Comparison of deficits in electrical self-stimulation after ibotenic acid lesion of the lateral hypothalamus and the medial prefrontal cortex

Mu-opioid receptor-mediated depression of the hypothalamic hypocretin/orexin arousal system

Arousal and maintenance of a wake state is dependent on the hypothalamic hypocretin/orexin system. We found that hypocretin neurons are depressed by opiates, drugs of abuse that reduce cognitive alertness. Met-enkephalin (mENK), an endogenous opioid, and exogenous opiates such as morphine inhibited the hypocretin system by direct actions on the cell body that include reduced spike frequency, hyperpolarization, increased G-protein-coupled inwardly rectifying K(+) channel current, and attenuated calcium current, and indirectly through reducing excitatory synaptic tone by a presynaptic mechanism. CTAP (H-d-Phe-Cys-Tyr-d-Trp-Arg-Thr-Pen-Thr-NH(2)) and naloxone, antagonists of mu-opioid receptors, blocked mu agonist actions. In the absence of exogenous opioids, mu receptor antagonists enhanced activity of the hypocretin system, suggesting ongoing inhibition by endogenous receptors. Morphine pretreatment attenuated subsequent excitatory responses to hypocretin, suggesting a long-lasting depression caused by opiate exposure. Chronic exposure to morphine reduced subsequent responses to morphine and to mENK, but increased the response to opioid receptor antagonists. Together, these data are consistent with the view that the hypocretin system may be an important direct target for drugs of abuse, including opiates, that induce sedation and mental lethargy.

The central extended amygdala network as a proposed circuit underlying reward valuation

The phenomenon of medial forebrain bundle self-stimulation offers a powerful model of reward-based behavior. In particular, it appears to activate a neural system whose natural function is to compute the survival value or utility of present stimuli and to help orchestrate responses toward those inputs. Although the anatomical identity of this system is as yet unknown, recent descriptions of anatomical macrosystems within the basal forebrain lead to the proposal that it may be largely contained within the central extended amygdala network. This paper reviews decades' worth of behavioral and neurophysiological investigations of brain stimulation reward that support or are at least consistent with this idea. The proposed network circuitry underlying self-stimulation is also placed into the larger context of basal forebrain function, specifically, the role of the ventral striatopallidum in linking motivation to behavior, the role of the amygdala in detecting motivationally significant inputs, and the role of the magnocellular complex in communicating reward information to cortical and hippocampal targets.

Pharmacology and behavioral pharmacology of the mesocortical dopamine system

The prefrontal cortex (PFC) has long been known to be involved in the mediation of complex behavioral responses. Considerable research efforts are directed towards refining the knowledge about the function of this brain area and the role it plays in cognitive performance and behavioral output. In the first part, this review provides, from a pharmacological perspective, an overview of anatomical, electrophysiological and neurochemical aspects of the function of the PFC, with an emphasis on the mesocortical dopamine system. Anatomy of the mesocortical system, basic physiological and pharmacological properties of neurotransmission within the PFC, and interactions between dopamine and glutamate as well as other transmitters within the mesocorticolimbic circuit are included. The coverage of these data is largely restricted to what is relevant for the second part of the review which focuses on behavioral studies that have examined the role of the PFC in a variety of phenomena, behaviors and paradigms. These include reward and addiction, locomotor activity and sensitization, learning, cognition, and schizophrenia. Although the focus of this review is on the mesocortical dopamine system, given the intricate interactions of dopamine with other transmitter systems within the PFC and the importance of the PFC as a source of glutamate in subcortical areas, these aspects are also covered in some detail where appropriate. Naturally, a topic as complex as this cannot be covered comprehensively in its entirety. Therefore this review is largely limited to data derived from studies using rats, and it is also specifically restricted to data concerning the medial PFC (mPFC). Since in several fields of research the findings concerning the function or role of the mPFC are relatively inconsistent, the question is addressed whether these inconsistencies might, at least in part, be related to the anatomical and functional heterogeneity of this brain area.

