Monotherapy treatment of epilepsy in pregnancy: congenital malformation outcomes in the child.

BACKGROUND: Prenatal exposure to certain anti-seizure medications (ASMs) is associated with an increased risk of major congenital malformations (MCM). The majority of women with epilepsy continue taking ASMs throughout pregnancy and, therefore, information on the potential risks associated with ASM treatment is required. OBJECTIVES: To assess the effects of prenatal exposure to ASMs on the prevalence of MCM in the child. SEARCH METHODS: For the latest update of this review, we searched the following databases on 17 February 2022: Cochrane Register of Studies (CRS Web), MEDLINE (Ovid, 1946 to February 16, 2022), SCOPUS (1823 onwards), and ClinicalTrials.gov, WHO International Clinical Trials Registry Platform (ICTRP). No language restrictions were imposed. SELECTION CRITERIA: We included prospective cohort controlled studies, cohort studies set within pregnancy registries, randomised controlled trials and epidemiological studies using routine health record data. Participants were women with epilepsy taking ASMs; the two control groups were women without epilepsy and untreated women with epilepsy. DATA COLLECTION AND ANALYSIS: Five authors independently selected studies for inclusion. Eight authors completed data extraction and/or risk of bias assessments. The primary outcome was the presence of an MCM. Secondary outcomes included specific types of MCM. Where meta-analysis was not possible, we reviewed included studies narratively. MAIN RESULTS: From 12,296 abstracts, we reviewed 283 full-text publications which identified 49 studies with 128 publications between them. Data from ASM-exposed pregnancies were more numerous for prospective cohort studies (n = 17,963), than data currently available for epidemiological health record studies (n = 7913). The MCM risk for children of women without epilepsy was 2.1% (95% CI 1.5 to 3.0) in cohort studies and 3.3% (95% CI 1.5 to 7.1) in health record studies. The known risk associated with sodium valproate exposure was clear across comparisons with a pooled prevalence of 9.8% (95% CI 8.1 to 11.9) from cohort data and 9.7% (95% CI 7.1 to 13.4) from routine health record studies. This was elevated across almost all comparisons to other monotherapy ASMs, with the absolute risk differences ranging from 5% to 9%. Multiple studies found that the MCM risk is dose-dependent. Children exposed to carbamazepine had an increased MCM prevalence in both cohort studies (4.7%, 95% CI 3.7 to 5.9) and routine health record studies (4.0%, 95% CI 2.9 to 5.4) which was significantly higher than that for the children born to women without epilepsy for both cohort (RR 2.30, 95% CI 1.47 to 3.59) and routine health record studies (RR 1.14, 95% CI 0.80 to 1.64); with similar significant results in comparison to the children of women with untreated epilepsy for both cohort studies (RR 1.44, 95% CI 1.05 to 1.96) and routine health record studies (RR 1.42, 95% CI 1.10 to 1.83). For phenobarbital exposure, the prevalence was 6.3% (95% CI 4.8 to 8.3) and 8.8% (95% CI 0.0 to 9277.0) from cohort and routine health record data, respectively. This increased risk was significant in comparison to the children of women without epilepsy (RR 3.22, 95% CI 1.84 to 5.65) and those born to women with untreated epilepsy (RR 1.64, 95% CI 0.94 to 2.83) in cohort studies; data from routine health record studies was limited. For phenytoin exposure, the prevalence of MCM was elevated for cohort study data (5.4%, 95% CI 3.6 to 8.1) and routine health record data (6.8%, 95% CI 0.1 to 701.2). The prevalence of MCM was higher for phenytoin-exposed children in comparison to children of women without epilepsy (RR 3.81, 95% CI 1.91 to 7.57) and the children of women with untreated epilepsy (RR 2.01. 95% CI 1.29 to 3.12); there were no data from routine health record studies. Pooled data from cohort studies indicated a significantly increased MCM risk for children exposed to lamotrigine in comparison to children born to women without epilepsy (RR 1.99, 95% CI 1.16 to 3.39); with a risk difference (RD) indicating a 1% increased risk of MCM (RD 0.01. 95% CI 0.00 to 0.03). This was not replicated in the comparison to the children of women with untreated epilepsy (RR 1.04, 95% CI 0.66 to 1.63), which contained the largest group of lamotrigine-exposed children (> 2700). Further, a non-significant difference was also found both in comparison to the children of women without epilepsy (RR 1.19, 95% CI 0.86 to 1.64) and children born to women with untreated epilepsy (RR 1.00, 95% CI 0.79 to 1.28) from routine data studies. For levetiracetam exposure, pooled data provided similar risk ratios to women without epilepsy in cohort (RR 2.20, 95% CI 0.98 to 4.93) and routine health record studies (RR 0.67, 95% CI 0.17 to 2.66). This was supported by the pooled results from both cohort (RR 0.71, 95% CI 0.39 to 1.28) and routine health record studies (RR 0.82, 95% CI 0.39 to 1.71) when comparisons were made to the offspring of women with untreated epilepsy. For topiramate, the prevalence of MCM was 3.9% (95% CI 2.3 to 6.5) from cohort study data and 4.1% (0.0 to 27,050.1) from routine health record studies. Risk ratios were significantly higher for children exposed to topiramate in comparison to the children of women without epilepsy in cohort studies (RR 4.07, 95% CI 1.64 to 10.14) but not in a smaller comparison to the children of women with untreated epilepsy (RR 1.37, 95% CI 0.57 to 3.27); few data are currently available from routine health record studies. Exposure in utero to topiramate was also associated with significantly higher RRs in comparison to other ASMs for oro-facial clefts. Data for all other ASMs were extremely limited. Given the observational designs, all studies were at high risk of certain biases, but the biases observed across primary data collection studies and secondary use of routine health records were different and were, in part, complementary. Biases were balanced across the ASMs investigated, and it is unlikely that the differential results observed across the ASMs are solely explained by these biases. AUTHORS' CONCLUSIONS: Exposure in the womb to certain ASMs was associated with an increased risk of certain MCMs which, for many, is dose-dependent.

