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Details

Stereochemistry ACHIRAL
Molecular Formula 2C8H15O2.Mg
Molecular Weight 310.712
Optical Activity NONE
Defined Stereocenters 0 / 0
E/Z Centers 0
Charge 0

SHOW SMILES / InChI
Structure of VALPROATE MAGNESIUM

SMILES

[Mg++].CCCC(CCC)C([O-])=O.CCCC(CCC)C([O-])=O

InChI

InChIKey=LKLLHOIUJVEAGU-UHFFFAOYSA-L
InChI=1S/2C8H16O2.Mg/c2*1-3-5-7(6-4-2)8(9)10;/h2*7H,3-6H2,1-2H3,(H,9,10);/q;;+2/p-2

HIDE SMILES / InChI

Molecular Formula C8H15O2
Molecular Weight 143.2035
Charge -1
Count
Stereochemistry ACHIRAL
Additional Stereochemistry No
Defined Stereocenters 0 / 0
E/Z Centers 0
Optical Activity NONE

Molecular Formula Mg
Molecular Weight 24.305
Charge 2
Count
Stereochemistry ACHIRAL
Additional Stereochemistry No
Defined Stereocenters 0 / 0
E/Z Centers 0
Optical Activity NONE

Description
Curator's Comment: Description was created based on several sources, including http://psychopharmacologyinstitute.com/mood-stabilizers/valproate-in-psychiatry-approved-indications-and-off-label-uses/ | https://www.accessdata.fda.gov/drugsatfda_docs/label/2009/022152s002lbl.pdf | https://www.ncbi.nlm.nih.gov/pubmed/12847559 | https://www.ncbi.nlm.nih.gov/pubmed/11742974 | https://www.ncbi.nlm.nih.gov/pubmed/11473107

Valproic acid (VPA; valproate; di-n-propylacetic acid, DPA; 2-propylpentanoic acid, or 2-propylvaleric acid) was first synthesized in 1882, by Burton. FDA approved valproic acid for the treatment of manic episodes associated with bipolar disorder, for the monotherapy and adjunctive therapy of complex partial seizures and simple and complex absence seizures and adjunctive therapy in patients with multiple seizure types that include absence seizures and for the prophylaxis of migraine headaches. The mechanisms of VPA which seem to be of clinical importance in the treatment of epilepsy include increased gamma-aminobutyric acid (GABA)-ergic activity, reduction in excitatory neurotransmission, and modification of monoamines. Recently, it was discovered that the VPA is a class I selective histone deacetylase inhibitor. This activity can be distinguished from its therapeutically exploited antiepileptic activity.

Originator

Sources: Burton B.S. (1882) On the propyl derivatives and decomposition products of ethylacetoacetate. Am Chem J3: 385–395
Curator's Comment: reference retrieved from https://link.springer.com/chapter/10.1007%2F978-3-0348-8759-5_1

Approval Year

TargetsConditions

Conditions

ConditionModalityTargetsHighest PhaseProduct
Primary
DEPAKENE

Approved Use

Depakene (valproic acid) is indicated as monotherapy and adjunctive therapy in the treatment of patients with complex partial seizures that occur either in isolation or in association with other types of seizures. Depakene (valproic acid) is indicated for use as sole and adjunctive therapy in the treatment of simple and complex absence seizures, and adjunctively in patients with multiple seizure types which include absence seizures. Simple absence is defined as very brief clouding of the sensorium or loss of consciousness accompanied by certain generalized epileptic discharges without other detectable clinical signs. Complex absence is the term used when other signs are also present.
Preventing
STAVZOR

Approved Use

Stavzor (valproic acid) delayed release capsules is indicated for: • Acute treatment of manic episodes associated with bipolar disorder • Monotherapy and adjunctive therapy of complex partial seizures and simple and complex absence seizures; adjunctive therapy in patients with multiple seizure types that include absence seizures • Prophylaxis of migraine headaches

Launch Date

2008
Primary
STAVZOR

Approved Use

Stavzor (valproic acid) delayed release capsules is indicated for: • Acute treatment of manic episodes associated with bipolar disorder • Monotherapy and adjunctive therapy of complex partial seizures and simple and complex absence seizures; adjunctive therapy in patients with multiple seizure types that include absence seizures • Prophylaxis of migraine headaches

