Withdrawal from chronic, intermittent access to a highly palatable food induces depressive-like behavior in compulsive eating rats.

The increased availability of highly palatable foods is a major contributing factor toward the development of compulsive eating in obesity and eating disorders. It has been proposed that compulsive eating may develop as a form of self-medication to alleviate the negative emotional state associated with withdrawal from highly palatable foods. This study was aimed at determining whether withdrawal from chronic, intermittent access to a highly palatable food was responsible for the emergence of depressive-like behavior. For this purpose, a group of male Wistar rats was provided a regular chow diet 7 days a week (Chow/Chow), whereas a second group of rats was provided chow for 5 days a week, followed by a 2-day access to a highly palatable sucrose diet (Chow/Palatable). Following 7 weeks of diet alternation, depressive-like behavior was assessed during withdrawal from the highly palatable diet and following renewed access to it, using the forced swim test, the sucrose consumption test, and the intracranial self-stimulation threshold procedure. It was found that Chow/Palatable rats withdrawn from the highly palatable diet showed increased immobility time in the forced swim test and decreased sucrose intake in the sucrose consumption test compared with the control Chow/Chow rats. Interestingly, the increased immobility in the forced swim test was abolished by renewing access to the highly palatable diet. No changes were observed in the intracranial self-stimulation threshold procedure. These results validate the hypothesis that withdrawal from highly palatable food is responsible for the emergence of depressive-like behavior, and they also show that compulsive eating relieves the withdrawal-induced negative emotional state.

Medial forebrain stimulation enhances intracranial nociception and attenuates morphine analgesia suggesting the existence of an endogenous opioid antagonist.

The purpose of this experiment was to test in the rat the hypotheses that activation of the brain reward system would attenuate the effects of intracranial nociceptive stimulation and would potentiate the antinociceptive effects of morphine. In this experiment pain (nociception) was generated by electrical stimulation of a brain pain pathway, the mesencephalic reticular formation (MRF) of the rat. Reward pathway stimulation was to the medial forebrain bundle at the level of the lateral hypothalamus (MFB-LH). Current thresholds for escape from MRF stimulation were determined using a modification of the psychophysical methods of limits. MRF stimulation was delivered concurrently with different intensities of non-contingent MFB-LH stimulation. The effects of morphine and saline were determined under all stimulation conditions. Contrary to expectation MFB-LH stimulation significantly lowered MRF stimulation escape thresholds. Morphine administration elevated MRF thresholds in the absence of MFB-LH stimulation. However, this effect was blocked by concurrent MFB-LH stimulation. These findings, which mimic the effects of the opiate antagonist naloxone, i.e., potentiating of pain and antagonism of morphine's analgesic effects, suggest the presence of an endogenous opiate receptor antagonist.

Deep brain stimulation of the nucleus accumbens reduces ethanol consumption in rats.

Recent studies have shown that deep brain stimulation (DBS) of the nucleus accumbens (NAcc) has an inhibitory effect on drug-seeking behaviors including reinstatement responding for cocaine. The objective of the present study was to expand on these findings by assessing the effects of DBS on behaviors related to alcohol consumption. The specific aim of this study was to determine whether DBS delivered to either the shell or core of the NAcc would reduce ETOH intake in rats using a two-bottle choice limited access procedure. Long Evans rats were induced to drink a 10% ethanol solution using a saccharin fading procedure. Bipolar electrodes were implanted bilaterally into either the core or shell of the NAcc. During testing animals received DBS 5 min prior to and during a 30-minute test session in which both ETOH and water bottles were accessible. Current was delivered at amplitudes ranging from 0 to 150 microA. ETOH consumption was significantly reduced from baseline levels at the 150 microA current for both shell and core electrode placements. A significant current effect was not found for water consumption for either site. These results provide evidence that DBS delivered either to the nucleus accumbens core or shell subregions can significantly reduce ethanol intake in the rat.

Deep brain stimulation of the nucleus accumbens shell attenuates cocaine priming-induced reinstatement of drug seeking in rats.

