Effects of neonatal alcohol exposure on vasoactive intestinal polypeptide neurons in the rat suprachiasmatic nucleus.

Neonatal alcohol exposure produces long-term changes in the suprachiasmatic nucleus (SCN) that are presumably responsible for disturbances in the light-dark regulation of circadian behavior in adult rats, including the pattern of photoentrainment, rate of re-entrainment to shifted light-dark cycles, and phase-shifting responses to light. Because SCN neurons containing vasoactive intestinal polypeptide (VIP) receive direct photic input via the retinohypothalamic tract and thus play an important role in the circadian regulation of the SCN clock mechanism by light, the present study examined the long-term effects of neonatal alcohol exposure on VIP neuronal populations within the SCN of adult rats. Male Sprague-Dawley rat pups were exposed to alcohol (EtOH; 3.0, 4.5, or 6.0 g/kg/day) or isocaloric milk formula (gastrostomy control; GC) on postnatal days 4-9 using artificial-rearing methods. At 2-3 months of age, animals from the suckle control (SC), GC, and EtOH groups were exposed to constant darkness (DD) and SCN tissue was harvested for subsequent analysis of either VIP mRNA expression by quantitative polymerase chain reaction (PCR) and in situ hybridization or of VIP-immunoreactive (ir) neurons using stereological methods. Neonatal alcohol exposure had no impact on VIP mRNA expression but dramatically altered immunostaining of neurons containing this peptide within the SCN of adult rats. The relative abundance of VIP mRNA and anatomical distribution of neurons expressing this transcript were similar among all control- and EtOH-treated groups. However, the total number and density of VIP-ir neurons within the SCN were significantly decreased by about 35% in rats exposed to alcohol at a dose of 6.0 g/kg/day relative to that observed in both control groups. These results demonstrate that VIP neuronal populations in the SCN are vulnerable to EtOH-induced insult during brain development. The observed alterations in SCN neurons containing VIP may have an impact upon clock responses to light input and thus contribute to the long-term effects of neonatal alcohol exposure on the photic regulation of circadian behavior.

Alcohol exposure on postnatal day 5 induces Purkinje cell loss and evidence of Purkinje cell degradation in lobule I of rat cerebellum.

The reduction in neuron number in specific brain regions is one of the most destructive aspects of alcohol-induced developmental brain injury, and its occurrence depends on the timing, pattern, and dose of maternal alcohol consumption during pregnancy. The purpose of this investigation was to quantify the dose-response aspect of Purkinje cell loss and rapid cellular degradation indicative of Purkinje cell loss following a single alcohol exposure on postnatal day 5 in lobule I, a lobule that has been shown to be vulnerable to alcohol-induced injury during cerebellar development. Fluoro-Jade B was used to identify Purkinje cell degeneration in 2-h intervals during the first 24h following the single alcohol exposure. At the end of 24h, stereology cell counting techniques were used to estimate the number of Purkinje cells in lobule I of the cerebellum. Significant Fluoro-Jade B labeling of lobule I Purkinje cells began at 12-h postexposure in the 6.0-g/kg group with continued significant expression of the marker at the 16- and 18-h time points. Notably, the magnitude of Fluoro-Jade B expression in the 6.0-g/kg group remained high during the period between 12 and 24h even though the difference between the 6.0-g/kg group and other groups did not reach statistical significance at the 14-, 20-, and 24-h time points. On postnatal day 6, 24h following the alcohol exposure, rats exposed to the highest alcohol dose (6.0 g/kg) had lost significantly more Purkinje cells than those in the nutritional or caloric control to the highest dose of alcohol group. These results are suggestive of a unique relationship among the quantity of alcohol, the onset and duration of cell degradation, and the degree of eventual cell loss. Given that cerebellar Purkinje cells (and many developing neurons) are vulnerable to alcohol-induced neuronal loss within hours of a single alcohol insult, women should be counseled to avoid drinking alcohol in a manner that significantly increases blood alcohol levels during pregnancy (e.g., binge drinking).

Neonatal alcohol exposure differentially alters clock gene oscillations within the suprachiasmatic nucleus, cerebellum, and liver of adult rats.