ANTECEDENTES: La exposición prenatal a determinados fármacos anticonvulsivos (FAC) se asocia con un mayor riesgo de malformaciones congénitas graves (MCG). La mayoría de las mujeres con epilepsia continúan tomando FAC durante todo el embarazo y, por lo tanto, se requiere información sobre los riesgos potenciales asociados con el tratamiento con FAC. OBJETIVOS: Evaluar los efectos de la exposición prenatal a los FAC sobre la prevalencia de MCG en el niño. MÉTODOS DE BÚSQUEDA: Para la última actualización de esta revisión se hicieron búsquedas el 17 de febrero de 2022 en las siguientes bases de datos: Registro Cochrane de Estudios (Cochrane Register of Studies [CRS Web]), MEDLINE (Ovid, 1946 hasta el 16 de febrero de 2022), SCOPUS (1823 en adelante) y ClinicalTrials.gov , Plataforma de registros internacionales de ensayos clínicos (ICTRP). No se impusieron restricciones de idioma. CRITERIOS DE SELECCIÓN: Se incluyeron estudios prospectivos controlados de cohortes, estudios de cohortes establecidos dentro de registros de embarazos, ensayos controlados aleatorizados y estudios epidemiológicos que utilizaron datos rutinarios de los historiales médicos. Las participantes fueron mujeres con epilepsia que tomaban FAC; los dos grupos de control fueron mujeres sin epilepsia y mujeres con epilepsia que no recibían tratamiento. OBTENCIÓN Y ANÁLISIS DE LOS DATOS: Cinco autores seleccionaron de forma independiente los estudios para inclusión. Ocho autores completaron la extracción de los datos y las evaluaciones del riesgo de sesgo. El desenlace principal fue la presencia de una MCG. Los desenlaces secundarios incluyeron tipos específicos de MCG. Cuando no fue posible realizar un metanálisis, los estudios incluidos se examinaron de forma narrativa. RESULTADOS PRINCIPALES: De 12 296 resúmenes, se revisaron 283 publicaciones a texto completo que identificaron 49 estudios con 128 publicaciones entre ellos. Los datos de los embarazos expuestos a FAC fueron más numerosos en el caso de los estudios prospectivos de cohortes (n = 17 963), que los datos actualmente disponibles de estudios de registros sanitarios epidemiológicos (n = 7913). El riesgo de MCG en los hijos de mujeres sin epilepsia fue del 2,1% (IC del 95%: 1,5 a 3,0) en los estudios de cohortes y del 3,3% (IC del 95%: 1,5 a 7,1) en los estudios de registros sanitarios. El riesgo conocido asociado con la exposición al valproato de sodio fue evidente en todas las comparaciones, con una prevalencia agrupada del 9,8% (IC del 95%: 8,1 a 11,9) a partir de los datos de los estudios de cohortes y del 9,7% (IC del 95%: 7,1 a 13,4) a partir de los estudios con datos rutinarios de los historiales médicos. Este fue elevado en casi todas las comparaciones con otros FAC como monoterapia, con diferencias absolutas de riesgo que variaron entre el 5% y el 9%. Múltiples estudios han constatado que el riesgo de MCG depende de la dosis. Los niños expuestos a la carbamazepina tuvieron una mayor prevalencia de MCG tanto en los estudios de cohortes (4,7%; IC del 95%: 3,7 a 5,9) como en los estudios con datos rutinarios de los historiales médicos (4,0%; IC del 95%: 2,9 a 5,4), que fue significativamente superior a la de los niños nacidos de mujeres sin epilepsia tanto en los estudios de cohortes (RR 2,30; IC del 95%: 1,47 a 3,59) como en los estudios de historias clínicas habituales (RR 1,14; IC del 95%: 0,80 a 1,64), con resultados significativos similares en comparación con los hijos de mujeres con epilepsia que no reciben tratamiento tanto en los estudios de cohortes (RR 1,44; IC del 95%: 1,05 a 1,96) como en los estudios con datos rutinarios de los historiales médicos (RR 1,42; IC del 95%: 1,10 a 1,83). Para la exposición al fenobarbital, la prevalencia fue del 6,3% (IC del 95%: 4,8 a 8,3) y del 8,8% IC del 95%: 0,0 a 9277,0) a partir de los datos de estudios de cohortes y los datos de estudios con datos rutinarios de los historiales médicos, respectivamente. Este aumento del riesgo fue significativo en comparación con los hijos de mujeres sin epilepsia (RR 3,22; IC del 95%: 1,84 a 5,65) y los nacidos de mujeres con epilepsia que no reciben tratamiento (RR 1,64; IC del 95%: 0,94 a 2,83) en estudios de cohortes; los datos procedentes de estudios con datos rutinarios de los historiales médicos fueron limitados. En cuanto a la exposición a la fenitoína, la prevalencia de MCG fue elevada en los datos de los estudios de cohortes (5,4%; IC del 95%: 3,6 a 8,1) y en los datos rutinarios de los historiales médicos (6,8%; IC del 95%: 0,1 a 701,2). La prevalencia de MCG fue mayor en los niños expuestos a la fenitoína en comparación con los hijos de mujeres sin epilepsia (RR 3,81; IC del 95%: 1,91 a 7,57) y los hijos de mujeres con epilepsia que no reciben tratamiento (RR 2,01; IC del 95%: 1,29 a 3,12); no hubo datos procedentes de estudios con datos rutinarios de los historiales médicos. Los datos agrupados de los estudios de cohortes indicaron un riesgo significativamente mayor de MCG en los niños expuestos a lamotrigina en comparación con los niños nacidos de mujeres sin epilepsia (RR 1,99; IC del 95%: 1,16 a 3,39); con una diferencia de riesgos (DR) que indica un riesgo 1% mayor de MCG (DR 0,01. IC del 95%: 0,00 a 0,03). Esto no se repitió en la comparación con los hijos de las mujeres con epilepsia que no reciben tratamiento (RR 1,04; IC del 95%: 0,66 a 1,63), que contenía el mayor grupo de niños expuestos a la lamotrigina (> 2700). Además, también se encontró una diferencia no significativa tanto en comparación con los hijos de mujeres sin epilepsia (RR 1,19; IC del 95%: 0,86 a 1,64) como con los hijos de mujeres con epilepsia que no reciben tratamiento (RR 1,00; IC del 95%: 0,79 a 1,28) a partir de los estudios con datos rutinarios. Para la exposición al levetiracetam, los datos agrupados proporcionaron razones de riesgos similares a las de las mujeres sin epilepsia en los estudios de cohortes (RR 2,20; IC del 95%: 0,98 a 4,93) y en los estudios con datos rutinarios de los historiales médicos (RR 0,67; IC del 95%: 0,17 a 2,66). Los resultados agrupados de los estudios de cohortes (RR: 0,71; IC del 95%: 0,39 a 1,28) y de los estudios con datos rutinarios de los historiales médicos (RR: 0,82; IC del 95%: 0,39 a 1,71) respaldan esta afirmación cuando se comparan con los hijos de las mujeres con epilepsia que no reciben tratamiento. En el caso del topiramato, la prevalencia de MCG fue del 3,9% (IC del 95%: 2,3 a 6,5) a partir de los datos de los estudios de cohortes y del 4,1% (0,0 a 27.050,1) a partir de los estudios con datos rutinarios de los historiales médicos. Las razones de riesgos fueron significativamente más altas para los niños expuestos al topiramato en comparación con los hijos de mujeres sin epilepsia en estudios de cohortes (RR 4,07; IC del 95%: 1,64 a 10,14), pero no en una comparación más pequeña con los hijos de mujeres con epilepsia que no reciben tratamiento (RR 1,37; IC del 95%: 0,57 a 3,27); actualmente se dispone de pocos datos a partir de estudios con datos rutinarios de los historiales médicos. La exposición en el útero al topiramato también se asoció con RR significativamente mayores en comparación con otros FAC para las hendiduras orofaciales. Los datos de todos las demás FAC fueron extremadamente limitados. Debido a los diseños observacionales, todos los estudios presentaron un alto riesgo de ciertos sesgos, pero los sesgos observados en los estudios de obtención de datos primarios y el uso secundario de historiales médicos rutinarios fueron diferentes y, en parte, complementarios. Los sesgos estaban equilibrados entre los FAC investigados, y es poco probable que los resultados diferenciales observados entre los FAC se expliquen únicamente por estos sesgos. CONCLUSIONES DE LOS AUTORES: La exposición en el útero a ciertos FAC se asoció con un mayor riesgo de ciertos MCG que, para muchos, depende de la dosis.

