Faculty Bibliography

The incentive-motivating effects of external stimuli are dependent, in part, upon the internal need state of the organism. The increased rewarding efficacy of food as a function of energy deficit, for example, has obvious adaptive value. The enhancement of food reward extends, however, to drugs of abuse and electrical brain stimulation, probably due to a shared neural substrate. Research reviewed in this paper uses lateral hypothalamic electrical stimulation to probe the sensitivity of the brain reward system and investigate mechanisms through which metabolic need, induced by chronic food restriction and streptozotocin-induced diabetes, sensitizes this system. Results indicate that sensitivity to rewarding brain stimulation varies inversely with declining body weight. The effect is not mimicked by pharmacological glucoprivation or lipoprivation in ad libitum fed animals; sensitization appears to depend on persistent metabolic need or adipose depletion. While the literature suggests elevated plasma corticosterone as a peripheral trigger of reward sensitization, sensitization was not reversed by meal-induced or pharmacological suppression of plasma corticosterone. Centrally, reward sensitization is mediated by opioid receptors, since the effect is reversed by intracerebroventricular (i.c.v.) infusion of naltrexone, TCTAP (mu antagonist) and nor-binaltorphimine (kappa antagonist). The fact that these same treatments, as well as i.c.v. infusion of dynorphin A antiserum, block the feeding response to lateral hypothalamic stimulation suggests that feeding and reward sensitization are mediated by a common opioid mechanism. Using in vitro autoradiography, radioimmunoassays and a solution hybridization mRNA assay, brain regional mu and kappa opioid receptor binding, levels of prodynorphin-derived peptides, and prodynorphin mRNA, respectively, were measured in food-restricted and diabetic rats. Changes that could plausibly be involved in reward sensitization are discussed, with emphasis on the increased dynorphin A1-3 and prodynorphin mRNA levels in lateral hypothalamic neurons that innervate the pontine parabrachial nucleus, where mu binding decreased and kappa binding increased. Finally, the possible linkage between metabolic need and activation of a brain opioid mechanism is discussed, as is evidence supporting the relevance of these findings to drug abuse

Diabetic rats display changes in opioid pharmacology and brain regional levels of opioid peptides and prodynorphin mRNA. Previous investigations of opioid receptor binding, carried out in whole-brain homogenates, have, however, failed to detect changes. In the present study, quantitative autoradiography was used to measure mu and kappa opioid receptor binding in discrete brain regions of streptozotocin-treated diabetic rats. Measurement was limited to regions that previously displayed opioid binding changes in chronically food-restricted rats, since our primary aim is to identify brain mechanisms that mediate adaptive responses to persistent metabolic need and adipose depletion. Diabetics displayed strong trends or statistically significant changes which matched seven of the thirteen binding changes observed in food-restricted rats. In no case did diabetics display changes in the opposite direction. The two statistically significant changes common to food-restricted and diabetic rats are increased kappa binding in the medial preoptic area and decreased mu binding in the lateral habenula. The possible functional significance of these changes is discussed

Tardive dyskinesia (TD) is a frequently occurring side effect of treatment with neuroleptic antipsychotic drugs. TD is a persistent and often irreversible syndrome characterized by abnormal movements, including lingual and orofacial dyskinesia, grimacing, tics, choreic movements of the limbs and trunk, and athetosis and dystonia. In some patients the muscles of respiration and speech may also be involved. There is no established treatment for TD

Chronic food restriction sensitizes animals to the rewarding effects of food, drugs and lateral hypothalamic electrical stimulation. The present study employed a curve-shift analysis of lateral hypothalamic self-stimulation (LHSS) to evaluate whether the elevated plasma corticosterone levels that accompany food restriction mediate the sensitization of reward. In Experiment 1, two adrenocorticoid synthesis inhibitors, aminoglutethimide and metyrapone, were administered to food-restricted rats and the magnitude of plasma corticosterone suppression was determined at two post-administration time points. In Experiment 2, these compounds were administered to ad libitum fed and food-restricted rats whose LHSS behavior was evaluated at a time coincident with suppression of corticosterone. It was found that neither compound reversed the sensitizing effect of food-restriction on the rewarding efficacy of brain stimulation. However, aminoglutethimide (50 mg/kg) produced an increase in maximal response rates (a performance factor) across groups while metyrapone (100 mg/kg) produced a decrease. The most interesting result of this study was that 2 h after aminoglutethimide administration, when corticosterone levels had recovered from suppression, the rewarding efficacy of LHSS increased markedly in food-restricted rats. Possible explanations for this effect, including adrenocortical rebound, alterations in neurosteroid synthesis, and exacerbation of metabolic need are discussed

OBJECTIVE: The purpose of this report was to determine 1) the effects of chronic haloperidol treatment on cerebral metabolism in schizophrenic patients, 2) the relation between negative symptoms and haloperidol-induced regional changes in cerebral glucose utilization, and 3) the relation between metabolic change and clinical antipsychotic effect. METHOD: Cerebral glucose utilization, as determined by position emission tomography (PET), was studied in 18 male schizophrenic subjects before and after chronic treatment with haloperidol at a standardized plasma level. RESULTS: Overall, haloperidol caused a widespread decrease in absolute cerebral glucose metabolism. The cerebral metabolic response to haloperidol was blunted in patients with high pretreatment negative symptom scores. CONCLUSIONS: Taken together with the results from a previously reported PET study of the effects of an acute amphetamine challenge (in which 14 of the current subjects participated), these data suggest that the negative symptom complex is associated with diminished cerebral response to change in dopaminergic activity. This deficit cannot be solely accounted for by structural differences