Factors Affecting Sleep and Wakefulness in People with Epilepsy: A Narrative Review

Sleep is considered one of the pillars of health. Irregular sleep, more so than sleep duration, is a strong predictor of premature mortality from various causes, including cancer and cardiovascular disorders [1]. The disruption of sleep–wake rhythms can be caused by internal factors that affect circadian rhythms, such as neurodegenerative disorders and visual problems, as well as external factors like behavioral issues or certain medications [2]. People with epilepsy tend to report a worse sleep quality and excessive daytime sleepiness [3], prompting additional research into the matter. Numerous factors contribute to the overall health issues in individuals with epilepsy. These factors can affect both sleep and wakefulness and can either be unmodifiable, such as genetic predispositions, or modifiable, such as antiseizure medication.

Given that epilepsy is a heterogeneous disorder, it is safe to assume that sleep–wake profiles are different in each individual with epilepsy. In this narrative review, we explore the factors that might influence sleep and wakefulness in people with epilepsy. In particular, we present an overview of the current evidence regarding molecular circadian system alterations in the context of seizures, the influence of seizures and interictal activity on sleep and circadian rhythms, and the influence of various syndromes, comorbidities, and antiseizure medications on sleep and wakefulness (Figure 1).

A comprehensive search was carried out across the MEDLINE (PubMed), Google Scholar, and ScienceDirect databases. The searches were performed using specific combinations of keywords: “epilepsy”, “seizures”, “sleep”, “circadian”, “sleep-wake rhythm”, “sleep structure”, “sleep architecture”, “antiseizure medication”, “anxiety”, “mood disorders” and, “psychosis”. The rest of the keywords included syndromes and etiologies associated with epilepsy and different groups or individual antiseizure medications. Further, titles and abstracts were screened for relevance. Full-text studies were assessed based on the criteria provided below.

Studies were included if they focused on disturbances or alterations in sleep, wakefulness, sleep–wake rhythms, circadian rhythms, sleep structure in people or animals with epilepsy, and epilepsy-related factors—comorbidities, syndromes, and antiseizure medications. Articles were included if they were published in English and were original research articles, systematic reviews, meta-analyses and observational studies. We included animal studies when human studies were scarce. Most of the animal studies are presented in. The search considered studies published from 1984 until April 2025. We included some historical studies from the 1990s and 1980s due to their relevance to the topic and lack of similar studies in the present day. Section 3

Studies were excluded if they were written in a language other than English or were duplicates from other databases. Editorials, letters, commentaries, and other articles that were not peer-reviewed were also excluded. Studies not examining thematic areas described previously were omitted.

The selected studies were analyzed, and data regarding disturbances or alterations in sleep, wakefulness, sleep–wake rhythms, circadian rhythms, and sleep structure in people or animals with epilepsy and epilepsy-related factors (comorbidities, syndromes, and antiseizure medications) were extracted. Key studies were organized in summary tables.

The master circadian pacemaker is in the suprachiasmatic nucleus (SCN) of the ventral hypothalamus and transmits the photic input of the light–dark cycle to peripheral clocks in the rest of the brain and the body [4]. These rather autonomous clocks can be entrained via environmental factors to maintain the body’s rhythmicity in various processes, including the sleep–wake cycle [5]. The internal molecular circadian rhythm is maintained by regulators that positively or negatively affect the transcriptional or translational processes. Proteins such as BMAL1 and CLOCK, encoded in genes BMAL1 and CLOCK, respectively, are the core transcription factors that have a variable influence on the mammalian circadian gene network, which in turn is linked to the regulation of cell metabolism and physiology at different times in the circadian rhythm [6]. Important pathways of the metabolism associated with epilepsy, such as pyridoxal, mTOR, and redox state, are linked to the molecular circadian system [7]. An overview of studies exploring the alterations in the circadian molecular system in animal models of epilepsy is presented in Table 1.

