U.S. flag

An official website of the United States government

NCBI Bookshelf. A service of the National Library of Medicine, National Institutes of Health.

Pratt VM, Scott SA, Pirmohamed M, et al., editors. Medical Genetics Summaries [Internet]. Bethesda (MD): National Center for Biotechnology Information (US); 2012-.

Cover of Medical Genetics Summaries

Medical Genetics Summaries [Internet].

Show details

Brivaracetam Therapy and CYP2C19 Genotype

, MD.

Author Information and Affiliations

Created: .

Estimated reading time: 10 minutes

Introduction

Brivaracetam (brand name Briviact) is an antiseizure drug used in the treatment of partial-onset (focal) epilepsy in adults. It is thought to act by binding to a synaptic vesicle glycoprotein, SV2A, and reducing the release of neurotransmitters.

Brivaracetam is primarily metabolized by hydrolysis, via amidase enzymes, to an inactive metabolite. To a lesser extent, it is also metabolized by a minor metabolic pathway via CYP2C19-dependent hydroxylation.

Individuals who have no CYP2C19 enzyme activity, “CYP2C19 poor metabolizers”, will have a greater exposure to standard doses of brivaracetam. Because they are less able to metabolize the drug to its inactive form for excretion, they may have an increased risk of adverse effects. The most common adverse effects of brivaracetam therapy include sedation, fatigue, dizziness, and nausea.

The recommended starting dosage for brivaracetam monotherapy or adjunctive therapy is 50 mg twice daily (100 mg per day). Based on how the individual responds, the dose of brivaracetam may be decreased to 25 mg twice daily (50 mg per day) or increased up to 100 mg twice daily (200 mg per day) (1).

The FDA-approved drug label for brivaracetam states that patients who are CYPC19 poor metabolizers, or are taking medicines that inhibit CYP2C19, may require a dose reduction (Table 1). Approximately 2% of Caucasians, 4% of African Americans, and 14% of Chinese are CYP2C19 poor metabolizers (1).

Table 1.

FDA (2017) Drug Label for Brivaracetam. Recommendations for CYP2C19 Phenotype: Pharmacokinetics.

PhenotypeRecommendations
CYP2C19 poor metabolizerCYP2C19 poor metabolizers and patients using inhibitors of CYP2C19 may require dose reduction.

This table is adapted from (1).

Drug: Brivaracetam

Brivaracetam is an antiseizure drug that is used in the treatment of partial-onset (focal) seizures in patients aged 16 years or older. Brivaracetam can be used as monotherapy, or more commonly, is used in combination with other antiseizure drugs (1). There is also some evidence to suggest that brivaracetam may be useful in the treatment of generalized seizures (2).

Brivaracetam displays a high and selective affinity for SV2A in the brain, which is thought to contribute to the antiseizure effect (3).

In a neuron, at the synapse, vesicles store various neurotransmitters. The neurotransmitters are released and then refilled in a process regulated by voltage-dependent calcium channels. These synaptic vesicles are essential for propagating nerve impulses between neurons, and the SV2A protein is a major component of the vesicle (4).

Levetiracetam was the first antiseizure drug that was found to bind to SV2A, among other targets. Brivaracetam is an analogue of levetiracetam and was designed to selectively target SV2A with a much higher affinity (5-7).

Over 50 million people worldwide suffer from epilepsy. Epilepsy is characterized by spontaneous recurrent epileptic seizures, which may be classified as focal or generalized. Generalized seizures appear to originate in all regions of the cortex simultaneously and include absence seizures (sudden impaired consciousness and staring) and general tonic-clonic seizures (loss of consciousness, stiffening of limbs in the tonic phase, and twitching or jerking muscles in the clonic phase). In contrast, symptoms of focal seizures depend upon where the focus of the seizure originates in the brain; e.g., jerking of a limb indicates a focus in the contralateral motor cortex.

