Cerebral blood flow modulation by transcutaneous cranial electrical stimulation with Limoge's current.

OBJECTIVES: Transcutaneous cranial electrical stimulation (TCES) delivers a high-frequency (166 kHz) pulsed biphasic balanced current with a pulse repetition frequency of 100 Hz with 40% duty cycle through a negative electrode and two positive electrodes over the skull. TCES has a proven ability to potentiate anesthesia and analgesia, although the physiological mechanisms of this effect remain unclear. We hypothesized that the mechanism is a modulation of CBF in the central endogenous opioid system. This study aimed at determining the effects of TCES on CBF to elucidate its physiological mechanism. METHODS: Thirty-six healthy volunteers were randomly assigned to active or placebo TCES, and all assessments were double blind. TCES was performed using the Anesthelec™ device. In the stimulated group, an active cable was used, and in the control group (sham), the cable was inactive. CBF was measured by XeCT™ before and after two hours of TCES. RESULTS: Globally, CBF was unchanged by TCES. However, locally, TCES induced a significant CBF decrease in the brainstem and thalamus, which are structures involved in pain and anxiety (TCES and control CBF decrease were 18.5 and 11.9 mL/100g brain tissue/min, respectively). CONCLUSION: TCES can modulate local CBF but it has no effect on overall CBF. [Clinical Trials. gov number: NCT00273663].

Reactivity and plasticity in the amygdala nuclei during opiate withdrawal conditioning: differential expression of c-fos and arc immediate early genes.

Opiate withdrawal leads to the emergence of an aversive state that can be conditioned to a specific environment. Reactivation of these withdrawal memories has been suggested to be involved in relapse to drug-seeking of abstinent opiate addicts. Among the limbic areas that are likely to mediate these features of opiate dependence, amygdala nuclei represent critical neural substrates. Using a conditioned place aversion paradigm (CPA), we have previously shown specific opposite patterns of reactivity in the basolateral (BLA) and the central (CeA) amygdala, when comparing the experience of acute opiate withdrawal with the re-exposure to a withdrawal-paired environment. These data gave clues about the potential mechanisms by which amygdala nuclei may be involved in withdrawal memories. To extend these results, the present study aimed to assess the cellular reactivity and plasticity of amygdala nuclei during the opiate withdrawal conditioning process. For this, we have quantified c-fos and arc expression using in situ hybridization in rats, following each of the three conditioning sessions during CPA, and after re-exposure to the withdrawal-paired environment. BLA output neurons showed an increase in the expression of the plasticity-related arc gene during conditioning that was also increased by re-exposure to the withdrawal-paired environment. Interestingly, the CeA showed an opposite pattern of responding, and the intercalated cell masses (ITC), a possible inhibitory interface between the BLA and CeA, showed a persistent activation of c-fos and arc mRNA. We report here specific c-fos and arc patterns of reactivity in amygdala nuclei during withdrawal conditioning. These findings improve our understanding of the involvement of the amygdala network in the formation and retrieval of withdrawal memories. Plasticity processes within BLA output neurons during conditioning, may participate in increasing the BLA reactivity to conditioned stimuli, which could in turn (by the control of downstream nuclei) reinforce and drive the motivational properties of withdrawal over drug consumption.

Role of imidazoline receptors in the anti-aversive properties of clonidine during opiate withdrawal in rats.

Clonidine is used as a treatment for heroin addiction. Previous studies have reported that clonidine attenuated conditioned place aversion (CPA) to naloxone-precipitated opiate withdrawal by acting on alpha2 adrenoceptors (alpha2R). However, clonidine acts as a partial agonist both at alpha2R and at imidazoline-1 receptors (I1Rs). The current study was designed to determine the role of I1R in the induction of naloxone-induced CPA in morphine-dependent rats. Morphine dependence was induced by subcutaneous implantation of morphine pellets. Morphine-dependent rats were tested in a three-chamber place-aversion apparatus. A range of agonists were chosen on the basis of their differential selectivity for alpha2R and I1R. As expected, pretreatment with clonidine prevented naloxone-induced CPA. By contrast, pretreatment with a selective alpha2R agonist (UK14304) failed to prevent the CPA. We then tested whether the high affinity of clonidine for I1R was responsible for the difference between these two alpha2R agonists. Rilmenidine (a mixed alpha2R/I1R agonist) attenuated aversion to opiate withdrawal in a dose-dependent manner. The action of clonidine on I1R was studied by co-administering clonidine with RX821002, a specific alpha2R antagonist. Co-treatment with RX821002 and clonidine blocked naloxone-induced CPA. These results indicate that the pharmacologically protective effects of clonidine on naloxone-induced CPA are related to actions on I1RS as well as alpha2Rs.

