Plasma sodium concentration and sodium excretion in the anaesthetized dog.

1. The effect of acute alterations of plasma sodium concentration (PNa) on renal sodium excretion (UNaV) was investigated by three types of experiments on anaesthetized dogs: (a) A local increase in PNa at one kidney was produced by infusion of hypertonic saline directly into its artery while systemic levels of PNa were stabilized by haemodialysis. (b) Systemic levels of PNa were lowered by exchange transfusion of blood for an equal volume of salt-free dextran-in-dextrose solution. The results were contrasted with those observed after similar exchanges, but using dextran-in-saline solution. (c) The level of PNa was altered by varying the sodium concentration of a saline solution infused at a fixed rate either intravenously or into one renal artery. 2. All three types of experiment suggest a dependence of UNaV on PNa Analysis demonstrated that this relationship was not due to contemporary changes in: packed cell volume; plasma solids concentration; plasma potassium concentration; blood pressure or plasma hydrogen ion concentration. The distribution of these variables did not change with PNa except for plasma hydrogen ion concentration. Moreover, the relationship persisted when data were selected to exclude clearance periods in which the value for any variable had shifted past the group mean obtained before PNa was altered. 3. The fall in UNaV at low levels of PNa could be attributed to a fall in glomerular filtration rate (GFR), but the progressive rise in UNaV seen as PNa exceeded 150 m-mole 1(-1) occurred despite a fall in GFR and no apparent change in the mean filtered load of sodium. These results suggest that the increased sodium excretion accompanying raised levels of PNa is due to reduced tubular re-absorption of sodium.     

Hemodynamic mechanisms influencing sodium excretion during angiotensin infusion.

To examine mechanisms of transition between antinatriuresis and natriuresis, angiotensin II was first infused intrarenally (0.001-0.07 mug/kg-min) in anesthetized dogs; glomerular filtration rate (GFR), sodium excretion, and intrarenal pressure (IRP), indicating tubular pressure, fell as during mechanical aortic constriction. During supplementary intravenous infusion (0.10-0.30 mug/kg-min), renal blood flow (RBF) rose toward control (tachyphylaxis). Tubular reabsorption increased but was still 17.1% below control. Filtration fraction averaging 0.31 remained constant. Sodium excretion and IRP exceeded control but were normalized by restoring renal arterial pressure mechanically. During intrarenal angiotensin infusion, carotid constriction increased blood pressure more, but RBF, IRP, and sodium excretion less than intravenous angiotensin. Intrarenal infusion of angiotensin at 0.10-0.20 mug/kg-min increased RBF and sodium excretion more in infused than in contralateral kidneys. Thus, angiotensin natriuresis depends on increased perfusion pressure and is augmented as tachyphylaxis develops. High correlation between sodium excretion and IRP at unchanged filtration fraction suggests a regulation of sodium excretion by hydrostatic rather than oncotic pressures in glomerular and peritubular capillaries.     

Neural control of renal excretory function during behavioral stress in conscious dogs

The renal and neural mechanisms underlying the excretory response to behavioral stress (aversive conditioning) were examined in 30 conscious dogs. Twenty-one dogs decreased urine flow more than 20% during stress, whereas 9 dogs showed less than a 10% decrease. In 11 of the 21 renal-reactive dogs, decreases in urine flow (42%) and sodium excretion (45%) were associated with unchanged glomerular filtration (-1.5%; GFR; inulin clearance) and effective renal blood flow (-4%; RBF; p-aminohippurate clearance). In the other 10 renal-reactive dogs, similar declines in urine flow (54%) and sodium excretion (52%) occurred with decreases in GFR (24%) and RBF (27%). Among all 30 dogs, greater increases in cardiovascular activity during stress were associated with greater decreases in renal excretion. Surgical renal denervation abolished the excretory response to stress in 4 of 5 dogs. These findings suggest that excretory responses in most dogs are mediated 1) primarily via increased tubular reabsorption rather than decreased GFR, 2) via central integration with cardiovascular responses, and 3) via the renal nerves.     

Denervated and intact kidney responses to saline load in awake and anesthetized dogs.

