Severity of hypertension in familial hyperaldosteronism type I: relationship to gender and degree of biochemical disturbance

In familial hyperaldosteronism type I (FH-I), inheritance of a hybrid 11beta-hydroxylase/aldosterone synthase gene causes ACTH-regulated aldosterone overproduction. In an attempt to understand the marked variability in hypertension severity in FH-I, we compared clinical and biochemical characteristics of 9 affected individuals with mild hypertension (normotensive or onset of hypertension after 15 yr, blood pressure never >160/100 mm Hg, < or = 1 medication required to control hypertension, no history of stroke, age >18 yr when studied) with those of 17 subjects with severe hypertension (onset before 15 yr, or systolic blood pressure >180 mm Hg or diastolic blood pressure >120 mm Hg at least once, or > or = 2 medications, or history of stroke). Severe hypertension was more frequent in males (11 of 13 males vs. 6 of 13 females; P < 0.05). All 4 subjects still normotensive after age 18 yr were females. Of 10 other affected, deceased individuals (7 males and 3 females) from a single family, all six who died before 60 yr of age (4 by stroke) were males. Biochemical studies were conducted in 6 mild and 16 severe subjects. The 2 groups were similar in terms of urinary sodium excretion. Mild subjects tended, although not significantly, to have lower urinary 18-oxo-cortisol (mean +/- SD, 27.4 +/- 9.0 vs. 35.2 +/- 12.9 nmol/mmol creatinine x day), higher plasma potassium (4.0 +/- 0.3 vs. 3.6 +/- 0.4 mmol/L), and lower recumbent (0800 h after overnight recumbency) plasma aldosterone levels (498 +/- 279 vs. 744 +/- 290 pmol/L). Upright (midmorning after 2-3 h of upright posture) plasma aldosterone levels were similar (mild, 485 +/- 150; severe, 474 +/- 188 pmol/L). In 1 normotensive female, upright PRA was much higher, and the upright aldosterone/PRA ratio was much lower than that in the other subjects. The remaining mild subjects had similar upright PRA levels (mild, 2.8 +/- 1.4; severe, 3.7 +/- 3.2 pmol/ L x min) and aldosterone/PRA ratios (mild, 199.5 +/- 133.4; severe, 200.6 +/- 150.9) as severe subjects. During angiotensin II (AII) infusion studies (n = 6 mild and 10 severe), performed during recumbency, aldosterone levels were lower in the mild group both basally (404 +/- 144 vs. 843 +/- 498 pmol/L; P < 0.05) and after 60 min AII (2 ng/kg x min; 261 +/- 130 vs. 520 +/- 330 pmol/L; P < 0.05). Aldosterone was unresponsive (rose by <50%) to AII in all subjects. Day curve studies (blood collected every 2 h for 24 h; n = 2 mild and 7 severe) demonstrated abnormal regulation of aldosterone by ACTH rather than by AII in both groups. In conclusion, in this series of patients with FH-I, males had more severe hypertension, and the degree of hybrid gene-induced aldosterone overproduction may have contributed to the severity of hypertension.     

Treatment of familial hyperaldosteronism type I: only partial suppression of adrenocorticotropin required to correct hypertension

In familial hyperaldosteronism type I, inheritance of a hybrid 11beta-hydroxylase/aldosterone synthase gene leads to ACTH-regulated overproduction of aldosterone (causing hypertension) and of "hybrid" steroids, 18-hydroxy- and 18-oxo-cortisol. To determine whether complete suppression of the hybrid gene is necessary to normalize blood pressure, we sought evidence of persisting expression in eight patients who were rendered normotensive for 1.3-4.5 yr by glucocorticoid treatment. At the time of the study, six patients were receiving dexamethasone (0.125-0.25 mg/day) and two patients were taking prednisolone (2.5 or 5 mg/day). Urinary 18-oxo-cortisol levels during treatment demonstrated close correlation with mean "day curve" (blood collected every 2 h for 24 h) cortisol (r = 0.74), consistent with regulation by ACTH. Although urinary 18-oxo-cortisol levels were lower during than before treatment (mean 12.6 +/- 2.4 SEM vs. 35.0 +/- 5.6 nmol/mmol creatinine; P < 0.01), they remained above normal (0.8-5.2 nmol/mmol creatinine) in all eight patients. Although mean upright plasma potassium levels during treatment were higher, aldosterone levels lower, PRA levels higher, and aldosterone to PRA ratios lower than before treatment, PRA levels were uncorrected (< 13 pmol/L x min) and aldosterone to PRA ratios were uncorrected (>65) during treatment in four patients. For each of the eight patients, day curve aldosterone levels during treatment correlated more tightly with cortisol (mean r for the eight patients, 0.87 +/- 0.05 SEM) than with PRA (mean r = 0.36 +/- 0.10 SEM). Hence, control of hypertension by glucocorticoid treatment was associated, in all patients, with only partial suppression of ACTH-regulated hybrid steroid and aldosterone production. Normalization of urinary hybrid steroid levels and abolition of ACTH-regulated aldosterone production is not a requisite for hypertension control and, if used as a treatment goal, may unnecessarily increase the risk of Cushingoid side effects.     

