Specialities

Specialities

Alzheimer's Disease & Dementia
Brain Trauma
COVID-19
Epilepsy
Headache Disorders
Neurodegenerative Diseases
Movement Disorders
Multiple Sclerosis
Neuroimmunology
Neurological Oncology
Neurometabolic Disease
Neuromuscular Diseases
Neuropathic Pain
Stroke
Neurosurgery
Paediatric Neurology
Parkinson's Disease
Rare Diseases
Psychiatric Disorders
Sleep Disorders
Central Nervous Disorders
Search

Trending Topic
4 mins

Trending Topic
Developed by Touch
Mark CompleteCompleted
BookmarkBookmarked

Foreword: touchREVIEWS in Neurology, Volume 20, Issue 2, 2024

Leontino Battistin

Welcome to this issue of touchREVIEWS in Neurology, where we explore significant advances in neurology, cognitive health, and wearable technology in the management of various chronic conditions. This issue brings together a collection of expert perspectives and research that spans innovative therapies, preventive strategies, and case studies, each offering critical insights for clinicians and researchers. […]

Connect With Us:

Facebook
X (Twitter)
Instagram
Youtube
Linkedin
Epilepsy
5 mins

New Add-on Therapy for Partial-onset Epilepsy

Reed Loring Levine, David Y Ko
Share
Facebook
X (formerly Twitter)
LinkedIn
Via Email
Mark CompleteCompleted
BookmarkBookmarked
Copy LinkLink Copied
Download as PDF
Published Online: Jun 4th 2011 US Neurology, 2008;4(1):48-52 DOI: http://doi.org/10.17925/USN.2008.04.01.48
Select a Section…
1

Article

Adequate control of partial-onset epilepsy often requires polypharmacy, either due the to less than ideal efficacy of one antiepileptic drug (AED) (see Table 1) or due to side effects caused by the initial AED (see Table 2). Up to one-third of patients with partial-onset epilepsy will require treatment with more than one AED.


Adequate control of partial-onset epilepsy often requires polypharmacy, either due the to less than ideal efficacy of one antiepileptic drug (AED) (see Table 1) or due to side effects caused by the initial AED (see Table 2). Up to one-third of patients with partial-onset epilepsy will require treatment with more than one AED.
The ideal medical management of epilepsy is based on tailoring each patient’s regimen to his or her seizure type, comorbidities, lifestyle, and history of medication side effects. Therefore, a greater number of potential treatments offers greater options for any given patient to be treated with the best combination of medications. In recent years, many new AEDs have become available for add-on therapy for partial-onset epilepsy.
Of the newer AEDs, those that are US Food and Drug Administration (FDA)-approved for the adjunctive treatment of partial-onset epilepsy include felbamate tigabine, lamotrigine, pregabalin, gabapentin, topiramate, oxcarbazapine, zonisamide, and levetiracetam. An add-on AED should ideally have a clean pharmodynamic and phamcokinetic profile to minimize drug interactions and side effect profile. The newer AEDs are generally safer than the first-generation AEDs and, with the exception of Felbamate, do not require routine blood monitoring. All of the newer AEDs are category C in terms of use in females who want to have children, although a patient who is planning a pregnancy should aim for the lowest number of AEDs given at the lowest dose.
Rational polypharmacy has long been a goal, but unfortunately this has not been well studied in this age of evidence-based medicine. With so many different possible combinations, one rule of thumb of rational polypharmacy is to use medications with different mechanisms of action. Of the newer AEDs, one combination that would not be ‘rational’ would be neurontin and pregabalin, as they have exactly the same mechanism of action. One rational combination is valproic acid and lamotrigine, as lamotrigine’s half-life is prolonged, resulting in the patient requiring significantly lower doses.

