Clinical course of epilepsy
Good seizure control is paramount during pregnancy, especially in the light of the observation that maternal mortality rates are higher in women with epilepsy compared to the general population (Adab et al., 2004). In addition, convulsive seizures in the mother may cause fetal bradycardia (Teramo et al., 1979), and status epilepticus has been associated with intrauterine fetal death (Teramo & Hiilesmaa, 1982; The EURAP Study Group, 2006).
Studies on the natural history of epilepsy during pregnancy have reported discordant and, often, poorly comparable findings. Methods are not uniform across studies, and many reports do not provide information on enrollment criteria or definitions of changes in seizure frequency, the duration of the observation period before pregnancy, the role of pharmacotherapy, or other confounders potentially influencing the clinical course of epilepsy during pregnancy.
A review of 27 studies published between 1884 and 1980 (Schmidt, 1982b) totaling 2,165 pregnancies, showed that on average seizure frequency increased during pregnancy in 24.1% (4–67%) of women with epilepsy, decreased in 22.7% (0–82%), and remained unchanged in 53.2% (4–96%). The mean rate of improvement in another 18 studies was slightly lower (13.5%), whereas the incidence of worsening was similar (24.5%) (Dravet et al., 1982; Remillard, 1982; Schmidt et al., 1983; Otani, 1985; Bardy, 1987; Gjerde et al., 1988; Specchio, 1989; Wilhelm et al., 1990; Lander & Eadie, 1991; Tanganelli & Regesta, 1992; Kilpatrick & Hopper, 1993; Tomson, 1994; Vidovic & Della Marina, 1994; Sabers et al., 1998; Kaneko et al., 1999; Thomas et al., 2001). Four studies reported that an increase in seizure frequency was more common during the first and third trimesters of pregnancy and was reversible after delivery (Remillard, 1982; Schmidt et al., 1983; Bardy, 1987; Sabers et al., 1998). On the other hand, Tomson et al. (1994) found that seizure frequency tended to diminish in the first trimester of pregnancy, with no further changes in the second and third trimesters. Some studies reported an intraindividual variability in seizure frequency, even among different pregnancies in the same patients (Sabers et al., 1998). Lastly, a recent prospective study analyzing approximately 2,000 pregnancies (The EURAP Study Group, 2006) showed that about 60% of women with epilepsy did not have seizures during pregnancy and that partial epilepsy, and polytherapy and monotherapy with oxcarbazepine were independently associated with an increased risk of seizure worsening during pregnancy (The EURAP Study Group, 2006). Thus far, only one retrospective study has investigated whether changes in seizure frequency during pregnancy could be due to random fluctuation (Kilpatrick & Hopper, 1993). This study reported a worsening in seizure frequency in 41% of pregnant women compared to 24% in controls (nonpregnant women). However, dose reductions and withdrawal of treatment were more common among pregnant women. Moreover, the risk of seizure worsening in this study was found to increase slightly but significantly with disease duration.
Eight studies have examined the relation between increased seizure frequency, type of seizures and/or epileptic syndrome, frequency of seizures before pregnancy, and disease duration (Remillard, 1982; Bardy, 1987; Specchio, 1989; Tanganelli & Regesta, 1992; Kilpatrick & Hopper, 1993; Tomson et al., 1994; Sabers et al., 1998; Kaneko et al., 1999). The correlation between worsening of seizure control and seizure type, when reported (Remillard, 1982; Tanganelli & Regesta, 1992; Tomson et al., 1994; Kaneko et al., 1999), was mainly confined to women with focal seizures. Some studies have also reported that a good seizure control before pregnancy, especially when long-lasting, exerted a protective effect toward subsequent worsening during pregnancy (Remillard, 1982; Specchio, 1989). On the other hand, the occurrence of frequent seizures before pregnancy was associated with worsening of seizure control in up to 50% of all patients (Tanganelli & Regesta, 1992; Sabers et al., 1998). Other potential risk factors, including metabolic and hormonal profiles, psychological distress, sleep disorders and, above all, irregular intake of AEDs, need to be explored in a more systematic manner.