A non-invasive gating device for continuous drug delivery that allows control over the timing and duration of spontaneous opiate withdrawal.

Opiate dependence in laboratory animals is commonly induced by two methods: (1) subcutaneous (s.c.) insertion of morphine pellets, and (2) daily injections of increasing doses of opiates. While both of these methods reliably induce opiate dependence, they do not allow one to discontinue, and subsequently reestablish steady state opiate plasma levels with minimal invasive procedures. We developed an "ON-OFF" gating device for repeatedly and non-invasively turning ON or OFF opiate delivery by standard osmotic minipumps. The reliability of this "device" was tested utilizing naloxone (NAL)-precipitated somatic signs of withdrawal, and body mass index (BMI) as measures of withdrawal. Rats were implanted with osmotic minipumps equipped with the gating device, containing heroin (2.66 mg per day). Three days after surgery, somatic signs of withdrawal were precipitated every 48 h by NAL (0.3mg/kg), with minipumps gated ON or OFF. For BMI, spontaneous withdrawal was repeatedly (three times) induced by turning OFF and ON the gating devices every 48 h. Body weights were measured every 4h from 06:00 to 22:00 h daily. Results show that NAL precipitated intense somatic signs of withdrawal when gating devices were ON. This effect was almost abolished when gating devices were OFF. BMI rapidly decreased after the gating devices were turned OFF with maximum weight loss occuring 12 h post-OFF position, and gradually returning to baseline values after gating devices were turned back ON. These results demonstrate the validity of the "ON-OFF" gating device for non-invasively and repeatedly inducing physical dependence to opiates over a prolonged time.

Interaction between neuropeptide FF and opioids in the ventral tegmental area in the behavioral response to novelty.

Considerable evidence has focused on the interaction between endogenous opioid peptides and the dopaminergic mesocorticolimbic system in behavioral responses to stress. Recently, it has been proposed that the CNS synthesizes and secretes neuropeptides that act as part of a homeostatic system to attenuate the effects of morphine or endogenous opioid peptides. Among these antiopioids, neuropeptide FF (NPFF) is particularly interesting since both NPFF immunoreactive-like terminals and NPFF binding sites are located in the vicinity of the dopaminergic cell bodies within the ventral tegmental area (VTA) suggesting an interaction at this level. The purpose of the present study was to evaluate the respective implication of opioid and antiopioid peptides at the level of the VTA in the locomotor response to novelty in rats. The results indicate that s.c. naloxone pretreatment, an opiate receptor antagonist, reduced locomotor activity in rats placed in a novel environment without having any effect in a familiar environment. This effect takes place in the VTA since intra-VTA administration of naloxone methobromide diminished similarly and dose-dependently the motor response to novelty. This effect is mainly dependent on opioid peptides released at VTA level since local injections of thiorphan, an inhibitor of enkephalin degradation, strongly increased locomotor response to novelty and this effect is completely prevented by the co-administration of naloxone methobromide. When injected in the VTA, NPFF is acting as an antiopioid compound, i.e. it reduces the locomotor activity triggered by exposure to novelty to the level recorded in a familiar environment. Moreover, NPFF decreased dose-dependently the potentiation of novelty-induced locomotor response produced by VTA injection of thiorphan. Taken together, these results suggest that NPFF neurons may participate at the level of the VTA to a homeostatic regulating process counteracting opioid effects induced by a mild stress such as novelty.

D-amphetamine-induced behavioral sensitization: effect of lesioning dopaminergic terminals in the medial prefrontal cortex, the amygdala and the entorhinal cortex.

