Investigating the effect of autoinduction in cynomolgus monkeys of a novel anticancer MDM2 antagonist, idasanutlin, and relevance to humans.

1. Idasanutlin (RG7388) is a potent p53-MDM2 antagonist currently in clinical development for treatment of cancer. The purpose of the present studies was to investigate the cause of marked decrease in plasma exposure after repeated oral administration of RG7388 in monkeys and whether the autoinduction observed in monkeys is relevant to humans. 2. In monkey liver and intestinal microsomes collected after repeated oral administration of RG7388 to monkeys, significantly increased activities of homologue CYP3A8 were observed (ex vivo). Investigation using a physiologically based pharmacokinetic (PBPK) model suggested that the loss of exposure was primarily due to induction of metabolism in the gut of monkeys. 3. Studies in monkey and human primary hepatocytes showed that CYP3A induction by RG7388 only occurred in monkey hepatocytes but not in human hepatocytes, which suggests the observed CYP3A induction is monkey specific. 4. The human PK data obtained from the first cohorts confirmed the lack of relevant induction as predicted by the human hepatocytes and the PBPK modelling based on no induction in humans.

Distribution, Metabolism, and Excretion of Cenobamate in Adult, Fetal, Neonatal, and Lactating Rats.

BACKGROUND AND OBJECTIVE: Cenobamate is an antiseizure medication (ASM) approved for treatment of focal epilepsy in adults. The objective of this study was to characterize the distribution, metabolism, and excretion of cenobamate in adult and pre- and postnatal rats, including pregnant and lactating females and nursing pups. METHODS: Distribution, metabolic, and excretion profiles were determined for 14C-labeled and unlabeled cenobamate using liquid scintillation counting, radiochromatography, LCMS, and LCMS/MS after oral or intravenous (IV) administration. RESULTS: Distribution of 14C-cenobamate-related material in adult male rats was widespread throughout the body, with nearly 1:1 tissue-to-plasma ratios observed for most tissues, including brain. Cenobamate administered to pregnant females was also transferred across the placental barrier into amniotic fluid and fetal plasma. Following administration to lactating F0 females, cenobamate was detected in breast milk and in plasma of nursing pups. 14C-cenobamate administered to adult male rats as a single oral dose was extensively metabolized with nine metabolites identified in urine and feces, including a principal dihydrodiol metabolite. Cenobamate was the principal drug-related material in rat plasma. Following a single dose of 14C-cenobamate to male and female rats, radioactivity was excreted equally into urine and feces, with mass balance achieved by 48 h postdose. CONCLUSIONS: Distribution of cenobamate was widespread into many rat tissues, including brain, amniotic fluid, fetal plasma, breast milk, and breastfeeding rat pups. These distribution findings, along with the results of the metabolism and excretion studies, may help inform treatment decisions for patients with epilepsy being treated with cenobamate, including pregnant or nursing mothers.

Anticonvulsant effects of cenobamate in chemically and electrically induced seizure models in rodents.

Background: Cenobamate is an antiseizure medication used to treat partial-onset (focal) seizures. It is a molecule with one chiral center and a unique dual mechanism of action: enhancement of fast and slow inactivation of sodium channels with preferential inhibition of the persistent current and positive allosteric modulation of GABAA receptor-mediated ion channels. Aims/Methods: Anticonvulsant effects of cenobamate (YKP3089; R-enantiomer), YKP3090 (S-enantiomer), and YKP1983 (racemate) were evaluated in chemically and electrically induced focal and generalized seizure models in rodents. The Genetic Absence Epilepsy Rat from Strasbourg (GAERS) model examined the effect of cenobamate on spike-wave seizures. Motor coordination was assessed with rotarod tests and minimal motor impairment exams. Results: Early in development, cenobamate was found to have activity in focal and generalized seizure models in animals and was selected for continued development. Cenobamate prevented seizures in a dose-dependent manner, prevented seizure spread, and increased seizure threshold without potentiating seizure initiation or the development of tolerance to its anticonvulsant effects. In contrast, YKP3090 and YKP1983 were only effective against generalized tonic-clonic seizures. Cenobamate also protected mice from 6 Hz psychomotor-induced seizures. Cenobamate showed significant dose-dependent reductions in the number and cumulative duration of spike-and-wave discharges in the GAERS model. Discussion: Cenobamate showed efficacy or efficacy signals in all animal models of epilepsy tested with a favorable risk-versus-benefit ratio, supporting its clinical use in the treatment of partial-onset (focal) seizures in adults and warranting further clinical research in generalized seizures and absence seizures.

