Relation of distal tubular NaCl delivery and glomerular hydrostatic pressure

Longitudinal study of living kidney donor glomerular dynamics after nephrectomy

BACKGROUND

Over 5,000 living kidney donor nephrectomies are performed annually in the US. While the physiological changes that occur early after nephrectomy are well documented, less is known about the long-term glomerular dynamics in living donors.

METHODS

We enrolled 21 adult living kidney donors to undergo detailed long-term clinical, physiological, and radiological evaluation pre-, early post- (median, 0.8 years), and late post- (median, 6.3 years) donation. A morphometric analysis of glomeruli obtained during nephrectomy was performed in 19 subjects.

RESULTS

Donors showed parallel increases in single-kidney renal plasma flow (RPF), renocortical volume, and glomerular filtration rate (GFR) early after the procedure, and these changes were sustained through to the late post-donation period. We used mathematical modeling to estimate the glomerular ultrafiltration coefficient (Kf), which also increased early and then remained constant through the late post-donation study. Assuming that the filtration surface area (and hence, Kf) increased in proportion to renocortical volume after donation, we calculated that the 40% elevation in the single-kidney GFR observed after donation could be attributed exclusively to an increase in the Kf. The prevalence of hypertension in donors increased from 14% in the early post-donation period to 57% in the late post-donation period. No subjects exhibited elevated levels of albuminuria.

CONCLUSIONS

Adaptive hyperfiltration after donor nephrectomy is attributable to hyperperfusion and hypertrophy of the remaining glomeruli. Our findings point away from the development of glomerular hypertension following kidney donation.

TRIAL REGISTRATION

Not applicable. FUNDING. NIH (R01DK064697 and K23DK087937); Astellas Pharma US; the John M. Sobrato Foundation; the Satellite Extramural Grant Foundation; and the American Society of Nephrology.

Mechanisms of glomerular immune injury: effects of antioxidant treatment

Significant glomerular vasoconstriction and production of reactive oxygen species has been known to occur with exposure to anti-glomerular basement membrane antibody (AGBM-Ab) in the rat model. Previously published studies have demonstrated that such effects can be reduced by therapy with phentolamine, an alpha-adrenergic antagonist. It was hypothesized that antioxidant pretreatment with water-soluble probucol would improve glomerular hemodynamics 60 to 90 min after the administration of AGBM-Ab. These relationships were examined with both in vivo renal micropuncture and in vitro studies in rats. Single-nephron GFR (SNGFR) decreased markedly in untreated rats after AGBM-Ab as a result of afferent and efferent arteriolar vasoconstriction with consequent reductions in nephron plasma flow (SNPF) and decreases in the glomerular ultrafiltration coefficient (LpA). Basal SNGFR was increased, and SNGFR was significantly higher after AGBM-Ab in probucol-treated versus untreated rats. This finding was due solely to higher values for SNPF and prevention of afferent arteriolar constriction. A reduction in LpA after AGBM-Ab was not prevented by probucol treatment. In vitro analyses of glomeruli revealed reduced myeloperoxidase activity in antioxidant-treated rats. Lipoxygenase activity and leukotriene products, however, were not changed by antioxidant therapy, yet vasoconstriction was prevented. H(2)O(2) generation before and after formyl-methionyl-leucyl-phenylalanine stimulation was significantly reduced before and after AGBM-Ab in glomeruli harvested from rats that were treated with the antioxidant. Antioxidant therapy in this model of AGBM-Ab injury did not prevent reductions in LpA, an index of glomerular membrane damage, but did prevent afferent arteriolar vasoconstriction. Reactive oxygen species generation was reduced by probucol. The specific mechanisms whereby antioxidant therapy ameliorates glomerular hemodynamic effects will be defined in additional studies and is likely to involve either enhanced vasodilator or diminished vasoconstrictor activity.

Glomerular hyperfiltration in experimental diabetes mellitus: potential role of tubular reabsorption

An increase in Na+/glucose cotransport upstream to the macula densa might contribute to the increase in single nephron GFR (SNGFR) in early diabetes mellitus by lowering the signal of the tubuloglomerular feedback, i.e., the luminal Na+, Cl-, and K+ concentration sensed by the macula densa. To examine this issue, micropuncture experiments were performed in nephrons with superficial glomeruli of streptozotocin-induced diabetes mellitus in rats. First, in nondiabetic control rats, ambient early distal tubular concentrations of Na+, Cl-, and K+ were about 21, 20, and 1.2 mM, respectively, suggesting collection sites relatively close to the macula densa. Second, glomerular hyperfiltration in diabetic rats was associated with a reduction in ambient early distal tubular concentrations of Na+, Cl-, and K+ by 20 to 28%, reflecting an increase in fractional reabsorption of these ions up to the early distal tubule. Third, in diabetic rats, early proximal tubular application of phlorizin, an inhibitor of Na+/glucose cotransport, elicited (1) a greater reduction in absolute and fractional reabsorption of Na+, Cl-, and K+ up to the early distal tubule, and (2) a greater increase in early distal tubular concentration of these ions, which was associated with a more pronounced reduction in SNGFR. These findings support the concept that stimulation of tubular Na+/glucose cotransport by reducing the tubuloglomerular feedback signal at the macula densa may contribute to glomerular hyperfiltration in diabetic rats. Glomerular hyperfiltration in diabetic rats serves to compensate for the rise in fractional tubular reabsorption to partly restore the electrolyte load to the distal nephron.

The effect of reducing proximal tubular fluid delivery on the rate of filtration of single nephrons

The rate of delivery of tubular fluid from the proximal tubule (PT) is thought to reset nephron filtration rate (SNGFR). In micropuncture experiments in rats we tested this hypothesis by reducing the efflux from the PT by simultaneously "double collecting" (DC) tubular fluid from the early distal tubule (DT) and from the last convolution of the PT of the same nephrons. SNGFR measured by total collection of tubular fluid was 34 +/- 3 nl/min at the DT and 34 +/- 3 nl/min at the PT (p > 0.97, n = 42). The simultaneous collection from proximal and distal sampling site was performed between these two paired measurements. It yielded an average SNGFR of 40 +/- 3 nl/min (p < 0.02). This may be due to the collection, at the distal site, of the extra amount of inulin stored between distal and proximal pipette, prior to starting the aspiration of tubular fluid. Since this error would decrease in longer collections, the difference in SNGFR between single and double collections was plotted against the duration of collections. In fact it was negatively correlated with the sampling time (p < 0.01), indicating no difference in SNGFRs for collections > 4 minutes. Reduction and complete interruption of the delivery of native proximal tubular fluid to the Macula Densa does not seem to influence the measurement of SNGFR. Filtration rate is not significantly different when measured within few minutes at the DT and PT of the same nephrons.

Proximal tubular stop flow pressure: an index of glomerular capillary pressure?

