Valsartan 40mg tablets
Prescription only
Requires a prescription from a doctor or prescriber
Tablet
40mg
Oral
Valsartan belongs to the angiotensin II receptor blocker (ARB) family of drugs, which also includes [telmisartan], [candesartan], [losartan], [olmesartan], and [irbesartan].
Active ingredients:
Valsartan
1 safety notice
Safety information for pregnancy and breastfeeding
Pregnancy
Approximate LD50 >2000 mg/kg (Gavage, rat) [L40064]
Reproductive Toxicology Studies
No teratogenic effects were seen when valsartan was given to pregnant mice and rats at oral doses up to 600 mg/kg/day and to pregnant rabbits at oral doses reaching up to 10 mg/kg/day.
Reproductive Toxicology Studies
No teratogenic effects were seen when valsartan was given to pregnant mice and rats at oral doses up to 600 mg/kg/day and to pregnant rabbits at oral doses reaching up to 10 mg/kg/day.
Despite this, marked decreases in fetal weight, pup birth weight, pup survival rate, and delays in developmental milestones were noted in studies in which parental rats were treated with valsartan at oral, maternally toxic doses of 600 mg/kg/day during the organogenesis period or during late gestation and lactation.[L11305]
Pregnancy
When used in pregnancy, drugs that act directly on the renin-angiotensin system (RAAS) can cause injury and death to the developing fetus.
Pregnancy
When used in pregnancy, drugs that act directly on the renin-angiotensin system (RAAS) can cause injury and death to the developing fetus.
When pregnancy is detected, valsartan should be discontinued as soon as possible.[L11305]
Breastfeeding
Despite this, marked decreases in fetal weight, pup birth weight, pup survival rate, and delays in developmental milestones were noted in studies in which parental rats were treated with valsartan at oral, maternally toxic doses of 600 mg/kg/day during the organogenesis period or during late gestation and lactation.[L11305]
Pregnancy
When used in pregnancy, drugs that act directly on the renin-angiotensin system (RAAS) can cause injury and death to the developing fetus.
Pregnancy
When used in pregnancy, drugs that act directly on the renin-angiotensin system (RAAS) can cause injury and death to the developing fetus.
Always consult your doctor or midwife before taking any medicine during pregnancy or while breastfeeding. Source: DrugBank (CC BY-NC 4.0).
Official documents, adverse reaction reporting, and safety monitoring
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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.
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Suspected adverse reactions reported for Valsartan
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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.
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Suspected adverse reactions reported for Valsartan
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EudraVigilance data is published by the European Medicines Agency (EMA). A suspected adverse reaction is not necessarily caused by the medicine.
21 branded products available
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21 products
MHRA licensed products
View all licensed products for Valsartan on the MHRA register
Valsartan 40mg tablets
Valsartan 40mg tablets
Valsartan 40mg tablets
Valsartan 40mg tablets
Valsartan 40mg tablets
Valsartan 40mg tablets
Valsartan 40mg tablets
Valsartan 40mg tablets
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£4.80indicative 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)
80 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
Losartan 12.5mg/5ml oral suspension
Oral suspension
12.5mg/5ml
Same therapeutic group
Candesartan 16mg/5ml oral solution
Oral solution
16mg/5ml
Same therapeutic group
Irbesartan 100mg/5ml oral suspension
Oral suspension
100mg/5ml
Same therapeutic group
Losartan 20mg/5ml oral suspension
Oral suspension
20mg/5ml
Same therapeutic group
Telmisartan 40mg/5ml oral suspension
Oral suspension
40mg/5ml
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
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Clinical guidelines and formulary information
British National Formulary
Valsartan
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)
Sacubitril valsartan for treating symptomatic chronic heart failure with reduced ejection fraction (TA388)
TA388
Technology appraisal
Updated Apr 2016Dapagliflozin for treating chronic heart failure with reduced ejection fraction (TA679)
TA679
Technology appraisal
Updated Feb 2021Empagliflozin for treating chronic heart failure with reduced ejection fraction (TA773)
TA773
Technology appraisal
Updated Mar 2022Chronic heart failure in adults (QS9)
QS9
Quality standard
Updated Sept 2025Source: National Institute for Health and Care Excellence (NICE). Contains public sector information licensed under the Open Government Licence v3.0.
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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
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These codes are used by healthcare IT systems and prescribers to identify this medicine.
NHS UK identifiers
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SNOMED CT and dm+d codes from NHS TRUD (Technology Reference data Update Distribution), licensed under the Open Government Licence v3.0. BNF 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
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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
54 found
Half-life
6 hours
Mechanism
Valsartan belongs to the angiotensin II receptor blocker (ARB) family of drugs,…
Food interactions
1 warning
Human targets
1 target
Data: DrugBank · CC BY-NC 4.0
Pharmacokinetics at a glance
Absorption
2 hours
After one oral dose, the antihypertensive activity of valsartan begins within approximately 2 hours and peaks within 4-6 hours in most patients.
[L40064]…
[L40064]…
Half-life
6 hours
After intravenous (IV) administration, valsartan demonstrates bi-exponential decay kinetics, with an average elimination half-life of about 6 hours.
[L11305]…
[L11305]…
Protein binding
95%
Valsartan is highly bound to serum proteins (95%), mainly serum albumin.