Data from 12 studies estimated at 1.1% the frequency of status epilepticus during pregnancy (43 of 2,915 cases) (Canger, 1982; Remillard, 1982; Schmidt et al., 1983; Otani, 1985; Bardy, 1987; Gjerde et al., 1988; Wilhelm et al., 1990; Tanganelli & Regesta, 1992; Tomson et al., 1994; Sabers et al., 1998; The EURAP Study Group, 2006), which is in line with other literature reviews (Schmidt, 1982a, 1982b). The EURAP Study Group (2006) reported only one case of intrauterine death related to status epilepticus and no cases of maternal mortality among 36 cases of status epilepticus (12 convulsive cases) during pregnancy.
Modifications of AED pharmacokinetics
Pregnancy gives rise to major physiologic changes that may significantly influence the absorption, distribution, metabolism, and renal elimination of drugs, thereby affecting their plasma concentrations, sometimes to a clinically significant degree (Perucca, 1987). In most cases, plasma AED concentrations decrease during pregnancy and promptly return to prepregnancy levels following delivery. Free plasma concentrations of drugs highly bound to plasma proteins (phenytoin, valproic acid and, to a lesser extent, carbamazepine) generally decrease to a lesser extent than total concentrations (Yerby et al., 1990, 1992a).
In general, the plasma concentration of AEDs begins to decline from the first trimester. In the third trimester, the mean decline is 55–61% for total phenytoin, 18–31% for free phenytoin, 0–42% for total carbamazepine, 0–28% for free carbamazepine; 50–55% for phenobarbital, 55% for primidone, 70% for primidone-derived phenobarbital, 50% for total valproic acid, and 0–29% for free valproic acid (free valproic acid concentrations, may actually be increased by 25% at delivery compared with prepregnancy values) (Tomson & Battino, 2007). It should be noted, however, that interindividual variability may be high (Tomson & Battino, 2007).
Among the newer AEDs, lamotrigine has been the most extensively studied. Its pharmacokinetics change dramatically, and the mean plasma concentrations of lamotrigine decline by 68% during pregnancy, albeit with a significant interindividual variability. An increase in seizure frequency has also been reported (Tomson & Battino, 2007). The reduction in plasma lamotrigine levels during pregnancy is appreciably attenuated by coadministration of valproic acid (Tomson et al., 2006). There is more limited evidence that pregnancy is also associated with a major reduction in the plasma levels of the MHD of oxcarbazepine (Tomson & Battino, 2007) and, possibly, levetiracetam (Tomson & Battino, 2007). No information is available on potential alterations in the pharmacokinetics of other new-generation AEDs (gabapentin, vigabatrin, pregabalin, tiagabine, topiramate, and zonisamide) (Tomson & Battino, 2007).
In clinical practice, pharmacokinetic changes can be assessed only by measuring plasma drug concentrations before, during, and after pregnancy (Committee on Educational Bulletins of the American College of Obstetricians and Gynecologists, 1997; Quality Standards Subcommittee of the American Academy of Neurology, 1998; Krishnamurthy, 2002). In general, AED dosage should not be modified unless there are changes in clinical response (seizure relapse, increased seizure frequency, adverse effects). However, laboratory parameters may prompt dose adjustment in some cases. For example, the optimal plasma concentration of each AED can often be established for each patient before conception (“optimum individualized therapeutic value”). In this regard, a reduction of plasma AED concentrations during pregnancy to levels previously associated with the occurrence or worsening of seizures in the same patient may warrant an increase in dosage, especially after the first trimester of pregnancy. Any dose modification should be made on an individual basis and potential risks should be weighed against achievable benefits. In interpreting analytical data for AEDs highly bound to plasma proteins (namely, phenytoin and valproic acid) and comparing them with the “optimum individualized therapeutic values,” the association of pregnancy with an elevation in the free fraction should be taken into account (Yerby et al., 1992a, 1992b; Pennell et al., 2004). In other words, the reduction in the free (pharmacologically active) plasma concentration may be of a much smaller magnitude than the reduction in total concentration. In the absence of direct measurements of free drug concentrations, changes in the free fraction of phenytoin and valproic acid may be estimated from plasma albumin levels (Perucca & Crema, 1982).