Electrical self-stimulation in the central amygdaloid nucleus after ibotenic acid lesion of the lateral hypothalamus

This experiment was carried out in order to investigate the involvement of lateral hypothalamus (LH) in electrical self-stimulation of the central amygdaloid nucleus (CeA). Adult male Sprague-Dawley rats were bilaterally implanted with a guide cannula situated above each LH and with two electrodes in the CeA. Self-stimulation was subsequently obtained separately from both right and left electrodes. The LH was then lesioned unilaterally by ibotenic acid (IBO) injection. Eight days later, the effect of this unilateral lesion on self-stimulation of the ipsilateral and contralateral CeA was tested. Then the neurons of the remaining non-lesioned LH side were lesioned with IBO and self-stimulation was tested 15 days after the second lesion. Both unilateral as well as bilateral lesions of LH produced a significant decrease in CeA self-stimulation rates but had no significant effect on the reward effectiveness. The unilateral lesions did not produce any modification of the rate-intensity function in the contralateral CeA. This lesion-induced depression in performance was reversed by treatment with phenobarbital. These results provide clear evidence that the rewarding effects of CeA electrical stimulation do not result from the activation of the LH outputs and that the apparent decrease in CeA self-stimulation may result from the LH lesion-induced increase in the frequency of epileptiform manifestations that occur following amygdaloid stimulation.

Rats self-inject a dopamine antagonist in the lateral hypothalamus where it acts to increase extracellular dopamine in the nucleus accumbens

Local injection of sulpiride to block dopamine (primarily D2-type) receptors in the perifornical lateral hypothalamus (pf-LH) can induce locomotion, feeding, and drinking, and in the present study, local sulpiride induced reward and dopamine (DA) release in the nucleus accumbens. Sulpiride injected bilaterally (4, 8, and 16 micrograms/0.3 microliters), ipsilaterally, or contralaterally (8 micrograms) in the pf-LH increased extracellular levels of DA and its metabolites in the accumbens. Bilateral sulpiride injected posterior and medial to the pf-LH controlled for diffusion to the ventricle or ventral midbrain. Rats self-injected sulpiride (210 ng/21 nl/2 s) in the pf-LH (111 resp/2 h on drug lever vs. 20 resp on a blank lever). Thus, cells in the pf-LH establish connections with mesolimbic DA neurons involved in the behavior reinforcement process. Evidently hypothalamic cells with DA receptors normally inhibit aspects of behavior reinforcement. Disinhibition with hypothalamic sulpiride is reward for self-injection and cause of overeating that can lead to obesity.

Interhemispheric links in brain stimulation reward

The MFB substrate of self-stimulation (SS) has generally been viewed as a unilateral system. We re-examined this belief with pairs of moveable SS electrodes placed bilaterally in the MFB. Rats barpressed for trains of single or twin cathodal pulses of fixed intensity and width and of variable frequency. The first (C) and second (T) pulse of each pair was delivered through the left and right electrode or inversely. C-T intervals ranging from 0.2 to 5.0 ms were tested. The frequency of C pulses required for criterial bar-pressing was used to plot the stimulation efficacy (SE), as a function of the C-T interval and pulse presentation order. The electrodes were subsequently moved and the same procedure repeated for more ventral sites. With some pairs of contralateral hypothalamic (H) sites, the SE was independent of the C-T interval. However, with other pairs of contralateral H sites, the SE increased with C-T interval in a manner resembling a collision effect, with the important exception that no conduction time (CT) was apparent in the data. The absence of CT excludes the presence of a genuine collision effect. When one pulse was sent to the H and another to the contralateral ventral tegmentum (VT), the H-VT curve rose always earlier than the VT-H curve, thus resembling a transynaptic collision effect. However, the C-T interval at which the VT-H curve began rising (always 1.0 ms or less) fails to support the contention that the electrodes activated fibers separated by a synapse. Finally, a typical collision effect was noted with ipsilateral H-VT electrode placements, confirming the presence of direct linkage between ipsilateral MFB sites. Computer-generated data based on two parsimonious assumptions were found to match the empirical results. These assumptions were that each electrode activated a different branch of the same reward neuron and that conduction failure occurred at the branchpoint. The model, which posits that a large number of MFB reward neurons send branches to the other hemisphere, is testable and makes clear-cut predictions about the effects of lesions. In a preliminary test, we recorded the H and contralateral VT threshold frequencies before and after lesioning the H. The H threshold increased more when using small pulse current and remained constant throughout the 4-week testing period. The VT threshold was elevated more for intermediate pulse current and kept increasing with time.(ABSTRACT TRUNCATED AT 250 WORDS)

