Sorafenib 200mg tablets
Requires a prescription from a doctor or prescriber
Sorafenib is a bi-aryl urea and an oral multikinase inhibitor.
Official documents, adverse reaction reporting, and safety monitoring
Report a side effect
Submit a Yellow Card report to the MHRA
Official medicine documents
Safety monitoring data
Yellow Card reports
The MHRA Yellow Card scheme collects reports of suspected side effects from healthcare professionals and patients. View the Drug Analysis Profile (iDAP) for real-world adverse reaction data.
View Drug Analysis Profile
Suspected adverse reactions reported for Sorafenib
Browse all iDAP reports
Interactive Drug Analysis Profiles for all medicines
Report a side effect
Submit a Yellow Card report to the MHRA
Data from the MHRA Yellow Card scheme. A reported reaction does not necessarily mean the medicine caused it. Contains public sector information licensed under the Open Government Licence v3.0.
EudraVigilance
The European Medicines Agency (EMA) collects suspected adverse reaction reports from across the EU/EEA through the EudraVigilance system. Search for safety data on this medicine.
View EudraVigilance report
Suspected adverse reactions reported for Sorafenib
About EudraVigilance
Learn about EU pharmacovigilance and safety monitoring
EudraVigilance data is published by the European Medicines Agency (EMA). A suspected adverse reaction is not necessarily caused by the medicine.
7 branded products available
MHRA licensed products
View all licensed products for Sorafenib on the MHRA register
Nexavar 200mg tablets
Sorafenib 200mg tablets
Sorafenib 200mg tablets
Sorafenib 200mg tablets
Sorafenib 200mg tablets
WHO defined daily dose (DDD)
800 mg
Not a recommended dose. The DDD is the assumed average maintenance dose per day for a drug used for its main indication in adults. It is a statistical measure used for research and comparison purposes only.
Source: WHO Collaborating Centre for Drug Statistics Methodology, distributed via the NHS dm+d supplementary BNF/ATC mapping files (NHSBSA). Contains public sector information licensed under the Open Government Licence v3.0.
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
Guidelines from the National Institute for Health and Care Excellence
NICE clinical guidance(12)
Sorafenib for treating advanced hepatocellular carcinoma (TA474)
Lenvatinib and sorafenib for treating differentiated thyroid cancer after radioactive iodine (TA535)
Bevacizumab (first-line), sorafenib (first- and second-line), sunitinib (second-line) and temsirolimus (first-line) for the treatment of advanced and/or metastatic renal cell carcinoma (TA178)
Ramucirumab for treating unresectable hepatocellular carcinoma after sorafenib (terminated appraisal) (TA609)
Atezolizumab with bevacizumab for treating advanced or unresectable hepatocellular carcinoma (TA666)
Lenvatinib for untreated advanced hepatocellular carcinoma (TA551)
Regorafenib for previously treated advanced hepatocellular carcinoma (TA555)
Durvalumab with tremelimumab for untreated advanced or unresectable hepatocellular carcinoma (TA1090)
Selective internal radiation therapies for treating hepatocellular carcinoma (TA688)
Selpercatinib for advanced thyroid cancer with RET alterations untreated with a targeted cancer drug in people 12 years and over (TA1039)
Cabozantinib for previously treated advanced hepatocellular carcinoma (TA849)
Tivozanib for treating advanced renal cell carcinoma (TA512)
Source: National Institute for Health and Care Excellence (NICE). Contains public sector information licensed under the Open Government Licence v3.0.
Check stock at pharmacies and supply information
Pharmacy stock checkers
Search for this medicine at major UK pharmacy chains. These links open the retailer's own website — results depend on their current online catalogue.
Supply & safety information
Official UK regulator monitoring and safety alerts
Pharmacy links redirect to the retailer's own search and do not represent real-time stock levels. Shortage and safety information sourced from MHRA drug safety updates (gov.uk, Crown Copyright under OGL v3.0).
Codes for healthcare professionals and prescribing systems
These codes are used by healthcare IT systems and prescribers to identify this medicine.
NHS UK identifiers
Browse tools
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 all 30 studies.
Reviews & meta-analyses: 3 · Randomised trials: 14 · 2007–2025
Showing all 30 studies, sorted by most relevant.
Shukui Qin, M. Kudo, Tim Meyer, et al.