Treatments for the prevention of Sudden Unexpected Death in Epilepsy (SUDEP).

BACKGROUND: This is an updated version of the original Cochrane Review, published in 2016, Issue 7. Sudden Unexpected Death in Epilepsy (SUDEP) is defined as sudden, unexpected, witnessed or unwitnessed, non-traumatic or non-drowning death of people with epilepsy, with or without evidence of a seizure, excluding documented status epilepticus and in whom postmortem examination does not reveal a structural or toxicological cause for death. SUDEP has a reported incidence of 1 to 2 per 1000 patient-years and represents the most common epilepsy-related cause of death. The presence and frequency of generalised tonic-clonic seizures (GTCS), male sex, early age of seizure onset, duration of epilepsy, and polytherapy are all predictors of risk of SUDEP. The exact pathophysiology of SUDEP is currently unknown, although GTCS-induced cardiac, respiratory, and brainstem dysfunction appears likely. Appropriately chosen antiepileptic drug treatment can render around 70% of patients free of all seizures. However, around one-third will remain drug-resistant despite polytherapy. Continuing seizures place patients at risk of SUDEP, depression, and reduced quality of life. Preventative strategies for SUDEP include reducing the occurrence of GTCS by timely referral for presurgical evaluation in people with lesional epilepsy and advice on lifestyle measures; detecting cardiorespiratory distress through clinical observation and seizure, respiratory, and heart rate monitoring devices; preventing airway obstruction through nocturnal supervision and safety pillows; reducing central hypoventilation through physical stimulation and enhancing serotonergic mechanisms of respiratory regulation using selective serotonin reuptake inhibitors (SSRIs); and reducing adenosine and endogenous opioid-induced brain and brainstem depression. OBJECTIVES: To assess the effectiveness of interventions in preventing SUDEP in people with epilepsy by synthesising evidence from randomised controlled trials of interventions and cohort and case-control non-randomised studies. SEARCH METHODS: For the latest update we searched the following databases without language restrictions: Cochrane Register of Studies (CRS Web, 4 February 2019); MEDLINE (Ovid, 1946 to 1 February 2019); SCOPUS (1823 to 4 February 2019); PsycINFO (EBSCOhost, 1887 to 4 January 2019); CINAHL Plus (EBSCOhost, 1937 to 4 February 2019); ClinicalTrials.gov (5 February 2019); and the World Health Organization (WHO) International Clinical Trials Registry Platform (ICTRP, 5 February 2019). We checked the reference lists of retrieved studies for additional reports of relevant studies and contacted lead study authors for any relevant unpublished material. We identified any grey literature studies published in the last five years by searching: Zetoc database; ISI Proceedings; International Bureau for Epilepsy (IBE) congress proceedings database; International League Against Epilepsy (ILAE) congress proceedings database; abstract books of symposia and congresses, meeting abstracts, and research reports. SELECTION CRITERIA: We aimed to include randomised controlled trials (RCTs), quasi-RCTs, and cluster-RCTs; prospective non-randomised cohort controlled and uncontrolled studies; and case-control studies of adults and children with epilepsy receiving an intervention for the prevention of SUDEP. Types of interventions included: early versus delayed pre-surgical evaluation for lesional epilepsy; educational programmes; seizure-monitoring devices; safety pillows; nocturnal supervision; selective serotonin reuptake inhibitors (SSRIs); opiate antagonists; and adenosine antagonists. DATA COLLECTION AND ANALYSIS: We aimed to collect data on study design factors and participant demographics for included studies. The primary outcome of interest was the number of deaths from SUDEP. Secondary outcomes included: number of other deaths (unrelated to SUDEP); change in mean depression and anxiety scores (as defined within the study); clinically important change in quality of life, that is any change in quality of life score (average and endpoint) according to validated quality of life scales; and number of hospital attendances for seizures. MAIN RESULTS: We identified 1277 records from the databases and search strategies. We found 10 further records by searching other resources (handsearching). We removed 469 duplicate records and screened 818 records (title and abstract) for inclusion in the review. We excluded 785 records based on the title and abstract and assessed 33 full-text articles. We excluded 29 studies: eight studies did not assess interventions to prevent SUDEP; eight studies were review articles, not clinical studies; five studies measured sensitivity of devices to detect GTCS but did not directly measure SUDEP; six studies assessed risk factors for SUDEP but not interventions for preventing SUDEP; and two studies did not have a control group. We included one cohort study and three case-control studies of serious to critical risk of bias. The 6-month prospective cohort study observed no significant effect of providing patients with SUDEP information on drug compliance and quality of life, anxiety and depression levels. The study was too short and with no deaths observed in either group to determine a protective effect. Two case control studies reported a protective effect for nocturnal supervision against SUDEP. However due to significant heterogeneity, the results could not be combined in meta-analysis. One study of 154 SUDEP cases and 616 controls reported an unadjusted odds ratio (OR) of 0.34 (95% CI 0.22 to 0.53; P < 0.0001). The same study demonstrated the protective effect was independent of seizure control, suggesting that nocturnal supervision is not just a surrogate marker of seizure control. The second case-control study of 48 SUDEP cases and 220 controls reported an unadjusted OR of 0.08 (95% CI 0.02 to 0.27; P < 0.0001). The third case-control study of residential care centre patients who were already receiving physical checks more than 15 minutes apart throughout the night did not report any protective effect for additional nocturnal supervision (physical checks < 15 minutes apart; use of listening devices; dormitory setting; and use of bed sensors). However the same study did ascertain a difference between centres: the residential centre with the lowest level of supervision had the highest incidence of SUDEP. The case-control studies did not report on quality of life or depression and anxiety scores. AUTHORS' CONCLUSIONS: We found limited, very low-certainty evidence that supervision at night reduces the incidence of SUDEP. Further research is required to identify the effectiveness of other current interventions - for example seizure detection devices, safety pillows, SSRIs, early surgical evaluation, educational programmes, and opiate and adenosine antagonists - in preventing SUDEP in people with epilepsy.

