Experimental studies on the nephrotoxicity of pentamidine in rats

Renal side-effects are frequently observed after parenteral administration of pentamidine. In this study in a rat model, the nephrotoxicity was assessed by measuring urinary loss of tubular cells, malate dehydrogenase activity and creatinine clearance. In addition, we studied the influence of other nephrotoxins such as tobramycin, amphotericin B and cyclosporin on the pentamidine-associated nephrotoxicity and proved the possibilities of reducing this toxicity by coadministration with other drugs. The tubular toxicity of pentamidine (1, 10 or 20 mg/kg daily) is dose-related and reversible. The toxicity can be reduced by coadministration of fosfomycin (1 x 500 or 2 x 250 mg/kg daily) and D-glucaro-1,5-lactam (2 x 5 mg/kg daily) and enhanced by tobramycin (2 x 2.5 mg/kg daily), amphotericin B (1 mg/kg daily) and cyclosporin (10 mg/kg daily). Furthermore, an increase in the creatinine clearance in pentamidine-treated rats can be obtained with both verapamil (2 x 1.5 mg/kg daily) and enalapril (5 mg/kg daily).     

Experimental studies on nephrotoxicity and pharmacokinetics of LY 146032 (daptomycin) in rats

The nephrotoxicity and pharmacokinetics of LY 146032 (daptomycin) were studied in an experimental rat model. Nephrotoxicity was assessed by measuring urinary loss of tubular cells and malate dehydrogenase. LY 146032 (10-250 mg/kg daily iv) led to a dose-dependent and reversible increase of cell elimination. The tubulo-toxic threshold dose is stated to be 10 mg/kg daily. Nephrotoxicity induced by LY 146032 can be reduced by coadministration of fosfomycin or D-glucaro-1.5-lactam, and enhanced by combination with tobramycin. LY 146032 accumulated in renal tissue during repeated administration. Electron microscopy revealed histopathological changes in the kidneys. Therefore the nephrotoxic potential of LY 146032 should be taken into consideration in clinical trials.     

Teicoplanin: renal tolerance and pharmacokinetics in rats

The nephrotoxicity and pharmacokinetics of teicoplanin were studied in an experimental rat model. Nephrotoxicity was assessed by measuring urinary excretion of tubular cells and malate dehydrogenase. The experiments revealed that 1 mg/kg or more of teicoplanin daily resulted in an increase of excretion rates of tubular cells. Similarly to vancomycin, teicoplanin is accumulated in the kidneys. Nephrotoxicity induced by teicoplanin can be reduced by coadministration of fosfomycin and D-glucaro-1.5-lactam, and enhanced by administration of tobramycin. We conclude that renal function should be monitored closely during teicoplanin therapy.     

Comparative nephrotoxicity of gentamicin and tobramycin: pharmacokinetic and clinical studies in 201 patients.

A total of 201 critically ill patients were studied during 267 courses of gentamicin or tobramycin treatment (139 gentamicin courses and 128 tobramycin courses). Of these 267 courses, pharmacokinetic and clinical data were obtained for 240 (120 gentamicin and 120 tobramycin). The data collected for pharmacokinetic analysis included measurements of serial blood and urine levels, urinary excretion of beta 2-microglobulin, protein levels, and granular casts. A two-compartment model was used to assess tissue accumulation, and in 89 courses the predicted accumulation was confirmed by cumulative urine collection or postmortem tissue analysis. As groups, the patients given gentamicin and tobramycin did not differ in age, weight, creatine clearance, total dose given, duration of treatment, initial aminoglycoside through serum levels, number of dosage adjustments, concurrent use of furosemide, or concurrent cephalosporins. Previous aminoglycoside treatment (usually gentamicin) had occurred more frequently in the tobramycin treated patients (P less than 0.01), and more males than females received tobramycin (P less than 0.05). Pharmacokinetic assessments of renal damage were based on both changes in glomerular filtration rate (serum creatinine levels, creatinine clearance) and renal tubular damage (beta 2-microglobin, casts), but only patients with elevated aminoglycoside tissue levels leading to renal tubular damage and subsequent creatinine clearance decreases were considered to have experienced aminoglycoside nephrotoxicity. In the pharmacokinetic analysis of nephrotoxicity, 29 gentamicin courses (24%) and 12 tobramycin courses (10%) were complicated by nephrotoxicity (P less than 0.01). The 201 study patients were also evaluated independently for clinical nephrotoxicity (defined as a serum creatinine level increase of 0.5 mg/dl or more). Clinical nephrotoxicity occurred at rates of 37% in the gentamicin-treated group and 22% in the tobramycin-treated group (P less than 0.02). In these similar groups of critically ill patients, tobramycin was less nephrotic than gentamicin.     

