Background: Futibatinib is an oral, irreversible, highly selective fibroblast growth factor receptor (FGFR)1e4 inhibitor with potent preclinical activity against tumors harboring FGFR aberrations. This first-in-human, phase I dose-escalation trial (NCT02052778) evaluates the safety and pharmacokinetics/pharmacodynamics of futibatinib in advanced solid tumors. Patients and methods: Following a standard 3þ3 dose-escalation design, eligible patients with advanced solid tumors refractory to standard therapies received 8e200 mg futibatinib three times a week (t.i.w.) or 4e24 mg once daily (q.d.). Results: A total of 86 patients were enrolled in the nine t.i.w. (n ¼ 42) and five q.d. cohorts (n ¼ 44); 71 patients (83%) had tumors harboring FGF/FGFR aberrations. Three of nine patients in the 24-mg q.d. cohort experienced dose-limiting toxicities, including grade 3 increases in alanine transaminase, aspartate transaminase, and blood bilirubin (n ¼ 1 each). The maximum tolerated dose (MTD) was determined to be 20 mg q.d.; no MTD was defined for the t.i.w. schedule. Across cohorts (n ¼ 86), the most common treatment-emergent adverse events (TEAEs) were hyperphosphatemia (59%), diarrhea (37%), and constipation (34%); 48% experienced grade 3 TEAEs. TEAEs led to dose interruptions, dose reductions, and treatment discontinuations in 55%, 14%, and 3% of patients, respectively. Pharmacokinetics were dose proportional across all q.d. doses but not all t.i.w. doses evaluated, with saturation observed between 80 and 200 mg t.i.w. Serum phosphorus increased dose dependently with futibatinib on both schedules, but a stronger exposureeresponse relationship was observed with q.d. dosing, supporting 20 mg q.d. as the recommended phase II dose (RP2D). Overall, partial responses were observed in five patients [FGFR2 fusion-positive intrahepatic cholangiocarcinoma (n ¼ 3) and FGFR1-mutant primary brain tumor (n ¼ 2)], and stable disease in 41 (48%). Conclusions: Futibatinib treatment resulted in manageable safety, pharmacodynamic activity, and preliminary responses in patients with advanced solid tumors. The results of this phase I dose-escalation trial support 20 mg q.d. futibatinib as the RP2D. Clinical trial registration: FOENIX-101 (ClinicalTrials.gov, NCT02052778).
Futibatinib, an oral, irreversible fibroblast growth factor receptor (FGFR) 1-4 inhibitor, is being evaluated for FGFRaberrant tumors. Two open-label phase 1 studies evaluated the effects of high-fat, high-calorie food and concomitant proton pump inhibitors (PPIs; lansoprazole) on single-dose futibatinib (20 mg) pharmacokinetics and safety in healthy adults. In the food effect study (N = 17), subjects received futibatinib under fed and fasted conditions, separated by a 7-day washout. In the PPI study (N = 20), subjects received futibatinib alone, underwent a 2-day washout, and then received lansoprazole 60 mg once daily for 5 days, with futibatinib also administered on day 5. Under fed versus fasted conditions, futibatinib bioavailability was 11.2% lower (area under the plasma concentration-time curve from time 0 to infinity geometric mean ratio 88.8%; 90% confidence interval, 79.8%-98.9%), and median time to maximum plasma concentration was significantly delayed (4.0 vs 1.5 hours; P < .0001). There were no significant differences in futibatinib exposure between futibatinib plus lansoprazole and futibatinib alone. No serious adverse events occurred in either study. These findings suggest that food and PPIs are unlikely to have clinically meaningful impacts on futibatinib bioavailability. Thus, futibatinib may be used with or without food and concomitantly with acid-reducing agents.
Tegafur (FT), a prodrug of 5-fluorouracil, is a chiral molecule, a racemate of R-and S-isomers, and CYP2A6 plays an important role in the enantioselective metabolism of FT in human liver microsomes (R-FT >> S-FT). This study examined the enantioselective metabolism of FT by microsomes prepared from Sf9 cells expressing wildtype CYP2A6 and its variants (CYP2A6*7, *8, *10, and *11) that are highly prevalent in the Asian population. We also investigated the metabolism of coumarin and nicotine, both CYP2A6 probe drugs, in these variants. Enzyme kinetic analyses showed that CYP2A6.7 (I471T) and CYP2A6.10 (I471T and R485L) had markedly lower V max values for both enantiomers than wild-type enzyme (CYP2A6.1) and other variant enzymes, whereas K m values were higher in most of the variant enzymes for both enantiomers than CYP2A6.1. The ratios of V max and K m values for R-FT to corresponding values for S-FT (R/S ratio) were similar among enzymes, indicating little difference in enantioselectivity among the wild-type and variant enzymes. Similarly, both CYP2A6.7 and CYP2A6.10 had markedly lower V max values for coumarin 7-hydroxylase and nicotine C-oxidase activities than CYP2A6.1 and other variant enzymes, whereas K m values were higher in most of the variant enzymes for both activities than CYP2A6.1. In conclusion, the amino acid substitutions in CYP2A6 variants generally resulted in lower affinity for substrates, while V max values were selectively reduced in CYP2A6.7 and CYP2A6.10. Consistent R/S ratios among CYP2A6.1 and variant enzymes indicated that the amino acid substitutions had little effect on enantioselectivity in the metabolism of FT.
