In vitro perfusion of the isolated dog glomerulus

Recent technological advances allowing direct in vivo measurements of the determinants of glomerular ultrafiltration have greatly expanded our understanding of that process. In addition, these in vivo studies have clarified the dynamics of glomerular ultrafiltration in a number of physiologic and pathophysiologic conditions. Despite this progress, important issues remain unresolved and beyond the scrutiny of in vivo techniques. We have therefore devised a technique for in vitro glomerular perfusion of the isolated dog glomerulus. In eight glomeruli perfused at physiologic rates, the glomerular filtration rate averaged 39 nl/min and the filtration fraction was 0.19. Filtration pressure disequilibrium was observed in all studies and thus allowed calculation of a unique value for the ultrafiltration coefficient. That parameter averaged 2.34 nl/(min X mmHg). Morphologic studies employing transmission electron microscopy indicate that isolated perfused glomeruli remain ultrastructurally intact. The method for glomerular isolation and in vitro perfusion is presented in detail, the results obtained are compared with published in vivo results, and the advantages offered by the technique are discussed.

Studies on the mechanism of sodium excretion during drug-induced vasodilatation in the dog

The administration of vasodilating agents such as bradykinin and acetylcholine cause an increase in urinary sodium excretion. Yet the mechanisms involved in this natriuretic effect are not clear. Recent studies with another renal vasodilator, secretin have shown this drug also causes a profound increase in renal blood flow but without major changes in sodium excretion. To attempt to delineate the basis of this difference in sodium excretion with these drugs, the renal functional effects of secretin and bradykinin were compared at an equivalent vasodilating dose. Bradykinin increased renal blood flow from 222 to 342 ml/min, urine volume from 0.2 to 1.2 ml/min, and urine sodium excretion from 28 to 115 mueq/min. Urine osmolality fell from 1,230 to 401 mosmol/kg. Secretin caused a comparable increase in renal blood flow (216 to 325 ml/min) while changes in urine flow, sodium excretion, and urine osmolality were significantly less. In further studies papillary plasma flow was estimated using the albumin accumulation technique. Control papillary plasma flow was 29 ml/min per 100 g. Bradykinin increased urinary sodium excretion 108 mueq/min and decreased urinary osmolality from 1,254 to 516 mosmol/kg in association with a rise in papillary plasma flow to 62 ml/min per 100 g. Urine sodium excretion, urinary osmolality, and urine flow rate, as well as papillary plasma flow rate (32 ml/min per 100 g) were unchanged from control when secretin was administered. Studies with acetylcholine were qualitatively similar to those of bradykinin. Renal blood flow increased from 150 to 248 ml/min, urinary sodium excretion increased from 20 to 243 mueq/min, urinary osmolality decreased from 1,237 to 411 mosmol/kg and papillary plasma flow increased from 39 to 52 ml/min per 100 g. It is suggested that the natriuretic effect of some vasodilators is due, at least in part, to alterations in medullary hemodynamics, as evidenced by the increase in papillary plasma flow seen with bradykinin and acetylcholine, but not secretin.

Methodologic considerations in the study of glomerular ultrafiltration

Over the past decade numerous studies have detailed the dynamics of glomerular ultrafiltration. Observations in a unique strain of Munich-Wistar rats, which afford the direct measurement of intraglomerular capillary hydrostatic pressure, have determined that under normal physiologic conditions these animals are in a state of filtration equilibrium. Both mathematical models based on this observation and experimental evidence indicate that under these circumstances the primary determinant of glomerular filtration rate (GFR) is the rate of glomerular plasma flow. In addition, this state of filtration equilibrium provides a condition in which changes in the product of glomerular surface area and glomerular capillary hydraulic conductivity (ultrafiltration coefficient) have no influence on glomerular filtration rate. Similarly, changes in glomerular hydrostatic pressure have a relatively small influence on GFR. These conclusions represent a marked alteration of the previously held concepts of the determinants of GFR. Unfortunately, studies in other strains of rats and in other animal species, particularly the dog, have led to the conclusion that filtration disequilibrium is the normal physiologic condition. The validity of this conclusion, however, is made uncertain by methodologic necessities that may lead to erroneous physiologic measurements of the determinants of GFR. In the present Editorial Review we examine the data reflecting on the applicability of filtration equilibrium to mammalian species. In addition, we summarize two new in vitro techniques for the further study of the dynamics of glomerular ultrafiltration.