[L11305]
[L11305]
Volume of distribution
17 L
The steady-state volume of distribution of valsartan after intravenous administration is small (17 L), indicating that valsartan does not distribute into tissues extensively.
[L40064]…
[L40064]…
Metabolism
20%
Valsartan undergoes minimal liver metabolism and is not biotransformed to a high degree, as only approximately 20% of a single dose is recovered as metabolites.
[A174124][L40064]…
[A174124][L40064]…
Elimination
83%
Valsartan, when administered as an oral solution, is primarily recovered in feces (about 83% of dose) and urine (about 13% of dose).…
Clearance
2 L/h
Following intravenous administration, plasma clearance of valsartan is approximately 2 L/hour and its renal clearance is 0.62…
Pharmacokinetic data: DrugBank · CC BY-NC 4.0
Status:
Approved
Investigational
Small molecule
About this compound
Valsartan belongs to the angiotensin II receptor blocker (ARB) family of drugs, which also includes [telmisartan], [candesartan], [losartan], [olmesartan], and [irbesartan]. ARBs selectively bind to angiotensin receptor 1 (AT1) and prevent the protein angiotensin II from binding and exerting its hypertensive effects, which include vasoconstriction, stimulation and synthesis of aldosterone and ADH, cardiac stimulation, and renal reabsorption of sodium, among others. Overall, valsartan's physiologic effects lead to reduced blood pressure, lower aldosterone levels, reduced cardiac activity, and increased excretion of sodium.
Valsartan also affects the renin-angiotensin aldosterone system (RAAS), which plays an important role in hemostasis and regulation of kidney, vascular, and cardiac functions. Pharmacological blockade of RAAS via AT1 receptor blockade inhibits negative regulatory feedback within RAAS, which is a contributing factor to the pathogenesis and progression of cardiovascular disease, heart failure, and renal disease. In particular, heart failure is associated with chronic activation of RAAS, leading to inappropriate fluid retention, vasoconstriction, and ultimately a further decline in left ventricular function. ARBs have been shown to have a protective effect on the heart by improving cardiac function, reducing afterload, increasing cardiac output and preventing ventricular hypertrophy and remodelling.[A174154]
By comparison, the angiotensin-converting enzyme inhibitor (ACEI) class of medications (which includes drugs such as [ramipril], [lisinopril], and [perindopril]) inhibit the conversion of angiotensin I to angiotensin II through inhibition of the ACE enzyme. However, this does not prevent the formation of all angiotensin II within the body. The angiotensin II receptor blocker (ARB) family of drugs unique in that it blocks all angiotensin II activity, regardless of where or how it was synthesized.
Valsartan is commonly used for the management of hypertension, heart failure, and Type 2 Diabetes-associated nephropathy, particularly in patients who are unable to tolerate ACE inhibitors. ARBs such as valsartan have been shown in a number of large-scale clinical outcomes trials to improve cardiovascular outcomes including reducing risk of myocardial infarction, stroke, the progression of heart failure, and hospitalization.[A174124][A178153][A173869][A185324][A185327][A185333][A185342][A185345] Valsartan also slows the progression of diabetic nephropathy due to its renoprotective effects.[A174157][A174160][A174163] Improvements in chronic kidney disease with valsartan include both clinically and statistically significant decreases in urinary albumin and protein excretion in patients diagnosed with type 2 diabetes and in nondiabetic patients diagnosed with chronic kidney disease.[A174124][A173869]
Valsartan was initially approved in 1996 in Europe for the treatment of hypertension in adults. Shortly after, in 1997, this drug was approved in the United States.[A174124] Valsartan is generally well-tolerated with a side-effect profile superior to that of other antihypertensive drugs.[A174130][A174133]
Valsartan also affects the renin-angiotensin aldosterone system (RAAS), which plays an important role in hemostasis and regulation of kidney, vascular, and cardiac functions. Pharmacological blockade of RAAS via AT1 receptor blockade inhibits negative regulatory feedback within RAAS, which is a contributing factor to the pathogenesis and progression of cardiovascular disease, heart failure, and renal disease. In particular, heart failure is associated with chronic activation of RAAS, leading to inappropriate fluid retention, vasoconstriction, and ultimately a further decline in left ventricular function. ARBs have been shown to have a protective effect on the heart by improving cardiac function, reducing afterload, increasing cardiac output and preventing ventricular hypertrophy and remodelling.[A174154]
By comparison, the angiotensin-converting enzyme inhibitor (ACEI) class of medications (which includes drugs such as [ramipril], [lisinopril], and [perindopril]) inhibit the conversion of angiotensin I to angiotensin II through inhibition of the ACE enzyme. However, this does not prevent the formation of all angiotensin II within the body. The angiotensin II receptor blocker (ARB) family of drugs unique in that it blocks all angiotensin II activity, regardless of where or how it was synthesized.
