Rosuvastatin 10mg tablets
Prescription only
Requires a prescription from a doctor or prescriber
Tablet
10mg
Oral
Lipid-regulating drugs
Active ingredients:
Rosuvastatin
1 safety notice
Genetic variations that may affect drug response
3 known genetic variations may influence how your body responds to Rosuvastatin 10mg tablets.Genes involved: KIF6, HMGCR, ABCG2
These are known genetic variations. They don't mean the medicine won't work for you — speak to your doctor or a pharmacogenomics specialist for personalised advice. Source: DrugBank (CC BY-NC 4.0).
rs20455
KIF6
Patients with this genotype have a greater reduction in risk of a major cardiovascular event with high dose rosuvastatin.
rs17244841
HMGCR
Patients with this genotype have a lesser reduction in LDL cholesterol with rosuvastatin.
rs2231142
ABCG2
Patients with this genotype have a greater reduction in LDL cholesterol with rosuvastatin.
Official documents, adverse reaction reporting, and safety monitoring
Report a side effect
Submit a Yellow Card report to the MHRA
Official medicine documents
Source: MHRA Products DatabaseOGL 3.0
Updated 3 months ago(16 Jan 2026)Safety monitoring data
Yellow Card reports
MHRA
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 Rosuvastatin
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
EMA
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 Rosuvastatin
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.
34 branded products available
Show details
34 products
MHRA licensed products
View all licensed products for Rosuvastatin on the MHRA register
Crestor 10mg tablets
Crestor 10mg tablets
Crestor 10mg tablets
Crestor 10mg tablets
Rosuvastatin 10mg tablets
Rosuvastatin 10mg tablets
Rosuvastatin 10mg tablets
Rosuvastatin 10mg tablets
Rosuvastatin 10mg tablets
Rosuvastatin 10mg tablets
Rosuvastatin 10mg tablets
Rosuvastatin 10mg tablets
Show details
£0.76indicative price
This is the NHS Drug Tariff indicative price used for reimbursement purposes. It may not reflect the price paid by patients or pharmacies.
View full Drug TariffSource: NHS Drug Tariff via NHSBSA. Derived from dm+d VMPP (Virtual Medicinal Product Pack) pricing data. Contains public sector information licensed under the Open Government Licence v3.0.
WHO defined daily dose (DDD)
10 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 NHS dm+d BNF mapping files. Contains public sector information licensed under the Open Government Licence v3.0.
Therapeutically similar medicines
Show details
Rosuvastatin 5mg orodispersible tablets sugar free
Tablet
5mg
Same therapeutic group
Rosuvastatin 10mg orodispersible tablets sugar free
Tablet
10mg
Same therapeutic group
Rosuvastatin 10mg/5ml oral solution sugar free
Oral solution
10mg/5ml
Same therapeutic group
Rosuvastatin 15mg tablets
Tablet
15mg
Same therapeutic group
Rosuvastatin 30mg tablets
Tablet
30mg
Same therapeutic group
Similarity based on WHO Anatomical Therapeutic Chemical (ATC) classification and NHS BNF section grouping. Source data: NHS dm+d via TRUD (OGL v3.0), WHO ATC/DDD Index.
NHS prescribing volume and spending trends
Show details
Loading prescribing data...
Clinical guidelines and formulary information
British National Formulary
Rosuvastatin
BNF
Drug monograph — bnf.nice.org.ukSource: British National Formulary, NICE. Joint Formulary Committee. Contains public sector information licensed under the Open Government Licence v3.0.
NICE clinical guidance(4)
Cardiovascular disease: risk assessment and reduction, including lipid modification (NG238)
NG238
NICE guideline
Updated Dec 2023Familial hypercholesterolaemia: identification and management (CG71)
CG71
Clinical guideline
Updated Oct 2019Familial hypercholesterolaemia (QS41)
QS41
Quality standard
Updated Nov 2017Inclisiran for treating primary hypercholesterolaemia or mixed dyslipidaemia (TA733)
TA733
Technology appraisal
Updated Oct 2021Source: 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
Show details
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 & product information
Official product databases and supply status monitoring
Pharmacy links redirect to the retailer's own search and do not represent real-time stock levels. emc (electronic medicines compendium) is operated by Datapharm Ltd. Shortage information sourced from NHS Specialist Pharmacy Service (SPS), sps.nhs.uk.
Codes for healthcare professionals and prescribing systems
Show details
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 codes from NHS Business Services Authority (NHSBSA). ATC codes from the WHO Collaborating Centre for Drug Statistics Methodology (whocc.no).
Active and completed clinical studies from ClinicalTrials.gov
Show details
Searching UK clinical trials...
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.
Pharmacology and chemical data from DrugBank
Key facts
Drug status
Approved
Major interactions
64 found
Half-life
19 hours
Mechanism
Rosuvastatin is a statin medication and a competitive inhibitor of the enzyme HM…
Food interactions
1 warning
Human targets
2 targets
Data: DrugBank · CC BY-NC 4.0
Pharmacokinetics at a glance
Absorption
20%
In a study of healthy white male volunteers, the absolute oral bioavailability of rosuvastatin was found to be approximately 20% while absorption…
Half-life
19 hours
The elimination half-life (t½) of rosuvastatin is approximately 19 hours and does not increase with increasing doses.[F4649, F4652]
Protein binding
88%
Rosuvastatin is 88% bound to plasma proteins, mostly albumin. This binding is reversible and independent of plasma concentrations.[F4649, F4652]
Volume of distribution
Rosuvastatin undergoes first-pass extraction in the liver, which is the primary site of cholesterol synthesis and LDL-C clearance.…
Metabolism
10%
Rosuvastatin is not extensively metabolized, as demonstrated by the small amount of radiolabeled dose that is recovered as a metabolite (~10%).…
Elimination
10%
Rosuvastatin is not extensively metabolized; approximately 10% of a radiolabeled dose is recovered as metabolite.…
Pharmacokinetic data: DrugBank · CC BY-NC 4.0
Status:
Approved
Investigational
Small molecule
About this compound
Rosuvastatin, also known as the brand name product Crestor, is a lipid-lowering drug that belongs to the statin class of medications, which are used to lower the risk of cardiovascular disease and manage elevated lipid levels by inhibiting the endogenous production of cholesterol in the liver. More specifically, statin medications competitively inhibit the enzyme hydroxymethylglutaryl-coenzyme A (HMG-CoA) Reductase,[A181421] which catalyzes the conversion of HMG-CoA to mevalonic acid and is the third step in a sequence of metabolic reactions involved in the production of several compounds involved in lipid metabolism and transport including cholesterol, low-density lipoprotein (LDL) (sometimes referred to as "bad cholesterol"), and very low-density lipoprotein (VLDL). Prescribing of statin medications is considered standard practice following any cardiovascular events and for people with a moderate to high risk of development of CVD, such as those with Type 2 Diabetes. The clear evidence of the benefit of statin use coupled with very minimal side effects or long term effects has resulted in this class becoming one of the most widely prescribed medications in North America.[A181087][A181406]
Rosuvastatin and other drugs from the statin class of medications including [atorvastatin], [pravastatin], [simvastatin], [fluvastatin], and [lovastatin] are considered first-line options for the treatment of dyslipidemia.[A181087][A181406] This is largely due to the fact that cardiovascular disease (CVD), which includes heart attack, atherosclerosis, angina, peripheral artery disease, and stroke, has become a leading cause of death in high-income countries and a major cause of morbidity around the world.[A181084] Elevated cholesterol levels, and in particular, elevated low-density lipoprotein (LDL) levels, are an important risk factor for the development of CVD.[A181087][A181553] Use of statins to target and reduce LDL levels has been shown in a number of landmark studies to significantly reduce the risk of development of CVD and all-cause mortality.[A181090][A181093][A181096][A181427][A181475][A181538] Statins are considered a cost-effective treatment option for CVD due to their evidence of reducing all-cause mortality including fatal and non-fatal CVD as well as the need for surgical revascularization or angioplasty following a heart attack.[A181087][A181406] Evidence has shown that even for low-risk individuals (with <10% risk of a major vascular event occurring within 5 years) statins cause a 20%-22% relative reduction in major cardiovascular events (heart attack, stroke, coronary revascularization, and coronary death) for every 1 mmol/L reduction in LDL without any significant side effects or risks.[A181397][A181403]
While all statin medications are considered equally effective from a clinical standpoint, rosuvastatin is considered the most potent; doses of 10 to 40mg rosuvastatin per day were found in clinical studies to result in a 45.8% to 54.6% decreases in LDL cholesterol levels, which is about three-fold more potent than [atorvastatin]'s effects on LDL cholesterol.[A181409][A1793] However, the results of the SATURN trial[A181427] concluded that despite this difference in potency, there was no difference in their effect on the progression of coronary atherosclerosis.
Rosuvastatin is also a unique member of the class of statins due to its high hydrophilicity which increases hepatic uptake at the site of action, low bioavailability, and minimal metabolism via the Cytochrome P450 system.[A181523] This last point results in less risk of drug-drug interactions compared to [atorvastatin], [lovastatin], and [simvastatin], which are all extensively metabolized by Cytochrome P450 (CYP) 3A4, an enzyme involved in the metabolism of many commonly used drugs.[A181460] Drugs such as [ciclosporin], [gemfibrozil], and some antiretrovirals are more likely to interact with this statin through antagonism of OATP1B1 organic anion transporter protein 1B1-mediated hepatic uptake of rosuvastatin.[F4649, F4652]
Rosuvastatin and other drugs from the statin class of medications including [atorvastatin], [pravastatin], [simvastatin], [fluvastatin], and [lovastatin] are considered first-line options for the treatment of dyslipidemia.[A181087][A181406] This is largely due to the fact that cardiovascular disease (CVD), which includes heart attack, atherosclerosis, angina, peripheral artery disease, and stroke, has become a leading cause of death in high-income countries and a major cause of morbidity around the world.[A181084] Elevated cholesterol levels, and in particular, elevated low-density lipoprotein (LDL) levels, are an important risk factor for the development of CVD.[A181087][A181553] Use of statins to target and reduce LDL levels has been shown in a number of landmark studies to significantly reduce the risk of development of CVD and all-cause mortality.[A181090][A181093][A181096][A181427][A181475][A181538] Statins are considered a cost-effective treatment option for CVD due to their evidence of reducing all-cause mortality including fatal and non-fatal CVD as well as the need for surgical revascularization or angioplasty following a heart attack.[A181087][A181406] Evidence has shown that even for low-risk individuals (with <10% risk of a major vascular event occurring within 5 years) statins cause a 20%-22% relative reduction in major cardiovascular events (heart attack, stroke, coronary revascularization, and coronary death) for every 1 mmol/L reduction in LDL without any significant side effects or risks.[A181397][A181403]
While all statin medications are considered equally effective from a clinical standpoint, rosuvastatin is considered the most potent; doses of 10 to 40mg rosuvastatin per day were found in clinical studies to result in a 45.8% to 54.6% decreases in LDL cholesterol levels, which is about three-fold more potent than [atorvastatin]'s effects on LDL cholesterol.[A181409][A1793] However, the results of the SATURN trial[A181427] concluded that despite this difference in potency, there was no difference in their effect on the progression of coronary atherosclerosis.
