Role of the Renin-Angiotensin-Aldosterone and Kallikrein-Kinin Systems in the Control of Fluid and Electrolyte Metabolism,Renal Function,and Arterial Blood Pressure

The long-term effects of angiotensin I converting enzyme (kininase II) inhibition with Captopril on fluid and electrolyte metabolism, aldosterone secretion, renal function, and arterial pressure were evaluated in conscious sodium deficient dogs. Plasma aldosterone concentration (PAC), plasma renin activity (PRA), urinary sodium excretion (U_NaV), arterial pressure (AP), renal blood flow (RBF), glomerular filtration rate (GFR), blood kinin concentration (BK), urinary kinin excretion (UK), and urinary kallikrein activity (UKA) were determined during long-term inhibition of angiotensin I converting enzyme (kininase II). In response to Captopril administration (20 mg/kg/day) PAC decreased from 38.9 ± 6.7 to 14.3 ± 2.3 ng/dl, PRA increased from 3.58 ± 0.53 to 13.7 ± 1.6 ng/ml/hr, U_NaV increased from 0.65 ± 0.27 to 6.4 ± 1.2 mEq/day, AP decreased from 102 ± 3 to 65 ± 2mmHg, RBF increased from 136 ± 7 to 156 ± 8 ml/min, GFR decreased from 65 ± 8 to 36 ± 7 ml/min, BK increased from 0.17 ± 0.02 to 0.41 ± 0.04 ng/ml, UK increased from 7.2 ± 1.5 to 31.4 ± 3.2 ug/day, and UKA decreased from 23.6 ± 3.1 to 5.3 ± 1.2 E.U./day. Aldosterone infusion in sodium deficient dogs maintained on Captopril failed to alter urinary sodium excretion, renal function, or arterial blood pressure. However, angiotensin II infusion (3 ng/kg/min) restored aldosterone secretion, renal function, and arterial blood pressure within three days to levels observed in untreated sodium deficient dogs. The marked alterations in renal function and urinary sodium excretion during angiotensin II infusion indicate that angiotensin II is several times more potent than aldosterone in the long-term control of sodium excretion. Also, our studies demonstrated that the long-term hypotensive and natriuretic actions of inhibitors of angiotensin I converting enzyme (kininase II) are mediated by inhibition of angiotensin II formation.     

Effect of infused captopril on blood pressure and the renin-angiotensin-aldosterone system in normal dogs subjected to varying sodium balance

Infusion of captopril at 20, 200, 2,000 and 6,000 μg/kg/hour into sodium-depleted conscious dogs produced a rapid, dose-dependent decrease in blood pressure and plasma angiotensin II and III, maximal suppression being achieved at 200 μg/kg/hour (97 ± 14 to 65 ± 8 [standard deviation]mm Hg, 38 ± 10.6 to 3.2 ± 1.5 pmol/liter and 7.0 ± 4.8 to 1 ± 0.5 pmol/liter, respectively). Angiotensin I concentration increased with each infusion rate to a maximal 16-fold increase at 6,000 μg/kg/hour (26 to 416 pmol/liter). For all infusion rates the percentage decrease in blood pressure correlated with the percentage decrease in plasma angiotensin II (r = 0.65, p < 0.001). Infusion of captopril at 6,000 μg/kg/hour into sodium-loaded dogs also produced a decrease in both blood pressure (117 ± 9 to 96.6 ± 11 mm Hg) and plasma angiotension II (11.0 ± 3 to 1.6 ± 1.3 pmol/liter). Plasma aldosterone concentrations decreased whereas both blood angiotensin I and renin concentration increased. In another experiment angiotensin II was infused at 2, 6, 18 and 54 ng/kg/min into sodium-depleted dogs firstly without modification and secondly combined with captopril (6,000 μg/kg/hour) given for 1 hour before the angiotensin dose-response study and continued throughout. Angiotensin II infusion raised mean arterial pressure and plasma angiotensin II in each animal. However, the angiotensin II blood pressure dose-response curve was shifted downwards and to the right in the captopril-treated animals.These results suggest that arterial pressure and aldosterone secretion in normal dogs are partly dependent on the renin-angiotensin system but that not all of the acute decrease in blood pressure produced by captopril can be explained by the suppression of the acute vasoconstrictor effect of circulating angiotensin II.     

