Inhibition of human leukocyte proteinase 3 by a novel recombinant serine proteinase inhibitor (LEX032).

The interaction of a bioengineered serpin (LEX032) with human leukocyte proteinase 3 (PR 3) has been investigated. LEX032 was found to be a time-dependent inhibitor of PR 3, forming a highly-stable enzyme-inhibitor complex (Ki 12 nM).

Hepatic and renal conjugation (Phase II) enzyme activities in young adult, middle-aged, and senescent male Sprague-Dawley rats.

Acetaminophen (APAP)-induced nephrotoxicity is age dependent in male Sprague-Dawley rats: nephrotoxicity occurs at lower dosages of APAP in 12- to 14-month olds compared with 2- to 3-month olds. The mechanisms responsible for enhanced nephrotoxicity in 12-month-old Sprague-Dawley rats are not entirely clear, but may be related to age-dependent differences in APAP metabolism in liver and/or kidney. Major pathways of hepatic APAP metabolism include sulfation and glucuronidation; glutathione conjugation represents a pathway for detoxification of reactive oxidative APAP metabolites. The present studies were designed to quantify in vitro activity of three Phase II enzyme activities: glutathione S-transferase using 1-chloro-2,4-dinitrobenzene as substrate, UDP-glucuronyl transferase using APAP as substrate, and sulfotransferase using APAP as substrate, in subcellular fractions of liver and kidney of 3-, 12-, 18-, and 30-month-old naive male Sprague-Dawley rats. In liver, glutathione S-transferase, UDP glucuronyl transferase, and sulfotransferase activities were not significantly different in rats from 3 through 30 months of age. Renal UDP glucuronyl transferase and sulfotransferase activities were similar in rats from 3 through 30 months of age. In contrast, renal glutathione S-transferase activity was characterized by a lower Km in 12- and 30-month olds when compared with 3-month olds. These data suggest that the reduced total systemic clearance of APAP in 12-month-old male Sprague-Dawley rats previously observed cannot be attributed to age-dependent differences in hepatic APAP metabolism. In addition, it is unlikely that differences in renal APAP metabolism contribute to age-dependent APAP nephrotoxicity.

Intrinsic susceptibility of the kidney to acetaminophen toxicity in middle-aged rats.

Acetaminophen (APAP)-induced nephrotoxicity is age-dependent in male Sprague-Dawley (SD) rats: middle-aged (9-12 months old) rats exhibit nephrotoxicity at lower dosages of APAP than do young adults (2-3 months old). The present study was designed to test the hypothesis that the intrinsic susceptibility of renal tissue to APAP toxicity is increased in middle-aged rats. APAP toxicity was evaluated in renal slices from naive 3- and 12-month-old male SD rats incubated with 0-50 mM APAP for 2-8 h. Renal slice glutathione (GSH) and APAP concentrations were determined; renal function was assessed by organic anion (para-aminohippurate, PAH) and cation (tetraethylammonium, TEA) accumulation; and cell viability was assessed by lactate dehydrogenase (LDH) leakage. At each concentration of APAP tested, accumulation of APAP by renal slices was similar in 3- and 12-month-olds. APAP toxicity in renal slices from both 3- and 12-month-old rats was characterized by concentration-dependent increases in LDH leakage. In contrast to APAP nephrotoxicity in vivo, APAP toxicity in renal slices was accompanied by decreased accumulation of PAH and TEA. Additionally, APAP produced marked reductions in renal slice GSH content in a concentration-dependent manner: however, in contrast to APAP nephrotoxicity in vivo, APAP-induced GSH depletion in vitro did not precede cytotoxicity. No consistent age-dependent differences in the time- and concentration-response curves for APAP nephrotoxicity were observed. These data suggest that APAP cytotoxicity in vitro is not increased in 12-month-old rats. However, since the pattern (and mechanisms) of APAP cytotoxicity in vitro appears to be different from that observed in vivo, extrapolation of in vitro cytotoxicity to in vivo nephrotoxicity is limited. Therefore, age differences in intrinsic susceptibility of the intact kidney cannot be excluded as a mechanism contributing to enhanced APAP nephrotoxicity in middle-aged rats.

Gentamicin-induced renal metabolic alterations in newborn rat kidney: lack of potentiation by vancomycin.