Ketogenic diets for drug-resistant epilepsy.

BACKGROUND: Ketogenic diets (KDs), being high in fat and low in carbohydrates, have been suggested to reduce seizure frequency in people with epilepsy. At present, such diets are mainly recommended for children who continue to have seizures despite treatment with antiepileptic drugs (AEDs) (drug-resistant epilepsy). Recently, there has been interest in less restrictive KDs, including the modified Atkins diet (MAD), and the use of these diets has extended into adult practice. This is an update of a review first published in 2003 and last updated in 2016. OBJECTIVES: To assess the effects of KDs for drug-resistant epilepsy by reviewing the evidence from randomised controlled trials. SEARCH METHODS: For the latest update we searched the Cochrane Epilepsy Group's Specialized Register (11 April 2017), the Cochrane Central Register of Controlled Trials (CENTRAL) via the Cochrane Register of Studies Online (CRSO, 11 April 2017), MEDLINE (Ovid, 11 April 2017), ClinicalTrials.gov (11 April 2017) and the WHO International Clinical Trials Registry Platform (ICTRP, 11 April 2017). We imposed no language restrictions. We checked the reference lists of retrieved studies for additional reports of relevant studies. SELECTION CRITERIA: Randomised controlled trials or quasi-randomised controlled trials of ketogenic diets for people with drug-resistant epilepsy. DATA COLLECTION AND ANALYSIS: Two review authors independently applied predefined criteria to extract data and assessed study quality. MAIN RESULTS: We identified 11 randomised controlled trials (RCTs) that generated 15 publications.All trials applied an intention-to-treat analysis with varied randomisation methods. The 11 studies recruited 778 patients; 712 children and adolescents and 66 adults. We assessed all 11 studies to be at low to unclear risk of bias for the following domains: random sequence generation, allocation concealment and selective reporting. For the other domains (blinding, incomplete outcome data, other bias) assessments were varied (low, unclear and high risk of bias). We could not conduct a meta-analysis due to the heterogeneity of the studies and the quality of the evidence was low to very low (GRADE ratings).Reported rates of seizure freedom reached as high as 55% in a classical 4:1 KD group after three months and reported rates of seizure reduction reached as high as 85% in a classical 4:1 KD group after three months (GRADE rating low).One trial found no significant difference between the fasting-onset and gradual-onset KD for rates of seizure freedom, and reported a greater rate of seizure reduction in the gradual-onset KD group.Studies assessing the efficacy of the MAD reported seizure freedom rates of up to 25% and seizure reduction rates of up to 60% in children. One study used a simplified MAD (sMAD) and reported seizure freedom rates of 15% and seizure reduction rates of 56% in children. One study utilised a MAD in adults and reported seizure reduction rates of 35%, but no patients became seizure free (GRADE rating low).Adverse effects of the dietary interventions were experienced in all studies. The most commonly reported adverse effects were gastrointestinal syndromes. It was common that adverse effects were the reason for participants dropping out of trials (GRADE rating low). Other reasons for dropout included lack of efficacy and non-acceptance of the diet (GRADE rating low).Although there was some evidence for greater antiepileptic efficacy for a classical 4:1 KD over lower ratios, the classical 4:1 KD was consistently associated with more adverse effects.One study assessed the effect of dietary interventions on quality of life, cognition and behavioural functioning, reporting participants in the KD group to be more active, more productive and less anxious after four months, compared to the control group. However, no significant difference was found in quality-adjusted life years (QALYs) between the KD group and control group at four or 16 months (GRADE rating very low). AUTHORS' CONCLUSIONS: The RCTs discussed in this review show promising results for the use of KDs in epilepsy. However, the limited number of studies, small sample sizes and the limited studies in adults, resulted in a low to very low overall quality of evidence.There were adverse effects within all of the studies and for all KD variations, such as short-term gastrointestinal-related disturbances and increased cholesterol. However, study periods were short, therefore the long-term risks associated with these adverse effects is unknown. Attrition rates remained a problem with all KDs and across all studies; reasons for this being lack of observed efficacy and dietary tolerance.Only one study reported the use of KDs in adults with epilepsy; therefore further research would be of benefit.Other more palatable but related diets, such as the MAD, may have a similar effect on seizure control as the classical KD, but this assumption requires more investigation. For people who have medically intractable epilepsy or people who are not suitable for surgical intervention, KDs remain a valid option; however, further research is required.