Sodium status influences chronic amphotericin B nephrotoxicity in rats.

The nephrotoxic potential of amphotericin B (5 mg/kg per day intraperitoneally for 3 weeks) has been investigated in salt-depleted, normal-salt, and salt-loaded rats. In salt-depleted rats, amphotericin B decreased creatinine clearance linearly with time, with an 85% reduction by week 3. In contrast, in normal-salt rats creatinine clearance was decreased but to a lesser extent at week 2 and 3, and in salt-loaded rats creatinine clearance did not change for 2 weeks and was decreased by 43% at week 3. All rats in the sodium-depleted group had histopathological evidence of patchy tubular cytoplasmic degeneration in tubules that was not observed in any normal-salt or salt-loaded rat. Concentrations of amphotericin B in plasma were not significantly different among the three groups at any time during the study. However, at the end of 3 weeks, amphotericin B levels in the kidneys and liver were significantly higher in salt-depleted and normal-salt rats than those in salt-loaded rats, with plasma/kidney ratios of 21, 14, and 8 in salt-depleted, normal-salt, and salt-loaded rats, respectively. In conclusion, reductions in creatinine clearance and renal amphotericin B accumulation after chronic amphotericin B administration were enhanced by salt depletion and attenuated by sodium loading in rats.     

Attenuation of amphotericin B nephrotoxicity in the dog by the fenoldopam prodrug, SK&F R-105058.

Amphotericin B administration to 8 dogs (1 mg/kg.d, i.v.) for 3 days resulted in significant (P less than .01) reductions in 24-hr creatinine clearance. SK&F R-105058 is an N-ethyl carbamate ester prodrug of the selective DA1 receptor agonist, fenoldopam, which, on oral administration to dogs, results in sustained plasma levels of the renal vasodilator, fenoldopam. Treatment of 6 dogs with SK&F R-105058 (10 mg/kg p.o. b.i.d.) resulted in a significant attenuation of the amphotericin B-induced reductions in creatinine clearance observed on days 2 and 3 after initiation of amphotericin treatment. However, the increase in urine flow and fractional sodium excretion induced by amphotericin B was not altered by SK&F R-105058 treatment. Subsequent histological analysis of the kidneys demonstrated lesions consisting of multifocal tubular degeneration, necrosis and mineralization of mostly distal tubules. Quantitation of tubular lesions indicated that SK&F R-105058 significantly reduced the morphological changes induced by amphotericin B. The data indicate that administration of a fenoldopam prodrug can delay amphotericin B-induced reductions in glomerular filtration rate in the dog.     

Vancomycin enhancement of experimental tobramycin nephrotoxicity.

The influence of vancomycin on tobramycin nephrotoxicity was assessed in male Fischer rats. Treatment groups included controls receiving diluent and groups receiving vancomycin alone at a dosage of 200 mg/kg (body weight) per day, tobramycin alone at a dosage of 80 mg/kg per day, and a combination of vancomycin and tobramycin at the above dosages. All regimens were injected on a twice-a-day schedule. The animals were sacrificed on days 1, 3, 10, 14, 17, and 21. When compared with controls, animals receiving vancomycin alone exhibited no detectable renal toxicity. Compared with the case with controls, tobramycin alone was toxic, as manifested by lower mean animal weights, increased blood urea nitrogen concentrations on days 14 and 17 (P less than 0.005), increased serum creatinine concentrations on days 17 and 21 (P less than 0.005), and the presence of renal cortical tubular necrosis and regeneration. When compared with tobramycin alone, the combination of vancomycin and tobramycin caused earlier and more severe toxicity. By day 10, the magnitude of weight loss, the rise in blood urea nitrogen, and the increase in serum creatinine concentration were all greater in the rats given the combination of vancomycin plus tobramycin than in the animals given tobramycin alone (P less than 0.005). In addition, there was more proximal tubular necrosis and regeneration in rats given vancomycin plus tobramycin compared with those given tobramycin alone. In this animal model, vancomycin alone caused no detectable renal injury, tobramycin alone produced minimal proximal tubular damage, and the combination of vancomycin and tobramycin resulted in a greater degree of kidney injury than observed with tobramycin alone.     