Renal lesions in acute rheumatic fever

In the past 4 years, four patients with acute rheumatic fever and abnormalities of renal function, urinary sediment, or both have undergone percutaneous renal biopsy at this institution. Distinctly different renal lesions were found and included focal glomerulonephritis, classic acute exudative poststreptococcal glomerulonephritis, mesangioproliferative glomerulonephritis, and severe interstitial nephritis. In each case, the clinical abnormalities were transient. In this report we describe the clinical and pathologic findings in each of these patients to stress the variability of renal lesions that may accompany acute rheumatic fever.

Sequential studies on the pathophysiology of glycerol-induced acute renal failure

The role of volume depletion and renal ischemia in the development of renal functional impairment in glycerol-induced ARF is not clear. This study was designed to evaluate the role of volume depletion in this model by determining the hemodynamic and functional alterations which occur between 3 and 18 hr after glycerol administration and the reversibility of these changes in response to Ringer loading. Three hours after glycerol, Cln and RBF, measured by flowmeter, were reduced 70% and 52%, respectively, in comparison with control values. FeNa was 0.04%. Ringer loading increased Clkn to 103% and RBF to 93% of control values. Qualitatively similar results were found 6 hr after glycerol. At 18 hr, Cln and RBF were 47% of control values. After Ringer loading, RBF rose to 100% of control. The response of Cln, however, was a function of the baseline FeNa. Cln incrased substantijally in rats with low FeNa but changed only slightly in animals in which this parameter was increased. These studies indicate that the early reduction in the Cln is dependent upon the fall in RBF. At 12 and 18 hr, however, the fall in Cln is not blood flow-dependent, and a second mechanism must be operative. FeNa seems to be a reliable index of the functional status of a given animal.

Need for faculty members in renal research in clinical departments: report of the Scientific Advisory Board of the National Kidney Foundation

To provide an approximate estimate of the need for academic faculty in renal research, 1200 questionnaires were mailed to most departments in all medical schools in the United States. There were 627 completed questionnaires returned from 99 divisions of nephrology, 79 divisions or departments of urology, and 67 divisions of pediatric nephrology or departments of pediatrics in 120 medical schools. Analysis of the responses revealed that in these three departments there are 1057 faculty members engaged in teaching and research related to the kidney and urinary tract, and 131 current vacancies. The responses suggest that from 1979 to 1984 another 483 faculty members will be required to fill projected vacancies in the foregoing three clinical departments, making the total needed 614.

Questions and replies: role of the collecting tubule in fluid, sodium, and potassium balance

In terms of day-to-day regulation of fluid and electrolyte balance, the collecting tubule system appears to occupy a paramount position among segments of the renal tubule. Controversy has arisen concerning the quantitative contribution by the collecting tubule system to the regulation of individual solute excretion, which in part may be due to differences among the investigative techniques employed. In this Editorial Review, R. L. Jamison summarizes current views on the function of the collecting tubule system, particularly with regard to regulation of sodium and potassium excretion, and then poses seven questions pertaining to this topic. H. Sonnenberg, who has revived the microcatheterization technique, and J. H. Stein, whose group has employed the micropuncture method, respond to these questions. The key issues addressed are: 1) the principal factors that influence transtubular movement of sodium and potassium across the collecting tubule; 2) the limitations and potential artifacts of the microcatheterization and micropuncture techniques when used to examine the function of the collecting tubule; 3) apparent discrepancies among results obtained by micropuncture in vivo, microcatheterization in vivo, and microperfusion in vitro of the collecting tubule; and 4) major unresolved questions concerning the function of the collecting tubule.

