Postural Augmentation of Plasma Renin Activity and Aldosterone Excretion in Normal People

Peripheral plasma renin activity and aldosterone excretion rates have been measured in normal people during recumbency, recumbent exercise, tilting, and continuous ambulation. Upright posture induces a prompt elevation in peripheral plasma renin activity beginning in 15 minutes and peaking between 60 and 120 minutes. Aldosterone excretion is increased during 120 minutes of upright posture and correlates directly with the elevation in renin activity. Upright posture induces increased plasma renin activity regardless of the level of sodium intake in the preparatory diet. Concomitant measurements of endogenous creatinine clearance and the rates of excretion of sodium and potassium suggest that a fall in renal arterial perfusion resulting from upright posture induces increased release of renin and the subsequent secondary stimulation of aldosterone secretion. Our data indicate that the changes in plasma renin activity are due to changes in the amount of the enzyme rather than to changes in other elements of the reninangiotensin systm. This report discusses the physiologic importance of postural augmentation of renin production, emphasizing that for proper interpretation of values of plasma renin activity, posture as well as dietary factors must be considered and controlled.     

Effects of 1-Sar-8-Ile-angiotensin II on urinary prostaglandin excretion in patients with essential hypertension

To investigate the interaction between the renin angiotensin aldosterone system and the renal prostaglandin (PG), urinary excretion of PGE, urinary excretion of main urinary metabolite (MUM) of PGF2a, urinary excretion of aldosterone, and plasma renin activity were measured before and after infusion of 1-Sar-8-Ile-Angiotensin II, a specific competitive inhibitor of angiotensin II, in 18 patients with essential hypertension under normal and low sodium diets. The values of urinary sodium excretion in these patients before the infusion of the peptide were 160.8 +/- 13.3 and 27.0 +/- 2.7 mEq per day on normal and low sodium diet, respectively. On normal sodium diet, urinary excretion of PGE was found to correlate with the level of plasma renin activity before the infusion (r = 0.6977, p less than 0.01), and it was decreased slightly from 0.37 +/- 0.05 ng/min to 0.26 +/- 0.04 ng/min after the infusion of the antagonist. On low sodium diet, urinary excretion of PGE was not significantly changed by the infusion of the peptide and showed no correlation with the level of plasma renin activity before the infusion, while urinary excretion of PGE showed a significant correlation with the excretion of urinary aldosterone (r = 0.6719, p less than 0.02). Excretion of PGF2aMUM decreased after the infusion of this peptide on both sodium diets, but the changes were not statistically significant. The present data suggest that angiotensin II influences the synthesis or release of renal PG in patients with essential hypertension on normal sodium diet, but not when they are on low sodium diet.     

Aldosterone and renin-angiotensin responses to stimuli in patients with treated congestive heart failure.

Aldosterone responses to physiologic doses of known regulatory factors have been studied in 8 patients with treated congestive heart failure under standard conditions of electrolyte balance and controlled body posture. The response of plasma aldosterone, plasma renin activity (PRA), and in some instances angiotension II, to the brief (120 minute) intravenous administration of ACTH (1.25 mug beta1-24 ACTH in 60 minute and 5 mug in 60 minutes), angiotensin II (30 mug) and potassium (30 mEq.), and to 2 hours in the upright posture, was measured. The plasma aldosterone increase was greatest in response to ACTH (mean increment 20.8 ng. per 100 ml.) followed by that with upright posture (mean rise 17.1 ng. per 100 ml.), potassium (mean 6.7 ng. per 100 ml.) and angiotensin II (5.8 ng. per 100 ml.). PRA rose vigorously following 2 hours of upright posture and fell with angiotensin II infusion, but showed no definite change in response to potassium or ACTH. A diurnal pattern of PRA, angiotensin II, and plasma aldosterone on control days was observed in these patients, with higher prenoon levels falling to a nadir at midnight. The electrolyte and hormone response to administered aldosterone (75 mug over 2 hours) was also studied in the same patients. During aldosterone infusions, plasma aldosterone increased (increment range 36 to 110 ng. per 100 ml.), urine sodium excretion decreased, but no significant change in urine potassium excretion or in PRA was observed. It is concluded that small fluctuations in ACTH secretion, as well as change in body posture, produce marked effects on plasma aldosterone in patients with controlled congestive heart failure. Aldosterone responses to ACTH in these patients is similar to that observed in normal subjects.     

