Seizures result from disruptions in the normal balance of excitatory and inhibitory processes. Hypersynchronous neuronal firing, the physiologic hallmark of seizure, is mediated predominantly by glutamate excitation and voltage-gated sodium and calcium channels. Seizure termination is largely dependent on the inhibitory effects of gamma-aminobutyric acid (GABA)-receptor activation and voltage-gated potassium channels [23]. After initiation, failure of intrinsic mechanisms or disruption of inhibition from extrinsic factors will lead to prolonged seizure activity. The maintenance phase of SE is characterized by synaptic internalization of GABA receptors and expression of excitatory N-methyl-D-aspartate (NMDA) and alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors, resulting in self-sustaining seizures refractory to conventional antiepileptic drugs (AEDs) [24]. In animal models, the potency of benzodiazepines decrease 20-fold within 30 minutes of SE, while phenytoin loses effectiveness to a lesser degree [25]. Observations in humans suggest that a refractory state is reached much faster. In a video electroencephalogram (EEG) study of 120 generalized convulsive seizures, the mean seizure duration was 62 seconds with no events lasting >2 minutes [26]. In clinical practice, seizures are less likely to terminate spontaneously after this period, leading to Lowenstein and Alldredge [8] proposing SE be defined as continuous seizure for ≥5 minutes. In the minutes-to-hours that follow, SE is maintained by increased expression of proconvulsive neuropeptides and decrease in inhibitory ones [27-30].

Less is known about the biochemical changes associated with RSE and SRSE. In the range of hours-to-weeks, long-term changes in gene expression may occur secondary to recurrent seizure activity and neuronal injury, resulting in neural reorganization [24].

Neuronal loss in SE was described in early foundational work in primate models by Meldrum and Horton [6] and Meldrum et al. [31]. Cell death occurs even in the absence of hypoxia, acidosis, hypoglycemia and other confounding factors [32-34], and may be mediated by ‘programmed necrosis’ and apoptosis [35,36]. In humans, serum neuron-specific enolase, a biomarker for neural injury, has been shown to be elevated in SE [37,38], while autopsy studies demonstrate decreased hippocampal neuron density postmortem [39].

To what extent similar pathologic changes occur in NCSE as compared to convulsive SE (CSE) is unclear. Early observational studies by Engel et al. [40] suggested long-standing neurocognitive changes following NCSE. Serum neuron-specific enolase has also been shown to be elevated [37,41,42]; however, it is difficult to determine whether NCSE directly causes neuronal injury, or if seizures reflect brain damage from other causes. NCSE also represents a heterogenous syndrome, with potential for neuronal injury dependent on the seizure type and etiology. Absence SE and NCSE in patients with underlying chronic epilepsy may be less prone to injury [43,44], while complex partial SE is most associated with pathologic changes [40-42].

Patients with CSE progress through physiologic stages [45]. In the early compensated phase, convulsions are accompanied by significant sympathetic activation. During this stage, hypertension, increased cardiac output, and increased cerebral blood flow is seen, and serum markers of hypermetabolism such as lactic acid and glucose will be elevated [46]. After prolonged seizure activity (>30 minutes), pathophysiologic decompensation occurs. This is characterized by cerebral dysautoregulation, cardiovascular dysfunction, and signs of systemic metabolic crisis: hypoxia, hypoglycemia, and acidosis. Failure to prevent profound physiologic disturbances may exacerbate secondary brain injury associated with RSE.

As described above, seizures are associated with profound pathophysiologic changes, that if left untreated, can lead to severe clinical consequences. When convulsive seizures occur, attention should be given to both basic life support measures while considering first line AED therapy. Evidence-based guidelines from both the NCCS and the American Epilepsy Society (AES) recommend benzodiazepines as initial therapy of choice [9,57]. Lorazepam is widely available, fast to administer, and terminates overt SE in 65% of cases [58]. Compared to diazepam, IV lorazepam is pharmacologically preferred because it is less lipid soluble and undergoes slower peripheral distribution [59]. Intramuscular midazolam is effective when IV access has not been established.

