黄芪水提物对阿霉素肾病大鼠ANP抵抗的改善作用及其机制研究

目的：研究黄芪水提物(ARE)对阿霉素肾病大鼠心房利钠肽(ANP)抵抗的影响，并探讨其机制。方法:雄性SD大鼠随机分为正常对照组、阿霉素肾病模型组(ADR)、ADR＋黄芪水提物(2.5 g·kg^-1·d^-1)组及ADR＋苯那普利(10 mg·kg^-1·d^-1)组。用药6周后观察大鼠在2%体重生理盐水扩容情况下的利钠反应、血浆ANP的浓度、尿环鸟苷酸(cGMP)排泄量(U_cGMPV)、肾内髓组织磷酸二酯酶5(PDE5)活性及蛋白表达水平。结果:ADR大鼠扩容后，尽管血浆ANP水平较正常大鼠明显增加，其利钠反应和U_cGMPV却显著降低(P<0.01)。ARE能部分恢复大鼠扩容利钠反应，显著增加尿钠排泄量(U_NaV)及U_cGMPV (P<0.01)。ARE明显抑制肾内髓组织PDE5活性［(6.8±0.8）nmol·g^-1·min^-1 vs (9.9± 1.1）nmol·g^-1·min^-1，P<0.01］及蛋白表达 (1.0±0.1 vs 1.4±0.2, P<0.01)。结论:ARE能显著改善阿霉素肾病大鼠ANP抵抗，其机制可能与其抑制PDE5活性及蛋白表达有关。     

A stereologic study of the granule population of rat atrial myoendocrine cells: effects of chronic water/sodium restriction and acute water/sodium load

The effects of chronic water/sodium restriction and acute water/sodium load on the "specific granule" population of rat atrial cardiocytes were investigated by stereology. The volume density (Vv) of atrial granules, which contain atrial natriuretic peptide (ANP), displayed a 135%-rise in water/sodium-restricted animals. The injection of 2.5 ml of isotonic saline to water/sodium-restricted rats provoked a striking degranulation of atrial myoendocrine cells (Vv of granules decreased by about 31%). The administration of an equal volume of hypertonic (5%) saline caused a more pronounced effect (Vv decreased by about 51%). These findings are in agreement with the view that chronic water/sodium restriction blocks the exocytotic release of atrial granules, without lowering the rate of their production. Moreover, they suggest that not only blood volume expansion, but also sodium ions can be a potent stimulating factor of ANP release.     

Effects of 0·9% saline infusion on urinary and renal tissue composition in the hydropaenic, normal and hydrated conscious rat

1. Changes in water and solute outputs of hydropaenic, normal and hydrated conscious rats were determined during intravenous infusion (0.2 ml./min) of isotonic (0.9%) saline for 4 hr; renal tissue composition was determined before, and after 1 or 2 hr, infusion.2. In normal and hydrated rats increased excretion of water and sodium was such that urinary output matched intravenous input from about 2 hr. In hydropaenic rats, the diuretic and natriuretic response was much reduced; a retention of infused saline, equivalent to 15% body weight, occurred over 4 hr.3. A considerable increase in urea output and clearance, and a smaller increase in potassium and ammonium outputs, occurred in all groups.4. The corticomedullary osmolal gradients characteristic of non-diuretic rats were largely dissipated during saline infusion: by 1 hr in normal and hydrated rats, and by 2 hr in the hydropaenic group.5. These changes were ascribable mainly to an increase in tissue water content in all segments, particularly in the hydropaenic group; and to a profound decrease in urea content in all groups.6. Changes in tissue sodium content were smaller, and differed between segments and between the differently hydrated groups. A decrease in papillary content occurred in hydropaenic and normal groups and an increase in cortical and outer medullary content occurred in all groups.7. After 2 hr saline infusion, incomplete papillary-urinary osmotic equilibration was evident in all groups.8. These changes in medullary osmolality and in papillary-urinary osmotic equilibration preceded the maximal diuresis, and must contribute to the diuresis induced by saline infusion, as in water and osmotic diureses.     