Chronic hypotensive effects of verapamil in angiotensin hypertension are steroid independent

This study was designed to examine the mechanisms that contribute to the chronic hypotensive effects of verapamil during angiotensin II-induced hypertension. Hypertension was induced in five dogs by continuous intravenous infusion of angiotensin II (5 ng/kg/min) for 17 days. On the sixth day of angiotensin II infusion when daily sodium balance was achieved, mean arterial pressure (control, 92 +/- 4 mm Hg), plasma aldosterone concentration (control, 5.2 +/- 0.9 ng/dl), and renal resistance (control, 0.28 +/- 0.01 mm Hg/ml/min) were increased 37 +/- 8 mm Hg, 13.6 +/- 5.0 ng/dl, and 0.20 +/- 0.05 mm Hg/ml/min, respectively. At this time there were no significant changes in glomerular filtration rate, effective renal plasma flow, net sodium and water balance, or extracellular fluid volume. Subsequently, when verapamil was infused (at 2 micrograms/kg/min) simultaneously with angiotensin II (days 7-13), there was a net loss of 55 +/- 10 meq sodium, a 7.0 +/- 0.7% fall in extracellular fluid volume, and approximately a 70% reduction in the chronic effects of angiotensin II on mean arterial pressure and renal resistance; in contrast, verapamil failed to attenuate the long-term aldosterone response to angiotensin II. Further, although glomerular filtration rate and effective renal plasma flow tended to increase during verapamil administration, there were no consistent chronic long-term changes in these renal indexes. In comparison with these responses in hypertensive dogs, when verapamil was infused for 7 days before the induction of angiotensin II hypertension, there were no significant changes in any measurements except mean arterial pressure, which fell 11 +/- 1 mm Hg. Thus, these data fail to support the hypothesis that the chronic stimulatory actions of angiotensin II on aldosterone secretion are dependent on a sustained increase in transmembranal calcium influx. Moreover, these data indicate that the pronounced long-term hypotensive effects of verapamil in angiotensin II hypertension are due to impairment of the direct renal actions of angiotensin II rather than the indirect sodium-retaining effects that are mediated via aldosterone secretion.     

Renal changes induced by a cyclooxygenase-2 inhibitor during normal and low sodium intake

Cyclooxygenase-2 (COX-2) has been identified in renal tissues under normal conditions, with its expression enhanced during sodium restriction. To evaluate the role of COX-2-derived metabolites in the regulation of renal function, we infused a selective inhibitor (nimesulide) in anesthetized dogs with normal or low sodium intake. The renal effects elicited by nimesulide and a non-isozyme-specific inhibitor (meclofenamate) were compared during normal sodium intake. In ex vivo assays, meclofenamate, but not nimesulide, prevented the platelet aggregation elicited by arachidonic acid. During normal sodium intake, nimesulide infusion (n=6) had no effects on arterial pressure or renal hemodynamics but did reduce urinary sodium excretion, urine flow rate, and fractional lithium excretion. In contrast, nimesulide administration increased arterial pressure and decreased renal blood flow, urine flow rate, and fractional lithium excretion during low sodium intake (n=6). COX-2 inhibition reduced urinary prostaglandin E(2) excretion in both groups but did not modify plasma renin activity in dogs with low (8.1+/-1.1 ng angiotensin I. mL(-1). h(-1)) or normal (1.8+/-0.4 ng angiotensin I. mL(-1). h(-1)) sodium intake. Meclofenamate infusion in dogs with normal sodium intake (n=8) induced a greater renal hemodynamic effect than nimesulide infusion. These results suggest that COX-2-derived metabolites (1) are involved in the regulation of sodium excretion in dogs with normal sodium intake, (2) play an important role in the regulation of renal hemodynamic and excretory function in dogs with low sodium intake, and (3) are not involved in the maintenance of the high renin levels during a long-term decrease in sodium intake.     