Given the heterogeneity of epilepsy, it might be expected that different epilepsy models, although to a varying degree, exhibit altered clock gene expressions and changes in circadian rhythms. A mesial temporal lobe epilepsy model showed circadian phase alterations and fragmentation in post-status epilepticus (SE), along with altered temporal transcriptions of Bmal1, Cry1, Cry2, Per1, Per2, and Per3 in baseline, early post-SE and epileptic conditions [8], indicating the possible involvement of clock genes during epileptogenesis. Additionally, in a pilocarpine-induced epilepsy mouse model, it was observed that core body temperature oscillations were significantly lower in epileptic mice, indicating circadian disruption [9]. The same study showed a total decrease in the relative expressions of Bmal1, Clock, Cry1, and Cry2 and an increase in Per1 and Per2 mRNA in the SCN and hippocampus [9]. Moreover, lesions in the SCN were associated with an increase in seizures via diminished GABAergic signaling [9]. This study shows a possible disruption of the circadian system in epilepsy and associations between the impairment of the circadian system and the worsening of seizures. Indeed, in a model of Bmal1 knockout mice, the diurnal seizure threshold was found to be significantly diminished [10]. REV-ERBα is another regulator in the mammalian circadian system and controls BMAL1 transcription [11]. Rev-erbα ablation was associated with a reduction in seizures via diminished GABA reuptake. Interestingly, the disruption of the circadian rhythm in a jet-lag-type manner was associated with a greater resistance to seizures [12]. A study of the Kcna1-null epilepsy mouse model revealed diminished oscillations of Clock, Per1, and Per2 in the hypothalamus and arrhythmic rest–activity patterns [13]. Importantly, no associations were found between changes in sleep parameters and the burden of seizures, indicating that in this epilepsy model, the disruption of the molecular circadian system rather than seizures affected sleep–wake rhythms [13]. Taken together, these studies suggest that the circadian system could be significantly disrupted in epilepsy, and that this is associated with an increase in seizure burden and the alteration of rest–activity rhythms.

A study conducted by Yamakawa and colleagues revealed the dysregulation of the core circadian clock genes Per1, Cry1, Clock, and Bmal1 in the hippocampus, hypothalamus and peripheral tissues such as the liver and small intestine in a mouse model of absence epilepsy [14]. Meanwhile, in a model of drug-resistant temporal lobe epilepsy, the dysregulation of Cry1, Clock, and Bmal1 was more evident in the hypothalamus and liver, along with Cry1 and Clock diurnal dysregulation in the hippocampus [14]. This not only shows the distinct involvement of the circadian molecular system in different types of epilepsy, but also the possible desynchronization of central and peripheral clocks.

Melatonin, also called “a dark hormone”, acts as a synchronizer of the body’s internal clock with light–dark cycles and has receptors in various parts of the brain [15]. A mouse model of temporal lobe SE showed increased mRNA expressions of melatonin 1 and melatonin 2 receptors in the hippocampus at 2 and 11 h post SE and 5 and 11 h post SE, respectively. Both receptors’ mRNA levels were reduced later compared to the levels a few hours post SE [16]. Although the effects of changes in the post-seizure melatonin receptor on the sleep–wake rhythm are yet to be seen, the increase in melatonin receptors in post-SE might be related to its potential seizure-reducing effects and neuroprotective properties [17].

Data on alterations in the circadian molecular system in human tissues are scarce. However, the CLOCK gene was found to be under-expressed in the brain tissue of tuberous sclerosis and focal cortical dysplasia patients with treatment-resistant epilepsy, and plays an important role in the excitatory and inhibitory neuron excitability threshold [18,19]. Meanwhile, CLOCK and REV-ERBα were found to be increased in the brain tissue of patients with temporal lobe epilepsy [12,20]. More studies are needed to draw conclusions on the potential effects of clock genes in homogeneous samples of epilepsy patients.

