A role of the basal ganglia in the occurrence of visual hallucinations (a hypothetical mechanism)

A hypothetical mechanism of the basal ganglia involvement in visual hallucinations is proposed. According to this mechanism, hallucination is the result of modulation of the efficacy of corticostriatal synaptic inputs and changes in spiny cell activity due to the rise of striatal dopamine concentration (or due to other reasons). These changes cause an inhibition of neurons in the substantia nigra pars reticulata and subsequent disinhibition of neurons in the superior colliculus and pedunculopontine nucleus (including its cholinergic cells). In the absence of afferentation from the retina this disinhibition leads to activation of neurons in the lateral geniculate nucleus, pulvinar and other thalamic nuclei projecting to the primary and highest visual cortical areas, prefrontal cortex, and also back to the striatum. Hallucinations as conscious visual patterns are the result of selection of signals circulating in several interconnected loops each of which includes one of above mentioned neocortical areas, one of thalamic nuclei, limbic and one of visual areas of the basal ganglia, superior colliculus and/or pedunculopontine nucleus. According to our model, cannabinoids, opioids and ketamine may lead to hallucinations due to their promotional role in the LTD of cortical inputs to GABAergic spiny cells of striatal striosomes projecting to dopaminergic neurons, disinhibition of the lasts, and increase in striatal dopamine concentration.     

Modulation of ventral pallidal dopamine and glutamate release by the intravenous anesthetic propofol studied by in vivo microdialysis

Summary. The intravenous anesthetic propofol is reported to have various psychological side effects as hallucinations, sexual disinhibition, or euphoria. Hedonic and rewarding states like these are modulated by the dopaminergic system in the nucleus accumbens, prefrontal cortex and also in the ventral pallidum and by the glutamatergic system in the neocortex and limbic system. In the present study, propofol was administered either alone or in combination with the GABAA receptor antagonist bicuculline via reverse microdialysis into the ventral pallidum of freely moving rats. Dialysis fractions were taken every 20min and analyzed for dopamine and glutamate using high performance liquid chromatography. Application of propofol decreased dopamine levels in the ventral pallidum. This effect seems to be mainly mediated through GABAA receptors, since it was compensated by the GABAA receptor antagonist bicuculline. Propofol and propofol plus bicuculline exerted no effect on glutamate release in this brain region. The reduced dopamine release in ventral pallidum was most probably mediated through a GABAergic feedback loop from the ventral pallidum via the nucleus accumbens to the dopaminergic neurons of the ventral tegmental area or by long loop feedback. As an increase but not a decrease of dopamine release in the ventral pallidum is involved in hedonic and rewarding properties, similar symptoms induced by propofol seem to be unrelated to an action of propofol in the ventral pallidum.     

A role of dopamine-dependent activity reorganizations in the cortico-basal ganglia-thalamocortical loops in visual attention (hypothetical mechanism)

A mechanism of attention is proposed according to which its influence on visual processing is switched on by release of dopamine into the striatum. A dopamine release during involuntary attention is promoted by visual activation of striatonigral cells via the thalamus and subsequent disinhibition through the basal ganglia of the superior colliculus. A dopamine release during voluntary attention is promoted by activation of prefrontal cortex. The strengthening of responses of neocortical neurons to attended stimulus, and suppression of responses to other stimuli is the result of opposite modulatory action of dopamine on the efficacy of strong and weak corticostriatal inputs. This leads to changes in the output basal ganglia signals ("attentional filter") that exert disinhibitory and inhibitory influence (via the thalamus) on neocortical cells that initially were strongly and weakly activated by a stimulus, respectively. From proposed mechanism follows, that attention modulates only those components of responses of cortical neurons which latency exceeds the latency of reactions of dopaminergic cells (80-100 ms).     

