Wanqi Li, Peiqing Li, Xiaowei Fan, Guangming Liu, Qiang Wang^*
Department of Pediatric Emergency, Guangzhou Women and Children’s Medical Center, Guangzhou Medical University, Guangzhou, China.
DOI: 10.4236/jbbs.2022.1211033   PDF    HTML   XML   115 Downloads   706 Views   Citations

Abstract

Objective: Febrile convulsion in children is age-dependent and genetic predisposition. However, mild electrolyte disturbances are not uncommon in such children. This study was to investigate the effect of electrolyte disturbance on febrile convulsion and to screen for febrile convulsion-related genes. Methods: This retrospective cohort study included children who admitted to the Pediatric Emergency Department of Guangzhou Women and Children’s Medical Center due to fever and febrile convulsion between May to December 2020. Clinical manifestations and serum electrolyte levels were recorded and analyzed by binary logistic regression on risk factors of convulsion, and children with family histories were screened for febrile convulsion-related genes. Results: This study included 322 children with fever: 161 in the febrile convulsion group (FC Group) including 71 in the single convulsion group (SC Group) and 90 in the multiple convulsion group (MC Group), and the control group consisted of 161 children with fever without convulsion and nervous system disease. Serum sodium, potassium and calcium in FC Group were lower than those in the control group (p < 0.05), but blood glucose was higher (5.7 mmol/L vs. 5.2 mmol/L, p = 0.01); meanwhile, the threshold of serum sodium level in convulsion was 133 mmol/L [Sensitivity: 70.2%, Specificity: 62.1%, AUC: 0.694, p < 0.001]. In the FC Group, there were no significant differences in serum sodium, calcium and chlorine between SC Group and MC Group, but lower level of blood glucose in the MC Group (5.6 mmol/L vs. 5.9 mmol/L, p = 0.008). Although univariate analysis showed that serum sodium, potassium, calcium, and sugar levels were associated with febrile convulsion, only serum sodium was below normal values. There was no pathogenicity variation related to disease phenotype was found in 5 FC patients with family histories, but four of them found other mutations. Conclusion: Hyponatremia may be a relative risk factor in febrile convulsion, and for children with a family history of febrile convulsion and serum sodium lower than 133 mmol/L, related gene analysis can be performed.

Keywords

Febrile Convulsion, Electrolyte, Recurrence of Convulsion, Hyponatremia, Family History, Gene

Share and Cite:

1. Introduction

Febrile convulsions are common in children with a febrile state (T ≥ 38˚C), without central nervous system diseases and metabolic disturbances that can cause convulsions, and most of them without history of febrile convulsions [1]. Febrile convulsions are divided into simple and complex febrile convulsion based on clinical features. The former mostly occurs in 6 months to 5 years old, with generalized seizures, duration less than 15 minutes, one attack in a febrile course, and no abnormal neurological signs; and the latter occurs in less than 6 months or more than 5 years, and the symptoms are focal or generalized seizures, neurological abnormalities before onset, seizure duration ≥ 15 min, or seizure duration ≥ 2 times in a febrile course, and neurological abnormalities after seizure, such as Todd’s palsy [1] [2]. Febrile convulsions are believed to be the result of multiple factors, including the vulnerability of the developing central nervous system to fever and potential risk factors (including environmental and genetic factors) [1] [3] [4] [5]. The prognosis of febrile convulsion is good generally, but convulsion happens repeatedly can cause organic pathological changes or functional abnormality in brain, especially in persistent convulsions [6] [7] [8] [9]. Therefore, it is very important to find out the risk factors in time, which may help to predict the progress of the disease such as recurrent convulsions.

Febrile convulsions are an age-dependent phenomenon. Although the most commonly identified risk factors of febrile convulsions include age, high fever, infection, recent immunization, and a family history of febrile convulsions [10] [11], some patients also have mild electrolyte disturbances, especially in children with complex febrile convulsions [3] [12] [13]. Whether electrolyte disturbances are a risk factor for febrile convulsions and recurrent convulsions still not clear. In addition, studies have shown that the direct effect of heat on ion channels [14], such as voltage-gated sodium channel [15], localized to the site of action potential initiation potentially causes a profound increase in neuronal excitability [14], which is likely to contribute to abnormal serum sodium levels and febrile convulsions genesis.