Effect of angiotensin II on baroreceptor reflex control of heart rate in conscious baboons

Studies of the baroreceptor-heart rate reflex were performed in four conscious, unrestrained male baboons to determine whether changes in circulating angiotensin II within the physiological range are associated with alterations in baroreceptor reflex sensitivity. With the animals on a high sodium intake, studies were performed before and during graded angiotensin II infusion (10 and 20 ng/kg/min). To separate effects on baroreceptor reflex function mediated by angiotensin II-induced increases in arterial pressure, these studies were repeated on a different day with simultaneous glyceryl trinitrate infusion to prevent increases in pressure during angiotensin II infusion. With the animals on a low sodium intake, studies were performed before and after angiotensin converting enzyme inhibition with captopril (1 and 5 mg/kg). These studies were also repeated on a separate day during simultaneous phenylephrine infusion to prevent a decrease in pressure with captopril. Reduction in sodium intake had no significant effect on arterial pressure, heart rate, or plasma volume, although arterial plasma angiotensin II concentration and renin activity were significantly increased (p less than 0.01). Infusion of angiotensin II produced a significant reduction in baroreceptor reflex sensitivity (p less than 0.01), and converting enzyme inhibition produced a significant increase (p less than 0.05). These effects accompanied significant increases and decreases in arterial angiotensin II concentration, respectively (p less than 0.01), but were independent of angiotensin II-related changes in arterial pressure. The data indicate that physiological variations in circulating angiotensin II have a direct effect on sensitivity of the baroreceptor-heart rate reflex.     

Control of arterial pressure and renal function during chronic renin inhibition

The aim of this study was to determine whether the renin inhibitor CP-71362 (Pfizer Central Research, Groton, Connecticut, USA) is capable of inducing sustained reductions in arterial pressure in sodium-depleted dogs and to examine the changes in renal function associated with chronic renin inhibition. In addition, we also examined the chronic effects on renal function and blood pressure of the angiotensin converting enzyme (ACE) inhibitor enalaprilat. Infusion of CP-71362 (1.1 micrograms/kg per min, intravenously) for 7 days decreased mean arterial pressure from 87 +/- 3 to 75 +/- 2 mmHg, while causing no significant changes in sodium excretion, the glomerular filtration rate, or effective renal plasma flow. Plasma renin activity was suppressed to undetectable levels throughout the 7 days of CP-71362 infusion. Infusion of enalaprilat (4 mg/kg per day) for 7 days in sodium-depleted dogs decreased mean arterial pressure (from 85 +/- 2 to 64 +/- 3 mmHg) and renal vascular resistance, and increased effective renal plasma flow and sodium excretion, but caused no significant changes in the glomerular filtration rate. Thus CP-71362 is a potent inhibitor of dog plasma renin, and we observed no waning of this inhibitory effect of CP-71362's hypotensive actions over 7 days. The mechanisms responsible for the differences in the blood pressure and renal responses to CP-71362 and ACE inhibition are not clear, but may be dose-related or due to differences in the distribution of these compounds to various tissues, including the kidney.     

Effects of prolonged and brief infusions of noradrenaline on arterial pressure and on the plasma concentrations of active renin, angiotensin II, aldosterone and potassium

Conscious male beagle dogs were given constant intravenous infusions of noradrenaline for 14 days, four receiving 125 ng/kg/min and four 250 ng/kg/min. Before, during and after these infusions dose-response studies were done in which additional noradrenaline was infused at 500, 1000 and 2000 ng/kg/min, each rate for 1 h. Blood samples were taken before and during infusions for measurement of haematocrit and plasma concentrations of noradrenaline, active renin, angiotensin II, aldosterone, sodium and potassium. Fourteen-day infusion of noradrenaline at 125 ng/kg/min did not raise blood pressure significantly though infusion at 250 ng/kg/min did, but for the first week of infusion only. Heart rate decreased significantly at both rates. Arterial pressure fell markedly and significantly on stopping infusion. Mean plasma concentrations of renin, angiotensin II and aldosterone tended to be lower during prolonged infusion of noradrenaline, but only the fall of renin during the second week was significant in one group of dogs. Noradrenaline at higher rates significantly raised blood pressure and increased plasma concentrations of renin and angiotensin II. Plasma aldosterone concentration did not rise significantly, perhaps because plasma potassium concentration decreased; in support of this theory changes of plasma aldosterone correlated with changes of plasma potassium but not with changes of angiotensin II. The rise in arterial pressure during dose-response studies was related to the increase of plasma noradrenaline. Prolonged infusion of noradrenaline did not alter the dose-response relation between plasma noradrenaline concentration and arterial pressure.     