The frequency of plasma AED monitoring during pregnancy will depend on the specific clinical conditions and the type of AED used. Monthly monitoring is recommended for AEDs with major and poorly predictable pharmacokinetic changes, such as lamotrigine, phenobarbital derived from primidone and, probably, levetiracetam and the MHD of oxcarbazepine. If dosage has been increased during pregnancy, more frequent monitoring may be useful in the 3 weeks following delivery (even as frequently as every 4–5 days for drugs with a relatively short half-life such as lamotrigine, levetiracetam, and the MHD of oxcarbazepine).
Clinical course of pregnancy and delivery
Vaginal delivery is recommended in all women. Seizures and status epilepticus during labor are rare and are generally associated with the occurrence of seizures during pregnancy (see preceding text). These events may cause fetal hypoxia and could hamper maternal collaboration. Maternal collaboration may be also reduced to a lesser extent by prolonged and frequent complex partial seizures. Under these circumstances, urgent cesarean delivery may be indicated, but its appropriateness should be evaluated on an individual basis (Barrett & Richens, 2003).
Epidural anesthesia is not contraindicated in women with epilepsy, either during labor or cesarean delivery, and may even lower the risk of seizures by reducing stress and pain. Finally, there are no documented contraindications to the use of locally administered prostaglandins for the induction of labor or voluntary pregnancy termination.
Risk of congenital malformations
The incidence of congenital malformations in the offspring of women with epilepsy is 3–10%, which corresponds to a 2- to 3-fold increase over the rate observed in the general population (2–4%).
Maternal seizures do not seem to increase the risk of congenital malformations (Speidel & Meadow, 1972; Fedrick, 1973; Starreveld-Zimmerman et al., 1973; Shapiro et al., 1976; Nakane et al., 1980; Annegers & Hauser, 1982; Beck-Mannagetta et al., 1982; Dravet et al., 1982; Koch et al., 1992; Yerby et al., 1992a, 1992b; Steegers-Theunissen et al., 1994; Kaneko et al., 1999; Fonager et al., 2000; Holmes et al., 2001; Kaaja et al., 2003; Sabers et al., 2004), although some discrepancies in the literature exist on this issue (Nakane et al., 1980; Majewski et al., 1981; Kaneko et al., 1988; Lindhout et al., 1992; Olafsson et al., 1998). The hypothesis that epilepsy per se increases the risk of congenital malformations was originally advanced in a large American and Finnish study (Shapiro et al., 1976). Although some subsequent reports found an increased risk in the absence of antiepileptic therapy or in the children of fathers with epilepsy (Meyer, 1973; Majewski et al., 1981; Beck-Mannagetta et al., 1982; Koch et al., 1982; Friis & Hauge, 1985; Rating, 1987; Koch et al., 1992), a recent meta-analysis concluded that there is no increased risk (Fried et al., 2004). The findings of this meta-analysis, however, should be interpreted with caution given the criteria used to select the studies, the small number of these studies, and their small sample size. A recent large prospective study failed to find any significant difference in the occurrence of congenital malformations between children of untreated women and children exposed to monotherapy during pregnancy (Morrow et al., 2006).
The association between exposure to AEDs and an increased risk of congenital malformations is, in any case, well documented. A genetic susceptibility to the teratogenic effects of AEDs is suggested by several family-based studies, case–control studies in patients with oral clefts (Dronamraju, 1970; Erickson & Oakley, 1974; Greenberg et al., 1977; Friis, 1979; Kelly et al., 1984a; Abrishamchian et al., 1994) or neural tube defects (NTDs) (Robert & Guibaud, 1982; Lindhout & Meinardi, 1984) and by cohort studies (Meadow, 1970; Elshove & van Eck, 1971; Starreveld-Zimmerman et al., 1973; Annegers et al., 1974; Knight & Rhind, 1975; Weber et al., 1977; Nakane et al., 1980; Annegers & Hauser, 1982; Nakane, 1982; Dansky, 1989; Oguni et al., 1992; Ornoy & Cohen, 1996; Canger et al., 1999; Kaneko et al., 1999; Dean et al., 2002).
