Role of brain norepinephrine in neuroleptic-induced catalepsy in rats

Drug effects on active immobility responses: what they tell us about neurotransmitter systems and motor functions

The literature reviewed indicates that active immobility can be promoted by systemic injections of various neurotransmitter systems, as follows: (1) Dopaminergic blockade of both D1 and D2 receptor subtypes. (2) Cholinergic agonism of both muscarinic and nicotinic receptors. (3) Noradrenergic agonism of both alpha-1 and alpha-2 receptors (but these agonists may interfere with haloperidol- and reserpine-induced catalepsy). (4) GABA agonism. (5) Histamine agonism, particularly at the H1 receptor. (6) Opiate agonism, including action of many endogenous opiate peptides, particularly those affecting mu and delta receptors. (7) Agonism by certain other peptides (neurotensin, cholecystokinin). Among the major interactions of neurotransmitter systems that regulate immobility, are the following: (1) Cholinergic-dopaminergic (cholinolytics disrupt catalepsy of dopaminergic blockade and dopaminergic agonists tend to disrupt cholinomimetic catalepsy). (2) Opiate-induced catalepsy is antagonized by the dopamine agonist, apomorphine, but is enhanced by amphetamine. It is also antagonized by certain alpha-2 adrenergic agonists, while it does not seem to be antagonized by anticholinergics. (3) Numerous other interactions have been reported, involving opiates and MSH, serotonin and dopamine mimetics, serotonin and ketamine, GABA and neuroleptics, neurotensin and anticholinergics and histamine. The significance of the multiple neurotransmitter systems is unknown. One possible explanation is that the various neurotransmitter systems participate in mediating the sensory inputs that are involved in triggering immobility and regulate the higher-order limbic and basal ganglia processing reactions that engage a final motor output pathway from the brainstem. The brain is assumed to contain two sets of systems, each with its own, or possibly overlapping, set of neurotransmitter systems, that promote either active immobility or locomotion. The systems reciprocally inhibit each other. Another view, not mutually exclusive, is that output from the locomotor-promoting system provides a negative feedback, via the active immobility pathways, to act as a "brake" on movement, while at the same time maintaining the muscular tonus that is characteristic of active immobility.

Social factors influence haloperidol-induced catalepsy in rat

This study employed manipulations which presumably influence social interactions in rats: (1) paired housing with a heavier conspecific and (2) exposure to the odors of other rats. The dependent variable was the akinetic state induced by haloperidol, a neuroleptic and dopamine antagonist. In Experiment 1, adult male Long-Evans hooded rats were matched by weight and caged alone or in pairs with one rat 30 g heavier than its cagemate. All rats received haloperidol (1.5 mg/kg) and catalepsy testing. Heavy rats showed more catalepsy than the lighter member of pairs or weight-matched, singly housed controls. In Experiment 2, adult male rats were left unrecaged or were recaged into cages with bedding recently soiled by females or other adult males. After haloperidol (1.0 mg/kg), the rats exposed to bedding soiled by other adult males showed more catalepsy than did the control groups. Thus, the results of both experiments indicated that social factors can influence the akinesia induced by dopamine antagonists.

Alpha noradrenergic agonists promote catalepsy in the mouse

Alpha adrenergic receptors are important in motor control. Adrenergic drugs reportedly modulate the catalepsy caused by other agents, such as opiates and neuroleptics. We tested a variety of adrenergic agonists and blockers in a nondrug, mouse model of catalepsy. A major cataleptic effect was produced by both alpha agonists, phenylephrine (0.5 to 3 mg/kg, IP) and clonidine (0.5 to 2 mg/kg), and this catalepsy was antagonized by pretreatment with both of the respective antagonists, phenoxybenzamine (alpha-1) and yohimbine (alpha-2) (p less than 0.0001). The mixed beta agonist, isoproterenol (2 mg/kg), appeared to have a minor cataleptic effect, and this was abolished by beta antagonist. Open-field locomotor scores during the same treatments revealed that catalepsy and hypokinesia are dissociable.

