Enhanced sensitivity to methadone in adult rats perinatally exposed to methadone

Adult rats, maternally exposed to methadone during gestation and/or lactation, were evaluated for thermoregulatory and nociceptive responsiveness following a challenge with 5 mg/kg (i.p.) methadone. Prior to drug administration, female rats in the gestation and gestation-lactation groups and all male rats perinatally exposed to methadone were subnormal in body temperature. One hour after acute methadone injection, male control rats were hypothermic. All groups of methadone-treated offspring exhibited a marked lowering in body temperature with respect to their pre-injection levels, as well as in regard to values of methadone-administered control animals. Prior to drug administration, male rats of the gestation-lactation group and female rats of the gestation and lactation groups had elevated nociceptive thresholds. Except for male rats in the lactation group, animals treated with methadone perinatally had longer latencies in response to the hot-plate relative to their pre-injection values, as well as to levels of methadone-injected controls. Three days after acute methadone administration, some groups of rats subjected to this drug during gestation and/or lactation were found to be hypothermic and hypalgesic in respect to their pre-injection values, and also relative to control rats. These results suggest that exposure to methadone early in life can have a profound influence on drug response in adulthood.     

Dietary iron and the integrity of the developing rat brain: a study with the artificially-reared rat pup.

Inadequate iron nutrition is thought to affect many aspects of brain development. Iron is a component of enzyme systems in DNA synthesis, the respiratory chain, neurotransmitter and lipid metabolism. The iron content of the striatum increases post-natally, with neuronal differentiation, myelin lipid and receptor formation: Seventy percent of the iron in the brain is associated with myelin. In an attempt to dissociate the global effects of under-and/or malnutrition and to produce exclusively an iron deficiency, we have used the gastrostomy-reared rat pup fed milk substitutes which vary only in their iron content. To ensure the pups did not have adequate iron reserves at birth, dams were fed a meal diet of low iron content (3 ppm) throughout gestation. The pups were then artificially reared on milk with (43 ppm), and without added iron (2.5 ppm) from 6 up to 21 days after birth. At 21 days of age, body weights of iron deficient pups were about 90% those of control animals. At 21 days of age, the pups were weaned, then fed standard laboratory rat chow. Brain was examined at 42 days of age (for young adults) and up to 6 months of age (180 days as mature adults). Morphometric analysis of sagittal sections of the cerebellum at 21 and 63 days of age revealed a deficit in white matter formation in pups fed low-iron at 21 days of age when compared to controls. This deficit was partially recouped by age 63 days. By contrast, animals fed milk supplemented with iron showed greater definition in white matter formation than controls at 21 days of age; indicative of precocious maturation of the white matter tracts. Our findings indicate that iron deficiency, without under/mal-nutrition and other variables, does not result in extensive growth deficits in body and brain weight. However, the iron status profoundly influences the development of myelination in that the process is delayed in iron deficiency.     

Effects of maternal ethanol consumption during pregnancy or lactation on intestinal absorption of folic acid in suckling rats

