Effects of indomethacin on furosemide induced renal prostaglandin synthesis and action in man

We had previously shown that the early increment in plasma renin activity occurring within ten minutes of intravenous furosemide is accompanied by an increase in urine 6-keto-prostaglandin F1 alpha (6-keto-PGF1 alpha) the hydrolysis product of prostacyclin. Renal prostacyclin and thromboxane A2 synthesis are apparently limited to the cortex. To assess whether indomethacin would inhibit renal cortical eicosanoid synthesis and whether such reduction correlated with reduced early renin release, we assessed responses to intravenous furosemide (0.5 mg/kg) before and after indomethacin (150 mg/day for seven days) in ten normal male volunteers. Indomethacin did not change blood pressure but increased weight slightly (79.7 +/- 2.5 kg to 80.4 +/- 2.4 kg, p less than 0.05). Serum thromboxane B2 (TXB2), a measure of platelet thromboxane A2 production, was profoundly depressed (142 +/- 29 ng/ml to 4.8 +/- 1.6 ng/ml, p less than 0.001). Neither diuresis nor natriuresis were changed by indomethacin but potassium excretion was reduced (33 +/- 4 mmol/4 hr to 27 +/- 3 mmol/4 hr, p less than 0.05). Basal as well as furosemide stimulated plasma renin activity (at 10, 30 and 240 minutes) was reduced, as well as the transient increase in excretion rates of 6-keto-PGF1 alpha and TXB2. We conclude that the reduction in furosemide stimulated renin release by indomethacin is due to renal cyclo-oxygenase inhibition which is reflected in decreased excretion rates of hydrolysis products of renal eicosanoids.     

Effects of atenolol and enalapril on blood pressure, plasma renin activity and urinary prostanoids

In order to assess whether blood pressure reduction with atenolol or enalapril is associated with changes in renal prostaglandin (PG) synthesis, we studied the effects of 10 weeks therapy in 20 subjects with mild or moderate hypertension. After a four week placebo run-in period, subjects were randomized to receive either atenolol 50-100 mg/day or enalapril 5-20 mg/day for 10 weeks, then crossed over to the alternate active drug. Both drugs lowered blood pressure: placebo 147/97, atenolol 135/87, enalapril 132/87 (p less than 0.05, for both). Atenolol reduced resting heart rate but neither drug changed body weight, serum sodium or potassium or creatinine clearance. Intravenous furosemide was used as a standardized stimulus of renal PG synthesis. Neither drug changed the excretion rates of 6ketoPGF1 alpha or thromboxane B2 (hydrolysis products of PGI2 and thromboxane A2 respectively). Diuretic, kaliuretic, and natriuretic effects of furosemide were also not affected. Plasma renin activity was increased by enalapril but reduced slightly by atenolol. Subjects with more marked blood pressure reduction showed responses to furosemide no different than those with less effect. We conclude that blood pressure reduction with atenolol or enalapril does not change the response of renal eicosanoid synthesis to acute stimulation with furosemide.     

Responses to furosemide in normotensive and hypertensive subjects

As well as inducing natriuresis, intravenous furosemide increases renal prostanoid synthesis and induces renal vasodilation and a rapid rise in plasma renin activity (PRA). Patients with hypertension have abnormalities in renin release and renal vascular resistance that might be due to abnormalities in renal prostaglandin synthesis. We investigated responses to furosemide and placebo in normotensive (n = 13) and hypertensive (n = 14) subjects. There were no clear differences in PRA, sodium and water excretion, or excretion of prostanoid hydrolysis products (6-ketoprostaglandin F1 alpha and thromboxane B2) after placebo. In the hours after furosemide, 0.5 mg/kg-1, hypertensive subjects excreted more sodium, 189 +/- 13 mEq (mean +/- SE) and 154 +/- 8, and water, 1990 +/- 116 ml and 1614 +/- 109, than normotensive subjects. Excretion rates of creatinine and 6-ketoprostaglandin F1 alpha were much the same. Thromboxane B2 excretion rose in hypertensive subjects and was greater than in normotensive subjects (117.6 +/- 17.2 and 58.3 +/- 8.2 ng). With timed urine samples the excretion rate of 6-ketoprostaglandin F1 alpha and thromboxane B2 increased transiently for 30 min or less, whereas sodium and water excretion rates remained elevated for 4 hr. PRA rose in both groups 10 min after injection but reached a higher level in normotensive subjects. These differences in excretion of prostanoid hydrolysis products likely reflect renal synthesis of prostanoids and may be responsible for functional abnormalities of the kidney of hypertensive patients.     