JAMA Oncology, 2023
- Antineoplastic Agents
- Carcinoma, Hepatocellular
- Liver Neoplasms
Importance: Hepatocellular carcinoma (HCC) is a leading cause of cancer-related mortality, and additional first-line treatments are needed. The programmed cell death protein 1 inhibitor tislelizumab demonstrated efficacy and a tolerable safety profile as second-line HCC treatment. Objective: To investigate efficacy and safety of tislelizumab vs sorafenib tosylate for first-line treatment of unresectable HCC. Design, Setting, and Participants: The open-label, global, multiregional phase 3 RATIONALE-301 randomized clinical trial enrolled systemic therapy-naive adults with histologically confirmed HCC, Barcelona Clinic Liver Cancer stage B or C disease, disease progression following (or patient was not amenable to) locoregional therapy, Eastern Cooperative Oncology Group performance status of 1 or less, and Child-Pugh class A, between December 27, 2017, and October 2, 2019. Data cutoff was July 11, 2022. Intervention: Patients were randomized 1:1 to receive tislelizumab, 200 mg intravenously every 3 weeks, or sorafenib tosylate, 400 mg orally twice daily. Main Outcomes and Measures: The primary end point was overall survival (OS); secondary end points included objective response rate, progression-free survival, duration of response, and safety. Results: A total of 674 patients were included in the analysis (570 men [84.6%]; median age, 61 years [range, 23-86 years]). As of July 11, 2022, minimum study follow-up was 33 months. The primary end point of OS noninferiority of tislelizumab vs sorafenib was met in the intention-to-treat population (n = 674); median overall survival was 15.9 (95% CI, 13.2-19.7) months vs 14.1 (95% CI, 12.6-17.4) months, respectively (hazard ratio [HR], 0.85 [95.003% CI, 0.71-1.02]), and superiority of tislelizumab vs sorafenib was not met. The objective response rate was 14.3% (n = 49) for tislelizumab vs 5.4% (n = 18) for sorafenib, and median duration of response was 36.1 (95% CI, 16.8 to not evaluable) months vs 11.0 (95% CI, 6.2-14.7) months, respectively. Median progression-free survival was 2.1 (95% CI, 2.1-3.5) months vs 3.4 (95% CI, 2.2-4.1) months with tislelizumab vs sorafenib (HR, 1.11 [95% CI, 0.92-1.33]). The incidence of treatment-emergent adverse events (AEs) was 96.2% (325 of 338 patients) for tislelizumab and 100% (n = 324) for sorafenib. Grade 3 or greater treatment-related AEs were reported in 75 patients (22.2%) receiving tislelizumab and 173 (53.4%) receiving sorafenib. There was a lower incidence of treatment-related AEs leading to drug discontinuation (21 [6.2%] vs 33 [10.2%]) and drug modification (68 [20.1%] vs 187 [57.7%]) with tislelizumab vs sorafenib. Conclusions and Relevance: In RATIONALE-301, tislelizumab demonstrated OS benefit that was noninferior vs sorafenib, with a higher objective response rate and more durable responses, while median progression-free survival was longer with sorafenib. Tislelizumab demonstrated a favorable safety profile vs sorafenib. Trial Registration: ClinicalTrials.gov Identifier: NCT03412773.
Abstract licence: CC BY-NC-ND
Thomas Cheung Yau, P. Galle, T. Decaens, et al.
Lancet, 2025
- Ipilimumab
- Sorafenib
- Nivolumab
Masatoshi Kudo, Richard S. Finn, S. Qin, et al.