Treatment of Goodpasture's syndrome with plasmapheresis. A case report and review of the literature

A case is reported of antiglomerular basement membrane antibody-induced Goodpasture's syndrome in which the patient required hemodialysis and was treated with immunosuppressive agents and plasmapheresis. A severe (80 per cent) cresentic lesion was reversed, and creatinine was stabilized at 2.5 mg/dl at one year follow-up. Earlier reports of therapy without plasmapheresis showed that 88 per cent of the patients would either die or require long-term hemodialysis. Fifteen other reported cases of Goodpasture's syndrome in which the patients were treated with plasmapheresis are reviewed. When reported, short-term follow-up showed that nine of these patients were alive without need of dialysis, five wee receiving dialysis, and only two had died. This suggests that plasmaheresis and immunosuppressive therapy may reverse the renal lesion in some patients with Goodpasture's syndrome.

Study of factors which modify the development of norepinephrine-induced acute renal failure in the dog

Previous studies have demonstrated that the fall in inulin clearance which occurs 3 hours after the intrarenal administration of norepinephrine can be markedly attenuated by the prior administration of intrarenal prostaglandin E2 (PGE). Since in the previous studies PGE led to a marked increase in both renal blood flow and solute excretion, we designed the present series of experiments to investigate whether an increase in renal blood flow, solute excretion, or other factors were responsible for the protective effect in the norepinephrine model. Two renal vasodilators, bradykinin and secretin, were evaluated initially. Bradykinin administration prior to norepinephrine administration had a protective effect similar to that previously found with PGE, whereas secretin did not. Both of these vasocilators increased renal blood flow to the same degree, but only bradykinin increased urine flow and solute excretion. The fall in inulin clearance 3 hours after the administration of norepinephrine was also attenuated by two diuretics (mannitol and furosemide) which tended to increase renal blood flow. In contrast, two natriuretic agents, which are also renal vasoconstrictors (chlorothiazide and benzolamide), had no protective effect. Further, chlorothiazide and benzolamide obviated the protective effect of bradykinin. These studies demonstrate that there are several types of pharmacologic agents which can modify the magnitude of renal functional impairment resulting from extreme renal ischemia. Although the mechanism of the protective effects remain unclear, the findings are compatible with the view that the protective effect noted with PGE, bradykinin, mannitol, and furosemide may be related to an increase in osmolar excretion which occurred with administration of each of these agents. This potentially salutory effect (increased osmolar excretion), however, could be overcome by an agent (e.g., chlorothiazide or benzolamide) which also increased renal resistance prior to the administration of norepinephrine.

Urinary prostaglandin E excretion: effect of chronic alterations in sodium intake and inhibition of prostaglandin synthesis in the rabbit

On the basis of acute experiments in animals, a role for prostaglandin E (PGE) in the regulation of urinary sodium excretion has been suggested. Limited information is available, however, concerning the possible role of PGE in chronic adjustments to sodium intake. These studies were designed to determine whether chronic changes in sodium balance would modify renal PGE excretion and whether partial inhibition of prostaglandin synthesis would alter the ability of the kidney to adjust to an alteration in sodium intake. Thus, we measured sodium and PGE excretion in rabbits on chronic high and low salt diets before and after inhibition of prostaglandin synthesis with indomethacin or meclofenamate. Although the alterations in salt intake resulted in large changes in sodium excretion there was no significant change in urinary PGE excretion. After administration of either indomethacin or meclofenamate for several days there was a significant fall in PGE excretion, but no significant change in sodium excretion. These results suggest that in the rabbit 1) chronic changes in sodium excretion can occur without modifying PGE excretion (and presumably renal PGE synthesis) and 2) inhibition of PGE synthesis does not impair the kidney's ability to adjust to a chronic high or low sodium intake.