Increased Adrenal Sensitivity to Angiotensin II in Low-Renin Essential Hypertension

Studies were undertaken to determine if the dissociation of aldosterone and plasma renin activity in low-renin essential hypertension is due to altered adrenal responsiveness to angiotensin II. The responsiveness of the adrenal glands to angiotensin II was determined by infusing graded doses of angiotensin II into normal subjects and into patients with essential hypertension and measuring changes in levels of plasma aldosterone in response to the infusion. To minimize the influence of endogenous angiotensin II and ACTH, supplemental sodium and dexamethasone were given before the infusions. Levels of plasma aldosterone and plasma renin activity were determined in normal subjects and in the same patients after the combined stimuli of furosemide and upright posture, a maneuver used to increase the level of endogenous angiotensin II. To determine if the changes in levels of plasma aldosterone during infusion of angiotensin II were due to alteration of the metabolic clearance of aldosterone, the metabolic clearance of aldosterone was measured before and during the infusion of angiotensin II.     

The renin-angiotensin-aldosterone system in decompensated cirrhosis: its activity in relation to sodium balance

Plasma renin activity (PRA), plasma renin concentration (PRC), plasma angiotensin II concentration (AII), plasma and urinary aldosterone (PA, UA) and urinary sodium excretion (UNaV) were measured in 51 normal controls, 16 patients with decompensated cirrhosis (i.e. ascites and/or oedema present) in sodium equilibrium (Group 1) and 13 patients with decompensated cirrhosis in a phase of active sodium retention (Group 2). In Group 1 the mean supine and erect values, although lower, were not significantly different from controls. In Group 2 the mean values were significantly elevated, but several individual values were within the normal range; there were significant direct relationships between plasma renin activity and plasma renin concentration (r = 0.85, p less than 0.001 erect), plasma renin concentration and plasma angiotensin II concentration (r = 0.86, p less than 0.001 erect), and plasma angiotensin II concentration and plasma aldosterone (r = 0.70, p less than 0.01 erect). In Group 2 there was an inverse correlation between urinary sodium excretion and both urinary aldosterone (r = -0.50) and erect plasma aldosterone (r = -0.36) but, perhaps because of the narrow range of sodium excretion rates, significance was not reached. The normal values in Group 1 indicate that hyperaldosteronism is not essential for the maintenance of established ascites, but do not exclude a role for aldosterone in the control of sodium excretion if it is accepted that renal tubular sensitivity to aldosterone is increased in these patients. In Group 2, the raised mean plasma and urinary aldosterone levels and the trend towards an inverse relationship with urinary sodium excretion suggests a role for aldosterone in the active retention of sodium. It appears that stimulation of the renin-angiotensin system is the major factor in the elevation of plasma aldosterone; there was no relationship between plasma aldosterone and either plasma sodium or potassium levels. The mechanism of renin hypersecretion is unclear but this may represent part of a sympathetically mediated response in order to maintain blood pressure. The close relationship between plasma renin activity and plasma renin concentration indicates that the former is a valid measure of circulating renin levels in cirrhosis, despite low renin-substrate levels.     

