Morphine-induced modification of the functional properties of ventral tegmental area neurons in conscious rat

Dopamine neurons encode errors in predicting movement trigger occurrence

The capacity to anticipate the timing of events in a dynamic environment allows us to optimize the processes necessary for perceiving, attending to, and responding to them. Such anticipation requires neuronal mechanisms that track the passage of time and use this representation, combined with prior experience, to estimate the likelihood that an event will occur (i.e., the event's "hazard rate"). Although hazard-like ramps in activity have been observed in several cortical areas in preparation for movement, it remains unclear how such time-dependent probabilities are estimated to optimize response performance. We studied the spiking activity of dopamine neurons in the substantia nigra pars compacta of monkeys during an arm-reaching task for which the foreperiod preceding the "go" signal varied randomly along a uniform distribution. After extended training, the monkeys' reaction times correlated inversely with foreperiod duration, reflecting a progressive anticipation of the go signal according to its hazard rate. Many dopamine neurons modulated their firing rates as predicted by a succession of hazard-related prediction errors. First, as time passed during the foreperiod, slowly decreasing anticipatory activity tracked the elapsed time as if encoding negative prediction errors. Then, when the go signal appeared, a phasic response encoded the temporal unpredictability of the event, consistent with a positive prediction error. Neither the anticipatory nor the phasic signals were affected by the anticipated magnitudes of future reward or effort, or by parameters of the subsequent movement. These results are consistent with the notion that dopamine neurons encode hazard-related prediction errors independently of other information.

Fast transmission from the dopaminergic ventral midbrain to the sensory cortex of awake primates

Motivated by the increasing evidence that auditory cortex is under control of dopaminergic cell structures of the ventral midbrain, we studied how the ventral tegmental area and substantia nigra affect neuronal activity in auditory cortex. We electrically stimulated 567 deep brain sites in total within and in the vicinity of the two dopaminergic ventral midbrain structures and at the same time, recorded local field potentials and neuronal discharges in cortex. In experiments conducted on three awake macaque monkeys, we found that electrical stimulation of the dopaminergic ventral midbrain resulted in short-latency (~35 ms) phasic activations in all cortical layers of auditory cortex. We were also able to demonstrate similar activations in secondary somatosensory cortex and superior temporal polysensory cortex. The electrically evoked responses in these parts of sensory cortex were similar to those previously described for prefrontal cortex. Moreover, these phasic responses could be reversibly altered by the dopamine D1-receptor antagonist SCH23390 for several tens of minutes. Thus, we speculate that the dopaminergic ventral midbrain exerts a temporally precise, phasic influence on sensory cortex using fast-acting non-dopaminergic transmitters and that their effects are modulated by dopamine on a longer timescale. Our findings suggest that some of the information carried by the neuronal discharges in the dopaminergic ventral midbrain, such as the motivational value or the motivational salience, is transmitted to auditory cortex and other parts of sensory cortex. The mesocortical pathway may thus contribute to the representation of non-auditory events in the auditory cortex and to its associative functions.

Dopamine in motivational control: rewarding, aversive, and alerting

Midbrain dopamine neurons are well known for their strong responses to rewards and their critical role in positive motivation. It has become increasingly clear, however, that dopamine neurons also transmit signals related to salient but nonrewarding experiences such as aversive and alerting events. Here we review recent advances in understanding the reward and nonreward functions of dopamine. Based on this data, we propose that dopamine neurons come in multiple types that are connected with distinct brain networks and have distinct roles in motivational control. Some dopamine neurons encode motivational value, supporting brain networks for seeking, evaluation, and value learning. Others encode motivational salience, supporting brain networks for orienting, cognition, and general motivation. Both types of dopamine neurons are augmented by an alerting signal involved in rapid detection of potentially important sensory cues. We hypothesize that these dopaminergic pathways for value, salience, and alerting cooperate to support adaptive behavior.

Endocannabinoid release from midbrain dopamine neurons: a potential substrate for cannabinoid receptor antagonist treatment of addiction

Substantial evidence suggests that all commonly abused drugs act upon the brain reward circuitry to ultimately increase extracellular concentrations of the neurotransmitter dopamine in the nucleus accumbens and other forebrain areas. Many drugs of abuse appear to increase dopamine levels by dramatically increase the firing and bursting rates of dopamine neurons located in the ventral mesencephalon. Recent clinical evidence in humans and behavioral evidence in animals indicate that cannabinoid receptor antagonists such as SR141716A (Rimonabant) can reduce the self-administration of, and craving for, several commonly addictive drugs. However, the mechanism of this potentially beneficial effect has not yet been identified. We propose, on the basis of recent studies in our laboratory and others, that these antagonists may act by blocking the effects of endogenously released cannabinoid molecules (endocannabinoids) that are released in an activity- and calcium-dependent manner from mesencephalic dopamine neurons. It is hypothesized that, through the antagonism of cannabinoid CB1 receptors located on inhibitory and excitatory axon terminals targeting the midbrain dopamine neurons, the effects of the endocannabinoids are occluded. The data from these studies therefore suggest that the endocannabinoid system and the CB1 receptors located in the ventral mesencephalon may play an important role in regulating drug reward processes, and that this substrate is recruited whenever dopamine neuron activity is increased.