Increase in plasma concentrations of atrial natriuretic peptide during infusion of hypertonic saline in conscious newborn calves

Plasma concentrations of atrial natriuretic peptide (ANP), plasma renin activity (PRA), plasma concentrations of aldosterone, urine flow rate and sodium and potassium excretion were studied in two groups of four conscious 3-day-old male calves, infused with hypertonic saline or vehicle. Hypertonic saline infusion (20 mmol NaCl/kg body weight) was accompanied by a progressive rise in plasma concentrations of ANP (from 16.5 +/- 0.2 pmol/l at time 0 to 29.3 +/- 3.0 pmol/l at 30 min; P less than 0.05) and by a gradual decrease in PRA (from 1.61 +/- 0.23 nmol angiotensin I/l per h at time 0 to 0.54 +/- 15 nmol angiotensin I/l per h at 90 min; P less than 0.05); there was no change in the plasma concentration of aldosterone. Within the first 2 h of the 24-h urine collection period there was a marked rise in urine flow rate and sodium excretion in treated calves when compared with control animals (66.0 +/- 8.3 vs 15.9 +/- 1.2 ml/kg body weight per 2 h (P less than 0.05) and 6.7 +/- 1.3 vs 0.4 +/- 0.02 mmol/kg body weight per 2 h (P less than 0.01) respectively). During the following 22 h, urinary water and sodium excretion remained at significantly high levels. Thus, in the conscious newborn calf, changes in plasma ANP levels and urinary water and sodium excretion during hypertonic saline infusion are compatible with the hypothesis that endogenous ANP participates, at least in part, in the immediate diuretic and natriuretic renal response induced by the sodium overload.     

Diurnal rhythm of plasma catecholamines in acromegaly.

We investigated the 24-h profiles of the circulating levels of norepinephrine (NE) and epinephrine (E), blood pressure (BP), and heart rate in 14 acromegalic patients, before (A) and 3-6 months after transsphenoidal surgery (C-A, cured; A-A, active), and in 8 age-matched normal subjects (N). In addition, the responses of NE, E, PRA, and aldosterone to upright posture were investigated. No significant differences in the mean 24-h plasma NE and E levels were observed between either group of acromegalics and the N subjects. Analysis of the 24-h profiles indicated a statistically significant 24-h rhythm of both NE and E in N subjects. No evidence of a 24-h rhythm of plasma NE and E and BP was found in A patients. After surgery, a statistically significant 24-h rhythm of NE was detected in the patients with acrophase (13.54 and 13.45 h in C-A and A-A patients, respectively) and mesor (1019.8+/-45.1 and 1017.8+/-54.7 pmol/L in C-A and A-A patients, respectively) similar to those observed in N subjects (acrophase, 13.21 h; mesor, 942.3+/-42.5 pmol/L). After surgery, the plasma concentration of E clearly fluctuated throughout the 24 h in both C-A and A-A patients, even if cosinor analysis failed to reveal a 24-h significant rhythm. A statistically significant 24-h rhythm of BP was restored only in C-A patients. The mean 24-h heart rate was slightly, but significantly (P<0.05), higher in A than in N subjects and decreased after surgery. No significant differences in upright-stimulated NE, E, and plasma aldosterone levels were observed between each group of acromegalics and N subjects. However, basal and upright-stimulated PRA levels were significantly (P<0.001) lower in A patients. In conclusion, our study demonstrates the lack of a clear circadian variation in catecholamine levels and BP in active acromegaly and the return of a significant 24-h rhythm of NE and BP after pituitary surgery, concomitant with the reduction in GH and insulin-like growth factor I serum levels.     

Glyburide enhances the responsiveness of the beta-cell to glucose but does not correct the abnormal patterns of insulin secretion in noninsulin-dependent diabetes mellitus