The behavioral sensitization produced by the repeated administration of D-amphetamine is known to involve dopaminergic neurons in the mesoaccumbens pathway. Induction of this process is dependent on action of the drug in the ventral tegmental area while its expression involves action in the nucleus accumbens. We studied here the putative involvement of dopaminergic projections other than the mesoaccumbens in this phenomenon. We examined the influence of dopaminergic lesion of the medial prefrontal cortex, the amygdala and the entorhinal cortex in the behavioral sensitization produced by repeated injections of amphetamine either peripherally or directly into the ventral tegmental area of the brain. The repeated administration of amphetamine induced a behavioral sensitization, with the ventral tegmental area a critical site for induction of the process. This sensitization to amphetamine cross-reacted with morphine and was still observed 2 weeks after cessation of the treatment. Bilateral 6-hydroxydopamine lesion of dopaminergic terminals in either the medial prefrontal cortex or the amygdala, but not in the entorhinal cortex, prevented the development of behavioral sensitization to amphetamine and the cross-sensitization with morphine, whether the amphetamine pretreatment was administered peripherally or directly into the ventral tegmental area. In conclusion, these results indicated that behavioral sensitization to amphetamine, which involves dopaminergic neurons of the ventral tegmental area, is also dependent on dopaminergic neurotransmission of the medial prefrontal cortex and amygdala but not of the entorhinal cortex.

Behavioral expression of opiate withdrawal is altered after prefrontocortical dopamine depletion in rats: monoaminergic correlates.

The objective of this study was to establish the effects of prefrontocortical dopamine depletion on opiate withdrawal and prefrontocortical neurochemical changes elicited by morphine dependence and withdrawal. The dopaminergic content was also measured in the nucleus accumbens during withdrawal, in order to detect reactive changes induced by prefrontocortical lesion. Withdrawal was induced by naloxone in morphine-dependent rats. Monoamine levels were analyzed post-mortem by high performance liquid cromatography. The results showed that chronic morphine dependence did not modify basal levels of monoamines in sham rats, revealing neuroadaptation of prefrontocortical dopamine, noradrenaline and serotonin systems to chronic morphine. The neuroadaptive phenomenon remained after prefrontocortical lesion (> 79% dopamine depletion). On the other hand, a strong increase of dopamine, noradrenaline, and serotonin contents in the medial prefrontal cortex of sham rats was detected during opiate withdrawal. However, in lesioned rats, the increase of prefrontocortical dopamine and serotonin content, but not that of noradrenaline, was much lower. In the nucleus accumbens, prefrontocortical lesion reactively enhanced the dopaminergic tone and, although opiate withdrawal reduced dopaminergic activity in both sham and lesioned rats, this reduction was less intense in the latter group. At a behavioral level, some symptoms of physical opiate withdrawal were exacerbated in lesioned rats (writhing, mastication, teeth-chattering, global score) and exploration was reduced. The findings hence indicate that: (i) prefrontocortical monoaminergic changes play a role in the behavioral expression of opiate withdrawal; (ii) the severity of some withdrawal signs are related to the dopaminergic and serotonergic tone of the medial prefrontal cortex rather than to the noradrenergic one, and (iii) an inverse relationship between mesocortical and mesolimbic dopaminergic systems exists.

Idazoxan and 8-OH-DPAT modify the behavioral effects induced by either NA, or 5-HT, or dual NA/5-HT reuptake inhibition in the rat forced swimming test.