Ethanol modulates GABA(B) receptor expression in cortex and hippocampus of the adult rat brain

Using in situ hybridization, RNase protection assay and Western blot, we studied the effects of ethanol on the expression levels of GABA(B) receptor mRNA and protein in the cortex and hippocampus from adult rat brain. The results showed that ethanol significantly increased GABA(B1) and GABA(B2) receptor protein expression in the cortex, whereas only GABA(B2) was increased in the hippocampus. GABA(B) receptor agonist baclofen could partially reverse the effect of ethanol. Further studies of the mRNA levels defined that GABA(B1) mRNA levels were significantly increased in the hippocampus, with no significant changes of GABA(B2) mRNA levels. Moreover, GABA(B1) and GABA(B2) receptor mRNA levels were increased on 3-week ethanol treatment. Finally, GABA(B) agonist baclofen and antagonist phaclofen showed significant decreasing effects on GABA(B1) receptor mRNA levels in the cortex, but not in the hippocampus. These results were further confirmed by in situ hybridization. Thus, the present results showed the effects of ethanol on GABA(B) receptors in the cortex and hippocampus, implying the possible role of GABA(B) receptor in ethanol effects. The effects of GABA(B) receptor agonist and antagonist suggested that the possible mechanisms underlying that GABA(B) receptor modulated the behavioral effect induced by ethanol.

Brain and body hyperthermia associated with heroin self-administration in rats

Intravenous heroin self-administration in trained rats was accompanied by robust brain hyperthermia (+2.0-2.5 degrees C); parallel changes were found in the dorsal and ventral striatum, mediodorsal thalamus, and deep temporal muscle. Temperature began to increase at variable latency after a signal of drug availability, increased reliably (approximately 0.4 degrees C) before the first lever press for heroin, increased further (approximately 1.2 degrees C) after the first heroin injection, and rose more slowly after the second and third injections to stabilize at an elevated plateau (39-40 degrees C) for the remainder of the session. Brain and body temperature declined slowly when drug self-administration was terminated; naloxone precipitated a much more rapid decrease to baseline levels. Changes in temperature were similar across repeated daily sessions, except for the increase associated with the first self-administration of each session, which had progressively shorter latency and greater acceleration. Despite consistent biphasic fluctuations in movement activity associated with heroin self-administrations (gradual increase preceding the lever press, followed by an abrupt hypodynamia after drug infusion), mean brain temperature was very stable at an elevated plateau. Only mean muscle temperature showed evidence of biphasic fluctuations (+/-0.2 degrees C) that were time locked to and correlated with lever pressing and associated movements. Drug- and behavior-related changes in brain temperature thus appear to reflect some form of neuronal activation, and, because temperature is a factor capable of affecting numerous neural functions, it may be an important variable in the control of behavior by drugs of abuse.

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.

Single-unit and polygraphic recordings associated with systemic or local pharmacology: a multi-purpose stereotaxic approach for the awake, anaesthetic-free, and head-restrained rat

In order to avoid any artifactual pharmacological interferences with anaesthetic agents, a procedure has been developed for working on the awake, anaesthetic-free rat in a head-restrained condition. It allows, on the same animal and over several consecutive days, single-unit recordings in combination with systemic or local pharmacology (microiontophoresis or micropressure ejections), as well as monitoring vigilance states via the electroencephalogram and the electromyogram. After the cementing of a special "U"-shaped device on its skull under general anaesthesia, the animal is progressively habituated to stay daily, for several hours, under a painless corresponding stereotaxic restraint. This system can be easily adapted to different stereotaxic frames and, because of its spatial flexibility for targetting the desired rostrocaudal or lateral positions, allows access to a large number of cerebral structures. Experiments performed on Globus Pallidus, Substantia Nigra, and Locus Coeruleus neurons, combining the different possibilities of this system, are reported. They demonstrate, on the awake anaesthetic-free head-restrained rat, and under suitable ethical conditions, the feasibility of single-unit recordings of identified neurons associated with the study of their pharmacological reactivity after systemic or local drug administrations without any other drug interferences, and in physiologically relevant conditions such as the spontaneous alternance of vigilance states.

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.