Central to the assumption that glomerular capillary pressure (Pgc) can be equated with the sum of arterial oncotic pressure (pi art) and the pressure in a blocked proximal tubule ("stop flow" pressure, Psf) is that filtration ceases in the blocked nephron. Should filtration not cease, but continue at a rate equal to tubular reabsorption between the block and the glomerulus, Psf, for a given Pgc, will depend on the distance between block and glomerulus. This would have serious consequences for the interpretation of Psf, particularly in respect to its frequent use in analysis of the tubuloglomerular feedback (TGF) mechanism. Experiments were performed in anaesthetized Wistar rats to examine whether a length dependency of Psf exists and, if so, to what extent this relationship alters during maximal TGF stimulation by loop of Henle perfusion. A length dependency of Psf existed both in the absence and presence of loop flow. The regression coefficients were significantly different from 0 and from each other. Pgc cannot thus be equated with the sum of Psf and pi art. The length dependent error in Psf makes it unsuitable for the quantitative analysis of TGF and glomerular haemodynamics.

Glomerular hemodynamics in cyclosporine nephrotoxicity following uninephrectomy

Experiments were performed to determine the cause of the reduced glomerular filtration rate (GFR) in cyclosporine nephrotoxicity during compensatory renal growth. Sprague-Dawley rats were uninephrectomized and given daily injections of cyclosporine (30 mg/kg, i.m.) or vehicle (olive oil), and studied 7 or 14 days later. In cyclosporine treated rats GFR was lower seven days (1.34 +/- 0.10 vs. 1.68 +/- 0.07 ml/min) and 14 days (1.19 +/- 0.08 vs. 1.58 +/- 0.04, P less than 0.025) following uninephrectomy. Arterial blood pressure, cardiac output and renal blood flow (RBF) were not different in cyclosporine and control rats. Kidney mass increased to the same extent in cyclosporine and control rats. Micropuncture of the glomerular microcirculation in similarly prepared Munich-Wistar rats demonstrated low whole kidney GFR (1.10 +/- 0.07 vs. 1.55 +/- 0.13 ml/min, P less than 0.01), and single nephron GFR (31.07 +/- 2.27 vs. 42.36 +/- 2.47 nl/min, P less than 0.005) in cyclosporine treated rats as compared to controls. Single nephron plasma flow, afferent and efferent arteriolar resistance, the transglomerular hydrostatic pressure gradient, and arterial blood pressure were the same in both groups. The glomerular capillary ultrafiltration coefficient (Kf) was lower in cyclosporine treated rats compared to controls [0.039 +/- 0.002 vs. 0.075 +/- 0.013 nl/(sec.mm Hg), P less than 0.025]. We conclude that in this model of cyclosporine nephrotoxicity the low GFR is caused solely by a reduction in Kf, and that cyclosporine can reduce GFR without causing renal vasoconstriction.

Effects of dietary protein content in streptozotocin-diabetic rats

We evaluated the influence of increased dietary protein intake on glomerular structure and function in Lewis rats made diabetic with streptozotocin. We found that diabetic animals on a 20% or 50% protein diet ate approximately 50% more protein and excreted about 50% more urinary urea nitrogen than did their respective similarly-fed nondiabetic controls. The 50% protein diet was associated with higher glomerular filtration rates (GFR) and renal blood flows (RBF) at two months in both diabetic and control animals compared to their respective controls on the lower protein diet. However, GFR and RBF were not significantly higher in the diabetic animals on the 50% protein diet in the controls on the 20% diet and were slightly, albeit not significantly lower than controls on the 50% diet. Glomerular capillary pressure (PGC) tended to be lower in the diabetic compared to their respective controls, while the high protein diet was associated with higher PGC in diabetic and nondiabetic animals. The PGC in the 50% diabetic rats was not different from the PGC in the nondiabetic rats. Urinary albumin excretion (UAE) rate was greater in the diabetic than in the nondiabetic animals. UAE was greatest in the high protein diabetic animals at six months. Glomerular basement membrane thickness after six months of diabetes was increased essentially equally in both normal and high-protein fed diabetic groups and was largely uninfluenced by diet in the controls. Fractional mesangial volume was increased and relative filtration surface was decreased only in the 50%-protein diet diabetic rats at six months. Thus, high protein diet was associated with increased fractional mesangial volume in diabetic rats, but this could not be explained by increased glomerular capillary flows or pressures. The mechanism of acceleration of mesangial expansion by high protein diet in diabetic animals was not elucidated by these studies.

Measurement of interstitial fluid pressure: comparison of methods

Interstitial fluid pressure (IFP), i.e., the pressure in a saline-filled tube brought into contact with the interstitium, has been measured in cats with two "acute" [micropipettes and wick-in-needle (WIN)] and two chronic (perforated and porous capsules) methods. In a control situation, similar pressures of -1.5 and -1.6 mm Hg were recorded in skin with micropipettes and both types of capsules, respectively, while WIN pressure in subcutis was -1.2 mm Hg. IFP in skeletal muscle was -0.5, -0.5, and -1.1 mm Hg as recorded with micropipettes, WIN, and porous capsules, respectively. During infusion of Ringer's solution, pressures in both types of capsules rose by 4 to 6 mm Hg, while pressure recorded with the acute methods increased by 1 to 1.5 mm Hg only. Two hours after infusion all techniques gave similar pressures. Peritoneal dialysis for 2 hours reduced micropipette and WIN pressures by 3 to 4 mm Hg. Pressure in perforated capsules fell by 10 mm Hg during dialysis and remained low for an additional 2 hours, while porous capsule pressure fell by 7 mm Hg during dialysis but thereafter increased and reached the pressure recorded with micropipettes and WIN 2 hours after ended dialysis. In both overhydration and dehydration, capsules probably react to changes in interstitial fluid colloid osmotic pressure; in overhydration the capsules react also to changes in capillary pressure, resulting in the discrepancy between chronic and acute methods during non-steady-state conditions. In conclusion, acute and chronic methods record similar pressures during steady-state conditions, but the chronic methods are sensitive to changes in vascular pressure and interstitial fluid colloid osmotic pressure and are therefore not suitable for measuring the changes that occur in IFP within a few hours.