The most common malformations found in newborns exposed to AEDs in utero are the same as those most commonly reported in the general population (congenital heart disease, orofacial clefts, hypospadias, and limb-reduction defects). There is evidence that the risk of NTDs is increased in offspring exposed to valproic acid (1–2%) (Robert & Guibaud, 1982; Bertollini et al., 1985; Lindhout & Schmidt, 1986; Kallen et al., 1989; Omtzigt et al., 1992; Canger et al., 1999; Samrén et al., 1999; Arpino et al., 2000; Hernandez-Diaz et al., 2001) and, to a lesser extent, carbamazepine (0.5–1%) (Rosa, 1991; Arpino et al., 2000; Hernandez-Diaz et al., 2001). An increased risk of congenital heart disease has been reported in offspring exposed to barbiturates (Annegers et al., 1978; Dravet et al., 1982; Nakane, 1982; Canger et al., 1999; Arpino et al., 2000). The association between congenital heart disease and exposure to barbiturates was confirmed by data from the North American Registry (Holmes et al., 2004), although the authors failed to comment on it: in that registry, 4 of 77 newborns exposed to phenobarbital monotherapy had congenital heart disease (5.2%). Finally, some studies have suggested that exposure to valproic acid may carry a higher risk of hypogenesis or agenesis of limbs (Arpino et al., 2000; Rodriguez-Pinilla et al., 2000) and hypospadias (Samrén et al., 1999; Arpino et al., 2000), and that the risk of orofacial clefts may be higher after exposure to barbiturates (Nakane et al., 1980; Kallen et al., 1989; Arpino et al., 2000) and lamotrigine (Holmes et al., 2006). The latter findings are based on less solid evidence, but deserve to be mentioned given their implications for prenatal diagnosis.
After excluding from the comparison offspring exposed to valproic acid, exposure to each of the following AEDs has been reported in different studies to be associated with a higher frequency of fetal malformations compared with other drugs: carbamazepine (Lindhout, 1982; Samren et al., 1997; Samrén et al., 1999; Diav-Citrin et al., 2001; Kaaja et al., 2003), primidone (Nakane et al., 1980; Kaneko et al., 1999), phenobarbital (Nakane et al., 1980; Waters et al., 1994; Olafsson et al., 1998; Holmes et al., 2004), and phenytoin (Fedrick, 1973; Dravet et al., 1982; Lindhout, 1982; Tanganelli & Regesta, 1992; Olafsson et al., 1998; Sabers et al., 1998). In addition to valproic acid (see subsequent text), phenobarbital is among the AEDs most frequently associated with congenital abnormalities; in particular, valproic acid and phenobarbital are the only AEDs which the North American Registry found associated with a significantly increased risk compared with the general population (6.5% risk, compared to an estimated 1.6% risk in the general population). It should be noted, however, that in that study, the number of exposures to phenobarbital was quite small (N = 77).
In recent years, debate has grown on the potentially greater teratogenic effect of valproic acid. Many studies have reported a higher incidence of congenital malformations in offspring exposed to valproic acid compared to offspring exposed to carbamazepine (Wide et al., 2004; Morrow et al., 2006), lamotrigine (Morrow et al., 2006), or other monotherapies (Wyszynski et al., 2005). These results should be viewed with caution, since there have also been studies that did not identify an increased risk of congenital malformations in offspring exposed to valproic acid given as monotherapy (Bertollini et al., 1987; Omtzigt et al., 1992; Dean et al., 2002) or combination therapy (Nakane et al., 1980; Lindhout et al., 1984; Kaneko et al., 1992; Olafsson et al., 1998; Sabers et al., 1998) compared to other commonly used AEDs. Such discrepancies may result from the presence of potential confounders. For example, a positive family history of congenital malformations is an important risk factor: in particular, the risk of recurrence of neural tube defects in women not exposed to AEDs ranges between 3% and 8% (Mitchell et al., 2004) and is, therefore, considerably higher than that found not only in the general population but also in cohorts exposed to valproic acid. Surprisingly, only four of the studies cited previously took into consideration a family history of congenital malformations (Kaneko et al., 1999; Kaaja et al., 2003; Vajda et al., 2003; Morrow et al., 2006) and only one of them (the U.K. Registry) identified a statistically significant increase in risk after exposure to valproic acid compared to other monotherapies, with a 6.2% incidence of congenital malformations