The function of the innervated and denervated kidney was examined in clearance studies with unilaterally renal-denervated conscious and anesthetized dogs before and after saline loading. Barbiturate anesthesia distinctly depressed hemodynamics and excretory function of both kidneys and increased the difference between the denervated and innervated organ. In conscious moderately hydrated dogs the denervated kidney excreted slightly more sodium and water, while after saline loading higher excretion was observed on the innervated side. The denervated-to-innervated kidney ratios for UNaV, UNaV/100 ml GFR, and urine flow fell significantly from mean control values of 1.27, 1.27, and 1.20, respectively, to 0.80, 0.87, and 0.77 after extracellular volume expansion. Similar alterations of the ratios were observed in anesthetized dogs, but higher excretion of the denervated kidney persisted after saline loading. It is concluded that the greater natriuretic response of the intact kidney to saline infusion was due to inhibition of sodium-retaining action of renal efferent nerve activity by acute extracellular volume expansion.     

Effect of sodium nitrate loading on electrolyte transport by the renal tubule.

Effects of sodium nitrate were compared with sodium chloride loading on transport of electrolytes by the nephron. Maximal levels of free water clearance/clomerular filtration rate (CH2O/GFR) averaged 8.4% with nitrate loading and 14.4% with saline loading. Since ethacrynic acid and chlorothiazide exert their major natriuretic effect in the distal nephron, the increment in Na ad Cl reabsorbed beyond the proximal tubule. The administration of these agents resulted in an increase in fractional sodium excretion (CNa/GFR) of 21.1%, urinary sodium excretion (UNaV) of 1,126 mueq/min, and urinary chloride excretion (UClV) of 848 mueq/min during nitrate loading compared with an increase in CNa/GFR of 37.6%, UNaV of 2,362 mueq/min, and UClV of 2,397 mueq/min during saline loading. The smaller diuretic-induced increment in Na and Cl excretion in the nitrate studies suggests, as do the hydrated studies, that less Cl and Na are reabsorbed in the distal nephron during nitrate than saline loading. At every level of UNaV, fractional bicarbonate reabsorption was higher, urine pH was lower, and urinary potassium excretion (UKV) was higher in the nitrate studies. Thus, compared with saline loading, sodium nitrate decreases chloride and sodium reabsorption in the distal nephron. The higher hydrogen and potassium secretion in the nitrate studies may be consequent to the decreased ability of the distal nephron to reabsorb chloride.     

Hemodynamic and excretory response of the neonatal canine kidney to acute volume expansion.

It is generally recognized that developing animals retain sodium due to an enhanced reabsorption in distal tubule segements, even when the amount administered is in excess of their needs. This study was designed to test the relationship between this relative inability to dispose of a saline load and the functional characteristics of the kidney during postnatal maturation. In addition, we explored the role played by some of the factors known to affect natriuresis in the adult subject. Measurements of sodium excretion, glomerular filtration rate (GFR), and renal blood flow (RBF) and its intrarenal distribution were made in three age groups of puppies and in adult dogs. During expansion the GFR rose rapidly and to a similar extent at all ages, but it fell thereafter, the rate of decline being much slower in adult than in developing animals (P less than 0.001). RBF and its intrarenal distribution were not altered by volume expansion. The degree of natriuresis did not reflect either the age-related or the expansion-induced changes in GFR. Fractional and absolute sodium excretion were substantially higher in 2-wk-old puppies than in either 1- or 3-wk-old animals (P less than 0.002). These findings demonstrate that the blunted renal response of the maturing animal to saline loading is due to the persistence of an enhanced tubular reabsorption rather than to a limitation in glomerular filtration.     