Sulindac does not spare renal prostaglandins

It has been suggested that the nonsteroidal anti-inflammatory drug, sulindac, selectively spares renal prostaglandin synthesis. We compared the effect of placebo and sulindac 300 mg daily for one week on furosemide-stimulated renal prostaglandin synthesis in twelve healthy young men. Sulindac reduced serum thromboxane B2, a measure of platelet thromboxane A2 production, from 21 +/- 3.9 to 10.9 +/- 2.2 ng/ml (p less than 0.01) but had no effect on body weight, blood pressure or serum creatinine. Sulindac did, however, decrease the natriuretic effect of intravenous furosemide, and reduced the increment in plasma renin activity. The excretion rates of 6-keto-prostaglandin F1 alpha and thromboxane B2 in urine were reduced by 34 and 27% respectively (p less than 0.001 for both). The reduced excretion rate was particularly prominent in the first ten minutes after furosemide injection. While these decreases are less marked than those seen with indomethacin, the reduction in platelet thromboxane A2 production is also of lesser degree. We conclude that, in the dose used, sulindac is a less potent inhibitor of cyclo-oxygenase than indomethacin and has no selective renal sparing effect.     

Diltiazem increases renal prostacyclin.

We sought to determine whether the specific renal vasodilator effect of low dose diltiazem (D) was mediated by increased renal prostacyclin (PGI2) synthesis. Groups of 7-9 Sprague-Dawley rats were fitted with an indwelling transabdominal bladder cannula. Cannulae were placed in the jugular and femoral veins and the carotid artery and the rats allowed to recover for 24 h. Angiotensin II (AII) was infused intravenously at a rate (10 ng/kg/min) which increased mean arterial pressure (MAP) by 5-10%. After 30 min D(1 mg/kg and 2 micrograms/kg/min), D plus indomethacin (IND) (2 mg/kg and 33 micrograms/kg/min), IND plus vehicle or vehicle alone were added to AII. AII increased urinary 6-keto-prostaglandinF1 alpha (6-ketoPGF1 alpha) excretion from 1.36 +/- 0.12 to 1.86 +/- 0.20 ng/30 min (p less than 0.05) and D increased it further to 3.19 +/- 0.39 (p less than 0.05). Renal plasma flow (RPF) was estimated by 14C-PAH clearance (CPAH). Urinary excretion of 6-ketoPGF1 alpha was increased with AII indicating increased renal PGI2 synthesis. This increase in PGI2 was unable to prevent a reduction in RPF. D administration further increased the excretion of 6-ketoPGF1 alpha and reversed AII-induced renal vasoconstriction. IND augmented the AII response and prevented the effect of D, suggesting the renal vasodilator effect of D is, at least in part, PGI2-mediated. This mechanism may help maintain renal blood flow under conditions of vasoconstrictor stress.     

Pharmacodynamics and Pharmacokinetics of Irbesartan in Patients With Mild to Moderate Hypertension

