Abstract
Rats were implanted with electrodes in the lateral hypothalamus, put on a 22-h food deprivation schedule and trained to bar-press for ICS and for food on a CRF schedule. Haloperidol (0.08 mg/kg) and pimozide (0.22 mg/kg) significantly decreased responding for both reinforcers, although responding for ICS was decreased more than it was for food. The same doses of these drugs did not decrease food consumption on a 15-min ad libitum test after 22-h of food deprivation, suggesting that the decreased bar-pressing for food was not the result of anorexia or reduced motivation for food. When similar rates of responding for ICS and for food were obtained on a V1 60 schedule, haloperidol (0.1 mg/kg) reduced responding for food and ICS to a similar extent. Thus, when baseline rate is controlled for, neuroleptics do not selectively reduce responding for ICS. In addition, examination of cumulative response records revealed that rather than producing an extinction curve, as would be predicted if neuroleptics reduced the rewarding properties of ICS, haloperidol produced a uniform decrease in the rate of responding throughout the experimental session. Similar results were obtained with intraventricular 6-hydroxydopamine (6-OHDA) injections. While these experiments do not exclude the possibility that dopaminergic (DA) systems participate in some central reinforcement mechanisms, they suggest that neuroleptics and 6-OHDA decrease responding for food or ICS primarily by impairing the function of DA systems critically involved in the initiation or maintenance of operant behaviour rather than by interfering with reward.
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References
Andén, N.-E., Butcher, S. G., Corrodi, H., Fuxe, K., Ungerstedt, U.: Receptor activity and turnover of dopamine and noradrenaline after neuroleptics. Europ. J. Pharmacol. 11, 303–314 (1970)
Belluzzi, J. D., Ritter, S., Wise, C. D., Stein, L.: Substantia nigra self-stimulation: dependence on noradrenergic reward pathways. Behav. Biol. 13, 103–111 (1975)
Breese, G. R., Howard, L. J., Leahy, J. P.: Effect of 6-hydroxydopamine on electrical self-stimulation of the brain. Brit. J. Pharmacol. 43, 255–257 (1971)
Cook, L., Kelleher, R. T.: Effects of drugs on behavior. Ann. Rev. Pharmacol. 3, 205–225 (1963)
Cooper, B. R., Breese, G. R.: A role for dopamine in the psychopharmacology of electrical self-stimulation of the lateral hypothalamus, substantia nigra and locus coeruleus. In: The functional significance of brain monoaminergic systems—Pharmacological and biochemical approaches (in press)
Cooper, B. R., Cott, J. M., Breese, G. R.: Effects of catecholamine-depleting drugs and amphetamine on self-stimulation of brain following various 6-hydroxydopamine treatments. Psychopharmacologia (Berl.) 37, 235–248 (1974)
Fibiger, H. C., Zis, A. P., McGeer, E. G.: Feeding and drinking deficits after 6-hydroxydopamine administration in the rat: similarities to the lateral hypothalamic syndrome. Brain Res. 55, 135–148 (1973)
Fibiger, H. C., Zis, A. P., Phillips, A. G.: Haloperidol-induced disruption of conditioned avoidance responding: attenuation by prior training or by anticholinergic drugs. Europ. J. Pharmacol. 30, 309–314 (1975)
German, D. C., Bowden, D. M.: Catecholamine systems as the neural substrate for intracranial self-stimulation. Brain Res. 73, 381–419 (1974)
Herz, A.: Drugs and the conditioned avoidance response. Int. Rev. Neurobiol. 2, 229–277 (1960)
Kelleher, R. T., Morse, W. H.: Determinants of the specificity of behavioral effects of drugs. Ergebn. Physiol. 60, 1–56 (1968)