Increasing evidence suggests that deep brain stimulation (DBS), which is currently being used as a therapy for neurological diseases, may be effective in the treatment of psychiatric disorders as well. Here, we examined the influence of DBS of the nucleus accumbens shell on cocaine priming-induced reinstatement of drug seeking, an animal model of relapse. Rats were allowed to self-administer cocaine (0.25 mg, i.v.) 2 h daily for 21 d and then cocaine-seeking behavior was extinguished by replacing cocaine with saline. During the reinstatement phase, DBS was administered bilaterally to the nucleus accumbens shell through bipolar stainless steel electrodes. Biphasic symmetrical pulses were delivered at a frequency of 160 Hz and a current intensity of 150 muA. DBS began immediately after a priming injection of cocaine (0, 5, 10, or 20 mg/kg, i.p.) and continued throughout each 2 h reinstatement session. Results indicated that only the higher doses of cocaine (10 and 20 mg/kg) produced robust and reliable reinstatement of cocaine seeking. DBS of the nucleus accumbens shell significantly attenuated the reinstatement of drug seeking precipitated by these higher cocaine doses. Additional experiments indicated that this DBS effect was both anatomically and reinforcer specific. Thus, DBS of the dorsal striatum had no influence on cocaine reinstatement and DBS of the accumbens shell did not affect the reinstatement of food seeking. Together, these results suggest that DBS of the nucleus accumbens shell may be a potential therapeutic option in the treatment of severe cocaine addiction.

Zonisamide decreases ethanol intake in rats and mice.

Several anticonvulsant agents, including topiramate and valproate, have been found to reduce alcohol consumption in rodent models of drinking. The question of whether the novel anticonvulsant agent, zonisamide, shares similar actions in either mice or rats was investigated in the present experiments. In an initial experiment, the consumption of a 10% ethanol-5% sucrose solution, available for one hour, by Wistar rats treated with lactose, topiramate, or zonisamide was determined. In a second experiment, the intake of a 10% ethanol/water solution, accessible for two hours, by C57BL/B6N mice treated with either zonisamide or vehicle was assessed. In the rat, 50 mg/kg (PO) doses of either topiramate or zonisamide produced significant, but moderate decreases in ethanol/sucrose intake. The administration of a 50 mg/kg (IP) dose of zonisamide to mice resulted in a marked lowering in ethanol consumption. These results provide evidence that zonisamide administration will decrease ethanol consumption by both mice and rats in limited access models of drinking, and might, like topiramate, be useful as a medication for alcoholism.

Effects of low dose cocaine on REM sleep in the freely moving rat.

Cocaine administration can be disruptive to sleep. In compulsive cocaine users, sleep disruption may be a factor contributing to relapse. The effects of cocaine on sleep, particularly those produced by low doses, have not been extensively studied. Low dose cocaine may stimulate brain reward systems that are linked to the liability of abusing of this drug. This study was designed to assess the effects of the acute administration of low to moderate cocaine doses on sleep in the rat. Polygraphic recordings were obtained from freely moving, chronically instrumented rats over a 6-h period after the administration of either cocaine (as a 2.5-10 mg/kg intraperitoneal dose) or saline. Following cocaine administration, time spent by the rats in wakefulness increased and slow wave sleep decreased in a dose-dependent manner, compared to controls. These changes lasted between 1 to 3 h following the cocaine administration. Rapid eye movement (REM) sleep was decreased during a 2- to 3-h period following the injection of 5 and 10 mg/kg doses of cocaine. In contrast, REM sleep increased during the periods 2-4 h after the administration of 2.5 and 5 mg/kg doses of cocaine. These results indicate that sleep can be significantly altered by low doses of cocaine when administered subacutely.

Nociceptive threshold and analgesic response to morphine in aged and young adult rats as determined by thermal radiation and intracerebral electrical stimulation.