Pharmacokinetics of the Aminoglycoside Antibiotic Tobramycin in Humans

The pharmacokinetics, distribution, and plasma and renal clearance of a new aminoglycoside antibiotic, tobramycin, was studied in the treatment of 18 elderly male patients (average age, 69 years) with urinary tract infections. Ten of these patients had normal renal function and eight had impaired renal function of various degrees. After administration of 1 mg of tobramycin/kg of body weight every 6 to 8 h (two to three times the half-life), urine concentrations were found to be sufficient in the treatment of urinary tract infections caused by susceptible organisms. The renal clearance of tobramycin during constant intravenous infusion was also studied in eight patients. Good correlation was found between the patients serum creatinine and the half-life of tobramycin. The half-life of tobramycin in patients with normal renal function (serum creatine [Formula: see text] to 1.5 mg/100) was on the average 3 h. For practical purposes, therefore, the dosage of tobramycin in the treatment of urinary tract infections should be 1 mg/kg of body weight every 6 to 8 h in patients with normal renal function. For patients with impaired renal function, the dosage interval is calculated by multiplying the patients' serum creatinine by six. If the dosage intervals are kept unchanged, the dosage must be divided by the patients' serum creatinine. The initial loading dose should always be 1 mg/kg. The total renal clearance of tobramycin (92% of the glomerular filtration rate) was not influenced by the administration of probenecid, which indicates that tobramycin is excreted only by glomerular filtration.     

Retinol binding protein in serum and in urine of glomerular and tubular nephropathies

RBP behaviour was studied in different kidney diseases. Serum RBP was increased in chronic renal diseases when the serum creatinine increased. RBP clearance and RBP clearance as a percentage of albumin clearance increased when GFR decreased; this is more evident in tubular kidney diseases. Urinary RBP loss as a percentage of urinary albumin loss increased especially in kidney diseases with persistent tubular lesions.     

Renal tolerance and pharmacokinetics of vancomycin in rats

The nephrotoxicity, as measured by urinary cell and enzyme excretion, of vancomycin was studied in rats. The lowest daily iv dose inducing significantly increased cell elimination was 25 mg/kg. Im administration caused less effects probably due to incomplete absorption from the im injection site, since im dosages of 100 mg/kg daily led to lower renal tissue concentrations than the same doses given iv. Nephrotoxicity of vancomycin increased when combined with tobramycin and was reduced when combined with D-glucaro-1.5-lactam, a beta-glucuronidase inhibitor. Vancomycin accumulated in renal tissue during repeated administration.     

Elimination of amphotericin B in impaired renal function

The influence of impaired renal function on the steady-state plasma clearance of amphotericin B was determined in seven patients with creatinine clearances ranging from zero to normal. Contrary to previous reports, steady-state plasma concentrations of total drug were lower in uremic patients than in patients with normal renal function. Total plasma clearance of amphotericin B ranged from 16.7 to 39.9 ml/min, correlated directly with the plasma creatinine concentration, and correlated inversely with the creatinine clearance. Urinary excretion of unchanged drug accounted for less than 10% of the dose. In 10 healthy subjects, mean percent of amphotericin B unbound in plasma was 3.55 +/- 0.32 (SD). Binding was determined in a further group of 10 uremic patients. Mean unbound percent (4.15 +/- 0.73, SD) was higher than in the healthy subjects, and the binding ratio (molar concentration of bound to unbound drug) correlated weakly with the creatinine clearance. This suggests that plasma clearance of unbound amphotericin B and, therefore, steady-state plasma concentrations of unbound drug are not affected by renal impairment, and that dosage requirements will be overestimated if based on measurements of total drug plasma concentration.     

