Futibatinib 4mg tablets
Requires a prescription from a doctor or prescriber
Futibatinib is an inhibitor of Fibroblast Growth Factor receptor (FGFR), which comprises a group of receptor tyrosine kinases that play a key role in cell proliferation, differentiation, migration, and survival.
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Suspected adverse reactions reported for Futibatinib
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Lytgobi 4mg tablets
Therapeutically similar medicines
Similarity is based on WHO Anatomical Therapeutic Chemical (ATC) classification and on a factual NHS dm+d therapeutic-grouping code prefix. Source data: NHS dm+d via TRUD (OGL v3.0), WHO ATC/DDD Index.
NHS prescribing volume and spending trends
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NICE clinical guidance(1)
Source: National Institute for Health and Care Excellence (NICE). Contains public sector information licensed under the Open Government Licence v3.0.
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Codes for healthcare professionals and prescribing systems
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NHS UK identifiers
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SNOMED CT and dm+d codes from NHS TRUD (Technology Reference data Update Distribution), licensed under the Open Government Licence v3.0. BNF code shown is the factual mapping value distributed by NHS Business Services Authority (NHSBSA) in the dm+d supplementary file under OGL v3.0; it is not affiliated with, nor licensed from, the publishers of the British National Formulary. ATC codes from the WHO Collaborating Centre for Drug Statistics Methodology (whocc.no).
Active and completed clinical studies from ClinicalTrials.gov
Source: ClinicalTrials.gov, a database of the U.S. National Library of Medicine (NLM), National Institutes of Health (NIH). Data accessed via ClinicalTrials.gov API v2. Trial information is provided for research purposes and does not constitute medical advice.
Academic studies and reviews for this medicine's active substance
Showing the 50 most relevant studies.
Reviews & meta-analyses: 4 · 2020–2026
Showing the 50 most relevant studies, sorted by most relevant.
Giulia Matranga, Anna Carollo, Miriam Alaimo, et al.
Therapeutic Advances in Drug Safety, 2025
Background: Cholangiocarcinoma (CCA) is a cancer with a low survival rate. New drugs targeting molecular alterations, oncogenic mutations, and gene fusions are being tested as second-line treatments. Objectives: This systematic review aims to summarize the results obtained with three new targeted therapies—pemigatinib, futibatinib, and ivosidenib—for the treatment of CCA, evaluating their safety and tolerability profiles in patients, compared to current standard therapies. Data sources and methods: A systematic literature search was performed with a cutoff date of July 24, 2023, in MEDLINE, Embase, and the Cochrane Library. The authors also conducted an advanced search in the ClinicalTrials.gov database, evaluated conference abstracts, article bibliographies, and drug monographs. Studies involving the treatment of patients with pemigatinib, futibatinib, and ivosidenib were considered. The selected studies had to report adverse events (AEs) that occurred during treatment with these therapies. Results: The most common AEs observed with pemigatinib, futibatinib, and ivosidenib were alopecia, diarrhea, fatigue, and dysgeusia. In addition, hyperphosphatemia, hypophosphatemia, and ocular disorders were observed with fibroblast growth factor receptor (FGFR) inhibitors, while the isocitrate dehydrogenase 1 (IDH1) inhibitor was associated with dose-dependent prolongation of the corrected QT interval (QTc). These AEs were effectively managed through dose adjustments. Conclusion: FGFR2 and IDH1 inhibitors have good tolerability in the population examined. All AEs were optimally managed with dose modulation. Future studies should focus on identifying the most effective dosages to further enhance treatment safety.
Abstract licence: CC BY-NC 4.0
Lipika Goyal, Funda Meric‐Bernstam, Antoine Hollebecque, et al.
New England Journal of Medicine, 2023
- Antineoplastic Agents
- Bile Duct Neoplasms
- Bile Ducts, Intrahepatic
Funda Meric‐Bernstam, Rastislav Bahleda, Cinta Hierro, et al.
