Developmental Trajectories for Visuo-Spatial Attention are Altered by Prenatal Alcohol Exposure: A Longitudinal FMRI Study

Functional magnetic resonance imaging (fMRI) reveals brain activation abnormalities during visuo-spatial attention and working memory among those with fetal alcohol spectrum disorders (FASD) in cross-sectional reports, but little is known about how activation changes over time during development within FASD or typically developing children. We studied 30 controls and 31 individuals with FASD over 2 years (7-14 years at first participation) with a total of 122 scans, as part of the Collaborative Initiative on Fetal Alcohol Spectrum Disorders. Despite comparable performance, there were significant group differences in visuo-spatial activation over time bilaterally in frontal, parietal, and temporal regions. Controls showed an increase in signal intensity in these multiple regions whereas FASD participants showed a decrease in brain activation. Effects were also found in 2 small independent samples from the USA, corroborating the findings from the larger group. Results suggest that the long-lasting effect of prenatal alcohol may impact the maturation of visuo-spatial attention and differentiate those with FASD from controls. Based on this first longitudinal fMRI study in FASD children, our novel findings suggest a possible neural mechanism for attention deficits common among individuals with FASD.

Prenatal alcohol exposure alters the patterns of facial asymmetry

Directional asymmetry, the systematic differences between the left and right body sides, is widespread in human populations. Changes in directional asymmetry are associated with various disorders that affect craniofacial development. Because facial dysmorphology is a key criterion for diagnosing fetal alcohol syndrome (FAS), the question arises whether in utero alcohol exposure alters directional asymmetry in the face. Data on the relative position of 17 morphologic landmarks were obtained from facial scans of children who were classified as either FAS or control. Shape data obtained from the landmarks were analyzed with the methods of geometric morphometrics. Our analyses showed significant directional asymmetry of facial shape, consisting primarily of a shift of midline landmarks to the right and a displacement of the landmarks around the eyes to the left. The asymmetry of FAS and control groups differed significantly and average directional asymmetry was increased in those individuals exposed to alcohol in utero. These results suggest that the developmental consequences of fetal alcohol exposure affect a wide range of craniofacial features in addition to those generally recognized and used for diagnosis of FAS.

Chromosomal microarray mapping suggests a role for BSX and Neurogranin in neurocognitive and behavioral defects in the 11q terminal deletion disorder (Jacobsen syndrome)

We performed a prospective analysis on 14 11q- patients to determine the relationship between the degree of cognitive impairment and relative deletion size. Seventeen measures of cognitive function were assessed. All nine patients with a deletion of at least 12.1 Mb had severe global cognitive impairment, with full-scale IQ <50, whereas all five patients with smaller deletions, <or=11.8 Mb, demonstrated mild cognitive impairment, with a full-scale IQ of 63 or higher (p < 0.001). Among these five patients, the two patients with the larger deletions (11.4, 11.8 Mb) had a selective impairment in freedom from distractability compared to the three patients with smaller deletions (<or=9.1 Mb). We propose the presence of a proximal critical region that contains a gene for global cognitive function and a distal critical region that contains a gene essential for auditory attention, which may be necessary for optimizing intellectual function. The proximal critical region is 300 kb and contains three annotated genes. One of these genes, BSX, encodes a brain-specific homeobox protein that in gene-targeted mice has been shown previously to have a role in regulating locomotory behavior via BSX-expressing neurons in the hypothalamus. The distal critical region, approximately 2.2 Mb, contains 18 annotated genes. One gene in this region, Neurogranin, has been demonstrated previously in mice to be critical for synapse plasticity and long-term potentiation. Taken together, our results implicate the presence of at least two loci in distal 11q that when deleted, cause global and selective deficits in neurocognitive function. These findings have important implications for genetic counseling and potential gene-specific therapies.

Administration of eliprodil during ethanol withdrawal in the neonatal rat attenuates ethanol-induced learning deficits

RATIONALE

Prenatal exposure to alcohol can disrupt brain development, leading to a variety of behavioral alterations, including learning deficits. We have postulated that some central nervous system damage may be due to N-methyl-D-aspartate (NMDA) receptor-mediated excitotoxicity that occurs during ethanol withdrawal. Consistent with this hypothesis, we previously demonstrated that administration of MK-801, an NMDA receptor antagonist, during ethanol withdrawal attenuates ethanol-related learning deficits using an animal model of fetal alcohol effects. However, MK-801 binds to the phencyclidine site, which affects all NMDA receptor subtypes and can cause adverse side effects and toxicity. Eliprodil is a more selective NMDA receptor antagonist that acts at the polyamine modulatory site of NMDA receptors.

OBJECTIVES

The purpose of this study was to determine if administration of eliprodil during ethanol withdrawal would reduce the severity of learning deficits associated with developmental alcohol exposure.

METHODS

Male rat pups were randomly assigned to ethanol-exposed or control treatments. On postnatal day (PD) 6, during a period of brain development similar to that of the mid-third trimester in humans, subjects were exposed to 6.0 g/kg ethanol or isocaloric maltose solutions via oral gavage. Twenty-four hours after the end of the ethanol treatment, during ethanol withdrawal, all subjects received an intraperitoneal injection of one of three doses of eliprodil (5, 10, or 25 mg/kg) or vehicle. On PD 40, all subjects were tested on a serial spatial discrimination reversal learning task.

RESULTS

Ethanol-exposed subjects treated with vehicle committed a significantly greater number of errors compared to controls. Administration of eliprodil during ethanol withdrawal significantly decreased the number of errors in the ethanol-exposed groups, but had no significant effect on the performance of controls.

CONCLUSION

These data support the hypothesis that NMDA receptor-mediated excitotoxicity during ethanol withdrawal contributes to fetal alcohol effects.