with valproic acid (N = 715) compared to 2.2% with carbamazepine (N = 927) (Morrow et al., 2006). Although the same study found a trend toward a lower incidence of congenital malformations with lamotrigine (2.2%, N = 617) compared to valproic acid, the rate of congenital malformations in offspring exposed to lamotrigine at doses equal to or higher than 200 mg/day (5.4%) was similar to that observed in offspring exposed to 600–1,000 mg/day valproic acid (6.1%). Valproic acid is, however, the only AED for which a correlation between dose and risk of congenital malformations has been demonstrated in the majority of high-quality studies (Jager-Roman et al., 1986; Samren et al., 1997; Kaneko et al., 1999; Samrén et al., 1999; Mawer et al., 2002; Duncan, 2003; Vajda et al., 2003; Artama et al., 2005), although not in all such studies (Kaaja et al., 2003; Sabers et al., 2004; Wyszynski et al., 2005). Recently, a single study reported that a relationship between dose and teratogenic risk may also exist for lamotrigine: in fact, in the U.K. Registry the dose of lamotrigine in pregnancies associated with fetal malformations was significantly higher than that recorded in pregnancies without malformations (Morrow et al., 2006). In addition, a report from the North American Registry suggested that prenatal exposure to lamotrigine may be associated with an increased risk of orofacial clefts (Anonymous, 2006; Holmes et al., 2006).
Most studies have reported an increased risk of congenital malformations in the offspring of mothers treated with polytherapy compared to monotherapy, with a particularly high increase in risk in offspring exposed to more than two drugs (Kaneko et al., 1988, 1999; Lander & Eadie, 1990; Shakir & Abdulwahab, 1991; Olafsson et al., 1998; Holmes et al., 2001; Kaaja et al., 2003; Wide et al., 2004). Not all studies, however, have confirmed this finding (Kallen, 1986; Eskazan & Aslan, 1992; Jick & Terris, 1997; Canger et al., 1999; Diav-Citrin et al., 2001; Richmond et al., 2004).
In conclusion, available information indicates that the risk of congenital malformations is increased among offspring of women with epilepsy, and that this increase may be attributed largely to the effects of AEDs. However, the incidence of congenital malformations varies 20-fold across published studies (Barrett & Richens, 2003), mainly because of methodologic differences. In fact, there are major differences in the populations studied, the diagnostic criteria used to identify abnormalities, exclusion criteria, and the denominators used to calculate the risk of malformations. The variability in malformation rates is also related to substantial methodologic deficiencies (Battino, 2001; Dolk & McElhatton, 2002; Barrett & Richens, 2003; Tomson et al., 2004), especially failure to control for potential risk factors. Although current evidence is inconclusive, several findings suggest that exposure to valproic acid, and possibly barbiturates, is associated with a higher risk of congenital malformations than exposure to carbamazepine and other commonly used AEDs. Valproic acid is also the drug for which a relationship between malformation risk and administered dose has been repeatedly demonstrated.
Adverse effects on fetal growth and postnatal development
Data on the risk of delayed fetal growth after prenatal exposure to AEDs are not univocal at least in part for methodologic reasons. In particular, measures are expressed at times as absolute values, at times as ratios between absolute values and gestational age, and in other instances as frequencies that refer to national or international standards (Battino et al., 1999). Some studies have found an increased risk for all parameters (Hvas et al., 2000), others an increased risk for head circumference only (Steegers-Theunissen et al., 1994; Wide et al., 2000a, 2000b), and others no differences compared to the general population (Kallen, 1986; Gaily & Granstrom, 1989; Olafsson et al., 1998; Sabers et al., 1998; Fonager et al., 2000; Thomas et al., 2001; Vajda et al., 2003). The risk of delayed fetal growth has been associated, in different studies, with the use of phenytoin (Hanson et al., 1976), phenobarbital, primidone (Hiilesmaa et al., 1981; Battino et al., 1999; Holmes et al., 2004), and carbamazepine (Hiilesmaa et al., 1981; Wide et al., 2000b). Reports on a correlation between drug dose and fetal growth are scant and limited primarily to phenobarbital (Battino et al., 1999). The risk for delayed fetal growth seems to be higher in patients on polytherapy (Wide et al., 2000a, 2000b).