The rat forced swimming test (FST) predicts the efficacy of antidepressants, which decrease immobility duration in the test, and can distinguish selective serotonin (5-HT) and noradrenaline (NA) reuptake inhibitors, which, respectively, increase swimming and climbing behaviors. However, dual 5-HT and NA reuptake-inhibition produces climbing behavior solely, thereby suggesting with other data that the NA-system mediates inhibiting interactions on 5-HT-induced swimming in the FST. Since alpha(2)-adrenoreceptors and 5-HT(1A)-receptors have important regulatory functions and are involved in 5-HT/NA interactions, we examined whether the alpha(2)-receptor-antagonist idazoxan and the 5-HT(1A)-receptor-agonist 8-hydroxy-2-(di-n-propylamino)-tetralin (8-OH-DPAT) would modify the behavioral pattern induced in the FST by either selective or non-selective antidepressant treatments. The rats were treated subacutely (3 injections IP over 48 h) with: (a) idazoxan (0.5-10 mg/kg) alone, and in combination with desipramine (10 mg/kg), or desipramine + fluoxetine (10/10 mg/kg), or the dual serotonin/noradrenaline reuptake-inhibitor milnacipran (20 mg/kg). (b) 8-OH-DPAT (0.25-1 mg/kg) alone, and in combination with either desipramine (10 mg/kg) or fluoxetine (10 mg/kg). The results indicated: (a) Idazoxan (0.5, 5, 10 mg/kg) produced no anti-immobility effects per se in the FST, antagonized the effects of the NA-reuptake-inhibitor desipramine, and allowed desipramine + fluoxetine, as well as milnacipran, to increase swimming behavior. (b) 8-OH-DPAT produced non-significant effects per se, potentiated desipramine-induced antidepressant-like effects on immobility and climbing, and both antagonized swimming and produced climbing behavior in combination with fluoxetine. Our data support clinical trials suggesting that alpha(2)-receptor-antagonists and 5-HT(1A)-receptor-agonists may be of interest in augmentation strategies for antidepressant treatments. The scoring of active behaviors in the FST appears to be an interesting tool for studying 5-HT/NA interactions induced by antidepressants, as well as for the testing of augmentation strategies.

Mapping of c-fos gene expression in the brain during morphine dependence and precipitated withdrawal, and phenotypic identification of the striatal neurons involved.

The c-fos gene is expressed in the central nervous system in response to various neuronal stimuli. Using in situ hybridization, we examined the effects of chronic morphine treatment and withdrawal on c-fos mRNA in the rat brain, and particularly within identified striatal neurons. Morphine dependence was induced by subcutaneous implantation of two pellets of morphine for 6 days and withdrawal was precipitated by administration of naltrexone. Placebo animals and morphine-dependent rats showed a very weak c-fos mRNA expression in all the structures studied. Our study emphasized the spatial variations in c-fos mRNA expression, and also revealed a peak expression of c-fos mRNA at 1 h after naltrexone-precipitated withdrawal in the projection areas of dopaminergic neurons, noradrenergic neurons and in several regions expressing opiate receptors. Interestingly, morphine withdrawal induces c-fos mRNA expression in the two efferent populations of the striatum (i.e. striatonigral and striatopallidal neurons) both in the caudate putamen and nucleus accumbens. Moreover, the proportions of activated neurons during morphine withdrawal are different in the caudate putamen (mostly in striatopallidal neurons) and in the shell and core parts of the nucleus accumbens (mostly in striatonigral neurons). The activation of striatopallidal neurons suggests a predominant dopaminergic regulation on c-fos gene expression in the striatum during withdrawal. On the contrary, c-fos induction in striatonigral neurons during withdrawal seems to involve a more complex regulation like opioid-dopamine interactions via the mu opioid receptor and the D1 dopamine receptor coexpressed on this neuronal population or the implication of other neurotransmitter systems.

Naloxone-induced opiate withdrawal produces long-lasting and context-independent changes in aggressive and social behaviors of postdependent male mice.

The purpose of this study was to determine whether an environment associated with naloxone-induced morphine withdrawal affects aggressive or social behaviors in postdependent mice. Morphine-dependent or saline-treated mice received 3 naloxone injections in 1 of 2 different environments (A or B); 15 days afterward, when the mice were completely drug free, an aggression test was carried out in Environment A. All the mice suffering morphine withdrawal showed a significant increase in aggression, irrespective of the environment in which the withdrawal took place. In these conditions, the impact of morphine dependence and the 3 induced withdrawals was so profound that the environment could not be discriminative. In addition, modifications in the behavioral profile of postdependent mice that suffered only spontaneous withdrawal were long-lasting, with the mice carrying out more attacks during social investigation without presenting threat postures.

Opiate withdrawal-induced place aversion lasts for up to 16 weeks.