Cancer Discovery, 2021
- Antineoplastic Agents
- Bile Duct Neoplasms
- Pyrazoles
Abstract Futibatinib, a highly selective, irreversible FGFR1–4 inhibitor, was evaluated in a large multihistology phase I dose-expansion trial that enrolled 197 patients with advanced solid tumors. Futibatinib demonstrated an objective response rate (ORR) of 13.7%, with responses in a broad spectrum of tumors (cholangiocarcinoma and gastric, urothelial, central nervous system, head and neck, and breast cancer) bearing both known and previously uncharacterized FGFR1–3 aberrations. The greatest activity was observed in FGFR2 fusion/rearrangement–positive intrahepatic cholangiocarcinoma (ORR, 25.4%). Some patients with acquired resistance to a prior FGFR inhibitor also experienced responses with futibatinib. Futibatinib demonstrated a manageable safety profile. The most common treatment-emergent adverse events were hyperphosphatemia (81.2%), diarrhea (33.5%), and nausea (30.4%). These results formed the basis for ongoing futibatinib phase II/III trials and demonstrate the potential of genomically selected early-phase trials to help identify molecular subsets likely to benefit from targeted therapy. Significance: This phase I dose-expansion trial demonstrated clinical activity and tolerability of the irreversible FGFR1–4 inhibitor futibatinib across a broad spectrum of FGFR-aberrant tumors. These results formed the rationale for ongoing phase II/III futibatinib trials in cholangiocarcinoma, breast cancer, gastroesophageal cancer, and a genomically selected disease-agnostic population. This article is highlighted in the In This Issue feature, p. 275
Abstract licence: CC BY-NC-ND 4.0
Hiroshi Sootome, Hidenori Fujita, Kenjiro Ito, et al.
Cancer Research, 2020
- Antineoplastic Agents
- Breast Neoplasms
- Lung Neoplasms
Rastislav Bahleda, Funda Meric‐Bernstam, Lipika Goyal, et al.
Annals of Oncology, 2020
- Antineoplastic Agents
- Neoplasms
- Maximum Tolerated Dose
Lipika Goyal, Funda Meric‐Bernstam, Antoine Hollebecque, et al.
Journal of Clinical Oncology, 2022
Lily Darman, Quinn Kaurich, Md Sazzad Hassan, et al.
International Journal of Molecular Sciences, 2025
- Cholangiocarcinoma
- Bile Duct Neoplasms
- Isocitrate Dehydrogenase
Cholangiocarcinoma (CCA) is a biliary tract cancer that accounts for approximately 3% of all gastrointestinal cancers. CCA is a “silent” disease that remains undetected for a long period of time, often presenting at an advanced stage with minimal treatment options and a poor prognosis. Advanced CCA remains largely inoperable, and combination gemcitabine plus cisplatin (GemCis) chemotherapy remains the standard treatment for patients affected by this disease. There is a desperate need for new therapeutic alternatives, and extensive research is ongoing to address this gap. Targeted therapies represent a rapidly expanding area of cancer treatment and are currently under active investigation in CCA. The FDA has approved the targeted therapies ivosidenib, pemigatinib, infigratinib, and futibatinib, as well as the immunotherapy durvalumab, for patients with CCA in recent years. Several other therapeutic strategies are still under investigation, targeting molecular pathways including p53/MDM2, JAK/STAT, KRAS, HER2, VEGFR, PDGFR, MET, ALK, MAPK, PI3K/AKT, BRAF, and DNA damage repair signaling. While several promising advancements have been made, further research is required to improve outcomes for patients with CCA. This review provides an up-to-date, comprehensive overview of currently approved targeted therapies in CCA, as well as those under investigation.
Abstract licence: CC BY
Sheridan M. Hoy
Targeted Oncology, 2024
- Cholangiocarcinoma
- Bile Duct Neoplasms
- Neoplasm Metastasis
Alessandro Rizzo, Angela Dalia Ricci, Giovanni Brandi
Expert Opinion on Investigational Drugs, 2020
- Antineoplastic Agents
- Bile Duct Neoplasms
- Pyrazoles
Milind Javle, Gentry King, Kristen Spencer, et al.
The Oncologist, 2023
- Bile Duct Neoplasms
- Cholangiocarcinoma
- Bile Ducts, Intrahepatic
AbstractFibroblast growth factor receptors (FGFR) are emerging as an important therapeutic target for patients with advanced, refractory cancers. Most selective FGFR inhibitors under investigation show reversible binding, and their activity is limited by acquired drug resistance. This review summarizes the preclinical and clinical development of futibatinib, an irreversible FGFR1-4 inhibitor. Futibatinib stands out among FGFR inhibitors because of its covalent binding mechanism and low susceptibility to acquired resistance. Preclinical data indicated robust activity of futibatinib against acquired resistance mutations in the FGFR kinase domain. In early-phase studies, futibatinib showed activity in cholangiocarcinoma, and gastric, urothelial, breast, central nervous system, and head and neck cancers harboring various FGFR aberrations. Exploratory analyses indicated clinical benefit with futibatinib after prior FGFR inhibitor use. In a pivotal phase II trial, futibatinib demonstrated durable objective responses (42% objective response rate) and tolerability in previously treated patients with advanced intrahepatic cholangiocarcinoma harboring FGFR2 fusions or rearrangements. A manageable safety profile was observed across studies, and patient quality of life was maintained with futibatinib treatment in patients with cholangiocarcinoma. Hyperphosphatemia, the most common adverse event with futibatinib, was well managed and did not lead to treatment discontinuation. These data show clinically meaningful benefit with futibatinib in FGFR2-rearrangement-positive cholangiocarcinoma and provide support for further investigation of futibatinib across other indications. Future directions for this agent include elucidating mechanisms of resistance and exploration of combination therapy approaches.
