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.     

Influence of antidiuretic hormone on intrarenal blood flow distribution in diabetes insipidus dogs and rats.

The distribution of labeled microspheres within the renal cortex was used to evaluate the influence of physiological amounts of antidiuretic hormone on intrarenal blood flow distribution in hypophysectomized dogs and in rats with hereditary diabetes insipidus. In both species, intravenous infusions of ADH caused a significant decrease in the ratio of inner to outer cortical blood flow. The change in blood flow distribution observed in the hypophysectomized dog with ADH was primarily a consequence of a decrease in inner cortical blood flow. No consistent changes in outer cortical blood flow were found. Also in the dog, glomerular filtration rates and electrolyte excretion rates (Na and K) increased following ADH. In contrast, ADH infusion into Brattleboro rats caused no change in glomerular filtration or excretion of Na and K.     

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.     

Effect of metabolic acidosis on fetal renal haemodynamics

The effects of metabolic acidosis on renal haemodynamics and intrarenal blood flow distribution was studied in two groups of chronically-catheterized fetal sheep between 122 and 130 days of gestation. One group (experimental group) was studied before and during infusion of 1.1 M lactic acid, whereas the second group received on infusion of dextrose 5% (w/v) in water and served as a time-control group. Infusion of lactic acid for 2 h decreased fetal arterial pH from 7.37 +/- 0.01 to 6.95 +/- 0.02, did not change arterial blood pressure, but produced a significant decrease in renal blood flow (41 +/- 3 to 33 +/- 7 ml/min, P less than 0.05) and a significant increase in renal vascular resistance (1.42 +/- 0.13 to 1.86 +/- 0.18 mmHg/ml/min, P less than 0.05). Moreover, a significant decline in cortical blood flow was also observed in the outer portion of the renal cortex during lactic acidosis. Taken together, these results suggest that metabolic acidosis produces significant changes in fetal renal haemodynamics not associated with changes in arterial blood pressure.     

Urinary concentrating processes in vertebrates.

Avian and mammalian kidneys can produce a urine hyperosmotic to the blood by means of a renal countercurrent system. Birds are uricotelic; mammals are ureotelic. It is proposed that the inner medulla present in mammalian, but not in avian kidneys serves specifically to accumulate urea in the inner and outer medulla. Among mammalian kidneys the degree to which urea accumulates in the inner medulla is inversely related to the complexity of the vascular bundles (in the outer medulla) and the cortical urea recycling index. A model is proposed for urea recycling via the vascular bundles. The renal pelvis varies in size among mammals. Its relative size is unrelated to the type of vascular bundles, cortical recycling index; or urea accumulation in the inner medulla. Since urine refluxes into the renal pelvis during rising urine flow only, the function of the pelvis could be that of bringing the more dilute urine into contact with the outer medulla and underlying capillaries, thereby aiding in reducing the urea concentration in outer and inner medulla during rising urine flow. The size of the renal pelvis may be related to the volume of the inner medulla. Other factors may also be involved.     

Effect of renal vasodilatation on intrarenal blood flow distribution

Total renal blood flow (TRBF) and its intrarenal and intracortical distribution were measured before and during renal vasodilatation induced by acetylcholine infusion using the 133Xe washout, 86Rb uptake and radioactive microspheres distribution techniques. A good agreement was observed between TRBF calculated from 133Xe washout and measured with the electromagnetic flowmeter (FM). 86Rb-TRBF was lower than FM-TRBF and, due to the progressive reduction of renal 86Rb uptake, the difference increased with the increase of flow. With the alteration of TRBF the intrarenal distribution of 86Rb uptake did, however, not change significantly and, accordingly there was no redistribution of RBF either between the cortex and medulla, or among the individual cortical zones. The intracortical distribution of labelled microspheres showed, however, moderate flow dependent changes: with the rise of TRBF, due probably to the reduction of the steric hindrance, the estimated fractional perfusion of the inner cortical zones increased. The sum of the per cent 86Rb content of the innermost cortical zone (C4) and of the medulla exceeded the per cent microsphere content of zone C4. It is concluded that the medulla is perfused not exclusively with blood flowing from the juxtamedullar glomeruli. The regional flow values obtained from the 133Xe curves are not comparable with the results obtained by other methods and cannot be attributed to well defined areas of the kidney.     