The role of dopamine in drug abuse viewed from the perspective of its role in motivation

Drugs of abuse share with conventional reinforcers the activation of specific neural pathways in the CNS that are the substrate of their motivational properties. Dopamine is recognized as the transmitter of one such neural pathway, being involved in at least three major aspects of motivation: modulation of motivational state, acquisition (incentive learning) and expression of incentive properties by motivational stimuli. Drugs of abuse of different pharmacological classes stimulate in the low dose range dopamine transmission particularly in the ventral striatum. Apart from psychostimulants, the evidence that stimulation of dopamine transmission by drugs of abuse provides the primary motivational stimulus for drug self-administration is either unconvincing or negative. However, stimulation of dopamine transmission is essential for the activational properties of drugs of abuse and might be instrumental for the acquisition of responding to drug-related incentive stimuli (incentive learning). Dopamine is involved in the induction and in the expression of behavioural sensitization by repeated exposure to various drugs of abuse. Sensitization to the dopamine-stimulant properties of specific drug classes leading to facilitation of incentive learning of drug-related stimuli might account for the strong control over behaviour exerted by these stimuli in the addiction state. Withdrawal from drugs of abuse results in a reduction in basal dopamine transmission in vivo and in reduced responding for conventional reinforcers. Although these changes are likely to be the expression of a state of dependence of the dopamine system their contribution to the motivational state of drug addiction is unclear.

Behavioral significance of phasic changes in mesolimbic dopamine-dependent electrochemical signal associated with heroin self-injections

High-speed chronoamperometry with monoamine-selective carbon fiber electrodes was used in rats to monitor, during 5-6 consecutive daily sessions, changes in DA-dependent electrochemical signal in the nucleus accumbens (NAcc) during intravenous heroin (0.1 mg/kg) self-administration (SA) behavior and passive repeated drug injections performed with a temporal scheme similar to that in the SA experiment. In trained animals, biphasic signal fluctuations time-locked to the individual lever-presses were found to accompany all but the first daily SAs. The signal gradually increased by 30-40 nM for the 10 minutes preceding the SA, reached a peak at the moment of lever-press and decreased abruptly by approximately 40 nM for 3-4 min after heroin SA. The cycle then repeated, reaching a new peak at the moment of the next lever-press. Rapid bi-directional fluctuations in signal associated with individual heroin SAs were superimposed on substantial tonic increase in signal baseline (400-500 nM). This increase quickly developed after presentation of heroin-related light cue and the first SA, was relatively stable during all subsequent SAs and decreased towards the baseline after the last SA of a session. Changes in signal baseline induced by repeated heroin SAs depended strongly upon the signal's basal level (r = -0.787); that signal preferentially increased when its basal values were low (0-300 nM), and decreased when signal was tonically elevated (> 600 nM). Repeated passive heroin injections also induced biphasic signal fluctuations and a similar tonic increase in signal baseline. Although a transient signal decrease (25 nM for 2-4 minutes) followed by a prolonged signal increase occurred after each but not the first passive injection, the gradual pre-injection signal acceleration was absent. Although DOPAC, a principal DA metabolite, may significantly contribute to the tonic increase in electrochemical signal seen during SA session, the changes in extracellular DA may be the main contributor to both the rapid signal increases preceding drug-taking and the transient signal decreases following heroin SA. If so, the present findings suggest that activation of mesolimbic DA cells and increase in DA transmission may be involved in the mediation of motivational and/or activational components of drug-seeking and drug-taking behavior. An acute termination of previous drug- and behavior-associated DA activation with a transient inhibition of DA release, immediately following heroin SA may correlate with the drug's rewarding action, representing a part of a mechanism regulating drug-taking behavior.

Drug- and behavior-associated changes in dopamine-related electrochemical signals during intravenous heroin self-administration in rats

High-speed chronoamperometry was used to monitor dopamine-related electrochemical signals in the nucleus accumbens of rats allowed to self-administer heroin intravenously and rats that received similar injections passively. Rats self-administered 100 micrograms/kg of heroin at approximately 20-min intervals. Dopamine-related electrochemical signals increased monotonically after the first injection of each day; the effect was weaker on the first than on the second and subsequent days. The second and subsequent injections in each session caused biphasic effects: the initial effect was a decrease in signal--a minor one when compared to the increase caused by the first injection--and this was followed by an increase that brought the signal back to or somewhat higher than the level at the time of the injection. Over the course of each 4-h session, the electrochemical signal reached and fluctuated around an elevated plateau; doubling the injection dose did not elevate this plateau but did cause larger phasic decreases and subsequent increases. Qualitatively similar electrochemical changes were seen in the animals passively receiving the drug, but there were two notable quantitative differences. First, in the passive animals the initial depressions in signal were of shorter duration. Second, in the passive animals (which were injected at intervals determined by the self-administering animals) the electrochemical signal reached a maximum and began to fall prior to the time of the next injection; in the animals that self-administered the drug, the signal was still rising at the time of the next injection. The changes in electrochemical signal are unlikely to represent fluctuations of ascorbate or dopamine metabolites; thus it appears that whereas self-administered heroin injections cause a slow and long-lasting elevation of extracellular dopamine concentration, short-term increases in dopamine concentration are associated with the behavioral activation that precedes the injections and it is short-term decreases that appear to be associated with the period usually thought to be most significant for positive reinforcement.