Eleven patients with noninsulin-dependent diabetes mellitus were studied before and after 6-10 weeks of glyburide therapy. Patients were studied during a 24-h period on a mixed diet comprising 30 Cal/kg divided into three meals. The following day a hyperglycemic clamp study was performed, with glucose levels clamped at 300 mg/dL (16.7 mmol/L) for a 3-h period. Insulin secretion rates were calculated by deconvolution of peripheral C-peptide concentrations using individual C-peptide clearance kinetics derived after bolus injection of biosynthetic human C-peptide. After 6-10 weeks on glyburide, the identical studies were repeated. In response to glyburide, the fasting plasma glucose level decreased from 12.3 +/- 1.2 to 6.8 +/- 0.9 mmol/L. Although the mean glucose over the 24 h of the meal study decreased from 12.7 +/- 1.4 to 10.8 +/- 1.2 mmol/L, postprandial hyperglycemia persisted on therapy, and after breakfast, glucose levels exceeded 10 mmol/L and did not return to fasting levels for the remainder of the day. Fasting serum insulin, plasma C-peptide, and the insulin secretion rate were not different before (152 +/- 48 pmol/L, 0.82 +/- 0.16 pmol/mL, and 196 +/- 34 pmol/min, respectively) and after (186 +/- 28 pmol/L, 0.91 +/- 0.11 pmol/mL, and 216 +/- 23 pmol/min, respectively) glyburide treatment despite lowering of the glucose level. However, average insulin and C-peptide concentrations over the 24-h period increased from 366 +/- 97 pmol/L and 1.35 +/- 0.19 pmol/mL to 434 +/- 76 pmol/L and 1.65 +/- 0.15 pmol/mL, respectively. The total amount of insulin secreted over the 24-h period rose from 447 +/- 58 nmol before therapy to 561 +/- 55 nmol while receiving glyburide. Insulin secretion was demonstrated to be pulsatile in all subjects, with periodicity ranging from 2-2.5 h. The number of insulin secretory pulses was not altered by glyburide, whereas pulse amplitude was enhanced after lunch and dinner, suggesting that the increased insulin secretion is characterized by increased amplitude of the individual pulses. In response to a hyperglycemic clamp at 300 mg/dL (16.7 mmol/L), insulin secretion rose more than 2-fold, from 47 +/- 9 nmol over the 3-h period before treatment to 103 +/- 21 nmol after glyburide therapy. We conclude that the predominant mechanism of action of glyburide in patients receiving therapy for 6-10 weeks is to increase the responsiveness of the beta-cell to glucose.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effect of atrial natriuretic peptide on potassium-stimulated aldosterone secretion: potential relevance to hypoaldosteronism in man.

Atrial natriuretic peptide (ANP) has been shown to suppress aldosterone secretion under certain circumstances, although the physiological significance of this is uncertain. We wondered if ANP would suppress potassium-stimulated aldosterone secretion in man and, if so, whether we might find high circulating levels of ANP in patients with the syndrome of acquired hypoaldosteronism. We studied seven healthy young subjects under two conditions: 1) infusion of KCl (0.5 mmol/kg) over 45 min, and 2) KCl infused with ANP (0.01 microgram/kg.min) for 60 min. We also evaluated ANP levels in eight elderly subjects with the syndrome of acquired hypoaldosteronism, as defined by hyperkalemia (mean serum K+, 5.3 +/- 0.1 mmol/L) associated with inappropriately low aldosterone levels (216 +/- 50 pmol/L). In the normal subjects, ANP almost completely suppressed the aldosterone response to KCl infusion (P less than 0.001, by analysis of variance) despite a similar rise in the serum potassium level with KCl alone (0.70 +/- 0.07 mmol/L) and KCl plus ANP (0.75 +/- 0.09 mmol/L). PRA fell slightly during KCl plus ANP treatment, but did not change during the infusion of KCl alone. ANP levels were approximately 800 pmol/L during the ANP infusion studies. Endogenous ANP levels in the hyperkalemic patients with hypoaldosteronism were markedly elevated at 1186 +/- 340 pmol/L (compared to 93 +/- 10 pmol/L in healthy elderly controls), a level that would be capable of suppressing the potassium-mediated aldosterone response. Exogenous infusion of ANP suppressed the aldosterone response to hyperkalemia, and ANP levels were found to be markedly elevated in a group of patients with hyperkalemia and hypoaldosteronism. We suggest that ANP may contribute to clinically significant hypoaldosteronism and hyperkalemia in the syndrome of acquired hypoaldosteronism.     

Effect of upright posture on the aldosterone responses to dopamine, metoclopramide, angiotensin II, and adrenocorticotropin

Aldosterone secretion in man is stimulated by potassium (K), ACTH, and angiotensin II (AII) and inhibited by dopamine (DA). In normal sodium-replete supine individuals, aldosterone secretion is under maximum tonic inhibition by DA and is not inhibited further by DA administration. Sodium depletion alters plasma aldosterone responses to secretogogues. Upright posture, another physiological stimulus to aldosterone secretion, recently was demonstrated to sensitize the adrenal cortex to inhibition of aldosterone secretion by a large quantity of DA (4.0 micrograms/kg X min). The effect of upright posture on aldosterone responses to other secretogogues is unknown. In this study, we investigated the effect of upright posture on aldosterone responses to low infusion rates of DA, to the DA antagonist metoclopramide (M) and to AII and ACTH. Fourteen normal men eating a normal sodium diet were studied. In eight, PRA, plasma aldosterone (PAC), plasma cortisol (F), and serum K concentrations were determined after 4 h of upright posture and infusion of vehicle (D5W) or DA at 0.1, 0.4, and 2.0 micrograms/kg X min. Six other normal men were kept supine for 3 h and, on separate days, upright for 3 h and given iv M (10-mg bolus dose), AII (1 and 4 pmol/kg X min for 30 min), and ACTH (20 and 120 mU/h for 30 min). PAC, PRA, F, and K were measured before and after these three secretogogues were administered. In the presence of vehicle, mean PAC increased by 15.1 +/- 4.3 (+/- SEM) ng/dL after 4 h of upright posture. In the presence of DA infused at 0.1, 0.4, and 2.0 micrograms/kg X min, the PAC response to upright posture was decreased to 9.7 +/- 2.5 (P = NS), 7.5 +/- 3.9 (P less than 0.05), and 8.1 +/- 2.0 (P less than 0.05) ng/dL, respectively. This occurred without a decrease in PRA, F, or K. The stimulation of PAC 10 and 20 min after a 10-mg bolus dose of M was 9.6 +/- 3.3 and 9.3 +/- 2.6 ng/dL, respectively, in supine subjects and 8.3 +/- 2.3 and 10.8 +/- 3.4 ng/dL 10 and 20 min after the M dose in upright subjects. The responses of PAC to ACTH and AII also were unchanged after 3 h of upright posture. We conclude that upright posture sensitizes the adrenal cortex to inhibition of aldosterone secretion by DA without affecting other modifiers of aldosterone secretion.(ABSTRACT TRUNCATED AT 400 WORDS)     