Dietary protein suppresses feedback control of glomerular filtration in rats

We have examined the possibility that changes in glomerular filtration rate (GFR) after changes in dietary protein intake may depend on altered function of the tubuloglomerular (TG) feedback system. We studied male Sprague-Dawley rats after dietary pretreatment for 9.6 +/- 3.6 (SD) d with isocaloric diets containing either 6% or 40% casein. We found that GFR in rats fed the high protein diet was 24-29% higher than in rats fed the low protein diet. Simultaneous measurements of single nephron GFR (SNGFR) in the distal tubule were 6.3 nl/min or 21% higher in the rats fed the high protein diet whereas proximally measured SNGFR was not statistically different in the two groups. The higher distally measured SNGFR of rats receiving the high protein diet was associated with a 4.2 nl/min or 50% smaller suppression of SNGFR by TG feedback (-4.3 vs. -8.5 nl/min, P less than 0.001). Loop perfusion experiments demonstrated that in rats fed the high protein diet the TG feedback mechanism was less sensitive than in rats fed the low protein diet. The TG feedback response in rats fed the low protein diet, as assessed by reductions in stop-flow pressure and SNGFR, was half-maximal at flows of 14-15 nl/min. In contrast, the TG feedback response in rats fed the high protein diet was half-maximal at 22-24 nl/min. Maximal suppression of stop-flow pressure and SNGFR and the slope of the TG feedback response to increasing loop flow rates were not different in the two groups. We conclude that the sensing mechanism of the TG feedback system is rendered less responsive by a high protein intake, and that this change permits GFR to increase.

Modulation of renal tubular function by renal interstitium

Rat micropuncture experiments have been performed to investigate the influence of renal interstitial pressure conditions on proximal tubular fluid absorption and on the tubulo-glomerular feedback mechanism. The feedback mechanism works by sensing the distal tubular fluid flow rate at the macula densa segment and adjusting the tonus of the arterioles with resulting changes in blood flow and glomerular filtration rate. It was found that in situations with high hydrostatic and low oncotic pressure within the interstitium like in saline volume expansion and post-nephrectomy situations, proximal tubular fluid absorption and the sensitivity of the tubulo-glomerular feedback control are reduced giving rise to increased urine production without activating the feedback mechanism. In situations with low hydrostatic and high oncotic interstitial pressures like in dehydration, hypotension and hypovolemia proximal fluid absorption and feedback sensitivity is increased, feedback sensitivity even so much that the mechanism is activated to reduce GFR even though the load to the distal portion of the nephron is reduced below normal. In this way renal interstitial pressure-volume conditions can modulate renal function in response to extracellular fluid needs and blood pressure level.

Compensatory hypertrophy of single nephrons following ischemic injury in the rat

In Sprague-Dawley rats, the increase in single nephron glomerular filtration rate (SNGFR) following uninephrectomy is due to an increase in glomerular plasma flow (GPF) along with an increase in the glomerular capillary ultrafiltration coefficient (Kf). Hypertrophy of individual nephrons also occurs when renal mass is reduced by disease or ischemic injury. To characterize the factors determining SNGFR in the minority of nephrons that recover from a severe ischemic insult, rats were studied 4 weeks after 1 hour of complete unilateral renal artery occlusion and the results compared to those obtained in normal rats. Indirect determination of the dynamics of glomerular ultrafiltration along with microangiographic studies indicated that despite a reduction in total renal blood flow in the postischemic kidney, a minority of nephrons were hyperperfused. The increase of GPF in these nephrons along with a significant increase in Kf was responsible for the observed increase in SNGFR.

Kidney pressures after the release of 24 hours of bilateral ureteral ligation in the rat

Kidney function was studied in rats after the release of 24 hours of bilateral ureteral ligation (BUL). After deligation, natriuresis was observed for 1 day while diuresis persisted up to 4 days. The possible defective collecting tubule to reabsorb sodium may improve within 1 day, since the urinary sodium concentration was well below the sham value. During the early phase of deligation, the glomerular filtration rate (GFR) averaged only 15 per cent of the sham value. Heterogeneity of the surface nephrons was apparent. About 17 per cent of the observed surface nephrons had no tubular fluid flow, suggesting possibly that these nephrons may not contribute to the kidney GFR. In the other 83 per cent of the nephrons, the stop-flow pressure, 29.0 mm. Hg, was lower than the sham value, 33.6 mm. Hg, whereas the proximal tubular pressure of 15.1 mm. Hg was significantly above the sham value of 13.2 mm. Hg. Both these factors may have induced a reduction in the effective filtration pressure, from 20.1 to 13.9 mm. Hg, and may have contributed to the reduction in GFR in those functioning nephrons. Four days later, a similar proportion of the surface nephrons still showed a marked reduction in function, whereas others had improved significantly. The proximal tubular pressure, the stop-flow and the effective filtration pressures approached the sham values. These improvements may be associated with an increase in GFR to 42 per cent of the sham value. It is suggested that the prolong suppression of the kidney GFR may not be due to the drastic change in the glomerular capillary pressure of the surface nephrons, at this latter period.

A model study of the tubuloglomerular feedback mechanism: effector site and influence on renal autoregulation

The effector site of the macula densa tubuloglomerular feedback mechanism was determined with a mathematical model of glomerular ultrafiltration. The feedback response was found to be mediated by an increase in the hydraulic resistance of the afferent arteriole, possibly accompanied by a slight decrease in the ultrafiltration coefficient of the glomerular membrane. The contribution of the tubuloglomerular feedback mechanism to the autoregulation of renal blood flow and GFR during increased arterial blood pressure was evaluated with a mathematical model of the kidney. The tubuloglomerular feedback system of the superficial nephron was found to be a less efficient regulator of renal blood flow and GFR than the remainder of the autoregulatory mechanism.

The effect of indomethacin on glomerular capillary pressure and pelvic pressure during ureteral obstruction

The present investigation was undertaken to determine whether elevated glomerular capillary and pelvic pressure resulting from ureteral obstruction could be lowered by injection of indomethacin. In hydropenic rats and rats subjected to saline volume expansion, the mean arterial blood pressure, renal pelvic pressure and proximal tubular free flow and stop-flow pressures were measured during acute ureteral obstruction. Indomethacin was injected intravenously 30 to 45 minutes after obstruction at a renal pelvic pressure of 35 mm. Hg or higher. In the former group of rats the proximal tubular stop-flow pressure decreased by an average of 32 per cent and renal pelvic pressure by 27 per cent on administration of indomethacin, whereas in the volume expanded rats (saline, 2 per cent of body weight) these pressures did not change significantly. These results suggest that the vasodilation consequent to ureteral obstruction in hydropenic animals is caused by prostaglandins release and can be abolished by indomethacin, whereas the vasodilation that results from ureteral obstruction in volume expanded animals may be affected by additional mechanisms.

The glomerulus, passive filter or regulatory organ?

This review summarizes recent evidence that glomerular filtration rate is highly regulated and not merely the passive consequence of uncontrolled renal and non-renal factors. Changes in the rate of nephron plasma flow and, under certain circumstances, the glomerular permeability coefficient are the major determining factors which influence the rate of glomerular ultrafiltration. Recent studies suggest that a variety a hormonal substances, when infused, share the capacity to affect glomerular filtration rate by influencing nephron plasma flow and specifically by decreasing the glomerular permeability coefficient. Angiotensin II appears to be the important "final common pathway" mediating many of these hormonal effects on the glomerular permeability coefficient. Of the hormonal substances examined, only ADH appears to exert an independent effect. Also, in certain normal and altered physiologic states, it has been demonstrated that certain hormonal substances, notably angiotensin II, participate in the active regulation of the rate of glomerular filtration through the capacity to influence and regulate the rate of nephron plasma flow and effect reduction in the glomerular permeability coefficient.