Differential vulnerability to motor deficits in second replicate HAS and LAS rats following neonatal alcohol exposure

Children exposed prenatally to alcohol suffer from a variety of behavioral alterations. However, variation exists in the pattern and severity of these alcohol-related neurodevelopmental disorders. We examined the influence of alcohol sensitivity in the etiology of fetal alcohol effects by studying rat lines selectively bred for extremes in alcohol-induced sleep time: high-alcohol-sensitive (HAS) and low-alcohol-sensitive (LAS) rats. Using subjects from the first replicate, we previously reported that HAS rats exposed to alcohol during development were more vulnerable to ethanol-induced hyperactivity and motor deficits compared to LAS rats. To determine if these effects were, in fact, related to the trait for which these subjects were selected, the present study examined the consequences of developmental alcohol exposure in second replicate HAS and LAS rats. Second replicate HAS and LAS rats, as well as Sprague-Dawley rats, were exposed to 6.0 g/kg/day ethanol on Postnatal Days (PD) 4-9, a period of brain development equivalent to the third trimester, via an artificial rearing procedure. Artificially and normally reared controls were included. Activity was measured on PD 18-21 and parallel bar motor coordination on PD 30-32. Ethanol exposure produced hyperactivity in all genetic groups, and there were no differences among HAS and LAS rats. In contrast, consistent with findings from the first replicate, ethanol-exposed HAS rats were more impaired on the motor coordination task compared with LAS rats. These data suggest that genetically mediated responses to alcohol may relate to behavioral vulnerability to motor deficits following developmental alcohol exposure. They also provide evidence that genetic factors play a role in fetal alcohol effects and suggest that phenotypic markers may indicate individuals at high risk for some fetal alcohol effects.

Administration of low doses of MK-801 during ethanol withdrawal in the developing rat pup attenuates alcohol's teratogenic effects

BACKGROUND

Alcohol exposure during development can produce severe and long-lasting central nervous system damage and consequent behavioral alterations. Recent evidence suggests that NMDA receptor-mediated excitotoxicity during periods of withdrawal may contribute to this damage. We have demonstrated that blocking the NMDA receptor with MK-801 during alcohol withdrawal can attenuate ethanol's adverse effects on behavioral development in the rat. This study examined the dose dependency of MK-801's ability to mitigate ethanol's teratogenic effects.

METHODS

Neonatal rat pups were exposed to 6.0 g/kg of ethanol in a binge-like manner on postnatal day (PD) 6, a period of brain development equivalent to a portion of the human third trimester. Alcohol administration was accomplished with an artificial rearing procedure. Twenty-one hours after ethanol treatment, pups were injected intraperitoneally with one of four doses of MK-801 (0.05, 0.1, 0.5, or 1.0 mg/kg) or saline vehicle. An artificially reared control and a normally reared control group were included. On PD 18-19, activity level was monitored, and on PD 40-42, serial spatial discrimination reversal learning was assessed.

RESULTS

Alcohol exposure on PD 6 produced significant increases in activity level and deficits in reversal learning. These alcohol-induced behavioral alterations were significantly attenuated in subjects treated with one of the three lower doses (0.05-0.5 mg/kg) of MK-801 during withdrawal. The performance of ethanol-exposed subjects treated with the high dose of MK-801 (1.0 mg/kg) did not differ from that of the Ethanol Only group.

CONCLUSIONS

These data suggest that alterations in NMDA receptor activation during alcohol withdrawal contribute to the neuropathology and consequent behavioral alterations associated with developmental alcohol exposure. These data have important implications for pregnant women and newborns undergoing ethanol withdrawal.

Early maternal separation alters neuropeptide Y concentrations in selected brain regions in adult rats

Human and animal studies support the involvement of neuropeptide Y (NPY) in the pathophysiology of depression. Thus, hippocampal NPY-LI is decreased in genetic models of depression, the Flinders Sensitive Line and Fawn Hooded rats. Maternal "deprivation" has been identified as one risk factor in the development of psychopathology, including depression in adulthood. In view of these findings we hypothesized that brain NPY may also be decreased in an animal model of early life maternal deprivation. To test this hypothesis, male and female Sprague-Dawley rats were maternally separated (MS) 6 h/day or briefly handled from postnatal day 2 (PN2) to PN6 and from PN9 to PN13. At 12 weeks of age the rats were sacrificed, the brains dissected and NPY-LI measured by radioimmunoassay. MS rats had lower NPY-LI in the hippocampus. NPY-LI was also lower in female compared to male rats in hippocampus. Lastly, NPY-LI was increased in the hypothalamus of both male and female MS rats. These findings support the hypothesis that altered NPY in the limbic region is a common denominator of several models of depression and might be a trait marker of vulnerability to affective disorders.

Fetal alcohol effects: mechanisms and treatment

This article represents the proceedings of a symposium at the 2000 ISBRA Meeting in Yokohama, Japan. The chair was Edward P. Riley. The presentations were (1) Does alcohol withdrawal contribute to fetal alcohol effects? by Jennifer D. Thomas and Edward P. Riley; (2) Brain damage and neuroplasticity in an animal model of binge alcohol exposure during the "third trimester equivalent," by Charles R. Goodlett, Anna Y. Klintsova, and William T. Greenough; (3) Ganglioside GM1 reduces fetal alcohol effects, by Basalingappa L. Hungund; and (4) Fetal alcohol exposure alters the wiring of serotonin system at mid-gestation, by F. Zhou, Y. Sari, Charles Goodlett, T. Powrozek, and Ting-Kai Li.

Mapping callosal morphology and cognitive correlates: effects of heavy prenatal alcohol exposure

BACKGROUND

Abnormalities of the corpus callosum (CC) have been documented in fetal alcohol syndrome (FAS), ranging from subtle decrements in its size to partial and even complete agenesis. Prenatal exposure to alcohol is also known to result in neurocognitive deficits.

OBJECTIVE

To 1) investigate abnormalities in size, shape, and location of the CC within the brain in individuals with FAS and in those exposed to high amounts of alcohol prenatally but without FAS (PEA group); and 2) determine if there is a relationship between callosal dysmorphology and cognitive test performance.

METHODS

MRI and novel surface-based image analytic methods were used. Twenty alcohol-exposed subjects (8 to 22 years) along with 21 normal controls (8 to 25 years) were studied with high-resolution MRI and measures of verbal learning and visuospatial abilities.

RESULTS

In addition to callosal area reductions, most severe in the splenium, the CC is significantly displaced in patients exposed to alcohol prenatally. In the alcohol-exposed group, this structure lies more anterior and inferior in posterior regions with relatively normal localization of anterior regions. These findings are significant in the FAS group, and a similar but less severe pattern is observed in the PEA patients. The authors show that the amount of CC displacement is correlated with impairment in verbal learning ability and that CC displacement is a better predictor of verbal learning than regional CC area. The brain-behavior relationship is only significant within the alcohol-exposed group, and the effect is not solely mediated by overall impaired verbal intellectual functioning.

CONCLUSIONS

These results further emphasize the vulnerability of midline brain structures to prenatal alcohol exposure.