Monotherapy treatment of epilepsy in pregnancy: congenital malformation outcomes in the child.

BACKGROUND: There is evidence that certain antiepileptic drugs (AEDs) are teratogenic and are associated with an increased risk of congenital malformation. The majority of women with epilepsy continue taking AEDs throughout pregnancy; therefore it is important that comprehensive information on the potential risks associated with AED treatment is available. OBJECTIVES: To assess the effects of prenatal exposure to AEDs on the prevalence of congenital malformations in the child. SEARCH METHODS: We searched the Cochrane Epilepsy Group Specialized Register (September 2015), Cochrane Central Register of Controlled Trials (CENTRAL) (2015, Issue 11), MEDLINE (via Ovid) (1946 to September 2015), EMBASE (1974 to September 2015), Pharmline (1978 to September 2015), Reprotox (1983 to September 2015) and conference abstracts (2010-2015) without language restriction. SELECTION CRITERIA: We included prospective cohort controlled studies, cohort studies set within pregnancy registries and randomised controlled trials. Participants were women with epilepsy taking AEDs; the two control groups were women without epilepsy and women with epilepsy who were not taking AEDs during pregnancy. DATA COLLECTION AND ANALYSIS: Three authors independently selected studies for inclusion. Five authors completed data extraction and risk of bias assessments. The primary outcome was the presence of a major congenital malformation. Secondary outcomes included specific types of major congenital malformations. Where meta-analysis was not possible, we reviewed included studies narratively. MAIN RESULTS: We included 50 studies, with 31 contributing to meta-analysis. Study quality varied, and given the observational design, all were at high risk of certain biases. However, biases were balanced across the AEDs investigated and we believe that the results are not explained by these biases.Children exposed to carbamazepine (CBZ) were at a higher risk of malformation than children born to women without epilepsy (N = 1367 vs 2146, risk ratio (RR) 2.01, 95% confidence interval (CI) 1.20 to 3.36) and women with untreated epilepsy (N = 3058 vs 1287, RR 1.50, 95% CI 1.03 to 2.19). Children exposed to phenobarbital (PB) were at a higher risk of malformation than children born to women without epilepsy (N = 345 vs 1591, RR 2.84, 95% CI 1.57 to 5.13). Children exposed to phenytoin (PHT) were at an increased risk of malformation compared with children born to women without epilepsy (N = 477 vs 987, RR 2.38, 95% CI 1.12 to 5.03) and to women with untreated epilepsy (N = 640 vs 1256, RR 2.40, 95% CI 1.42 to 4.08). Children exposed to topiramate (TPM) were at an increased risk of malformation compared with children born to women without epilepsy (N = 359 vs 442, RR 3.69, 95% CI 1.36 to 10.07). The children exposed to valproate (VPA) were at a higher risk of malformation compared with children born to women without epilepsy (N = 467 vs 1936, RR 5.69, 95% CI 3.33 to 9.73) and to women with untreated epilepsy (N = 1923 vs 1259, RR 3.13, 95% CI 2.16 to 4.54). There was no increased risk for major malformation for lamotrigine (LTG). Gabapentin (GBP), levetiracetam (LEV), oxcarbazepine (OXC), primidone (PRM) or zonisamide (ZNS) were not associated with an increased risk, however, there were substantially fewer data for these medications.For AED comparisons, children exposed to VPA had the greatest risk of malformation (10.93%, 95% CI 8.91 to 13.13). Children exposed to VPA were at an increased risk of malformation compared with children exposed to CBZ (N = 2529 vs 4549, RR 2.44, 95% CI 2.00 to 2.94), GBP (N = 1814 vs 190, RR 6.21, 95% CI 1.91 to 20.23), LEV (N = 1814 vs 817, RR 5.82, 95% CI 3.13 to 10.81), LTG (N = 2021 vs 4164, RR 3.56, 95% CI 2.77 to 4.58), TPM (N = 1814 vs 473, RR 2.35, 95% CI 1.40 to 3.95), OXC (N = 676 vs 238, RR 3.71, 95% CI 1.65 to 8.33), PB (N = 1137 vs 626, RR 1.59, 95% CI 1.11 to 2.29, PHT (N = 2319 vs 1137, RR 2.00, 95% CI 1.48 to 2.71) or ZNS (N = 323 vs 90, RR 17.13, 95% CI 1.06 to 277.48). Children exposed to CBZ were at a higher risk of malformation than those exposed to LEV (N = 3051 vs 817, RR 1.84, 95% CI 1.03 to 3.29) and children exposed to LTG (N = 3385 vs 4164, RR 1.34, 95% CI 1.01 to 1.76). Children exposed to PB were at a higher risk of malformation compared with children exposed to GBP (N = 204 vs 159, RR 8.33, 95% CI 1.04 to 50.00), LEV (N = 204 vs 513, RR 2.33, 95% CI 1.04 to 5.00) or LTG (N = 282 vs 1959, RR 3.13, 95% CI 1.64 to 5.88). Children exposed to PHT had a higher risk of malformation than children exposed to LTG (N = 624 vs 4082, RR 1.89, 95% CI 1.19 to 2.94) or to LEV (N = 566 vs 817, RR 2.04, 95% CI 1.09 to 3.85); however, the comparison to LEV was not significant in the random-effects model. Children exposed to TPM were at a higher risk of malformation than children exposed to LEV (N = 473 vs 817, RR 2.00, 95% CI 1.03 to 3.85) or LTG (N = 473 vs 3975, RR 1.79, 95% CI 1.06 to 2.94). There were no other significant differences, or comparisons were limited to a single study.We found significantly higher rates of specific malformations associating PB exposure with cardiac malformations and VPA exposure with neural tube, cardiac, oro-facial/craniofacial, and skeletal and limb malformations in comparison to other AEDs. Dose of exposure mediated the risk of malformation following VPA exposure; a potential dose-response association for the other AEDs remained less clear. AUTHORS' CONCLUSIONS: Exposure in the womb to certain AEDs carried an increased risk of malformation in the foetus and may be associated with specific patterns of malformation. Based on current evidence, LEV and LTG exposure carried the lowest risk of overall malformation; however, data pertaining to specific malformations are lacking. Physicians should discuss both the risks and treatment efficacy with the patient prior to commencing treatment.

