Intrarenal haemodynamics in postobstructive diuresis in the dog

Intrarenal haemodynamics were investigated in the dog prior to and after relief of 24 hr bilateral ureteral ligation (BUL), by the radioactive microsphere technique. Prior to release of 24 hr BUL there was an about 50% reduction in total blood flow (RBR), with a nearly proprotional decrease in the perfusion of the four cortical layers. Following release of the obstruction, total renal and outer cortical (zones 1 and 2) blood flow remained diminished, while perfusion of the inner (juxtamedullary) layers (zones 3 and 4) increased as compared to its prerelease values and equalled controls. Glomerular filtration rate (GFR) amounted to about 27% of controls in the postrelease phase. A marked increase in absolute and fractional sodium water excretion was observed after release of 24 hr BUL, as contrasted to normal controls and dogs after 24 hr unilateral ureteral ligation (UUL). This state, designated as postopstructive diuresis, might be explained by redistribution of intrarenal blood flow towards the juxtamedullary zones, and by a powerful natriuretic substance accumulated during complete obstruction.     

Uranyl nitrate induced corpuscular derangement: an early indication of induced acute renal failure.

Erythrocyte structure was studied in rat after uranyl nitrate (UN:5 mg/kg) intoxication. The study of pathogenic progression of UN induced renal failure (ARF) was confined to the early initiation phase (2 hr), late initiation phase (8 hr) and the maintenance phase (24 hr). Erythrocyte structure has been found to be greatly influenced. The UN induced hemolytic syndrome/hypoxia was accompanied by a marked anisocytosis and poikilocytosis during different phases of ARF, which is characteristic of UN poisoning. Subsequent alterations in erythrocyte structure followed by UN administration or during the pathogenic progression of ARF has clinical and diagnostic importance as the alterations were much distinct prior to the clinical manifestation of ARF even at light microscopic level.     

Pancreatectomy, amino acids and glucagon: effect on canine renal autoregulation

Using pancreactectomized (PX) dogs, we recently suggested the importance of glucagon in modulating amino acid-induced increases in renal blood flow (RBF) and glomerular filtration rate (GFR). We have now ascertained whether glucagon's modulatory effect is associated with an impairment in renal autoregulation. As renal arterial pressure (RAP) was reduced to 70 mmHg (the lower limit of the autoregulatory range) in both sham-operated control (C) and PX control dogs, RBF and GFR remained at values that were greater than 90% of their respective controls. In control dogs infused with amino acids (0.051 mmol/kg per min, i.v.), RBF and GFR rose by 26 and 27%, respectively, at baseline RAP. As RAP was reduced to 70 mmHg, RBF and GFR fell by 25 and 37%, respectively. In PX dogs infused with either amino acids or glucagon (0.86 pmol/kg per min, i.v.) alone, RBF and GFR did not increase appreciably at baseline RAP. As RAP was reduced to 70 mmHg in these dogs, RBF and GFR remained at values that were greater than 90% of their respective controls. Yet, in PX dogs infused simultaneously with amino acids and glucagon, RBF and GFR rose by 22 and 24%, respectively, at baseline RAP. Moreover, as RAP was reduced to 70 mmHg, RBF and GFR fell by 22 and 31%, respectively. These data suggest that the ability of glucagon to modulate the renal hemodynamic response to amino acid infusion involves an impairment in renal autoregulation.     

Autoregulation of renal hemodynamics is not impaired by a 'physiologic' dose of glucagon