Felbamate

Felbamate is recommended to patients with severe partial epilepsy or Lennox-Gastaut syndrome who fail other treatments. It is a potent blocker of N-methyl D-aspartate (NMDA) receptors and voltage-gated calcium (Ca) channels, and modulates sodium (Na+)-channel conductance. It is approximately 25% bound to plasma proteins and undergoes hepatic metabolism. In monotherapy, its elimination half-life may be as long as 30 hours, but when given with P450-inducing agents its half-life decreases to roughly 14 hours.1,2 The co-administration of valproate leads to increased plasma concentrations of felbamate. This medication will notably increase phenytoin levels and decrease carbamazepine levels.2,3 In both the adult and pediatric population, concomitant AEDs should be reduced by a minimum of 20% when starting felbamate, and may be reduced further if levels are high.1
Felbamate is generally well tolerated, with the most common adverse effects being insomnia, dizziness, fatigue, decreased appetite, weight loss, nausea, ataxia, and lethargy.2–5 In 110,000 patients, there were 10 cases of fatal aplastic anemia and 14 cases of fatal hepatic failure. The labeling was changed to advise that it be utilized in a limited subset of patients along with bi-weekly blood monitoring. Due to the risk for aplastic anemia and hepatic failure, it should be used when the benefits outweigh the risks.

Topiramate

Topiramate is currently approved for partial-onset and secondarily generalized tonic-clonic seizures, primary generalized tonic-clonic seizures, and Lennox-Gastaut syndrome. Topiramate acts via several different mechanisms: the enhancement of Gamma-aminobutyric acid (GABA); the inhibition of Na+ conductance, thus reducing the duration of spontaneous bursts and the frequency of action potentials; the inhibition of alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA); and weak inhibition of carbonic anhydrase.6
Topiramate has nearly 100% bioavailability. Its elimination half-life is 18–23 hours.6 The hepatic P450 system metabolizes ~15% of topiramate and the remainder (~85%) is excreted unchanged in urine, and thus in renal failure dosages must be reduced. P450-inducing drugs, such as phenytoin or carbamazepine, may significantly reduce serum topiramate concentrations: levels were found to be reduced by 50% in some studies. Conversely, topiramate has not been found to significantly influence steady-state concentrations of other drugs given in polytherapy, except for an increased phenytoin level observed in a subset of patients. Physicians should be aware that topiramate decreases ethyl estradiol levels, and may therefore inactivate low-dose oral contraceptives at doses greater than 200mg.6,7
In adults the most common adverse effects are paresthesia in the extremities, cognitive slowing (including impairment of concentration, confusion, memory disturbance, and slowness of speech), ataxia, dizziness, fatigue, somnolence, depression, and agitation.8 Weight loss, which appears to be secondary to appetite suppression, may be >10kg, an effect that may lead to discontinuation if the patient is of normal or below ideal weight prior to treatment initiation. This is thought of as a positive side effect by some overweight patients.
Topiramate’s carbonic anhydrase inhibition increases the risk for renal calculi. Patients should be encouraged to stay well hydrated. Another potential side effect related to carbonic anhydrase inhibition is the development of hyperchloremic non-anion gap metabolic acidosis; this can be checked by measuring bicarbonate levels. A rare adverse event is acute myopia in closed-angle glaucoma.9

Oxcarbazapine

Oxcarbazepine is approved for monotherapy or adjunctive treatment of partial and secondary generalized seizures. Oxcarbazepine is similar to carbamazepine in that it has a tricyclic ring structure and primarily works as an Na-channel blocker, but it has a different effect on the Ca-channel subtype. Oxcarbazepine was produced with the goal of avoiding carbamazepine’s auto-induction and drug interactions. The metabolism of oxcarbazepine does not generate the 10,11-epoxide metabolite responsible for many of the adverse effects of carbamazepine. Oxcarbazepine is nearly completely absorbed and broken down into the active metabolite monohydroxy derivative (MHD). Peak plasma levels are reached at approximately four hours. It has a half-life of eight to 10 hours. Hepatic metabolism induces a limited subset of P450 enzymes. Oxcarbazepine in high doses (>1,200mg) significantly affects oral contraceptives and may render them ineffective.10
Studies have been performed where oxcarbazepine and carbamazepine were used together successfully with additive benefit. If oxcarbazepine were to be substituted for carbamazepine, a recommended ratio of 3:2 has been studied; dosing is outlined in Table 1. As noted above, oxcarbazepine has fewer drug interactions and is better tolerated than carbamazepine. However, some retrospective studies have uncovered the exacerbation of seizures in juvenile idiopathic generalized epilepsies in patients treated with oxcarbazepine.10–12
The most commonly reported adverse effects include headache, weight gain, somnolence, dizziness, rash, hyponatremia, alopecia, and gastrointestinal upset. If a patient is allergic to carbamazepine, allergic cross-reactivity to oxcarbamazepine has also been reported, although at a rate of 27% it occurs less frequently. Many of the reported adverse effects are dose-related (fatigue, dizziness, ataxia, and headache). Hyponatremia (uncommon in children <17 years of age, but reported in 2.5% of adults and 7.4% of elderly patients) is generally mild and can usually be easily treated with fluid restriction.10–14