Population pharmacokinetics and renal function-sparing effects of amphotericin B colloidal dispersion in patients receiving bone marrow transplants.

The purpose of this study was to evaluate the pharmacokinetics of amphotericin B colloidal dispersion and its effect on creatinine clearance in bone marrow transplant patients with systemic fungal infections. Seventy-five patients (42 females and 33 males) with a median age of 34.5 years and a median weight of 70.0 kg were enrolled in the study. Patients received 1 of 15 dose levels (range, 0.5 to 8.0 mg/kg of body weight) daily for a mean duration of 28 days and a mean cumulative dose amount of 8 g. Plasma samples for amphotericin B determination (median number, 4; range, 2 to 30) and daily serum creatinine values were obtained for each patient. Iterative two-stage analysis, one of several approaches to population pharmacokinetic and pharmacodynamic modelling, was employed for the pharmacokinetic analysis. The plasma data were available for 51 of 75 patients and were best described by a two-compartment model. Both plasma clearance and volume of distribution increased with escalating doses; the overall average terminal elimination half-life was 29 h. Of the covariates studied, only body weight and dose size were significant. Serum creatinine values over the duration of therapy were available for 59 of 75 patients. Overall, there was no net change in renal function over the duration of therapy; 12 patients had > 30% increases in creatinine clearance, whereas 13 had > 30% decreases. No measure of amphotericin B colloidal dispersion exposure, demographic values, or concomitant treatment with other medications was related to changes in the creatinine clearance.     

Ciprofloxacin pharmacokinetics in patients with normal and impaired renal function.

The pharmacokinetics of ciprofloxacin following single oral doses of 500 and 750 mg in 32 patients with various degrees of renal function impairment were investigated in an open, randomized crossover fashion. Ciprofloxacin was administered after overnight fasting; the washout time between the two doses was 1 week. Serum and urine samples were collected serially between 0 and 24 h and subjected to bioassay and high-performance liquid chromatography. Pharmacokinetic parameters were analyzed, assuming an open two-compartment model with first-order input and elimination. A distinct difference was observed in pharmacokinetic parameters between patients with impaired renal function (creatinine clearance, less than 50 ml/min per 1.73 m2) and those with normal renal function (creatinine clearance, greater than or equal to 50 ml/min per 1.73 m2). For the former group, the area under the curve of serum concentration versus time was doubled, the renal clearance of ciprofloxacin was cut to one-fourth, the total and nonrenal ciprofloxacin clearance was reduced by 50%, and the elimination half-life was prolonged by a factor of approximately 1.7. The correlation between renal drug clearance and creatinine clearance was highly significant (r = 0.890; P less than 0.001). On the basis of these findings, it appears that a 50% dose reduction of ciprofloxacin in patients with impaired renal function (creatinine clearance, less than 50 ml/min per 1.73 m2) may be indicated to achieve concentrations in serum similar to those observed in normal individuals. As the concentration of ciprofloxacin in urine after 24 h remained above the MIC for most urinary pathogens, this drug appears to be of potential benefit for the treatment of urinary tract infections in patients with impaired renal function.     

Iopentol in patients with chronic renal failure: its effects on renal function and its use as glomerular filtration rate parameter.

Iopentol (mean dose 0.42 g I kg-1) was administered for abdominal aortography and pelvic angiography in 10 patients with advanced non-diabetic chronic renal failure (S-creatinine 672 +/- 259 mumol l-1, mean +/- SD). Renal glomerular function measured as creatinine clearance and plasma clearance of [99Tcm]-diethyl-enetriaminepentaacetic acid (DTPA) was unchanged by iopentol, as also was urinary excretion of the renal tubular enzymes N-acetyl-beta-glucosaminidase (NAG) and alkaline phosphatase (ALP). The elimination of iopentol from serum and urine was delayed, and detectable serum and urine concentrations were found 5 days after administration of the contrast medium. Creatine clearance was 47% higher than the corresponding renal iopentol clearance. Plasma iopentol clearance, measured as the total area under the plasma concentration curve, was 40% higher than renal iopentol clearance because of extrarenal elimination of iopentol. We conclude that abdominal aortography with iopentol can be performed without effects on renal glomerular or tubular function parameters in patients with advanced renal failure. If iopentol is used for measurement of glomerular filtration rate (GFR) in this group of patients, one should measure renal clearance, as plasma clearance overestimates GFR.     