Plasma adrenocorticotrophin, cortisol and aldosterone responses to ovine corticotrophin-releasing factor and vasopressin in sheep

Ovine corticotrophin-releasing factor (oCRF) (1 microgram/kg) and arginine vasopressin (AVP) (1 microgram/kg) were injected iv in sheep, both separately and in combination. Plasma levels of immunoreactive ACTH (IR-ACTH), cortisol, and aldosterone were measured for 3 h after the injections. Mean levels before injections were 8 +/- 4 pmol/l for ACTH, 7 +/- 3 nmol/l for cortisol, and 28 +/- 9 pmol/l for aldosterone. CRF caused a rapid rise in IR-ACTH and a peak level of 125 +/- 52 pmol/l was obtained 15 min after injection. Highest values for cortisol and aldosterone levels were 40 +/- 9 nmol/l and 64 +/- 13 pmol/l, respectively, 30 min after injection. AVP also increased IR-ACTH (maximum level: 202 +/- 77 pmol/l at 5 min) and aldosterone (128 +/- 36 pmol/l at 15 min), whereas the cortisol increase was lower than after CRF. Simultaneous injection of CRF and AVP produced an addition of the IR-ACTH response (295 +/- 82 pmol/l at 15 min), but the changes in cortisol levels were similar to those obtained after CRF alone and those in aldosterone levels resembled those induced by AVP alone. Plasma Na and K, osmolality, and plasma renin activity (PRA) were not modified by either CRF or AVP. It is suggested that the increase in aldosterone levels after CRF could be mediated by ACTH and that after AVP by an IR-ACTH peptide with less effect on cortisol secretion.     

Alterations in aldosterone secretion and metabolism in low renin hypertension

Low renin essential hypertensives (LRH) have normal plasma aldosterone levels which are inappropriately high in relation to their PRA. Posture is the major determinant for plasma aldosterone and PRA levels, but it is not known whether postural increments (delta) of plasma aldosterone and (delta) PRA are also abnormal in LRH. To evaluate this, LRH (n = 8), normal renin hypertensives (NRH; n = 9), normotensive controls (n = 18), and subjects with idiopathic hyperaldosteronism (IHA; n = 5) were studied in a metabolic unit on a controlled diet over 7 days. Overnight supine and 4-h upright PRA, plasma aldosterone, and 24-h urinary tetrahydroaldosterone (THA) and aldosterone secretion rates (ASR) were measured. The delta in plasma aldosterone after 4 h of upright posture was not different in the four groups. The ratio of delta plasma aldosterone/delta PRA, however, was elevated in both IHA and LRH compared to that in NRH and normals. THA excretion was also elevated in IHA and LRH, but LRH had a normal ASR. This resulted in a higher fractional THA excretion (THA/ASR) in LRH compared to the other three groups. These data further support enhanced adrenal angiotensin-II sensitivity in LRH. Aldosterone was preferentially metabolized to THA in LRH. Since THA has reduced biological activity, this may be a compensatory mechanism to reduce mineralocorticoid activity in LRH.     

Aldosterone excretion among subjects with resistant hypertension and symptoms of sleep apnea

