The effects of cocaine on cerebral metabolic function in periweanling rats: the roles of serotonergic and dopaminergic uptake blockade

Sex differences in the effects of cocaine abuse across the life span

Cocaine alters brain function from the early days of development throughout the entire life of an individual. Since the first preclinical research on cocaine sensitization was published, sex differences in response to the drug in adult rats have been noted. With the appearance of reports on "crack babies" during the 1980s, sex differences in response to prenatal (developmental) exposure have been identified in both clinical and preclinical reports. Cocaine administered during early development in the rat produces wide-spread alterations in function which depend on the timing of drug administration as well as the sex of the animal. In males, the response patterns following postnatal days (PND) 11-20 cocaine administration (equivalent to the late prenatal period in humans) are quite similar to those seen following prenatal exposure (equivalent to the first half of pregnancy in humans). There is a general decrease in dopaminergic (DA) markers and reactivity perhaps due to the uncoupling of the D1 receptor from its second messenger system. While similar changes in D1 uncoupling are seen in females, behavioral and metabolic responses to drug challenges generally show increases in DA responsivity (except adolescents) perhaps due to the activational effects of estrogen and/or decreases in serotonin (5-HT) mediated regulation of DA function. We have found that a significant factor in the hyper-responsivity of the female is the role of the testing environment and the responses to stress which can obscure underlying neurochemical dysregulation. Whether parallel factors are operational in adult males and females is currently under investigation.

Standardization of a novel blood-sampling method through the jugular vein for use in the quantified [14C] 2-deoxyglucose method

In the traditional [14C] deoxyglucose (2DG) method for the measurement of local cerebral glucose utilization (LCGU), blood samples are collected from the femoral artery. However, the placement of a femoral catheter can affect locomotor activity of the animal. We wanted to develop a new technique for blood sampling that would not interfere with the ongoing behavior. Therefore, the present report establishes a method of collecting blood samples for the 2DG method through the jugular vein. To calibrate this method, catheters were inserted in both the femoral artery and jugular vein of adult male Sprague Dawley rats. The next day, rats were injected with 2DG (125 microCi/kg) through the jugular vein. To quantify 14C in plasma, the standard method of blood collection was used for the femoral artery while syringes were used to extract blood samples from the jugular vein. We calculated the integrated specific activity of the plasma and final tissue 2DG concentrations based on Sokoloff's original equation using blood samples derived from both vessels. LCGU determined in selected brain regions was equivalent using both sampling methods. In conclusion, sampling from the jugular vein is appropriate for the quantified 2DG method and does not disrupt locomotor activity of the rat.

Cocaine in adolescent rats produces residual memory impairments that are reversible with time

Rats received injections (subcutaneous) of either 10 or 20 mg/kg cocaine on postnatal days 26-33, while lab chow-fed and pair-fed controls received saline. Spatial memory in a Morris water maze was assessed on four different occasions commencing 10 days postcocaine and ending approximately 12 months later. To determine whether there existed long-term changes in cholinergic processes, maze performance was evaluated following 1 mg/kg scopolamine challenge 4 months postcocaine. Subjects survived under standard laboratory housing conditions until they died. Results from the first assessment indicated a working memory deficit in the low-dose cocaine group and a long-term memory impairment in the high-dose cocaine group. These decrements neither were permanent nor were exacerbated by age-related processes in that cocaine-treated subjects performed at control levels on subsequent assessments. An exception to this was the results derived from the third assessment indicating that animals previously treated with 20 mg/kg cocaine were impaired when challenged with scopolamine. Examination of mortality rates revealed that cocaine-treated rats died significantly sooner than lab chow-fed control subjects. Taken together, these data indicate that cocaine during adolescence causes residual, but not permanent, deleterious effects on memory that may be mediated by alterations in cholinergic neurochemistry. More provocatively, the results showed that cocaine during adolescence shortened the lifespan of rats. This latter finding suggests that cocaine during adolescence may produce residual physiological effects that last well into adulthood.

Preweaning cocaine exposure alters brain glucose metabolic rates following repeated amphetamine administration in the adult rat

Developmental cocaine exposure produces long-term alterations in function of many neuronal circuits. This study examined glucose metabolic rates following repeated amphetamine administration in adult male and female rats pretreated with cocaine during postnatal days (PND) 11-20. PND11-20 cocaine increased the response to amphetamine in many components of the motor system and the dorsal caudate-putamen, in particular, and decreased the metabolic response in the hypothalamus. While amphetamine alone produced widespread increases in metabolism, there were no cocaine-related effects in the mesolimbic, limbic or sensory structures. These data suggest that a brief cocaine exposure during development can alter ontogeny and result in abnormal neuronal responses to repeated psychostimulant administration in adulthood.

