Arginine vasopressin (AVP) mediates water transport in the renal collecting ducts by forming water channels of aquaporin-2 (AQP2) in the apical plasma membrane. AQP2 is excreted in human urine. We wanted to test the hypothesis that urinary excretion of AQP2 (u-AQP2) reflects the effect of AVP on the renal collecting ducts during water deprivation and hypertonic saline infusion in healthy subjects. Fifteen healthy subjects underwent a 24-h period of fluid restriction. Urine and blood samples were collected at timed intervals. Fifteen healthy subjects were given 7 ml/kg 3% hypertonic saline infusion for 30 min. Urine and blood samples were collected at timed intervals. During fluid restriction, the u-AQP2 rate increased from 3.9 (25th percentile: 3.1; 75th percentile: 5.2) to 7.6 (5.9-9.1; P < 0.001) ng/min, and the plasma AVP (p-AVP) level increased from 0.5 (0.4-0.6) to 3 (1.7-3.3) pmol/l. There was a positive correlation between the maximum change in u-AQP2 rate and the maximum change in p-AVP (r = 0.57, P < 0.03). During the infusion study, u-AQP2 rate was at maximum 90 min after the infusion [baseline: 4.5 ng/min (3.5-4.8); 90 min: 5 ng/min (4.5-6.0) P < 0.02]. p-AVP increased from 1.0 (0.9-1.1) to 1.5 (1.2-1.8; P < 0.002) pmol/l. There was a positive correlation between the maximum change in u-AQP2 rate and the maximum change in p-AVP (r = 0.83; P < 0.0001). It can be concluded that p-AVP and u-AQP2 are increased during thirst and hypertonic saline infusion and that u-AQP2 reflects the action of AVP on the collecting ducts.
Animal studies have implicated an important role of nitric oxide (NO) in the regulation of blood pressure, renal hemodynamics, and renal excretion of sodium. NG-monomethyl-L-arginine (L-NMMA) is a specific, competitive inhibitor of NO synthesis interfering with NO synthase. The purpose of the present study was to investigate the effect of L-NMMA on renal plasma flow (RPF), glomerular filtration rate (GFR), urinary sodium excretion (UNa), fractional sodium excretion (FENa), fractional lithium excretion (FELi), mean arterial blood pressure (MAP), and heart rate (HR) in healthy humans. In a randomized placebo-controlled study, 23 healthy subjects were randomized to receive either bolus injection of L-NMMA (3 mg/kg in 10 ml saline, n = 12 subjects) or placebo (10 ml saline, n = 11). GFR and RPF were measured using the renal clearances of 51Cr-labeled EDTA and 125I-labeled hippuran by the constant infusion technique. L-NMMA treatment induced 60 min after injection a 14.6% decrease in RPF, a 5.8% decrease in GFR, a 9.8% increase in filtration fraction, a 34.7% decrease in UNa a 28.6% decrease in FENa, and a 12.1% decrease in FELi. These changes were still evident 120 min after injection. None of the effect parameters were changed after placebo, except FENa, which increased 9.9% 60 min after injection. Ten minutes after L-NMMA injection, MAP increased significantly (80 vs. 88 mmHg), and HR decreased (58 vs. 47 beats/min). The changes in HR and MAP normalized within 30 min. L-NMMA significantly reduced the plasma level of cGMP 60 min (3.0 vs. 3.7 pmol/l) and 120 min after injection (2.5 vs. 3.7 pmol/l). It is concluded that, in healthy humans, NO is a regulator of renal hemodynamics as a tonic vasodilator and a regulator of sodium excretion, due at least in part to a proximal tubular effect.
Animal studies have indicated that increased nitric oxide (NO) synthesis plays a significant role in the renal adaptation to increased sodium intake. To investigate the role of NO during increased sodium intake in humans, we studied the effect of acute, systemic injection of N G-monomethyl-l-arginine (l-NMMA) on renal hemodynamics [glomerular filtration rate and renal plasma flow (GFR and RPF, respectively)], urinary sodium excretion (FENa), systemic hemodynamics [mean arterial blood pressure and heart rate (MAP and HR)], and plasma levels of several vasoactive hormones in 12 healthy subjects during high (250 mmol/day) and low (77 mmol/day) sodium intake in a crossover design. The sodium diets were administered for 5 days before the l-NMMA treatments, in randomized order, with a washout period of 9 days between each diet and l-NMMA treatment. GFR and RPF were measured using the renal clearance of51Cr-labeled EDTA and125I-labeled hippuran by the constant infusion technique in clearance periods of 30-min duration. Two baseline periods were obtained, after whichl-NMMA was given (3 mg/kg over 10 min), and the effect of treatment was followed over the next five clearance periods. During high sodium intake,l-NMMA induced a more pronounced relative decrease in RPF ( P = 0.0417, ANOVA), a more pronounced relative decrease in FENa( P = 0.0032, ANOVA), and a more pronounced relative increase in MAP ( P= 0.0231, ANOVA). During low sodium intake, the effect ofl-NMMA on FENa was abolished. During low sodium intake, l-NMMA induced a sustained drop in plasma renin (31 ± 5 vs. 25 ± 5 μU/ml, P < 0.001), which was not seen during high sodium intake. The data indicate that increased production of NO is an important part of the adaptation to increased dietary sodium intake in healthy humans, with respect to renal hemodynamics, sodium excretion, and the secretion of renin.
1. In a placebo-controlled, randomized dose-response study the effect of the prostaglandin analogue epoprostenol (Flolan) on the plasma level of atrial natriuretic peptide has been investigated in 14 healthy control subjects. 2. During epoprostenol infusion, atrial natriuretic peptide increased significantly in a dose-dependent manner, while it remained unchanged during placebo infusion [2 ng min-1 kg-1: epoprostenol 13.2% versus placebo -2.9%; 4 ng min-1 kg-1: epoprostenol 13.4% versus placebo -6.1%; 8 ng min-1 kg-1: epoprostenol 40.7% versus placebo -7.8% (medians), P < 0.01 for all]. 3. Mean blood pressure and heart rate increased significantly after epoprostenol, but were unchanged during placebo infusion [8 ng min-1 kg-1; mean blood pressure: epoprostenol -5.6% versus placebo 3.2%; heart rate: epoprostenol 32.7% versus placebo 3.1% (medians), P < 0.01]. 4. It is concluded that epoprostenol given intravenously increases the plasma level of atrial natriuretic peptide. The results support the hypothesis of an interaction between the prostaglandin system and atrial natriuretic peptide.
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