Rosuvastatin is also a unique member of the class of statins due to its high hydrophilicity which increases hepatic uptake at the site of action, low bioavailability, and minimal metabolism via the Cytochrome P450 system.[A181523] This last point results in less risk of drug-drug interactions compared to [atorvastatin], [lovastatin], and [simvastatin], which are all extensively metabolized by Cytochrome P450 (CYP) 3A4, an enzyme involved in the metabolism of many commonly used drugs.[A181460] Drugs such as [ciclosporin], [gemfibrozil], and some antiretrovirals are more likely to interact with this statin through antagonism of OATP1B1 organic anion transporter protein 1B1-mediated hepatic uptake of rosuvastatin.[F4649, F4652]
Properties:
solid
Avg. mass: 481.54 Da
DrugBank indication
The FDA monograph states that rosuvastatin is indicated as an adjunct to diet in the treatment of triglyceridemia, Primary Dysbetalipoproteinemia (Type III Hyperlipoproteinemia), and Homozygous Familial Hypercholesterolemia.F4649
The Health Canada monograph for rosuvastatin further specifies that rosuvastatin is indicated for the reduction of elevated total cholesterol (Total-C), LDL-C, ApoB, the Total-C/HDL-C ratio and triglycerides (TG) and for increasing HDL-C in hyperlipidemic and dyslipidemic conditions when response to diet and exercise alone has been inadequate. It is also indicated for the prevention of major cardiovascular events (including risk of myocardial infarction, nonfatal stroke, and coronary artery revascularization) in adult patients without documented history of cardiovascular or cerebrovascular events, but with at least two conventional risk factors for cardiovascular disease.F4652
Prescribing of statin medications is considered standard practice following any cardiovascular events and for people with a moderate to high risk of development of CVD. Statin-indicated conditions include diabetes mellitus, clinical atherosclerosis (including myocardial infarction, acute coronary syndromes, stable angina, documented coronary artery disease, stroke, trans ischemic attack (TIA), documented carotid disease, peripheral artery disease, and claudication), abdominal aortic aneurysm, chronic kidney disease, and severely elevated LDL-C levels.
[A181087][A181406]
The Health Canada monograph for rosuvastatin further specifies that rosuvastatin is indicated for the reduction of elevated total cholesterol (Total-C), LDL-C, ApoB, the Total-C/HDL-C ratio and triglycerides (TG) and for increasing HDL-C in hyperlipidemic and dyslipidemic conditions when response to diet and exercise alone has been inadequate. It is also indicated for the prevention of major cardiovascular events (including risk of myocardial infarction, nonfatal stroke, and coronary artery revascularization) in adult patients without documented history of cardiovascular or cerebrovascular events, but with at least two conventional risk factors for cardiovascular disease.F4652
Prescribing of statin medications is considered standard practice following any cardiovascular events and for people with a moderate to high risk of development of CVD. Statin-indicated conditions include diabetes mellitus, clinical atherosclerosis (including myocardial infarction, acute coronary syndromes, stable angina, documented coronary artery disease, stroke, trans ischemic attack (TIA), documented carotid disease, peripheral artery disease, and claudication), abdominal aortic aneurysm, chronic kidney disease, and severely elevated LDL-C levels.
[A181087][A181406]
Also known as(114)
(3R,5S,6E)-7-(4-(4-fluorophenyl)-6-(1-methylethyl)-2-(ethyl(methylsulfonyl)amino)-5-pyrimidinyl)-3,5-dihydroxy-6-heptenoic acid
(3R,5S,6E)-7-{4-(4-fluorophenyl)-6-isopropyl-2-[methyl(methylsulfonyl)amino]pyrimidin-5-yl}-3,5-dihydroxyhept-6-enoic acid
Rosuvastatin
Rosuvastatina
1.1.1.34
HMG-CoA reductase
CD11 antigen-like family member A
CD11A
Dosage forms(105)
Tablet, coated (Oral) — 10 mg
Tablet, coated (Oral) — 20 mg
Tablet, film coated (Oral)
Tablet, effervescent (Oral)
Tablet (Oral; Sublingual) — 20 mg
Tablet, effervescent (Oral) — 10 mg
Tablet, effervescent (Oral) — 20 mg
Tablet, effervescent (Oral) — 40 mg
Molecular properties(19)
Drug interactions(1026)
Known interactions with other medications. Always consult a healthcare professional.
Troglitazone
Moderate
Troglitazone may decrease the excretion rate of Rosuvastatin which could result in a higher serum level.
Reserpine may decrease the excretion rate of Rosuvastatin which could result in a higher serum level.
Progesterone
Moderate
Progesterone may decrease the excretion rate of Rosuvastatin which could result in a higher serum level.
Chlorpromazine
Moderate
Chlorpromazine may decrease the excretion rate of Rosuvastatin which could result in a higher serum level.
Cimetidine
Moderate
Cimetidine may decrease the excretion rate of Rosuvastatin which could result in a higher serum level.
Glyburide may decrease the excretion rate of Rosuvastatin which could result in a higher serum level.
Ursodeoxycholic acid
Moderate
Ursodeoxycholic acid may decrease the excretion rate of Rosuvastatin which could result in a higher serum level.
Cholic Acid
Moderate
Cholic Acid may decrease the excretion rate of Rosuvastatin which could result in a higher serum level.
Lenvatinib
Moderate
Lenvatinib may decrease the excretion rate of Rosuvastatin which could result in a higher serum level.
Letermovir
Moderate
The metabolism of Rosuvastatin can be decreased when combined with Letermovir.
Valinomycin
Moderate
Valinomycin may decrease the excretion rate of Rosuvastatin which could result in a higher serum level.
Celecoxib may decrease the excretion rate of Rosuvastatin which could result in a higher serum level.
Nifedipine
Moderate
Rosuvastatin may decrease the excretion rate of Nifedipine which could result in a higher serum level.
Pralsetinib
Moderate
Pralsetinib may decrease the excretion rate of Rosuvastatin which could result in a higher serum level.
Cyclosporine
Unknown severity
The serum concentration of Rosuvastatin can be increased when it is combined with Cyclosporine.
Acipimox may increase the myopathic rhabdomyolysis activities of Rosuvastatin.
Bezafibrate
Major
Bezafibrate may increase the myopathic rhabdomyolysis activities of Rosuvastatin.
Ciprofibrate
Major
The risk or severity of myopathy, rhabdomyolysis, and myoglobinuria can be increased when Ciprofibrate is combined with Rosuvastatin.
Colchicine
Major
Colchicine may increase the myopathic rhabdomyolysis activities of Rosuvastatin.
Daptomycin
Unknown severity
The risk or severity of myopathy can be increased when Rosuvastatin is combined with Daptomycin.
The metabolism of Rosuvastatin can be increased when combined with Phenytoin.
Fosphenytoin
Moderate
The metabolism of Rosuvastatin can be increased when combined with Fosphenytoin.
The risk or severity of myopathy and rhabdomyolysis can be increased when Niacin is combined with Rosuvastatin.
Rosuvastatin may increase the hepatotoxic activities of Pazopanib.
Raltegravir
Major
The risk or severity of myopathy and rhabdomyolysis can be increased when Raltegravir is combined with Rosuvastatin.
Trabectedin
Major
The risk or severity of myopathy and rhabdomyolysis can be increased when Rosuvastatin is combined with Trabectedin.
The risk or severity of adverse effects can be increased when Rosuvastatin is combined with Nicotine.
Mecamylamine
Unknown severity
The risk or severity of adverse effects can be increased when Rosuvastatin is combined with Mecamylamine.
Pentolinium
Unknown severity
The risk or severity of adverse effects can be increased when Rosuvastatin is combined with Pentolinium.
Trimethaphan
Unknown severity
The risk or severity of adverse effects can be increased when Rosuvastatin is combined with Trimethaphan.
Hexamethonium
Unknown severity
The risk or severity of adverse effects can be increased when Rosuvastatin is combined with Hexamethonium.
Cyclopentamine
Unknown severity
The risk or severity of adverse effects can be increased when Rosuvastatin is combined with Cyclopentamine.
Amiodarone
Moderate
The metabolism of Rosuvastatin can be increased when combined with Amiodarone.
The serum concentration of Rosuvastatin can be decreased when it is combined with Bosentan.
The serum concentration of Rosuvastatin can be increased when it is combined with Danazol.
Methotrexate
Unknown severity
The protein binding of Methotrexate can be increased when combined with Rosuvastatin.
Colestipol
Moderate
Colestipol can cause a decrease in the absorption of Rosuvastatin resulting in a reduced serum concentration and potentially a decrease in efficacy.
Sevelamer can cause a decrease in the absorption of Rosuvastatin resulting in a reduced serum concentration and potentially a decrease in efficacy.
Colesevelam
Moderate
Colesevelam can cause a decrease in the absorption of Rosuvastatin resulting in a reduced serum concentration and potentially a decrease in efficacy.
Cholestyramine
Moderate
Cholestyramine can cause a decrease in the absorption of Rosuvastatin resulting in a reduced serum concentration and potentially a decrease in efficacy.
The excretion of Rosuvastatin can be decreased when combined with Aspartame.
The excretion of Rosuvastatin can be decreased when combined with Cefotiam.
Conjugated estrogens
Unknown severity
The excretion of Rosuvastatin can be decreased when combined with Conjugated estrogens.
Indomethacin
Unknown severity
The excretion of Rosuvastatin can be decreased when combined with Indomethacin.
Aminohippuric acid
Unknown severity
The excretion of Rosuvastatin can be decreased when combined with Aminohippuric acid.
The excretion of Rosuvastatin can be decreased when combined with Cefalotin.
The excretion of Rosuvastatin can be decreased when combined with Tenoxicam.
Cefotaxime
Unknown severity
The excretion of Rosuvastatin can be decreased when combined with Cefotaxime.
The excretion of Rosuvastatin can be decreased when combined with Guanidine.
The excretion of Rosuvastatin can be decreased when combined with Piroxicam.
Showing 50 of 1026 interactions
Food & lifestyle interactions
Advice
Take with or without food. Co-administration with food does not affect absorption.