Although genetic susceptibility to febrile convulsions has received attention, the exact modes of inheritance are not fully understood. Susceptibility to febrile seizures has been linked to several genetic loci in different families, including the long arm of chromosome 8q13-21 (FEB1) [16], chromosome 19p (FEB2) [17] and chromosome 2q23-24 (FEB3) [18], which is transmitted in an autosomal dominant pattern with reduced penetrance or as a polygenic or multifactorial model [19]. According to Yuxin Xu et al. [20], the series of genes controlling important nodes of neural signaling, including SCN1A, SCN2A, SCN1B, SCN9A, GABRG2, STX1B, and PCDH19, which are believed to be responsible for the early identification of generalized epilepsy with febrile seizures plus (GEFS+), Dravet syndrome (DS), and PCDH19 gene-related seizures. In some patients and families, the propensity for febrile convulsions is an early manifestation of GEFS+ [21] [22], and some with severe myoclonic epilepsy of infancy DS is another genetic epilepsy with a well-known preponderance for seizures with fever in early childhood [23]. Stefania Scalise et al. [11] also investigated the role of SCN1A mutations in encoding the voltage-gated sodium channel (VGSC) NaV1.1 gene in children with thermal convulsions, suggesting that SCN1A mutations lead to immature intracellular expression, which leads to normal neuronal transmission.

In this study, we investigated whether electrolyte balance disturbances were associated with convulsions during fever and which electrolytes were associated with recurrence of convulsions. Meanwhile, the genes related to febrile convulsions in children with a family history of convulsions were also analyzed.

2. Patients and Methods

2.1. Patients

Children with fever who visited the Pediatric Emergency Department (PED) of our hospital from May to December 2020 were selected as the research objects. Patients from convulsion to PED admission within 2 hours, including those were convulsing on admission, were classified as febrile convulsion (FC) group. And febrile patients without convulsion and neurological disease during the same period were selected as the control group. The criteria for febrile convulsion included: the presence of a seizure during fever (anal temperature ≥ 38.5˚C, axillary temperature ≥ 38˚C), no central nervous system infection or other cause of convulsion, and no history of febrile convulsion [24]; and the exclusion criteria included: gastrointestinal symptoms such as diarrhea and vomiting, central nervous system (CNS) infection or inflammation, acute systemic metabolic abnormality that may produce convulsions, history of previous afebrile seizures. The FC group was divided in single convulsion group (SC Group), and multiple convulsion group (MC Group) whose convulsions occurred more than once.

2.2. Ethics Approval

This work has been carried out in accordance with the Declaration of Helsinki (2000) of the World Medical Association. The study was approved by the ethics committee of Guangzhou Women and Children’s Medical Center (No. [2022]199A01). Written informed consent was obtained from the legal guardians of the patients.

2.3. Method

Detailed demographic, convulsion characteristics and family histories, and blood electrolyte indicators of the patients were extracted from the structured electronic medical records system (EMRS). In addition, the first blood sample for measurement of electrolyte indicators was obtained from patients immediately after admission. The demographic and clinical data of the patients were collected, mainly including age, sex, form and numbers of convulsion, serum sodium, potassium, chlorine, calcium and blood glucose. Serum electrolyte indicators were measured by blood gas analyzer (instrument model: GEM Premier 4000; Manufacturer: American Instrumentation Laboratory; Instrument serial number: 19042043).

Genetic testing was performed for febrile convulsions children with family histories. Peripheral blood 2 ml was collected from the children and their parents respectively. Genomic DNA was extracted from blood samples using genomic DNA extraction kits. NextSeq 500 NGS was used for sequencing. The average depth of sequencing was 300×, and the average gene coverage was above 98.8%. The method of case analysis was used to screen the candidate mutation loci of each family. Firstly, gene mutation locus with frequency < 0.001 were screened from the frequency database. Secondly, potential pathogenic mutation sites were retained, including frameshift mutations, nonsense mutations, splicing mutations, and missense mutations predicted by various software to damage protein structure. Finally, the potential pathogenic loci in each family were analyzed in the following five patterns: 1) Epilepsy related gene pattern; 2) Dominant inheritance mode of emerging mutation; 3) Autosomal recessive inheritance pattern, including homozygous and compound heterozygous variants; 4) The model of X chromosome inheritance; 5) Family co-separation analysis model. All filtered rare variants were annotated according to the standards and guidelines recently recommended by the American Society of Medical Genetics and Genomics (ACMG [25]), and were divided into five categories: pathogenic, suspected pathogenic, benign, suspected benign, and of unknown clinical significance.