Recurrent convulsive seizures in RSE and SRSE are treated similarly. In intubated patients, full-dose lorazepam (0.1 mg/kg) or equivalent benzodiazepine can be given, with smaller doses considered when attempting to avoid intubation or when significant hypotension is present.

Benzodiazepines lose effectiveness in established SE and are suboptimal for long-term anti-seizure management; therefore, next-line AEDs should be ordered and administered early, within 10 minutes of seizure onset [9]. First-line conventional AEDs are selected for their broad spectrum of activity and their ability to be given safely as an IV loading dose in attempts to abort SE and reach therapeutic levels rapidly (Table 1).

Historically, phenytoin has been the initial stage II AED given after benzodiazepines, terminating overt seizure in 44% in the Veterans Affairs Cooperative Study [58]. Many clinical concerns may limit its use. Phenytoin is not considered sedating; however, hypotension and cardiac arrhythmia can occur with bolus doses [60]. Other acute complications include ‘purple glove syndrome’ and metabolic acidosis, while long-term side effects including teratogenicity and coarsening of facial features make it nonideal for chronic therapy. Phenytoin is also limited by its narrow therapeutic range. Additionally, bioavailability is influenced by factors common to ICU patients: drug-drug interactions, renal insufficiency, and hypoalbuminemia.

For many neurointensivists, levetiracetam has been explored as a stage I and II AED in SE. Preferred pharmacologic properties include its high bioavailability and few drug-drug interactions owing to low plasma protein binding and minimal hepatic metabolism [61]. Unfortunately, data for levetiracetam as an emergent treatment is limited. In a pilot study involving traditional AEDs, levetiracetam demonstrated equal efficacy in aborting overt seizure compared to lorazepam [62], and in a recent meta-analysis, showed similar activity in benzodiazepine-resistant SE (68.5% relative effectiveness) compared to phenytoin (50.2%), phenobarbital (73.6%), and valproic acid (75.7%) [63]. The drug is well tolerated, ideal in critically ill patients on multiple medications, and for long-term therapy in those who remain at risk for seizures after hospital discharge.

Optimal therapy after failure of benzodiazepines and first stage II AED is unknown. Although a second conventional AED is typically added in this setting, the likelihood of success is marginal and may delay seizure termination. Development of RSE should prompt planning for ICU admission, intubation, and initiation of a general anesthetic agent. Seizure activity is definitively aborted with use of a single anesthetic agent, or with combination of agents in SRSE, with no method or agent proven superior to another [12,64]. Anesthetic drugs used are outlined in Table 2.

Whether propofol or midazolam are used first largely depends on provider preference. Propofol, a GABA agonist and NMDA-receptor antagonist, is often preferred because its highly lipophilic properties with large volume of distribution allow for rapid offset to facilitate neurologic examination. In patients with hypotension with or without propofol, midazolam is an alternate; however, it itself is associated with hypotension in 40% of patients and may exhibit either tachyphylaxis or drug accumulation resulting in prolonged sedation [65,66]. Adequate EEG suppression may be difficult to achieve with a single anesthetic agent.

Because of its side effect profile, pentobarbital is typically reserved for cases of SRSE refractory to combined propofol and midazolam. Pentobarbital infusion can result in profound hypotension, cardiorespiratory depression, metabolic acidosis, and immunosuppression [67,68], which may outweigh any potential benefit of the drug. In a systematic review of outcomes in RSE and SRSE, barbiturate infusion achieved seizure control in 64%, but was associated with prolonged mechanical ventilation and increased mortality [12]. Whether poorer outcomes are due to the therapy and its complications, or a result of SRSE being associated with more severe illness is unclear.

There are several reasons why AEDs fail to prevent seizure recurrence in SRSE. Although an epileptogenic focus may be refractory to certain medications, subtherapeutic drug levels commonly contribute to their ineffectiveness. AED levels should be checked serially throughout the early phase of SRSE, with titration of AEDs as appropriate.