Treatments for the prevention of Sudden Unexpected Death in Epilepsy (SUDEP).

BACKGROUND: Sudden Unexpected Death in Epilepsy (SUDEP) is defined as sudden, unexpected, witnessed or unwitnessed, non-traumatic or non-drowning death of people with epilepsy, with or without evidence of a seizure, excluding documented status epilepticus and in whom postmortem examination does not reveal a structural or toxicological cause for death. SUDEP has a reported incidence of 1 to 2 per 1000 patient years and represents the most common epilepsy-related cause of death. The presence and frequency of generalised tonic-clonic seizures (GTCS), male sex, early age of seizure onset, duration of epilepsy, and polytherapy are all predictors of risk of SUDEP. The exact pathophysiology of SUDEP is currently unknown, although GTCS-induced cardiac, respiratory, and brainstem dysfunction appears likely. Appropriately chosen antiepileptic drug treatment can render around 70% of patients free of all seizures. However, around one-third will remain drug refractory despite polytherapy. Continuing seizures place patients at risk of SUDEP, depression, and reduced quality of life. Preventative strategies for SUDEP include reducing the occurrence of GTCS by timely referral for presurgical evaluation in people with lesional epilepsy and advice on lifestyle measures; detecting cardiorespiratory distress through clinical observation and seizure, respiratory, and heart rate monitoring devices; preventing airway obstruction through nocturnal supervision and safety pillows; reducing central hypoventilation through physical stimulation and enhancing serotonergic mechanisms of respiratory regulation using selective serotonin reuptake inhibitors (SSRIs); reducing adenosine and endogenous opioid-induced brain and brainstem depression. OBJECTIVES: To assess the effectiveness of interventions in preventing SUDEP in people with epilepsy by synthesising evidence from randomised controlled trials of interventions and cohort and case-control non-randomised studies. SEARCH METHODS: We searched the following databases: Cochrane Epilepsy Group Specialized Register; Cochrane Central Register of Controlled Trials (CENTRAL, Issue 11, 2015) via the Cochrane Register of Studies Online (CRSO); MEDLINE (Ovid, 1946 onwards); SCOPUS (1823 onwards); PsycINFO (EBSCOhost, 1887 onwards); CINAHL Plus (EBSCOhost, 1937 onwards); ClinicalTrials.gov; and the World Health Organization (WHO) International Clinical Trials Registry Platform (ICTRP). We used no language restrictions. The date of the last search was 12 November 2015. We checked the reference lists of retrieved studies for additional reports of relevant studies and contacted lead study authors for any relevant unpublished material. We identified duplicate studies by screening reports according to title, authors' names, location, and medical institute, omitting any duplicated studies. We identified any grey literature studies published in the last five years by searching: Zetoc database; ISI Proceedings; International Bureau for Epilepsy (IBE) congress proceedings database; International League Against Epilepsy (ILAE) congress proceedings database; abstract books of symposia and congresses, meeting abstracts, and research reports. SELECTION CRITERIA: We aimed to include randomised controlled trials (RCTs), quasi-RCTs, and cluster-RCTs; prospective non-randomised cohort controlled and uncontrolled studies; and case-control studies of adults and children with epilepsy receiving an intervention for the prevention of SUDEP. Types of interventions included: early versus delayed pre-surgical evaluation for lesional epilepsy; educational programmes; seizure-monitoring devices; safety pillows; nocturnal supervision; selective serotonin reuptake inhibitors (SSRIs); opiate antagonists; and adenosine antagonists. DATA COLLECTION AND ANALYSIS: We aimed to collect data on study design factors and participant demographics for included studies. The primary outcome of interest was the number of deaths from SUDEP. Secondary outcomes included: number of other deaths (unrelated to SUDEP); change in mean depression and anxiety scores (as defined within the study); clinically important change in quality of life, that is any change in quality of life score (average and endpoint) according to validated quality of life scales; and number of hospital attendances for seizures. MAIN RESULTS: We identified 582 records from the databases and search strategies. We found 10 further records by searching other resources (handsearching). We removed 211 duplicate records and screened 381 records (title and abstract) for inclusion in the review. We excluded 364 records based on the title and abstract and assessed 17 full-text articles. We excluded 15 studies: eight studies did not assess interventions to prevent SUDEP; five studies measured sensitivity of devices to detect GTCS but did not directly measure SUDEP; and two studies assessed risk factors for SUDEP but not interventions for preventing SUDEP. One listed study is awaiting classification.We included one case-control study at serious risk of bias within a qualitative analysis in this review. This study of 154 cases of SUDEP and 616 controls ascertained a protective effect for the presence of nocturnal supervision (unadjusted odds ratio (OR) 0.34, 95% confidence interval (CI) 0.22 to 0.53) and when a supervising person shared the same bedroom or when special precautions, for example a listening device, were used (unadjusted OR 0.41, 95% CI 0.20 to 0.82). This effect was independent of seizure control. Non-SUDEP deaths; changes to anxiety, depression, and quality of life; and number of hospital attendances were not reported. AUTHORS' CONCLUSIONS: We found very low-quality evidence of a preventative effect for nocturnal supervision against SUDEP. Further research is required to identify the effectiveness of other current interventions, for example seizure detection devices, safety pillows, SSRIs, early surgical evaluation, educational programmes, and opiate and adenosine antagonists in preventing SUDEP in people with epilepsy.

