Pharmacotherapy for Dravet Syndrome: A Systematic Review and Network Meta-Analysis of Randomized Controlled Trials

Dravet syndrome (DS), formerly known as severe myoclonic epilepsy of infancy, is a severe developmental and epileptic encephalopathy with onset in the first year of life in previously healthy infants [1]. The syndrome is characterized by drug-resistant, lifelong seizures and is associated with comorbidities such as intellectual disability, behavior disturbances, sleep disorders, and gait problems that negatively impact the quality of life of the patients and their families [1]. Pathogenic variants in SCN1A, the gene that encodes the α-1 subunit of voltage-gated sodium channel Nav1.1, may lead to loss of channel function and are identified in over 80–90% of the individuals with DS [2]. In the central nervous system, Na_V1.1 is highly expressed in many GABAergic inhibitory neurons, and the loss of function of the channel leads to hyperexcitability of the neuronal networks [3].

The pharmacological treatment of seizures associated with DS remains challenging. Seizures are highly pharmacoresistant, people usually require polytherapy to achieve a reduction in the seizure burden, and some drugs such as carbamazepine, oxcarbazepine, lamotrigine, phenytoin, and vigabatrin can even exacerbate seizures [4]. The management of seizures in DS has changed in recent years with the approval of new antiseizure medications (ASMs) for this condition, and the therapeutic landscape is still growing with treatment options in clinical development.

This study aims to systematically evaluate and summarize the available evidence about the efficacy and tolerability of the ASMs for managing seizures in DS and to assess their comparative efficacy and tolerability by performing a network meta-analysis (NMA) of randomized controlled trials (RCTs). Compared with a recent NMA that also assessed the efficacy and safety of adjunctive ASMs for DS [5], the present study aims to consider additional outcomes and provide subgroup analyses.

There is high-quality evidence from randomized, placebo-controlled trials about the efficacy of either stiripentol, pharmaceutical-grade cannabidiol, fenfluramine hydrochloride, or soticlestat as treatments for convulsive seizures associated with DS. Each of these drugs acts by different mechanisms of action. The antiseizure activities of cannabidiol are mainly due to the inhibition of the reuptake of adenosine and modulation of the Ca²⁺ intracellular levels by inhibiting the G-protein-coupled receptor GPR55, desensitizing the transient receptor channel TRPV1 and modulating the M-current of Kv7.2/7.3 [29, 30]. Fenfluramine has a multimodal mechanism of action enhancing serotoninergic transmission both directly by acting as an agonist of 5-HT_1D, 5-HT_2A, and 5-HT_2C, and indirectly by increasing extracellular serotonin, while it also positively modulates σ-1 receptors [31‐34]. Stiripentol potentiates the GABAergic transmission by inhibiting the synaptosomal uptake of GABA and/or GABA transaminase and by acting as a positive allosteric modulator of GABA_A receptors at a site that is different from benzodiazepines [27] or inhibiting spike-and-wave discharges by targeting T-type calcium channels [35]. Moreover, stiripentol potentiates the efficacy of other ASMs such as clobazam, sodium valproate, phenobarbital, carbamazepine, and phenytoin through the metabolic inhibition of several isoenzymes, in particular cytochrome P450 (CYP) 2C19 and CYP3A4 [27]. Soticlestat is a selective inhibitor of cholesterol 24-hydroxylase, which plays a role in the homeostasis of cholesterol in the brain [36]. The reduction in the levels of 24S-hydroxycholesterol induced by soticlestat treatment has been shown to decrease glutamatergic signaling via multimodal mechanisms and potentially reduce inflammation, which may affect seizure susceptibility [36]. The NMA suggested that fenfluramine hydrochloride may have greater efficacy than pharmaceutical-grade cannabidiol in the reduction of convulsive seizure frequency, and fenfluramine hydrochloride at dosages of 0.5 and 0.8 mg/kg/day was associated with a higher probability of seizure response than pharmaceutical-grade cannabidiol at either the daily dosages of 10 or 20 mg/kg/day. Interestingly, physicians who participated in the international consensus on the management of DS perceived fenfluramine hydrochloride as the most efficacious maintenance medication for focal or generalized convulsive seizures, and 84% of them believed it should be used as a first or second line [4].

