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 Table of Contents  
ORIGINAL ARTICLE
Year : 2022  |  Volume : 17  |  Issue : 6  |  Page : 621-634

Efficacy and safety of FLOT regimen vs DCF, FOLFOX, and ECF regimens as perioperative chemotherapy treatments for resectable gastric cancer patients; a report from the middle east


1 Department of Pharmacy Practice and Pharmaceutical Sciences, College of Pharmacy, University of Minnesota, Minneapolis, USA., USA
2 Department of Internal Medicine-Haematology-Oncology Section, School of Medicine, Isfahan University of Medical Sciences, Isfahan, I.R. Iran., I.R. Iran
3 Department of Radiology and Oncology, Instituto do Câncer do Estado de São Paulo, São Paulo, Brazil., Brazil
4 Department of Clinical Pharmacy, School of Pharmacy and Pharmaceutical Sciences, Isfahan University of Medical Sciences, Isfahan, I.R. Iran., Iran

Date of Submission15-May-2022
Date of Decision13-Aug-2022
Date of Acceptance23-Aug-2022
Date of Web Publication29-Oct-2022

Correspondence Address:
Azadeh Moghaddas
Department of Clinical Pharmacy, School of Pharmacy and Pharmaceutical Sciences, Isfahan University of Medical Sciences, Isfahan, I.R. Iran.
Iran
Mehran Sharifi
Department of Internal Medicine-Haematology-Oncology Section, School of Medicine, Isfahan University of Medical Sciences, Isfahan, I.R. Iran.
I.R. Iran
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Source of Support: None, Conflict of Interest: None


DOI: 10.4103/1735-5362.359430

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  Abstract 


Background and purpose: This study aimed to compare the efficacy and toxicity of perioperative chemotherapy regimens including epirubicin, cisplatin, 5-fluorouracil (ECF), docetaxel, cisplatin, 5-fluorouracil (DCF), leucovorin, 5-fluorouracil, oxaliplatin (FOLFOX), and 5-fluorouracil, leucovorin, oxaliplatin, and docetaxel (FLOT) to identify the most effective chemotherapy regimen with less toxicity.
Experimental approach: This retrospective cohort study (2014-2021) was based on 152 eligible resectable gastric cancer patients who had received one of the perioperative mentioned chemotherapy regimens and followed for at least two years. The primary endpoint of this study was overall survival (OS), progression-free survival (PFS), overall response rate (ORR), and R0 resection.
Findings / Results: Of included patients, 21%, 33.7%, 24.3%, and 21% had received ECF, DCF, FOLFOX and FLOT, respectively. After the median 30-month follow-ups, OS was higher with the FLOT regimen in comparison with other regimens (hazard ratio = 0. 276). The median OS of the FLOT regimen was 39 months. Besides, the median OS was 28, 25, and 21 months for DCF, FOLOFX, and ECF regimens, respectively. Moreover, a median PFS of 24, 18, 17, and 14 months was observed for FLOT, DCF, FOLFOX, and ECF regimens, respectively (Log-rank < 0.001). FLOT regimen showed 84. 4% ORR which was notably higher than other groups.
Conclusions and implications: For resectable gastric cancer patients, the perioperative FLOT regimen led to a significant improvement in patients’ OS and PFS versus ECF, DCF, and FOLFOX regimens. As such, the FLOT regimen could be considered the optimal option for managing resectable gastric cancer patients.

Keywords: Chemotherapy adjuvant; Gastrointestinal; Neoplasms; Progression-free survival; Stomach neoplasms; Survival analysis.


How to cite this article:
Farrokhi P, Sadeghi A, Sharifi M, Riechelmann R, Moghaddas A. Efficacy and safety of FLOT regimen vs DCF, FOLFOX, and ECF regimens as perioperative chemotherapy treatments for resectable gastric cancer patients; a report from the middle east. Res Pharma Sci 2022;17:621-34

How to cite this URL:
Farrokhi P, Sadeghi A, Sharifi M, Riechelmann R, Moghaddas A. Efficacy and safety of FLOT regimen vs DCF, FOLFOX, and ECF regimens as perioperative chemotherapy treatments for resectable gastric cancer patients; a report from the middle east. Res Pharma Sci [serial online] 2022 [cited 2022 Nov 30];17:621-34. Available from: https://www.rpsjournal.net/text.asp?2022/17/6/621/359430