Lamotrigine

Lamortigine is approved for adjunctive treatment and for cross-over to monotherapy for partial-onset and secondarily generalized tonic-clonic seizures, for Lennox-Gastaut syndrome, and as add-on therapy for primary generalized tonic clonic seizures in patients ≥2 years of age.
Lamotrigine is believed to work via several mechanisms, the principal one being Na+-channel blockade, and its bioavailability approaches 100%. It is 55% protein-bound and has an elimination half-life of 24–41 hours. Co-administration with valproate increases lamotrigine levels by increasing its half-life to roughly 70 hours. Lamotrigine is metabolized hepatically and excreted renally. At higher doses, it may cause autoinduction.
Lamotrigine will neither induce nor inhibit hepatic enzymes, therefore no dosing changes are indicated when given with oral contraceptives or warfarin. However, medications that induce hepatic enzymes may decrease lamotrigine’s half-life to 14–16 hours, and dosing must be adjusted accordingly.10,15 Oral contraceptives decrease lamotrigine half-life, but as combined oral contraceptive monthly packs have seven days with no hormonal placebo pills, lamotrigine levels can rise by as much as 40%, leading to monthly flucutuations and causing side effects. It has been found to be effective in myoclonic seizures, but can cause worsening of myoclonic seizures in some juvenile myoclonic epilepsy. Dosing and titration depends on AED co-administration, with a slower titration required with enzyme-inhibiting AEDs than with enzyme-inducing AEDs.6,10,15,16
Lamotrigine is available in several starter packs. These have different titrations depending on the co-administered AEDs to aid in patient compliance with what may otherwise be a complicated initiation of medication. Up to 5% of patients develop a rash, often associated with a rapid titration. A severe rash, most common in children on valproate, may develop and result in the rare but potentially fatal Stevens-Johnson syndrome (0.1%). Other adverse reactions include ataxia, diplopia, headache, tremor, blood dyscrasias, gastrointestinal upset, psychosis, somnolence, insomnia, and hypersensitivity reactions.15–17

Zonisamide

Zonisamide is approved by the FDA for adjunctive treatment in patients above 12 years of age with partial seizures. Its major mechanism of action is Na-channel blockade, although it also has been shown to bind and reversibly inactivate T-type Ca channels, making it effective for myoclonus, as found in juvenile myoclonic epilepsy.
Zonisamide is rapidly and completely absorbed. It is partially metabolized by the liver (~70%), and although it utilizes P450, it does not induce the enzymes. Zonisamide has long half-life of about 63 hours, permitting once-daily administration and lack of drug interactions with other AEDs. The half-life of zonisamide may be decreased from 63 to 27–46 hours when co-administered with pheytoin, carbamazepine, phenobarbital, or valproic acid, although zonisamide has no effect on the levels of these medications.10,19
Although generally well-tolerated, the most commonly reported adverse reactions with zonisamide were somnolence, fatigue, headache, weight gain, dizziness, anorexia, ataxia, tremor, confusion, speech abnormalities, mental slowing, and irritability. Zonisamide has been associated with renal calculi in 1.5% of patients, and its carbonic anhydrase-inhibiting effects may produce oligohidrosis in some children. Zonisamide should not be used in patients with known allergies to sulfonamides, as it may produce allergic reactions in these individuals.