Canine renal vascular response to bilateral carotid occlusion during hypoxia

Chloralose-urethane anesthetized dogs were utilized to determine if hypoxemic potentiation of the baroreceptor-mediated increase in renal sympathetic nerve activity (RSNA) results in sufficient renal vascular vasoconstriction to reduce renal blood flow (RBF) during bilateral carotid occlusion (BCO). Additionally, hypercapnia and mechanical ventilation were randomly combined with hypoxemia during BCO to determine if further augmentation of renal vasoconstriction could be accomplished. BCO resulted in a similar increase in blood pressure (renal perfusion pressure) in all periods. RBF was not reduced significantly by BCO during any period even though renal vascular resistance was significantly increased by BCO during each period. When hypoxemia was combined with hypercapnia and mechanical ventilation simultaneously, there was a greater percentage increase in renal resistance with BCO. During BCO, when renal perfusion pressure was returned to control values by suprarenal aortic constriction, RBF remained unchanged and renal resistance decreased to control values. These results indicate that the BCO-induced increase in RSNA is relatively moderate and, even when potentiated by hypoxemia, hypercapnia, and mechanical ventilation, is not sufficient to reduce RBF in the presence of an increase in blood pressure and renal autoregulation.     

Proceedings: The effects of hypothalamic and reflexogenic hypertension on renal and femoral circulation.

In anaesthetized dogs, electrical stimulation of the median posterior hypothalamus provoked hypertension accompanied by a decrease of renal blood flow and an increase of femoral blood flow. Similar hypothalamic reactions occurred after bilateral cervical vagotomy or after atropine, 2 mg/kg i.v. During reflexogenic hypertension induced by bilateral carotid occlusion in bivagotomized dogs, the renal and femoral blood flows were not significantly modified. The decrease of the renal blood flow and the increase of the femoral blood flow, during hypothalamic stimulation were greatly reduced or reversed after R 28935 equals erythro-1-(1--e12-(1,4-benzodioxan-2-yl)-2-OH-Et]-4-piperidyl)-2-benzimidaxolinone, 80 mug/kg i.v., but not after clonidine, 5 mug/kg i.v.     

The effect of PGI2 on canine renal function and hemodynamics.

The effect of prostaglandin I2 (prostacyclin) on renal and intrarenal hemodynamics and function was studied in mongrel dogs to elucidate the role of this novel prostaglandin in renal physiology. Starting at a dose of 10(-8) g/kg/min, PGI2 decreased renal vascular resistance and redistributed the blood flow away from the outer cortex (zone 1) and towards the juxtamedullary cortex (zone 4). At 3 X 10(-8) g/kg/min, the renal vascular resistance decreased even further, but at this dose the mean arterial blood pressure also declined 13% indicating recirculation of this prostaglandin. PGI2 infusion at a vasodilatory dose resulted in natriuresis and kaliuresis. With a decline in filtration fraction, these changes were most likely secondary to the hemodynamic effects of this prostaglandin. Unlike PGE2, PGI2 had no direct effect on free water clearance indicating lack of activity at the collecting duct. PGI2 may be the important renal prostaglandin involved in modulating renal vascular resistance and intrarenal hemodynamics as well as influencing systemic blood pressure.     

Cerebrovascular reserve in the cat after acute bilateral carotid occlusion

Cerebral blood flow in the cat was studied before and after acute bilateral common carotid occlusion under normocapnic and hypercapnic conditions and after induced hypotension. Regional blood flow to different brain structures was studied with the microsphere method. Local blood flow in the caudate nucleus, the cerebral cortex and medulla oblongata was studied with H2-polarography. Although the blood flow to the anterior brain regions is significantly decreased after bilateral common carotid occlusion, their blood supply is kept above ischaemic levels by re-distribution of the vertebrobasilar flow. Cerebrovascular reserve in anterior brain regions, however, is lost as indicated by the severe impairment of both the flow response to hypercapnia and to blood pressure decrease. After bilateral common carotid occlusion paradoxical CO2-reactions, indicating intracerebral steal, were seen in the caudate nucleus. In posterior brain regions resting blood flow, flow-reaction to hypercapnia and to hypotension are better preserved under these conditions. Measurement of the CBF responses to induced hypercapnia is a dependable test for appreciation of cerebrovascular reserve after cerebrovascular occlusion but may be potentially hazardous where local flow is close to ischaemic levels.     

Is the renin-angiotensin system involved in urinary concentration mechanisms?

Renin release elicited by i.v. injection of loop-diuretics was used to study the effects of angiotensin II (AII) on intrarenal hemodynamics. The vasoconstrictive action of intrarenally synthesized AII predominates in the efferent glomerular arteriole. Such a vasoconstrictive effect could affect blood flow in the vasa recta which stem from efferent arterioles of juxtamedullary glomeruli. Renin secretion and renal inner medullary blood flow (tissue clearance of 133Xe) were simultaneously measured before and after frusemide-induced renin release. The relationship between renin secretion and renal inner medullary blood flow was inverse. Changes in renal medullary blood flow may be physiological determinants of medullary osmolality and renal concentration ability. The intrarenal role of AII in urinary concentration recovery after frusemide was examined. Inhibition of renin release by propranolol or AII-blockade (by saralasin or Hoe 409) delayed recovery of urinary osmolality. In the conscious rat, propranolol slowed down recovery of the cortico-papillary gradient for sodium. Its vasoconstrictive action on the efferent glomerular arteriole might enable the renin-angiotensin system to participate in the control of renal excretion of salt and water.     