A fostering/crossfostering analysis of the effects of maternal ethanol exposure on jejunal and ileal folate absorption was performed. Male and female rats were randomized into two groups. In the first group, ethanol-treated rats received ad libitum 5, 10 and 15% ethanol in the drinking fluid during three successive weeks. A consumption of 20% was maintained in this group for 5 additional weeks. Ethanol-treated rats were mated. Group 2 served as the control. To study the effect of chronic alcoholism during lactation or gestation separately, at birth (2nd day postpartum) control newborns were cross-fostered to ethanol dams (EG), and the pups issued from the ethanol treated mothers were cross-fostered to control dams (CG). Thus, three experimental groups of pups were formed: (1) control pups receiving no treatment during gestation and lactation (CG); (2) pups exposed to ethanol only during gestation (GG); and (3) pups exposed to ethanol only during lactation (LG). At 21 days postpartum the jejunal and distal ileum folate absorption was determined in the offspring rats by a perfusion technique. Milk folic acid levels were determined by an immunoluminometric assay. The results showed an increase in jejunal folic acid absorption in offsprings exposed to ethanol only during the lactation period (LG). However, in pups exposed to ethanol only during the gestation period (GG), the jejunal folic acid absorption was significantly increased only at concentrations of 0.25, 0.5 and 2.5 microM. No free folic acid absorption occurred in the distal ileum of control pups (CG) at day 21 at all assayed concentrations but in offsprings exposed to ethanol only during the gestation or lactation periods absorption did take place. Pups exposed to ethanol during the gestation period (GG) showed decreased values in ileum folic acid absorption at the lowest assayed concentration (0.25 microM) compared to values obtained for pups exposed to ethanol only during lactation (LG). Milk folic acid levels were significantly decreased in the ethanol-fed dams on day 21 of lactation. These results indicate that exposure of rats to ethanol during the lactation period affects more severely postnatal development of intestinal functions than ethanol exposure only during gestation. In summary, both the exposure to ethanol itself and the decrease in folic acid intake caused alterations in the function of the intestinal mucosa in the offspring, which in turn altered absorption time and development. However, the present results do not explain how ethanol stimulated intestinal absorption of folic acid in pups exposed to ethanol during the gestation or lactation periods. Further studies are needed.     

Thyroxine-induced hyperthyroidism upon the reproductive performance of female rats.

L-Thyroxine (L-T4) was injected into mature rats daily at levels of 0, 3, 6, 12, 24, 48 and 96 mug/100 g body weight through estrous cycling, conception, pregnancy, parturition and 20 days of lactation. Mothers which lactated to 20 days were killed and mammary glands measured for DNA and RNA content. Those which were not able to maintain their pups were killed on the day when all pups died. Estrous cycling and pregnancy were not markedly effected by exogenous L-T4 at levels 3-96 times the normal thyroxine secretion rate in rats. After parturition the mothers on L-T4 above 12 mug did not allow the pups to suckle. As a result the pups died within 2-7 days after birth. Levels of L-T4 from 3 to 12 mug allowed lactation to progress, but survival of pups to day 20 of lactation was significantly lower than in the normal control group. The results of this study indicate that high levels of L-T4 inhibit mammary growth and mild secretion. This, in turn, results in the loss of pups, probably through depletion of prolactin as a result of higher metabolic rate due to hyperthyroidism.     

Effect of ethanol on rat brain polyphosphoinositides

Abstract: Female rats were allowed to consume ethanol during gestation and lactation, and brain polyphosphoinositides of the 21-day-old pups were quantified. Ethanol intake prevented the disappearance of the metabolically labile pools of phosphatidylinositol-4-phosphate and phosphatidylinositol-4,5-bis-phosphate, which are rapidly degraded in the control group. In contrast, preweaning undernutrition left the size of these pools virtually unchanged, indicating a differential effect of the two nutritional regimens. Key Words: Polyphosphoinositides—Labile pools—Ethanol—Brain of offspring—Phosphati-dylinositol - 4 - phosphate—Phosphatidylinositol - 4,5 -bis-phosphate—Ethanol feeding—Undernutrition (preweaning). Shah I. R. et al. Effect of ethanol on rat brain polyphosphoinositides.     

Effects of cobalt on postnatal development and late gestation in rats upon oral administration

Four groups of pregnant Wistar rats, each of which consisted of 15 animals were administered 0, 12, 14 and 48 mg/kg/day of cobalt (II) chloride from the 14th day of gestation through 21 days of lactation. The offspring were observed for mortality, body weight, body and tail length and general symptomatology after 1, 4 and 21 days of nursing. The number of litters was higher for the control group. The survival ratios were also higher for the control group. Besides, a dose-dependent delay in the growth of the living young could be observed. No significant differences in organ weights in the animals killed 21 days after birth were observed. The blood parameters analysed did not show differences between the treated and control pups. Cobalt produced toxic effects on the mothers, affecting the late gestation as well as the postnatal development of the pups.     

