Systematic Review and Meta-Analysis of the Efficacy and Safety of Perampanel in the Treatment of Partial-Onset Epilepsy

Epilepsy is a set of chronic neurological disorders involving a predisposition to generate seizures [1]. According to the WHO, approximately 50 million people in the world have epilepsy, and about 80 % of cases are found in developing countries [2]. Pharmacological treatment is the first-line intervention for partial-onset epilepsy. Antiepileptic drugs (AEDs) that aim to suppress seizure occurrence have been widely used in epilepsy treatment. Clinical guidelines have been issued for the management of epilepsy [3, 4]. These guidelines suggest that the use of AEDs should be personalised, and the choice of AEDs should be based on factors including the patient’s epilepsy syndrome, seizure type and lifestyle. A variety of AEDs have been designed to target different mechanisms involved in seizure development. Common mechanisms of AEDs include the blocking of sodium or calcium channels, activation of potassium channels, enhancement of gamma aminobutyric acid (GABA) activity and inhibition of excitatory amino acids [5].

Perampanel is a highly selective and non-competitive antagonist of the α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) glutamate receptor [6]. AMPA receptors are found on the excitatory synapses in the central nervous system [7]. These receptors mediate fast synaptic signalling by the binding of glutamate, which is an excitatory neurotransmitter. Overexpression of AMPA receptors plays a crucial role in the forming and spreading of seizures. Therefore, as an AMPA receptor antagonist, perampanel produces an antiepileptic effect. The European Medicines Agency (EMA) and the US FDA approved perampanel under the trade name Fycompa^® in July 2012 and October 2012, respectively [8]. It is a first-in-class AED approved for adjunctive treatment of partial-onset seizure in patients aged 12 years or older.

A meta-analysis study conducted by Gao et al. [9] investigated the efficacy and safety of six AEDs, including eslicarbazepine, retigabine (or ezogabine), carisbamate, lacosamide, brivaracetam and perampanel. Gao et al. assessed efficacy using the 50 % responder rate, and the odds ratio (OR) of perampanel compared with placebo was reported to be 1.79 (95 % CI 0.88–3.63; p = 0.11). Randomised controlled trials (RCTs) of perampanel included in the study by Gao et al. (labelled as study 206 and 208) were designed to investigate tolerability, and therefore only provided preliminary efficacy results [10]. The small sample sizes in the two studies may not be sufficient to obtain a conclusive result.

There is a need to conduct a meta-analysis with a larger dataset and an appropriate study design. We conducted a meta-analysis to combine evidence from currently available RCTs and further investigated the efficacy and safety of perampanel. Two dose-escalation phase II studies (labelled as studies 206 and 208) and three placebo-controlled phase III studies (labelled as studies 304, 305 and 306) were included in our analysis [10‐13].

This systematic review was conducted according to the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) statement [14]. The Cochrane Library [Cochrane Central Register of Controlled Trials (CENTRAL); Cochrane Database of Systematic Reviews; and Cochrane Epilepsy Group Register], EMBASE and PubMed electronic databases were used to perform the literature search. The following search terms were used: (perampanel) OR (Fycompa) OR (E2007). In order to identify relevant potential studies, the following trial registers were used: the WHO International Clinical Trials Registry Platform [ICTRP] (http://​www.​who.​int/​ictrp/​en/​), the US National Institutes of Health Clinical Trials Registry (http://​www.​clinicaltrials.​gov) and the metaRegister of Controlled Trials [mRCT] (http://​www.​controlled-trials.​com). The search was performed on 11 March 2013. Titles, abstracts and the content of the articles were screened to determine whether the articles met the inclusion criteria. The reference lists of the articles that met the inclusion criteria were also screened to identify potentially relevant studies. The searching workflow is shown in Fig. 1.