RATIONALE: Administration of low doses of opiate antagonists to morphine-dependent rats produces an aversive response as measured by a conditioned place aversion, but the time course of such a learned aversion is largely unknown. OBJECTIVES: The purpose of this experiment was to examine the time course for the expression of a place aversion to opiate withdrawal. METHODS: Morphine-dependent rats were tested in a three-chamber place-aversion apparatus. The conditioning phase consisted of three pairings of either naloxone (15 microg/kg s.c.) or vehicle with two compartments, with the most similar time allotments during the preconditioning test. During the testing phase, rats were again allowed to explore the entire apparatus. Different groups were tested at 24 h, 1 week, 2 weeks, 4 weeks, 8 weeks, and 16 weeks post-conditioning (morphine-free tests). RESULTS: A robust place aversion was recorded at every time point tested, including at 16 weeks. In previously published work, placebo-pelleted rats tested with naloxone at the same dose failed to show a place aversion and nondependent rats showed a stable lack of aversion at tests up to 56 days. Dependent animals without naloxone also failed to show a place aversion at any of those time points. CONCLUSIONS: In the absence of any active intervention, the place aversion produced by opiate withdrawal is very long lasting and provides a model for protracted abstinence that may be useful for delineating the neurobiological substrate for vulnerability to relapse.

Reward and somatic changes during precipitated nicotine withdrawal in rats: centrally and peripherally mediated effects.

The negative affective aspects of nicotine withdrawal have been hypothesized to contribute to tobacco dependence. In the present studies in rats, brain stimulation reward thresholds, conditioned place aversions, and somatic signs of withdrawal were used to investigate the role of central and peripheral nicotinic acetylcholine and opioid receptors in nicotine withdrawal. Rats prepared with s.c. osmotic mini-pumps delivering 9.0 mg/kg/day nicotine hydrogen tartrate or saline were administered various doses of the nicotinic antagonists mecamylamine (s.c.), chlorisondamine (s. c. or i.c.v.), dihydro-beta-erythroidine (s.c.), or the opiate antagonist naloxone (s.c.). Nicotine-treated rats receiving mecamylamine or i.c.v. chlorisondamine exhibited elevated thresholds and more somatic signs than saline-treated rats. Nicotine-treated rats receiving s.c. chlorisondamine, at doses that do not readily cross the blood-brain barrier, exhibited more somatic signs than saline-treated rats with no threshold elevations. Naloxone administration produced threshold elevations and somatic signs only at high doses that induced similar magnitude effects in both nicotine- and saline-treated subjects. Mecamylamine or dihydro-beta-erythroidine administration induced conditioned place aversions in nicotine-treated rats but required higher doses than those needed to precipitate threshold elevations. In contrast, naloxone administration induced conditioned place aversions at lower doses than those required to precipitate threshold elevations and somatic signs. These data provide evidence for a dissociation between centrally mediated elevations in reward thresholds and somatic signs that are both centrally and peripherally mediated. Furthermore, threshold elevations and somatic signs of withdrawal appear to be mediated by cholinergic neurotransmission, whereas conditioned place aversions appear to be primarily mediated by the opioid system.

D-amphetamine-induced behavioral sensitization: implication of a glutamatergic medial prefrontal cortex-ventral tegmental area innervation.

Behavioral sensitization to amphetamine is expressed as a progressive enhancement of the behavioral activating effects of the drug when repeated injections are performed as well as a long-lasting hypersensitivity to later environmental or pharmacological challenges. The mesoaccumbens dopamine system has been proposed to be the major candidate so far responsible for the induction and expression of this process, which are dependent on the action of amphetamine in the ventral tegmental area and nucleus accumbens, respectively. The development of this process has been proposed to be the result of an interaction between somatodendritically released dopamine and dopaminergic D1 receptors localized on different inputs to the ventral tegmental area, including glutamate afferents arising in part from mesocorticolimbic areas such as the medial prefrontal cortex and the amygdala. Three groups of experiments were designed to test the role of each of these components in the behavioral sensitization to amphetamine. First, the intervention of the glutamatergic transmission of the ventral tegmental area in the induction of sensitization to amphetamine was tested. The effects of an N-methyl-D-aspartate antagonist, 3-(R-2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid. on the behavioral sensitization induced by amphetamine administered repeatedly in the ventral tegmental area was tested. It was found that the blockade of N-methyl-D-aspartate receptors with 3-(R-2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid coadministered with amphetamine in the ventral tegmental area dose-dependently prevented the induction of sensitization. In a second step, the role of the structures which send glutamatergic inputs to the ventral tegmental area in the process of behavioral sensitization was tested. We evaluated the effects of ibotenic acid lesion of the medial prefrontal cortex and the amygdala on behavioral sensitization induced by peripheral or intra-ventral tegmental area administration of amphetamine. We found that ibotenic acid lesion of the medial prefrontal cortex blocked the behavioral sensitization induced by both intra-ventral tegmental area and peripheral treatment with amphetamine. In contrast, ibotenic acid lesion of the amygdala produced no effect on behavioral sensitization induced peripherally or centrally. These experiments confirmed (i) that the ventral tegmental area, where dopaminergic cell bodies are located, is a critical site for the induction of behavioral sensitization, (ii) that this process implicates the glutamatergic transmission in the ventral tegmental area, and (iii) that the medial prefrontal cortex is crucially implicated merely because of its direct glutamatergic inputs on to ventral tegmental area neurons. Together, these results reinforce the view that the behavioral sensitization to amphetamine implicates not only the mesoaccumbens dopaminergic neurons, but also other structures of the mesocorticolimbic system, such as the medial prefrontal cortex and more specifically its glutamatergic component.