The present experiment compared the nociceptive threshold and analgesic response to morphine in young (4-5 months) and aged (24 months) rats using peripheral thermal stimulation and intracerebral electrical stimulation. Responses to thermal stimuli were assessed using both the classical tail-flick procedure in which latency of response is the dependent variable and a new method in which threshold in calories of heat is the dependent variable. In the intracerebral nociceptive threshold procedure, electrical stimuli were delivered via an electrode implanted in the mesencephalic reticular formation (MRF), a pain pathway, and the animals were trained to terminate the stimulation by turning a cylindrical manipulandum embedded in one wall of the experimental chamber. For the classical tail-flick method, the aged rats required a greater intensity of stimulation to produce a basal response latency that was between 2.5 and 3.5 s. Using the new psychophysical method for determining the tail-flick threshold, the aged rats' basal thresholds were significantly higher than that of the young rats. However, the basal thresholds obtained by direct stimulation of the MRF failed to show a significant age effect, suggesting that the registration of pain is not different between young and aged rats. These age-related differences in baseline tail-flick response may be due to changes in the spinal reflex associated with aging. Although, there was no difference in the analgesic effects of morphine between young and aged rats using the latency of the tail-flick response, evidence for decreased analgesic response was seen using the tail-flick threshold measure and the intracerebral stimulation threshold method.

Increased sensitization to morphine-induced oral stereotypy in aged rats.

Sensitization develops to the stereotypic biting behavior that appears with the repeated administration of high dose morphine to rats. Because there is evidence that this behavior is dopamine-mediated and that there are age-related changes in dopamine systems, we compared the development and expression of morphine-induced biting behavior in aged (24 months) and young rats (5 months). Animals were treated with four sensitizing 10 mg/kg doses of morphine or saline, followed by three weekly challenges with 4 mg/kg doses of morphine or saline. By the fourth sensitizing morphine dose and after the administration of each low dose challenge, the biting time was significantly greater for aged than for young morphine pre-treated rats. After the first weekly low dose challenge, the aged but not young animals expressed more biting than when they did after the last 10 mg/kg dose. These results indicate that sensitization to morphine-induced oral stereotypy is significantly greater in aged as compared to young rats. Age-related enhanced sensitivity to morphine-induced oral stereotypy might be related to age-induced increases in vulnerability to opioid-induced insults to the basal ganglia, and may be a model for certain diseases of this pathway.

Effects of morphine on brain-stimulation reward thresholds in young and aged rats.

Mesolimbic opioid systems are altered with aging; however, the effects of these changes on the rewarding actions of opioids have not been examined. The present experiment assessed differences in the responsiveness of brain reward pathways in young and aged rats to the effects of morphine using the brain-stimulation reward (BSR) model. Aged (24 months) and young (5 months) male F344/BNF1 rats were stereotaxically implanted with a bipolar stainless steel electrode into the lateral hypothalamic (LH) region of the medial forebrain bundle. Thresholds were determined using the rate-independent psychophysical method. Each animal was tested after the administration of saline or morphine at 0.5, 1, 2.5, 5 and 10 mg/kg doses. A significant difference in the mean baseline threshold between aged (99.8+/-6 microA) and young rats (149.1+/-14 microA) was observed. Although in both groups morphine lowered the BSR threshold, there were no significant differences between the groups except at the 10-mg/kg dose, the difference did approach significance. This study indicates that there are baseline differences in the rewarding threshold in the two groups, that morphine lowers the threshold in young and aged animals and that the hedonic effects produced by morphine, for the most, part remain preserved in aged animals.

The effects of cocaine on the rate independent brain stimulation reward threshold in the mouse.

