Intrarenal Distribution Of Blood Flow Research Articles

Visualization of the intrarenal distribution of capillary blood flow.

This study describes a modified technique to fill the renal vasculature with a silicon rubber (Microfil) compound and obtain morphologic information about the intrarenal distribution of capillary blood flow under a variety of conditions. Kidneys and cremaster muscles of rats were perfused in vivo with Microfil using a perfusion pressure equal to the animal's mean arterial pressure at body temperature. Microfil did not alter arteriolar diameter or the pattern of flow in the microcirculation of the cremaster muscle. The modified protocol reproducibly filled the renal vasculature, including; glomerular, peritubular, and vasa recta capillaries. We compared the filling of the renal circulation in control rats with that seen in animals subjected to maneuvers reported to alter the intrarenal distribution of blood flow. Infusion of angiotensin II, hypotension, volume expansion, and mannitol‐ or furosemide‐induced diuresis redistributed flow between renal cortical and medullary capillaries. The advantage of the current technique is that it provides anatomical information regarding the number, diameter, and branching patterns of capillaries in the postglomerular circulation critical in determining the intrarenal distribution of cortical and medullary blood flow.

High-resolution renal perfusion mapping using contrast-enhanced ultrasonography in ischemia-reperfusion injury monitors changes in renal microperfusion

Alterations in renal microperfusion play an important rolein the development of acute kidney injury with long-term consequences. Here we used contrast-enhanced ultrasonography as a novel method for depicting intrarenal distribution of blood flow. After infusion of microbubble contrast agent, bubbles were collapsed in the kidney and postbubble destruction refilling was measured in various regions of the kidney. Local perfusion was monitored invivo at 15, 30, 45, 60 minutes and 24 hours after 28 minutes of bilateral ischemia in 12 mice. High-resolution, pixel-by-pixel analysis was performed on each imaging clip using customized software, yielding parametric perfusion maps of the kidney, representing relative blood volume ineach pixel. These perfusion maps revealed that outer medullary perfusion decreased disproportionately to the reduction in the cortical and inner medullary perfusion after ischemia. Outer medullary perfusion was significantly decreased by 69% at 60 minutes postischemia and remained significantly less (40%) than preischemic levels at24 hours postischemia. Thus, contrast-enhanced ultrasonography with high-resolution parametric perfusion maps can monitor changes in renal microvascular perfusion in space and time in mice. This novel technique can be translated to clinical use in man.

Commentary

Commentary

Short-term effects of tolvaptan on renal function and volume in patients with autosomal dominant polycystic kidney disease

Tolvaptan and related V(2)-specific vasopressin receptor antagonists have been shown to delay disease progression in animal models of polycystic kidney disease. Slight elevations in serum creatinine, rapidly reversible after drug cessation, have been found in clinical trials involving tolvaptan. Here, we sought to clarify the potential renal mechanisms to see whether the antagonist effects were dependent on underlying renal function in 20 patients with autosomal dominant polycystic kidney disease (ADPKD) before and after 1 week of daily split-dose treatment. Tolvaptan induced aquaresis (excretion of solute-free water) and a significant reduction in glomerular filtration rate (GFR). The serum uric acid increased because of a decreased uric acid clearance, and the serum potassium fell, but there was no significant change in renal blood flow as measured by para-aminohippurate clearance or magnetic resonance imaging (MRI). No correlation was found between baseline GFR, measured by iothalmate clearance, and percent change in GFR induced by tolvaptan. Blinded post hoc analysis of renal MRIs showed that tolvaptan significantly reduced total kidney volume by 3.1% and individual cyst volume by 1.6%. Preliminary analysis of this small cohort suggested that these effects were more noticeable in patients with preserved renal function and with larger cysts. No correlation was found between changes of total kidney volume and body weight or estimated body water. Thus, functional and structural effects of tolvaptan on patients with ADPKD are likely due to inhibition of V(2)-driven adenosine cyclic 3',5'-monophosphate generation and its aquaretic, hemodynamic, and anti-secretory actions.