Launch Date

2008
Cmax

Cmax

ValueDoseCo-administeredAnalytePopulation
107.2 mg/L
500 mg 2 times / day multiple, oral
dose: 500 mg
route of administration: Oral
experiment type: MULTIPLE
co-administered:
VALPROIC ACID plasma
Homo sapiens
population: HEALTHY
age: UNKNOWN
sex: FEMALE / MALE
food status: FED
AUC

AUC

ValueDoseCo-administeredAnalytePopulation
1951 mg × h/L
500 mg 2 times / day multiple, oral
dose: 500 mg
route of administration: Oral
experiment type: MULTIPLE
co-administered:
VALPROIC ACID plasma
Homo sapiens
population: HEALTHY
age: UNKNOWN
sex: FEMALE / MALE
food status: FED
T1/2

T1/2

ValueDoseCo-administeredAnalytePopulation
16 h
1000 mg 1 times / day steady-state, oral
dose: 1000 mg
route of administration: Oral
experiment type: STEADY-STATE
co-administered:
VALPROIC ACID unknown
Homo sapiens
population: UNKNOWN
age: UNKNOWN
sex: UNKNOWN
food status: UNKNOWN
Doses

Doses

DosePopulationAdverse events​
150 mg/kg single, intravenous
Highest studied dose
Dose: 150 mg/kg
Route: intravenous
Route: single
Dose: 150 mg/kg
Sources: Page: p.6
healthy, 30.2 ± 11.7
n = 3
Health Status: healthy
Age Group: 30.2 ± 11.7
Sex: M+F
Population Size: 3
Sources: Page: p.6
DLT: Headache, Nausea...
Dose limiting toxicities:
Headache
Nausea
Sources: Page: p.6
140 mg/kg single, intravenous
MTD
Dose: 140 mg/kg
Route: intravenous
Route: single
Dose: 140 mg/kg
Sources: Page: p.6
healthy, 30.2 ± 11.7
n = 6
Health Status: healthy
Age Group: 30.2 ± 11.7
Sex: M+F
Population Size: 6
Sources: Page: p.6
25 g single, oral
Overdose
Dose: 25 g
Route: oral
Route: single
Dose: 25 g
Sources: Page: p.1
unhealthy, 37
n = 1
Health Status: unhealthy
Condition: Seizures |Bipolar disorder
Age Group: 37
Sex: M
Population Size: 1
Sources: Page: p.1
Disc. AE: Somnolence...
AEs leading to
discontinuation/dose reduction:
Somnolence
Sources: Page: p.1
100 g single, oral
Overdose
Dose: 100 g
Route: oral
Route: single
Dose: 100 g
Sources: Page: 110000
unhealthy, 41
n = 1
Health Status: unhealthy
Condition: Epilepsy
Age Group: 41
Sex: M
Population Size: 1
Sources: Page: 110000
Disc. AE: Coma...
AEs leading to
discontinuation/dose reduction:
Coma
Sources: Page: 110000
120 mg/kg 1 times / day multiple, intravenous
Highest studied dose
Dose: 120 mg/kg, 1 times / day
Route: intravenous
Route: multiple
Dose: 120 mg/kg, 1 times / day
Sources: Page: p.179
unhealthy, 62.5
n = 5
Health Status: unhealthy
Condition: Cancer
Age Group: 62.5
Sex: M+F
Population Size: 5
Sources: Page: p.179
DLT: Somnolence...
Dose limiting toxicities:
Somnolence (40%)
Sources: Page: p.179
60 mg/kg 1 times / day multiple, intravenous
MTD
Dose: 60 mg/kg, 1 times / day
Route: intravenous
Route: multiple
Dose: 60 mg/kg, 1 times / day
Sources: Page: p.178
unhealthy, 62.5
n = 3
Health Status: unhealthy
Condition: Cancer
Age Group: 62.5
Sex: M+F
Population Size: 3
Sources: Page: p.178
60 mg/kg 1 times / day multiple, oral
Recommended
Dose: 60 mg/kg, 1 times / day
Route: oral
Route: multiple
Dose: 60 mg/kg, 1 times / day
Sources: Page: p.1
unhealthy
Health Status: unhealthy
Condition: Seizures
Sources: Page: p.1
Disc. AE: Hepatotoxicity, Pancreatitis...
AEs leading to
discontinuation/dose reduction:
Hepatotoxicity
Pancreatitis
Sources: Page: p.1
AEs