Effects of endothelin on renal haemodynamics and segmental sodium handling in conscious rats

The effects of endothelin (100 and 600 pmol/kg) on renal plasma flow (RPF), glomerular filtration rate (GFR), sodium excretion (U_Na V) and segmental sodium handling were investigated in conscious rats. Low-dose endothelin decreased renal plasma flow by 26% without affecting glomerular filtration rate and sodium excretion. High-dose endothelin reduced renal plasma flow, glomerular filtration rate, sodium excretion and lithium clearance by 57, 45, 38 and 52%, respectively. The fall in sodium excretion was not due to a direct effect of endothelin on tubular sodium transport since sodium excretion corrected by glomerular filtration rate and fractional proximal and distal sodium reabsorption did not change throughout the study. These results indicate that the impairment in renal perfusion is responsible for the antinatriuretic effect of endothelin in conscious rats.     

Effects of dopamine blockade on renal sodium excretion

The renal responses to a specific dopamine antagonist (cis-flupentixol) and its stereoisomer (trans-flupentixol), a weak dopamine antagonist, were examined during hydropenia and Ringer loading in anesthetized rats. During hydropenia glomerular filtration (GFR), absolute (UNaV), and fractional (FENa) sodium excretion rates were similar as were single-nephron filtration (SNGFR) and proximal tubular flow rate (VTF). After Ringer loading GFR, UNaV, and FENa increased in all groups, but the increments were less in the cis-flupentixol than in the control or trans-flupentixol group. SNGFR and VTF increased similarly in all groups. In another series of experiments Ringer loading was performed prior to drug administration. Perfusion pressure (PP) was decreased in trans-flupentixol rats by aortic constriction to control for cis-flupentixol-induced reduction in PP. UNAV and FENa were lower in the cis-flupentixol- than trans-flupentixol-treated rats at comparable PP and GFR. In conclusion, dopamine blockade attenuated the natriuresis of Ringer loading; the mechanism is uncertain but may be related to a tubular effect at a site beyond the proximal convoluted tubule and/or in deeper nephrons.     

Maleate-induced bicarbonaturia in the dog: a carbonic anhydrase-independene effect.

Studies were performed to characterize the renal effects of maleate in anesthetized dogs. Following the intravenous administration of maleate or maleic acid (50 mg/kg), mean fractional bicarbonate excretion (CHCO3/GFR) rose to as high as 26%. Na, K, and phosphate excretion also increased markedly, whereas C1 excretion remained low. An initial transient fall in urinary pH from 6.53 to 6.13 contrasted sharply with the rapid alkalinization of the urine induced by acetazolamide administration. During saline expansion CHCO3/GFR rose from 4 to 37% after maleate administration, whereas Cl excretion did not change significantly. During continuous carbonic anhydrase inhibition with acetazolamide, maleate administration resulted in a further rise in CHCO3/GFR from 22 to 35%. Whereas CPO4/GFR increased only from 1 to 3% during acetazolamide administration, this ratio reached 75% following the addition of maleate. Fumarate, the transisomer of maleate, and malonate, a well-known inhibitor of Krebs cycle, failed to affect bicarbonate excretion. This study demonstrates that maleate inhibits the fraction of bicarbonate reabsorption uncatalyzed by carbonic anhydrase. Impaired anionic reabsorption of bicarbonate or accelerated passive backflux of this ion into proximal tubular lumen are the two mechanisms that best explain the bicarbonaturia induced by maleate.     

Effect of infusion of pharmacologic amounts of vasopressin on renal electrolyte excretion.

Aqueous vasopressin was infused to bicarbonate- and glucose-loaded dogs and to nonloaded antidiuretic dogs in doses of 50 mU/kg per min or 50 mU/kg per h. Both doses caused a marked increase in sodium, chloride, and water excretion. The larger dose raised the fractional excretion (sodium clearance (C-Na)/glomerular filtration rate (GFR) times 100) of these ions from 2% or less to in excess of 20%. Blocking the pressor effects of these doses of vasopressin with sodium nitroprusside did not alter the marked natriuretic and chloriuretic effect. The maximal rate of bicarbonate and glucose reabsorption was not depressed by vasopressin infusion; fractional phosphate excretion, however, was markedly increased. Inhibiting distal hydrogen ion secretion by inducing selective aldosterone deficiency failed to uncover a vasopressin-induced inhibition of proximal bicarbonate reabsorption that might have been masked by increased distal bicarbonate reabsorption. There was no significant change in GFR, renal plasma flow, or filtration fraction. The distribution of cortical renal blood flow (measured by the radioactive microsphere technique) shifted toward the inner cortex after vasopressin administration. Vasopressin, in pharmacologic doses, is a potent diuretic that most likely exerts this effect by directly inhibiting sodium reabsorption at a point in the nephron distal to the proximal tubule.     