A true champion of Hungarian kidney research and nephrology education — Tribute to László Rosivall

This article pays tribute to the tremendous achievements of Dr. László Rosivall in renal (patho)physiology research and nephrology education in Hungary on the occasion of his 60th birthday. For the past several decades Dr. Rosivall has been a charismatic leader of academic institutions, national and international societies, foundations in physiology, nephrology and hypertension, but the most important of his many contributions, is his role as a scientist. He earned his MD with Summa cum Laude at Semmelweis University (1973) and was invited immediately after that to join the laboratory of Hársing. He studied the distribution of intra-renal blood flow employing then state-of-the-art methods as well as developed his own technique at Semmelweis University and at the University of Bergen with Knut Aukland. This led to his PhD thesis and degree in 1980. An important determinant of his early basic scientific training and development was his postdoctoral research fellowship and later many visiting professorships in the Nephrology Research and Training Center (NRTC) at the University of Alabama at Birmingham, Birmingham, AL, USA between 1981 and 1983. Actually, this research fellowship not only impacted his own future career, but it also cleared the path for many other young Hungarian scientists who later trained with Dr. Rosivall and then at UAB. The early 1980s were the years of significant scientific discoveries and the NRTC team at UAB made important contributions by their studies on renal and glomerular hemodynamics, the renin-angiotensin system (12, 19, 22) and by the development of classic experimental techniques like renal micropuncture, microperfusion, and the juxtamedullary nephron preparation (3) that are still being used worldwide. When Dr. Rosivall joined UAB in the 1980s, the team at the NRTC included Drs. Navar, Bell, Inscho, Carmines, Casellas, and Oparil, among many others, who share their fond memories of working with Dr. Rosivall in this article.

The intrarenal blood flow distribution and role of nitric oxide in diabetic rats

A few attempts have so far been made to determine the regional renal blood flow distribution in experimental diabetic rats. In the present experiment, 3 weeks after successful streptozotocin injection in diabetic rats (n = 8), the blood flows in the renal superficial and deep cortexes and outer medulla with implanted fibers were measured by laser-Doppler techniques. Renal blood flow was measured by an ultrasonic flow probe placed around the renal artery. Studies were performed at the baseline condition, during the administration of nonselective nitric oxide synthesis inhibitor, nitro- l-arginine methyl-ester ( l-NAME), and during the postinfusion period. The results showed that superficial cortical blood flow and deep cortical blood flow were significantly greater ( P < .05) in diabetic rats compared with control rats (n = 8) (superficial cortical blood flow, 2.18 ± 0.22 vs 1.55 ± 0.21 V; deep cortical blood flow, 1.32 ± 0.13 vs 0.99 ± 0.14 V) with the significant increase in renal blood flow (18.1 ± 3.3 vs 14.5 ± 2.7 mL/min). Furthermore, it was shown that in diabetic rats the intravenous infusion of a low dose of l-NAME, which did not alter medullary blood flow, decreased cortical blood flow (CBF) ( P < .05), whereas in control rats l-NAME did not affect CBF but a high dose of l-NAME decreased medullary blood flow ( P < .05). We conclude that in early diabetic nephropathy the blood flow is increased in both the superficial and deep cortexes, and nitric oxide plays an important role in regulating the CBF during the development of diabetic nephropathy.

Enhanced renal cortical vascularization in experimental hypercholesterolemia

Experimental hypercholesterolemia is associated with pro-inflammatory changes and impaired regulation of tissue perfusion, which may lead to neovascularization. However, it is yet unknown whether such changes take place in the kidney. In this study, using a novel three-dimensional (3-D) micro computed-tomography technique we tested the hypothesis that hypercholesterolemia was associated with increased microvascular density in the renal cortex. Kidneys were excised from pigs after 12 weeks of either a normal (N = 6) or high cholesterol (HC; N = 5) diet, histology slides processed, and a segmental renal artery injected with a radio-opaque intravascular silicone polymer. Renal samples were scanned with micro computed-tomography, transverse and three-dimensional images were reconstructed, and microvessels (80 to 360 microm in diameter) counted in situ. Serum cholesterol levels were significantly higher in hypercholesterolemic compared to normal pigs (383 +/- 76 vs. 81 +/- 7 mg/dL, P < 0.01), and microvascular spatial density was significantly higher in their inner and middle renal cortex (189 +/- 7 vs. 126 +/- 6 microvessels/cm2, P < 0.0001). Hypercholesterolemic kidneys also showed mild interstitial mononuclear infiltration and heavier immunostaining of vascular endothelial growth factor, but no other signs of morphological damage. These results demonstrate that early diet-induced hypercholesterolemia is associated with increased microvascular density in the renal cortex, which precedes signs of overt renal morphological damage. These alterations may potentially affect regulation and/or spatial distribution of intrarenal blood flow in hypercholesterolemia, and may participate in renal disease progression.