An increasing body of evidence shows that seizures and interictal activity have circadian and even circannual properties [21,22]. Seizure forecasting is a term describing the prediction of seizure occurrence and is important for managing the timed use of antiseizure medications, a process called chronotherapy [22]. Some epilepsy syndromes have more predictable ictal and interictal activities in relation to vigilance states, e.g., seizures in genetic generalized epilepsies tend to happen upon awakening, while the majority of seizures in self-limiting focal epilepsies occur during sleep [23]. However, seizures and, at least to some extent, interictal activity are events that can significantly affect a person’s quality of life, but data on whether and how ictal and interictal activity affects sleep–wake rhythms are quite scarce. Animal studies have shown that pentylenetetrazol-induced generalized seizures are associated with increased wakefulness before the onset of seizures and diminished slow-wave and REM sleep [24]. To our knowledge, there are no human studies on pre-ictal effects on sleep. A prospective case–control study of 200 epilepsy patients and 100 healthy controls revealed that non-seizure-free patients experienced significantly increased excessive daytime sleepiness (EDS) compared to seizure-free patients. Moreover, 41% of patients with epilepsy complained that nocturnal seizures resulted in EDS the following day, 16% required a nap after a generalized seizure, and 5% had a disturbed night of sleep following a generalized seizure [25]. Similarly, another prospective case–control study that included 160 people with epilepsy showed a significant positive correlation between seizure frequency, increased EDS, and worse sleep quality measures on the Pittsburg Sleep Quality Index (PSQI) [26]. It remains unclear how the much severity and frequency of different types of seizures affect a person’s rest–activity rhythms.

Changes in sleep architecture have been studied extensively in people with epilepsy. An overview of relevant studies is provided in Table 2.

Ictal and interictal activity are associated with increased awakening and arousal, with symptomatic seizures being more frequently associated with awakening [27]. The most common, although to a different extent, findings regarding the disruption of sleep parameters in both mixed and homogenous epilepsy samples are a reduced sleep efficiency and total sleep time, prominent sleep fragmentation, and a reduction in slow-wave and REM sleep [27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44]. It is more likely that people with drug-resistant epilepsy and seizures during the night will have their sleep continuity disrupted more severely. Some studies have found that sleep-disordered breathing could be more common in people with epilepsy [34,37], although this could be an accidental finding in populations with fewer comorbidities.

People with epilepsy may have different sleep–wake profiles based on their age and type of epilepsy. A recent systematic literature review that included 11 studies showed that sleep–wake preferences varies among children with epilepsy, while in adults, waking up early in the morning was preferred, and going to sleep later in the evening was more dominant in patients with generalized epilepsies [45]. Most of these studies are questionnaire-based, and only two involved testing a circadian rhythm biomarker dim-light melatonin onset [45]. It was shown that circadian system impairment in epilepsy might not be related to seizures [13]; however, there are some controversial results in human studies. Decreased melatonin levels in the morning hours were a common finding in patients with febrile seizures [46]. Also, increased melatonin levels were found early in the postictal state, but the base levels were decreased hours after a seizure [47,48]. Further, morning serum melatonin levels were decreased in patients with continuous spikes and waves during sleep, and the basal serum levels of melatonin also decreased in electric status epilepticus in sleep (ESES) patients [49,50]. Despite evidence of an increase in melatonin receptors after a prolonged seizure in previously mentioned rodent studies, no circadian melatonin profile alterations were observed in a small study of epilepsy patients experiencing seizures [51]. Cortisol is another hormone that has circadian properties, with peak levels occurring within the first hour of awakening and being influenced by a variety of factors, such as cognition, mood, or light levels [52]. Seizures can influence cortisol secretion; in particular, cortisol serum levels were found to be increased in the first hour after a seizure [53]. Interestingly, both ictal and interictal activity have been found to be correlated with circadian changes in cortisol levels [53,54]. Peak seizure occurrence follows an increase in cortisol in the early hours of the morning, with a time delay of approximately 2 h. However, another seizure peak in the afternoon was found to be independent of cortisol rhythms [55]. There is a lack of literature regarding other circadian biomarkers, such as core body temperature, and their association with seizures and interictal activity. However, current data on melatonin and cortisol alterations in relation to seizures and prominent interictal activity show the disturbance of normal rhythms in people with epilepsy.

Epilepsy is a heterogeneous disorder. Based on the position of the International League Against Epilepsy Commission for Classification and Terminology Comorbidities, epilepsy can be classified according to its etiology, which includes metabolic, structural, genetic, immune, infectious, and unknown etiologies. Some etiologies might overlap, e.g., structural and genetic or genetic and metabolic [56]. In this paper, we review a few selected syndromes, of which epilepsy is one of the most debilitating phenomena, with sleep problems being a frequent comorbidity. The sleep problems observed in specific syndromes related to epilepsy are summarized in Table 3.