Daily subcutaneous administration of 20 or 100 mg/kg gentamicin for 4 days significantly decreased pyridoxal-5'-phosphate and lysosomal specific phosphatidylinositol-phospholipase C (PI-PLC) in newborn rat kidney. The fall in PI-PLC was associated with an elevation in renal phosphatidylinositol, phosphatidylserine, and phosphatidylcholine. The 100 mg/kg gentamicin dose also produced a rise in renal sphingomyelin, phosphatidylethanolamine, phosphatidylglycerol, and total phospholipid (TPL) accompanied by inhibition in the activities of Na+,K+-ATPase and alkaline phosphatase. In contrast, daily intraperitoneal injection of 100 mg/kg vancomycin for 4 days failed to markedly alter renal metabolic parameters. However, the 500 mg/kg vancomycin dose increased kidney weight, TPL, and all individual phospholipid class concentrations accompanied by inhibition of lysosomal specific PI-PLC activity and reduced pyridoxal-5'-phosphate levels. Simultaneous administration of 20 mg/kg gentamicin with either vancomycin dose resulted in renal alterations similar to those produced by gentamicin alone. Concurrent treatment with 100 mg/kg aminoglycoside and either vancomycin dose produced changes in kidney which were similar to those produced by gentamicin alone, except for a synergistic rise in PI as well as a greater fall in alkaline phosphatase and pyridoxal-5'-phosphate. Surprisingly, the concentration of gentamicin and vancomycin was less in newborn kidneys of rats receiving a simultaneous high dose of vancomycin and aminoglycoside treatment compared to levels found in animals given either antibiotic separately. The lack of potentiation of nephrotoxicity in newborns administered a combination of vancomycin and gentamicin may be due to decreased accumulation of either antibiotic in kidney.

Strain differences in acetaminophen nephrotoxicity in rats: role of pharmacokinetics.

Strain differences in susceptibility of rats to acetaminophen (APAP)-induced nephrotoxicity have been previously reported. Young adult male Fischer-344 (F-344) rats are susceptible whereas weight-matched Sprague-Dawley (SD) rats are not susceptible to APAP nephrotoxicity. The present study was designed to evaluate the role of pharmacokinetics in strain-dependent APAP nephrotoxicity. Age-matched (2-month-old) male F-344 and SD rats received 250-750 mg APAP/kg, i.v., or 0-1000 mg APAP/kg, i.p. Pharmacokinetic variables were evaluated following i.v. APAP and 24 h urinary excretion of APAP and major metabolites was determined following both i.v. and i.p. administration of APAP. Following i.p. administration, nephrotoxicity was observed only in F-344 rats following 1000 mg APAP/kg; SD rats were not susceptible to APAP-induced nephrotoxicity. In contrast, nephrotoxicity did not occur in either F-344 or SD rats administered APAP i.v. Pharmacokinetic variables (volume of distribution, apparent systemic clearance, and apparent terminal half-life) of APAP were similar in F-344 and SD rats. No striking differences in the pattern of specific urinary metabolites were observed between F-344 and SD rats treated with i.p. or i.v. APAP. Thus, strain differences in APAP-induced nephrotoxicity do not appear to be due to differences in pharmacokinetics or major pathways of APAP metabolism.

Role of pharmacokinetics and metabolism in the enhanced susceptibility of middle-aged male Sprague-Dawley rats to acetaminophen nephrotoxicity.

Middle-aged male Sprague-Dawley (SD) rats (9-12 months) are more susceptible to acetaminophen (APAP)-induced nephrotoxicity than are young (2-3 months) adult males. The present studies were designed to evaluate the role of pharmacokinetics and renal and hepatic metabolism of APAP in age-dependent nephrotoxicity. Following 750 mg/kg APAP, ip, a nephrotoxic dosage in 12-month-old but not 3-month-old rats, renal cortical APAP concentrations were significantly greater in 12-month-old compared with 3-month-old SD rats at 3, 4, and 6 hr after treatment. Renal medullary APAP concentrations in 12 month-old rats were significantly greater than in 3-month-old rats at 2, 3, and 5 hr after treatment. Serum APAP concentrations were significantly elevated in 12-month-old compared with 3-month-old rats from 2 through 5 hr after APAP (750 mg/kg ip). However, APAP tissue/serum concentration ratios were similar in 3- and 12-month-old rats, indicating that differences in tissue concentration were secondary to increased serum concentrations in older rats. Conjugated APAP metabolites in blood were similar in 3- and 12-month-olds during the initial 2-3 hr after 750 mg/kg APAP, ip, but began to accumulate in 12-month-old but not 3-month-old rats within 6-8 hr after APAP administration, perhaps secondary to declining renal function. After 500 mg/kg APAP, iv, blood APAP concentrations were markedly elevated in 12-month-old compared with 3-month-old rats during the entire course of the experiment.(ABSTRACT TRUNCATED AT 250 WORDS)

Acetaminophen and p-aminophenol nephrotoxicity in aging male Sprague-Dawley and Fischer 344 rats.