N-acetyl-L-cysteine improves renal medullary hypoperfusion in acute renal failure.

This study evaluated the effects of N-acetyl-L-cysteine (NAC), a free radical scavenger, and N(omega)-nitro-L-arginine methyl ester (L-NAME), a nitric oxide (NO) synthesis inhibitor, on the changes in renal function, intrarenal blood flow distribution (laser-Doppler flowmetry), and plasma peroxynitrite levels during the acute renal failure (ARF) produced by inferior vena cava occlusion (IVCO; 45 min) in anesthetized rats. Renal blood flow fell on reperfusion (whole kidney by -45.7%; cortex -58.7%, outer medulla -62.8%, and papilla -47.7%); glomerular filtration rate (GRF) also decreased (-68.6%), whereas fractional sodium excretion (FE(Na%)) and peroxynitrite and NO/NO plasma levels increased (189.5, 46.5, and 390%, respectively) after ischemia. Pretreatment with L-NAME (10 microg. kg(-1). min(-1)) aggravated the fall in renal blood flow seen during reperfusion (-60%). Pretreatment with NAC (150 mg/kg bolus + 715 microg. kg(-1). min(-1) iv) partially prevented those changes in renal function (GFR only fell by -29.2%, and FE(Na%) increased 119.4%) and laser-Doppler blood flow, especially in the outer medulla, where blood flow recovered to near control levels during reperfusion. These beneficial effects seen in rats given NAC seem to be dependent on the presence of NO, because they were abolished in rats pretreated with L-NAME. Also, the antioxidant effects of NAC prevented the increase in plasma peroxynitrite after ischemia. In conclusion, NAC ameliorates the renal failure and the outer medullary vasoconstriction induced by ICVO, effects that seem to be dependent on the presence of NO and the scavenging of peroxynitrite.

Ischémie du greffon rénal et hyperlactatémie

The authors report four cases of patients presenting with hyperlactatemia following renal transplantation. The post-transplantation course of three patients who underwent renal transplantation was complicated by occult haemorrhage. Excessive blood loss was not evident, the patients were haemodynamically stable and their blood pressure, pulse rare and filling pressure (central venous pressure) were unremarkable. Late examinations revealed an early increase in arterial lactate concentrations a non-aniograp acidosis or lactic acidaemia occurred. Surgical decompression was carried on in all patients. An increase in the intra-abdominal pressure might have caused renal impairment in the absence of haemodynamic disturbance, and retroperitoneal haematoma a change in the distribution of intrarenal blood flow. Another patient developed a partial renal venous thrombosis associated with hyperlactatemia. During this re-operation, a renal lactate production was measured. The renal cortex is a site of lactate clearance. Impaired renal perfusion should result in decreased lactate clearance and when the kidney is hypoperfused a lactate production was occur. In the absence of any signs of clinical shock, patient at risk of retroperitoneal haematoma or presenting with oliguria should benefit from lactate measurements, which could help diagnosing severe hypoperfusion of the graft.

Differential control of intrarenal blood flow during reflex increases in sympathetic nerve activity.

The role of renal sympathetic nerve activity (RSNA) in the physiological regulation of medullary blood flow (MBF) remains ill defined, yet regulation of MBF may be crucial to long-term arterial pressure regulation. To investigate the effects of reflex increases in RSNA on intrarenal blood flow distribution, we exposed pentobarbital sodium-anesthetized, artificially ventilated rabbits (n = 7) to progressive hypoxia while recording RSNA, cortical blood flow (CBF), and MBF using laser-Doppler flowmetry. Another group of animals with denervated kidneys (n = 6) underwent the same protocol. Progressive hypoxia (from room air to 16, 14, 12, and 10% inspired O(2)) significantly reduced arterial oxygen partial pressure (from 99 +/- 3 to 65 +/- 2, 51 +/- 2, 41 +/- 1, and 39 +/- 2 mmHg, respectively) and significantly increased RSNA (by 8 +/- 3, 44 +/- 25, 62 +/- 21, and 76 +/- 37%, respectively, compared with room air) without affecting mean arterial pressure. There were significant reductions in CBF (by 2 +/- 1, 5 +/- 2, 11 +/- 3, and 14 +/- 2%, respectively) in intact but not denervated rabbits. MBF was unaffected by hypoxia in either group. Thus moderate reflex increases in RSNA cause renal cortical vasoconstriction, but not at vascular sites regulating MBF.