2.4. Statistical Analysis

Data were expressed as mean ± SD for normally distributed variables, median (IQR) for non-normally distributed variables, and number (percentage) for categorical variables. The normality of the data distribution was examined by using the Kolmogorov-Smirnov tests. Baseline characteristics were compared between different groups using Mann-Whitney U-Test and Chi-square/Fisher’s exact test to detect any differences. Logistic regression models were used to estimate the odds ratio (OR) and 95% confidence intervals (CIs) for risk factors of febrile convulsions in different characteristics comparisons. The Receiver Operating Characteristic (ROC) Curve was also adopted to assess the predictive factors for electrolyte disturbances in patients with febrile convulsions. A two-sided p-value of <0.05 was regarded as statistically significant. Data management and statistical analyses were conducted using SPSS19.0 statistical software.

3. Results

3.1. Clinical Characteristics of Enrolled Patients

A total of 322 children with fever were collected in this study, including 161 children in the febrile convulsions (FC) group and 161 children in the control group. In the FC group, 71 cases (44.10%) who had only convulsion once during the febrile course classified as SC Group, and 90 cases (55.90%) whose convulsions had more than once classified as MC Group. In this study, febrile convulsion was most common from 6 months to 3 years of age (80.75%), and there were no gender and age differences among the groups (p > 0.05) (Table 1). In febrile convulsion group, 159 cases (98.76%) had generalized tonic-clonic, 2 cases (1.24%) had focal onset, and 3 cases (1.86%) had prolonged convulsion (>30 minutes). There were fifteen cases (9.31%) had family history of convulsion, and 5 cases among them completed genetic testing.

*FC Group: Febrile Convulsion Group; ^#SC Group: Single Convulsion Group; ^&MC Group: Multiple Convulsion Group. The numbers in bold in the p-value column in the table are the statistically different p-values.

3.2. Correlation between Electrolyte Disturbance and Febrile Convulsion

As shown in Table 2 and Figure 1, the serum sodium level of patients in each group was lower than the normal value of 138 mml/L, and the FC group was significantly lower than the control group (132 mmol/L vs. 134 mmol/L, p = 0.001), but among the FC group, there was no difference between SC group and MC group. Although Serum potassium and calcium in the FC group were significantly lower than those in the control group (both p = 0.001), but there was

no difference between SC group and MC group (p > 0.05), and these two indicators in each group were within the normal range. In addition, the blood glucose level in the FC group was significantly lower than that in the control group (5.2 mmol/L vs. 5.7 mmol/L, p = 0.001), while there was no difference between the SC and MC groups, and the values in each group were within the normal range.

Further univariate analysis of risk factors showed that serum sodium (OR 0.803, 95% CI 0.731 - 0.881, p = 0.001), potassium, calcium and blood glucose were associated with febrile convulsion in children (Table 3). However, only serum sodium was below normal levels, and the rest of the indicators were within normal ranges. Therefore, mild hyponatremia may be a risk factor for febrile convulsions in our study.

In order to explore the sensitivity of hyponatremia level to the occurrence of febrile seizures in this group of patients, ROC curve analysis was further conducted. The threshold of serum sodium level in convulsion was 133 mmol/L [Sensitivity: 70.2%, Specificity: 62.1%, AUC: 0.694, p < 0.001] (Figure 2).

3.3. Genetic Analysis

There were 15 patients with febrile convulsions who had family history of convulsions, and 5 of them with their family members were tested for febrile convulsions related genes. Although all of them the genetic variants with highly

*FC Group: Febrile Convulsion Group; ^#SC Group: Single Convulsion Group; ^##MC Group: Multiple Convulsion Group; ^§p was SC Group vs. MC Group; ^§§p was FC Group vs. Control Group. The numbers in bold in the p-value column in the table are the statistically different p-values.

The numbers in bold in the p-value column in the table are the statistically different p-values.

correlated clinical phenotypes and well-documented pathogenicity were not found, four cases found other mutations (Table 4), including in the list of analyzed genes (Supplementary table), with insufficient pathogenic evidence need to be further combined with clinical analysis. On the other hand, three of the families underwent household analysis (Figure 3). One case found a mutant gene ARHGEF15, a gene known to have functional roles that are plausibly relevant to epilepsy [26]. One case found mutant gene ATP7A, which is the pathogenic gene of Menkes kinky-hair syndrome and X-linked Distal spinal muscular atrophy [27] [28], and GABRG2 mutation, c.548 + 6C > A (splicing) from mother associated with generalized epilepsy with febrile seizures plus type 3 (OMIM: 611277) [29], familial febrile epilepsy 8 (OMIM: 607681) [30], and early infantile epileptic encephalopathy 74 (OMIM: 618396) [31]. One case found SCN9A mutation, c.3976A > C (p.I1326L) from mother associated with generalized epilepsy with febrile seizures type 7 (OMIM: 613863) [32], and a modifier gene in Dravet syndrome (OMIM: 607208) [33]. One case found SPTAN1 mutation, c.7010_ 7011insTAAG (p.F2337fs) from father associated with early-onset childhood epileptic encephalopathy type 5 (OMIM: 613477) [34].