Comparison of directly measured and calculated glomerular capillary pressure in the dog kidney at varying perfusion pressure

To gain access to glomeruli of the dog kidney, an approximately 0.3 mm thick superficial tissue layer was cut off from the convexity of the kidney. The surface was superfused with warm Ringer's. Renal perfusion pressure (PP) was changed by an aortic clamp. The afferent oncotic pressure (pi A) was calculated from arterial plasma protein concentration, the efferent (pi E) from pi A and single nephron filtration fraction. At PP 17 and 13kPa, directly measured GCP was significantly lower than that calculated from stop-flow pressure (SFP + pi A). At PP8kPa, the difference was not significant. Hydraulic pressure differences across the glomerular capillary wall was still significantly different from pi E at PP 17 and 13 kPa. Hence, filtration pressure equilibrium was achieved in the dog kidney only at PP 8kPa.

Autoregulation of superficial nephron function in the alloperfused dog kidney

Isolated dog kidneys were each pump-perfused by another dog during 4 experimental periods at perfusion pressures (PP) of 21, 17, 13, and 8 kPa, resp. (i.e. 160, 130, 94, and 60 mm Hg). At the 3 highest PP values, the total kidney renal blood flow (RBF) and glomerular filtration rate (GFR) were perfectly autoregulated while at the lowest value both values were significantly lowered. No significant difference was observed between the single nephron GFR (SNGFR) of periods 1 and 2; in period 3 (PP = 13 kPa) a lower value was observed (P less than 0.05). Free flow pressure in proximal convolution (FFP), stop-flow pressure (SFP), and peritubular capillary pressure (PCP) were not different in period 2 than in period 1, but were significantly lower in period 3 (P = 0.02--0.05). Effective filtration pressure (EFP) was the highest in period 1, decreasing significantly with decreasing PP. Filtration pressure equilibrium was observed in period 4 at PP 8 kPa. Total blood flow resistance (RT) fell with decreasing PP, the drop being due to a steep decline in afferent resistance (RA). Efferent resistance (RE) increased as PP decreased. Ultrafiltration coefficient (Kf) rose with declining PP both within and outside the autoregulatory range. The results indicate that the lower limit of autoregulation is higher in superficial nephrons than in the whole kidney.

Studies on the tubulo-glomerular feedback system in the rat. The mechanism of reduction in filtration rate with benzolamide

The specific mechanism whereby superficial nephron glomerular filtration rate (sngfr) is reduced after the administration of benzolamide, a carbonic anhydrase inhibitor with a primary inhibitory effect in the proximal tubule, have been examined by measuring pertinent pressures, flows, and glomerular permeabilities in the hydropenic Munich-Wistar rat, a strain with surface glomeruli. Because benzolamide decreases absolute proximal reabsorptive rate, the rate of delivery of tubular fluid to the distal nephron should be at least transiently increased and may reduce sngfr by activating the tubulo-glomerular feedback system. Sngfr fell from 29.2+/2.0 to 2.1+/3.1 nl/min (P less than 0.01) after benzolamide (group 1), a percentage reduction equal to kidney glomerular filtration rate and similar to sngfr obtained in collections from distal tubules. Separate studies (group 2) revealed that if transient increases in distal nephron delivery were prevented by insertion of a long oil block in proximal tubules before control, the decrease in sngfr was prevented (30.3+/1.0 vs. 30.3+/1.8 nl/min, P greater than 0.9). In paired "unblocked" nephrons in the same rats, sngfr fell in group 2 (33.0+/1.0 vs. 25.2+/2.3 nl/min, P less than 0.01). In "blocked" nephrons in which sngfr reduction was prevented, the rate of fluid leaving the proximal tubule increased from 16.9+/ to 23.1+/1.0 nl/min (P less than 0.01). In group 1 studies in which sngfr fell and transient increases in flow out of the last segment of the proximal tubule (distal delivery) (approximately equal to 8 nl/min) were not prevented, steady-state distal delivery was unchanged by benzolamide (13.9+/1.1 vs. 14.2+/2.2 nl/min). Also, sngfr returned toward control, pre-benzolamide values, when a proximal oil block was placed for 15 min and the rate of distal delivery reduced after benzolamide administration, which suggests that this activation was reversible. These data suggest that activation of tubulo-glomerular feedback by transient increases in distal delivery was responsible for decreases in sngfr. Analysis of all determinants of glomerular ultra-filtration revealed that the efferent mechanism leading to reduced sngfr after benzolamide was decreased nephron plasma flow (101+/13 vs. 66+/13 nl/min, P less than 0.01). Hydrostatic pressure and the glomerular permeability coefficient did not contribute to reductions in sngfr with benzolamide. Because the rate of distal delivery remained constant in spite of large changes in both sngfr and absolute proximal reabsorptive rate, it is suggested that the rate of distal delivery may be the physiologic entity that is regulated by the tubulo-glomerular feedback system via alterations in sngfr.

Renal micropuncture study of normotensive and Milan hypertensive rats before and after development of hypertension

Earlier studies of renal transplantation and of sodium metabolism indicated that the cause of high blood pressure in the Milan strain of genetically hypertensive rats (MHS) was altered renal function. To pinpoint the active factors, we used micropuncture to study several indices of renal function in normal (NR) and MHS rats at three different ages: A) 26 to 30 days, before development of hypertension (pre-MHS); B) 35 to 40 days; and C) 75 to 90 days, after the development of hypertension. The indices studied and the important differences found between the two strains were: 1) Single nephron filtration rate (SNFR) and late proximal tubular fluid delivery to the distal nephron (LPF). In group A, the pre-MHS rats had significantly lower values than did the NR (SNFR = 6.3 +/- 0.8 nl/min [MHS] vs. 8.3 +/- 1.2 [NR], P less than 0.01; LPF = 3.14 +/- 0.25 nl/min [MHS] vs. 4.1 +/- 0.35 [NR], p less than 0.05). In group C, the values in the MHS rats were significantly higher than those of the NR (SNFR = 17.3 +/- 1.4 nl/min [MHS] vs. 12.1 +/- 0.8 [NR], P less than 0.05; LPF - 7.4 +/- 0.5 nl/min [MHS] vs. 5.3 +/- 0.3 [NR], P less than 0.01). 2) Number of glomeruli. In group C only, the MHS rats had significantly fewer than did the NR rats (MHS = 55, 253 +/- 2,821 vs. NR = 64,527 +/- 2,900, P less than 0.05). 3) Glomerular filtration rate (GFR) and SNFR as a function of the mean blood pressure (MAP). In group A, the GFR of the MHS rats was lower than that of the NR rats (GFR = 0.38 +/- 0.03 ml/min . 100 g of body wt [MHS], 0.50 +/- 0.03 [NR] P less than 0.05). In group C, there was no longer any significant difference. At equal MAP, SNFR was equal in all the groups, except group A, where SNFR was significantly lower in MHS. 4) Pressure differences: Glomerular capillary pressure (gP). GP was significantly higher in MHS rats than in NR rats (group A, + 5.2 mm Hg; group C, + 6.7 mm Hg). In the pre-MHS rats, anesthesia significantly increased (P less than 0.001) the blood pressure difference between the two strains. This effect was not seen in the adult MHS rats. This may increase the differences in GP between pre-MHS and NR. 5) Afferent effective filtration pressure (EFPA). EFPA values were also higher in MHS rats (+ 2.9 mm Hg in group A, + 6.8 mm Hg in group C), but once again the effects of anesthesia probably account for the differences in magnitude seen between pre-MHS and NR. Only 22% of the absolute differences in systemic arterial pressure in the adult MHS and NR rats was transmitted to the glomerular capillary, while 33% of the difference was transmitted in the younger rats. These values suggest a reduced glomerular hydraulic conductivity, even though other explanations could not be excluded, and they are consistent with the hypothesis that the primary cause of development of hypertension in the MHS rats may be a decrease in SNFR.