BACKGROUND: The pharmacodynamics (plasma angiotensin II [AII], plasma renin activity [PRA], renal function, blood pressure [BP], urinary excretion of major metabolites of prostacyclin [PGI(2)-M], and thromboxane A(2) [TXA(2)-M]) and pharmacokinetics of irbesartan were assessed in hypertensive patients. METHODS AND RESULTS: Twenty-four white patients with seated diastolic blood pressure 95 to 110 mmHg were randomized to double-blind irbesartan 300 mg or placebo once daily for 4 weeks, following a placebo lead-in. Irbesartan-treated patients had significantly greater 24-hour area under the curve values for mean change from baseline in AII and PRA versus placebo-treated patients on day B15 (AII [pg |mZ h/mL]: 261 +/- 515 vs 12 +/- 51; PRA [(ng/mL/h); h]:74 +/-162 vs -2 +/-14; P values >.05). Irbesartan significantly lowered BP without clinically important changes in renal function. Irbesartan had no effect on 24-hour urinary TXA(2)-M excretion, but significantly increased 24-hour PGI(2)-M excretion versus placebo on day B29 (20.7 +/- 23 pg/mg creatinine vs _2.3 +/- 43 pg/mg creatinine; P <.05). Pharmacokinetics were comparable to those from previous studies. The hourly relationship between plasma irbesartan concentration and antihypertensive effect indicated a broad, clockwise hysteresis, with peak concentration occurring at 1.5 hours, whereas peak antihypertensive effect occurred at 4 hours. CONCLUSIONS: Irbesartan increases plasma AII and PRA and lowers BP consistent with AT(1) receptor blockade, without clinically important effects on renal function.     

Sulindac is not renal sparing in man

We investigated the claimed renal-sparing effect of the cyclooxygenase inhibitor sulindac. Fifteen normal women following a diet of 50 mEq salt a day were randomly assigned to 5 days of either placebo, sulindac, 200 mg b.i.d., or indomethacin, 25 mg q.i.d., after first serving as their own controls. Renal effects were assessed by the excretion rate of prostaglandin (PG) E2 (an index of renal PG synthesis), sodium balance, plasma renin activity (PRA), and the response to furosemide. Systemic effects were assessed by collagen-induced platelet aggregation and thromboxane B2 formation and by the urinary excretion of a systemically formed metabolite of PGF2 alpha (PGF-M). Both sulindac and indomethacin resulted in a positive sodium balance and a reduction in 24-hour urinary PGE2 excretion (range -49% to -86%). Basal PRA was decreased by indomethacin only, but the increases in PRA and in urinary PGE2 excretion in response to furosemide were inhibited by both sulindac and indomethacin. Sulindac reduced the natriuresis induced by furosemide, and indomethacin reduced the rise in inulin clearance after furosemide. Thus the two nonsteroidal anti-inflammatory drugs had similar effects on the kidney. Indomethacin had a greater effect than sulindac on the inhibition of collagen-induced platelet aggregation and thromboxane synthesis and the two drugs had equivalent effects on the reduction of PGF-M excretion. Peak plasma drug concentration of indomethacin (1.9 +/- 0.4 microgram/ml) and sulindac sulfide (7.7 +/- 1.9 microgram/ml) were those associated with clinical efficacy.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dissociation of systemic and renal effects in endotoxemia. Prostaglandin inhibition uncovers an important role of renal nerves.

To elucidate the mechanisms responsible for systemic and renal hemodynamic changes in early endotoxemia, the roles of prostaglandins (PG) and renal nerves were investigated. Endotoxin (E, 3 micrograms/kg i.v.) was given to two groups of anesthetized dogs that had undergone unilateral renal denervation: Group I (n = 9) E only; Group II (n = 11) E + indomethacin (10 mg/kg i.v.) or meclofenamate (5 mg/kg i.v.). A third group of dogs (Group III, n = 5) received indomethacin (10 mg/kg i.v.) only. 1 h after E group I dogs, mean arterial pressure (MAP) decreased from 126 to 94 mm Hg (P less than 0.001), and prostacyclin (6-keto-Fl alpha metabolite, PGI2) increased (from 0.64 to 2.08 ng/ml, P less than 0.005). Glomerular filtration rate (GFR) and renal blood flow (RBF) declined comparably both in innervated and denervated kidneys. In marked contrast, group II dogs had a stable MAP (136-144 mm Hg, NS) and no increase in PGI2 levels. Plasma renin activity (0.7-2.5 ng/ml per h, P less than 0.005) increased, and renin secretion was greater in innervated compared with denervated kidneys (255 vs. 74 U/min, P less than 0.01) in these PG-inhibited dogs. In addition, denervated kidneys in group II dogs had a greater GFR (42 vs. 34 ml/min, P less than 0.01) and RFB (241 vs. 182 ml/min, P less than 0.01) than innervated kidneys after E. Group III animals had no significant changes in systemic or renal hemodynamics, plasma renin activity or PGI2 during the study. These results suggest that PGI2 mediates the systemic hypotension of early endotoxemia in the PG-intact animal. Moreover, PG inhibition uncovers an important effect of E to increase efferent renal nerve activity with a consequent decline in GFR and RBF independent of changes in MAP. Finally, the results demonstrate that renal nerves are important stimuli to renin secretion in early endotoxemia via pathways that are PG-independent.     

