Valproate metabolism during valproate-associated hepatotoxicity in a surviving adult patient.

The plasma profiles of valproate (VPA), its beta-oxidation metabolites E-2-en-VPA and 3-oxo-VPA and its terminal desaturation metabolite 4-en-VPA, have been measured in a patient receiving NaVPA 1000 mg twice per day from early in the course of serious hepatotoxicity and for 2 weeks after the drug was stopped. Concurrent profiles of liver, renal and haematological function parameters were available. Relative to concurrent plasma VPA concentrations, E-2-en-VPA concentrations were not different to those of the VPA-treated epileptic population at any stage of the illness, whereas 3-oxo-VPA concentrations relative to concurrent VPA concentrations were abnormally high early in the toxicity, abnormally low at its peak (3-5 days later), and comfortably within normal limits for the treated epileptic population late in the recovery phase (9-13 days from the onset). When measurable, plasma 4-en-VPA concentrations were not elevated. The elimination half-life of VPA during the recovery phase was 100 h, which is some 6-12 times greater than values reported for this parameter in normal patients. These data clearly define, in this patient, a link between idiosyncratic VPA-associated hepatotoxicity at its onset and peak and the later stages of VPA beta-oxidation. Whether the beta-oxidation abnormalities are causative or a consequence of an as yet undefined defect is unknown. In this patient, 4-en-VPA was unlikely to have been involved in the pathogenesis of the toxicity.

Steady-state dispositions of valproate and diflunisal alone and coadministered to healthy volunteers.

OBJECTIVE: The effects of coadministration of the non-steroidal anti-inflammatory drug diflunisal (DF) on glucuronidation and beta-oxidation of the antiepileptic agent valproic acid (VPA), and of VPA on DF glucuronidation, were studied in human volunteers. METHODS: Seven healthy male volunteers received sodium valproate (NaVPA, 200 mg) orally twice daily for 7 days, after which all drug intake ceased for 1 month. The volunteers then took DF (250 mg) orally twice daily for 7 days. Both drugs were then taken (at the same doses as previously) twice daily for 7 days. On day 7 of each dosing phase, serial blood samples and all urine passed over the 12-h inter-dosing interval were collected. VPA, DF and selected metabolites were analysed using validated methods. Statistical comparisons of pharmacokinetic parameters were made using paired Student's t-tests. RESULTS: Mean plasma concentrations of total VPA were lower and apparent plasma clearances significantly higher during DF coadministration. This was associated with a significant 20% increase in the unbound fraction of VPA (from 6.6+/-1.3% to 7.9+/-1.8%). The apparent clearance of unbound VPA was not different. There was no evidence of any significant effect of DF coadministration on VPA metabolism: urinary recoveries of and formation clearances to urinary VPA-glucuronide, E-2-en-VPA, 3-oxo-VPA and 4-en-VPA were not significantly altered. However, there was a highly significant 35% increase in the area under the plasma concentration-time curve from 0-12 h (AUC0-12h) of 3-oxo-VPA and its renal clearance was lower, though not significantly so. VPA coadministration had no effect on DF pharmacokinetics or formation clearances of DF to its acyl glucuronide (DAG), phenolic glucuronide (DPG) or sulfate (DS) conjugates. However, plasma AUC0-12h values of the glucuronides were significantly lower and their renal clearances higher (though significantly so only in the case of DPG) during VPA coadministration. CONCLUSIONS: Steady-state coadministration of VPA and DF leads to a significant displacement of VPA from plasma protein binding sites. There was no evidence of competition for glucuronidation capacity or other metabolic interactions. Rather, the interactions detected appeared to be renal in nature, with renal clearance of 3-oxo-VPA being reduced by DF coadministration, and renal clearance of DPG and perhaps DAG being increased by VPA coadministration.

Urinary excretion of valproate metabolites in children and adolescents.

The objective of this communication is to describe the changes in the metabolic profile of valproic acid (VPA) from early to late childhood and adolescence. A cross-sectional study of 12 children and adolescents attending a neurological outpatients department, who were medicated with VPA, was carried out. The proportions of daily dose excreted as VPA-glucuronide, 3-oxo-VPA and 4-OH-VPA were calculated by relating 24-h recovery of these metabolites from urine to daily VPA dose. VPA, 3-oxo-VPA and 2-en-valproic acid (2-en-VPA) were measured in trough serum samples. VPA and its metabolites were measured using a capillary gas chromatograpy method. The proportion of daily dose recovered as VPA-glucuronide in children 10 years and younger was smaller than in older children (p<0.05). There were no differences between age groups in the recovery of the other measured metabolites. Lamotrigine (LTG) comedication was also associated with a higher proportion of VPA dose recovered as glucuronide (p<0.01). LTG comedication had a stronger association with a higher proportion of dose being recovered as VPA-glucuronide on multivariate analysis than did the age group (p=0.001 versus p<0.05). In conclusion, older children and adolescents, when compared with younger children, and those comedicated with LTG excrete a higher proportion of VPA dose as VPA-glucuronide.

Effect of naproxen co-administration on valproate disposition.

The effects of co-administration of the antiepileptic agent valproic acid (VPA) and the non-steroidal anti-inflammatory drug naproxen (NAP) on their relative dispositions (particularly with respect to glucuronidation) were investigated in human volunteers. Seven healthy males received each drug alone and then in combination (orally twice daily for seven days, 500 mg sodium VPA, 500 mg NAP). On day 7 of each dosing phase, serial plasma and 24 h urine samples were collected for analysis. Co-administration of NAP resulted in significant increases (about 20%, p<0.05) in the apparent plasma clearance of total VPA and in the unbound fraction of VPA in plasma, with the apparent plasma clearance of unbound VPA being unchanged. There were associated increases in the formation clearances to urinary VPA-glucuronide and 3-oxo-VPA, though these were relatively greater for the glucuronidation pathway (and remained significant when formation clearances were calculated using the unbound fraction of drug in plasma). The data thus point to a shift towards glucuronidation as a result of the NAP-induced increase in the unbound fraction of VPA in plasma. By contrast, VPA co-administration caused a decrease (of about 10%, p<0.05) in the apparent plasma clearance of total NAP. Taken in hand with in vitro results showing a VPA-induced displacement (of about 40%) of NAP from plasma protein binding sites, the data strongly support a role for diminished glucuronidation of NAP and its desmethyl metabolite in the presence of co-administered VPA.