ASM Selection & Treatment Initiation

The decision to initiate antiseizure medication (ASM) therapy is among the most consequential in epilepsy management. It requires balancing the risk of seizure recurrence against the potential burden of long-term pharmacotherapy, including adverse effects, drug interactions, teratogenicity, and psychosocial consequences. Once the decision is made, ASM selection must be individualized based on seizure and epilepsy type, patient demographics, comorbidities, reproductive considerations, and cost. Landmark trials such as SANAD I and SANAD II have provided Class I evidence to guide first-line ASM choices. Despite the availability of more than 25 ASMs, approximately one-third of patients develop drug-resistant epilepsy—defined by the International League Against Epilepsy (ILAE) as failure of two adequately trialed ASMs—underscoring the importance of optimizing initial treatment selection.

When to Initiate ASM Therapy

After a First Unprovoked Seizure

The recurrence risk after a single unprovoked seizure is approximately 40–50% within 2 years. Immediate ASM treatment reduces early recurrence risk but does not alter long-term remission rates. The decision to treat should be shared with the patient and guided by risk factors for recurrence:

• Factors favoring treatment: Epileptiform abnormalities on EEG, structural brain lesion on MRI, prior neurologic insult (stroke, TBI, CNS infection), remote symptomatic etiology, nocturnal seizure, Todd paralysis
• Factors favoring observation: Normal EEG and MRI, provoked or situation-related seizure, patient preference against medication, low-risk occupation/lifestyle
• Psychosocial considerations: Driving restrictions (vary by state/country), employment implications, patient anxiety about recurrence vs. medication side effects

After Two or More Unprovoked Seizures

Two unprovoked seizures occurring more than 24 hours apart define epilepsy by ILAE criteria, and ASM treatment is generally recommended. The recurrence risk after a second unprovoked seizure exceeds 60–70%. The ILAE 2014 definition also allows a diagnosis of epilepsy after a single seizure if the estimated recurrence risk equals or exceeds that after two unprovoked seizures (≥60% over 10 years).

Factors in ASM Selection

Seizure and Epilepsy Type

The most critical factor in ASM selection is the seizure type and epilepsy syndrome. ASMs are classified as broad-spectrum (effective for both focal and generalized epilepsies) or narrow-spectrum (effective primarily for focal seizures). Narrow-spectrum sodium channel blockers—carbamazepine, oxcarbazepine, eslicarbazepine, phenytoin—and gabapentinoids may exacerbate generalized absence and myoclonic seizures and must be avoided in idiopathic generalized epilepsy (IGE).

Patient-Specific Factors

Landmark Clinical Trials

SANAD I (Lancet, 2007)

The Standard and New Antiepileptic Drugs (SANAD I) trial was a large, unblinded, randomized controlled trial conducted in the UK comparing first-line ASMs:

• Arm A (focal epilepsy): Carbamazepine vs. gabapentin vs. lamotrigine vs. oxcarbazepine vs. topiramate. Lamotrigine was significantly better than carbamazepine for time to treatment failure and noninferior for seizure freedom at 12 months; gabapentin was inferior to carbamazepine for seizure control
• Arm B (generalized/unclassified epilepsy): Valproate vs. lamotrigine vs. topiramate. Valproate was significantly better than topiramate for time to treatment failure and better than lamotrigine for 12-month seizure freedom; topiramate was the least well tolerated
• Key conclusion: Lamotrigine recommended as first-line for focal epilepsy; valproate recommended as first-line for generalized/unclassified epilepsy

SANAD II (Lancet, 2021)

SANAD II was an open-label, noninferiority, multicenter, phase 4 randomized controlled trial that compared newer ASMs:

• Arm A (focal epilepsy): Lamotrigine vs. levetiracetam vs. zonisamide. Lamotrigine was superior to both levetiracetam and zonisamide for time to 12-month remission; levetiracetam was noninferior to lamotrigine for time to treatment failure
• Arm B (generalized/unclassified epilepsy): Valproate vs. levetiracetam. Valproate was superior to levetiracetam for time to 12-month and 24-month remission; levetiracetam was noninferior for time to treatment failure
• Key conclusion: Lamotrigine remains the recommended first-line ASM for focal epilepsy; valproate remains the most effective for generalized epilepsy but should be avoided in females of childbearing potential

Monotherapy vs. Polytherapy

The Monotherapy Principle

Initial treatment should always begin with a single ASM (monotherapy). This approach minimizes adverse effects, simplifies adherence, avoids drug interactions, and facilitates identification of the responsible agent if side effects occur. Approximately 47–50% of patients with newly diagnosed epilepsy achieve seizure freedom with the first appropriately chosen ASM.

When to Add a Second ASM

If the first ASM fails, the approach depends on the reason for failure:

• Failure due to intolerability: Replace with an alternative monotherapy, preferably one without the same adverse effect profile; if the adverse effect was mechanism-related, consider a different mechanism of action
• Failure due to lack of efficacy (well tolerated): Either substitution monotherapy or adjunctive (add-on) therapy are equally effective options; add-on therapy is preferred if the first ASM was partially effective
• Failure due to both: Substitution monotherapy is preferred unless the tolerability issue was purely dose-related

Titration Principles and Therapeutic Drug Monitoring

General Titration Approach

Most ASMs should be started at a low dose and titrated gradually ("start low, go slow") to minimize dose-related adverse effects. The rate of titration varies by ASM and clinical urgency:

When to Monitor Drug Levels

Routine therapeutic drug monitoring (TDM) is not necessary for all ASMs. It is most valuable in the following situations:

• ASMs with nonlinear kinetics: Phenytoin (saturable metabolism makes small dose changes produce large concentration changes)
• Dose optimization: To determine whether a higher dose can be safely attempted when seizures persist despite the initial target dose
• Suspected toxicity: Symptoms consistent with supratherapeutic levels (ataxia, diplopia, tremor)
• Pregnancy: Lamotrigine clearance increases markedly during pregnancy due to estrogen-induced glucuronidation; monthly levels recommended
• Drug interactions: When enzyme inducers or inhibitors are added or removed
• Adherence assessment: Unexpectedly low levels may indicate nonadherence
• Establishing an individual reference range: Obtain 2–3 levels during the period of best seizure control to define the patient's "individual therapeutic concentration"

Treatment Goals and Seizure Freedom

Defining Treatment Success

The goal of ASM therapy is complete seizure freedom with no or minimal side effects. However, "seizure freedom" is defined operationally and varies by context:

• Clinical trials: Typically defined as no seizures during a defined maintenance period (e.g., 6–12 months)
• Clinical practice: Generally requires at least 12 months of seizure freedom; many epileptologists use a "rule of 3" (seizure-free interval of at least three times the longest pretreatment interseizure interval)
• Driving eligibility: Varies by jurisdiction; most US states require 3–12 months of seizure freedom

Probability of Seizure Freedom

Prospective longitudinal data from the Glasgow cohort (Kwan and Brodie, NEJM 2000; updated through 2018) have established the following estimates:

• First ASM: ~47–50% achieve seizure freedom
• Second ASM (monotherapy or add-on): ~13% of the remaining patients achieve seizure freedom
• Third ASM and beyond: Each subsequent ASM achieves seizure freedom in only ~2–5% of patients
• Cumulative: Overall, approximately 64% of patients eventually achieve seizure freedom with ASMs; the remaining ~36% have drug-resistant epilepsy

Drug-Resistant Epilepsy

ILAE Definition (2010)

Drug-resistant epilepsy is defined as failure of adequate trials of two tolerated, appropriately chosen and used ASM schedules (whether as monotherapy or in combination) to achieve sustained seizure freedom. This definition requires:

• Adequate trial: Appropriate ASM for the seizure/epilepsy type, at an adequate dose, for a sufficient duration
• Tolerated: The ASM was not discontinued due to adverse effects before reaching an effective dose
• Sustained seizure freedom: No seizures for at least three times the longest pretreatment interseizure interval, or 12 months (whichever is longer)

Synergistic ASM Combinations

When monotherapy fails, rational polytherapy should aim for supra-additive efficacy and infra-additive toxicity. Evidence-based principles include:

• Combine different mechanisms: A sodium channel blocker (lamotrigine, lacosamide) plus an SV2A ligand (levetiracetam, brivaracetam) is a well-supported combination; the Glasgow cohort showed this pairing had the best chance of achieving seizure freedom
• Avoid similar mechanisms: Two sodium channel blockers (e.g., lacosamide + carbamazepine) increase adverse effects through pharmacodynamic interactions without proportional gains in efficacy
• Synergistic combinations with human evidence: Lamotrigine + valproate (strongest evidence); lamotrigine + levetiracetam; cannabidiol + clobazam; lamotrigine + topiramate; cenobamate + clobazam
• Avoid >2 ASMs when possible: Three-drug combinations increase the risk of pharmacokinetic and pharmacodynamic interactions; replace ineffective agents rather than adding a third

References

1. Abou-Khalil B. Update on antiseizure medications 2025. Continuum (Minneap Minn) 2025;31(1):123–165.
2. Marson AG, Al-Kharusi AM, Alwaidh M, et al. The SANAD study of effectiveness of carbamazepine, gabapentin, lamotrigine, oxcarbazepine, or topiramate for treatment of partial epilepsy: an unblinded randomised controlled trial. Lancet 2007;369(9566):1000–1015.
3. Marson AG, Al-Kharusi AM, Alwaidh M, et al. The SANAD study of effectiveness of valproate, lamotrigine, or topiramate for generalised and unclassifiable epilepsy: an unblinded randomised controlled trial. Lancet 2007;369(9566):1016–1026.
4. Marson A, Burnside G, Appleton R, et al. The SANAD II study of the effectiveness and cost-effectiveness of valproate versus levetiracetam for newly diagnosed generalised and unclassifiable epilepsy. Lancet 2021;397(10282):1375–1386.
5. Kwan P, Brodie MJ. Early identification of refractory epilepsy. N Engl J Med 2000;342(5):314–319.
6. Kwan P, Arzimanoglou A, Berg AT, 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):1069–1077.
7. Krumholz A, Wiebe S, Gronseth GS, et al. Evidence-based guideline: management of an unprovoked first seizure in adults. Neurology 2015;84(16):1705–1713.
8. Mattson RH, Cramer JA, Collins JF, et al. Comparison of carbamazepine, phenobarbital, phenytoin, and primidone in partial and secondarily generalized tonic-clonic seizures. N Engl J Med 1985;313(3):145–151.
9. Chen Z, Brodie MJ, Liew D, Kwan P. Treatment outcomes in patients with newly diagnosed epilepsy treated with established and new antiepileptic drugs: a 30-year longitudinal cohort study. JAMA Neurol 2018;75(3):279–286.
10. Cohen JM, Alvestad S, Cesta CE, et al. Comparative safety of antiseizure medication monotherapy for major malformations. Ann Neurol 2023;93:551–562.