Importance of alcohol and drug abuse in psychiatric emergencies.

Three cases of acute bilateral renal cortical necrosis, each with a different clinical course, are discussed. One patient spontaneously recovered renal function after prolonged oliguria. This case should be added to the small number of similar case reports in the literature. The second patient recovered adequate renal function temporarily, but eventually required chronic hemodialysis and renal transplantation. There was pathological evidence of progression from focal to massive cortical necrosis. The third patient never regained renal function, but is well after dialysis and transplantation.The influence of modern theories of pathogenesis of the disease, and increased availability of dialysis, are discussed in relation to the initial prognostic assessment of the patient with cortical necrosis.     

The Sequence of Events in the Development of Bilateral Renal Cortical Necrosis Accompanying the Generalized Shwartzman Reaction

The generalized Shwartzman reaction, or Shwartzman-like conditions, were induced in a variety of experimental mammalian species by systemic injections of disintegrated cells of Gram negative bacteria, live Salmonella cholerae-suis or Liquoid. A comparative study of the renal lesions showed that the initial step in the development of bilateral cortical necrosis is stagnation and disintegration of red cells in glomerular capillaries. The glomerular “microthrombi” consist mainly of erythrocytic debris, which frequently has staining properties akin to those of fibrin; even wide-spread glomerular “thrombosis” is not accompanied by obvious destruction of renal parenchyma. A second step is necrotic mural lesions in afferent arteries, with ensuing thrombosis. These vascular lesions lead to the formation of individual infarcts which fuse to form total bilateral cortical necrosis in fulminant cases of the generalized Shwartzman reaction.     

Carbon monoxide poisoning and nonoliguric acute renal failure.

Carbon monoxide poisoning in a 37-year-old man was complicated by neurologic damage, skin changes, muscle necrosis and nonoliguric renal failure. The relation between nontraumatic rhabdomyolysis and acute renal failure in carbon monoxide poisoning is reviewed. Recognition of the acute renal failure in such cases is important, for this complication can be fatal; the prognosis is excellent, however, if proper medical management is provided.     

Hypovolemic models of acute tubular necrosis in the rat kidney.

Studies were undertaken to determine whether a hypotensive episode under variable conditions is capable of inducing experimental acute renal failure in rats. Animals were subjected to hypovolemic shock by withdrawing volumes of blood necessary to maintain a systolic pressure of 30-40 mm Hg for 105-110 min. The blood was then reinfused and the animal was allowed to recover for 48 h prior to sacrifice. In an attempt to increase the injury, a second group of animals was salt-depleted prior to injury, a third group was volume-depleted by being deprived of H2O for 72 h prior of injury, a fourth group received 7.5 mg/kg indomethacin 30 min prior to injury, and a fifth group had 30% of the blood which was removed to produce shock hemolyzed and returned following the injury. In all groups examined, light microscopy revealed a moderate to severe acute tubular necrosis localized mainly in the outer stripe of the outer zone as defined by Peter (1909). Tubular damage was confined to the medullary pars recta of the proximal tubule and only in the most severe cases did injury involve the cortical pars recta and pars convoluta. Casts were present in the distal tubules and collecting ducts. Despite these significant histologic alterations, BUN values from all experimental groups remained within control levels. These studies clearly show that extensive necrosis of the medullary pars recta can be dissociated from the development of acute renal failure.     

Nephrotoxic Lesions from 5-Aminosalicylic Acid

5-Aminosalicylic acid given to rats as a single intravenous injection led to necrosis of the proximal convoluted tubules and of the renal papilla. These two lesions developed at the same time and the cortical lesions did not appear to be a consequence of the renal papillary necrosis. Since the compound possesses the molecular structure both of a phenacetin derivative and of a salicylate these observations may be relevant to the problem of renal damage incident to abuse of analgesic compounds and suggest the possibility that in this syndrome cortical lesions may develop independently of renal papillary necrosis.     

Renal Cortical Lactate Dehydrogenase: A Useful,Accurate, Quantitative Marker of In Vivo Tubular Injury and Acute Renal Failure