  Introduction Top


Gastric cancer is known as one of the most fatal cancers worldwide, being the fifth and third cause of cancer-related deaths in women and men, respectively. Eastern Asia, Eastern Europe, and South America are considered regions with a high incidence rate of gastric cancer in the world [1]. Available evidence supports the beneficial effect of perioperative chemotherapy in comparison with surgery alone on the prognosis of resectable gastric cancers [2][3][4][5]. Perioperative chemotherapy has been reported to lead to higher overall survival (OS), progression-free survival (PFS), and curative resection rate [6],[7]. According to a systematic review and meta-analysis conducted in 2015, the administration of chemotherapy before and after gastric surgery has resulted in a 42% increase in the 5-year overall survival rate in comparison with a 30% reported increase by the surgery alone [7].

The best perioperative chemotherapy regimen for the management of resectable gastric cancer is still a matter of debate. In the Medical Research Council adjuvant gastric infusional chemotherapy (MAGIC) trial performed on 503 patients with advanced gastric cancer in 2006, the combination of chemotherapy drugs contained epirubicin, cisplatin, and 5-fluorouracil (ECF regimen) as perioperative chemotherapy was compared to surgery alone. The results indicated that the OS (hazard ratio (HR) for death 0.75, P = 0.009; 5-year survival rate, 36% vs 23%) and PFS (HR 0.66; P < 0.001) were significantly higher than control group [6]. Docetaxel together with cisplatin and 5-fluorouracil (DCF regimen) is another regimen that has been considered for perioperative chemotherapy [8]. In the Ajani et al. study, the result of the trial indicated an improved quality of life, time to progression, and OS compared with the control group received a combination of cisplatin and 5-fluorouracil [9]. The combination of 5-fluorouracil, leucovorin, and oxaliplatin (FOLFOX regimen) has been shown as a tolerable and effective perioperative regimen for resectable gastric cancer with a median improvement of up to 22 months in PFS and 29 months in OS [10],[11]. In a study conducted by Wang et al. the perioperative administration of the modified FOLFOX6 regimen contains a higher dose of leucovorin (400 mg/m2) and 5-fluorouracil (2.8 g/m2) in comparison with the conventional FOLFOX regimen (which contains 200 mg/m2 leucovorin and 2.6 g/m2 5-fluorouracil) [11],[12], resulted in a 50% tumor regression rate achieved in 42.9% of patients, which was suggestive for the efficacy of FOLFOX regimen while maintaining a favorable toxicity profile [12]. According to the aforementioned studies, FOLFOX regimens seem to be effective and well-tolerated in the perioperative setting for the treatment of resectable gastric cancers. Newer combination regimens including 5-fluorouracil, leucovorin, oxaliplatin, and docetaxel (FLOT regimen) have also shown advantages over surgery alone by increasing in 3-years OS up to 58.7% in patients who received FLOT regimen in comparison with 30.9% in patients only underwent surgery [13]. The superiority of the FLOT regimen against the ECF regimen has been noted in FLOT-AIO clinical trials as well [14]. Moreover, in Schulz et al. trial neoadjuvant FLOT regimen demonstrated promising results in terms of efficacy by 32.9 months PFS and 79.3% one-year survival rate [15]. These results led to establishing the FLOT regimen as one of the frontline treatments for patients who suffer from operable gastric cancer. However, apart from the ECF regimen, there is no study comparing the efficacy and toxicity of this emerging regimen with other common chemotherapy treatments such as DCF and FOLFOX which are routinely administered in perioperative settings.

In addition to the improvement of clinical outcomes, the tolerability of the regimen concerning toxicity is another important aspect to be considered when comparing different chemotherapy regimens. For instance, the DCF regimen has been reported to result in notable toxicity, especially in terms of hematological toxicity including neutropenia that could occur in up to 80% of patients or mucositis or diarrhea that has an incidence of approximately 60% in patients [8]. Noteworthy, the FOLFOX regimen could be considered a safe regimen for elderly patients or patients who couldn’t tolerate a more intense regimen [11],[12] In this context, toxicities such as grade 3-4 of neutropenia or mucositis have been reported to be more frequent in patients receiving FLOT regimen compared to those receiving ECF regimen; however, overall complications in both groups were comparable [14]. Furthermore, the FLOT regimen was associated with gastrointestinal toxicity subsuming nausea, vomiting, and diarrhea that should be addressed when considering a therapeutic regimen [13],[14],[15].