Glucagon has been suggested to be involved in the pathway by which protein and amino acids elevate renal blood flow (RBF) and glomerular filtration rate (GFR) postprandially. Recent data suggest that amino acids elevate RBF and GFR through an autoregulatory mechanism (i.e., by impairing renal autoregulation). If glucagon mediates the renal hemodynamic effects of amino acids, 'physiologic' infusion of glucagon would also be expected to impair autoregulation. We examined the effects of glucagon (5 ng/kg per min given intraportally and intravenously) on RBF and GFR autoregulation in anesthetized dogs. Intraportal glucagon (n = 6) increased RBF (24%) and GFR (23%) at normal arterial pressure. RBF and GFR were well autoregulated (greater than 90% of control) at renal arterial pressures greater than or equal to 85 mm Hg before and after glucagon. At 70 mm Hg, RBF and GFR decreased by 15 and 16%, respectively, before glucagon and by 19 and 22%, respectively, after glucagon. Intravenous glucagon (n = 6) produced similar effects. Intraportal glucagon at 500 ng/kg per min increased RBF (35%), heart rate (69%) and plasma glucose (78%) and decreased arterial pressure (16%) (GFR not measured). This dose impaired RBF autoregulation by 30%. The data suggest that a 'physiologic' dose of glucagon increases renal hemodynamics without impairing renal autoregulation. It is suggested that glucagon's vasodilatory effect on the renal vasculature may be additive to the renal effects of amino acids.     

Increased glomerular filtration rate in early metabolic syndrome is associated with renal adiposity and microvascular proliferation

Metabolic syndrome (MetS) is associated with glomerular hyperfiltration and is a risk factor for chronic kidney disease, but the underlying mechanisms are poorly defined. This study tested the hypothesis that increased glomerular filtration rate (GFR) in early MetS is associated with renal adiposity and microvascular proliferation. Twelve MetS-prone Ossabaw pigs were randomized to 10 wk of a standard (lean, n = 6) or atherogenic (MetS, n = 6) diet. Kidney hemodynamics and function, perirenal fat volume, and tubular dynamics were assessed in vivo by multidetector computed tomography (CT) and blood oxygen level-dependent (BOLD)-MRI. Microvascular architecture was assessed ex vivo with micro-CT. Candidate injury mechanisms were evaluated in kidney tissue by Western blotting and histology. Basal GFR, renal blood flow, and renal cortical perfusion and volume were elevated in the MetS group. Perirenal and kidney tissue fat, proximal-nephron intratubular fluid concentration, and endothelial nitric oxide synthase expression were increased in MetS. GFR levels correlated with tissue triglyceride levels. Elevated spatial density of 20- to 40-μm cortical microvessels was accompanied by mild oxidative stress, inflammation, and with proximal tubular vacuolization. Medullary size and perfusion were relatively preserved, and BOLD-MRI showed intact medullary tubular response to furosemide. Increased GFR in early MetS is associated with renal adiposity and microvascular proliferation, which involve mainly the renal cortex and precede significant activation of oxidative stress and inflammation. Renal adiposity and proliferative microvessels may represent novel therapeutic targets for preserving renal function in early MetS.     

Renal hemodynamic response to galanin: importance of elevated plasma glucose

Although recent data point to a possible indirect role for galanin in modulating renal blood flow (RBF) and fluid homeostasis in experimental animals, there have been no systematic studies exploring the possible direct effects of the peptide on the mammalian kidney. We ascertained the RBF, glomerular filtration rate (GFR) and plasma glucose responses to direct intrarenal infusion of three progressively increasing doses of synthetic galanin in anesthetized dogs. A 50 ng/kg per min dose (n = 6) failed to affect RBF, GFR or arterial plasma glucose (APG). Yet, a 100 ng/kg per min dose elevated RBF and GFR by 13 and 14%, respectively, while concomitantly increasing APG by 38%. At 200 ng/kg per min, galanin elevated RBF and GFR by 32 and 33%, respectively, while elevating APG by 57%. Intrarenal infusion of glucose (12.5 mg/kg per min; n = 6), reproducing the percentage rise in glucose (62%) elicited by the highest dose of galanin, elevated RBF and GFR by 20 and 23%, respectively. These data indicate that the elevated plasma glucose level, stimulated by galanin infusion, may account for about 63 and 70% of the RBF and GFR responses, respectively, elicited by galanin infusion at the 200 ng dose. The factors mediating the remaining renal hyperemia and hyperfiltration await resolution.     

