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. 2017 Oct 3;9:461–469. doi: 10.2147/CMAR.S113320

Emerging combination therapies for metastatic colorectal cancer – impact of trifluridine/tipiracil

Jeevan M Puthiamadathil 1, Benjamin A Weinberg 1,2,
PMCID: PMC5635852  PMID: 29056855

Abstract

Patients with metastatic colorectal cancer (mCRC) are surviving longer now than ever before, but mortality rates are still high and more effective therapies are clearly needed. For patients with disease that is refractory to fluoropyrimidines, oxaliplatin, irinotecan, and biologic agents targeting the vascular endothelial growth factor and epidermal growth factor receptor pathways, novel treatment options trifluridine/tipiracil (TAS-102) and regorafenib can be effective disease stabilizers. However, objective clinical responses are rare and toxicities are manageable but common. In order to tackle poor clinical responses to TAS-102, there is an ongoing effort to effectively combine this drug with other agents, particularly those targeting angiogenesis. Certain subpopulations appear to benefit more than others from TAS-102; those that benefit often have underlying genetic defects in DNA repair pathways and/or develop neutropenia. In this review, we focus on the role of TAS-102 in the treatment of mCRC, including its use in combination with other agents, potential predictive biomarkers of response to TAS-102, and possible future directions.

Keywords: metastatic colorectal cancer, trifluridine, tipiracil, TAS-102, regorafenib

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Introduction

In 2017, it is estimated that there will be 135,430 new cases of colorectal cancer (CRC) and 50,260 deaths resulting from this disease, making it the second leading cause of cancer mortality in the USA.1 At diagnosis, about 21% of patients have metastatic disease, and these individuals have a 5-year survival rate of only 13.9%.2 Due to advances in chemotherapy for patients with metastatic colorectal cancer (mCRC), median overall survival (mOS) has increased to ≥30 months, compared with <12 months in the era of treatment with single-agent fluoropyrimidines.35

First-line chemotherapeutic options for mCRC involve fluoropyrimidines, such as 5-fluorouracil (5-FU) or capecitabine, combined with oxaliplatin and/or irinotecan. Standard treatment regimens include FOLFOX (leucovorin/5-FU/oxaliplatin), CAPOX (capecitabine/oxaliplatin), FOLFIRI (leucovorin/5-FU/irinotecan), and FOLFOXIRI (leucovorin/5-FU/oxaliplatin/irinotecan).3,69 The advent of monoclonal antibodies (mAbs) bevacizumab (Avastin®; Genentech, South San Francisco, CA, USA),9 an anti-vascular endothelial growth factor A (VEGF-A) antibody, and cetuximab (Erbitux; Eli Lilly and Company, Indianapolis, IN, USA),10 an anti-epidermal growth factor receptor (EGFR) antibody, given in combination with fluoropyrimidine/oxaliplatin/irinotecan regimens, gave rise to the most promising treatment options available in the first line. EGFR targeting agents are restricted to patients with RAS wild-type tumors.11,12 When first-line therapies fail, patients are often treated with yet unused cytotoxic therapies combined with continued bevacizumab therapy,13,14 the anti-EGFR antibody, panitumumab (Vectibix®; Amgen, Thousand Oaks, CA, USA),15 or other antiangiogenic agents including ziv-aflibercept (Zaltrap®; Sanofi/Regeneron, Tarrytown, NY, USA) and ramucirumab (Cyramza®; Eli Lilly and Company).16,17 Pembrolizumab, an anti-programmed death 1 (PD1) mAb immune checkpoint inhibitor, is now Food and Drug Administration (FDA) approved for microsatellite instability-high (MSI-H) or mismatch repair deficient (dMMR) mCRC following treatment with fluoropyrimidine, oxaliplatin, and irinotecan regimens.1820 Previously, patients who progressed on standard chemotherapy and biologics were often left to rely on best supportive care (BSC) or participate in a clinical trial. However, now there are new and approved treatment options available with proven efficacy and tolerability in patients with refractory mCRC.