Determinants of the slow acquisition of medical and sulcal prefrontal cortex self-stimulation: an individual differences approach

Stimulation-naive rats were tested for motor activity during noncontingent electrical stimulation of the medial prefrontal cortex (MPC) or sulcal prefrontal cortex (SPC). Defecation during stimulation was also measured. The rats were then tested using a conditioned taste aversion paradigm for aversion to a novel flavor (0.1% saccharin) paired with stimulation. Finally, the rats were trained to acquire self-stimulation over 26 days of training. Large individual differences were seen in motor activity, defecation, and conditioned taste aversion to initial stimulation and in the subsequent speed of self-stimulation acquisition. In the MPC-stimulated group, acquisition speed was positively correlated with motor activity to initial stimulation and negatively correlated with defecation to this stimulation. In the SPC-stimulated group, the same correlations were evident, but only when rats suffering seizures prior to self-stimulation acquisition were excluded from the analysis. Such preacquisition seizures, which were only found in the SPC-stimulated group, retarded self-stimulation acquisition. In most rats, MPC or SPC stimulation failed to condition a taste aversion to saccharin. These results suggest that the slow acquisition of MPC and SPC self-stimulation may be partly related to the motor suppressive, aversive, and convulsive properties of initial stimulation.

Haloperidol attenuates conditioned place preferences produced by electrical stimulation of the medial prefrontal cortex

A Conditioned Place Preference test procedure [Ettenberg and Duvauchelle (13)] was used to investigate the effects of dopamine antagonist challenge on the rewarding properties of medial prefrontal cortex (MPFC) electrical stimulation. Rats exhibited strong preferences for the side of a two-compartment test apparatus in which they experienced sessions of experimenter-administered 0.5-s trains of MPFC sine-wave 60-Hz stimulation. Pretreatment with the neuroleptic dopamine antagonist drug, haloperidol (0.0, 0.15, or 0.3 mg/kg IP), resulted in a dose-dependent reduction in the magnitude of observed place preferences. Preference tests were conducted 24 hours after drug-conditioning trials and, hence, were not subject to motoric or other nonspecific actions of the neuroleptic treatments. In a control experiment, haloperidol did not block the place aversions produced by dorsomedial tegmental stimulation. Animals can, therefore, recall place-associations formed in the presence of haloperidol, a result which challenges "state-dependent learning" explanations of the drug's actions. Together, these results are consistent with the view that dopamine neurotransmission is involved in the rewarding consequences of electrical stimulation in the medial prefrontal cortex.

The effects of excitotoxin lesions of the lateral hypothalamus on self-stimulation reward

Unilateral microinjection into rat lateral hypothalamus (LH) of the excitotoxins ibotenic acid (IBO) and N-methyl-D-aspartic acid (NMDA) produced a local zone of neuronal death but also produced a zone of demyelination. The size of this demyelination zone was related to excitotoxin dose and was smaller than the zone of neuron killing. In behavioral testing, MFB self-stimulation reward and performance were measured with a rate-frequency curve-shift method before and after IBO or NMDA lesions of the LH. Excitotoxin lesions were made anterior or posterior to the LH electrode so that the zone of neuronal death, but not demyelination, extended to the electrode tip. These lesions produced small, temporary LH stimulation reward deficits, leading to the conclusion that intrinsic LH neurons are not a major substrate of MFB stimulation reward.

Amphetamine affects the extinction of self-stimulation differently in prefrontal cortex and posterior hypothalamus of rats

The effects of amphetamine on the extinction of intracranial self-stimulation (ICSS) and on postextinction ICSS performance were examined in rats implanted with electrodes either in medial prefrontal cortex (mPFC) or in the posterior hypothalamus-ventral tegmental area (PH-VTA). Lever-pressing for ICSS was allowed to stabilize in daily 15-minute sessions before each animal was exposed to 5 minutes of extinction (responding without reward). Animals were administered either 0.25 mg/kg d-amphetamine or saline before baseline, extinction and postextinction sessions. After amphetamine treatment, the number of lever presses during extinction was higher in mPFC animals and lower in PH-VTA animals compared with saline-treated controls. Rates did not change immediately after extinction but, one day later, rates had increased in all saline-treated animals (both PH-VTA and mPFC animals) and had decreased in all amphetamine-treated animals. These findings demonstrated that the effects of amphetamine on the extinction of ICSS were different in cortical and hypothalamic sites, possibly because of regional differences in stimulus-evoked reinforcement and inhibitory processes.