Fetal alcohol effects: mechanisms and treatment

This article represents the proceedings of a symposium at the 2000 ISBRA Meeting in Yokohama, Japan. The chair was Edward P. Riley. The presentations were (1) Does alcohol withdrawal contribute to fetal alcohol effects? by Jennifer D. Thomas and Edward P. Riley; (2) Brain damage and neuroplasticity in an animal model of binge alcohol exposure during the "third trimester equivalent," by Charles R. Goodlett, Anna Y. Klintsova, and William T. Greenough; (3) Ganglioside GM1 reduces fetal alcohol effects, by Basalingappa L. Hungund; and (4) Fetal alcohol exposure alters the wiring of serotonin system at mid-gestation, by F. Zhou, Y. Sari, Charles Goodlett, T. Powrozek, and Ting-Kai Li.

MK-801 can exacerbate or attenuate behavioral alterations associated with neonatal alcohol exposure in the rat, depending on the timing of administration

BACKGROUND

We have reported that administration of MK-801, an NMDA receptor antagonist, during ethanol withdrawal in the developing rat attenuates ethanol's adverse effects on behavioral development. In the present study, we altered the timing of MK-801 delivery in relation to the last alcohol dose to determine if its protective effects were specific to the ethanol withdrawal phase.

METHODS

Five groups of rats were artificially reared and exposed to alcohol in a binge-like manner on postnatal day (PD) 6, producing peak blood alcohol levels of 335 mg/dl that cleared to 0 mg/dl by 33 hours. Four groups received MK-801 at various times after alcohol treatment (0, 9, 21, or 33 hr post-ethanol). The fifth alcohol-treated group received saline. Two artificially reared control groups were included: one was injected with saline and the other injected with 0.5 mg/kg MK-801. Finally, a normally reared suckle control group was also included. Activity level and performance on a spatial discrimination reversal-learning task were evaluated at PD 18 and PD 40, respectively.

RESULTS

Administration of MK-801 at the same time as ethanol treatment (0 hr) produced a high rate of mortality. Ethanol exposure on PD6 increased activity level relative to controls. Administration of MK-801 at 0 hr exacerbated this ethanol-induced overactivity, whereas administration of MK-801 at 21 and 33 hr reduced the severity of ethanol-related overactivity. Similarly, ethanol exposure on PD 6 significantly increased the number of errors committed on a spatial discrimination reversal-learning task. MK-801 injections 9 hrs after ethanol exacerbated this effect, whereas MK-801 treatment 33 hrs after ethanol attenuated this effect. Thus, MK-801 administration at the time of ethanol treatment was highly toxic, whereas during the withdrawal period it was protective.

CONCLUSION

These data are consistent with the hypothesis that ethanol exposure in the neonatal rat inhibits the NMDA receptor, producing a subsequent rebound in NMDA receptor activation and possible excitotoxicity during withdrawal. Both the acute inhibitory effects of ethanol and the excitatory effects of withdrawal may contribute to fetal alcohol effects.

Voxel-based morphometric analyses of the brain in children and adolescents prenatally exposed to alcohol

Children of mothers who abuse alcohol during pregnancy can suffer varying degrees of neurological abnormality, cognitive impairment, and behavioral problems, and in the worst case, are diagnosed with fetal alcohol syndrome (FAS). The purpose of the present study was to localize brain abnormalities in a group of children and adolescents prenatally exposed to alcohol using high resolution, 3D structural MRI data and whole-brain voxel-based morphometry (VBM). Data were collected for 21 children and adolescents with histories of prenatal alcohol exposure (ALC) and 21 normally developing individuals. Statistical parametric maps revealed abnormalities most prominent in the left hemisphere perisylvian cortices of the temporal and parietal lobes where the ALC patients tended to have too much gray matter and not enough white matter. These results provide further support for dysmorphology in temporo-parietal cortices above and beyond the overall microcephaly that results from severe prenatal alcohol exposure.

Verbal and nonverbal fluency in children with heavy prenatal alcohol exposure

OBJECTIVE

Executive function deficits, including verbal fluency, have been documented in children with histories of prenatal alcohol exposure. Whereas nonverbal fluency impairments have been reported in adults with such exposure, these abilities have not been tested in children. Deficits in both verbal and nonverbal fluency were predicted and assessed in children and adolescents with histories of heavy prenatal alcohol exposure.

METHOD

There was a total of 28 (54% female) subjects; children with heavy prenatal alcohol exposure with (n = 10) and without (n = 8) fetal alcohol syndrome (FAS) were compared to nonexposed controls (n = 10) on the design and verbal fluency measures from the Delis-Kaplan Executive Function System. Both fluency measures consist of three conditions, including a new set-shifting task. All tests require the generation of multiple responses within both rule and time constraints.

RESULTS

Data were analyzed using repeated measures analyses of variance and hierarchical regression analyses. Compared to controls, children with heavy prenatal alcohol exposure with and without FAS displayed deficits in both fluency domains, but did not differ from each other. In addition, prenatal alcohol exposure was a significant predictor of performance on the set-shifting design fluency task above and beyond performance on more traditional fluency tasks. IQ was not a significant predictor for the traditional or set-shifting fluency measures, whereas diagnostic group remained a significant predictor when IQ was included in the model.

CONCLUSIONS

This study adds to the literature on the integrity of executive functions in children with heavy prenatal alcohol exposure, documenting fluency impairment in both verbal and nonverbal domains. It is important to note that these impairments were demonstrated in higher functioning alcohol-exposed children, both with and without FAS, and that diagnostic group explained such deficiencies above and beyond general intellectual ability.

Teratogenic effects of alcohol on brain and behavior

Children prenatally exposed to alcohol can suffer from serious cognitive deficits and behavioral problems as well as from alcohol-related changes in brain structure. Neuropsychological studies have identified deficits in learning and memory as well as in executive functioning both in children with fetal alcohol syndrome and in children with less severe impairments. Both groups of children also exhibit problem behaviors, such as alcohol and drug use, hyperactivity, impulsivity, and poor socialization and communication skills. Brain imaging studies have identified structural changes in various brain regions of these children--including the basal ganglia, corpus callosum, cerebellum, and hippocampus--that may account for the cognitive deficits. Functional brain imaging studies also have detected changes in alcohol-exposed children indicative of deficits in information processing and memory tasks.