Strain differences in susceptibility of rats to acetaminophen (APAP)-induced nephrotoxicity have been reported previously. Young adult male Fischer 344 (F344) rats are susceptible, whereas weight-matched Sprague-Dawley (SD) rats are not susceptible to APAP nephrotoxicity. Susceptibility to APAP nephrotoxicity is also age dependent, at least in F344 rats. Middle-aged (12-15 months old) male F344 rats are more susceptible to APAP-induced nephrotoxicity than are young adult (2-4 months old) males. APAP nephrotoxicity in aging SD rats has not been evaluated. The present studies were designed to define strain differences in the nephrotoxicity of APAP and p-aminophenol (PAP), a nephrotoxic metabolite of APAP, using 2-, 3-, and 9- to 12-month-old F344 and SD rats. At 2 months of age, F344, but not SD, rats were susceptible to APAP-induced nephrotoxicity. However, at 3 months of age, strain differences were less marked, as susceptibility to APAP nephrotoxicity appeared to increase between 2 and 3 months of age only in SD rats. By 9-12 months of age, susceptibility to APAP nephrotoxicity was comparable in F344 and SD rats. No age- or strain-related differences were observed in the excretory pattern of urinary APAP and metabolites that might explain the increased susceptibility of aging rats to APAP nephrotoxicity. Strain differences in age-matched rats were not marked for PAP-induced nephrotoxicity. Susceptibility of both 3- and 12-month-old F344 and SD rats to PAP-induced nephrotoxicity was greater compared to strain-matched 2-month-old rats. In both F344 and SD rats, PAP nephrotoxicity increased only modestly between 3 and 12 months of age, indicating that increased susceptibility to PAP probably does not play a major role in the age-dependent increase in APAP nephrotoxicity. Thus, strain differences in APAP nephrotoxicity decrease with advancing age. The mechanisms mediating the increased susceptibility to APAP nephrotoxicity in middle-aged rats are not known but may relate, at least in part, to age-dependent differences in pharmacokinetics. The present study highlights the importance of considering the age of rats when evaluating drug toxicity. Even in young adult rats, subtle maturational changes in drug metabolism and/or disposition may occur, making toxicological evaluation in weight-matched rats of different strains and ages inappropriate.

Preparing for the twenty-first century: report of the TOX-90's Commission. Planning Committee.

A clear consensus developed that toxicology will be driven by advances in related fields. New technology and knowledge developed by all relevant disciplines, therefore, must be integrated into toxicology; progress in toxicology demands that the discipline must increasingly address good science and the scientific method. Issues of critical importance to the field, such as risk estimation of the health effects of chemical and physical agents and the education of toxicologists, can only be addressed by meeting these objectives.

Carcinogenicity study of auranofin, an orally administered gold compound, in mice.

Auranofin, a gold-containing compound, was administered to Charles River CD-1 mice for 18 months to assess its possible carcinogenicity. The mice were dosed orally with 1.0, 3.0, or 6.0 (increased to 9.0 on Day 294) mg/kg/day. Each dose group and each of two control groups contained 110 males and 110 females. Survival was greater than 70% at the end of the study. No effect of the treatment on neoplastic or nonneoplastic lesions was found. This is in contrast to the results reported in rats. Auranofin in rats produced a heavy metal nephropathy characterized by acute coagulative necrosis, subacute renal cortical fibrosis, chronic cytomegaly and karyomegaly, and finally renal cortical neoplasia (adenomas and adenocarcinomas). The lack of effect of auranofin on tumor incidence in mice suggests the findings in rats may be species specific.

Age-related nephropathy in laboratory rats.

