This subproject is one of many research subprojects utilizing the resources provided by a Center grant funded by NIH/NCRR. The subproject and investigator (PI) may have received primary funding from another NIH source, and thus could be represented in other CRISP entries. The institution listed is for the Center, which is not necessarily the institution for the investigator. The optimal treatment for Childhood Absence Epilepsy (CAE), a common pediatric epilepsy syndrome affecting 10-15% of all children with epilepsy, and the basis for the inter-individual variation in response to therapy, has not been defined. Commonly misperceived as a benign epilepsy syndrome, patients with CAE demonstrate variable response to therapy, exhibit cognitive deficits, and demonstrate long-term psychosocial difficulties. The objectives of this proposal are 1) to identify the anti-epileptic drug (AED) that produces and sustains the highest rate of seizure control coupled with the lowest incidence of treatment limiting toxicity for children with CAE, and 2) to determine the pharmacogenetic and non-heritable factors underlying the inter-individual variation in AED efficacy and toxicity. A randomized, double blind comparative trial of ethosuximide (ETX), lamotrigine (LTG) and valproate (VPA) as initial monotherapy will be performed in children with CAE utilizing freedom from failure rate as the primary endpoint. Twenty sites in the U.S. will enroll 473 children, 2- 13 years of age, over a 3-year period. Treatment success will be defined as a composite of seizure control and short and long-term tolerability. Each AED's impact on cognition (especially attention), behavior, and quality of life will be studied. Each patient's epilepsy syndrome will be extensively phenotyped with video EEGs. Individual systemic drug exposures, determined using a population pharmacokinetic (pK) approach, will define the impact of interpatient variability in drug disposition on AED efficacy and toxicity, and will be utilized in pharmacogenetic (pG) correlative studies of select drug metabolizing enzymes. The role of polymorphic variation in the genes coding for the a1G, a1H, a1I subunits of the T type calcium channels in response to therapy will be investigated. Factors potentially predictive for the most common treatment limitations of each AED will be studied, including the pG, pK and clinical profiles of patients developing LTG associated rash, VPA induced weight gain or evidence of impaired neurocognitive skills (potential limitation of all AEDs). This study will determine the AED that provides for the greatest likelihood of seizure control coupled with the best short and long term tolerability. By comprehensively defining the phenotypic spectrum of absence seizures along with pG and non-heritable factors that underlie interpatient variability in AED response, this proposal will form the foundation of a pharmacologically rational approach to syndrome based AED therapy. Knowledge gained by this study will lead to individualized treatment for children with CAE that can be generalized to other pediatric and adult seizure disorders.
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