Insulin induces the correlation between renal blood flow and glomerular filtration rate in diabetes: implications for mechanisms causing hyperfiltration

Glomerular filtration rate (GFR) and renal blood flow (RBF) are normally kept constant via renal autoregulation. However, early diabetes results in increased GFR and the potential mechanisms are debated. Tubuloglomerular feedback (TGF) inactivation, with concomitantly increased RBF, is proposed but challenged by the finding of glomerular hyperfiltration in diabetic adenosine A(1) receptor-deficient mice, which lack TGF. Furthermore, we consistently find elevated GFR in diabetes with only minor changes in RBF. This may relate to the use of a lower streptozotocin dose, which produces a degree of hyperglycemia, which is manageable without supplemental suboptimal insulin administration, as has been used by other investigators. Therefore, we examined the relationship between RBF and GFR in diabetic rats with (diabetes + insulin) and without suboptimal insulin administration (untreated diabetes). As insulin can affect nitric oxide (NO) release, the role of NO was also investigated. GFR, RBF, and glomerular filtration pressures were measured. Dynamic RBF autoregulation was examined by transfer function analysis between arterial pressure and RBF. Both diabetic groups had increased GFR (+60-67%) and RBF (+20-23%) compared with controls. However, only the diabetes + insulin group displayed a correlation between GFR and RBF (R(2) = 0.81, P < 0.0001). Net filtration pressure was increased in untreated diabetes compared with both other groups. The difference between untreated and insulin-treated diabetic rats disappeared after administering N(ω)-nitro-l-arginine methyl ester to inhibit NO synthase and subsequent NO release. In conclusion, mechanisms causing diabetes-induced glomerular hyperfiltration are animal model-dependent. Supplemental insulin administration results in a RBF-dependent mechanism, whereas elevated GFR in untreated diabetes is mediated primarily by a tubular event. Insulin-induced NO release partially contributes to these differences.     

Persistent kidney dysfunction in swine renal artery stenosis correlates with outer cortical microvascular remodeling

Percutaneous transluminal renal stenting (PTRS) does not consistently improve renal function in patients with atherosclerotic renovascular disease, but the mechanisms underlying irreversible kidney injury have not been fully elucidated. We hypothesized that renal dysfunction after PTRS is linked to ongoing renal microvascular (MV) remodeling. Pigs were studied after 10 wk of atherosclerosis and renal artery stenosis (ARAS), ARAS treated with PTRS 4 wk earlier, and normal controls (n = 10 each). Renal blood flow (RBF) and glomerular filtration rate (GFR) were studied using multidetector computer tomography. Renal microvascular architecture (micro-CT), angiogenic activity, oxidative stress, and fibrosis were evaluated ex vivo. Four weeks after PTRS, blood pressure was normalized. However, GFR and RBF remained similarly decreased in untreated ARAS and ARAS+PTRS (P < 0.05 vs. normal). MV rarefaction was unaltered after revascularization, and the spatial density of outer cortical microvessels correlated with residual GFR. Interstitial fibrosis and altered expression of proangiogenic and profibrotic factors persisted after PTRS. Tubulointerstitial injury in ARAS persisted 4 wk after mechanically successful PTRS, and vessel loss correlated with residual renal dysfunction. MV loss and fibrosis in swine ARAS might account for persistent renal dysfunction after PTRS and underscore the need to assess renal parenchymal disease before revascularization.     