Toxicity & overdose
Generally well-tolerated. Side effects may include myalgia, constipation, asthenia, abdominal pain, and nausea. Other possible side effects include myotoxicity (myopathy, myositis, rhabdomyolysis) and hepatotoxicity.
To avoid toxicity in Asian patients, lower doses should be considered. Pharmacokinetic studies show an approximately two-fold increase in peak plasma concentration and AUC in Asian patients (Philippino, Chinese, Japanese, Korean, Vietnamese, or Asian-Indian descent) compared to Caucasian patients.
To avoid toxicity in Asian patients, lower doses should be considered. Pharmacokinetic studies show an approximately two-fold increase in peak plasma concentration and AUC in Asian patients (Philippino, Chinese, Japanese, Korean, Vietnamese, or Asian-Indian descent) compared to Caucasian patients.
How it works
Mechanism of action
Rosuvastatin is a statin medication and a competitive inhibitor of the enzyme HMG-CoA (3-hydroxy-3-methylglutaryl coenzyme A) reductase, which catalyzes the conversion of HMG-CoA to mevalonate, an early rate-limiting step in cholesterol biosynthesis.[A181421] Rosuvastatin acts primarily in the liver, where decreased hepatic cholesterol concentrations stimulate the upregulation of hepatic low density lipoprotein (LDL) receptors which increases hepatic uptake of LDL. Rosuvastatin also inhibits hepatic synthesis of very low density lipoprotein (VLDL).F4649 The overall effect is a decrease in plasma LDL and VLDL.
In vitro and in vivo animal studies also demonstrate that rosuvastatin exerts vasculoprotective effects independent of its lipid-lowering properties, also known as the pleiotropic effects of statins.[A181424] This includes improvement in endothelial function, enhanced stability of atherosclerotic plaques, reduced oxidative stress and inflammation, and inhibition of the thrombogenic response.
Statins have also been found to bind allosterically to β2 integrin function-associated antigen-1 (LFA-1), which plays an important role in leukocyte trafficking and in T cell activation.[A181559]
Rosuvastatin exerts an anti-inflammatory effect on rat mesenteric microvascular endothelium by attenuating leukocyte rolling, adherence and transmigration.[A1807] The drug also modulates nitric oxide synthase (NOS) expression and reduces ischemic-reperfusion injuries in rat hearts.[A1787] Rosuvastatin increases the bioavailability of nitric oxide[A1807][A1799][A1787] by upregulating NOS[A1791] and by increasing the stability of NOS through post-transcriptional polyadenylation.[A1796] It is unclear as to how rosuvastatin brings about these effects though they may be due to decreased concentrations of mevalonic acid.
In vitro and in vivo animal studies also demonstrate that rosuvastatin exerts vasculoprotective effects independent of its lipid-lowering properties, also known as the pleiotropic effects of statins.[A181424] This includes improvement in endothelial function, enhanced stability of atherosclerotic plaques, reduced oxidative stress and inflammation, and inhibition of the thrombogenic response.
Statins have also been found to bind allosterically to β2 integrin function-associated antigen-1 (LFA-1), which plays an important role in leukocyte trafficking and in T cell activation.[A181559]
Rosuvastatin exerts an anti-inflammatory effect on rat mesenteric microvascular endothelium by attenuating leukocyte rolling, adherence and transmigration.[A1807] The drug also modulates nitric oxide synthase (NOS) expression and reduces ischemic-reperfusion injuries in rat hearts.[A1787] Rosuvastatin increases the bioavailability of nitric oxide[A1807][A1799][A1787] by upregulating NOS[A1791] and by increasing the stability of NOS through post-transcriptional polyadenylation.[A1796] It is unclear as to how rosuvastatin brings about these effects though they may be due to decreased concentrations of mevalonic acid.
Pharmacodynamics
Rosuvastatin is a synthetic, enantiomerically pure antilipemic agent. It is used to lower total cholesterol, low density lipoprotein-cholesterol (LDL-C), apolipoprotein B (apoB), non-high density lipoprotein-cholesterol (non-HDL-C), and trigleride (TG) plasma concentrations while increasing HDL-C concentrations. High LDL-C, low HDL-C and high TG concentrations in the plasma are associated with increased risk of atherosclerosis and cardiovascular disease. The total cholesterol to HDL-C ratio is a strong predictor of coronary artery disease and high ratios are associated with higher risk of disease. Increased levels of HDL-C are associated with lower cardiovascular risk. By decreasing LDL-C and TG and increasing HDL-C, rosuvastatin reduces the risk of cardiovascular morbidity and mortality.[A181087][A181406]
Elevated cholesterol levels, and in particular, elevated low-density lipoprotein (LDL) levels, are an important risk factor for the development of CVD.[A181087] Use of statins to target and reduce LDL levels has been shown in a number of landmark studies to significantly reduce the risk of development of CVD and all-cause mortality.[A181090][A181093][A181096][A181427][A181475] Statins are considered a cost-effective treatment option for CVD due to their evidence of reducing all-cause mortality including fatal and non-fatal CVD as well as the need for surgical revascularization or angioplasty following a heart attack.[A181087][A181406] Evidence has shown that even for low-risk individuals (with <10% risk of a major vascular event occurring within 5 years) statins cause a 20%-22% relative reduction in major cardiovascular events (heart attack, stroke, coronary revascularization, and coronary death) for every 1 mmol/L reduction in LDL without any significant side effects or risks.[A181397, A181403]
Skeletal Muscle Effects
Cases of myopathy and rhabdomyolysis with acute renal failure secondary to myoglobinuria have been reported with HMG-CoA reductase inhibitors, including rosuvastatin. These risks can occur at any dose level, but are increased at the highest dose (40 mg). Rosuvastatin should be prescribed with caution in patients with predisposing factors for myopathy (e.g., age ≥ 65 years, inadequately treated hypothyroidism, renal impairment).
The risk of myopathy during treatment with rosuvastatin may be increased with concurrent administration of some other lipid-lowering therapies (such as [fenofibrate] or [niacin]), [gemfibrozil], [cyclosporine], [atazanavir]/[ritonavir], [lopinavir]/ritonavir, or [simeprevir]. Cases of myopathy, including rhabdomyolysis, have been reported with HMG-CoA reductase inhibitors, including rosuvastatin, coadministered with [colchicine], and caution should therefore be exercised when prescribing these two medications together.F4649
Real-world data from observational studies has suggested that 10-15% of people taking statins may experience muscle aches at some point during treatment.[A182258]
Liver Enzyme Abnormalities
Increases in serum transaminases have been reported with HMG-CoA reductase inhibitors, including rosuvastatin. In most cases, the elevations were transient and resolved or improved on continued therapy or after a brief interruption in therapy. There were two cases of jaundice, for which a relationship to rosuvastatin therapy could not be determined, which resolved after discontinuation of therapy. There were no cases of liver failure or irreversible liver disease in these trials.F4649
Endocrine Effects
Increases in HbA1c and fasting serum glucose levels have been reported with HMG-CoA reductase inhibitors, including rosuvastatin calcium tablets. Based on clinical trial data with rosuvastatin, in some instances these increases may exceed the threshold for the diagnosis of diabetes mellitus.F4649
An in vitro study found that [atorvastatin], [pravastatin], [rosuvastatin], and [pitavastatin] exhibited a dose-dependent cytotoxic effect on human pancreas islet β cells, with reductions in cell viability of 32, 41, 34 and 29%, respectively, versus control]. Moreover, insulin secretion rates were decreased by 34, 30, 27 and 19%, respectively, relative to control.[A182012]
HMG-CoA reductase inhibitors interfere with cholesterol synthesis and lower cholesterol levels and, as such, might theoretically blunt adrenal or gonadal steroid hormone production. Rosuvastatin demonstrated no effect upon nonstimulated cortisol levels and no effect on thyroid metabolism as assessed by TSH plasma concentration. In rosuvastatin treated patients, there was no impairment of adrenocortical reserve and no reduction in plasma cortisol concentrations. Clinical studies with other HMG-CoA reductase inhibitors have suggested that these agents do not reduce plasma testosterone concentration. The effects of HMG-CoA reductase inhibitors on male fertility have not been studied. The effects, if any, on the pituitarygonadal axis in premenopausal women are unknown.F4652
Cardiovascular
Ubiquinone levels were not measured in rosuvastatin clinical trials, however significant decreases in circulating ubiquinone levels in patients treated with other statins have been observed. The clinical significance of a potential long-term statin-induced deficiency of ubiquinone has not been established. It has been reported that a decrease in myocardial ubiquinone levels could lead to impaired cardiac function in patients with borderline congestive heart failure.F4652
Lipoprotein A
In some patients, the beneficial effect of lowered total cholesterol and LDL-C levels may be partly blunted by a concomitant increase in the Lipoprotein(a) [Lp(a)] concentrations. Present knowledge suggests the importance of high Lp(a) levels as an emerging risk factor for coronary heart disease. It is thus desirable to maintain and reinforce lifestyle changes in high-risk patients placed on rosuvastatin therapy.F4652 Further studies have demonstrated statins affect Lp(a) levels differently in patients with dyslipidemia depending on their apo(a) phenotype; statins increase Lp(a) levels exclusively in patients with the low molecular weight apo(a) phenotype.[A181418]
Elevated cholesterol levels, and in particular, elevated low-density lipoprotein (LDL) levels, are an important risk factor for the development of CVD.[A181087] Use of statins to target and reduce LDL levels has been shown in a number of landmark studies to significantly reduce the risk of development of CVD and all-cause mortality.[A181090][A181093][A181096][A181427][A181475] Statins are considered a cost-effective treatment option for CVD due to their evidence of reducing all-cause mortality including fatal and non-fatal CVD as well as the need for surgical revascularization or angioplasty following a heart attack.[A181087][A181406] Evidence has shown that even for low-risk individuals (with <10% risk of a major vascular event occurring within 5 years) statins cause a 20%-22% relative reduction in major cardiovascular events (heart attack, stroke, coronary revascularization, and coronary death) for every 1 mmol/L reduction in LDL without any significant side effects or risks.[A181397, A181403]
Skeletal Muscle Effects
Cases of myopathy and rhabdomyolysis with acute renal failure secondary to myoglobinuria have been reported with HMG-CoA reductase inhibitors, including rosuvastatin. These risks can occur at any dose level, but are increased at the highest dose (40 mg). Rosuvastatin should be prescribed with caution in patients with predisposing factors for myopathy (e.g., age ≥ 65 years, inadequately treated hypothyroidism, renal impairment).
