- Research article
- Open Access
- Open Peer Review
Pegylated liposomal doxorubicin (Lipo-Dox®) combined with cyclophosphamide and 5-fluorouracil is effective and safe as salvage chemotherapy in taxane-treated metastatic breast cancer: an open-label, multi-center, non-comparative phase II study
© Rau et al.; licensee BioMed Central. 2015
- Received: 12 January 2015
- Accepted: 13 May 2015
- Published: 21 May 2015
Anthracycline and taxane are classes of drugs that are frequently used in the adjuvant and palliative settings of metastatic breast cancer (MBC); however, treatment failure occurs in most cases. Limited data demonstrated favorable response in MBC after previous taxane-based treatment. The aim of this study was to evaluate the efficacy and safety of pegylated liposomal doxorubicin (Lipo-Dox®) used as part of a combination salvage therapy for patients with MBC whose tumors progressed during or after taxane-based treatment.
Patients with MBC who failed to respond to previous taxane-based treatments were recruited. Treatment with pegylated liposomal doxorubicin (40 mg/m2), cyclophosphamide (500 mg/m2), and 5-fluorouracil (500 mg/m2) was administered every 3 weeks. Tumor response to treatment was determined by using the Response Evaluation Criteria in Solid Tumor criteria version 1.0, and left ventricular ejection fraction was measured before and after treatment using echocardiography. Each patient was followed for 30 days after the last dose of study medication or until resolution/stabilization of any drug-related adverse event.
Forty-five patients were recruited. As of December 2012, the median follow-up duration was 29.8 months, the overall response rate was 41.9 %, the median progression-free survival was 8.2 months, and the median overall survival was 36.6 months for all treated patients. Grade 3/4 neutropenia, leucopenia, and neutropenic fever were observed in 14 %, 9 %, and 1 % of the cycles, respectively. Other non-hematologic adverse effects were mild to moderate and were manageable. No decrease in left ventricular ejection function was noted.
This regimen of combined of pegylated liposomal doxorubicin, cyclophosphamide, and 5-fluorouracil exhibited a promising overall response rate, progression-free survival rate, and overall survival rate, with a safe cardiac toxicity profile and manageable adverse effects. This regimen could be considered as a treatment option for patients with MBC whose tumors progressed during or after taxane-based treatment.
- Advanced breast cancer
- Pegylated liposomal doxorubicin
- Metastatic breast cancer
- Taxane failure
Breast cancer is now the most frequently diagnosed cancer among women in 140 of 184 countries and the most common cause of cancer death among women (522,000 deaths in 2012), especially in less developed countries. Since 2008, the incidence and mortality rate of breast cancer has increased by more than 20 % and 14 %, respectively . While the incidence of breast cancer remains highest in more developed regions, the mortality rate is much higher in less developed countries, primarily because early detection and access to treatment facilities are lacking. Although improvements in early detection and systemic therapy have significantly decreased recurrence and prolonged survival, metastatic breast cancer (MBC) is still a predominantly incurable disease [2–4]. With prolonged survival and tumor recurrence, serious problems emerge, including accumulated drug dosages that approach the upper limit of safety, therapy-related toxicity, and drug resistance. Consequently, there is an ever-increasing need for new drugs or combination regimens for the treatment of MBC.
Pegylated liposomal doxorubicin (PLD, Lipo-Dox®) is a formulation of doxorubicin in poly(ethylene glycol)-coated (stealth) liposomes. This formulation causes fewer cardiac events, has a longer half-life, and exhibits higher tumor tissue penetration compared to standard doxorubicin . O’Brien et al. reported that, compared to doxorubicin, PLD provides equivalent progression-free survival (PFS; 7.8 vs. 6.9 months, respectively) and overall survival (OS; 22 and 21 months, respectively) when used as the first-line therapy for MBC . As a maintenance therapy, the adverse effects of PLD are manageable and include bone marrow suppression, mucositis, and hand-foot skin reaction [6, 7].
Taxanes and/or anthracyclines are widely used as the initial therapy for breast cancer, as well as for adjuvant and palliative chemotherapy. Data are limited regarding effective treatment strategies for MBC that has recurred or progressed following taxane- and/or anthracycline-based treatment. A triweekly PLD-cyclophosphamide regimen has been reported to be effective and well tolerated as the first-line therapy for patients with metastatic or recurrent breast cancer [8, 9]. The aim of this study was to evaluate the efficacy and safety of a PLD-combined regimen as second-line treatment for patients with progressed MBC who had undergone a previous taxane-based treatment.