成人肾病综合征31例病理与临床观察

目的　通过 31例成人肾病综合征 (Nephroticsyndrome ,NS)病理与临床观察 ,分析探讨 2 4小时尿蛋白排出量和血肌酐与合并肾小管间质损害的关系。方法　将患者分A组 (无合并肾小管间质损害 ,n =12 )和B组 (合并肾小管间质损害 ,n =19)进行对比分析。结果　NS时肾小管间质病变的发病率相当高 ( 19/31;6 1.2 9% ) ,B组 2 4小时尿蛋白排出量明显高于A组 (P <0 .0 5 ) ,两组血肌酐值差别无显著性意义 (P >0 .0 5 )。结论　大量蛋白尿是NS的最主要临床特征 ,但其除作为一种肾脏损害标志外 ,更是一种促进肾病进展的独立危险因子 ,提示大量尿蛋白对肾小管间质的损害作用     

Renal effects of antihypertensive therapy in uninephrectomized diabetic rats

Diabetic nephropathy is a major cause of chronic renal failure. The evidence available indicates that renal hemodynamics are altered in clinical and experimental diabetes mellitus. In these circumstances, an increased glomerular filtration rate (GFR) is associated with albuminuria and eventually with glomerulosclerosis. We studied the renal and hemodynamic effects of long-term treatment (5 months) using an angiotensin-converting enzyme inhibitor (trandolapril, 0.7 mg/g b.w. per day) and a calcium antagonist (verapamil, 20 mg/g b.w. per day), and the combination of the two (veratran) at the same dose, on streptozotocin-diabetic uninephrectomized rats. A moderate degree of hyperglycemia (2–4 g/l) was maintained with daily insulin. Mean arterial pressure (MAP) was measured monthly using the tail-cuff method. Determinations were made of urinary protein excretion, creatinine clearance, urinary electrolyte excretion and, at the end of treatment, renal and cardiac hypertrophy. MAP was similar in control and untreated diabetic rats. Trandolapril and veratran reduced MAP whereas verapamil alone had no effect on these animals. All groups showed a slight proteinuria that increased with verapamil treatment. The GFR of diabetic animals was higher than in the control group (mainly the first 2 months), except for veratran group, in which it was similar to the control value. Urinary electrolyte excretion increased in all diabetic groups with no significant differences among them. Veratran induced a protective effect against cardiac hypertrophy. None of the treatments affected renal hypertrophy. It is concluded that in a murine model of diabetes without hypertension or proteinuria, a combination of verapamil and trandolapril prevents hyperfiltration whereas verapamil alone increases proteinuria.     

Ampicillin and cephalexin in renal insufficiency

We analyzed the relationship between functional damage and transport processes in the kidney in patients with glomerulonephritis and renal failure by a new analytic method. In renal failure patients, there was substantial diminution of maximum transport of secretion in renal tubules. This reduction affected the urinary excretion of ampicillin and cephalexin substantially because both drugs depend on active renal tubular secretion. Our results indicate that dosage adjustment based on creatinine clearance is not appropriate for patients receiving drugs requiring active tubular secretion for urinary excretion. Our data point to a need for a prolongation of the dosage interval of cephalexin to 20 times that in normal subjects, while five times is recommended by the creatinine clearance. In these patients, it is therefore suggested that a dosage adjustment method that involves both factors--glomerular and renal tubular functions--is required.     

Comparative pharmacokinetics of tromethamine fosfomycin and calcium fosfomycin in young and elderly adults.