EFFECT OF UNDERNUTRITION ON CELL FORMATION IN THE RAT BRAIN

Abstract— Rats were undernourished by approximately halving the normal food given from the 6th day of gestation throughout lactation. Growth of the foetuses was nearly normal, in marked contrast to the severe retardation caused by undernutrition during the suckling period. In comparison with controls the size and the DNA content of the brain were permanently reduced by undernutrition during the suckling period: this effect was relatively small, approx. 15 per cent decrease at 21 and 35 days. The rate of ¹⁴C incorporation into brain DNA at 30 min after administration of [2-¹⁴C] thymidine was taken as an index of mitotic activity; compared with controls there was severe reduction in mitotic activity (maximal decrease by about 80 per cent at 6 days in the cerebrum and by 70 per cent at 10 days in the cerebellum). The rate of acquisition of cells was calculated from the slopes of the logistic curves fitted to the estimated DNA contents. In normal animals the maximal slope was attained at 2·7 days and at 12·8 days after birth in cerebrum and cerebellum respectively; the daily acquisition of cells at these times was 4·8 × 10⁶ and 18 × 10⁶ cells respectively. The fractional increase in cell number at the maximum was 5·4 percent per day in the cerebrum and 15·2 per cent per day in the cerebellum. The rate of acquisition of cells relative to the rate of mitotic activity was higher in the brains of undernourished animals than in controls. One of the compensatory mechanisms for the severe depression of mitotic activity in the brain of undernourished animals Seems to involve a reduction in the normal rate of cell loss.     

Regulation of brain water during acute hyperosmolality in ovine fetuses, lambs, and adults.

In adult rats, when plasma osmolality increases, water flows across the blood-brain barrier down its concentration gradient from brain to plasma, and brain volume deceases. The brain responds to this stress by gaining osmotically active solutes, which limit water loss. This phenomenon is termed brain volume (water) regulation. We tested the hypothesis that brain volume regulation is more effective in young lambs and adult sheep than in fetuses, premature lambs, and newborn lambs. Brain water responses to acute hyperosmolality were measured in the cerebral cortex, cerebellum, and medulla of fetuses at 60 and 90% of gestation, premature ventilated lambs at 90% of gestation, newborn lambs, young lambs at 20-30 days of age, and adult sheep. After exposure of the sheep to increases in systemic osmolality with mannitol plus NaCl, brain water content and electrolytes were quantified. The ideal osmometer is a system in which impermeable solutes do not enter or leave in response to an osmotic stress. There were significant differences from an ideal osmometer in the cerebral cortex of fetuses at 90% of gestation, cerebral cortex, and cerebellum of newborn lambs, and cerebral cortex, cerebellum, and medulla of young lambs and adult sheep; however, there were no differences in the brain regions of fetuses at 60% of gestation and premature lambs, cerebellum and medulla of fetuses at 90% of gestation, and medulla of newborn lambs. We conclude that 1) brain water loss is maximal and brain volume regulation impaired in most brain regions of fetuses at 60 and 90% of gestation and premature lambs; 2) brain volume regulation develops first in the cerebral cortex of the fetuses at 90% of gestation and in the cerebral cortex and cerebellum of newborn lambs, and then it develops in the medulla of the lambs at 20-30 days of age; 3) brain water loss is limited and volume regulation present in the brain regions of young lambs and adult sheep; and 4) the ability of the brain to exhibit volume regulation develops in a region- and age-related fashion.     

The food intake of rats during pregnancy and lactation

Quantities of food required by Sprague-Dawley rats during gestation and lactation and in the post-lactation period were examined. Rats allowed to eat ad libitum during pregnancy consumed quantities of food only slightly greater than the amount reported to be the average intake of pregnant Sprague-Dawley rats (20 g/day). Rats delivered their pups on day 22 or day 23 of the gestation period, but regardless of the day of delivery, the food intake of each rat decreased on day 21 of pregnancy and then decreased a second time on the day of parturition. During lactation, food consumption of the rats soon exceeded the amount reported as the average intake of lactating rats (30-35 g/day). Food intake was found to escalate from 12.2 +/- 3.1 g/rat on day 0 of lactation, the lowest intake in the study, to 94.4 +/- 23.7 g on day 21 of lactation. However, in the latter part of the lactation period, the intake represented the combined food intake of dams and pups. Eight days in the post-lactation period were required for food intake of dams to return to a level near that recorded at the beginning of pregnancy.     