This study was an open-label, multicenter, non-comparative prospective phase II clinical trial performed from August 2005 to July 2010 following approval by the Institutional Review Board Committee at the Chang Gung Memorial Hospital, Taiwan.
Eligible patients included women with histologically proven MBC, presenting with at least one disease lesion measuring ≥ 20 mm in at least one dimension by conventional techniques or ≥ 10 mm by spiral computed tomography (CT) or magnetic resonance imaging (MRI). Enrolled patients were ≥20 years old with an Eastern Cooperative Oncology Group (ECOG) performance status ≤ 2 and had received a prior taxane-based chemotherapy regimen for metastatic disease. Biological criteria that were to be met before the first cycle of treatment were as follows: hemoglobin ≥ 10 g/dl, absolute neutrophil count (ANC) ≥ 1,500/μl, platelets ≥ 100,000/μl, total bilirubin ≤ 3.0 mg/dl, aspartate aminotransferase/alanine aminotransferase ≤ 2 × upper normal value, and creatinine ≤ 1.5 mg/dl. All patients received both oral and written information regarding the trial and provided written informed consent.
Exclusion criteria consisted of 1) a life expectancy of less than 3 months, 2) prior use of free anthracycline or PLD for MBC, 3) contraindication to anthracycline, fluorouracil (5-FU), or cyclophosphamide, 4) bone metastasis, 5) brain metastasis, 6) other malignancy except curative, treated non-melanoma skin cancer or cervical carcinoma in situ, 7) serious concomitant illness potentially aggravated by the study medication, including uncontrolled infection or active cardiac disease, 8) pregnancy or breast feeding, and 9) child-bearing potential unless a reliable contraceptive method is used throughout the treatment period and for 3 months following cessation of treatment.
Trial design and treatment
Although the typical chemotherapeutic regimen involves a sequence of monochemotherapy, we used a combination of three therapies to obtain a synergistic effect. All eligible subjects received cyclophosphamide (500 mg/m2) and 5-FU (500 mg/m2) intravenous infusion (IVF) over 1 h, followed by Lipo-Dox® (40 mg/m2) IVF over 1 h on day 1 of each 21-day cycle. Dose modifications were permitted for hematologic and non-hematologic toxicity. Complete blood counts were checked on days 1 and 8. If the absolute neutrophil count was lower than 500/mm3, administration of granulocyte-stimulating factors was allowed. Treatment continued until progression, unacceptable toxicity, or the patient’s decision to withdraw from the study.
Tumors were assessed within the 21 days preceding chemotherapy and after every 3 cycles of chemotherapy. Tumor response was determined by using the Response Evaluation Criteria in Solid Tumors version 1.0. Each patient was followed for 30 days after the last dose of study medication or until resolution/stabilization of any drug-related adverse event.
The primary endpoint was the overall response rate (ORR) of patients with MBC treated with Lipo-Dox® combined with cyclophosphamide/5-FU as a salvage treatment. The secondary endpoints included 1) PFS, defined as the time interval between the start date of treatment and the date of disease progression, death by any cause without progression, or the last follow-up without progression, 2) duration of response (DR), defined as the time interval between the onset of a clinical response and objective evidence of progression, death by any cause without progression, or last follow-up, and 3) OS, defined as the time interval between the start date of treatment and the date of death by any cause or last follow-up without death and the safety profiles.
At the end of the study, patients were categorized into evaluable and/or intent-to-treat (ITT) patient populations according to their termination status. The ITT population was defined as all patients exposed to at least one study regimen. The evaluable population was the subset of ITT patients who completed the baseline evaluation, who had at least one post-treatment evaluation, and who were exposed to at least three cycles of treatment.
Simon’s optimal two-stage design was used to determine the target patient number for this study. Drug treatment was considered inactive if the response probabilities were less than 20 %, while treatment was considered effective if response probabilities were greater than 40 %. ORR was assessed in both the evaluable and ITT population data sets; however, the main analysis was focused on the evaluable population. Efficiency was calculated as the number of responding patients divided by the number of all patients treated (i.e. ITT and/or evaluable patients). Descriptive statistics were used for the primary analysis, presented by a point estimate and 95 % confidence interval (CI) for the primary efficacy variable (ORR). The PFS, DR, and OS were evaluated using the Kaplan-Meier method.