Lancet, 2018
- Sorafenib
- Antineoplastic Agents
- Carcinoma, Hepatocellular
J. Bruix, S. Qin, P. Merle, et al.
Lancet, 2017
- Sorafenib
- Antineoplastic Agents
- Carcinoma, Hepatocellular
T. Yau, Yoon-Koo Kang, Tae-You Kim, et al.
JAMA Oncology, 2020
- Carcinoma, Hepatocellular
- Liver Neoplasms
- Ipilimumab
IMPORTANCE: Most patients with hepatocellular carcinoma (HCC) are diagnosed with advanced disease not eligible for potentially curative therapies; therefore, new treatment options are needed. Combining nivolumab with ipilimumab may improve clinical outcomes compared with nivolumab monotherapy. OBJECTIVE: To assess efficacy and safety of nivolumab plus ipilimumab in patients with advanced HCC who were previously treated with sorafenib. DESIGN, SETTING, AND PARTICIPANTS: CheckMate 040 is a multicenter, open-label, multicohort, phase 1/2 study. In the nivolumab plus ipilimumab cohort, patients were randomized between January 4 and September 26, 2016. Treatment group information was blinded after randomization. Median follow-up was 30.7 months. Data cutoff for this analysis was January 2019. Patients were recruited at 31 centers in 10 countries/territories in Asia, Europe, and North America. Eligible patients had advanced HCC (with/without hepatitis B or C) previously treated with sorafenib. A total of 148 patients were randomized (50 to arm A and 49 each to arms B and C). INTERVENTIONS: Patients were randomized 1:1:1 to either nivolumab 1 mg/kg plus ipilimumab 3 mg/kg, administered every 3 weeks (4 doses), followed by nivolumab 240 mg every 2 weeks (arm A); nivolumab 3 mg/kg plus ipilimumab 1 mg/kg, administered every 3 weeks (4 doses), followed by nivolumab 240 mg every 2 weeks (arm B); or nivolumab 3 mg/kg every 2 weeks plus ipilimumab 1 mg/kg every 6 weeks (arm C). MAIN OUTCOMES AND MEASURES: Coprimary end points were safety, tolerability, and objective response rate. Duration of response was also measured (investigator assessed with the Response Evaluation Criteria in Solid Tumors v1.1). RESULTS: Of 148 total participants, 120 were male (81%). Median (IQR) age was 60 (52.5-66.5). At data cutoff (January 2019), the median follow-up was 30.7 months (IQR, 29.9-34.7). Investigator-assessed objective response rate was 32% (95% CI, 20%-47%) in arm A, 27% (95% CI, 15%-41%) in arm B, and 29% (95% CI, 17%-43%) in arm C. Median (range) duration of response was not reached (8.3-33.7+) in arm A and was 15.2 months (4.2-29.9+) in arm B and 21.7 months (2.8-32.7+) in arm C. Any-grade treatment-related adverse events were reported in 46 of 49 patients (94%) in arm A, 35 of 49 patients (71%) in arm B, and 38 of 48 patients (79%) in arm C; there was 1 treatment-related death (arm A; grade 5 pneumonitis). CONCLUSIONS AND RELEVANCE: In this randomized clinical trial, nivolumab plus ipilimumab had manageable safety, promising objective response rate, and durable responses. The arm A regimen (4 doses nivolumab 1 mg/kg plus ipilimumab 3 mg/kg every 3 weeks then nivolumab 240 mg every 2 weeks) received accelerated approval in the US based on the results of this study. TRIAL REGISTRATION: ClinicalTrials.gov Identifier: NCT01658878.
Abstract licence: CC BY-NC-ND
T. Yau, Joong-Won Park, R. Finn, et al.
The Lancet. Oncology, 2021
- Sorafenib
- Nivolumab
- Carcinoma, Hepatocellular
M. Kudo, K. Ueshima, M. Ikeda, et al.
Gut, 2019
- Sorafenib
- Progression-Free Survival
- Antineoplastic Agents
OBJECTIVE: This trial compared the efficacy and safety of transarterial chemoembolisation (TACE) plus sorafenib with TACE alone using a newly established TACE-specific endpoint and pre-treatment of sorafenib before initial TACE. DESIGN: Patients with unresectable hepatocellular carcinoma (HCC) were randomised to TACE plus sorafenib (n=80) or TACE alone (n=76). Patients in the combination group received sorafenib 400 mg once daily for 2-3 weeks before TACE, followed by 800 mg once daily during on-demand conventional TACE sessions until time to untreatable (unTACEable) progression (TTUP), defined as untreatable tumour progression, transient deterioration to Child-Pugh C or appearance of vascular invasion/extrahepatic spread. Co-primary endpoints were progression-free survival (PFS), which is not a conventional one but defined as TTUP, or time to any cause of death plus overall survival (OS). Multiplicity was adjusted by gatekeeping hierarchical testing. RESULTS: Median PFS was significantly longer in the TACE plus sorafenib than in the TACE alone group (25.2 vs 13.5 months; p=0.006). OS was not analysed because only 73.6% of OS events were reached. Median TTUP (26.7 vs 20.6 months; p=0.02) was also significantly longer in the TACE plus sorafenib group. OS at 1 year and 2 years in TACE plus sorafenib group and TACE alone group were 96.2% and 82.7% and 77.2% and 64.6%, respectively. There were no unexpected toxicities. CONCLUSION: TACE plus sorafenib significantly improved PFS over TACE alone in patients with unresectable HCC. Adverse events were consistent with those of previous TACE combination trials. TRIAL REGISTRATION NUMBER: NCT01217034.