ANG II type 2 receptors and neural control of intrarenal blood flow

We tested the hypothesis that activation of angiotensin type 2 (AT(2)) receptors, by both exogenous and endogenous ANG II, modulates neurally mediated vasoconstriction in the renal cortical and medullary circulations. Under control conditions in pentobarbital-anesthetized rabbits, electrical stimulation of the renal nerves (RNS; 0.5-8 Hz) reduced renal blood flow (RBF; -88 +/- 3% at 8 Hz) and cortical perfusion (CBF; -92 +/- 2% at 8 Hz) more than medullary perfusion (MBF; -67 +/- 6% at 8 Hz). Renal arterial infusion of ANG II, at a dose titrated to reduce RBF by approximately 40-50% (5-50 ng.kg(-1).min(-1)) blunted responses of MBF to RNS, without significantly affecting responses of RBF or CBF. Subsequent administration of PD123319 (1 mg/kg plus 1 mg.kg(-1).h(-1)) during continued renal arterial infusion of ANG II did not significantly affect responses of RBF or CBF to RNS but enhanced responses of MBF, so that they were similar to those observed under control conditions. In contrast, administration of PD123319 alone blunted responses of CBF and MBF to RNS. Subsequent renal arterial infusion of ANG II in PD123319-pretreated rabbits restored CBF responses to RNS back to control levels. In contrast, ANG II infusion in PD123319-pretreated rabbits did not alter MBF responses to RNS. These data indicate that exogenous ANG II can blunt neurally mediated vasoconstriction in the medullary circulation through activation of AT(2) receptors. However, AT(2)-receptor activation by endogenous ANG II appears to enhance neurally mediated vasoconstriction in both the cortical and medullary circulations.     

Reversal of renal dysfunction by targeted administration of VEGF into the stenotic kidney: a novel potential therapeutic approach

Renal microvascular (MV) damage and loss contribute to the progression of renal injury in renovascular disease (RVD). Whether a targeted intervention in renal microcirculation could reverse renal damage is unknown. We hypothesized that intrarenal vascular endothelial growth factor (VEGF) therapy will reverse renal dysfunction and decrease renal injury in experimental RVD. Unilateral renal artery stenosis (RAS) was induced in 14 pigs, as a surrogate of chronic RVD. Six weeks later, renal blood flow (RBF) and glomerular filtration rate (GFR) were quantified in vivo in the stenotic kidney using multidetector computed tomography (CT). Then, intrarenal rhVEGF-165 or vehicle was randomly administered into the stenotic kidneys (n = 7/group), they were observed for 4 additional wk, in vivo studies were repeated, and then renal MV density was quantified by 3D micro-CT, and expression of angiogenic factors and fibrosis was determined. RBF and GFR, MV density, and renal expression of VEGF and downstream mediators such as p-ERK 1/2, Akt, and eNOS were significantly reduced after 6 and at 10 wk of untreated RAS compared with normal controls. Remarkably, administration of VEGF at 6 wk normalized RBF (from 393.6 ± 50.3 to 607.0 ± 45.33 ml/min, P < 0.05 vs. RAS) and GFR (from 43.4 ± 3.4 to 66.6 ± 10.3 ml/min, P < 0.05 vs. RAS) at 10 wk, accompanied by increased angiogenic signaling, augmented renal MV density, and attenuated renal scarring. This study shows promising therapeutic effects of a targeted renal intervention, using an established clinically relevant large-animal model of chronic RAS. It also implies that disruption of renal MV integrity and function plays a pivotal role in the progression of renal injury in the stenotic kidney. Furthermore, it shows a high level of plasticity of renal microvessels to a single-dose VEGF-targeted intervention after established renal injury, supporting promising renoprotective effects of a novel potential therapeutic intervention to treat chronic RVD.     

Renal hyperemia in portal hypertension is not mediated by gastrointestinal peptides

The objectives of this study were to characterize the time course of development of the renal hyperemia induced by chronic portal vein stenosis (PVS) in the rat, and to assess the possibility that vasoactive blood-borne gastrointestinal peptides mediate the renal hyperemia in established portal hypertension. Blood flow to the kidneys was measured with radioactive microspheres over a ten day time course. On day 2, no difference in renal blood flow (RBF) was observed in PVS rats as compared with controls. However, by day 4, RBF significantly increased by 35% in PVS vs. control animals. On day 6, the renal hyperemia in PVS rats reached a maximal value that was 42% higher than controls. A steady state hyperemia (approximately 40%) was maintained thereafter. Radioimmunoassay of plasma from control and established portal hypertensive rats (10 days samples) revealed that vasoactive intestinal polypeptide, substance P, cholecystokinin, gastrin, neurotensin, pancreatic polypeptide, beta-endorphin and peptide histidine-isoleucine amide are not elevated in arterial plasma of portal hypertensive rats. These data suggest that the renal hyperemia induced by chronic portal vein stenosis is apparent within 4 days of the onset of a hypertensive state and attains a steady state by day 8. Furthermore, at least eight blood-borne gastrointestinal peptides are not directly involved in the renal hyperemia associated with chronic portal hypertension.     