Valsartan is commonly used for the management of hypertension, heart failure, and Type 2 Diabetes-associated nephropathy, particularly in patients who are unable to tolerate ACE inhibitors. ARBs such as valsartan have been shown in a number of large-scale clinical outcomes trials to improve cardiovascular outcomes including reducing risk of myocardial infarction, stroke, the progression of heart failure, and hospitalization.[A174124][A178153][A173869][A185324][A185327][A185333][A185342][A185345] Valsartan also slows the progression of diabetic nephropathy due to its renoprotective effects.[A174157][A174160][A174163] Improvements in chronic kidney disease with valsartan include both clinically and statistically significant decreases in urinary albumin and protein excretion in patients diagnosed with type 2 diabetes and in nondiabetic patients diagnosed with chronic kidney disease.[A174124][A173869]
Valsartan was initially approved in 1996 in Europe for the treatment of hypertension in adults. Shortly after, in 1997, this drug was approved in the United States.[A174124] Valsartan is generally well-tolerated with a side-effect profile superior to that of other antihypertensive drugs.[A174130][A174133]
Properties:
solid
Avg. mass: 435.52 Da
DrugBank indication
Valsartan is indicated for the treatment of hypertension to reduce the risk of fatal and nonfatal cardiovascular events, primarily strokes and myocardial infarctions. It is also indicated for the treatment of heart failure (NYHA class II-IV) and for left ventricular dysfunction or failure after myocardial infarction when the use of an angiotensin-converting enzyme inhibitor (ACEI) is not appropriate.[F4703, L11305]
It is also used in combination with [sacubitril].
[L36445]
It is also used in combination with [sacubitril].
[L36445]
Also known as(57)
(S)-N-Valeryl-N-{[2'-(1H-tetrazol-5-yl)biphenyl-4-yl]-methyl}-valine
N-(P-(O-1H-Tetrazol-5-ylphenyl)benzyl)-N-valeryl-L-valine
N-pentanoyl-N-{[2'-(1H-tetrazol-5-yl)biphenyl-4-yl]methyl}-L-valine
Valsartan
AGTR1A
AGTR1B
Angiotensin II type-1 receptor
AT1 receptor
Dosage forms(72)
Tablet (Oral) — 40.000 mg
Tablet (Oral) — 80.000 mg
Tablet, film coated (Oral) — 12.5 mg
Tablet, coated (Oral)
Capsule (Oral) — 160 mg/1
Capsule (Oral) — 80 mg/1
Tablet (Oral) — 160 mg/1
Tablet (Oral) — 320 mg
Molecular properties(19)
Drug interactions(1144)
Known interactions with other medications. Always consult a healthcare professional.
Duloxetine
Major
The risk or severity of orthostatic hypotension and syncope can be increased when Valsartan is combined with Duloxetine.
The risk or severity of hypotension and orthostatic hypotension can be increased when Valsartan is combined with Levodopa.
Risperidone
Moderate
Valsartan may increase the hypotensive activities of Risperidone.
Alfuzosin may increase the hypotensive activities of Valsartan.
Amifostine
Moderate
Valsartan may increase the hypotensive activities of Amifostine.
Canagliflozin
Major
The risk or severity of hypotension, hyperkalemia, and reduced intravascular volume can be increased when Canagliflozin is combined with Valsartan.
Diazoxide may increase the hypotensive activities of Valsartan.
Drospirenone
Unknown severity
The risk or severity of hyperkalemia can be increased when Valsartan is combined with Drospirenone.
Eplerenone
Unknown severity
The risk or severity of hyperkalemia can be increased when Eplerenone is combined with Valsartan.
Semuloparin
Unknown severity
The risk or severity of hyperkalemia can be increased when Semuloparin is combined with Valsartan.
Lithium citrate
Unknown severity
The serum concentration of Lithium citrate can be increased when it is combined with Valsartan.
Lithium carbonate
Unknown severity
The serum concentration of Lithium carbonate can be increased when it is combined with Valsartan.
Lithium hydroxide
Unknown severity
The serum concentration of Lithium hydroxide can be increased when it is combined with Valsartan.
Methylphenidate
Moderate
Methylphenidate may decrease the antihypertensive activities of Valsartan.
Dexmethylphenidate
Moderate
Dexmethylphenidate may decrease the antihypertensive activities of Valsartan.
Obinutuzumab
Moderate
Valsartan may increase the hypotensive activities of Obinutuzumab.
Pentoxifylline
Moderate
Pentoxifylline may increase the hypotensive activities of Valsartan.
Valsartan may increase the hypotensive activities of Rituximab.
The risk or severity of hyperkalemia can be increased when Tolvaptan is combined with Valsartan.
Trimethoprim
Unknown severity
The risk or severity of hyperkalemia can be increased when Trimethoprim is combined with Valsartan.
Desmopressin
Moderate
Desmopressin may decrease the antihypertensive activities of Valsartan.
Phentermine
Moderate
Phentermine may decrease the antihypertensive activities of Valsartan.
Midodrine may decrease the antihypertensive activities of Valsartan.
Isoetharine
Moderate
Isoetharine may decrease the antihypertensive activities of Valsartan.
Methysergide
Moderate
Methysergide may decrease the antihypertensive activities of Valsartan.
Cabergoline
Moderate
Cabergoline may decrease the antihypertensive activities of Valsartan.
Atomoxetine
Moderate
Atomoxetine may decrease the antihypertensive activities of Valsartan.
Etomidate may decrease the antihypertensive activities of Valsartan.
Zolmitriptan
Moderate
Zolmitriptan may decrease the antihypertensive activities of Valsartan.
Dihydroergotamine
Moderate
Dihydroergotamine may decrease the antihypertensive activities of Valsartan.
Protriptyline
Moderate
Protriptyline may decrease the antihypertensive activities of Valsartan.
Methylergometrine
Moderate
Methylergometrine may decrease the antihypertensive activities of Valsartan.
