It is known that vasopressin decreases PRA and heart rate and increases blood pressure and plasma corticosteroid concentration. The purpose of this study was to determine the plasma concentration of vasopressin required to produce these effects. Arginine vasopressin was administered iv to five normal conscious dogs as priming injections of 0.1, 0.5, 1.0, 2.5, 5.0, and 10.0 ng/kg, followed by infusions of 0.01, 0.05, 0.1, 0.25, 0.5, and 1.0 ng/kg x min, respectively, for 30 min. These doses produced increases in the plasma vasopressin concentration (+/- SE) of 1.0 +/- 0.8, 2.1 +/- 4.3, 4.3 +/- 1.8, 11.4 +/- 1.0, 19.7 +/- 6.4, and 30.8 +/- 7.8 pg/ml, respectively, from a basal level of 2.7 +/- 0.2 pg/ml. An increase in the plasma vasopressin concentration of 2.1 +/- 0.3 pg/ml suppressed PRA by 19 +/- 5% (P < 0.02); increases of 4.2 +/- 1.8 pg/ml or more suppressed PRA by 34 +/- 12% (P < 0.005). Only the highest dose of vasopressin produced a significant pressor effect (9 +/- 3 mm Hg; P < 0.05) or lowered the heart rate (18 +/- 4 beats/min; P < 0.005). An increase in plasma vasopressin concentration of 19.7 +/- 6.4 pg/ml was required to increase the plasma corticosteroid concentration (1.2 +/- 0.2 to 2.2 +/- 0.4 microgram/dl; P < 0.01); the largest dose of vasopressin increased the plasma corticosteroid concentration from 1.5 +/- 0.1 to 2.4 +/- 0.6 microgram/dl (P < 0.02). Twenty-four-hour water deprivation in the same dogs increased the plasma vasopressin concentration from 2.5 +/- 0.2 to 7.4 +/- 0.6 pg/ml (P < 0.01). Nonhypotensive hemorrhage in another group of dogs increased the plasma vasopressin concentration from 2.5 +/- 0.2 to 47.4 +/- 16.8 pg/ml (P < 0.05). These data indicate that elevations in the plasma vasopressin concentration within the range observed during 24 h of water deprivation and nonhypotensive hemorrhage produced significant decreases in renin secretion and heart rate and elevations in blood pressure and corticosteroid secretion.
SUMMARY Inflatable suits were constructed for lower body compression in pigs and dogs. The suit for pigs encompassed hindquarters and part of the abdomen, and the smaller suit for dogs compressed only the hindquarters, leaving free the abdominal cavity. In conscious, diazepam-pretreated pigs, the compression lasted 30 minutes; during that period the blood pressure increased 50/38 mm Hg over the baseline. In chloralose-anesthetized dogs, the compression was extended to 3 hours; the blood pressure increase was 44/53 mm Hg. Blood pressure fell to the baseline immediately after decompression in both animals. In both species the substantial blood pressure increase was due to an increase of vascular resistance; this did not induce the expected baroreceptor-mediated bradycardia. In dogs, the blood pressure increase was accompanied by a large increase of plasma norepinephrine (from 179 to 975 pg/ml). To test whether the increase of vascular resistance reflected the mechanical compression of the vessels under the suit, animals were pretreated with trimethaphan. In pigs the trimethaphan substantially decreased the vascular resistance and the blood pressure response. This indicated that a portion of the vasoconstriction occurred in areas outside the suit. Lower body compression is a new model to cause prolonged blood pressure elevation by noninvasive and nonpharmacologic means. The mechanism of the blood pressure elevation requires further investigation. (Hypertension 4: 782-788, 1982) KEY WORDS • cardiac output • hemodynamics • right atrial pressure • norepinephrine * vascular resistance • trimethaphan A S a follow-up to our work on the role of cardiac receptors in the regulation of renin release, 1 we searched for a practical way to translocate blood from the lower part of the body to the cardiopulmonary region. A suit for lower body compression of pigs was constructed. It soon became evident that external compression of the lower body induces a prolonged increase of blood pressure. This blood pressure elevation became the main focus of our research. A smaller suit that compresses only the hindquarters but not the abdomen of dogs was then constructed to further investigate this blood pressure response. Large and prolonged blood pressure elevations were also seen in dogs.The hemodynamic characteristics of the sustained blood pressure response to the lower body compression in pigs and to hindquarter compression in dogs are the subject of this report. Material and Methods PigsNine young male Yorkshire pigs weighing between 30 and 60 kg were used in this study. Aortic pressure was measured via a Herd-Barger catheter 2 inserted in the thoracic part of the descending aorta, and central venous pressure was measured through a similar catheter with its tip placed at the confluence of the superior and inferior vena cavae. Both pressures were monitored by means of Statham strain gauges and recorded on a Grass polygraph. Relative cardiac output was measured with an electromagnetic flow probe (Zapeda Instruments, Seattle, Washing...
The purpose of this study was to determine whether centrally administered renin stimulated vasopressin secretion. Vasopressin was not measured directly, but, instead, changes in urinary water excretion in anesthesized dogs undergoing a water excretion in anesthetized dogs undergoing a water diuresis were used as an index of changes in vasopressin secretion. Intraventricular injection of hog renin in a dose of 0.1 Goldblatt unit produced a marked decrease in urine flow which was associated with a decrease in free water clearance and an increase in urinary osmolatiy with no change in osmolar clearance. Sodium excretion increased significantly but there was no change in potassium excretion. These effects, which closely resemble those resulting from an increase in vasopressin secretion, were prevented by hypophysectomy. The antidiuretic effect clearly resulted from an action of renin in the central nervous system since renin had no effect on urine flow or osmolality when administered intravenously. Intraventricular administration of saralasin acetate, a specific antagonist of angiotensin II, completely blocked the effects of intraventricular renin indicating that these effects were mediated via the formation of angiotensin II. The data therefore indicate that there is an interaction between injected renin, brain angiotensinogen, and converting enzyme resulting in the formation of angiotensin II which stimulates the secretion of vasopressin. Additional studies are required to determine whether the brain renin-angiotensin system plays a physiological role in the regulation of a vasopressin secretion.
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