Activity of dopamine-containing substantia nigra neurons in freely moving cats

[Diagnostic criteria for prolonged and chronic disturbances of consciousness after aneurysmal subarachnoid hemorrhages]

BACKGROUND

In recent years, prolonged states of impaired consciousness became widespread among patients with aneurysmal subarachnoid hemorrhage. Treatment and maintenance of vital functions in such patients represent a complex medical, economic and social problem. In this regard, searching for the causes of prolonged states of impaired consciousness and predicting the outcomes are important.

OBJECTIVE

To analyze available literature data on prevention and treatment of prolonged states of impaired consciousness after aneurysmal subarachnoid hemorrhage.

RESULTS

We reviewed the PubMed database using the keywords «unresponsive wakefulness syndrome», «persistent vegetative state2, «minimal consciousness state» and «outcome of subarachnoid hemorrhage». Only 4 reports devoted to the causes and treatment outcomes in patients with prolonged impairment of consciousness after aneurysmal subarachnoid hemorrhage were found. At the same time, patients with aneurysmal subarachnoid hemorrhage comprise up to 11% among all cases of prolonged states of impaired consciousness. Examination, management and treatment of patients with prolonged impairment of consciousness after aneurysmal subarachnoid hemorrhage are carried out according to general principles without taking into account specific etiological and pathogenetic factors.

CONCLUSION

Increased number of patients with prolonged impairment of consciousness after aneurysmal subarachnoid hemorrhage necessitates analysis of etiopathogenesis and outcomes of these disorders based on modern clinical, instrumental and laboratory assessment of the brain.

Circadian and Homeostatic Modulation of Multi-Unit Activity in Midbrain Dopaminergic Structures

Although the link between sleep disturbances and dopamine (DA)-related neurological and neuropsychiatric disorders is well established, the impact of sleep alterations on neuronal activity of midbrain DA-ergic structures is currently unknown. Here, using wildtype C57Bl mice, we investigated the circadian- and sleep-related modulation of electrical neuronal activity in midbrain ventral-tegmental-area (VTA) and substantia nigra (SN). We found no significant circadian modulation of activity in SN while VTA displayed a low amplitude but significant circadian modulation with increased firing rates during the active phase. Combining neural activity recordings with electroencephalogram (EEG) recordings revealed a strong vigilance state dependent modulation of neuronal activity with increased activity during wakefulness and rapid eye movement sleep relative to non-rapid eye movement sleep in both SN and VTA. Six-hours of sleep deprivation induced a significant depression of neuronal activity in both areas. Surprisingly, these alterations lasted for up to 48 hours and persisted even after the normalization of cortical EEG waves. Our results show that sleep and sleep disturbances significantly affect neuronal activity in midbrain DA structures. We propose that these changes in neuronal activity underlie the well-known relationship between sleep alterations and several disorders involving dysfunction of the DA circuitry such as addiction and depression.

Evaluation of Neurotransmitter Alterations in Four Distinct Brain Regions After Rapid Eye Movement Sleep Deprivation (REMSD) Induced Mania-Like Behaviour in Swiss Albino Mice

A number of neurotransmitter systems have been implicated in contributing to the pathology of mood disorders, including those of dopamine (DA), serotonin (5-HT), norepinephrine (NE) and γ-aminobutyric acid (GABA). Rapid eye movement sleep deprivation (REMSD) alters most of the neurotransmitters, which may have adverse behavioural changes and other health consequences like mania and other psychiatric disorders. The exact role of REMSD altered neurotransmitter levels and the manner in which emerging consequences lead to mania-like behaviour is poorly understood. Thus, we sought to verify the levels of neurotransmitter changes after 48, 72 and 96 h of REMSD induced mania-like behaviour in mice. We performed modified multiple platform (MMP) method of depriving the REM sleep and one group maintained as a control. To measure the hyperactivity through locomotion, exploration and behavioural despair, we performed the Open Field Test (OFT) and the Forced Swim Test (FST). Quantitative determinations of DA, 5-HT, NE and GABA concentrations in four distinct brain regions (cerebral cortex, hippocampus, midbrain, and pons) were determined by the spectrofluorimetric method. These experiments showed higher locomotion and increased swimming, struggling/climbing and decreased mobility among REMSD animals as well as disrupted concentrations of the majority of the studied neurotransmitters during REMSD. Our study indicated that REMSD results in mania-like behaviour in mice and associated disruption to neurotransmitter levels, although the exact mechanisms by which these take place remain to be determined.

Stress and sleep disorder

The purpose of this study was to review potential, physiological, hormonal and neuronal mechanisms that may mediate the sleep changes. This paper investigates the literatures regarding the activity of the hypothalamic-pituitary-adrenal (HPA) axis, one of the main neuroendocrine stress systems during sleep in order to identify relations between stress and sleep disorder and the treatment of stress-induced insomnia. Sleep and wakefulness are regulated by the aminergic, cholinergic brainstem and hypothalamic systems. Activation of the HPA and/or the sympathetic nervous systems results in wakefulness and these hormones including corticotropin-releasing hormone (CRH), adrenocorticotropic hormone (ACTH), cortisol or corticosterone, noradrenaline, and adrenaline, are associated with attention and arousal. Stress-related insomnia leads to a vicious circle by activating the HPA system. An awareness of the close interaction between sleep and stress systems is emerging and the hypothalamus is now recognized as a key center for sleep regulation, with hypothalamic neurontransmitter systems providing the framework for therapeutic advances. An updated understanding of these systems may allow researchers to elucidate neural mechanisms of sleep disorder and to develop effective intervention for sleep disorder.

