Antiepileptic Strategies for Patients with Primary and Metastatic Brain Tumors

Seizure activity is a common occurrence for patients with a primary or metastatic brain tumor. In this setting, the presence of persistent seizure activity is termed Brain Tumor-Related Epilepsy (BTRE) and is variable depending on specific aspects of the tumor, including histology, grade, and molecular phenotype [1‐5, 6•]. Epilepsy from a brain tumor constitutes 6–10% of all cases of epilepsy as a whole, and 12% of acquired epilepsy. In general, the incidence of BTRE is higher in low-grade tumors in comparison to high-grade tumors. For example, patients with dysembryoplastic neuroepithelial tumors (DNETs; grade 1) experience a very high seizure incidence at presentation, roughly 100%, while those with other low-grade glioneuronal tumors have an incidence in the 70–80% range. In patients with isocitrate dehydrogenase (IDH) mutant grade 2 diffuse gliomas (including astrocytomas and oligodendrogliomas), the incidence of BTRE is roughly 65–75%. In contrast, the incidence of BTRE in patients with high-grade gliomas ranges from 25 to 60%, including those with IDH wildtype grade 4 glioblastoma (GBM), where the incidence is 25–30%. For patients with meningiomas, the incidence of BTRE is 30–50%, while for those with brain metastases, it is in the 20–35% range.

The seizures in BTRE are usually focal motor events affecting the contralateral face, arm, hand, or leg; or a combination of these locations [1‐5, 6•]. Focal seizure activity can also affect speech (e.g., speech arrest). Partial complex-type seizures can also occur if the tumor is located in the anterior temporal lobe. Status epilepticus and non-convulsive status epilepticus can potentially arise in the setting of BTRE, but are not very common. If seizure activity is suspected in a brain tumor patient, but is not totally clear based on the history, then a workup will be necessary [7]. The differential diagnosis for a seizure event is very broad and includes syncope of cardiac origin, syncope of non-cardiac origin, toxic disturbances, and metabolic disturbances. A cardiac workup is often necessary in this situation, along with new imaging studies (MRI, MRS), toxic and metabolic lab studies, baseline EEG, and possibly long-term monitoring in an epilepsy unit.

In recent years, it has been clarified that brain tumor–related seizure events do not arise from within the bulk of the tumor tissue, but instead in the peritumoral regions around the tumor, where multiple factors contribute to an ongoing and escalating epileptogenic environment [1, 2, 8, 9, 10•, 11]. The initial alterations to the peritumoral region involve mechanical factors as the tumor enlarges, including compression, regional ischemia, metabolic changes such as acidosis, focal disruption of the blood-brain barrier (BBB) with fluid and protein leakage, hypoxia, glial swelling, and tissue damage—all of which contribute to the early phase of epileptogenesis [8, 9, 10•, 11]. Concomitant with these mechanical alterations are numerous other regional changes related to tumor cells, interactions with neurons, inflammatory processes, molecular factors, receptor activity, and neurotransmitter imbalance.

The peritumoral region is in a pro-inflammatory state, with recruitment of astrocytes, microglial cells, and macrophages, increased concentrations of cytokines including interleukins (IL) IL-1β, IL-6, and IL-8, tumor necrosis factor (TNF)-α, chemokines, and matrix metalloproteinases (MMP) MMP-2 and MMP-9—all of which promote tumor proliferation, invasiveness, and seizure susceptibility [8, 9, 10•, 11]. Within this background, it is also known that glioma cells secrete large amounts of the excitatory neurotransmitter glutamate, which is important in favoring epileptogenesis [6•, 7‐9, 10•]. Secretion of glutamate is primarily mediated by the xCT cysteine/glutamate antiporter, which has increased expression on the surface of glioma cells and is an independent biomarker for seizures in these patients [12, 13]. In addition, peritumoral astrocytes demonstrate impaired expression of excitatory amino acid transporter 1 (EAAT1) and EAAT2, which uptake synaptic glutamate, thereby contributing to the accumulation of glutamate in the extracellular space. In parallel with an increased availability of glutamate, there is an augmented expression of ionotropic α–amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) and N-methyl-D-aspartate (NMDA) receptors in glioma cells and peritumoral astrocytes, which contributes to the high glutamatergic tone and excitability in the peritumoral region [12]. Stimulation of AMPA and NMDA receptors by glutamate promotes growth and invasiveness in glioma cells; however, for neurons, it promotes epileptogenesis and excitotoxicity and may lead to neuronal death. In addition, it has been shown that glioma cells can form microtubes—thin tube-like structures with membranes—that can develop functional synapses with nearby neurons (i.e., neurogliomal synapses) that communicate via postsynaptic currents mediated by AMPA-glutamate receptors [8, 9, 10•]. This has led to extensive research into the utility of inhibiting AMPA receptor activity (e.g., perampanel; see below).