Behavioral and neurophysiological evidence for a facilatory interaction between co-existing transmitters: cholecystokinin and dopamine

Cholecystokinin (CCK) and dopamine (DA) co-exist in ventral tegmental neurons which project via the mesencephalic pathway to the nucleus accumbens of the rat. CCK and DA are located in separate neurons in the substantia nigra which projects via the nigrostriatal pathway to the caudate nucleus in the rat. The functional significance of this peptide-amine co-localization was investigated using behavioral and neurophysiological techniques. CCK injected directly into the nucleus accumbens potentiated apomorphine-induced stereotypy and dopamine-induced hyperlocomotion. CCK injected directly into the caudate nucleus had no effect on apomorphine-induced stereotypy or dopamine-induced hyperlocomotion CCK injected alone into either site did not induce stereotypy or hyperlocomotion. The dose-response curve to apomorphine induction of stereotypy was shifted to the left by CCK, indicating increased sensitivity to the dopaminergic agonist. Neurophysiological analysis of the firing rate of ventral tegmental neurons demonstrated that CCK produced a left-shift in the dose-response curve of apomorphine on inhibition of neuronal firing. These data suggest that CCK acts as a modulator of dopamine, increasing neuronal responses to dopaminergic agonists. The potentiation of dopamine by CCK may be specific to the mesolimbic neurons, where CCK and DA co-exist in the rat.     

Role of the basal ganglia in the occurrence of paradoxical sleep dreams (hypothetical mechanism)

A hypothetical mechanism of the basal ganglia involvement in the occurrence of paradoxical sleep dreams and rapid eye movements is proposed. According to this mechanism, paradoxical sleep is provided by facilitation of activation of cholinergic neurons in the pedunculopontine nucleus as a result of suppression of their inhibition from the output basal ganglia nuclei. This disinhibition is promoted by activation of dopaminergic cells by pedunculopontine neurons, subsequent rise in dopamine concentration in the input basal ganglia structure. striatum, and modulation of the efficacy of cortico-striatal inputs. In the absence of signals from retina, a disinhibition of neurons in the pedunculopontine nucleus and superior colliculus allows them to excite neurons in the lateral geniculate body and other thalamic nuclei projecting to the primary and higher visual cortical areas, prefrontal cortex and back into the striatum. Dreams as visual images and "motor hallucinations" are the result of an increase in activity of definitely selected groups of thalamic and neocortical neurons. This selection is caused by modifiable action of dopamine on long-term changes in the efficacy of synaptic transmission during circulation of signals in closed interconnected loops, each of which includes one of the visual cortical areas (motor cortex), one of the thalamic nuclei, limbic and one of the visual areas (motor area) of the basal ganglia. pedunculopontine nucleus, and superior colliculus. Simultaneous modification and modulation of synapses in diverse units of neuronal loops is provided by PGO waves. Disinhibition of superioir colliculus neurons and their excitation by pedunculopontine nucleus lead to an appearance of rapid eye movements during paradoxical sleep.     

Alpha-MSH injected into the substantia nigra or intraventricularly alters behavior and the striatal dopaminergic activity

Rats were injected with 1 μg of alpha-melanocyte stimulating hormone (α-MSH) into the third ventricle and locally in the ventral tegmental area and in different regions of the substantia nigra. The modifications produced on grooming behavior and locomotion as well as on the dopamine content of the nucleus accumbens and the caudate putamen, were studied. Both intraventricular peptide administration and microinjections into the ventral tegmental area induced excessive grooming and a significant increase of the locomotor activity. The dopamine content of the nucleus accumbens and caudate putamen was markedly reduced. Injections of the peptide into the substantia nigra pars compacta failed to induce excessive grooming but did provoke a slight increase in locomotor activity and a smaller change in caudate dopamine content than that observed by injections in the ventral tegmental area or in the third ventricle. Dopamine levels in the nucleus accumbens were not changed. Finally, the injections of α-MSH into the lateral substantia nigra did not produce either biochemical or behavioral changes.The results suggests that α-MSH can modify, directly or indirectly, the striatal dopaminergic activity and that the behavioral alterations observed such as excessive grooming, could be mediated by the activation of the dopamine cells from the ventral tegmental area, that in turn may provoke a significative release of dopamine at the caudate putamen nucleus as well as in nucleus accumbens.     