Chronic progressive nephropathy is a spontaneous disease common among aging laboratory rats, often making it difficult to distinguish age-related from drug-related effects in chronic toxicity studies. Morphological changes of the kidney that occur with age include thickening of glomerular and proximal tubular basement membranes, mesangial proliferation, fusion of foot processes, and, ultimately, glomerular sclerosis. Proteinuria (specifically, albuminuria) is the most striking characteristic change in renal function of aging rats and, generally, correlates well with the severity of age-related glomerular pathology. Changes in tubular functions also may occur with aging but have not been investigated sufficiently. The pathogenesis of chronic progressive nephropathy is not known; however, hemodynamic adaptations after ad libitum consumption of protein-rich diets may be a contributing factor. High-protein diets increase glomerular pressures and flows, perhaps facilitating excretion of metabolic end products. These hemodynamic adaptations may impair the permselective properties of the glomerulus, leading to: enhanced accumulation of macromolecules in the mesangium, progressive mesangial expansion, and, ultimately, glomerular sclerosis. Indeed, decreasing total food or protein intake retards or prevents the progression of age-related nephropathy. Inasmuch as chronic toxicity studies are complicated by a high incidence of spontaneous nephropathy, implementation of a restricted dietary regimen may improve detection of drug-induced toxicity.

Biochemical mechanisms of cephaloridine nephrotoxicity.

Large doses of the cephalosporin antibiotic, cephaloridine, produce acute proximal tubular necrosis in humans and in laboratory animals. Cephaloridine is actively transported into the proximal tubular cell by an organic anion transport system while transport across the lumenal membrane into tubular fluid appears restricted. High intracellular concentrations of cephaloridine are attained in the proximal tubular cell which are critical to the development of nephrotoxicity. There is substantial evidence indicating that oxidative stress plays a major role in cephaloridine nephrotoxicity. Cephaloridine depletes reduced glutathione, increases oxidized glutathione and induces lipid peroxidation in renal cortical tissue. The molecular mechanisms mediating cephaloridine-induced oxidative stress are not well understood. Inhibition in gluconeogenesis is a relatively early biochemical effect of cephaloridine and is independent of lipid peroxidation. Furthermore, cephaloridine inhibits gluconeogenesis in both target (kidney) and non-target (liver) organs of cephaloridine toxicity. Since glucose is not a major fuel of proximal tubular cells, it is unlikely that cephaloridine-induced tubular necrosis is mediated by the effects of this drug on glucose synthesis.

Cisplatin nephrotoxicity: role of filtration and tubular transport of cisplatin in isolated perfused kidneys.

Isolated perfused rat kidneys were used to determine the contribution of filtration and tubular transport of cisplatin to its nephrotoxicity. Perfusion of kidneys with 0.5 mM cisplatin concomitantly reduced tubular reabsorption of electrolytes and glomerular filtration rate in a time-dependent manner. These renal functional changes were similar to those obtained following in vivo cisplatin treatment (10 mg/kg). In vitro exposure to cisplatin reduced the renal clearance of organic ions without reducing renal perfusate flow, suggesting that renal hemodynamic changes do not mediate cisplatin-induced proximal tubular dysfunction. Inhibition of organic ion transport also was observed in non-filtering perfused kidneys treated with 0.5 mM cisplatin, implying that filtration of cisplatin is not a prerequisite for induction of toxicity. These data also suggest that cisplatin transport from a basolateral site may be important in the development of acute nephrotoxicity.

Age-related differences in susceptibility to renal ischemia in rats.

These experiments were designed to determine the influence of age on the response of the kidney to ischemia. Renal ischemia was induced in female Fischer-344 rats, 3-4 or 37-38 months old, by renal arterial and venous occlusion followed by 0, 1, 24, or 96 hr of reflow. Age-matched controls were sham operated but were not subjected to ischemia. A transient postischemic increase in blood urea nitrogen (BUN) and serum creatinine was observed in young rats. In old rats, BUN and serum creatinine remained markedly elevated through 96 hr postischemia. In vitro renal cortical slice accumulation of organic ions was inhibited to a greater extent in old rats than in young rats 96 hr postischemia. Histologically, renal tubular damage was more severe in old than in young rats 24 and 96 hr postischemia. Tubular regenerative activity was similar in old and young rats at 96 hr, but restoration of tubular architecture was more complete in young rats. Organic ion accumulation by renal cortical slices from naive old rats was inhibited by in vitro anoxia (treatment with 100% N2) to a greater extent than tissue from young rats. These data suggest that old rats are more susceptible to renal ischemia than are young rats and these differences in susceptibility may reflect intrinsic age-related differences in basal renal metabolism.

Mechanisms mediating cephaloridine inhibition of renal gluconeogenesis.