Neurons in both pallidal segments change their firing properties similarly prior to closure of the eyes

Current anatomical models of the cortico-basal ganglia (BG) network predict reciprocal discharge patterns between the external and internal segments of the globus pallidus (GPe and GPi, respectively), as well as cortical driving of BG activity. However, physiological studies revealing similarity in the transient responses of GPe and GPi neurons cast doubts on these predictions. Here, we studied the discharge properties of GPe, GPi, and primary motor cortex neurons of two monkeys in two distinct states: when eyes are open versus when they are closed. Both pallidal populations exhibited decreased discharge rates in the "eye closed" state accompanied by elevated values of the coefficient of variation (CV) of their interspike interval (ISI) distributions. The pallidal modulations in discharge patterns were partially attributable to larger fractions of longer ISIs in the "eye closed" state. In addition, the pallidal discharge modulations were gradual, starting prior to closing of the eyes. Cortical neurons, as opposed to pallidal neurons, increased their discharge rates steeply on closure of the eyes. Surprisingly, the cortical rate modulations occurred after pallidal modulations. However, as in the pallidum, the CV values of cortical ISI distributions increased in the "eye closed" state, indicating a more bursty discharge pattern in that state. Thus changes in GPe and GPi discharge properties were positively correlated, suggesting that the subthalamic nucleus and/or the striatum constitute the main common driving force for both pallidal segments. Furthermore, the early, unexpected changes in the pallidum are better explained by a subcortical rather than a cortical loop through the BG.

Sensory effects of intravenous cocaine on dopamine and non-dopamine ventral tegmental area neurons

Intravenous (iv) cocaine mimics salient somato-sensory stimuli in their ability to induce rapid physiological effects, which appear to involve its action on peripherally located neural elements and fast neural transmission via somato-sensory pathways. To further clarify this mechanism, single-unit recording with fine glass electrodes was used in awake rats to examine responses of ventral tegmental area (VTA) neurons, both presumed dopamine (DA) and non-DA, to iv cocaine and tail-press, a typical somato-sensory stimulus. To exclude the contribution of DA mechanisms to the observed neuronal responses to sensory stimuli and cocaine, recordings were conducted during full DA receptor blockade (SCH23390+eticloptide). Iv cocaine (0.25 mg/kg delivered over 10 s) induced significant excitations of approximately 63% of long-spike (presumed DA) and approximately 70% of short-spike (presumed non-DA) VTA neurons. In both subgroups, neuronal excitations occurred with short latencies (4-8 s), peaked at 10-20 s (30-40% increase over baseline) and disappeared at 30-40 s after the injection onset. Most long-(67%) and short-spike (89%) VTA neurons also showed phasic responses to tail-press (5-s). All responsive long-spike cells were excited by tail-press; excitations were very rapid (peak at 1 s) and strong (100% rate increase over baseline) but brief (2-3 s). In contrast, both excitations (60%) and inhibitions (29%) were seen in short-spike cells. These responses were also rapid and transient, but excitations of short-spike units were more prolonged and sustained (10-15 s) than in long-spike cells. These data suggest that in awake animals iv cocaine, like somato-sensory stimuli, rapidly and transiently excites VTA neurons of different subtypes. Therefore, along with direct action on specific brain substrates, central effects of cocaine may occur, via an indirect mechanism, involving peripheral neural elements, visceral sensory nerves and rapid neural transmission. Via this mechanism, cocaine, like somato-sensory stimuli, can rapidly activate DA neurons and induce phasic DA release, creating the conditions for DA accumulation by a later occurring and prolonged direct inhibiting action on DA uptake. By providing a rapid neural signal and triggering transient neural activation, such a peripherally driven action might play a crucial role in the sensory effects of cocaine, thus contributing to learning and development of drug-taking behavior.

Naltrexone reduces the relative reinforcing value of nicotine in a cigarette smoking choice paradigm

RATIONALE

Human behavioral pharmacology studies can examine how medications that target different neurotransmitter systems influence different aspects of smoking. Naltrexone and bupropion have been shown to alter ad lib smoking behavior; however, medication effects on nicotine reward in a cigarette choice paradigm have yet to be investigated.

OBJECTIVE

This study explored the effects of an acute dose of naltrexone, bupropion, or placebo on the relative reinforcing value of nicotine from cigarette smoking using new nicotine and de-nicotinized (Quest, 0.6 and 0.05 mg = "denicotinized") cigarettes.

METHODS

In a double-blind, within-subjects design, 26 dependent smokers participated in three experimental cigarette smoking sessions following pretreatment with either naltrexone (50 mg), bupropion (300 mg), or placebo. After medication administration and 2 h of monitored deprivation from cigarettes and food, participants rated their responses to the initial exposure to the cigarettes and then participated in four choice sessions over a 2-h period during which they could take four puffs from either cigarette.

RESULTS

The relative reinforcing value of nicotine, as measured by the number of nicotine puffs chosen out of 16, was significantly lower following naltrexone compared to placebo. There were no effects of an acute dose of bupropion on nicotine choices.

CONCLUSIONS

These results suggest that naltrexone may reduce the relative reinforcing effects of nicotine via cigarette smoking and support ongoing investigation of opioid antagonists as potential smoking cessation pharmacotherapies.