The dopamine receptor antagonist haloperidol blocks natriuretic but not hypotensive effects of the atrial natriuretic factor

Studies were performed on anesthetized male Münich-Wistar rats to investigate the influence of the dopamine (DA) receptor antagonist haloperidol on the natriuretic response to infusion of a synthetic atrial natriuretic factor. The whole kidney glomerular filtration rate (GFR), urinary excretion of electrolytes, and arterial blood pressure (BP) were therefore measured in groups of animals pretreated with haloperidol or vehicle and given a continuous intravenous infusion of atrial natriuretic peptide (ANP; 28 amino acids). Forty-five minutes of ANP infusion at 10 micrograms h-1 kg-1 body wt did not increase GFR (change from 1.14 +/- 0.08 to 1.15 +/- 0.05 ml min-1 g-1 kidney wt). Sodium excretion (UNaV) increased more than four-fold from 0.037 +/- 0.008 to 0.165 +/- 0.070 mumol min-1 g-1 kidney wt (P less than 0.01). Potassium excretion (UKV) increased by 86% (P less than 0.001) and the urine flow rate (V) increased transiently by 63% (P less than 0.05) and did not differ from the control value during the last 15 min of ANP infusion. The urinary sodium concentration (UNa) increased almost three-fold, while BP decreased by 14%. There was no change in urine osmolality. In animals pretreated with haloperidol (1 mg kg-1 body wt), 45 min of ANP infusion did not significantly alter GFR (from 1.10 +/- 0.08 to 0.98 +/- 0.09 ml min-1 g-1 kidney wt). The UNaV did not increase significantly (change from 0.026 +/- 0.006 to 0.030 +/- 0.009 mumol min-1 g-1 kidney wt). The UKV was not elevated by ANP infusion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of renal beta 1-adrenoceptors and prostaglandins in reflex renin release

Anesthetized dogs with isolated carotid sinus preparation were used to examine the mechanisms involved in the increase in renin secretion rate produced by carotid baroreceptor reflex renal nerve stimulation (RNS) at constant renal perfusion pressure. Lowering carotid sinus pressure by 41 +/- 5 mmHg for 10 min increased mean arterial pressure and heart rate, caused no or minimal renal hemodynamic changes, decreased urinary sodium excretion, and increased renin secretion rate. Metoprolol, a beta 1-adrenoceptor antagonist, given in the renal artery, did not affect the decrease in urinary sodium excretion but attenuated the increase in renin secretion rate, from 1,764 +/- 525 to 412 +/- 126 ng/min (70 +/- 8%). Indomethacin or meclofenamate, prostaglandin synthesis inhibitors, did not affect the decrease in urinary sodium excretion but attenuated the increase in renin secretion rate, from 1,523 +/- 416 to 866 +/- 413 ng/min (51 +/- 18%). Addition of metoprolol to indomethacin-pretreated dogs attenuated the increase in renin secretion rate from 833 +/- 327 to 94 +/- 60 ng/min (86 +/- 10%). These results indicate that reflex RNS at constant renal perfusion pressure results in an increase in renin secretion rate that is largely mediated by renal beta 1-adrenoceptors and is partly dependent on intact renal prostaglandin synthesis. The beta 1-adrenoceptor-mediated increase in renin secretion rate is independent of and not in series with renal prostaglandins.     

Renin secretion during dynamic changes in renal perfusion pressure.