Nicotine exposure during the neonatal brain growth spurt produces hyperactivity in preweanling rats

Despite warning labels and increases in evidence of the adverse effects of tobacco use, women continue to use tobacco products during pregnancy. Cigarette smoking has been linked to increased prenatal mortality, increased incidence of SIDS, reductions in birth weight, and disruptions in CNS and behavioral development. Animal model systems have critically established the causal relationship between nicotine and adverse developmental outcome. The present study examines the behavioral effects of nicotine exposure in the rat during the third trimester equivalent of the human brain growth spurt, a period of rapid development of the cholinergic systems and a period during which the CNS is particularly vulnerable to a number of insults. Sprague-Dawley rat pups were exposed to nicotine (6.0 mg/kg/day) from postnatal days (PD) 4-9 via an artificial rearing procedure. This procedure ensures that observed effects are not due to nutritional deficits. Two control groups were employed, an artificially reared control group and a normally reared control group. Activity level was measured on PD 18-19. Nicotine-exposed subjects were significantly overactive compared to both control groups, which did not differ significantly from one another. This behavioral alteration was observed in the absence of nicotine-induced body weight deficits. These results suggest that women who use tobacco products during late gestation may place their fetuses at risk for hyperactivity later in life, particularly during early adolescence.

Neonatal choline supplementation ameliorates the effects of prenatal alcohol exposure on a discrimination learning task in rats

Prenatal alcohol exposure can disrupt brain development and lead to a myriad of behavioral alterations, including motor coordination deficits, hyperactivity, and learning deficits. There remains a need, however, to identify treatments and interventions for reducing the severity of alcohol-related neurodevelopmental disorders. Some of the alcohol-induced deficits in learning may be related to alterations in cholinergic functioning. Interestingly, there is a growing literature demonstrating that pre- and/or early postnatal choline supplementation can lead to long-term enhancement in learning and memory and cholinergic activity in rats. The present study examined whether such early choline supplementation might counter the effects of prenatal alcohol treatment on a visuospatial discrimination task. Pregnant Sprague-Dawley rats were randomly assigned to one of three prenatal treatment groups. One group received a liquid diet containing 35% ethanol-derived calories (EDC) from gestational day (GD) 6-20. A second group served as a pair-fed (PF) control group and the third group served as an ad lib lab chow (LC) control. On postnatal day (PD) 2, pups were assigned within-litter to one of three postnatal treatments: choline, saline vehicle, or no treatment. Choline and vehicle pups were intubated with a choline chloride solution or vehicle daily from PD 2 to 21, whereas the non-treated pups were handled daily but not intubated. On PD 45, subjects were tested on a visuospatial discrimination task. Ethanol-exposed subjects who were not treated neonatally with choline committed a significantly greater number of errors both during acquisition and during delayed discrimination training compared to both PF and LC controls. Neonatal choline treatment significantly improved performance on the discrimination task in all groups; however, the beneficial effects of choline were significantly larger in ethanol-exposed subjects. Indeed, the performance of ethanol-exposed pups treated with neonatal choline did not differ from any of the PF or LC groups on any measure. Thus, early postnatal choline supplementation significantly attenuated the effects of prenatal alcohol on this learning task. Importantly, these effects were not due to the acute effects of choline, but rather to long-term changes in brain and behavioral development. These data suggest that early dietary interventions may reduce the severity of fetal alcohol effects.

Neonatal nicotine exposure alters hippocampal EEG and event-related potentials (ERPs) in rats

A consensus is forming that nicotine can damage the developing rat central nervous system. However, few studies have assessed the electrophysiological effects of neonatal nicotine exposure in rodents in brain regions known to be sensitive to the teratogenic properties of nicotine. In a previous study it was reported that 1.0 and 4.0 mg/kg/day nicotine exposure from postnatal days 4-9, a developmental period corresponding to human third-trimester exposure, significantly altered hippocampal event-related potentials (ERPs) but did not effect cortical ERPs, cortical EEG, or hippocampal EEG. Because alterations in behavior and cortical/hippocampal neurochemistry and morphology have been reported following nicotine exposure, the present study used a higher dose of nicotine during the postnatal period (6.0 mg/kg/day) determine if functional changes in the EEG of these regions might contribute to behavioral changes that have been observed. Male Sprague-Dawley rats were exposed to 6. 0 mg/kg/day nicotine via gastric infusion using an artificial rearing, "pup-in-the-cup," technique for 6 consecutive days (postnatal days 4-9). At adulthood, EEG and auditory ERPs were recorded from the cortex and hippocampus. There were no significant differences in EEG or ERPs recorded from the cortex between nicotine-treated and control subjects. Examination of the hippocampal EEG revealed significantly decreased power in the 1-2-Hz frequency band of nicotine-treated rats. In addition, there was a significantly attenuated P300 ERP response to a noise tone in the nicotine-treated rats compared to controls. These data indicate that neonatal nicotine exposure alters functional activity in the hippocampus of adult rats. These effects are likely to be the result of synaptic disorganization in the hippocampus, and indicate that neonatal nicotine exposure exerts teratogenic effects on the developing central nervous system, particularly the hippocampus, which persist into adulthood.

Parent ratings of behavior in children with heavy prenatal alcohol exposure and IQ-matched controls

BACKGROUND

Behavioral disturbances are well documented in children with heavy prenatal alcohol exposure. However, the degree to which these disturbances are related to factors other than alcohol, such as general intellectual functioning or socioeconomic status, is not known.

METHODS

Using the Child Behavior Checklist, parent-rated behaviors of children with histories of heavy prenatal alcohol exposure were compared with those of a control group matched by age, sex, socioeconomic status, ethnicity, and verbal IQ score. Using this same questionnaire, children with fetal alcohol syndrome were compared with children with heavy prenatal alcohol exposure that did not meet the criteria for fetal alcohol syndrome classification.

RESULTS

Data were analyzed by multivariate analyses of covariance. In the comparison of children with and without a history of prenatal alcohol exposure, significant differences were found on the competence, problem, and summary scales (all p < 0.05). For the secondary comparison between the fetal alcohol syndrome and the heavy prenatal alcohol exposure groups, there were no significant differences on any of the scales (allp > 0.10).

CONCLUSIONS

These results suggest that prenatal alcohol exposure results in the significant and profound impairment of parent-rated behaviors and that these deficits are not explained entirely by the presence or absence of facial dysmorphology, general intellectual functioning, or demographic factors.