Most antiseizure drugs currently available target sodium channels (e.g., carbamazepine, phenytoin), calcium channels (e.g., ethosuximide), or the GABA pathway (e.g., clobazam). However, up to one-third of patients may not achieve seizure control or they may not be able to tolerate the side effects. Newer antiseizure drugs have unconventional targets, such as SV2A (8-10).

Brivaracetam was licensed in 2016, and in phase III trials and with long term follow up, brivaracetam was reported to be well tolerated with good efficacy (11, 12). Compared with the addition of placebo to a treatment regime, the addition of brivaracetam reduced the frequency of focal seizures by approximately half (13-16).

The most common side effects associated with brivaracetam therapy include dizziness, fatigue, somnolence, nausea and vomiting. Psychiatric symptoms such as irritability, insomnia and depression, and behavioral effects have also been reported, but some studies suggest these may be less likely to occur with brivaracetam compared with levetiracetam (17-20).

Brivaracetam is primarily metabolized (approximately 60%) by cytochrome P450 (CYP)-independent hydrolysis (via amidase) to inactive metabolites. Minor metabolic pathways include hydroxylation by CYP2C19.

One study found that co-administration of rifampin (a strong enzyme inducer) decreased exposure to brivaracetam by 45%, this is probably through an induction of the CYP2C19 pathway which clears brivaracetam metabolites from the blood (21). One small study (n=79) found that individuals who lacked CYP2C19 activity had increased exposure to brivaracetam (22). It is therefore possible that genetic variations associated with a loss of CYP2C19 function may reduce brivaracetam metabolism leading to increased levels of active drug levels in the plasma, and possibly increases the probability of side effects. However, the recommended therapeutic dose is 50–200 mg/day, and patients are individually titrated to optimal efficacy, safety, and tolerability.

Gene: CYP2C19

The CYP superfamily is a large and diverse group of enzymes that form the major system for metabolizing lipids, hormones, toxins, and drugs. The CYP genes are very polymorphic and can result in reduced, absent, or increased drug metabolism.

The CYP2C19 enzyme contributes to the metabolism of a range of clinically important drugs, such as antidepressants (23), benzodiazepines, several proton pump inhibitors, the antifungal agent voriconazole (24), the antiplatelet agent clopidogrel (25), and antiseizure drugs such as brivaracetam, clobazam, diazepam, lacosamide, phenytoin, and phenobarbital.

The CYP2C19 gene is highly polymorphic—35 variant star (*) alleles are cataloged at the Pharmacogene Variation (PharmVar) Consortium. The CYP2C19*1 is the wild type allele and is associated with normal enzyme activity and the “normal metabolizer” phenotype.

The CYP2C19*17 allele is associated with increased enzyme activity and, depending on the number of alleles present, is associated with the “rapid” (one *17 allele) and “ultrarapid” (two *17 alleles) metabolizer phenotypes.

Nonfunctional alleles include CYP2C19*2 and *3. The CYP2C19 “intermediate” metabolizers carry one copy of an allele that encodes a nonfunctional allele (e.g., *1/*2), whereas “poor” metabolizers carry 2 nonfunctional alleles (e.g., *2/*2, *2/*3) (Table 2).

Table 2.

CPIC (2016) CYP2C19 Functional Status and Phenotypes

PhenotypeGenotypeExamples of diplotypes
CYP2C19 ultrarapid metabolizer
(~2–5% of patients)a
An individual carrying 2 increased function alleles. *17/*17
CYP2C19 rapid metabolizer
(~2–30% of patients)
An individual carrying one normal function allele and one increased function allele. *1/*17
CYP2C19 normal metabolizer
(~35–50% of patients)
An individual carrying 2 normal function alleles. *1/*1
CYP2C19 intermediate metabolizer
(~18–45% of patients)
An individual carrying one normal function allele and one no function allele, or one no function allele and one increased function allele. *1/*2
*1/*3
*2/*17b
CYP2C19 poor metabolizer
(~2–15% of patients)
An individual carrying 2 no function alleles. *2/*2
*2/*3
*3/*3
a

CYP2C19 metabolizer status frequencies are based on average multiethnic frequencies. See the CYP2C19 Frequency Tables for population-specific allele and phenotype frequencies (23).

b

The predicted metabolizer phenotype for the*2/*17 genotype is a provisional classification. The currently available evidence indicates that the CYP2C19*17 increased function allele is unable to completely compensate for the CYP2C19*2 nonfunctional allele.