Effect of cenobamate on the single-dose pharmacokinetics of multiple cytochrome P450 probes using a cocktail approach in healthy subjects.

This study was designed to evaluate the effects of cenobamate, an antiseizure medication for focal seizures, on the pharmacokinetics of cytochrome P450 probes (bupropion, CYP2B6; midazolam, CYP3A4/5; warfarin, CYP2C9; and omeprazole, CYP2C19) in healthy subjects. Probes were administered alone on days 1 (bupropion) and 7 (midazolam/warfarin/omeprazole), and with cenobamate 100 mg/day on day 69 (midazolam) and cenobamate 200 mg/day on days 99 (bupropion) and 105 (midazolam/warfarin/omeprazole). No significant interaction was concluded if 90% confidence intervals (CIs) for geometric mean ratios (GMRs) for area under the curve (AUC) and maximum concentration of CYP substrates and/or their metabolites were within the no-effect interval (0.80-1.25). When co-administered with cenobamate 100 mg/day, AUC from time of administration up to the time of the last quantifiable concentration (AUC0-last ) GMR (90% CIs) for midazolam was 0.734 (0.647-0.832). When co-administered with cenobamate 200 mg/day, AUC0-last GMRs (90% CI) for midazolam, bupropion, S-warfarin, and omeprazole were 0.277 (0.238-0.323), 0.615 (0.522-0.724), 1.14 (1.10-1.18), and 2.07 (1.44-2.98), respectively. Co-administration of cenobamate with midazolam and bupropion probes led to values that were outside and below the no effect boundary, indicating that cenobamate induces the CYP3A4/5 and CYP2B6 enzymes. Co-administration of cenobamate led to omeprazole values which were outside and above the no-effect boundary, but with high variability, suggesting that cenobamate may moderately inhibit CYP2C19 activity. No effect on CYP2C9 was observed with the cenobamate and warfarin combination. Co-administration of cenobamate with these probes drugs was well-tolerated. In this study, 200 mg/day cenobamate moderately induced CYP3A4/5 (dose-dependently; 100 mg/day was a weak inducer), was a weak inducer of CYP2B6, moderately inhibited CYP2C19, and had a negligible effect on CYP2C9.

Positive allosteric modulation of GABAA receptors by a novel antiepileptic drug cenobamate.

Cenobamate is a novel antiepileptic drug under investigation for use in patients with focal (partial-onset) seizures. To understand its potential molecular mechanism of action, the effects of cenobamate on GABAA-mediated currents and GABAA receptors in rodent hippocampal neurons were examined. Cenobamate potentiated GABA-induced currents (IGABA) in acutely isolated CA3 pyramidal cells in a concentration-dependent manner (EC50, 164 µM), which was not affected by flumazenil, a benzodiazepine receptor antagonist. Cenobamate enhanced tonic GABAA currents (Itonic), which is defined as a holding current shift by the GABAA receptor antagonist bicuculline (EC50, 36.63 µM). At therapeutically relevant concentrations, cenobamate induced minimal changes in the frequency, amplitudes, and decay time of spontaneous inhibitory postsynaptic currents in the CA1 neurons. Flumazenil failed to affect cenobamate-potentiated Itonic and Iphasic in CA1 neurons. Cenobamate showed positive allosteric modulation of GABA-induced IGABA mediated by GABAA receptors. This effect was similar for all tested hGABAA receptors containing six different alpha subunits (α1ß2γ2 or α2-6ß3γ2), with EC50 values ranging from 42 to 194 µM. Cenobamate did not displace the binding of flunitrazepam, a benzodiazepine derivative, or flumazenil to GABAA receptors. The results showed that cenobamate, a novel antiepileptic drug, acts as a positive allosteric modulator of high-affinity GABAA receptors, activated by GABA at a site independent of the benzodiazepine binding site and efficiently enhances Itonic inhibition in hippocampal neurons, which could be an underlying molecular mechanism stabilizing neural circuits of the epileptic hippocampus.