Background Futibatinib is an oral, irreversible FGFR1-4 inhibitor with clinical activity in cholangiocarcinoma and other FGFR-aberrant tumors. The recommended futibatinib dosage is 20 mg once daily (QD). In vitro studies have shown that futibatinib is predominantly metabolized by and inhibits cytochrome p450 3A (CYP3A); futibatinib is also a P-glycoprotein substrate. Two phase 1 studies were performed in healthy volunteers to evaluate potential DDIs between futibatinib and CYP3A substrates (midazolam; study 1) or CYP3A inhibitors/inducers (itraconazole/rifampin; study 2). As the solubility of futibatinib is pH dependent, study 3 assessed the effect of PPI (lansoprazole) coadministration on futibatinib pharmacokinetics (PK). Methods All 3 studies, conducted in adult nonsmokers, were open-label, fixed-sequence, 2-period cross-over studies with a 1- or 2-d washout between each period. In study 1, midazolam 2 mg was given on d1 of period 1 (-futibatinib) and on d7 of period 2 (+futibatinib 20 mg QD d1-7). In study 2, futibatinib 20 mg was given on d1 of period 1 (alone) and on d5 (+itraconazole 200 mg QD d1-6) or d8 (+rifampin 600 mg QD d1-9) of period 2. In study 3, futibatinib 20 mg was given on d1 of period 1 (-lansoprazole) and d5 of period 2 (+lansoprazole 60 mg QD d1-5). Plasma samples for PK assessment were collected predose through 24 h post-midazolam dosing (study 1) and predose through 48 h post-futibatinib dosing (studies 2 and 3). Results In study 1 (N=24), coadministration of futibatinib did not result in clinically significant changes in midazolam PK, based on the area under the concentration curve extrapolated to the last measurable time (AUC0-t; -9%) or infinity (AUC0-inf; -9%) or maximum plasma concentration (Cmax; -5%), compared with midazolam alone. In study 2 (N=40), relative to futibatinib administered alone, coadministration with itraconazole increased futibatinib Cmax (+51%) and plasma exposure (AUC0-t and AUC0-inf +41% each), whereas coadministration with rifampin decreased futibatinib Cmax (-53%) and plasma exposure (AUC0-t and AUC0-inf -64% each). In study 3 (N=20), coadministration of lansoprazole did not result in clinically significant changes in futibatinib PK parameters vs futibatinib alone (AUC0-t +5%; AUC0-inf +5%; Cmax +8%). Agents were well tolerated, and all 3 studies were completed with no clinically relevant safety signals. Conclusions Futibatinib is not expected to affect the exposure of concomitant medications metabolized via CYP3A, the most common drug metabolism pathway. Caution should be exercised when coadministering strong CYP3A inducers or inhibitors with futibatinib, as significant DDIs were observed with itraconazole and rifampin. Futibatinib can be concomitantly administered with PPIs with no clinically relevant impact on futibatinib exposure. Citation Format: Ikuo Yamamiya, John Laabs, Allen Hunt, Toru Takenaka, Daryl Sonnichsen, Mark Mina, Yaohua He, Karim Benhadji. Evaluation of potential drug-drug interactions (DDIs) between futibatinib and CYP3A inhibitors/inducers, CYP3A substrates, or proton pump inhibitors (PPIs) [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr CT125.
ABSTRACT:Tegafur (FT) is a 5-fluorouracil (5-FU) prodrug that has been clinically used for various cancer chemotherapies. The following metabolites of FT were identified in patients: 5-FU, fluoro--alanine, and ␥-butyrolactone (GBL) and its acidic form, ␥-hydroxybutyrate (GHB). GBL/ GHB, which is probably generated from the furan ring of FT, inhibits tumor cell angiogenesis, contributing to the antitumor effect of FTbased therapies. In the present study, we identified the metabolites formed from the furan ring of FT by CYP2A6 and thymidine phosphorylase (TPase) using 2,4-dinitrophenylhydrazine derivatization procedures and clarified the metabolic pathway of FT to GBL/GHB. Succinaldehyde (SA) and 4-hydroxybutanal (4-OH-BTL) were produced as the metabolites because of the cleavage of the furan ring of FT during its conversion to 5-FU in cDNA-expressed CYP2A6 and purified TPase, respectively; however, GBL/GHB was hardly detected in cDNA-expressed CYP2A6 and purified TPase. GBL/GHB was formed after human hepatic microsomes or cDNA-expressed CYP2A6 mixed with cytosol were incubated with FT. Furthermore, 4-OH-BTL was converted to GBL/GHB in the microsomes and cytosol. These results suggest that GBL/GHB is generated from FT through the formation of SA and 4-OH-BTL but not directly from FT. Furthermore, the amount of 5-FU and GBL/GHB formed in the hepatic S9 was markedly decreased in the presence of a CYP2A6 inhibitor, suggesting that GBL/ GHB may be mainly generated through the CYP2A6-mediated formation of SA.
Deregulating fibroblast growth factor receptor (FGFR) signaling is a promising strategy for cancer therapy. Herein, we report the discovery of compound 5 (TAS-120, futibatinib), a potent and selective covalent inhibitor of FGFR1−4, starting from a unique dual inhibitor of mutant epidermal growth factor receptor and FGFR (compound 1). Compound 5 inhibited all four families of FGFRs in the single-digit nanomolar range and showed high selectivity for over 387 kinases. Binding site analysis revealed that compound 5 covalently bound to the cysteine 491 highly flexible glycine-rich loop region of the FGFR2 adenosine triphosphate pocket. Futibatinib is currently in Phase I−III trials for patients with oncogenically driven FGFR genomic aberrations. In September 2022, the U.S. Food & Drug Administration granted accelerated approval for futibatinib in the treatment of previously treated, unresectable, locally advanced, or metastatic intrahepatic cholangiocarcinoma harboring an FGFR2 gene fusion or other rearrangement.
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