Abstract licence: CC BY-NC
M. He, Qijiong Li, Ruhai Zou, et al.
JAMA oncology, 2019
- Sorafenib
- Antineoplastic Agents
- Antineoplastic Combined Chemotherapy Protocols
R. Kelley, L. Rimassa, A. Cheng, et al.
The Lancet. Oncology, 2022
- Carcinoma, Hepatocellular
- Liver Neoplasms
- Sorafenib
BACKGROUND: Cabozantinib has shown clinical activity in combination with checkpoint inhibitors in solid tumours. The COSMIC-312 trial assessed cabozantinib plus atezolizumab versus sorafenib as first-line systemic treatment for advanced hepatocellular carcinoma. METHODS: COSMIC-312 is an open-label, randomised, phase 3 trial that enrolled patients aged 18 years or older with advanced hepatocellular carcinoma not amenable to curative or locoregional therapy and previously untreated with systemic anticancer therapy at 178 centres in 32 countries. Patients with fibrolamellar carcinoma, sarcomatoid hepatocellular carcinoma, or combined hepatocellular cholangiocarcinoma were not eligible. Tumours involving major blood vessels, including the main portal vein, were permitted. Patients were required to have measurable disease per Response Evaluation Criteria in Solid Tumors version 1.1 (RECIST 1.1), Barcelona Clinic Liver Cancer stage B or C disease, an Eastern Cooperative Oncology Group performance status of 0 or 1, adequate organ and marrow function, and Child-Pugh class A. Previous resection, tumour ablation, radiotherapy, or arterial chemotherapy was allowed if more than 28 days before randomisation. Patients were randomly assigned (2:1:1) via a web-based interactive response system to cabozantinib 40 mg orally once daily plus atezolizumab 1200 mg intravenously every 3 weeks, sorafenib 400 mg orally twice daily, or single-agent cabozantinib 60 mg orally once daily. Randomisation was stratified by disease aetiology, geographical region, and presence of extrahepatic disease or macrovascular invasion. Dual primary endpoints were progression-free survival per RECIST 1.1 as assessed by a blinded independent radiology committee in the first 372 patients randomly assigned to the combination treatment of cabozantinib plus atezolizumab or sorafenib (progression-free survival intention-to-treat [ITT] population), and overall survival in all patients randomly assigned to cabozantinib plus atezolizumab or sorafenib (ITT population). Final progression-free survival and concurrent interim overall survival analyses are presented. This trial is registered with ClinicalTrials.gov, NCT03755791. FINDINGS: Analyses at data cut-off (March 8, 2021) included the first 837 patients randomly assigned between Dec 7, 2018, and Aug 27, 2020, to combination treatment of cabozantinib plus atezolizumab (n=432), sorafenib (n=217), or single-agent cabozantinib (n=188). Median follow-up was 15·8 months (IQR 14·5-17·2) in the progression-free survival ITT population and 13·3 months (10·5-16·0) in the ITT population. Median progression-free survival was 6·8 months (99% CI 5·6-8·3) in the combination treatment group versus 4·2 months (2·8-7·0) in the sorafenib group (hazard ratio [HR] 0·63, 99% CI 0·44-0·91, p=0·0012). Median overall survival (interim analysis) was 15·4 months (96% CI 13·7-17·7) in the combination treatment group versus 15·5 months (12·1-not estimable) in the sorafenib group (HR 0·90, 96% CI 0·69-1·18; p=0·44). The most common grade 3 or 4 adverse events were alanine aminotransferase increase (38 [9%] of 429 patients in the combination treatment group vs six [3%] of 207 in the sorafenib group vs 12 [6%] of 188 in the single-agent cabozantinib group), hypertension (37 [9%] vs 17 [8%] vs 23 [12%]), aspartate aminotransferase increase (37 [9%] vs eight [4%] vs 18 [10%]), and palmar-plantar erythrodysaesthesia (35 [8%] vs 17 [8%] vs 16 [9%]); serious treatment-related adverse events occurred in 78 (18%) patients in the combination treatment group, 16 (8%) patients in the sorafenib group, and 24 (13%) in the single-agent cabozantinib group. Treatment-related grade 5 events occurred in six (1%) patients in the combination treatment group (encephalopathy, hepatic failure, drug-induced liver injury, oesophageal varices haemorrhage, multiple organ dysfunction syndrome, and tumour lysis syndrome), one (<1%) patient in the sorafenib group (general physical health deterioration), and one (<1%) patient in the single-agent cabozantinib group (gastrointestinal haemorrhage). INTERPRETATION: Cabozantinib plus atezolizumab might be a treatment option for select patients with advanced hepatocellular carcinoma, but additional studies are needed. FUNDING: Exelixis and Ipsen.
