Unaltered dopaminergic modulation of aldosterone secretion in cirrhosis

1. The responses of plasma aldosterone and plasma prolactin concentrations to metoclopramide (10 mg intravenously) were evaluated over 2 h in eight healthy controls and in 23 patients with cirrhosis (10 without and 13 with ascites). Plasma renin activity, glomerular filtration rate and renal sodium excretion were also determined. 2. Metoclopramide did not significantly influence plasma renin activity, whereas both plasma aldosterone and plasma prolactin rose significantly. The incremental areas under the curves did not differ among controls and cirrhotic patients without and with ascites. No significant correlations between plasma prolactin and aldosterone, either under basal conditions or after metoclopramide administration, were found in either controls or patients. 3. Glomerular filtration rate did not change after metoclopramide. Renal sodium excretion in controls and cirrhotic patients without ascites was also unaffected, whereas it decreased significantly in cirrhotic patients with ascites. In the latter, renal sodium excretion was inversely correlated with plasma aldosterone both under basal conditions and after metoclopramide administration. 4. The dopaminergic control of aldosterone secretion does not appear to be significantly altered in cirrhosis. Metoclopramide administration to cirrhotic patients with ascites leads to an increase in plasma aldosterone that may enhance renal sodium retention.     

Effect of chronic renal failure on oxaprozin multiple-dose pharmacokinetics

The effects of renal disease on the steady-state kinetics of oxaprozin were assessed in eight patients on hemodialysis with normal serum albumin levels and eight normal subjects who received six doses. A larger clearance and volume of distribution at steady state for total and unbound oxaprozin occurred in the patients on hemodialysis. The elimination half-lives were not different. The mean total AUC, peak concentration, average steady-state plasma concentration, and trough concentration for total and unbound oxaprozin were decreased in the patients on hemodialysis. These differences are consistent with impaired absorption of oxaprozin in patients on hemodialysis. The higher dose-averaged unbound fraction of oxaprozin in plasma in patients on hemodialysis may be caused by endogenous binding inhibitors. Because clearance was not reduced in patients on hemodialysis, the dose of oxaprozin may not need to be reduced when albumin levels are normal.     

Ganciclovir pharmacokinetics during renal impairment.

Limited information is available concerning the use of ganciclovir (GCV) in patients with severe renal impairment. The pharmacokinetics of GCV were studied in a heart transplant recipient requiring hemodialysis. The total body clearance was calculated to be approximately 5% of that previously reported for patients with normal renal function. GCV was removed by hemodialysis; a single 4-h procedure decreased the concentration in plasma by approximately 50%. GCV can be safely administered to patients with renal insufficiency if concentrations in plasma are monitored.     

Kinetic disposition of intravenous ceftriaxone in normal subjects and patients with renal failure on hemodialysis or peritoneal dialysis.

The kinetic disposition of a single intravenous dose of ceftriaxone (250 to 665 mg) was studied in six normal subjects and nine patients with renal insufficiency and normal hepatic function. In normal subjects, ceftriaxone was eliminated with a t1/2 beta of 5.2 h (range, 4.1 to 5.8). The total body clearance (Qb) was 13.5 ml/kg per h (range, 8.4 to 23.3), and renal clearance was 8.3 ml/kg per h (range, 5.8 to 13.3). In patients with severe renal insufficiency requiring peritoneal or hemodialysis, the mean t1/2 beta was prolonged to 13.4 h (range, 7.7 to 15.8) and the mean Qb was reduced to 6.9 ml/kg per h (range, 3.4 to 12.8). The apparent volumes of distribution (Vc and Vss) were not different from those determined in normal subjects. Peritoneal dialysis did not remove ceftriaxone. The dialysate of three patients on continuous peritoneal dialysis did not contain any measureable ceftriaxone, and the kinetic disposition in these patients was similar to the hemodialysis patients between their dialysis treatment. During a 4-h hemodialysis session, the total body clearance of ceftriaxone was reduced, perhaps secondary to a decrease in hepatic blood flow induced by the hemodialysis procedure. After a 12- or 24-h dose regimen, predicted trough concentrations of ceftriaxone in plasma at steady state derived from kinetic data generated from the study and assuming linear pharmacokinetic behavior were well above the minimum inhibitory concentrations of most sensitive bacteria, suggesting the feasibility of a once-a-day dosage regimen especially for patients with severe renal insufficiency.     