Influence of volume expansion,serum sodium,and fractional excretion of sodium on urate excretion

The relative contributions of volume expansion and increased fractional excretion of sodium to the uricosuria of saline infusion were assessed in 19 subjects by volume expansion with rapid infusion of 21 of hypertonic saline (3%), isotonic saline (0.9%), or hypotonic saline (0.45%). Urate excretion increased 385 mug/min (P less than 0.01) with hypertonic, 145 mug/min (P less than 0.05) with isotonic saline, and 294 mug/min (P less than 0.001) with hyptonic saline. When 150 meq of sodium chloride was administered as appropriate volumes of hypertonic, isotonic of hypotonic saline, the magnitude or uricosuria was correlated with volume load (r = 0.66, P less than 0.002). fractional excretion of sodium correlated with infusion volumes for all studies taken together (r = 0.35, P greater than 0.1). The relationship between fractional excretion of sodium and fractional excretion of urate was entirely attributed to their correlation with infusion volume. Both post-pyrazinamide urate excretion and pyrazinamide suppressible urate excretion increased with volume expansion.     

Non-occurrence of a natriuretic factor in circulating blood of rats after expansion of the extracellular or the intravascular space

Summary Evidence for the occurrence of a natriuretic factor in rats, in which diuretic and natriuretic responses had been induced, either by expanding the extracellular or the blood volume, was sought in isovolemic cross-circulation experiments, in which a sizable fraction of the cardiac output was exchanged per unit time. In 8 experiments, in which the extracellular space of the donor animal was expanded by infusing isotonic saline, no diuretic or natriuretic response was observed in the recipients, though the recipients' blood underwent the same hemodilution as that of the donors. In six experiments in which the intravascular volume of the donor animal was considerably expanded by injecting heparinized blood obtained from other rats, cross-circulation did not induce any natriuresis or diuresis in the recipients. A natriuretic response was observed in one such cross-circulation experiment and was presumably due to an experimental error. The data do not lend any support to the hypothesis of a circulating natriuretic factor in isotonic saline diuresis or in diuresis after blood volume expansion.Supported by Fonds National Suisse de la Recherche Scientifique: grants No. 4190 and 5315.3.     

Renal effects of atriopeptin II and dopamine receptor blockade in acutely volume-expanded rats

Studies were made of the effects of continuous intravenous infusion of a synthetic atrial natriuretic factor (ANF) or, pre-treatment with the dopamine receptor antagonist haloperidol, on the renal response in anaesthetized rats subjected to volume expansion with an isotonic solution at 2% kg-1 body weight (wt) h-1. A time-control group receiving vehicle alone was studied in parallel. Measurements were compared 75 and 145 min after initiation of the volume expansion. Seventy minutes of Atriopeptin II infusion at 10 micrograms h-1 kg-1 body wt did not significantly alter the glomerular filtration rate [control value 1.29 +/- 0.10 ml min-1 g-1 kidney wt (n = 7, mean +/- 1 SEM), experimental value 1.20 +/- 0.12], but increased sodium excretion by 49% (from 2.87 +/- 0.56 to 4.27 +/- 0.45 mumol min-1). The arterial blood pressure was reduced by 9%. In previous investigations we found that in the same dosage Atriopeptin II increased sodium excretion 10-fold in euvolaemic animals. In the time-control group (n = 7) the response was similar to that in the atrial natriuretic factor-treated animals with the exception that the blood pressure was unaltered. Thus, glomerular filtration rate showed no statistically significant change (1.28 +/- 0.06 vs. 1.27 +/- 0.09 ml min-1 g-1 kidney wt) while the sodium excretion increased by 96% (from 2.29 +/- 0.22 to 4.50 +/- 0.49 mumol min-1). In animals pretreated with haloperidol (n = 5), the natriuretic response to the volume expansion was attenuated and was about ten times below that in the time-control group.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of prolactin, ANPergic, oxytocinergic and adrenal systems in response to extracellular volume expansion in rats

The present study evaluated the effect of acute extracellular volume expansion (EVE) induced by intravenous injection of isotonic (0.15 m NaCl) or hypertonic saline (0.3 m NaCl) on prolactin, corticosterone, vasopressin, oxytocin and atrial natriuretic peptide (ANP) secretion. Male Wistar rats were treated with bromocriptine, sulpiride or dexamethasone. After isotonic and hypertonic EVE, the control group showed a significant increase in the plasma concentrations of prolactin, corticosterone, ANP and oxytocin. The increase in ANP and oxytocin levels in response to hypertonic EVE was more pronounced than to isotonic EVE. Bromocriptine and sulpiride treatments did not modify corticosterone, ANP and oxytocin responses to either isotonic or hypertonic EVE. The increases in prolactin and oxytocin, but not ANP, were blocked in dexamethasone pretreated rats. In conclusion, isotonic or hypertonic EVE induced an increase in the plasma concentrations of prolactin, corticosterone, ANP and oxytocin. The increases in ANP and oxytocin were independent of plasma concentrations of prolactin. The increases in prolactin and oxytocin were blocked by the inhibition of the hypothalamo-pituitary-adrenal (HPA) axis by dexamethasone. However, dexamethasone did not alter the increase in ANP secretion induced by isotonic or hypertonic EVE. Therefore, prolactin might participate in regulation of the hydroelectrolytic balance in mammals; however, in the present study, there was no evidence for direct interaction with ANPergic and oxytocinergic systems. In addition, the responses of prolactin and oxytocin induced by isotonic or hypertonic EVE are modulated by the HPA axis.     