Executive functioning in preschool-age children prenatally exposed to alcohol, cocaine, and marijuana

BACKGROUND

Reports from clinical and experimental (animal) research converge on the suggestion that prenatal exposure to alcohol, cocaine, or marijuana undermines executive functioning (EF) and its neurological underpinnings. However, large, adequately controlled, prospective studies of alcohol and marijuana effects on EF have reported conflicting findings, and there have been no such studies of cocaine exposure.

METHODS

EF was investigated in a cohort (n = 316) of 4-year-old children the majority of whose mothers had used varying combinations of cocaine, alcohol, and marijuana during pregnancy. With use of postpartum maternal report and biological assay, children were assigned to overlapping prenatal cocaine-exposed, alcohol-exposed, and marijuana-exposed groups and to complementary control groups. The postnatal environmental assessment included measures of maternal intellectual and psychosocial functioning, current drug or alcohol use, and home environment.

RESULTS

The children in the alcohol-exposed group had worse tapping-inhibition performance than children in the non-alcohol-exposed group, and this effect persisted when potential confounding environmental variables, other drug variables, and concurrent verbal intelligence were controlled for.

CONCLUSIONS

Prenatal alcohol is predictive of decreased EF in early childhood that could not be attributed to environmental factors. The results are discussed in terms of the age and overall high-risk status of the children.

Correlating brain metabolism with stereotypic and locomotor behavior

Many studies have shown that developmental cocaine exposure alters brain function and behavior, the present study examined the relationship between brain metabolism and behavioral responses to drug challenge. SKF 82958, a selective D1 dopamine agonist, was administered to preweaning cocaine-exposed (50 mg/kg/day) rats and controls at 60 days of age. Deoxyglucose was administered 30 min later, during the peak behavioral response, to measure brain functional activity. Pearsonproduct-moment correlations of behavior (locomotor activity and stereotypic behavior) with rates of glucose metabolism in components of the nigrostriatal and mesolimbic circuits were analyzed. The analysis revealed that under saline-challenge conditions in control animals, rates of metabolism in mesolimbic regions are positively correlated to rates of locomotor activity, whereas in cocaine-treated rats, these correlations were absent. Following SKF challenge, a different pattern was seen; locomotor activity or stereotypic behavior was not correlated with mesolimbic or nigrostriatal metabolism, respectively, in controls but was positively correlated in cocaine-treated rats. Therefore, cocaine exposure during development enhances the coupling of metabolism in components of the mesolimbic and nigrostriatal dopamine systems with the behavioral output associated with these systems under drug-challenge conditions. This may be due to loss of inhibitory influences within the mesolimbic and nigrostriatal systems. Thus, the correlation of behavior and cerebral glucose metabolism provides a unique way of examining the effect of developmental cocaine exposure.

Blunted metabolic response to SKF 82958 in the mesolimbic system following preweaning cocaine treatment

This study examined glucose metabolic rates following dopamine D(1) agonist challenge in adult male rats pretreated with cocaine during postnatal days 11-20. Water-pretreated control rats showed a reliable decrease in glucose metabolism of rostral mesolimbic structures when challenged with SKF 82958 while cocaine-pretreated males did not. These data support the notion that cocaine exposure during the preweaning period dampens D(1) receptor-mediated function and that the mesolimbic system exhibits a selective vulnerability to early cocaine exposure.

Executive functioning in preschool-age children prenatally exposed to alcohol, cocaine, and marijuana

BACKGROUND

Reports from clinical and experimental (animal) research converge on the suggestion that prenatal exposure to alcohol, cocaine, or marijuana undermines executive functioning (EF) and its neurological underpinnings. However, large, adequately controlled, prospective studies of alcohol and marijuana effects on EF have reported conflicting findings, and there have been no such studies of cocaine exposure.

METHODS

EF was investigated in a cohort (n = 316) of 4-year-old children the majority of whose mothers had used varying combinations of cocaine, alcohol, and marijuana during pregnancy. With use of postpartum maternal report and biological assay, children were assigned to overlapping prenatal cocaine-exposed, alcohol-exposed, and marijuana-exposed groups and to complementary control groups. The postnatal environmental assessment included measures of maternal intellectual and psychosocial functioning, current drug or alcohol use, and home environment.