4. Discussion

Febrile convulsion is the most common disease in Pediatric Emergency Department, usually occurring between 6 months and 5 years old [1]. Age, infection, vaccination, trace element deficiency, maternal states and genetic predisposition are the commonly known risk factors for febrile convulsion. [10] [11]. Studies have shown that various electrolyte disturbances occur in patients with febrile convulsion [12] [35] [36] [37]. Similarly, in our study, significant hyponatremia was found in the febrile convulsion group compared with the febrile-only group within 2 hours after the onset of convulsions. However, hyponatremia levels in children with febrile convulsion did not reach levels of severe hyponatremia that could trigger convulsion, and there was no different between Single Convulsion Group and Multiple Convulsion Group. In addition, some mutations genes with insufficient pathogenic evidence were found, which need to be further combined with clinical analysis.

In this study, the children in this study were all febrile patients, and most of them had hyponatremia, which may be related to hyponatremia caused by inappropriate ADH secretion syndrome in infected patients [38] [39] [40]. The serum sodium of the children in the febrile convulsion group was mostly lower than 133 mmol/L, and ROC curve analysis suggested that serum sodium had a certain predictive effect on febrile convulsion (serum sodium AUC0.694), and determined the critical value (serum sodium < 133 mmol/L, sensitivity 70.2%, specificity 62.1%). However, there was no correlation between serum sodium and recurrence of febrile convulsions. The additional gating defects for both R859H and R865G mutants were detected at 40˚C, and the GEFS+ mutant R859H showed a loss of function in the voltage dependence of inactivation and an increased channel use-dependency at 40˚C with no reduction in peak current density [41]. Meanwhile, the DS mutant R865G exhibited reduced peak sodium currents, enhanced entry into slow inactivation, and increased use-dependency at 40˚C [41]. These studies explain that patients with defects of R859H or R865G mutants had higher levels of hyponatremia triggering febrile convulsions than patients with nonfebrile convulsions [42], but had not shown that this mechanism was associated with repeated convulsions.

On the other hand, potassium, and calcium concentrations were lower and blood glucose concentrations higher than those in the control group, both of which were associated with febrile convulsion. However, these indicators are within the normal range and have no effect on clinical judgment. In a study of 1199 children, febrile seizures and trauma were found to be more likely to cause stress hyperglycemia than fever alone, and none of the children in the study went on to develop diabetes [43]. Raluca Maria Costea et al. suggested that the duration of febrile convulsions was longer (>15 min), repeated febrile convulsion\, focal convulsion, body temperature ≥ 39.5˚C, and higher lactate values are significantly associated with stress hyperglycemia, and stress hyperglycemia can be a predictor of recurrence of febrile convulsions [44]. In this study, although blood glucose in the MC group was significantly lower than that in SC group, the mean blood glucose in the two groups was still within the normal range, and the effect of hyperglycemia on recurrent convulsion was not reflected in this study.