To summarize, although the available evidence has shown that the administration of perioperative chemotherapy could lead to an improvement in the prognosis of patients suffering from resectable gastric cancers [16], studies are needed to compare these regimens in terms of their benefits and toxicity, enabling clinicians to choose the optimal regimen. To our knowledge, there is no available head-to-head clinical trial, comparing the aforementioned common chemotherapy regimens for resectable gastric cancer patients. In this study, we aimed to evaluate and compare the efficacy and toxicity of common regimens used as perioperative chemotherapy including ECF, DCF, FOLFOX, and FLOT in resectable gastric cancers to identify the most effective chemotherapy regimen with less toxicity.


  Materials and methods Top


This retrospective cohort study, conducted in Iran, was based on the follow-up of patients with resectable gastric cancers who had undergone gastrectomy and received peri-operational chemotherapy. Iran has one of the highest incidences of resectable gastric cancer in the world with an incidence rate of 15 and 8 per 100000 cases in men and women, respectively [17],[18],[19). The study was approved by the Ethics Committee of Isfahan University of Medical Sciences with the Iranian approval ID of IR.MUI.RESEARCH.REC.1398.167 and all enrolled patients signed the consent form at the beginning of data gathering.

Patients

We recruited all the eligible patients with resectable gastric cancer who had information in the archives of the hospital admitted to the Omid Hospital, Isfahan, Iran, between July 2014 and July 2021. Omid Hospital is a tertiary referral hospital allocated exclusively to oncology patients and affiliated with the Isfahan University of Medical Sciences. The inclusion criteria were: (i) age between 18-75 years old at the time of diagnosis, (ii) pathologic diagnosis of the resectable gastric tumor without metastasis, (iii) having undergone gastrectomy (partial or total), (iv) having received any chemotherapy regimens including ECF, FOLFOX, DCF or FLOT as the first-line chemotherapy in preoperative and postoperative chemotherapy plan, (v) being without any concurrent active malignancy. In the Omid hospital, the patient is considered for surgery when they have no or limited metastasis, with the latter defined as having” abdominal or retroperitoneal lymph node metastases only (e.g. para-aortic, intra-aortic-canal, peripancreatic, or mesenteric lymph nodes) or one incurable organ site according to the Al-Batran et al. studies’ definition for limited metastasis [20].

Chemotherapy regimens

The following perioperative chemotherapy regimens were administrated for our included patients:

1- DCF regimen containing docetaxel (75 mg/m2, day 1), cisplatin: (75 mg/m2, days 1), and fluorouracil: (750 mg/m2/day, days 1-5).

2- ECF regimen including epirubicin (50 mg/m2, day 1), cisplatin (60 mg/m2, day1), and fluorouracil (200 mg/m2/day, continuous infusion during days 1-21).

3- FOLFOX regimen containing oxaliplatin (85 mg/m2, day 1), leucovorin (200 mg/m2, day 1), and fluorouracil (2600 mg/m2 continuous infusion over 24 h, day 1).

4- FLOT regimen including docetaxel (50 mg/m2, day 1), oxaliplatin (85 mg/m2, day1), leucovorin (200 mg/m2, day 1), and fluorouracil (2600 mg/m2 continuous infusion over 24 h, day 1).

Before and during each cycle of chemotherapy the bone marrow function was checked and all patients received filgrastim (7.5 mg/kg), 48-72 h after the completion of chemotherapy. In the case of any grade 3-4 toxicity, the chemotherapeutic dosage of the next cycle was reduced by 20%.

Outcome evaluation

During the follow-up period, the evaluation of the tumors’ response was carried out through the review of histopathologic reports and computed tomography scans according to the RECIST CRITERIA v 1.1 [21]. The physicians performed a response evaluation every 8-12 weeks after initiation of perioperative chemotherapy during the entire follow-up period. According to these criteria, clinical response was classified based on a decrease in tumor size as follows: (i) complete response (CR) defined as the disappearance of tumor lesion for at least four weeks; (ii) partial response (PR) defined as more than 30% decrease of the longest diameter of the tumor lesion that was lasting for at least four weeks; (iii) progressive disease (PD) was defined as a 20% increase in the longest diameter of a target tumor lesion or appearance of a new lesion on imaging findings; and (iv) stable disease was considered for a patient who had not met the criteria of PD or partial response [20]. We defined the overall response rate (ORR) as the sum of CR and PR. Furthermore, the sum of CR, PR, and stable disease was considered the disease control rate (DCR).