Abstract licence: CC BY-NC-ND
S. Qin, F. Bi, S. Gu, et al.
Journal of Clinical Oncology, 2021
- Sorafenib
- Antineoplastic Combined Chemotherapy Protocols
- Carcinoma, Hepatocellular
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
1 found
Half-life
25 to 48 hours
Mechanism
Kinases are involved in tumour cell signalling, proliferation, angiogenesis, and apoptosis.
Food interactions
4 warnings
Human targets
11 targets
Data: DrugBank · CC BY-NC 4.0
Pharmacokinetics at a glance
Absorption
400 mg
Half-life
25 to 48 hours
[L9341]
Protein binding
99.5%
[L9341]
Volume of distribution
[A255852]
Metabolism
70-85%
[A255852][L9341]…
Elimination
100 mg
Pharmacokinetic data: DrugBank · CC BY-NC 4.0
[L9341][L44577]
In the US, it is also indicated for the treatment of patients with locally recurrent or metastatic, progressive, differentiated thyroid carcinoma that is refractory to radioactive iodine treatment.
[L9341]
Known interactions with other medications. Always consult a healthcare professional.
Showing 50 of 1981 interactions
[L44582]
The oral LD50 of sorafenib tosylate in rats is >2000 mg/kg.
[L44607]
The adverse reactions observed at 800 mg sorafenib twice daily (twice the recommended dose) were primarily diarrhea and dermatologic. No information is available on symptoms of acute overdose in animals because of the saturation of absorption in oral acute toxicity studies conducted in animals. The prescribing information recommends the discontinuation of sorafenib treatment and initiation of supportive care in cases of suspected overdose.
[L9341]
Sorafenib is thought to exhibit a dual mechanism of action: it blocks tumour proliferation and growth by inhibiting the RAF/MEK/extracellular signal-regulated kinase (ERK) pathway on tumour cells, and reduces tumour angiogenesis by inhibiting VEGFR and PDGFR signalling in tumour vasculature.[A255852][A10489]
How the body processes this drug — absorption, distribution, metabolism, and elimination
The Tmax is approximately three hours.
[L9341]
The mean relative bioavailability was 38–49% following the administration of oral sorafenib tablets. A high-fat meal reduced bioavailability by 29%.
[L9341]
[L9341]
[L9341]
[A255852]
[A255852][L9341]
At steady-state, sorafenib accounts for 70-85% of the circulating analytes in plasma.
[A255852]
About eight metabolites of sorafenib have been identified, of which five were detected in plasma. The main circulating metabolite was the pyridine N-oxide form, which comprises approximately 9–16% of the total circulating dose at steady-state: the pharmacological activity of this metabolite was comparable to the parent drug.
[L9341]
[L9341]
Proteins and enzymes this drug interacts with in the body
PMID:21441910 PMID:29433126
Phosphorylates PFKFB2 .
PMID:36402789
May play a role in the postsynaptic responses of hippocampal neurons PMID:1508179
Phosphorylates adenylyl cyclases: ADCY2, ADCY5 and ADCY6, resulting in their activation. Phosphorylates PPP1R12A resulting in inhibition of the phosphatase activity. Phosphorylates TNNT2/cardiac muscle troponin T.
Can promote NF-kB activation and inhibit signal transducers involved in motility (ROCK2), apoptosis (MAP3K5/ASK1 and STK3/MST2), proliferation and angiogenesis (RB1). Can protect cells from apoptosis also by translocating to the mitochondria where it binds BCL2 and displaces BAD/Bcl2-antagonist of cell death. Regulates Rho signaling and migration, and is required for normal wound healing.