The use of perampanel at doses of 4, 8 and 12 mg resulted in statistically significant reductions in seizure frequency with respect to the 50 % responder rate in patients with partial-onset epilepsy compared with those treated with placebo. Our meta-analysis showed that the withdrawal rate due to any cause in the 12 mg perampanel group was significantly higher than that of the placebo group with OR of 2.03 (95 % CI 1.15–3.58). However, no statistically significant differences were observed between 4 mg or 8 mg perampanel and placebo in withdrawal due to any cause.

The previous meta-analysis of Gao et al. [9] did not show statistical evidence of a difference between perampanel and placebo in reducing seizure frequency in terms of 50 % responder rate. It is likely due to the limited number of studies available at the time of their meta-analysis. Our meta-analysis included more patients and has sufficient power to confirm the efficacy. Gao et al. also reported the 50 % responder rate ORs for eslicarbazepine, retigabine, carisbamate, lacosamide and brivaracetam to be 2.43 (95 % CI 1.77–3.35), 2.81 (95 % CI 2.09–3.78), 1.49 (95 % CI 1.19–1.88), 2.11 (1.58–2.82) and 3.78 (95 % CI 1.73–8.26), respectively. Our results on 4, 8 and 12 mg perampanel were all comparable with that results of Gao et al. on the five individual AEDs, suggesting significantly higher 50 % responder rates in the AEDs when compared with placebo.

The individual ORs (treatment groups/placebo groups) for withdrawal rates of eslicarbazepine, retigabine, carisbamate, lacosamide and brivaracetam were 1.12 (95 % CI 0.71–1.79), 2.33 (95 % CI 1.56–3.45), 1.52 (95 % CI 0.78–2.94), 2.78 (95 % CI 1.39–5.56) and 0.29 (0.09–0.99) in the study by Gao et al. Our results on 4 mg and 8 mg perampanel were comparable with the results for eslicarbazepine and carisbamate in the study by Gao et al., suggesting non-significant differences in withdrawal rate in the AEDs when compared with placebo. On the other hand, our result on the withdrawal rate due to any cause of 12 mg perampanel was consistent with the ORs of Gao et al. for retigabine and lacosamide, which showed significantly higher withdrawal rates in the AED groups when compared with placebo. In order to confirm the results and compare perampanel with other AEDs, further head-to-head direct comparison studies are needed.

Perampanel treatments at 4, 8 and 12 mg had all resulted in higher 50 % responder rates compared with the placebo group. A non-statistically significant dose-dependent effect was observed. Comparing the three dose groups on the forest plot (Fig. 2), the use of 8 mg perampanel appeared to result in a slightly higher responder rate than when using 4 mg. This dose-dependent effect seems to be saturated when the dose reached 8 mg, as a difference could not be observed when comparing 8 mg and 12 mg. The manufacturer of perampanel recommends a starting dose of 2 mg daily and a maximum daily dose of 12 mg as adjunctive treatment of partial-onset seizure in patients aged 12 years or older [21]. They also state in their prescribing information that the use of a daily dose of 12 mg may lead to a moderately improved reduction of seizure frequency compared with the use of a daily 8 mg dose [21]. However, our study did not show any clear difference in 50 % responder rate when comparing the use of 8 mg and 12 mg perampanel.

Freedom from seizures is one of the main goals of AED treatment. However, our meta-analysis did not demonstrate a statistically significant improvement in seizure freedom with 8 or 12 mg perampanel when compared with placebo. This finding is consistent with that of the meta-analysis conducted by Martyn-St James et al. [22] who also reported a non-statistically significant improvement in seizure freedom in patients treated with eslicarbazepine acetate, lacosamide and tiagabine compared with patients treated with placebo. These results probably reflected the fact that the populations selected for the study by Martyn-St James et al. and our included add-on clinical trials were patients with difficult-to-treat epilepsy. All the patients recruited in our included RCTs were patients with partial-onset epilepsy despite being treated with at least two AEDs prior to the baseline period. This suggests that the recruited patients were likely to be drug resistant; therefore, the poor outcome in seizure freedom was not unexpected.

