Structure-pharmacokinetic relationships in a series of valpromide derivatives with antiepileptic activity

The following valpromide (VPD) derivatives were synthesized and their structure-pharmacokinetic relationships explored: ethylbutylacetamide (EBD), methylpentylacetamide (MPD), propylisopropylacetamide (PID), and propylallylacetamide (PAD). In addition, the anticonvulsant activity of these compounds...

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Bibliographic Details
Published in:Pharmaceutical research 1989-08, Vol.6 (8), p.683-689
Main Authors: ABDULLA HAJ-YEHIA, BIALER, M
Format: Article
Language:English
Subjects:
Acetamides - chemical synthesis
Acetamides - pharmacology
Allylisopropylacetamide - chemical synthesis
Allylisopropylacetamide - pharmacokinetics
Allylisopropylacetamide - pharmacology
Animals
Anticonvulsants - chemical synthesis
Anticonvulsants - pharmacokinetics
Anticonvulsants - pharmacology
Anticonvulsants. Antiepileptics. Antiparkinson agents
Biological and medical sciences
Dogs
Drug Stability
Female
Male
Medical sciences
Neuropharmacology
Pharmacology. Drug treatments
Protein Binding
Solubility
Structure-Activity Relationship
Valproic Acid - analogs & derivatives
Valproic Acid - pharmacology
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Summary:The following valpromide (VPD) derivatives were synthesized and their structure-pharmacokinetic relationships explored: ethylbutylacetamide (EBD), methylpentylacetamide (MPD), propylisopropylacetamide (PID), and propylallylacetamide (PAD). In addition, the anticonvulsant activity of these compounds was evaluated and compared to that of VPD, valnoctamide (VCD), and valproic acid (VPA). MPD, the least-branched compound had the largest clearance and shortest half-life of all the amides investigated and was the least active. All other amides had similar pharmacokinetic parameters. Unlike the other amides, PID and VCD did not metabolize to their respective homologous acids and were the most active compounds. Our study showed that these amides need an unsubstituted beta position in their aliphatic side chain in order to biotransform to their homologous acids. An amide which is not metabolized is more potent as an anticonvulsant than its biotransformed isomer. All amides were more active than their respective homologous acids. In this particular series of aliphatic amides, which were derived from short-branched fatty acids, the anticonvulsant activity was affected by the pharmacokinetics in general and by the biotransformation of the amide to its homologous acid in particular. This amide-acid biotransformation appeared to be dependent upon the chemical structure, especially upon the substitution at position beta of the molecule.
ISSN:0724-8741
1573-904X
DOI:10.1023/A:1015934321764