E-ISSN: 2792-0550
Sex Differences in Epilepsies: A Narrative Review
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Review
VOLUME: 30 ISSUE: 4
P: 100-103
December 2024

Sex Differences in Epilepsies: A Narrative Review

Arch Epilepsy 2024;30(4):100-103
DOI: 10.4274/ArchEpilepsy.2024.24124
Ali A. Asadi-Pooya 1,2
Modhi Alkhaldi 3
Nafiseh Mirzaei Damabi 1
Khatereh Fazelian Dehkordi 1
1. Shiraz University of Medical Sciences, Epilepsy Research Center, Shiraz, Iran
2. Thomas Jefferson University, Jefferson Comprehensive Epilepsy Center, Department of Neurology, Philadelphia, USA
3. Imam Abdulrahman Bin Faisal University, College of Medicine, Department of Neurology, Dammam, Saudi Arabia
No information available.
No information available
Received Date: 05.05.2024
Accepted Date: 20.08.2024
Online Date: 15.11.2024
Publish Date: 15.11.2024
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Abstract

Epilepsy affects people of all ages and sexes. The aim of the current narrative review was to summarize the sex differences in patients with epilepsy. In January 2024, we systematically searched PubMed for relevant articles. The following keywords were used: “Epilepsy” or “Seizure” and “Sex”. The prevalence and symptomatology of many neurological conditions, including epilepsy syndromes, may differ between male and female patients. The reasons behind these sex differences are not yet clear. It is likely that sex hormones, neurosteroid, and sex chromosome gene differences play roles in the development of this phenomenon. The existence of sex differences in epilepsy is well recognized, but there is little discussion of their mechanisms and therapeutic implications. Future research should investigate the exact roles of sex hormones, neurosteroid, and genes in the development of sex differences in epilepsy. Similarly, future studies should investigate whether sex differences exist in seizure characteristics (e.g., seizure frequency, semiology, response to treatment, outcome) in different syndromes. These issues may have important clinical implications for designing appropriate sex-specific treatment strategies for various syndromes and conditions. Furthermore, sex should be considered as a biological variable in basic and clinical research.

Keywords:
Epilepsy, gene, hormone, seizure, sex

MAIN POINTS

• Systematically, PubMed was searched in January 2024.

• Keywords: “Epilepsy” or “Seizure” and “Sex”.

• Epilepsy syndromes are affected by sex hormone, neurosteroid, and sex chromosome genes-related brain differences.

INTRODUCTION

Gender and sex disparities exist in all aspects of human life; they may represent biology, bias, or both. In general, “sex” refers to the biological differences between males and females, while “gender” refers to the role of a male or female in society.1 Sex differences in the characteristics of neurological conditions may be explained by the actions of sex hormones and also by sex chromosome gene-related brain differences.2 These sex differences may influence the clinical characteristics, management, and even outcomes of neurological conditions.3

Evidence from human and animal studies supports a bidirectional relationship; the role of sex on seizures and epilepsy, as well as changes in the endocrine system and levels of sex hormones by epilepsy.4 The aim of the current narrative review was to summarize the biological reasons for sex differences in people with epilepsy.

In January 2024, we systematically searched PubMed for relevant articles. The following keywords were used: “Epilepsy” or “Seizure” and “Sex”. We included all original studies and articles written in English. Both authors independently participated in the screening, eligibility, and inclusion phases of the study. The authors collected the full manuscripts for all publications that appeared to meet the inclusion and exclusion criteria. The inclusion criteria were all human studies on sex differences in epilepsies (i.e., retrospective, cross sectional, case-control, case series, prospective trials, etc.), review articles, and articles written in English. The exclusion criterion was gray materials (i.e., letters, etc.) Because this was a narrative review, we did not follow the recommendations of the preferred reporting items for systematic reviews and meta-analyses statement; therefore, we did not track the number of identified papers in each step of the work.

Sex Differences in Patients with Epilepsy

The prevalence and symptomatology of many neurological conditions, including epilepsy syndromes, may differ between male and female patients. Although the sex differences in the incidence of epilepsy do not reach a significant difference, consistent trends across many studies suggest that the incidence and prevalence of epilepsy are slightly higher in males than in females, in general.4, 5 Sex differences in seizure susceptibility may result from differences in factors, such as steroid hormone levels, cytochrome P450 activity, and biological factors in the brain.6, 7 These differences are most likely multifactorial phenomena, and many factors may contribute to these differences (e.g., environmental factors and lifestyle). In this review, we focused on the neurobiology of sex differences in various epilepsy syndromes.

