Evolutionary Advantages of Participation of Vasopressin instead of Vasotocin in Regulation of Water–Salt Balance in Mammals

In experiments on non-anesthetized Wistar white rats there was studied reaction of kidney to an intramuscular injection of arginine vasotocin or arginine vasopressin at doses from 0.001 to 0.05 µg/100 g body mass on the background of a water load. Water (5 ml/100 g body mass) was administered through a catheter into stomach to suppress secretion of endogenous antidiuretic hormone (ADH). In experiments with water administration, diuresis increased due to a decrease of osmotic permeability of renal tubules and to excretion of osmotically free water, with the constant clearance of sodium ions. Injection of 0.05 µg arginine vasopressin led to a marked decrease of diuresis due to a rise of reabsorption of osmotically free water without elevation of excretion of osmotically active substances. Injection of the same dose of arginine vasotocin resulted in no increase of diuresis; however, reabsorption of osmotically free water and excretion of osmotically active substances including sodium ions were more pronounced. Hence, both vasotocin and vasopressin increased osmotic permeability of the tubular epithelium, but vasotocin, unlike vasopressin, promoted reduction of reabsorption of sodium ions and their loss with urine. A suggestion is made that one of the reasons for replacement in mammals of the molecular ADH forms (vasotocin by vasopressin) was the absence of the pronounced natriuretic effect in arginine vasopressin. This was of crucial significance to preserve sodium ions in the organism, to maintain water–salt balance in animals adapted to the terrestrial life, and to provide not only osmo-, but also volumoregulation.     

The function of innervated kidneys during stimulation of the carotid chemoreceptors under constant renal perfusion pressure]

The carotid chemoreceptors of narcotized, vagotomized and spontaneously breathing hydropenic cats in hypertonic mannite diuresis were stimulated by perfusion with venous blood penic cats in hypertonic mannite diuresis were stimulated by perfusion with venous blood for 70 min. Elevation of blood pressure at the innervated kidneys was prevented by an automatically controlled balloon located within the aorta. Stimulation of the chemoreceptors intensified respiration and raised the arterial systemic pressure. With the renal arteries at constant pressure, the effective renal plasma flow and the glomerular filtration rate significantly declined. The filtration fraction remained unchanged. The absolute urinary and sodium excretion did not change significantly, whereas the fractional time-volume, fractional sodium excretion, and the fractional osmotic excretion significantly increased. The fractional tubular reabsorption of osmotically free water was significantly enhanced. These reactions subsided during subsequent perfusion of the glomerula carotici with arterial blood. The results suggest that tubular sodium reabsorption is inhibited by stimulation of the carotid chemoreceptors, although re-adjustment of renal perfusion and filtrate volume cannot be excluded.     

Kidney function and arterial acid-base status during continuous stimulation of the carotid chemoreceptors in vagotomized cats]

In spontaneously breathing, chloralose narcotized and bilaterally vagotomized cats under mannite saline diuresis, the isolated carotid sinus were perfused for 1 hr with arterial and then for 1 hr with venous blood, and subsequently again with arterial blood for 1 hr. Either measure d or calculated were the parameters of arterial acid-base status, the arterial systemic bl-od pressure, the p-aminohippuric acid (PAH), inulin (IN), and osmolar clearance, the filtration fraction, the tubular reabsorption of oxmotically free water, the urinary time volume, and fractional excretions of the kidneys. Stimulation of the carotic chemoreceptors increased respiration, slightly enhanced the CPAH, and caused a minor fall of CIN with little altered filtration fraction. The renal resistance increased. The absolute and fractional excretions of urine, sodium, potassium, and of osmotically active particles rose significantly. Tubular reabsorption of osmotically free water showed a singificant increase. Urinary osmolarity remained constant in general. The changes of water and electrolyte excretion did not correlate with those of renal hemodynamics. The results argue against natriuresis being caused on chemoreceptor stimulation by increased filtrate volume of the whole kidney, or by decreased osmolarity of the renal medulla. The results are discussed with regard to the renal function in arterial oxygen deficiency.     