Dizziness and somnolence are common adverse events found in many AEDs [22, 23]. In the study by James et al., the AEDs eslicarbazepine acetate, lacosamide, pregabalin, retigabine, tiagabine and zonisamide were statistically associated with the increased incidence of dizziness compared with placebo. Notably, there was a statistically significant increase in the incidence of somnolence with pregabalin, retigabine and zonisamide versus placebo. Our meta-analysis demonstrated a statistically significant increase in the incidence of dizziness for 8 mg or 12 mg perampanel versus placebo. Our study also showed a statistically significant association between the use of 8 mg perampanel and an increased incidence of somnolence. We were not able to investigate rare adverse events since the included studies only reported the common TEAEs. Furthermore, rare adverse events may not be apparent in the relatively small number of patients treated with perampanel over such short follow-up periods.

Data for the use of 2 mg perampanel could only be found in study 306 [13], and it was not included in the meta-analysis. Based on data from study 306 only, the RR for 50 % responder rate was calculated to be 1.15 (95 % CI 0.75–1.75). There was no evidence of a statistically significant association between the use of 2 mg perampanel and a change in the 50 % responder rate. RRs were also calculated for the TEAEs and withdrawal rates, and there was no statistical evidence of an association between the use of 2 mg perampanel and the incidence of withdrawal for the five commonly reported TEAEs (dizziness, somnolence, headache, fatigue and nasopharyngitis).

Our study included all relevant published RCTs investigating perampanel to date. No unpublished or ongoing RCTs on perampanel treatment for patients with partial-onset epilepsy were identified in the three trial registers; therefore, it is reasonable to assume that the results of our meta-analysis are unlikely to change in the foreseeable future. Data extraction and statistical analysis were carried out by independent reviewers and carefully cross-checked.Several potential study limitations are worthy of mention. Firstly, the number of studies and RCTs exploring perampanel was relatively small. Only five studies were included in this meta-analysis and all were pharmaceutical company funded.

The second limitation was the inclusion of studies 206 and 208, which were relatively different from those others included in terms of design and data presentation. The reported responder rates in studies 206 and 208 were calculated using pooled data across different dose groups, while the other included studies reported responder rates independently for each dose group. Despite this, the sensitivity analysis showed that the overall conclusions were not materially altered by removing or moving study 208. Traditionally, newly-marketed AEDs are evaluated in patients with severe epilepsy as on-add treatments for short-term RCTs. Perampanel is no exception and we were only able to identify add-on trials. Consequently, we were not able to identify RCTs that evaluated perampanel as a monotherapy or long-term treatment. We identified one extension study (307) which involved patients from three of the included studies (namely 304, 305 and 306). Study 307 investigated the long-term effect of perampanel [24]; however, it was not included in our analysis as it was an open-label study targeting patients who had already participated in those included studies. Nevertheless, study 307 reported that tolerability and efficacy of perampanel were maintained in the long term. Further long-term RCTs with newly diagnosed patients will be useful in studying the long-term effect of perampanel.

Lastly, it is worthy to note that the common outcome measures in short-term clinical trials investigating epilepsy include 50 % seizure reduction, mean seizure reduction and short-term tolerability. Such parameters are traditionally designed for regulatory purposes. These trials do not provide the impact of the new drugs on mortality and morbidity rates, and often do not report the proportion of patients becoming seizure free [25]. Other important outcomes including ‘time to treatment failure’, ‘time to achieve a 12-month remission of seizures’, quality of life outcomes and health economic outcomes are also used in clinical trials [26]. Future clinical and pharmacoepidemiological studies should be conducted to evaluate the real-life clinical use and define the roles of each new AED in the pragmatic setting [27, 28].

This meta-analysis showed that the use of perampanel resulted in a statistically significant reduction of seizure frequency with respect to the 50 % responder rate when compared with placebo. The safety analysis showed that perampanel was well tolerated at 4 mg and reasonably tolerated at 8 and 12 mg. Further clinical and pharmacovigilance studies will be needed to investigate the long-term efficacy and safety of perampanel and, specifically, the efficacy of perampanel in the management of other types of epilepsy.