Sleep impairments in rats implanted with morphine pellets.

Morphine pellets (2 x 75 mg) were subcutaneously implanted in rats and vigilance states (wakefulness, slow wave sleep and paradoxical sleep) were observed during ten days. Significant impairment of each vigilance state distribution appeared during the first days of morphine dependence. Although waking and slow wave sleep were not affected during the last days, paradoxical sleep duration was reduced during dependence. Nevertheless, the sleep-wake circadian rhythm was not abolished. These results suggest that the sleep process is affected differently in its components (slow wave sleep and paradoxical sleep) during morphine dependence.

Effects of SCH 23390, raclopride, and haloperidol on morphine withdrawal-induced aggression in male mice.

Dopamine seems to play a very important role in aggressive behavior observed in morphine withdrawal. The effect of SCH 23390 (0.5 mg/kg), raclopride (0.3 mg/kg), and haloperidol (0.1 mg/kg) on morphine withdrawal-induced aggression has been studied in this work. Mice were rendered dependent by a daily injection of morphine (2.5 mg/kg) for 14 days. Three different experiments were carried out with the objective to evaluate the antiaggressive effect of the dopamine antagonists on: first, spontaneous morphine withdrawal; second, naloxone-induced withdrawal; and third, naloxone-induced withdrawal after previous administration of the neuroleptics. Thirty minutes after injection of the dopamine antagonists, experimental animals were confronted in a neutral area with anosmic, group-housed conspecifics (standard opponents), and aggression was evaluated by estimation of times allocated to 11 different behavioral categories. Morphine withdrawal produced an increase in aggressive behavior and a decrease in social and nonsocial behaviors. The three neuroleptics counteracted this aggression, but when SCH 23390 (selective D1 antagonist) and haloperidol (mixed D1/D2 antagonist) were administered in naloxone-induced withdrawal, the effect was greater in comparison to the spontaneous withdrawal. However, no changes were observed after raclopride administration (selective D2 antagonist). In conclusion, the alterations in the dopaminergic system produced by opiate withdrawal depend on the type of withdrawal produced, and this produces a change in the antiaggressive potency of the dopamine antagonists.

Total neurochemical lesion of noradrenergic neurons of the locus ceruleus does not alter either naloxone-precipitated or spontaneous opiate withdrawal nor does it influence ability of clonidine to reverse opiate withdrawal.

It has been suggested that an increase firing rate of noradrenergic neurons of the locus ceruleus is responsible for the opiate withdrawal syndrome. However, lesion studies have indicated that the noradrenergic neurons of the locus ceruleus are not essential for either the expression or suppression by clonidine of opiate withdrawal. The present study was designed to determine the effect of the almost complete 6-hydroxydopamine lesion of noradrenergic neurons (94%) of the locus ceruleus on various components of the opiate withdrawal syndrome and on its protection by clonidine. Morphine dependence was induced by s.c. implantation of morphine pellets (2 x 75 mg base). The following paradigms were used: 1) naloxone-induced conditioned place aversion, 2) naloxone-precipitated acute opiate withdrawal syndrome, 3) nycthemeral locomotor activity as a measure of spontaneous opiate withdrawal. The results showed that quasi-total lesion of noradrenergic neurons of the locus ceruleus did not modify opiate dependence as revealed by naloxone-induced conditioned place aversion and the expression of an acute morphine withdrawal syndrome. Moreover, clonidine prevented the opiate withdrawal syndrome in both lesioned and sham-operated rats, suggesting that the action of clonidine is certainly mediated through postsynaptic alpha(2)-adrenoceptor stimulation. Finally, the nycthemeral locomotor activity during spontaneous morphine withdrawal did not differ between the lesioned and the sham-operated rats.