Central action of endogenous sugar acid (2-buten-4-olide): comparison with local anesthesia in hypothalamus

Rats were trained to discriminate cue tone stimuli (CTS) predicting reward (CTS+) [juice or intracranial self-stimulation (ICSS)], or aversion (CTS-) (mild electric shock or tail pinch). Unit activity in the lateal hypothalamus (LHA) and lateral preoptic-anterior hypothalamic area (lPOA-AHA) of the rat was recorded during CTS learning. The effects of local anesthesia of the amygdala (AM), ventral tegmental area (VTA) or LHA by procaine hydrochloride, and the effects of intraperitoneal or intravenous 2-buten-4-olide (2-B4O) on LHA neural activity and licking behavior were compared. LHA neurons differentiated between rewarding and aversive stimuli, and acquired corresponding discrimination of CTS+ and CTS-. In the lPOA-AHA, neurons responded similarly to CTS+, rewarding stimuli, CTS- and aversive stimuli. Procainization of the AM suppressed LHA neural responses to CTS1+ predicting juice, and stopped licking for juice. Procainization of the VTA suppressed LHA neural responses to CTS2+ predicting ICSS, and stopped licking for ICSS. LHA procainization suppressed both licking for juice and ICSS. Both intraperitoneal and intravenous 2-B4O stopped licking for juice and ICSS, but did not influence LHA responses to CTS1+ or CTS2+. The results suggest that dynamic interaction of AM-LHA-VTA are important for CTS+ learning, and 2-B4O acts directly on LHA neurons while maintaining afferent sensory inputs to the LHA.

Neural substrates of behavioral aversion in lateral hypothalamus of rabbits

Unit electrophysiology of lateral hypothalamus (LH) in rabbits has revealed two functionally contrasting, topographically distinguishable groups of neurons that relate to hedonic properties of taste stimuli. To assess the neurobehavioral role of aversion-type cells (maximally excited by aversive stimuli and inhibited by rewarding stimuli) found in the rostral part of mid-lateral LH at the level of ventromedial nucleus (vmh), intracranial self stimulation (ICSS) and stimulation-escape were studied with moveable-type electrodes in this and an adjoining caudal region of LH dominated by a contrasting type of neuron. Hedonic properties of the brain stimulation conformed to the distribution of these cellular elements. Stimulation of the rostral area supported weaker ICSS and stronger escape behavior. Aversive reactions predominated in ventral parts of the rostral area. Aversion-type cells identified electrophysiologically in this region would appear to mediate behaviorally aversive functions. These cells may play a role in the activation of feeding (possibly also drinking) and in drive-reduction reward.

Controllability of prestimulation of the medial prefrontal cortex determines the facilitation of self-stimulation and kindled seizures

Electrical stimulation of the medial prefrontal cortex (MPC) was administered according to the triadic design typically used to demonstrate learned helplessness. Three groups received either controllable, uncontrollable or no stimulation during the pretreatment phase. The effects of this pretreatment on the acquisition of self-stimulation at the same electrode site were investigated in the second phase of the experiment. Relative to unstimulated controls, both controllable and uncontrollable prestimulation facilitated the acquisition of self-stimulation and produced higher self-stimulation rates. In addition, compared with controllable stimulation, pretreatment with uncontrollable stimulation produced a greater facilitation in self-stimulation rate. The unambiguous demonstration of a behavioural facilitation produced by pretreatment with uncontrollable stimulation is, effectively, the inverse of the typical learned helplessness finding. It was also found, in the second phase of the experiment, that 6 of the 7 rats previously exposed to uncontrollable stimulation developed full class 5 seizures. No behavioural evidence of kindling was seen in any of the other rats or during the prestimulation procedure. These data are interpreted in terms of kindling and stress effects both proximal and distal to the site of stimulation.