Endogenous bradykinin and the renin and pressor responses to furosemide in humans

In humans, bradykinin contributes to the acute renin response after ACE inhibition. To further explore the role of endogenous bradykinin in human renin regulation, we determined the effect of HOE 140, a specific bradykinin B(2) receptor antagonist, on the renin response to 0.5 mg/kg i.v. furosemide in a randomized, single blind, crossover design study of 10 healthy, salt-replete volunteers. HOE 140 did not affect basal plasma renin activity, aldosterone, mean arterial pressure, or heart rate. Furosemide administration increased plasma renin activity from 1.0 +/- 0.2 to 4.5 +/- 1.2 ng of angiotensin I/ml/h and there was no effect of HOE 140 (from 1.1 +/- 0.2 to 3.9 +/- 0.8 ng of angiotensin I/ml/h). Similarly, there was no effect of HOE 140 on the diuretic response to furosemide. Mean arterial pressure increased in response to furosemide after HOE 140 (82 +/- 2 to 94 +/- 2 mm Hg), but not after vehicle (81 +/- 3 to 85 +/- 2 mm Hg), whereas heart rate was unchanged. In conclusion, activation of the B(2) receptor by endogenous bradykinin does not contribute to the renin response to acute furosemide treatment in humans. However, bradykinin may contribute to blood pressure regulation under conditions in which the renin-angiotensin system is stimulated.     

Autoregulatory vasodilation enhances renal prostaglandin E2 and associated renin release during arachidonic acid infusion in dogs

To examine whether autoregulatory dilation of preglomerular vessels enhances prostaglandin (PG)E2 and renin release during arachidonic acid infusion, the ureter was occluded or the renal artery constricted in anesthetized dogs. Intrarenal arachidonic acid infusion (40 micrograms X kg-1 X min-1) increased PGE2 release by 41 +/- 17 pmol/min at control pressures and by 149 +/- 60 pmol/min during ureteral occlusion. Arachidonic acid infusion (160 micrograms X kg-1 X min-1) increased PGE2 release by 149 +/- 60 pmol/min at control pressures, by 505 +/- 211 pmol/min during ureteral occlusion and by 581 +/- 201 pmol/min during renal arterial constriction. Thus, PGE2 release during arachidonic acid infusion was trebled by autoregulatory dilation. Arachidonic acid infusion (160 micrograms X kg-1 X min-1) raised renin release by 6 +/- 2 micrograms of angiotensin I per min at control pressures, by 25 +/- 9 micrograms of angiotensin I per min during renal arterial constriction and during ureteral occlusion by 16 +/- 4 micrograms of angiotensin I per min, which was not significantly higher than induced by the lower rate of infusion. Arachidonic acid infusion (160 micrograms X kg-1 X min-1) raised renal blood flow by 54 +/- 5% at control pressures but exerted no vasoactive effect during ureteral occlusion and renal arterial constriction. We conclude that autoregulatory dilation enhances the stimulatory effects of arachidonic acid on renal PG synthesis. Both increased intrarenal PG concentration and autoregulatory dilation may contribute to enhancement of renin release. The stimulatory effects of arachidonic acid on PG synthesis and renin release are independent of the vasoactive effects of arachidonic acid.     

Prostaglandins mediate the vasodilatory effect of mannitol in the hypoperfused rat kidney.