Repeated exposure to methamphetamine, cocaine or morphine induces augmentation of dopamine release in rat mesocorticolimbic slice co-cultures

Repeated intermittent exposure to psychostimulants and morphine leads to progressive augmentation of its locomotor activating effects in rodents. Accumulating evidence suggests the critical involvement of the mesocorticolimbic dopaminergic neurons, which project from the ventral tegmental area to the nucleus accumbens and the medial prefrontal cortex, in the behavioral sensitization. Here, we examined the acute and chronic effects of psychostimulants and morphine on dopamine release in a reconstructed mesocorticolimbic system comprised of a rat triple organotypic slice co-culture of the ventral tegmental area, nucleus accumbens and medial prefrontal cortex regions. Tyrosine hydroxylase-positive cell bodies were localized in the ventral tegmental area, and their neurites projected to the nucleus accumbens and medial prefrontal cortex regions. Acute treatment with methamphetamine (0.1-1000 μM), cocaine (0.1-300 μM) or morphine (0.1-100 μM) for 30 min increased extracellular dopamine levels in a concentration-dependent manner, while 3,4-methylenedioxyamphetamine (0.1-1000 μM) had little effect. Following repeated exposure to methamphetamine (10 μM) for 30 min every day for 6 days, the dopamine release gradually increased during the 30-min treatment. The augmentation of dopamine release was maintained even after the withdrawal of methamphetamine for 7 days. Similar augmentation was observed by repeated exposure to cocaine (1-300 μM) or morphine (10 and 100 μM). Furthermore, methamphetamine-induced augmentation of dopamine release was prevented by an NMDA receptor antagonist, MK-801 (10 μM), and was not observed in double slice co-cultures that excluded the medial prefrontal cortex slice. These results suggest that repeated psychostimulant- or morphine-induced augmentation of dopamine release, i.e. dopaminergic sensitization, was reproduced in a rat triple organotypic slice co-cultures. In addition, the slice co-culture system revealed that the NMDA receptors and the medial prefrontal cortex play an essential role in the dopaminergic sensitization. This in vitro sensitization model provides a unique approach for studying mechanisms underlying behavioral sensitization to drugs of abuse.     

Mechanisms of effects of adenosine and dopamine on modification of synapses in striato-nigral and striato-pallidal neurons

On the basis of earlier suggested unitary mechanism of synaptic plasticity opposite effects of adenosine and dopamine on the cAMP concentration in striatal spinal cells can emphasize the well known antagonistic interactions between A2A and D2 receptors on striatopallidal cells and between A1 and D1 receptors on striatonigral cells. This is due to that both the dopamine agonist and adenosine antagonist must promote the induction of long-term potentiation/depression of efficacy of excitatory cortical inputs to striatopallidal/striatonigral cells. This modification must lead to synergistic disinhibition of thalamic cells via "direct" and "indirect" pathways through basal ganglia and subsequent strengthening of motor activity.     

Effects of Cannabinoids on Dopamine Release in the Corpus Striatum and the Nucleus Accumbens In Vitro

Cannabinoid receptors are widely distributed in the nuclei of the extrapyramidal motor and mesolimbic reward systems; their exact functions are, however, not known. The aim of the present study was to characterize the effects of cannabinoids on the electrically evoked release of endogenous dopamine in the corpus striatum and the nucleus accumbens. In rat brain slices dopamine release elicited by single electrical pulses was determined by fast cyclic voltammetry. Dopamine release was markedly inhibited by the OP2 opioid receptor agonist U-50488 and the D2/D3 dopamine receptor agonist quinpirole, indicating that our method is suitable for studying presynaptic modulation of dopamine release. In contrast, the CB1/CB2 cannabinoid receptor agonists WIN55212-2 (10(-6) M) and CP55940 (10(-6)-10(-5) M) and the CB1 cannabinoid receptor antagonist SR141716A (10(-6) M) had no effect on the electrically evoked dopamine release in the corpus striatum and the nucleus accumbens. The lack of a presynaptic effect on terminals of nigrostriatal and mesolimbic dopaminergic neurons is in accord with the anatomical distribution of cannabinoid receptors: The perikarya of these neurons in the substantia nigra and the ventral tegmental area do not synthesize mRNA, and hence protein, for CB1 and CB2 cannabinoid receptors. It is therefore unlikely that presynaptic modulation of dopamine release in the corpus striatum and the nucleus accumbens plays a role in the extrapyramidal motor and rewarding effects of cannabinoids.     