Pharmacokinetics of meropenem in subjects with various degrees of renal impairment.

Five healthy volunteers and 18 patients with various degrees of renal impairment received 500 mg of meropenem intravenously as a 30-min infusion. Five dialysis patients were dosed 2 h prior to hemodialysis, and four of them were also dosed between hemodialysis treatments. Plasma and urine samples were collected for up to 48 h and 12 h, respectively. Concentrations of meropenem and its open ring metabolite ICI 213,689 were determined by high-performance liquid chromatography and radioimmunoassay, respectively. The subjects were divided into four groups with glomerular filtration rates (GFR) of greater than 80, 30 to 80, 5 to 29, or less than 5 ml/min. There were linear correlations between the GFR and the rates for total plasma clearance as well as renal clearance of meropenem (group mean values for total clearance of 186, 74, 53, and 19 ml/min/1.73 m2, respectively). In subjects with normal renal function, nonrenal clearance accounted for approximately 20% of total elimination, increasing to about 50% in patients with GFR between 5 and 29 ml/min/1.73 m2. The terminal half-life of meropenem increased from 0.9 h in the healthy volunteers to 6.8 h in patients with end-stage renal disease. The half-life of ICI 213,689 was 2.31 h in the healthy volunteers and increased to 23.6 h in patients with GFR of 5 to 29 ml/min. In patients with end-stage renal disease, half-lives could not be measured, as concentrations were hardly declining during the 48-h observation period. The area under the concentration-time curve for meropenem increased more than 10-fold. Both meropenem and its open ring metabolite were readily dialyzable, with dialysis clearances of 79 and 81 ml/min/1.73 m2, respectively.     

Ceftriaxone pharmacokinetics in patients with various degrees of renal impairment

The effects of renal impairment on the pharmacokinetics of ceftriaxone in humans were examined after intravenous infusion of a 1-g dose over 15 min to 30 renally impaired patients. The study included 12 dialysis patients and 18 patients with severe, moderate, or mild renal impairment. Plasma and, where appropriate, urine and dialysate samples were collected at predetermined times and analyzed for ceftriaxone by high-pressure liquid chromatography. The elimination half-life (group mean ranged from 11.7 to 17.3 h) and plasma clearance (group mean ranged from 529 to 705 ml/h) did not correlate linearly with creatinine clearance. The renal clearance and fraction of dose excreted unchanged in urine were related linearly, however weakly, with creatinine clearance. Ceftriaxone was not removed from plasma to a significant extent during hemodialysis. The half-life was prolonged twofold, the plasma clearance was lowered less than 50%, and the volume of distribution was relatively unchanged in renally impaired patients compared with young or elderly healthy subjects with normal renal function at an equivalent dose. Since these changes are moderate, adjustment in the dosage regimen of ceftriaxone for patients with impaired renal function should not be necessary when ceftriaxone dosage is 2 g or less per day (2 g every 24 h or 1 g every 12 h). It was reported that the elimination half-life of ceftriaxone is substantially prolonged in a small percentage of patients with end-stage renal disease maintained on hemodialysis. Therefore, plasma concentrations of ceftriaxone should be monitored in dialysis patients to determine whether dosage adjustments are necessary.     

Plasma and urinary amino acids in primary gout, with special reference to glutamine

Measurement of the plasma free amino acids by column chromatography (AutoAnalyzer) in 32 patients with primary gout showed statistically significant increases or decreases in several components when compared with the spectrum in 18 control subjects, but the absolute amounts involved were small and the mean total plasma amino acid concentrations in both groups were the same. In the urine all major amino acid components, notably glutamine, serine, threonine, and leucine, were lower in our gouty than in our nongouty subjects, as were also the corresponding renal clearance ratios. These deficits could be reproduced by restricting dietary protein, so appear to be due largely to the some-what reduced mean dietary protein intake of our gouty subjects. However, the low renal clearance of glutamine, the most striking and consistent of the deficits in urinary amino acids noted, could not be accounted for by dietary or other relevant factors, and is interpreted as indicating increased tubular reabsorption of glutamine in primary gout. This interpretation was supported by the results of glutamine loading. The possible compensatory relationship of the abnormality in renal handling of glutamine to the deficiency in renal production of ammonia previously reported is discussed.     