The risk of myopathy during treatment with rosuvastatin may be increased with concurrent administration of some other lipid-lowering therapies (such as [fenofibrate] or [niacin]), [gemfibrozil], [cyclosporine], [atazanavir]/[ritonavir], [lopinavir]/ritonavir, or [simeprevir]. Cases of myopathy, including rhabdomyolysis, have been reported with HMG-CoA reductase inhibitors, including rosuvastatin, coadministered with [colchicine], and caution should therefore be exercised when prescribing these two medications together.F4649
Real-world data from observational studies has suggested that 10-15% of people taking statins may experience muscle aches at some point during treatment.[A182258]
Liver Enzyme Abnormalities
Increases in serum transaminases have been reported with HMG-CoA reductase inhibitors, including rosuvastatin. In most cases, the elevations were transient and resolved or improved on continued therapy or after a brief interruption in therapy. There were two cases of jaundice, for which a relationship to rosuvastatin therapy could not be determined, which resolved after discontinuation of therapy. There were no cases of liver failure or irreversible liver disease in these trials.F4649
Endocrine Effects
Increases in HbA1c and fasting serum glucose levels have been reported with HMG-CoA reductase inhibitors, including rosuvastatin calcium tablets. Based on clinical trial data with rosuvastatin, in some instances these increases may exceed the threshold for the diagnosis of diabetes mellitus.F4649
An in vitro study found that [atorvastatin], [pravastatin], [rosuvastatin], and [pitavastatin] exhibited a dose-dependent cytotoxic effect on human pancreas islet β cells, with reductions in cell viability of 32, 41, 34 and 29%, respectively, versus control]. Moreover, insulin secretion rates were decreased by 34, 30, 27 and 19%, respectively, relative to control.[A182012]
HMG-CoA reductase inhibitors interfere with cholesterol synthesis and lower cholesterol levels and, as such, might theoretically blunt adrenal or gonadal steroid hormone production. Rosuvastatin demonstrated no effect upon nonstimulated cortisol levels and no effect on thyroid metabolism as assessed by TSH plasma concentration. In rosuvastatin treated patients, there was no impairment of adrenocortical reserve and no reduction in plasma cortisol concentrations. Clinical studies with other HMG-CoA reductase inhibitors have suggested that these agents do not reduce plasma testosterone concentration. The effects of HMG-CoA reductase inhibitors on male fertility have not been studied. The effects, if any, on the pituitarygonadal axis in premenopausal women are unknown.F4652
Cardiovascular
Ubiquinone levels were not measured in rosuvastatin clinical trials, however significant decreases in circulating ubiquinone levels in patients treated with other statins have been observed. The clinical significance of a potential long-term statin-induced deficiency of ubiquinone has not been established. It has been reported that a decrease in myocardial ubiquinone levels could lead to impaired cardiac function in patients with borderline congestive heart failure.F4652
Lipoprotein A
In some patients, the beneficial effect of lowered total cholesterol and LDL-C levels may be partly blunted by a concomitant increase in the Lipoprotein(a) [Lp(a)] concentrations. Present knowledge suggests the importance of high Lp(a) levels as an emerging risk factor for coronary heart disease. It is thus desirable to maintain and reinforce lifestyle changes in high-risk patients placed on rosuvastatin therapy.F4652 Further studies have demonstrated statins affect Lp(a) levels differently in patients with dyslipidemia depending on their apo(a) phenotype; statins increase Lp(a) levels exclusively in patients with the low molecular weight apo(a) phenotype.[A181418]
Pharmacokinetics
How the body processes this drug — absorption, distribution, metabolism, and elimination
Absorption
In a study of healthy white male volunteers, the absolute oral bioavailability of rosuvastatin was found to be approximately 20% while absorption was estimated to be 50%, which is consistent with a substantial first-pass effect after oral dosing.
[A181451][A181454]
Another study in healthy volunteers found that the peak plasma concentration (Cmax) of rosuvastatin was 6.06ng/mL and was reached at a median of 5 hours following oral dosing.
[A181463]
Both Cmax and AUC increased in approximate proportion to dose. Neither food nor evening versus morning administration was shown to have an effect on the AUC of rosuvastatin.[F4649, F4652] Many statins are known to interact with hepatic uptake transporters and thus reach high concentrations at their site of action in the liver.
Breast Cancer Resistance Protein (BCRP) is a membrane-bound protein that plays an important role in the absorption of rosuvastatin, particularly as CYP3A4 has minimal involvement in its metabolism.
[A181460]
Evidence from pharmacogenetic studies of c.421C>A single nucleotide polymorphisms (SNPs) in the gene for BCRP has demonstrated that individuals with the 421AA genotype have reduced functional activity and 2.4-fold higher AUC and Cmax values for rosuvastatin compared to study individuals with the control 421CC genotype. This has important implications for the variation in response to the drug in terms of efficacy and toxicity, particularly as the BCRP c.421C>A polymorphism occurs more frequently in Asian populations than in Caucasians.
[A181478][A181487]
Other statin drugs impacted by this polymorphism include [fluvastatin] and [atorvastatin].
[A181478]
Genetic differences in the OATP1B1 (organic-anion-transporting polypeptide 1B1) hepatic transporter have also been shown to impact rosuvastatin pharmacokinetics.
Evidence from pharmacogenetic studies of the c.521T>C SNP showed that rosuvastatin AUC was increased 1.62-fold for individuals homozygous for 521CC compared to homozygous 521TT individuals.
[A181493]
Other statin drugs impacted by this polymorphism include [simvastatin], [pitavastatin], [atorvastatin], and [pravastatin].
[A181460]
For patients known to have the above-mentioned c.421AA BCRP or c.521CC OATP1B1 genotypes, a maximum daily dose of 20mg of rosuvastatin is recommended to avoid adverse effects from the increased exposure to the drug, such as muscle pain and risk of rhabdomyolysis.F4652
[A181451][A181454]
Another study in healthy volunteers found that the peak plasma concentration (Cmax) of rosuvastatin was 6.06ng/mL and was reached at a median of 5 hours following oral dosing.
[A181463]
Both Cmax and AUC increased in approximate proportion to dose. Neither food nor evening versus morning administration was shown to have an effect on the AUC of rosuvastatin.[F4649, F4652] Many statins are known to interact with hepatic uptake transporters and thus reach high concentrations at their site of action in the liver.
Breast Cancer Resistance Protein (BCRP) is a membrane-bound protein that plays an important role in the absorption of rosuvastatin, particularly as CYP3A4 has minimal involvement in its metabolism.
[A181460]
Evidence from pharmacogenetic studies of c.421C>A single nucleotide polymorphisms (SNPs) in the gene for BCRP has demonstrated that individuals with the 421AA genotype have reduced functional activity and 2.4-fold higher AUC and Cmax values for rosuvastatin compared to study individuals with the control 421CC genotype. This has important implications for the variation in response to the drug in terms of efficacy and toxicity, particularly as the BCRP c.421C>A polymorphism occurs more frequently in Asian populations than in Caucasians.
[A181478][A181487]
Other statin drugs impacted by this polymorphism include [fluvastatin] and [atorvastatin].
[A181478]
Genetic differences in the OATP1B1 (organic-anion-transporting polypeptide 1B1) hepatic transporter have also been shown to impact rosuvastatin pharmacokinetics.
Evidence from pharmacogenetic studies of the c.521T>C SNP showed that rosuvastatin AUC was increased 1.62-fold for individuals homozygous for 521CC compared to homozygous 521TT individuals.
[A181493]
Other statin drugs impacted by this polymorphism include [simvastatin], [pitavastatin], [atorvastatin], and [pravastatin].
[A181460]
For patients known to have the above-mentioned c.421AA BCRP or c.521CC OATP1B1 genotypes, a maximum daily dose of 20mg of rosuvastatin is recommended to avoid adverse effects from the increased exposure to the drug, such as muscle pain and risk of rhabdomyolysis.F4652
Half-life
The elimination half-life (t½) of rosuvastatin is approximately 19 hours and does not increase with increasing doses.[F4649, F4652]
Protein binding
Rosuvastatin is 88% bound to plasma proteins, mostly albumin. This binding is reversible and independent of plasma concentrations.[F4649, F4652]
Volume of distribution
Rosuvastatin undergoes first-pass extraction in the liver, which is the primary site of cholesterol synthesis and LDL-C clearance. The mean volume of distribution at steady-state of rosuvastatin is approximately 134 litres.[F4649, F4652]
Metabolism
Rosuvastatin is not extensively metabolized, as demonstrated by the small amount of radiolabeled dose that is recovered as a metabolite (~10%). Cytochrome P450 (CYP) 2C9 is primarily responsible for the formation of rosuvastatin's major metabolite, N-desmethylrosuvastatin, which has approximately 20-50% of the pharmacological activity of its parent compound in vitro.[F4649, F4652] However, this metabolic pathway isn't deemed to be clinically significant as there were no observable effects found on rosuvastatin pharmacokinetics when rosuvastatin was coadministered with fluconazole, a potent CYP2C9 inhibitor.
[A34483]
In vitro and in vivo data indicate that rosuvastatin has no clinically significant cytochrome P450 interactions (as substrate, inhibitor or inducer). Consequently, there is little potential for drug-drug interactions upon coadministration with agents that are metabolized by cytochrome P450.F4652
[A34483]
In vitro and in vivo data indicate that rosuvastatin has no clinically significant cytochrome P450 interactions (as substrate, inhibitor or inducer). Consequently, there is little potential for drug-drug interactions upon coadministration with agents that are metabolized by cytochrome P450.F4652
Route of elimination
Rosuvastatin is not extensively metabolized; approximately 10% of a radiolabeled dose is recovered as metabolite. Following oral administration, rosuvastatin and its metabolites are primarily excreted in the feces (90%). After an intravenous dose, approximately 28% of total body clearance was via the renal route, and 72% by the hepatic route.[F4649, F4652, A181451]
A study in healthy adult male volunteers found that approximately 90% of the rosuvastatin dose was recovered in feces within 72 hours after dose, while the remaining 10% was recovered in urine. The drug was completely excreted from the body after 10 days of dosing.
They also found that approximately 76.8% of the excreted dose was unchanged from the parent compound, with the remaining dose recovered as the metabolites n-desmethyl rosuvastatin and rosuvastatin-5S-lactone.
[A181463]
Renal tubular secretion is responsible for >90% of total renal clearance, and is believed to be mediated primarily by the uptake transporter OAT3 (Organic anion transporter 1), while OAT1 had minimal involvement.
[A181490]
A study in healthy adult male volunteers found that approximately 90% of the rosuvastatin dose was recovered in feces within 72 hours after dose, while the remaining 10% was recovered in urine. The drug was completely excreted from the body after 10 days of dosing.
They also found that approximately 76.8% of the excreted dose was unchanged from the parent compound, with the remaining dose recovered as the metabolites n-desmethyl rosuvastatin and rosuvastatin-5S-lactone.
[A181463]
Renal tubular secretion is responsible for >90% of total renal clearance, and is believed to be mediated primarily by the uptake transporter OAT3 (Organic anion transporter 1), while OAT1 had minimal involvement.