Uninephrectomized ewes were prepared with a renal artery flow probe and catheters were implanted into the renal artery, vein, and ureter. The renal perfusion pressure (RPP) of conscious animals was decreased externally by 13 +/- 3, 21 +/- 3, 31 +/- 3 mmHg over 5 min and returned to control levels over 5 min. Reduction of RPP by 13 and 21 mmHg resulted in prompt increases in renin secretion (RS) which were maximal coincident with the nadir of the downward ramp (delta RS 195 +/- 43 P less than 0.05, and 1,077 +/- 208 ng AI/min, P less than 0.01, respectively). Directly measured renal blood flow (RBF) was not decreased and no measurable change occured in GFR. When RPP was reduced by 31 mmHg, RBF and GFR were decreased and renin secretion rose further (delta RS 1,480 +/- 384 AI/min, P less than 0.05). On the upward pressure ramp, RS fell promptly and was nearly at control levels upon restoration of RPP. It was concluded that renin secretion responds rapidly to alterations in RPP in the autoregulatory range and these changes in renin secretion are unlikely to be mediated by a tubular receptor.     

The effects of ureteral occlusion and renal venous constriction on kidney kallikrein-kinin and prostaglandin systems in dogs

Olsen , U. B. The effects of ureteral occlusion and venal cenous constriction on kidney kallikrein-kinin and prostaglandin systems in dogs. Acta physiol. scand. 1978. 104. 443–452. The intrarenal pressure was raised to 40–50 mmHg by ureteral occlusion or by renal venous constriction in anesthetized dogs loaded with 10% mannitol in saline and with a urine flow of approximately I ml/min/ kidney. Both manoeuvres produced vasodilation and decreased urine creatinine excretion (GFR). Ureteral occlusion was associated with a marked antinatriuresis, which contrasted the variable decrements in sodium excretion during renal venous constriction. Ureteral occlusion did not affect urine excretion of kallikrein or kinins, whilst renal venous constriction decreased urinary kallikrein excretion, yet markedly increased urinary kinin excretion. Ureteral occlusion and renal venous constriction comparably increased urine prostaglandin (E-like) excretion by a presumably pressure dependent mechanism. Inhibition of prostaglandin synthesis by indomethacin abolished the vasodilation during renal venous constriction and this was accompanied by marked reductions of urinary creatinine (GFR) and kallikrein excretions. whilst the kinin excretion was enhanced as observed before the administration of indomethacin.     

Renal effects of furosemide in glycerol induced acute renal failure of the rat

Summary The renal effects of furosemide in acute renal failure of the rat were studied using clearance and micropuncture techniques. Acute renal failure was induced by an intramuscular injection of 50% glycerol (10 ml/kg). Functional impairement of the glycerol treated animals consisted of a decrease in urinary sodium excretion, renal blood flow, total kidney GFR and effective filtration pressure of superficial nephrons. Effective filtration pressure was calculated from proximal free flow and stop flow pressure measurements.In contrast to control animals furosemide did not increase urine volume during acute renal failure due to a marked fall in GFR. Renal blood flow, as measured by an electromagnetic flowmeter, also decreased after furosemide in glycerol treated rats and increased in control animals. Furosemide reduced effective filtration pressure during acute renal failure to almost zero, whereas in control animals effective filtration pressure virtually remained constant.Supported by Deutsche Forschungsgemeinschaft.     

Endogenous variations and sodium intake-dependent components of diurnal sodium excretion patterns in dogs.

1. Automated, sequential, 20 min urine collections were made to provide a record of diurnal variations of urinary sodium excretion (UNaV) in seven dogs, in which the same daily intake of sodium, potassium and water was administered, at first orally (between 08.30 and 08.50 h) on day 1 and then by i.v. infusion at a constant rate on days 2 and 3. This basic protocol was employed for two different levels of sodium intake: normal (NSI; 2.5 mmol (kg body wt)-1 (24 h)-1) and high (HSI; 14.5 mmol (kg body wt)-1 (24 h)-1). 2. The aims were: firstly, to establish the diurnal pattern of UNaV under these circumstances; secondly, to find out whether the quantity of sodium administered influences this diurnal pattern; and thirdly, to distinguish endogenous fluctuations from intake-dependent components in the UNaV excretion patterns. 3. On day 1 (oral intake) all dogs exhibited a similar excretion pattern, which peaked between 13.00 and 15.00 h on both diets and then diminished again over the remainder of the 24 h period. 4. On days 2 and 3 (infusion) UNaV fluctuated within a considerable range. 5. On HSI, the maximal UNaV rates on day 1 were about double those observed on infusion days. On HSI, UNaV during infusion days seems to consist of a constant basal component of about 5-6 mumol (kg body wt)-1 min-1 upon which a fluctuating component is superimposed. The basal component may be a reactive homeostatic response to the high sodium intake, whereas the superimposed fluctuating component may reflect endogenous variations.(ABSTRACT TRUNCATED AT 250 WORDS)     