Interest in the development of mouse models of drug abuse liability has increased with the introduction of selective gene expression. In the rat, the ability of drugs to lower brain stimulation reward (BSR) thresholds often correlates with high abuse liability. Measurement of BSR thresholds using rate-independent methods decreases the influence of impaired motor performance on threshold determination that may confound studies of mutant mice. In the present experiment, the effects of cocaine on mouse BSR thresholds were assessed using a modification of the rate-independent psychophysical method of limits as current intensity was systematically varied in a series of descending and ascending discrete trials. Bipolar electrodes were implanted into the medial forebrain bundle of male C57Bl/6N mice and the effects of intraperitoneal saline and cocaine (5.0-30.0 mg/kg) on BSR thresholds were assessed using a within-subject crossover design. Threshold was defined as the intensity at which the mouse would respond in 50% of the trials. Threshold levels were significantly lowered below levels of control following cocaine administration with the maximum lowering following a 20.0-mg/kg dose. These findings indicate that cocaine increases the sensitivity of the mouse to BSR, and that BSR thresholds can be determined using rate-independent methods in this species.

Brain-stimulation reward, morphine-induced oral stereotypy, and sensitization: implications for abuse.

Early professionals believed that it was unlikely that anyone but the emotionally unstable received pleasure and became addicted to narcotic drugs. This position was well entrenched and influenced much of the thinking well into the latter half of the last century. Although the discovery of a brain reward system was made early in the 1950's it was not until 20 years later that this discovery was applied to the study of the mechanisms involved in the rewarding aspects of abused substances. Along this vein results will be shown in which opiate antagonist block the dopamine agonist activation of the brain reward system as well as the corollary. Sensitization of the reward system suggests that a driving force for drug use is 'liking' and not just 'wanting.' Basal changes in cerebral metabolic rates of glucose are seen in the presence of cues associated with morphine experience, giving evidence for the role of drug related cues in craving. Finally we asked the question 'Do old rats have as much fun as young rats?'

Effects of cue exposure on brain glucose utilization 8 days after repeated cocaine administration.

Relapse to cocaine use may involve exposure to cocaine-associated environmental cues. The present experiment tested the hypothesis that basal local cerebral metabolic rate for glucose (LCMR(glu)), as measured by the 2-deoxy-D-[l-(14)C]glucose (2-DG) autoradiography, would change in the presence of cocaine conditioned cues at 8 days after the last of seven daily cocaine injections (30 mg/kg). This dose regimen results in sensitization to the locomotor effects of cocaine. Cocaine was administered to two groups of rats while saline was administered to a third. In the conditioned group, the rats were placed into the 2-DG experimental chamber immediately after cocaine injection. Rats in the non-conditioned group were placed into their home cage after cocaine administration. A control group received only saline. The 2-DG experiment was conducted in non-drugged animals 8 days after treatment completion. The interaction between treatment status and brain region was significant. Mean basal LCMR(glu) was significantly lower in 12 brain regions in the conditioned group as compared to the control group, but was significantly lower in only four areas in the non-conditioned group. Regions in which there were significant changes in the conditioned group included the basolateral amygdala, subiculum, medial thalamus, lateral habenula and the substantia nigra pars compacta. LCMR(glu) was significantly reduced in the ventrolateral orbital cortex and rostral nucleus accumbens in both experimental groups. These findings indicate that repeated cocaine administration can cause protracted decreases in basal LCMR(glu), decreases that are more widespread in the brain during exposure to cocaine-associated cues.

Potentiation of morphine analgesia by D-amphetamine is mediated by norepinephrine and not dopamine.

Morphine will raise the threshold for escape from aversive electrical stimulation delivered to the mesencephalic reticular formation and this effect is potentiated by D-amphetamine. In order to study the roles which dopamine and norepinephrine play in modulating opiate analgesia, the effects of amfonelic acid, an indirect dopamine agonist, and nisoxetine, a selective norepinephrine reuptake blocker, were determined alone and in combination with morphine using this supraspinal model of analgesia. Amfonelic acid alone produced hyperalgesia and completely antagonized the analgesic effect of morphine. Nisoxetine had no effect by itself, however, it potentiated the analgesic effect of morphine when the two drugs were administered concomitantly. These findings suggest that norepinephrine and not dopamine plays a predominant role in the potentiation of opiate analgesia by D-amphetamine.