Captopril in clinical hypertension. Changes in components of renin-angiotensin system and in body composition in relation to fall in blood pressure with a note on measurement of angiotensin II during converting enzyme inhibition.

The effect of the converting enzyme inhibitor captopril on arterial pressure, the components of the renin-angiotensin-aldosterone system, and body sodium and potassium content was studied in eight hypertensive patients with renal artery stenosis and, in conjunction with diuretics, in seven patients with hypertension unresponsive to previous treatment. Two hours after the first dose, captopril caused significant falls in systolic and diastolic pressures, plasma angiotensin II, and aldosterone, with converse increases in angiotensin I and both active and total renin; the initial fall in diastolic pressure was significantly related to the drop in plasma angiotensin II. The biochemical changes were sustained during prolonged treatment, even when diuretics were added. One untreated patient with renal artery occlusion had severe secondary aldosterone excess, was sodium and potassium depleted, and severely hyponatraemic and hypokalaemic; captopril restored blood pressure, plasma electrolyte concentrations, and exchangeable sodium and total body potassium to normal. In one man with renal artery stenosis and overall renal impairment captopril led to sodium retention, and blood pressure did not fall until a diuretic was added. In the remaining patients with renal artery stenosis, pretreatment renin, angio tensin II, and aldosterone concentrations were either normal or only modestly raised, and plasma electrolyte concentrations and body content of sodium and potassium were normal. Captopril alone controlled arterial pressure in all, three cases showing a gradual fall of pressure over the first six weeks of treatment; no significant changes in exchangeable sodium or total body potassium were seen. The group of patients with previously intractable hypertension were all controlled with a combination of captopril and diuretic.     

Effects of calcium on renin and aldosterone

A series of experiments was undertaken to assess the effects of calcium administration, in vivo, on renin and aldosterone secretion. In the anesthetized dog, renin secretion was decreased by renal arterial infusions of calcium chloride and calcium gluconate; aldosterone excretion was not affected. In the sodium chloride-deprived rat, dietary calcium chloride loading decreased plasma renin activity, whereas calcium gluconate did not. Both calcium salts increased aldosterone production. In the non-filtering, denervated, papaverine-treated dog kidney, renin release was stimulated by renal arterial infusion of verapamil. In the rat, chronic oral verapamil administration decreased plasma aldosterone but had no effect on renin. In humans, chronic oral verapamil decreased aldosterone responsiveness to infusion of angiotensin II. Thus, in vivo renin release is inhibited by hypercalcemia and stimulated by blocking calcium transport; conversely, aldosterone production is stimulated by a high calcium intake and inhibited by blocking calcium transport. These effects of calcium on renin and aldosterone may have implications for understanding the putative relation between calcium and hypertension.     

Hepatorenal syndrome. Studies of the effect of vascular volume and intraperitoneal pressure on renal and hepatic function