Capillary pressure in deep and superficial glomeruli of the rat kidney

A new technique has been developed to make deep renal cortical structures in rats accessible for micropuncture: The left kidney is dissected free and immobilized in a lucite cup. A lense-shaped slice, 1--2 mm thick and about 5 x 5 mm wide, is cut off from the dorsal aspect of the kidney. Blood oozing from the cut surface is removed by flushing with saline and suction by microsponges. The bleeding stops in 1--3 min and causes none or only transient fall in arterial pressure (PA). Up to 40 glomeruli become visible and remain circulated for several hours, as shown by injection of dye or silicone rubber. Glomerular capillary pressures (PG), measured with servocontrolled counter pressure (Wiederhielm), showed no consistent change with time and no correlation to PA. Average PG +/- S.E. in mmHg (number of glomeruli in parentheses) were: Wistar rats (WR), Inactin anesthesia, 57.8 +/- 1.4 (41), Membumal anesthesia, 58.1 +/- 1.3 (13). Sprague Dawley rats, Inactin, 58.1 +/- 1.7 (14). In WR, PG was lower in deep than in midcortical glomeruli: less than or equal to 0.4 mm below kidney surface, 57.9 +/- 1.8 (20); 0.5--0.9 mm: 60.5 +/- 1.5 (20) and greater than or equal to 1.0 mm: 53.8 +/- 2.5 (13). Pressure in Bowman's capsule: 11.2 +/- 0.6 (30). The observed PG is higher than previously reported on the Munich mutant strain of WR, and suggests that glomerular filtration equilibrium is not reached.

Single nephron filtration, luminal flow and tubular fluid reabsorption along the proximal convolution and the pars recta of the rat kidney as influenced by luminal pressure changes

Intratubular pressures were measured in free flow and after blockade of tubular flow at different distances from the glomerulum in the kidney of Wistar rats. Free flow pressure was ffp = 13.3 +/- 2.5 Torr and stop flow pressure sfp = 41.7 +/- 3.8 Torr. With increasing distance of the blockade from the glomerulum the intratubular pressure decreased being 22.4 +/- 2.1 Torr, when the tubule was blocked at the end of the pars recta. In a second series single nephron filtration rate (gfr) and late proximal flow rates (V) were measured at different intratubular pressures. Free flow gfrf was 26.5 +/- 5.9 nl/min and Vf = 14.7 +/- 4.0 nl/min. The difference of these flow rates divided by tubular length results in a local reabsorption rate of C = 2.9 +/- 0.9 nl/min-mm in the proximal convolution. In the pars recta local reabsorbtion rate was 1.0 +/- 0.3 nl/min-mm. In the proximal convolution C increased with increasing intratubular pressure: deltaC/deltaitp = (2.7 +/- 1.2)-10(-2) nl/min-mm-Torr. Filtration was in disequilibrium in these animals under all conditions examined, hydraulic filtration conductance was K = 1.2 +/- 0.4 nl/min-Torr. Modified methods have been used for intratubular pressure and for flow rate measurements in order to reduce experimental procedure. It is shown, that fractional reabsorption, calculated on the basis of pressure measurements, is a good approximation to results usually obtained by inulin measurements.

Distal Tubule [Na+] and juxtaglomerular apparatus Renin activity in uranyl nitrate induced acute renal failure in the rat. An evaluation of the role of tubuloglomerular feedback

It has been previously demonstrated that single neophron filtration rate, whole kidney glomerular filtration rate and total renal blood flow decreased by 30-35% 6 h after uranyl nitrate induced acute renal failure in the rat. In order to evaluate a role of the renin-angiotensin system in the initiating phase (0-6 h) of this model of acute renal failure determinations of plasma renin activity, superficial (S) and deep (D) juxtaglomerular apparatus (JGA) renin activity and distal nephron [Na+] were obtained. Plasma renin activity increased from the control value of 1.5 +/- 0.3 (S.E.M.) to 2.9 +/- 0.4 ng/ml/h (P less than 0.005) at 6 h. Mean renin activity in S- and D-JGA's of control rats was 6.99 +/- 0.41 and 2.67 +/- 0.21 ng/JGA/h, respectively. After uranyl nitrate, renin activity in S-JGA's increased to 13.62 +/- 0.80 ng/JGA/h (P less than 0.001) at 2 h and remained elevated, 12.56 +/- 0.90 and 12.75 +/- 0.87 ng/JGA/h at 4 and 6 h. D-JGA renin activity increased (P less than 0.05) to 7.04 +/- 0.53, 6.23 +/- 0.31 and 3.44 +/- 0.33 ng/JGA/h at 2, 4 and 6 h after uranyl nitrate. Distal tubule [Na+], 27 samples in 6 rats, increased from a mean control value of 53.7 +/- 1.2 mEq/l to 116.9 +/- 2.5 mEq/l, 24 samples in 6 rats (P less than 0.001). Prompt increases in JGA renin activity were observed in the initiating phase of acute renal failure, suggesting a role for the renin-angiotensin system in the pathophysiology of this nephrotoxic model. The association of increased JGA renin activity and increased distal [Na+] is consistent with a role for the tubuloglomerular feedback mechanism in the initiating phase of uranyl nitrate induced acute renal failure in the rat.