Brain temperature fluctuations during passive vs. active cocaine administration: clues for understanding the pharmacological determination of drug-taking behavior

While it is generally assumed that cocaine self-administration (SA) is determined and maintained by the pharmacological actions of cocaine in the brain, it is also a drug-motivated and drug-reinforced goal-directed behavior, which is determined by concurrent learning and behavioral performance. To dissociate the contributions of pharmacological and behavioral factors to cocaine SA, it is important to compare cocaine SA with its pharmacological copy, passive intravenous (iv) cocaine administration. This approach was employed in the present study with respect to brain temperatures, a dynamic parameter that reflects metabolic neural activity and shows consistent fluctuations during cocaine SA. Passive cocaine injections performed with the same dose/pattern as SA induced brain temperature fluctuations similar in many ways to those in behaving animals. The initial passive drug administration of a session elevated brain temperature, while subsequent repeated injections were associated with biphasic temperature fluctuations that maintained at a relatively stable plateau. Although the magnitude of these fluctuations was twofold smaller than in behaving animals, passive animals had the same pattern; brain temperatures transiently decreased after cocaine injection, then increased, and were inhibited again by the next cocaine infusion. In contrast to self-administering animals, rats exposed to passive cocaine injections had significantly lower basal temperatures and never showed gradual temperature increases preceding the initial injection. Striking differences in brain temperature dynamics seen in the beginning of a session suggest that during the development of drug-taking behavior the initial cocaine-induced neural activation becomes transformed into behavior-related "anticipatory" neural activation (motivational arousal) that fuels drug seeking and results in the initial drug intake. While this activation is triggered by drug-related cues and enhanced by the initial cocaine intake, subsequent highly cyclical cocaine intakes appear to be primarily pharmacologically determined.

Ethanol withdrawal reduces the number of spontaneously active ventral tegmental area dopamine neurons in conscious animals

Withdrawal from chronic ethanol treatment leads to a reduction in the electrical activity in dopamine (DA) neurons in the ventral tegmental area (VTA). However, there is disagreement on how the electrical activity is reduced (i.e., in the number of spontaneously active DA neurons or their firing rates and burst firing activity) and on the underlying mechanisms. The use of general anesthesia has been suggested to cause this discrepancy. In the present study, we demonstrate that ethanol withdrawal, in conscious animals, causes a reduction in the number of spontaneously active VTA DA neurons, but not in their firing rate or burst firing activity. Similar results were obtained in a previous study using anesthetized preparation, showing that general anesthesia does not cause this difference. Ethanol withdrawal-induced reduction in a number of spontaneously active VTA DA neurons could be mediated by depolarization inactivation because this effect was reversed by systemic administration of amphetamine, which inhibits VTA DA neurons by hyperpolarization. In addition, the withdrawal effect was normalized by acute ethanol administration, suggesting that the decrease in the number of spontaneously active VTA DA neurons represents an adaptational change to chronic ethanol treatment. Because the electrical activity of DA neurons controls the release of DA, it is possible that the decreased DA release during ethanol withdrawal observed in previous studies is caused by the reduction in the electrical activity of VTA DA neurons.

Dopamine in the nucleus accumbens: cellular actions, drug- and behavior-associated fluctuations, and a possible role in an organism's adaptive activity

This review expounds the idea that the analysis of dopamine (DA) action on target cells under behaviorally relevant conditions and behavior-related changes in DA activity can offer new information to clarify the functional significance of mesocorticolimbic DA. In contrast to the traditional association of DA with certain behavioral processes and mechanisms (activation, arousal, conditioning, motivation, reinforcement, sensorimotor integration, etc.), evaluation of DA activity during well-controlled behaviors established by different reinforcers can provide important clues for determining the role of DA in the development and regulation of goal-directed behavior. This review summarizes the results of our microiontophoretic studies of striatal neurons in awake, unrestrained rats, particularly the action of DA on spontaneously active and glutamate (GLU)-stimulated cells, the pattern of DA-GLU interaction, and the role of tonic DA release in regulating the activity and afferent responsiveness of these units. We present the results of our iontophoretic studies of ventral tegmental area (VTA) neurons in freely moving animals suggesting the complexity and limitations in their identification as DA- and non-DA cells under behaviorally relevant conditions. We also consider technical and methodological problems related to electrophysiological and electrochemical evaluation of DA transmission in behaving animals. Finally, we discuss parallels and differences in the activity of presumed DA VTA neurons and changes of nucleus accumbens DA-dependent electrochemical signal during heroin self-administration (SA) behavior.

Firing modes of midbrain dopamine cells in the freely moving rat

There is a large body of data on the firing properties of dopamine cells in anaesthetised rats or rat brain slices. However, the extent to which these data relate to more natural conditions is uncertain, as there is little quantitative information available on the firing properties of these cells in freely moving rats. We examined this by recording from the midbrain dopamine cell fields using chronically implanted microwire electrodes. (1) In most cases, slowly firing cells with broad action potentials were profoundly inhibited by the dopamine agonist apomorphine, consistent with previously accepted criteria. However, a small group of cells was found that were difficult to classify because of ambiguous combinations of properties. (2) Presumed dopamine cells could be divided into low and high bursting (>40% of their spikes in bursts) groups, with the majority having low bursting rates. The distribution of burst incidence was similar to that previously reported with chloral hydrate anaesthesia, but the average intraburst frequency was higher in the conscious animal at rest and was higher again in bursts triggered by salient stimuli. (3) There was no evidence for spike frequency adaptation within bursts on average, consistent with the hypothesis that afterhyperpolarisation currents may be disabled during behaviourally induced bursting. (4) Presumed dopamine cells responded to reward-related stimuli with increased bursting rates and significantly higher intraburst frequencies compared to bursts emitted outside task context, indicating that modulation of afferent activity might not only trigger bursting, but may also regulate burst intensity. (5) In addition to the irregular single spike and bursting modes we found that extremely regular (clock-like) firing, previously only described for dopamine cells in reduced preparations, can also be expressed in the freely moving animal. (6) Cross-correlation analysis of activity recorded from simultaneously recorded neurones revealed coordinated activity in a quarter of dopamine cell pairs consistent with at least "functional" connectivity. On the other hand, most dopamine cell pairs showed no correlation, leaving open the possibility of functional sub-groupings within the dopamine cell fields. Taken together, the data suggest that the basic firing modes described for dopamine cells in reduced or anaesthetised preparations do reflect natural patterns of activity for these neurones, but also that the details of this activity are dependent upon modulation of afferent inputs by behavioural stimuli.