Effect of metoclopramide on dopamine-induced changes in renal function in healthy controls and in patients with renal disease

1. The effects of intravenous metoclopramide on baseline values and dopamine dose-response curves for renal haemodynamics and natriuresis were investigated in healthy volunteers and patients with renal disease. 2. Dopamine infusion alone, in doses ranging from 0.25 to 8 micrograms min-1 kg-1, resulted in a dose-dependent increase in effective renal plasma flow (ERPF) and glomerular filtration rate (GFR) with a fall in filtration fraction (FF) in eight hydrated healthy volunteers and, to a lesser degree, in 12 patients with renal disease. An increase in natriuresis (urinary excretion of sodium, UNa+V), fractional excretion of sodium (FENa+) and diuresis (urine flow rate, UV) was found in both groups for doses of 2 micrograms min-1 kg-1 and higher. 3. Metoclopramide infusion did not alter baseline values of GFR, ERPF or FF, but shifted the dopamine dose-response curve for ERPF and FF in the healthy volunteers. Metoclopramide induced a fall in UNa+V and FENa+ in both groups (fall in baseline FENa+ from 1.52 to 0.71 during metoclopramide in healthy volunteers and from 1.23 to 0.56 in patients; P less than 0.01) and blunted the natriuretic response to subsequent dopamine infusion. The fall in UNa+V during metoclopramide infusion showed a strong correlation with baseline GFR (r = -0.944). In the patients, the response for the fractional excretions of beta 2-microglobulin and gamma-glutamyltransferase was comparable with that of FENa+. 4. Dopamine infusion induced a fall, and metoclopramide led to rise, in plasma aldosterone concentration. 5. We conclude that metoclopramide acts as a dopamine antagonist at the renal level in man.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pharmacokinetics of ampicillin (2.0 grams) and sulbactam (1.0 gram) coadministered to subjects with normal and abnormal renal function and with end-stage renal disease on hemodialysis.

The single-dose pharmacokinetics of intravenously administered ampicillin (2.0 g) and sulbactam (1.0 g) were studied in normal subjects and in patients with various degrees of creatinine clearance (CLCR). Six normal subjects (CLCR, greater than 60 ml/min), six patients with mild renal failure (CLCR, 31 to 60 ml/min), four patients with severe renal failure (CLCR, 7 to 30 ml/min), and four patients requiring maintenance hemodialysis (CLCR, less than 7 ml/min) were studied. The terminal half-lives for ampicillin and sulbactam more than doubled in patients with severe renal failure compared with subjects with normal renal function and mild renal insufficiency. CLCR significantly correlated with ampicillin (r = 0.88) and sulbactam (r = 0.54) total body clearance. Mean steady-state volume of distribution and nonrenal clearance for ampicillin and sulbactam were not affected by renal function. Hemodialysis approximately doubled the ampicillin and sulbactam total body clearance. Mean totals of 34.8 +/- 4.0% of the ampicillin dose and 44.7 +/- 3.2% of the sulbactam dose were removed during a 4-h hemodialysis treatment. A slight rebound in concentrations in serum after hemodialysis was observed for both drugs in all four subjects. In hemodialysis patients, the ampicillin half-life was 17.4 +/- 8.0 h and the sulbactam half-life was 13.4 +/- 7.4 h. The ampicillin and sulbactam half-lives were appreciably altered during the hemodialysis period (means of 2.2 and 2.3 h, respectively). The nearly parallel decrease in total body clearance, with volume of distribution and nonrenal clearance remaining relatively constant, suggests that the same ratio of ampicillin to sulbactam is appropriate regardless of renal function. An adjustment of the ampicillin (2.0 g) and sulbactam (1.0 g) dose to twice daily would be appropriate in patients with a CLCR between 7 and 30 ml/min. Doses should be given every 24 h for those undergoing maintenance hemodialysis. On hemodialysis days, doses should be given after hemodialysis.     

Pharmacokinetics of meropenem in patients with various degrees of renal function, including patients with end-stage renal disease.