One such treatment is trifluridine/tipiracil (TAS-102, Lonsurf®; Taiho Oncology, Princeton, NJ, USA), which contains the oral cytotoxic agent trifluridine that was developed more than half a century ago. In this review, we discuss the pharmacology and clinical data of TAS-102; compare TAS-102 with regorafenib (Stivarga®, Bayer AG, Leverkusen, Germany), an alternative treatment option for patients with refractory mCRC; and discuss other therapies used in combination with TAS-102. Additionally, we consider potential biomarkers that could predict response to therapy with TAS-102 and examine clinical trials of TAS-102 in patients with refractory mCRC.

Pharmacology

TAS-102, which consists of trifluridine and tipiracil in a 1:0.5 molar ratio, was approved by the FDA for the treatment of refractory mCRC in September 2015.21 Trifluridine (5-trifluoro-2′-deoxythymidine) was developed by Heidelberger et al in 1964 as an alternative to 5-FU.22 It is a thymidine analog that inhibits cell growth by affecting DNA synthesis (Figure 1). Thymidine kinase (TK) phosphorylates trifluridine to its monophosphate form, trifluridine monophosphate (TF-TMP), which then inhibits thymidylate synthase (TS) and prevents methylation of 2′-deoxyuridine-5′-monophosphate (dUMP) to 2′-deoxythymidine-5′-monophosphate.2326 dUMP is then alternatively phosphorylated to its triphosphate form, 2′-deoxyuridine-5′-triphosphate, which causes the incorporation of uracil into DNA, inhibiting DNA synthesis and leading to cell death.27,28 Additionally, in a separate pathway, TF-TMP is further phosphorylated to trifluridine triphosphate (TF-TTP), which causes cell death via direct incorporation into DNA.29,30 Despite the evident clinical activity of trifluridine in patients with CRC and breast cancer, its short half-life (12–18 minutes) and significant myelosuppression were found to limit its clinical utility.31

Figure 1.

Figure 1

Mechanism of action of TAS-102.

Note: Enzymes are italicized.

Abbreviations: TP, thymidine phosphorylase; FTY, 5-trifluoromethyl-2,4(1H,3H)-pyrimidinedione; hENT, human equilibrative nucleoside transporter; TK, thymidine kinase; TF-TMP, trifluorothymidine monophosphate; TF-TDP, trifluorothymidine diphosphate; TF-TTP, trifluorothymidine triphosphate; TS, thymidylate synthase; dTMP, 2′-deoxythymidine-5′-monophosphate; dTTP, 2′-deoxythymidine-5′-triphosphate; dUMP, 2′-deoxyuridine-5′-monophosphate; dUTP, 2′-deoxyuridine-5′-triphosphate.

In the 1990s, it was discovered that the combination of tipiracil (5-chloro-6-[(2-iminopyrrolidin-1-yl)methyl]-1H-pyrimidine-2,4-dione) with trifluridine increased the bioavailability of trifluridine by inhibiting thymidine phosphorylase (TP), the enzyme that converts trifluridine into inactive 5-trifluoromethyl-2,4(1H,3H)-pyrimidinedione.32 Inhibition of TP, a known platelet-derived endothelial cell growth factor, also has indirect antiangiogenic benefits.3335 TAS-102 was effective in 5-FU-resistant CRC cell lines, due to direct TF-TTP incorporation into DNA and the resistance of trifluridine to degradation by DNA glycosylase, suggesting efficacy in 5-FU-refractory mCRC.32,3638