Study of autacoids role in the regulation of circadian rhythm of the human renal function

The circadian rhythm of urine formation was studied in younger (27 +/- 8 yr) and aged (76 +/- 3 yr) males. In 11 younger healthy examined persons a decrease of diuresis during the night as compared with the day time was due to a rise of solute free water reabsorption. In 31 aged males the change of the urine formation rhythm with increase of the nocturnal diuresis is based on a rise of osmolal clearance combined with an increase of the solute free water reabsorption. It is shown that blockade of autacoid secretion leads to normalization of the diuresis circadian rhythm. In 10 aged men, nocturia was due to a decrease of vasopressin secretion which resulted in a decrease of the solute free water reabsorption and an increase of diuresis. The obtained data are considered as an evidence for the role of renal autacoids, alongside with vasopressin, in regulation of the circadian rhythm of the kidney function.     

The role of renal acid mucopolysaccharides in the mechanism of reabsorption of osmotically free water]

The authors compared the histochemical characteristics of acid mucopolysaccharides (MPS) of the medulla of the kidney with functional indices of the latter in dogs under conditions of water, osmotic diuresis and in polyuria caused by the administration of heparin. There was seen a correlation between the changes in the MPS staining and the intensity of reabsorption of osmotically free water. On the basis of the results obtained a supposition was put forward that the change in the physico-chemical properties of the MPS served as one of the most significant factors determining the permeability of the medulla structures for the passage of water from the tubular lumina into the interstitium.     

Role of V1- and V2-receptors in mechanism of physiological paradox--an increase of reabsorption of the solute free water and simultaneous rise of diuresis

In experiments on non-anesthetized rats with administration into stomach of water (5 ml/100 g body mass) direct correlation has been found between an increase of diuresis and excretion of solute free water (r = 0.98, p < 0.01), while after injection to these animals of 5 x 10(-11) M arginine-vasotocin - between an increase of diuresis and simultaneous rise reabsorption of solute free water (r = 0.8, p < 0.01). The rise of diuresis after the vasotocin injection is due to inhibition of sodium re- absorption, with the solute excretion fraction increasing from 2.6 +/- 0.2 % to 11.9 +/- 1.2, p < 0.001. A similar physiological paradox - an increase of diuresis with the simultaneous increase of reabsorption of solute free water - has been revealed at night hours in children with tendency for nocturnal enuresis (r = 0.64, p < 0.01). Mechanism responsible for this phenomenon consists in a rise of diuresis due to a decrease of sodium ion reabsorption in the ascending Henle loop limb. A problem is discussed of the homeostatic significance of a decrease of sodium reabsorption combined with an increase of solute-free water reabsorption; it is suggested that this phenomenon is based on a redistribution of reabsorption inside the nephron - a decrease of ion and water reabsorption in the initial parts of the nephron distal segment and an increase of solute free water reabsorption with the antidiuretic hormone-stimulated high osmotic permeability of terminal parts of renal tubules. An intraperitoneal injection of V1-anatagonist (OPC-21268) decreased the natriuretic component of response to arginine-vasotocin, while injection of V2-antagonist (OPC-31260) eliminated the antidiuretic component.     

Physicochemical Parameters of the Blood Serum and Renal Function in Children with Some Internal Diseases

The blood serum osmolality and ion concentrations were studied in 144 children (healthy or having some diseases), and no deviations from the universally accepted normal values were found. Although the mean values were in the normal range, the diseases were associated with an increased variation of serum osmolality and ion concentrations, indicating an imbalance of the regulatory system. Normally, human urine is hyperosmolal and the urination depends on the excretion of osmotically active substances. This determines a physiological paradox: an increase in diuresis is accompanied by a concurrent increase in reabsorption of osmotically free water.     

Antidiuretic reaction of the human and rat kidney to peroral administration of arginine-vasopressin and desmopressin

Water in amount of 5 ml/100 g body weight was administered through a gastric probe into the stomach in alert rats; subjects-volunteers drank 20 ml of water per 1 kg of body weight. This resulted in diuresis at the peak of which the excreted water fraction reached 23% in rats and 12.4% in human subjects, whereas excretion of the osmotically free water amounted to 0.103 +/- 0.018 ml/min/100 g body weight and 10.0 +/- 1.8 ml/min/1.73 m2 of the body surface, respectively. These data indicate a practically complete inhibition of the arginine vasopressin secretion. On intragastric administration of 10 micrograms of arginine vasopressin or 0.2 microgram of desmopressin, with water in rats, a prolonged and quite obvious antidiuretic response occurred, with a marked increase of reabsorption of the osmotically free water in kidneys. A direct correlation has been found between the dose of the intragastrically administered vasopressin in the dose range from 0.1 to 10 micrograms/100 g body weight and a decrease of clearance of the osmotically free water. In subjects volunteers, an antidiuretic reaction to administration of 0.2 mg of desmopressin with water, was found. The data obtained provide a direct proof of intestinal absorption of nanopeptides without loss of their physiological activity. Significance of the data obtained for physiology of digestion and for clinical medicine, is discussed.     