Abstract licence: CC BY-NC 4.0
Sources: aggregated from Europe PMC (EMBL-EBI), OpenAlex, Crossref, PubMed and other open scholarly databases. Retracted articles are excluded. Study information is provided for research purposes and does not constitute medical advice.
Pharmacology and chemical data from DrugBank
Key facts
Drug status
Approved
Major interactions
None known
Half-life
2.9 hours
Mechanism
Fibroblast Growth Factor receptor (FGFR) pathway play a key role in cell prolife…
Food interactions
2 warnings
Human targets
4 targets
Data: DrugBank · CC BY-NC 4.0
Pharmacokinetics at a glance
Absorption
1.2 to 22.8 hours
Half-life
2.9 hours
[L43347]
Protein binding
95%
[L43347]
Volume of distribution
66 L
[L43347]
Metabolism
59%
Elimination
20 mg
Clearance
20 L/h
[L43347]
Pharmacokinetic data: DrugBank · CC BY-NC 4.0
As a novel inhibitor of FGFR, futibatinib was first approved by the FDA in September 2022 to treat different types of intrahepatic cholangiocarcinoma.[L43347] On July 4, 2023, the European Commission granted Conditional Marketing Authorization for futibatinib for the treatment of cholangiocarcinoma.[L47800]
[L43347]
In Europe, it is indicated in patients whose disease has progressed after at least one prior line of systemic therapy.
[L47795]
Futibatinib is approved in the US under accelerated approval and in Europe under conditional marketing authorization. This currently approved indication is subject to change, as it may be contingent upon verification and description of clinical benefit in a confirmatory trial(s).
[L43347]
Known interactions with other medications. Always consult a healthcare professional.
Showing 50 of 356 interactions
Futibatinib is a selective, irreversible inhibitor of FGFR 1, 2, 3, and 4 with IC50 values of less than 4 nM.[A253198][L43347] It binds to the FGFR kinase domain by forming a covalent bond with cysteine in the ATP-binding pocket.[A253198] Upon binding to FGFR, futibatinib blocks FGFR phosphorylation and downstream signalling pathways,[L43347] such as the RAS-dependent mitogen-activated protein kinase (MAPK), phosphatidylinositol 3-kinase (PI3KCA)/Akt/mTOR, phospholipase Cγ (PLCγ), and JAK/STAT.[A253223] Futibatinib ultimately decreases cell viability in cancer cell lines with FGFR alterations, including FGFR fusions or rearrangements, amplifications, and mutations.[L43347]
How the body processes this drug — absorption, distribution, metabolism, and elimination
[L43347]
[L43347]
[L43347]
[L43347]
[L43347]
[L43347]
[L43347]
Proteins and enzymes this drug interacts with in the body
Ligand binding leads to the activation of several signaling cascades. Activation of PLCG1 leads to the production of the cellular signaling molecules diacylglycerol and inositol 1,4,5-trisphosphate. Phosphorylation of FRS2 triggers recruitment of GRB2, GAB1, PIK3R1 and SOS1, and mediates activation of RAS, MAPK1/ERK2, MAPK3/ERK1 and the MAP kinase signaling pathway, as well as of the AKT1 signaling pathway.
Promotes phosphorylation of SHC1, STAT1 and PTPN11/SHP2. In the nucleus, enhances RPS6KA1 and CREB1 activity and contributes to the regulation of transcription. FGFR1 signaling is down-regulated by IL17RD/SEF, and by FGFR1 ubiquitination, internalization and degradation
Promotes cell proliferation in keratinocytes and immature osteoblasts, but promotes apoptosis in differentiated osteoblasts. Phosphorylates PLCG1, FRS2 and PAK4. Ligand binding leads to the activation of several signaling cascades.