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.

Neurotransmitter regulation of dopamine neurons in the ventral tegmental area

Over the last 10 years there has been important progress towards understanding how neurotransmitters regulate dopaminergic output. Reasonable estimates can be made of the synaptic arrangement of afferents to dopamine and non-dopamine cells in the ventral tegmental area (VTA). These models are derived from correlative findings using a variety of techniques. In addition to improved lesioning and pathway-tracing techniques, the capacity to measure mRNA in situ allows the localization of transmitters and receptors to neurons and/or axon terminals in the VTA. The application of intracellular electrophysiology to VTA tissue slices has permitted great strides towards understanding the influence of transmitters on dopamine cell function, as well as towards elucidating relative synaptic organization. Finally, the advent of in vivo dialysis has verified the effects of transmitters on dopamine and gamma-aminobutyric acid transmission in the VTA. Although reasonable estimates can be made of a single transmitter's actions under largely pharmacological conditions, our knowledge of how transmitters work in concert in the VTA to regulate the functional state of dopamine cells is only just emerging. The fact that individual transmitters can have seemingly opposite effects on dopaminergic function demonstrates that the actions of neurotransmitters in the VTA are, to some extent, state-dependent. Thus, different transmitters perform similar functions or the same transmitter may perform opposing functions when environmental circumstances are altered. Understanding the dynamic range of a transmitter's action and how this couples in concert with other transmitters to modulate dopamine neurons in the VTA is essential to defining the role of dopamine cells in the etiology and maintenance of neuropsychiatric disorders. Further, it will permit a more rational exploration of drugs possessing utility in treating disorders involving dopamine transmission.

Long-term changes of striatal D-2 receptors in rats chronically exposed to morphine under aversive life conditions

Chronic morphine treatment has been shown to cause the development of hyperreactivity of the dopamine system detected as the increased behavioral and biochemical responses to the action of specific dopamine agonists. Furthermore, inverted changes in animal behavioral reactivity to the stimulation of presynaptic, proposed D-2 receptors by apomorphine in a low dose was found in our previous study when morphine was chronically used in animals under conditions of restraint. To estimate the nature and proposed receptor mechanisms of changes found in behavioral reactivity due to chronic morphine administration in aversive life conditions at the level of highly sensitive D-2 receptors, the density and affinity of [3H] spiroperidol binding sites was studied in these animals two weeks after the last opiate administration. Increased density and affinity of D-2 receptors probably indicating their hypersensitivity was found in animals chronically exposed to two-hour restraint stress, while a significant decrease in density accompanied by increase in affinity of these receptors was typical to rats chronically exposed to morphine under conditions of restraint. The data are discussed in aspects of quantitative and qualitative changes in D-2 receptors, and their proposed mechanisms and functional significance in the mediation of modified organism's functional state due to chronic opiate administration in different environmental conditions.

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.

Nociceptive sensitivity/behavioral reactivity regulation in rats during aversive states of different nature: its mediation by opioid peptides

To study the regulation of nociceptive sensitivity/behavioral reactivity in animals during aversive states of different nature, the changes of vocalization thresholds and tail-withdrawal latencies were investigated in rats in free behavior, during restraint stress, after acute trauma to an extremity and under intraperitoneal acetic acid administration. To understand opioid peptide involvement in mediation of the changes obtained, this analysis was also done during opiate receptor blockade by naloxone. The data on the modification of vocalization and movement reactivity as well as on the changes of suprarenal weight and gastric ulceration, produced in normal and naloxone-treated rats by innoxious stressogenic, noxious somatic and visceral stimulation are discussed in relation with: 1. the peculiarities of sensitivity and responsivity of animals to external stimuli in aversive environment; 2. the role of these changes in maintenance of an animal's adaptive activity produced by environmental threat and their mediation by endogenous opioids; 3. the functional significance of the activation of endogenous opioidergic neurotransmission in organization, realization and modification of an animal's adaptive activity, directed on behavioral escape from aversive environment as well as on satisfaction of actual biological and zoosocial needs, in regulation of precise conformity among homeostasis, behavior and variable environment.