Ketogenic diet and other dietary treatments for epilepsy.

BACKGROUND: The ketogenic diet (KD), being high in fat and low in carbohydrates, has been suggested to reduce seizure frequency. It is currently used mainly for children who continue to have seizures despite treatment with antiepileptic drugs. Recently, there has been interest in less restrictive KDs including the modified Atkins diet (MAD) and the use of these diets has extended into adult practice. OBJECTIVES: To review the evidence for efficacy and tolerability from randomised controlled trials regarding the effects of KD and similar diets. SEARCH METHODS: We searched the Cochrane Epilepsy Group's Specialized Register (30 March 2015), the Cochrane Central Register of Controlled Trials (CENTRAL) via the Cochrane Register of Studies Online (CRSO, 30 March 2015), MEDLINE (Ovid, 30 March 2015), ClinicalTrials.gov (30 March 2015) and the WHO International Clinical Trials Registry Platform (ICTRP, 30 March 2015). We imposed no language restrictions. We checked the reference lists of retrieved studies for additional reports of relevant studies. SELECTION CRITERIA: Studies of KDs and similar diets for people with epilepsy. DATA COLLECTION AND ANALYSIS: Two review authors independently applied pre-defined criteria to extract data and assessed study quality. MAIN RESULTS: We identified seven randomised controlled trials that generated eight publications.All trials applied an intention-to-treat analysis with varied randomisation methods. The seven studies recruited 427 children and adolescents and no adults. We could not conduct a meta-analysis due to the heterogeneity of the studies.Reported rates of seizure freedom reached as high as 55% in a 4 : 1 KD group after three months and reported rates of seizure reduction reached as high as 85% in a 4 : 1 KD group after three months.One trial found no significant difference between the fasting-onset and gradual-onset KD for rates of seizure freedom and reported a greater rate of seizure reduction in the gradual-onset KD group.Studies assessing the efficacy of the MAD reported seizure freedom rates of up to 10% and seizure reduction rates of up to 60%. One study compared the MAD to a 4 : 1 KD, but did not report rates of seizure freedom or seizure reduction.Adverse effects were fairly consistent across different dietary interventions. The most commonly reported adverse effects were gastrointestinal syndromes. It was common that adverse effects were the reason for participants dropping out of trials. Other reasons for drop-out included lack of efficacy and non-acceptance of the diet.Although there was some evidence for greater antiepileptic efficacy for a 4 : 1 KD over lower ratios, the 4 : 1 KD was consistently associated with more adverse effects.No studies assessed the effect of dietary interventions on quality of life, or cognitive or behavioural functioning. AUTHORS' CONCLUSIONS: The randomised controlled trials discussed in this review show promising results for the use of KDs in epilepsy. However, the limited number of studies, small sample sizes and a sole paediatric population resulted in a poor overall quality of evidence.There were adverse effects within all of the studies and for all KD variations, such as short-term gastrointestinal-related disturbances, to longer-term cardiovascular complications. Attrition rates remained a problem with all KDs and across all studies, reasons for this being lack of observed efficacy and dietary tolerance.There was a lack of evidence to support the clinical use of KD in adults with epilepsy, therefore, further research would be of benefit.Other more palatable but related diets, such as the MAD ketogenic diet, may have a similar effect on seizure control as classical KD but this assumption requires more investigation. For people who have medically intractable epilepsy or people who are not suitable for surgical intervention, a KD remains a valid option; however, further research is required.

Pharmacological interventions for epilepsy in people with intellectual disabilities.

BACKGROUND: The prevalence of epilepsy among people with intellectual disabilities is much higher than in the general population. Seizures in this population are often complex and refractory to treatment and antiepileptic medication may have a profound effect upon behaviour (Kerr 1997).This is an updated version of a Cochrane Review first published in Issue 3, 2007. OBJECTIVES: To assess the data available from randomised controlled trials (RCTs) of the efficacy of antiepileptic drug (AED) interventions in people with epilepsy and intellectual disabilities. SEARCH METHODS: For the latest update of this review, we searched the Cochrane Epilepsy Group Specialised Register (2 September 2014), the Cochrane Central Register of Controlled Trials (CENTRAL) via the Cochrane Register of Studies Online (CRSO) (2 September 2014), MEDLINE (Ovid, 1946 to 3 September 2014) and PsycINFO (EBSCOhost, 1887 to 3 September 2014). SELECTION CRITERIA: Randomised and quasi-randomised controlled trials (RCTs) of pharmacological interventions for people with epilepsy and a learning disability. DATA COLLECTION AND ANALYSIS: Two review authors independently assessed trial quality and extracted data. We contacted study authors for additional information. We assessed epilepsy/seizure, behavioural and cognitive outcomes, as well as quality of life and adverse effects. MAIN RESULTS: We included 14 RCTs (1116 participants) in the present review. Data were heterogenous and a descriptive analysis is presented. In the majority of cases where antiepileptic drugs (AEDs) were trialled in this population, we found moderate reductions in seizure frequency in that there was a significantly higher rate of responders (reduction of 50% or more) in the treatment group compared with the placebo group, with some studies reporting a higher incidence of seizure freedom in the treatment group. In general, AEDs that are proven to be effective in the general epilepsy population are also effective for refractory epilepsy in people with intellectual disability. It is not possible to comment on the relative efficacy of medications, making clinical decisions difficult.In trial settings patients continued on treatment in the majority of cases. Placebo groups often experienced fewer adverse events. Where adverse events were experienced they appeared similar to those in the general population. The methods by which adverse events were recorded and reported appeared to be inconsistent, resulting in very large variation between studies. This is problematic as clinically relevant interpretation of these findings is limited.The quality of evidence provided in the present review is low to moderate. Additionally the majority of studies lacked or used non-reliable measures of behavioural exacerbation. However, where measured, little obvious impact on behaviour was seen in terms of behaviour disorder. AUTHORS' CONCLUSIONS: This review broadly supports the use of AEDs to reduce seizure frequency in people with refractory epilepsy and intellectual disability. The evidence suggests that adverse events are similar to those in the general population and that behavioural adverse events leading to discontinuation are rare; however, other adverse effects are under-researched.