BACKGROUND: In rats, alcohol exposure during the period of rapid brain growth produces long-term changes in the free-running period, photoentrainment and phase-shifting responses of the circadian rhythm in wheel-running behavior. To determine whether these alterations in circadian behavior are associated with permanent damage to the circadian timekeeping mechanism or reconfiguration of its molecular components, we examined the long-term effects of neonatal alcohol exposure on clock gene rhythms in the pacemaker located in the suprachiasmatic nucleus (SCN) and in other brain or peripheral tissues of adult rats. METHODS: Artificially reared male rat pups were exposed to alcohol (4.5 g/kg/d) or isocaloric milk formula (gastrostomy control; GC) on postnatal days 4 to 9. At 3 months of age, animals were exposed to constant darkness and then SCN, cerebellum, and liver tissue were harvested at 6-hour intervals for subsequent analysis of Period1 (Per1), Per2, Cryptochrome1 (Cry1), Bmal1, and Rev-erbalpha mRNA levels by quantitative PCR. RESULTS: In the SCN, cerebellum and liver, Per1, Per2, Cry1, Bmal1, and Rev-erbalpha expression oscillated with a similar amplitude (peak-to-trough differences of 2- to 9-fold) and phase in the suckle control (SC) and GC groups. These clock gene rhythms in control animals were marked by peak expression of Per1, Per2, Cry1, and Rev-erbalpha during the subjective day and of Bmal1 during the subjective night. The EtOH group was distinguished by altered rhythms in the expression of specific clock genes within the SCN, cerebellum and liver. In EtOH-treated rats, the SCN rhythm in Cry1 expression was strongly damped and the Per2 rhythms in the cerebellum and liver were phase-advanced such that peak expression occurred during the mid-subjective day. CONCLUSIONS: These results demonstrate alcohol exposure during the brain growth spurt alters the circadian regulation of some molecular components of the clock mechanism in the rat SCN, cerebellum, and liver. The observed alterations in the temporal configuration of essential "gears" of the molecular clockworks may play a role in the long-term effects of neonatal alcohol exposure on the regulation of circadian behavior.

Temporal vulnerability of fetal cerebellar Purkinje cells to chronic binge alcohol exposure: ovine model.

BACKGROUND: Human magnetic resonance imaging (MRI) and autopsy studies reveal abnormal cerebellar development in children who had been exposed to alcohol prenatally, independent of the exposure period. Animal studies conducted utilizing the rat model similarly demonstrate a broad period of vulnerability, albeit the third trimester-equivalent of human brain development is reported to be the most vulnerable period, and the first trimester-equivalent exposure produces cerebellar Purkinje cell loss only at high doses of alcohol. However, in the rat model, all 3 trimester-equivalents do not occur prenatally, requiring the assumption that intrauterine environment, placenta, maternal interactions, and parturition do not play an important role in mediating the damage. In this study, we utilized the ovine model, where all 3 trimester-equivalents occur in utero, to determine the critical window of vulnerability of fetal cerebellar Purkinje cells. METHODS: Four groups of pregnant sheep were used: first trimester-equivalent pair-fed saline control group, first trimester-equivalent alcohol group (1.75 g/kg), third trimester-equivalent pair-fed saline control group, and third trimester-equivalent alcohol group (1.75 g/kg). The alcohol exposure regimen was designed to mimic a human binge pattern. Alcohol was administered intravenously on 3 consecutive days beginning on day 4 and day 109 of gestation in the first and third trimester-equivalent groups, respectively, and the alcohol treatment was followed by a 4-day inter-treatment interval when the animals were not exposed to alcohol. Such treatment episodes were replicated until gestational day 41 and 132 in the first and third trimester-equivalent groups, respectively. All fetal brains were harvested on day 133 and processed for stereological cerebellar Purkinje cell counting. RESULTS: Significant deficits were found in the fetal cerebellar Purkinje cell number and density in the first and third trimester-equivalent alcohol exposed fetuses compared with those in the saline controls. However, there was no difference between the first and third trimester-equivalent alcohol administered groups. When comparing the present findings to those from a previous study where the duration of alcohol exposure was all 3 trimester-equivalents of gestation, we did not detect a difference in fetal cerebellar Purkinje cell number. CONCLUSIONS: We conclude that the fetal cerebellar Purkinje cells are sensitive to alcohol exposure at any time during gestation and that women who engage in binge drinking during the first trimester are at a high risk of giving birth to children with cerebellar damage even if drinking ceases after the first trimester. Our findings also support the hypothesis that only a certain population of Purkinje cells are vulnerable to alcohol-induced depletion irrespective of the timing or duration of alcohol exposure.