Adverse events

The adverse effects of chemotherapy were evaluated according to the Common Terminology Criteria for Adverse Events (CTCAE) 5.0 criteria [22]. We focused on all reported 3-4 grades of hematological including anemia, thrombocytopenia, and neutropenia. Besides, grades 3-4 of gastrointestinal toxicities, as well as nausea, vomiting, diarrhea, and mucositis were evaluated according to CTCAE criteria.

Endpoints

The primary endpoints of this study were ORR, OS, and PFS associated with each chemotherapy regimen in patients who were undergone perioperative chemotherapy with respective surgery. The OS was defined as the length of time from either the date of diagnosis or the start of treatment until the patient's death for any reason [14]. Progression-free survival was defined as the length of time during and after the treatment until disease progression [14]. R0 resection which indicated no microscopic remained cancer cells in the primary tumor site [14] and major toxicities (mainly grade 3-4 hematological and non-hematological adverse effects) were also considered secondary endpoints.

Statistical analysis

We reported and compared the continuous variables, as the mean ± SD, and categorical variables using a one-way ANOVA test and Chi-square test, respectively. Regarding analyses of the primary outcome, we estimated OS and PFS by the Kaplan-Meier method and compared survival using the log-rank test. All aforementioned tests were considered statistically significant if they had a two-sided P-value less than 0.05. To calculate the crude and adjusted HR with a 95% confidence interval (CI) with ECF regimen as the referent, the univariate and multivariate cox-regression analyses were applied. The adjusted HR was based on confounders such as an eastern cooperative oncology group (ECOG) performance status, family history of cancer, disease histopathology, cancer stage, tumor size, having other organ metastasis, site of metastasis, resection rate, and the response to chemotherapy (defined as PD or stable disease) as a result of plausibility and associations with survival. To estimate the clinical and pathological patients’ characteristics on prognosis, first, we performed a univariate logistic regression analysis for every single variable, then the covariate with P-values < 0.1 were considered in multivariate logistic analyses. The results of multivariate analyses on covariates which were shown P-values < 0.05 defined as statistically significant and considered independent prognostic factors in survival. The IBM SPSS software (Chicago, IL, USA), version 25.0 was used to calculate statistical analysis.


  Results Top


The characteristics of patients have been shown in [Table 1]. Among 152 included patients, 32 (24.2%), 51 (33.5%), 37 (24.3%), and 32 (21%) had received ECF, DCF, FOLFOX, and FLOT as the perioperative chemotherapy regimens, respectively. The majority of the included patients were male and the mean age of enrolled patients was 55.95 ± 12.01 years old. The mean age of the patients was significantly higher in those who received the FOLFOX regimen in comparison with the other chemotherapy regimens. Eighty-nine (58.9%) patients had a normal body mass index (BMI) (18-24 kg/m2). ECOG performance status was less than 2 in 92.7% of enrolled patients. Eighty (52.6%) and 75 (49.3%) patients had a history of smoking and Helicobacter pylori infection, successively. Most of the patients with a positive history of smoking had received a DCF regimen in comparison with the other regimens (p-value = 0.001). Tumor size of less than 4 cm was found in 64 (42.4%) patients. One hundred and thirty (85.5 %) patients had no metastatic lesion and the proximal tumor site was seen in 86 (56.6%) patients. According to the TNM classification, stage 3 (including 3a and 3b) was reported in 40 (26.3%) patients and patients who received the DCF regimen significantly have more advanced stages of the disease. The N1 and T3 stages were recorded in 69 (45.4%) and 60 (39.4%) patients, respectively. Additionally, more lymph node metastasis was seen in the DCF group.

hundred and thirty-six (89.5%) patients underwent total gastrectomy. The most common site of invasion was lymph nodes. Free margin of surgery (R0 resection) was reached in 132 (86.6%) patients, although 20 (13.2%) of patients had a positive surgical margin either in distal or proximal tumor sites.
Table 1: Demographic characteristics and disease-related characteristics.