All safety analyses were performed on the safety population, which was defined as all the ITT patients available for a follow-up evaluation of safety. Incidences of adverse events were tabulated by severity and relationship to the treatment. Treatment toxicity was evaluated according to the National Cancer Institute Common Terminology Criteria for Adverse Events, version 4.0.
Patients’ baseline characteristics
Median Age, years
ECOG performance status
Initial stage at diagnosis
Regional lymph nodes
Distant lymph nodes
Number of metastatic sites
ITT* (n = 45)
Evaluable (N = 43)
Treatment response in different populations
ITT population (N = 45)
Evaluable population (N = 43)
Estrogen receptor positive (N = 26)
Her-2 positive (N = 5)
CR, n (%)
0 (0.0 %)
0 (0.0 %)
0 (0.0 %)
0 (0.0 %)
PR, n (%)
18 (40.0 %)
18 (41.9 %)
12 (46.2 %)
1 (20.0 %)
SD, n (%)
18 (40.0 %)
18 (41.9 %)
11 (42.3 %)
3 (60.0 %)
PD, n (%)
7 (15.6 %)
7 (16.3 %)
2 (7.7 %)
1 (20.0 %)
NE, n (%)
2 (4.4 %)
0 (0.0 %)
1 (3.8 %)
0 (0.0 %)
Disease control rate
CR + PR + SD, n (%)
36 (80.0 %)
36 (83.7 %)
23 (88.5 %)
4 (80 %)
Objective response rate
CR + PR, n (%)
18 (40.0 %)
18 (41.9 %)
12 (46.2 %)
1 (20.0 %)
Response rate evaluated by site of metastasis
Number of responsive lesions
Number of evaluable lesions
Response rate (%)
Progression free survival and overall survival
ITT population (N = 45)
Evaluable population (N = 43)
PR Population (N = 45)
SD Population (N = 45)
Median PFS (95 % CI)
8.2 mo (6–10.8)
8.2 mo (6–10.8)
9.96 mo (8.03-17.38)
6.16 mo (3.9-16.95)
Median OS (95 % CI)
36.6 mo (23.8-45.8)
36.6 mo (23.8-45.8)
41.48 mo (23.21-NA)
36.62 mo (17.51-NA)
Specific toxicities, evaluated by cycles (total 284 cycles)
Change of left ventricular ejection fraction before and after treatment
Patients with Cardiovascular history
Previous exposure to anthracyclines
Recent improvements in screening and adjuvant therapies are responsible for the nearly 90 % 5-year survival rate for all breast cancer patients . Nonetheless, except for some cases of oligometastasis, MBC remains an incurable disease with a median survival of less than 2 years. As the first-line therapy, taxane-based regimens provide better response rates (RRs) and longer PFS than anthracycline-based combinations, with a median OS of 19.3 months . However, resistance to these drugs is common and once resistance develops, there is no standard palliative treatment.
As it is common practice to combine anthracycline, taxane, and targeted therapy for neoadjuvant or adjuvant treatments, alternative therapeutic options after recurrence are limited. Different drugs such as capecitabine, vinorelbine, gemcitabine, ixabepilone, and eribulin, either alone or in combination, have been reported to provide therapeutic benefit, including increased RR, PFS, and OS [12–19].
Although all these drugs can be effective when administered to taxane-pretreated patients, additional drug combinations are usually accompanied by increasing adverse effects such as neutropenia, peripheral neuropathy, and mucositis. Long-term adverse effects from previous treatments such as neuropathy from taxane, cardiomyopathy from anthracyclines, and pulmonary fibrosis from radiation may prevent further treatment with the above agents.