Afferents to the ventrolateral preoptic nucleus

Sleep is influenced by diverse factors such as circadian time, affective states, ambient temperature, pain, etc., but pathways mediating these influences are unknown. To identify pathways that may influence sleep, we examined afferents to the ventrolateral preoptic nucleus (VLPO), an area critically implicated in promoting sleep. Injections of the retrograde tracer cholera toxin B subunit (CTB) into the VLPO produced modest numbers of CTB-labeled monoaminergic neurons in the tuberomammillary nucleus, raphe nuclei, and ventrolateral medulla, as well as a few neurons in the locus coeruleus. Immunohistochemistry for monoaminergic markers showed dense innervation of the VLPO by histaminergic, noradrenergic, and serotonergic fibers. Along with previous findings, these results suggest that the VLPO and monoaminergic nuclei may be reciprocally connected. Retrograde and anterograde tracing showed moderate or heavy inputs to the VLPO from hypothalamic regions including the median preoptic nucleus, lateral hypothalamic area, and dorsomedial hypothalamic nucleus (DMH), autonomic regions including the infralimbic cortex and parabrachial nucleus, and limbic regions including the lateral septal nucleus and ventral subiculum. Light to moderate inputs arose from orexin and melanin concentrating hormone neurons, but cholinergic or dopaminergic inputs were extremely sparse. Suprachiasmatic nucleus (SCN) projections to the VLPO were sparse, but the heavy input to the VLPO from the DMH, which receives direct and indirect SCN inputs, could provide an alternate pathway regulating the circadian timing of sleep. These robust pathways suggest candidate mechanisms by which sleep may be influenced by brain systems regulating arousal, autonomic, limbic, and circadian functions.

Impulse activity of ventral tegmental area neurons during heroin self-administration in rats

To assess the pattern of mesocorticolimbic dopamine activity associated with drug-seeking and drug-taking behavior, we recorded impulse activity of ventral tegmental area neurons during intravenous heroin self-administration in trained rats. Although these neurons had considerable variability, two major groups-units with triphasic long-duration spikes and biphasic short-duration spikes-were identified. Relative to a slow and irregular basal activity of long-spike units, the first self-administration of each session was preceded by a phasic neuronal activation and followed by a more sustained drug-induced activation that reached a maximum at the time of the second self-injection. After each subsequent heroin self-injection, the discharge rate transiently decreased, correlating with the blockade of preceding motor activation and the appearance of freezing, but slowly and gradually increased again in parallel with searching behavior, reaching a maximum at the time of the next self-injection. Passive drug injections in either drug-naive, freely moving or drug-experienced, anesthetized rats caused much smaller, tonic increases in activity of long-spike units; these monophasic increases changed into biphasic responses with repeated injections. Although short-spike units had highly varying discharge rate and showed phasic activation during movement, during heroin self-injections they generally mimicked the activity pattern seen in long-spike units. Our results indicate that in behaving animals indirect "identification" of dopamine cells based on their distinctive electrophysiological features is more complex than in vitro and in anesthetized preparations. With respect to long-spike units, a candidate group of presumed dopamine neurons, our data agree with the view that mesocorticolimbic dopamine activation is important for the activational and/or motivational aspects of heroin-taking behavior and suggest the role of an abrupt termination of dopamine activation for drug reinforcement (reward). Although the neurochemical nature of long- and short-spike units is obviously different, similar changes in their activity may indicate that they are regulated by similar afferent inputs and that these inputs change similarly during drug-taking behavior.

Neuromodulation of the prefrontal cortex during sleep: a microdialysis study in rats

To test the hypothesis that biogenic amines of the prefrontal cortex are involved in state-dependent cortical and behavioural activation, changes in extracellular levels of serotonin (5-HT), dopamine (DA), and noradrenaline (NA) were determined during the sleep-wake cycle in freely moving rats using microdialysis probes with parallel EEG recording. Serotonin gradually increased up to 450% during wakefulness (W) as compared to slow wave sleep (SWS), before decreasing toward stable levels during the next episode of SWS. Dopamine and its metabolite homovanillic acid (HVA) were reduced during W as compared to SWS. Although contradictory with the generally admitted enhancement of DA activity related to vigilance, this may be due to the particular role of DA neurons in the prefrontal cortex. However, DA and HVA showed dramatic changes announcing the transition between SWS and W. During paradoxical sleep (PS), DA and 5-HT showed complex changes, the direction of which depended on whether PS was followed by SWS or W. Biogenic amines of the prefrontal cortex are probably involved in cortical and behavioural activation.