Lippa, A. S., Antelman, S. M., Fisher, A. E., Canfield, D. R.: Neurochemical mediation of reward: A significant role for dopamine? Pharmacol. Biochem. Behav. 1, 23–28 (1973)
Liebman, J. M., Butcher, L. L.: Effects on self-stimulation behavior of drugs influencing dopaminergic neurotransmission mechanisms. Naunyn-Schmiedeberg's Arch. Pharmacol. 277, 305–318 (1973)
Liebman, J. M., Butcher, L. L.: Comparative involvement of dopamine and noradrenaline in rate-free self-stimulation in substantia nigra, lateral hypothalamus, and mesencephalic central gray. Naunyn-Schmiedeberg's Arch. Pharmacol. 284, 167–194 (1974)
McGeer, E. G., McGeer, P. L.: Catecholamine content of spinal cord. Canad. J. Biochem. Physiol. 40, 1141–1151 (1962)
Olds, J., Killam, K. F., Bach-y-Rita, P.: Self-stimulation of the brain used as a screening method for tranquilizing drugs. Science 124, 265–266 (1956)
Olds, J., Travis, R. P.: Effects of chlorpromazine, meprobamate, pentobarbital and morphine on self-stimulation. J. Pharmacol. exp. Ther. 128, 397–404 (1960)
Phillips, A. G., Brooke, S. M., Fibiger, H. C.: Effects of amphetamine isomers and neuroleptics on self-stimulation from the nucleus accumbens and dorsal noradrenergic bundle. Brain Res. 85, 13–22 (1975a)
Phillips, A. G., Carter, D. A., Fibiger, H. C.: Dopaminergic substrates of intracranial self-stimulation in caudate-putamen. Brain Res. (in press, 1975b)
Phillips, A. G., Fibiger, H. C.: Dopaminergic and noradrenergic substrates of positive reinforcement: differential effects of d- and l-amphetamine. Science 79, 575–577 (1973)
Reynolds, R. W.: The relationship between stimulation voltage and rate of hypothalamic self-stimulation in the rat. J. comp. physiol. Psychol. 51, 193–198 (1958)
Roberts, D. C. S., Zis, A. P., Fibiger, H. C.: Ascending catecholamine pathways and amphetamine-induced locomotor activity: Importance of dopamine and apparent non-involvement of norepinephrine. Brain Res. 93, 441–454 (1975)
Rolls, E. T., Rolls, B. J., Kelly, P. H., Shaw, S. G., Wood, R. J., Dale, R.: The relative attenuation of self-stimulation, eating and drinking produced by dopamine-receptor blockade. Psychopharmacologia (Berl.) 38, 219–230 (1974)
Schlechter, J. M., Butcher, L. L.: Blockade by pimozide of (+)-amphetamine-induced hyperkinesia in mice. J. Pharm. Pharmacol. 24, 408–409 (1972)
Skinner, S. E.: Neuroscience: A laboratory manual. Philadelphia: Saunders 1971
Stein, L., Ray, O. S.: Brain stimulation reward “thresholds” self-determined in rat. Psychopharmacologia (Berl.) 1, 251–256 (1960)
Stein, L., Wise, C. D.: Possible etiology of schizophrenia: Progressive damage to the noradrenergic reward system by 6-hydroxydopamine. Science 171, 1032–1036 (1971)
Valenstein, E. S.: Problems of measurement and interpretation with reinforcing brain stimulation. Psychol. Rev. 71, 415–437 (1964)
Valenstein, E. S., Weyers, W. J.: Rate-independent test of reinforcing consequences of brain stimulation. J. comp. physiol. Psychol. 57, 52–60 (1964)
Wauquier, A., Niemegeers, C. J. E.: Intracranial self-stimulation in rats as a function of various stimulus parameters. II. Influence of haloperidol, pimozide and pipamperone on medial forebrain bundle stimulation with monopolar electrodes. Psychopharmacologia (Berl.) 27, 191–202 (1972)
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Fibiger, H.C., Carter, D.A. & Phillips, A.G. Decreased intracranial self-stimulation after neuroleptics or 6-hydroxydopamine: Evidence for mediation by motor deficits rather than by reduced reward. Psychopharmacology 47, 21–27 (1976). https://doi.org/10.1007/BF00428696
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DOI: https://doi.org/10.1007/BF00428696