Discordant data also exist on the psychomotor development of children exposed to AEDs in utero (Barrett & Richens, 2003; Adab, 2004). Earlier studies reported a lower intelligence in children of women with epilepsy, whereas most recent studies failed to find any cognitive deficits or any specific cognitive dysfunctions in children with normal intelligence. Few longitudinal studies have been undertaken to date, and among these most of the so-called prospective findings were confined to maternal parameters, since children were examined for the first time many years after birth. The risk of systematic confounding errors is very high because the etiology of developmental delay involves a large number of risk factors, the importance of which has been widely documented in the general population. No study has addressed most of these factors and the majority have ignored epilepsy-related factors, and in particular how seizures and the effects of AEDs may have affected a mother’s ability to care for her children. Another critical issue is the confusion between normal and pathologic outcomes. Indeed, normal IQs are sometimes considered as signals of an increased risk of mental retardation solely because they are slightly, but statistically significantly, reduced compared with internal and external controls. These issues might explain why some studies have found an increased risk of delayed psychomotor development in children of women with epilepsy (Speidel & Meadow, 1972; Hanson et al., 1976; Majewski et al., 1981; Hill, 1982; Hattig, 1987; Van der Pol et al., 1991; Scolnik et al., 1994; Leonard et al., 2006), whereas others have reported normal intelligence (Kelly et al., 1984a, 1984b; Losche et al., 1994; Steinhausen et al., 1994; Gaily et al., 1998; Wide et al., 2000a, 2000b) or a transient delay compared to normal controls (Shapiro et al., 1976; Jager-Roman, 1982; Gramstrom, 1982; Koch, 1983; Nomura, 1984; Fujioka, 1984) or children of fathers with epilepsy (Beck-Mannagetta & Janz, 1982), and others again reported specific cognitive disturbances in children of normal intelligence (Nelson & Ellenberg, 1982; Gaily et al., 1990; D’Souza et al., 1991; Van der Pol et al., 1991; Leavitt et al., 1992; Vanoverloop et al., 1992; Dessens et al., 1994; Losche et al., 1994; Rovet et al., 1995; Ornoy & Cohen, 1996; Gaily et al., 1998; Adab et al., 2001; Wide et al., 2002; Adab et al., 2004; Gaily et al., 2004; Vinten et al., 2005).
Although some authors claim that cognitive dysfunctions correlate with the type of epilepsy (Gaily et al., 1990, 1998; Hirano et al., 2004) and maternal seizures (Nelson & Ellenberg, 1982; Gaily et al., 1990, 2004; Leonard et al., 1997; Adab et al., 2004; Hirano et al., 2004), the major prognostic factors are likely to be maternal IQ (Rovet et al., 1995; Adab et al., 2004; Gaily et al., 2004; Eriksson et al., 2005) and maternal educational level (Gaily et al., 1990, 1998; Wide et al., 2002; Hirano et al., 2004). In separate studies, prenatal exposure to valproic acid (Hattig, 1987; Koch et al., 1999; Ohtsuka et al., 1999; Adab et al., 2004; Gaily et al., 2004; Eriksson et al., 2005), phenytoin (Hanson et al., 1976; Leavitt et al., 1992; Vanoverloop et al., 1992; Scolnik et al., 1994), phenobarbital (Van der Pol et al., 1991), carbamazepine (Jones et al., 1989; Ornoy & Cohen, 1996), and primidone (Koch et al., 1999) has been associated with a possible higher frequency of cognitive deficits, but many discrepancies exist (Shapiro et al., 1976; Hill, 1982; Leavitt et al., 1992; Scolnik et al., 1994; Gaily et al., 1998, 2004). Similarly, a correlation between the number of AEDs taken during pregnancy and cognitive disturbances in the children has been suggested by some authors (Leavitt et al., 1992; Losche et al., 1994; Ornoy & Cohen, 1996; Leonard et al., 1997; Koch et al., 1999; Wide et al., 2002; Gaily et al., 2004; Hirano et al., 2004) but not by others (Shapiro et al., 1976; Van der Pol et al., 1991; Gaily et al., 1998; Wide et al., 2002). The role of confounding factors was clearly demonstrated in two recent studies showing that the correlation between negative outcomes and maternal use of AEDs was no longer statistically significant after adjustment for maternal education level (Gaily et al., 1998; Eriksson et al., 2005). In addition, a large prospective, population-based study from the United States reported a significantly higher risk of mental retardation in children of black women with epilepsy compared with children of white women with epilepsy (Camp et al., 1998).