Plays a role in the oncogenic transformation of epithelial cells via repression of the TJ protein, occludin (OCLN) by inducing the up-regulation of a transcriptional repressor SNAI2/SLUG, which induces down-regulation of OCLN. Restricts caspase activation in response to selected stimuli, notably Fas stimulation, pathogen-mediated macrophage apoptosis, and erythroid differentiation
Modulates KDR signaling by forming heterodimers. The secreted isoform 3 may function as a decoy receptor for VEGFC and/or VEGFD and play an important role as a negative regulator of VEGFC-mediated lymphangiogenesis and angiogenesis. Binding of vascular growth factors to isoform 1 or isoform 2 leads to the activation of several signaling cascades; isoform 2 seems to be less efficient in signal transduction, because it has a truncated C-terminus and therefore lacks several phosphorylation sites.
Mediates activation of the MAPK1/ERK2, MAPK3/ERK1 signaling pathway, of MAPK8 and the JUN signaling pathway, and of the AKT1 signaling pathway. Phosphorylates SHC1. Mediates phosphorylation of PIK3R1, the regulatory subunit of phosphatidylinositol 3-kinase.
Promotes phosphorylation of MAPK8 at 'Thr-183' and 'Tyr-185', and of AKT1 at 'Ser-473'
Promotes reorganization of the actin cytoskeleton. Isoforms lacking a transmembrane domain, such as isoform 2 and isoform 3, may function as decoy receptors for VEGFA, VEGFC and/or VEGFD. Isoform 2 plays an important role as negative regulator of VEGFA- and VEGFC-mediated lymphangiogenesis by limiting the amount of free VEGFA and/or VEGFC and preventing their binding to FLT4.
Modulates FLT1 and FLT4 signaling by forming heterodimers. Binding of vascular growth factors to isoform 1 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 and the activation of protein kinase C.
Mediates activation of MAPK1/ERK2, MAPK3/ERK1 and the MAP kinase signaling pathway, as well as of the AKT1 signaling pathway. Mediates phosphorylation of PIK3R1, the regulatory subunit of phosphatidylinositol 3-kinase, reorganization of the actin cytoskeleton and activation of PTK2/FAK1. Required for VEGFA-mediated induction of NOS2 and NOS3, leading to the production of the signaling molecule nitric oxide (NO) by endothelial cells.
Phosphorylates PLCG1. Promotes phosphorylation of FYN, NCK1, NOS3, PIK3R1, PTK2/FAK1 and SRC
Can promote endothelial cell proliferation, survival and angiogenesis in adulthood. Its function in promoting cell proliferation seems to be cell-type specific. Promotes PGF-mediated proliferation of endothelial cells, proliferation of some types of cancer cells, but does not promote proliferation of normal fibroblasts (in vitro).
Has very high affinity for VEGFA and relatively low protein kinase activity; may function as a negative regulator of VEGFA signaling by limiting the amount of free VEGFA and preventing its binding to KDR. Modulates KDR signaling by forming heterodimers with KDR. Ligand binding leads to the activation of several signaling cascades.
Activation of PLCG leads to the production of the cellular signaling molecules diacylglycerol and inositol 1,4,5-trisphosphate and the activation of protein kinase C. Mediates phosphorylation of PIK3R1, the regulatory subunit of phosphatidylinositol 3-kinase, leading to activation of phosphatidylinositol kinase and the downstream signaling pathway. Mediates activation of MAPK1/ERK2, MAPK3/ERK1 and the MAP kinase signaling pathway, as well as of the AKT1 signaling pathway.
Phosphorylates SRC and YES1, and may also phosphorylate CBL. Promotes phosphorylation of AKT1 at 'Ser-473'. Promotes phosphorylation of PTK2/FAK1 PMID:16685275
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
PMID:11856762 PMID:12523936 PMID:12835412 PMID:12883481 PMID:15364914 PMID:15454390 PMID:16282361 PMID:17959747 PMID:18300232 PMID:26721430
Mediates the ATP-dependent efflux of glutathione conjugates such as leukotriene C4 (LTC4) and leukotriene B4 (LTB4) too. The presence of GSH is necessary for the ATP-dependent transport of LTB4, whereas GSH is not required for the transport of LTC4 .
PMID:17959747
Mediates the cotransport of bile acids with reduced glutathione (GSH) .
PMID:12523936 PMID:12883481 PMID:16282361
Transports a wide range of drugs and their metabolites, including anticancer, antiviral and antibiotics molecules .
PMID:11856762 PMID:12105214 PMID:15454390 PMID:17344354 PMID:18300232
Confers resistance to anticancer agents such as methotrexate PMID:11106685
PMID:10220572 PMID:10421658 PMID:11500505 PMID:16332456
Mediates hepatobiliary excretion of mono- and bis-glucuronidated bilirubin molecules and therefore play an important role in bilirubin detoxification .