AEs

AESignificanceDosePopulation
Headache DLT
150 mg/kg single, intravenous
Highest studied dose
Dose: 150 mg/kg
Route: intravenous
Route: single
Dose: 150 mg/kg
Sources: Page: p.6
healthy, 30.2 ± 11.7
n = 3
Health Status: healthy
Age Group: 30.2 ± 11.7
Sex: M+F
Population Size: 3
Sources: Page: p.6
Nausea DLT
150 mg/kg single, intravenous
Highest studied dose
Dose: 150 mg/kg
Route: intravenous
Route: single
Dose: 150 mg/kg
Sources: Page: p.6
healthy, 30.2 ± 11.7
n = 3
Health Status: healthy
Age Group: 30.2 ± 11.7
Sex: M+F
Population Size: 3
Sources: Page: p.6
Somnolence Disc. AE
25 g single, oral
Overdose
Dose: 25 g
Route: oral
Route: single
Dose: 25 g
Sources: Page: p.1
unhealthy, 37
n = 1
Health Status: unhealthy
Condition: Seizures |Bipolar disorder
Age Group: 37
Sex: M
Population Size: 1
Sources: Page: p.1
Coma Disc. AE
100 g single, oral
Overdose
Dose: 100 g
Route: oral
Route: single
Dose: 100 g
Sources: Page: 110000
unhealthy, 41
n = 1
Health Status: unhealthy
Condition: Epilepsy
Age Group: 41
Sex: M
Population Size: 1
Sources: Page: 110000
Somnolence 40%
DLT
120 mg/kg 1 times / day multiple, intravenous
Highest studied dose
Dose: 120 mg/kg, 1 times / day
Route: intravenous
Route: multiple
Dose: 120 mg/kg, 1 times / day
Sources: Page: p.179
unhealthy, 62.5
n = 5
Health Status: unhealthy
Condition: Cancer
Age Group: 62.5
Sex: M+F
Population Size: 5
Sources: Page: p.179
Hepatotoxicity Disc. AE
60 mg/kg 1 times / day multiple, oral
Recommended
Dose: 60 mg/kg, 1 times / day
Route: oral
Route: multiple
Dose: 60 mg/kg, 1 times / day
Sources: Page: p.1
unhealthy
Health Status: unhealthy
Condition: Seizures
Sources: Page: p.1
Pancreatitis Disc. AE
60 mg/kg 1 times / day multiple, oral
Recommended
Dose: 60 mg/kg, 1 times / day
Route: oral
Route: multiple
Dose: 60 mg/kg, 1 times / day
Sources: Page: p.1
unhealthy
Health Status: unhealthy
Condition: Seizures
Sources: Page: p.1
Overview

Overview

Drug as perpetrator​

Drug as perpetrator​

TargetModalityActivityMetaboliteClinical evidence
minimal
minimal
minimal
no
weak [Ki 7975 uM]
weak [Ki 8553 uM]
weak [Ki 9150 uM]
yes [Ki 600 uM]
likely (co-administration study)
Comment: competitive inhibition; risk of pharmacokinetic drug–drug interactions should be taken into account during concomitant use of valproic acid and CYP2C9 substrates
Drug as victim
PubMed