Medial prefrontal cortical output neurons to the ventral tegmental area (VTA) and their responses to burst-patterned stimulation of the VTA: neuroanatomical and in vivo electrophysiological analyses

During a delayed period in a delayed-response task, prefrontal cortical neurons show a change in neuronal firing rate that is dependent on a functional mesocortical dopamine input. This change in firing rate has been attributed to be part of the cellular processes underlying working memory. However, it is unclear what neural mechanisms activate mesocortical dopamine neurons to provide an optimal level of dopamine to modulate the firing of the medial prefrontal cortical (mPFC) neurons. This study examined the possibility of whether mPFC neurons that project to the ventral tegmental area (VTA) might activate the ascending mesocortical dopamine neurons. To determine the locations of the mPFC-->VTA neurons, cholera toxin subunit B was microinjected into the VTA. Retrogradely labeled mPFC neurons mainly reside in the deep lamina V and VI. In vivo single unit recording in urethane-anesthetized rats were also used to determine the responses of some of these neurons to burst-patterned stimulation of the VTA. Single-pulse stimulation (1 Hz) of the VTA antidromically activated burst firing mPFC-->VTA neurons. In response to burst-patterned stimulation of the VTA, which mimicked burst firing of VTA dopamine neurons (4-10 pulses at 10-15 Hz cycled at 0.5-3 Hz), the temporal structure of spontaneous burst firing patterns of these neurons but not their mean firing rate were changed. However, the mean firing rate of the non-VTA projecting neurons (i.e., no antidromic response to VTA stimulations) was either increased or decreased by similar burst-patterned stimulation of the VTA. These data suggest that burst-patterned stimulation of the ascending VTA-->mPFC or putative mesocortical dopamine neurons might have released dopamine and/or other neuromodulators to modulate the temporal code, rather than the rate code, of mPFC-->VTA neurons. Medial PFC neurons that project elsewhere (e.g., nucleus accumbens or mediodorsal thalamus) may mediate the sustained firing rate changes during, e.g., short-term working memory.

Striatal neuronal activity and responsiveness to dopamine and glutamate after selective blockade of D1 and D2 dopamine receptors in freely moving rats

Although striatal neurons receive continuous dopamine (DA) input, little information is available on the role of such input in regulating normal striatal functions. To clarify this issue, we assessed how systemic administration of selective D1 and D2 receptor blockers or their combination alters striatal neuronal processing in freely moving rats. Single-unit recording was combined with iontophoresis to monitor basal impulse activity of dorsal and ventral striatal neurons and their responses to glutamate (GLU), a major source of excitatory striatal drive, and DA. SCH-23390 (0.2 mg/kg), a D1 antagonist, strongly elevated basal activity and attenuated neuronal responses to DA compared with control conditions, but GLU-induced excitations were enhanced relative to control as indicated by a reduction in response threshold, an increase in response magnitude, and a more frequent appearance of apparent depolarization inactivation. In contrast, the D2 antagonist eticlopride (0.2 mg/kg) had a weak depressing effect on basal activity and was completely ineffective in blocking the neuronal response to DA. Although eticlopride reduced the magnitude of the GLU response, the response threshold was lower, and depolarization inactivation occurred more often relative to control. The combined administration of these drugs resembled the effects of SCH-23390, but whereas the change in basal activity and the GLU response was weaker, the DA blocking effect was stronger than SCH-23390 alone. Our data support evidence for DA as a modulator of striatal function and suggest that under behaviorally relevant conditions tonically released DA acts mainly via D1 receptors to provide a continuous inhibiting or restraining effect on both basal activity and responsiveness of striatal neurons to GLU-mediated excitatory input.

Functional significance of mesolimbic dopamine

Although a large body of neuropharmacological evidence suggests that the mesolimbic dopamine system (ML DA) is critical for goal-directed behaviors, exactly which aspects of behavior are mediated or modulated by this system remains a matter of conjecture. By measuring changes in DA cell firing patterns and extracellular DA concentrations in target areas of ML DA cells during the development and performance of goal-directed behavior, it is possible to directly examine the relationship between ML DA transmission and various stages and components of behavior. This permits tests of hypotheses concerned with the functional significance of ML DA. This review will discuss recent electrophysiological, microdialysis and electrochemical data on behavior-associated changes in firing activity of ML DA cells and fluctuations in DA concentrations in target areas of these cells. Although application of an electrochemical technique to study behavior-associated changes in DA transmission is an area of hot debates, a close correlation between DA-dependent electrochemical signal changes and separate behavioral components, with a generally similar pattern of rapid signal fluctuations found in trained animals during operant lever-pressing behavior maintained by palatable food, cocaine or heroin, suggests that extrasynaptic DA may have some important functions in regulating behavior. This review will discuss possible mechanisms underlying phasic and tonic changes in ML DA transmission accompanying development and performance of positively-reinforced behavior, the contribution of learning, behavioral and pharmacological variables in the mediation of these changes, and their relevance for the organization and regulation of goal-directed behavior.

Multiunit activity from the A9 and A10 areas in rats following chronic treatment with different neuroleptic drugs

Effects of repeated twice daily i.p. administration of haloperidol (0.5 mg/kg), clozapine (3.0 mg/kg) and prothipendyl (1.0 mg/kg) on spontaneous A9 and A10 cell activity were studied using extracellular multiunit recording in rats, which offers relatively rapid access to neural activity in a large number of cells. Two cell types were identified, which probably represent the putative dopaminergic and non-dopaminergic neurons. Repeated neuroleptic treatment reduced the number of spontaneously active type 1 A10 cells per track. The effect of haloperidol was more pronounced than that of clozapine or prothipendyl. A9 cells were affected by haloperidol only. The frequency and amplitude of A9 and A10 active cells remained quite stable, except for a clozapine-induced increase of their values for type 1 A10 cells. Stability of spontaneously active type 1 A10 cells was significantly reduced by the chronic neuroleptic treatment. Collectively the activity of type 2 cells was not altered. Prothipendyl was classified as an atypical neuroleptic drug with potency comparable to clozapine.