Studies of experimental acute kidney injury (AKI) are critically dependent on having precise methods for assessing the extent of tubular cell death. However, the most widely used techniques either provide indirect assessments (e.g., BUN, creatinine), suffer from the need for semi-quantitative grading (renal histology), or reflect the status of residual viable, not the number of lost, renal tubular cells (e.g., NGAL content). Lactate dehydrogenase (LDH) release is a highly reliable test for assessing degrees of in vitro cell death. However, its utility as an in vivo AKI marker has not been defined. Towards this end, CD-1 mice were subjected to graded renal ischemia (0, 15, 22, 30, 40, or 60 min) or to nephrotoxic (glycerol; maleate) AKI. Sham operated mice, or mice with AKI in the absence of acute tubular necrosis (ureteral obstruction; endotoxemia), served as negative controls. Renal cortical LDH or NGAL levels were assayed 2 or 24 hrs later. Ischemic, glycerol, and maleate-induced AKI were each associated with striking, steep, inverse correlations (r, −0.89) between renal injury severity and renal LDH content. With severe AKI, >65% LDH declines were observed. Corresponding prompt plasma and urinary LDH increases were observed. These observations, coupled with the maintenance of normal cortical LDH mRNA levels, indicated the renal LDH efflux, not decreased LDH synthesis, caused the falling cortical LDH levels. Renal LDH content was well maintained with sham surgery, ureteral obstruction or endotoxemic AKI. In contrast to LDH, renal cortical NGAL levels did not correlate with AKI severity. In sum, the above results indicate that renal cortical LDH assay is a highly accurate quantitative technique for gauging the extent of experimental acute ischemic and toxic renal injury. That it avoids the limitations of more traditional AKI markers implies great potential utility in experimental studies that require precise quantitation of tubule cell death.     

Local infusion of urokinase and heparin into renal arteries in impending renal cortical necrosis.

Two patients with presumed impending cortical necrosis, after haemolytic uraemic syndrome in one and after concealed accidental haemorrhage in the other, were treated by local infusion of urokinase and heparin into the renal artery. Both recovered and one regained normal renal function. Local infusion of anticoagulants or thrombolytic drugs into one renal artery offers the possibility of a controlled examination of the efficacy of this treatment in preventing cortical necrosis.     

Acute Paracetamol Poisoning

Of 41 cases of acute paracetamol poisoning one died of gastrointestinal haemorrhage and acute massive necrosis of the liver, three became jaundiced, and 13 others had biochemical evidence of hepatocellular damage. Liver damage is a toxic effect which is present in most patients who ingest more than 15 g. of paracetamol. One patient with liver damage survived renal failure due to acute tubular necrosis. It is suggested that the renal lesion was also the result of paracetamol overdosage.Profound hypoglycaemia and metabolic acidosis may also complicate severe poisoning. Plasma levels of para-aminophenol fall rapidly, and procedures currently used to enhance the elimination of the drug cannot be expected to prevent development of hepatic damage.     

Effects of Large Doses of Colistin Sulphomethate Sodium on Renal Function

High doses of colistin were used in the treatment of severely ill patients with refractory klebsiella chest and urinary tract infections. At the same time renal function was monitored to determine possible nephrotoxicity. In all patients it produced acute renal failure and in some acute tubular necrosis. Though renal failure contributed to the final cause of death in some cases, in the majority death was due to the primary neurological illness.     

Combined use of dopamine and prostaglandin A1 in patients with acute renal failure and hepatorenal syndrome.

Dopamine and prostaglandin A1 were infused intravenously in 4 patients with the hepatorenal syndrome, in 1 patient with acute tubular necrosis, and 1 patient with cortical necrosis. Large doses of prostaglandin A1 decreased arterial blood pressure preventing increase in dosage; in contrast, high doses of dopamine elevated blood pressure. When the two drugs were administered conjointly, much larger doses of each agent could be administered without change in arterial blood pressure. Significant improvement of renal function was not observed in any of these critically ill patients during or within 24 hours after dopamine and prostaglandin A1 administration. This study demonstrated that extremely large doses of these vasodilating agents can be safely administered conjointly.     

Depletion of renal cortical glutathione and nephrotoxicity by cephaloridine,cephalothin and gentamicin in male sprague-dawley rats

Cephaloridine and gentamicin are selectively accumulated in renal cortex and produce necrosis of proximal tubular cells. However, the mechanisms responsible for renal cortical accumulation of these two antibiotics are quite different; therefore the early pathogenetic processes may not be the same. In the present study, effects of two cephalosporins (cephaloridine and cephalothin) and an aminoglycoside (gentamicin) on rat renal cortical glutathione were determined. Cephaloridine produced a dose-related depletion of renal cortical glutathione one hour following a single administration of the drug. In contrast, cephalothin in equivalent doses did not reduce renal cortical glutathione. Gentamicin had no effect on renal cortical glutathione, even when an acutely lethal dose (1000 mg/kg) was used. Pretreatment of rats with diethyl maleate (0.4 ml/kg) markedly depleted renal cortical glutathione and this pretreatment also potentiated cephaloridine nephrotoxicity. These results suggest that glutathione may play a protective role against cephaloridine but not gentamicin nephrotoxicity.     