Dopamine receptor blockade and synthesis inhibition during exaggerated natriuresis in spontaneously hypertensive rats.

The influence of dopamine receptor blockade and synthesis inhibition on natriuresis induced by isotonic saline volume expansion was investigated in anaesthetized spontaneously hypertensive rats and normotensive Wistar-Kyoto rats. The aim of the study was to elucidate the mechanisms underlying the phenomenon of exaggerated natriuresis during volume expansion that has been observed in spontaneously hypertensive rats. Volume expansion, at 5% of body weight, resulted in a larger and faster natriuretic response in spontaneously hypertensive rats than in Wistar-Kyoto rats. Sixty minutes after commencement of volume expansion the natriuretic response (accumulated sodium excretion) in Wistar-Kyoto rats (n = 8) was only 24% of that in spontaneously hypertensive rats (n = 17). When spontaneously hypertensive rats were pretreated with the dopamine receptor blockers haloperidol (n = 14, 1 mg kg-1), SCH23390 (n = 8, 30 micrograms h-1 kg-1) or the dopamine synthesis inhibitor benserazide (n = 8, 50 mg kg-1; n = 5, 100 mg kg-1), the natriuretic response to volume expansion was only 16, 35, 59 and 42%, respectively, of that in untreated SHR. The corresponding proportion in the haloperidol-treated (n = 8) compared with untreated Wistar-Kyoto rats was 22%. In conclusion, isotonic volume loading results in more pronounced natriuresis in spontaneously hypertensive than in Wistar-Kyoto rats. Dopamine receptor blockade and synthesis inhibition attenuate the expansion of exaggerated natriuresis in spontaneously hypertensive rats and reduces the volume expansion natriuresis in Wistar-Kyoto rats, indicating that the dopamine system plays an important role.     

Intravascular receptors and renal responses of monkey to volume expansion

Experiments were performed in anesthetized Macaca fascicularis monkeys to determine the effects of combined thoracic dorsal rhizotomy (C8-T7) and vagotomy-sinoaortic denervation on the renal responses to acute intravascular volume expansion. Expansion of the estimated blood volume by 15% with 6% dextran in isotonic saline produced attenuated diuretic and natriuretic responses in the denervated animals when compared with sham-operated controls. The times to peak diuresis and natriuresis after volume expansion also were significantly earlier in the denervated group. Although central venous pressure increased similarly in both groups, mean arterial pressure increased to a greater extent after volume expansion in the denervated group. As opposed to the previously reported failure of either denervation alone to attenuate the renal responses to hypervolemia in the monkey, our results suggest that these neural pathways may play a role in maintaining salt and water balance in this species. However, because of the possibility of functionally redundant afferent mechanisms, blunted renal responses to volume expansion in the primate can only be demonstrated after an extensive denervation.     

Isotonic and hypertonic sodium loading in supine humans

The hypothesis that hypertonic saline infusion induces a greater natriuresis than infusion of the same amount of sodium as isotonic saline was tested in 8 supine subjects on fixed sodium intake of 150 mmol NaCl day^–1. Sodium loads equivalent to the amount of sodium contained in 10% of measured extracellular volume were administered intravenously over 90 min either as isotonic saline or as hypertonic saline (850 mmol L^–1). A third series without saline infusion served as time control. Experiments lasted 8 h. Water balance and sodium loads were maintained by replacing the excreted amounts every hour. Plasma sodium concentrations only increased following hypertonic saline infusion (by 2.7 ± 0.3 mmol L^–1). Oncotic pressure decreased significantly more with isotonic saline (4.1 ± 0.3 mmHg) than with hypertonic saline (3.2 ± 0.2 mmHg), indicating that isotonic saline induced a stronger volumetric stimulus. Renal sodium excretion increased more than a factor of four with isotonic and hypertonic saline but also increased during time control (factor of three). Cumulated sodium excretions following isotonic (131 ± 13 mmol) and hypertonic saline (123 ± 10 mmol) were statistically identical exceeding that of time control (81 ± 9 mmol). Plasma angiotensin II decreased in all series but plasma ANP concentrations and urinary excretion rates of endothelin-1 remained unchanged. In conclusion, hypertonic saline did not produce excess natriuresis. However, as the two loading procedures induced similar natriureses during different volumetric stimuli, part of the natriuresis elicited by hypertonic saline could be mediated by stimulation of osmoreceptors involved in renal sodium excretion. The supine position does not provide stable time control conditions with regard to renal excretory function.     

