Link to Problems for Discussion
Sodium Valproate
DRUGS INCLUDED IN THIS CATEGORY
In Australia, 100 mg tablets of sodium valproate are normal release while all other strengths are enteric controlled release formulations. Divalproex sodium is converted to valproate in the small intestine and this is responsible for delayed peak concentrations.
OVERVIEW
Sodium valproate is an anti-epileptic medication that is also used bipolar & affective disorders with a consequent increase in presentations with self-poisoning. In the majority of patients the clinical course is benign and manifest as sedation only (in spite of numerous case reports of severe toxicity). In general, it is less toxic in overdose than either phenytoin or carbamazepine. Severe toxicity is unlikely to occur with doses less than 400 mg/kg, and almost never with doses < 200 mg/kg. However, in very large ingestions ingestions (> 400 mg/kg) significant clinical toxicity (metabolic acidosis, bone marrow failure, unconsciousness and circulatory collapse) can occur and death is a significant risk with massive ingestions of >1,000 mg/kg. Serious complications are more likely at concentrations > 5,900 micromol/L (> 850 mg/L) and death is a significant risk at concentrations > 6,900 micromol/L (> 1,000 mg/L). Asymptomatic thrombocytopenia & leukopenia can occur.
MECHANISM OF TOXIC EFFECTS
Valproate is a drug with anticonvulsant activity against a wide range of seizure types and appears to be well tolerated at therapeutic doses. In therapeutic use valproate's action may be related to altered turnover of GABA and actions on voltage sensitive sodium channels. The mechanisms involved in toxicity are unclear. It appears to have teratogenic effects in therapeutic doses.
KINETICS IN OVERDOSE
Absorption
Peak plasma concentrations are achieved 1-2 h after standard release preparations. Peak concentrations were delayed > 10 hours in 15% of patients in one series. Bioavailability is high (~100%).
Distribution
In low therapeutic concentrations there is 90% protein binding (albumin). Protein binding saturates at 350 micromol/L (50 mg/L) so at concentrations greater than this the free fraction of valproate will increase. The apparent volume of distribution is low (0.13 to 0.23 L/kg).
Metabolism - Elimination
Hepatic conjugation to glucuronides, some metabolites probably contribute to the therapeutic effects. 1-3% of the ingested dose is excreted unchanged in the urine. The plasma half-life varies between 9 and 21 h with a mean of 12 - 13 h.
CLINICAL EFFECTS
Central nervous system effects
Patients are often described as lethargic, 2 - 3% develop coma. Seizures & cerebral oedema are occasionally reported in very large overdoses (> 400 mg/kg).
Cardiac effects
Tachycardia (25 - 30%) and hypotension (2 - 3%) are the most common manifestations and are probably secondary to vasodilatation or volume depletion. QT prolongation occurs and cardiac arrest has occurred in very large poisonings (> 400 mg/kg).
Haematological effects
Thrombocytopenia (5 - 8%) and leukopenia (1 - 3%) are concentration related transient events which are normally clinically insignificant. In massive overdose, bone marrow failure can occasionally occur.
Other effects
Nausea and vomiting (10 - 15%). Metabolic acidosis can occur in very large or massive overdoses. Cholestatic hepatitis & pancreatitis appears to be an idiosyncratic complication (1/10,000) occurring rarely in overdose & therapeutically. In therapeutic use, severe liver toxicity, occasionally with a fatal outcome, is extremely rare. It appears to be caused by an idiosyncratic reaction and usually occurs during the first 6 months of valproate therapy. It may be related to metabolism to hepatotoxic metabolites occurring in some individuals and is not usually a problem in overdose.
INVESTIGATIONS
Biochemistry
FBC, electrolytes, and acid base estimation should be performed in clinically severe patients.
Blood concentrations
Conversion factor
- mg/L x 6.93 = micromol/L
- micromol/L x 0.144 = mg/L
Serum sodium valproate concentrations (therapeutic range 350 - 700 micromol/L, 50 - 100 mg/L) confirm ingestion but probably do not give a great deal of additional information to the clinical assessment. Very high concentrations > 5,900 micromol/L (> 850 mg/L) are associated with more severe toxicity and should prompt consideration of extracorporeal removal. Death is a significant risk at concentrations > 6,930 micromol/L (> 1,000 mg/L) and extracorporeal elimination may be life-saving. For very large (> 400 mg/kg) and particularly for massive ingestions (> 1,000 mg/kg) serum valproate should be measured frequently (2nd hourly) as concentrations can rise precipitously. Patients with severe clinical toxicity and a concentration of < 5,900 micromol/L (< 850 mg/L) should prompt a search for other contributing causes.
ECG
ECG should be done at baseline and repeated in patients with increasing concentrations or progressive clinical toxicity.
Other investigations
Moderate elevations in blood ammonia concentrations are fairly common during treatment with valproic acid and can occur in overdose. The clinical importance of the hyperammonaemia is unclear and outcome is not predicted by its presence.
DIFFERENTIAL DIAGNOSIS
The differential diagnosis should be directed towards other medications to which the patient may have access. Depending on the underlying diagnosis this includes other anticonvulsants and psychiatric medication.
TREATMENT
Supportive
The treatment is primarily supportive. Adequate IV fluids are need to combat vasodilatation.
GI decontamination
Single dose activated charcoal is the recommended gastrointestinal decontamination procedure for patients presenting within 1- 2 hours of overdose. Whole bowel irrigation should be considered for controlled release preparations of > 200 mg/kg and is probably justified in ingestions > 400 mg/kg.
Treatment of specific complications
Seizures
Seizures should be treated with intravenous benzodiazepines (adults: diazepam 5 to 10 mg, repeated if necessary every 15 to 20 minutes). Seizures refractory to diazepam may require phenobarbitone (15 mg/kg).
Antidotes
L-carnitine
L-carnitine has been used in a number of case reports. There is evidence it reduces ammonia concentrations in acute valproate overdose but the correlation between reducing ammonia concentrations and improving outcome is lacking. A suggested dose is 100 mg/kg bolus, then 50 mg/kg/hr
Elimination enhancement
High Flux Haemodialysis and haemoperfusion enhance elimination. One recent case report and review of extracorporeal techniques in valproate poisoning suggests that haemodialysis is more effective than haemoperfusion, although this may be limited by the circulatory collapse that can occur. The recent case series of Spiller et al suggests that haemodialysis should not be used for cases with peak levels < 5,900 micromol/L (< 850 mg/L) because all patients in that series with concentrations< 5.900 micromol/L recovered with supportive care.
Concentrations > 6,900 micromol/L (> 1,000 mg/L) are potentially life-threatening and extracorporeal removal may be life-saving.
LATE COMPLICATIONS, PROGNOSIS - FOLLOW UP
No routine follow-up is required.
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