Evaluating the efficacy of prototype antiseizure drugs using a preclinical pharmacokinetic approach

Objective Pharmacokinetics (PK) of a drug drive its exposure, efficacy, and tolerability. A thorough preclinical PK assessment of antiseizure medications (ASMs) is therefore essential to evaluate the clinical potential. We tested protection against evoked seizures of prototype ASMs in conjunction with analysis of plasma and brain PK as a proof-of-principle study to enhance our understanding of drug efficacy and duration of action using rodent seizure models. Methods In vivo seizure protection assays were performed in adult male CF-1 mice and Sprague-Dawley rats. Clobazam (CLB), N-desmethylclobzam (NCLB), carbamazepine (CBZ), carbamazepine-10,11-epoxide (CBZE), valproic acid (VPA), and levetiracetam (LEV) concentrations were quantified in plasma and brain using liquid chromatography-tandem mass spectrometry. Mean concentrations of each analyte were calculated and used to determine PK parameters via non-compartmental analysis in Phoenix WinNonLin. Results NCLB concentrations were approximately 10-fold greater than CLB in mice. The antiseizure profile of CLB was partially sustained by NCLB in mice. CLB concentrations were lower in rats than in mice. CBZE plasma exposures were approximately 70% of CBZ in both mice and rats, likely contributing to the antiseizure effect of CBZ. VPA showed a relatively short half-life in both mice and rats, which correlated with a sharp decline in efficacy. LEV had a prolonged brain and plasma half-life, associated with a prolonged duration of action in mice. Significance The study demonstrates the utility of PK analyses for understanding the seizure protection time-course in mice and rats. The data indicate that distinct PK profiles of ASMs between mice and rats likely drive differences in drug efficacy between rodent models. Key Points There exist potential contributions of active metabolites to the efficacy of some ASMs. The utility of preclinical PK assessment of ASM is critical to guide our insight into a drug efficacy profile and provide a framework for subchronic dosing strategies. Species-specific variations in PK profiles of ASMs in rodent models of epilepsy may underpin the differences in antiseizure effect in these models. Pre-clinical drug screening of ASMs should include a (sub)chronic dosing paradigm to better mimic the dosing regimen in the clinic.

[1]  Weihong Lin,et al.  Treatment Outcome and Risk Factors of Adult Newly Diagnosed Epilepsy: A Prospective Hospital-Based Study in Northeast China , 2021, Frontiers in Neurology.

[2]  F. Główka,et al.  New Methods Used in Pharmacokinetics and Therapeutic Monitoring of the First and Newer Generations of Antiepileptic Drugs (AEDs) , 2020, Molecules.

[3]  M. Barker-Haliski,et al.  Antiseizure drug efficacy and tolerability in established and novel drug discovery seizure models in outbred vs inbred mice , 2020, Epilepsia.

[4]  Chasity M. Shelton,et al.  Persistent Hypersomnolence Following Clobazam in a Child With Epilepsy and Undiagnosed CYP2C19 Polymorphism. , 2020, The journal of pediatric pharmacology and therapeutics : JPPT : the official journal of PPAG.

[5]  B. Steinhoff,et al.  Levetiracetam and brivaracetam: a review of evidence from clinical trials and clinical experience , 2019, Therapeutic advances in neurological disorders.

[6]  D. Tolbert,et al.  A Comprehensive Overview of the Clinical Pharmacokinetics of Clobazam , 2018, Journal of clinical pharmacology.

[7]  Ming-Xia Song,et al.  Synthesis and Evaluation of the Anticonvulsant Activities of 4-(2-(Alkylthio)benzo[d]oxazol-5-yl)-2,4-dihydro-3H-1,2,4-triazol-3-ones , 2018, Molecules.

[8]  Patrick Kwan,et al.  Treatment Outcomes in Patients With Newly Diagnosed Epilepsy Treated With Established and New Antiepileptic Drugs: A 30-Year Longitudinal Cohort Study , 2017, JAMA neurology.

[9]  V. Castagné,et al.  Efficacy of anticonvulsant substances in the 6Hz seizure test: Comparison of two rodent species , 2017, Epilepsy Research.

[10]  K. Thomson,et al.  Development and pharmacologic characterization of the rat 6 Hz model of partial seizures , 2017, Epilepsia.

[11]  S. B. Amor,et al.  The relationship between pharmacokinetic parameters of carbamazepine and therapeutic response in epileptic patients , 2016, Archives of medical science : AMS.

[12]  W. Löscher The Search for New Screening Models of Pharmacoresistant Epilepsy: Is Induction of Acute Seizures in Epileptic Rodents a Suitable Approach? , 2016, Neurochemical Research.

[13]  K. Oniki,et al.  Determination of the Optimal Concentration of Valproic Acid in Patients with Epilepsy: A Population Pharmacokinetic-Pharmacodynamic Analysis , 2015, PloS one.

[14]  D. Mager,et al.  Interspecies Pharmacokinetic Modeling of Subcutaneous Absorption of Rituximab in Mice and Rats , 2014, Pharmaceutical Research.

[15]  R. Altman,et al.  Valproic acid pathway: pharmacokinetics and pharmacodynamics , 2013, Pharmacogenetics and genomics.

[16]  Wolfgang Löscher,et al.  Critical review of current animal models of seizures and epilepsy used in the discovery and development of new antiepileptic drugs , 2011, Seizure.

[17]  K. Wilcox,et al.  Discovery of antiepileptic drugs , 2011, Neurotherapeutics.