Children with a family history of convulsions are more likely to develop febrile convulsions, which may be associated with multiple genes. Studies have shown that mutations in sodium channel and GABA receptor genes are found in families with syndromes associated with febrile convulsions [45]. In this study, 5 of the 15 family members of children with a family history of convulsion agreed to be tested for gene related to febrile convulsion. 189 gene loci, such as AARS, were detected, and no obvious gene mutations related to clinical phenotype of febrile convulsion were found, but mutations at other gene loci were reported in 4 of them, such as ARHG EF15, MAG12, ATP7A, GABRG2, SCN9A, SPTAN, RELN, MTOR. Patient A tested a large sample of data supporting the predisposition locus ATP7A (a gene that encodes an inherited or acquired predisposition to a disease in response to appropriate environmental stimuli). ATP7A is an important gene encoding copper pump, and its clinical phenotypes are Menkes disease, occipital Angle syndrome, and X-linked distal spinal muscular atrophy type 3 [46]. At the same time, GABRG2 mutation was also detected. Although the evidence of pathogenicity was insufficient, the possibility of pathogenicity was not excluded in combination with the clinical practice of febrile convulsion in children, which needs further follow-up. The gene GABRG2 was derived from the mother, and the disease phenotypes were generalized epilepsy with febrile seizures plus type 3 (OMIM: 611277), familial febrile epilepsy 8 (OMIM: 607681), and early infantile epileptic encephalopathy 74 (OMIM: 618396) [47]. The SCN9A mutation was detected in patient B, which originated from his mother. Combined with clinical analysis, the possibility of pathogenesis was not excluded. The clinical phenotypes consistent with clinical manifestations were generalized epilepsy with febrile convulsion type 7 (OMIM: 613863) and Dravet syndrome (OMIM: 607208) [8] (. SPTAN1 mutation was detected in Patient C. The variant originated from the father and had the clinical phenotype of early onset infant epileptic encephalopathy type 5 (OMIM: 613477), it has also been reported that SPTAN1 encephalopathy is a unique clinical syndrome caused by SPTAN1 specific mutations [31]. Although the current history of febrile convulsion in the child is not supported by clinical evidence, it is not excluded that the child will later develop corresponding epileptic encephalopathy, and need further followed up. In patient D, genetic variants of ARHGEF15 and MAGI2 were detected, both of which were of undetermined pathogenicity and of non-parental origin, and ARHGEF15 was reported to be a mutation associated with epileptic encephalopathy [26].

5. Conclusions

Hyponatremia may be a relative risk factor for febrile convulsions, which may also be a reflection of patient carrying genes involved in sodium channel regulation in febrile seizure-related genes such as R859H or R865G mutants in patients. Therefore, for children with a family history of febrile convulsion and serum sodium lower than 133 mmol/L, related gene analysis can be performed to clarify the etiological diagnosis and predict subsequent neurological diseases.

Furthermore, Gene mutations of various ion channels are closely related to the occurrence of febrile convulsions. It is expected to be further investigated by multicenter randomized controlled studies in future.

Limitations

The current study has some limitations that should be noted. One of the limitations is that blood samples were collected within 2 hours after febrile convulsions and blood electrolyte indicators were measured, which could not be evaluated before the occurrence of convulsions. Future prospective cohort studies or long-term clinical follow-up studies are needed to reveal the intrinsic link between electrolytes and febrile convulsions. In addition, due to economic and family reasons, many families did not agree to complete febrile convulsions related genes, resulting in a small quantity of genetical cases. In the future, education and promotion of the conclusions in this study can be conducted to obtain more clinical data conducive to research.

Acknowledgements

Thanks all the enrolled patients and the Clinical Biological Resource Bank of Guangzhou Women and Children’s Medical Center for providing the clinical samples used in this study.

Data Availability Statement

The data reported in this paper have been deposited in the OMIX, China National Center for Bioinformation/Beijing Institute of Genomics, Chinese Academy of Sciences. The information record number is BF2022083012025. (https://ngdc.cncb.ac.cn/omix: accession No.OMIX807).

Conflicts of Interest

All authors declare no conflict of interest.