We have previously reported that mannitol strikingly increases blood flow to rat kidneys hypoperfused at 35-40mm Hg. This vasodilator effect is not due to volume expansion or alterations in plasma osmolality. We have tested the hypothesis that the vasodilatory effect of mannitol in the ischemic rat kidney is mediated by one of the vasoactive renal hormone systems: renin-angiotension, kallikrein-kinin, or prostaglandins. Rats were infused with 5% mannitol in 0.9% saline to 3-5% of body weight. In agreement with our previous studies, RBF increased 1.3 +/- 0.1 ml/min despite maintenance of perfusion pressure at 35-40 mm Hg. The cyclooxygenase inhibitors, meclofenamate and indomethacin had no effect on renal blood flow (RBF) in hypoperfused kidneys. However, in rats pretreated with these inhibitors, expansion with mannitol increased RBF by only 0.37 +/- 0.02 ml/min, 28% of the response in the untreated group (p less than 0.001). Infusion of prostacyclin (PGI2) into the renal artery during reduced perfusion resulted in an increase in RBF of 1.0 +/- 0.1 ml/min. Subsequent expansion with mannitol increased RBF by only 0.5 +/- 0.1 ml/min more, less than one-half of the effect of mannitol in a concurrent group of rats not treated with PGI2. Unlike PGI2 prostaglandin E2 had only a minimal vasodilator effect during hyperperfusion. Imidazole, an inhibitor of thromboxane synthesis, did not alter RBF or renal vascular resistance during hypoperfusion. Treatment of rats during hypoperfusion. with the angiotensin-converting enzyme (kininase II) inhibitor teprotide increased RBF by 1.1 +/- 0.3 ml/min. However, teprotide did not alter the vascular response to mannitol: RBF increased 1.2 +/- 0.1 ml/min more when mannitol was infused into teprotide-treated rats. The renal vascular response to mannitol was not altered by treatment with aprotinin, an inhibitor of the kallikrein-kinin system. Aprotinin was ineffective whether given before or after the vascular response to mannitol was established. We conclude that the vasodilator response to mannitol in the ischemic rat kidney is mediated in large part by increased prostaglandin (PGI2) activity. The failure of converting enzyme inhibition and aprotinin to block the vasodilator response to mannitol is evidence against a role for the renin-angiotension or kallikreinkinin systems in mediating the vasodilator response.     

The antihypertensive efficacy of hydrochlorothiazide is not prostacyclin dependent

We tested the hypothesis that vascular prostacyclin synthesis is stimulated by hydrochlorothiazide and could account for some of the drug's antihypertensive effect. We studied 13 patients with mild essential hypertension in a randomized, double-blind design to assess the effects of indomethacin on hydrochlorothiazide's ability to lower blood pressure, alter body weight, stimulate plasma renin activity, and modulate vascular prostacyclin biosynthesis as assessed by the urinary excretion of the major enzymatically produced metabolite of prostacyclin, 2,3-dinor-6-keto-prostaglandin F1 alpha (PGF1 alpha), measured by GC/MS. Administration of hydrochlorothiazide, 50 mg daily for 2 weeks, was associated with a significant decrease in both systolic and diastolic blood pressure in both supine (systolic, 148 +/- 3 to 136 +/- 3 mm Hg; diastolic, 97 +/- 2 to 94 +/- 3 mm Hg) and upright (systolic, 151 +/- 4 to 131 +/- 2 mm Hg; diastolic, 103 +/- 2 to 97 +/- 3 mm Hg) positions. Hydrochlorothiazide administration resulted in a 1 kg weight loss and stimulation of plasma renin activity from 1.7 +/- 0.4 to 5.3 +/- 1.1 ng angiotensin I/ml/hr. However, the urinary excretion of 2,3-dinor-6-keto-PGF1 alpha was unchanged after administration of hydrochlorothiazide (86 +/- 13/ng/gm creatinine during placebo, 74 +/- 13 ng/gm during week 1 of hydrochlorothiazide, and 70 +/- 9 ng/gm during week 2 of the drug). Administration of indomethacin, 50 mg twice a day, resulted in greater than 60% inhibition of 2,3-dinor-6-keto-PGF1 alpha excretion but did not affect the antihypertensive response to hydrochlorothiazide. Indomethacin did not oppose the diuretic effect of hydrochlorothiazide as assessed by weight loss but did attenuate the rise in plasma renin activity. Our data demonstrate that the blood pressure-lowering effect of a thiazide diuretic does not require enhanced prostacyclin synthesis and the cyclooxygenase inhibitor indomethacin does not antagonize the antihypertensive efficacy of hydrochlorothiazide.     