Antidiuretic Response of Kidneys to Different Modes of Vasopressin Administration

The effect of vasopressin given simultaneously with a water load was studied in healthy human volunteers. During maximal water diuresis induced by oral water load of 20 ml water per kilogram body weight, the excreted water fraction was 12.4%, whereas the excretion of osmotically free water was 10.0 ± 1.8 ml/min per 1.73 m² of body surface area. These data suggest that the secretion of arginine vasopressin by the neurohypophysis was almost completely blocked. A water load simultaneously with 8 g sublingual or 0.2 mg oral desmopressin caused a strong and long-lasting antidiuretic response accompanied by a drastic increase in the reabsorption of osmotically free water in the kidneys. It was shown that the magnitude and the time course of the antidiuretic response to therapeutic doses of desmopressin depended on the mode of its administration.     

Renin-Aldosterone System in Osmoregulatory Reactions of Healthy Subjects in Response to Desmopressin

Systemic regulation of osmotic and ionic homeostasis was studied in healthy male volunteers after oral administration of desmopressin. Endogenous secretion of the antidiuretic hormone was inhibited by a water load (WL, 2% of the body mass). Desmopressin exerted an antidiuretic effect. In addition, the WL portion excreted during 4 h decreased and the urine osmolality at peak diuresis increased with the absence of osmotically free water. At maximum diuresis, the ratio between concentrations of osmotically active substances in the urine and in the blood was high, which reflected an intense antidiuretic effect. Desmopressin progressively decreased the rate of sodium excretion owing to a change of sodium reabsorption in the kidneys. The WL increased the level of aldosterone and the activity of renin in blood plasma 1.5 h after its administration. Contrary to the control series, desmopressin stimulated the renin-angiotensin-aldosterone system only by the end of the 4-h observation period. A significant negative correlation between the aldosterone level and the rate of sodium excretion was observed 3 h after the beginning of testing (r = ?0.76). Thus, under conditions of water loading, desmopressin had a specific antidiuretic effect involving systemic mechanisms of ion regulation.     

大鼠脑胆碱能系统对血量扩张引起利尿与尿钠排泄...

The role of brain cholinergic system on diuresis and natriuresis induced by volume expansion was studied in conscious rats. In a series of experiments, the diuretic, natriuretic and kaliuretic responses induced by volume expansion were compared in three groups of conscious rats pretreated respectively with intracerebroventricular (icv) injection of artificial cerebrospinal fluid (ACSF), atropine and hexamethonium. The natriuretic, kaliuretic and diuretic responses induced by volume expansion were much less in the animals with icv injection of atropine than in the control group with injection of ACSF (P less than 0.01). While the group pretreated with icv injection of hexamethonium showed no significant decrease in these responses of volume expansion than that of the control (P greater than 0.05). Volume expansion produced no change in insulin and PAH clearance in both the atropine and the ACSF group. Thus the atropine suppressed diuresis, natriuresis and kaliuresis are independent of changes in GFR and RPF. It is inferred from the results of the present investigation that volume expansion induced diuresis and natriuresis appear to be due to inhibition of water and sodium reabsorption in the renal tubules and regulated by certain brain cholinergic system.     