Isotonic and hypertonic sodium loading in supine humans.

The hypothesis that hypertonic saline infusion induces a greater natriuresis than infusion of the same amount of sodium as isotonic saline was tested in 8 supine subjects on fixed sodium intake of 150 mmol NaCl day(-1). Sodium loads equivalent to the amount of sodium contained in 10% of measured extracellular volume were administered intravenously over 90 min either as isotonic saline or as hypertonic saline (850 mmol L(-1)). A third series without saline infusion served as time control. Experiments lasted 8 h. Water balance and sodium loads were maintained by replacing the excreted amounts every hour. Plasma sodium concentrations only increased following hypertonic saline infusion (by 2.7 +/- 0.3 mmol L(-1)). Oncotic pressure decreased significantly more with isotonic saline (4.1 +/- 0.3 mmHg) than with hypertonic saline (3.2 +/- 0.2 mmHg), indicating that isotonic saline induced a stronger volumetric stimulus. Renal sodium excretion increased more than a factor of four with isotonic and hypertonic saline but also increased during time control (factor of three). Cumulated sodium excretions following isotonic (131 +/- 13 mmol) and hypertonic saline (123 +/- 10 mmol) were statistically identical exceeding that of time control (81 +/- 9 mmol). Plasma angiotensin II decreased in all series but plasma ANP concentrations and urinary excretion rates of endothelin-1 remained unchanged. In conclusion, hypertonic saline did not produce excess natriuresis. However, as the two loading procedures induced similar natriureses during different volumetric stimuli, part of the natriuresis elicited by hypertonic saline could be mediated by stimulation of osmoreceptors involved in renal sodium excretion. The supine position does not provide stable time control conditions with regard to renal excretory function.     

Changes in renal hemodynamics and sodium excretion during saline infusion in lambs.

The renal response to a progressive isotonic extracellular volume (ECV) expansion was studied in 13 lambs of two age groups (5-28 days and 48-57 days). Changes in renal hemodynamics induced by the ECV expansion were followed. Intrarenal blood flow was determined by the microsphere method. For determination of the glomerular filtration rate (GFR) standard clearance techniques were used. Recordings were made during control conditions and when normal saline had been infused in amounts up to 4.5% of the body weight. During the infusion there was an increase in sodium excretion both in absolute values and in relationship to GFR. The increase was, however, much less pronounced in the younger lambs. The GFR did not change significantly during saline infusion. The cortical blood flow increased only in the older lambs. As a consequence the quotient between GFR and cortical blood flow decreased in the older lambs. The possibility of a causal relationship between the fall in filtration fraction so obtained and the more pronounced natriuretic response in the older lambs is discussed. The inner to outer cortical blood flow ratio increased more in the younger lambs during saline infusion. The functional significance of an age related blood flow redistribution is, however, not clear.     

Renal nerve activity and exaggerated natriuresis in conscious spontaneously hypertensive rats

Exaggerated natriuresis upon volume loading occurs in both human and animal hypertension and is mainly due to suppressed tubular reabsorption. To explore whether altered renal sympathetic activity contributes to this response, conscious male spontaneously hypertensive rats (SHR) were exposed to isotonic saline loading in comparison with normotensive male Wistar Kyoto rats (WKR). After a 60 min control hydropenic period, during which mean arterial pressure, heart rate, renal sympathetic nerve activity and urinary sodium excretion were followed, a 60 min period of intravenous volume expansion with isotonic saline (0.2 ml/minx 100 g b. w.) was started followed by a 60 min hydropenic recovery period. Already during the control period sodium excretion was significantly higher in SHR. During the volume load and subsequent recovery period a clearly exaggerated natriuresis occurred in SHR compared with WKR. Further, volume loading reduced renal sympathetic nerve activity in all animals, but significantly more in SHR. Moreover, volume loading reduced mean arterial pressure and heart rate in both groups. It is suggested that the accentuated reflex inhibition of renal sympathetic activity in SHR upon volume loading emanates from cardiac mechanoreceptors and partly explains the exaggerated natriuresis in SHR. This augmented ‘volume’ reflex response is probably due to reduced systemic venous compliance in SHR with a consequently increased central filling and cardiac receptor activation.     

