Introduction
Metastatic breast cancer (MBC) is an incurable but treatable disease. Thus, it is crucial to achieve disease control with preservation of quality of life (QoL) [
1]. In the last decades low-dose metronomic chemotherapy (LDMC) gained increasing popularity [
2,
3]. LDMC is defined as a continuous administration of cytotoxic drugs at low doses, distinctly lower than the maximum tolerable dose (MTD) of conventional chemotherapy (CCT) [
4]. Consequently, compared to MTD the lower doses of chemotherapeutic drugs may induce less adverse events like myelosuppression, mucositis or hair loss [
5‐
7]. It is assumed that LDMC is not simply a different way of administering chemotherapy but a truly new treatment option [
3,
8,
9]. This alternative strategy has been used especially in elderly patients, not eligible for a CCT [
8]. The orally available and well-established cytostatic agents like cyclophosphamide (CTX), methotrexate (MTX), vinorelbine (VRL) and capecitabine (CAPE) are suited for metronomic chemotherapy. The best experience about LDMC arises from phase II studies, however phase III studies are still lacking. Furthermore, to the best of our knowledge, there is insufficient experience regarding the efficacy of metronomic chemotherapy, compared to CCT in MBC.
In this retrospective case–control study, the efficacy of metronomic administered CTX/MTX and CCT was compared in matched pairs and subgroup analyses were performed to define patients in which LDMC might be a more effective treatment option.
Methods
MBC patients receiving LDMC with oral CTX (50 mg daily) and MTX (2.5 mg every other day) at the Department of Gynecology and Obstetrics of the University Medical Center Mainz, Germany between 2009 and 2018 were selected for this retrospective analysis as previously described [
10]. Each LDMC patient was matched with two patients, who received CCT, if matching criteria (measurable metastatic disease, age at start of therapy, number of chemotherapy lines and different metastatic sites as well as hormone receptor (HR) status) were met. No antiemetic treatment was routinely given to patients in the LDMC group. In the CCT group only patients without therapy termination due to toxicity were included. No concomitant treatment like radiotherapy, endocrine or targeted therapy was allowed. HER2-positive patients and patients with presence of additional cancer were excluded.
Primary endpoint was disease control rate longer than 24 weeks (DCR). DCR included stable disease (SD), partial response (PR) and complete response (CR). Secondary endpoints were progression-free survival (PFS), duration of response (DoR), as well as DCR and PFS in subgroups. The DoR was defined as the time from documentation of tumor response to progression disease (PD) or death. The therapy efficacy was assessed using the standard clinical and imaging methods. For subgroup analyses we used the a priori determined matching criteria to obtain comparable populations of same size. Thereby, we stratified the patients by age at start of LDMC/CCT (younger: ≤ median age vs. elderly: > median age), the number of chemotherapy lines (non-heavily pretreated: ≤ 2 chemotherapy lines vs. heavily pretreated: > 2 chemotherapy lines), number of different metastatic sites (no multiple metastases: ≤ 2 different metastatic sites vs. multiple metastases: > 2 different metastatic sites) and by HR status (HR-positive: oestrogen/progesterone positive and HER2-negative vs. triple-negative). SPSS (statistical software system, version 23.0. IBM Corp., Armonk, NY, U.S.) was used for statistical analyses. Patient characteristics and therapy response (DCR and therapy response in subgroups) were analysed by applying a Fisher’s Exact test. For PFS and DoR analysis Kaplan–Meier estimator was used. The Log-rank test was used for the comparisons of survival curves between LDMC and CCT group. A Cox regression model was used to estimate the hazard ratio (HR) and 95% confidence interval (CI) in the analysis of PFS and DoR. All tests were two-sided and p < 0.05 was considered as statistically significant. Written informed consent was obtained from all patients included in the study.