Tigabine

Tigabine is used as add-on therapy in patients with partial or secondarily generalized seizures. Tigabine, a derivative of the GABA uptake inhibitor nipecotic acid, reversibly inhibits GABA transporter-1.20,21 It binds 96% to plasma proteins and is metabolized by the hepatic P450 system. In a patient co-medicated with enzyme-inducing drugs, tigabine’s plasma half-life of four to eight hours may be reduced slightly to four to five hours. Its metabolism and removal from the body is reduced in liver patients. Tigabine induces a minor decrease in valproate levels (valproate has no effect on tigabine levels), but does not alter the efficacy of oral contraceptives. P450-inducing drugs increase the clearance of tigabine by roughly two-thirds.10,20–22
There have been reports of both convulsive and non-convulsive status epilepticus with tigabine usage, and therefore it should be used with caution in a patient with a history of status epilepticus. It is contraindicated in absence epilepsy and in partial epilepsies with generalized spike wave on electrocardiogram (EEG), where it may worsen seizure control.21

Gabapentin

Gabapentin is approved for the treatment of partial and secondarily generalized tonic-clonic seizures. It binds the alpha-2 delta subunit of Ca channels in the cerebral cortex, hippocampus, and spinal cord, reducing the influx of Ca at nerve terminals, in turn reducing excitatory neurotransmitters release.3,6,19,16,23,24
Gabapentin, unlike many other newer AEDs, has a relatively poor bioavailability of less than 60%, which is altered primarily by variable absorption via an L-amino acid transporter. At doses greater than 1,200mg, bioavailability further drops off to ~35%. Gabapentin neither binds to plasma proteins nor is metabolized (and does not induce hepatic enzymes), and it is excreted entirely unchanged. Gabapentin has an elimination half-life of five to nine hours. In patients with compromised renal function, dosing must be adjusted according to creatinine clearance.3,6,16,19 Owing to its lack of drug interactions, lack of plasma protein-binding, and renal excretion, gabapentin is particularly useful in patients with hepatic or renal disease, or in patients on complex drug regimens.3,10,23–25 It is typically well tolerated, with common adverse effects being somnolence, ataxia, and dizziness. No significant serious idiosyncratic or systemic adverse effects of gabapentin have been reported.23,25

Pregabalin

Pregabalin is approved for adjunctive therapy for adult patients with partial-onset seizures. Like gabapentin, pregabalin binds the alpha-2-delta subunit of Ca channels, reducing the influx of calcium at nerve terminals, in turn reducing the release of excitatory neurotransmitters (glutamate, noradrenaline, substance P), but it does not block the Ca channel. Pregabalin is more potent than gabapentin, with a higher binding affinity for the Ca channel subunit, which is a modulator of Ca.
Pregbalin has a high (>90%) oral bioavailability that distinguishes it from gabapentin. Its elimination half-life is roughly six hours. Pregabalin is not significantly metabolized, has no effect on liver enzymes, and is excreted unchanged by the kidneys. Pregabalin does not significantly bind plasma proteins. No significant drug interactions with pregabalin have been identified.32,33
Pregabalin’s efficacy as add-on therapy in partial-onset seizures was established in three studies, which showed a 43–51% decrease in seizure frequency from baseline versus a 1–10% decrease with placebo.34–36 Adverse effects were dizziness, somnolence, ataxia, and asthenia. Weight gain >7% from baseline was dose-related and reported in 18% of patients. No significant, serious toxicity related to pregabalin was reported. In patients with significant renal dysfunction (creatinine clearance <60 minutes), doses must be lowered.36

Levetiracetam

Levetiracetam is approved as adjunctive therapy in the treatment of partial-onset seizures, myoclonic seizures in juvenile myoclonic epilepsy, and primary generalized tonic-clonic seizures in adults and children ≥6 years of age. There is now an intravenous form of leveitracetam available. Its mechanism of action has not yet been fully identified, but levetiracetam binds a brain-specific binding site presynatpic vesicle protein SV2A, and has been shown to inhibit Ca2+ release and other possible neurotransmitters.27,28
Levetiracetam has a bioavailability of nearly 100%. It does not bind plasma proteins, is minimally metabolized (~27%), and does not induce P450 enzymes, with two-thirds of the drug excreted unchanged in urine. It has an elimination half-life of six to eight hours, although it appears to have a significantly longer pharmacodynamic half-life. In renal insufficiency, its elimination half-life may approach 24 hours.27
Levetiracetam has no known significant drug interactions. It is an AED that is generally well tolerated. Dosing is outlined in Table 1. The most significant adverse effects are somnolence, asthenia, and dizziness. A drug-specific adverse effect is irritability, which seems to be more common in patients with underlying behavioral issues and may be doserelated. No serious acute idiosyncratic reactions were reported.29–31

