evaluated. High-dose chemotherapy of cyclophosphamide, epidoxorubicin, etoposide and cisplatin with rhGM-CSF support for four cycles was compared with a standard-dose regimen with the same drugs given for six cycles, both at 4-weekly intervals. Planned cumulative doses of the drugs were the same in both arms (except for cisplatin: 80% in the high-dose arm), but DI was planned to be increased by 50% due to the shorter treatment duration. At a planned interim analysis, 125 patients were included, after which it was decided to close the accrual. The cumulative doses of actually delivered chemotherapy were significantly lower in the high-dose arm (84% of planned in standard-dose arm versus 75% in high-dose arm, P < 0.05). The actually delivered DI was not reported. The CR rate was 38% for the standard-dose arm and 22% for the high-dose arm (P = 0.05). Patients in the high-dose arm had a significant reduced TTP with a shorter MST of 2 months and reduced 2-year survival of 10% (P = 0.0005).
The European Organisation for Research and Treatment of Cancer (EORTC) recently performed a trial in which patients were randomised to standard-dose CDE chemotherapy given at 3-week intervals for five cycles or intensified CDE chemotherapy given at 125% of the standard dose at 2-week intervals for four cycles with support of G-CSF [27]. By the design of the study the planned cumulative dose was intended to be the same for both treatment arms, with an increase in DI of nearly 90% in the intensified arm. The actually delivered increase in DI was 70%, while the delivered cumulative dose was comparable for both arms. However, dose intensification of CDE chemotherapy by dose-escalation and treatment-densification did not result in improved survival, with an MST of 12.5 months for the standard arm and 12 months for the intensified arm (not significant), possibly due to the reduced number of cycles.
In conclusion, it may be hypothesised that the small benefit from dose-escalation and/or densified chemotherapy does not seem to outweigh the negative impact of the reduced number of cycles.
Median of the MSTs
In Figure 2A, the MSTs of the intensified arms are plotted against the MSTs of standard-dose arms. For the categories (i)(iii), the MST of the intensified arms are generally located above the MST of the standard-dose arms.
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The median of the MSTs of all 20 randomised trials is 9.8 months (range 5.815 months) for the standard arms and 11.5 months (range 6.418 months) for the intensified arms. The difference becomes even more striking when the data for the two trials in which the so-called high-dose arms in fact used a reduced number of chemotherapy cycles [26, 27] are omitted, with a median of MSTs of the remaining 18 trials of 8.7 months (range 6.715 months) and 11.5 months (range 6.818 months), respectively.
Median of the 2-year survival rates
The 2-year survival rates were available for 17 trials. Figure 2B shows the 2-year survival rates of the intensified arms against the 2-year survival rates of standard-dose arms, which were improved by intensified chemotherapy in 12 of 17 trials.
In category (i), the median of 2-year survival rates is 7% (range 5% to 24%) in the short arm versus 6% (4% to 28%) in the maintenance arm (Table 2); in category (ii), 12% (range 2% to 26%) in the standard-dose arm versus 20% (range 2% to 43%) in the high-dose arm (Table 3); and in category (iii), 12% (range 7% to 18%) in the standard arm versus 32% (range 13% to 33%) in the densified arm (Table 4).
The median of the 2-year survival rates of the available 17 randomised trials is 10% (range 2% to 26%) for the standard arms and 11% (range 2% to 43%) for the intensified arms. When omitting the data for the two trials in which the so-called high-dose arms in fact used a reduced number of chemotherapy cycles [26, 27], the median of 2-year survival rates is 9% (range 2% to 26%) and 11% (range 2% to 43%), respectively. Importantly, for category (ii) plus (iii), the difference in median of 2-year survival rates is 19% (12% versus 31%).
Discussion
Despite the conducting of clinical trials in SCLC over >20 years, doubt about the relevance of chemotherapy intensification still exist. Cohen et al. [28] were the first to report a benefit of increased chemotherapy dose, but in this study a comparison between low and standard dose was made. Currently, the more critical issue is whether further chemotherapy intensification, beyond the standard, will improve efficacy.
Variations in cumulative dose and DI can be achieved by differences in the dose per cycle, the number of cycles and/or the intervals between cycles. The impact of dose escalation may not necessarily be the same as that of dose densification. At present, a total of 20 randomised trials have been published in SCLC, in which the number of cycles, dose per cycle, interval between cycles, cumulative dose and/or DI were changed while the chemotherapy regimens were kept the same. A classification based on each of these five variables may give more insight, and may be helpful for making future directions (Tables 1 and 6).