Differences can be identified in the tolerability profiles of the ASMs. The AEs most frequently encountered in clinical trials with the use of pharmaceutical-grade cannabidiol included somnolence, decreased appetite, and diarrhea [21‐23, 37]. The rate of somnolence was higher when cannabidiol was coadministered with clobazam, likely due to the pharmacokinetic interaction that leads to an increase in the serum levels of clobazam and its active metabolite. Elevation in the concentrations of transaminases by threefold or more of the upper limit of the normal range occurred in approximately 15% of the participants randomized to pharmaceutical-grade cannabidiol and was the main cause for treatment discontinuation [21‐23]. Importantly, in all cases, laboratory abnormalities reversed either spontaneously, when the dose of a concomitant ASM was decreased, or when pharmaceutical-grade cannabidiol was tapered or discontinued. The concomitant administration of valproic acid and high levels of transaminases at baseline can increase the risk of hepatotoxicity, which usually develops during the first 30 days and rarely after 100 days of pharmaceutical-grade cannabidiol use [38].

The non-cardiovascular AEs associated with fenfluramine hydrochloride treatment during the clinical trials were decreased appetite, diarrhea, fatigue, and weight loss [24, 25, 39]. Fenfluramine was originally developed as an anorectic drug, and decreased appetite represented the most common AE. Clinically meaningful weight loss, defined as a loss above 7% of body weight, occurred in around 5–20% of participants randomized to fenfluramine hydrochloride and up to 5% of participants randomized to placebo; of note, weight loss did not result in treatment withdrawal in any case [24, 25, 39]. Regarding the cardiovascular safety of fenfluramine hydrochloride, the echocardiographic monitoring during the trials did not identify pathological functional changes in cardiac valves and no signs of pulmonary arterial hypertension in any participant at any time [24, 25]; however, it is worth noting the short observation period in RCTs.

The main AEs associated with the addition of stiripentol in STICLO trials were somnolence, decreased appetite, and decreased weight [19, 27], and in some cases, these AEs disappeared after the decrease in the dose of comedications as planned by the protocol. During the treatment period, an adjustment in sodium valproate and clobazam dose was allowed: the sodium valproate dose could be decreased by 10 mg/kg/day in the event of a severe decrease in appetite or weight loss, and clobazam dose could be decreased by 25% (and then an additional 25% if the AE persists) in the case of drowsiness or hyperexcitability [19, 27]. Hematological AEs observed in the STICLO studies included declining neutrophil and platelet counts. Furthermore, blood counts should be assessed before starting treatment with stiripentol and checked every 6 months unless otherwise clinically indicated [40]. In the trial of soticlestat included in this NMA, lethargy and constipation were the only AEs that occurred, with a difference of ≥ 5% compared with placebo in the pooled cohort of participants with DS and Lennox–Gastaut syndrome; no details were available for the AEs that developed in the DS population only [26]. In a phase Ib/IIa randomized, double-blind, placebo-controlled trial of soticlestat in adults with developmental and epileptic encephalopathies, the only non-serious AEs that occurred in more than one participant in the soticlestat group were dysarthria, lethargy, upper respiratory tract infection, fatigue, and headache. Of these, fatigue and headache were each reported in one placebo-treated participant. Although the trial included one individual with DS, no details about the tolerability were provided according to the diagnoses of participants [41]. The NMA suggested that pharmaceutical-grade cannabidiol could be better tolerated than stiripentol, and pharmaceutical-grade cannabidiol at a dosage of 10 mg/kg/day was associated with a lower proportion of participants experiencing AEs than fenfluramine hydrochloride.

Considerations are required according to known and potential drug–drug interactions, which can significantly influence the efficacy and tolerability profiles of ASMs. Stiripentol is known to inhibit CYP2C19, CYP3A4, CYP2D6, and likely other enzymes, leading to an increase in the plasma levels of several drugs [40]. The combination of stiripentol with clobazam, which leads to increased levels of clobazam and its active metabolite N-desmethylclobazam, represents a mainstay of DS treatment. Stiripentol also inhibits the metabolism of fenfluramine hydrochloride and leads to an increase in the plasma concentrations of the latter; this interaction has imposed a limitation on the maximum fenfluramine hydrochloride dose to be used when combined with stiripentol to reduce the risk of adverse effects [42]. Of note, the use of fenfluramine hydrochloride at a dosage of 0.5 mg/kg/day relied on the use of concomitant stiripentol (plus valproate or clobazam, at a minimum), which is known to increase fenfluramine plasma levels, as an entry criterion to the trial [25]. Pharmaceutical-grade cannabidiol can both induce and inhibit several enzymes involved in the metabolism of drugs and cause drug–drug interactions. By inhibiting the catalytic activity of CYP2C19, cannabidiol determines a two- to fourfold increase in plasma concentrations of N-desmethylclobazam [21, 43, 44]. An interaction also exists with fenfluramine hydrochloride, whose levels are increased by the concomitant use of cannabidiol; however, dose adjustments are unlikely to be required and there are no restrictions in the concomitant use of these two drugs [42]. Of note, the potential impact of the interaction between fenfluramine and cannabidiol was not explored in the RCTs as people taking cannabidiol were excluded. Fenfluramine is reported to induce CYP3A4 and CYP2B6 and minimally inhibit CYP2D6, suggesting potential interactions with other drugs [42].