[A181490]
Drug targets(2)
Proteins and enzymes this drug interacts with in the body
3-hydroxy-3-methylglutaryl-coenzyme A reductase
HMGCR
inhibitor
Specific functioncoenzyme A binding
Cellular location
Endoplasmic reticulum membrane
General function & pharmacology
Catalyzes the conversion of (3S)-hydroxy-3-methylglutaryl-CoA (HMG-CoA) to mevalonic acid, the rate-limiting step in the synthesis of cholesterol and other isoprenoids, thus plays a critical role in cellular cholesterol homeostasis .
PMID:21357570 PMID:2991281 PMID:36745799 PMID:6995544
HMGCR is the main target of statins, a class of cholesterol-lowering drugs PMID:11349148 PMID:18540668 PMID:36745799
PMID:21357570 PMID:2991281 PMID:36745799 PMID:6995544
HMGCR is the main target of statins, a class of cholesterol-lowering drugs PMID:11349148 PMID:18540668 PMID:36745799
Integrin alpha-L
ITGAL
inhibitory allosteric modulator
Specific functioncell adhesion molecule binding
Cellular location
Cell membrane
General function & pharmacology
Integrin ITGAL/ITGB2 is a receptor for ICAM1, ICAM2, ICAM3 and ICAM4. Integrin ITGAL/ITGB2 is a receptor for F11R .
PMID:11812992 PMID:15528364
Integrin ITGAL/ITGB2 is a receptor for the secreted form of ubiquitin-like protein ISG15; the interaction is mediated by ITGAL .
PMID:29100055
Involved in a variety of immune phenomena including leukocyte-endothelial cell interaction, cytotoxic T-cell mediated killing, and antibody dependent killing by granulocytes and monocytes. Contributes to natural killer cell cytotoxicity .
PMID:15356110
Involved in leukocyte adhesion and transmigration of leukocytes including T-cells and neutrophils .
PMID:11812992
Acts as a platform at the immunological synapse to translate TCR engagement and density of the ITGAL ligand ICAM1 into graded adhesion .
PMID:38195629
Required for generation of common lymphoid progenitor cells in bone marrow, indicating a role in lymphopoiesis (By similarity).
Integrin ITGAL/ITGB2 in association with ICAM3, contributes to apoptotic neutrophil phagocytosis by macrophages PMID:23775590
PMID:11812992 PMID:15528364
Integrin ITGAL/ITGB2 is a receptor for the secreted form of ubiquitin-like protein ISG15; the interaction is mediated by ITGAL .
PMID:29100055
Involved in a variety of immune phenomena including leukocyte-endothelial cell interaction, cytotoxic T-cell mediated killing, and antibody dependent killing by granulocytes and monocytes. Contributes to natural killer cell cytotoxicity .
PMID:15356110
Involved in leukocyte adhesion and transmigration of leukocytes including T-cells and neutrophils .
PMID:11812992
Acts as a platform at the immunological synapse to translate TCR engagement and density of the ITGAL ligand ICAM1 into graded adhesion .
PMID:38195629
Required for generation of common lymphoid progenitor cells in bone marrow, indicating a role in lymphopoiesis (By similarity).
Integrin ITGAL/ITGB2 in association with ICAM3, contributes to apoptotic neutrophil phagocytosis by macrophages PMID:23775590
Metabolizing enzymes(1)
Enzymes involved in drug metabolism — important for understanding drug interactions
Enzyme activity key
substrate
inhibitor
inducer
CYP2C9Cytochrome P450 2C9
substrate
Transporters(11)
Proteins that transport this drug across cell membranes
ATP-binding cassette sub-family C member 4
ABCC4
substrate
Specific function15-hydroxyprostaglandin dehydrogenase (NAD+) activity
Cellular location
Basolateral cell membrane
General function & pharmacology
ATP-dependent transporter of the ATP-binding cassette (ABC) family that actively extrudes physiological compounds and xenobiotics from cells. Transports a range of endogenous molecules that have a key role in cellular communication and signaling, including cyclic nucleotides such as cyclic AMP (cAMP) and cyclic GMP (cGMP), bile acids, steroid conjugates, urate, and prostaglandins .
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: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
Solute carrier organic anion transporter family member 1A2
SLCO1A2
Specific functionbile acid transmembrane transporter activity
Cellular location
Cell membrane
General function & pharmacology
Na(+)-independent transporter that mediates the cellular uptake of a broad range of organic anions such as the endogenous bile salts cholate and deoxycholate, either in their unconjugated or conjugated forms (taurocholate and glycocholate), at the plasmam membrane .
PMID:19129463 PMID:7557095
Responsible for intestinal absorption of bile acids (By similarity). Transports dehydroepiandrosterone 3-sulfate (DHEAS), a major circulating steroid secreted by the adrenal cortex, as well as estrone 3-sulfate and 17beta-estradiol 17-O-(beta-D-glucuronate) .
PMID:11159893 PMID:12568656 PMID:19129463 PMID:23918469 PMID:25560245 PMID:9539145
Mediates apical uptake of all-trans-retinol (atROL) across human retinal pigment epithelium, which is essential to maintaining the integrity of the visual cycle and thus vision .
PMID:25560245
Involved in the uptake of clinically used drugs .
PMID:17301733 PMID:20686826 PMID:27777271
Capable of thyroid hormone transport (both T3 or 3,3',5'-triiodo-L-thyronine, and T4 or L-tyroxine) .
PMID:19129463 PMID:20358049
Also transports prostaglandin E2 .
PMID:19129463
Plays roles in blood-brain and -cerebrospinal fluid barrier transport of organic anions and signal mediators, and in hormone uptake by neural cells (By similarity). May also play a role in the reuptake of neuropeptides such as substance P/TAC1 and vasoactive intestinal peptide/VIP released from retinal neurons .
PMID:25132355
May play an important role in plasma and tissue distribution of the structurally diverse chemotherapeutic drugs methotrexate and paclitaxel .
PMID:23243220
Shows a pH-sensitive substrate specificity 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
May contribute to regulate the transport of organic compounds in testis across the blood-testis-barrier (Probable)
PMID:19129463 PMID:7557095
Responsible for intestinal absorption of bile acids (By similarity). Transports dehydroepiandrosterone 3-sulfate (DHEAS), a major circulating steroid secreted by the adrenal cortex, as well as estrone 3-sulfate and 17beta-estradiol 17-O-(beta-D-glucuronate) .
PMID:11159893 PMID:12568656 PMID:19129463 PMID:23918469 PMID:25560245 PMID:9539145
Mediates apical uptake of all-trans-retinol (atROL) across human retinal pigment epithelium, which is essential to maintaining the integrity of the visual cycle and thus vision .
PMID:25560245
Involved in the uptake of clinically used drugs .
PMID:17301733 PMID:20686826 PMID:27777271
Capable of thyroid hormone transport (both T3 or 3,3',5'-triiodo-L-thyronine, and T4 or L-tyroxine) .
PMID:19129463 PMID:20358049
Also transports prostaglandin E2 .
PMID:19129463
Plays roles in blood-brain and -cerebrospinal fluid barrier transport of organic anions and signal mediators, and in hormone uptake by neural cells (By similarity). May also play a role in the reuptake of neuropeptides such as substance P/TAC1 and vasoactive intestinal peptide/VIP released from retinal neurons .
PMID:25132355
May play an important role in plasma and tissue distribution of the structurally diverse chemotherapeutic drugs methotrexate and paclitaxel .
PMID:23243220
Shows a pH-sensitive substrate specificity 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
May contribute to regulate the transport of organic compounds in testis across the blood-testis-barrier (Probable)
Solute carrier organic anion transporter family member 1B1
SLCO1B1
substrate
inhibitor
Specific functionbile acid transmembrane transporter activity
Cellular location
Basolateral cell membrane
General function & pharmacology
Mediates the Na(+)-independent uptake of organic anions .
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
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
Solute carrier organic anion transporter family member 1B3
SLCO1B3
Specific functionbile acid transmembrane transporter activity
Cellular location
Basolateral cell membrane
General function & pharmacology
Mediates the Na(+)-independent uptake of organic anions .
PMID:10779507 PMID:15159445 PMID:17412826
Shows broad substrate specificity, can transport both organic anions such as bile acid taurocholate (cholyltaurine) and conjugated steroids (17-beta-glucuronosyl estradiol, dehydroepiandrosterone sulfate (DHEAS), and estrone 3-sulfate), as well as eicosanoid leukotriene C4, prostaglandin E2 and L-thyroxine (T4) .
PMID:10779507 PMID:11159893 PMID:12568656 PMID:15159445 PMID:17412826 PMID:19129463
Hydrogencarbonate/HCO3(-) acts as the probable counteranion that exchanges for organic anions .
PMID:19129463
Shows a pH-sensitive substrate specificity towards sulfated steroids, taurocholate 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
Involved in the clearance of bile acids and organic anions from the liver .
PMID:22232210
Can take up bilirubin glucuronides from plasma into the liver, contributing to the detoxification-enhancing liver-blood shuttling loop .
PMID:22232210
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 pitavastatin, a clinically important class of hypolipidemic drugs .
PMID:15159445
May play an important role in plasma and tissue distribution of the structurally diverse chemotherapeutic drugs methotrexate and paclitaxel .
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
PMID:10779507 PMID:15159445 PMID:17412826
Shows broad substrate specificity, can transport both organic anions such as bile acid taurocholate (cholyltaurine) and conjugated steroids (17-beta-glucuronosyl estradiol, dehydroepiandrosterone sulfate (DHEAS), and estrone 3-sulfate), as well as eicosanoid leukotriene C4, prostaglandin E2 and L-thyroxine (T4) .
PMID:10779507 PMID:11159893 PMID:12568656 PMID:15159445 PMID:17412826 PMID:19129463
Hydrogencarbonate/HCO3(-) acts as the probable counteranion that exchanges for organic anions .
PMID:19129463
Shows a pH-sensitive substrate specificity towards sulfated steroids, taurocholate 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
Involved in the clearance of bile acids and organic anions from the liver .
PMID:22232210
Can take up bilirubin glucuronides from plasma into the liver, contributing to the detoxification-enhancing liver-blood shuttling loop .
PMID:22232210
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 pitavastatin, a clinically important class of hypolipidemic drugs .
PMID:15159445
May play an important role in plasma and tissue distribution of the structurally diverse chemotherapeutic drugs methotrexate and paclitaxel .
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
Solute carrier organic anion transporter family member 2B1
SLCO2B1
Specific functionbile acid transmembrane transporter activity
Cellular location
Cell membrane
General function & pharmacology
Mediates the Na(+)-independent transport of steroid sulfate conjugates and other specific organic anions .