Non-pharmacological interventions for people with epilepsy and intellectual disabilities.

BACKGROUND: Approximately 30% of patients with epilepsy remain refractory to drug treatment and continue to experience seizures whilst taking one or more antiepileptic drugs (AEDs). Several non-pharmacological interventions that may be used in conjunction with or as an alternative to AEDs are available for refractory patients. In view of the fact that seizures in people with intellectual disabilities are often complex and refractory to pharmacological interventions, it is evident that good quality randomised controlled trials (RCTs) are needed to assess the efficacy of alternatives or adjuncts to pharmacological interventions.This is an updated version of the original Cochrane review (Beavis 2007) published in The Cochrane Library (2007, Issue 4). OBJECTIVES: To assess data derived from randomised controlled trials of non-pharmacological interventions for people with epilepsy and intellectual disabilities.Non-pharmacological interventions include, but are not limited to, the following.• Surgical procedures.• Specialised diets, for example, the ketogenic diet, or vitamin and folic acid supplementation.• Psychological interventions for patients or for patients and carers/parents, for example, cognitive-behavioural therapy (CBT), electroencephalographic (EEG) biofeedback and educational intervention.• Yoga.• Acupuncture.• Relaxation therapy (e.g. music therapy). SEARCH METHODS: For the latest update of this review, we searched the Cochrane Epilepsy Group Specialised Register (19 August 2014), the Cochrane Central Register of Controlled Trials (CENTRAL) via CRSO (19 August 2014), MEDLINE (Ovid, 1946 to 19 August 2014) and PsycINFO (EBSCOhost, 1887 to 19 August 2014). SELECTION CRITERIA: Randomised controlled trials of non-pharmacological interventions for people with epilepsy and intellectual disabilities. DATA COLLECTION AND ANALYSIS: Two review authors independently applied the inclusion criteria and extracted study data. MAIN RESULTS: One study is included in this review. When two surgical procedures were compared, results indicated that corpus callosotomy with anterior temporal lobectomy was more effective than anterior temporal lobectomy alone in improving quality of life and performance on IQ tests among people with epilepsy and intellectual disabilities. No evidence was found to support superior benefit in seizure control for either intervention. This is the only study of its kind and was rated as having an overall unclear risk of bias. The previous update (December 2010) identified one RCT in progress. The study authors have confirmed that they are aiming to publish by the end of 2015; therefore this study (Bjurulf 2008) has not been included in the current review. AUTHORS' CONCLUSIONS: This review highlights the need for well-designed randomised controlled trials conducted to assess the effects of non-pharmacological interventions on seizure and behavioural outcomes in people with intellectual disabilities and epilepsy.

Neuropsychological and psychological interventions for people with newly diagnosed epilepsy.

BACKGROUND: Many people with epilepsy report experiencing psychological difficulties such as anxiety, depression and neuropsychological deficits including memory problems. Research has shown that these difficulties are often present not only for people with chronic epilepsy but also for people with newly diagnosed epilepsy. Despite this, there are very few published interventions that detail means to help people with newly diagnosed epilepsy manage these problems. OBJECTIVES: To identify and assess possible psychological and neuropsychological interventions for adults with newly diagnosed epilepsy. SEARCH METHODS: We searched the following databases on 30 June 2015: the Cochrane Epilepsy Group Specialized Register, the Cochrane Central Register of Controlled Trials (CENTRAL), MEDLINE (Ovid), SCOPUS, PsycINFO, CINAHL, ClinicalTrials.gov and the World Health Organization (WHO) International Clinical Trials Registry Platform (ICTRP). SELECTION CRITERIA: This review includes all randomised controlled trials, quasi-randomised controlled trials, prospective cohort controlled studies, and prospective before and after studies which include psychological or neuropsychological interventions for people with newly diagnosed epilepsy. We excluded studies that included people with epilepsy and any other psychological disorder or neurological condition. We excluded studies carried out which recruited only children. DATA COLLECTION AND ANALYSIS: We used the standard methodological procedure expected by The Cochrane Collaboration. Two authors independently completed data extraction and risk of bias analysis. The results of this were cross-checked and third author resolved any discrepancies. In the event of missing data, we contacted the study authors. Meta-analysis was not completed due to differences in the intervention and outcomes reported in the two studies. MAIN RESULTS: We included two randomised controlled trials assessing psychological interventions for people with newly diagnosed epilepsy. One study assessed a cognitive behavioural intervention (CBI) in an adolescent population. This study was rated as low quality. One study assessed a specialist nurse intervention in an adult population. This study was rating as very low quality.We rated one study as having unclear risk of bias and one study as having high risk of bias.The CBI study indicated that this intervention could significantly reduce depressive symptoms in people with subthreshold depressive disorder. However, the study assessing the effectiveness of a nurse intervention found no significant benefit for depressive symptoms,but did find that in individuals with the least knowledge of epilepsy, a nurse intervention could increase their knowledge of epilepsy scores. AUTHORS' CONCLUSIONS: Meta-analysis was not possible as we identified only two studies and they utilised different interventions and outcome measures.Previous research has highlighted the impact of psychological and neuropsychological difficulties experienced by people with epilepsy and the negative effect this has on their quality of life. The main finding of this review is that there is a paucity of research assessing possible neuropsychological and psychological interventions for adults with newly diagnosed epilepsy.