Norepinephrine
Moderate
Norepinephrine may decrease the antihypertensive activities of Valsartan.
Mirtazapine
Moderate
Mirtazapine may decrease the antihypertensive activities of Valsartan.
Phenylephrine
Moderate
Phenylephrine may decrease the antihypertensive activities of Valsartan.
Phenylpropanolamine
Moderate
Phenylpropanolamine may decrease the antihypertensive activities of Valsartan.
Droperidol
Moderate
Droperidol may decrease the antihypertensive activities of Valsartan.
Buspirone may decrease the antihypertensive activities of Valsartan.
Nortriptyline
Moderate
Nortriptyline may decrease the antihypertensive activities of Valsartan.
Amoxapine may decrease the antihypertensive activities of Valsartan.
Doxapram may decrease the antihypertensive activities of Valsartan.
Atropine may decrease the antihypertensive activities of Valsartan.
Lisuride may decrease the antihypertensive activities of Valsartan.
Metaraminol
Moderate
Metaraminol may decrease the antihypertensive activities of Valsartan.
Trazodone may decrease the antihypertensive activities of Valsartan.
Ergotamine
Moderate
Ergotamine may decrease the antihypertensive activities of Valsartan.
Nicergoline
Moderate
Nicergoline may decrease the antihypertensive activities of Valsartan.
Methoxamine
Moderate
Methoxamine may decrease the antihypertensive activities of Valsartan.
Propiomazine
Moderate
Propiomazine may decrease the antihypertensive activities of Valsartan.
Alfentanil
Moderate
Alfentanil may decrease the antihypertensive activities of Valsartan.
Showing 50 of 1144 interactions
Food & lifestyle interactions
Advice
Take with or without food. Co-administration with food slightly alters pharmacokinetics, but not to a clinically significant extent.
Toxicity & overdose
Approximate LD50 >2000 mg/kg (Gavage, rat) [L40064]
Reproductive Toxicology Studies
No teratogenic effects were seen when valsartan was given to pregnant mice and rats at oral doses up to 600 mg/kg/day and to pregnant rabbits at oral doses reaching up to 10 mg/kg/day. Despite this, marked decreases in fetal weight, pup birth weight, pup survival rate, and delays in developmental milestones were noted in studies in which parental rats were treated with valsartan at oral, maternally toxic doses of 600 mg/kg/day during the organogenesis period or during late gestation and lactation.
[L11305]
Pregnancy
When used in pregnancy, drugs that act directly on the renin-angiotensin system (RAAS) can cause injury and death to the developing fetus. When pregnancy is detected, valsartan should be discontinued as soon as possible.
[L11305]
Reproductive Toxicology Studies
No teratogenic effects were seen when valsartan was given to pregnant mice and rats at oral doses up to 600 mg/kg/day and to pregnant rabbits at oral doses reaching up to 10 mg/kg/day. Despite this, marked decreases in fetal weight, pup birth weight, pup survival rate, and delays in developmental milestones were noted in studies in which parental rats were treated with valsartan at oral, maternally toxic doses of 600 mg/kg/day during the organogenesis period or during late gestation and lactation.
[L11305]
Pregnancy
When used in pregnancy, drugs that act directly on the renin-angiotensin system (RAAS) can cause injury and death to the developing fetus. When pregnancy is detected, valsartan should be discontinued as soon as possible.
[L11305]
How it works
Mechanism of action
Valsartan belongs to the angiotensin II receptor blocker (ARB) family of drugs, which selectively bind to angiotensin receptor 1 (AT1) and prevent angiotensin II from binding and exerting its hypertensive effects. These include vasoconstriction, stimulation and synthesis of aldosterone and ADH, cardiac stimulation, and renal reabsorption of sodium among others. Overall, valsartan's physiologic effects lead to reduced blood pressure, lower aldosterone levels, reduced cardiac activity, and increased excretion of sodium.
Valsartan also affects the renin-angiotensin aldosterone system (RAAS), which plays an important role in hemostasis and regulation of kidney, vascular, and cardiac functions. Pharmacological blockade of RAAS via AT1 receptor blockade inhibits negative regulatory feedback within RAAS which is a contributing factor to the pathogenesis and progression of cardiovascular disease, heart failure, and renal disease. In particular, heart failure is associated with chronic activation of RAAS, leading to inappropriate fluid retention, vasoconstriction, and ultimately a further decline in left ventricular function. ARBs have been shown to have a protective effect on the heart by improving cardiac function, reducing afterload, increasing cardiac output and prevent ventricular hypertrophy.[A174154]
The angiotensin-converting enzyme inhibitor (ACEI) class of medications (which includes drugs such as [ramipril], [lisinopril], and [perindopril]) inhibits the conversion of angiotensin I to angiotensin II by inhibiting the ACE enzyme but does not prevent the formation of all angiotensin II. ARB activity is unique in that it blocks all angiotensin II activity, regardless of where or how it was synthesized.