PMID:10421658
Also mediates hepatobiliary excretion of others glucuronide conjugates such as 17beta-estradiol 17-glucosiduronic acid and leukotriene C4 .
PMID:11500505
Transports sulfated bile salt such as taurolithocholate sulfate .
PMID:16332456
Transports various anticancer drugs, such as anthracycline, vinca alkaloid and methotrexate and HIV-drugs such as protease inhibitors .
PMID:10220572 PMID:11500505 PMID:12441801
Confers resistance to several anti-cancer drugs including cisplatin, doxorubicin, epirubicin, methotrexate, etoposide and vincristine PMID:10220572 PMID:11500505
PMID:7673236
As a GTPase-activating protein/GAP can inactivate CDC42 and RAC1 by stimulating their GTPase activity .
PMID:7673236
As part of the Ral signaling pathway, may also regulate ligand-dependent EGF and insulin receptors-mediated endocytosis .
PMID:10910768 PMID:12775724
During mitosis, may act as a scaffold protein in the phosphorylation of EPSIN/EPN1 by the mitotic kinase cyclin B-CDK1, preventing endocytosis during that phase of the cell cycle .
PMID:12775724
During mitosis, also controls mitochondrial fission as an effector of RALA .
PMID:21822277
Recruited to mitochondrion by RALA, acts as a scaffold to foster the mitotic kinase cyclin B-CDK1-mediated phosphorylation and activation of DNM1L PMID:21822277
PMID:10358072 PMID:15159445 PMID:17412826
Shows broad substrate specificity, can transport both organic anions such as bile acid taurocholate (cholyltaurine) and conjugated steroids (dehydroepiandrosterone 3-sulfate, 17-beta-glucuronosyl estradiol, and estrone 3-sulfate), as well as eicosanoids (prostaglandin E2, thromboxane B2, leukotriene C4, and leukotriene E4), and thyroid hormones (T4/L-thyroxine, and T3/3,3',5'-triiodo-L-thyronine) .
PMID:10358072 PMID:10601278 PMID:10873595 PMID:11159893 PMID:12196548 PMID:12568656 PMID:15159445 PMID:15970799 PMID:16627748 PMID:17412826 PMID:19129463 PMID:26979622
Can take up bilirubin glucuronides from plasma into the liver, contributing to the detoxification-enhancing liver-blood shuttling loop .
PMID:22232210
Involved in the clearance of endogenous and exogenous substrates from the liver .
PMID:10358072 PMID:10601278
Transports coproporphyrin I and III, by-products of heme synthesis, and may be involved in their hepatic disposition .
PMID:26383540
May contribute to regulate the transport of organic compounds in testes across the blood-testis-barrier (Probable). Can transport HMG-CoA reductase inhibitors (also known as statins), such as pravastatin and pitavastatin, a clinically important class of hypolipidemic drugs .
PMID:10601278 PMID:15159445 PMID:15970799
May play an important role in plasma and tissue distribution of the structurally diverse chemotherapeutic drug methotrexate .
PMID:23243220
May also transport antihypertension agents, such as the angiotensin-converting enzyme (ACE) inhibitor prodrug enalapril, and the highly selective angiotensin II AT1-receptor antagonist valsartan, in the liver .
PMID:16624871 PMID:16627748
Shows a pH-sensitive substrate specificity towards prostaglandin E2 and T4 which may be ascribed to the protonation state of the binding site and leads to a stimulation of substrate transport in an acidic microenvironment .