This table is adapted from (23).

Approximately 2% of Caucasians, 4% of African Americans, and 14% of Chinese are CYP2C19 poor metabolizers; and up to 45% of patients are CYP2C19 intermediate metabolizers.

The most common nonfunctional variant is CYP2C19*2, which contains a NM_000769.1:c.681G>A variant in exon 5 that results in an aberrant splice site that produces a truncated and nonfunctioning protein. The CYP2C19*2 allele frequencies are ~15% in Caucasians and Africans, and ~29–35% in Asians.

Another commonly tested nonfunctional variant is CYP2C19*3, which contains a NM_000769.1:c.636G>A variant in exon 4 that causes a premature stop codon. The CYP2C19*3 allele frequencies are ~2-9% in Asian populations, but rare in other racial groups. Other nonfunctional variants occur in less than 1% of the general population and include CYP2C19*4-*8 (25).

Linking Gene Variation with Treatment Response

One small study (n=79) reports that CYP2C19 allele status influences the pharmacokinetics of brivaracetam, but that this is unlikely to be clinically relevant because of the minor role of CYP-dependent hydroxylation in the metabolism of brivaracetam (22). However, the FDA does state that CYP2C19 poor metabolizers may require a reduction in the dose of brivaracetam (1).

Genetic Testing

Clinical genotyping tests are available for several CYP2C19 alleles. The NIH’s Genetic Testing Registry (GTR) provides examples of the genetic tests that are currently available for the CYP2C19 gene.

Usually a patient’s result is reported as a diplotype, such as CYP2C19 *1/*1, and may also include an interpretation of the patient’s predicted metabolizer phenotype (ultrarapid, rapid, normal, intermediate, or poor).

The CYP2C19*2 and *3 alleles are most commonly tested for, and Table 2 summarizes common CYP2C19 phenotypes. Less common nonfunctional alleles (e.g., CYP2C19*4-*8) may also influence drug response similarly to *2 and *3 but they may not be tested for, and data are lacking on their effects on the brivaracetam drug response.

To facilitate CYP2C19 genetic testing and improve genotyping concordance across laboratories, the Pharmacogenetics Working Group of the Association for Molecular Pathology Clinical Practice Committee (AMP PGx) has recommended a minimum set of CYP2C19 alleles, referred to as "tier 1", which should be included in clinical CYP2C19 pharmacogenomic tests. As of 2018, the tier 1 alleles are CYP2C19*2, CYP2C19*3, and CYP2C19*17 (Table 3) (26).

In addition, AMP PGx have defined a list of tier 2 CYP2C19 alleles that do not meet the criteria for inclusion in tier 1 and are thus considered optional (Table 4) (26).

Table 3.

AMP PGx (2018) CYP2C19 Tier 1 Variant Alleles.

AlleleAllele functional statusaDefining functional variantMultiethnic allele frequency, %
CYP2C19*2 No functionrs424428512-54
CYP2C19*3 No functionrs49868930.3-15
CYP2C19*17 Increased functionrs122485604-21
a

Citations for assignment of function can be found at PharmGKB Gene-specific Information for CYP2C19.

Note that the defining *2 variant (rs4244285) is most likely linked with the defining variant of the *35 allele (rs12769205); however, the *35 definition includes rs12769205 without rs4244285.

Table 4.

AMP PGx (2018) CYP2C19 Tier 2 Variant Alleles.