This systematic review represents a comprehensive analysis of the currently available evidence from RCTs regarding the ASMs for treating convulsive seizures in DS. It performs a comparative assessment of the efficacy and tolerability of the different drugs and considers additional outcomes and subgroup analyses compared with prior work in the literature [5]. The results by daily doses may provide clinically useful information, and the subgroup analyses of trials with a maintenance phase of at least 12 weeks may minimize the risk to assess effects that are short-lasting [18]. However, some limits need to be considered in the interpretation of the results. Only one single RCT of soticlestat was included and some of the estimates were associated with wide CIs. Furthermore, data regarding AEs associated with soticlestat were only available for the pooled population of participants with DS and Lennox–Gastaut syndrome and could not be considered in the NMA. In this regard, a global trial testing soticlestat as add-on therapy in a larger cohort of people with DS is ongoing and is expected to enrol approximately 142 participants worldwide (ClinicalTrials.gov: NCT04940624). Randomized, controlled trials were available for pharmaceutical-grade CBD oral solution, and results cannot be translated to other cannabis-based or non-purified products. The low rates of seizure-free individuals across the trials may have hampered the likelihood to reach a statistical power adequate to detect differences between the interventions and led to extreme results due to the imprecision and uncertainty. None of the included trials were rated as having a high risk of bias, but pharmaceutical companies sponsored all of them. Some differences in the characteristics of studies and populations as well as the broad interpretation and different definition of ‘convulsive seizures’ across the trials need to be acknowledged. The general shortcomings of the clinical trials, such as their short duration, may also limit the external validity of the findings. A further overall weakness of the RCTs is that they have all been conducted in children and did not include adults with DS. Real-life and cost-effectiveness data will complement the current evidence and better clarify the therapeutic potentialities and positioning of these ASMs.

According to the practical guides, valproic acid and clobazam represent the first-line drugs for treating DS, although no randomized, placebo-controlled studies have specifically investigated these medications in people with this developmental and epileptic encephalopathy [45]. Nowadays, there exists first-class evidence that documents the efficacy and tolerability of stiripentol, pharmaceutical-grade cannabidiol, fenfluramine hydrochloride, and soticlestat for the treatment of seizures associated with DS, and allows physicians to have reliable data and discuss with the caregivers of people with DS about the expected outcomes regarding seizure frequency reduction and tolerability profiles. Three of these drugs have already been approved by regulatory agencies, and the demonstrated efficacy may support their earlier use in the treatment paradigm [4]. Although only head-to-head trials may draw definitive evidence about how one drug compares with the others, similar studies are unlikely to be conducted. In this scenario, NMAs can offer reliable cues to decipher the comparative efficacy and tolerability of ASMs and inform evidence-based healthcare decision making [46‐49]. The indirect comparative analyses suggested fenfluramine hydrochloride and stiripentol to be more efficacious therapeutic options than pharmaceutical-grade cannabidiol, and pharmaceutical-grade cannabidiol to be overall better tolerated than stiripentol and fenfluramine hydrochloride. These data support the recently proposed therapeutic algorithm, which considers fenfluramine hydrochloride and stiripentol as first- or second-line and pharmaceutical-grade cannabidiol as third-line maintenance therapies for seizures due to DS [4]. Importantly, treatment needs to be individualized on a case-by-case basis and the selection of the drug for any person with DS should rely on an evidence-based framework, integrating the best available evidence for efficacy and tolerability, risk of drug interactions, presence of comorbidities, and preferences of the caregivers [4, 51].

New options are under development for the treatment of DS. Randomized trials to investigate serotonin modulators such as clemizole (ClinicalTrials.gov: NCT04462770), lorcaserin (ClinicalTrials.gov: NCT04572243), and LP352 (ClinicalTrials.gov: NCT05364021) are recruiting participants. Furthermore, strategies targeting the underlying cause of DS, such as antisense oligonucleotides [50] and gene therapy (ClinicalTrials.gov: NCT05419492) are on the horizon. Although current treatments focused mainly on seizure reduction, non-seizure-related comorbidities should also be addressed. Disease-modifying therapies that can interfere with the neurobiological process of the disease may have favorable impacts on the overall quality of life for both people with DS and caregivers. Functional analysis for evaluating the consequences of pathogenic variants may also be relevant to tailor the appropriate treatment [52]. Finally, the research activity and progress for DS may lead to further advances in the treatment of other genetic epilepsy syndromes and developmental epileptic encephalopathies.