Natriuresis following fourth ventricle perfusion with high-sodium artificial CSF.

Perfusion of the fourth cerebral ventricle with high-sodium artificial cerebrospinal fluid was found to result in an increase in urinary sodium excretion in anesthetized cats. The natriuresis was accompanied by an increase in blood pressure and glomerular filtration rate. However, in animals with the changes in blood pressure and glomerular filtration rate prevented by alpha adrenergic blockade (phenoxybenzamine), the increase in urinary sodium excretion persisted. the data suggest the presence of a neural mechanism in the vicinity of the fourth ventricle sensitive to cerebrospinal fluid sodium levels and capable of affecting urinary sodium excretion independent of changes in blood pressure or glomerular filtration rate. The possible role of the area postrema and adjacent medulla is considered.     

Low sodium intake does not impair renal compensation of hypoxia-induced respiratory alkalosis.

Acute hypoxia causes hyperventilation and respiratory alkalosis, often combined with increased diuresis and sodium, potassium, and bicarbonate excretion. With a low sodium intake, the excretion of the anion bicarbonate may be limited by the lower excretion rate of the cation sodium through activated sodium-retaining mechanisms. This study investigates whether the short-term renal compensation of hypoxia-induced respiratory alkalosis is impaired by a low sodium intake. Nine conscious, tracheotomized dogs were studied twice either on a low-sodium (LS = 0.5 mmol sodium x kg body wt-1 x day-1) or high-sodium (HS = 7.5 mmol sodium x kg body wt-1 x day-1) diet. The dogs breathed spontaneously via a ventilator circuit during the experiments: first hour, normoxia (inspiratory oxygen fraction = 0.21); second to fourth hour, hypoxia (inspiratory oxygen fraction = 0.1). During hypoxia (arterial PO2 34.4 +/- 2.1 Torr), plasma pH increased from 7.37 +/- 0.01 to 7.48 +/- 0.01 (P < 0.05) because of hyperventilation (arterial PCO2 25.6 +/- 2.4 Torr). Urinary pH and urinary bicarbonate excretion increased irrespective of the sodium intake. Sodium excretion increased more during HS than during LS, whereas the increase in potassium excretion was comparable in both groups. Thus the quick onset of bicarbonate excretion within the first hour of hypoxia-induced respiratory alkalosis was not impaired by a low sodium intake. The increased sodium excretion during hypoxia seems to be combined with a decrease in plasma aldosterone and angiotensin II in LS as well as in HS dogs. Other factors, e.g., increased mean arterial blood pressure, minute ventilation, and renal blood flow, may have contributed.     

Reduction of the effects of diuretics or sodium chloride loading in the conscious rat by inhibitors of prostaglandin synthesis

In conscious rats pretreatment with indomethacin or flurbiprofen, two chemically unrelated inhibitors of prostaglandin synthesis, reduced urine volume and sodium excretion induced by four diuretics, acetazolamide, amiloride, bendrofluazide and frusemide, or oral sodium chloride loads. The maximum reduction in sodium excretion was limited to approximately 2 mmol/kg Na⁺ even when sodium excretion was greatly increased. In contrast these inhibitors did not appreciably affect potassium excretion. These results indicate that part of the natriuretic response in the rat to highly and moderately efficacious diuretics and to sodium chloride loading is modified by prostaglandins. We suggest that the lack of effects on potassium excretion indicate that the collecting tubule is the probable site of action.     

Distal blockade in experimental glomerulonephritis: the role of the diluting segment in sodium retention

In the light of accumulating evidence implicating the diluting segment as the site of final regulation of sodium excretion by the nephron, we produced in this experiment distal blockade in anti-glomerular basement membrane (GBM) glomerulonephritic (GN) rats by the administration of furosemide and polythiazide. This allowed to dissociate the sodium reabsorption that occurs in the proximal tubule from the one that occurs more distally and permitted an appreciation of the r?le played by the diluting segment in the sodium retention of anti GBM GN. In a previous experiment we showed that GN conscious or anaesthetized rats presented an increase in Na tubular reabsorption and failed to raise their fractional and absolute excretion of sodium as normal one did after rapid volume expansion. In this study distal blockade corrected almost completely the difference in sodium excretion that existed between GN and normal groups before the administration of diuretics, pointing to the important r?le played by the diluting segment in the sodium retention of experimental GN.     