GenotypeAllele functional status*Defining functional variant*Multiethnic allele frequency, %
CYP2C19*4 No functionrs283995040.1-0.3
CYP2C19*4B No functionrs28399504; rs122485600-0.2
CYP2C19*5 No functionrs563370130
CYP2C19*6 No functionrs725522670-0.1
CYP2C19*7 No functionrs725581860
CYP2C19*8 No functionrs412915560.1-0.3
CYP2C19*9 Decreased functionrs178847120.1-4.2
CYP2C19*10 Decreased functionrs64134380.1-6
CYP2C19*35 No functionrs127692050.8-3.1
*

Multiethnic allele frequency from PharmVar​.org (last accessed June 20, 2017.)

Both Table 3 and Table 4 are adapted from (26).

Therapeutic Recommendations based on Genotype

This section contains excerpted1 information on gene-based dosing recommendations. Neither this section nor other parts of this review contain the complete recommendations from the sources.

2017 Statement from the US Food and Drug Administration (FDA)

Brivaracetam is primarily metabolized by hydrolysis of the amide moiety to form the corresponding carboxylic acid metabolite, and secondarily by hydroxylation on the propyl side chain to form the hydroxy metabolite. The hydrolysis reaction is mediated by hepatic and extra-hepatic amidase. The hydroxylation pathway is mediated primarily by CYP2C19. In human subjects possessing genetic variations in CYP2C19, production of the hydroxy metabolite is decreased 2-fold or 10-fold, while the blood level of brivaracetam itself is increased by 22% or 42%, respectively, in individuals with one or both mutated alleles. CYP2C19 poor metabolizers and patients using inhibitors of CYP2C19 may require dose reduction. An additional hydroxy acid metabolite is created by hydrolysis of the amide moiety on the hydroxy metabolite or hydroxylation of the propyl side chain on the carboxylic acid metabolite (mainly by CYP2C9). None of the 3 metabolites are pharmacologically active.

Please review the complete therapeutic recommendations that are located here: (1).

Nomenclature of selected CYP2C19 alleles

Common allele nameAlternative namesHGVS reference sequencedbSNP reference identifier for allele location
CodingProtein
CYP2C19*2 681G>A
Pro227Pro
NM_000769​.1:c.681G>A NP_000760​.1:p.Pro227= rs4244285
CYP2C19*3 636G>A
Trp212Ter
NM_000769​.1:c.636G>A NP_000760​.1:p.Trp212Ter rs4986893
CYP2C19*17 -806C>T NM_000769​.1:c.-806C>T Not applicable - variant occurs in a non-coding region rs12248560

Note: the normal “wild type” allele is CYP2C19*1.

Pharmacogenetic Allele Nomenclature: International Workgroup Recommendations for Test Result Reporting (27).

Guidelines for the description and nomenclature of gene variations are available from the Human Genome Variation Society (HGVS).

Nomenclature for Cytochrome P450 enzymes is available from the Pharmacogene Variation (PharmVar) Consortium.

Acknowledgments

The author would like to thank Ben Kong, PharmD, BCPS, Clinical Pharmacist, Oregon Health & Science University, Portland, OR, USA; Gouri Mukerjee, Scientific Officer at Geneyouin Inc., Toronto, Canada; Michael A. Rogawski, Professor of Neurology, University of California, Davis, Davis, CA, USA; and Armel Stockis, UCB Pharma, Brussels, Belgium; for reviewing this summary.

