The effects of nitric oxide synthase (NOS) inhibition (effected using L-NAME, 14 mg (kg body mass (BM))(-1), administered intravenously) on systemic and renal circulation and renal excretory function has been investigated in anaesthetized Wistar rats subjected to one of two different degrees of isotonic extracellular (EC) volume expansion (40 and 60 ml x kg(-1) (240 min)(-1)). The administration of L-NAME resulted in an increase in mean arterial blood pressure and total peripheral vascular resistance (TPR), and a significant reduction in cardiac output (CO) and the kidney fraction of CO in both experimental groups. The total renal blood flow (RBF) dropped from 557 + 43.4 to 149 +/- 13.1 ml x min(-1) (100 g BM)(-1) and from 592 +/- 45.9 to 191 +/- 16.3 ml x min(-1) (100 g BM)(-1) in the 40 and 60 ml x kg(-1) (240 min)(-1) experimental volume expansion groups, respectively. A redistribution of the intrarenal circulation from the medulla of the kidney toward the cortex may have occurred. The NOS inhibition induced a significant decrease in the glomerular filtration rate (GFR; from 1.18 +/- 0.10 to 0.53 +/- 0.08 ml x min(-1) (100 g BM)(-1) and from 1.26 +/- 0.07 to 0.73 +/- 0.08 ml x min(-1) (100 g BM)(-1) in the 40 and 60 ml x kg(-1) (240 min)(-1) experimental volume expansion groups, respectively), and the filtration fraction increased. The urine excretion dropped in parallel with the GFR, while the reduction in sodium and potassium excretion was more marked than that of the GFR, raising the possibility of a direct effect on the kidney tubules. The difference in EC volume expansion (the calculated increases in the EC volume in the last 90 min were 1.30 and 5.44% in the two time control groups and 3.66 and 7.45% in the two L-NAME-treated groups) did not induce any significant modification of the L-NAME effect.
The renal hemodynamic effects of nitric oxide synthase (NOS) inhibition and dietary salt were studied in rats. L-NAME (0.1 mg/ml in the drinking fluid, about 12 mg/kg/day) was given for 4 days to rats receiving low (sodium depletion, SD), normal (N) or high (sodium load, SL) NaCl diet. Intrarenal hemodynamics was studied in anaesthesia. NOS inhibition decreased renal blood flow and increased renal vascular resistance in each group. Cortical and outer medullary but not inner medullary blood flow increased in direct ratio to the sodium intake. NOS inhibition decreased the blood flow and increased the vascular resistance in all layers of the kidney in SD, N, and SL rats as well. In SD and N, but not in SL rats L-NAME induced vasoconstriction was higher in the outer (OM) and inner medulla (IM) than in the cortex (C) [SD: ΔCVR 43%, ΔOMVR 54%, ΔIMVR 84%; N: ΔCVR 54%, ΔOMVR 96%, ΔIMVR 106%; SL: ΔCVR 50%, ΔOMVR 64%, ΔIMVR 35%]; in normal rats blood flow shifts from the medulla toward the cortex. In conclusion, nitric oxide may have a role in the regulation of renal vascular tone not only in the case of regular sodium uptake but in the sodium depleted or loaded organism as well. However, nitric oxide has no role in the dietary salt evoked vascular adaptation in the kidney.
The inhibitory action of indomethacin administered as a single-dose injection (4mg/kg) was examined under general anaesthesia in dogs, moderate volume expansion having been induced with physiological saline infusion. At 20 to 30 min after the administration of indomethacin, excretion of Na and water showed a fall of the same extent, GFR remaining stable and the effective plasma flow (CPAH) declining. RBF estimated by the 86Rb method decreased from 411 +/- 96 ml/min/100 g to 292 +/- 53 ml/min/100 g (p less than 0.01). This fall was coupled with an intrarenal redistribution of blood flow. While the cortical fraction of renal blood flow increased from 79% to 83.9% (p less than 0.001), its outer medullary fraction decreased from 17% to 13.2% (p less than 0.001) and its inner medullary fraction from 4.0% to 2.8% (p less than 0.05). The renal, primarily the medullary, vasculature is assumed on these grounds to be under the influence of a continuous secretion of prostaglandins which thus seem to be involved in the physiological control of intrarenal distribution of blood flow and of sodium and water excretion.
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