Valsartan is commonly used for the management of hypertension, heart failure, and type 2 diabetes-associated nephropathy, particularly in patients who are unable to tolerate ACE inhibitors. ARBs such as valsartan have been shown in a number of large-scale clinical outcomes trials to improve cardiovascular outcomes including reducing risk of myocardial infarction, stroke, the progression of heart failure, and hospitalization.[A174124][A178153][A173869][A185324][A185327][A185333][A185342][A185345] Valsartan also slows the progression of diabetic nephropathy due to its renoprotective effects.[A174157][A174160][A174163] Improvements in chronic kidney disease with valsartan include both clinically and statistically significant decreases in urinary albumin and protein excretion in patients diagnosed with type 2 diabetes and in nondiabetic patients diagnosed with chronic kidney disease.[A174124][A173869]
Valsartan also binds to the AT2 receptor, however AT2 is not known to be associated with cardiovascular homeostasis like AT1. Valsartan has about 20,000-fold higher affinity for the AT1 receptor than for the AT2 receptor. The increased plasma levels of angiotensin II following AT1 receptor blockade with valsartan may stimulate the unblocked AT2 receptor.[L11305]
Valsartan also affects the renin-angiotensin aldosterone system (RAAS), which plays an important role in hemostasis and regulation of kidney, vascular, and cardiac functions. Pharmacological blockade of RAAS via AT1 receptor blockade inhibits negative regulatory feedback within RAAS which is a contributing factor to the pathogenesis and progression of cardiovascular disease, heart failure, and renal disease. In particular, heart failure is associated with chronic activation of RAAS, leading to inappropriate fluid retention, vasoconstriction, and ultimately a further decline in left ventricular function. ARBs have been shown to have a protective effect on the heart by improving cardiac function, reducing afterload, increasing cardiac output and prevent ventricular hypertrophy.[A174154]
The angiotensin-converting enzyme inhibitor (ACEI) class of medications (which includes drugs such as [ramipril], [lisinopril], and [perindopril]) inhibits the conversion of angiotensin I to angiotensin II by inhibiting the ACE enzyme but does not prevent the formation of all angiotensin II. ARB activity is unique in that it blocks all angiotensin II activity, regardless of where or how it was synthesized.
Valsartan is commonly used for the management of hypertension, heart failure, and type 2 diabetes-associated nephropathy, particularly in patients who are unable to tolerate ACE inhibitors. ARBs such as valsartan have been shown in a number of large-scale clinical outcomes trials to improve cardiovascular outcomes including reducing risk of myocardial infarction, stroke, the progression of heart failure, and hospitalization.[A174124][A178153][A173869][A185324][A185327][A185333][A185342][A185345] Valsartan also slows the progression of diabetic nephropathy due to its renoprotective effects.[A174157][A174160][A174163] Improvements in chronic kidney disease with valsartan include both clinically and statistically significant decreases in urinary albumin and protein excretion in patients diagnosed with type 2 diabetes and in nondiabetic patients diagnosed with chronic kidney disease.[A174124][A173869]
Valsartan also binds to the AT2 receptor, however AT2 is not known to be associated with cardiovascular homeostasis like AT1. Valsartan has about 20,000-fold higher affinity for the AT1 receptor than for the AT2 receptor. The increased plasma levels of angiotensin II following AT1 receptor blockade with valsartan may stimulate the unblocked AT2 receptor.[L11305]
Pharmacodynamics
Valsartan inhibits the pressor effects of angiotensin II with oral doses of 80 mg inhibiting the pressor effect by about 80% at peak with approximately 30% inhibition persisting for 24 hours. Removal of the negative feedback of angiotensin II causes a 2- to 3-fold rise in plasma renin and consequent rise in angiotensin II plasma concentration in hypertensive patients. Minimal decreases in plasma aldosterone were observed after administration of valsartan.
In multiple-dose studies in hypertensive patients, valsartan had no notable effects on total cholesterol, fasting triglycerides, fasting serum glucose, or uric acid.[L11305]
Hypotension
Excessive hypotension was rarely seen (0.1%) in patients with uncomplicated hypertension treated with valsartan alone. In patients with an activated renin-angiotensin system, such as volume- and/or salt-depleted patients receiving high doses of diuretics, symptomatic hypotension may occur. This condition should be corrected prior to administration of valsartan, or the treatment should start under close medical supervision.
Caution should be observed when initiating therapy in patients with heart failure. Patients with heart failure given valsartan commonly have some reduction in blood pressure, but discontinuation of therapy because of continuing symptomatic hypotension usually is not necessary when dosing instructions are followed. In controlled trials in heart failure patients, the incidence of hypotension in valsartan-treated patients was 5.5% compared to 1.8% in placebo-treated patients.
If excessive hypotension occurs, the patient should be placed in the supine position and, if necessary, given an intravenous infusion of normal saline. A transient hypotensive response is not a contraindication to further treatment, which usually can be continued without difficulty once the blood pressure has stabilized.[L11305]
Impaired Renal Function
Changes in renal function including acute renal failure can be caused by drugs that inhibit the renin-angiotensin system and by diuretics. Patients whose renal function may depend in part on the activity of the renin-angiotensin system (e.g., patients with renal artery stenosis, chronic kidney disease, severe congestive heart failure, or volume depletion) may be at particular risk of developing acute renal failure on valsartan. Monitor renal function periodically in these patients. Consider withholding or discontinuing therapy in patients who develop a clinically significant decrease in renal function on valsartan.[L11305]
Hyperkalemia
Some patients with heart failure have developed increases in potassium. These effects are usually minor and transient, and they are more likely to occur in patients with pre-existing renal impairment. Dosage reduction and/or discontinuation of valsartan may be required.[L11305]
In multiple-dose studies in hypertensive patients, valsartan had no notable effects on total cholesterol, fasting triglycerides, fasting serum glucose, or uric acid.[L11305]
Hypotension
Excessive hypotension was rarely seen (0.1%) in patients with uncomplicated hypertension treated with valsartan alone. In patients with an activated renin-angiotensin system, such as volume- and/or salt-depleted patients receiving high doses of diuretics, symptomatic hypotension may occur. This condition should be corrected prior to administration of valsartan, or the treatment should start under close medical supervision.
