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    Bulletin of problems biology and medicine / Issue 2 Part 1 (150), 2019 / THE EFFECT OF ANTIEPILEPTIC DRUGS ON CONVULSIV ACTIVITY ANDER CONDITIONS OF CORNEAL KINDLING IN MICE AND MODULATION OF THE ACTIVITY OF CYTOCHROME P450 ENZYMES

    Boiko Y. A., Tantsura Y. A.

    THE EFFECT OF ANTIEPILEPTIC DRUGS ON CONVULSIV ACTIVITY ANDER CONDITIONS OF CORNEAL KINDLING IN MICE AND MODULATION OF THE ACTIVITY OF CYTOCHROME P450 ENZYMES

    About the author:

    Boiko Y. A., Tantsura Y. A.

    Heading:

    BIOLOGY

    Type of article:

    Scentific article

    Annotation:

    Pharmacoresistant epilepsy refers to forms of epilepsy that are poorly therapeutic and its pathogenetic mechanisms are not well understood. The purpose of this work was to study the pharmacodynamics of anti-epileptic drugs in the conditions of the established Kindling syndrome against the background of the prior introduction of anticonvulsant substances acting on the cytochrome P450 system. The work was carried out on white outbred mice-males. Kindling syndrome was caused by repeated corneal electrostimulation. Simultaneously with the formation of Kindling syndrome, intragastric administration of carbamazepine and suliam was performed as an activator and inhibitor of the cytochrome P450 system, respectively. After the development of persistent convulsive syndrome with an intensity of at least 5 points in all animals, the study of the anticonvulsant activity of the following drugs – sultiam, levetiracetam, carbamazepine, valproate, lamotrigine, retigabine – was conducted. Also investigated the behavioral activity of experimental animals in the test «Open field» and «Black and white camera». We have shown that the preliminary administration of carbamazepine for 17 days seriously reduces its anticonvulsant activity upon subsequent administration. Preliminary administration of suliam, on the contrary, increased the anticonvulsant effect of subsequent administration of carbamazepine (2.7-2.8 points). The introduction of lamotrigine gave a significant anticonvulsant effect in the group of stuliam, in the group of carbamazepine a significant anticonvulsant effect was absent. The introduction of stuliam caused a significant anticonvulsant effect in all groups, however, it was the greatest in the group previously treated with slimeam (1.5-1.77 points). The pharmacodynamics of valproate was similar to pharmacodynamic sultiam. For levetiracetam and retigabine, nontargeted results were obtained, which are likely to be related to the pharmacokinetics of these drugs. The effect on behavioral activity was provided by stuliam and lamotrigine (a decrease in horizontal and vertical motor activity), as well as retigabine (an increase in research activity). Preliminary administration of carbamazepine, which is an inducer of the cytochrome P450 system, leads to a weakening of the anticonvulsant activity of drugs metabolized by this enzyme system (carbamazepine, valproate) and the formation of pharmacological resistance to the action of these drugs. Also for the first time, a decrease in the anticonvulsant activity of lamotrigine was shown under conditions of prior administration of carbamazepine. Sultiam, which suppresses the activity of the cytochrome P450 system, on the contrary, increased the anticonvulsant effect of lamotrigine. The obtained data are important for understanding the mechanisms of interaction of antiepileptic drugs under combined use

    Tags:

    pharmacoresistant epilepsy, corneal kindling, sultiam, carbamazepine.

    Bibliography:

    1. Kwan P, Brodie MJ. Epilepsy after the first drug fails: substitution or add-on? Seizure. 2000;9(7):464-8.
    2.  Tang F, Hartz A, Bauer B. Drug-resistant epilepsy: multiple hypotheses, few answers. Frontiers in neurology. 2017;8:301.
    3.  Löscher W, Potschka H. Role of multidrug transporters in pharmacoresistance to antiepileptic drugs J. Pharm. Exp. Ther. 2002;301(1):7-14.
    4. Bazilevich SN. Obektivnye faktory otnositelnoj i vozmozhnye prichiny istinnoj farmakorezistentnosti u bolnyh epilepsiej. Vestnik rossijskoj voenno-medicinskoj akademii. 2009;2:118-23. [in Russian].
    5. Nogueira MH, Yasuda CL, Coan AC, Kanner AM, Cendes F. Concurrent mood and anxiety disorders are associated with pharmacoresistant seizures in patients with MTLE. Epilepsia. 2017;58(7):1268-76.
    6. Begley CE, Durgin TL. The direct cost of epilepsy in the United States: a systematic review of estimates. Epilepsia. 2015;56(9):1376-87.
    7.  Devinsky O, Spruill T, Thurman D, Friedman D. Recognizing and preventing epilepsy-related mortality: a call for action. Neurology. 2016;86(8):779-86.
    8. Kwan P, Arzimanoglou A, Berg AT, Brodie MJ, Allen Hauser W, Mathern G, et al. Definition of drug resistant epilepsy: consensus proposal by the ad hoc Task Force of the ILAE Commission on Therapeutic Strategies. Epilepsia. 2010;51(6):1069-77.
    9. Ghosh C, Puvenna V, Gonzalez-Martinez J, Janigro D, Marchi N. Blood-brain barrier P450 enzymes and multidrug transporters in drug resistance: a synergistic role in neurological diseases. Cur. Drug Metab. 2011;12(8):742-9.
    10. Emich-Widera E, Likus W, Kazek B, Niemiec P, Balcerzyk A, Sieroń AL, et al. CYP3A5* 3 and C3435T MDR1 polymorphisms in prognostication of drug-resistant epilepsy in children and adolescents. BioMed Res. Internat. 2013;2013.
    11. Walzer M, Bekersky I, Blum RA, Tolbert D. Pharmacokinetic drug interactions between clobazam and drugs metabolized by cytochrome P450 isoenzymes. Pharmacotherapy: J. Hum. Pharm. Drug Ther. 2012;32(4):340-53.
    12.  Ke XJ, Cheng YF, Yu N, DiQ. Effects of carbamazepine on the P-gp and CYP3A expression correlated with PXR or NF-κB activity in the bEnd. 3 cells. Neuroscien. Let. 2019;690:48-55.
    13. Peigné S, Rey E, Le Guern ME, Dulac O, Chiron C, Pons G, et al. Reassessment of stiripentol pharmacokinetics in healthy adult volunteers. Epilepsy research. 2014;108(5):909-16.
    14. Potschka H, Löscher W. Corneal kindling in mice: behavioral and pharmacological differences to conventional kindling. Epilepsy research. 1999;37(2):109-20.
    15. Barton ME, Klein BD, Wolf HH, White HS. Pharmacological characterization of the 6 Hz psychomotor seizure model of partial epilepsy. Epilepsy research. 2001;47(3):217-27.
    16. Barker-Haliski ML, Vanegas F, Mau MJ, Underwood TK, White HS. Acute cognitive impact of antiseizure drugs in naive rodents and corneal‐ kindled mice. Epilepsia. 2016;57(9):1386-97.
    17. Hock FJ, ed. Drug discovery and evaluation: Pharmacological assays. 4th ed. Springer International Publishing 2016. 4239 p.
    18. Glantz SA. Primer of Biostatistics. 4th ed. McGraw-Hill Inc., New York; 1997. 473 p.
    19. Reeta KH, Mehla J, Pahuja M, Gupta YK. Pharmacokinetic and pharmacodynamic interactions of valproate, phenytoin, phenobarbitone and carbamazepine with curcumin in experimental models of epilepsy in rats. Pharmac. Biochem. Behav. 2011;99(3):399-407.
    20. Bertilsson L, Höjer B, Tybring G, Osterloh J, Rane A. Autoinduction of carbamazepine metabolism in children examined by a stable isotope technique. Clinic. Pharmac. Therap. 1980;27(1):83-8.
    21. Kudriakova TB, Sirota LA, Rozova GI, Gorkov VA. Autoinduction and steady‐state pharmacokinetics of carbamazepine and its major metabolites. Brit. J. Clin. pharmac. 1992;33(6):611-5.
    22. Patsalos PN, Ghattaura S, Ratnaraj N, Sander JW. In situ metabolism of levetiracetam in blood of patients with epilepsy. Epilepsia. 2006;47(11):1818-21.
    23. Freitas-Lima P, Alexandre JrV, Pereira LRL, Feletti F, Perucca E, Sakamoto AC. Influence of enzyme inducing antiepileptic drugs on the pharmacokinetics of levetiracetam in patients with epilepsy. Epilepsy Res. 2011;94(1-2):117-20.
    24. May TW, Korn-Merker E, Rambeck B, Boenigk HE. Pharmacokinetics of sulthiame in epileptic patients. Therap. Drug Monitor. 1994;16(3):251- 7.
    25. Rambeck B, Wolf P. Lamotrigine clinical pharmacokinetics. Clinic. pharmacokin. 1993;25(6):433-43. 26. Weintraub D, Buchsbaum R, Resor SR, Hirsch LJ. Effect of antiepileptic drug comedication on lamotrigine clearance. Arch. Neurol. 2005;62(9):1432-6.
    26. Levy RH, Rettenmeier AW, Anderson GD, Wilensky AJ, Friel PN, Baillie TA, et al. Effects of polytherapy with phenytoin, carbamazepine, and stiripentol on formation of 4‐ene‐valproate, a hepatotoxic metabolite of valproic acid. Clin. Pharmac. Therap. 1990;48(3):225-35.
    27. Brodie MJ, Mumford JP. Double-blind substitution of vigabatrin and valproate in carbamazepine-resistant partial epilepsy. Epilepsy Res. 1999;34(2-3):199-205.
    28. Shandra A, Shandra P, Kaschenko O, Matagne A, Stöhr T. Synergism of lacosamide with established antiepileptic drugs in the 6‐H z seizure model in mice. Epilepsia. 2013;54(7):1167-75.
    29. Patsalos PN. Drug interactions with the newer antiepileptic drugs (AEDs) – part 1: pharmacokinetic and pharmacodynamic interactions between AEDs. Clin. pharmacokin. 2013;52(11):927-66.
    30. Koneval Z, Knox KM, White HS, Barker-Haliski M. Lamotrigine‐resistant corneal‐kindled mice: A model of pharmacoresistant partial epilepsy for moderate‐throughput drug discovery. Epilepsia. 2018;59(6):1245-56.
    31. Opryshko VI. Issledovanie vzaimodejstviya karbamazepina i tiotriazolina na modeli farmakorezistentnoj epilepsii. Zaporozh. med. zh. 2008;4:31-5. [in Russian].

    Publication of the article:

    «Bulletin of problems biology and medicine» Issue 2 Part 1 (150), 2019 year, 72-78 pages, index UDK 615.213:616.853+577.152.112

    DOI:

    10.29254/2077-4214-2019-2-1-150-72-78