Comorbidities in epilepsy, both somatic and psychiatric, are a frequent phenomenon with a considerable burden [96]. The associations between epilepsy and comorbidities can be causative; these include, for example, frequent seizures and cognitive decline in epileptic encephalopathies. These associations can also be direct or indirect when there is an intermediate factor causing a comorbidity, such as treatment with antiseizure medication resulting in side effects. Some comorbidities are due to shared risk factors like a genetic etiology [97]. Addressing all comorbidities in epilepsy is beyond the scope of this review. However, some are particularly associated with sleep problems.

Antiseizure medications (ASMs) have a broad spectrum of effects on the central nervous system; in particular, sedation is of concern when discussing the effects of ASMs on sleep and wakefulness. Importantly, a subset of patients with monotherapy will not achieve seizure freedom and will require more than one ASM with overall negative outcomes regarding quality of life [126]. We further discuss the effects of ASMs that are reported to exhibit effects on sleep, wakefulness, and sleep structure. The effects of ASMs on sleep are summarized in Table 4.

In this review, we have adopted a rather pragmatic approach to sleep and wakefulness alterations in relation to epilepsy. We discussed how the sleep–wake rhythm, although to different extents, can be impacted by virtually every domain of epilepsy, including by molecular and etiological factors, comorbidities, seizures, interictal activity and antiseizure medication.

In our review, we have included animal studies of molecular circadian systems due to a lack of studies with humans. However, a growing body of evidence shows that alterations in the molecular circadian feedback loop system have a profound negative impact on metabolic and other domains of health. The misalignment of external cues to the circadian system is associated with an increased body weight, insulin resistance, and dyslipidemia [171]. Indeed, at least half of people with epilepsy have metabolic syndrome, although this is related to multiple factors, such as antiseizure medications and a lack of physical activity [172]. Moreover, alterations in CLOCK gene expression and thus changes in the dopaminergic, GABAergic, and glutamatergic systems are associated with known epilepsy comorbidities, such as mood disorders, ADHD, autism spectrum disorder, and schizophrenia [173]. So far, different epilepsy experimental models exhibit different clock gene characteristics in the central nervous system and peripheral tissues. Whether these changes have a meaningful clinical impact on sleep–wake and metabolic rhythms, particularly in people with epilepsy, remains to be seen. However, this prompts further research into more homogeneous samples of epilepsy participants. Also, more human studies are needed to confirm the results of studies utilizing animal experimental models.

So far, it is difficult to quantify how seizures and interictal activity affect sleep–wake rhythms. As shown previously, seizures during sleep and interictal activity are related to increased arousability and sleep fragmentation. Continuous fragmented sleep has a negative impact on cognition and increases the risk of obesity and congestive heart failure, among other deleterious effects [174,175,176]. The postictal state also has a myriad of manifestations, including drowsiness, cognitive dysfunction, and changes in mood, with some even lasting days [177]. Both seizures and related behavioral aspects might play a role in the disruption of normal sleep–wake rhythms. It is interesting that even seizure-free patients tend to demonstrate disturbed sleep–wake rhythms, particularly a delayed sleep–wake pattern, less regular activity–rest patterns, and a fragmented sleep–wake cycle [178]. The impairment of sleep–wake rhythms is most likely multifactorial. Yet, changes in circadian biomarkers, such as melatonin and cortisol, in relations to seizures and interictal activity are seen in people with epilepsy.

Comorbid conditions, syndromes associated with epilepsy, and antiseizure medications by themselves are associated with alterations in sleep profiles via different mechanisms, and it is logical to assume that these factors usually work in combination. Therefore, some sleep issues or alterations might always be present in a patient with epilepsy.

Some disorders present with a phenotype that involves both seizures and sleep disturbances, which might be unrelated, as in cases of mitochondropathies, where excessive daytime sleepiness is primarily due to sleep-disordered breathing. Meanwhile, other syndromes involving nighttime seizures, such as tuberous sclerosis complex, could severely impact sleep due to frequent awakenings. Most of the disorders described in this review are considered rare; therefore, sleep studies are quite scarce. However, patients with rare disorders are usually subjected to multidisciplinary care in specialized centers with an increased awareness of such issues.