Urinary kallikrein and systemic prostacyclin synthesis during sodium chloride infusion in normal man

An intravenous infusion of 3 litres of sodium chloride solution (saline: 150 mmol/l) was given over 1 h to normal subjects. During and immediately after the infusion, renal plasma flow increased in the majority of subjects, but the rise was not statistically significant. Significant increases in urine flow, sodium excretion, urinary kallikrein excretion and urinary excretion of dinor-6-keto prostaglandin (PG) F1 alpha, a measure of systemic PGI2 synthesis, were noted. Plasma renin activity and plasma protein concentration were significantly lowered by the infusion. At 2 h after the end of the infusion, although urine flow fell significantly, sodium excretion had not decreased. The reduction in plasma renin activity and plasma proteins persisted, and excretion of kallikrein and the PGI2 metabolite returned to control values. Overall, urinary kallikrein excretion correlated significantly with urine flow and with sodium excretion. Peak kallikrein excretion occurred in the second 30 min of the infusion, and preceded maximal urine flow and sodium excretion. The results suggest that increased systemic synthesis of PGI2 occurs in response to an acute infusion of sodium chloride, and may be an adaptive response of the vasculature to volume expansion. They support a role for the renal kallikrein-kinin system in the early diuretic and natriuretic response to saline infusion; the reduction in plasma renin activity and plasma protein concentration may be involved in both the early response and the persistent natriuresis 2 h after the infusion.     

Short-term augmented calcium intake has no effect on sodium homeostasis

To test the hypothesis that the supplementation of dietary calcium intake influences sodium homeostasis, the renin-angiotensin system, and sympathetic nervous system in a manner that might evoke a decrease in arterial blood pressure, we gave 16 participants (eight normal and eight with hypertension) placebo for 8 days, followed by 500 mg elemental calcium as the carbonate salt twice a day for 8 days. The same diet was prepared for each meal for the entire study. Sodium intake was fixed for each participant and averaged 150 mEq/day. All urine was collected every day. Blood was drawn at the end of the placebo and calcium periods for determinations of plasma renin, aldosterone, and norepinephrine values. Calcium supplementation increased urinary calcium excretion significantly in both groups. However, calcium supplementation failed to influence sodium or potassium excretion, serum electrolytes, total serum calcium, renin, aldosterone, or norepinephrine levels, or heart rate. Systolic and diastolic blood pressure were not influenced in normal subjects, but in patients with hypertension the supine systolic blood pressure decreased significantly. We conclude that blood pressure lowering effects of calcium, should they occur, are not likely the result of augmented urinary sodium excretion or of straight-forward influences on the renin-angiotensin system or sympathetic nervous system.     

Renal adaptation and gut hormone release during sodium restriction in ileostomized man

The renal excretion of water, electrolytes, aldosterone and kallikrein was monitored in 12 ileostomized patients before and during sodium deprivation. Changes in plasma renin activity (PRA), plasma aldosterone and plasma arginine vasopressin (AVP) concentrations were measured, together with aldosterone in ileal fluid. The pattern of gut peptide release in response to a test meal was also examined to assess whether a circulating gut peptide might be involved in the renal adaptation to sodium restriction, and compared with healthy normal subjects who were under no dietary constraint. In each patient renal sodium excretion fell within 8-12 h of sodium deprivation and was associated with a prompt and significant rise in PRA; much later increases in plasma aldosterone concentration and renal aldosterone excretion occurred, and were established by day 2 of sodium restriction. No consistent change in renal kallikrein excretion was found. Ileal sodium loss was little changed by sodium deprivation, but ileal potassium concentration rose steadily and became significantly correlated with PRA, and to a lesser extent with renal aldosterone excretion. Of the gut peptides measured in plasma, only the insulin profile was altered by sodium deprivation, with an increase in the test meal response; insulin has previously been shown to have a significant antinatriuretic action at physiological concentrations. Plasma levels of pancreatic polypeptide and motilin were increased in ileostomized patients when compared with normal subjects, but were unaffected by the change to a low sodium diet. An early increase in urine flow and water diuresis occurred during sodium deprivation, following a cyclical pattern with peaks each evening.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of furosemide on urinary kallikrein excretion in patients with essential hypertension