Protein-energy malnutrition during pregnancy alters caffeine's effect on brain tissue of neonate rats

We studied whether protein-energy malnutrition changed brain susceptibility to a small dose of caffeine in newborn rats. Since we had demonstrated previously that caffeine intake during lactation increased the brain neuropeptide on newborns, we investigated further the effects of the prenatal administration of caffeine on TRH and cyclo (His-Pro). From day 13 of gestation to delivery day, pregnant rats in one group were fed either a 20% or a 6% protein diet ad libitum, and those in the other group were pair-fed with each protein diet supplemented with caffeine at an effective dose of 2 mg/100 g body weight. Upon delivery, brain weight, brain protein, RNA, DNA and the neuropeptides thyrotropin-releasing hormone (TRH) and cyclo (His-Pro) were measured in the newborn rats. A 6% protein without caffeine diet caused reductions in brain weights and brain protein, RNA and DNA contents, but did not alter brain TRH and cyclo (His-Pro) concentrations in the newborn animals. In the offspring from dams fed a 6% protein diet, caffeine administration significantly elevated brain weights and brain contents of protein, RNA and DNA. In contrast, these values were similar between noncaffeine and caffeine-supplemented animals in a 20% protein diet group. Brain TRH and cyclo (His-Pro) concentrations were not changed by caffeine administration. These data suggest that caffeine augments protein synthesis in the newborn rat brain when malnourished, but that the same dose of caffeine did not affect protein synthesis in brains of newborn rats from normally nourished dams. Therefore, the present findings indicate that the nutritional status of mothers during pregnancy has important implication in the impact of caffeine on their offspring's brains.     

A neurochemical study of developmental impairment of the brain caused by the administration of cytosine arabinoside during the fetal or neonatal period of rats

Injection of pregnant rats with cytosine arabinoside (ara-C) (280 mg/kg) on day 15 of gestation caused a significant rise (about two times the control value) in monoamine concentrations (norepinephrine, dopamine, and serotonin) accompanied by a decrease (about 60% of the control) in the brain weight and DNA content in the cerebrum of the offspring at 60 days of age. When neonatal rats were injected with ara-C (30 mg/kg/day) for four consecutive days from the fourth to seventh days after birth, a decrease of DNA content per cerebellum and an elevation of monoamine concentrations in the cerebellum were found. However, the total content of each monoamine per cerebrum or cerebellum showed no difference from the control. These results suggest that monoaminergic neurons may remain intact, with normal monoaminergic synapses compressed into a small brain volume. The neonatal administration of ara-C caused an elevation of 2, 3-cyclic nucleotide 3-phosphodiesterase (CNPase) (EC 3.1.4.37) activity and myelin protein content in the cerebellum, suggesting a relative increase in myelin concentration as a result of hypoplasia of granule cells.     

LHRH and LH in peripubertal female rats following prenatal and/or postnatal ethanol exposure

The effects of pre- and postnatal exposure to ethanol (ETOH) on LHRH and LH were investigated. Pregnant and/or lactating dams were fed ETOH during: 1) gestation, 2) lactation, or 3) gestation-lactation. Female offspring were decapitated at 30 or 40 days-of-age; trunk blood was collected for plasma LH RIA; and hypothalamic tissues were collected for LHRH RIA. Hypothalamic LHRH content of all ETOH-exposed groups was less than that of non-ETOH-fed controls at 30 and 40 days-of-age (p less than 0.05). Plasma LH concentrations of all ETOH-exposed groups were less than those of non-ETOH-fed controls at 30 and 40 days-of-age (p less than 0.05). Also, at 30 and 40 days-of-age, the plasma LH concentrations of the animals exposed to ETOH during lactation and gestation-lactation were less than those of the animals exposed to ETOH during gestation (p less than 0.05). These data suggest that ETOH exposure during gestation and/or lactation negatively affects hypothalamic LHRH content of female rat offspring. Decreased hypothalamic LHRH content with corresponding lowered plasma LH concentration suggests that ETOH influences development or maturation of hypothalamic LHRH neurons by possibly decreasing their number or synthesizing capability.     