Neonatal alcohol exposure produces more severe motor coordination deficits in high alcohol sensitive rats compared to low alcohol sensitive rats

Prenatal exposure to alcohol can produce a number of behavioral alterations, including hyperactivity, learning deficits and motor impairments. However, the severity and nature of behavioral alterations varies markedly among children of women who drink during pregnancy. One important determinant of this variation may be genetic differences in the response to alcohol. Recently, we demonstrated that exposure to alcohol during development produced hyperactivity in rats bred for high alcohol sensitivity (HAS), but not in rats bred for low alcohol sensitivity (LAS). These lines were selectively bred for extremes in alcohol-induced "sleep time." The present study investigated the effects of ethanol exposure during development on motor coordination later in life in both HAS and LAS rats. Using an artificial rearing procedure, neonatal pups from each line were exposed to a binge-like alcohol treatment on postnatal days (PD) 4-9. Within each line, one group was exposed to ethanol (6.0 g/kg/day), one group served as an artificially reared control, and a third served as a normally reared control group. On PD 30, parallel bar motor performance was evaluated. Exposure to ethanol during development severely impaired motor performance in the HAS rats compared to their controls. In LAS rats, early ethanol exposure produced only mild and nonsignificant effects on motor performance. Thus, HAS rats were more vulnerable to ethanol-induced motor deficits compared to the LAS rats. Importantly, there were no differences in peak blood alcohol level between the lines, indicating that vulnerability to ethanol's teratogenic effects was not due to differences in metabolic rate. These results suggest that genetic differences in response to alcohol may serve as a predictor for susceptibility to ethanol's teratogenic effects.

Executive functioning in children with heavy prenatal alcohol exposure

BACKGROUND

Children with heavy prenatal alcohol exposure have well documented deficits in overall cognitive ability. Recently, attention has turned to the executive function (EF) domain in this population. Until recently, comprehensive measures of EF have not been available within one test battery. This study used a battery of tests to assess four domains of EF in alcohol-exposed children.

METHODS

The Delis-Kaplan Executive Function Scale was used to evaluate EF in 18 children with heavy prenatal alcohol exposure, with and without a diagnosis of fetal alcohol syndrome (FAS), and 10 nonexposed controls. Children ranged in age from 8 to 15 years. Measures from four domains of executive functioning were analyzed: planning ability, cognitive flexibility, selective inhibition, and concept formation and reasoning. Tasks consisted of primary EF measures as well as measures of secondary component skills.

RESULTS

Alcohol-exposed children were deficient on EF measures compared with nonexposed controls. Furthermore, in most cases, children with and without the FAS diagnosis did not differ from one another. These deficits were not entirely explainable by concomitant deficits on component skills. Specific impairments were identified within the domains of planning and response inhibition, with additional deficits in abstract thinking and flexibility.

CONCLUSIONS

Deficits in executive functioning were observed in alcohol-exposed children with or without the diagnosis of FAS and in the absence of mental retardation. Performance on these EF tasks provides insight into the cognitive processes driving overall performance and has implications for adaptive and daily functions. These results are consistent with anecdotal and empirical reports of deficits in behavioral control and with neuroanatomical evidence of volumetric reductions in structures within the frontal-subcortical system in children with heavy prenatal alcohol exposure.

Implicit and explicit memory functioning in children with heavy prenatal alcohol exposure

Prenatal alcohol exposure is associated with widespread and devastating neurodevelopmental deficits. Numerous reports have suggested memory deficits in both humans and animals exposed prenatally to alcohol. However, the nature of these memory deficits remains to be characterized. Recently children with fetal alcohol syndrome were shown to have learning and memory deficits on a verbal learning and memory measure that involved free recall and recognition memory. The current study seeks to further characterize memory functioning in children with heavy prenatal alcohol exposure by evaluating priming performance. The choice of task is also relevant given previous studies of memory performance in patient groups with and without involvement of the basal ganglia, a group of structures known to be affected in fetal alcohol syndrome. Three groups were evaluated for lexical priming, free recall, recognition memory, and verbal fluency: (1) children with heavy prenatal alcohol exposure; (2) children with Down syndrome; and (3) nonexposed controls. The children with Down syndrome showed significantly less priming than alcohol-exposed children, who did not differ from controls. In addition, the alcohol-exposed children were impaired on the free recall task but not on the recognition memory task, whereas the children with Down syndrome performed significantly worse than the alcohol-exposed group on both tasks. Finally, on the verbal fluency task, children with heavy prenatal alcohol exposure were impaired on both category and letter fluency, but the degree of impairment was greater for letter fluency. These results further characterize the memory deficits in children with heavy prenatal alcohol exposure suggesting that in spite of learning and memory deficits, they are able to benefit from priming of verbal information.

Behavioral and psychosocial profiles of alcohol-exposed children

BACKGROUND

It is widely known that prenatal alcohol exposure is related to cognitive and behavioral deficits throughout childhood and adolescence. Much research has focused on understanding and quantifying the cognitive profile of children with fetal alcohol syndrome (FAS) with relatively less empirical research on behavioral or psychosocial adjustment. The primary purpose of this study was to examine the behavioral and psychosocial profile of children exposed to heavy amounts of alcohol prenatally.

METHOD

Two groups of subjects were evaluated: an alcohol-exposed group (ALC) and a nonexposed control group (NC) each made up of 32 subjects matched for age, gender, and ethnicity. The alcohol-exposed group consisted of children heavily exposed to alcohol in utero, including 19 children diagnosed with FAS. The Personality Inventory for Children (PIC) was completed by the caretaker of each child. Four validity/screening scales and 12 clinical scales were scored for all subjects.

RESULTS

Analyses revealed significant group differences on four validity/screening scales and 12 substantive scales. Within the ALC group, the profile of children without FAS was similar to that of children with FAS, with the exception that their profiles were consistent with less cognitive impairment.

CONCLUSIONS

These findings indicate that in addition to previously reported cognitive impairments, heavy prenatal alcohol exposure is related to significant impairments in psychosocial functioning. Even children without alcohol-related physical anomalies suffer from impaired psychosocial functioning. Because impairments of this nature can interfere with functioning across multiple domains, effective early intervention programs should be considered for families of alcohol-exposed children. Furthermore, given the similarities of alcohol-exposed children with and without FAS, it is imperative to obtain prenatal alcohol exposure histories on all children experiencing cognitive or psychosocial deficits.

