László Lénárd

Self-injection of amphetamine directly into the brain

Rats learned to self-administer d-amphetamine (10 μg/μl) through a cannula implanted in the nucleus accumbens. They responded more frequently for 65±15 nl of amphetamine than for equal amounts of saline. When presented with two levers (one amphetamine, one blank) they responded more on the correct lever for amphetamine. They would also switch levers, when necessary, to maintain access to the drug. When half the usual drug intake was given automatically, animals reduced their response rate by half, thus self-regulating the total amount of amphetamine they received. In tests for leakage into the ventricles, eight rats that self-injected with an accumbens cannula showed response extinction when switched to a ventricular cannula. We conclude that amphetamine self-injected into the accumbens is a positive reinforcer. This localization of ‘amphetamine reward’ suggests that the nucleus accumbens contains a synaptic mechanism underlying amphetamine abuse and, perhaps, also natural reinforcement of behavior.

Is there any relationship between obesity and mental flexibility in children

Cognitive profiles of 12 schoolboys with obesity were compared with their peers with normal weight. For the cognitive assessment five clinical tasks were selected: digit span memory, Ravens progressive matrices (intelligence), semantic verbal fluency, D2 attention endurance and Wisconsin card sorting test. We found no differences in memory, intelligence and verbal fluency between the two groups. Children with obesity performed worse on D2 and Wisconsin tests. Correlations confirmed relationships between body weight, body mass index, attention and Wisconsin measured perseveration in set-shifting. This suggests that childhood obesity involves cognitive deficits in shifting and attention abilities.

Altered executive function in obesity. Exploration of the role of affective states on cognitive abilities

There is a growing evidence that obesity is not only a weight problem, but it is linked to adverse neurocognitive outcomes. Besides obesity, frontal lobe based cognitive deficits in depressed patients are confirmed, and interactions between depression and obesity are known. In our study we investigated the relationship between cognitive functioning, mood and female obesity. Our findings revealed reduced mental flexibility and sustained attention capacity in obesity together with the presence of depressive mood. The mediating role of depression is confirmed. Positive emotion was associated with cognitive functions independently from BMI. Positive affectivity in obesity treatment is discussed.

Effects of pretreatment with PACAP on the infarct size and functional outcome in rat permanent focal cerebral ischemia

PACAP exerts neuroprotective effects under various neurotoxic conditions in vitro. In vivo, it reduces brain damage after global and transient focal ischemia. The present study investigated whether PACAP has neuroprotective effects when applied before the onset of permanent ischemia. Rats were given bolus injections of PACAP38 intracerebroventricularly, and then underwent permanent middle cerebral artery occlusion. The results show that 2 microg of PACAP significantly reduced the infarct size measured 12 and 24h after the onset of ischemia. No further reduction was obtained by a 7-day pretreatment. PACAP also ameliorated certain sensorimotor deficits. Our present study provides further evidence for the neuroprotective effects of PACAP, and implies that it might be a promising preventive therapeutic agent in ameliorating ischemic brain damage.

Feeding-related activity of glucose-and morphine-sensitive neurons in the monkey amygdala

Feeding-related neuronal activity of monkey amygdalar glucose-sensitive and morphine-sensitive cells was investigated during a task that required bar-pressing to obtain food. Both glucose-sensitive and morphine-sensitive cells, located mostly in the centromedial part of the amygdala, decreased firing during the bar-press period more often than insensitive cells. Naloxone attenuated the decrease in activity during the bar press period. The results suggest involvement of these glucose- and morphine-sensitive cells in the control of food acquisition behavior.

Behavioral significance of monkey hypothalamic glucose-sensitive neurons

Feeding-related neuronal activity of lateral hypothalamic glucose-sensitive and glucose-insensitive neurons was investigated in behaving monkeys. The behavioral paradigm was a high fixed ratio of bar pressing for food reward signaled by light and tone cues. Twenty-seven percent of the neurons tested were glucose-sensitive. The population of neurons which changed in firing rate during the feeding task was higher among glucose-sensitive cells than among glucose-insensitive cells. The activity of many glucose-sensitive neurons decreased during the bar pressing and reward periods. A small population of glucose-sensitive neurons responded to cue stimuli. The results suggest that glucose-sensitive neurons are mainly involved in the drive and/or reward mechanism of feeding behavior, and that these cells may have specific roles in neural control of hunger-motivated food acquisition.

Pathophysiological process after transient ischemia of the middle cerebral artery in the rat

For the understanding of pathophysiology of the cerebral ischemia, we made a transient intraluminal occlusion of the middle cerebral artery in the rat and investigated the appearance of collapsed dark neurons and the extravasation of serum proteins using argyrophil III method and immunohistochemistry. In the acute stage (minutes to 3 days), dark neurons appeared in the lateral half of the ipsilateral striatum and adjacent cortex which formed the ischemic core of this model. Dark neurons also appeared in the ipsilateral reticular thalamic nucleus, hippocampus, and amygdala. The extravasation of serum proteins, albumin, leucocyte common antigen, immunoglobulin G, complement factor C3, as well as heat shock protein 70, was observed not only in the ischemic but sometimes also in the contralateral hemisphere. Among these, the expression of IgG and C3 was most prominent in the ischemic core. In the chronic stage (1 to 3 months), the ischemic core changed into the porencephaly, and the ventrobasal nucleus of the thalamus got also involved in the necrosis. A strong microgliosis was observed in the substantia nigra pars reticulata. Data suggest, that among many mechanisms that contribute to ischemic neuronal death, the activation of immune response, due to the damage of blood-brain barrier and the extravasation of serum proteins could promote the ischemic cell death in the brain.