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Chemotherapy efficacy

The results of the response rate based on the received chemotherapy regimens are summarized in [Table 2.]
Table 2: The results of response to chemotherapy, the number of total patients was 152.

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Complete response was reported in only one patient who received FOLFOX and FLOT regimes and three patients with DCF regimens. Besides, DCR and ORR were also remarkably higher in the FLOT regimen in comparison with the other regimens. The R0 resection rate was significantly higher in the FLOT regimen (93.8%) and DCF regimen (94.11%) than in the other regimens. [Table 2]

Kaplan-Meier survival analysis [Table 3] demonstrated that patients who received the FLOT regimen had a higher median PFS time (24 months, CI 95% = 16.95-21.95, log-rank = 0.001). In addition, in terms of OS time, the FLOT regimen demonstrated superiority over other regimens by 39 months’ OS times.
Table 3: Kaplan-Meier survival analysis results.

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Regarding the comparison between other regimens, the median OS of the DCF regimen was higher than ECF and FOLFOX regimen; off note, the difference was not statistically significant (P-value = 0.41). There was no significant difference between the median PFS of all FOLFOX, ECF, and DCF regimens. The one-year and two-year survival rate of the FLOT regimen was calculated substantially higher in comparison with the other regimens and were estimated to be 64%-28%, 94%-57%, 86%-48%, and 100%-97%, in ECF, DCF, FOLFOX, and FLOT regimens, respectively.

Moreover, the results of one-year and two-year’ PFS analysis were shown to be 39% and 11% for ECF regimen, 57%, and 34% for DCF regimen, 62%, and 18% for FOLFOX regimen and 91% and 50% for FLOT regimen.

By considering the ECF regimen a reference regimen in cox-proportional analysis, the FLOT regimen demonstrated its significant superiority in OS and PFS in comparison with the other regimens. Besides, subgroup analysis revealed that the DCF regimen had a significant survival rate in comparison with the ECF regimen in the crude model analysis. However, when these differences were adjusted by confounders such as ECOG performance status, family history of cancer, disease histopathology, cancer stage, tumor size, having other organs’ metastasis, site of metastasis, resection rate, and the response to chemotherapy (defined as PD or stable disease), the differences were not remarkable either for survival rate or for PFS. [Tables 4] and [Tables 5], and [Figure 1] and [Figure 2]
Figure 1: Kaplan-Meier plot of overall survival.

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Figure 2: Kaplan-Meier plot of progression-free survival.

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Table 4: Cox-regression survival analysis.

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Table 5: Toxic effects of chemotherapy regimens based on CTCAE criteria.

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Toxicity

All 3-4 grades of hematological and non-hematological toxicities were reported in [Table 5.] Grade 3-4 neutropenia was noted in 11 (34.3%), 26 (51%), 6 (16.2%), 12 (37.2%) of patients receiving ECF, DCF, FOLFOX, and FLOT regimens, respectively. Neutropenia significantly had a higher incidence among patients who received the DCF regimen. Moreover, 5 (15.6%) patients in the ECF group, 10 (19.6%) patients in the DCF group, 1 (2.7%) patient in the FOLFOX group, and 2 (6.3%) patients in the FLOT group experienced anemia as an adverse effect of chemotherapy and the incidence of anemia was not statistically different among treatment regimens (P-value = 0.28). The most reported 3-4 grades of non-hematological toxicities were occurrences of gastrointestinal adverse effects such as nausea, vomiting, and diarrhea noted in 30 (19.7%), 10 (15.2%), and 26 (17.1%) of the enrolled patients, respectively. DCF regimen represented a higher rate of toxicity and hospitalization rate in comparison with other chemotherapy regimens.

Multivariate analyses

The results of univariate analysis by Cox regression revealed that several factors including BMI, ECOG performance status, tumor differentiation, resection rate, and response to chemotherapy had a significant correlation with either PFS or OS (data are summarized in [Table 6]).
Table 6: Multivariate analysis of overall survival and progression-free survival.

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As shown in [Table 6], the results of multivariate analysis by Cox regression showed a significant correlation between diminishing in OS by variants such as having poorly-differentiated pathology, the lack of response to chemotherapy (defined as PD or stable disease) and R1 resection.