Changes in plasma renin activity and haemodynamics during vasodilator therapy in conscious dogs with myocardial infarction or chronic volume overload

The aim of the study was to compare the changes in plasma renin activity induced by a vasodilator in normal dogs and in dogs with an impaired cardiac reserve. In normal conscious dogs, a 60-min nitroprusside infusion increased plasma renin activity from 1.05 +/- 0.26 to 8.35 +/- 1.20 ng, angiotensin I ml-1 h-1 (P less than 0.002) and heart rate from 83 +/- 6 to 149 +/- 15 beats/min (P less than 0.002). In five dogs in which a aortocaval fistula had been created 4 weeks earlier, the same infusion still increased plasma renin activity but significantly less than in normal dogs (0.90 +/- 0.29 to 4.44 +/- 0.64 ng ml-1 h-1; P less than 0.01) and the heart rate was unchanged (134 +/- 4 to 139 +/- 7 beats/min; NS). Similarly, in five dogs with a previous myocardial infarction, the heart rats response to nitroprusside was blunted (108 to 107 beats/min;NS) and plasma renin activity increased less than in normal dogs. Plasma renin activity also increased acutely after hydralazine administration in dogs which myocardial infarction (1.05 +/- 0.26 to 8.99 +/- 0.79 ng ml-1 h-1; P less than 0.05); after 1 week of hydralazine, plasma volume had increased from 54.9 +/- 0.9 ml kg-1 to 74.5 +/- 4.9 ml kg-1 (P less than 0.05) and plasma renin activity remained higher than control (4.66 +/- 0.66 ng ml-1 h-1; P less than 0.01). In conclusion, vasodilator therapy rapidly activates vasoconstrictor forces and fluid retention even in dogs with limited cardiac reserve. Although the regulation of plasma renin secretion appears altered in these models of heart disease, the renin response remains sufficient to seriously limit the beneficial effects of vasodilator therapy.     

Role of Renal Prostaglandins in Sympathetically Mediated Renin Release in the Rat

Renal prostaglandins (PG) appear to mediate renin release due to stimulation of the intrarenal baroreceptor, but not that due to activation of the macula densa. However, as the role of PG in sympathetically mediated renin release remains unclear, a possible interrelationship between these factors was examined in conscious rats. Hydralazine increased the serum renin levels from 3.1+/-0.8 to 16.7+/-3.0 ng/ml per h at a dose of 1 mg/kg. Indomethacin (5 mg/kg) suppressed urinary PGE(2) and PGF(2alpha) excretion by 89 and 74%, respectively, arachidonate hypotension by 82%, and inhibited the elevated renin levels from hydralazine by 100% without altering the hypotensive effect of the drug. Another PG synthetase inhibitor, meclofenamate, was also effective in attenuating hydralazine-induced renin release, urinary PGE(2) and PGF(2alpha) excretion, and arachidonate hypotension. Isoproterenol, a nonselective beta-adrenergic agonist, increased heart rate, lowered blood pressure, and also stimulated the release of renin when administered intraperitoneally. However, intrarenal infusion of the drug only resulted in increased renin release. Indomethacin inhibited isoproterenol-induced renin release by 66 and 67%, respectively, without altering the hemodynamic effects associated with the intraperitoneal administration of the drug. The selective beta(1) agonist, H133/22, increased the release of renin and heart rate in a dose-related manner without altering blood pressure. H133/22-induced renin release was inhibited by 80% by indomethacin pretreatment. Finally, intrarenal infusions of dibutyryl cyclic AMP (3 mg/kg per min) increased the serum activity from 4.1+/-0.2 to 20.4+/-3.9 ng/ml per h without altering mean arterial pressure. Indomethacin inhibited this renin response to dibutyryl cyclic AMP by 96%. Thus, renal PG appear to be important mediators of sympathetically stimulated renin release acting as a site distal to the beta-adrenergic receptor.     