Recent research has revealed that the presence of a mutation in IDH can have a direct role in promoting epileptogenesis and is associated with a more aggressive BTRE phenotype in glial tumors, via several different mechanisms [2, 8, 9, 10•, 11, 14, 15]. The IDH mutation results in the conversion of α–ketoglutarate into 2-hydroxyglutarate (2-HG), which accumulates in and is secreted by glioma cells and has structural similarity to glutamate. 2-HG is able to function as a glutamate agonist, further increasing excitatory tone by activating NMDA receptors in surrounding neurons—thereby promoting epileptogenesis. In addition, recent in vitro data from Mortazavi and colleagues [16] suggests that the presence of elevated levels of D-2-HG results in metabolic re-programming of peritumoral neurons, such that they become hyperexcitable—including elevated spiking activity. This alteration of neuronal excitability and metabolic activity is mediated via upregulation of the mTOR signaling pathway.

In parallel with the increase in glutamatergic excitatory activity in the peritumoral region, there is also a reduction of inhibitory γ-aminobutyric acid (GABA) input to neuronal cells, further increasing the potential for epileptogenesis [2, 8, 9, 10•, 11, 12]. There is evidence for altered expression of chloride transporters on the neuronal surface, with an increase in the concentration of Na⁺-K⁺-Cl⁻ cotransporter 1 (NKCC1) and a reduction in the concentration of Cl⁻-K⁺ symporter 5 (KCC2). These alterations result in increased neuronal concentrations of Cl⁻, so that when GABA_A receptors are activated there is an efflux of Cl⁻ out of the cell, resulting in a paradoxical depolarization and activation of the neuron [12]. In addition, upregulation of several subunits of the GABA_A receptor (α1, α5, β1, β3) on glioma cells may lead to impairment of tonic GABAergic inhibition, and thus increased neuronal excitability.

In addition to the mechanisms reviewed above, other contributors to the process of peritumoral epileptogenesis include reduced expression of glutamine synthetase in regional astrocytes, increased expression of aquaporin-4 channels in glioma cells, and reduced expression of hypoxia-inducible factor 1α (HIF-1α) and signal transducer and activator of transcription 5B (STAT5B) in glioma cells [2, 8, 9, 10•, 11].

As noted above, the overall frequency of seizure activity in brain tumor patients ranges from 35 to 70%, with seizures at presentation in 20–40% [1‐5, 6•]. In another 10% of patients, seizures will be experienced at some point during the course of their illness. Before we review the use of antiepileptic drugs (AEDs) and pharmacological approaches in BTRE patients, it will be useful to briefly discuss the efficacy of non-AED—antitumor—approaches to seizure control.