Caution should be observed when initiating therapy in patients with heart failure. Patients with heart failure given valsartan commonly have some reduction in blood pressure, but discontinuation of therapy because of continuing symptomatic hypotension usually is not necessary when dosing instructions are followed. In controlled trials in heart failure patients, the incidence of hypotension in valsartan-treated patients was 5.5% compared to 1.8% in placebo-treated patients.
If excessive hypotension occurs, the patient should be placed in the supine position and, if necessary, given an intravenous infusion of normal saline. A transient hypotensive response is not a contraindication to further treatment, which usually can be continued without difficulty once the blood pressure has stabilized.[L11305]
Impaired Renal Function
Changes in renal function including acute renal failure can be caused by drugs that inhibit the renin-angiotensin system and by diuretics. Patients whose renal function may depend in part on the activity of the renin-angiotensin system (e.g., patients with renal artery stenosis, chronic kidney disease, severe congestive heart failure, or volume depletion) may be at particular risk of developing acute renal failure on valsartan. Monitor renal function periodically in these patients. Consider withholding or discontinuing therapy in patients who develop a clinically significant decrease in renal function on valsartan.[L11305]
Hyperkalemia
Some patients with heart failure have developed increases in potassium. These effects are usually minor and transient, and they are more likely to occur in patients with pre-existing renal impairment. Dosage reduction and/or discontinuation of valsartan may be required.[L11305]
Pharmacokinetics
How the body processes this drug — absorption, distribution, metabolism, and elimination
Absorption
After one oral dose, the antihypertensive activity of valsartan begins within approximately 2 hours and peaks within 4-6 hours in most patients.
[L40064]
Food decreases the exposure to orally administered valsartan by approximately 40% and peak plasma concentration by approximately 50%. AUC and Cmax values of valsartan generally increase linearly with increasing dose over the therapeutic dose range. Valsartan does not accumulate appreciably in plasma following repetitive administration.
[L11305]
[L40064]
Food decreases the exposure to orally administered valsartan by approximately 40% and peak plasma concentration by approximately 50%. AUC and Cmax values of valsartan generally increase linearly with increasing dose over the therapeutic dose range. Valsartan does not accumulate appreciably in plasma following repetitive administration.
[L11305]
Half-life
After intravenous (IV) administration, valsartan demonstrates bi-exponential decay kinetics, with an average elimination half-life of about 6 hours.
[L11305]
[L11305]
Protein binding
Valsartan is highly bound to serum proteins (95%), mainly serum albumin.
[L11305]
[L11305]
Volume of distribution
The steady-state volume of distribution of valsartan after intravenous administration is small (17 L), indicating that valsartan does not distribute into tissues extensively.
[L40064]
[L40064]
Metabolism
Valsartan undergoes minimal liver metabolism and is not biotransformed to a high degree, as only approximately 20% of a single dose is recovered as metabolites.
[A174124][L40064]
The primary metabolite, accounting for about 9% of dose, is valeryl 4-hydroxy valsartan. In vitro metabolism studies involving recombinant CYP 450 enzymes indicated that the CYP 2C9 isoenzyme is responsible for the formation of valeryl-4-hydroxy valsartan. Valsartan does not inhibit CYP 450 isozymes at clinically relevant concentrations.
CYP 450 mediated drug interaction between valsartan and coadministered drugs are unlikely because of the low extent of metabolism.
[L11305]
[A174124][L40064]
The primary metabolite, accounting for about 9% of dose, is valeryl 4-hydroxy valsartan. In vitro metabolism studies involving recombinant CYP 450 enzymes indicated that the CYP 2C9 isoenzyme is responsible for the formation of valeryl-4-hydroxy valsartan. Valsartan does not inhibit CYP 450 isozymes at clinically relevant concentrations.
CYP 450 mediated drug interaction between valsartan and coadministered drugs are unlikely because of the low extent of metabolism.
[L11305]
Route of elimination
Valsartan, when administered as an oral solution, is primarily recovered in feces (about 83% of dose) and urine (about 13% of dose). The recovery is mainly as unchanged drug, with only about 20% of dose recovered as metabolites.
[L11305]
[L11305]
Clearance
Following intravenous administration, plasma clearance of valsartan is approximately 2 L/hour and its renal clearance is 0.62 L/hour (about 30% of total clearance).
[L11305]
[L11305]
Drug targets(1)
Proteins and enzymes this drug interacts with in the body
Type-1 angiotensin II receptor
AGTR1
antagonist
Specific functionangiotensin type I receptor activity
Cellular location
Cell membrane
General function & pharmacology
Receptor for angiotensin II, a vasoconstricting peptide, which acts as a key regulator of blood pressure and sodium retention by the kidney .