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The delivery of higher initial doses could prevent the emergence of chemo-resistant tumour cells, while late intensification may be attractive because patients may be selected by their response to the induction regimen. Indeed, in two out of five dose-escalation studies, an improved overall or relapse-free survival rate was observed. Trials with more patients are warranted.
Particularly for a rapidly dividing tumour like SCLC, the administration of chemotherapy at shortened intervals may also be a rational approach. In all studies that used densification as the only variable, survival was clearly improved, with an increase in median of MSTs of 2.7 months [2023]. The maintained survival difference at 2 years indicates that dose densification also increased the curative potential of the densified regimens. This implies that research should continue on maximising dose densification.
When appreciating the impact on survival of each of the five discussed variables, the outcome of the remaining three trials may even become predictable [2527] (Table 6). In one trial, more cycles were given at a reduced interval but at a lower dose in the experimental arm, leading to an equivalent cumulative dose and DI for both arms, and also to an equivalent survival [25]. Pujol et al. [26] administered a higher dose per cycle for a reduced number of cycles in the experimental arm, while keeping the interval the same. The delivered DI was increased, but the cumulative dose was reduced in the so-called high-dose arm. In concordance with the lower number of cycles and the reduced cumulative dose, survival was worse in the high-dose arm. Recently, Tjan-Heijnen et al. [27] reported on the results of a randomised EORTC trial in which high-dose chemotherapy was given at shorter intervals for a reduced number of cycles in comparison with the conventional dose arm. The survival curves were completely overlapping. By extrapolating from the discussed trials, it may be hypothesised that the small benefit from dose escalation and/or densified chemotherapy do not outweigh the negative impact of the reduced number of cycles.
Although the trials are rather different in design, we also combined all data for the sake of simplicity. For all trials together, the MST was improved by 1.7 months, and after omitting the two high-dose trials with a reduced number of cycles in the high-dose arm, the MST was improved by 2.8 months. There was only a slight improvement in 2-year survival of 1% when all trials were taken together. However, when only taking high-dose and dose-densified chemotherapy trials into account, the difference in median 2-year survival was 19%.
How can we then explain the lack of significance in the majority of the trials? The low number of patients randomised certainly plays a role. To find a 2-month improvement in MST for a MST of 9 months in the control arm the required sample size is 419 patients per arm, taking 3 years accrual and 2 years of follow-up into account (Table 7). In 12 of 20 included trials, <200 patients were randomised. In case of 200 patients being randomised (100 per arm), an increase in MST from 9 to 14 months is detectable. In this situation, the power to detect a difference smaller than 5 months is <80%, and the power to detect a difference of 2 months is only 18%. However, it is totally unreasonable to expect such a huge difference (5 months). Chute et al. [30] reported that in 20 years of North American phase III trials, the MST in ED SCLC had improved by 2 months, as was also seen in the population-based Surveillance, Epidemiology and End Results (SEER) database.
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As both a shorter interval and a higher dose may be relevant, an additional question emerges: do haematopoietic growth factors during standard dose chemotherapy improve survival, by preventing dose reductions and delays? In none of the reported trials evaluating the use of haematopoietic growth factors was an increase in survival reported [21, 22, 24, 3135]. But again, as survival was seldom an endpoint, the number of patients included may have been too low to detect a small survival difference. A meta-analysis would be needed to adequately address the role of haematopoietic growth factors during standard-dose chemotherapy. Importantly, non-haematological toxicities such as increased creatinine concentration also prevented an increase in the relative DI (and thus of survival) in the G-CSF arm in one study [24], stressing that not all chemotherapy regimens are suitable for dose intensification.
In conclusion, the above classification improves our understanding: from these randomised studies it can be learned that apparently the number of cycles, the dose per cycle, the interval between cycles, the cumulative dose and the DI are all relevant for improving survival. However, as dose densification and escalation seem to improve survival only modestly, research should also focus on alternative approaches in the treatment of SCLC.
Acknowledgement
We like to thank Dr T. M. De Boo, statistician, for his comments on the number of patients used in the various trials.
Footnotes
+ Corresponding author: Dr V. C. G. Tjan-Heijnen, University Medical Center Nijmegen, Department of Medical Oncology, PO Box 9101, 6500 HB Nijmegen, The Netherlands. Tel: +31-24-3615215; Fax: +31-24-3540788; E-mail: V.Tjan{at}onco.azn.nl
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