The effect of furosemide on urinary kallikrein excretion was studied in 10 patients with essential hypertension and 9 normal volunteer subjects. After intravenous administration of furosemide and 2 hours of upright posture, urine volume (UV), urinary sodium (UNaV) and potassium (UKV) excretion, plasma renin activity (PRA), plasma aldosterone concentration (PAC) and urinary kallikrein markedly increased. However, the augmentation of urinary kallikrein in patients with essential hypertension (1.50 +/- 0.19 EU/2 hr) was less remarkable than that in normal subjects (2.33 +/- 0.24 EU/2 hr), although the same degrees of response were observed in PRA and PAC. The increments of UV, UNaV and UKV in patients with essential hypertension were also significantly lower than in normal subjects. Significant positive relations were found between urinary kallikrein and UV or UNaV in both hypertensive and normotensive groups, but there was no such correlation before fursemide administration. It is likely that diuresis and natriuresis induced by furosemide are somehow associated with an increase in urinary kallikrein excretion. Blunted response of urinary kallikrein in essential hypertension may suggest an abnormality in the renal kallikrein-kinin system in this disease.     

Renin, aldosterone and renal haemodynamics in cirrhosis with ascites

The interrelationships between the renin-angiotensin-aldosterone system, renal haemodynamics and urinary sodium excretion were investigated in fifty-six non-azotaemic cirrhotics with ascites. In twelve additional patients the renal renin secretion rate was also studied. Plasma renin activity and concentration and plasma aldosterone ranged from normal to very high values. There was a significant inverse relationship between plasma aldosterone and the urinary sodium excretion. Plasma aldosterone showed a highly significant direct correlation with plasma renin activity, and plasma renin concentration was closely and directly related to the estimated renin secretion rate. Neither plasma renin activity, plasma renin concnetration nor the estimated renin secretion rate correlated with the renal plasma flow or the glomerular filtration rate. These results suggest that in non-azotaemic cirrhosis with ascites the renin-angiotensin-aldosterone system is an important factor influencing sodium excretion, increased plasma renin and aldosterone concentrations are mainly due to an increased secretion rate, and total renal perfusion is not a major factor influencing renin secretion.     

The influence of potassium administration and of potassium deprivation on plasma renin in normal and hypertensive subjects

The effect of potassium administration and of dietary potassium deprivation on plasma renin activity and aldosterone excretion has been studied in 10 normal subjects and in 12 hypertensive patients maintained on a constant dietary regimen.Potassium administration reduced plasma renin activity in 18 of 28 studies of both normal and hypertensive subjects. Suppression of renin often occurred despite sodium diuresis induced by potassium administration. The renin suppression was related to induced changes in plasma potassium concentration and urinary potassium excretion.The failure of suppression of plasma renin in 10 studies could be accounted for by the smaller amounts of potassium administered to these subjects, together with a possibly overriding influence of an induced sodium diuresis.In six studies potassium deprivation invariably increased plasma renin activity even though a tendency for sodium retention often accompanied this procedure.The data indicate that both the suppression of plasma renin activity induced by potassium administration and the stimulation of renin activity which follows potassium depletion occur independently of associated changes in either aldosterone secretion or in sodium balance. However, the results do suggest that in various situations, the influence of potassium on plasma renin activity may be either amplified or preempted by changes in sodium balance.These interactions between potassium and plasma renin could be mediated by an ill-defined extrarenal pathway. But the findings are more consistent with an intrarenal action of potassium ions to modify renin release. Potassium might modify renin secretion directly by acting on the juxtaglomerular cells or by a change in its tubular reabsorption or secretion. The effects of potassium ions on renin secretion might also be mediated indirectly via an induced change in tubular sodium transport.     