PMID:15611106 PMID:1567413 PMID:25913193 PMID:26420482 PMID:30639100 PMID:32079768 PMID:8987975
The activated receptor in turn couples to G-alpha proteins G(q) (GNAQ, GNA11, GNA14 or GNA15) and thus activates phospholipase C and increases the cytosolic Ca(2+) concentrations, which in turn triggers cellular responses such as stimulation of protein kinase C PMID:15611106
PMID:15611106 PMID:1567413 PMID:25913193 PMID:26420482 PMID:30639100 PMID:32079768 PMID:8987975
The activated receptor in turn couples to G-alpha proteins G(q) (GNAQ, GNA11, GNA14 or GNA15) and thus activates phospholipase C and increases the cytosolic Ca(2+) concentrations, which in turn triggers cellular responses such as stimulation of protein kinase C PMID:15611106
Metabolizing enzymes(1)
Enzymes involved in drug metabolism — important for understanding drug interactions
Enzyme activity key
substrate
inhibitor
inducer
CYP2C9Cytochrome P450 2C9
substrate
Transporters(3)
Proteins that transport this drug across cell membranes
Solute carrier organic anion transporter family member 1B3
SLCO1B3
substrate
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 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
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
Biological pathways(1)
Involved compounds
Scientific references(16)
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Valsartan: more than a decade of experience.
Drugs
200969(17):2393-414. doi: 10.2165/11319460-000000000-00000
Fogari R., Zoppi A.
A drug safety evaluation of valsartan.
Expert Opinion Drug Saf
2011 Mar10(2):295-303. doi: 10.1517/14740338.2011.543416. Epub 2010 Dec 11
McInnes G.T.
Clinical advantage of valsartan.
Cardiology
199991 Suppl 1:14-8. doi: 10.1159/000047283
Chiolero A., Burnier M.
Pharmacology of valsartan, an angiotensin II receptor antagonist.
Expert Opinion Investig Drugs
1998 Nov7(11):1915-25. doi: 10.1517/13543784.7.11.1915
Akazawa H., Yabumoto C., Yano M., Kudo-Sakamoto Y., Komuro I.
ARB and cardioprotection.
Cardiovasc Drugs Therapeutics
2013 Apr27(2):155-60. doi: 10.1007/s10557-012-6392-2
Zhou G., Cheung A.K., Liu X., Huang Y.
Valsartan slows the progression of diabetic nephropathy in db/db mice via a reduction in podocyte injury, and renal oxidative stress and inflammation.
Clinical Science (Lond)
2014 May126(10):707-20. doi: 10.1042/CS20130223
Suzuki K., Souda S., Ikarashi T., Kaneko S., Nakagawa O., Aizawa Y.
Renoprotective effects of low-dose valsartan in type 2 diabetic patients with diabetic nephropathy.
Diabetes Research and Clinical Practice
200257(3):179-183. doi: 10.1016/s0168-8227(02)00098-0
Currie G., Bethel M.A., Holzhauer B., Haffner S.M., Holman R.R., McMurray J.J.V.
Effect of valsartan on kidney outcomes in people with impaired glucose tolerance.
Diabetes Obes Metabolism
2017 Jun19(6):791-799. doi: 10.1111/dom.12877. Epub 2017 Mar 17
Ezekowitz J.A., O'Meara E., McDonald M.A., Abrams H., Chan M., Ducharme A., Giannetti N., Grzeslo A., Hamilton P.G., Heckman G.A., Howlett J.G., Koshman S.L., Lepage S., McKelvie R.S., Moe G.W., Rajda M., Swiggum E., Virani S.A., Zieroth S., Al-Hesayen A., Cohen-Solal A., D'Astous M., De S., Estrella-Holder E., Fremes S., Green L., Haddad H., Harkness K., Hernandez A.F., Kouz S., LeBlanc M.H., Masoudi F.A., Ross H.J., Roussin A., Sussex B.
2017 Comprehensive Update of the Canadian Cardiovascular Society Guidelines for the Management of Heart Failure.
Can Journal Cardiology
2017 Nov33(11):1342-1433. doi: 10.1016/j.cjca.2017.08.022. Epub 2017 Sep 6
Leung A.A., Daskalopoulou S.S., Dasgupta K., McBrien K., Butalia S., Zarnke K.B., Nerenberg K., Harris K.C., Nakhla M., Cloutier L., Gelfer M., Lamarre-Cliche M., Milot A., Bolli P., Tremblay G., McLean D., Tran K.C., Tobe S.W., Ruzicka M., Burns K.D., Vallee M., Prasad G.V.R., Gryn S.E., Feldman R.D., Selby P., Pipe A., Schiffrin E.L., McFarlane P.A., Oh P., Hegele R.A., Khara M., Wilson T.W., Penner S.B., Burgess E., Sivapalan P., Herman R.J., Bacon S.L., Rabkin S.W., Gilbert R.E., Campbell T.S., Grover S., Honos G., Lindsay P., Hill M.D., Coutts S.B., Gubitz G., Campbell N.R.C., Moe G.W., Howlett J.G., Boulanger J.M., Prebtani A., Kline G., Leiter L.A., Jones C., Cote A.M., Woo V., Kaczorowski J., Trudeau L., Tsuyuki R.T., Hiremath S., Drouin D., Lavoie K.L., Hamet P., Gregoire J.C., Lewanczuk R., Dresser G.K., Sharma M., Reid D., Lear S.A., Moullec G., Gupta M., Magee L.A., Logan A.G., Dionne J., Fournier A., Benoit G., Feber J., Poirier L., Padwal R.S., Rabi D.M.