Multiple reward systems and the prefrontal cortex

Electrical stimulation of the major divisions of the prefrontal cortex, the mediodorsal and sulcal areas, can serve as a reinforcing stimulus. Studies of self-stimulation of the prefrontal cortex have produced behavioral, anatomical and pharmacological evidence that the substrate of these rewarding effects can be dissociated from that subserving self-stimulation of ventral diencephalic sites such as the lateral hypothalamus. Other studies indicate that within the prefrontal cortex itself, self-stimulation of the medial and sulcal divisions can be attributed to dissociable processes. These observations suggest the existence of multiple, largely autonomous prefrontal subsystems involved in reinforcement. This raises the question of the functional significance of such systems, and of their organization. An approach to this problem is to consider the relationship between the behavioral functions of the prefrontal divisions and the characteristics of stimulation-induced reward obtained at each site. Studies of the effects of restricted prefrontal lesions indicate that the medial and sulcal divisions can be dissociated according to their involvement in the control of distinct types of sensory and motor events. Further experiments indicate that damage to each division causes selective deficits in the learning of stimulus-reinforcer and response-reinforcer relations, depending in part on the nature of the reinforcing event. Conditioning experiments further show that the rewarding effects produced by stimulation of these areas are preferentially associated to sensory events which correspond to the functional specialization of each division. These data are interpreted to suggest that different rewarding events and/or different attributes of rewarding stimuli are processed by distinct systems which are reflected by the organization of dissociable self-stimulation pathways.

The role of the lateral cortico-cortical prefrontal pathway in self-stimulation of the medial prefrontal cortex in the rat

Effects of electrolytic and kainic acid lesions at several stereotaxic planes of the lateral cortico-cortical prefrontal efferent pathway on self-stimulation of the medial prefrontal cortex were investigated. Electrolytic bilateral lesion of the sulcal prefrontal cortex, the first terminal area of this pathway, produced no effects on self-stimulation of the medial prefrontal cortex. However, bilateral electrolytic lesion of this pathway at the rostral part of the external capsule produced a permanent abolition of self-stimulation of the medial prefrontal cortex. These effects seemed selective since operant behaviour to obtain water, similar to that performed for self-stimulation and used as a control, was not affected by the lesion except on the 1st, 3rd (P less than 0.01) and 5th (P less than 0.05) days postlesion. Interestingly, bilateral microinjections of kainic acid (10 nmol in 0.8 microliters) at the same stereotaxic planes of the external capsule where electrolytic lesion was produced, had no effects on self-stimulation. These results suggest that fibres-of-passage through the external capsule are responsible for the abolition of self-stimulation. Bilateral electrolytic lesion of the entorhinal cortex, one of the caudal terminal areas of this descending set of fibres, produced a short transient decrease of self-stimulation of the medial prefrontal cortex. These results are discussed on the basis that complex, rather than single circuits are involved in maintaining self-stimulation in this neocortical area.

Basal forebrain knife cuts and medial forebrain bundle self-stimulation

Current autoradiographic and electrophysiological data suggest that fibers coursing from the diagonal band/medial septum and lateral preoptic area through the medial forebrain bundle (MFB) to the midbrain may carry the reward signals generated by lateral hypothalamic stimulation. To test this hypothesis, 40 rats were given a unilateral lateral hypothalamic stimulating electrode and an ipsilateral guide cannula for knife cut transection. In baseline self-stimulation testing, both the animal's capacity to respond for the stimulation and the reward efficacy of the stimulation were measured. A coronal plane knife cut transection was given following stabilization of baseline behavior, and any changes in response capacity and stimulation reward efficacy were observed for up to two weeks, beginning 24 h after transection. Cuts to the diagonal band/medial septal region or the outflow therefrom did not permanently or significantly alter stimulation reward effectiveness. Cuts in the lateral preoptic area or in the MFB just anterior to the stimulating electrode decreased stimulation reward effects only if considerable concomitant rostrocaudal tissue damage was apparent around the knife cut. Even in these cases, reward degradation was rarely permanent. These results suggest that the majority of reward-relevant fibers probably do not arise in forebrain nuclei rostral to the stimulating electrode. A possible role of neurons endemic to the lateral hypothalamus in stimulation reward effects is discussed.