Summary

The physician’s armamentarium to treat epilepsy has been significantly improved by the increasing number of new AEDs, all of which can be used as add-on therapy. In treating a patient, one must consider not only efficacy, but also comorbidities, potential adverse effects, and dosing schedules. The real-world dosing of AEDs as add-on therapy does not need to follow the package insert dosing recommendation derived from clinical trial titration schedule because the mantra of starting with a lower dose and slowly increasing it will lead to better tolerability and higher retention in most cases, especially in the elderly. With a greater understanding of the strengths and weaknesses of each AED, physicians can use each medication optimally for each patient. ■

1

References

  1. Palmer KJ, McTavish D, Felbamate. A review of its pharmacodynamic and phamacokinetic properties, and therapeutic efficacy in epilepsy, Drugs, 1993;45(6):1041–65.
  2. Leppik IE, et al., Felbamate for partial seizures: results of a controlled clinical trial, Neurology, 1991;41(11):1785–9.
  3. Dichter MA, Brodie MJ, New antiepileptic drugs, N Engl J Med, 1996;334:1583–90.
  4. Theodore WH, et al., Felbamate: a clinical trial for complex partial seizures, Epilepsia, 1991;32(3):392–7.
  5. Jensen PK, Felbamate in the treatment of refractory partial-onset seizures, Epilepsia, 1993;34(Suppl 7):525–9.
  6. Curry WJ, Kulling DL, Newer antiepileptic drugs: gabapentin, lamotrigine, felbamate, topiramate, and fosphenytoin, Am Fam Physician, 1998;57(3):513–20.
  7. Dorit Mimrod, et al., A Comparative Study of the Effect of Carbamazepine and Valproic Acid on the Pharmacokinetics and Metabolic Profile of Topiramate at Steady State in Patients with Epilepsy, Epilepsia, 2005;46:7–1046.
  8. Faught E, et al., Topiramate placebo-controlled dose-ranging trial in refractory partial epilepsy using 200, 400, and 600mg daily dosages, Neurology, 1996;46:1684–90.
  9. Shorvon SD, Safety of topiramate: adverse events and relationships to dosing, Epilepsia, 1996;37(Suppl. 2):18–22.
  10. Perucca E, The Clinical Pharmacokinetics of the New Antiepileptic Drugs, Epilepsia, 1999;40(Suppl. 9);S7–13.
  11. Clemens B, et al., Objective assessment of neurotoxicity while shifting from carbamazepine to oxcarbazepine, Acta Neurologica Scandinavica, 2004;109(5);324–9.
  12. Gelisse P, et al.,Worsening of Seizures by Oxcarbazepine in Juvenile Idiopathic Generalized Epilepsies, Epilepsia, 2004;45(10); 1282–6.
  13. Beydoun A, et al., Sustained Efficacy and Long-term Safety of Oxcarbazepine: One-year Open-label Extension of a Study in Refractory Partial Epilepsy, Epilepsia, 2003;44(9);1160–65.
  14. D. Schmidt, et al., Recommendations on the clinical use of oxcarbazepine in the treatment of epilepsy:a consensus view, Acta Neurologica Scandinavica, 2001;104:3–167.
  15. Lamotrigine, Package insert, Research Triangle Park, Glaxo Wellcome Inc., 1997.
  16. Ramsay RE, Advances in the pharmacotherapy of epilepsy, Epilepsia, 1993;34(Suppl. 5):S9–16.
  17. Blum D, et al., Cognitive effects of lamotrigine compared with topiramate in patients with epilepsy, Neurology, 2006;67(3): 400–406.
  18. Cunnington MC, The International Lamotrigine Pregnancy Registry Update for the Epilepsy Foundation, Epilepsia, 2004;45:11–1468.