Discussion
In this retrospective case–control study 120 MBC patients were evaluated regarding the efficacy of the chemotherapy treatment. The primary endpoint DCR did not differ significantly between LDMC and CCT group (30.0% vs. 22.5%,
p = 0.380). The impact of metronomic CTX/MTX in our cohort of HR-positive and HER2-negative MBC patients as measured by DCR after 24 weeks of treatment was in line with previous studies [
11‐
13]. Gebbia et al. [
6] observed a higher PR rate in the cohort of patients with the combination CTX/MTX as compared to that treated with CTX alone (20% vs. 14%,
p = 0.45). The median PFS was 12.0 weeks in the LDMC as well as in the CCT group (
p = 0.218). Furthermore, DoR (31.0 vs. 20.5 weeks,
p = 0.383) and therapy response (37.5% vs. 30.0%,
p = 0.417) failed to show any significant differences between LDMC and CCT group. Moreover, the rate of treatment response may also depend on patient characteristics like age, metastatic spread, HR status as well as previous treatment. In the subgroup of younger patients, DCR was documented in 40.0% patients in the LDMC group and in 25.0% patients in the CCT group (
p = 0.249). According to current recommendations for treatment of MBC, LDMC is primarily intended for elderly and frail patients, who are not suitable for conventional dosis of chemotherapy [
14‐
16]. However, we have shown that LDMC can also be a treatment option for younger patients. Based on previous data from phase II studies, LDMC regimens provide promising results in the first-line setting with a clinical benefit rate (CBR) of up to 78% and a median time to progression (TTP) of up to 22 months [
17‐
19]. Among the non-heavily pretreated subgroup, 33.3% LDMC patients and 26.2% CCT patients showed DCR (
p = 0.568). More importantly, it is well established that the duration of disease control decreases with the increasing number of chemotherapy lines [
20]. In the subgroup without multiple metastases, LDMC patients showed DCR twice as often as in the control group (36.0% vs. 18.0%,
p = 0.096) and the median PFS was 16.0 weeks vs. 12.0 weeks (
p = 0.064) with a trend towards significance. In the HR-positive group, we found no differences in DCR between the two groups. However, among triple-negative patients, 30.0% patients with LDMC compared to 5.0% patients with CCT showed DCR (
p = 0.095) resulting in a borderline significance in favor of LDMC. A beneficial effect of the metronomic combination of VRL and CAPE was also shown in the triple-negative subgroup (28 patients) in the VICTOR-2 study [
21]. The DCR was 53.7% and the median PFS was 4.7 months. Furthermore, LDMC with CTX/MTX was well-tolerable with almost only grade 1–2 toxicities. The most frequent adverse events were leukopenia (1–49%), nausea/vomiting (3–39%) and gastric pain (6–7%). Elevated values of transaminases, observed in up to 60% patients (10% grade 3–4), were mostly attributable to concomitant hepatic metastases or recovered with reduction or transient interruption of MTX [
10,
12,
22]. In order to reduce hepatic toxicity and simplify the drug administration we modified the MTX schedule (2.5 mg every other day instead of 2.5 mg twice a day on days 1 and 4 every week) and found no grade 3–4 hepatic toxicities [
10].
By reference to current experience, endocrine-based therapy should be provided as the first choice for MBC with positive HR status except in the case of life-threating disease [
23]. In the last decade, new options as cyclin-dependent-kinase (CDK) inhibitors and immune checkpoint inhibitors for the treatment of MBC were established [
24‐
26]. Moreover, LDMC has gained increasing interest through its multi-targeted nature. In addition to direct cytotoxic effect, LDMC induces indirect effects on tumor cells by modulation of tumor microenvironment via inhibition of angiogenesis and stimulation of immune response [
27‐
29]. Thus, while the anti-tumor response to LDMC may be delayed, the effect is more likely to be sustained, owing to the decreased selection of resistant tumor cell clones and the suppression of anti-tumour immunity with a decreased likelihood of disease relapse [
30]. Oral administration of well-tolerable LDMC including improvement of QoL of patients and reduced healthcare costs as well as having benefits over intravenous administration such as prolonged plasma drug concentration or increased therapeutic window makes LDMC attractive in clinical practice [
31,
32]. Apart from that there are still several aspects that need to be clarified, such as patient selection, the choice of cytotoxic drug used for treatment, its optimal dose and decision between single versus doublet agent administration [
8,
33]. Nevertheless, based on previous studies, LDMC represents a therapy option for MBC patients without need for rapid response and can be recommended according to the Breast Committee of the German Gynecological Oncology Working Group in HR-positive, HER2-negative MBC patients after anthracycline and taxane pretreatment [
34,
35]. In addition to HR-positive patients, we demonstrated a favorable effect also in the triple-negative subgroup. Considering that, the therapeutic goal in advanced disease is on the one hand to maintain the QoL and on the other hand to control the disease, LDMC is a valuable option. It may be administered particularly in asymptomatic patients with endocrine resistance and triple-negative disease to prolong PFS and delay the onset of the often more toxic CCT with MTD regimen. Furthermore, combination of LDMC with anti-angiogenic and immunomodulatory substances seems to be promising [
36‐
40]. Further analyses are needed to gain detailed experience about the role of LDMC in the management of MBC, including QoL issues and combination therapies with e.g. immunomodulatory drugs.
To the best of our knowledge, the presented analyses are the first to compare and show a similar efficacy of LDMC and CCT in terms of age, previous chemotherapy and severity of metastatic lesions. However, the retrospective character limits the validity of the presented data. In particular, since the median age at first diagnosis MBC was 59 for both groups and the median age at start of therapy was 63 in LDMC and 61 in CCT group, it can be assumed that LDMC patients had a less aggressive disease and/or better response to prior therapies compared to CCT patients. Reliable information on the toxicity of the administered therapies is not presented. Moreover, the validity of our conclusions is impaired by the study design and should be regarded as hypothesis generating. Therefore, we try to overcome this limitation and prepare a prospective non-interventional study to gather further insights about LDMC in MBC regarding patient-reported outcome, QoL, safety and efficacy, named PROmetronomic.
In conclusion, in our retrospective case–control study we could demonstrate a similar efficacy of LDMC compared to CCT in the treatment of MBC. Our analyses support further efforts to investigate the LDMC in selected MBC patients.
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