PLD is formulated with a polyethylene glycol coating that covers a liposome bilayer containing an aqueous doxorubicin core. Concentrations in tumor tissue can be several-fold higher than those in the adjacent normal tissue . PLD doses are effective in both elderly women with locally advanced or MBC  and in patients with advanced breast cancer, even those who have been heavily pretreated. Flegi et al. reported a retrospective study of single-agent PLD in the treatment of MBC. Treatment resulted in an ORR of 26 %, a PFS of 5.8 months, and an OS of 14.2 months . A recently published randomized phase 3 study comparing PLD with capecitabine as the first-line chemotherapy in elderly patients with MBC reported a median PFS of 5.6 versus 7.7 months (P = 0.11), and a median OS of 13.8 and 16.8 months (P = 0.59) for PLD and capecitabine, respectively. Both treatments demonstrated comparable efficacy and acceptable tolerance as first-line single-agent chemotherapies in elderly patients with MBC . In summary, evidence suggests that regimens including PLD as part of a combined therapy are efficacious and safe as a first-line treatment for MBC.
In the present study, all patients had previously received taxane for MBC, while only seven patients had previously received adjuvant anthracycline, and all other patients were naïve to anthracycline, cyclophosphamide, and 5-FU. In the majority of cases, hematologic toxicity was managed by dose reduction and symptomatic treatment with hematopoietic growth factor. The most common non-hematologic toxicities were hand-foot skin reactions (all grades, 21 %; grade 3/4, 1 %), while other adverse effects were mild and manageable. The incidence of severe toxicity was low and resulted in only two patients dropping out of the study. The mean number of treatment cycles received was 5.7 and 5.9 for patients in the ITT and evaluable populations, respectively. The efficiency evaluation was almost the same for these two groups; the ORR was more than 40 % in both populations, and the DCR was more than 80 % in both the groups. Similarly, the median PFS and OS were identical (8.2 months and 36.6 months, respectively).
PLD is suspected to have the advantage of low cardiac toxicity. After following 141 patients, Gill et al. reported that only one patient had a clinically significant decrease in LVEF at a cumulative dose of 1670 mg/m2, suggesting that this routine surveillance of LVEF may not be necessary in the absence of other risk factors . Similarly, the current study found that there was no significant decline in LVEF after treatment, including patients who had a history of cardiovascular disease or who were treated with anthracycline prior to the study. To evaluate the effect of PLD as adjuvant chemotherapy, Rayson et al. compared the concurrent administration of trastuzumab and PLD with the sequential administration of anthracycline and trastuzumab as adjuvant chemotherapy. Of the 179 randomized patients, the incidence of cardiac toxicity was 18.6 % in the anthracycline group, compared to 4.2 % in the PLD group .
The major weak point of our study was the small sample size and inadequate information on Her2 status, which prevented us from performing further efficiency analyses in the different subgroups. As there is no reported aggravated cardiac toxicity associated with PLD, adding PLD to Her2-targeting therapy is an attractive option. The GEICAM/2004-05 study combined PLD with cyclophosphamide and trastuzumab as the first-line therapy for Her2-positive MBC patients. Among the 48 evaluable patients, the ORR was 68.8 %, the median time-to-progression (TTP) was 12 months (95 % CI: 9–15.1 months), and the median OS was 34.2 months (95 % CI: 27.2–41.2 months). There were no reports of symptomatic heart failure .
Several different combinations of PLD have also been reported, including PLD and gemcitabine, which resulted in an ORR of 50 %, and a median PFS and OS of 8.8 months and 19 months, respectively. However, with this combination, seventy-five percent of the patients experienced grade 3 or 4 treatment-related toxicity . PLD in combination with docetaxel was evaluated in two separated studies, and an ORR of 35 %, a median TTP of 9.8 months, and a median OS of 20.6 months were observed, but the incidence of grade 3 and 4 neutropenia was higher than 50 % in each study [28, 29]. Finally, PLD combined with oral vinorelbine results in an ORR of 52 %, and a median PFS and OS of 8.8 months and 24.8 months, respectively. However, symptomatic grade 3 cardiotoxicity and febrile neutropenia occurred in 15 % and 47 % of the patients, respectively [30, 31]. In summary, PLD used as combination therapy results in different treatment efficacies and produces different adverse effects, depending on the drug with which it is combined. Compared to these studies, our study had the lowest toxicities, especially hematologic toxicity, but the determined efficacy was the same.
In conclusion, the regimen of PLD, cyclophosphamide, and 5-FU combination was associated with promising ORR and PFS, a safe cardiac toxicity profile, and manageable adverse effects. This regimen could be considered as a treatment option for patients with progressed MBC who have undergone taxane-based treatment.
We would like to thank TTY Biopharma, Taiwan for providing a grant to support this study.
The funding of this study was supported by TTY Biopharma at Taiwan.
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