Chronic morphine exposure and spontaneous withdrawal are associated with modifications of dopamine receptor and neuropeptide gene expression in the rat striatum.

The influence of chronic morphine and spontaneous withdrawal on the expression of dopamine receptors and neuropeptide genes in the rat striatum was investigated. Morphine dependence was induced by subcutaneous implantation of two morphine pellets for 6 days. Rats were made abstinent by removal of the pellets 1, 2 or 3 days before they were killed. The mRNA levels coding for D1- and D2-dopamine receptors, dynorphin, preproenkephalin A and substance P were determined by quantitative in situ hybridization. The caudate putamen and the nucleus accumbens showed equivalent modifications in dopamine receptor and neuropeptide gene expression. After 6 days of morphine, a decrease in D2-dopamine receptor and neuropeptide mRNA levels was observed (-30%), but there was no change in D1-dopamine receptor mRNA. In abstinent rats, both D1- and D2-dopamine receptor mRNA levels were decreased 1 day after withdrawal (-30% compared with chronic morphine). In contrast, neuropeptide mRNA levels were unaffected when compared with those observed after 6 days of morphine. During the second and third day of withdrawal, there was a gradual return to the levels seen in the placebo-treated group, for both dopamine receptor and neuropeptide mRNAs. Phenotypical characterization of striatal neurons expressing mu and kappa opioid receptor mRNAs showed that, in striatonigral neurons, both mRNAs were colocalized with D1-receptor and Dyn mRNAs. Our results suggest that during morphine dependence, dopamine and morphine exert opposite effects on striatonigral neurons, and that effects occurring on striatopallidal neurons are under dopaminergic control. We also show that withdrawal is associated with a down regulation of the postsynaptic D1 and D2 receptors.

Transcranial electrical stimulation (Limoge's currents) potentiates the inhibition of righting reflex induced by droperidol in rats.

The effects of transcranial electrical stimulation (TCES) on droperidol-treated rats were evaluated using the righting reflex latency (RRL) test. TCES (high frequency (HF)-166 kHz, intermittent-100 Hz current) delivered through three electrodes (a negative electrode placed between the eyebrows and positive electrodes located in the retro-mastoid region) was shown to potentiate the inhibition of righting reflex induced by droperidol. This potentiation was found to depend on the dose of the drug, the characteristics of the current delivered and the duration of stimulation. We also observed that TCES-induced potentiation of inhibition of righting reflex produced by droperidol injection was not reversed: (i) after naltrexone administration, (ii) when measures were performed on p-chlorophenylalanine (pCPA)-treated animals. These results suggest that, under the experimental conditions: (i) TCES does not interact with opioid endogenous to potentiate droperidol effects, (ii) the effect of TCES on dopaminergic system prevails against TCES action on serotonergic system. Though these findings enlarge the comprehension of TCES effects on the central nervous system, further investigations are necessary to elucidate TCES mechanisms.

Amphetamine-induced conditioned activity is insensitive to perturbations known to affect pavlovian conditioned responses in rats.

Psychostimulant-induced conditioned activity is characterized by the presence of a hyperactivity in drug-free rats exposed to an environment previously paired with the effects of a psychostimulant. This phenomenon is thought to result from a Pavlovian conditioning process. This hypothesis predicts that conditioned activity will be sensitive to perturbations known to affect classical conditioned responses. In direct contrast with this prediction, the authors report here that conditioned activity is insensitive to (a) the temporal order between the stimulant injection and the exposure to the environment, (b) unsignaled stimulant injections between drug-environment pairings, and (c) drug preexposures before the start of drug-environment pairings. It is concluded that the stimulant effects responsible for the establishment of conditioned activity may not be amenable to a Pavlovian associative process.