Clinical trials of TAS-102

Hong et al published the initial Phase I trial of TAS-102 in 14 patients with refractory mCRC (Table 1).39 The maximally tolerated dose (MTD) was 50 mg/m2/day administered once daily on days 1–14 of a 21-day cycle (grade 3–4 granulocytopenia was the dose limiting toxicity [DLT] in 3 of 6 patients treated at the 60 mg/m2/day dose level). Of the 12 patients evaluable for response, the best response was in 4 patients with stable disease. Another Phase I study reported by Overman et al examined 2 TAS-102 dosing schedules.40 In the 63 patients studied (52 with refractory mCRC), the recommended Phase II doses (RP2Ds) were 100 mg/m2/day administered once daily on days 1–5 and 8–12 of a 28-day cycle or 160 mg/m2/day once daily on days 1–5 of a 21-day cycle. Granulocytopenia was again the DLT in most cases. Thirty percent of patients had stable disease, but no objective clinical responses were seen.

Table 1.

Completed TAS-102 trials in mCRC

First author (year) Ph Patient population Treatment Primary endpoint
Hong (2006)39 I 14, refractory mCRC Dose de-escalation, daily D1–14 q 21 days RP2D =50 mg/m2/day
Overman (2008)40 I 63, 52 with refractory mCRC Dose escalation, daily D1–5 and D8–12 q 28 days (A) or D1–5 q 21 days (B) RP2D =100 mg/m2/day (A) or 160 mg/m2/day (B)
Overman (2008)42 I 15, advanced solid tumors Dose escalation, TID on D1–5 and D8–12 q 28 days MTD =80 mg/m2/day divided into 3 doses daily
Doi (2012)41 I 21, 18 with refractory mCRC (Japan only) Dose escalation, BID D1–5 and D8–12 q 28 days RP2D =70 mg/m2/day divided into 2 doses daily
Yoshino (2012)44 II 169, refractory mCRC (Japan only) 35 mg/m2 BID D1–5 and D8–12 q 28 days + BSC vs PBO + BSC (2:1) OS =9.0 vs 6.6 months
HR 0.56, 95% CI 0.39–0.81, P=0.0011
Bendell (2015)43 I 27, refractory mCRC Dose escalation, BID D1–5 and D8–12 q 28 days RP2D =70 mg/m2/day divided into 2 doses daily
Mayer (2015)45 III 800, refractory mCRC 35 mg/m2 BID D1–5 and D8–12 q 28 days + BSC vs PBO + BSC (2:1) OS =7.1 vs 5.3 months, HR 0.68, 95% CI 0.58–0.81, P<0.001
Doi (2015)68 I 10, refractory mCRC Dose escalation, BID D1–5 and D8–12 + irinotecan D1 and D15 fixed 150 mg/m2 q 28 days RP2Ds =50 mg/m2/day (TAS-102) divided into 2 doses daily, 150 mg/m2 (irinotecan)
Kuboki (2015)64 I/II 25, refractory mCRC Dose de-escalation, BID D1–5 and D8–12 + bevacizumab D1 and D15 q 28 days RP2Ds =70 mg/m2/day TAS-102, divided into 2 doses daily, 5 mg/kg bevacizumab. PFS @ 16 weeks =42.9%, 80% CI 27.8–59.0%

Abbreviations: Ph, phase; mCRC, metastatic colorectal cancer; RP2D, recommended Phase II dose; D, day; TID, three times daily; MTD, maximum tolerated dose; BID, twice daily; BSC, best supportive care; PBO, placebo; OS, overall survival; HR, hazard ratio; CI, confidence interval; PFS, progression-free survival.