Chronic ethanol increases fetal cerebral blood flow specific to the ethanol-sensitive cerebellum under normoxaemic, hypercapnic and acidaemic conditions: ovine model.

Cerebral hypoxia has been proposed as a mechanism by which prenatal ethanol exposure causes fetal alcohol spectrum disorder (FASD) in children, but no study had tested this hypothesis using a chronic exposure model that mimicks a common human exposure pattern. Pregnant sheep were exposed to ethanol, 0.75 or 1.75 g kg(-1) (to create blood ethanol concentrations of 85 and 185 mg dl(-1), respectively), or saline 3 days per week in succession (a 'binge drinking' model) from gestational day (GD) 109 until GD 132. Fetuses were instrumented on GD 119-120 and studied on GD 132. The 1.75 g kg(-1) dose resulted in a significant increase in fetal biventricular output (measured by radiolabelled microsphere technique) and heart rate, and a reduction of mean arterial pressure and total peripheral resistance at 1 h, the end of ethanol infusion. The arterial partial pressure of CO(2) was increased, arterial pH was decreased and arterial partial pressure of O(2) did not change. Fetal whole-brain blood flow increased by 37% compared with the control group at 1 h, resulting in increased cerebral oxygen delivery. The elevation in brain blood flow was region specific, occurring preferentially in the ethanol-sensitive cerebellum, increasing by 44% compared with the control group at 1 h. There were no changes in the lower dose group. Assessment of regional differences in the teratogenic effects of ethanol by stereological cell-counting technique showed a reduced number of cerebellar Purkinje cells in response to the 1.75 g kg(-1) dose compared with the control brains. However, no such differences in neuronal numbers were observed in the hippocampus or the olfactory bulb. We conclude that repeated exposure to moderate doses of ethanol during the third trimester alters fetal cerebral vascular function and increases blood flow in brain regions that are vulnerable to ethanol in the presence of acidaemia and hypercapnia, and in the absence of hypoxia.

Uptake and elimination of ethanol by young zebrafish embryos.

Among animal models being explored to understand ethanol-induced teratogenesis, the zebrafish (Danio rerio) is attracting attention because its embryonic development is well characterized and readily visualized. Despite the potential of the zebrafish embryo in research on developmental anomalies produced by ethanol exposure, little is known about the relationship between embryonic ethanol content and the nature/severity of ethanol-mediated deficits. Here, using gas chromatography and radiometry of labeled ethanol carbon, we examine accumulation and clearance of ethanol by dechorionated zebrafish embryos during blastulation/gastrulation. Our data indicate that: (a) rates of uptake and loss of ethanol are directly proportional to the extra-/intra-embryonic ethanol concentration gradient and (b) ethanol in the water fraction of embryos reaches near equimolarity with ethanol in the exposure medium. It appears that, within a wide range of exposure concentrations, embryonic ethanol content can be predicted accurately according to exposure time. Furthermore, it appears that embryonic ethanol can be adjusted rapidly to and maintained at a targeted concentration.

Binge alcohol exposure during all three trimesters alters bone strength and growth in fetal sheep.

Women who drink while pregnant are at a high risk of giving birth to children with neurodevelopmental disorders. Heavy consumption of alcohol during pregnancy is also known to be deleterious to fetal bone growth in both humans and laboratory animals. However, nothing is known regarding the effect of maternal moderate and heavy alcohol binging on fetal and maternal bone strength. The purpose of this study was to determine the effects of moderate and heavy alcohol binging throughout gestation on fetal and maternal bone growth and strength. The study was conducted using an ovine model system. The large body mass of the ovine fetus, the longer gestation that is more similar to that of humans, and the fact that all three trimester equivalents occur in utero, make the sheep an excellent model for studying Fetal Alcohol Spectrum Disorder. Suffolk ewes were mated and, beginning on gestational day 4, received intravenous infusions over 1 h on 3 consecutive days per week followed by 4 days without treatment concluding on day 132 of pregnancy. Pregnant ewes were divided into four groups: two alcohol treatment groups (0.75 and 1.75 g/kg of body weight), one pair-fed saline control group, and an untreated normal control group. The fetuses were harvested on gestational day 133. Maternal and fetal femoral and tibial dimensions were measured and the maximum strength (MPa) carried by the bone tissue was determined using a three-point bending procedure. Maternal bones were not different among groups. The higher alcohol dose resulted in reduced fetal femoral bone strength, whereas the tibial bone strength was lower when compared with the normal control subjects. In contrast, the lower alcohol dose increased fetal femoral strength compared to the normal control subjects. The alcohol-exposed fetal bones also tended to exhibit reduced lengths. We conclude that binge alcohol exposure throughout gestation resulted in dose-dependent differences in the maximum stress absorbed by the fetal bones.