The general consensus among Neuro-Oncologists, Epileptologists, and Neurosurgeons is that after a single verified seizure—either witnessed or with an unequivocal history—a patient with a primary or metastatic brain tumor should be placed on an AED, and will be considered to have BTRE [2‐5, 6•, 8, 21]. This is also the official position of the International League against Epilepsy (ILAE), as well as from an updated Society for Neuro-Oncology (SNO) and European Association of Neuro-Oncology (EANO) practice guideline [21, 22•]. Tumor histology, grade, location in the brain, and molecular markers do not play a role in determining if the patient should be placed on an AED, or which AED should be the first choice. Since most BTRE seizures are of the focal or partial type, the potential AEDs to consider should be approved for that indication. In addition, the efficacy of the available AEDs against BTRE events are fairly equivalent, so the final choice for the initial AED monotherapy will also be determined by patient-related factors, such as age, organ dysfunction, co-morbidities, concomitant drugs, and other therapies, as well as the side effect profile of the individual AEDs [2‐5, 6•, 8, 21]. For patients with BTRE, it is best to avoid first-generation AEDs that are hepatic CYP3A4 enzyme inducers (EIAED), such as phenytoin, carbamazepine, and phenobarbital, due to the risk of compromising concurrent chemotherapy. Second-generation AEDs that are non-enzyme inducers (NEIAED) are usually the best choice for BTRE and include levetiracetam (LEV), lacosamide (LCM), lamotrigine, valproic acid (VPA), topiramate, and zonisamide (see Table 1). Of the available NEIAEDs to consider for initial monotherapy, the two with the most evidence for efficacy against focal epilepsy are LEV and VPA, which have Class 1A and 1B evidence, respectively.

For grade 2–4 glioma patients with BTRE, there has been a recent meta-analysis by de Bruin and colleagues [23••] of the efficacy and tolerability of AEDs. They evaluated the outcomes data for AED monotherapy and polytherapy from 66 studies. In terms of the efficacy of monotherapy, the highest seizure freedom rate at 6 months was with phenytoin, while at 12 months LEV and pregabalin demonstrated the highest efficacy. For ≥ 50% seizure reduction rates, LEV was noted to have the highest efficacy at 6 and 12 months. In addition, LEV had the lowest treatment failure rate. When using polytherapy with follow-up ≥ 6 months, the most efficacious combinations were LEV with phenytoin or VPA. Lacosamide was also considered to be an excellent choice for add-on therapy in BTRE. This data is consistent with the results of a recent international survey of European Neuro-Oncology professionals, in terms of their AED preferences in brain tumor patients [24•, 25]. The vast majority of respondents prescribed an AED in the setting of BTRE for patients with gliomas (98%), meningiomas (85%), and brain metastases (90%). Levetiracetam was the first choice of AED in 90% of the respondents, due to the perception of it having the highest efficacy, a favorable adverse event profile, and lack of any significant interactions with antineoplastic treatments. Other choices for a trial of monotherapy or as an add-on AED were LCM, lamotrigine, and VPA. Surgical respondents were more likely to consider using an EIAED as initial therapy for BTRE in comparison to non-surgical respondents. In addition, surgical respondents were also more likely to consider a prophylactic AED in a brain tumor patient without a verified seizure.

As noted above, in a brain tumor patient after a first verified seizure event, there is consensus to initiate an AED for an attempt at monotherapy—LEV is the first option in the majority of cases [1‐5, 6•, 8, 21, 22•, 24•]. If the patient continues to have seizure episodes with initial monotherapy at maximally tolerated doses (which occurs in roughly 50–60% of glioma patients), and there has been some reduction in seizure frequency, then the recommendation would be to add on a second AED; the best initial options for an add-on AED are LCM, VPA, or lamotrigine. If the initial monotherapy did not result in any reduction in seizure frequency at maximum dosing, then one of the other AED options noted above should be started as monotherapy. Refractory BTRE is noted in 15% of GBM patients and 40% of grade 2 gliomas and is present when patients have not achieved seizure freedom after using two AEDs at maximally tolerated doses [1‐5, 6•]. In this setting, it is common to add on a third AED; however, the additional benefit to seizure control has to be weighed against the likely increase in toxicity and side effects. In general, add-on AEDs should have a different mechanism of action to the primary anticonvulsant, in order to reduce the potential for intolerable side effects.