Effect of Maternal Ethanol Consumption during Pregnancy and Lactation on Kinetic Parameters of Folic Acid Intestinal Transport in Suckling Rats

Ethanol ingestion is known to interfere with folate absorption and metabolism. A fostering/crossfostering analysis of maternal ethanol exposure effects on jejunum and ileum kinetic parameters in vivo of offspring rat folic acid absorption at 21 days postpartum was carried out. The rats were divided into four groups: CP, control pups; GP, pups exposed to ethanol only during gestation; LP, pups exposed to ethanol only during lactation; GLP, pups exposed to ethanol during gestation and lactation. Jejunal and ileal loop transport studies were performed using in vivo perfusion at a flow rate of 3 ml/min for 5 min. Folic acid concentrations of 0.25, 0.5, 1, 1.5 and 2.5 μm were used. Jejunal and ileal absorption values were determined by the difference between the initial and the final amounts of substrate in the perfusate and expressed as picomoles per square centimeter of intestinal surface every 5 min. The results indicated that ethanol consumption by the dams during gestation and/or lactation led to significant changes in V _max, with no significant changes in apparent K _m. These findings suggest that exposure to ethanol during gestational and suckling periods leads to a general delay in postnatal body weight and that intestinal folate absorption appears to be upregulated in suckling rats, this effect being higher in the LP group.     

Effects of maternal thiamine deficiency on the lipid composition of rat whole brain, gray matter and white matter

Studies were made of the effects of maternal thiamine deficiency on rat whole brain, gray matter and white matter lipids. Mothers were fed a high protein diet (controls) or thiamine deficient high protein diet (thiamine deficient, TD) from 14th day of gestation through lactation. An additional group (pair fed control, PFC) was pair fed with the thiamine deficient group. The TD pups started showing symptoms of abnormalities in posture, arched back and hind limb paralysis from 16th day of lactation. Significant deficits were found in body weight and brain weight of TD and PFC pups. But the deficits seem to be more in the former group. Significant deficits were observed with regard to the concentration of lipids such as galactolipids, phospholipids and plasmalogens in the whole brain of TD and PFC pups at 21 days of age. Additional deficits were also found in the concentration of cholesterol in PFC pups. Gray matter lipids from TD pups seem to be completely spared. However, deficits were found in galactolipid and ganglioside concentrations in PFC pups. The deficits found in the concentration of different lipids in white matter are similar to those observed in whole brain. These results suggest that the effects of thiamine deficiency may be partly due to resultant growth retardation and partly due to the deficiency of thiamine per se.     

Transfer of iodine through the milk in protein-restricted lactating rats

Iodine supply is important to avoid neonatal hypothyroidism. This study evaluated whether protein restriction during lactation affects iodine transfer to the pups through the milk. We studied lactating rats fed an 8% protein-restricted diet (PR), a control 23% protein diet (C), and an energy-restricted diet group (ER). On days 4, 12 and 21, mothers were separated from their pups for 4 h, injected with (131)I IP, and put together with their pups. The animals were killed 2 h later. PR pups had a significant decrease in iodine uptake in the gastric content and duodenal mucosa on the 4th day. On the contrary, at 12 and 21 days radioiodine was increased in the gastric content and in the duodenal mucosa. ER pups had an increase in iodine uptake in the gastric content and in the duodenal mucosa only at the end of lactation. The thyroid iodine uptake in PR pups was significantly decreased on the 4th day and significantly increased on the 21st day compared to control. When injected IP with an equivalent amount of (131)I, the PR pups had a decrease in thyroid iodine uptake on the 4th and 12th day, while ER pups had no significant changes. So, these data suggest that protein restriction during lactation was associated with lower iodine secretion into the milk in the beginning of lactation. However, at the end of lactation, an adaptation process seems to occur leading to a higher transfer of iodine through the milk that compensates the impairment of thyroid iodine uptake in these pups.     

Oxidative damage following chronic aluminium exposure in adult and pup rat brains.