The pharmacokinetics of meropenem were studied after intravenous infusion in 13 patients grouped according to the impairment of their renal function. Creatinine clearance (CLCR) was greater than 50, 50 to 30, and less than 30 ml/min in groups I, II, and III, respectively. Two other groups, groups IV and V, each comprising four patients with end-stage renal disease (CLCR, < 5 ml/min), were also studied, the former on days off of hemodialysis and the latter on days of hemodialysis. The elimination half-lives of meropenem were 1.54 +/- 0.70 h in group I patients, 3.36 +/- 1.02 h in group II patients, and 5.00 +/- 1.05 h in group III patients. Cumulative urinary excretion accounted for 48.5% of the dose in group I patients and decreased progressively with a decline in renal function. Hemodialysis shortened the elimination half-life of meropenem from 7.0 h to 2.9 h. H-4295, the main metabolite of meropenem, had a peak level in plasma of 0.5 to 1.0 h in patients with renal failure. The level of H-4295 decreased with hemodialysis. The dosing interval of meropenem should be prolonged in a regular proportion to the decline in CLCR (12 h in group II patients and 24 h in group III patients). In patients receiving hemodialysis, dosing after each hemodialysis session is recommended.     

Pharmacokinetics of telbivudine in subjects with various degrees of renal impairment

This study evaluates the effect of renal impairment on the pharmacokinetics of telbivudine. Thirty-six subjects were assigned, on the basis of creatinine clearance (CL(CR)), to 1 of 5 renal function groups with 6 to 8 subjects per group: normal renal function; mild, moderate, or severe renal impairment; or end-stage renal disease [ESRD] requiring hemodialysis. Subjects received a single oral dose of telbivudine at 600 mg (normal function and mild impairment), 400 mg (moderate impairment), or 200 mg (severe impairment and ESRD); plasma and/or urine samples were collected over a 48-h period for pharmacokinetic analyses. Telbivudine was well tolerated by all subjects. The pharmacokinetics of 600 mg of telbivudine were comparable for subjects with mild renal impairment and normal renal function. Likewise, for subjects with moderate to severe impairment, including ESRD, reduced doses from 200 to 400 mg produced plasma exposure similar to that for subjects with normal renal function. These results indicate that the pharmacokinetics of telbivudine were dependent on renal function, especially for subjects with moderate to severe renal impairment or ESRD. Apparent total plasma clearance, renal clearance (CL(R)), and urinary excretion of telbivudine decreased as renal function deteriorated. A linear relationship was established between CL(R) and CL(CR). In ESRD subjects, a routine 3.5- to 4-h hemodialysis session removed telbivudine from plasma at an extraction ratio of approximately 45%, representing a approximately 23% reduction in total exposure. These results suggest that while no adjustment of the telbivudine dose appears necessary for subjects with mild renal impairment, dose adjustment is warranted for those with moderate to severe renal impairment or ESRD in order to achieve optimal plasma exposure.     

Metoclopramide decreases renal plasma flow

Intravenous dopamine has been shown to increase renal plasma flow in man. The role of endogenous dopamine in the maintenance of renal plasma flow has not been described. We speculated that if endogenous dopamine activity is important in the maintenance of renal plasma flow, then high doses of a potent dopamine blocking drug such as metoclopramide would decrease renal flow. To test this hypothesis, we measured renal plasma flow using a single-injection technique with 131I-labeled orthoiodohippurate. Measurements were made before and after the administration of high doses of metoclopramide (1 to 2.5 mg/kg) to 20 patients receiving metoclopramide as an antiemetic before chemotherapy. Seven control subjects underwent sequential measurements of renal plasma flow without intervening metoclopramide dosing. Mean (+/- SD) renal plasma flow did not change in the control population (from 441 +/- 198 to 437 +/- 117 ml/min), but declined significantly in the patients who received metoclopramide (443 +/- 115 ml/min before metoclopramide and 387 +/- 137 ml/min after metoclopramide; P less than 0.001). In 25% of our study population the decline in renal plasma flow was greater than 20% below baseline levels. The magnitude of the effect did not appear to correlate with the pretreatment creatinine clearance, age, or sex of the patients. We conclude that high doses of metoclopramide decrease renal plasma flow in man. These data suggest a role for dopamine in the maintenance of renal plasma flow in patients receiving intravenous hydration. Changes of the magnitude we observed may well be of clinical importance. These findings therefore also suggest the possibility of metoclopramide potentiation of cisplatin nephrotoxicity.     