Eleven patients with well-documented hepatorenal syndrome were studied by measurement of blood volume, glomerular filtration rate, renal plasma flow, plasma aldosterone concentration, renin substrate concentration, and plasma renin activity. They were then given 750 ml of stored plasma, 750 ml of fresh frozen plasma, and then an infusion of angiotensin II, in random order on successive days. Infusion of fresh frozen plasma improved function more than did stored plasma and in addition returned a very low filtration fraction toward normal. Angiotensin II infusion increased filtration fraction, but decreased glomerular filtration rate, renal plasma flow, and urine flow sharply. Patients were then given a daily infusion of 1,000 ml of fresh frozen plasma for seven to 18 days to expand the blood volume to supranormal levels as assayed by serial measurement of blood volume. Plasma aldosterone levels decreased to a normal range, glomerular filtration rate and renal plasma flow both increased, and urinary excretion of sodium and potassium both returned toward normal. The effect of intraperitoneal pressure was then studied by measuring glomerular filtration rate, renal plasma flow, pressure in the vena cava, hepatic vein free flow, and hepatic vein wedged pressure before, during, and after paracentesis to reduce the intraperitoneal pressure from 30 to 40 cm H2O to 12 to 17 cm H2O. Venous pressures moved parallel to ascitic fluid pressures, and glomerular filtration rate, renal plasma flow, and urine flow all improved sharply; then, as ascitic fluid continued to form, reducing vascular volume, urine flow, glomerular filtration rate, and renal plasma flow all decreased slowly. Six patients then underwent placement of a LeVeen shunt. Improvement in glomerular filtration rate and renal plasma flow and clinical condition was dramatic. During postoperative observation of up to two years, progressive improvement in hepatic function has occurred.     

Renal Kallikrein-Kinin System and the Depressor Effect of Angiotensin Converting Enzyme Inhibitors MK 421, SA 446, And Captopril In Rats

Responses in urinary kallikrein and kinin excretion and systolic blood pressure to MK 421, SA 446 or captopril were studied in normotensive rats fed on a regular or a low sodium diet to assess the role of renal kallikrein-kinin system in their hypotensive effect. MK 421, SA 446 or captopril were infused at a rate of 6 mg/kg/day by osmotic minipump implanted intraperito-neally for up to 6 days. The magnitude of fall in systolic blood pressure was greater on a low sodium diet when compared to on a regular diet, whereas the pattern of the fall was similar on both diets. The magnitude of falls in plasma angiotensin II and aldosterone concentration induced by MK 421, SA 446 and captopril was not significantly different between both regular and low sodium diets. Urinary kallikrein and kinin excretion and sodium excretion were increased during infusion of MK 421, SA 446 or captopril on a low sodium diet, however any significant changes were not found in each of them on a regular diet

The present results suggest that on a low sodium diet the augmented hypotensive response to angiotensin converting enzyme inhibitors in the rats might be due to the enhanced renal kallikrein-kinin system in addition to suppressed renin-angiotensin system     

Enhanced antinatriuresis in response to angiotensin II in essential hypertension

Angiotensin II regulates sodium homeostasis by modulating aldosterone secretion, renal vascular response, and tubular sodium reabsorption. We hypothesized that the antinatriuretic response to angiotensin II is enhanced in human essential hypertension. We therefore studied 48 white men with essential hypertension (defined by ambulatory blood pressure measurement) and 72 normotensive white control persons, and measured mean arterial pressure, sodium excretion, renal plasma flow, glomerular filtration rate, and aldosterone secretion in response to angiotensin II infusion (0.5 and 3.0 ng/kg/min). Hypertensive subjects exhibited a greater increase of mean arterial pressure (16.7+/-8.2 mm Hg v 13.4+/-7.1 mm Hg in normotensives, P < .05) and a greater decrease of renal plasma flow (-151.5+/-73.9 mL/ min v -112.6+/-68.0 mL/min in controls, P < .01) when 3.0 ng/kg/min angiotensin II was infused. The increase of glomerular filtration rate and serum aldosterone concentration was similar in both groups. Sodium excretion in response to 3.0 ng/kg/min angiotensin II was diminished in both groups (P < .01). However, the decrease in sodium excretion was more pronounced in hypertensives than in normotensives (-0.18+/-0.2 mmol/min v -0.09+/-0.2 mmol/min, P < .05), even if baseline mean arterial pressure and body mass index were taken into account (P < .05). We conclude that increased sodium retention in response to angiotensin II exists in subjects with essential hypertension, which is unrelated to changes in glomerular filtration rate and aldosterone concentration. Our data suggest a hyperresponsiveness to angiotensin II in essential hypertension that could lead to increased sodium retention.     

Acute and chronic dose-response relationships for angiotensin, aldosterone, and arterial pressure at varying levels of sodium intake.