Further studies on segmental sodium transport in the rat kidney during expansion of the extracellular fluid volume

The present studies were designed to further investigate the possibility of heterogeneity of nephron function during Ringer loading in the rat, and to determine the specific nephron segment responsible for this finding. As in previous studies from this laboratory with smaller rats (50-125 g), net addition of sodium between late distal tubule and papillary base (6.9 vs. 10.4% of the filtered load, respectively, P <0.005) was found in more mature rats (170-230 g). In contrast, there was net reabsorption of sodium between these two segments in nonvolume-expanded animals, 1.70 vs. 0.45% of the filtered sodium load, P <0.005. Because nephron heterogeneity of sodium transport during extracellular volume expansion is the most likely explanation for these findings, further studies were performed to determine the specific juxtamedullary nephron segment responsible for the net addition pattern between late distal tubule and papillary base in Ringer-loaded animals. First, a comparison was made of sodium delivery to the late proximal tubule of superficial nephrons vs. the delivery rate to the bend of Henle's loop of juxtamedullary nephrons in both hydropenia and Ringer loading. Fractional sodium delivery was quite comparable between the superficial and juxtamedullary nephrons in both hydropenia and Ringer loading although the absolute level was much greater in both groups of nephrons in the Ringer studies. Chlorothiazide (15 mg/kg loading and 15 mg/kg per h) given during Ringer loading markedly increased late distal sodium delivery, 19% of the filtered load, but did not prevent net addition of sodium at the papillary base. In contrast, furosemide (5 mg/kg loading and 5/mg/kg per h) given during Ringer loading completely reversed the segmental pattern, 35.5 and 28.8% at late distal tubule and papillary base, respectively, P <0.005. These studies demonstrate that the net addition of sodium between late distal tubule and papillary base during Ringer loading is not limited to immature rats and that the segmental pattern does not occur in non-volume-expanded animals. Further, the reversal of the net addition pattern with furosemide, but not chlorothiazide, and the comparable proximal nephron delivery rates in Ringer loading suggest that the loop of Henle of juxtamedullary nephrons reabsorbs less sodium than the same portion of superficial nephrons in this setting. A model is proposed to explain this finding.

Current concepts on the pathophysiology of acute renal failure

In the pase decade, several experimental models of acute renal failure (ARF) have been evaluated with micropuncture and hemodynamic techniques. Five of these models have been most extensively studied: glycerol injection, renal artery clamping, intrarenal norepinephrine infusion, uranyl nitrate, and mercuric chloride administration. In the first three models, renal ischemia is the initiating insult, whereas in the two nephrotoxic models a direct effect of the agent on cellular integrity is also seemingly operative. In all of these models, renal blood flow 24--48 h after the initial insult either spontaneously returns to normal or can be elevated to this level with volume expansion but without restoration of the glomerular filtration rate. Therefore, the maintenance of ARF in these various models is due to other factors, which include tubular obstruction, leakage of filtrate across damaged tubular epithelium, and a decrease in the glomerular capillary ultrafiltration coefficient. In a given model, one or all three of these alterations may be present. Although these various models may not be completely analogous to the clinical setting, they have provided powerful tools for the study of ARF and their use has greatly increased our knowledge in this field.

Studies on the mechanism of reduced urinary osmolality after exposure of renal papilla

Studies were performed in Munich-Wistar rats to determine whether changes in papillary plasma flow might be responsible for the concentrating defect which occurs after exposure of the extrarenal papilla. Papillary plasma flow was measured by (125)I-albumin accumulation. Initial studies in hydropenic animals revealed that papillary plasma flow was 40% higher in the kidney with the exposured papilla, 41 vs. 29 ml/min per 100 g of papilla (P < 0.001). This increase in papillary plasma flow was detectable 15 or 45 min after removing the ureter. Because it was unclear whether the rise in papillary plasma flow was a cause or the result of the fall in urine osmolality, similar studies were performed in animals undergoing a water diuresis. In this setting, papillary plasma flow still increased on the exposed side compared to the control side, 81 vs. 60 ml/min per 100 g, despite similarly low urine osmolalities of 155 and 174 mosmol/kg, respectively. This finding is compatible with the possibility that papillary exposure per se causes an increase in papillary plasma flow and that this hemodynamic alteration may lead to a reduction in urinary osmolality secondary to washout of the medullary interstitium. A final group of hydropenic rats was given either indomethacin or meclofenamate before removing the ureter. In these studies, there was no difference in either the papillary plasma flow or the urine osmolality between control and exposed kidneys. It is therefore suggested that opening the ureter induces an increase in papillary plasma flow by some mechanism which may involve an alteration in prostaglandin synthesis.