Idiopathic Generalized Epilepsy

Female patients often outnumber male patients with idiopathic generalized epilepsy (IGE). The sex (female to male) ratio of the whole cohort of patients with IGE was approximately 1.5 in various studies.8-10 This sex disparity is to some extent syndrome-related in patients with IGEs; the female-to-male ratio was significantly higher in patients with juvenile myoclonic epilepsy (JME) (of 1.8) compared with those in other syndromes of IGE (e.g., 1.33 in childhood absence epilepsy) in one study.10 It is likely that sex hormones, neurosteroid, and sex chromosome gene differences play a role in the development of the aforementioned phenomenon (Figure 1).11-13 Considering the peripubertal onset of JME, it is plausible to assume that the expression of genes that increase susceptibility to myoclonic seizures is regulated or affected by sex steroids.14 In addition, it is hypothetically possible that mutant epilepsy genes have greater penetrance in females and males.15

Both female and male sex steroid hormones may influence brain excitability. Progesterone and its metabolites are anticonvulsants, whereas estrogens are mainly proconvulsants. The results from clinical studies have been supported by several animal studies that have demonstrated increased and decreased seizure frequencies after estrogen and progesterone administration, respectively.11

Androgens have more varied effects, although a generally antiseizure effect has been suggested; testosterone increases the electroconvulsive threshold in males at low doses and in both sexes at higher doses.11The effects of sex hormones on neuronal excitability and seizures involve complex mechanisms that are difficult to separate, as they range from regulation of gene expression to rapid effects via activation of various membrane receptors or acting as ligands on neurotrophin and ion-channel coupled receptors.4 Furthermore, sex hormone surges during distinct maturation periods may also affect brain function and seizure outcomes (e.g., by inducing sexual differentiation of regions responsible for seizure control or initiation, or brain maturation).4 Some epilepsy syndromes may either remit (e.g., childhood absence epilepsy) or have onset (e.g., JME) around the adolescence ages, indicating the likely influence of sex hormone changes and brain maturation occurring around puberty.4

Neurosteroids are key endogenous molecules in the brain that can affect many neural functions.12 Neurosteroids are known for their nongenomic effects via the direct modulation of N-methyl-D-aspartate and gamma-aminobutyric acid (GABA)-A receptors. Neurosteroids are mainly responsible for the “fine tuning” of neuronal excitability by acting at synaptic and extrasynaptic receptors.4 The neuronal GABA-A receptor chloride channel is a prime molecular target of neurosteroid.12 At low concentrations, neurosteroid potentiate GABA-A receptor currents, whereas at higher concentrations, they directly activate the receptor.16, 17 Allopregnanolone-like neurosteroid are potent allosteric agonists and direct activators of synaptic and extrasynaptic GABA-A receptors.12 The resulting chloride current conductance generates a form of shunting inhibition that controls brain network excitability and seizures. These mechanisms of neurosteroid provide potential innovative therapies for epilepsy and epilepticus.12

Finally, while sex differences in the brain have been largely attributed to the effects of sex hormones, it is becoming increasingly clear that brain sex differences are also mediated by the complement of genes encoded on sex chromosomes.13 Sex chromosome gene expression is sexually dimorphic in the brain in a region-specific and cell type-specific manner.13 Genes on the sex chromosome may influence neurological diseases by modifying the differentiation process of neurons, encoding proteins, neurotransmitter biosynthesis, and synaptic transmission (Figure 1).13 Interestingly, evidence suggests the preponderance of female sex in the transmission of seizure liability in IGEs.18 In one study of families with 82 index cases with IGEs, the highest risk for siblings was conferred by an affected mother. If a father was affected, the risk for proband siblings was almost equal to that in families with both parents unaffected.18

The relationship between menstrual cycle and seizure susceptibility in women is a well-known phenomenon (catamenial epilepsy); this is greatly influenced by hormonal fluctuations associated with the menstrual cycle phases. Catamenial seizures are considered neurosteroid withdrawal symptoms.19 The pathophysiology of perimenstrual catamenial epilepsy involves withdrawal of progesterone-derived GABA ergic neurosteroid due to a decline in progesterone levels at the time of menstruation.20 However, other mechanisms such as changes in water content, fluctuations in calcium levels, interactions between anticonvulsant drugs and steroid hormones, and thyroid hormone deficiency have also been implicated in the pathophysiology of perimenstrual catamenial epilepsy 4. A detailed review of catamenial epilepsy is beyond the scope of this manuscript, and readers should refer to other studies on this topic.11, 19, 20

Most of the abovementioned discussions on the neurobiology of sex differences in epilepsy also apply to other types of epilepsies [e.g., focal epilepsies, genetic epilepsies, status epilepticus (SE)]. Below, we highlight some sex differences that are specific to other epilepsy.