Doi et al conducted another Phase I study using twice daily dosing in 21 Japanese patients (18 with refractory mCRC).41 In this trial, the RP2D was 70 mg/m2/day split into 2 daily doses on days 1–5 and 8–12 of a 28-day cycle (the DLT again was grade 4 neutropenia). No objective responses were observed in patients with mCRC, but 50% had stable disease. Median progression-free survival (mPFS) was 2.4 months and mOS was 9.8 months. Three times daily dosing was also studied in a separate Phase I trial of 15 patients with advanced solid tumors. On a schedule of TAS-102 split into 3 daily doses on days 1–5 and 8–12 of a 28-day cycle, the MTD was 80 mg/m2/day and the DLT was granulocytopenia. Nine patients had prolonged stable disease.42 Finally, Bendell et al conducted a Phase I study involving TAS-102 treatment of 27 US patients with refractory mCRC. The RP2D in this study was 70 mg/m2/day, split into 2 daily doses, administered on days 1–5 and 8–12 of a 28-day cycle, at which dose 70% of evaluable patients had stable disease lasting at least 6 weeks, and mPFS and mOS of the entire population were 5.3 and 7.5 months, respectively.43

In the J003 Phase II trial published by Yoshino et al, 169 Japanese patients with refractory mCRC were randomized 2:1 to 35 mg/m2 TAS-102 or placebo, both administered twice daily on days 1–5 and 8–12 of a 28-day cycle.44 The primary endpoint of the study was mOS, which was significantly longer in the TAS-102 group compared to placebo: 9.0 versus 6.6 months (hazard ratio [HR] for death 0.56, 80% confidence interval [CI] 0.44–0.71; P=0.0011). mPFS was also significantly longer in the TAS-102 group: 2.0 versus 1.0 month (HR 0.41, 95% CI 0.28–0.59; P<0.0001). In the subgroup analysis, patients with KRAS exon 2 mutated tumors were found to have a greater overall survival (OS) benefit (13.0 vs 6.9 months with placebo, P=0.0056) than patients with KRAS exon 2 wild-type tumors (7.2 vs 7.0 months, P=0.191). Regarding adverse events, patients who received TAS-102 had significantly more hematological adverse events (including 50% with grade 3–4 neutropenia), as well as diarrhea, nausea, and anorexia than those receiving placebo.

These early phase trials led to the randomized, double-blind, Phase III study of TAS-102 plus BSC versus placebo plus BSC in patients with mCRC refractory to standard chemotherapies (RECOURSE). The RECOURSE trial randomized 800 patients 2:1 to receive 35 mg/m2 TAS-102 or placebo twice daily on days 1–5 and 8–12 every 28 days, stratified by KRAS exon 2 mutation status, time between diagnosis of metastatic disease and randomization (<18 months or not), and region (Japan or US, Europe, and Australia).45 mOS, the primary endpoint, and mPFS were significantly longer following TAS-102 treatment compared with placebo (mOS, 7.1 vs 5.3 months; HR 0.68, 95% CI 0.58–0.81; P<0.001; mPFS, 2.0 vs 1.7 months; HR 0.48, 95% CI 0.41–0.57; P<0.001). Response rates were low, with an objective response rate (ORR) following TAS-102 treatment of 1.6% compared with 0.4% following placebo (P=0.29). Contrary to results from the Phase II study by Yoshino et al,44 there was no significant difference in OS benefit between patients with KRAS exon 2 wild-type and patients with KRAS exon 2 mutant tumors. In the study population as a whole, grade 3–4 neutropenia was more common with TAS-102 than placebo (38% vs 0%), and febrile neutropenia was rare (4% vs 0%). Time to an Eastern Cooperative Oncology Group performance status of ≥2 was also longer following TAS-102 therapy: 5.7 versus 4.0 months (HR 0.66, 95% CI 0.56–0.78; P<0.001). This trial led to the FDA approval of TAS-102 for patients with mCRC refractory to standard therapies.21