Pressure diuresis mechanism in the control of renal function and arterial pressure

Precise knowledge of the interrelationships between arterial pressure and urinary excretion of sodium and water is crucial to understanding the long-term control of arterial pressure. Although increases in renal perfusion pressure have been known for more than 35 years to inhibit tubular reabsorption, the mechanism of this pressure diuresis response, the humoral or physical factors involved, and even the nephron segments in which the changes in tubular function occur remain relatively unknown. This review focuses on the experimental evidence that supports current hypotheses concerning the mechanism of pressure diuresis. Specifically, it examines the possibility that pressure diuresis is caused by a small increase in glomerular filtration rate, alterations in the humoral or physical factors regulating proximal tubular reabsorption, and/or inhibition of tubular reabsorption in deep nephrons secondary to changes in hemodynamics in juxtamedullary nephrons. The concept originally proposed that the kidney serves as the dominant long-term controller of arterial pressure is largely based on the assumptions that the pressure diuresis phenomenon exists and that it occurs via a nonadaptive mechanism. It has been proposed that hypertension can develop only if the relationship between arterial pressure and sodium excretion is shifted toward higher pressures. The remainder of this review examines recent evidence indicating that an abnormality in the pressure natriuresis relationship may be associated with the development of hypertension in humans and in the genetic rat models of the disease.     

Effect of crude extract of Stevia rebaudiana on renal water and electrolytes excretion.

To evaluate the effect of crude extract of Stevia rebaudiana on renal water, Na+ and K+ excretion, male Wistar rats (250-350 g each) under antidiuresis or water diuresis conditions, were evaluated. During intravenous infusion of the extract (0.05 mg/min/100 g) no significant differences were detected in mean arterial pressure or renal hemodynamics parameters. In contrast, fractional water and sodium excretion and solute clearance increased significantly, in both groups of animals. In antidiuresis rats the extract significantly increased reabsorption of water by the collecting duct and in water diuresis animals the extract significantly increased free water clearance. The data suggest preferential action of the extract in the proximal tubular cells involved with salt transport mechanism.     

Renal response to furosemide in normal subjects during hyperinsulinaemic clamp

The study has been performed in an attempt to provide further data on the supposed direct action of insulin on the kidney, based on the assumption that any effect of insulin on sodium reabsorption via co-transport should shift the dose-response curve to the furosemide administration. In five normal male volunteers plasma insulin concentration was changed by means of a hyperinsulinaemic euglycaemic clamp. The diuresis and natriuresis following intravenous injections of furosemide (in increasing doses) were measured in basal conditions and during clamp. No significant difference was found between the experiments performed in the two conditions. Our study has not identified a direct sodium-retaining effect of insulin on the furosemide-sensitive mechanisms of the renal tubule.     

Regulation of sodium and water excretion by catecholamines

There is considerable evidence that the renal nerves contribute to the regulation of salt and water excretion by a direct effect on tubular reabsorption, independent of changes in renal hemodynamics. Whereas the effect of the adrenergic nervous system on sodium reabsorption appears to be established in anesthetized animals, it has been suggested that the basal activity of the renal sympathetic nerves in conscious dogs is too low to have a significant effect on sodium reabsorption by the proximal tubules. However, denervation natriuresis and diuresis have recently been demonstrated in conscious euvolemic and conscious volume-expanded rats. The effects of renal nerve stimulation on the handling of sodium and water by the proximal tubule can be mimicked by infusion of the α-adrenergic agonist norepinephrine and prevented by infusion of an α-adrenergic antagonist. This confirms that they are mediated by α-receptors. The adrenergic nervous system may have an independent role in the control of sodium excretion or may be complementary to other systems such as the renin-angiotensin-aldosterone system.     

A search for a defect of proximal transport in denervated kidneys of conscious dogs

The influence of renal nerves on proximal Na+ reabsorption was studied in clearance experiments with unilaterally renal-denervated conscious dogs prepared by surgical bladder division. Two types of experiments were made : A. maximal water diuresis, and B. Total blockade of distal NaCl reabsorption with ethacrynic acid and chlorothiazide. In maximal water diuresis CH2O + CNa was used as a measure of fluid delivery to the distal nephron. At similar GFR on both sides, the proximal reabsorption estimated as GFR--(CH2O + CNa) was 38.4 +/- 5.6 ml/min for the intact and 35.9 +/- 4.2 ml/min for the denervated kidney (n = 6, difference NS). After distal tubular blockade, proximal Na+ reabsorption calculated as filtered load minus urinary excretion was 3.84 +/- 0.43 mmol/min for the intact and 3.91 +/- 0.36 mmol/min for the denervated kidney (n = 6, difference NS). The fractional reabsorption of NA+ was 64.9 +/- 1.0% for the intact and 66.9 +/- 1.1% for the denervated kidney (difference NS). In contrast to data from renal denervation studies with anaesthetized animals, the present experiments did not show any difference in proximal reabsorption between the innervated- and denervated kidney. We conclude that in absence of anaesthesia renal efferent nerves have no major effect on NaCl transport in dog proximal tubule.     