Nicotine decreases blood alcohol concentrations in adult rats: a phenomenon potentially related to gastric function.

BACKGROUND: In spite of the fact that drinking and smoking often occur together, little is known about the pharmacokinetic interaction between alcohol and nicotine. Previous research in neonatal rats demonstrated that nicotine reduces blood alcohol concentrations (BACs) if alcohol and nicotine are administered simultaneously. However, it is unclear whether such a phenomenon can be observed in adult subjects, given the fact that there is an ontogenetic difference in alcohol metabolism. METHODS: A range of nicotine doses (0, 0.25, 0.5, 1, 2, 4, and 6 mg/kg) were administered individually with an alcohol dose (4 g/kg) via intragastric (IG) intubation to adult female rats, and the resultant BACs were measured at various time points following drug administration. Furthermore, the hypothesis that nicotine's role in reducing BACs is mediated through factors related to gastric function was examined by comparing the resultant BACs after an IG intubation or intraperitoneal (IP) injection of alcohol. RESULTS: The results from this study showed significant nicotine dose-related decreases in BACs with 0.5, 1, 2, 4, and 6 mg/kg doses of nicotine at the various time points assessed. This effect, however, occurred only when alcohol was administered via IG intubation, but not after an IP injection of alcohol. CONCLUSIONS: These results suggest that the nicotine-induced decrease in BAC may be related to gastric function. One possible explanation was related to nicotine's action in delaying gastric emptying. The longer the alcohol was retained in the stomach, the more likely that the alcohol would be metabolized by gastric alcohol dehydrogenase before its absorption into the bloodstream by the small intestine (the major site of alcohol absorption).

Neonatal alcohol exposure permanently disrupts the circadian properties and photic entrainment of the activity rhythm in adult rats.

BACKGROUND: Alcohol exposure during the period of rapid brain development produces structural damage in different brain regions, including the suprachiasmatic nucleus (SCN), that may have permanent neurobehavioral consequences. Thus, this study examined the long-term effects of neonatal alcohol exposure on circadian behavioral activity in adult rats. METHODS: Artificially reared Sprague-Dawley rat pups were exposed to alcohol (EtOH; 4.5 g/kg/day) or isocaloric milk formula (gastrostomy control; GC) on postnatal days 4-9. At 2 months of age, rats from the EtOH, GC, and suckle control (SC) groups were housed individually, and properties of the circadian rhythm in wheel-running behavior were continuously analyzed during exposure to a 12-hr light:12-hr dark photoperiod (LD 12:12) or constant darkness (DD). RESULTS: Neonatal alcohol exposure had distinctive effects on the rhythmic properties and quantitative parameters of adult wheel-running behavior. EtOH-treated animals were distinguished by unstable and altered entrainment to LD 12:12 such that their daily onsets of activity were highly variable and occurred at earlier times relative to control animals. In DD, circadian regulation of wheel-running behavior was altered by neonatal alcohol exposure such that the free-running period of the activity rhythm was shorter in EtOH-exposed rats than in control animals. Total amount of daily wheel-running activity in EtOH-treated rats was greater than that observed in the SC group. In addition, the circadian activity patterns of EtOH-exposed rats were fragmented such that the duration of the active phase and the number of activity bouts per day were increased. CONCLUSIONS: These data indicate that neonatal alcohol exposure produces permanent changes in the circadian regulation of the rat activity rhythm and its entrainment to LD cycles. These long-term alterations in circadian behavior, along with the developmental alcohol-induced changes in SCN endogenous rhythmicity, may have important implications in clinical sleep-wake disturbances observed in neonates, children, and adults exposed to alcohol in utero.

Fetal alcohol syndrome: an assessment of the field.