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.     

Endogenous Angiotensin Stimulation of Vasopressin in the Newborn Lamb

The effect of furosemide on plasma renin, vasopressin (AVP), and aldosterone concentrations was studied in 10 control and 6 nephrectomized lambs during the 1st 2 wk of life. In a separate study in 10 newborn lambs, 1-sarcosine-8-alanine-angiotensin II (saralasin acetate, 5 mug/kg per min) was infused alone for 40 min, after which furosemide 2 mg/kg i.v. was injected in association with continuing saralasin acetate infusion.Plasma renin activity increased from a mean (+/-SEM) of 21.3+/-3.4 ng/ml per h in the 10 control lambs to 39.4+/-8.2 ng/ml per h at 8 min (P < 0.001) and remained high through 120 min after furosemide. Plasma AVP and aldosterone concentrations increased from respective mean values of 2.1+/-0.4 muU/ml and 12.8+/-2.5 ng/dl to 9.8+/-2.0 muU/ml (P < 0.01) and 23.0+/-7.7 ng/dl (P < 0.05) at 35 min and 13.8+/-2.1 muU/ml and 23.0+/-4.4 ng/dl at 65 min after furosemide (each P < 0.01). There was an insignificant AVP response in the 10 lambs treated with angiotensin inhibitor: from a mean base line of 4.7+/-0.9 to 8.3+/-2.0 muU/ml at 35 min, and 7.4+/-2.0 muU/ml at 65 min after furosemide. There was no increase in AVP in the anephric lambs.The mean increment AVP response from base line in the newborn lambs without saralasin, Delta 10.8+/-2.0 muU/ml, was greater than in the lambs with saralasin, Delta4.0+/-1.9 (P < 0.05), and greater than in the anephric lambs, Delta3.3+/-2.1 muU/ml (P < 0.05). The mean blood pressure fell 6 mm Hg in the 10 control lambs (P < 0.05), 7 mm Hg in the anephric lambs (P < 0.05), and 16 mm Hg in the lambs treated with angiotensin inhibitor (P < 0.05) by 35 min after furosemide. However, the changes in plasma AVP were not related to the fall in blood pressure.These data support the view that the observed AVP response to furosemide in the newborn lamb was mediated through the renin-angiotensin system.     

Mechanisms of Renin Secretion during Hemorrhage in the Dog

The importance of renal perfusion pressure (RPP), the sympathetic beta adrenergic nervous system and renal prostaglandins (PG) on renin release during a uniform 15-17% reduction in blood pressure by hemorrhage (HH) was studied systematically in anesthetized dogs. All groups of animals had similar decrements in systemic and renal hemodynamics with HH. In control dogs (n = 7), both plasma renin activity (PRA, 4.1-9.0 ng angiotensin I/ml per h, P < 0.05) and renin secretory rate (RSR, 26-228 ng/ml per h.min, P < 0.005) increased significantly with HH. This increase in renin release during HH was not abolished by any single maneuver alone including beta adrenergic blockade with d,l-propranolol (n = 6), renal PG inhibition with indomethacin (n = 7), or control of RPP (n = 6). However, when beta adrenergic blockade was combined with control of RPP (n = 7) during HH, neither PRA (1.9-2.7 ng/ml per h, NS) nor RSR (16-53 ng/ml per h.min, NS) increased significantly. Similarly, a combination of beta adrenergic blockade and PG inhibition (n = 6) also abolished the increase in PRA (1.5-1.4 ng/ml per h, NS) and RSR (14-55 ng/ml per h.min, NS) during HH despite significant decreases in sodium excretion. Finally, a combination of PG inhibition and RPP control was associated with significant increases in PRA and RSR during HH. These results support a multifactorial mechanism in renin release during HH and implicate both the beta adrenergic receptors, renal baroreceptors, and possibly the macula densa as constituting the primary pathways of renin release during HH of this magnitude. Because either constant RPP or PG inhibition blunted renin release during HH in the setting of beta adrenergic blockade, the present results strongly suggest that the renal baroreceptor, and probably the macula densa mechanism are PG mediated.     