Hemorrhagic fever with renal syndrome: clinical aspects

Hemorrhagic fever with renal syndrome (HFRS) is an acute viral fever which typically progresses through five stages: an acute grippe, followed by hemorrhage and shock, acute renal insufficiency from tubulo-interstitial nephritis, and recovery. Death from circulatory or renal failure occurs in 5%-15% of cases. In mild or abortive forms of the disease, associated with viral strains enzootic in Scandinavia the illness is milder. Hemorrhage and shock occur with lower frequency and the fatality rate is less than 1%. Pathologic examination of HFRS cases from Asia discloses generalized congestion, hyperemia, and hemorrhage, with scattered foci of necrosis in numerous organs. Congestion and hemorrhage are most evident in the kidney medulla. Widespread microscopic evidence of capillary and vascular dysfunction is found, with endothelial cell swelling, perivascular edema, diapadesis of erythrocytes and mononuclear cell infiltration. Hemorrhage and inflammation in the renal interstitium and tubular epithelial degeneration characterize the kidney pathology. Limited data indicate pathogenic roles for cell destruction from viral infection as well as immune mediated mechanisms. No specific therapy is available.     

Effects of oxygen free radical scavengers on uranium-induced acute renal failure in rats

Study was made to determine whether oxygen free radicals mediate uranium-induced acute renal failure (ARF). Superoxide dismutase (SOD), a superoxide anion scavenger, did not prevent uranium acetate (UA) (5 mg/kg, i.v.)-induced renal injury 48 h after injection. In contrast, dimethylthiourea (DMTU), a hydroxyl radical scavenger, significantly attenuated UA-induced rise in serum creatinine concentration (1.11 ± 0.05 (DMTU) vs. 1.40 ± 0.06 mg/dl (control), p < .05), and tubular necrosis. Dimethyl sulfoxide (DMSO), a hydroxyl radical scavenger, decreased UA-induced tubular damage. UA injection caused no increase in renal cortical malondialdehyde (MDA) content. DMTU and DMSO did not modify intrarenal MDA content. UA administration brought about significant increase in plasma renin activity but not in renal cortical renin content. Treatment with DMTU and DMSO had no effect on plasma renin activity or intrarenal renin content. It follows from these findings that DMTU and DMSO may attenuate UA-induced renal injury. Such a protective effect would not be mediated through modulation of lipid peroxidation or renin activity.     

Renal papillary necrosis in the tiger

Two examples of renal papillary necrosis in the tiger are described. The necrosis was characterised by large zones of liquefaction with minimal inflammation and was associated with pronouced scarring in the cortex. Both animals had been vomiting terminally and were severely dehydrated. It is suggested that papillary necrosis was precipitated by the reduced renal perfusion associated with dehydration in kidneys in which the medullary blood supply was already compromised by chronic cortical scarring. Comparisons are made between the lesions described in these tigers and those reported in the domestic cat, man and other domestic animals.     

Urinary enzyme excretion and renal lactate dehydrogenase isoenzyme pattern in acute HgCl2 nephropathy of rat

The activity of several enzymes with different intracellular sites was determined in urine at various times following nonfatal acute tubular necrosis induced by mercuric chloride administration. The excretion rate of all tested enzymes rose on the 1st and 2nd day; in the next observations (days 7-15) enzymatic values approached the basal values. The lactate dehydrogenase isoenzyme pattern of the renal cortical zone showed an early shift towards cathodic fractions and later (7 days) an increase of middle ones; the normal anodic zymogram recovered after a suitable time interval (30 days). The isoenzymatic changes are related both to the renal hypoxia and to the appearance of less differentiated cells. The behaviour of functional parameters (urine flow, osmolality, urea clearance, creatinine clearance) were well in agreement with the observed enzyme and renal isoenzyme changes.     

Importance of medullary events in ammonium excretion: studies in acute respiratory and acute metabolic acidosis

The renal medulla can play an important role in acid excretion by modulating both hydrogen ion secretion in the medullary collecting duct and the medullary PNH3. The purpose of these experiments was to characterize the intrarenal events associated with ammonium excretion in acute acidosis. Cortical events were monitored in two ways: first, the rates of glutamine extraction and ammoniagenesis were assessed by measuring arteriovenous differences and the rate of renal blood flow; second, the biochemical response of the ammoniagenesis pathway was examined by measuring glutamate and 2-oxoglutarate, key renal cortical metabolites in this pathway. There were no significant differences noted in any of these cortical parameters between acute respiratory and metabolic acidosis. Despite a comparable twofold rise in ammonium excretion in both cases, the urine pH, PNH3, and the urine minus blood PCO2 difference (U-B PCO2) were lower during acute hypercapnia. In these experiments, the urine PCO2 was 34 mmHg (1 mmHg = 133.322 Pa) lower than that of the blood during acute respiratory acidosis while the U-B PCO2 was 5 +/- 3 mmHg in acute metabolic acidosis. Thus there were significant differences in medullary events during these two conditions. Although the urine pH is critical in determining ammonium excretion in certain circumstances, these results suggest that regional variations in the medullary PNH3 can modify this relationship.     