References

[1]	Laino, D., Mencaroni, E. and Esposito, S. (2018) Management of Pediatric Febrile Seizures. International Journal of Environmental Research and Public Health, 15, Article No. 2232. https://doi.org/10.3390/ijerph15102232
[2]	Capovilla, G., Mastrangelo, M., Romeo, A. and Vigevano, F. (2009) Recommendations for the Management of “Febrile Seizures”: Ad Hoc Task Force of LICE Guidelines Commission. Epilepsia, 50, 2-6. https://doi.org/10.1111/j.1528-1167.2008.01963.x
[3]	Gunes, A., Fidan, S., Dulkadir, R. and Unlu, E. (2021) Evaluation of Risk Factors Associated with First Episode Febrile Seizure. European Review for Medical and Pharmacological Sciences, 25, 7089-7092.
[4]	Renda, R., Yuksel, D. and Gurer, Y.K.Y. (2020) Evaluation of Patients with Febrile Seizure: Risk Factors, Recurrence, Treatment and Prognosis. Pediatric Emergency Care, 36, 173-177.
[5]	Choi, Y.J., Jung, J.Y., Kim, J.H., Kwon, H., Park, J.W., Kwak, Y.H., et al. (2019) Febrile Seizures: Are They Truly Benign? Longitudinal Analysis of Risk Factors and Future Risk of Afebrile Epileptic Seizure Based on the National Sample Cohort in South Korea, 2002-2013. Seizure, 64, 77-83. https://doi.org/10.1016/j.seizure.2018.12.004
[6]	Nezami, A., Tarhani, F. and Shoshtari, N.K. (2021) Organic Lesions in the Brain MRI of Children with Febrile Seizure. Current Medical Imaging, 17, 148-154. https://doi.org/10.2174/1573405616666200226103615
[7]	Tanabe, T., Hara, K., Shimakawa, S., Fukui, M. and Tamai, H. (2011) Hippocampal Damage after Prolonged Febrile Seizure: One Case in a Consecutive Prospective Series. Epilepsia, 52, 837-840. https://doi.org/10.1111/j.1528-1167.2010.02958.x
[8]	Asano, T., Ichiki, K., Koizumi, S., Kaizu, K., Hatori, T., Fujino, O., et al. (2010) IL-8 in Cerebrospinal Fluid from Children with Acute Encephalopathy Is Higher than in That from Children with Febrile Seizure. Scandinavian Journal of Immunology, 71, 447-451. https://doi.org/10.1111/j.1365-3083.2010.02391.x
[9]	Asoh, M. (1997) The Clinical Study of the First Febrile Convulsion in Children with Brain-Damage. No To Hattatsu, 29, 227-233.
[10]	Kajiwara, K. and Koga, H. (2022) Risk Factors for Acute Encephalitis and Early Seizure Recurrence in Complex Febrile Seizures. European Journal of Pediatrics, 181, 3103-3110. https://doi.org/10.1007/s00431-022-04529-1
[11]	Scalise, S., Zannino, C., Lucchino, V., Lo Conte, M., Scaramuzzino, L., Cifelli, P., et al. (2022) Human iPSC Modeling of Genetic Febrile Seizure Reveals Aberrant Molecular and Physiological Features Underlying an Impaired Neuronal Activity. Biomedicines, 10, Article No. 1075. https://doi.org/10.3390/biomedicines10051075
[12]	Gorabi, V.S., Nikkhoo, B., Faraji, O., Mohammadkhani, M., Mirzaee, S., Rasouli, M.A., et al. (2018) Hypercalciuria and Febrile Convulsion in Children under 5 Years Old. Korean Journal of Pediatrics, 61, 129-131. https://doi.org/10.3345/kjp.2018.61.4.129
[13]	Bakhtiari, E., Heydarian, F., Khalesi, M., Jafarian, F. and Heidarian, M. (2022) A Comparison between Serum Selenium Level in Febrile Children with or without Seizure. Biological Trace Element Research, 200, 3103-3106. https://doi.org/10.1007/s12011-021-02936-3
[14]	Thomas, E.A., Hawkins, R.J., Richards, K.L., Xu, R., Gazina, E.V. and Petrou, S. (2009) Heat Opens Axon Initial Segment Sodium Channels: A Febrile Seizure Mechanism? Annals of Neurology, 66, 219-226. https://doi.org/10.1002/ana.21712
[15]	Scalise, S., Scaramuzzino, L., Lucchino, V., Esposito, C., Malatesta, P., Grillone, K., et al. (2020) Generation of iPSC Lines from Two Patients Affected by Febrile Seizure Due to Inherited Missense Mutation in SCN1A Gene. Stem Cell Research, 49, Article ID: 102083. https://doi.org/10.1016/j.scr.2020.102083