On the other hand, several patients’ factors such as being overweight (BMI > 24), having ECOG performance status > 1, no response to chemotherapy (define as progressive disease or stable disease) and R1 resection had a lower chance of PFS.


  Discussion Top


In this retrospective study, for the first time in the Iranian population, we evaluated the most common administrative chemotherapy regimens for the perioperative protocol of management for gastric cancer patients with resectable tumors, including ECF, DCF, FOLFOX, and FLOT. Based on our implication, the FLOT regimen ascertained significant improvement in patients’ OS and PFS in comparison with the other regimens.

The predominance efficiency of the perioperative FLOT regimen in managing resectable gastric cancer has been demonstrated in the FLOT-AIO4 study which has compared FLOT and ECF perioperative chemotherapy regimens in 356 and 360 patients with resectable gastric cancer, respectively [14]. In this study, the FLOT regimen was superior in demonstrating either OS up to 50 months or PFS up to 32 months to the ECF regimen [14]. Additionally, Schulz et al. phase 2 trial with 50 patients who had received the perioperative FLOT regimen showed that the FLOT regimen improved PFS (32.9 months) significantly in comparison with the surgery alone [15]. Similarly, our study results revealed that the FLOT regimen had superiority in increasing both PFS and OS in comparison with a reference regimen (ECF regimen). However, the median overall and progression survival time in our study were 39 and 24 months, respectively. Which were lower than the previous studies [14],[15],[16],[17],[18],[19],[20],[21],[22], possibly due to the effect of sample size. Moreover, according to Malekzadeh et al. study, most Iranian patients suffering from gastric cancer were diagnosed with an advanced level of tumors that can be directly attributed to poor survival time [23]. The most two noted reasons for delayed recognition of Iranian gastric cancer patients were patients’ refusal and economic problems [23].

It is worth mentioning that, as opposed to other noted median PFS time for FLOT chemotherapy regimen [13],[14],[22], the one-year and two-year reported OS rate, as well as indicators such as ORR and DCR in FLOT regimen, was higher in our study than other similar studies [13],[14],[22]. In the present study, comparing the FLOT regimen with other chemotherapy regimens has shown the superiority of this regimen not only by improving OS and PFS period but also by enhancing survival rate and R0 resection rate. R0 resection rate was considered as an endpoint in our investigation and demonstrated to be as high as a 93.8% resection rate for the FLOT regimen. This resection rate for the FLOT regimen was similar to Wang K. et al retrospective study with a 91% resection rate in 40 included patients [13] and higher than the resection rate reported by Schulz et al. study which was 86% in 50 patients [15].

When it comes to the DCF regimen, the median OS and PFS were reported at 28 months and 18 months, respectively. The results were compatible with similar studies that were conducted to evaluate the efficiency of the perioperative DCF regimen [25],[26]. Nevertheless, in the retrospective survey conducted by Fiteni et al. [26], the reported median OS (57 months) and three-year survival rate (60%) were higher than our results or even other similar studies [24],[25] which can be due to longer follow-up duration (near 10 years) and more enrolled patients (62 patients) in comparison to our study.

In resemblance to a recently published meta-analysis [27],[28], our cox-regression analysis demonstrated that there was a significant difference between OS enhancement by ECF and DCF regimens. The superiority of taxane-based regimens over non-taxane-containing chemotherapy was confirmed by Chaudhuri et al. not only in operable gastric cancer patients but also in the metastatic situation [29]. Besides, we found that the PFS of patients receiving the DCF regimen was higher than the ECF regimen, despite non-statistically significant results. Even though, the taxane-based regimen has shown improvement in PFS rather than an anthracycline-based regimen; however, the difference was not statically significant [28]. To put all data into a nutshell, despite several data on the increasing PFS by both DCF and ECF regimens [6],[26],[29], the DCF regimen remained the superior regimen in the perioperative setting of gastric cancer management due to enhancement in other survival indices such as median time of overall, PFS, and ORR.

We found that in the second place after the FLOT regimen, the DCF regimen led to an increase in median survival time, DCR, ORR, and R0 resection rate in comparison with FOLFOX and ECF regimens; however, the maximum level of toxicity has been detected by DCF regimen. Despite the similar resection rate reported between DCF and FLOT regimens, by considering other survival endpoints such as median survival time, ORR, and toxicity, the DCF regimen seems to be inferior in comparison to the FLOT chemotherapy regimen. Furthermore, introducing the DCF regimen as an optimal regimen is not reasonable.