Induction of nephrotoxicity by high doses of gentamicin in diabetic rats

Rats with streptozotocin-induced diabetes mellitus (DM) are resistant to aminoglycoside (AG) nephrotoxicity presumably because of defective transport and accumulation of drug by proximal tubular cells. To test this hypothesis we injected DM rats with saline or with gentamicin, 100, 200, and 400 mg/kg per day for 6 days, to determine if the renal cortical concentration of gentamicin could be raised to toxic levels. Nephrotoxicity was assessed by monitoring for evidence of accelerated lipid peroxidation in the renal cortex, for elevation of the serum creatinine concentration, and for evidence of proximal tubular cell injury and necrosis by light and electron microscopy. At 100 mg/kg per day renal cortical gentamicin was 454 +/- 85 micrograms/g. Except for an increase in renal cortical phospholipids these rats manifested no evidence of accelerated lipid peroxidation or elevation of serum creatinine. At 200 mg/kg per day renal cortical gentamicin rose to 636 +/- 20 micrograms/g. These rats manifested mild functional and morphological evidence of toxicity. At 400 mg/kg renal cortical gentamicin rose to 741 +/- 43 micrograms/g. These rats developed severe nephrotoxic injury as manifested by a marked increase of lipid peroxidation evident by an increase of malondialdehyde from a control level of 0.48 +/- 0.02 to 1.72 +/- 0.12 nmole/mg protein, a shift from unsaturated to saturated fatty acids esterified in renal cortical phospholipids, depression of superoxide dismutase and catalase, and a shift from reduced to oxidized glutathione. The serum creatinine rose from a baseline level of 0.24 +/- 0.01 to 0.46 +/- 0.05 mg/dl. Light and electron microscopy revealed enlarged lysosomes distended with typical myeloid bodies and extensive proximal tubular cell necrosis. These observations provide compelling evidence in support of the view that the resistance of DM rats to AG nephrotoxicity is causally linked to the low rate of drug uptake by renal proximal tubular cells. When the renal cortical concentration reaches a critical level, it elicits a pattern of toxic injury indistinguishable from that of nondiabetic rats. Thus, there is nothing inherent to the diabetic state that prevents AGs from causing their usual adverse effects on the metabolism of renal proximal tubular cells once they gain access in sufficient quantity into these cells.     

Combined use of dopamine and prostaglandin A1 in patients with acute renal failure and hepatorenal syndrome

Dopamine and prostaglandin A₁ were infused intravenously in 4 patients with the hepatorenal syndrome, in 1 patient with acute tubular necrosis, and 1 patient with cortical necrosis. Large doses of prostaglandin A₁ decreased arterial blood pressure preventing increase in dosage; in contrast, high doses of dopamine elevated blood pressure. When the two drugs were administered conjointly, much larger doses of each agent could be administered without change in arterial blood pressure. Significant improvement of renal function was not observed in any of these critically ill patients during or within 24 hours after dopamine and prostaglandin A₁ administration. This study demonstrated that extremely large doses of these vasodilating agents can be safely administered conjointly.     

Renal failure in otherwise uncomplicated acute viral hepatitis.

Twelve patients with otherwise uncomplicated acute viral hepatitis (two were HBsAg-positive) developed renal failure. Apart from dehydration due to repeated vomiting in one patient, no factor responsible for precipitating renal failure could be identified. The clinical course was characterised by renal failure with plasma urea concentrations reaching maximum values of 26-69 mmol/l (175-416 mg/100 ml). Ten patients needed dialysis for up to two weeks. Seven patients recovered completely, while the other five died from sepsis. The types of renal failure were similar to those described in fulminant hepatic failure and cirrhosis--namely, functional renal failure in five patients and acute tubular necrosis in seven. Two of the patients with functional renal failure later developed tubular necrosis. The mechanism responsible for renal failure in acute viral hepatitis is uncertain, though endotoxaemia may contribute.     

Studies on the mechanism of non-oliguric experimental acute renal failure.

Although acute renal failure, caused either by renal ischemia or nephrotoxic agents, is usually characterized by oliguria, a severe fall in glomerular filtration rate, and a fall in renal blood flow, some patients and experimental models display a non-oliguric pattern of renal injury. The present study was designed to evaluate the mechanism of preservation of high urinary flow rate under this condition. Following the administration of the aminoglycoside gentamicin to rats for five days, a decrease in concentrating ability was demonstrated, caused by impaired vasopressin-mediated water transport. Further treatment resulted in a fall in Cin to 15 percent of control, although RBF was reduced to only 67 percent of control, and urine flow rate rose above control levels. Induction of acute and renal failure with dichromate was associated with variable high or low urinary flow rates according to pre-injury intake of sodium. Urine volume correlated directly with cortical blood flow. These data suggest that the non-oliguric pattern of acute renal injury is caused by preservation of cortical perfusion in the setting of severe tubular injury.