The Renin--Angiotensin--Aldosterone System in Decompensated Cirrhosis: Its Activity in Relation to Sodium Balance

Plasma renin activity (PRA), plasma renin concentration (PRC),plasma angiotensin II concentration (All), plasma and urinaryaldosterone (PA, UA) and urinary sodium excretion (UNaV) weremeasured in 51 normal controls, 16 patients with decompensatedcirrhosis (i. e. ascites and/or oedema present) in sodium equilibrium(Group 1) and 13 patients with decompensated cirrhosis in aphase of active sodium retention (Group 2). In Group 1 the meansupine and erect values, although lower, were not significantlydifferent from controls. In Group 2 the mean values were significantlyelevated, but several individual values were within the normalrange; there were significant direct relationships between plasmarenin activity and plasma renin concentration (r = 0.85, p <0.001 erect), plasma renin concentration and plasma angiotensinII concentration (r = 0.86, p < 0.001 erect), and plasmaangiotensin II concentration and plasma aldosterone (r = 0.70,p < 0.01 erect). In Group 2 there was an inverse correlationbetween urinary sodium excretion and both urinary aldosterone(r = – 0.50) and erect plasma aldosterone (r = –0.36) but, perhaps because of the narrow range of sodium excretionrates, significance was not reached. The normal values in Group 1 indicate that hyperaldosteronismis not essential for the maintenance of established ascites,but do not exclude a role for aldosterone in the control ofsodium excretion if it is accepted that renal tubular sensitivityto aldosterone is increased in these patients. In Group 2, theraised mean plasma and urinary aldosterone levels and the trendtowards an inverse relationship with urinary sodium excretionsuggests a role for aldosterone in the active retention of sodium.It appears that stimulation of the renin-angiotensin systemis the major factor in the elevation of plasma aldosterone;there was no relationship between plasma aldosterone and eitherplasma sodium or potassium levels. The mechanism of renin hypersecretionis unclear but this may represent part of a sympatheticallymediated response in order to maintain blood pressure. The closerelationship between plasma renin activity and plasma reninconcentration indicates that the former is a valid measure ofcirculating renin levels in cirrhosis, despite low renin-substratelevels.     

Pharmacodynamic characterization of posture-related diuretic and saluretic responses to furosemide in humans

To characterize the postural effect on the pharmacodynamic response to furosemide, seven healthy female subjects received the drug (30 mg i.v.), and the diuretic response and urinary drug excretion were monitored either in the supine or upright posture more than 5 h after dose. Six days later the same procedure was repeated, each subject being assigned to the other posture. Diuresis, chlor- and natriuresis were about 50% greater (P less than .01) in the supine than in the upright posture up to 45 min after dose, despite no significant difference in urinary drug excretion between the postures. Creatinine clearance and fractional sodium excretion were also significantly (P less than .05) greater in the supine posture. Pharmacodynamic analysis with the Emax model revealed that the maximum drug response (Emax) to furosemide in the upright posture was significantly (P less than .01) attenuated by about 65% of that in the supine posture, with no significant difference in either ER50 (urinary drug excretion rate producing 50% of Emax) or slope between the postures. Plasma norepinephrine concentration was significantly (P less than .05) greater, whereas urinary kallikrein excretion was significantly (P less than .05) less in the upright posture. There were no significant differences in blood pressure, plasma renin activity and atrial natriuretic peptide as well as in urinary excretion of prostaglandin E2, dopamine and adenosine between the postures.(ABSTRACT TRUNCATED AT 250 WORDS)     

Diurnal change in plasma atrial natriuretic peptide concentrations

1. Diurnal changes in plasma concentrations of atrial natriuretic peptide (ANP), renin, angiotensin II, aldosterone, cortisol and antidiuretic hormone were investigated in seven normal volunteers studied under standardized conditions of dietary sodium, posture and physical activity. After completion of the diurnal study serial measurements of these variables were continued during, and on recovery from, a 2 day period of severe sodium depletion. 2. Clear diurnal variations in plasma concentrations of renin, angiotensin II, aldosterone, cortisol and antidiuretic hormone were observed. 3. Plasma ANP concentrations also varied significantly over 24 h. Values peaked about mid-day and a distinct trough in peptide concentrations occurred in the early evening. However, variations in plasma ANP values were of relatively small amplitude and not clearly independent of modest parallel shifts in sodium balance. 4. Changes in plasma ANP concentrations both within the diurnal study period and during sodium deprivation were closely and positively correlated with concomitant changes in cumulative sodium balance. 5. No simple parallel or reciprocal relationships between plasma concentrations of ANP, on the one hand, and concurrent plasma concentrations of other hormones or in the rate of urinary sodium excretion, on the other, were observed during the 25 h of the diurnal study.     