Concerning the FOLFOX regimen, the numbers of our survival analysis results were consistent with other studies that utilized a variety of types of FOLFOX regimens as perioperative chemotherapy regimens [10],[12],[30],[31]. To illustrate this resemblance, the retrospective cohort study conducted by Sun et al. FOLFOX4 regimen showed a 29-month OS time similar to our noted 25-month median OS in our study [10].

Moreover, our reported one and two-year OS, as well as ORR (75.5%), and DCR (89.1%), was comparable with other similar studies administrated FOLFOX7 and modified-FOLFOX6 regimens [1],[30]. However, our 21% OS rate after three-year follow-up was in disagreement with the approximate amount of 60% which was reported in the previous studies [10],[12],[29],[30]. The lower OS rate in patients who had received the FOLFOX regimen in our study can be attributed to the higher median age of our enrolled patients (60 years old) in comparison with the other important studies with less than 50-year-old patients recruitment [10],[12].

Regarding the efficacy of the ECF regimen, the results of one-year survival in our study (71.9%) were in accordance with both studies including FLOT-AIO4 and MAGIC which were successful in showing almost 60-70% one-year survival rate during their follow-up [6],[14]. In a retrospective cohort study conducted by Achili et al. ECF as a perioperative chemotherapy regimen, the ORR and DCR rates were reported at 37% and 42%, accordingly, which is less than our study with an ORR rate of 56% and DCR rate of 87.6% [32]. However, in our study, 21 months median OS and 14 months of PFS were lower than the aforementioned study which had 25.7 months of PFS and 36.6 months of OS [32]. This controversy is explainable by a smaller number of enrolled patients and a shorter period of follow-up in our study. In addition, Iranian patients were diagnosed at a higher stage of the disease which may lead to a lower chance of survival [12],[23],[30].

In consensus with the aforementioned results of our study about the inferiority of the ECF regime, this regimen showed the lowest R0 resection rate. This R0 resection rate was 75% which was comparable to other reported R0 resection rates for the ECF regimen [6],[14]. By considering all factors related to survival including median PFS, OS, ORR, and R0 resection rate, the ECF regimen failed to represent the optimum efficiency in comparison with other regimens.

Regarding the toxicity of chemotherapy regimens as a secondary endpoint in the study, we could show that the DCF regimen was significantly associated with more grade 3-4 toxicities such as neutropenia and mucositis in comparison with another regimen. The reported grade 3-4 hematological toxicity especially neutropenia in our study was in accordance with other reported DCF regimens’ toxicity rate which was around 31-87% [24], [26], [33], [34], [35]. Besides, the rate of 3-4 grade mucositis and hospitalization for the DCF regimen were 21% and 52%, respectively, similar to other published reports [34],[35],[36].

On the other hand, the grade 3-4 neutropenia incidence rate for the FLOT regimen was reported between 30-51% [14],[22],[37], in a range revealed by our findings. Although the rate of 3-4 grade mucositis (16%) was higher than in other similar studies [14],[22] due to possible differences in inappropriate oral hygiene in Iranian patients [38], as an important risk factor of mucositis [39]. The hospitalization rate for our study was 37% as opposed to the FLOT-ATIO4 trial with a 25% rate [14]. This difference can arise by the inappropriate use of granulocyte colony-stimulating factor (G-CSF) by some physicians to the prevention of chemotherapy toxicity in our institute [40].

Like the other similar reports [31],[41], the FOLFOX regimen had the lowest rate of toxicities among the other three regimens by inducing 16% grade 3-4 neutropenia and 8.5% grade 3-4 mucositis.

It is worth mentioning that another advantage of using oxaliplatin-based chemotherapy regimens like FLOT and FOLFOX is a lower rate of adverse effects rather than a cisplatin-based regimen like DCF and ECF. In addition, oxaliplatin-based regimens maintain the same or even better effectiveness overall. This issue is well demonstrated in the meta-analysis which was conducted by Huang et al. to compare the effectiveness and safety of oxaliplatin-based and cisplatin-based therapy in advanced gastric cancer [42] and demonstrated that there is no difference in terms of the effectiveness of factors such as OS, PFS, and ORR between the oxaliplatin and cisplatin-based chemotherapy [41],[43]. However, the oxaliplatin-based regimen was associated with less adverse toxicity except for neurotoxicity.