Role of the efferent arteriole in glomerular hemodynamics of superficial nephrons

Hemodynamic pressure in glomerular capillaries (GCP) and in first order peritubular capillaries (EAP) in superficial nephrons of mutant Wistar rats with surface glomeruli was measured by micropuncture with a servo-nulling device in the following conditions: 1) control;2) norepinephrine infusion (NE); 3) epinephrine infusion (E): 4) dopamine infusion (D); 5) hemorrhagic hypotension (HH); 6) HH + NE; 7) HH + E; 8) HH + D; 9) acute hypertension secondary to bilateral cervical vagotomy and occlusion of both common carotid arteries. BP was also recorded. Both GCP/BP and EAP/GCP ratios averaged 0.40 in control conditions, but only the EAP/GCP ratio remained constant in all conditions under study, indicating that approximately 60% of the hydrostatic pressure in glomerular capillaries is constantly dissipated by the efferent arteriole. When all values of EAP were plotted against the respective values of GCP, a liner relationship was detected (r=0.843). These results indicate that changes of pressure in the first order peritubular capillaries of superficial nephrons are merely secondary to changes in glomerular capillary pressure.

Angiotensin II effects upon the glomerular microcirculation and ultrafiltration coefficient of the rat

The effects of both synthetic and biologically produced angiotensin II (AII) upon the process of glolerular filtration were examined in the plasma-expanded (2.5% body wt) Munich-Wistar rat, by micropuncture evaluation of pressures, nephron plasma flow (rpf) and filtration rate (sngfr). Plasma expansion was chosen as a control condition because (a) response to AII was uniform and predictable, (b) endogenous generation of AII was presumably suppressed, and (c) the high control values for rpf permitted accurate determination of values for the glomerular permeability coefficient (LpA) before and during AII infusion. With subpressor quantities of synthetic Asn-1, Val-5 AII (less than 5 ng/100 g body wt/min), sngfr fell from 47.7 in the control group to 39.8 nl/min/g kidney (P less than 0.005). The rpf fell to 60% of control values (P less than 0.001). Measurement of glomerular capillary (PG) and Bowman's space (Pt) hydrostatic pressures in surface glomeruli with a servo-nulling device permitted evaluation of the hydrostatic pressure gradient (deltaP = PG - Pi). DeltaP increased from 38.1 +/- 1.2 in control to 45.9 +/- 1.3 mm Hg after Asn-1, Val-5 AII and essentially neutralized the effect of decreased rpf in sngfr. The sngfr then fell as a result of a decreased in LpA from 0.063 +/- 0.008 in control to 0.028 +/- 0.004 nl/s/g kidney/mm Hg after Asn-1, Val-5 AII (P less than 0.02). Lower doses of Asp-1, Ile-5 AII (less than 3 ng/100 g body wt/min) had no effect on sngfr, rpf, deltaP, and afferent and efferent vascular resistance, but significantly elevated systemic blood pressure, suggesting peripheral effects on smooth muscle at this low dose. LpA was 0.044 +/- 0.007 nl/s/g kidney/mm Hg after low-dose Asp-1, Ile-5 AII, and 0.063 +/- 0.008 in the control group (0.02 greater than P greater than 0.1). Higher, equally pressor doses of native AII (5 ng/100 g body wt/min) produced effects almost identical to similar quantites of synthetic Asn-1, Val-5 AII upon rpf, deltaP, sngfr, and renal vascular resistance. LpA again fell to 0.026 +/- 0.004 nl/s/g kidney/mn Hg, a value almost identical to that after the synthetic AII. Paired studies with Asp-1, Ile-5 AII also demonstrated a consistent reduction in LpA.

Glomerular filtration response to elevated ureteral pressure in both the hydropenic and the plasma-expanded rat

The factors affecting glomerular ultrafiltration with elevated ureteral pressure were examined in both plasma-expanded (2.5% body weight) and hydropenic Munich-Wistar rats. Elevated ureteral pressure (20 mm Hg) alternated as the initial condition in both groups. Glomerular capillary hydrostatic pressure (PG) and Bowman's space pressure (Pt) were measured directly in surface glomeruli with a servonulling device (deltaP = PG - PT), systemic (piA) and efferent (piE) peritubular capillary oncotic pressures were estimated by microprotein methods, and single-nephron glomerular filtration rates (sngfr) were determined by micropuncture techniques under control ureteral pressure and after increased ureteral pressure in both experimental groups. All data were then applied to equations describing the process of glomerular ultrafiltration to define the profile of effective filtration pressure (EFP = deltaP - pi) and the glomerular permeability coefficient (LpA), where sngfr = LpA-EFP. In plasma-expanded rats, sngfr fell from 44.8 +/- 2.2 to 38.5 +/- 1.5 nilters/min g-1 kidney weight (P less than 0.025) with elevated ureteral pressure entirely as a result of a decrease in the hydrostatic pressure gradient (deltaP), since PG did not rise and nephron plasma flow remained constant. In hydropenic rats, sngfr fell from 34.7 +/- 1.6 to 27.3 +/- 1.6 nliters/min g-1 kidney weight with increased ureteral pressure. PG rose 8.7 mm Hg (P less than 0.001) due to an increase in vascular resistance between the peritubular capillaries and the renal vein which prevented the reduction in deltaP. The reduction in sngfr appeared to result from a reduction in LpA resulting in disequilibration of EFP. Nephron plasma flow was not changed. The filtration response to elevated ureteral pressure was modified by the prior state of volume expansion and was not associated with changes in either nephron blood flow or afferent arteriolar resistance.

Kinetics of the glomerular ultrafiltration in the rat kidney. An experimental study

The quantitative relation between the driving forces over the glomerular membrane and the glomerular plasma flow, on the one hand, and the single glomerular filtration rate (SNGFR), on the other, is still uncertain. Micropuncture measurements on Sprague-Dawley rats made it possible to calculate the net driving force over the glomerular membrane. The single glomerular plasma flow was determined from SNGFR and the single nephron filtration fraction (SNFF). The effective plasma flow was measured with PAH for total kidney and for superficial nephrons. The mean glomerular capillary pressure was found to be 62.6 mm Hg. The results indicate a net driving force of about 13 mm Hg at the distal end of the glomerular capillary. SNGFR was found to be 14.1 nl/min-100 g. SNFF amounted to about 0.27. The filtration fractions determined with the PAH method were in the same range. The results indicate a filtration disequilibrium, in contrast to those of Brenner et al. from measurements on a mutant Wistar rat strain. The filtration fractions seemed to be the same in all glomerular populations. It is clear that the SNGFR is pressure dependent. Our earlier findings of a nonautoregulation of the blood flow through the outer glomeruli were also confirmed.