Haloperidol in large doses reduces the cataleptic response and increases noradrenaline metabolism in the brain of the rat

The neurochemical basis for the clinical observation that some patients receiving a large dose of haloperidol exhibit no extrapyramidal side effects was investigated in rats. Haloperidol at doses of 1, 2.5, 5, 7.5 and 10 mg/kg (i.p.) caused a dose-dependent decrease in the duration of catalepsy. Haloperidol at a dose of 10 mg/kg induced catalepsy lasting for only 20% of that obtained with 1 mg/kg. Haloperidol decreased the content of noradrenaline in the frontal cortex and thalamus in a dose-dependent manner, while the content of 3-methoxy-4-hydroxyphenylglycol (MHPG) showed a dose-dependent increase in the same areas of the brain. Thus, there was an inverse relationship between the duration of catalepsy and the ratio of 3-methoxy-4-hydroxyphenylglycol to noradrenaline in the frontal cortex or thalamus. The concomitant administration of 20 mg/kg of phenoxybenzamine with 10 mg/kg of haloperidol induced a long-lasting catalepsy. The result may indicate that the increased metabolism of noradrenaline by large doses of haloperidol was not secondary to the blocking of dopaminergic receptors. In contrast, haloperidol caused a dose-dependent decrease in the content of homovanillic acid and 3,4-dihydroxyphenylacetic acid in the striatum and mesolimbic area. These results indicate that noradrenergic hyperfunction in the frontal cortex or thalamus induced by large doses of haloperidol may reduce the cataleptogenic effect of the drug via indirect stimulation of a dopaminoceptive neuron in the striatum or mesolimbic area.

Possible function of alpha 1-adrenoceptors in the CNS in anaesthetized and conscious animals

The influence of St 587 (2-(2-chloro-5-trifluoromethylphenylimino)imidazolidine), a selective alpha 1-adrenoceptor agonist which easily penetrates the blood-brain barrier, was tested on behavior and cardiovascular functions, respectively. The substance (up to 10 mg/kg subcutaneously (s.c.)) did not increase the exploratory activity of naive mice. The hexobarbitone 'sleeping' time in mice was reduced in a dose-dependent manner (St 587 ED50 = 14.4 mg/kg s.c.). Haloperidol 10 mg/kg s.c. induced catalepsy which was antagonized by St 587 in a dose-dependent manner (ED50 = 2.7 mg/kg i.p.). Conversely, the alpha 1-adrenoceptor-blocking agents prazosin and corynanthine elicited catalepsy in mice which had been treated with a subthreshold dose (2 mg/kg s.c.) of haloperidol; the ED50 values of the antagonists were 0.26 and 4.7 mg/kg i.p., respectively. In anaesthetized cats blood pressure and heart rate were not affected by 100 micrograms/kg St 587 injected into the left vertebral artery. In conscious dogs with beta-adrenoceptors blocked, the drug was without effect (100 micrograms/kg intracisternally) on vagally mediated reflex bradycardia, as evoked by intravenous noradrenaline injection. As a positive control the alpha 2-adrenoceptor agonist B-HT 920 which is equipotent to St 587 with respect to peripheral vasopressor effects in rats was injected with 10 micrograms/kg intracisternally and facilitated the reflex bradycardia. It is concluded that alpha 1-adrenoceptors within the brain mediate behavioral activation in states of CNS depression but remain without effect on cardiovascular centers.

The involvement of serotonergic neurons in the central nervous system as the possible mechanism for slow head-shaking behavior induced by methamphetamine in rats

Following the IV administration of d-methamphetamine (MA), rats showed slow head shaking (SHS) and stereotyped gnawing (SG) behaviors in a dose-dependent manner. Methysergide, cyrpoheptadine, and p-chlorophenylalanine given intracerebroventricularly (ICV) or systemically significantly blocked SHS behavior induced by 10 mg/kg MA. Combined administration of L-5-hydroxytryptophan and peripheral decarboxylase inhibitor (Ro 4-4602) enhanced SHS behavior. Tyrosine hydroxylase inhibitor (H44/68) blocked SG behaviors, but dopamine-beta-hydroxylase inhibitors (FLA 63 and U-14, 624) and combined administration of L-3,4-dihydroxyphenylalanine and Ro-4-4602 enhanced it. These drugs did not affect SHS behavior. Phentolamine, phenoxybenzamine, clonidine, isoproterenol, and propranolol given ICV or systemically showed no effect on either SHS or SG behaviors. These results suggest that SHS behavior is produced by the activation of seronergic neurons in the central nervous system and are consistent with the view that SG behaviors are mediated through the release of dopamine. Some neuroleptics inhibited SHS as well as SG behaviors, but the older of inhibitory activity of neuroleptics onSHS behavior was quite different from their effects on SG behaviors induced by MA or apomorphine.