Incubation of renal cortical slices with cephaloridine (CPH) markedly inhibits pyruvate-supported gluconeogenesis, an effect which is independent of CPH-induced lipid peroxidation. CPH was found to inhibit pyruvate-supported gluconeogenesis in a time-and concentration-dependent manner. Pyruvate-supported gluconeogenesis was inhibited as early as 10 min following incubation of renal cortical slices with 5 mM CPH. Similarly, endogenous gluconeogenesis was impaired following CPH treatment. CPH depressed the renal cortical slice content of ATP by 50%, but only following 90 and 120 min of drug exposure, suggesting that mitochondrial dysfunction does not mediate the inhibition of gluconeogenesis by CPH. To identify the intracellular site(s) of CPH inhibition of gluconeogenesis, the effects of CPH on glucose production were evaluated using substrates catalyzed by rate-limiting reactions. CPH inhibited renal cortical slice gluconeogenesis when the following substrates were used: pyruvate (mitochondrial), oxaloacetate and fructose-1,6-diphosphate (FDP) (postmitochondrial), and glucose-6-phosphate (G6P, endoplasmic reticulum). Inhibition of G6P-supported gluconeogenesis occurred within 5 min of incubation with 5 mM CPH. Direct addition of CPH to microsomal suspensions inhibited G6Pase activity in a concentration-dependent fashion. By contrast, addition of CPH to cytosolic fractions did not affect FDPase activity. CPH increased the Km and decreased the Vmax of G6Pase, indicating mixed competitive and noncompetitive inhibition. These data indicate that the profound inhibition of renal cortical slice gluconeogenesis by CPH is mediated by inhibition of microsomal G6Pase activity.

Metabolism and excretion of a glutathione conjugate of acetaminophen in the isolated perfused rat kidney.

Acetaminophen-glutathione (APAP-GSH) is the initial sulfur-containing metabolite of APAP produced by the liver. However, little, if any, APAP-GSH is found in the urine of intact animals. Rather, the cysteine (APAP-CYS) and N-acetylcysteine (APAP-NAC) conjugates are the predominant sulfur-containing metabolites of APAP excreted in the urine. To define more precisely the role of the kidney in total body disposition of APAP, the metabolism and excretion of each of these metabolites was quantified in the isolated perfused rat kidney (IPK). With perfusate concentrations of 0.031, 0.125 and 0.250 mM APAP-GSH, the IPK metabolized APAP-GSH to APAP-CYS rapidly. Further metabolism of APAP-CYS to APAP-NAC proceeded at a much slower rate. Consequently, at 0.031 mM APAP-GSH, negligible amounts of APAP-CYS were found in the urine. However, as the concentration of APAP-GSH was increased so did the excretion of APAP-CYS. In contrast, the excretion of APAP-NAC did not exhibit dependence on APAP-GSH concentration. APAP-NAC was excreted by a probenecid sensitive transport mechanism whereas APAP-CYS excretion appeared to be related only to glomerular filtration. In addition, the disappearance of APAP-GSH was much greater than could be accounted for by glomerular filtration. These data indicate that the IPK is an effective model for the study of metabolism and excretion of xenobiotics that have undergone conjugation with GSH.

Biochemical mechanisms of cephaloridine nephrotoxicity: time and concentration dependence of peroxidative injury.

These experiments were designed to elucidate the initiating biochemical events mediating cephaloridine (CPH) nephrotoxicity. Renal cortical slices from naive male Fischer-344 rats were incubated at 37 degrees C in a phosphate- or bicarbonate-buffered medium containing 0, 1, 5, or 10 mM CPH. Slices were incubated for 15, 30, 45, 60, 90, 120, and 180 min and evaluated for accumulation of organic ions [p-aminohippurate (PAH) and tetraethylammonium (TEA)], pyruvate-stimulated gluconeogenesis, malondialdehyde (MDA) production, and reduced glutathione (GSH) content. Renal cortical slice accumulation of PAH and TEA was decreased by 5 and 10 mM CPH as early as 120 and 90 min of incubation, respectively. CPH-induced MDA production by renal cortical slices preceded the effects of CPH on organic ion accumulation. Coincubation of CPH with the antioxidants promethazine and N,N'-diphenyl-p-phenylenediamine inhibited CPH-induced lipid peroxidation and changes in organic ion accumulation. In contrast, 5 or 10 mM CPH inhibited gluconeogenic capacity at all time points examined, an effect which was not influenced by antioxidant treatment. Depletion of renal cortical GSH by 5 or 10 mM CPH was evident following 30 min of incubation and was also unaffected by antioxidant treatment. These results support the hypothesis that lipid peroxidation mediates the effects of CPH on renal organic ion transport. The early and profound inhibition of gluconeogenesis by CPH suggests that the biochemical pathways of gluconeogenesis are either proximal to or represent a primary target for CPH nephrotoxicity.