Loading doses are given at drug initiation to reach therapeutic range early. AEDs with linear pharmacokinetics and low protein-binding can be loaded with greater predictability than those without such properties. Phenytoin, in contrast to levetiracetam, demonstrates non-linear kinetics and is highly protein-bound, making therapeutic ranges difficult to achieve and maintain. Patient weight influences volume of distribution; therefore, weight-based dosing should be given when established. Similarly, general anesthetics should be bolused on initiation. Propofol is given as a 2–5 mg/kg bolus, midazolam as a 0.2 mg/kg bolus, and pentobarbital with 5–10 mg/kg.

Drug bioavailability should be considered when choosing IV versus oral (PO) routes of administration. Although bioavailability of many first-line AEDs such as phenytoin, valproate, and levetiracetam is high in healthy subjects [71,72], alterations in gastric motility, gut absorption and drug metabolism in the critically ill likely interfere [73]. In a study of IV versus PO phenytoin loading, IV doses resulted in faster times to therapeutic drug concentrations (0.21 ± 0.28 hours) compared to PO (5.63 ± 0.28 hours) [74]. At our institution, IV formulations are typically continued until seizure termination and relapse has not occurred, and additionally during significant gastrointestinal illness.

Failure to account for the half-life of an AED can result in sub-therapeutic drug troughs. Clinically, this can be observed as EEG suppression after drug dosing, but recurrent seizure or increased frequency of epileptiform discharges prior to next administration. In highly-tolerated medications with shorter half-lives, such as levetiracetam and valproate, dosing every 8 hours instead of twice daily should be considered. In cases of polytherapy, AEDs can be scheduled in staggered fashion to prevent long spans between drug doses.

Patients failing benzodiazepines and first-line scheduled AEDs are unlikely to achieve seizure termination without anesthetics; however, in SRSE, polytherapy is necessary to prevent seizure recurrence. Managing multiple AEDS requires consideration of several factors: risks and benefits of treatment, dosing strategies, and drug-drug interactions that alter drug efficacy and metabolism, and potentiate side effects. Second and third-line agents are listed in Table 1.

In general, AEDs fall in to two broad categories: enzyme-inducers and enzyme-inhibitors. Table 3 categorizes commonly used AEDs. Concurrent use of an enzymeinducer and inhibitor can become problematic. This most commonly occurs when phenytoin, phenobarbital, or carbamazepine (inducers) are used in conjunction with valproic acid (an inhibitor), leading to supratherapeutic inducer levels and reductions in valproate concentrations by up to 50%–75% [75]. Free phenytoin, the active component of phenytoin, also increases with displacement from protein binding sites by valproate [76]. Increases in serum drug concentrations can result in toxicities at doses lower than expected. Carbamazepine, a second-line agent in SRSE, demonstrates auto-induction, where higher doses can result in increased drug metabolism [71].

In polytherapy, the most effective regiments consider the pharmacokinetic properties and mechanisms of drug actions (MOAs). There is no proven benefit of one AED MOA compared to another in the treatment of SRSE. Similarly, no large study has investigated the efficacy of combining AEDs of different MOAs; however, this strategy is rationale, with early research suggesting polytherapy can be more effective and less toxic than monotherapy [77]. Use of consecutive AEDs with different MOAs is increasingly being employed in RSE protocols [78], and is common practice at our institution.

First-line scheduled AEDs are typically sodium channel blockers (phenytoin), or have a broad spectrum of action (valproic acid, levetiracetam) [79]. The established MOAs of AEDs is outlined in Table 4. Some medications listed, including perampanel and ezogabine, have not yet been established in the treatment of SE, but are occasionally used at our hospital for SRSE given their novel MOA and overall tolerability. Although SE is often refractory to benzodiazepines, addition of a scheduled GABAergic benzodiazepine can be useful, especially in patients demonstrating responsiveness to midazolam infusion.