Enhanced locomotor reactivity to apomorphine following repeated cocaine treatment

To study the involvement of postsynaptic dopamine (DA) receptors in cocaine-induced behavioral sensitization, locomotor responses to apomorphine (APO, 360 micrograms/kg, IP), a direct DA agonist, were compared in rats repeatedly treated with cocaine (15 mg/kg, IP x 5 and one challenge injection 4 days later) and saline under different environmental conditions. When cocaine was injected under activated conditions, immediately before animal placement in activity chamber, more powerful locomotor response to the initial drug and a significant effect of repeated treatment (sensitization) were found compared to drug administration under quiet conditions, 2 h after animal placement in activity chamber. In this case, locomotor response to the initial drug was similar to that of saline, and the effect of repeated injections on locomotion was absent (no sensitization). Locomotor stimulation induced by APO was significantly enhanced in both groups of cocaine-treated animals compared to saline controls. This effect, however, was more powerful in animals treated with cocaine under activated conditions. Present data suggest that enhanced responsiveness of postsynaptic DA receptors developed due to chronic cocaine treatment may contribute to stable alteration of DA transmission thought to mediate cocaine sensitization.

Cocaine enhances the changes in extracellular dopamine in nucleus accumbens associated with reinforcing stimuli: a high-speed chronoamperometric study in freely moving rats

Numerous data suggest that the mesocorticolimbic dopamine (DA) system is critically involved in the organization and regulation of goal-directed behaviours of various types as well as in the mediation of the psychogenic effects of cocaine. To test the hypothesis that cocaine not only alters levels of extracellular DA within the mesolimbic DA system, but in addition changes the response of this system to reinforcing environmental stimuli, a study using high-speed chronoamperometry was done to evaluate the effects of cocaine (15 mg/kg, i.p.) on extracellular DA in the nucleus accumbens and to assess the effects of cocaine on the response evoked by the presentation of tail-pinch and palatable food. Cocaine was found to induce long-term biphasic changes in extracellular DA (an increase followed by a decrease) and, more importantly, to enhance DA increases evoked by both tail-pinch and food. The powerful enhancing action of cocaine on DA release, triggered by significant environmental stimuli and associated with behaviours of different types, is considered to be a possible primary mechanism of its rewarding or euphorigenic effect.

Activity in monkey substantia nigra neurons related to a simple learned movement

Single cell activity was recorded in the pars compacta (SNc) and pars reticulata (SNr) of the substantia nigra (SN) in 4 unanesthetized Macaca fascicularis to determine the motor role of the nucleus. Animals were trained to perform a simple task that involved moving a lever by elbow flexion-extensions, in the horizontal plane using the hand contralateral to the recording site. Two monkeys learnt to execute the task on both sides. Electromyograms (EMG) of limb muscles were recorded simultaneously with SN neurons. Discharge rate modulation related to specific movement phases was present in 35% of the neurons. A significant positive correlation of the discharge rate with movement velocity and amplitude was found in SNc and SNr neurons. Some SNr cells discharged in anticipation of the EMG, suggesting a participation of the nucleus in the preparation of movement. The activity of SNr neurons was also related to movement of the left and right upper limb. In conclusion, the SN seems to play an important role in the control of specific motor mechanisms, probably modulating movement velocity, amplitude and direction, with little participation of somatosensory feedback. The involvement of the SNr in the coordination of bilateral arm activity is discussed.

Neurobiological background of pain and analgesia: the attempt at revaluation according to position of the organism's adaptive activity

The most adequate and successful way to understand the essence of any complex psychophysiological phenomenon, including pain, is obviously the study of its origin, its genesis, i.e., its biological background. Based on critical analysis of recent literature and our own electrophysiological, biochemical and pharmacological data we tried to overcome the difficulties and contradictions derived from the traditional reflex approach and analytical orientation in understanding the experimental investigation of pain-related problems and to determine the neurobiological background of pain and analgesia through the notion of the organism's adaptive activity. Interrelations between the notion of pain and other biological and psychological ideas, the place and functional significance of pain and endogenous analgesic mechanisms in the organization, maintenance and regulation of the organism's adaptive activity, characterization of the involvement of endogenous opioid peptides and monoamines in central processes associated with pain and analgesia, the essence and mechanisms of pain-depressing activity of the opiates are the main stages in our neurobiological consideration of the phenomenon of pain and its natural and pharmacological regulation.

In vivo neurochemical and anatomical heterogeneity of the dopamine uptake system in the rat caudate putamen

The neurochemical and anatomical heterogeneity of dopamine uptake blockade was studied at a medial and lateral position in each of 3 rostrocaudal areas of the rat caudate-putamen. In vivo voltammetric measures of extracellular dopamine indicated a lateral-to-medial and rostral-to-caudal gradient in the effect of uptake blockade. The percentage increase in dopamine was greatest in the rostrolateral area (300%) and least in the caudomedial area (10%). The existence of these lateromedial and rostrocaudal gradients was confirmed by tissue content measures of DOPAC and dopamine to DOPAC ratios in each area. The rostrocaudal gradient in the effect of uptake blockade was independent of the rostrocaudal gradient in dopamine tissue content. The regional gradients detected in dopamine uptake blockade may indicate a heterogeneous distribution in the number of uptake sites, a regional variation in the affinity of the uptake site for the blocker and/or altered neuronal activity mediated by an action of the blocker on dopaminergic cell bodies.

Neurophysiology and neurochemistry of drug dependence: a review

To understand the neurophysiological and neurochemical mechanisms of drug dependence, the functional significance of dopamine, noradrenaline and endogenous opioid peptides in the mediation of natural, self-stimulation and pharmacological reinforcement are discussed. Data on search of system(s), mediator(s) and neurons of reinforcement as well as my own notions on reinforcement as a critical element in organization and regulation of the organism's adaptive activity in variable environments are presented. The role of chronic drug-induced stable modification of central neurochemical systems' functioning as a basis for the alteration of endogenous reinforcement processes and raising drug dependence are examined in detail for main addictive drugs, opiates and psychomotor stimulants.