PubMed

TitleDatePubMed
Reversible cortical atrophy and cognitive decline induced by valproic acid.
1998
Influence of adenosine agonists and antiepileptic drugs on theophylline-induced seizures in rats.
1998 Oct
Intravenous valproate associated with significant hypotension in the treatment of status epilepticus.
1999 Dec
Cognitive dysfunction induced by phenytoin and valproate in rats: effect of nitric oxide.
1999 Jul
[A case report of valproate encephalopathy].
1999 Oct
Pathomorphological changes in mouse liver and kidney during prolonged valproate administration.
2000
Ribonucleotide reductase subunit R1: a gene conferring sensitivity to valproic acid-induced neural tube defects in mice.
2000 Apr
Fatal deterioration of neurological disease after orthotopic liver transplantation for valproic acid-induced liver damage.
2000 Aug
Effects of anticonvulsants on local anaesthetic-induced neurotoxicity in rats.
2000 Feb
Orthotopic liver transplantation with poor neurologic outcome in valproate-associated liver failure: a need for critical risk-benefit appraisal in the use of valproate.
2000 Feb
A multicenter randomized controlled trial on the clinical impact of therapeutic drug monitoring in patients with newly diagnosed epilepsy. The Italian TDM Study Group in Epilepsy.
2000 Feb
Sodium valproate inhibits production of TNF-alpha and IL-6 and activation of NF-kappaB.
2000 Feb 28
Valproate-induced hyperammonemic encephalopathy in the presence of topiramate.
2000 Jan 11
Valproic acid-induced alterations in growth and neurotrophic factor gene expression in murine embryos [corrected].
2000 Jan-Feb
Phenytoin poisoning after using Chinese proprietary medicines.
2000 Jul
Valproic acid-induced hyperammonemic encephalopathy with triphasic waves.
2000 Jul
Incidence of intravenous site reactions in neurotrauma patients receiving valproate or phenytoin.
2000 Jun
Visual and auditory hallucinations with the association of bupropion and valproate.
2000 Mar
Testosterone abuse and affective disorders.
2000 Mar
Gabapentin prophylaxis of clozapine-induced seizures.
2000 Mar
The safety of rapid valproic acid infusion.
2000 Oct
Vitamin E decreases valproic acid induced neural tube defects in mice.
2000 Oct 13
Influence of chronic barbiturate administration on sleep apnea after hypersomnia presentation: case study.
2000 Sep
Effects of combined administration of zonisamide and valproic acid or phenytoin to nitric oxide production, monoamines and zonisamide concentrations in the brain of seizure-susceptible EL mice.
2000 Sep 15
Probenecid-associated alterations in valproate glucuronide hepatobiliary disposition: mechanistic assessment using mathematical modeling.
2001 Apr
Comparison the cognitive effect of anti-epileptic drugs in seizure-free children with epilepsy before and after drug withdrawal.
2001 Apr
Determination of the antiepileptics vigabatrin and gabapentin in dosage forms and biological fluids using Hantzsch reaction.
2001 Feb
Valproate, but not lamotrigine, induces ovarian morphological changes in Wistar rats.
2001 Feb
Collaborative study on rat sperm motion analysis using CellSoft Series 4000 semen analyzer.
2001 Feb
Antiepileptic drug withdrawal in patients with temporal lobe epilepsy undergoing presurgical video-EEG monitoring.
2001 Feb
[Treatment of cluster headache].
2001 Feb
Glutamate receptor antagonists differentially affect the protective activity of conventional antiepileptics against amygdala-kindled seizures in rats.
2001 Feb
Different control of GH secretion by gamma-amino- and gamma-hydroxy-butyric acid in 4-year abstinent alcoholics.
2001 Feb 1
[Maintenance dose requirement for phenytoin is lowered in genetically impaired drug metabolism independent of concommitant use of other antiepileptics].
2001 Feb 17
[Febrile convulsions, Treatment and prognosis].
2001 Feb 19
Valproic acid has temporal variability in urinary clearance of metabolites.
2001 Jan
Pharmacologic treatment of patients hospitalized with the diagnosis of schizoaffective disorder.
2001 Jan
Electrophysiological and pharmacological properties of the human brain type IIA Na+ channel expressed in a stable mammalian cell line.
2001 Jan
Evaluating the tolerability of the newer mood stabilizers.
2001 Jan
Clozapine therapy for a patient with a history of Hodgkin's disease.
2001 Jan
Effects of antiepileptic drugs on rat platelet aggregation: ex vivo and in vitro study.
2001 Jan
Occurrence of thrombocytopenia in psychiatric patients taking valproate.
2001 Jan
Additional educational needs in children born to mothers with epilepsy.
2001 Jan
[Febrile pleuropericarditis during valproic acid treatment].
2001 Jan 20
A 25-year-old woman with bipolar disorder.
2001 Jan 24-31
Hypothermia and thermoregulatory derangements induced by valproic acid.
2001 Jan 9
Reproductive effects of valproate, carbamazepine, and oxcarbazepine in men with epilepsy.
2001 Jan 9
Mood stabilizers and ion regulation.
2001 Jan-Feb
Mood-stabilisers reduce the risk of developing antidepressant-induced maniform states in acute treatment of bipolar I depressed patients.
2001 Mar
Naltrexone as a treatment of self-injurious behavior--a case report.
2001 Mar
Patents