Fetal exposure to alcohol is the major known cause of mental retardation in the Western world. For more than half of the 20th century, the placenta was widely believed to be an effective barrier against environmental agents. The discovery that offspring of pregnant women who were exposed to German measles or administered thalidomide were often malformed raised awareness that teratogens could be any environmental agent, including viruses and drugs, that caused abnormal development. Alcohol was not identified as a teratogen until the 1970s. Fetal exposure to alcohol can cause fetal alcohol syndrome (FAS), which is characterized by specific physical traits and central nervous system dysfunctions. The development of animal model systems has facilitated our study of the effects of fetal alcohol exposure and the elucidation of the mechanisms involved in alcohol-induced abnormal development. Despite our current understanding of the effects of fetal alcohol exposure, the occurrence of FAS and associated fetal alcohol spectrum disorders is still widespread and the associated health-care costs are staggering. This symposium provides an up-to-date analysis of fetal exposure to alcohol and FAS. It is directed not only to investigators working in the field but to a diverse group of scientists working in the biological and biomedical fields to stimulate cross-disciplinary awareness, interest, and collaboration.

Long-term effects of neonatal alcohol exposure on photic reentrainment and phase-shifting responses of the activity rhythm in adult rats.

In rats, neonatal alcohol (EtOH) exposure coinciding with the period of rapid brain growth produces structural damage in some brain regions that often persists into adulthood and thus may have long-term consequences in the neural regulation of behavior. Because recent findings indicate that the circadian clock located in the rat suprachiasmatic nucleus is vulnerable to alcohol-induced insults during development, the present study examined the long-term effects of neonatal alcohol exposure on the photic regulation of circadian behavior in adult rats. Rat pups were exposed to alcohol (3.0, 4.5, or 6.0 g x kg(-1) x day(-1)) or isocaloric milk formula on postnatal days 4-9 using artificial-rearing methods. At 2 months of age, animals were housed individually and circadian wheel-running behavior was continuously analyzed to determine the effects of neonatal alcohol treatment on the rate of reentrainment to a 6-h advance in the 12-h light:12-h dark photoperiod and the phase-shifting properties of free-running rhythms in response to discrete light pulses on a background of constant darkness. For all doses, neonatal alcohol exposure had a significant effect in reducing the time for reentrainment such that EtOH-treated rats required four to five fewer days than control animals for stable realignment of the activity rhythm to the shifted light-dark cycle. Coupled with the accelerated rate of reentrainment, the amplitude of light-evoked phase delays at circadian time 14 and advances at circadian time 22 in the 4.5 and 6.0 g x kg(-1) x day(-1) EtOH groups was almost twofold greater than that observed in control animals. The present observations indicate that the mechanisms by which photic signals regulate circadian behavior are permanently altered following alcohol exposure during the period of rapid brain development. These long-term alterations in the photic regulation of circadian rhythms may account, at least partially, for some neurobehavioral consequences of prenatal alcohol exposure in humans such as depression.

Long-term alcohol exposure prior to conception results in lower fetal body weights.

BACKGROUND: It is well known that alcohol consumption during pregnancy can result in lower birth weight babies but many women stop consuming alcohol prior to conception as a part of pregnancy planning. The purpose of this study was to determine whether alcohol consumption prior to conception may also have an effect on fetal development. METHODS: Male and female C57BL/6J mice at 4, 6, or 8 weeks of age received either a single administration of alcohol (3.0 g/kg) via intragastric gavage (IG) each day for at least 60 days, or an isovolumetric IG administration of sterile water. After 60 treatment days, males and females within each age and treatment group were mated overnight. Females continued to receive daily alcohol treatments until conception. Males continued to receive treatments until all females were successfully mated. At conception, females were isolated and left undisturbed. On embryonic day 14, fetus number, size, and weight was determined. RESULTS: Maternal food consumption, body weight at conception, and delay to conception onset did not differ between the two treatment groups or among the three age groups. Fetal body weights did not differ among the three age groups. Fetuses from females treated with alcohol had lower body weights compared to those treated with water. Male treatments did not seem to affect fetal body weight. CONCLUSIONS: Fetal growth and development can be affected by alcohol consumption prior to the time of conception. Alcohol consumption prior to conception is a potential risk factor to fetal outcome and an important consideration for those females planning to have children.

Developmental alcohol exposure alters light-induced phase shifts of the circadian activity rhythm in rats.