Regulation of sodium excretion by renal interstitial hydrostatic pressure

Renal interstitial hydrostatic pressure (RIHP) appears to play a crucial role in linking the renal circulation to the rate of tubular reabsorption of sodium and water. Various physiological and pharmacological maneuvers that increase RIHP are associated with increases in sodium excretion. Renal vasodilators that increase RIHP also increase sodium excretion, whereas the vasodilators that do not alter RIHP do not affect sodium excretion. Preventing increases in RIHP during intrarenal infusion of vasodilators markedly attenuates the normal increase in sodium and water excretion. Techniques that directly increase RIHP by renal interstitial volume expansion increase urinary excretion of sodium and water. RIHP may be an important mediator of renal perfusion pressure (RPP) natriuresis. Experimental evidence suggests that the proximal tubule of deep nephrons may be an important nephron site that is sensitive to changes in RPP.     

Urinary prostaglandin E excretion: Effect of chronic alterations in sodium intake and inhibition of prostaglandin synthesis in the rabbit

On the basis of acute experiments in animals, a role for prostaglandin E (PGE) in the regulation of urinary sodium excretion has been suggested. Limited information is available, however, concerning the possible role of PGE in chronic adjustments to sodium intake. These studies were designed to determine whether chronic changes in sodium balance would modify renal PGE excretion and whether partial inhibition of prostaglandin synthesis would after the ability of the kidney to adjust to an alteration in sodium intake. Thus, we measured sodium and PGE excretion in rabbits on chronic high and low salt diets before and after inhibition of prostaglandin synthesis with indomethacin or meclofenamate. Although the alterations in salt intake resulted in large changes in sodium excretion there was no significant change in urinary PGE excretion. After administration of either indomethacin or meclofenamate for several days there was a significant fall in PGE excretion, but no significant change in sodium excretion. These results suggest that in the rabbit 1) chronic changes in sodium excretion can occur without modifying PGE excretion (and presumably renal PGE synthesis) and 2) inhibition of PGE synthesis does not impair the kidney's ability to adjust to a chronic high or low sodium intake.     

Fluid consumption, electrolyte excretion and heart remodeling in rats with myocardial infarct maintained on regular and high sodium intake.

The purpose of the study was to determine effect of high sodium intake on fluid and electrolyte turnover and heart remodeling in the cardiac failure elicited by myocardial infarction (MI). The experiments were performed on four groups of Sprague Dawley rats maintained on food containing 0.45% NaCl and drinking either water (groups 1, 2) or 1% NaCl (groups 3, 4). Groups 1 and 3 were sham-operated while in groups 2 and 4 MI was produced by the coronary artery ligation. In each group food and fluid as well as sodium intake, urine (Vu), sodium (UNaV), potassium (UKV) and solutes (UosmV) excretion were determined before and four weeks after the surgery. Size of the infarct, left ventricle (LV) weight and diameter of LV and right ventricle (RV) myocytes were determined during post-mortem examination. Before the surgery groups 3 and 4 ingested significantly more fluid and sodium, had higher Vu, UNaV, UKV and UosmV than the respective groups 1 and 2. In groups 2 and 4 MI resulted in significant decrease in Vu, UNaV and UosmV in comparison to the pre-surgical level. In Group 4 MI resulted also in a significant decrease of food and sodium intake. The MI size did not differ in groups 2 and 4 while diameter of LV myocytes was significantly greater in groups 2 and 4 than in groups 1 and 3, and in group 4 than in group 2. The study reveals that prolonged high sodium consumption increases fluid and electrolyte turnover both in the sham and in the MI rats and that the MI causes decrease in food and sodium intake in rats on high but not on regular sodium intake. In addition high sodium diet promotes development of greater post-MI hypertrophy of the LV myocytes.     