Neuromuscular responses to disturbance of balance in children with prenatal exposure to alcohol

Alcohol-exposed children display delayed motor development and impaired fine- and gross-motor skills, including deficits in the maintenance of balance. In a recent study, we assessed the contribution of visual, somatosensory, and vestibular information to the ability to maintain balance. Our findings suggested that alcohol-exposed children were overly reliant on somatosensory information and were unable to compensate by using the visual and/or vestibular systems. To understand the nature of these observed balance deficits, corrective postural reactions were examined by exposing standing subjects to rapid toe-up movements of the support surface. Subjects for this study were alcohol-exposed (ALC) and normal control (NC) children matched for age and sex. Postural reactions were quantified by measuring electromyographic activity of the triceps surae and anterior tibialis muscles. Analyses revealed no differences between the ALC and NC groups on short- and medium-latency electromyographic responses, which are thought to be involuntary mono- and polysynaptic spinal reflexes, respectively. However, when compared with the NC group, the ALC group displayed increased long-latency responses, which are thought to involve a transcortical pathway. Although we are not able to rule out the possibility of additional peripheral (e.g., vestibular) disturbance as a contributing factor to postural instability, our findings suggest that the balance deficits seen in alcohol-exposed children are, at least in part, central in nature.

Neonatal alcohol exposure produces hyperactivity in high-alcohol-sensitive but not in low-alcohol-sensitive rats

Children of women who consume high amounts of alcohol during their pregnancies vary greatly in physical and behavioral outcomes. Although many factors, such as dose and timing of exposure, undoubtedly contribute to this variation, one important determinant may be genetic differences in the response to alcohol. The present study examined activity levels in high alcohol sensitivity (HAS) and low alcohol sensitivity (LAS) rats following neonatal alcohol exposure. These lines were selectively bred for extremes in ethanol-induced "sleep times." The HAS and LAS offspring were exposed to alcohol via an artificial rearing procedure using the "pup-in-the-cup" technique. Rat pups were exposed to ethanol (6 g/kg/day) from postnatal day (PD) 4 through 7 and faded to a dose of 3 g/kg/day on PD 8 and 9. An artificially reared gastrostomy control group (GC) and a normally reared suckle control group (SC) were also included. Activity level was measured on PD 18 through PD 21 for 30 min daily in automated activity monitors. Neonatal ethanol exposure produced overactivity in HAS rats, relative to their controls, but the same ethanol treatment had no effect on the LAS rats. Importantly, there were no differences in blood alcohol concentrations (around 420 mg/dl) between the two lines during the treatment period. These data suggest that genetic differences in response to alcohol may be a predictor for some of the behavioral teratogenic effects of alcohol.

A review of the neuroanatomical findings in children with fetal alcohol syndrome or prenatal exposure to alcohol

Human and animal studies have clearly demonstrated that alcohol is both a physical and behavioral teratogen and that heavy prenatal alcohol exposure can lead to a distinct pattern of birth defects termed the fetal alcohol syndrome. Underlying the behavioral and cognitive anomalies seen in fetal alcohol syndrome are alterations in brain structure and/or function. This paper reviews the literature examining brain anomalies attributable to prenatal alcohol exposure, beginning with a survey of autopsy studies and leading up to current findings using magnetic resonance imaging and positron emission tomography studies. Autopsy reports clearly illustrate the wide and devastating influence alcohol has on the developing brain, although for the most part no specific pattern of brain malformation has been identified. More recent magnetic resonance imaging studies, particularly when combined with quantitative analysis, have indicated that specific brain areas--such as the basal ganglia, the corpus callosum, and parts of the cerebellum--might be especially susceptible to alcohol's teratogenic effects. Further studies using functional brain imaging techniques may provide even more information about the unique effects prenatal alcohol exposure has on the developing brain. Discovering specific areas of the brain that are affected by alcohol may allow clinicians and researchers to look for patterns of vulnerable regions in the brain, thereby helping in the future detection of children who are prenatally exposed to alcohol.

Comparison of social abilities of children with fetal alcohol syndrome to those of children with similar IQ scores and normal controls

Children diagnosed with fetal alcohol syndrome (FAS) were assessed with items from the social skills domain of the Vineland Adaptive Behavior Scales (VABS) via interviews with their caregivers. Their scores were compared with scores from children in two control groups. The control groups included children matched for IQ to the FAS group (specifically on verbal IQ, henceforth, the VIQ group) and children with IQ scores in the average to above-average range (normal control group). Forty-five children (age range, 5 years 7 months to 12 years 11 months) were assessed (n/group = 15). All groups differed with regard to social ability, as measured by the VABS (NC > VIQ > FAS), even when the effects of socioeconomic status were held constant. The three subdomains of the VABS social scale (interpersonal relationship skills, use of play and leisure time, and coping skills) were assessed, and results showed that the children with FAS were most impaired on the subdomain that assessed interpersonal relationship skills. An additional measure was constructed by obtaining an age-equivalent score for the VABS social scale and calculating a difference score by subtracting the child's chronological age from his/her age-equivalent score. There was a significant correlation between chronological age and difference scores for children in the FAS group but not for children in the two control groups. Specifically, in older children with FAS, there was an increased discrepancy between their ages and their age-equivalent scores, a discrepancy that was not present in children in the control groups. These results suggest that social deficits in children with FAS are beyond what can be explained by low IQ scores and indicate that there may be arrested, and not simply delayed, development of social abilities in children with FAS.

A review of the neurobehavioral deficits in children with fetal alcohol syndrome or prenatal exposure to alcohol

Fetal alcohol syndrome is a devastating developmental disorder caused by prenatal exposure to high amounts of alcohol. In addition to structural abnormalities and growth deficits, fetal alcohol syndrome is associated with a broad spectrum of neurobehavioral anomalies. This paper reviews the behavioral and cognitive effects of prenatal alcohol exposure. More than 20 years of research are discussed, with a focus on IQ, activity, attention, learning, memory, language, motor, and visuospatial abilities in children prenatally exposed to varying amounts of alcohol, including those with fetal alcohol syndrome.

Neuropsychological comparison of alcohol-exposed children with or without physical features of fetal alcohol syndrome

Fetal alcohol syndrome (FAS) is associated with behavioral and cognitive deficits. However, the majority of children born to alcohol-abusing women do not meet the formal criteria for FAS and it is not known if the cognitive abilities of these children differ from those of children with FAS. Using a set of neuropsychological tests, 3 groups were compared: (a) children with FAS, (b) children without FAS who were born to alcohol-abusing women (the PEA group), and (c) normal controls. The results indicated that, relative to controls, both the FAS and the PEA groups were impaired on tests of language, verbal learning and memory, academic skills, fine-motor speed, and visual-motor integration. These data suggest that heavy prenatal alcohol exposure is related to a consistent pattern of neuropsychological deficits and the degree of these deficits may be independent of the presence of physical features associated with FAS.