The renin-angiotensin-aldosterone system in congestive failure in conscious dogs.

The role of the renin-angiotensin-aldosterone system in the development of congestive failure has been assessed in the conscious dog by use of the nonapeptide converting enzyme inhibitor. Constriction of the pulmonary artery or thoracic inferior vena cava was maintained for 2 wk while daily measurements were made of plasma renin activity, plasma aldosterone, plasma volume, hematocrit, serum sodium and potassium concentrations, sodium and water balance, body weight, and arterial, caval, and atrial pressures. The initial response to constriction was a reduction in blood pressure, a rise in plasma renin activity, plasma aldosterone, and water intake, and nearly complete sodium retention. In the days after moderate constriction plasma volume and body weight increased (with development of ascites and edema); blood pressure, sodium excretion, plasma renin acvitity, and plasma aldosterone returned to normal. In animals in which blood pressure was not restored, plasma renin activity and plasma aldosterone remained elevated throughout the period of constriction. Single injections of converting enzyme inhibitor reduced blood pressure when plasma renin activity was elevated. Chronic infusion of the inhibitor in dogs with thoracic inferior vena caval constriction prevented the restoration of blood pressure and suppressed the rise in plasma aldosterone; sodium retention and volume expansion were less than in control experiments. Thus the renin-angiotensin-aldosterone system plays an essential role in the maintenance of blood pressure during the genesis of congestive failure. Initially, the restoration of blood pressure is dependent upon circulating angiotensin II; in the later stages, blood pressure is dependent upon the increase in plasma volume.     

The contribution of the renin-angiotensin system to limb vasoregulation in patients with heart failure: observations during orthostasis and alpha-adrenergic blockade

1. In patients with congestive heart failure, both the sympathetic nervous system and renin-angiotensin system are often stimulated. In order to assess the contribution of the renin-angiotensin system to limb vascular resistance, the forearm haemodynamic response to captopril was studied in 13 patients with heart failure. 2. Seven subjects were studied while supine and during 60 degrees head-up tilt. To eliminate alpha-adrenergic effects, six additional patients with heart failure were pretreated with intra-arterial phentolamine and then given captopril. Venous occlusion plethysmography was used to determine forearm blood flow and forearm vascular resistance. 3. Tilt did not significantly increase pretreatment plasma renin activity or plasma noradrenaline concentration, nor did it decrease forearm blood flow. Furthermore, captopril did not alter forearm vascular resistance during supine or upright posture. During the phentolamine infusion, however, captopril reduced forearm vascular resistance by 19% (P < 0.05). 4. Despite increased plasma renin activity, captopril did not cause forearm vasodilatation during supine or upright posture in these patients with heart failure. When the contribution of the sympathetic nervous system was eliminated, captopril decreased forearm vascular resistance. Therefore, in patients with congestive heart failure, the sympathetic nervous system is important in limb vasoregulation, and the contribution of the renin-angiotensin system is apparent only after alpha-adrenergic blockade.     

Effect of propranolol therapy on aldosterone responses to angiotensin II and adrenocorticotropic hormone in essential hypertension

1. The plasma aldosterone responses to exogenous angiotensin II and adrenocorticotropic hormone (ACTH) were studied before and after 1 month of propranolol therapy (120-240 mg/day) in eight patients with essential hypertension. 2. Basal supine plasma renin activity was decreased (P less than 0.001) after propranolol, whereas plasma aldosterone was unchanged. After 3 h of upright posture the increases in both plasma renin activity and aldosterone were decreased (P less than 0.05) after propranolol. 3. Plasma aldosterone responses to exogenous angiotensin II and ACTH were not significantly different after propranolol. Serum and urinary electrolytes and plasma cortisol were also unaffected by propranolol therapy. 4. It is concluded that changes in adrenal sensitivity are not responsible for maintaining unchanged supine plasma aldosterone concentrations after beta-adrenoceptor antagonism in essential hypertension.     