Comparison with regorafenib

TAS-102 is often compared with regorafenib, another oral agent approved for refractory mCRC. Regorafenib is a polytyrosine kinase inhibitor that blocks many targets promoting angiogenesis (VEGF receptors 1–3, TIE2, platelet-derived growth factor receptor [PDGFR], and fibroblast growth factor receptor [FGFR]) along with other oncogenic kinases (including KIT, BRAF, and RET).46 The landmark regorafenib monotherapy for previously treated mCRC (CORRECT) trial randomized 760 patients with refractory mCRC 2:1 to regorafenib 160 mg daily or placebo administered on days 1–21 of a 28-day cycle.47 The primary endpoint of mOS was statistically significantly longer following regorafenib therapy: 6.4 versus 5.0 months (HR 0.77, 95% CI 0.64–0.94; P=0.0052). mPFS was also significantly extended by regorafenib (1.9 vs 1.7 months; HR 0.49, 95% CI 0.42–0.58; P<0.0001), but the observed increase in ORR was not significant (1.0% of patients treated with regorafenib had an objective response compared with 0.4% of those receiving placebo; P=0.19). Fifty-four percent of patients who received regorafenib had grade 3–4 adverse events compared with only 14% of those receiving placebo; adverse events included hand–foot skin reaction (17% vs <1%), fatigue (10% vs 5%), diarrhea (7% vs 1%), hypertension (7% vs 1%), and rash (6% vs 4%).

Although both oral agents are approved by the FDA for the treatment of refractory mCRC, TAS-102 and regorafenib have important differences in their side effect profiles; thus, 2 retrospective analyses from Japan demonstrated that TAS-102 and regorafenib have similar efficacy but that regorafenib leads to more hand–foot skin reaction and a greater elevation of liver enzymes and bilirubin, whereas TAS-102 causes more neutropenia, febrile neutropenia, leukopenia, and nausea.48,49 The decision of how to best sequence the order of the 2 drugs is typically based on their side effect profiles. Although efficacy has not been prospectively compared head-to-head, both agents are associated with similar survival outcomes and very low ORRs. Thus, these drugs can be effective at controlling disease but are not expected to elicit tumor shrinkage as single agents.

Predictive biomarkers

A biomarker that is able to predict which patients might benefit most from TAS-102 would be highly useful, and research on potential candidates is ongoing. Early neutropenia following initiation of TAS-102 may be predictive of improved OS. A retrospective study of 95 Japanese patients treated with TAS-102 demonstrated that patients who had grade 2 or greater chemotherapy-induced neutropenia (absolute neutrophil count <1,500/mm3) during the first cycle had an improved disease control rate (52.6% vs 29.2%; odds ratio 2.67, 95% CI 1.01–7.24; P=0.045) and mPFS (2.7 vs 2.0 months; HR 0.59, 95% CI 0.38–0.91; P=0.017), although improvements in mOS were not statistically significant (6.7 vs 5.0 months; HR 0.68, 95% CI 0.41–1.10; P=0.11).50 One prospective cohort study of 149 US patients with refractory mCRC who were chosen for TAS-102 treatment compared subjects who had grade 2 or greater chemotherapy-induced neutropenia at 1 month with those who did not.51 mOS (14.0 vs 5.6 months; P<0.0001) and mPFS (3.0 vs 2.4 months; P=0.0096) were both longer in the neutropenic group. While these results are intriguing, the etiology of this association between neutropenia and improved survival with TAS-102 remains unclear. The authors of the US study postulate that the patients in the non-neutropenic group are rapid TAS-102 metabolizers and therefore are not receiving the same therapeutic benefit. In a post hoc analysis of the Phase II J003 study, neutropenia during the first 2 cycles was also associated with an OS benefit.52 Data from the RECOURSE trial confirm the association between neutropenia and survival: patients who received TAS-102 and had grade 3 or greater neutropenia during any cycle had an OS benefit compared with patients who did not develop neutropenia; additionally, delays between TAS-102 cycles due to neutropenia were also associated with an OS benefit.53 Therefore, intensifying dose and schedule for patients not experiencing grade 2–4 neutropenia may need to be considered, although this strategy should be first evaluated in a prospective trial.