Dopaminergic involvement in nociceptive sensitivity/behavioral reactivity regulation during aversive states of different nature in the rat

To investigate the involvement of dopamine (DA) in nociceptive sensitivity-behavioral reactivity regulation in animals during aversive states of different nature, the influence of pharmacologically-induced decrease and increase of DA neurotransmission on vocalization and movement reactivity were studied in rats in free behavior, during restraint stress, after acute trauma of an extremity and under intraperitoneal acetic acid administration. The influence of longterm increase (apomorphine in a high dose) and decrease (haloperidol, apomorphine in a low dose) on suprarenals weight and gastric ulceration in animals exposed by polymodal aversive stimulation was also studied. The data obtained are discussed in relation with; 1. DA involvement in regulation of nociceptive sensitivity and behavioral reactivity in aversive environment; 2. the role of DA and endogenous opioid peptides in endogenous analgesic mechanisms; 3. the functional significance of cerebral DA in organization and realization of various types of an organism's adaptive activity produced by different environmental and homeostatic variables; and 4. the interaction of DA and endogenous opioid peptides in mediation of this activity.

Firing patterns of midbrain dopamine neurons: differences between A9 and A10 cells

Dopamine neurons of the substantia nigra (A9) and the ventral tegmental area (A10), giving rise to the nigrostriatal and mesolimbic dopamine pathways, respectively, are commonly supposed to show similar electrophysiological activity. There are, however, instances where the two systems are differently modulated. To assess possible physiological differences in the neuronal activity of A9 and A10 neurons, randomly sampled single cells were extracellularly recorded in the chloral hydrate-anaesthetized male rat. In addition to firing rate, the degree of burst firing and the regularity of firing were quantitatively analysed. Our results show that although A9 and A10 do not differ in firing rates, A10 neuronal activity is markedly less regular and shows a higher degree of burst firing, as judged from analysis of inter-spike time interval histograms. Mean burst firing values were 3% for the A9, and 23% for the A10 neurons. Regularity was described by variation coefficients of inter-spike time interval histograms. The mean variation coefficient was 38.4% in the A9 group and 63.8% in the A10 group, i.e. the A10 neuronal firing was less regular. The difference in regularity is partly, but not fully, dependent on the difference in burst firing. Previous biochemical and physiological studies strongly support the functional significance of modulatory changes in midbrain dopamine-cell firing patterns. Since the firing pattern of midbrain dopamine cells seems to be controlled by synaptic inputs, our results indicate a higher tonic modulatory influence on the A10 than on the A9 neurons. Thus the present results imply the pharmacological possibility of preferentially affecting A10 versus A9 dopamine cell function.

Functional properties of presumed dopamine-containing and other ventral tegmental area neurons in conscious rats

To elucidate the functional significance of mesolimbocortical dopamine (DA)-containing neurons in animal adaptive activity, the properties of single units in ventral tegmental area (VTA) and adjacent regions of the midbrain were studied in conscious rats with strictly fixed skull. Analysis of spontaneous firing activity, its changes during polymodal activating and aversive stimulations and their interrelations was performed in electrophysiologically-identified presumed DA-containing (D-type, 48 cells) and other (A-B and C-type, 47 and 29 cells accordingly) neurons found in this brain area. A common feature of all cells was the dependence of their discharge changes on the biological significance of the stimulation used and the strong correlation between these firing changes and stimulation-induced or spontaneous movement activity and blood pressure oscillations. Moreover, a significant correlation between the rate of firing and its dispersion and constancy of directions of neuronal changes during experimental stimulation in single cells were found. Presumed DA-containing neurons of D-type had a high variability of all properties and heterogeneity in the pattern of their discharges and in direction changes (prevalent activations). In presumed acetylcholine (ACh)-containing A-B type cells strong tonic-like activations and in presumed GABA- or ACh-containing interneurons of C-type depressions of firing both correlated with animal movement activity were found. Present data were discussed in relation with mediator specifity of studied cells and the differences of their participation in avoidance behavior forming in aversive environment.

Wire electrodes for chronic single unit recording of dopamine cells in substantia nigra pars compacta of awake rats

Stainless steel wire electrodes of varying sizes and coated with different insulating materials were tested in order to find a flexible fine wire which would allow the recording of small cells in deep structures of the brain in unrestrained, awake rats. Our main interest is to record from cells of substantia nigra pars compacta during locomotion. We found that stress relieved 18 micron stainless steel wire doubly insulated with lacquer and Parylene C provided the impedance, physical size, and flexibility needed to record single units during intense motor behavior.

Dopamine neuron transplants: electrophysiological unit activity of intrastriatal nigral grafts in freely moving cats

Fetal transplants of substantia nigra dopamine (DA)-containing neurons into the caudate nucleus in cats produced functional synaptic connections, as measured by behavioral analysis. Electrophysiological activity of single units from the intrastriatal nigral grafts revealed that these neurons displayed some of the characteristic electrophysiological parameters of DA neurons, i.e., long duration action potentials and tri-phasic waveform. However, these neurons discharged at a faster rate and never displayed the characteristic decremental burst pattern seen in intact, non-grafted animals. These data are the first electrophysiological recordings of grafted DA neurons in freely moving animals.