  19. Leppik E, Zonisamide: chemistry, mechanism of action, and pharmacokinetics, Seizure, 2004;13(Suppl. 1):S5–9.
  20. Giardina WJ, Anticonvulsant action of tiagabine, a new GABA-uptake inhibitor, J Epilepsy, 1994;7:161–6.
  21. Tigabine, Package insert, Package insert, Cephalon, Inc.
  22. Hitoshi Sato, et al., Anticonvulsant Effects of Tigabine, a New Antiepileptic Drug: The Profile of Action in the Rat Kindling Model of Epilepsy, Epilepsia, 1996;37:s3–110.
  23. Gabapentin, Package insert, Morris Plains: Parke-Davis, 1994.
  24. Rosner H, Rubin L, Kestenbaum A, Gabapentin adjunctive therapy in neuropathic pain states, Clin J Pain, 1996;12:56–8.
  25. Lynda V, Wilton, Saad Shakir, A Post-marketing Surveillance Study of Gabapentin as Add-on Therapy for 3,100 Patients in England, Epilepsia, 2002;43:9–983.
  26. Appleton R, et al., Gabapentin as add-on therapy in children with refractory partial seizures: a 24-week, multicentre, open-label study, Development Med Child Neurol, 2001;43:4–269.
  27. Radtke RA, Pharmacokinetics of Levetiracetam, Epilepsia, 2001;42:s4–24.
  28. Lukyanetz EA, Shkryl VM, Kostyuk PG, Selective blockade of N-Type calcium channels by levetiracetam, Epilepsia, 2002;43(1): 9–18.
  29. Shorvon SD, et al., for the European Levetiracetam Study Group, Multicenter Double-Blind, Randomized, Placebo-Controlled Trial of Levetiracetam as Add-On Therapy in Patients with Refractory Partial Seizures, Epilepsia, 2000;41:9–1179.
  30. Frenc J, Arrigo C, Rapid Onset of Action of Levetiracetam in Refractory Epilepsy Patients, Epilepsia, 2005;46:2–324.
  31. Levetiracetam, Package insert, UCB, Inc.
  32. Ben-Menachem E, Pregabalin Pharmacology and Its Relevance to Clinical Practice, Epilepsia, 2004;45:s6–13.
  33. Brodie MJ, et al., Pregabalin Drug Interaction Studies: Lack of Effect on the Pharmacokinetics of Carbamazepine, Phenytoin, Lamotrigine, and Valproate in Patients with Partial Epilepsy, Epilepsia, 2005;46:9–1407.
  34. Ryvlin P, Defining success in clinical trials—profiling pregabalin, the newest AED, Eur J Neurol, 2005;12:s4–12.
  35. Arroyo S, et al., For the Pregabalin 1008-011 International Study Group, Pregabalin Add-on Treatment: A Randomized, Double-blind, Placebo-controlled, Dose-Response Study in Adults with Partial Seizures, Epilepsia, 2004;45:1–20.
  36. Pregabalin, Package insert, Pfizer.
2

Further Resources

Share
Facebook
X (formerly Twitter)
LinkedIn
Via Email
Mark CompleteCompleted
BookmarkBookmarked
Copy LinkLink Copied
Download as PDF
6 mins

Trending Topic
Developed by Touch
Mark CompleteCompleted
BookmarkBookmarked

Exploring Cellular Mechanisms and Restorative Cell-based Therapeutics for Epilepsy

Lily H Kim, Muhammad Ammar Haider, Kevin K Kumar

Affecting over 70 million patients worldwide, epilepsy is a chronic neurological disorder characterized by intermittent bursts of hyper-synchronous neuronal discharges.1 The manifestations are variable but reflective of the unique milieu and biology of epileptogenic foci.2 Pharmacological treatment with antiepileptic drugs (AEDs) is supportive only and, for up to 30% of patients, is inadequate in preventing seizures.3 While surgical […]

touchREVIEWS in Neurology. 2024;20(2):2-5
Advertisement
    • 3

    Related Content in Epilepsy

    Latest articles videos and clinical updates - straight to your inbox

    Close Popup