Focal Epilepsy

Generally, men may have a greater predisposition to behaviors that cause brain injury and acquired epilepsy.21 In addition, animal studies have implicated that the presence of testosterone in intact and gonadectomized males with testosterone replacement increases their susceptibility to seizure. Seizures were either stronger (full limbic) or more frequent in animals with testosterone compared to animals devoid of testosterone.22 In contrast, women may be protected from brain injury by the neuroprotective effects of estrogens and progesterone.21 Furthermore, some symptomatic (structural) focal epilepsy may be more frequent in men (e.g., focal cortical dysplasia, perinodular heterotopia).7, 21 In one study of non-acquired focal epilepsy, no sex differences were observed for seizure types with or without altered consciousness or progression to bilateral tonic-clonic seizures. However, autonomic, psychic, and visual symptoms are more frequently reported in females than in males.3

In temporal lobe epilepsy (TLE), which is the most common type of focal epilepsy, the sex distribution is almost similar between males and females,23 but some clinical aspects appear to differ between men and women (e.g., auras are more common in women).21, 24 Interestingly, one study suggested the existence of sex differences in the spatial distribution of brain dysfunction in patients with mesial TLE, perhaps reflecting sexual dimorphism in regional cerebral connectivity.25 Male patients more often exhibited frontal lobe hypometabolism ipsilateral to the seizure onset zone and epileptiform activity spread to this region. By contrast, female patients more often exhibited hypometabolism and ictal spread to the contralateral temporal lobe.25

Investigating sex differences in focal epilepsies may have important clinical implications; for example, in designing individualized sex-specific surgical plans for patients with drug-resistant mesial TLE, considering the extent of cerebral dysfunction in different sexes.

Symptomatic (Structural-Metabolic-Genetic) Generalized Epilepsy

Lennox-Gastaut syndrome (LGS) is the prototype of symptomatic (structural-metabolic-genetic) generalized epilepsy. Male patients often outnumber female patients in LGS. In one study, the sex (female to male) ratio of patients with LGS was 0.6;26this was consistent with other studies.27 Male preponderance has also been reported in other epilepsy syndromes, such as Landau-Kleffner syndrome, epilepsy with myoclonic absences, Ohtahara syndrome, and Dravet syndrome.4-7 Sex-dependent genetic disorders (e.g., X-linked syndromes such as Rett syndrome and fragile X syndrome) may explain some of these sex differences in symptomatic (structural-metabolic-genetic) generalized epilepsies.28-31

Status Epilepticus

SE is more prevalent in males than in females. In one large study from the USA, a higher incidence, earlier age at onset, and higher mortality of SE were observed among males.32 In another study conducted in Taiwan, the male-to-female ratio of SE incidence rate was 1.57;33 however, the in-hospital mortality was significantly lower in males (7.4%) than in females (11.1%).33

Sex Differences in the Adverse Effects of Antiseizure Medications

A recent systematic review suggested a higher frequency of general adverse effects of antiseizure medications in girls (than that in boys).34 Higher risks of overweight, hyperammonemia, and carnitine deficiency were suggested in girls taking valproic acid. Similarly, an increase in height and an increased risk of weight loss were suggested to occur in girls on topiramate. Finally, a higher risk of retinal toxicity was observed in boys taking vigabatrin. However, the authors concluded that the effect of sex on the susceptibility to adverse effects of antiseizure medications is poorly investigated.34

The choice of antiseizure medications may have direct effects on hormonal cycles, hormonal contraception, pregnancy, fetal risk of major congenital malformation, and lactation in adolescents and adults with epilepsy. A detailed review of these issues is beyond the scope of this manuscript, and readers are encouraged to refer to other references.35-37 For a comprehensive review of the molecular mechanisms of sex differences in epilepsy and seizure susceptibility in terms of chemical, genetic, and acquired epileptogenesis, readers may refer to the review by Reddy et al.38

CONCLUSION

The existence of sex differences in epilepsy is well recognized, but there is little discussion of their mechanisms and therapeutic implications. Future research should investigate the exact roles of sex hormones, neurosteroid, and genes in the development of sex differences in epilepsy. Similarly, future studies should investigate whether sex differences exist in seizure characteristics (e.g., seizure frequency, semiology, response to treatment, outcome) in different syndromes. These issues may have important clinical implications for designing appropriate sex-specific treatment strategies for various syndromes and conditions. Furthermore, sex should be considered as a biological variable in basic and clinical research.

Footnotes

References

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