BACKGROUND: Developmental alcohol (EtOH) exposure produces long-term changes in the photic regulation of rat circadian behavior. Because entrainment of circadian rhythms to 24-hr light/dark cycles is mediated by phase shifting or resetting the clock mechanism, we examined whether developmental EtOH exposure also alters the phase-shifting effects of light pulses on the rat activity rhythm. METHODS: Artificially reared Sprague-Dawley rat pups were exposed to EtOH (4.5 g/kg/day) or an isocaloric milk formula (gastrostomy control; GC) on postnatal days 4 to 9. At 2 months of age, rats from the EtOH, GC, and suckle control groups were housed individually, and wheel-running behavior was continuously recorded first in a 12-hr light/12-hr dark photoperiod for 10 to 14 days and thereafter in constant darkness (DD). Once the activity rhythm was observed to stably free-run in DD for at least 14 days, animals were exposed to a 15-min light pulse at either 2 or 10 hr after the onset of activity [i.e., circadian time (CT) 14 or 22, respectively], because light exposure at these times induces maximal phase delays or advances of the rat activity rhythm. RESULTS: EtOH-treated rats were distinguished by robust increases in their phase-shifting responses to light. In the suckle control and GC groups, light pulses shifted the activity rhythm as expected, inducing phase delays of approximately 2 hr at CT 14 and advances of similar amplitude at CT 22. In contrast, the same light stimulus produced phase delays at CT 14 and advances at CT 22 of longer than 3 hr in EtOH-treated rats. The mean phase delay at CT 14 and advance at CT 22 in EtOH rats were significantly greater (p < 0.05) than the light-induced shifts observed in control animals. CONCLUSIONS: The data indicate that developmental EtOH exposure alters the phase-shifting responses of the rat activity rhythm to light. This finding, coupled with changes in the circadian period and light/dark entrainment observed in EtOH-treated rats, suggests that developmental EtOH exposure may permanently alter the clock mechanism in the suprachiasmatic nucleus and its regulation of circadian behavior.

Developmental alcohol exposure disrupts circadian regulation of BDNF in the rat suprachiasmatic nucleus.

In rats, damage to neuronal populations in some brain regions occurs in response to neonatal alcohol exposure coinciding with the period of rapid brain growth. These alcohol-induced defects in brain development may persist into adulthood and thus have long-term implications for the functional characteristics of damaged neuronal populations. The present study examined the effects of neonatal alcohol exposure on endogenous rhythmicity of the circadian clock located in the rat suprachiasmatic nucleus (SCN). Specifically, experiments were conducted to determine whether neonatal alcohol exposure alters the circadian rhythm of brain-derived neurotrophic factor (BDNF) content in the rat SCN because this neurotrophin is an important rhythmic output from the SCN clock. Male rat pups were exposed to alcohol (4.5 g/kg/day) or isocaloric milk formula on postnatal days 4-9 using artificial rearing methods. At 5-6 months of age, SCN and hippocampal tissue was harvested and subsequently examined for content of BDNF protein. Time-dependent fluctuations in BDNF protein levels were assessed by enzyme-linked immunosorbent assay (ELISA). In alcohol-treated rats, SCN levels of BDNF were significantly decreased and were characterized by a loss of circadian rhythmicity relative to those observed in control animals. In comparison, hippocampal levels of BDNF displayed no evidence of circadian regulation in all three treatment groups, but were slightly lower in alcohol-treated animals than in control groups. Importantly, these observations suggest that alcohol exposure during the period of rapid brain development may cause permanent changes in the SCN circadian clock.

Alcohol and nutritional control treatments during neurogenesis in rat brain reduce total neuron number in locus coeruleus, but not in cerebellum or inferior olive.