Erythrocyte sodium transport and renal sodium excretion after saline loading in young and adult spontaneously hypertensive (SHR) and normotensive (WKY) rats

Adult SHR aged 19-21 weeks, subjected to osmotic diuresis, responded to an intravenous 1.8% saline loading (15 ml/kg b.w.) with greater sodium excretion than age-matched WKY. Young (6-7 weeks old) SHR and WKY also responded to saline loading with an increased sodium excretion but there were no differences in the relative changes of sodium excretion between young WKY and SHR. In adult WKY, saline loading induced a faster erythrocyte 22Na uptake as compared with adult SHR or young WKY. This suggests that volume and/or sodium loading increased sodium turnover of red cells only in adult WKY. The sodium transport differences found in erythrocytes of adult SHR and WKY could be caused by some membrane differences or could be due to different hormonal and nonhormonal response(s) to saline loading. If similar alterations would also occur in other tissues, they might be important for the sodium excretion pattern.     

Glucocorticoids increase salt appetite by promoting water and sodium excretion

Glucocorticoids [e.g., corticosterone and dexamethasone (Dex)], when administered systemically, greatly increase water drinking elicited by angiotensin and sodium ingestion in response to mineralocorticoids [e.g., aldosterone and deoxycorticosterone acetate (DOCA)], possibly by acting in the brain. In addition, glucocorticoids exert powerful renal actions that could influence water and sodium ingestion by promoting their excretion. To test this, we determined water and sodium intakes, excretions, and balances during injections of Dex and DOCA and their coadministration (DOCA+Dex) at doses commonly employed to stimulate ingestion of water and sodium. In animals having only water to drink, Dex treatment greatly increased water and sodium excretion without affecting water intake, thereby producing negative water and sodium balances. Similar results were observed when Dex was administered together with DOCA. In animals having water and saline solution (0.3 M NaCl) to drink, Dex treatment increased water and sodium excretion, had minimal effects on water and sodium intakes, and was associated with negative water and sodium balances. DOCA treatment progressively increased sodium ingestion, and both water and sodium intakes exceeded their urinary excretion, resulting in positive water and sodium balances. The combination of DOCA+Dex stimulated rapid, large increases in sodium ingestion and positive sodium balances. However, water excretion outpaced total fluid intake, resulting in large, negative water balances. Plasma volume increased during DOCA treatment and did not change during treatment with Dex or DOCA+Dex. We conclude that increased urinary excretion, especially of water, during glucocorticoid treatment may explain the increased ingestion of water and sodium that occurs during coadministration with mineralocorticoids.     

Systemic vasodilatation and renal sodium excretion: Effects of hydralazine and diazoxide

The effects on renal sodium excretion of two systemic vasodilators, hydralazine and diazoxide, were investigated in volume expanded, anesthetized rats with unilaterally denervated kidneys. Urinary sodium excretion and fractional excretion of filtered sodium increased following hydralazine but decreased following diazoxide. Changes in renal hemodynamics were dissimilar as well: renal plasma flow was increased following hydralazine, but unchanged with diazoxide. All changes in renal sodium excretion and renal hemodynamics following hydralazine were prevented by pretreatment with indomethacin. Renal denervation accentuated the increases in fractional sodium excretion and renal blood flow that occured following hydralazine.Hydralazine and diazoxide differ substantially in their effects on renal sodium excretion, apparently due to the stimulation of renal prostaglandins by the former agent. Although renal innervation attenuates the natriuretic effect of hydralazine, stimulation of the sympathetic nervous system does not account for differences in the renal effects of these two drugs.     

Biological half-life of bromide in the rat depends primarily on the magnitude of sodium intake

The parallel course of the excretion rates of bromide and sodium ions was demonstrated in adult male and female rats administered simultaneously with potassium 82Br-bromide and 24Na-sodium chloride. The animals were exposed to various intakes of sodium ions accompanied with five different anions: Br-, Cl-, HCO3-, ClO4-, and SCN-. Regardless of the anion accompanying the sodium ion, the excretion rates of 82Br- and 24Na+ ions were proportional to the magnitude of sodium intake in the animals. Hence, we have proved our hypothesis that the biological half-life of bromide depends on the magnitude of sodium intake rather than on the intake of chloride.     