References

1.
BRIVIACT- brivaracetam tablet, film coated; BRIVIACT- brivaracetam solution; BRIVIACT- brivaracetam injection, suspension [Packet insert]. Smyrna, GA; September 19, 2017. Available from: https://dailymed​.nlm​.nih.gov/dailymed/drugInfo​.cfm?setid=3cf2f439-0e97-443e-8e33-25ecef616f6c.
2.
Grande-Martín A., Sopelana-Garay D., Pardal-Fernandez J.M., Sanchez-Honrubia R.M., et al. Exceptional response to brivaracetam in a patient with refractory idiopathic generalized epilepsy and absence seizures. Epileptic Disord. 2018 Feb 1;20(1):60–64. [PubMed: 29160210]
3.
Niespodziany I., Rigo J.M., Moonen G., Matagne A., et al. Brivaracetam does not modulate ionotropic channels activated by glutamate, gamma-aminobutyric acid, and glycine in hippocampal neurons. Epilepsia. 2017 Nov;58(11):e157–e161. [PubMed: 28850675]
4.
Khaleghi F., Nemec E.C. 2nd. Brivaracetam (Briviact): A Novel Adjunctive Therapy for Partial-Onset Seizures. P T. 2017 Feb;42(2):92–96. [PMC free article: PMC5265234] [PubMed: 28163554]
5.
Kwok C.S., Johnson E.L., Krauss G.L. Comparing Safety and Efficacy of "Third-Generation" Antiepileptic Drugs: Long-Term Extension and Post-marketing Treatment. CNS Drugs. 2017 Dec 4;31(11):959–974. [PubMed: 29204953]
6.
Rogawski M.A. A New SV2A Ligand for Epilepsy. Cell. 2016 Oct 20;167(3):587. [PubMed: 27768878]
7.
Wood M.D., Gillard M. Evidence for a differential interaction of brivaracetam and levetiracetam with the synaptic vesicle 2A protein. Epilepsia. 2017 Feb;58(2):255–262. [PubMed: 28012162]
8.
Ben-Menachem E., Mameniskiene R., Quarato P.P., Klein P., et al. Efficacy and safety of brivaracetam for partial-onset seizures in 3 pooled clinical studies. Neurology. 2016 Jul 19;87(3):314–23. [PMC free article: PMC4955277] [PubMed: 27335114]
9.
Milovanović J.R., Jankovic S.M., Pejcic A., Milosavljevic M., et al. Evaluation of brivaracetam: a new drug to treat epilepsy. Expert Opin Pharmacother. 2017 Sep;18(13):1381–1389. [PubMed: 28737479]
10.
Russo E., Citraro R., Mula M. The preclinical discovery and development of brivaracetam for the treatment of focal epilepsy. Expert Opin Drug Discov. 2017 Nov;12(11):1169–1178. [PubMed: 28829199]
11.
Toledo M., Whitesides J., Schiemann J., Johnson M.E., et al. Safety, tolerability, and seizure control during long-term treatment with adjunctive brivaracetam for partial-onset seizures. Epilepsia. 2016 Jul;57(7):1139–51. [PubMed: 27265725]
12.
Brigo F., Bragazzi N.L., Nardone R., Trinka E. Efficacy and tolerability of brivaracetam compared to lacosamide, eslicarbazepine acetate, and perampanel as adjunctive treatments in uncontrolled focal epilepsy: Results of an indirect comparison meta-analysis of RCTs. Seizure. 2016 Nov;42:29–37. [PubMed: 27710868]
13.
Brandt C., May T.W., Bien C.G. Brivaracetam as adjunctive therapy for the treatment of partial-onset seizures in patients with epilepsy: the current evidence base. Ther Adv Neurol Disord. 2016 Nov;9(6):474–482. [PMC free article: PMC5066531] [PubMed: 27800023]
14.
Li-Na Z., Deng C., Hai-Jiao W., Da X., et al. Indirect comparison of third-generation antiepileptic drugs as adjunctive treatment for uncontrolled focal epilepsy. Epilepsy Res. 2018 Nov 26;139:60–72. [PubMed: 29197667]
15.
Zhu L.N., Chen D., Xu D., Tan G., et al. Newer antiepileptic drugs compared to levetiracetam as adjunctive treatments for uncontrolled focal epilepsy: An indirect comparison. Seizure. 2017 Oct;51:121–132. [PubMed: 28854405]
16.
Hoy S.M. Brivaracetam: A Review in Partial-Onset (Focal) Seizures in Patients with Epilepsy. CNS Drugs. 2016 Aug;30(8):761–72. [PubMed: 27503181]