Renal tubular reabsorption in spontaneously hypertensive rats.

We characterized renal tubular reabsorption before and during acute expansion in anesthetized 12-wk-old spontaneously hypertensive rats (SHR) and Wistar-Kyoto rats (WKY). Although mean arterial pressure was higher in euvolemic, nondiuretic SHR than in WKY, 158 vs. 114 mmHg, kidney and nephron glomerular filtration rate (GFR) as well as fluid reabsorption by the proximal convoluted tubule, loop of Henle, and distal convoluted tubule-collecting duct were similar. In euvolemic SHR with aortic constriction (SHR-AC), an acute decrease in renal perfusion pressure to 114 mmHg reduced sodium and water excretion. Kidney and nephron GFR and fluid reabsorption by segments along the nephron resembled values for SHR and WKY. Infusion of isotonic saline (3 ml.100 g body wt-1.h-1) produced similar increases in fractional sodium and water excretion by SHR and WKY, whereas SHR-AC exhibited a blunted natriuresis and diuresis. During expansion, fluid reabsorption by the nephron segments did not differ appreciably among the three groups. The effect(s) of perfusion pressure on reabsorption by superficial nephrons may be covert and was not unmasked, or may be manifested preferentially by deeper nephrons. We conclude that kidneys of SHR require a higher arterial pressure than kidneys of WKY to excrete a given amount of salt and water.     

Relationship between glucose and sodium excretion in the new-born dog

1. The relationship between renal glucose and sodium excretion was studied in thirty-three new-born dogs aged 1-14 days and in ten adult dogs.2. Glucose was infused into the animals at rates sufficient to produce an amount of filtered glucose at least 1.5 times the tubular transport of glucose (saturating glucose load). In both puppies and adults tubular glucose reabsorption at saturating glucose loads varied directly with the glomerular filtration rate (r = 0.54 and 0.73 respectively, P < 0.01 for both).3. In the puppy, as the fraction of filtered sodium excreted (C(Na)/C(In)) increased from 0.05 to 0.45, the ratio, renal tubular glucose transport divided by glomerular filtration rate at saturating glucose loads, (T(G)/GFR)(m), decreased from 3.7 to 1.7 mg/ml. (r = -0.75, P < 0.01). In the adult C(Na)/C(In) was below 0.08 in all experiments and (T(G)/GFR)(m) was within the 95% confidence limits predicted by regression analysis of the data from puppies. Although mean (T(G)/GFR)(m) was greater in the adult than in the puppy (P < 0.01), when puppies had C(Na)/C(In) similar to that for adults, they had (T(G)/GFR)(m) values equivalent to that for the adult.4. There was excellent correlation between glucose excretion and water excretion for both adult and new-born dogs (r = 0.93 and 0.87, respectively). However, for any glucose loss, water loss was greater in the puppy than in the adult (P < 0.01).5. During the control period total sodium excretion (per gram kidney) and C(Na)/C(In) were similar in the new-born and adult dog. However, during glucose loading, the puppies excreted more sodium and had a higher C(Na)/C(In) than did the adult, although glucose excretion was greater in the adult than in the puppy (P < 0.01 for all comparisons).6. Glomerular blood flow, as measured by radioactive microspheres, was redistributed towards inner cortical nephrons during glucose loading in the puppy. There was no such redistribution of glomerular blood flow in the adult.7. Sodium reabsorption beyond the proximal tubule was blocked with ethacrynic acid and chlorothiazide. In the puppy, the increase of C(Na)/C(In) following a glucose load was the same whether the glucose load followed control or distal blockade collections, suggesting that reductions of sodium reabsorption following a glucose load probably came from the proximal tubule. C(Na)/C(In) during glucose loading plus distal blockade was significantly (P < 0.01) higher in the puppy (0.598) than in the adult (0.280), indicating that glucose diuresis produced a greater inhibition of proximal tubular sodium reabsorption in the new-born than in the adult dog.These results support the hypothesis that the high sodium excretion rate during glucose diuresis in the new-born dogs appears to be due to the greater sensitivity of the neonatal proximal tubule to the osmotic effect of glucose. When presented with a glucose osmotic load the new-born dog diminishes net proximal sodium reabsorption more than does the adult and thus depresses tubular glucose reabsorption to a greater extent. The lower values of maximal glucose transport rates found in new-born animals may be related, therefore, to the higher fractional sodium excretion rates during glucose diuresis rather than to a diminished intrinsic glucose transport capacity in the new-born kidney.     