PMID:19129463
Hydrogencarbonate/HCO3(-) acts as the probable counteranion that exchanges for organic anions PMID:19129463
Involved compounds
ATC L01EX02
Chemical identifiers
CAS, UNII, InChI Key and database cross-references
Show
Chemical identifiers
CAS, UNII, InChI Key and database cross-references
Linked compound data from DrugBank Open Data (CC BY-NC 4.0)
Sorafenib
Additional database identifiers
Drugs Product Database (DPD)
15231
ChemSpider
187440
BindingDB
16673
PDB
BAX
ZINC
ZINC000001493878
HUGO Gene Nomenclature Committee (HGNC)
HGNC:1097
GenAtlas
BRAF
GeneCards
BRAF
GenBank Gene Database
M95712
GenBank Protein Database
41387220
Guide to Pharmacology
1943
UniProt Accession
BRAF_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:9829
GenAtlas
RAF1
GeneCards
RAF1
GenBank Gene Database
X03484
GenBank Protein Database
35842
Guide to Pharmacology
2184
UniProt Accession
RAF1_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:3767
GenAtlas
FLT4
GeneCards
FLT4
GenBank Gene Database
X69878
GenBank Protein Database
297050
Guide to Pharmacology
1814
UniProt Accession
VGFR3_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:6307
GenAtlas
KDR
GeneCards
KDR
GenBank Gene Database
AF035121
GenBank Protein Database
2655412
Guide to Pharmacology
1813
UniProt Accession
VGFR2_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:3763
GenAtlas
FLT1
GeneCards
FLT1
GenBank Gene Database
X51602
GenBank Protein Database
31432
Guide to Pharmacology
1812
UniProt Accession
VGFR1_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:3765
GenAtlas
FLT3
GeneCards
FLT3
GenBank Gene Database
U02687
GenBank Protein Database
409573
Guide to Pharmacology
1807
UniProt Accession
FLT3_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:8804
GenAtlas
PDGFRB
GeneCards
PDGFRB
GenBank Gene Database
J03278
GenBank Protein Database
189732
Guide to Pharmacology
1804
UniProt Accession
PGFRB_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:6342
GenAtlas
KIT
GeneCards
KIT
GenBank Gene Database
X06182
GenBank Protein Database
34085
Guide to Pharmacology
1805
UniProt Accession
KIT_HUMAN
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:9967
GenAtlas
RET
GeneCards
RET
GenBank Gene Database
X12949
Guide to Pharmacology
2185
UniProt Accession
RET_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:3236
GenAtlas
EGFR
GeneCards
EGFR
GenBank Gene Database
X00588
GenBank Protein Database
757924
Guide to Pharmacology
1797
UniProt Accession
EGFR_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:2622
GenAtlas
CYP2C8
GeneCards
CYP2C8
GenBank Gene Database
M17397
Guide to Pharmacology
1325
UniProt Accession
CP2C8_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:2638
GenAtlas
CYP3A5
GeneCards
CYP3A5
GenBank Gene Database
J04813
GenBank Protein Database
181346
Guide to Pharmacology
1338
UniProt Accession
CP3A5_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:2640
GeneCards
CYP3A7
GenBank Gene Database
D00408
GenBank Protein Database
220149
UniProt Accession
CP3A7_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:2615
GeneCards
CYP2B6
GenBank Gene Database
M29874
GenBank Protein Database
181296
Guide to Pharmacology
1324
UniProt Accession
CP2B6_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:2596
GenAtlas
CYP1A2
GeneCards
CYP1A2
GenBank Gene Database
Z00036
Guide to Pharmacology
1319
UniProt Accession
CP1A2_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:2621
GeneCards
CYP2C19
GenBank Gene Database
M61854
GenBank Protein Database
181344
Guide to Pharmacology
1328
UniProt Accession
CP2CJ_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:12541
GeneCards
UGT1A9
GenBank Gene Database
S55985
GenBank Protein Database
7690346
UniProt Accession
UD19_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:12530
GeneCards
UGT1A1
GenBank Gene Database
M57899
GenBank Protein Database
184473
Guide to Pharmacology
2990
UniProt Accession
UD11_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
HUGO Gene Nomenclature Committee (HGNC)
HGNC:55
GenAtlas
ABCC4
GeneCards
ABCC4
GenBank Gene Database
AF071202
GenBank Protein Database
3335173
Guide to Pharmacology
782
UniProt Accession
MRP4_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:53
GenAtlas
ABCC2
GeneCards
ABCC2
GenBank Gene Database
U63970
GenBank Protein Database
1764162
Guide to Pharmacology
780
UniProt Accession
MRP2_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:9841
GeneCards
RALBP1
UniProt Accession
RBP1_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:10959
GenAtlas
SLCO1B1
GeneCards
SLCO1B1
GenBank Gene Database
AF060500
GenBank Protein Database
5051630
Guide to Pharmacology
1220
UniProt Accession
SO1B1_HUMAN
DrugBank citations
If you use DrugBank data in your research, please cite the following publications:
Show earlier publications
Structured knowledge from the free knowledge base
ATC classifications (Wikidata)
Linked open data from Wikidata (Q421136), a free and open knowledge base operated by the Wikimedia Foundation. Data is available under the Creative Commons CC0 1.0 Public Domain Dedication.