Activation of PLCG1 leads to the production of the cellular signaling molecules diacylglycerol and inositol 1,4,5-trisphosphate. Phosphorylation of FRS2 triggers recruitment of GRB2, GAB1, PIK3R1 and SOS1, and mediates activation of RAS, MAPK1/ERK2, MAPK3/ERK1 and the MAP kinase signaling pathway, as well as of the AKT1 signaling pathway. FGFR2 signaling is down-regulated by ubiquitination, internalization and degradation.
Mutations that lead to constitutive kinase activation or impair normal FGFR2 maturation, internalization and degradation lead to aberrant signaling. Over-expressed FGFR2 promotes activation of STAT1.
Promotes apoptosis in chondrocytes, but can also promote cancer cell proliferation. Required for normal development of the inner ear. Phosphorylates PLCG1, CBL and FRS2.
Ligand binding leads to the activation of several signaling cascades. Activation of PLCG1 leads to the production of the cellular signaling molecules diacylglycerol and inositol 1,4,5-trisphosphate. Phosphorylation of FRS2 triggers recruitment of GRB2, GAB1, PIK3R1 and SOS1, and mediates activation of RAS, MAPK1/ERK2, MAPK3/ERK1 and the MAP kinase signaling pathway, as well as of the AKT1 signaling pathway.
Plays a role in the regulation of vitamin D metabolism. Mutations that lead to constitutive kinase activation or impair normal FGFR3 maturation, internalization and degradation lead to aberrant signaling. Over-expressed or constitutively activated FGFR3 promotes activation of PTPN11/SHP2, STAT1, STAT5A and STAT5B.
Secreted isoform 3 retains its capacity to bind FGF1 and FGF2 and hence may interfere with FGF signaling
Ligand binding leads to the activation of several signaling cascades. Activation of PLCG1 leads to the production of the cellular signaling molecules diacylglycerol and inositol 1,4,5-trisphosphate. Phosphorylation of FRS2 triggers recruitment of GRB2, GAB1, PIK3R1 and SOS1, and mediates activation of RAS, MAPK1/ERK2, MAPK3/ERK1 and the MAP kinase signaling pathway, as well as of the AKT1 signaling pathway.
Promotes SRC-dependent phosphorylation of the matrix protease MMP14 and its lysosomal degradation. FGFR4 signaling is down-regulated by receptor internalization and degradation; MMP14 promotes internalization and degradation of FGFR4. Mutations that lead to constitutive kinase activation or impair normal FGFR4 inactivation lead to aberrant signaling
Enzymes involved in drug metabolism — important for understanding drug interactions
Proteins that transport this drug across cell membranes
PMID:2897240 PMID:35970996 PMID:8898203 PMID:9038218 PMID:35507548
Catalyzes the flop of phospholipids from the cytoplasmic to the exoplasmic leaflet of the apical membrane. Participates mainly to the flop of phosphatidylcholine, phosphatidylethanolamine, beta-D-glucosylceramides and sphingomyelins .
PMID:8898203
Energy-dependent efflux pump responsible for decreased drug accumulation in multidrug-resistant cells PMID:2897240 PMID:35970996 PMID:9038218
PMID:11306452 PMID:12958161 PMID:19506252 PMID:20705604 PMID:28554189 PMID:30405239 PMID:31003562
Involved in porphyrin homeostasis, mediating the export of protoporphyrin IX (PPIX) from both mitochondria to cytosol and cytosol to extracellular space, it also functions in the cellular export of heme .
PMID:20705604 PMID:23189181
Also mediates the efflux of sphingosine-1-P from cells .
PMID:20110355
Acts as a urate exporter functioning in both renal and extrarenal urate excretion .
PMID:19506252 PMID:20368174 PMID:22132962 PMID:31003562 PMID:36749388
In kidney, it also functions as a physiological exporter of the uremic toxin indoxyl sulfate (By similarity). Also involved in the excretion of steroids like estrone 3-sulfate/E1S, 3beta-sulfooxy-androst-5-en-17-one/DHEAS, and other sulfate conjugates .
PMID:12682043 PMID:28554189 PMID:30405239
Mediates the secretion of the riboflavin and biotin vitamins into milk (By similarity). Extrudes pheophorbide a, a phototoxic porphyrin catabolite of chlorophyll, reducing its bioavailability (By similarity).