OBJECTIVE: The severity of obstructive sleep apnea (OSA) correlates with the difficulty of controlling BP. The mechanism, however, by which sleep apnea contributes to the development of resistant hypertension remains obscure. Having observed a high prevalence of OSA among hypertensive subjects with primary hyperaldosteronism, we hypothesized a possible association between sleep apnea and aldosterone excretion. DESIGN: In consecutive subjects referred to a university clinic for resistant hypertension, we prospectively determined plasma renin activity (PRA), plasma aldosterone concentration (PAC), and 24-h urinary aldosterone excretion during high dietary salt ingestion. In addition, all subjects completed the Berlin Questionnaire, a survey designed to identify subjects at risk of having sleep apnea. Primary hyperaldosteronism (PA) was defined as a PRA < 1.0 ng/mL/h and 24-h urinary aldosterone excretion > 12 micro g during high urinary sodium excretion (> 200 mEq/24 h). RESULTS: Of the 114 subjects evaluated, 72 subjects had a high probability and 42 subjects had a low probability of having sleep apnea based on their responses to the Berlin Questionnaire. Subjects at high risk for sleep apnea were almost two times more likely to have PA diagnosed (36 vs 19%, p < 0.05), tended to have lower PRA (1.2 +/- 1.8 ng/mL/h vs 1.9 +/- 4.1 ng/mL/h), and had significantly greater 24-h urinary aldosterone excretion (13.6 +/- 9.6 micro g vs 9.8 +/- 7.6 micro g, p < 0.05) compared to subjects at low risk of sleep apnea. CONCLUSION: These data provide evidence of increased aldosterone excretion in subjects with resistant hypertension and symptoms of sleep apnea. While the causality of this association is unknown, it is hypothesized that sleep apnea contributes to the development of resistant hypertension by stimulating aldosterone excretion.     

Calcitonin gene-related peptide: 24-hour profile and responses to volume contraction and expansion in normal men

Plasma immunoreactive calcitonin-gene related peptide (CGRP) concentrations were measured in 10 normal male subjects, aged 23-34 yr, who were studied under 3 separate conditions at intervals of at least 1 week. In phase 1, plasma CGRP concentrations were measured hourly for 24 h during normal activity; in phase 2, the CGRP response to diuretic-induced volume depletion and upright posture was measured over 3 h; in phase 3, the CGRP response to volume loading and supine posture was measured over 4 h. During phase 1, the mean 24-h plasma CGRP concentration averaged 30 +/- 16 pmol/L; hourly CGRP concentrations ranged from 25-37 pmol/L over 24 h and oscillated from 16% below to 27% above the mean 24-h CGRP value, changes that were highly significant (P = 0.005). The peaks were at 0600 and 0700 h, while the nadirs were at 1200 and 2000 h. No significant difference was found between fasting CGRP at 0800 h and levels taken 1, 2, and 3 h postprandially (P = 0.68). During phase 2 (volume depletion and upright) mean plasma CGRP rose significantly, going from a baseline of 42 +/- 8 pmol/L at 0800 h to a peak of 60 +/- 10 pmol/L at 1100 h (P = 0.0005). The percent CGRP increment was relatively small (26% to 42%) compared to the rise in PRA (518% to 1033%) and aldosterone concentrations (333% to 465%). Hematocrit increased from 40.5 +/- 0.7% to 45.8 +/- 0.7% (P = 0.0001) in phase 2, while serum osmolality did not change significantly. In phase 3 (volume loading and supine), plasma CGRP did not change significantly, while PRA and aldosterone concentrations fell significantly (P = 0.0001); neither serum osmolality nor hematocrit changed significantly. We conclude that plasma CGRP concentrations fluctuate spontaneously and significantly during the day, and rise in response to volume depletion. The reasons for the CGRP fluctuations seen over 24 h, which are not apparent from this study, may be related to changes in vascular volume or other as yet unidentified factors. These studies are consistent with the concept that CGRP, acting either directly or through the renin-aldosterone system, may have a role in regulating peripheral vascular tone or controlling vascular volume.     

Adrenocorticotropin stimulation of aldosterone: prolonged continuous versus pulsatile infusion

Continuous iv administration of ACTH leads to a sustained stimulation of cortisol but a transient stimulation of aldosterone followed by a decline to prestimulation levels by 72 h. Since CRH and ACTH are released in a pulsatile pattern in man, this study sought to investigate whether pulsatile administration of alpha-cosyntropin-(1-24) would lead to the maintenance of aldosterone stimulation over time. Eight normal male subjects on a 10-meq sodium, 100-meq potassium diet received both a continuous and a pulsatile (0.33 U ACTH/pulse over 15 min, pulsed every 2 h) infusion of cosyntropin (4 U/24 h) for 48 h (n = 4) or 72 h (n = 4). Aldosterone and cortisol were sampled every 6 h, and PRA and angiotensin-II every 24 h. Continuous infusion led to a stimulation of aldosterone followed by a progressive decline to preinfusion levels by 72 h [preinfusion 29 +/- 5 ng/dL (810 +/- 139 pmol/L); 72 h, 38 +/- 10 ng/dL (1054 +/- 277 pmol/L); P = 0.40]. Pulsatile infusion led to a stimulation of aldosterone which was maintained up to 72 h [preinfusion 33 +/- 7 ng/dL (915 +/- 194 pmol/L); 72 h, 85 +/- 13 ng/dL (2358 +/- 361 pmol/L); P less than 0.05]. Regression analysis of aldosterone (y) over time (x) from the peak level at 18 h for the continuous infusion showed a significant negative relation (r = 0.63; P = 0.001), indicating a progressive decline in aldosterone. However, for the pulsatile infusion, there was no relation (r = 0.02; P = 0.85), indicating maintenance of aldosterone levels. There were no significant differences in sodium, potassium, PRA, angiotensin-II, or cortisol between infusions to explain these differences in aldosterone levels. Therefore, pulsatile infusion of cosyntropin maintains aldosterone secretion over time.     