New methods to investigate the intrarenal distribution of blood flow and tubular fluid flow dynamics

Renal functional imaging has greatly advanced thanks to new imaging techniques. The elucidation of physiopathological mechanisms in diseases such as renovascular disease, ischemic nephropathy and hypertension may be facilitated by the detection of changes in the total and intrarenal distribution of

The development of x-ray imaging to study renal function

The well-established role of the kidney in control of blood volume and ultimately arterial blood pressure has been underscored by the demonstration of alterations in renal hemodynamics and function recognized as responsible for these and other regulatory mechanisms. Nevertheless, the spatial complexity of intrarenal structure and function has made evident the need to study these separately in different regions of the intact kidney. Because of the introduction of x-rays, assessment of renal function has indeed been one of their attractive applications. However, despite the appeal of their noninvasiveness, several limitations confounded the different x-ray techniques used, most of which remained unresolved until the development of computed tomography. Furthermore, the development of fast imaging, which allows repetitive analysis of the same region of interest during the transit of contrast medium, holds a great potential to estimate intrarenal distribution of blood flow and the dynamic characteristics of tubular fluid flow in individual nephron segments. This latter assessment requires the administration of filterable x-ray contrast medium, which is cleared from the plasma almost exclusively by glomerular filtration, and the generation of contrast dilution curves. A historical review of the development and progress of the various x-ray techniques used will help understand the past and present of x-ray imaging, and will make it easier to envision the importance of their future roles in the study of renal physiology and pathophysiology.

Nitric oxide(NO)とangiotensin II(Ang II)の腎血行動態への影響

We have already reported that decreased renal medullary blood flow and retention of sodium play an important role in the development of hypertension during chronic systemic L-NAME (NG-nitro-L-arginine methyl ester) administration, despite the absence of measurable changes in renal cortical blood flow as determined from fibers implanted for laser-Doppler flowmetry. In the present experiment, to investigate the interaction between nitric oxide and angiotensin II on renal hemodynamics, the effect of chronic intravenous infusion of L-NAME on blood pressure, sodium and water retention, and intrarenal blood flow distribution were studied in a separate group of rats pretreated with captopril and in which optical fiber for laser-Doppler flowmetry had been implanted. Captopril completely prevented sustained hypertension, sodium retention, and decreased medullary blood flow during chronic L-NAME infusion. These date indicated that angiotensin plays an important role in the regulation of renal medullary blood flow and sodium excretion by modulating the effects of nitric oxide in renal medullary blood flow.

Reduction of renal cortical blood flow assessed by Doppler in cirrhotic patients with refractory ascites.

The usefulness in cirrhotic patients of hemodynamic measurements by Doppler ultrasonography (US) is still not defined. We investigated the relationships between Doppler measurements and the severity of ascites. Portal blood flow velocity and volume, and hepatic and renal arterial resistance indexes (RI) were measured in 57 cirrhotic patients (19 without ascites, 28 with responsive ascites, and 10 with refractory ascites) and 15 healthy controls. The renal arterial RI were obtained for the main renal artery, interlobar vessels, and cortical vessels. Cirrhotic patients had decreased portal blood flow and an increased congestion index (CI). Only the CI was correlated to the severity of ascites, showing that it is also a reliable measure of the severity of portal hypertension in patients with ascites. The hepatic and renal artery RI were increased in cirrhotic patients, and the two values were correlated (r = .68; P = .00001). The RI of renal interlobar and cortical vessels were higher in patients with refractory ascites than in patients without ascites (P < .02 and P < .009), and correlated with sodium excretion rate (r = -.45; P < .003), the renin-aldosterone system, and creatinine clearance (r = -.62; P < .0002). The RI decreased from the hilum of the kidney to the outer parenchyma in healthy subjects and patients with responsive ascites, but this difference disappeared in patients with refractory ascites. This indicates that the degree of renal vasoconstriction varies in different areas according to the severity of the ascites. Cortical vessels are involved mainly in patients with refractory ascites, suggesting that the intrarenal blood flow distribution in cirrhosis tends to preserve the cortical area and that severe cortical ischemia is a feature of refractory ascites.