PMID:10873595 PMID:11159893 PMID:11932330 PMID:12724351 PMID:14610227 PMID:16908597 PMID:18501590 PMID:20507927 PMID:22201122 PMID:23531488 PMID:25132355 PMID:26383540 PMID:27576593 PMID:28408210 PMID:29871943 PMID:34628357
Responsible for the transport of estrone 3-sulfate (E1S) through the basal membrane of syncytiotrophoblast, highlighting a potential role in the placental absorption of fetal-derived sulfated steroids including the steroid hormone precursor dehydroepiandrosterone sulfate (DHEA-S) .
PMID:11932330 PMID:12409283
Also facilitates the uptake of sulfated steroids at the basal/sinusoidal membrane of hepatocytes, therefore accounting for the major part of organic anions clearance of liver .
PMID:11159893
Mediates the intestinal uptake of sulfated steroids .
PMID:12724351 PMID:28408210
Mediates the uptake of the neurosteroids DHEA-S and pregnenolone sulfate (PregS) into the endothelial cells of the blood-brain barrier as the first step to enter the brain .
PMID:16908597 PMID:25132355
Also plays a role in the reuptake of neuropeptides such as substance P/TAC1 and vasoactive intestinal peptide/VIP released from retinal neurons .
PMID:25132355
May act as a heme transporter that promotes cellular iron availability via heme oxygenase/HMOX2 and independently of TFRC .
PMID:35714613
Also transports heme by-product coproporphyrin III (CPIII), and may be involved in their hepatic disposition .
PMID:26383540
Mediates the uptake of other substrates such as prostaglandins D2 (PGD2), E1 (PGE1) and E2 (PGE2), taurocholate, L-thyroxine, leukotriene C4 and thromboxane B2 (PubMed:10873595, PubMed:14610227, PubMed:19129463, PubMed:29871943, Ref.25). May contribute to regulate the transport of organic compounds in testis across the blood-testis-barrier (Probable). Shows a pH-sensitive substrate specificity 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:14610227 PMID:19129463 PMID:22201122
The exact transport mechanism has not been yet deciphered but most likely involves an anion exchange, coupling the cellular uptake of organic substrate with the efflux of an anionic compound .
PMID:19129463 PMID:20507927 PMID:26277985
Hydrogencarbonate/HCO3(-) acts as a probable counteranion that exchanges for organic anions .
PMID:19129463
Cytoplasmic glutamate may also act as counteranion in the placenta .
PMID:26277985
An inwardly directed proton gradient has also been proposed as the driving force of E1S uptake with a (H(+):E1S) stoichiometry of (1:1) PMID:20507927
PMID:10873595 PMID:11159893 PMID:11932330 PMID:12724351 PMID:14610227 PMID:16908597 PMID:18501590 PMID:20507927 PMID:22201122 PMID:23531488 PMID:25132355 PMID:26383540 PMID:27576593 PMID:28408210 PMID:29871943 PMID:34628357
Responsible for the transport of estrone 3-sulfate (E1S) through the basal membrane of syncytiotrophoblast, highlighting a potential role in the placental absorption of fetal-derived sulfated steroids including the steroid hormone precursor dehydroepiandrosterone sulfate (DHEA-S) .
PMID:11932330 PMID:12409283
Also facilitates the uptake of sulfated steroids at the basal/sinusoidal membrane of hepatocytes, therefore accounting for the major part of organic anions clearance of liver .
PMID:11159893
Mediates the intestinal uptake of sulfated steroids .
PMID:12724351 PMID:28408210
Mediates the uptake of the neurosteroids DHEA-S and pregnenolone sulfate (PregS) into the endothelial cells of the blood-brain barrier as the first step to enter the brain .
PMID:16908597 PMID:25132355
Also plays a role in the reuptake of neuropeptides such as substance P/TAC1 and vasoactive intestinal peptide/VIP released from retinal neurons .
PMID:25132355
May act as a heme transporter that promotes cellular iron availability via heme oxygenase/HMOX2 and independently of TFRC .
PMID:35714613
Also transports heme by-product coproporphyrin III (CPIII), and may be involved in their hepatic disposition .
PMID:26383540
Mediates the uptake of other substrates such as prostaglandins D2 (PGD2), E1 (PGE1) and E2 (PGE2), taurocholate, L-thyroxine, leukotriene C4 and thromboxane B2 (PubMed:10873595, PubMed:14610227, PubMed:19129463, PubMed:29871943, Ref.25). May contribute to regulate the transport of organic compounds in testis across the blood-testis-barrier (Probable). Shows a pH-sensitive substrate specificity 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:14610227 PMID:19129463 PMID:22201122
The exact transport mechanism has not been yet deciphered but most likely involves an anion exchange, coupling the cellular uptake of organic substrate with the efflux of an anionic compound .
PMID:19129463 PMID:20507927 PMID:26277985
Hydrogencarbonate/HCO3(-) acts as a probable counteranion that exchanges for organic anions .
PMID:19129463
Cytoplasmic glutamate may also act as counteranion in the placenta .
PMID:26277985
An inwardly directed proton gradient has also been proposed as the driving force of E1S uptake with a (H(+):E1S) stoichiometry of (1:1) PMID:20507927
Cystine/glutamate transporter
SLC7A11
Specific functioncystine
Cellular location
Cell membrane
General function & pharmacology
Heterodimer with SLC3A2, that functions as an antiporter by mediating the exchange of extracellular anionic L-cystine and intracellular L-glutamate across the cellular plasma membrane .
PMID:11133847 PMID:11417227 PMID:14722095 PMID:15151999 PMID:34880232 PMID:35245456 PMID:35352032
Provides L-cystine for the maintenance of the redox balance between extracellular L-cystine and L-cysteine and for the maintenance of the intracellular levels of glutathione that is essential for cells protection from oxidative stress (By similarity). The transport is sodium-independent, electroneutral with a stoichiometry of 1:1, and is drove by the high intracellular concentration of L-glutamate and the intracellular reduction of L-cystine .
PMID:11133847 PMID:11417227
In addition, mediates the import of L-kynurenine leading to anti-ferroptotic signaling propagation required to maintain L-cystine and glutathione homeostasis .
PMID:35245456
Moreover, mediates N-acetyl-L-cysteine uptake into the placenta leading to subsequently down-regulation of pathways associated with oxidative stress, inflammation and apoptosis .
PMID:34120018
In vitro can also transport L-aspartate .
PMID:11417227
May participate in astrocyte and meningeal cell proliferation during development and can provide neuroprotection by promoting glutathione synthesis and delivery from non-neuronal cells such as astrocytes and meningeal cells to immature neurons (By similarity). Controls the production of pheomelanin pigment directly (By similarity)
PMID:11133847 PMID:11417227 PMID:14722095 PMID:15151999 PMID:34880232 PMID:35245456 PMID:35352032
Provides L-cystine for the maintenance of the redox balance between extracellular L-cystine and L-cysteine and for the maintenance of the intracellular levels of glutathione that is essential for cells protection from oxidative stress (By similarity). The transport is sodium-independent, electroneutral with a stoichiometry of 1:1, and is drove by the high intracellular concentration of L-glutamate and the intracellular reduction of L-cystine .
PMID:11133847 PMID:11417227
In addition, mediates the import of L-kynurenine leading to anti-ferroptotic signaling propagation required to maintain L-cystine and glutathione homeostasis .
PMID:35245456
Moreover, mediates N-acetyl-L-cysteine uptake into the placenta leading to subsequently down-regulation of pathways associated with oxidative stress, inflammation and apoptosis .
PMID:34120018
In vitro can also transport L-aspartate .
PMID:11417227
May participate in astrocyte and meningeal cell proliferation during development and can provide neuroprotection by promoting glutathione synthesis and delivery from non-neuronal cells such as astrocytes and meningeal cells to immature neurons (By similarity). Controls the production of pheomelanin pigment directly (By similarity)
Bile salt export pump
ABCB11
substrate
Specific functionABC-type bile acid transporter activity
Cellular location
Apical cell membrane
General function & pharmacology
Catalyzes the transport of the major hydrophobic bile salts, such as taurine and glycine-conjugated cholic acid across the canalicular membrane of hepatocytes in an ATP-dependent manner, therefore participates in hepatic bile acid homeostasis and consequently to lipid homeostasis through regulation of biliary lipid secretion in a bile salts dependent manner .
PMID:15791618 PMID:16332456 PMID:18985798 PMID:19228692 PMID:20010382 PMID:20398791 PMID:22262466 PMID:24711118 PMID:29507376 PMID:32203132
Transports taurine-conjugated bile salts more rapidly than glycine-conjugated bile salts .
PMID:16332456
Also transports non-bile acid compounds, such as pravastatin and fexofenadine in an ATP-dependent manner and may be involved in their biliary excretion PMID:15901796 PMID:18245269
PMID:15791618 PMID:16332456 PMID:18985798 PMID:19228692 PMID:20010382 PMID:20398791 PMID:22262466 PMID:24711118 PMID:29507376 PMID:32203132
Transports taurine-conjugated bile salts more rapidly than glycine-conjugated bile salts .
PMID:16332456
Also transports non-bile acid compounds, such as pravastatin and fexofenadine in an ATP-dependent manner and may be involved in their biliary excretion PMID:15901796 PMID:18245269
Broad substrate specificity ATP-binding cassette transporter ABCG2
ABCG2
substrate
Specific functionABC-type xenobiotic transporter activity
Cellular location
Cell membrane
General function & pharmacology
Broad substrate specificity ATP-dependent transporter of the ATP-binding cassette (ABC) family that actively extrudes a wide variety of physiological compounds, dietary toxins and xenobiotics from cells .
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: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
ATP-binding cassette sub-family C member 2
ABCC2
substrate
Specific functionABC-type glutathione S-conjugate transporter activity
Cellular location
Apical cell membrane
General function & pharmacology
ATP-dependent transporter of the ATP-binding cassette (ABC) family that binds and hydrolyzes ATP to enable active transport of various substrates including many drugs, toxicants and endogenous compound across cell membranes. Transports a wide variety of conjugated organic anions such as sulfate-, glucuronide- and glutathione (GSH)-conjugates of endo- and xenobiotics substrates .
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: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
Organic anion transporter 3
SLC22A8
substrate
inhibitor
Specific functionorganic anion transmembrane transporter activity
Cellular location
Basolateral cell membrane
General function & pharmacology
Functions as an organic anion/dicarboxylate exchanger that couples organic anion uptake indirectly to the sodium gradient .
PMID:14586168 PMID:15644426 PMID:15846473 PMID:16455804 PMID:31553721
Transports organic anions such as estrone 3-sulfate (E1S) and urate in exchange for dicarboxylates such as glutarate or ketoglutarate (2-oxoglutarate) .