Very few studies have addressed socioeconomic status (Reinisch et al., 1995; Koch et al., 1999; Wide et al., 2002), paternal education level (Gaily et al., 1990), and perinatal risk factors (Hill, 1982; D’Souza et al., 1991; Van der Pol et al., 1991; Losche et al., 1994; Ornoy & Cohen, 1996; Wide et al., 2002). An Australian study published in 2006 showed a higher incidence of mental retardation in children of women with epilepsy, which remained significant after correcting for several sociodemographic factors. The study design, however, did not allow for differentiation of the effects of epilepsy from the effects of therapy or any concomitant diseases (Leonard et al., 2006).
Among the AEDs potentially implicated as a cause of cognitive deficits after prenatal exposure, valproic acid has been the focus of the most recent studies. Although several studies have reported specific cognitive deficits in children whose mothers used valproic acid during pregnancy (Hattig, 1987; Koch et al., 1999; Ohtsuka et al., 1999; Adab, 2004; Gaily et al., 2004; Eriksson et al., 2005), these findings are subject to an important extent to confounding factors (Adab, 2004). For example, in some of the studies it is possible that the association between prenatal exposure to valproic acid and cognitive deficits could be at least in part due to a lower educational level of valproic acid–treated mothers (Gaily et al., 2004; Eriksson et al., 2005).
Transvaginal ultrasound evaluation of neural tube defects (13th week of gestation) allows identification of all cases of anencephaly and myelomeningocele, but the diagnostic accuracy in detecting spina bifida is lower (Blumenfeld et al., 1993). For spina bifida, the association of microcephaly and scalloping of the frontal bones (lemon sign) and obliteration of the cisterna magna and curvature of the cerebellar hemispheres (banana sign) has a 98% diagnostic sensitivity within 24 weeks of gestation (Van den Hof et al., 1990).
Cardiac defects are identified by screening ultrasonography in 40–50% of cases and by fetal echocardiography in 80–90% (Comstock, 2000; Robinson et al., 2003). Fetal echocardiography should be performed after 20 weeks of gestation, and its diagnostic sensitivity depends on the type of anomaly (Società Italiana di Ecografia Ostetrico-Ginecologica, 2006). Interventricular defects are difficult to visualize, and interatrial defects even more so, whereas prenatal diagnosis of patent ductus arteriosus is not possible given the physiologic situation of the fetal circulation. Other congenital defects, such as semilunar valve stenosis and aortic coarctation, may not manifest until the third trimester. The risk of cardiac defects increases exponentially in relation to the thickness of nuchal translucency, which can be assessed by ultrasound at 10–13 weeks of gestation. The risk is particularly high when nuchal translucency is above the 99th percentile in fetuses without chromosomal abnormalities. A thorough cardiac examination is recommended even before the 20th week of gestation in cases at risk (Hyett et al., 1999).
In the majority of cases, orofacial clefts can be detected by bidimensional ultrasound imaging at around the 20th week of gestation. Expert operators are able to distinguish monolateral from bilateral defects, and isolated cleft lip from cleft lip associated with cleft palate. Although the degree of extension to the posterior palate is generally difficult to assess, accurate evaluation is crucial for prognosis in terms of surgical implications and risk of complications affecting swallowing, suction, speech, and hearing. With a targeted ultrasound examination, the diagnostic sensitivity increases from 27% (Stoll & Clementi, 2003) to 73%, with a further increase in sensitivity to 83% for evaluations performed after the 20th week of gestation (Robinson et al., 2001). Cleft lip and cleft palate are diagnosed in 91% and 46% of cases, respectively, by using the bidimensional technique, and in 100% and 90% of cases, respectively, when the examination is complemented with the tridimensional technique (Chmait et al., 2002).