Effect of ventilation on sodium excretion in the anesthetized dog with unilateral renal denervation

We studied if the effect of mechanical ventilation induced to keep arterial blood gas values within normal physiological limits has any influence on renal sodium excretion in anesthetized dogs (n = 17) subjected to acute unilateral renal denervation. Compared to the control and the postcontrol periods, ventilation elevated arterial pO2 from 86 +/- 5 to 96 +/- 5 mmHg and blood pH from 7.37 +/- 0.02 to 7.41 +/- 0.01 while arterial pCO2 was decreased from 38 +/- 2 to 33 +/- 1 mmHg (p less than 0.05 in all cases). Compared to the innervated kidney urine flow, urinary sodium and potassium excretion from the denervated kidney were markedly elevated both during spontaneous respiration and during mechanical ventilation but GFR and cPAH were similar on the two sides. Ventilation decreased sodium excretion by the denervated kidney from 314 +/- 26 to 252 +/- 31 mumols/min/100 g k. w. (p less than 0.05). No other excretory changes were noted either in the innervated or in the denervated kidneys. Difference in sodium excretion between innervated and denervated kidneys was decreased from 209 +/- 19 to 126 +/- 20 mumole/min/100 g k. w. (p less than 0.001), due to the ventilation induced diminution of sodium excretion from the denervated kidney. It is concluded that mechanical ventilation of anesthetized dogs modifies sodium excretion, and this phenomenon can be demonstrated only in the denervated kidney.     

Role of sodium on H+ excretion in the integument of the leopard frog Rana pipiens

1. The northern leopard frog, Rana pipiens, pipiens, in contrast to the southern leopard frog, Rana pipiens, berlandieri, did not demonstrate any significant H+ excretion across its integument even during a challenge of chronic metabolic acidosis. Likewise, no increase in the number of H+ secreting mitochondria-rich cells were observed in the northern frogs. 2. Under normal acid-base conditions in the southern frogs, H+ excretion was found to be dependent on mucosal sodium concentrations, whereas during chronic metabolic acidosis, H+ excretion was independent of mucosal sodium concentrations, but was amiloride sensitive. 3. High salinity adapted southern frogs, under normal and acidotic conditions, had enhanced H+ excretion rates as compared to the control non-salt adapted frogs. 4. Blood analyses demonstrated that significant acid-base changes were the result of systemic acidosis and not due to salt adaptations. Blood Na+ and K+ concentrations were also efficiently maintained during salt adaptations or chronic metabolic acidosis. 5. The results suggest that H+ excretion in epithelia can be influenced by the sodium transport state of the cell and the systemic acid-base profile. Models are proposed explaining these relationships.     

18-oxocortisol: effect of dexamethasone, ACTH and sodium restriction

The urinary excretion of 18-oxocortisol in 37 normal subjects consuming a normal sodium diet was 1.2 +/- 0.9(SD) microgram/24 h. Dexamethasone administration to 5 normal individuals suppressed the excretion of 18-oxocortisol from 1.16 +/- 0.5 micrograms/24 h to 0.6 +/- 0.2 micrograms/24 h. While they still received dexamethasone, ACTH administration raised the 18-oxo-cortisol excretion to 3.82 +/- 1.2 micrograms/24 h. Seven normal subjects were placed on a sodium restricted diet, and the urinary excretion of 18-oxocortisol rose from 1.5 +/- 1.21 micrograms/24 h to 8.54 +/- 5.08 micrograms/24 h and aldosterone from 6.6 +/- 2.0 micrograms/24 h to 39.7 +/- 14.6 micrograms/24 h. Two of the seven individuals showed minimal increases in the excretion of 18-oxocortisol, but in all cases aldosterone increased with sodium restriction. The urinary excretion of 18-oxocortisol correlated significantly with the excretion of aldosterone, 18-hydroxycortisol, cortisol, and 19-nordeoxycorticosterone. These studies indicate that 18-oxocortisol secretion is under ACTH regulation, but since sodium restriction also increases the excretion of 18-oxocortisol, the renin-angiotensin system must also participate in its regulation. However, some individuals do not increase their excretion of 18-oxocortisol with sodium restriction, although aldosterone excretion increases as expected, suggesting that additional factors participate in the regulation of 18-oxocortisol production.     