Primary hyperaldosteronism: A missed diagnosis in ‘essential hypertensives’?

Background: It has been recognised recently that primary hyperaldosteronism may be more common than previously thought, the frequency of diagnosis being improved by screening using a plasma aldosterone concentration to renin activity ratio. Aims: To determine the frequency of primary hyperaldosteronism, screening with both plasma aldosterone to renin concentration (PRC) and activity (PRA) ratios, in normokalaemic subjects previously diagnosed as having essential hypertension. Methods: Plasma potassium, aldosterone and PRCs and PRA and blood pressure (BP) were measured in 74 hypertensive subjects previously diagnosed by one physician as having essential hypertension. A normal range for plasma aldosterone/renin ratios was determined in 147 control subjects. Hypertensive subjects with elevated aldosterone/renin ratios were further assessed for primary hyperaldosteronism using saline loading and fludrocortisone suppression. Those in whom plasma aldosterone concentration exceeded 140 pmol/L after suppression tests underwent adrenal vein sampling for measurement of aldosterone and Cortisol concentrations as well as adrenal CT scanning to diagnose the cause of primary hyperaldosteronism. The main outcome measures were a diagnosis of aldosterone producing adenoma or bilateral adrenal hyperplasia based upon adrenal vein sampling. Results: Four subjects (5%) had an elevated plasma aldosterone to renin ratio using PRC and six (8%) using PRA. Two subjects (2.7%) in this selected population had primary hyperaldosteronism, both of whom had BP > 160/110 mmHg at the time of testing. Conclusions: The frequency of normokalaemic primary hyperaldosteronism appears to be greater than previously thought, though the true incidence in the general population of hypertensive subjects remains unknown. The sensitivity of diagnosis (but not specificity) may be improved by measurement of the plasma aldosterone/renin ratio and PRC is at least as adequate as PRA for this process.     

Hemodynamic, hormonal, and renal effects of short-term adrenomedullin infusion in healthy volunteers

The actions of adrenomedullin (ADM), a 52-amino acid peptide, are not well defined in man. We, therefore, studied eight normal volunteers aged 1832 yr in a placebo-controlled crossover study. On the 2 study days, subjects received, in random order, ADM in "low" and "high" dose (2.9 pmol/kg x min and 5.8 pmol/kg x min for 2 h each) or vehicle (hemaccel) infusion on day 4 of a metabolic diet (Na+ 80 mmol/day, K+ 100 mmol/day). Achieved plasma ADM levels were in the pathophysiological range, and plasma cAMP values rose 5 pmol/L during the higher dose. Compared with time-matched vehicle infusion, high-dose ADM increased peak heart rate by 10 beats per minute (P < 0.05) and lowered diastolic (by 5 mm Hg, P < 0.01) blood pressure. Cardiac output increased in both phases of ADM (low dose, 7.6 L/min; high dose, 10.2 L/min; vehicle, 6 L/min; P < 0.05 for both). Despite a 2-fold rise in PRA during high-dose ADM (P < 0.01), aldosterone levels were unaltered. Norepinephrine levels increased by 50% during high-dose ADM (P < 0.001), but epinephrine levels were unchanged. Plasma PRL levels increased during high-dose ADM (P = 0.014). ADM had no significant effect on urine volume and sodium excretion. Infusion of ADM to achieve pathophysiological plasma levels produced significant hemodynamic effects, stimulated renin but inhibited the aldosterone response to endogenous angiotensin II, and activated the sympathetic system and PRL without altering urine sodium excretion in normal subjects.     

Increased adrenal sensitivity to angiotensin II in idiopathic hyperaldosteronism.

Plasma aldosterone increases briskly during upright posture in patients with idiopathic hyperaldosteronism, despite only small increases in PRA and presumably small increases in angiotensin II. To examine the postulate that small increments in angiotensin II mediate these brisk increases in aldosterone, we infused graded doses of angiotensin II into normal subjects and patients with idiopathic hyperaldosteronism and compared the changes in levels of plasma aldosterone in the two groups. Supplemental sodium and dexamethasone were given before the infusion to minimize the influence of endogenous angiotensin II and ACTH. In response to the infusion of angiotensin II, increases in the levels of plasma aldosterone of patients with idiopathic hyperaldosteronism were significantly greater than those of normal subjects. In addition, levels of plasma aldosterone increased at a lower rate of infusion of angiotensin II in patients than in normal subjects. It is concluded that patients with idiopathic hyperaldosteronism have increased adrenal sensitivity to angiotensin II. This increased sensitivity may explain the brisk increases in aldosterone that occur during upright posture in these patients.     