We examined the acute and chronic dose-response relationships between intravenously infused angiotensin II (A II) and the resulting changes in arterial pressure and plasma aldosterone concentration at varying levels of sodium intake. Sequential analysis of plasma aldosterone at each A II infusion rate resulted in an acute dose-related increase in plasma aldosterone which was markedly attenuated after the first 24 hours of infusion, the final level being directly related to the dose of A II and inversely related to sodium intake. A II infused at 5,15, and 23 ng/kg per min was associated with an initial increase (2nd to 8th hour) in plasma aldosterone to 2,6, and 9 times control values, respectively, in dogs receiving 40 mEq Na+/day. But, after the 1st day, aldosterone averaged only 1, 1.7, and 3 times control values for the next 2 weeks at the same rates of A II infusion. Dogs receiving 120 mEq Na+/day during A II infusion exhibited only a transient increase in plasma aldosterone during the 1st day. Sustained hypertension developed over a period of a week at all doses of A II at normal and high sodium intake, but did not occur at any dose of A II in sodium-depleted dogs. Increasing sodium intake from 40 to 120 mEq/day resulted in higher levels of hypertension, 125% compared to 140% of ocntrol values for dogs infused with A II, 5.0 ng/kg per min. We conclude that primary angiotensin-induced hypertension need not be associated with increased levels of plasma aldosterone, which appears to remain elevated only with amounts of A II greater than those required to sustain a significant degree of hypertension.     

Preservation of renal function by angiotensin during chronic adrenergic stimulation

The purpose of the present study was to determine the role of angiotensin II (Ang II) in mediating renal responses to chronic intrarenal norepinephrine infusion. Norepinephrine was continuously infused for 5 days into the renal artery of unilaterally nephrectomized dogs at progressively higher daily infusion rates: 0.05, 0.10, 0.20, 0.30, and 0.40 micrograms/kg/min. In three additional groups of dogs, norepinephrine infusion was repeated during chronic intravenous captopril administration to fix plasma Ang II concentration at 1) low levels (no Ang II infused), 2) high levels in the renal circulation (Ang II infused intrarenally at a rate of 1 ng/kg/min), and 3) high levels in the systemic circulation (Ang II infused intravenously at a rate of 5 ng/kg/min). In the control group of animals with intact renin-angiotensin systems, there were progressive increments in mean arterial pressure (from 96 +/- 4 to 141 +/- 6 mm Hg) and plasma renin activity (from 0.4 +/- 0.1 to 10.9 +/- 4.5 ng angiotensin I/ml/hr) and concomitant reductions in glomerular filtration rate and renal plasma flow to approximately 40% of control during the 5-day norepinephrine infusion period. In marked contrast, when captopril was infused chronically without Ang II, mean arterial pressure was 20-25 mm Hg less than that under control conditions, and the renal hemodynamic effects of norepinephrine were greatly exaggerated; by day 3 of norepinephrine infusion, both glomerular filtration rate (16 +/- 2% of control) and renal plasma flow (12 +/- 4% of control) were considerably lower than values in control animals (86 +/- 4% and 80 +/- 8% of control, respectively). Similarly, when a high level of Ang II was localized in the renal circulation during captopril administration, mean arterial pressure was depressed, and again there were pronounced renal responses to norepinephrine. Conversely, when Ang II was infused intravenously during captopril administration, mean arterial pressure was not reduced, and the glomerular filtration rate and renal plasma flow responses to norepinephrine were similar to those that occurred under control conditions. These findings indicate that the renin-angiotensin system prevents exaggerated renal vascular responses to chronic norepinephrine stimulation by preserving renal perfusion pressure.     

The Effect of Captopril on Renin,Angiotensin II,Cortisol and Aldosterone During Acth-Infusion in man

Prolonged low-dose ACTH infusion (5 or 10 iU/24h) leads to a transient increase in plasma renin activity and angiotensin II concentration in normal man. In order to find out whether the increase in angiotensin II stimulates aldosterone secretion, 12 normal men received ACTH (10 IU/24h) for 34 hours altogether, 6 with and 6 without simultaneous administration of captopril, 50 mg every 6 hours.

