Prefrontal dopamine release and sensory-specific satiety altered in rats with neonatal ventral hippocampal lesions.

Rats with a neonatal ventral hippocampal lesion (NVHL) have been used to model certain features of schizophrenia because they display dopaminergic activity and behavioral alterations consistent with a dysfunctional prefrontal cortex after puberty. Microdialysis studies in normal rats demonstrated increased prefrontal dopamine release during the incentive phase of behavior in an experimental situation specifically designed to evidence this behavioral aspect: the so called "sensory-specific satiety" procedure. Our hypothesis is that if dopaminergic activity in the prefrontal cortex of NVHL rats differs from sham lesioned rats, the responsiveness to the aforementioned experimental situation should also be different. Extracellular medial prefrontal dopamine outflow increased in hungry control rats when they had access to food and decreased across satiety. It increased again when a new food was presented, even when the rats were satiated. NVHL rats also had increased dopamine prefrontal outflow in these conditions, but it remained high after the end of the consumption period. The food consumption behavior declined less rapidly and the reinstatement of food consumption, usually produced by new food, did not occur in NVHL rats, provided the lesions were large. These data were discussed in relation to several theoretical backgrounds developed about the incentive aspect of behavior and for understanding the pathophysiology of schizophrenia.

Adrenergic drugs modify the level of noradrenaline in the insular cortex and alter extinction of conditioned taste aversion in rats.

We compared the effect of conditioned taste aversion in rats by measuring the amount of sucrose that they drunk after conditioning, which differed according to whether rats had drunk the sucrose freely (SD: self drinking) during the conditioning session, or had been forced to drink it (IO: intra-oral administration through a chronically implanted cannula). The SD procedure delayed the extinction of conditioned taste aversion. Enhanced arousal, alertness, awareness or attention in the SD condition may have strengthened the memory of the taste. Brain noradrenergic networks are involved in such processes. We administered two noradrenergic drugs that produce opposite effects on noradrenaline release in the brain, methoxy-idazoxan, RX821002 (1mg/kg, i.p.), and guanfacine (0.12mg/kg, i.p.). We evaluated their effect (i) on the level of noradrenaline in the gustatory cortex using microdialysis, (ii) on glycaemia that is an essential factor of taste learning and (iii) on the comparative SD versus IO conditioned taste aversion protocol mentioned above. Injecting RX821001 increased the level of noradrenaline in the gustatory cortex up to two-fold of the baseline. This effect lasted 1h. The same dose of RX821002 did not elicit any alteration of glycaemia. It enhanced extinction of conditioned taste aversion in the SD group of rats. Injecting 0.12mg/kg of guanfacine produced the opposite effect. The noradrenaline level of the gustatory cortex decreased, but only down to 20% of the baseline. This decrease lasted 2h. Guanfacine increased glycaemia. Extinction of conditioned taste aversion was only marginally decreased by guanfacine in the SD group of rats. These results fit with Aston-Jones' point of view that the role of the noradrenergic coeruleo-cortical system may be to enhance arousal, alertness, awareness or attention to an event by a transient increase of cortical noradrenaline.

In vivo dopamine measurements in the nucleus accumbens after nonanesthetic and anesthetic doses of propofol in rats.

UNLABELLED: There is growing evidence that propofol acts on affective and reward processes. We designed this study to assess the effect of propofol on the concentration of dopamine in the nucleus accumbens, a main component of the mesolimbic system. The concentration of dopamine in the nucleus accumbens was assessed by using in vivo brain microdialysis in freely moving rats. A microdialysis probe was placed within guide cannulae previously placed during stereotaxic surgery. Fluid was perfused through the probe, and samples were collected every 20 min for measuring concentrations by high-pressure liquid chromatography. All rats served as their own controls and were randomized to four different doses of propofol, injected intraperitoneally: 0, 9, 60, or 100 mg/kg, according to a within design. Compared with the baseline value, dopamine concentration was decreased at the smallest dose of 9 mg/kg, whereas concentration was largely increased at the subanesthetic (60 mg/kg) and anesthetic (100 mg/kg) doses. This increase was of the same magnitude (+90%) for subanesthetic and anesthetic doses but was more prolonged at the anesthetic dose. Data show that only subanesthetic and anesthetic doses of propofol increase the concentration of dopamine in the nucleus accumbens, as previously described with drugs of potential abuse. IMPLICATIONS: Depending on the dose, propofol either increased or decreased the concentration of dopamine in the nucleus accumbens, as assessed during microdialysis in freely moving rats. Only large doses which display a pharmacological profile, such as propofol, may show promise.

Gamma-hydroxybutyrate increases tryptophan availability and potentiates serotonin turnover in rat brain.

Gamma-hydroxybutyrate (GHB) is both a therapeutic agent and a recreative drug. It has sedative, anxiolytic and euphoric effects. These effects are believed to be due to GHB-induced potentiation of cerebral GABAergic and dopaminergic activities, but the serotonergic system might also be involved. In this study, we examine the effects of pharmacological doses of GHB on the serotonergic activity in rat brain. Administration of 4.0 mmol/kg i.p. GHB to rats induces an accumulation of tryptophan and 5-HIAA (5-hydroxyindole acetic acid) in the frontal cortex, striatum and hippocampus without causing significant change in the tissue serotonin content. In the extracellular space, GHB induced a slight decrease in serotonin release. The tryptophan and 5-HIAA accumulation induced by GHB is mimicked by the GHB receptor agonist para-chlorophenyl-transhydroxycrotonate (NCS-356) and blocked by NCS-382 (6,7,8,9-tetrahydro-5-[H]-benzocycloheptene-5-ol-4-ylidene acetic acid) a selective GHB receptor antagonist. GHB induces the accumulation of either a derivative of or [3H]-tryptophan itself in the extracellular space, possibly by increasing tryptophan transport across the blood-brain barrier. The blood content of certain neutral amino-acids, including tryptophan, is also increased by peripheral GHB administration. Some of the effect of GHB could be reproduced by baclofen and reduced by the GABAB antagonist CGP 35348. Taken together, these results indicate that the GHB-induced stimulation of tissue serotonin turnover may be due to an increase in tryptophan transport to the brain and in its uptake by serotonergic cells. As the serotonergic system may be involved in the regulation of sleep, mood and anxiety, the stimulation of this system by high doses of GHB may be involved in certain neuropharmacological events induced by GHB administration.