Gustatory preference-aversion thresholds are increased by ibotenic acid lesion of the lateral hypothalamus in the rat

The main purpose of this study was to quantitate possible changes in the rewarding and aversive values of certain gustatory stimuli produced by bilateral ibotenic acid lesions of the lateral hypothalamus in the rat. Non-operated rats served as controls. Thirteen days after the operation, rats were placed on a water-deprivation schedule during 5 consecutive days. Rats were then given the choice of one of 5 concentrations of saccharin solution, using a two-bottle procedure. Fluid intake across concentrations generated a preference-aversion curve. The same type of procedure was used to obtain the aversion curve for increasing concentrations of quinine solution. The lesioned rats as well as the control animals showed a clear preference-aversion response to saccharin solutions and an aversive response to quinine solutions. However, the highest preference score of the lesioned rats was obtained with a saccharin concentration 3 times higher than the concentration preferred by the control rats. Moreover, unlike control rats operated animals did not show aversion to the highest concentrations of saccharin solutions. Finally in the lesioned rats the aversion threshold to quinine solutions was obtained with concentration 5 times higher than the concentration inducing aversion in the control rats. At the end of these experiments, rats used as controls were submitted, in turn, to bilateral lesion of the lateral hypothalamus. The change in the preference-aversion threshold of these rats in the saccharin choice procedure was the same as that observed with naive rats. Taken together, these results suggest that in the normal rat the palatability of certain gustatory stimuli is modulated by the intrinsic neurons of the lateral hypothalamus.

Electrical self-stimulation in the parabrachial area is depressed after ibotenic acid lesion of the lateral hypothalamus

The involvement of lateral hypothalamic intrinsic neurons on electrical self-stimulation of the parabrachial area was analyzed. Rats were bilaterally implanted in the parabrachial area and with a guide cannula located above each lateral hypothalamus. They were subsequently tested for intracranial self-stimulation. Then, the lateral hypothalamus on one side of the brain was injected with ibotenic acid. The effect of the induced lesion was tested 8 days later on self-stimulation of the ipsilateral and contralateral parabrachial areas. The intrinsic neurons of the non-lesioned lateral hypothalamus were then destroyed with ibotenic acid. Self-stimulation was then tested 8, 12 and 30 days later. The unilateral lesion produced a significant decrease of self-stimulation using the electrode ipsilateral to the lesion, without any modification of the stimulation using the contralateral electrode. After bilateral lesion, self-stimulation was greatly reduced bilaterally. The results suggest that the main effect of the lesion was to increase the self-stimulation threshold. Given that the parabrachial area is a relay station for the gustatory inputs and that the intrinsic neurons of the lateral hypothalamus project back to the parabrachial area, the present results are tentatively interpreted as an indication that self-stimulation in this pontine area results from the activation of feedback loops between the lateral hypothalamus and the parabrachial area.

The basolateral limbic circuit and self-stimulation of the medial prefrontal cortex in the rat

The effects of lesions of the basolateral nucleus of the amygdala (ABL) and the mediodorsal nucleus of the thalamus (MD) on self-stimulation (SS) of the medial prefrontal cortex (MPC) were investigated. Spontaneous motor activity (SMA) was measured as a control for possible non-specific effects of the lesions. Bilateral electrolytic lesions of ABL or MD produced a parallel transient decrease of SS and SMA. However, combined lesion of ABL and MD produced clearly different effects on both parameters. SMA decreased during the 1st day post-lesion and recovered to control levels by the 3rd day post-lesion. SS, on the contrary, was significantly decreased during the first five days post-lesion and after that time SS rate recovered to control levels. These results suggest the involvement of the basolateral limbic circuit in the neural substate underlying SS behavior of the MPC.

Neurotransmitters, pathways and circuits as the neural substrates of self-stimulation of the prefrontal cortex: facts and speculations