Psychiatric comorbidities are not uncommon [179]. Insomnia is a common symptom of psychosis, depression, and anxiety disorders. Similarly, a variety of sleep problems are prevalent in neurodevelopmental disorders, such as autism spectrum disorder and ADHD. Some forms of epilepsy are particularly sensitive to sleep deprivation. Idiopathic (genetic) generalized epilepsies, especially juvenile myoclonic epilepsy, which is also known as awakening epilepsy, are characterized by enhanced interictal activity and an increased risk of seizures after sleep deprivation [23]. Moreover, in cases of focal epilepsy, an increase in sleep duration is associated with a lower risk of seizures in the next two days [180]. Discussing psychiatric and neurodevelopmental comorbidities in people with epilepsy is important, as improving sleep-related issues during a patient‘s visit would be beneficial to both their quality of life and seizure control.

Another layer of complexity in the issues discussed is introduced with ASM. As was shown previously, almost every ASM has some effect on sleep and wakefulness. The most common side effect is EDS, which is mostly seen in BZD and barbiturate users. So far, it is difficult to quantify the burden of sleep structure alterations associated with the chronic use of ASM. This is due to studies including low sample sizes and heterogeneous groups of patients, with the most controversial results presented in CBD, LTG, LCZ, LEV, and PER studies. Some ASM, such as PER, are shown to improve sleep structure, but this is most likely related to the control of seizures.

Currently, the management of sleep disorders and sleep problems in people with epilepsy remains similar to that without epilepsy. However, some additional aspects should be considered. Sleep hygiene is related to a worse quality of life in people with epilepsy [181], therefore suggesting that proper sleep practices, including regular sleep schedules, are essential. An expert opinion on managing sleep disturbances in people with epilepsy has recently been published. The authors suggest that, along with proper sleep practices, the revision and optimization of antiseizure medications, the consideration of nocturnal seizures, and the detection and treatment of concomitant sleep disorders based on currently existing guidelines are essential if the patient complains of insomnia or excessive daytime sleepiness [182].

Studies exploring the molecular circadian system in human epilepsy patients are incredibly scarce. Animal studies show various alterations in molecular circadian systems in different epilepsy models. Future studies on molecular circadian systems should include homogeneous samples of epilepsy patients. Moreover, data on peripheral circadian markers and sleep–wake rhythm behaviors in people with epilepsy are still needed. Taking together, these data could provide valuable insights into the different circadian profiles of epilepsy patients, circadian aspects of seizures, and interictal activity, and would become a useful tool for predicting seizures and applying pharmacological treatment.

Sleep disturbances are common in various syndromes and comorbidities associated with epilepsy. Various sleep problems are associated with syndromes related to epilepsy. However, these syndromes are usually considered rare disorders. Therefore, multicenter studies that include larger sample sizes of patients are needed. Further, studies of epilepsy patients with comorbid psychiatric and neurodevelopmental disorders could highlight the differences between populations with and without seizures.

Sleep studies exploring the effects of epilepsy on sleep include mixed samples of patients, such as drug-naïve patients and patients with polytherapy. To better distinguish alterations in sleep parameters in people with epilepsy, more homogenous samples of drug-naïve patients should be included in longitudinal studies measuring polygraphic parameters before and during treatment.

In this review, we have presented multiple epilepsy-related factors that impact sleep and wakefulness. The molecular circadian system is likely involved in both ictal activities and sleep–wake rhythm disturbances. However, more studies with human epilepsy patients are needed. Seizures and interictal activity could be related to sleep and circadian rhythm disruption. Therefore, adequate seizure control is required. Comorbid conditions and syndromes by themselves have a negative impact on sleep and wakefulness; thus, screening for sleep problems in these conditions is mandatory. Alterations in the sleep structure and excessive daytime sleepiness can be related to antiseizure medications; however, bigger longitudinal studies are needed to confirm the current findings.

Conceptualization, D.B. and G.J.; methodology, D.B. and G.J.; writing—original draft preparation, D.B., G.G., E.P., G.S., V.M. and G.J.; writing—review and editing, D.B., G.G., E.P., G.S., V.M. and G.J.; visualization, D.B.; supervision, V.M. and G.J. All authors have read and agreed to the published version of the manuscript.

No new data were created or analyzed in this study.

The authors declare no conflicts of interest.

This research received no external funding.