Amygdalar noradrenergic and dopaminergic mechanisms in the regulation of hunger and thirst-motivated behavior

The feeding behavior of rats was studied after neurochemical damage of the amygdalar terminal fields of mesolimbic dopaminergic (DA) and coerular noradrenergic (NA) pathways. 6-Hydroxydopamine (6-OHDA) or 6-hydroxydopa (6-OHDOPA) were injected bilaterally into the central part of amygdala. 6-OHDA was also injected after desmethylimipramine (DMI) pretreatment in order to study the selective destruction of DA terminals. The body weight increased after 6-OHDA injection and a mild hyperphagia and hyperdipsia developed. The 6-OHDA plus DMI treatment resulted in body weight decrease, hypophagia and hypodipsia. These effects were dose-dependent. While a high dose of 6-OHDOPA (15 mug/mul) decreased the body weight, an increase of weight was observed after a low dose (4 mug/0.5 mul). After 6-OHDA, 6-OHDA plus DMI or the high dose of 6-OHDOPA the DA concentration dropped significantly in the amygdala while low-dose 6-OHDOPA resulted in DA increase. In every case there was a parallel change in striatal DA content. The amygdalar NA concentration decreased after both 6-OHDA and the high dose of 6-OHDOPA. There was no change in NA levels after 6-OHDA plus DMI treatment and the NA concentration increased after the injection of a low dose of 6-OHDOPA. When DA/NA ratio was calculated the results showed that body weight increases were accompanied by a relative deficit in NA while a relative deficit of DA was present if body weight decreased. Our results suggest that the amygdalar balance of these transmitters may play an important role in the regulation of body weight and the contradictions of results with electrolytic lesions in the amygdala can be resolved at transmitter level.

Alterations of conditioned taste aversion after microiontophoretically applied neurotoxins in the medial prefrontal cortex of the rat

The prefrontal cortex (PFC) has been reported to be essential in neural control of feeding. In the present study, we aimed to provide a complex characterization of behavioral consequences of PFC microlesions in CFY rats. Kainic acid (KA) was microiontophoretically applied into the mediodorsal division of PFC to damage intrinsic neurons, whereas in another group of rats, 6-hydroxydopamine (6-OHDA) was microiontophoretized into the same region to destroy catecholaminergic (CA) projection fiber terminals. Body weights, food and fluid intake of both lesioned and (sham-operated or intact) control animals were daily measured. Effects of intracellular dehydration and water deprivation were also studied. Open field activity, stereotyped behaviors, and orientation towards visual and somesthetic stimuli were pre- and postoperatively tested. To examine hypothesized consequences of mPFC microlesions on central taste information processing, the acquisition and retention of saccharine conditioned taste aversion (CTA) were studied. No major changes were recorded in body weights, food and water consumption. Dehydration or deprivation similarly increased water intake in all animals. Scores of open field activity and stereotyped behaviors in the 6-OHDA group were significantly higher than those of the other groups. As the main findings of the present studies, both KA and 6-OHDA lesioned rats displayed significant deficits in CTA acquisition and retention tests. These results suggest that the medial PFC has a substantial role in both the formation and the retrieval of CTA. Furthermore, the present findings also indicate the general significance of prefrontal CA mechanisms in the organization of goal-directed, adaptive behaviors.

Accumbens cholinergic interneurons play a role in the regulation of body weight and metabolism.

The aims of the present study were (1) to determine whether selective lesions of the accumbens cholinergic interneurons impair feeding and body weight regulation, and (2) to characterize the nature of disturbances using motivational and metabolic challenges. Rats with bilateral cholinotoxic (AF64A) lesions in the nucleus accumbens showed a significant and lasting lag in body weight gain in comparison to the sham-operated controls. This failure to gain weight was not due to a decrease in feeding because lesioned rats actually ate more food and drank more water than controls under basal conditions. Lesion-induced deficits were also exposed when the rats were challenged with food deprivation or cold exposure. Lesioned rats ate less than controls when 24 h food deprived and maintained both a higher core temperature and a higher metabolic rate than controls following either 24-h food deprivation or exposure to cold. Thyroid hormones, insulin, and blood glucose levels were, however, within the physiological range, and no sensory and motor disturbances were observed. The results suggest that the altered body weight regulation is partly due to the enhanced metabolic responsiveness to stress. Possible explanations for the effects of the lesions are also discussed in the context of motivational alterations, including possible dopamine-acetylcholine interactions.