[16]	Wallace, R.H., Berkovic, S.F., Howell, R.A., Sutherland, G.R. and Mulley, J.C. (1996) Suggestion of a Major Gene for Familial Febrile Convulsions Mapping to 8q13-21. Journal of Medical Genetics, 33, 308-312. https://doi.org/10.1136/jmg.33.4.308
[17]	Johnson, E.W., Dubovsky, J., Rich, S.S., O’Donovan, C.A., Orr, H.T., Anderson, V.E., et al. (1998) Evidence for a Novel Gene for Familial Febrile Convulsions, FEB2, Linked to Chromosome 19p in an Extended Family from the Midwest. Human Molecular Genetics, 7, 63-67. https://doi.org/10.1093/hmg/7.1.63
[18]	Peiffer, A., Thompson, J., Charlier, C., Otterud, B., Varvil, T., Pappas, C., et al. (1999) A Locus for Febrile Seizures (FEB3) Maps to Chromosome 2q23-24. Annals of Neurology, 46, 671-678. https://doi.org/10.1002/1531-8249(199910)46:4<671::AID-ANA20>3.0.CO;2-5
[19]	Holm, I.A., Poduri, A., Crandall, L., Haas, E., Grafe, M.R., Kinney, H.C., et al. (2012) Inheritance of Febrile Seizures in Sudden Unexplained Death in Toddlers. Pediatric Neurology, 46, 235-239. https://doi.org/10.1016/j.pediatrneurol.2012.02.007
[20]	Xu, Y.X. and Zhong, J.M. (2021) Early Identification and Diagnosis of Epilepsy Related to Fever Sensitivity. Chinese Journal of Contemporary Pediatrics, 23, 749-754.
[21]	Scheffer, I.E., Harkin, L.A., Grinton, B.E., Dibbens, L.M., Turner, S.J., Zielinski, M.A., et al. (2007) Temporal Lobe Epilepsy and GEFS+ Phenotypes Associated with SCN1B Mutations. Brain, 130, 100-109. https://doi.org/10.1093/brain/awl272
[22]	Zhang, Y.H., Burgess, R., Malone, J.P., Glubb, G.C., Helbig, K.L., Vadlamudi, L., et al. (2017) Genetic Epilepsy with Febrile Seizures plus: Refining the Spectrum. Neurology, 89, 1210-1219. https://doi.org/10.1212/WNL.0000000000004384
[23]	Nordli, D.R. (2005) Idiopathic Generalized Epilepsies Recognized by the International League against Epilepsy. Epilepsia, 46, 48-56. https://doi.org/10.1111/j.1528-1167.2005.00313.x
[24]	Subcommittee on Febrile Seizures; American Academy of Pediatrics (2011) Neurodiagnostic Evaluation of the Child with a Simple Febrile Seizure. Pediatrics, 127, 389-394. https://doi.org/10.1542/peds.2010-3318
[25]	Bahcall, O.G. (2015) Genetic Testing. ACMG Guides on the Interpretation of Sequence Variants. Nature Reviews Genetics, 16, 256-257. https://doi.org/10.1038/nrg3940
[26]	Veeramah, K.R., Johnstone, L., Karafet, T.M., Wolf, D., Sprissler, R., Salogiannis, J., et al. (2013) Exome Sequencing Reveals New Causal Mutations in Children with Epileptic Encephalopathies. Epilepsia, 54, 1270-1281. https://doi.org/10.1111/epi.12201
[27]	Fister, P., Rakus, J., Primec, Z.R. and Strazisar, B.G. (2006) Menkes Kinky Hair Disease (Menkes Syndrome). A Case Report. Acta Dermatovenerologica Alpina Pannonica et Adriatica, 15, 126-130.
[28]	Perez-Siles, G., Cutrupi, A., Ellis, M., Kuriakose, J., La Fontaine, S., Mao, D., et al. (2020) Modelling the Pathogenesis of X-Linked Distal Hereditary Motor Neuropathy Using Patient-Derived iPSCs. Disease Models & Mechanisms, 13, dmm041541. https://doi.org/10.1242/dmm.041541
[29]	Kang, J.Q. and Macdonald, R.L. (2016) Molecular Pathogenic Basis for GABRG2 Mutations Associated with a Spectrum of Epilepsy Syndromes, from Generalized Absence Epilepsy to Dravet Syndrome. JAMA Neurology, 73, 1009-1016. https://doi.org/10.1001/jamaneurol.2016.0449
[30]	Boillot, M., Morin-Brureau, M., Picard, F., Weckhuysen, S., Lambrecq, V., Minetti, C., et al. (2015) Novel GABRG2 Mutations Cause Familial Febrile Seizures. Neurology Genetics, 1, e35. https://doi.org/10.1212/NXG.0000000000000035
[31]	Hirabayashi, K., Uehara, D.T., Abe, H., Ishii, A., Moriyama, K., Hirose, S., et al. (2019) Copy Number Variation Analysis in 83 Children with Early-Onset Developmental and Epileptic Encephalopathy after Targeted Resequencing of a 109-Epilepsy Gene Panel. Journal of Human Genetics, 64, 1097-1106. https://doi.org/10.1038/s10038-019-0661-x