Plays an important role in the exclusion of xenobiotics from the brain (Probable). It confers to cells a resistance to multiple drugs and other xenobiotics including mitoxantrone, pheophorbide, camptothecin, methotrexate, azidothymidine, and the anthracyclines daunorubicin and doxorubicin, through the control of their efflux .
PMID:11306452 PMID:12477054 PMID:15670731 PMID:18056989 PMID:31254042
In placenta, it limits the penetration of drugs from the maternal plasma into the fetus (By similarity). May play a role in early stem cell self-renewal by blocking differentiation (By similarity).
In inflammatory macrophages, exports itaconate from the cytosol to the extracellular compartment and limits the activation of TFEB-dependent lysosome biogenesis involved in antibacterial innate immune response
Proteins that carry this drug through the body
PMID:19021548
Major calcium and magnesium transporter in plasma, binds approximately 45% of circulating calcium and magnesium in plasma (By similarity).
Potentially has more than two calcium-binding sites and might additionally bind calcium in a non-specific manner (By similarity). The shared binding site between zinc and calcium at residue Asp-273 suggests a crosstalk between zinc and calcium transport in the blood (By similarity). The rank order of affinity is zinc > calcium > magnesium (By similarity).
Binds to the bacterial siderophore enterobactin and inhibits enterobactin-mediated iron uptake of E.coli from ferric transferrin, and may thereby limit the utilization of iron and growth of enteric bacteria such as E.coli .
PMID:6234017
Does not prevent iron uptake by the bacterial siderophore aerobactin PMID:6234017
Appears to function in modulating the activity of the immune system during the acute-phase reaction
ATC L01EN04
Chemical identifiers
CAS, UNII, InChI Key and database cross-references
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Chemical identifiers
CAS, UNII, InChI Key and database cross-references
Linked compound data from DrugBank Open Data (CC BY-NC 4.0)
Futibatinib
Additional database identifiers
ChemSpider
58877816
BindingDB
161389
PDB
TZ0
ZINC
ZINC000207800318
HUGO Gene Nomenclature Committee (HGNC)
HGNC:3688
GenAtlas
FGFR1
GeneCards
FGFR1
GenBank Gene Database
X51803
GenBank Protein Database
31368
Guide to Pharmacology
1808
UniProt Accession
FGFR1_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:3689
GenAtlas
FGFR2
GenBank Gene Database
X52832
GenBank Protein Database
31374
Guide to Pharmacology
1809
UniProt Accession
FGFR2_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:3690
GenAtlas
FGFR3
GeneCards
FGFR3
GenBank Gene Database
M58051
GenBank Protein Database
182569
Guide to Pharmacology
1810
UniProt Accession
FGFR3_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:3691
GenAtlas
FGFR4
GeneCards
FGFR4
GenBank Gene Database
X57205
GenBank Protein Database
31372
Guide to Pharmacology
1811
UniProt Accession
FGFR4_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:2637
GenAtlas
CYP3A4
GeneCards
CYP3A4
GenBank Gene Database
M18907
Guide to Pharmacology
1337
UniProt Accession
CP3A4_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:2623
GenAtlas
CYP2C9
GeneCards
CYP2C9
GenBank Gene Database
AY341248
Guide to Pharmacology
1326
UniProt Accession
CP2C9_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:2625
GenAtlas
CYP2D6
GeneCards
CYP2D6
GenBank Gene Database
M20403
GenBank Protein Database
181350
Guide to Pharmacology
1329
UniProt Accession
CP2D6_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:399
GenAtlas
ALB
GeneCards
ALB
GenBank Gene Database
V00494
GenBank Protein Database
28590
UniProt Accession
ALBU_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:8498
GenAtlas
ORM1
GeneCards
ORM1
GenBank Gene Database
X02544
GenBank Protein Database
757907
UniProt Accession
A1AG1_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:40
GenAtlas
ABCB1
GeneCards
ABCB1
GenBank Gene Database
M14758
GenBank Protein Database
307180
Guide to Pharmacology
768
UniProt Accession
MDR1_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:74
GenAtlas
ABCG2
GeneCards
ABCG2
GenBank Gene Database
AF103796
GenBank Protein Database
4185796
Guide to Pharmacology
792
UniProt Accession
ABCG2_HUMAN
DrugBank citations
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Structured knowledge from the free knowledge base
Linked open data from Wikidata (Q76791462), a free and open knowledge base operated by the Wikimedia Foundation. Data is available under the Creative Commons CC0 1.0 Public Domain Dedication.