Temafloxacin pharmacokinetics in subjects with normal and impaired renal function.

The pharmacokinetics of temafloxacin were investigated following oral administration of single 400-mg doses to 6 normal subjects and 18 subjects with various degrees of impaired renal function. Renal impairment did not significantly affect the peak concentration, time to peak concentration, or the nonrenal clearance of temafloxacin. Both renal clearance (CLR) and total apparent clearance (CLT/F, where F represents the fraction of dose absorbed) of temafloxacin were highly correlated with creatinine clearance (CLCR). The regression equations were as follows: CLR = 0.85.CLCR, with R2 = 0.907, and CLT/F = 56.0 + 0.92.CLCR, with R2 = 0.656. The half-life (mean +/- standard deviation) increased from 10.6 +/- 2.4 h in the normal volunteers to 24.6 +/- 7.3 h in the subjects with a CLCR of less than 10 ml/min; the respective CLT/F decreased from 169 +/- 58 to 70 +/- 27 ml/min. Compared with the CLT/F in the subjects with normal renal function, CLT/F was reduced 60% in subjects with a CLCR of less than 40 ml/min, indicating that the dosage should be reduced by at least one-half for patients with comparable impairment. For the subjects on chronic hemodialysis, most of the variability in the nonrenal clearance and the terminal-phase rate constant of temafloxacin was associated with the quantity of calcium carbonate and related medication taken for the treatment of hyperphosphatemia. Supplemental dosage is not required for patients undergoing hemodialysis, since the distribution of temafloxacin in tissue is extensive and the recoveries from 4-h dialysis sessions accounted for less than 10% of the drug present at the start of the dialysis.     

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.     

Pharmacokinetics of linezolid in subjects with renal dysfunction

Linezolid is a member of a new, unique class of synthetic antibacterial agents called oxazolidinones that are effective against gram-positive bacteria, including vancomycin-resistant organisms. We tested the hypothesis that the linezolid clearance would not be altered in subjects with renal dysfunction. Twenty-four subjects with renal function that ranged from normal to severe chronic impairment were enrolled, including patients with end-stage renal disease who were maintained on hemodialysis. Hemodialysis subjects were studied while they were both on and off dialysis. Linezolid was administered as a single oral 600-mg dose, and plasma and urine samples were assayed for linezolid and metabolites for 48 h for all subjects and for up to 96 h for those subjects with impaired renal function not on dialysis. The total apparent oral clearance of linezolid did not change with renal function and ranged from 92.5 to 109.6 ml/min for subjects not requiring dialysis. For subjects on dialysis, the total apparent oral clearance increased from 76.6 ml/min on their off-dialysis day to 130.0 ml/min on their on-dialysis day. Approximately one-third of the dose was removed by dialysis. However, those subjects with severe renal insufficiency (creatinine clearance, <40 ml/min) and those with end-stage renal disease maintained on hemodialysis had higher concentrations of both metabolites. We conclude that no adjustment of the linezolid dosage is needed in subjects with renal dysfunction or subjects on hemodialysis.     

Pharmacokinetics of intravenous amdinocillin in healthy subjects and patients with renal insufficiency.

Five healthy volunteers and 31 patients with various degrees of renal impairment received a 10-mg/kg intravenous dose of amdinocillin by infusion over 15 min to establish the disposition profile of the drug in plasma and urine. Both clearance from plasma and elimination rate constant showed a linear relationship with creatinine clearance. It was noted that in subjects with creatinine clearances of greater than 50 ml/min, the elimination half-life remained relatively constant; however, as the creatinine clearance decreased from 50 to 5 ml/min, there was a progressive rise in the elimination half-life. Despite the removal of the drug by hemodialysis (32 to 72% of the dose), concentrations of amdinocillin in plasma remained in the therapeutic range. In patients undergoing peritoneal dialysis, less than 4.0% of the infused dose was removed by dialysis during the hourly exchanges over a 14- to 18-h period. Although the clearance from plasma and the half-life of amdinocillin were altered up to fourfold in patients with creatinine clearances of less than 15 ml/min, the amdinocillin dosage per se may not need to be reduced for these patients if the frequency of dosing is reduced from six to three or four times daily. This is based on drug accumulation estimates of 56% from a regimen of 10 mg/kg every 8 h in these patients as compared with less than 10% from a regimen of 10 mg/kg every 4 h in subjects with normal renal function. In addition, supplemental doses may not be necessary during or at the end of hemodialysis for patients undergoing hemodialysis.     