RESULTS

The children in the alcohol-exposed group had worse tapping-inhibition performance than children in the non-alcohol-exposed group, and this effect persisted when potential confounding environmental variables, other drug variables, and concurrent verbal intelligence were controlled for.

CONCLUSIONS

Prenatal alcohol is predictive of decreased EF in early childhood that could not be attributed to environmental factors. The results are discussed in terms of the age and overall high-risk status of the children.

Behavioral responses to dopamine agonists in adult rats exposed to cocaine during the preweaning period

In order to determine whether developmental cocaine exposure altered the functional responses of dopamine systems, the behavioral responses to selective D1 or D2/D3 agonists were examined and compared to rats treated during the same period with a selective inhibitor of the dopamine transporter, GBR 12909. Sprague-Dawley rats were administered cocaine or GBR 12909 at 25 or 50 mg/kg/day during postnatal days (PND) 11-20. At 60+ days of age, rats were administered a challenge drug (either SKF 82958, a full D1 agonist, at 1.0 or 10 mg/kg, or quinpirole, a D2/D3 agonist, at 0.08 or 0.5 mg/kg, or saline) and subjected to 1 h of behavioral assessment. The cocaine or GBR treatments produced significant effects in three behavioral categories: distance traveled, sniffing, and rearing. For distance traveled, preweaning treatments interacted with sex since in the males, all cocaine- and GBR-treated groups showed relatively flat patterns of locomotor activity across time blocks, while in the treated females, locomotor activity typically increased across the time blocks. For other behaviors, the treatments generally produced enhanced responses to the challenge drugs. These results suggest that intermittent inhibition of the dopamine transporter with either cocaine or GBR during PND 11-20 produces long-term alterations in the functional responses of dopaminergic systems but that the neural substrates for these effects depend upon the sex of the animal.

Impairment of spatial learning following preweaning cocaine exposure in the adult rat

The present investigation focuses on learning and working memory capabilities of adult male and female Sprague-Dawley rats that were exposed to either cocaine (50 mg/kg/day sc) or distilled water during infancy (postnatal days 11-20). Learning and memory were assessed at 4 months using the eight-arm radial maze. Training was carried out in three phases in order to separate procedural learning from spatial capacity. Once criterion (entering at least seven arms without repeating arms for four out of five trials) was achieved in the first training room (Room 1), testing was moved to a second room (Room 2) with unique visual cues and an identical maze. Upon reaching criterion in Room 2, animals were returned to Room 1 and examined again. Cocaine-pretreated rats were less accurate than vehicle-pretreated rats during the first 10 trials of training. During the first five trials in Room 2 cocaine-pretreated animals made more errors, and made errors earlier within trials, than the vehicle-pretreated animals. Upon return to Room 1, reliable Gender x Pretreatment interactions were found for errors and total arms entered. These data demonstrate that a brief period of postnatal cocaine exposure can impair spatial cognition in adulthood and tentatively suggest that females are more sensitive than males.

Differential behavioral responses to chronic amphetamine in adult male and female rats exposed to postnatal cocaine treatment

The impact of cocaine exposure during development on behavioral sensitization as measured by locomotor activity and stereotypy following repeated intermittent administration of amphetamine is examined. Male and female Sprague-Dawley rats were exposed to cocaine at 50 mg/kg/day during postnatal days (PND) 11-20 and, as adults (PND193-212), were administered seven daily injections of 2.0 mg/kg amphetamine. Both locomotor activity and stereotypic behavior were assessed following the first and seventh injections. Control males and females showed sensitized behavior following repeated amphetamine injections with females showing greater locomotion while males showed increased stereotypy. Male rats pretreated with cocaine failed to develop sensitized locomotor or stereotypic responses following repeated amphetamine injections consistent with dampened D(1) receptor activity. Females pretreated with cocaine did not show a sensitized locomotor response but did display sensitization of stereotypy following repeated amphetamine administration. Thus, it appears that postnatal cocaine treatment produces differential effects on the circuits mediating sensitization behavior in male and female rats.