Induction of renal and hepatic mixed function oxidases in the hamster and guinea pig.

A marked species difference exists in the induction of renal and hepatic mixed function oxidase (MFO) activity between rats and rabbits. However, little is known about MFO induction in these organs from other laboratory animals. Male Golden Syrian hamsters and male Hartley guinea pigs were administered phenobarbital (PB) or beta-napthoflavone (BNF) at 70 and 40 mg/kg, respectively, as daily i.p. injections for 4 days. Polybrominated biphenyl (PBB) (Firemaster BP-6) was given as a single i.p. injection (50 mg/kg). Hamster hepatic microsomal ethoxyresorufin-O-deethylase (EROD) and benzphetamine-N-demethylase (BPND) were selectively induced by BNF and PB, respectively. PBB administration induced both hamster hepatic EROD and BPND. In contrast, hepatic microsomal MFO activity from the guinea pig was inducible by PB, PBB and BNF. Renal microsomal MFO activity in both species was inducible by BNF and PBB as arylhydrocarbon hydroxylase and EROD were induced approximately 10-fold. On the other hand, hamster BPND was induced by PB whereas guinea pig MFO activity was unaffected. Total renal cytochrome P-450 content was not affected by any of these inducers in either species. These data demonstrate selective patterns of induction in both hamster and guinea pig liver and kidney suggesting the involvement of multiple forms of cytochrome P-450.

Induction of renal mixed function oxidases in the rat and mouse: correlation with ultrastructural changes in the proximal tubule.

Rats and mice were pretreated with beta-naphthoflavone (BNF) at 100 mg/kg/day, ip, for 4 days, or polybrominated biphenyl (PBB) as a single ip dose at 150 mg/kg, and the temporal changes in renal mixed function oxidase (MFO) activity and ultrastructural changes in the proximal tubule were examined. Rat renal cytochrome P-450 (P-450), ethoxycoumarin-O-deethylase (ECOD), and ethoxyresorufin-O-deethylase (EROD) were increased 5 days following the first dose of inducer. P-450 content and enzyme activity peaked on Day 5 to Day 10 and returned to control values by Day 15. BNF and PBB caused proliferation of smooth endoplasmic reticulum (SER) in only the S3 segment of the rat proximal tubule. Histologic analysis indicated that there was a close correlation between the temporal changes in renal MFO activity and proliferation of SER in the S3 segment of the proximal tubule. In contrast to the rat, mouse renal P-450 and ECOD were not induced by either BNF or PBB nor was there any significant proliferation of SER in any segment of the proximal tubule. Mouse renal EROD was slightly increased on Day 5 but not Day 10 or 15 by BNF; PBB had no effect. In addition to proliferation of SER, these inducers also caused proliferation of peroxisomes in the rat and mouse proximal tubule. These results demonstrate a temporal relationship between induction of rat renal MFOs and proliferation of SER in specific sections of the proximal tubule and thus suggest that induction of these renal enzymes may also be restricted to specific cell populations of the kidney. A species difference apparently exists since proliferation of SER was not observed in the mouse.

Cephaloridine nephrotoxicity in aging male Fischer-344 rats.

Age-related differences in susceptibility to cephaloridine nephrotoxicity were evaluated in male Fischer-344 rats. Rats, 2.5, 4, 10-12 and 27-29 months old, were administered a single intraperitoneal dose of cephaloridine and renal function evaluated 24 h later. Susceptibility to cephaloridine-induced nephrotoxicity was age-related. Older rats (10-12 and 27-29 months) were the most susceptible to cephaloridine nephrotoxicity as indicated by a dose-related increase in relative kidney weight, elevation in blood urea nitrogen concentrations and a diminished capacity of renal cortical slices to accumulate the organic anion, p-aminohippurate (PAH) and the organic cation, tetraethylammonium (TEA). Impaired renal function following cephaloridine treatment was not detected in 2.5-month-old, apparent to a slight extent in 4-month-old, and most pronounced in 10-12- and 27-29-month-old rats. Serum and renal cortical concentrations of cephaloridine tended to be greater in older rats compared to that of young adults. Thus, the enhanced susceptibility of older rats to cephaloridine nephrotoxicity may be related in part to the increased renal cortical accumulation of cephaloridine.