The renal circulation of conscious rabbits

1. The renal circulatory instability that some believe is inherent in rabbits was studied. 2. In five, conscious rabbits, glomerular filtration rate (GFR) averaged 4.2 +/- 0.6 ml/min/kg body wt after 1 hr, but changed to an overall average of 3.5 +/- 1.5 ml/min/kg wt after 3 hr. 3. Between-measurement coefficient of variation for GFR was more than 30% for three rabbits and 10% or less for two. 4. Renal blood flow (RBF) was even more variable. 5. The renal circulatory instability may be associated with differences in sympathetic activity by mechanisms not existing in other mammals.     

Early superoxide scavenging accelerates renal microvascular rarefaction and damage in the stenotic kidney

Renal artery stenosis (RAS), the main cause of chronic renovascular disease (RVD), is associated with significant oxidative stress. Chronic RVD induces renal injury partly by promoting renal microvascular (MV) damage and blunting MV repair in the stenotic kidney. We tested the hypothesis that superoxide anion plays a pivotal role in MV dysfunction, reduction of MV density, and progression of renal injury in the stenotic kidney. RAS was induced in 14 domestic pigs and observed for 6 wk. Seven RAS pigs were chronically treated with the superoxide dismutase mimetic tempol (RAS+T) to reduce oxidative stress. Single-kidney hemodynamics and function were quantified in vivo using multidetector computer tomography (CT) and renal MV density was quantified ex vivo using micro-CT. Expression of angiogenic, inflammatory, and apoptotic factors was measured in renal tissue, and renal apoptosis and fibrosis were quantified in tissue sections. The degree of RAS and blood pressure were similarly increased in RAS and RAS+T. Renal blood flow (RBF) and glomerular filtration rate (GFR) were reduced in the stenotic kidney (280.1 ± 36.8 and 34.2 ± 3.1 ml/min, P < 0.05 vs. control). RAS+T kidneys showed preserved GFR (58.5 ± 6.3 ml/min, P = not significant vs. control) but a similar decreases in RBF (293.6 ± 85.2 ml/min) and further decreases in MV density compared with RAS. These changes were accompanied by blunted angiogenic signaling and increased apoptosis and fibrosis in the stenotic kidney of RAS+T compared with RAS. The current study shows that tempol administration provided limited protection to the stenotic kidney. Despite preserved GFR, renal perfusion was not improved by tempol, and MV density was further reduced compared with untreated RAS, associated with increased renal apoptosis and fibrosis. These results suggest that a tight balance of the renal redox status is necessary for a normal MV repair response to injury, at least at the early stage of RVD, and raise caution regarding antioxidant strategies in RAS.     

A Novel Therapy to Attenuate Acute Kidney Injury and Ischemic Allograft Damage after Allogenic Kidney Transplantation in Mice

Ischemia followed by reperfusion contributes to the initial damage to allografts after kidney transplantation (ktx). In this study we tested the hypothesis that a tetrapeptide EA-230 (AQGV), might improve survival and attenuate loss of kidney function in a mouse model of renal ischemia/reperfusion injury (IRI) and ischemia-induced delayed graft function after allogenic kidney transplantation. IRI was induced in male C57Bl/6N mice by transient bilateral renal pedicle clamping for 35 min. Treatment with EA-230 (20–50mg/kg twice daily i.p. for four consecutive days) was initiated 24 hours after IRI when acute kidney injury (AKI) was already established. The treatment resulted in markedly improved survival in a dose dependent manner. Acute tubular injury two days after IRI was diminished and tubular epithelial cell proliferation was significantly enhanced by EA-230 treatment. Furthermore, CTGF up-regulation, a marker of post-ischemic fibrosis, at four weeks after IRI was significantly less in EA-230 treated renal tissue. To learn more about these effects, we measured renal blood flow (RBF) and glomerular filtration rate (GFR) at 28 hours after IRI. EA-230 improved both GFR and RBF significantly. Next, EA-230 treatment was tested in a model of ischemia-induced delayed graft function after allogenic kidney transplantation. The recipients were treated with EA-230 (50 mg/kg) twice daily i.p. which improved renal function and allograft survival by attenuating ischemic allograft damage. In conclusion, EA-230 is a novel and promising therapeutic agent for treating acute kidney injury and preventing IRI-induced post-transplant ischemic allograft injury. Its beneficial effect is associated with improved renal perfusion after IRI and enhanced regeneration of tubular epithelial cells.     