[32]	Zhang, T., Chen, M., Zhu, A., Zhang, X. and Fang, T. (2020) Novel Mutation of SCN9A Gene Causing Generalized Epilepsy with Febrile Seizures plus in a Chinese Family. Neurological Sciences, 41, 1913-1917. https://doi.org/10.1007/s10072-020-04284-x
[33]	Ma, H., Guo, Y., Chen, Z., Wang, L., Tang, Z., Zhang, J., et al. (2021) Mutations in the Sodium Channel Genes SCN1A, SCN3A, and SCN9A in Children with Epilepsy with Febrile Seizures plus (EFS+). Seizure, 88, 146-152. https://doi.org/10.1016/j.seizure.2021.04.006
[34]	Rapaccini, V., Esposito, S., Strinati, F., Allegretti, M., Manfroi, E., Miconi, F., et al. (2018) A Child with a c.6923_6928dup (p.Arg2308_Met2309dup) SPTAN1 Mutation Associated with a Severe Early Infantile Epileptic Encephalopathy. International Journal of Molecular Sciences, 19, Article No. 1976. https://doi.org/10.3390/ijms19071976
[35]	Hasegawa, H., Okubo, S., Ikezumi, Y., Uchiyama, K., Hirokawa, T., Hirano, H., et al. (2009) Hyponatremia Due to an Excess of Arginine Vasopressin Is Common in Children with Febrile Disease. Pediatric Nephrology, 24, 507-511. https://doi.org/10.1007/s00467-008-1053-1
[36]	Smith, D.K., Sadler, K.P. and Benedum, M. (2019) Febrile Seizures: Risks, Evaluation, and Prognosis. American Family Physician, 99, 445-450.
[37]	Heydarian, F., Bakhtiari, E., Badzaee, S. and Heidarian, M. (2019) Gastroenteritis Related Seizure with or without Fever: Comparison Clinical Features and Serum Sodium Level. Iranian Journal of Child Neurology, 13, 47-52.
[38]	Rodriguez Cuartero, A. and Gonzalez Martinez, F. (1996) Inappropriate ADH Secretion Syndrome. Anales de Medicina Interna, 13, 127-129.
[39]	Habas, E., Ali, E., Habas, A., Rayani, A., Ghazouani, H., Khan, F., et al. (2022) Hyponatremia and SARS-CoV-2 Infection: A Narrative Review. Medicine (Baltimore), 101, e30061. https://doi.org/10.1097/MD.0000000000030061
[40]	Foppiani, L. (2018) SIADH with Severe Hyponatremia in an Elderly Man with Herpes Zoster Infection: A Causal or Casual Association? Internal Medicine, 57, 3393-3398. https://doi.org/10.2169/internalmedicine.0785-18
[41]	Volkers, L., Kahlig, K.M., Das, J.H., van Kempen, M.J., Lindhout, D., Koeleman, B.P., et al. (2013) Febrile Temperatures Unmask Biophysical Defects in Nav1.1 Epilepsy Mutations Supportive of Seizure Initiation. Journal of General Physiology, 142, 641-653. https://doi.org/10.1085/jgp.201311042
[42]	Adrogue, H.J. and Madias, N.E. (2000) Hyponatremia. The New England Journal of Medicine, 342, 1581-1589. https://doi.org/10.1056/NEJM200005253422107
[43]	Valerio, G., Franzese, A., Carlin, E., Pecile, P., Perini, R. and Tenore, A. (2001) High Prevalence of Stress Hyperglycaemia in Children with Febrile Seizures and Traumatic Injuries. Acta Paediatrica, 90, 618-622. https://doi.org/10.1080/080352501750258658
[44]	Costea, R.M., Maniu, I., Dobrota, L. and Neamtu, B. (2020) Stress Hyperglycemia as Predictive Factor of Recurrence in Children with Febrile Seizures. Brain Sciences, 10, Article No. 131. https://doi.org/10.3390/brainsci10030131
[45]	Poduri, A. and Lowenstein, D. (2011) Epilepsy Genetics—Past, Present, and Future. Current Opinion in Genetics & Development, 21, 325-332. https://doi.org/10.1016/j.gde.2011.01.005
[46]	Horn, N. and Wittung-Stafshede, P. (2021) ATP7A-Regulated Enzyme Metalation and Trafficking in the Menkes Disease Puzzle. Biomedicines, 9, Article No. 391. https://doi.org/10.3390/biomedicines9040391
[47]	Deng, H., Zheng, W. and Song, Z. (2018) The Genetics and Molecular Biology of Fever-Associated Seizures or Epilepsy. Expert Reviews in Molecular Medicine, 20, e3. https://doi.org/10.1017/erm.2018.2