Physiologically Based Pharmacokinetic Modeling of Oxcarbazepine to Characterize Its Disposition in Children with Obesity
09/2025
Journal Article
Authors:
Maglalang, P. D.;
Sinha, J.;
Helfer, V. E.;
Edginton, A.;
Zimmerman, K.;
Hornik, C. D.;
Muller, W. J.;
Rathore, M.;
Benjamin, D. K., Jr.;
Chen, J. Y.;
Anand, R.;
Gonzalez, D.;
Best Pharmaceuticals for Children Act - Pediatric Trials Network Steering, Committee
Volume:
66
Issue:
2
Journal:
J Clin Pharmacol
PMID:
41020741
URL:
https://www.ncbi.nlm.nih.gov/pubmed/41020741
Keywords:
Humans Child Adolescent *Oxcarbazepine/pharmacokinetics/administration & dosage/blood *Models, Biological Child, Preschool *Anticonvulsants/pharmacokinetics/administration & dosage/blood Male Female Young Adult *Pediatric Obesity/metabolism *Carbamazepine
*Carbamazepine/pharmacokinetics/analogs & derivatives children obesity oxcarbazepine pharmacokinetics physiologically based pharmacokinetic modeling
Abstract:
Oxcarbazepine (OXC) is a second-generation antiseizure medication, effective through its active metabolite, 10-mono-hydroxy derivative (MHD). OXC is used as adjunctive therapy for focal-onset and primary generalized tonic-clonic seizures, with recommended dosing based on age and body weight. This study uses physiologically based pharmacokinetic (PBPK) modeling and leverages pharmacokinetic (PK) data acquired from children enrolled in pragmatic trials to understand dosing and subsequent exposure requirements in children with obesity. Drug concentrations of OXC and MHD (n = 148 each) from children with (n = 31) and without (n = 10) obesity, aged 2-20 years, were collected from two clinical trials (NCT01431326 and NCT02993861) and used for external evaluation of a previously developed PBPK model of OXC using PK-Sim. We used a previously published virtual population that accounts for the obesity-related changes in physiology (e.g., liver size and glomerular filtration rate) in children for PK simulations in children with obesity. Model evaluation showed that >/=80% of MHD concentrations contributed by about two thirds of study subjects (26 out of 41) fell within the 90% prediction interval. The PBPK model showed that children with obesity had lower median (interquartile range) simulated weight-normalized clearance (0.060 L/h/kg [0.048-0.076 L/h/kg]) than children without obesity (0.067 L/h/kg [0.060-0.077 L/h/kg]). Simulations revealed that the recommended pediatric dosing regimen produced comparable MHD exposure between children with and without obesity at steady state, supporting its applicability regardless of obesity status. This PBPK-based dosing aligns with product label recommendations and demonstrates the potential of PBPK modeling for dosing other drugs in children with obesity.