Effects of Bay K 8644 on renal function and renin secretion in anesthetized rats

Our previous study on kidney cortical slices showed that Bay K 8644, a dihydropyridine calcium channel agonist, produced a dose-dependent inhibitory action on the release of renin. The present study was performed to examine the effect of Bay K 8644 on renal function and renin secretion in vivo. When Bay K 8644 was directly infused into the renal artery of anesthetized rats, 2 micrograms/kg/min had no effect on renal blood flow (RBF) and glomerular filtration rate (GFR), but decreased urine flow (UF), urinary sodium excretion (UNaV) and fractional sodium excretion (FENa) by about 30%, 55% and 35%, respectively, thereby suggesting that Bay K 8644 enhanced the tubular reabsorption of water and sodium. When 10 micrograms/kg/min were infused, RBF, GFR, UF, UNaV and FENa decreased to about 95%, 70%, 35%, 35% and 30% of each control value. The administration of Bay K 8644 at 10 micrograms/kg/min did not influence the basal levels of plasma renin activity (PRA) and renin secretion rate (RSR), but did inhibit significantly isoproterenol-induced increasing effects on PRA and RSR. These results indicate that the activation of voltage-dependent calcium channels with Bay K 8644 influences the control of renal function and renin secretion in vivo.     

Role of NO and COX pathways in mediation of adenosine A1 receptor-induced renal vasoconstriction

The mechanism of adenosine A1 receptor-induced intrarenal vasoconstriction is unclear; it depends on sodium intake and may be mediated by changing the intrarenal activity of the nitric oxide (NO) and/or cyclooxygenase (COX) pathway of arachidonic acid metabolism. The effects of 2-chloro-N(6)-cyclopentyl-adenosine (CCPA), a selective A1 receptor agonist, on renal hemodynamics were examined in anesthetized rats maintained on high sodium (HS) or low sodium (LS) diet. Total renal (i.e., cortical) blood flow (RBF) as well as superficial cortical (CBF), outer medullary (OMBF), and inner medullary (IMBF) flows were determined by laser-Doppler. In HS rats, suprarenal aortic infusions of 8-40 nmol/kg/hr CCPA decreased IMBF (15%) and other perfusion indices (22%-27%); in LS rats, IMBF increased 3% (insignificant) and other indices decreased 13%-24%. In LS rats, pretreatment with N-nitro-L-arginine methyl ester prevented the A1 receptor-mediated decrease in RBF and CBF but not OMBF; the response in IMBF was not altered. Pretreatment with indomethacin prevented the decreases in RBF, CBF, and OMBF and did not change the response of IMBF. Thus, within the cortex the vasoconstriction that follows A1 receptor activation results both from inhibition of NO synthesis and from stimulation of vasoconstrictor products of the COX pathway. In the outer medulla, the latter products seem exclusively responsible for CCPA-induced vasoconstriction. The observation that in LS rats IMBF was not affected by stimulation of adenosine A1 receptors suggests that limiting salt intake may help protect medullary perfusion against vasoconstrictor stimuli which have the potential to disturb long-term control of arterial pressure.     