Evidence for cholinergic modulation of aldosterone secretion in man

Acetylcholine stimulates aldosterone secretion in bovine glomerulosa cells in vitro via specific cholinergic receptors. In this study we examined the effect of peripheral muscarinic blockade with atropine on metoclopramide-, angiotensin-II-, and ACTH-stimulated aldosterone secretion in man. Atropine (0.6 mg, iv) administered 10 min before MCP delayed the onset of the plasma aldosterone response and attenuated the mean peak response from 502 +/- 103 (+/- SE) to 322 +/- 72 pmol/L (P less than 0.05) without affecting zero time mean plasma aldosterone levels (144 +/- 28 vs. 136 +/- 36 pmol/L for control and atropine, respectively). This inhibitory effect was not mediated by changes in PRA or plasma potassium or ACTH (as reflected by cortisol) concentrations. Atropine also attenuated the plasma aldosterone response to a low dose angiotensin II infusion (2 ng/kg.min; control, 449 +/- 99 pmol/L; atropine, 297 +/- 78 pmol/L; P less than 0.05). In contrast, atropine had no effect on the plasma aldosterone response to a bolus dose (250 micrograms) of ACTH. Neither atropine (0.6 mg, iv) nor the cholinergic muscarinic agonist bethanechol (5 mg, sc) alone elicited a change in plasma aldosterone. Collectively, these data provide evidence for cholinergic modulation of aldosterone secretion in man. We conclude that cholinergic mechanisms may facilitate the aldosterone responses to angiotensin-II and metoclopramide, but not to ACTH.     

Comparison of adrenal vein sampling and computed tomography in the differentiation of primary aldosteronism

Determination of the etiology of primary aldosteronism remains a diagnostic challenge. The most common types of primary aldosteronism are bilateral adrenal hyperplasia (BAH), aldosterone-producing adenomas (APA), and primary adrenal hyperplasia. Computed tomography (CT) and adrenal vein sampling (AVS) are the primary modalities used to differentiate these subtypes. The purpose of this study was to compare AVS and CT imaging of the adrenal glands in patients with hyperaldosteronism in whom CT imaging was normal or in whom focal unilateral or bilateral adrenal abnormalities were detected. The diagnosis of primary aldosteronism was made in 62 patients based on an elevated plasma aldosterone to PRA ratio and an elevated urinary aldosterone excretion rate. Thirty-eight patients had CT imaging and successful bilateral adrenal vein sampling and were included in the final analysis. AVS was considered the gold standard in determining the specific subtype of primary aldosteronism. There were 15 patients with APA, 21 patients with BAH, and 2 patients with primary adrenal hyperplasia. Plasma aldosterone was significantly higher in patients with APA (46.3 +/- 8.5 ng/dL; 1284 +/- 235 pmol/L) than in those with BAH (29.3 +/- 2.4 ng/dL; 813 +/- 11 pmol/L; P < 0.05). Plasma potassium was significantly lower in patients with APA (3.1 +/- 0.1 mmol/L) than in patients with BAH (3.5 +/- 0.1 mmol/L; P < 0.02). There was considerable overlap in the other biochemical indices (e.g. PRA and urinary aldosterone) in patients with the different subtypes. In patients with APA proven by AVS, eight had concordant findings with CT imaging, four had discordant findings, and three had normal CT imaging. In patients with BAH proven by AVS, four had concordant findings with CT imaging, eight had discordant findings, and nine had normal CT imaging. Compared with AVS, CT imaging was either inaccurate or provided no additional information in 68% of the patients with primary aldosteronism. We conclude that adrenal CT imaging is not a reliable method to differentiate primary aldosteronism. Adrenal vein sampling is essential to establish the correct diagnosis of primary aldosteronism.     

Increased urinary endothelin-1 excretion in newly diagnosed type 2 diabetic patients

To investigate whether urinary and plasma endothelin (ET)-1 concentrations are responsive to the alteration of intravascular blood volume in uncontrolled diabetic patients, we determined urinary ET-1 excretion and plasma ET-1 concentration in 42 newly diagnosed type 2 diabetic patients and 38 normal subjects. Mean fasting plasma glucose value (12.8 +/- 0.72 mmol l-1) and plasma renin activity (PRA, 2.80 +/- 0.44 ng ml-1 hr-1) in diabetic patients were significantly higher as compared to normal controls (mean plasma glucose value: 5.2 +/- 0.83 mmol l-1; mean PRA value: 1.34 +/- 0.17 ng ml-1 hr-1), whereas plasma ET-1 value (1.33 +/- 0.07 pmol l-1) was not significantly different from that (1.29 +/- 0.06 pmol l-1) of normal controls. Mean urinary ET-1 excretion level (7.53 +/- 0.74 nmol mol-1 creatinine) was significantly higher than that (5.36 +/- 0.37 nmol mol-1 creatinine) of normal controls. Urinary ET-1 excretion was correlated with plasma glucose value (r = 0.360, p < 0.05) and PRA value (r = 0.381, p < 0.05). Urinary ET-1 excretion rate (5.17 +/- 0.37 nmol mol-1 creatinine) and PRA value (1.42 +/- 0.18 ng ml-1 hr-1) declined to normal levels when mean plasma glucose value decreased to the level of 7.1 +/- 0.39 mmol l-1 in diabetic patients after 4 months of glycemic control. Our results indicated that renal-derived ET-1 was responsive to the alteration of intravascular blood volume in untreated newly diagnosed type 2 diabetic patients.     