Another interesting post hoc analysis of the RECOURSE trial sorted patients according to number of lines of prior treatment due to progression of disease between lines of therapy. Patients who had >3 prior lines of treatment had significantly improved OS compared with placebo (HR 0.59, 95% CI 0.44–0.78) as opposed to patients with <3 prior lines (HR 0.89, 95% CI 0.65–1.22).54 This study suggests that a greater number of prior lines of therapy may predict improved survival of patients later treated with TAS-102. Also, a prespecified analysis of the RECOURSE trial looked at TAS-102 efficacy in patients aged ≥65 years compared with younger patients (<65 years of age). There were no significant differences in adverse event profiles, and the OS benefit of TAS-102 was similar regardless of age group (≥65 years: n=352, 7.0 months [TAS-102] vs 4.6 months [placebo], HR 0.62, 95% CI 0.48–0.80; P=0.0002; <65 years: n=448, 7.1 vs 5.7 months, HR 0.74, 95% CI 0.59–0.94; P=0.0130).55 Thus, patient age does not appear to be a predictive biomarker of survival with TAS-102.

Defects in the DNA repair pathway within CRC cells may predict susceptibility to TAS-102. When TF-TTP is incorporated into DNA, it induces single-strand breaks that ultimately cause double-strand breaks.37 In response to DNA damage, the homologous recombination repair (HRR) path way mediates DNA repair mechanisms and interacts with cell cycle checkpoints to halt DNA synthesis.56 Suenaga et al analyzed genomic DNA from 181 mCRC patients treated with TAS-102 and 52 patients treated with regorafenib, specifically looking at single nucleotide polymorphisms (SNPs) in HRR pathway genes (ATM, BRCA1, BRCA2, XRCC3, FANCD2, H2AX, and RAD51) and cell cycle checkpoint genes (ATR, CHEK1, CHEK2, CDKN1A, TP53, CHE1, PIN1, and PCNA).57 Genetic variants in the HRR pathway genes—ATM rs609429 and XRCC3 rs861539—were found to be predictive biomarkers of OS upon TAS-102 treatment. Interestingly, there was also an association between neutropenia and ATM rs609429. This field requires further investigation, but combination therapies with TAS-102 and HRR pathway targeting agents have a rational scientific basis.

As it is known that TK phosphorylates trifluridine to TF-TMP, leading to both inhibition of TS and, in a separate pathway, the formation of TF-TTP, which is directly incorporated into DNA, the finding that TK and TS are frequently overexpressed in CRC cells is promising for using TAS-102 in patients with CRC.58 In studies using CRC cell lines, TAS-102 resistance mechanisms included decreased expression of TK and human equilibrative nucleoside transporter (hENT), the transmembrane transport protein responsible for allowing cellular influx of trifluridine.59 Thus, tumors with high TK expression should be more susceptible to TAS-102 due to increased formation of TF-TMP and TF-TTP. In a pooled retrospective analysis of patients with refractory mCRC, patients with high tumor TK1 expression (cytoplasmic TK) had significantly improved mOS upon treatment with TAS-102 compared with placebo. Interestingly, it was observed that patients with high TK1 who received placebo had an overall worse prognosis than those with low TK1.60 Therefore, it was concluded that high TK1 expression is a negative prognostic factor in general but a positive predictor of TAS-102 efficacy. Similarly, the hENT-1 germline SNPs rs760370 and rs9394992 have also been shown to be candidate prognostic and predictive biomarkers in retrospective studies.61 TK1 and hENT-1 expression should be validated as predictive and prognostic biomarkers in future prospective studies of TAS-102.