Pharmacological stimulation of arterial chemoreceptors in conscious rats produces differential responses in renal cortical and medullary blood flow.

1. There have been no previously published data regarding intrarenal blood flow distribution in acute whole-body hypoxic hypoxia and/or arterial chemoreceptor stimulation in normoxic mammals. 2. Cortical and medullary blood flows were measured simultaneously before and in response to pharmacological stimulation of peripheral arterial chemoreceptors by i.v. injection of almitrine bismesylate (0.25 mg/kg). 3. Arterial chemoreceptor excitation reduced cortical blood flow but only in innervated kidneys. An effect on medullary blood flow was observed in neither innervated nor denervated kidneys. 4. These data indicate that renal cortical and medullary blood flows react differently to arterial chemoreceptor stimulation.

Heterogeneity of glomerular perfusion and filtration induced by epinephrine and norepinephrine.

The role of catecholamines in the distribution of intrarenal blood flow and in single-nephron glomerular filtration rate (SNGFR) was evaluated in anesthetized Wistar rats by the Hanssen technique. Epinephrine (EPI) and norepinephrine (NOR) were infused to produce elevations of 20-30 mmHg in mean arterial pressure. Superficial and juxtamedullary nephron perfusion and filtration were determined by the presence of Prussian blue dye. In the control group, 100% of the nephrons presented a homogeneous pattern of perfusion and filtration. In contrast, a heterogeneous distribution of the dye was found even in the larger arteries (arciform and radial), indicating variable perfusion and filtration in both superficial and juxtamedullary nephrons. The effects of EPI and NOR were also evaluated in the superficial cortex by the micropuncture technique in two additional groups of Munich-Wistar rats. Mean SNGFR was 27% and 54% lower in the EPI- and NOR-treated groups, respectively. No change in mean intraglomerular hydraulic pressure was observed after EPI or NOR infusion in spite of a highly scattered pattern, indicating an important variability in perfusion along the superficial cortex, and/or different sensitivity of the pre- and post-glomerular arterioles. The present data suggest that EPI and NOR may affect intrarenal hemodynamics by modifying perfusion and filtration in both superficial and juxtamedullary glomeruli and not by shifting blood flow from superficial to juxtamedullary nephrons. The heterogeneous pattern of perfusion was a consequence of differential vasoconstriction along the intrarenal arteries, probably due to different density and/or sensitivity of the adrenergic receptor subtypes present in the intrarenal vascular tree.

Renal Dopamine Production and Release in the Rat: A Microdialysis Study

This chapter summarizes several studies that investigate renal interstitial (RIF) dopamine (DA) and urinary DA excretion (U DA V) in anesthetized rats on either normal or high sodium balance and in response to acute administration of a DA prodrug, γ-L-glutamyl-L-dopa (gludopa). Responses of renal sodium excretion and intrarenal blood flow distribution to gludopa have also been examined. The studies confirmed that U DA V increases in response to chronic salt loading. The mechanism underlying the observed reduction in RIF DA with chronic salt loading is not apparent. Histofluorescent and neurochemical findings also suggest the presence of dopaminergic neurons in the kidney, and adrenergic nerves may become dopaminergic under certain circumstances. Vagal afferents have been shown to stimulate renal release of DA and produce a neurogenically mediated natriuresis. The data confirm that the main source of DA in the urine is nonneuronal, and further demonstrate that renal nerve activity does not contribute significantly to either urinary or interstitial fluid DA. The studies presented in the chapter strongly support that intrarenal DA plays a role in the control of natriuresis through a tubule mechanism. The renal sympathetic nerve endings are closely related to the juxtaglomerular apparatus and proximal tubule cells. It has been also demonstrated that intrarenal production of DA and its renal effects are not significantly influenced by renal sympathetic nerve activity.