Hormonal regulation of renal sodium and water excretion during normotensive sodium loading in conscious dogs

Saline was infused intravenously for 90 min to normal, sodium-replete conscious dogs at three different rates (6, 20, and 30 micromol x kg(-1) x min(-1)) as hypertonic solutions (HyperLoad-6, HyperLoad-20, and HyperLoad-30, respectively) or as isotonic solutions (IsoLoad-6, IsoLoad-20, and IsoLoad-30, respectively). Mean arterial blood pressure did not change with any infusion of 6 or 20 micromol x kg(-1) x min(-1). During HyperLoad-6, plasma vasopressin increased by 30%, although the increase in plasma osmolality (1.0 mosmol/kg) was insignificant. During HyperLoad-20, plasma ANG II decreased from 14+/-2 to 7+/-2 pg/ml and sodium excretion increased markedly (2.3+/-0.8 to 19+/-8 micromol/min), whereas glomerular filtration rate (GFR) remained constant. IsoLoad-20 decreased plasma ANG II similarly (13+/-3 to 7+/-1 pg/ml) concomitant with an increase in GFR and a smaller increase in sodium excretion (1.9+/-1.0 to 11+/-6 micromol/min). HyperLoad-30 and IsoLoad-30 increased mean arterial blood pressure by 6-7 mm Hg and decreased plasma ANG II to approximately 6 pg/ml, whereas sodium excretion increased to approximately 60 micromol/min. The data demonstrate that, during slow sodium loading, the rate of excretion of sodium may increase 10-fold without changes in mean arterial blood pressure and GFR and suggest that the increase may be mediated by a decrease in plasma ANG II. Furthermore, the vasopressin system may respond to changes in plasma osmolality undetectable by conventional osmometry.     

Impairment of renal sodium excretion in tropical residents – phenomenological analysis

There is evidence of impaired renal sodium excretion in salt-sensitive African Blacks. A decreased rate of renal sodium chloride (NaCl) excretion, low plasma renin activity and a tendency to elevated blood pressure are the hallmarks of salt sensitivity. Recent evidence indicates that increased proximal and distal tubular fluid reabsorption in some tropical residents may explain the impaired sodium excretion in these people. In this study of a cohort population, we speculated that subjects selected from that population might be salt-sensitive. We therefore measured the sodium balance in 10 normotensive male subjects over 10 consecutive days, after they had ingested a normal or a high amount of sodium, as NaCl (salt) in their diet. We quantified their renal sodium excretion rate by phenomenological analysis of their sodium balance data. We also measured plasma renin activity for 7 consecutive days in a separate group of 6 male and 4 female subjects in order to assess the state of their renin/angiotensin system. We selected all our subjects from a cohort population of 269 subjects randomly selected from a community known to have a high prevalence of primary hypertension. Our data on two separate groups of subjects from the same cohort population revealed delayed renal sodium excretion with t _1/2 of about 5 days, compared to published data for normal individuals with t _1/2 of less than 24 h. Also, plasma renin activity levels were low. Hence, our subjects are salt-sensitive. Quantification of their renal impairment is important for various reasons: it heightens one’s appreciation of the problem of salt retention in African Blacks who are salt-sensitive and it also underlines the importance of the need for further research into the benefits of dietary salt restriction for reducing cardiovascular mortality in African populations, as has been done in some Western countries. Received: 4 March 1999 / Accepted: 12 May 1999     

Oxytocin, water intake, and food sodium availability in male rats

This study examined the effect of subcutaneous administration of the neurohormone oxytocin on water intake of ad lib-fed (with or without sodium availability in the diet) and food-deprived animals. Results of the first experiment showed that oxytocin increased water intake and urine excretion in food-deprived but not in ad lib-fed animals. However, oxytocin treatment did not modify the reduced water "balance" (fluid intake minus urine volume) resulting from food deprivation or the daily food intake (Experiment 1). The dose-dependent polydipsic effect of oxytocin on food-deprived rats was always preceded by an increase in sodium and fluid urine excretion (Experiment 2). Oxytocin also increased the water intake of animals fed ad lib with a low sodium diet (Experiment 3). These results suggest that the effect of oxytocin on water intake is dependent on the presence or absence of sodium in the diet and that the excretion of sodium is the main mechanism of oxytocinergic polydipsia in food-deprived male rats.     