Prenatal exposure to alcohol affects the ability to maintain postural balance

Prenatal exposure to alcohol is known to affect gross motor functioning. Animal studies have shown that balance is particularly affected, and there is some evidence that similar deficits exist in alcohol-exposed children. In the current study, postural balance, or the ability to maintain equilibrium, was assessed in a group of alcohol-exposed children (ALC group; n = 11) and controls (NC group; n = 11) individually matched for age and sex. Balance was measured across six conditions designed to systematically manipulate or eliminate visual or somatosensory information. Equilibrium and strategy scores for each condition and a derived composite balance score were analyzed. Although the ALC group had a lower mean composite balance score, their performance was similar to that of the NC group on all conditions where somatosensory input was reliable. However, when somatosensory input was manipulated, and when both somatosensory and visual input were inaccurate, the ALC group performed more poorly than controls. Interestingly, there were no differences between the ALC group and NC group in the type of control strategy used to maintain balance. These results suggest that alcohol-exposed children are overly reliant on somatosensory input. When this input is atypical, alcohol-exposed children display significantly greater anterior-posterior body sway and are unable to compensate using available visual or vestibular information. These deficits may be related to cerebellar anomalies previously reported in fetal alcohol syndrome children.

Fetal alcohol syndrome: does alcohol withdrawal play a role?

Alcohol use by a pregnant woman may interfere with the development of her fetus. Newborns whose mothers are intoxicated during delivery can experience withdrawal symptoms, such as tremors and even seizures. It is likely that withdrawal also can occur during fetal development. Thus, the possibility exists that withdrawal by the pregnant woman may exacerbate alcohol's adverse effects on her fetus. One potential mechanism through which alcohol withdrawal might damage the fetus involves the receptor for the neurotransmitter glutamate (i.e., the N-methyl-D-aspartate [NMDA] receptor). This receptor plays a crucial role during neuronal development. Excessive activation of the NMDA receptor, which occurs during withdrawal, may lead to neuronal cell death. Animal studies suggest that these effects may contribute to behavioral deficits following prenatal exposure to alcohol.

Neuropsychological comparison of alcohol-exposed children with or without physical features of fetal alcohol syndrome

Fetal alcohol syndrome (FAS) is associated with behavioral and cognitive deficits. However, the majority of children born to alcohol-abusing women do not meet the formal criteria for FAS and it is not known if the cognitive abilities of these children differ from those of children with FAS. Using a set of neuropsychological tests, 3 groups were compared: (a) children with FAS, (b) children without FAS who were born to alcohol-abusing women (the PEA group), and (c) normal controls. The results indicated that, relative to controls, both the FAS and the PEA groups were impaired on tests of language, verbal learning and memory, academic skills, fine-motor speed, and visual-motor integration. These data suggest that heavy prenatal alcohol exposure is related to a consistent pattern of neuropsychological deficits and the degree of these deficits may be independent of the presence of physical features associated with FAS.

Effects of neonatal exposure to nicotine on electrophysiological parameters in adult rats

In clinical studies and animal models, there is evidence that nicotine exposure during gestation can result in deficits in cognitive performance. The present study examined the effects of two doses of neonatal nicotine exposure on adult brain activity as assessed by the N1 and P3 components of the event-related potential (ERP) and background electroencephalography (EEG). Nicotine (0 mg, 1 mg/kg/day, 4 mg/kg/day) was administered to neonatal rat pups from postnatal day 4 (PN4) through PN12 with an artificial rearing paradigm; suckled rats served as additional control subjects. Nicotine exposure was specifically found to alter responses of the P3 component of the ERP, recorded in dorsal hippocampus, to changes in stimulus parameters. A significant reduction in the response of the P3A component to the noise tone as compared with the level of the frequently presented tone was found. A significant reduction in the response to the noise tone as compared with the level of the infrequently presented tone also was seen in the P3B component. No effects of drug exposure were found on the N1 component in any lead, although artificial rearing produced specific effects on the latency of the N1 component in cortex. No significant differences among treatment groups were found on any of the EEG-dependent variables. Female rats overall were found to have significantly higher EEG amplitudes than the males, a finding previously reported in our laboratory. However, no overall effects of gender were found on any ERP component. These studies suggest that neonatal nicotine exposure specifically reduces the electrophysiological response of the hippocampus to changes in auditory stimuli. Additional studies will be necessary to link these P3 amplitude changes to the effects of nicotine on the developing brain in human and animal subjects.

Heavy prenatal alcohol exposure with or without physical features of fetal alcohol syndrome leads to IQ deficits

OBJECTIVE

To assess general intellectual functioning in children with histories of heavy prenatal alcohol exposure, with or without the facial features and growth deficiencies characteristic of fetal alcohol syndrome (FAS).

DESIGN

Forty-seven alcohol-exposed children were recruited on evaluation at a dysmorphology clinic and evaluated as part of a university research project using standard tests of IQ. Thirty-four of the alcohol-exposed patients met the traditional diagnostic criteria for FAS. The other 13 alcohol-exposed children lacked both the pattern of facial features and prenatal or postnatal growth deficiency characteristic of the diagnosis.

RESULTS

Compared with normal control subjects matched for age, sex, and ethnicity, both groups of alcohol-exposed children displayed significant deficits in overall IQ measures and deficits on most of the subtest scores. Although those in the nondysmorphic group usually obtained marginally higher IQ scores than those in the FAS group, few significant differences were found between the two alcohol-exposed groups.

CONCLUSIONS

These results indicate that high levels of prenatal alcohol exposure are related to an increased risk for deficits in intellectual functioning and that these can occur in children without all of the physical features required for a diagnosis of FAS. They also emphasize the need for conducting a thorough history of prenatal alcohol exposure in children with intellectual deficits.