Hypertension Canada's 2017 Guidelines for Diagnosis, Risk Assessment, Prevention, and Treatment of Hypertension in Adults.
Can Journal Cardiology
2017 May33(5):557-576. doi: 10.1016/j.cjca.2017.03.005. Epub 2017 Mar 10
Lee V.C., Rhew D.C., Dylan M., Badamgarav E., Braunstein G.D., Weingarten S.R.
Meta-analysis: angiotensin-receptor blockers in chronic heart failure and high-risk acute myocardial infarction.
Annals of Internal Medicine
2004 Nov 2141(9):693-704. doi: 10.7326/0003-4819-141-9-200411020-00011
Brenner B.M., Cooper M.E., de Zeeuw D., Keane W.F., Mitch W.E., Parving H.H., Remuzzi G., Snapinn S.M., Zhang Z., Shahinfar S.
Effects of losartan on renal and cardiovascular outcomes in patients with type 2 diabetes and nephropathy.
New England Journal of Medicine
2001 Sep 20345(12):861-9. doi: 10.1056/NEJMoa011161
Yusuf S., Teo K.K., Pogue J., Dyal L., Copland I., Schumacher H., Dagenais G., Sleight P., Anderson C.
Telmisartan, ramipril, or both in patients at high risk for vascular events.
New England Journal of Medicine
2008 Apr 10358(15):1547-59. doi: 10.1056/NEJMoa0801317. Epub 2008 Mar 31
Pfeffer M.A., McMurray J.J., Velazquez E.J., Rouleau J.L., Kober L., Maggioni A.P., Solomon S.D., Swedberg K., Van de Werf F., White H., Leimberger J.D., Henis M., Edwards S., Zelenkofske S., Sellers M.A., Califf R.M.
Valsartan, captopril, or both in myocardial infarction complicated by heart failure, left ventricular dysfunction, or both.
New England Journal of Medicine
2003 Nov 13349(20):1893-906. doi: 10.1056/NEJMoa032292. Epub 2003 Nov 10
O'Gara P.T., Kushner F.G., Ascheim D.D., Casey DE Jr, Chung M.K., de Lemos J.A., Ettinger S.M., Fang J.C., Fesmire F.M., Franklin B.A., Granger C.B., Krumholz H.M., Linderbaum J.A., Morrow D.A., Newby L.K., Ornato J.P., Ou N., Radford M.J., Tamis-Holland J.E., Tommaso C.L., Tracy C.M., Woo Y.J., Zhao D.X.
2013 ACCF/AHA guideline for the management of ST-elevation myocardial infarction: a report of the American College of Cardiology Foundation/American Heart Association Task Force on Practice Guidelines.
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2013 Jan 2961(4):e78-e140. doi: 10.1016/j.jacc.2012.11.019. Epub 2012 Dec 17
Nakashima A., Kawashita H., Masuda N., Saxer C., Niina M., Nagae Y., Iwasaki K.
Identification of cytochrome P450 forms involved in the 4-hydroxylation of valsartan, a potent and specific angiotensin II receptor antagonist, in human liver microsomes.
Xenobiotica
200535(6):589-602. doi: 10.1080/00498250500158175
ATC classification(9 codes)
ATC C09DX05
ATC C10BX10
ATC C09DA03
ATC C09CA03
ATC C09DX02
ATC C09DX01
ATC C09DB08
ATC C09DB01
ATC C09DX04
Affected organisms(1)
Humans and other mammals
Experimental properties(5)
Commercial products(1400)
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)
Valsartan
Additional database identifiers
Drugs Product Database (DPD)
11702
ChemSpider
54833
BindingDB
50049186
PDB
U35
Guide to Pharmacology
3937
ZINC
ZINC000003875259
HUGO Gene Nomenclature Committee (HGNC)
HGNC:336
GenAtlas
AGTR1
GeneCards
AGTR1
GenBank Gene Database
M91464
GenBank Protein Database
179122
Guide to Pharmacology
34
UniProt Accession
AGTR1_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: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: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:53
GenAtlas
ABCC2
GeneCards
ABCC2
GenBank Gene Database
U63970
GenBank Protein Database
1764162
Guide to Pharmacology
780
UniProt Accession
MRP2_HUMAN
International reference pricing
9 formulations
Reference pricing from DrugBank. Prices are indicative and may not reflect current UK costs.
From $2.32/tablet
To $4.63/tablet
Diovan 40 mg tablet
$2.32/tablet
Diovan 80 mg tablet
$2.33/tablet
Diovan 160 mg tablet
$2.42/tablet
Diovan hct 80-12.5 mg tablet
$3.00/tablet
Diovan 320 mg tablet
$3.17/tablet
Source: DrugBank. Used under CC BY-NC 4.0 academic licence for non-commercial purposes.
Patent information
10 active patents, 13 expired
10722471
United States
Approved 28 Jul 2020 · Expires 2 Feb 2037
10y 10m
11058667
United States
Approved 13 Jul 2021 · Expires 9 May 2036
10y 1m
9517226
United States
Approved 13 Dec 2016 · Expires 22 Aug 2033
7y 4m
9937143
United States
Approved 10 Apr 2018 · Expires 22 Aug 2033
7y 4m
11135192
United States
Approved 5 Oct 2021 · Expires 22 Aug 2033
7y 4m
The earliest active patent expires July 2026. Generic versions may become available after this date.
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)