Sample Use Guides

Usual Adult Dose for Epilepsy Complex partial seizures: Initial dose: 10 to 15 mg/kg orally or intravenously per day as an IV infusion in divided doses, increased by 5 to 10 mg/kg per week if necessary according to clinical response Maintenance dose: 10 to 60 mg/kg per day in divided doses Maximum dose: 60 mg/kg per day Simple and complex absence seizures: Initial dose: 15 mg/kg orally or intravenously per day as an IV infusion in divided doses, increased at one week intervals by 5 to 10 mg/kg/day according to seizure control and tolerability Maximum dose: 60 mg/kg per day Comments: -If the total daily dose exceeds 250 mg, it should be given in 2 to 3 divided doses. -Use of IV valproate sodium for periods longer than 14 days has not been studied; patients should be converted to oral valproate as soon as clinically feasible. -When switching from oral to IV valproate, the total daily dose of IV valproate should be equivalent to the total daily dose of oral valproate, and administered at the same frequency as the oral product. -Equivalence between IV and oral valproate products at steady state has only been evaluated in a 6-hourly dosing regimen. Trough plasma level monitoring may be required if IV valproate is administered 2 to 3 times a day. -Complex partial seizures: When converting patients to valproate monotherapy, concomitant antiepileptic drug dosage can generally be reduced by approximately 25% every 2 weeks, commencing either at the start of valproate therapy or delayed by 1 to 2 weeks. Patients should be monitored closely during this period for increased seizure frequency. Uses: Monotherapy and adjunctive therapy in the treatment of complex partial seizures; sole and adjunctive therapy for simple and complex absence seizures; adjunctive therapy in patients with multiple seizure types that include absence seizures. Usual Adult Dose for Mania Delayed-release capsules : Initial dose: 750 mg orally per day in divided doses Maximum dose: 60 mg/kg orally per day Duration: Safety and efficacy beyond 3 weeks has not been established Comments: -The dose should be increased as rapidly as possible to achieve the lowest therapeutic dose which produces the desired clinical effect or the desired range of plasma concentrations. -In placebo-controlled clinical trials of acute mania, patients were dosed to a clinical response with a trough plasma concentration of 50 to 125 mcg/mL. -Maximum concentrations were generally achieved within 14 days. -Safety and efficacy for longer term use in the maintenance of the initial response and prevention of new manic episodes has not been systematically evaluated in clinical trials. Use for extended periods should be accompanied by regular review for the long-term usefulness of the drug for the individual patient. Use: Treatment of manic episodes associated with bipolar disorder. Usual Adult Dose for Migraine Prophylaxis Delayed release oral capsules: Initial dose: 250 mg orally twice a day Comments: -Some patients may benefit from doses up to 1000 mg per day. -In clinical trials, there was no evidence that higher doses led to greater efficacy. Usual Pediatric Dose for Epilepsy 10 years of age or older: Complex partial seizures: Initial dose: 10 to 15 mg/kg orally or intravenously per day as an IV infusion in divided doses, increased by 5 to 10 mg/kg per week if necessary according to clinical response Maintenance dose: 10 to 60 mg/kg per day in divided doses Maximum dose: 60 mg/kg per day Simple and complex absence seizures: Initial dose: 15 mg/kg orally or intravenously per day as an IV infusion in divided doses, increased at one week intervals by 5 to 10 mg/kg/day according to seizure control and tolerability Maximum dose: 60 mg/kg per day Comments: -If the total daily dose exceeds 250 mg, it should be given in 2 to 3 