In multivariate regression analysis, the histopathological tumor type showed a significant correlation with patients’ survival time (both OS and PFS) in a way that patients with the well-differentiated subtype had improved OS and PFS remarkably. These finding has been noted in other similar studies [44], in which the histopathology of the gastric tumor was introduced as an independent risk factor of gastric cancer patients’ OS. Also, in agreement with our findings, Castellanos et al. retrospective study [24], and a Li et al. [45] meta-analysis reached the conclusion that the response to chemotherapy and achieving to R0 resection rate significantly increased the time of survival in gastric cancer patients.

Body mass index (BMI) was detected as a prognostic factor for PFS and OS according to multivariate and univariate analysis as well. Along with, underweight and overweight patients considerably had a lower chance of survival in comparison with normal BMI patients suffering from gastric cancer. In a results analysis of a large cohort study that recruited 7700 gastric cancer patients, underweight patients showed a lower duration of survival, although obese patients had a better survival [46]. It is worth mentioning that malnutrition and less reserve of adipose tissues were repeatedly noted as the prognostic factors of poor survival in cancer patients and could diminish the antitumor activity of the immune system [46],[47]. Furthermore, it will be recommended that nutritional support before and during chemotherapy should be considered for the underweight patient suffering from gastric cancer. In addition, some studies suggested that lower BMI was associated with a higher rate of lymph node metastasis and a more advanced tumor stage which is considered a poor prognosis factor in gastric cancer [47],[48]. Our study demonstrated that patients with BMI > 25 also had unfavorable outcomes which were confirmed by Nam. et al studies regarding the poor prognosis of male gastric cancer patients with BMI < 25 [49]. However, it seems that being overweight is a protective factor for patients and this inconsistency between our results and other studies could be the result of the small number of patients in our study.

To our knowledge, this is one of the first studies performed to compare the efficacy and tolerability of the most common perioperative chemotherapy regimens in the management of resectable gastric cancer in the Iranian population. Mousavi et al. evaluated the efficacy of several most prescribed chemotherapy regimens in resectable and metastatic gastric cancer patients living in the north of Iran and concluded that the DCF regimen prolonged patients’ survival time more than ECF, DOX, and Xeloda®-based chemotherapy [50]. Due to the high prevalence of gastric cancer in the countries such as Iran and a lack of definite national and international guidelines to recommend the best therapeutic options [23],[49], the necessity of conducting a comparative study among chemotherapeutic regimens is crucial.

Our study suffered from several limitations. First, the FLOT regimen has recently been used in our country and for completing the ultimate documents, more follow-up duration and more patients who will be treated by the FLOT regimen is necessary. Second, due to the retrospective methodology of the study, meticulous documentation and data gathering were challenging. To overcome the limitations and verify our results, a multicenter randomized clinical trial in the Iranian population for collecting comprehensive and accurate data to decide on the optimal first-line chemotherapy regimen for the treatment of resectable gastric cancer as perioperative modalities is recommended.


  Conclusion Top


We demonstrated that the FLOT chemotherapy regimen significantly enhanced survival parameters including OS and PFS and additionally exerted a higher rate of R0 resection and overall response with a tolerable toxicity profile in comparison with other included chemotherapy regimens. Conducting large and well-designed clinical trials to confirm the assertion is crucial.

Acknowledgments

The study was part of a Pharm.D thesis that was financially supported by Isfahan University of Medical Sciences, Iran, through Grant No. 297132. For all their kind help and cooperation, we highly appreciate the nurses and medical staff in the inpatient chemotherapy ward.

Conflict of interest statement

The authors declared no conflict of interest in this study.

Authors’ contribution

A. Moghaddas, P. Farrokhi, and R. Richelman contributed to the literature review, study design, providing data, writing, and revising the manuscript. A. Sadeghi, M. Sharifi, A. Moghaddas, and P. Farrokhi were responsible for recruiting patients. P. Farrokhi was responsible for data gathering and analysis. A. Moghaddas supervised the whole study. All authors approved the final version of the manuscript.



 
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