Cardiovascular function in anesthetized miniature swine.

Miniature swine anesthetized with pentobarbital were studied with respect to their cardiovascular function under control conditions and in response to catecholamines, baroreceptor inhibition, bilateral vagotomy and vagal nerve stimulation. Measurements included aortic pressure, heart rate, intraventricular pressure and its maximum rate of rise during contraction, carotid blood flow and resistance, femoral blood flow and resistance, and renal blood flow and resistance. The cardiovascular actions of norepinephrine, epiniphrine and isoproterenol were similar to those in other mammals, and the adrenergic receptor mechanisms also were susceptible to blockade with phentolamine or propranolol. Inhibition of the carotid baroreceptors was accompanied by elevation of aortic pressure, reflex bradycardia and increased femoral and renal resistances. Bileteral vagotomy was followed by hypertension, tachycardia and increased renal resistance. Changes in femoral resistance to these procedures differed between the two strains of miniature swine studied. Stimulation of the peripheral end of either vagus nerve was accompanied by bradycardia without hypotension.     

Regional responsiveness of renal perfusion to activation of the renal nerves

We tested for regional differences in perfusion responses, within the renal medulla and cortex, to renal nerve stimulation in pentobarbital sodium-anesthetized rabbits. Laser-Doppler flux (LDF) was monitored at various depths below the cortical surface (1-15 mm). Basal cortical LDF (1-3 mm, approximately 200-450 U) was greater than medullary LDF (5-15 mm, approximately 70-160 U), but there were no statistically significant differences in basal LDF within these regions. The background LDF signal during aortic occlusion was similar in the cortex (2 mm, 31 U) and outer medulla (7 mm, 31 U), but slightly greater in the inner medulla (12 mm, 44 U). During electrical stimulation of the renal nerves (0.5-8 Hz), cortical LDF and total renal blood flow were similarly progressively reduced with increasing stimulus frequency. Medullary LDF (measured between 5 and 15 mm) was overall less responsive than cortical LDF. For example, 4-Hz stimulation reduced inner medullary LDF (9 mm) by 19 +/- 6% but reduced cortical LDF (1 mm) by 54 +/- 11%. However, medullary LDF responses to nerve stimulation were similar at all depths measured. Our results indicate that while the vascular elements controlling medullary perfusion are less sensitive to the effects of electrical stimulation of the renal nerves than are those controlling cortical perfusion, sensitivity within these vascular territories appears to be relatively homogeneous.     

Early postischaemic renal fibrin deposition and reduction of glomerular filtration rate in the rat: effect of the defibrinating agent Arwin

The correlation between the extent of intrarenal fibrin deposition induced by 15, 20 and 30-min bilateral occlusion of the renal arteries and the reduction of glomerular filtration rate (GFR) has been studied. The tissue level of fibrin was estimated by 125I-labelled human fibrinogen. There was a significant negative correlation between cortical and medullary fibrin content and GFR. In rats pretreatment with the defibrinating agent Arwin failed to prevent postischaemic coagulation in the kidney and the reduction of GFR.     

Role of prostaglandins in the cortical distribution of renal blood flow following reductions in renal perfusion pressure

The purpose of this study was to examine the role of prostaglandins in the redistribution of renal cortical blood flow that occurs following reductions in renal perfusion pressure. The distribution of blood flow to the renal cortex was examined using radio-labeled microspheres (15 +/- 1 micron). It was found that in animals not treated with a prostaglandin synthesis inhibitor a decrease in renal perfusion pressure to the limit of renal blood flow autoregulation was associated with a decrease in fractional flow to the outer cortex (Zone I) and an increase in fractional flow to the inner cortex (Zones III and IV). A further decrease in renal perfusion pressure below the limit of autoregulation produced a further decrease in the fractional flow to Zone I and a further increase in fractional flow to Zones III and IV. In contrast, in animals treated with the prostaglandin synthesis inhibitor meclofenamate (5 mg/kg, i.v. bolus) a reduction in renal perfusion pressure to the limit of renal blood flow autoregulation produced no change in fractional blood flow to any of the 4 cortical zones. A further decrease in renal perfusion pressure, however, did produce a fall in fractional blood flow to Zone I and an increase in fractional flow to Zones III and IV. In conclusion, the results of this study indicate that within, but not below, the limit of renal blood flow autoregulation prostaglandin synthesis is an important factor in the regulation of renal cortical blood flow distribution.     