Quinolinic acid lesion of nucleus accumbens reduces D1 but not D2 dopamine receptors: an autoradiographic study

Information concerning the cellular localization of dopamine receptor subtypes in the nucleus accumbens (NAcc) was obtained using receptor autoradiographic analysis. Unilateral, stereotaxic injection of the axon-sparing neurotoxin, quinolinic acid, into the NAcc resulted in a prominent loss of dopamine D1 receptors (as labeled by [3H]SCH 23390). Contrarily, no appreciable decrement in D2 receptors (labeled by [3H]raclopride) could be identified within the same region of the NAcc. The findings support the view that accumbens D1 receptors are located postsynaptically on neurons or their processes, while D2 receptors within this nucleus are primarily located on afferent terminals.     

Positive Reinforcement Mediated by Midbrain Dopamine Neurons Requires D1 and D2 Receptor Activation in the Nucleus Accumbens

The neural basis of positive reinforcement is often studied in the laboratory using intracranial self-stimulation (ICSS), a simple behavioral model in which subjects perform an action in order to obtain exogenous stimulation of a specific brain area. Recently we showed that activation of ventral tegmental area (VTA) dopamine neurons supports ICSS behavior, consistent with proposed roles of this neural population in reinforcement learning. However, VTA dopamine neurons make connections with diverse brain regions, and the specific efferent target(s) that mediate the ability of dopamine neuron activation to support ICSS have not been definitively demonstrated. Here, we examine in transgenic rats whether dopamine neuron-specific ICSS relies on the connection between the VTA and the nucleus accumbens (NAc), a brain region also implicated in positive reinforcement. We find that optogenetic activation of dopaminergic terminals innervating the NAc is sufficient to drive ICSS, and that ICSS driven by optical activation of dopamine neuron somata in the VTA is significantly attenuated by intra-NAc injections of D1 or D2 receptor antagonists. These data demonstrate that the NAc is a critical efferent target sustaining dopamine neuron-specific ICSS, identify receptor subtypes through which dopamine acts to promote this behavior, and ultimately help to refine our understanding of the neural circuitry mediating positive reinforcement.     

The cortico-basal ganglia-thalamocortical circuit with synaptic plasticity. II. Mechanism of synergistic modulation of thalamic activity via the direct and indirect pathways through the basal ganglia

A possible mechanism underlying the modulatory role of dopamine, adenosine and acetylcholine in the modification of corticostriatal synapses, subsequent changes in signal transduction through the "direct" and "indirect" pathways in the basal ganglia and variations in thalamic and neocortical cell activity is proposed. According to this mechanism, simultaneous activation of dopamine D1/D2 receptors as well as inactivation of adenosine A1/A(2A) receptors or muscarinic M4/M1 receptors on striatonigral/striatopallidal inhibitory cells can promote the induction of long-term potentiation/depression in the efficacy of excitatory cortical inputs to these cells. Subsequently augmented inhibition of the activity of inhibitory neurons of the output nuclei of the basal ganglia through the "direct" pathway together with reduced disinhibition of these nuclei through the "indirect" pathway synergistically increase thalamic and neocortical cell firing. The proposed mechanism can underlie such well known effects as "excitatory" and "inhibitory" influence of dopamine on striatonigral and striatopallidal cells, respectively; the opposite action of dopamine and adenosine on these cells; antiparkinsonic effects of dopamine receptor agonists and adenosine or acetylcholine muscarinic receptor antagonists.     

Different Effects of Opiate Withdrawal on Dopamine Turnover,Uptake, and Release in the Striatum and Nucleus Accumbens

The purpose of these experiments was to further characterize changes in dopaminergic function that follow withdrawal from chronic opiate treatment. Withdrawal after treatment to a maximum dose of 120 mg/kg of morphine did not alter dopamine concentrations in the substantia nigra, ventral tegmental area, striatum, or nucleus accumbens; but did decrease concentrations of DOPAC and the ratio of DOPAC to dopamine in the lateral striatum and nucleus accumbens. Uptake of tritiated dopamine was diminished for withdrawn slices obtained from the striatum with no effect observed for tissue from the nucleus accumbens. Deficits of in vitro release of tritiated dopamine also occurred following withdrawal, with the nucleus accumbens being sensitive to dependence produced by a lower dose of morphine. In conclusion, opiate withdrawal produces a complex pattern of effects on dopaminergic function that is specific for the striatum and nucleus accumbens.     