Combination therapies with TAS-102 and ongoing clinical trials

Given the low response rate associated with TAS-102, there is significant interest in combining it with other effective therapies. Preclinical CRC xenograft models have demonstrated synergy when combining TAS-102 with bevacizumab, panitumumab, or cetuximab.62,63 High quality data from the ML18147 and BRiTE studies support the use of bevacizumab beyond disease progression and into later lines of CRC therapy.16,17 In a Phase I/II trial of TAS-102 combined with bevacizumab, Kuboki et al confirmed that standard dosing of TAS-102 (35 mg/m2 twice daily on days 1–5 and 8–12 of a 28-day cycle) and bevacizumab (5 mg/kg every 14 days) were the RP2Ds, and the study met its primary endpoint; thus, the PFS rate at 16 weeks was 42.9% (95% CI 27.8%–59.0%) in 21 evaluable patients with refractory mCRC.64 mPFS and mOS were relatively impressive at 5.6 and 11.2 months, respectively, although these findings should be validated in a randomized trial. One ongoing randomized Phase II trial is comparing TAS-102 plus bevacizumab therapy with capecitabine plus bevacizumab therapy in patients with untreated mCRC deemed unsuitable for intensive therapy (defined as combination 5-FU with oxaliplatin or irinotecan, TASCO1, NCT02743221, Table 2). While both capecitabine and TAS-102 inhibit TS, TAS-102 could be more effective in untreated mCRC patients because of direct TF-TTP incorporation into DNA and resistance to degradation by DNA glycosylase as described in the “Pharmacology” section above. Our institution has an ongoing Phase II trial of TAS-102 plus bevacizumab as maintenance therapy for patients with mCRC and stable disease or better after first-line chemotherapy (ALEXANDRIA, NCT02654639).65

Table 2.

Ongoing TAS-102 trials in mCRC

Title Trial Ph Patient population Treatment Primary outcome
A Phase I/II study for the safety and efficacy of panitumumab in combination with TAS-102 for patients with colorectal cancer (APOLLON) NCT02613221 I/II 56, RAS wild-type refractory mCRC Panitumumab + TAS-102 PFS @ 6 months (Ph I: RP2D is standard dosing)
TAS-102 and radioembolization with 90Y resin microspheres for chemo-refractory colorectal liver metastases NCT02602327 I 24, liver-dominant, refractory mCRC 90Y TARE + TAS-102 Safety (adverse events)
A study evaluating TAS-102 plus nivolumab in patients with MSS CRC NCT02860546 II 35, MSS refractory mCRC Nivolumab + TAS-102 irORR
Phase I study of SGI-110 with irinotecan followed by randomized Phase II study of SGI-110 with irinotecan versus regorafenib or TAS-102 in previously treated mCRC NCT01896856 I/II 108, refractory mCRC SGI-110 + irinotecan vs regorafenib or TAS-102 Safety (adverse events), ORR
Study of TAS-102 in patients with mCRC in Asia (TERRA) NCT01955837 III 400, refractory mCRC, Asia only TAS-102 vs PBO OS
Phase II study of TAS-102/bevacizumab maintenance therapy post-induction chemotherapy in mCRC (ALEXANDRIA) NCT02654639 II 45, maintenance (stable disease or better on first-line chemotherapy) Bevacizumab + TAS-102 PFS
Study of S 95005 in combination with oxaliplatin in mCRC NCT02848443 I 94, mCRC, second line or greater TAS-102 + oxaliplatin (± bevacizumab or nivolumab) MTD
TAS-OX for refractory mCRC NCT02848079 I/II 68, mCRC, third line or greater Oxaliplatin + TAS-102 ORR
A study evaluating S 95005 plus bevacizumab in patients with previously untreated colorectal cancer who are non-eligible for intensive therapy (TASCO1) NCT02743221 II 150, mCRC, first line TAS-102 + bevacizumab vs capecitabine + bevacizumab PFS
Multicenter Phase Ib/II trial of nintedanib with TAS-102 in patients with mCRC who had progression or were intolerant to standard therapies (N-task force: EPOC1410) UMIN000017114 I/II 52, mCRC refractory/intolerant Nintedanib + TAS-102 MTD, PFS @ 16 weeks

Abbreviations: mCRC, metastatic colorectal cancer; PFS, progression-free survival; RP2D, recommended Phase II dose; TARE, transarterial radioembolization; MSS, microsatellite stable; irORR, immune-related objective response rate; CRC, colorectal cancer; ORR, objective response rate; PBO, placebo; OS, overall survival; Ph, phase; MTD, maximum tolerated dose.