Angiotensin II receptors in the kidney

Angiotensin II (AngII) receptors have been localized in rat kidney by using the high-affinity agonist analog 125I-labeled [Sar1]AngII as a probe for in vitro autoradiography. Receptors were associated with four morphologically distinct patterns of distribution. First, a high density of receptors occurs in glomeruli. These are diffusely distributed, consistent with a mesangial localization. AngII receptor density shows a cortical gradient, which is highest in superficial and midcortical glomeruli and lowest in juxtamedullary glomeruli. Receptors associated with both superficial and deep glomeruli show down-regulation during low-sodium intake. Second, low levels of tubular AngII binding were seen in the outer cortex. Third, a very high density of AngII receptors occurs in longitudinal bands in the inner zone of the outer medulla in association with vasa recta bundles. Receptors in this site also show down-regulation during low dietary sodium intake. Fourth, a moderate density of receptors occurs diffusely throughout the inner zone of the outer medulla in the interbundle areas. These results suggest that AngII exerts a number of different intrarenal regulatory actions. In addition to the known vascular, glomerular, and proximal tubular effects of AngII, these findings focus attention on possible actions of AngII in the renal medulla where it could regulate medullary blood flow and thereby modify the function of the countercurrent concentrating system.     

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.     

Role of prostagalandins in the cortical distribution of renal blood flow following reductions in renal perfusion pressure

The purpose of this study was to examine the role of prostaglandins in the redistribution of renal cortical blood flow that occurs following reductions in renal perfusion pressure. The distribution of blood flow to the renal cortex was examined using radio-labeled microspheres (15 ± 1 μm). It was found that in animals not treated with a prostaglandin synthesis inhibition a decrease in renal perfusion pressure to the limit of renal blood flow autoregulation was associated with a decrease in fractional flow to the outer cortex (Zone I) and an increase in fractional flow to the inner cortex (Zones III and IV). A further decrease in renal perfusion pressure below the limit of autoregulation produced a further decrease in the fractional flow to Zone I and a further increase in fractional flow to Zones III and IV. In contrast, in animals treated with the prostaglandin synthesis inhibitor meclofenamate (5 mg/kg, i.v. bolus) a reduction in renal perfusion pressure to the limit of renal blood flow autoregulation produced no change in fractional blood flow to any of the 4 cortical zones. A further decrease in renal perfusion pressure, however, did produce a fall in fractional blood flow to Zone I and an increase in fractional flow to Zones III and IV. In conclusion, the results of this study indicate that within, but not below, the limit of renal blood flow autoregulation prostaglandin synthesis is an important factor in the regulation of renal cortical blood flow distribution.     

Renal blood flow distribution during steady-state exercise and exhaustion in conscious dogs.

To determine whether renal blood flow is reduced or redistributed during exercise, we measured total renal flow (TRF) and intrarenal flow distribution (IRFD) in nine dogs. They ran on a motor-driven treadmill at 3-8 mph at grades of 8-15% for an average of 35 min. We measured aortic pressure, heart rate, stroke volume, and cardiac output (CO) via chronically implanted catheters and an electromagnetic flow probe. We injected 15-mum radiolabeled microspheres (85Sr, 141Ce, and 51Cr) via a left atrial catheter during resting control, steady state (SS) and exhaustive (EE) exercise; measured their distribution by gamma spectrometry; and determined TRF as % CO and as ml/100 g per min. We determined IRFD for the outer and inner cortex and the outer medulla. TRF as %CO dropped (P less than 0.05) during both levels of exercise: from 10.2 +/- 0.7% to 3.9 +/- 0.4% (SS) and 3.4 +/- 0.6% (EE). TRF in ml/100 g per min did not change significantly from control (228 +/- 30 ml/100 g per min). IRFD was unchanged with exercise, remaining at about 80, 20, and 3% of TRF for the outer and inner cortex and outer medulla, respectively. We conclude that blood flow is not diverted from the kidneys during severe exercise in the dog.     

The effect of PGI2 on canine renal function and hemodynamics

The effect of prostaglandin I₂ (prostacyclin) on renal and intrarenal hemodynamics and function was studied in mongrel dogs to elucidate the role of this novel prostaglandin in renal physiology. Starting at a dose of 10^?8 g/kg/min, PGI₂ decreased renal vascular resistance and redistributed the blood flow away from the outer cortex (zone 1) and towards the juxtamedullary cortex (zone 4). At 3 × 10^?8 g/kg/min, the renal vascular resistance decreased even further, but at this dose the mean arterial blood pressure also declined 13% indicating recirculation of this prostaglandin. PGI₂ infusion at a vasodilatory dose resulted in natriuresis and kaliuresis. With a decline in filtration fraction, these changes were most likely secondary to the hemodynamic effects of this prostaglandin. Unlike PGE₂, PGI₂ had no direct effect on free water clearance indicating lack of activity at the collecting duct. PGI₂ may be the important renal prostaglandin involved in modulating renal vascular resistance and intrarenal hemodynamics as well as influencing systemic blood pressure.