Captopril prevanted the increase in plasma angiotensin II during ACTH infusion and lowered its levels below those on the control day two hours after a new dose of the converting enzyme inhibitor was given. The increase in plasma cortisol was similar in both groups. The increase in plasma aldosterone was significantly blunted by captopril. The early blood pressure rise and the kaliuresis during ACTH infusion were also significantly decreased in the captopril group. These results suggest that angiotensin II mediates in part the effect of ACTH on aldosterone and blood pressure during the first 2 days of infusion. Since captopril reduced plasma angiotensin II for some time below normal, it is alternatively possible that ACTH requires normal plasma angiotensin II levels for a full effect on aldosterone secretion.     

Renal sensitivity to angiotensin II in the conscious dog

Local formation of angiotensin II (AII) within the kidney has been demonstrated. Changes in renal function induced by inhibitors of the renin-angiotensin system have been the basis for the postulate that AII may act as a paracrine substance in the kidney. We studied the renal action of chronic intrarenal infusions of AII at doses between 2 and 2000 fmol/kg X min in uninephrectomized conscious dogs monitored on 80 meq daily sodium intake. Exogenous AII was confined to the kidney, as demonstrated by the absence of systemic pressor and adrenal cortical responses during the intrarenal infusion. After 2 control days, each dose of AII was infused intrarenally for a period of 3 days. The smallest intrarenal dose of AII that caused significant antinatriuresis and antidiuresis was 20 fmol/kg X min. A significant reduction in urinary volume and sodium excretion occurred during the first 24 h of the infusion period and was proportionate to the amount of peptide infused. Renal escape from the antinatriuretic and antidiuretic effects of the peptide ensued on the second and third days of infusion. There were no significant changes in urinary potassium excretion, plasma renin activity (PRA), plasma aldosterone concentration, or blood pressure throughout the period of intrarenal AII administration. These data demonstrate dose-dependent direct antinatriuretic and antidiuretic actions of low AII concentrations. Escape from the sodium-retaining action of intrarenal AII occurred by 48 h and was independent of suppression of endogenous renin-angiotensin. These results indicate that AII alters renal function by direct intrarenal mechanisms.     

Are hypertensive effects of aldosterone, angiotensin, vasopressin, and norepinephrine chronically additive?

The effects of chronic combined administration of angiotensin II, norepinephrine, aldosterone, and arginine vasopressin were compared with the response to each of these hormones administered alone. The studies were performed in dogs to determine the extent to which moderately inappropriate elevations of these hormones could enhance each other's ability to produce chronic hypertension and influence Na and water homeostasis. Blood pressure sensitivity to Na intake was also evaluated by infusing the hormones for 11 days at normal levels of Na intake followed by 11 days at high Na intake with ad libitum drinking. Combined hormone administration did not enhance each hormone's singular hypertensive actions. With aldosterone infusion alone and normal Na intake, mean arterial pressure rose nearly 15 mm Hg and an additional 3 mm Hg during high Na intake. Combined hormone infusion also resulted in a nearly 15 mm Hg rise during normal Na intake and an additional 3 mm Hg rise in mean arterial pressure during high Na intake. Marked Na retention and hypernatremia were observed with aldosterone infusion, while hyponatremia characterized arginine vasopressin infusion. The combined hormone infusion resulted in a tendency toward hypernatremia, although daily Na balance was not significantly changed. Daily water turnover was substantially increased and urine osmolality fell to hypoosmotic levels, despite elevated arginine vasopressin levels. Even with high Na intake, dogs receiving either angiotensin II, arginine vasopressin, or norepinephrine at the same concentrations showed 4 to 10 mm Hg increases in mean arterial pressure. Thus, humoral summation or synergism of these hormones probably does not play a major role in the development of chronic hypertension.     