Sodium handling by the Sabra hypertension prone (SBH) and resistant (SBN) rats

The acute and chronic renal handling of salt was evaluated in age matched Sabra hypertension-prone (SBH) and hypertension-resistant (SBN) rats. Acute oral (4 ml/100 g) and intravenous (3.3 ml/100 g) isotonic saline loading in unanesthetized normotensive animals maintained on normal diet elicited a significantly lesser diuretic and natriuretic response in SBH than in SBN. Intermittent studies in metabolic cages in rats aged 5 to 21 weeks showed that both strains consumed similar amounts of salt but that SBH excreted significantly less urinary sodium than SBN (F=40,p<0.001). Twenty four hour clearance studies showed a similar filtered sodium load in the two strains but a lower total and fractional sodium excretion in SBH, suggesting increased tubular reabsorption. Under conditions of water diuresis, free water clearance was similar in the two strains, suggesting the site for disparate tubular sodium handling to be distal to the thick medullary ascending limb of the loop of Henle. Acute oral saline loading and long term studies in metabolic cages in rats prepared with deoxycorticosteroneacetate (doca) and salt showed no significant differences in sodium excretion between hypertensive SBH and normotensive SBN. These findings indicate disparate renal sodium handling between SBH and SBN rats, already apparent before the onset of hypertension, which dissipates during doca-salt treatment.     

Sodium balance and the natriuresis of hypertonic saline infusion in dogs.

Recently, a paradoxical effect of dietary salt intake on the natriuresis following hypertonic saline infusion was observed in rats. In these experiments the effects of alterations in dietary sodium on the natriuretic response to a hypertonic saline load was studied in dogs. Dogs maintained on a high-sodium diet did not have a significantly different natriuresis than those on a low-sodium diet. When differences in sodium balance were amplified by the use of deoxycorticosterone, furosemide, and manipulation of dietary sodium, dogs in positive sodium balance showed a significantly enhanced initial excretion of sodium followed by a reversal of the pattern. Consequently, the cumulative sodium excretion was not different between low- and high-sodium groups. Since the cumulative natriuretic response to isotonic saline infusion was larger in dogs in positive sodium balance compared to those in negative sodium balance, the failure to detect a difference following hypertonic saline infusion was probably because of the increased plasma sodium concentration.     

Parathormone as a mediator of inorganic phosphate diuresis during saline infusion in the rat

Summary Normal rats were infused with isotonic saline at 0.50 ml/min for 2 hours in order to expand their extracellular fluid volume. Under these conditions fractional excretion of inorganic phosphate was found to be as high as 38.8±3.0% of filtered phosphate, while fractional sodium excretion was 12.9±0.7% of filtered sodium. The combined addition of calcium and magnesium to the infusion solution decreased inorganic phosphate excretion significantly (P<0.001) to 11.2±3.6% (presumably by inhibiting parathyroid gland activity), while sodium excretion was unchanged (13.5±1.1%). Parathyroidectomized rats were infused with isotonic saline at 0.50 ml/min to achieve a similar extent of extracellular fluid volume expansion as in the normal rats. In these animals inorganic phosphate excretion was as low as 0.9±0.9% of filtered phosphate, while sodium excretion was 11.8±2.2% of filtered sodium. Administration of parathormone to volume expanded parathyroidectomized rats resulted in marked increases or inorganic phosphate excretion to 41.5±3.1% of filtered phosphate (P<0.001), while sodium excretion remained unaltered (12.0±2.8% of filtered sodium), thus resembling very closely the results in normal volume expanded rats.From these results it is concluded, that saline induced phosphaturia in normal rats is mediated primarily by parathormone. Furthermore, sodium excretion during volume expansion of extracellular fluid appears to be independent of inorganic phosphate excretion and independent of changes in parathyroid activity.This work was supported in part by a grant from the Deutsche Forschungsgemeinschaft.     

