Intracranial self-stimulation of the lateral hypothalamus of the rat was markedly increased by d-amphetamine administration and by food deprivation. In contrast, similar self-stimulation response rates obtained in the same animals from the medial frontal cortex were unaffected by food deprivation and only slightly increased by d-amphetamine administration. Furthermore, a large difference between d-vs. Z-amphetamine on response rate was obtained for lateral hypothalamic but not for medial frontal cortex self-stimulation. The results of this study were consistent with a noradrenergic self-stimulation system for the lateral hypothalamus. Medial frontal cortex self-stimulation, however, appears to be mediated by a neuroanatomical and neurochemical system different from that of the lateral hypothalamus.
Three groups of rats received haloperidol 0.5 mg/kg IP twice daily for 20 days, twice daily for 10 days, or every other day for 40 days. The rats in control groups received saline injections according to the same schedules as the experimental groups. During the chronic treatments, spontaneous motor activity was measured as an indicator of behavioral tolerance, and at the completion of treatments, limbic and striatal homovanillic acid (HVA) levels were determined in order to provide a biochemical indication of tolerance. Both of the haloperidol groups on twice-daily injection schedules exhibited a trend towards recovery of spontaneous motor activity during treatment, indicative of behavioral tolerance, as well as reduced HVA levels indicative of near complete biochemical tolerance. The group receiving haloperidol every other day exhibited a trend toward behavioral intolerance to haloperidol, along with elevated HVA levels that indicated a complete absence of tolerance. The suggested importance of treatment schedule rather than cumulative drug dosage in the development of tolerance to haloperidol may have significance to long-term side effects of chronic neuroleptic treatment such as tardive dyskinesia and clinical issues such as drug holidays.
Studies were carried out in the rat to detemine if hypothalamic lesions which caused polydipsia and polyuria had their effect mediated through an alteration of the ability of the neurohypophyseal system to release ADH. Rats with medial preoptic lesions hadincreased water intake while on ad libitum access to water and slightly impaired ability to conserve water following dehydration, but with no impairment of urine-concentrating ability. These were associated with an increase in plasma osmolality both during ad libitum fluid intake and after dehydration. Urinary ADH excretion was at leastas great as in shamoperated controls during ad libitum water intake, but failed to increase during dehydration in spite of a marked increase in plasma osmolality. Pituitary ADH content did not differ from control animals either during ad libitum water intake of after dehydration. Animals with lesions in the lateral preoptic and septal areas did not differ from control animals during ad libitum fluid intake and after dehydration even though lateral preoptic lesions produced polydipsia. In all animals, lesions were remote from the supraoptic nuclei, which showed no histological evidence of damage. It is concluded thatareas of the central nervous system away from the supraoptic nuclei are involved in the regulation of both water intake and ADH release.
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