Second-line treatment following a GEM-based regimen has been established based on the results of the NAPOLI-1 phase III trial [6]. Despite recent advances in treatment for patients with unresectable PDAC, the prognosis of these patients remains poor. Therefore, the development of subsequent treatments is urgently required. Currently, in Japan, L-OHP-containing regimens are sometimes used as a subsequent treatment after failure of the GEM-based regimen and 5-FU/LV + nal-IRI; however, their efficacy and safety have not been elucidated. Therefore, in this study, we evaluated the efficacy and safety of the FOLFOX regimen as third- or later-line treatment after the 5-FU/LV + nal-IRI regimen in 43 patients. Although the toxicity was acceptable, the efficacy was limited: the median PFS was only 1.3 months, and the disease control rate was only 25.6% with no PR.
The combination treatment of 5-FU, LV, and L-OHP has been tested as a second-line treatment after a GEM-based regimen in two previous phase III trials. The first trial was the CONKO-003 trial, which demonstrated improvement in OS in combination treatment of the three drugs (OFF regimen) compared with in 5-FU plus LV (FF) [9]: the median of OS and time to progression was 5.9 months and 2.9 months in the OFF arm, and 3.3 months and 2.0 months in the FF arm, respectively. Despite the statistical significance, the OFF regimen was inconvenient because 5-FU and LV were administered once a week via 24-h intravenous infusion. Therefore, a second trial, called the PANCREOX trial, was conducted. This trial employed a modified FOLFOX6 regimen in which 5-FU, LV, and L-OHP were administered biweekly via 48-h intravenous infusion [10]. Although this trial did not meet the primary endpoint of PFS, it showed that the median PFS was 3.1 months in the modified FOLFOX6 arm compared with the 2.9 months in the 5-FU/LV arm. Based on these results, the median PFS may be approximately 3 months when the combination of 5-FU, LV and L-OHP is used as a second-line treatment. We used the FOLFOX regimen after failure of 5-FU/LV + nal-IRI, as all patients except one who quit prior treatment due to adverse events would be resistant to 5-FU/LV. Hence, it is reasonable that the median PFS in our study was worse than that in studies on second-line treatment. Yamai et al. also evaluated the efficacy of the FOLFOX regimen as salvage treatment after GEM plus nab-PTX and 5-FU/LV + nal-IRI [14]; although the sample size was 17, which was smaller than that in our study, the results are consistent with those of our study.
The continuous use of 5-FU/LV after failure is an issue that needs to be discussed. We considered 5-FU as a key drug for advanced pancreatic cancer because the standard treatment of PDAC in every disease stage includes 5-FU: GEM + S-1 as a neoadjuvant therapy for resectable disease [15], GEM + capecitabine [16], FOLFIRINOX [17] and S-1 [18] in adjuvant therapy after radical resection, and FOLFIRINOX in borderline and unresectable stages [2, 19, 20]. Therefore, we used 5-FU/LV with L-OHP even after failure of the 5-FU/LV containing regimen rather than L-OHP monotherapy. In contrast, L-OHP monotherapy was selected in most patients who received subsequent therapy in the FF arm of CONKO-003 [9]; this might be because they considered that continuous use of 5-FU/LV was not effective and that L-OHP monotherapy could maintain efficacy and improve safety. Indeed, we did not reduce the initial dose of L-OHP but reduced that of 5-FU in eight patients (18.6%). In addition, the efficacy results of a phase II study of L-OHP monotherapy as a second-line treatment for advanced PDAC were comparable with those of our study: SD for more than 2 months and the clinical benefit response was observed in 16.7% and 27.7% of patients, respectively [21]. Taking these results into consideration, continuous use of 5-FU after failure might be ineffective for advanced PDAC, although further investigation using a randomised controlled study is needed.
Although the overall efficacy of FOLFOX was insufficient to consider a standard treatment, multivariable analysis showed that patients with serum CRP < 1.0 mg/dL had better PFS and OS than those with ≥ 1.0 mg/dL. This indicates that patients with low CRP levels might be a good indication for FOLFOX, even in the third or later lines. Serum CRP level has often been reported as a prognostic factor for OS in advanced PDAC [22–24]. Haas et al. reported that serum CRP levels had the highest hazard ratio for OS among CEA, CA 19 − 9, and LDH in patients who received second-line chemotherapy for advanced PDAC [25].
Patients with homologous recombination repair deficiency (HRD) may be another indication for FOLFOX even after failure of 5-FU/LV + nal-IRI, although one patient with a germline BRCA mutation did not show any response in our study. Patients with a gene mutation associated with HRD, particularly germline BRCA mutation, are expected to respond to platinum-containing regimens because platinum-induced double-strand breaks cannot be fixed in cancer cells with HRD, resulting in cell death [26]. BRCA mutation status was not examined in nine patients in this study because these patients were diagnosed with contraindications for FOLFIRINOX. The prevalence of germline BRCA mutation was reported to be 4–7% [27–29] and that of HRD gene mutations, such as ATM, PALB2, CHEK2, and RAD51C, may be higher [14, 30]. HRD gene mutation was reported to be predictive of the FOLFOX regimen [14]. Next-generation sequencing using a cancer genome panel would aid in selecting patients who may be candidates for FOLFOX in the third or later lines of advanced PDAC.
Regarding safety, anaemia was the most common adverse event; however, the baseline haemoglobin level was grades 1–2 in 24 patients (56%) and the difference in haemoglobin level between baseline and worse point (Additional Fig. 1-a, b), therefore, anaemia was a manageable toxicity. Therefore, it was not an obstacle to using FOLFOX as a third- or later-line treatment for patients with PDAC. Moreover, grade 1 non-haematological adverse events might have been overlooked due to the retrospective nature of this study. In addition, short PFS may underestimate the incidence and severity of peripheral sensory neuropathy (PSN), since PSN is worsen upon L-OHP dose accumulation. Therefore, patients with grade 2 PSN should be carefully treated with a FOLFOX regimen. Incidence of chemotherapy-induced nausea and vomiting was higher during FOLFOX therapy than that experienced during 5-FU/LV + nal-IRI or FOLFIRI as second-line treatment [8, 31]. This could be caused by the disease symptom itself and poorer general condition of patients in the third- or later-line treatment than that in the second-line; however, the use of maximum anti-emetic treatment, such as aprepitant, palonosetron, and dexamethasone, must be considered when administering FOLFOX as third- or later-line treatment since the incidence of nausea and vomiting was high in our study.
Our study has some limitations. First, it was retrospective study. It is preferable to evaluate the efficacy with prespecified thresholds and expectations; however, there have been little reports on OS or PFS data by best supportive care after 5-FU/LV + nal-IRI. The results of our study will help to facilitate future clinical studies to develop third-line treatment after 5-FU/LV + nal-IRI in advanced PDAC. Second, the sample size was small, especially for the multivariable analysis. Third, we had no comparator arm to evaluate the efficacy of FOLFOX treatment. Nevertheless, to the best of our knowledge, our study included the largest cohort of patients who received FOLFOX as a treatment following 5-FU/LV + nal-IRI.