[18]  H. White,et al.  Comparative anticonvulsant efficacy in the corneal kindled mouse model of partial epilepsy: Correlation with other seizure and epilepsy models , 2010, Epilepsy Research.

[19]  A. Wahab Difficulties in Treatment and Management of Epilepsy and Challenges in New Drug Development , 2010, Pharmaceuticals.

[20]  S. Kadam,et al.  The pharmacokinetics of commonly used antiepileptic drugs in immature CD1 mice , 2010, Neuroreport.

[21]  E. Spack,et al.  The basics of preclinical drug development for neurodegenerative disease indications , 2009, BMC neurology.

[22]  L. Mello,et al.  Assessment of seizure susceptibility in pilocarpine epileptic and nonepileptic Wistar rats and of seizure reinduction with pentylenetetrazole and electroshock models , 2009, Epilepsia.

[23]  W. Löscher The Pharmacokinetics of Antiepileptic Drugs in Rats: Consequences for Maintaining Effective Drug Levels during Prolonged Drug Administration in Rat Models of Epilepsy , 2007, Epilepsia.

[24]  Michael A. Rogawski,et al.  Diverse mechanisms of antiepileptic drugs in the development pipeline , 2006, Epilepsy Research.

[25]  R. Twyman,et al.  Correlation analysis between anticonvulsant ED50 values of antiepileptic drugs in mice and rats and their therapeutic doses and plasma levels , 2004, Epilepsy & Behavior.

[26]  J. Treluyer,et al.  In vitro characterization of clobazam metabolism by recombinant cytochrome P450 enzymes: importance of CYP2C19. , 2004, Drug metabolism and disposition: the biological fate of chemicals.

[27]  R. Remmel,et al.  Dose-Dependent Pharmacokinetics of Carbamazepine in Rats: Determination of the Formation Clearance of Carbamazepine-10,11-epoxide , 1990, Pharmaceutical Research.

[28]  P. Patsalos The pharmacokinetic characteristics of levetiracetam. , 2003, Methods and findings in experimental and clinical pharmacology.

[29]  Wolfgang Löscher,et al.  Animal models of epilepsy for the development of antiepileptogenic and disease-modifying drugs. A comparison of the pharmacology of kindling and post-status epilepticus models of temporal lobe epilepsy , 2002, Epilepsy Research.

[30]  M. Whittington,et al.  A comparison of the efficacy of carbamazepine and the novel anti‐epileptic drug levetiracetam in the tetanus toxin model of focal complex partial epilepsy , 2002, British journal of pharmacology.

[31]  M. Barton,et al.  Pharmacological characterization of the 6 Hz psychomotor seizure model of partial epilepsy , 2001, Epilepsy Research.

[32]  J. Potter,et al.  Carbamazepine-10,11-epoxide in therapeutic drug monitoring. , 1998, Therapeutic drug monitoring.

[33]  W. Löscher,et al.  Intravenous valproate: onset and duration of anticonvulsant activity against a series of electroconvulsions in comparison with diazepam and phenytoin , 1992, Epilepsy Research.

[34]  G. I. Rozova,et al.  Autoinduction and steady-state pharmacokinetics of carbamazepine and its major metabolites. , 1992, British journal of clinical pharmacology.

[35]  D. Shen,et al.  Comparative Pharmacodynamics and Brain Distribution of E‐δ2‐Valproate and Valproate in Rats , 1991 .

[36]  W. Löscher,et al.  Amygdala-kindling as a model for chronic efficacy studies on antiepileptic drugs: Experiments with carbamazepine , 1989, Neuropharmacology.

[37]  T. Pullar,et al.  N-desmethylclobazam: a possible alternative to clobazam in the treatment of refractory epilepsy? , 1987, British journal of clinical pharmacology.

[38]  T. Tomson,et al.  Clinical Pharmacokinetics and Pharmacological Effects of Carbamazepine and Carbamazepine-10,11-Epoxide , 1986 .

[39]  M Lindsay,et al.  Epilepsy in adults. , 1983, Nursing.

[40]  T. Tomson,et al.  Single‐dose kinetics and metabolism of carbamazepine‐10,11‐epoxide , 1983, Clinical pharmacology and therapeutics.

[41]  S. Garattini,et al.  Species differences in clobazam metabolism and antileptazol effect , 1980, The Journal of pharmacy and pharmacology.

[42]  T. Karasawa,et al.  Pharmacokinetic and pharmacodynamic tolerance of a new anticonvulsant agent (3-sulfamoylmethyl-1,2-benzisoxazole) compared to phenobarbital, diphenylhydantoin and carbamazepine in rats. , 1979, Archives internationales de pharmacodynamie et de therapie.

[43]  F. Cavagna,et al.  Kinetics and metabolism of clobazam in animals and man. , 1979, British journal of clinical pharmacology.

[44]  W. Löscher Rapid Determination of Valproate Sodium in Serum by Gas‐Liquid Chromatography , 1977, Epilepsia.

[45]  S. Garattini,et al.  Carbamazepine pharmacokinetics in young, adult and pregnant rats. Relation to pharmacological effects. , 1976, Archives internationales de pharmacodynamie et de therapie.

[46]  Grant R. Wilkinson,et al.  A physiological approach to hepatic drug clearance , 1975 .

[47]  L S Higgins,et al.  THE DENSITY OF TISSUES IN AND ABOUT THE HEAD , 1970, Acta neurologica Scandinavica.

[48]  F. M. Wadley Probit Analysis: a Statistical Treatment of the Sigmoid Response Curve , 1952 .