Tubuloglomerular feedback in rat kidneys of different renin contents

Variations in flow rate through the loop of Henle in the range of 0--50 nl/min were induced using pressure controlled microperfusion. Simultaneously, with the aid of a second pressure-microperfusionsystem, the glomerular function of the same nephron was studied by continuous measurement of two parameters, early proximal flow rate (EPFR) and/or stop flow pressure (SFP). Elevation of loop perfusion above physiological values (40 nl/min) resulted in a drop of EPFR and SFP, whereas lowering perfusion rates had no effect. This feedback behaviour was studied in kidneys with different renin contents to test the role of the renin-angiotensin system in the mediation of the macula densa signal to the adjacent glomerular vessels. Renal renin content, measured after micropuncture experiments by incubation with substrate followed by radioimmunoassay of angiotensin I, was unaltered in control (Ia) and heminephrectomized rats (Ib), lowered in contralateral kidneys of 2 kidneys Goldblatt hypertensive rats (IIa), in DOCA- and salt-loaded rats (IIb), and in DOCA-, salt-loaded and heminephrectomized rats (IIc), and it was evaluated in clipped kidneys of Goldblatt hypertension rats (IIIa). Micropuncture evaluation of the tubuloglomerular feedback behaviour in these experimental groups revealed the following results: 1. a feedback response under all conditions independent of the widely varying renin contents (1000-fold), 2. an asymmetrical behaviour of the feedback response in all kidneys as demonstrated by suppression of EPFR and SFP at elevated loop flow rates, but no change of these parameters when loop flow was interrupted. 3. compared to controls the decrease of each GFR parameter between 0 and 40 nl/min loop perfusion was lower in DOCA- and salt-loaded rats (IIb, IIc). Additional heminephrectomy (IIc) had no further influence on the reduced feedback response in DOCA- and salt-loaded rats, whereas this maneuver reduced the renal renin content drastically. A somewhat higher response than in controls was found in heminephrectomized rats (IIb) and in clipped kidneys of Goldblatt hypertensive rats (IIIa). These different magnitudes of feedback responses do not correlate with the renal renin content. It has been concluded, therefore, that renal renin activity is not the sole determinant of the effectiveness of the tubuloglomerular feedback response.

3H-inulin and electrolyte concentrations in Bowman's capsule in rat kidney. Comparison with artificial ultrafiltration

Micropuncture experiments were performed on Bowman's capsules in male and female non-diuretic Munich rats. 55 samples were collected and analysed for Na, Cl, K, Ca, P, Mg and 3H-inulin contents. Their electrolyte concentrations were compared to the corresponding concentrations obtained from plasma artificial ultrafiltrates. Compared to normal Wistar rats, our Munich rats had several special characteristics: high arterial pressure (115-155 mm Hg), high concentrating ability (phi equals 2684 mOsm/1) and high NaCl reabsorption capacity. Whole kidney GFR was low in males (0.361 ml/min/kidney/100 g B.W.). 3H-Inulin concentration was the same in plasma and glomerular ultrafiltrates (GF). The corresponding ratio (GF/P) in equals 1.03 plus or minus 0.01 (N equals 55) confirmed the lack of sieving effect for inulin. GF electrolyte concentrations were, for Na, Cl, K, Ca, P, Mg respectively 139 plus or minus 0.05, 1.46 plus or minus 0.07 and 0.52 plus or minus 0.04 ml/1 (N equals 23) in females and 141 plus or minus 2, 120 plus or minus 2, 3.84 plus or minus 0.07, 1.31 plus or minus 0.03, 1.78 plus or minus 0.05 and 0.48 plus or minus 0.01 mM/1 (N equals 32) in males. Comparison of ultrafiltration trough a cuprophan membrane and glomerular ultrafiltration led to the following conclusions: For Na, Cl and P artificial and glomerular ultrafiltration produced identical results. On the other hand, for Ca and to a lesser extent for Mg and K ions, artificial ultrafiltration did not accurately reflect the true glomerular ultrafiltrate composition. The reasons for these differences are discussed below.

The mechanism of acute renal failure after uranyl nitrate

Administration of 25 mg/kg uranyl nitrate (UN) to rats leads to a brief period of polyuria followed by progressive oliguria with death at 5 days. Factors that determine glomerular filtration rate (GFR) were examined in control Munich-Wistar rats (n equals 16) and 2 h after either 15 mg/kg (n equals 8) or 25 mg/kg (n equals 7) of UN (i.v.) utilizing direct measurements of hydrostatic and oncotic pressures and plasma flow. Total kidney GFR was reduced to 47% of control in the low dose group and to 21% in the high dose group. The simultaneous nephron filtration rate (sngfr) was 28.6 plus or minus 0.8 nl/min/g kidney wt in control, 29.1 plus or minus 1.0 in the low dose group, and 18.1 plus or minus 1.2 (P less than 0.001) in the higher dose group. This disparity in UN effect upon GFR and sngfr was due to tubular back-diffusion of solute through damaged epithelia beyond the early proximal tubule as demonstrated by microinjection of inulin and mannitol in the proximal tubule. Inulin "leak" persisted at 6 h after UN when tubular pressure had returned to normal. Comparison of sngfr measured in early vs. late proximal tubule revealed no difference after high dose UN, suggesting no significant leak of inulin from the early proximal tubule, and that the decreased sngfr was due to primary reductions in ultrafiltration. Nephron plasma flow was equal to control at both doses of UN. Also directly measured hydrostatic pressure gradient across the glomerular capillary was not changed. The effective filtration pressure achieved equilibrium in control of animals but became significantly positive at the efferent end of the capillary at both doses of UN and increased. Total glomerular permeability (LpA) was progressively reduced from control (0.089 plus or minus 0.005 nl/s/g kidney wt/mm Hg) at low dose UN (0.047 plus or minus 0.013) and high dose 0.024 plus or minus 0.003 nl/s/g kidney wt/mm Hg). Therefore UN decreases GFR by two mechanisms: (1) tubular damage leading to back-diffusion of solutes and (b) a primary reduction in sngfr due to reduced LpA.

Determinants of glomerular filtration in experimental glomerulonephritis in the rat

Pressures and flows were measured in surface glomerular capillaries, efferent arterioles, and proximal tubules of 22 Wistar rats in the early autologous phase of nephrotoxic serum nephritis (NSN). Linear deposits of rabbit and rat IgG and C3 component of complement were demonstrated in glomerular capillary walls by immunofluorescence microscopy. Light microscopy revealed diffuse proliferative glomerulonephritis, and proteinuria was present. Although whole kidney and single nephron glomerular filtration rate (GFR) in NSN (0.8 plus or minus 0.04 SE2 ml/min and 2 plus or minus 2 nl/min, respectively) remained unchanged from values in 16 weight-matched NORMAL HYDROPENIC control rats (0.8 plus or minus 0.08 and 28 plus or minus 2), important alterations in glomerular dynamics were noted. Mean transcapillary hydraulic pressure difference (deltaP) averaged 41 plus or minus 1 mm Hg in NSN versus 32 plus or minus 1 in controls (P LESS THAN 0.005). Oncotic pressures at the afferent (piA) end of the glomerular capillary were similar in both groups ( 16 mm /g) but increased much less by the efferent end (piE) in NSN (to 29 plus or minus 1 mm Hg) than in controls (33 plus or minus 1, P less than 0.025). Hence, equality between deltaP and piE, denoting filtration pressure equilibrium, obtained in control but not in NSN rats. While glomerular plasma flow rate was slightly higher in NSN (88 plus or minus 8 nl/min) than in controls (76 plus or minus 6, P greater than 0.2), the failure to achieve filtration equilibrium in NSN rats was primarily the consequence of a marked fall in the glomerular capillary ultrafiltration coefficient, Kf, to a mean value of 0.03 nl/(s times mm Hg), considerably lower than that found recently for the normal rat, 0.08 nl/(s times mm Hg). Thus, despite extensive glomerular injury, evidenced morphologically and by the low Kf, GFR remained normal. This maintenance of GFR resulted primarily from increases in deltaP, which tended to increase the net driving force for filtration, and thereby compensate for the reduction in Kf.