Noninvasive measurement of intrarenal blood flow distribution: kinetic model of renal 123I-hippuran handling.

A new technique for noninvasive measurement of intrarenal blood flow distribution over cortex and medulla is proposed. The technique involves analysis of 123I-labeled hippuran renography, according to a kinetic model that describes the flow of 123I-hippuran from the heart (input) through the renal cortex and medulla to the bladder (output). The method is validated and compared with the standard microsphere injection technique in anesthetized dogs. Changes in intrarenal blood flow distribution were induced by infusion of placebo (n = 6), angiotensin I (n = 5), or atrial natriuretic factor (n = 5). Baseline percentage medullary blood flow in the left kidney was 12 +/- 1% of total renal blood flow measured with microspheres and 15 +/- 1% with renography. During infusion of the placebo, medullary blood flow decreased slightly compared with baseline, as measured with both methods, by 2 +/- 6 (microspheres) and 1 +/- 8% (renography). Infusion of angiotensin I caused a marked fall in medullary blood flow by 42 +/- 11 (microspheres) and 57 +/- 8% (renography). In contrast, infusion of atrial natriuretic factor caused a small rise in medullary blood flow as measured with both methods (9 +/- 3 and 12 +/- 11%, respectively). The absolute and percent changes in medullary blood flow measured with renography correlated with those measured with microspheres (left kidney: r = 0.67, P = 0.005; r = 0.71, P = 0.003, respectively; right kidney: r = 0.62, P = 0.01; r = 0.68, P = 0.004, respectively). We conclude that the proposed kinetic model of renal 123I-hippuran handling can be used to measure changes in intrarenal blood flow distribution and, because of its noninvasive character, may be of use in clinical studies.

Nitric Oxide Mediates Redistribution of Intrarenal Blood Flow during Bacteremia

The normal or hyperdynamic circulatory response during the early phases of the systemic septic response is associated with renal microvascular constriction and can result in renal dysfunction. Intrarenal redistribution of blood flow from the outer cortex to the medulla appears to account for decreased glomerular filtration in spite of normal or elevated renal blood flow, but the mechanisms of this response are not well described. Nitric oxide is recognized as an important regulator of regional blood flow during both normal and pathologic conditions including sepsis, and we hypothesized that alterations in nitric oxide contribute to redistribution of renal blood flow during sepsis. The current study used laser Doppler fluximetry and clearance of p-aminohippuric acid (effective renal plasma flow, ERPF) to study intrarenal distribution of blood flow during basal conditions and during normodynamic Escherichia coli bacteremia, with and without inhibition of nitric oxide. Inhibition of nitric oxide in normal animals resulted in a decrease in ERPF (-19%) with a decrease in cortical flux (-39%) without alteration of medullary flux. Bacteremia resulted in a decrease in cortical flow (-17%), an increase in medullary flow (36%), and a modest reduction (-9%) in ERPF. Inhibition of nitric oxide synthase during bacteremia worsened cortical flow (-43%), reversed the increase in medullary flux (-42%), and further impaired ERPF (-28%). These data suggest that nitric oxide regulates renovascular tone during normal conditions and bacteremia, and indicate that it is a prime mediator of intrarenal redistribution of blood flow during sepsis.

Disturbances in renal microcirculation induced by myoglobin and hemorrhagic hypotension in anesthetized rat.

The question was studied of whether myoglobin (Mb), when released into the general circulation during hemorrhagic hypotension (HH), causes disturbances of renal blood flow. In anesthetized rats 250 mg/kg Mb was intravenously infused within 1 h; HH at 50 mmHg with subsequent retransfusion was induced for 30 min. By allowing two dyes to circulate for 1 and 3 min, respectively, and detecting their localization histologically after rapid freezing of the organ, intrarenal distribution of capillary blood flow was studied. In contrast to the results obtained with Mb or HH alone, when Mb was infused during HH, the development of large areas within cortex and medulla lacking any capillary perfusion was observed. In > 70% of the tissue, a distance > 60 microns to the next dye-labeled capillary was found (in controls 0%). At this time total renal flow had decreased from 5.3 to 0.20 ml/min (HH without Mb: 5.1 to 1.1 ml/min). It is concluded that the observed changes in renal blood flow contribute to the known direct nephrotoxic potential of Mb.