Hydrochlorothiazide Increases Efferent Glomerular Arteriolar Resistance in Spontaneously Hypertensive Rats

BACKGROUND: Micropuncture studies were performed to determine the intrarenal hemodynamic effects of two conventional antihypertensive agents, hydrochlorothiazide (HCTZ) and hydralazine (HYDR) alone and in combination. METHODS AND RESULTS: Male spontaneously hypertensive and normotensive Wistar Kyoto rats (19 weeks old) were treated for 3 weeks with vehicle (control), HCTZ (80 mg/kg/d), HYDR (5 mg/kg/d), or combined therapy (HCTZ 30 mg/kg/d and HYDR 2 mg/kg/d). Each treatment significantly reduced arterial pressure while effective renal plasma flow, glomerular filtration rate and single nephron glomerular filtration rate were unaffected by any treatment in either strain. In spontaneously hypertensive rats HCTZ decreased single nephron plasma flow (111 +/- 8 to 84 +/- 4 nL/min; P <.05) but, despite this reduction, glomerular pressure remained unchanged (51.4 +/- 0.7 to 52.1 +/- 0.8 mmHg) attributable to increased efferent glomerular resistance (1.58 +/- 0.14 to 2.11 +/- 0.12 10 U; P <.05). By contrast, HYDR increased single nephron plasma flow (to 147 +/- 8 nL/min; P <.01) and decreased efferent glomerular resistance (to 1.09 +/- 0.09 U; P <.05). Combined treatment produced responses similar to HCTZ when used alone, thereby nullifying the beneficial efferent glomerular resistance effects: single nephron plasma flow +/- fell (to 89 +/- 7 nL/min; P <.05) and efferent glomerular resistance increased (to 2.05 +/- 0.17 U; P <.05). In Wistar Kyoto rats, HCTZ and combined treatment had no effect. HCTZ alone induced glomerular ischemia that was associated with efferent glomerular arteriolar constriction in these spontaneously hypertensive rats. CONCLUSIONS: These findings provide a possible explanation for the lack of improved renal target-organ damage in controlled multicenter trials employing thiazide diuretics.     

Comparison of intravenous dilevalol with placebo in moderate hypertension

Dilevalol, an agent that combines nonselective beta-blocking and beta 2-mediated vasodilating properties, was compared with placebo in 16 subjects with moderate hypertension in a double-blind crossover study. Dilevalol or a placebo was administered intravenously in bolus injections of 25, 50, and 50 mg at 15-minute intervals. Fifteen minutes after a cumulative dose of 125 mg, the blood pressure was lowered by 11/9 mm Hg, compared with 2/1 mm Hg after placebo (p less than 0.01 between groups for systolic and diastolic blood pressure), an effect that persisted for at least 105 minutes. Standing systolic blood pressure was also lowered in dilevalol-treated patients without orthostatic symptoms. No significant effects on heart rate were noted. Fifteen minutes after the last dose of dilevalol, plasma norepinephrine levels increased from a baseline of 200 +/- 24 to 495 +/- 44 pg/ml (p less than 0.01), compared with a nonsignificant rise from 262 +/- 21 to 306 +/- 28 pg/ml with placebo vehicle. Dilevalol also increased alpha-human atrial natriuretic factor by 5.4 pg/ml, compared with 0.5 pg/ml after placebo (p less than 0.01 between groups). Plasma renin activity and plasma epinephrine, aldosterone, and cyclic guanosine monophosphate levels were unchanged by dilevalol. There were no significant adverse effects with dilevalol administration. Compared with placebo, dilevalol given intravenously appears to be safe and effective antihypertensive treatment.     

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.