Masking,De Lange curves and integration time as revealed by the electroretinogram of a tree shrew (Tupaia chinensis)

In order to elucidate the effects of angiotensin II on renal function, angiotensin II (AII; 1 ng/kg per min) and the AII antagonist 1-sar-8-ala-angiotensin II (AIIA; 200 ng/kg per min) were infused into the renal artery of anesthetized dogs (pentobarbital), on either a high (8 mmol/kg per day for seven days) or a low sodium intake (0.5 mmol/kg). In sodium replete dogs AII produced renal vasoconstriction with decreased RBF (–28%;P<0.001), but with less decrease of GFR (–14%;P<0.001), leading to an increase of FF (+19%;P<0.01),andantidiuresis(–39%;P<0.001); the antinatriuresis (–58%;P<0.001) exceeded the antidiuresis (P<0.001). RBF (–10%;P<0.001) was less pronounced (P<0.001) during AII in sodium deplete dogs, GFR remained unchanged, but FF increased to the same extent (+16%;P<0.05); diuresis and urinary electrolyte excretion were however not affected. AIIA did not affect RBF, GFR, FF, nor diuresis in sodium replete dogs suggesting that endogenous AII has no tonic influence on renal function in these conditions. In sodium deplete animals AIIA produced an 11% (P<0.001) increase of RBF, without changes of GFR; FF decreased by 12% (P<0.01), but diuresis, natriuresis and kaliuresis were not affected.     

Different renal effects of two inhibitors of catechol-O-methylation in the rat: Entacapone and CGP 28014

Dopamine is a natriuretic hormone that is abundantly synthesized in the kidney and is involved in sodium homeostasis. It is metabolized by monoamine oxidase (MAO) and catechol-O-methyl transferase (COMT) to form 3-methoxytyramine and dihydroxyphenylacetic acid (DOPAC) and finally homovanillic acid (HVA). In order to investigate whether dopamine metabolism is involved in renal sodium regulation, we tested the renal effects of the nitrocatechol entacapone (COMT inhibitor), in comparison with those of the pyridine derivative CGP 28014, in the anaesthetized rat. Entacapone injection resulted in a more than 5-fold increase in sodium excretion, while the renal excretion of dopamine only transiently increased by 20%. DOPAC excretion showed a more than 2-fold increase which persisted throughout the study. Pretreatment with the selective dopamine DA₁-receptor antagonist SCH23390 reduced the entacapone-induced natriuretic response by 69%. Glomerular filtration rate (GFR) and mean arterial blood pressure (MAP) remained unchanged. Injection of CGP 28014 did not produce a natriuretic response; nevertheless, both dopamine and DOPAC excretion increased by 78% and more than 2-fold, respectively. GFR and MAP remained unchanged. In conclusion, COMT inhibition using entacapone results in a mainly DA₁ receptor mediated natriuresis involving inhibition of tubular transport processes, supporting a role for dopamine metabolism in sodium homeostasis. Although CGP 28014 increases the renal excretion of both dopamine and DOPAC it does not affect renal sodium handling indicating a different mechanism of action.