Neurohormonal activation, the renal dopaminergic system and sodium handling in patients with severe heart failure under vasodilator therapy

The benefits of tailoring therapy with vasodilators in patients with severe heart failure are well documented, but this may lead to neurohormonal activation and sodium retention. Renal dopamine has local natriuretic actions and interacts with other hormones involved in renal sodium handling. The aim of the present work was to determine the effects of arterial underfilling induced by vasodilator therapy on renal sodium handling, neurohormonal activation and the activity of the renal dopaminergic system in patients with severe heart failure. For this purpose we monitored haemodynamic parameters, plasma levels of type B natriuretic peptide (BNP), catecholamines, aldosterone, renin activity (PRA), sodium and creatinine, and urinary excretion of sodium, creatinine, L-DOPA, dopamine and its metabolites, before initiation of sodium nitroprusside therapy and every 6 h thereafter (for 42 h), and again after 5 days of angiotensin-converting enzyme (ACE) inhibition, in 10 male patients with severe heart failure. The results of nitroprusside therapy were a marked increase in cardiac index and a substantial decrease in systemic vascular resistance index. Plasma levels of BNP decreased significantly, while PRA, noradrenaline and aldosterone showed marked increases, resulting in a substantial reduction in urinary sodium excretion. Creatinine clearance was not affected. Urinary dopamine and dopamine metabolites increased in response to nitroprusside therapy. After 5 days of ACE inhibition, urinary sodium returned to baseline values, while urinary dopamine was markedly reduced. These results suggest that the renal dopaminergic system is activated in patients with severe heart failure by stimuli leading to sodium renal reabsorption.     

Urinary prostaglandin and sodium metabolism in patients with essential hypertension

Urinary prostaglandin E (PGE) excretion as an indicator of renal PGE, urinary aldosterone excretion, plasma renin activity, urinary sodium excretion, and urinary potassium excretion were measured after sodium depletion in 15 patients with essential hypertension to investigate the interaction between renal PGE and sodium metabolism. Following sodium depletion, urinary PGE excretion decreased, whereas urinary aldosterone excretion and plasma renin activity increased. Significant positive correlations were found between urinary PGE excretion and urinary sodium excretion (r=0.41, p less than 0.01) or urinary sodium excretion-urinary potassium excretion ratio (r = 0.43, p less than 0.005). These results support the hypothesis that the renal PGE may play an important role in the regulation of sodium metabolism and this action of PGE is independent of the renin-aldosterone system.     

Dissociation between plasma atrial natriuretic peptide levels and urinary sodium excretion after intravenous saline infusion in normal man

1. Plasma immunoreactive atrial natriuretic peptide (ANP) and urinary sodium excretion were measured in six normal male subjects before, during and for 195 min after a 60 min infusion of 2 litres of saline (0.9% NaCl, 308 mmol of Na+). 2. During the saline infusion, there was a significant increase in plasma ANP and urinary sodium excretion and a significant decrease in plasma renin activity, aldosterone, albumin, creatinine and packed cell volume. 3. The maximal rise in mean plasma ANP occurred 15 min after stopping the infusion and the maximal rise in mean urinary sodium excretion in the collection period 30 min later. 4. Plasma ANP then decreased so that by the end of the study the level was the same as before the saline infusion. However, at this time, 195 min after the saline infusion was stopped, there was still a net positive sodium balance of 220 mmol and urinary sodium excretion remained significantly elevated. 5. Our results are compatible with the concept that increased ANP secretion may play a role in the immediate increase in sodium excretion after a saline load. However, they also suggest that other mechanisms may be more important for the longer term increase in sodium excretion.