Recording of mouse ventral tegmental area dopamine-containing neurons

We examined the electrophysiologic and pharmacologic properties of dopamine-containing ventral tegmental area neurons in the mouse using extracellular single-unit recording techniques in both chloral hydrate-anesthetized mice and in vitro mouse midbrain slices. In vivo the ventral tegmental area neurons had long-duration action potentials (2 to 5 ms) and discharged at 1 to 9 spikes/s with either a decremental burst pattern or a regular pattern. Systemic administration of the dopamine agonist, apomorphine, decreased their firing rate, and the dopamine receptor blocker, haloperidol, reversed this effect. Similarly, systemic administration of the dopamine-releasing agent, d-amphetamine, suppressed their discharge rate, an effect blocked by pretreatment of the animals with alpha-methyl-p-tyrosine. When recorded in vitro from midbrain slices, ventral tegmental area neurons showed electrophysiologic properties similar to those found in vivo; however, the neurons recorded in vitro fired at a significantly faster rate and their firing pattern tended to be more pacemaker-like, especially when recordings were made in an incubation medium that blocked synaptic transmission (i.e., low calcium/high magnesium). The activity of most of these neurons was suppressed by addition of apomorphine to the incubation medium, an effect reversed by haloperidol. Pretreatment with alpha-methyl-p-tyrosine produced no significant change in the discharge pattern or rate for cells recorded in vitro. These data indicate that mouse ventral tegmental area dopamine neurons in vivo exhibit the same electrophysiologic and pharmacologic properties as do rat and cat dopamine-containing neurons and that in vitro they fire with pacemaker regularity in a low-calcium/high-magnesium medium. The in vitro preparation offers an approach to examining the fundamental properties of ventral tegmental area dopamine-containing neurons in the absence of afferent inputs.

Dopamine re-uptake inhibitors show inconsistent effects on the in vivo release of dopamine as measured by intracerebral dialysis in the rat

The effects of the dopamine (DA) re-uptake blockers amfonelic acid and GBR 12909 on the in vivo release of DA were investigated. DA release was measured by means of a fully automated brain dialysis system. GBR 12909 induced a 3-fold increase in the output of DA; amfonelic acid was without effect. These results indicate a dissociation between the behavioural effects of DA re-uptake blockers and the effects on DA release. A strong synergistic rise of DA release was observed when haloperidol was co-administered with amfonelic acid or GBR 12909. The potentiation of DA release was completely prevented by infusion of 1 microM tetrodotoxin.

Activity of A9 and A10 dopaminergic neurons in unrestrained rats: further characterization and effects of apomorphine and cholecystokinin

The activity of single dopaminergic (DA) neurons (total n = 77) in the midbrain of awake, unrestrained rats was examined. The firing rates and patterns of ventral tegmental area (A10) cells (n = 39) were similar to those of identified DA neurons in anesthetized and paralyzed rats. Unit activity was briefly stimulated (increased firing rate and burst activity) in response to an auditory stimulus and during manual stimulation of the vibrissae. Similar changes occurred during orienting responses and periods of sniffing. Twenty-six percent of A10 cells recorded appeared to be electronically coupled which matched the prevalence previously observed among A9 neurons. The effects on A9 and A10 DA cell activity of apomorphine and the carboxyterminal octapeptide of cholecystokinin (CCK-8) were then determined. Sequential doses of apomorphine (5-320 micrograms/kg, i.v.) reduced the firing rate of each neuron tested (n = 19). Ten of these cells were classified as 'sensitive' to the drug (ED50 less than 20 micrograms/kg), while the remainder were considerably 'less sensitive' (ED50 greater than 30 micrograms/kg). Cells of either sensitivity were as likely to be found in A9 as in A10. Sulfated CCK-8 (1-16 micrograms/kg, i.v.) excited (firing rate and bursting increased) 73% of the A9 neurons sampled but produced inconsistent effects on A10 cell firing. CCK-8 pretreatment increased the percentage of A9 and A10 neurons which were classified as 'sensitive' to apomorphine (82%). Enhanced sensitivity to apomorphine occurred regardless of the effect of CCK-8 on unit firing. Thus, as has been found in anesthetized rats, CCK-8 appeared to enhance the inhibitory effects of a DA agonist on DA neurons.

Functional reconfiguration of midbrain neurons by ovarian steroids in behaving hamsters

Previous studies have demonstrated the importance of the midbrain, especially the tectum, in the sensorimotor control of the sexually-receptive posture, lordosis, in female golden hamsters. In the present study, midbrain single unit activity was recorded during hormonal induction of lordosis, to identify neuronal activity mediating the sensorimotor control of the response and to observe functional changes in these neurons associated with the hormones' behavioral effect. Progesterone administration to estrogen-primed hamsters initiated pronounced changes in neuronal activity levels, somatosensory responsiveness and movement-related firing. These changes began in some neurons within 10 min of subcutaneous hormone injection and affected progressively more neurons until lordosis was elicitable 2-4 hr later. The pattern of these changes, including increased neuronal responsiveness to lumbosacral stimuli, appearance of lordosis-related firing (especially in the tectum) and reduced incidence of firing associated with lordosis-incompatible behaviors, constituted a transformation, or reconfiguration of midbrain sensorimotor function. It is proposed that this reconfiguration enables the elicitation and maintenance of lordosis by lumbosacral stimuli. Neural effects of comparable magnitude didn't result from control progesterone injections which failed to induce lordosis.

Simultaneous recording of substantia nigra neurons and voltammetric release of dopamine in the caudate of behaving cats

Simultaneous electrophysiological recordings of single dopamine-containing neurons in the pars compacta of the substantia nigra and the voltammetric release of dopamine in the caudate were made in the behaving cat. Unit activity showed no significant changes during sleep and small changes during active waking, while the release of dopamine in post-synaptic target regions of the caudate nucleus decreased by approximately 35% during sleep and increased approximately 50% during movement. These data demonstrate that recording the electrophysiological activity of single dopamine-containing neurons alone does not accurately reflect the functional state of the central dopamine system. The present study is the first report on the simultaneous measurement of the post-synaptic release of a neurotransmitter and the electrophysiological recording of neurons identified to contain that transmitter substance.