Diuretic effect of intraventricular and intravenous infusions of noradrenaline in conscious sheep

Infusion of noradrenaline at rates between 32-160 nmol.min-1 for 30 min into one lateral cerebral ventricle of conscious sheep caused a diuresis which was accompanied by negative solute-free water reabsorption and which lasted for 90-120 min. The range of noradrenaline infusion rates used reflects differences between individual animals in the rate of infusion necessry to cause diuresis. Intracerebroventricular (ICV) infusion of noradrenaline at half the diuretic rate caused no significant changes in urine flow. The diuresis induced by ICV noradrenaline infusion was prevented by concurrent ICV administration of the alpha-adrenergic antagonist, phentolamine, but was not prevented by concurrent ICV administration of the beta antagonist, propranolol, or by concurrent intravenous infusion of phentolamine. Intravenous infusion of noradrenaline at rates that were diuretic by ICV infusion caused a diuresis of approximately 30 min duration which coincided with the period of intravenous noradrenaline infusion. This diuresis was prevented by concurrent intravenous infusion of phentolamine. These results were interpreted as indicating that the higher rates of ICV infusion of noradrenaline caused the prolonged water diuresis by acting at a site in the brain and, thereby, inhibiting the release of endogenous vasopressin. ICV infusion of noradrenaline at all rates was followed by a reduction in mean arterial blood pressure and pulse pressure with variable changes in heart rate and by depression of the rates of renal clearance of PAH, potassium and total solute.     

Age-specific features in renal response to food intakes and training loads in young professional skiers

The age-specific features of renal functions have been studied in older adolescents and young adults training in ski racing before and after their water and food intake and training loads. Baseline renal functions in the morning demonstrated higher glomerular filtration rate (GFR) and more mature development of the osmoregulatory mechanisms (higher excretion of osmotically active substances, osmotic concentration index, and reabsorption of solute-free liquid) in young adults, compared with adolescents. After food intake, the osmoregulatory mechanisms provided in young adults an adequate renal response—increased excretion of ions in exchange for urea, which preserves osmolality. At the same time, increased excretion of osmotically active substances synchronously with growth in the rate of urine output, higher GFR and reabsorption of solute-free liquid was marked in adolescents, which points to less mature development of the osmoregulatory system. The similar trend of renal homeostatic responses after physical training indicated the activation of volume regulatory mechanisms which did not differ between age groups. Our conclusion is that the definitive volume regulation develops ahead of osmoregulation.     

Sulpiride (stereoisomers, racemic) and dopamine: actions and interactions on renal excretion of hydro-saline

Renal effects of Dopamine (DA, subpressor dosage 0.1 microgram X kg -1 X min -1) during hypotonic polyuria in moderate hydro-saline retention are variously modified by either d- or l-Sulpiride isomers. In the presence of d-Sulpiride, DA effects, such as an increase in diuresis, free water clearance (CH20) and kaliuresis are suppressed, while increases of saluresis and natriuresis are significantly blunted. In the presence of l-Sulpiride no changes are observed in both saluresis and natriuresis, while decreases occur in diuresis, CH20 and kaliuresis. The inhibitory DA effects on isosmotic sodium reabsorption as a percentage of sodium filtered load are prevented by either isomer as well. A possible role of ineffective renal vascular DA action can be involved in such defective tubular inhibition. However is also suggested a pharmacological blockade of proximal tubular specific DA receptors.     

A clinical approach to common electrolyte problems. 1. Hyponatremia.

The clinical approach to hyponatremia described in this paper involves identification of the hyponatremia as iso-osmolar (factitious), hyperosmolar (mediated by osmotically induced flux of water from cells) or hypo-osmolar. Hypo-osmolar hyponatremia results from decreased renal excretion of dilute urine. This may be caused by renal failure through decreased delivery of filtrate to or function of the ascending limb of the loop of Henle, where dilute urine is made, or through increased water reabsorption in the collecting duct, either independent of antidiuretic hormone or related to a physiologic, drug-induced or pathologic increase in the bioactivity of antidiuretic hormone. The treatment of hyponatremia must be individualized.