Aluminium is known to cause neurotoxic effects. In the past few years there has been an upsurge of interest in aluminium exposure through diet and environment, which might impair the development of mammals. The present in vivo study was designed to investigate the potential of aluminium to participate in either antioxidant or pro-oxidant processes in both developed and developing rat brain. Markers of oxidative stress were determined in rat brains exposed to AlCl3 (100 mg/kg body weight) for 8 weeks. The aluminium dose was given to adult rats for 8 weeks and in another group, exposure of aluminium for 60 days was done postnatally, 21 days to the feeding mother (lactation period) and 39 days to the rat pups. The results showed a statistically significant (p相似文献   

Effect of maternal iron deficiency on GABA shunt pathway of developing rat brain

Iron deficiency during pregnancy and lactation (35 mg iron/kg diet) produced a significant reduction in liver nonheme iron in dams as well as in fetus and young ones. The body, liver and brain weights of fetus, new-born, and developing pups remained unaffected. However, the body weight and PCV were reduced only in 21-day-old pups. The enzyme activities of GDH, GAD, GABA-transaminase, and NAD(+)-linked ICDH were reduced in 14 and 21-day-old pups. The enzyme activities of NADP(+)-linked ICDH activities remained unaffected in the fetus and developing pups brain. Maternal rehabilitation on iron sufficient diet for 1 week from day 14 to 21 of lactation period did not reverse these changes. The maternal iron deficiency during lactation period alone did not cause any alteration in all parameters assayed, however, there was a reduction in liver non-heme iron of pups on days 14 and 21.     

Cerebellar malformations in prenatally X-irradiated rats: quantitative analysis and detailed description

Pregnant WKA/Hok rats were exposed to 100 R or 200 R X-irradiation on one of gestation days 16 through 21. Offspring were killed at 60 days of age and the cerebellum was examined. The cerebellum of animals exposed to 200 R was slightly reduced in weight but not in width. The observed reduction in the dorsoventral length of the cerebellum was more evident when the X-irradiation was early in gestation. The anteroposterior length of the hemispheres increased following exposure to X-ray on days 16 through 19, and that of the vermis and paravermis decreased following treatment on days 17 through 21. Therefore, the anterior portions of hemispheres were situated anterior to the culmen in every 200 R group. Somewhat anteroposteriorly and horizontally directed lobules, as opposed to the normal transverse arrangement, were seen in the cerebellum of rats treated on day 16 or 17. Lobule contortion and fragmentation and an increased number of sublobules were striking in cases treated later. Histologically, ectopic Purkinje cells in the granule cell layer and white matter appeared following X-irradiation on day 20 or 21, but they were not found following earlier treatment. In the cerebellum of animals exposed to 100 R the reduction in size was mild and the folial abnormalities were rare, but the number of sublobules decreased.     

Leptin levels in rat offspring are modified by the ratio of linoleic to alpha-linolenic acid in the maternal diet

The supply of polyunsaturated fatty acids (PUFA) is important for optimal fetal and postnatal development. We have previously shown that leptin levels in suckling rats are reduced by maternal PUFA deficiency. In the present study, we evaluated the effect of maternal dietary intake of (n-3) and (n-6) PUFA on the leptin content in rat milk and serum leptin levels in suckling pups. For the last 10 days of gestation and throughout lactation, the rats were fed an isocaloric diet containing 7% linseed oil (n-3 diet), sunflower oil (n-6 diet), or soybean oil (n-6/n-3 diet). Body weight, body length, inguinal fat pad weight, and adipocyte size of the pups receiving the n-3 diet were significantly lower during the whole suckling period compared with n-6/n-3 fed pups. Body and fat pad weights of the n-6 fed pups were in between the other two groups at week one, but not different from the n-6/n-3 group at week 3. Feeding dams the n-3 diet resulted in decreased serum leptin levels in the suckling pups compared with pups in the n-6/n-3 group. The mean serum leptin levels of the n-6 pups were between the other two groups but not different from either group. There were no differences in the milk leptin content between the groups. These results show that the balance between the n-6 and n-3 PUFA in the maternal diet rather than amount of n-6 or n-3 PUFA per se could be important for adipose tissue growth and for maintaining adequate serum leptin levels in the offspring.