MK-801 administration during ethanol withdrawal in neonatal rat pups attenuates ethanol-induced behavioral deficits

Alcohol exposure during development can produce central nervous system dysfunction, resulting in a wide range of behavioral alterations. The various mechanisms by which alcohol causes these behavioral changes, however, remain unknown. One mechanism that has been suggested is NMDA receptor-mediated excitotoxic cell death produced by ethanol withdrawal. The present study examined whether MK-801, an antagonist of the NMDA receptor that has been shown to protect against NMDA receptor-mediated excitotoxicity, could block alcohol's adverse effects on behavior. Sprague-Dawley rat pups were exposed to alcohol (6.0 g/kg) in a binge-like manner on postnatal day 6 using an artificial rearing procedure. Subjects then received an injection of MK-801 (0.1 mg/kg) or vehicle during withdrawal, 21 hr after ethanol exposure. At postnatal day 40, all subjects were tested on a serial spatial discrimination reversal task. Ethanol-exposed subjects were impaired in both discrimination and reversal learning, and committed a significantly greater number of perseverative-type errors, compared with controls. MK-801 administration during ethanol withdrawal significantly attenuated ethanol-induced deficits in reversal learning and increases in perseverative-type errors, whereas MK-801 exposure by itself had no significant effect on performance. Thus, exposure to MK-801 during ethanol withdrawal partially protected against alcohol-related disruptions in spatial reversal learning. These results support the suggestion that NMDA receptor-mediated excitotoxicity may be one mechanism by which alcohol induces behavioral teratogenicity.

A decrease in the size of the basal ganglia in children with fetal alcohol syndrome

Magnetic resonance imaging was conducted on six children and adolescents with fetal alcohol syndrome and seven matched normal controls. Detailed volumetric analyses demonstrated significant reductions in the cerebral vault, basal ganglia, and diencephalon in the children with fetal alcohol syndrome, compared with control children. In addition, the volume of the cerebellar vault was smaller than controls in 4 of the 6 children with fetal alcohol syndrome, although the group difference did not reach significance. When the basal ganglia were divided into the caudate and lenticular nuclei, both of these regions were significantly reduced in the children with fetal alcohol syndrome. Finally, when the overall reduction in brain size was controlled, the proportional volume of the basal ganglia and, more specifically, the caudate nucleus was reduced in the children with fetal alcohol syndrome. These results may relate to behavioral findings in both humans and animals exposed to alcohol prenatally.

Verbal learning and memory in children with fetal alcohol syndrome

Children with fetal alcohol syndrome (FAS) were administered the California Verbal Learning Test-Children's Version, a word list learning task that assesses immediate and delayed recall and recognition memory. When compared with matched control children, the children with FAS had difficulty learning and recalling the words after a delay period and tended to make an increased number of intrusion and perseverative errors. In addition, they had difficulty discriminating target words from distracter words and made more false-positive errors on recognition testing. Some of these deficits persisted even when mental age was controlled. The results suggest that children with FAS have profound verbal learning and memory deficits, and that some of these deficits cannot be accounted for even when mental age is considered. Furthermore, the results are consistent with deficits in encoding verbal information and impairment in response inhibition capabilities.

Auditory event-related potentials in fetal alcohol syndrome and Down's syndrome children

Abnormal or borderline electroencephalograms are commonly observed in cases of gross mental retardation. However, fewer studies have focused on the use of event-related responses to aid in the differential diagnosis of developmental cognitive disorders. Fetal alcohol syndrome (FAS) and Down syndrome represent the most common known causes of mental retardation in the Western world. Although Down syndrome is easily diagnosed with a chromosome assay, FAS can be more difficult to diagnose since the diagnostic features are more subjectively based. The present study is the first to characterize auditory event-related potentials (ERPs) in children with FAS and contrast them to subjects with Down syndrome and controls. A passive auditory "oddball-plus-noise" paradigm was utilized to elicit ERPs. Parietal P300 latencies in response to the noise-burst stimuli for the FAS children were significantly longer, as were the P300s from all cortical sites in Down syndrome subjects in response to the both the infrequent tone and noise-burst stimuli when compared with the controls. Frontal P300s in Down syndrome children were significantly larger in amplitude compared to the controls and FAS children in response to the infrequent tone. A discriminant function analysis also revealed that these children could be correctly classified as being either Down syndrome, FAS, or normal controls using measures of latency and amplitude of the P300. These data suggest that an evaluation of ERP characteristics may provide a better understanding of the differences between FAS and Down syndrome children, and prove to be an aid in the early identification of children with FAS. These results demonstrate neurophysiological differences between FAS and Down syndrome, and suggest that P300 amplitude and latency data collected from a passive ERP task may be helpful in the discrimination of developmental cognitive disorders.

Abnormal development of the cerebellar vermis in children prenatally exposed to alcohol: size reduction in lobules I-V

Abnormalities of the cerebellar vermis have been well documented in animal models of fetal alcohol syndrome. At this point, it is not known if the same brain region is affected in humans prenatally exposed to alcohol. In this study, the area of the cerebellar vermis was measured from brain magnetic resonance images of 9 children and young adults with prenatal alcohol exposure and 24 control subjects in the same age range. Six of the exposed children met standard criteria for fetal alcohol syndrome. The remaining three subjects had significant histories of prenatal exposure to alcohol, but did not have enough of the classic facial features for the diagnosis. For each subject with a suitable midsagittal section, three vermal areas were circumscribed: anterior vermis (vermal lobules I-V), posterior vermis (vermal lobules VI and VII), and the remaining vermal area (including lobules VIII-X). Statistical analyses revealed that the anterior region of the vermis was significantly smaller in subjects with prenatal alcohol exposure, whereas the posterior region and the remaining vermal area did not differ between groups. Previous findings from an animal model of neonatal alcohol exposure have documented Purkinje cell loss in vermal lobules I-V and IX-X, with notable sparing in lobules VI-VII. Thus, the results of both studies indicate similar patterns of abnormal brain development in the anterior vermal region, with apparent sparing in the posterior vermal region. Our findings, for the first time, suggest that regionally specific Purkinje cell death may also occur in humans prenatally exposed to alcohol.

Effects of artificial rearing on electrophysiology and behavior in adult rats

Maternal separation during crucial periods of development can lead to both physiological and behavioral sequelae. However, the exact consequences of maternal separation are paradigm dependent. The present study utilized complete artificial rearing (AR) to evaluate the effects of maternal separation on behavioral and electrophysiological functioning. In this procedure thermoregulation and weight gain progress are normal, but pups are deprived of any maternal influence from postnatal day 4 to 12. Artificial rearing was found to have no effect on EEG as assessed using spectral analyses. However, the N1 component of the auditory event-related potential (ERP) in artificially reared rats was significantly delayed. Artificial rearing had no effect on overall locomotor activity, but artificially reared rats were more behaviorally inhibited than suckled controls in the open field. This study suggests that artificial rearing or chronic maternal separation (24 h/day from PN4 to PN12), while not producing gross behavioral effects, can produce selective enduring alterations in neurosensory responses.