The pharmacokinetics of two oral forms of fosfomycin, tromethamine (trometamol) salt and calcium salt, were studied in five young (age, 29 +/- 3 [standard deviation] years) and eight elderly (age, 72 +/- 6 years) adults. The subjects received a single 40-mg/kg (body weight) (approximately equal to 3-g) calcium fosfomycin dose and a 25-mg/kg (approximately equal to 2-g) tromethamine fosfomycin dose in fosfomycin acid form. Blood and urine samples were collected for 24 h. Antibiotic concentrations in serum and urine were measured by microbiological assay. In all subjects, the peak levels of the calcium salt in serum were two- to fourfold lower than those of the tromethamine salt (6 to 7 and 18 to 22 micrograms/ml, respectively), indicating poor intestinal absorption of the calcium form. The elimination half-life of the two oral forms was about 5 h in young adults, and the half-life was only moderately longer in elderly subjects, with large individual variations: 8.28 +/- 5.51 h for tromethamine fosfomycin and 11.80 +/- 6.86 h for calcium fosfomycin. In elderly subjects, absorption of the tromethamine salt form was not modified, but the time to peak level was delayed for the calcium salt (2.58 +/- 0.54 h versus 1.41 +/- 0.67 h in young adults). Pharmacokinetic elimination of the two forms of fosfomycin was only moderately affected in elderly subjects; we observed lower urinary elimination, about 58 versus 28% of the dose in 24-h urines for the tromethamine salt and decreased renal clearance of both forms. However, the dosages of tromethamine and calcium fosfomycin need not be adjusted for elderly subjects who have endogenous creatinine clearances above 50 ml/min per 1.73 m2.     

Safety and tolerability of voriconazole in patients with baseline renal insufficiency and candidemia

Acutely ill patients with candidemia frequently suffer from renal insufficiency. Voriconazole's intravenous formulation with sulfobutylether beta-cyclodextrin (SBECD) is restricted in patients with renal insufficiency. We evaluated the use of intravenous voriconazole formulated with SBECD in candidemic patients with renal insufficiency and compared treatment outcome and safety to those who received a short course of amphotericin B deoxycholate followed by fluconazole. We reviewed data on treatment outcome, survival, safety, and tolerability from the subset of patients with moderate (creatinine clearance [CrCl], 30 to 50 ml/min) or severe (CrCl, <30 ml/min) renal insufficiency enrolled in a trial of voriconazole compared to amphotericin B deoxycholate followed by fluconazole for treatment of candidemia in 370 patients. Fifty-eight patients with renal impairment were identified: 41 patients on voriconazole and 17 on amphotericin B/fluconazole. The median duration of treatment was 14 days for voriconazole (median, 7 days intravenous) and 11 days for amphotericin B/fluconazole, 3 days of which were for amphotericin B. Despite the short duration of exposure, worsening of renal function or newly emerged renal adverse events were reported in 53% of amphotericin B-treated patients compared to 39% of voriconazole-treated patients. During treatment, median serum creatinine decreased in the voriconazole arm, whereas creatinine increased in the amphotericin B/fluconazole arm, before return to baseline at week 3. All-cause mortality at 14 weeks was 49% in the voriconazole arm compared to 65% in the amphotericin B/fluconazole arm. Intravenous voriconazole formulated with SBECD was effective in patients with moderate or severe renal insufficiency and candidemia and was associated with less acute renal toxicity than amphotericin B/fluconazole.     

Lack of evidence for interaction between tobramycin and shock in their effect on renal function.

We sought to determine whether there was an interaction between aminoglycoside use and shock in their effect on renal function among seriously ill patients suspected of having gram-negative sepsis. Serial serum creatinine determinations were used to estimate changes in creatinine clearance rates in 179 patients entered onto a prospective randomized trial of tobramycin-nafcillin versus cefotaxime. A 25% decline in estimated creatinine clearance was considered to be clinically important. Univariate chi-square analysis showed that both shock (P less than 0.01) and tobramycin use (P less than 0.001) were independently associated with decline in estimated creatinine clearance. A two-way analysis of variance showed that both shock (F = 10.44, P less than 0.01) and tobramycin use (F = 42.6, P less than 0.001) continued to be significantly associated with renal dysfunction in the presence of each other, but there was no significant interaction between shock and tobramycin in their effect (F = 0.62, P less than 0.43). A multiple logistic regression with an interaction term representing the occurrence of shock and tobramycin use simultaneously yielded similar results. Our study provided no analytic evidence supporting the existence of an interaction between shock and aminoglycoside use in their effect on renal function.