A new method for intratubular blockade in micropuncture experiments

Criteria for a reliable blockade of tubular flow are generally discussed and experimental evidence is presented that solid paraffin meets all the necessary criteria in rat kidney tubules when an immobile and tight sealing intratubular blockade is requested. A special microinjection apparatus for the application of paraffin is described. Furthermore, several alternative methods and materials have been tested and have been found to be inferior to solid paraffin.

Effect of mannitol on glomerular ultrafiltration in the hydropenic rat

The effect of mannitol upon glomerular ultrafiltration was examined in hydropenic Munich-Wistar rats. Superficial nephron filtration rate (sngfr) rose from 32.0+/-0.9 nl/min/g kidney wt to 42.0+/-1.6 (P < 0.001) in eight rats. Hydrostatic pressure gradients acting across the glomerular capillary (DeltaP) were measured in glomerular capillaries and Bowman's space with a servo-nulling device, systemic (piA) and efferent arteriolar oncotic pressures (piE) were determined by microprotein analysis. These data were applied to a computer-based mathematical model of glomerular ultrafiltration to determine the profile of effective filtration pressure (EFP = DeltaP - pi) and total glomerular permeability (L(p)A) in both states. Filtration equilibrium obtained in hydropenia (L(p)A >/= 0.099+/-0.006 nl/s/g kidney wt/mm Hg) and sngfr rose because EFP increased from a maximum value of 4.2+/-1.1 to 12.8+/-0.5 mm Hg after mannitol (P <0.01). This increase was due to both increased nephron plasma flow and decreased piA. Computer analysis of these data revealed that more than half (>58%) of this increase was due to decreased piA, consequent to dilution of protein. Since EFP was disequilibrated after mannitol, L(p)A could be calculated accurately (0.065 +/- 0.003 nl/s/g kidney wt/mm Hg) and was significantly lower than the minimum estimate in hydropenia.Therefore, sngfr does increase with mannitol and this increase is not wholly dependent upon an increase in nephron plasma flow since the major factor increasing EFP was decreased piA.

Interference with feedback control of glomerular filtration rate by furosemide, triflocin, and cyanide

Microperfusion experiments have shown that increases in flow rate of tubule fluid through the loop of Henle are followed by reductions in single nephron glomerular filtration rate (SNGFR) and stop-flow pressure (SFP) measured in the proximal tubule of the same nephron. Because changes in luminal sodium concentration are not consistently related to changes in SNGFR and SFP, we explored the possibility that a transport step at a flow-dependent distal-sensing site might be involved in feedback control of SNGFR. Because the macula densa cells of the distal tubule are adjacent to the glomerular vessels of the same nephrons, they could be the distal-sensing mechanism. We perfused superficial loops of Henle from late proximal to early distal segments in three groups of rats while measuring SFP in the proximal tubule of the same nephron, SNGFR in the proximal tubule of the same nephron, or flow rates of fluid, Na, K, and Cl emerging from the perfused loops. Perfusion solutions used were 0.15 NaCl, Ringer or Ringer with one of several inhibitors of electrolyte transport. Perfusion rates were 10 or 40 nl/min (also, zero during measurements of SFP and SNGFR). With Ringer alone the loop-flow rate increased from 10 to 40 nl/min, caused a decrease in SFP from 37.6 to 32.1 mm Hg, and a decrease in SNGFR from 29.9 to 18.7 nl/min. Concentrations of Na, K, and Cl in early distal fluid and absorption of Na and Cl along the loop segment were also increased when loop perfusion rate was increased. Decreasing the perfusion rate to zero had little effect on SFP or SNGFR. The SFP response to increased flow rate did not occur when the perfusion solution contained furosemide (10(-4) M). No reduction of the SFP response was seen with other diuretics tested (amiloride, acetazolamide, ethacrynic acid, mercaptomerin) or with 0.15 M NaCl alone. The SNGFR response to increased perfusion rate was reduced by furosemide, triflocin, and cyanide but not by amiloride. Na and Cl absorption by the perfused segment were inhibited by furosemide, triflocin, cyanide, and amiloride. Amiloride and acetazolamide, probably do not act in the ascending limb. Ethacrynic acid and mercaptomerin are known to be ineffective in rat nephrons. Thus, agents that could have inhibited NaCl absorption by macula densa cells interfered with the feedback mechanism.

Autoregulation of single nephron filtration rate in the presence and the absence of flow to the macula densa

Flow of tubule fluid to the macula densa is part of a proposed feedback loop for autoregulation of glomerular filtration rate. In the present study, autoregulation of single nephron filtration rate was tested in the presence and the absence of flow to the macula densa in the rat. Filtration rates were measured at elevated arterial blood pressures caused by carotid occlusion and vagal section and at reduced renal perfusion pressures caused by partial aortic constriction. Measurements of single nephron filtration rate in the presence and the absence of flow to the macula densa were obtained by complete volume collections from the distal nephron beyond the macula densa and from the proximal tubule, respectively. Mean blood pressure was 130 ± 4 (SE) mm Hg for the initial collections, and renal perfusion pressure was 100 ± 1 mm Hg for the repeat collections (nine rats). Distal single nephron filtration rate was 42 ± 1 nliters/min at elevated perfusion pressure and 41 ± 1 nliters/min at reduced perfusion pressure; proximal single nephron filtration rate was 41 ± 1 nliters/min at elevated perfusion pressure and 41 ± 1 nliters/min at reduced perfusion pressure. Similarly, glomerular filtration rate was 4.6 ± 0.4 ml/min kg -1 body weight and 4.7 ± 0.3 ml/min kg -1 body weight at elevated and reduced perfusion pressures, respectively. Additional studies in seven dogs showed good correlation between autoregulation of single nephrons in the absence of flow to the macula densa and autoregulation of the micropunctured kidney. It is concluded that autoregulation of single nephron filtration rate is unaltered by interruption of tubule fluid flow to the macula densa.