Characterization of dopamine receptors involved in central thermoregulation in rabbits.

Intracerebroventricularly administered dopamine produced dose dependent hyperthermia in rabbits. Haloperidol, a D1 receptor blocker produced consistent hypothermia, whereas D2 receptor blocker metoclopramide produced hyperthermia, pretreatment with haloperidol competitively blocked the hyperthermic response of dopamine. Pretreatment with metoclopramide augmented the onset and peak response of dopamine. It is suggested that D1 receptors are involved in producing hyperthermia and D2 receptors in hypothermia.

Mechanism of haloperidol-induced miosis.

Haloperidol administration (iv) has been shown to produce miosis in dogs. In the present study on rabbits, haloperidol administration (iv) produced dose-related miosis but when administered intracerebroventricularly, it failed to produce any change in pupillary size. Higher degree of miosis was observed when haloperidol was administered directly into the anterior chamber of eye. Haloperidol pretreatment failed to significantly modify the mydriasis produced by phenylephrine or atropine. These observations suggest that the miosis produced by haloperidol is a peripheral effect, and also that the miosis is not mediated through the blockade of alpha adrenoceptors of radial muscles or stimulation of cholinoceptors of circular muscles of iris.

Characterization of alpha-adrenoceptors involved in central thermoregulation in rabbits.

Intracerebroventricular (icv) injection of methyldopa induced body temperature changes in the rabbits. The dose of 100 micrograms/kg did not produce any significant change on body temperature whereas 250 micrograms/kg of the drug induced hyperthermia. Higher dose of 500 micrograms/kg produced initial hypothermia which was followed by hyperthermia. On further increase of the dose to 1 mg/kg, consistent hypothermia was evident. Prazosin, a specific post-synaptic alpha 1 adrenoceptor blocker, induced hypothermia whereas piperoxan (presynaptic alpha 2 antagonist) produced hyperthermia. The pretreatment with prazosin, blocked the hyperthermic response of methyldopa. The initial hypothermia by 500 micrograms/kg of methyldopa was also potentiated. The pretreatment with piperoxan completely blocked the hypothermia but had no effect on hyperthermic response of methyldopa. Pretreatment of rabbits with both prazosin and piperoxan completely blocked the hypothermia as well as hyperthermic response of methyldopa. Thus it appeared that both presynaptic alpha 2 and postsynaptic alpha 1 adrenoceptors are involved in central thermoregulation in rabbits.

Evidence for the presence of osmoreceptors in medulla of the dog.

Hypertonic solutions of different substances were injected into the vertebral artery of dogs anesthetized with chloralose, preventing their access to the hypothalamic osmoreceptors by ligating the basilar artery and both the external carotid arteries. The hypertonic solution of sodium chloride produced graded inhibition of water diuresis and a concomitant rise in plasma antidiuretic hormone (ADH) level; hypertonic solution of glucose produced lesser effect. Hypertonic urea solution, on the other hand, did not alter the course of water diuresis. It was concluded that osmoreceptors are also present in the medulla which sense the changes in blood osmolarity and accordingly modify the ADH release.

Central mechanism of vasopressin-induced changes in antidiuretic hormone release.

1. Intracerebroventricularly (i.c.v.) administered vasopressin (0.001-1.0 u) in dogs anaesthetized with chloralose produced adose-dependent increase in urine flow with a concomitant decrease in the levels of antidiuretic hormone (ADH) in jugular vein blood. 2. Higher doses of vasopressin (1.5-2.0 u, i.c.v) on the other hand had an antidiuretic effect and produced an increase in blood ADH level. 3. Pretreatment (i.c.v.) with a beta-adrenoceptor antagonist completely blocked the diuretic response of low doses of vasopressin (i.c.v.) but did not influence the antidiuretic response obtained with high doses. 4. Repeated administration of vasopressin (1.0 u, i.c.v.) induced tachyphylaxis; central catecholamine depletion with tetrabenazine significantly inhibited the vasopressin-induced diuretic response. 5. It is concluded that intracerebroventricular vasopressin-induced changes in ADH secretion are mediated through the release of catecholamines in the central nervous system.

Mechanism of histamine-induced antidiuretic response.

1. In dogs anaesthetized with alpha-chloralose, intracerebroventricular (i.c.v.) injection of histamine induced antidiuresis and increase in jugular vein blood antidiuretic hormone (ADH) level but no change in urinary electrolytes. The mechanism of the histamine-induced antidiuretic response was analysed by the use of pharmacological agents.2. Histamine (i.c.v.) in 1-20 mug doses produced a variable effect on urine outflow as well as on the blood ADH concentration; however, higher doses (25-500 mug) of histamine elicited a dose-dependent antidiuretic response with concomitant rise in blood ADH titre.3. Repeated administration of high doses of i.c.v. histamine (400 mug) elicited a diminishing antidiuretic response which was not observable after the fourth dose, thus exhibiting tachyphylaxis. The antidiuretic response to histamine could be restored by central administration of noradrenaline (500 mug).4. Central pretreatment with mepyramine (5 mg) prevented the histamine-induced antidiuresis. Atropine (2 mg i.c.v.) was ineffective in blocking the antidiuretic effect of histamine. A diuretic response to histamine (400 mug i.c.v.) was obtained in phenoxybenzamine (i.c.v.) pretreated animals; this response could be blocked by i.c.v. injection of propranolol. Tetrabenazine pretreatment prevented the antidiuretic response to histamine.5. The results of the study lead us to conclude that histamine releases central catecholamines which activate the central adrenergic mechanism for the release of antidiuretic hormone.

Central cholinergic and adrenergic mechanisms in the release of antidiuretic hormone.

1. Studies on the urine outflow, blood ADH concentration and electrolyte excretion were carried out in alpha-chloralose anaesthetized hydrated dogs; the agonists and antagonists of specific cholinoceptors and adrenoceptors were injected by the intracerebroventricular technique, to delineate the role of the C.N.S. receptors in the control of ADH secretion.2. Central injection of acetylcholine elicited a dose-dependent antidiuretic response which was associated with an increase in the blood ADH titre. Central atropinization partially blocked the antidiuretic response. The remaining antidiuretic response was reversed to a diuretic one by further pretreatment with phenoxybenzamine. The diuretic response thus obtained could be blocked by propranolol.3. The alpha-adrenoceptor agonists, phenylephrine and noradrenaline, induced dose-dependent antidiuretic responses with a concomitant rise in blood ADH concentration. Their effect could be blocked by pretreatment centrally with phenoxybenzamine. Low doses of adrenaline induced a diuretic response and a decrease in blood ADH concentration, higher doses elicited a dose-dependent antidiuretic response and increase in the titre of ADH in blood. Central phenoxybenzamine pretreatment reversed the antidiuretic effect of high doses of adrenaline to a diuretic effect which could be blocked by propranolol.4. Isoprenaline elicited a dose-dependent diuretic response and a decrease in blood ADH titre and propranolol competitively blocked the effect of isoprenaline.5. It is concluded that central muscarinic cholinoceptors and the alpha-adrenoceptors are concerned in the release of ADH, whereas the beta-adrenoceptors are concerned with inhibition of ADH release.