Although a significant amount of progress has been made during the past two decades in determining the effects of alcohol on brain development, there is still a gap in the literature in terms of when the neurons in the brain are more or less vulnerable to the deleterious effects of alcohol. Using a rat model system, we examined the effect of alcohol on the development of three brain regions after exposure to alcohol only during the period of neurogenesis of each specific region. Our working hypothesis was that all three regions would be equally vulnerable to alcohol-induced reductions in neuron number after exposure during neurogenesis. The Purkinje cells of the cerebellum and the neurons of the locus coeruleus and inferior olive were chosen for examination because of their functional relation to the neuroanatomical circuit for motor coordination and gait, which is disrupted in children exposed to alcohol during gestation. Groups of timed-pregnant Sprague-Dawley rats were administered alcohol or nutritional control substitute daily by gavage during the period of neurogenesis for each region, or they were given no treatments. On postnatal day 10, neuron counts were derived from the three regions of the offspring brains by using stereological cell-counting techniques. The number of neurons in the locus coeruleus was reduced in both the alcohol- and nutritional control-treated groups relative to findings for the normal control group. There was no similar reduction in neuron number in the Purkinje cells of the cerebellum, nor in the neurons of the inferior olive, among the treatment groups. These results demonstrate that the period of neurogenesis is not a uniformly vulnerable period for the three brain regions tested, and the findings support the suggestion of a possible avenue for examining the underlying explanation for why some regions are more vulnerable than other regions during various phases of neuronal development.

Fetal alcohol exposure and temporal vulnerability: effects of binge-like alcohol exposure on the developing rat hippocampus.

Children with fetal alcohol syndrome (FAS) display altered performance in tasks of learning and memory, behaviours thought to be associated with the hippocampus. Altered hippocampal structure has been reported in some FAS children; therefore, a rat model system was used to determine whether the size and numbers of pyramidal cells in regions CA1 and CA3 of the hippocampal formation and granule cells in the dentate gyrus were altered by alcohol exposure during different periods of development. Rat pups were exposed to alcohol in utero during the second trimester-equivalent (E10-20), the first two trimesters-equivalent (E1-20), during the time of hippocampal pyramidal cell neurogenesis (E16-20), part of the third trimester-equivalent (P4-9), and all three trimesters-equivalent (E1-20+P4-9). Control animals (nutritional and untreated) were reared for all treatment conditions. All pups were perfused on P10. CA1 volume, pyramidal cell density, and number were reduced in pups treated with alcohol during the third trimester-equivalent, whether unique or as exposure during all three trimesters-equivalent. CA3 volume was reduced in alcohol-treated animals across all gestational ages; however, pyramidal cell density and number in this region were only reduced in animals treated with alcohol during the third trimester-equivalent. Volume of the dentate gyrus did not appear to be affected by alcohol treatment. Granule cell density and number in this region were reduced in animals treated with alcohol during the third trimester-equivalent. The third trimester-equivalent in the rat appears to be a developmental period during which the hippocampus is particularly susceptible to the effects of alcohol consumption. The resulting damage to the hippocampus may contribute to the behavioural deficits related to learning and memory noted in children with FAS.

Blood ethanol concentration profiles: a comparison between rats and mice.

It is important to select an appropriate model system for studies examining the mechanisms of ethanol-induced injury. The most common model systems use either mice or rats with ethanol administered by means of intragastric gavage or intraperitoneal injection, yet few studies have compared directly the blood ethanol concentration (BEC) profiles that result from each of these model systems. In the current study, Sprague-Dawley rats and C57BL/6J mice were given ethanol by means of intragastric gavage or intraperitoneal injection at 40 days of age. Blood samples were collected at consistent time intervals to determine BECs. Blood ethanol concentrations in mice were sharper, with a more rapid rise to a sharp peak BEC, followed by a relatively rapid decline. In contrast, rat BEC profiles showed an initial rapid rise, followed by a more gradual rise to peak concentrations, and, then, a relatively gradual decline. This difference was particularly evident in rats receiving ethanol intragastrically. The differences found in BEC profiles between rats and mice and between ethanol administration paradigms may yield differences in the extent or mechanism of damage induced by ethanol, an important consideration when selecting an appropriate model for the investigation of ethanol-induced tissue damage.

Alcohol and the developing brain: neuroanatomical studies.

One of the distinguishing features of prenatal alcohol exposure is impaired cognitive and behavioral function resulting from damage to the central nervous system. Information available from the small number of autopsied cases in humans indicates that the offspring of mothers who abused alcohol during pregnancy have various neuroanatomical alterations ranging from gross reductions in brain size to cellular alterations. Recent neuroimaging technology provides the most powerful tool for assessing the neurotoxic effects of fetal alcohol exposure in living organisms and for exploring the relationship between behavioral dysfunction and brain damage at the regional level. Recently, animal research has suggested that the damaging effects of alcohol exposure during brain development could be prevented or attenuated by various pharmacological manipulations or by complex motor training. These promising findings provide directions for developing future prevention or intervention strategies.