Interaction between the natriuretic effects of renal perfusion pressure and the antinatriuretic effects of angiotensin and aldosterone in control of sodium excretion

Aldosterone has been recognized as an important sodium retaining hormone for many years. Recently we have demonstrated that angiotensin II has a much more powerful antinatriuretic effect than that of aldosterone. The importance of angiotensin II in regulation of sodium excretion has been observed in experiments in which angiotensin II has been infused intravenously or into the renal artery in acute and chronic situations, and in studies involving blockade of angiotensin II formation. In other experiments we have studied the effects of changes in renal perfusion pressure on sodium excretion. While earlier work by others indicated that an acute 10 mm Hg increase in perfusion pressure would increase sodium excretion 60%-70% we observed that a chronic 10 mm Hg change in perfusion pressure would result in a 300% change in sodium excretion. In view of evidence suggesting that changes in the ability of the kidney to excrete sodium normally at normal arterial pressure is an important element in hypertension we studied the effects of aldosterone and angiotensin II on arterial pressure regulation in normal dogs. High physiological levels of each hormone were infused intravenously for several weeks. Both produced sustained hypertension. Aldosterone hypertension was a typical volume loading type with sodium retention, increased blood volume and extracellular fluid volume and a slow rise in arterial pressure. Angiotensin hypertension was a typical vasoconstrictor type with high peripheral resistance, normal or decreased blood volume, decreased cardiac output, a rapid rise in arterial pressure and only initial sodium retention.(ABSTRACT TRUNCATED AT 250 WORDS)     

Chronic activation of plasma renin is log-linearly related to dietary sodium and eliminates natriuresis in response to a pulse change in total body sodium

Responses to acute sodium loading depend on the load and on the level of chronic sodium intake. To test the hypothesis that an acute step increase in total body sodium (TBS) elicits a natriuretic response, which is dependent on the chronic level of TBS, we measured the effects of a bolus of NaCl during different low-sodium diets spanning a 25-fold change in sodium intake on elements of the renin-angiotensin-aldosterone system (RAAS) and on natriuresis. To custom-made, low-sodium chow (0.003%), NaCl was added to provide four levels of intake, 0.03-0.75 mmol.kg(-1).day(-1) for 7 days. Acute NaCl administration increased PV (+6.3-8.9%) and plasma sodium concentration (~2%) and decreased plasma protein concentration (-6.4-8.1%). Plasma ANG II and aldosterone concentrations decreased transiently. Potassium excretion increased substantially. Sodium excretion, arterial blood pressure, glomerular filtration rate, urine flow, plasma potassium, and plasma renin activity did not change. The results indicate that sodium excretion is controlled by neurohumoral mechanisms that are quite resistant to acute changes in plasma volume and colloid osmotic pressure and are not down-regulated within 2 h. With previous data, we demonstrate that RAAS variables are log-linearly related to sodium intake over a >250-fold range in sodium intake, defining dietary sodium function lines that are simple measures of the sodium sensitivity of the RAAS. The dietary function line for plasma ANG II concentration increases from theoretical zero at a daily sodium intake of 17 mmol Na/kg (intercept) with a slope of 16 pM increase per decade of decrease in dietary sodium intake.     

Quantitative measurement of the influence of plasma sodium concentration on the overall tubular reabsorption of sodium.

Comparative experiments on isolated dog kidneys perfused with heparinized blood with or without dilution of the blood by isotonic or hypotonic saline demonstrated that the fractional excretion of sodium is modulated positively by plasma sodium concentration. This relationship was evaluated quantitatively and corresponded to the values found in the whole animal. The renal response to the variations of plasma sodium concentration is therefore autonomous and its mediation by extrarenal natriuretic or antinatriuretic factors cannot be demonstrated in the narcotized animal.