The effects of anesthesia on the excretion of an isotonic saline load in the rat

The ability to excrete a volume of isotonic saline equal to 10% of body weight infused over 60 min, was examined in awake rats and in rats anesthetized with 1 of the 2 agents most commonly used in renal clearance studies, Inactin or Nembutal. Rats anesthetized with Inactin excreted significantly less of the infused sodium during the period of infusion and in the 120-min post-infusion periods as compared to Nembutal-anesthetized rats or awake rats. Following saline infusion, there was a significantly greater decrease in serum protein concentration (25.5±4.7%) in rats anesthetized with Inactin, compared to that observed in the awake or Nembutal-treated rats. In a separate group of saline-infused awake rats, induction of anesthesia with Inactin resulted in a significant increase in hematocrit and a decrease in serum protein concentration. These studies suggest that Inactin anesthesia decreases the ability of the kidney to excrete a saline load and that, in studies of sodium excretion in the rat, especially if volume expansion is to be part of the experimental protocol, Nembutal rather than Inactin may be the anesthetic of choice.These studies were performed while Drs. Knight and Frankfurt were Fellows in Nephrology of Baylor College of Medicine, and were supported in part by a Clinical Investigatorship award to Dr. Weinman and an Associate Investigatorship award to Dr. Frankfurt from the Veterans Administration. This work was presented in part at the Combined Session, Southern Section, American Federation for Clinical Research and the Southern Society for Clinical Investigation, New Orleans, Louisiana, January 27–29, 1977, and has appeared in abstract form in Clin. Res.25, 61 A (1977)     

The effect of renal arterial infusion of albumin on renal function in the rat

Summary An infusion of an isotonic saline solution or of the same solution to which human serum albumin had been added in a concentration of 6 and 25% was administered into the renal artery of rats. The sodium and water excretion and the inulin and PAH clearances were not different when isotonic saline solution or 6% albumin were applied. After an infusion of 25% albumin solution a transient natriuresis and diuresis, accompanied by an increase of blood pressure, was observed. These experiments do not support the hypothesis which suggests the importance of peritubular oncotic pressure for the reabsorption of fluid and sodium in the rat renal tubules.     

Role of hypervolemia and renin in the blood pressure control of patients with pyelonephritis renal scarring

Patients with pyelonephritic renal scarring are at risk of developing renal failure and hypertension. We studied glomerular filtration rate (GFR), renal plasma flow (RPF), filtration fraction (FF), systolic (SBP) and diastolic (DBP) blood pressure, fractional sodium, potassium and phosphate excretion, peripheral renin activity (PRA), plasma aldosterone (p-Aldo), urinary albumin excretion (U-Alb) and urinary beta 2-microglobulin excretion (beta 2-M) in hydropenia and during transition to 3% volume expansion with isotonic saline infusion in 22 female patients with renal scarring due to pyelonephritis and 9 healthy controls. The patients had significantly lower GFR, higher SBP and higher PRA in hydropenia, but there was no significant difference in RPF, FF, DBP or p-Aldo. After volume expansion, SBP, DBP, PRA and p-Aldo were significantly higher in patients than in controls. Transition to 3% volume expansion was associated with a similar increase in SBP in both patients and controls, whereas DBP increased significantly more in the patients (p less than 0.01). Volume expansion resulted in a significant suppression of PRA and p-Aldo in both patients and controls. The patients with renal scarring had the same capacity to excrete sodium and water during transition to volume expansion as the healthy controls. The renin-aldosterone system seems abnormally activated and is probably more important than hypervolemia in the development of hypertension in this group of patients.     

The influence of antibodies against bradykinin on isotonic saline diuresis in the rat

Summary The urinary excretion of water, sodium and potassium by salineloaded rats treated with antibradykinin serum was studied. Control animals received normal rabbit serum. Blockade of the kallikrein system by bradykinin-binding antibodies resulted in a decreased natriuretic and diuretic response to expansion of the extracellular space. The fractional excretion of sodium and water was lower in antibradykinin-treated rats. Antibradykinin serum did not affect the clearances of PAH or inulin, nor did it influence potassium excretion. The reduced ability of antibradykinin-treated rats to excrete a saline load suggests that a normally functioning kallikrein system may be a prerequisite for the occurrence of saline diuresis after extracellular fluid volume expansion.Supported by Fonds National Suisse de la Recherche Scientifique, Grant No. 3.7420.72.