Effects of short-term hypothermic perfusion and cold storage on function of the isolated-perfused dog kidney

The isolated-perfused dog kidney was used as a model to measure the effects of short-term hypothermic preservation on renal function and metabolism. Kidneys were cold-stored in Collins' solution, hypotonic citrate, or phosphate-buffered sucrose for 4 and 24 hr, or were continuously perfused for 4 and 24 hr with a synthetic perfusate. Following preservation kidneys were perfused with an albumin-containing perfusate at 37 degrees C for 60 min for determination of renal function. The results indicate that many of the effects of short-term preservation on renal function in dog kidneys are similar to results reported for rat and rabbit kidneys. Cold storage for 4 hr resulted in a large decrease in GFR (57%), but only a small decrease in Na reabsorption (from 97 to 87%). Cold storage for 24 hr caused a further decline in renal function (GFR = 95% decrease, Na reabsorption = 49-64%). Results were similar for all cold storage solutions tested. Perfusion for 4 hr was less damaging to renal function than cold storage. The GFR decreased only 14% and urine formation and Na reabsorption were practically normal. After 24 hr of hypothermic perfusion, the GFR was reduced by 79%, urine flow was normal, and Na reabsorption was 78%. There were no obvious biochemical correlates (adenine nucleotides, tissue edema, or electrolyte concentration) with the loss of renal function during short-term preservation. The results suggest that the isolated-perfused dog kidney can be used to test the effects of preservation on renal function, and yields results similar to those obtained using small animal models.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mechanisms of the early and late response of the kidney to contralateral nephrectomy.

The immediate (1 day, D1) and late (90 days, D90) effects of unilateral nephrectomy on contralateral renal hemodynamics, and the renal handling of electrolytes and water were investigated in the whole animal. The immediate and late ability of the remnant kidney to autoregulate perfusate flow and glomerular filtration rate (GFR) was studied in the isolated perfused kidney of the rat. In the whole animal, in D1 rats as compared to controls, GFR calculated for a single kidney increased from 0.85 +/- 0.3 to 1.1 +/- 0.2 ml/min (p less than 0.05). In D90 rats GFR increased further and was similar to prenephrectomy GFR (1.4 +/- 0.5 vs. 1.7 +/- 0.5 ml/min, p NS). Urinary prostanoid excretion in 24 h, calculated for one kidney, increased by 50-500% in D1 rats, but returned to prenephrectomy values in D90 rats. In the isolated perfused kidney, decreasing perfusion pressure (PP) from 100 to 70 mmHg did not change the renal vascular resistance (RVR) in control and D90 kidneys, but in D1 kidneys RVR decreased from 8.6 +/- 1.3 to 7 +/- 1.3 mm Hg/ml/min (p less than 0.05). In D90 kidneys RVR was significantly lower as compared to control and D1 kidneys at all perfusion pressures. Decreasing PP from 100 to 70 mm Hg resulted in a significant decrease in perfusion flow in control, D1 and D90 kidneys, while with the increase in PP from 100 to 130 mm Hg the perfusion flow increased significantly in all three kidney groups.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of cold ischemia on the preserved rat kidney: Intrarenal distribution of perfusate

The intrarenal distribution of a modified Collins solution containing 5% of human albumin was investigated during the initial perfusion of rat kidneys and after 2, 12, and 16 hr of cold storage. Carbonized microspheres 9 μm in diameter were injected upstream into a mixing chamber and the change in regional renal resistance of three cortical zones was calculated. The resistance in the inner cortical zone increased to a significantly greater extent than that in the outer cortical zone. The prerequisites for a reduction of deep cortical and thus medullary blood flow after recirculation of the kidney seem to be already established during the hypothermic storage.     

Early renal hemodynamic modifications following the ablation of the controlateral kidney]

Instantaneous measurements of renal blood flow (RBF) and glomerular filtration rate (GFR) have been performed in anesthetized dogs to determine if removal of one kidney induces early functional adaptation in the remaining kidney. Increases in RBF (10%) and GFR (20%) were observed within the first minutes after exclusion of controlateral kidney; these are the earliest events described until now. These observations favour the concept that a functional adjustement may contribute to development of compensatory renal hypertrophy.