Cortical Regulation of Subcortical Dopamine Release: Mediation via the Ventral Tegmental Area

Abstract: In vivo microdialysis was used to determine the extent to which ionotropic glutamate receptors in the ventral tegmental area (VTA) regulate dopamine release in the nucleus accumbens. Coapplication of 2-amino-5-phosphonopentanoic acid (AP5; 200 µ M ) and 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 50 µ M ) to the VTA via reverse dialysis decreased extracellular concentrations of dopamine in the nucleus accumbens by ∼30%. In accordance with previous results, electrical stimulation of the prefrontal cortex increased dopamine release by 60%. Application of AP5 and CNQX to the VTA during cortical stimulation blocked the effect of stimulation on dopamine release. These results indicate that ionotropic glutamate receptors in the VTA are critically involved in basal and evoked dopamine release in the nucleus accumbens and suggest that a glutamatergic projection from the prefrontal cortex regulates the activity of dopaminergic neurons in the VTA.     

Receptors in the Ventral Tegmental Area Mediating Nicotine-Induced Dopamine Release in the Nucleus Accumbens

Nicotine or cocaine, when administered intravenously, induces an increase of extracellular dopamine in the nucleus accumbens. The nicotine-mediated increase was shown to occur at least in part through increase of the activity of dopamine neurons in the ventral tegmental area. As part of our continuing studies of the mechanisms of nicotine effects in the brain, in particular, effects on reward and cognitive mechanisms, in the present study we examined the role of various receptors in the ventral tegmental area in nicotine and cocaine reward. We assayed inhibition of the increase of dopamine in the nucleus accumbens induced by intravenous nicotine or cocaine administration by antagonists administered into the ventral tegmental area. Nicotine-induced increase of accumbal dopamine release was inhibited by intrategmental nicotinic (mecamylamine), muscarinic (atropine), dopaminergic (D₁: SCH 23390, D₂: eticlopride), and NMDA glutamatergic (MK 801) and GABA_B (saclofen) antagonists, but not by AMPA-kainate (CNQX, GYKI-52466) antagonists under our experimental circumstances. The intravenous cocaine-induced increase of dopamine in the nucleus accumbens was inhibited by muscarinic (atropine), dopamine 2 (eticlopride), and GABA_B (saclofen) antagonists but not by antagonists to nicotinic (mecamylamine), dopamine D₁ (SCH 23390), glutamate (MK 801), or AMPA-kainate (CNQX, GYKI-52466) receptors. Antagonists administered in the ventral tegmental area in the present study had somewhat different effects when they were previously administered intravenously. When administered intravenously atropine did not inhibit cocaine effects. The inhibition by atropine may be indirect, since this compound, when administered intrategmentally, decreased basal dopamine levels in the accumbens. The findings indicate that a number of receptors in the ventral tegmental area mediate nicotine-induced dopamine changes in the nucleus accumbens, a major component of the nicotine reward mechanism. Some, but not all, of these receptors in the ventral tegmental area also seem to participate in the reward mechanism of cocaine. The importance of local receptors in the ventral tegmental area was further indicated by the increase in accumbal dopamine levels after intrategmental administration of nicotine or also cocaine.     

Projections of the Tsai tegmental ventral area to the hippocampus: a study of the rat using the Fink-Heimer technic

The projection from the ventral tegmental area of Tsai (VTA-A10) to the hippocampal formation was investigated in the rat by means of the Fink-Heimer technique, after VTA destruction by electrolytic lesion or local injection of 6-hydroxydopamine (6-OHDA, 1 micrograms/0.5 microliters). Degenerated fibers are prevalently present in the ventral subiculum and CA1 field. These areas match with the area projecting towards the nucleus accumbens. Thus the dopaminergic meso-cortico-limbic pathway could modulate the HF-striatal projection which represents a link between the limbic and central motor systems.     