PMID:14586168 PMID:15846473 PMID:15864504 PMID:22108572 PMID:23832370
Plays an important role in the excretion of endogenous and exogenous organic anions, especially from the kidney and the brain .
PMID:11306713 PMID:14586168 PMID:15846473
E1S transport is pH- and chloride-dependent and may also involve E1S/cGMP exchange .
PMID:26377792
Responsible for the transport of prostaglandin E2 (PGE2) and prostaglandin F2(alpha) (PGF2(alpha)) in the basolateral side of the renal tubule .
PMID:11907186
Involved in the transport of neuroactive tryptophan metabolites kynurenate and xanthurenate .
PMID:22108572 PMID:23832370
Functions as a biopterin transporters involved in the uptake and the secretion of coenzymes tetrahydrobiopterin (BH4), dihydrobiopterin (BH2) and sepiapterin to urine, thereby determining baseline levels of blood biopterins .
PMID:28534121
May be involved in the basolateral transport of steviol, a metabolite of the popular sugar substitute stevioside .
PMID:15644426
May participate in the detoxification/ renal excretion of drugs and xenobiotics, such as the histamine H(2)-receptor antagonists fexofenadine and cimetidine, the antibiotic benzylpenicillin (PCG), the anionic herbicide 2,4-dichloro-phenoxyacetate (2,4-D), the diagnostic agent p-aminohippurate (PAH), the antiviral acyclovir (ACV), and the mycotoxin ochratoxin (OTA), by transporting these exogenous organic anions across the cell membrane in exchange for dicarboxylates such as 2-oxoglutarate .
PMID:11669456 PMID:15846473 PMID:16455804
Contributes to the renal uptake of potent uremic toxins (indoxyl sulfate (IS), indole acetate (IA), hippurate/N-benzoylglycine (HA) and 3-carboxy-4-methyl-5-propyl-2-furanpropionate (CMPF)), pravastatin, PCG, E1S and dehydroepiandrosterone sulfate (DHEAS), and is partly involved in the renal uptake of temocaprilat (an angiotensin-converting enzyme (ACE) inhibitor) .
PMID:14675047
May contribute to the release of cortisol in the adrenals .
PMID:15864504
Involved in one of the detoxification systems on the choroid plexus (CP), removes substrates such as E1S or taurocholate (TC), PCG, 2,4-D and PAH, from the cerebrospinal fluid (CSF) to the blood for eventual excretion in urine and bile (By similarity). Also contributes to the uptake of several other organic compounds such as the prostanoids prostaglandin E(2) and prostaglandin F(2-alpha), L-carnitine, and the therapeutic drugs allopurinol, 6-mercaptopurine (6-MP) and 5-fluorouracil (5-FU) (By similarity). Mediates the transport of PAH, PCG, and the statins pravastatin and pitavastatin, from the cerebrum into the blood circulation across the blood-brain barrier (BBB).
In summary, plays a role in the efflux of drugs and xenobiotics, helping reduce their undesired toxicological effects on the body (By similarity)
PMID:14586168 PMID:15644426 PMID:15846473 PMID:16455804 PMID:31553721
Transports organic anions such as estrone 3-sulfate (E1S) and urate in exchange for dicarboxylates such as glutarate or ketoglutarate (2-oxoglutarate) .
PMID:14586168 PMID:15846473 PMID:15864504 PMID:22108572 PMID:23832370
Plays an important role in the excretion of endogenous and exogenous organic anions, especially from the kidney and the brain .
PMID:11306713 PMID:14586168 PMID:15846473
E1S transport is pH- and chloride-dependent and may also involve E1S/cGMP exchange .
PMID:26377792
Responsible for the transport of prostaglandin E2 (PGE2) and prostaglandin F2(alpha) (PGF2(alpha)) in the basolateral side of the renal tubule .
PMID:11907186
Involved in the transport of neuroactive tryptophan metabolites kynurenate and xanthurenate .
PMID:22108572 PMID:23832370
Functions as a biopterin transporters involved in the uptake and the secretion of coenzymes tetrahydrobiopterin (BH4), dihydrobiopterin (BH2) and sepiapterin to urine, thereby determining baseline levels of blood biopterins .
PMID:28534121
May be involved in the basolateral transport of steviol, a metabolite of the popular sugar substitute stevioside .
PMID:15644426
May participate in the detoxification/ renal excretion of drugs and xenobiotics, such as the histamine H(2)-receptor antagonists fexofenadine and cimetidine, the antibiotic benzylpenicillin (PCG), the anionic herbicide 2,4-dichloro-phenoxyacetate (2,4-D), the diagnostic agent p-aminohippurate (PAH), the antiviral acyclovir (ACV), and the mycotoxin ochratoxin (OTA), by transporting these exogenous organic anions across the cell membrane in exchange for dicarboxylates such as 2-oxoglutarate .
PMID:11669456 PMID:15846473 PMID:16455804
Contributes to the renal uptake of potent uremic toxins (indoxyl sulfate (IS), indole acetate (IA), hippurate/N-benzoylglycine (HA) and 3-carboxy-4-methyl-5-propyl-2-furanpropionate (CMPF)), pravastatin, PCG, E1S and dehydroepiandrosterone sulfate (DHEAS), and is partly involved in the renal uptake of temocaprilat (an angiotensin-converting enzyme (ACE) inhibitor) .
PMID:14675047
May contribute to the release of cortisol in the adrenals .
PMID:15864504
Involved in one of the detoxification systems on the choroid plexus (CP), removes substrates such as E1S or taurocholate (TC), PCG, 2,4-D and PAH, from the cerebrospinal fluid (CSF) to the blood for eventual excretion in urine and bile (By similarity). Also contributes to the uptake of several other organic compounds such as the prostanoids prostaglandin E(2) and prostaglandin F(2-alpha), L-carnitine, and the therapeutic drugs allopurinol, 6-mercaptopurine (6-MP) and 5-fluorouracil (5-FU) (By similarity). Mediates the transport of PAH, PCG, and the statins pravastatin and pitavastatin, from the cerebrum into the blood circulation across the blood-brain barrier (BBB).
In summary, plays a role in the efflux of drugs and xenobiotics, helping reduce their undesired toxicological effects on the body (By similarity)
Hepatic sodium/bile acid cotransporter
SLC10A1
Specific functionbile acid transmembrane transporter activity
Cellular location
Cell membrane
General function & pharmacology
As a major transporter of conjugated bile salts from plasma into the hepatocyte, it plays a key role in the enterohepatic circulation of bile salts necessary for the solubilization and absorption of dietary fat and fat-soluble vitamins .
PMID:14660639 PMID:24867799 PMID:34060352 PMID:8132774
It is strictly dependent on the extracellular presence of sodium .
PMID:14660639 PMID:24867799 PMID:34060352 PMID:8132774
It exhibits broad substrate specificity and transports various bile acids, such as taurocholate, cholate, as well as non-bile acid organic compounds, such as estrone sulfate .
PMID:14660639 PMID:34060352
Works collaboratively with the ileal transporter (NTCP2), the organic solute transporter (OST), and the bile salt export pump (BSEP), to ensure efficacious biological recycling of bile acids during enterohepatic circulation PMID:33222321
PMID:14660639 PMID:24867799 PMID:34060352 PMID:8132774
It is strictly dependent on the extracellular presence of sodium .
PMID:14660639 PMID:24867799 PMID:34060352 PMID:8132774
It exhibits broad substrate specificity and transports various bile acids, such as taurocholate, cholate, as well as non-bile acid organic compounds, such as estrone sulfate .
PMID:14660639 PMID:34060352
Works collaboratively with the ileal transporter (NTCP2), the organic solute transporter (OST), and the bile salt export pump (BSEP), to ensure efficacious biological recycling of bile acids during enterohepatic circulation PMID:33222321
Carriers(1)
Proteins that carry this drug through the body
Albumin
ALB
substrate
Specific functionantioxidant activity
Cellular location
Secreted
General function & pharmacology
Binds water, Ca(2+), Na(+), K(+), fatty acids, hormones, bilirubin and drugs (Probable). Its main function is the regulation of the colloidal osmotic pressure of blood (Probable). Major zinc transporter in plasma, typically binds about 80% of all plasma zinc .
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
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
Biological pathways(1)
Scientific references(42)
Di Napoli P., Taccardi A.A., Grilli A., De Lutiis M.A., Barsotti A., Felaco M., De Caterina R.
Chronic treatment with rosuvastatin modulates nitric oxide synthase expression and reduces ischemia–reperfusion injury in rat hearts.
Cardiovascular Research
200566(3):462-471. doi: 10.1016/j.cardiores.2005.02.008
Everett B.M., Glynn R.J., MacFadyen J.G., Ridker P.M.
Rosuvastatin in the prevention of stroke among men and women with elevated levels of C-reactive protein: justification for the Use of Statins in Prevention: an Intervention Trial Evaluating Rosuvastatin (JUPITER).
Circulation
2010 Jan 5121(1):143-50. doi: 10.1161/CIRCULATIONAHA.109.874834. Epub 2009 Dec 21
Jones S.P., Gibson M.F., Rimmer DM 3rd, Gibson T.M., Sharp B.R., Lefer D.J.
Direct vascular and cardioprotective effects of rosuvastatin, a new HMG-CoA reductase inhibitor.
Journal of the American College of Cardiology
200240(6):1172-1178. doi: 10.1016/s0735-1097(02)02115-0
Jones P.H., Davidson M.H., Stein E.A., Bays H.E., McKenney J.M., Miller E., Cain V.A., Blasetto J.W.
Comparison of the efficacy and safety of rosuvastatin versus atorvastatin, simvastatin, and pravastatin across doses (STELLAR**STELLAR = Statin Therapies for Elevated Lipid Levels compared Across doses to Rosuvastatin.
Trial)
The American Journal of Cardiology. 200392(2):152-160. doi: 10.1016/s0002-9149(03)00530-7
Kilic E., Kilic U., Matter C.M., Luscher T.F., Bassetti C.L., Hermann D.M.
Aggravation of Focal Cerebral Ischemia by Tissue Plasminogen Activator Is Reversed by 3-Hydroxy-3-Methylglutaryl Coenzyme A Reductase Inhibitor but Does Not Depend on Endothelial NO Synthase.
Stroke
200536(2):332-336. doi: 10.1161/01.str.0000152273.24063.f7
Kosmidou I., Moore J.P., Weber M., Searles C.D.
Statin Treatment and 3′ Polyadenylation of eNOS mRNA.
Arteriosclerosis, Thrombosis, and Vascular Biology
200727(12):2642-2649. doi: 10.1161/atvbaha.107.154492
Laufs U., Gertz K., Dirnagl U., Bohm M., Nickenig G., Endres M.