divided doses. -Use of IV valproate sodium for periods longer than 14 days has not been studied; patients should be converted to oral valproate as soon as clinically feasible. -When switching from oral to IV valproate, the total daily dose of IV valproate should be equivalent to the total daily dose of oral valproate, and administered at the same frequency as the oral product. -Equivalence between IV and oral valproate products at steady state has only been evaluated in a 6-hourly dosing regimen. Trough plasma level monitoring may be required if IV valproate is administered 2 to 3 times a day. -Complex partial seizures: When converting patients to valproate monotherapy, concomitant antiepileptic drug dosage can generally be reduced by approximately 25% every 2 weeks, commencing either at the start of valproate therapy or delayed by 1 to 2 weeks. Patients should be monitored closely during this period for increased seizure frequency. Uses: Monotherapy and adjunctive therapy in the treatment of complex partial seizures; sole and adjunctive therapy for simple and complex absence seizures; adjunctive therapy in patients with multiple seizure types that include absence seizures.
Route of Administration: Other
H9C2 cells were cultured and allotted to the blank, vehicle, and valproic acid (VPA)-treated groups: the VPA treated group received VPA exposure at concentrations of 2.0, 4.0 and 8.0 mmol/L. VPA might result in acetylation/deacetylation imbalances by inhibiting HDAC1-3 protein expression and total HDAC activity, leading to the down-regulation of mRNA and protein expression of Vangl2 and Scrib.
Substance Class Chemical
Created
by admin
on Sat Dec 16 05:15:57 GMT 2023
Edited
by admin
on Sat Dec 16 05:15:57 GMT 2023
Record UNII
Q400352CM2
Record Status Validated (UNII)
Record Version
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Name Type Language
VALPROATE MAGNESIUM
WHO-DD  
Systematic Name English
MAGNESIUM DIPROPYLACETATE
Systematic Name English
Valproate magnesium [WHO-DD]
Common Name English
MAGNESIUM VALPROATE
Systematic Name English
PENTANOIC ACID, 2-PROPYL-, MAGNESIUM SALT (2:1)
Common Name English
DIPROMAL
Brand Name English
Classification Tree Code System Code
NCI_THESAURUS C264
Created by admin on Sat Dec 16 05:15:57 GMT 2023 , Edited by admin on Sat Dec 16 05:15:57 GMT 2023
FDA ORPHAN DRUG 334411
Created by admin on Sat Dec 16 05:15:57 GMT 2023 , Edited by admin on Sat Dec 16 05:15:57 GMT 2023
NCI_THESAURUS C1946
Created by admin on Sat Dec 16 05:15:57 GMT 2023 , Edited by admin on Sat Dec 16 05:15:57 GMT 2023
Code System Code Type Description
CAS
62959-43-7
Created by admin on Sat Dec 16 05:15:57 GMT 2023 , Edited by admin on Sat Dec 16 05:15:57 GMT 2023
PRIMARY
SMS_ID
100000084784
Created by admin on Sat Dec 16 05:15:57 GMT 2023 , Edited by admin on Sat Dec 16 05:15:57 GMT 2023
PRIMARY
FDA UNII
Q400352CM2
Created by admin on Sat Dec 16 05:15:57 GMT 2023 , Edited by admin on Sat Dec 16 05:15:57 GMT 2023
PRIMARY
PUBCHEM
147515
Created by admin on Sat Dec 16 05:15:57 GMT 2023 , Edited by admin on Sat Dec 16 05:15:57 GMT 2023
PRIMARY
NCI_THESAURUS
C71156
Created by admin on Sat Dec 16 05:15:57 GMT 2023 , Edited by admin on Sat Dec 16 05:15:57 GMT 2023
PRIMARY
RXCUI
134422
Created by admin on Sat Dec 16 05:15:57 GMT 2023 , Edited by admin on Sat Dec 16 05:15:57 GMT 2023
PRIMARY RxNorm
EVMPD
SUB05073MIG
Created by admin on Sat Dec 16 05:15:57 GMT 2023 , Edited by admin on Sat Dec 16 05:15:57 GMT 2023
PRIMARY
ECHA (EC/EINECS)
263-770-9
Created by admin on Sat Dec 16 05:15:57 GMT 2023 , Edited by admin on Sat Dec 16 05:15:57 GMT 2023
PRIMARY
EPA CompTox
DTXSID0041062
Created by admin on Sat Dec 16 05:15:57 GMT 2023 , Edited by admin on Sat Dec 16 05:15:57 GMT 2023
PRIMARY
Related Record Type Details
PARENT -> SALT/SOLVATE
Related Record Type Details
ACTIVE MOIETY