Disposition of hexobarbitone and antipyrine in DOCA-hypertensive rats.

The disposition of antipyrine and hexobarbitone, and their effects on drug metabolizing hepatic enzymes have been investigated in DOCA-hypertensive rats. Antipyrine pharmacokinetic parameters were the same in hypertensive and control animals. Hexobarbitone sleeping time was longer in hypertensive rats compared with controls, while the activity of hepatic hexobarbitone hydroxylase was the same in both groups. Hepatic aminopyrine-N-demethylase activity was elevated in hypertensive rats while aniline hydroxylase and aryl hydrocarbon hydroxylase were lower. Glucuronyl transferase was the same in both groups. The sensitivity of the central nervous system of hypertensive rats to hexobarbitone was not altered, as determined by hexobarbitone concentration in blood and in brain. The total hepatic blood flow (arterial and portal) was significantly increased. Thus it is suggested that the difference in the disposition of the two drugs is probably not due to drug metabolizing enzyme activity. It is likely that the increase in total hepatic blood flow and rapid saturation of hepatic hexobarbitone metabolizing enzymes have significant roles in the slower metabolism and increased activity of hexobarbitone in hypertensive rats as compared with control rats.

Cardiovascular and hormonal changes following haemorrhage in the anaesthetized Brattleboro rat with an extracorporeal circulation.

An extracorporeal circulation technique was developed for use in rats to provide equilibrated blood samples for multiple hormone assays. The inclusion of the extracorporeal circulation did not significantly alter arterial blood pressure, cardiac output, heart rate or central venous pressure in either Brattleboro rats with hereditary diabetes insipidus (BDI) or normal rats of the parent Long Evans (LE) strain. Plasma adrenaline and noradrenaline levels did not alter in either BDI or LE rats following inclusion of the extracorporeal circulation but the vasopressin concentration rose significantly in the LE rats. The impaired recovery of the mean arterial blood pressure following haemorrhage in the BDI rats compared with normal LE animals was not further influenced by the inclusion of the extracorporeal circulation. Plasma vasopressin and adrenaline (but not nor-adrenaline) levels were significantly raised during, and after, haemorrhage in the LE rats while in the BDI rats only plasma adrenaline levels were significantly increased. These results show that the insertion of an extracorporeal circulation into an anaesthetized BDI or LE rat does not adversely affect the cardiovascular system despite the increase in baseline plasma vasopressin concentration in normal rats, and its subsequent removal provides an additional equilibrated blood sample for multiple hormone assay within the same animal. The increased release of both adrenaline and vasopressin (but not noradrenaline) after haemorrhage in the same animal is detected using this technique, and the importance of vasopressin to the normal recovery process confirmed.

Effects of carotid occlusion and angiotensin II on vasopressin secretion in intact and vagotomized conscious rabbits.

Experiments were performed in conscious rabbits with sectioned aortic depressor nerves to determine whether there is an interaction between angiotensin II (Ang II) and the baroreceptor reflexes in the control of arginine vasopressin (AVP) secretion. Baroreceptor reflexes were activated by a 5- or 10-min period of bilateral carotid occlusion with or without background infusion of Ang II at 10 or 20 ng/kg.min. Carotid occlusion increased mean arterial pressure, right atrial pressure, and heart rate, but did not change plasma AVP (PAVP) concentration. Infusion of Ang II at 10 ng/kg.min increased PAVP from 4.0 +/- 0.9 to 6.3 +/- 1.8 pg/ml (P less than 0.05). Carotid occlusion during Ang II infusion produced the same cardiovascular changes as before Ang II, but still failed to increase PAVP. Because increased atrial pressure can inhibit AVP secretion, the experiments were repeated in acutely vagotomized rabbits. Vagotomy increased heart rate but did not change mean arterial pressure or PAVP. Carotid occlusion after vagotomy increased PAVP from 2.2 +/- 0.2 to 3.3 +/- 0.5 pg/ml (P less than 0.05). Ang II infusion again increased PAVP but did not enhance the AVP response to carotid occlusion (2.9 +/- 0.4 to 3.9 +/- 0.7 pg/ml). These results provide further evidence for a role of the carotid sinus baroreceptors and vagal afferents in the control of AVP secretion and demonstrate that Ang II stimulates AVP secretion in rabbits. However, they do not reveal any interaction between Ang II and the baroreceptor reflexes in the control of AVP secretion.

The cardiovascular effects of vasopressin after haemorrhage in anaesthetized rats.

The cardiovascular effects of an acute haemorrhage (2% of the body weight) were studied over a 60 min period in three groups of rats: (a) Brattleboro rats with hereditary hypothalamic diabetes insipidus (b.d.i.) lacking circulating vasopressin, (b) control rats of the parent Long Evans (l.e.) strain, and (c) l.e. rats treated with an antagonist of the vascular action of vasopressin. Prior to the haemorrhage there were no significant differences between the three groups of rats with respect to mean arterial blood pressure, cardiac output, stroke volume or total peripheral resistance. Following the haemorrhage cardiac output and stroke volume were severely reduced in all three groups of rats. Total peripheral resistance was relatively unaffected in antagonist-treated l.e. rats and b.d.i. rats, but rose substantially in response to the loss of blood in the control l.e. group. Both total peripheral resistance and mean arterial blood pressure were markedly greater in the untreated l.e. control rats than in the other two groups of animals during the first 20 min after haemorrhage. The mean heart rate measured in Brattleboro rats was elevated compared with that of control l.e. rats throughout the experiment and, in addition, significantly greater than that of antagonist-treated l.e. rats during the first 40 min after the haemorrhage. Survival rate for the b.d.i. rats following the 2% haemorrhage was lower than that for l.e. control rats and antagonist-treated l.e. rats. The results indicate that the recovery of the blood pressure following an acute arterial haemorrhage is significantly influenced by vasopressin, particularly during the first 20 min, and that the predominant effect of the hormone is to increase the total peripheral resistance. The higher mortality associated with volume depletion in the b.d.i. rats is unlikely to be directly related to the absence of the vascular action of vasopressin, since administration of the vasopressin antagonist to normal l.e. rats does not reduce their survival rate.