Through a multidisciplinary approach considerable progress has been made in understanding the neural substrates of self-stimulation (SS) of the medial prefrontal cortex (MPC). Thus, neuroanatomical studies have revealed that intrinsic neurones in the MPC seem to be the central elements responsible for initiating and maintaining this phenomenon in this area of the brain. Complementary to this central finding are the electrophysiological and neurohistological data reviewed here, showing that neurones in the MPC are directly activated and have monosynaptic feed-back connections with neurones located in areas which also support SS. These findings have given rise to the hypothesis that several single feed-back pathways or single circuits exist between points of SS in the MPC and points of SS in other areas of the brain. This hypothesis implies that SS in a particular area would depend not only on the intrinsic local activity induced by the electrical stimulation but on the functional and specific activity of other nuclei in the brain. The fact that lesions of single circuits, which are apparently involved in SS of the MPC such as the medial prefrontal cortex-ventrotegmental area-medial prefrontal cortex and medial prefrontal cortex-n. dorsomedialis of the thalamus-medial prefrontal cortex, do not produce a permanent decrease of SS, together with the finding that transynaptic connections seem to exist between MPC and other areas of the brain, suggests further that a complex rather than several single independent circuits could be at the neural basis of SS of the MPC. If that were the case, then SS of the MPC would not only depend upon local and single feed-back activity but upon specific functional feed-back activity among the nuclei, which in turn have single feed-back connections with the MPC (see the concept of 'complex circuit' outlined in the section of Behavioural studies). On the basis of this hypothesis no permanent changes should be expected after lesions of single pathways since physiological and even anatomical compensation could be reached through the rest of the undamaged circuit. That terminals containing specific neurotransmitters exist in layers of the PC where electrodes for SS are located has been reviewed in this paper. Some of these neurotransmitters have been suggested to be part of the local substrates activated by SS.(ABSTRACT TRUNCATED AT 400 WORDS)

The role of intrinsic neurons in lateral hypothalamic self-stimulation

In this brief review, we summarize some of our recent work concerning the effect of a specific lesion of the intrinsic neurons located in the middle part of the lateral hypothalamus on electrical self-stimulation of this structure by electrodes implanted along the medial forebrain bundle. In a first experiment the neurons of the lateral hypothalamus were destroyed unilaterally by local injection of ibotenic acid (4 micrograms in 0.5 microliter). The contralateral side served as the sham-lesion control. Between 10 and 20 days later, electrodes were bilaterally implanted, one in the lesioned area, the other in the contralateral hypothalamus. Intracranial self-stimulation (ICSS) was obtained separately for each electrode, at various current intensities, using a nose-poke response. ICSS from electrodes implanted in the lesioned area was decreased in all cases, whereas ICSS of the sham-lesioned side was normal. In a second experiment, two groups of rats lesioned and implanted as above, received two additional electrodes either in the anterior hypothalamus or in the posterior hypothalamus. In rats with electrodes in the anterior hypothalamus, the lesion produced a large deficit in self-stimulation when stimulation was applied to the anterior electrode ipsilateral to the lesion. Only 3 of 6 rats showed a decrease in ICSS with stimulation of the posterior hypothalamic electrode ipsilateral to the lesion. These results suggest that ICSS in the anterior part of the medial forebrain bundle is sustained by long fibers originating in the middle part of the lateral hypothalamus, while ICSS in the posterior part of the lateral hypothalamus may not depend on the neurons located in the lesioned area.

The role of corticocortical projections in self-stimulation of the prelimbic and sulcal prefrontal cortex in rats

Four experiments were performed to assess the nature of the contribution of the corticocortical projections between the prelimbic and sulcal divisions of the rat prefrontal cortex to self-stimulation (SS) of these sites. The first experiment showed that transection of these projections by parasagittal knife cuts or bilateral electrolytic lesions of the prelimbic cortex had no effect on SS of the sulcal cortex. The second experiment demonstrated that SS of the prelimbic cortex could be obtained after transection of the corticocortical projection path. The third experiment demonstrated that the deficit in prelimbic SS, seen to follow such bilateral transections, is a function of the amount of exposure to the stimulation given to the animals after the lesion. The fourth experiment showed that the stimulation-dependent process underlying the acquisition of prelimbic and sulcal SS could be dissociated by the knife cuts. The discussion focused on the implications of these findings for an account of prefrontal self-stimulation behavior.

Unilateral lesion of the intrinsic cells in the medial forebrain bundle depresses self-stimulation but not stimulus-bound locomotor activity

The intrinsic neurons of the medial forebrain bundle were unilaterally destroyed, in rats, through local injection of ibotenic acid (4 micrograms in 0.5 microliter). Ten days later, electrodes were bilaterally implanted, one in the lesioned lateral hypothalamus, the other into the contralateral hypothalamus. Firstly, self-stimulation was studied with stimulation of each electrode separately. Later on, the effect of non-contingent electrical stimulation on evoked locomotor activity in the open-field was analysed for each electrode. While self-stimulation of the lesion area was greatly depressed in comparison with the unlesioned lateral hypothalamus, the increase in locomotor activity produced by stimulation, at the intensity applied, was the same whether the stimulated hypothalamus was lesioned or not.