Timing and magnitude of response of plasma aldosterone concentration to bolus adrenocorticotropin: importance of sodium balance in outpatient testing.

Plasma aldosterone concentration (PAC) response to ACTH is utilized in clinical and experimental protocols. However, PAC response to ACTH in normal subjects controlled for modifiers of PAC has not been established. Our report includes two experiments. In both, subjects were studied in the morning and were in sodium (Na+) balance prior to study on 4 g Na+ for phase I, and 2 and 8 g Na+ diets for phase II. Na+ balance was established by 24-h urinary Na+ (UNa+) in phases I and II, and also by fractional excretion of Na+ (FENa+) in phase II. After being supine for 60 min, subjects received 0.25 mg of iv bolus ACTH. PAC, plasma renin activity and plasma potassium (K+) were drawn every 30 min in phase I and every 15 min in phase II. The rise in PAC (rPAC) and correlation coefficients were calculated. In phase I, peak PAC occurred at 30 min, 1130 +/- 420 pmol/L, with a rPAC of 810 +/- 310 pmol/L. Twenty-four hour UNa+ was 86 +/- 45 mmol/24 h. In phase II, time and magnitude of peak PAC and rPAC were dependent on diet. Both occurred at 30 min for 8 g Na+: peak PAC was 640 +/- 210 pmol/L and rPAC was 440 +/- 190 pmol/L; and at 60 min for 2 g Na+: peak PAC was 1040 +/- 320 pmol/L and rPAC was 690 +/- 220 pmol/L. Correlation coefficients for rPAC and 24-h UNa+ was r = -0.44, P less than 0.05 and for rPAC and FENa+ was r = -0.46, P less than 0.05. In summary, in subjects supine for 60 min prior to iv bolus ACTH, Na+ balance is the most important determinant of PAC response. Both magnitude and timing of rPAC is influenced by Na+ balance. Finally, both 24-h UNa+ and FENa+ are valid for establishing pretesting Na+ status.     

Effect of physiological levels of atrial natriuretic peptide on hormone secretion: inhibition of angiotensin-induced aldosterone secretion and renin release in normal man

Large doses of atrial natriuretic peptide (ANP) inhibit renin and aldosterone secretion in normal man, but the effect of physiological levels is unknown. We, therefore, studied the effect of a low infusion rate of alpha-human ANP (alpha hANP; 0.5 microgram/min for 180 min) on the plasma corticosteroid response to graded physiological doses of angiotensin II (0.5, 1.0, 2.0, and 4.0 ng/kg X min, each for 30 min) and ACTH (6.25, 12.5, 25, and 50 mIU, each for 30 min) in six normal men eating a low salt diet (10 mmol sodium and 100 mmol potassium daily). The angiotensin II and ACTH infusions were given from 0900-1100 h on separate days, during which randomized infusions of placebo or alpha hANP were given from 0800-1100 h according to a single blind protocol. Plasma immunoreactive ANP levels were less than 10 pmol/L on the placebo day compared to 30-50 pmol/L during the alpha hANP infusions, and were not altered by either ACTH or angiotensin II. Compared with the control observations, there was no significant change in arterial pressure or heart rate during either the alpha hANP or angiotensin II infusions. ACTH infusions evoked an incremental response in plasma aldosterone and cortisol, and the dose-response relationship was unaltered by alpha hANP. In contrast, while an incremental and significant increase in plasma aldosterone in response to angiotensin II occurred with the placebo infusion, no significant increase occurred in response to angiotensin during the alpha hANP infusion. The slope of the angiotensin II/aldosterone regression line was significantly less during all alpha hANP infusions compared to that during the placebo infusion (P less than 0.02). In addition, on the ACTH infusion day significant suppression of both PRA (P less than 0.05) and plasma angiotensin II (P less than 0.008) occurred during the alpha hANP infusion compared to that during the placebo infusion, whereas PRA was equally suppressed by angiotensin II in the presence or absence of alpha hANP. alpha hANP also increased urine volume [176 +/- 31 (+/- SEM) vs. 113 +/- 19 mL/mmol creatinine with placebo; P less than 0.03] and sodium excretion (2.14 +/- 0.48 vs. 0.58 +/- 0.22 mmol/mmol creatinine with placebo; P less than 0.004) on the ACTH infusion days. With angiotensin II, urine volume was also significantly increased by alpha hANP (150 +/- 27 vs. 81 +/- 15 mL/mmol creatinine with placebo; P less than 0.03), and urine sodium excretion doubled.(ABSTRACT TRUNCATED AT 400 WORDS)