Captopril in the management of hypertension with renal artery stenosis: Its long-term effect as a predictor of surgical outcome

Fifteen patients with hypertension and unilateral renal artery disease were treated with captopril alone; 10 came to operation and were later assessed postoperatively with no drug treatment. Captopril caused both immediate and sustained decreases in plasma angiotensin II and aldosterone, with increases in plasma active renin and blood angiotensin I concentrations. Decrements in systolic and diastolic pressure 2 hours after the first dose of captopril were closely correlated with the initial decreases in plasma angiotensin II. Blood pressure was decreased by long-term captopril therapy irrespective of whether plasma angiotensin II was abnormally high before treatment. The long-term response of both systolic and diastolic pressure correlated well with the response to surgery. By contrast, the blood pressure decrease 2 hours after the initial dose of captopril variously underestimated and overestimated the decrease during prolonged use of the drug and did not relate to surgical outcome. In patients who, before treatment, had secondary aldosteronism, hyponatremia, hypokalemia and sodium and potassium deficiency, captopril corrected these abnormalities. In the remaining patients, long-term captopril therapy did not alter exchangeable sodium, plasma sodium or total body potassium, although plasma potassium levels increased.     

Characterization of the antihypertensive effect of a thiazide diuretic in angiotensin II-induced hypertension

OBJECTIVES : The antihypertensive effect of thiazide diuretics in angiotensin II induced hypertension has never been characterized. In the current study, we sought to determine the effect of a thiazide diuretic on arterial pressure and renal fluid excretion in rats receiving a chronic intravenous infusion of angiotensin II while on fixed normal or high sodium intakes. DESIGN AND METHODS : Male rats were chronically instrumented with arterial and venous catheters for drug injection and direct daily measurements of blood pressure and heart rate. Rats were maintained on high salt intake (HS), 6 mEq/day, or on normal salt intake (NS), 2 mEq/day. Rats were randomly assigned to four groups: HS and NS with 15 day angiotensin II infusion (5 ng/min) and HS and NS without angiotensin II infusion. Trichlormethiazide (TCM), a thiazide diuretic, was orally administered, approximately 10 mg/kg per day, for the middle 5 days of angiotensin II infusion. RESULTS : Only HS rats receiving angiotensin II infusion became hypertensive. Angiotensin II infusion did not produce changes in heart rate, sodium balance or water balance. Chronic administration of TCM significantly reduced mean arterial pressure (MAP) within 24 h in HS rats receiving angiotensin II, but did not affect MAP in any other group. TCM produced a similar loss of Na+ and water in all rats. Blood volumes and plasma electrolytes did not change during the study. CONCLUSIONS : The antihypertensive effects of thiazide diuretics are not due exclusively to volume depletion. We propose that salt and water loss caused by TCM may lower MAP by impairment of salt-sensitive pressor mechanisms activated by angiotensin II.     

Role of angiotensin II in the hormonal, renal, and electrolyte response to sodium restriction

Adrenal responses to angiotensin II (ANG II) are enhanced with restriction of sodium intake. To determine whether increased circulating ANG II levels are responsible for the enhanced responsiveness, the adrenal and blood pressure responses to ANG II in human subjects were assessed four times: in balance on a high and a low salt diet and before and after the administration of a converting enzyme inhibitor (enalapril). Before enalapril administration, sodium restriction significantly increased (p less than 0.02) plasma renin activity, ANG II, and aldosterone levels; the aldosterone response to ANG II was enhanced twofold (p less than 0.01); and the blood pressure response to ANG II infusion was reduced significantly (p less than 0.05). Despite a fixed and low plasma ANG II concentration when enalapril was employed, the adrenal response to ANG II on the low salt diet was enhanced to the same degree as that observed before administration of the converting enzyme inhibitor. Conversely, enalapril substantially altered the blood pressure response to ANG II with sodium restriction, completely preventing the reduction in responsiveness. If the subjects were first given enalapril and then sodium intake was restricted, ANG II levels did not change significantly but renal excretion of both sodium and potassium was substantially modified. The rate at which renal excretion of sodium fell to match intake was retarded strikingly (p less than 0.001); conversely, renal retention of potassium increased significantly (p less than 0.03) as low salt balance was attained. Possibly because of the potassium retention, aldosterone levels rose, but significantly less than when enalapril was absent.