Unique properties of mesoprefrontal neurons within a dual mesocorticolimbic dopamine system

The mesocorticolimbic dopamine system is essential for cognitive and emotive brain functions and is thus an important target in major brain diseases like schizophrenia, drug addiction, and attention deficit hyperactivity disorder. However, the cellular basis for the diversity in behavioral functions and associated dopamine-release pattern within the mesocorticolimbic system has remained unclear. Here, we report the identification of a type of dopaminergic neuron within the mesocorticolimbic dopamine system with unconventional fast-firing properties and small DAT/TH mRNA expression ratios that selectively projects to prefrontal cortex and nucleus accumbens core and medial shell as well as to basolateral amygdala. In contrast, well-described conventional slow-firing dopamine midbrain neurons only project to the lateral shell of the nucleus accumbens and the dorsolateral striatum. Among this dual dopamine midbrain system defined in this study by converging anatomical, electrophysiological, and molecular properties, mesoprefrontal dopaminergic neurons are unique, as only they do not possess functional somatodendritic Girk2-coupled dopamine D2 autoreceptors.     

The neurobiology of neurotensin: focus on neurotensin-dopamine interactions.

Neurotensin (NT) is a tridecapeptide which fulfills many of the requisite criteria for a role as a central nervous system (CNS) neurotransmitter. It is closely associated with CNS dopamine neurons and has been shown to interact with dopamine at physiological, anatomical and behavioral levels. Neurotensin is colocalized with dopaminergic neurons in the hypothalamus and midbrain. In addition, it blocks behaviors associated with activation of the dopaminergic pathways. Centrally administered NT has been shown to mimic many of the actions of antipsychotic drugs. In addition, the concentration of NT in cerebrospinal fluid is decreased in patients with schizophrenia. Administration of clinically effective antipsychotic drugs increases concentrations of NT in the caudate nucleus and nucleus accumbens. NT has been shown to play a role in signal transduction by mostly mobilizing calcium stores following inositol phosphate formation. This has been linked to subsequent events in protein phosphorylation. Lipophilic NT receptor agonists may represent a novel approach to the development of a new class of antipsychotic drugs.     

A contribution of synaptic plasticity in the basal ganglia to processing of visual information

The mechanism of involvement of the basal ganglia in processing of visual information on the basis of dopamine-dependent modulation of efficacy of synaptic transmission in interconnected parallel associative and limbic loops (cortex--basal ganglia--thalamus--cortex) is proposed. Each loop consists of one of the visual or prefrontal cortical areas connected with the thalamic nucleus and corresponding loci in different nuclei of the basal ganglia. Circulation of activity in such a loop provides reentrance of information into the thalamus and neocortex. Dopamine releasing in response to a visual stimulus oppositely modulates the efficacy of "strong" and "weak" corticostriatal inputs. Subsequent reorganization of activity in the loop leads to a disinhibition (inhibition) of activity of those cortical neurons that were "strongly" ("weakly)" excited by the visual stimulus simultaneously with activation of dopaminergic cells. A selected neuronal pattern in each cortical area represents a property of the visual stimulus processed by this area. Excitation of dopaminergic cells by the visual stimulus via the superior colliculi requires parallel activation of a disinhibitory input to the superior colliculi via the thalamus and a "direct" pathway through the basal ganglia. The prefrontal cortex excited by the visual stimulus via the mediodorsal thalamic nucleus performs a top-down control over the dopaminergic cell activity, supervising simultaneous dopamine release in different striatal loci and thus promotes the interconnected selection of neuronal representations of individual properties of the visual stimulus and their binding in an integrated image.     

A possible mechanism of dopamine-induced synergistic disinhibition of thalamic cells via "direct" and "indirect" pathways in basal ganglia

On the basis of the mechanism of synaptic plasticity that we have earlier suggested for striatal spiny neurons and with regard to the known data about the predominance of dopamine-sensitive D1/D2 receptors on the striatonigral/striatopallidal cells it is hypothesized that the induction of the long-term potentiation/depression of the efficacy of excitatory cortical inputs to these cells can underlie the excitatory/inhibitory effect of dopamine on the activity of neurons that originate the "direct"/"indirect" pathways through the basal ganglia. Both these effects will lead to an enhancement of the activity of thalamic cells and activity of the efferent neocortical neurons excited by thalamic cells. The long-term potentiation of corticostriatal inputs to striosomal neurons, where, predominantly, D1 receptors are located, can also be induced by dopamine. This effect can be responsible of a rise of inhibition of dopaminergic cells and decrease in dopamine release by these cells. Such an event sequence can provide a stable dopamine concentration in the loop neocortex-basal ganglia-thalamus-neocortex.