Rosuvastatin, a new HMG-CoA reductase inhibitor, upregulates endothelial nitric oxide synthase and protects from ischemic stroke in mice.
Brain Research
2002942(1-2):23-30. doi: 10.1016/s0006-8993(02)02649-5
McKillop T.
The statin wars.
The Lancet
2003362(9394):1498. doi: 10.1016/s0140-6736(03)14698-3
McTaggart F., Buckett L., Davidson R., Holdgate G., McCormick A., Schneck D., Smith G., Warwick M.
Preclinical and clinical pharmacology of rosuvastatin, a new 3-hydroxy- 3-methylglutaryl coenzyme A reductase inhibitor11CRESTOR is a trademark, the property of AstraZeneca PLC.
Research discussed in this article was supported by AstraZeneca
. The American Journal of Cardiology. 200187(5):28-32. doi: 10.1016/s0002-9149(01)01454-0
Nissen S.E., Nicholls S.J., Sipahi I., Libby P., Raichlen J.S., Ballantyne C.M., Davignon J., Erbel R., Fruchart J.C., Tardif J.C., Schoenhagen P., Crowe T., Cain V., Wolski K., Goormastic M., Tuzcu E.M.
Effect of Very High-Intensity Statin Therapy on Regression of Coronary Atherosclerosis.
Journal of the American Medical Association
2006295(13):1556. doi: 10.1001/jama.295.13.jpc60002
Stalker T.J., Lefer A.M., Scalia R.
A new HMG‐CoA reductase inhibitor, rosuvastatin, exerts anti‐inflammatory effects on the microvascular endothelium: the role of mevalonic acid.
British Journal of Pharmacology
2001133(3):406-412. doi: 10.1038/sj.bjp.0704070
Authors unspecified
The statin wars: why AstraZeneca must retreat.
The Lancet
2003362(9393):1341. doi: 10.1016/s0140-6736(03)14669-7
Ho R.H., Tirona R.G., Leake B.F., Glaeser H., Lee W., Lemke C.J., Wang Y., Kim R.B.
Drug and Bile Acid Transporters in Rosuvastatin Hepatic Uptake: Function, Expression, and Pharmacogenetics.
Gastroenterology
2006130(6):1793-1806. doi: 10.1053/j.gastro.2006.02.034
Kreatsoulas C., Anand S.S.
The impact of social determinants on cardiovascular disease.
Can Journal Cardiology
2010 Aug-Sep26 Suppl C:8C-13C. doi: 10.1016/s0828-282x(10)71075-8
Anderson T.J., Gregoire J., Pearson G.J., Barry A.R., Couture P., Dawes M., Francis G.A., Genest J Jr, Grover S., Gupta M., Hegele R.A., Lau D.C., Leiter L.A., Lonn E., Mancini G.B., McPherson R., Ngui D., Poirier P., Sievenpiper J.L., Stone J.A., Thanassoulis G., Ward R.
2016 Canadian Cardiovascular Society Guidelines for the Management of Dyslipidemia for the Prevention of Cardiovascular Disease in the Adult.
Can Journal Cardiology
2016 Nov32(11):1263-1282. doi: 10.1016/j.cjca.2016.07.510. Epub 2016 Jul 25
Authors unspecified
Prevention of cardiovascular events and death with pravastatin in patients with coronary heart disease and a broad range of initial cholesterol levels.
New England Journal of Medicine
1998 Nov 5339(19):1349-57. doi: 10.1056/NEJM199811053391902
Cannon C.P., Braunwald E., McCabe C.H., Rader D.J., Rouleau J.L., Belder R., Joyal S.V., Hill K.A., Pfeffer M.A., Skene A.M.
Intensive versus moderate lipid lowering with statins after acute coronary syndromes.
New England Journal of Medicine
2004 Apr 8350(15):1495-504. doi: 10.1056/NEJMoa040583. Epub 2004 Mar 8
Ridker P.M., Danielson E., Fonseca F.A., Genest J., Gotto AM Jr, Kastelein J.J., Koenig W., Libby P., Lorenzatti A.J., MacFadyen J.G., Nordestgaard B.G., Shepherd J., Willerson J.T., Glynn R.J.
Rosuvastatin to prevent vascular events in men and women with elevated C-reactive protein.
New England Journal of Medicine
2008 Nov 20359(21):2195-207. doi: 10.1056/NEJMoa0807646. Epub 2008 Nov 9
Mihaylova B., Emberson J., Blackwell L., Keech A., Simes J., Barnes E.H., Voysey M., Gray A., Collins R., Baigent C.
The effects of lowering LDL cholesterol with statin therapy in people at low risk of vascular disease: meta-analysis of individual data from 27 randomised trials.
The Lancet
2012 Aug 11380(9841):581-90. doi: 10.1016/S0140-6736(12)60367-5. Epub 2012 May 17
Taylor F., Huffman M.D., Macedo A.F., Moore T.H., Burke M., Davey Smith G., Ward K., Ebrahim S.
Statins for the primary prevention of cardiovascular disease.
Cochrane Database of Systematic Reviews
2013 Jan 31(1):CD004816. doi: 10.1002/14651858.CD004816.pub5
ATC classification(16 codes)
ATC C10BX10
ATC C10BX05
ATC C10BX07
ATC C10AA07
ATC A10BH52
ATC G01AE10
ATC C10BX13
ATC C10BX09
ATC C10BA09
ATC C10BX20
ATC C10BX21
ATC C10BX16
ATC C10BX17
ATC C10BX14
ATC C10BX22
ATC C10BA06
Affected organisms(1)
Humans and other mammals
International brands(17)
Salt forms(2)
Rosuvastatin calcium(DBSALT000154)
Rosuvastatin zinc(DBSALT001337)
Experimental properties(2)
Commercial products(711)
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)
Rosuvastatin
Additional database identifiers
Drugs Product Database (DPD)
13123
ChemSpider
393589
BindingDB
18372
PDB
FBI
ZINC
ZINC000001535101
HUGO Gene Nomenclature Committee (HGNC)
HGNC:5006
GenAtlas
HMGCR
GeneCards
HMGCR
GenBank Gene Database
M11058
GenBank Protein Database
306865
Guide to Pharmacology
639
UniProt Accession
HMDH_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:6148
GenAtlas
ITGAL
GeneCards
ITGAL
GenBank Gene Database
Y00796
GenBank Protein Database
31422
Guide to Pharmacology
2451
UniProt Accession
ITAL_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:399
GenAtlas
ALB
GeneCards
ALB
GenBank Gene Database
V00494
GenBank Protein Database
28590
UniProt Accession
ALBU_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:10956
GeneCards
SLCO1A2
GenBank Gene Database
U21943
GenBank Protein Database
885978
Guide to Pharmacology
1219
UniProt Accession
SO1A2_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
HUGO Gene Nomenclature Committee (HGNC)
HGNC:10961
GeneCards
SLCO1B3
GenBank Gene Database
AJ251506
GenBank Protein Database
9187497
Guide to Pharmacology
1221
UniProt Accession
SO1B3_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:10962
GenAtlas
SLCO2B1
GeneCards
SLCO2B1
GenBank Gene Database
AB026256
GenBank Protein Database
5006263
Guide to Pharmacology
1224
UniProt Accession
SO2B1_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:11059
GenAtlas
SLC7A11
GeneCards
SLC7A11
GenBank Gene Database
AB026891
GenBank Protein Database
5668545
Guide to Pharmacology
902
UniProt Accession
XCT_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:42
GenAtlas
ABCB11
GeneCards
ABCB11
GenBank Gene Database
AF091582
GenBank Protein Database
3873243
Guide to Pharmacology
778
UniProt Accession
ABCBB_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: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:10972
GeneCards
SLC22A8
GenBank Gene Database
AF097491
GenBank Protein Database
4378059
Guide to Pharmacology
1027
UniProt Accession
S22A8_HUMAN
HUGO Gene Nomenclature Committee (HGNC)
HGNC:10905
GeneCards
SLC10A1
GenBank Gene Database
L21893
GenBank Protein Database
410214
Guide to Pharmacology
959
UniProt Accession
NTCP_HUMAN
International reference pricing
8 formulations
Reference pricing from DrugBank. Prices are indicative and may not reflect current UK costs.
From $1.45/tablet
To $4.70/tablet
Crestor 5 mg Tablet
$1.45/tablet
Crestor 10 mg Tablet
$1.53/tablet
Crestor 20 mg Tablet
$1.91/tablet
Crestor 40 mg Tablet
$2.24/tablet
Crestor 10 mg tablet
$4.68/tablet
Source: DrugBank. Used under CC BY-NC 4.0 academic licence for non-commercial purposes.
Patent information
3 active patents, 7 expired
10413543
United States
Approved 17 Sept 2019 · Expires 12 Feb 2036
9y 10m
10376470
United States
Approved 13 Aug 2019 · Expires 1 May 2033
7y 1m
9763885
United States
Approved 19 Sept 2017 · Expires 1 May 2033
7y 1m
Approved 22 Feb 2005 · Expires 17 Jun 2022
Expired
Approved 13 Nov 2001 · Expires 4 Feb 2021
Expired
Source: DrugBank · CC BY-NC 4.0. Patent data sourced from national patent offices. Expiry dates may not reflect extensions, regulatory exclusivity periods, or legal challenges.
DrugBank citations
If you use DrugBank data in your research, please cite the following publications:
Knox C., Wilson M., Klinger C.M., et al
DrugBank 6.
0: the DrugBank Knowledgebase for 2024
Nucleic Acids Res. 2024 Jan 552(D1):D1265-D1275
Wishart D.S., Feunang Y.D., Guo A.C., et al
DrugBank 5.
0: a major update to the DrugBank database for 2018
Nucleic Acids Res. 2017 Nov 846(D1):D1074-D1082
Show earlier publications
Law V., Knox C., Djoumbou Y., et al
DrugBank 4.
0: shedding new light on drug metabolism
Nucleic Acids Res. 2014 Jan 142(1):D1091-7
Knox C., Law V., Jewison T., et al
DrugBank 3.
0: a comprehensive resource for 'omics' research on drugs
Nucleic Acids Res. 2011 Jan39(Database issue):D1035-41
Wishart D.S., Knox C., Guo A.C., et al
DrugBank: a knowledgebase for drugs, drug actions and drug targets.
Nucleic Acids Research
2008 Jan36(Database issue):D901-6
Wishart D.S., Knox C., Guo A.C., et al
DrugBank: a comprehensive resource for in silico drug discovery and exploration.
Nucleic Acids Research
2006 Jan 134(Database issue):D668-72
Source: go.drugbank.comCC BY-NC 4.0
Updated 27 days ago(8 Mar 2026)