Another potentially exciting clinical strategy is to combine TAS-102 with the anti-EGFR mAbs cetuximab and panitumumab. Kato et al are conducting the APOLLON trial, a Japanese Phase I/II study of panitumumab combined with TAS-102 in patients with RAS wild-type, refractory mCRC (NCT02613221). Phase I results confirmed that the RP2Ds are standard panitumumab (6 mg/kg every 14 days) and TAS-102 dosing (35 mg/m2 twice daily on days 1–5 and 8–12 of a 28-day cycle), and Phase II is ongoing.66

Aside from the use of combination biological agents in the form of mAbs, there are also ongoing studies using chemotherapy in combination with TAS-102. The combination of TAS-102 and oxaliplatin is supported in mouse xenograft studies.67 TAS-102 and oxaliplatin are being evaluated in an ongoing Phase I/II study of patients with refractory mCRC (NCT02848079). In a Phase I study of combination irinotecan and TAS-102, the RP2D of irinotecan was 150 mg/m2 on days 1 and 15, and the RP2D of TAS-102 was 50 mg/m2/day split into 2 daily doses on days 1–5 and 8–12, both on a 28-day cycle.68 There is also an ongoing Phase I study evaluating TAS-102 in combination with irinotecan and bevacizumab (NCT01916447).

Nintedanib is an oral antiangiogenic agent that inhibits VEGF receptors 1–3, PDGFRs-α/β, FGFR1–3, RET, FLT3, Lck, and Lyn.69,70 An ongoing Phase III trial is comparing the efficacy of nintedanib (200 mg twice daily) plus BSC compared with that of placebo plus BSC, both in 21-day courses (LUME-Colon 1, NCT02149108).71 Additionally, nintedanib is being studied in combination with TAS-102 in a Phase I/II Japanese study. In the Phase I portion of the study, the RP2D of TAS-102 was established at 50 mg/m2/day on days 1–5 and 8–12, and the RP2D of nintedanib was established at 200 mg twice daily, both on a 28-day cycle; the Phase II part of the study is ongoing (UMIN000017114).72

Finally, there is considerable effort underway to combine immune checkpoint inhibitors with other agents to treat microsatellite stable (MSS) mCRC. While pembrolizumab is effective in dMMR or MSI-H mCRC, no objective responses have been seen in MSS mCRC.18,19 Ongoing studies include a Phase II study of nivolumab, an anti-PD1 mAb, combined with TAS-102 in refractory MSS mCRC (NCT02860546) and a Phase I study of TAS-102 and oxaliplatin with or without bevacizumab or nivolumab (NCT02848443). Results from these studies will help inform future combination strategies with TAS-102.

Conclusion

TAS-102 is an excellent addition to the armamentarium of treatments for mCRC. However, valid biomarkers of potential efficacy need to be established to improve patient selection for TAS-102 therapy. Given the better outcomes of patients who develop neutropenia, future studies might evaluate dose and schedule intensification in patients without neutropenia. In addition, there are limited prospective data regarding combination strategies. The increased efficacy of TAS-102 in combination with bevacizumab is supported by Phase II data and is frequently utilized in our clinical practice, although the benefit of bevacizumab in this setting has not been confirmed in a randomized trial. Ongoing studies are evaluating a range of TAS-102 combinations and the use of TAS-102 in earlier lines of therapy. Important strides are being made in the treatment of mCRC, but more effective therapies are still needed.

Acknowledgments

We would like to thank Marion L Hartley for her edits to this review.

Footnotes

Disclosure

The authors report no conflicts of interest in this work.

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