17.
Brodie M.J. Tolerability and Safety of Commonly Used Antiepileptic Drugs in Adolescents and Adults: A Clinician's Overview. CNS Drugs. 2017 Feb;31(2):135–147. [PubMed: 28101765]
18.
Ortega G., Abraira L., Marti G., Quintana M., et al. Anger Assessment in Patients Treated With Brivaracetam. Clin Neuropharmacol. 2018 Dec 1;41(1):6–9. [PubMed: 29194113]
19.
Zaccara G., Giovannelli F., Giorgi F.S., Franco V., et al. Tolerability of new antiepileptic drugs: a network meta-analysis. Eur J Clin Pharmacol. 2017 Jul;73(7):811–817. [PubMed: 28378057]
20.
Brivaracetam (Brivlera) [Internet], in Brivaracetam (Brivlera). 2017: Ottawa (ON).
21.
Stockis A., Watanabe S., Scheen A.J., Tytgat D., et al. Effect of Rifampin on the Disposition of Brivaracetam in Human Subjects: Further Insights into Brivaracetam Hydrolysis. Drug Metab Dispos. 2016 Jun;44(6):792–9. [PubMed: 27002062]
22.
Stockis A., Watanabe S., Rouits E., Matsuguma K., et al. Brivaracetam single and multiple rising oral dose study in healthy Japanese participants: influence of CYP2C19 genotype. Drug Metab Pharmacokinet. 2014;29(5):394–9. [PubMed: 24717838]
23.
Hicks J.K., Sangkuhl K., Swen J.J., Ellingrod V.L., et al. Clinical pharmacogenetics implementation consortium guideline (CPIC) for CYP2D6 and CYP2C19 genotypes and dosing of tricyclic antidepressants: 2016 update. Clin Pharmacol Ther. 2016;(Dec):20. [PMC free article: PMC5478479] [PubMed: 27997040]
24.
Moriyama B., Obeng A.O., Barbarino J., Penzak S.R., et al. Clinical Pharmacogenetics Implementation Consortium (CPIC) Guidelines for CYP2C19 and Voriconazole Therapy. Clin Pharmacol Ther. 2016;(Dec):16. [PMC free article: PMC5474211] [PubMed: 27981572]
25.
Scott S.A., Sangkuhl K., Stein C.M., Hulot J.S., et al. Clinical Pharmacogenetics Implementation Consortium guidelines for CYP2C19 genotype and clopidogrel therapy: 2013 update. Clin Pharmacol Ther. 2013 Sep;94(3):317–23. [PMC free article: PMC3748366] [PubMed: 23698643]
26.
Pratt VM. D.T.A., Hachad H, Ji Y, Kalman LV, Scott SA, Weck KE, Recommendations for Clinical CYP2C19 Genotyping Allele Selection: A Report of the Association for Molecular Pathology. J Mol Diagn. 2018;20(3):269–276. [PubMed: 29474986]
27.
Kalman L.V., Agundez J., Appell M.L., Black J.L., et al. Pharmacogenetic allele nomenclature: International workgroup recommendations for test result reporting. Clin Pharmacol Ther. 2016 Feb;99(2):172–85. [PMC free article: PMC4724253] [PubMed: 26479518]

Footnotes

1

The FDA labels specific drug formulations. We have substituted the generic names for any drug labels in this excerpt. The FDA may not have labeled all formulations containing the generic drug.

Copyright Notice

All Medical Genetics Summaries content, except where otherwise noted, is licensed under a Creative Commons Attribution 4.0 International (CC BY 4.0) license which permits copying, distribution, and adaptation of the work, provided the original work is properly cited and any changes from the original work are properly indicated. Any altered, transformed, or adapted form of the work may only be distributed under the same or similar license to this one.

Bookshelf ID: NBK500036PMID: 29763212

Views

Related Summaries by Drug Class

Tests in GTR by Gene

Related information

  • PMC
    PubMed Central citations
  • PubMed
    Links to PubMed

Similar articles in PubMed

See reviews...See all...

Recent Activity

Your browsing activity is empty.

Activity recording is turned off.

Turn recording back on

See more...