Long-term effects of postnatal amphetamine treatment on striatal protein kinase A activity, dopamine D(1)-like and D(2)-like binding sites, and dopamine content

The purpose of the present study was to determine whether exposure to amphetamine during the preweanling period would alter dopaminergic functioning in the dorsal striatum of adult rats. In three experiments, we assessed the effects of repeated amphetamine treatment on striatal protein kinase A (PKA) activity, dopamine (DA) D(1)-like and D(2)-like binding sites, and DA content. Rats were pretreated with saline or amphetamine (2.5 mg/kg, ip) for 7 consecutive days starting on postnatal day (PD) 11. At PD 90, rats were killed and their dorsal striata (i.e., caudate-putamen) were removed and frozen until time of assay. Amphetamine pretreatment produced long-term reductions in both striatal PKA activity and DA content. Early amphetamine exposure also resulted in an upregulation of D(2)-like binding sites, while leaving D(1)-like binding sites unaffected. It is likely that the upregulation of D(2)-like binding sites was stimulated by the persistent decline in striatal DA levels. Although speculative, it is possible that excess striatal D(2)-like receptors were responsible for inhibiting PKA activity through actions on the cAMP signal transduction pathway. The behavioral relevance of these amphetamine-induced neurochemical changes has not yet be determined.

Evaluation of neonatal exposure to cocaine on learning, activity, startle, scent marking, immobility, and plasma cocaine concentrations

Prenatal cocaine treatment produces equivocal effects on spatial learning and memory; however, no data are available on neonatal treatment as a model of human third-trimester exposure. Sprague-Dawley rats were treated on postnatal days (P) 1-10 or 11-20 with cocaine (15 mg/kg x 4 per day at 2-h intervals) or saline (P1-P20) and evaluated as adults in the Morris water maze and on tests of activity, startle, scent marking, swimming immobility, and sequential learning. Neonatal cocaine had no effect on mortality; however, early treatment reduced body weight, whereas later treatment did not. Neonatal cocaine had no effects on exploratory activity, swimming ability, sequential learning, multiday activity rhythms, scent marking, or swimming immobility, but augmented acoustic startle amplitude in the early-treated group. Neonatal cocaine also produced an interaction on spatial learning in which the cocaine early-treated males performed slightly more efficiently than controls. Plasma cocaine concentrations were significantly higher in the early-treated group than the later-treated group despite receiving the same weight-adjusted doses. It was concluded that neonatal cocaine, when administered during a stage of brain development analogous to human third trimester, induces few behavioral effects based on the assessments used in this study.

Preweaning cocaine administration alters the adult response to quipazine: comparison with fluoxetine

This study investigated whether exposure to cocaine during the preweaning period affects the behavioral response to administration of a challenge dose of quipazine, a relatively nonselective serotonin (5-HT) mixed agonist/antagonist, in adulthood. To determine whether selective inhibition of the 5-HT transporter during the preweaning period would produce a cocaine-like pattern of effects, another group of rats was given fluoxetine, a highly selective and potent inhibitor of the 5-HT transporter, and was tested along with the cocaine-treated rats. Male and female rats received 25 mg/kg cocaine HCl (82.5 mumol/kg), 25 mg/kg fluoxetine HCl (72.3 mumol/kg), or vehicle subcutaneous (s.c.) during postnatal days 11-20. Both treatments reduced weight gain during the injection period only. At 60 days of age, subjects were administered a single dose of quipazine (0, 0.4, or 1.0 mg/kg, s.c.) and placed in the Accuscan activity monitor for 1 h of behavioral recording. Overall, distance traveled, vertical activity, and time in the center of the chamber decreased during the initial time blocks of the session and vertical activity decreased with increasing doses of quipazine. Females in general showed greater overall activity levels than males as well as greater responsivity to quipazine. Preweaning cocaine exposure produced different effects in males and females. In males, cocaine enhanced the response to quipazine for vertical activity whereas it had no effect on quipazine-induced alterations on the other two behaviors. On the other hand, cocaine-treated females showed dampened dose-related quipazine responses across all behavioral measures. Fluoxetine administration produced a dampening of the quipazine effect for vertical activity and distance traveled in males and females. Therefore, these data indicate that cocaine administration during the preweaning period of development produced an increase in the effect of a serotonergic drug to alter vertical activity in males and a global dampening of the behavioral responses to that same drug in females. Preweaning fluoxetine treatment produced effects that resembled those produced by cocaine in females, a dampening of serotonergic responsivity, along with an overall decrease in locomotor activity. Because the majority of effects are seen during the initial portion of the behavioral session, a time of heightened activity in response to a novel environment, the data suggest that inhibition of the 5-HT transporter during the preweaning period alters serotonergic influences over novelty-induced activity but that brief periods of inhibition or other actions of cocaine, such as those at the catecholamine transporters, prevent this from happening, particularly in males.