Elimination of enoxacin in renal disease

The elimination of enoxacin was investigated in 15 subjects, 10 of whom were hospital outpatients with renal disease and varying degrees of renal impairment. Each was given enoxacin orally (200 mg b.i.d.) for 7 days. Blood specimens collected over 24 hours after the final dose of enoxacin and urine collected during the 12-hour dose interval after the final dose were assayed for enoxacin by HPLC. The elimination half-life of enoxacin increased with worsening renal function. In general, patients with diminished renal function had lower plasma enoxacin clearance values than had normal subjects, and a statistically significant correlation between apparent oral clearance and creatinine clearance was observed. Excretion of enoxacin by the kidney accounted for 26% to 72% of the apparent plasma clearance in normal subjects. This was markedly reduced in patients with severe renal failure.     

Isepamicin disposition in subjects with various degrees of renal function.

The disposition of isepamicin, an investigational aminoglycoside antibiotic, was evaluated in 30 subjects with various degrees of renal function. The subjects were divided into five groups: those with normal renal function (creatinine clearance [CLCR], greater than 80 ml/min/1.73 m2), those with mild renal insufficiency (CLCR, 50 to 80 ml/min/1.73 m2), those with moderate renal insufficiency (CLCR, 30 to 49 ml/min/1.73 m2), those with severe renal insufficiency (CLCR, 5 to 29 ml/min/1.73 m2), and those maintained on hemodialysis (CLCR, less than 5 ml/min/1.73 m2). Subjects on hemodialysis were studied both during hemodialysis and during an interdialytic period. The volumes of distribution of isepamicin were not significantly different among the five groups of patients. The total body clearance (CLP) and renal clearance (CLR) of isepamicin significantly decreased as CLCR decreased. The CLP of isepamicin and CLCR were significantly related [(COP = 0.391.[CLCR] + 1.83; r2 = 0.878)]. Nonrenal clearance of isepamicin did not differ between groups. Hemodialysis augmented the CLP of isepamicin by approximately 25-fold. The amount of isepamicin recovered in the dialysate was 60.6 +/- 15.8% of the dose administered. The maximal rebound of the isepamicin concentration in plasma after cessation of hemodialysis was observed at 0.78 +/- 0.7 h. Concentrations in plasma increased 32.7 +/- 22.9% over that measured at the end of hemodialysis. These data indicate that dosage adjustments are necessary in subjects with decreased renal function.     

Pharmacokinetics of imipenem-cilastatin in patients with renal insufficiency undergoing continuous ambulatory peritoneal dialysis.

In six patients with end-stage renal disease, a single bolus of imipenem-cilastatin (500 mg each) was given either intravenously or intraperitoneally in a randomized crossover protocol such that each patient received the drug by both routes at a 2- to 3-week interval. Drug levels in plasma and the peritoneal dialysis fluid were analyzed at frequent intervals, and various pharmacokinetic variables were calculated for a one-compartment open model. Data obtained in the present study suggest that while no significant difference in peak plasma levels or volume of distribution were noted, the following variables were significantly different for imipenem as compared with cilastatin: elimination half-life, total plasma clearance, area under the concentration-time curve, and percent drug excretion in the peritoneal dialysis fluid. The elimination half-life of imipenem (3.28 h) or cilastatin (8.84 h) in our patients was in the same range as observed in patients with minimal renal function undergoing hemodialysis. The dose of imipenem-cilastatin should be reduced appropriately in patients with end-stage renal disease undergoing peritoneal dialysis.     

Cefmenoxime pharmacokinetics in healthy volunteers and subjects with renal insufficiency and on hemodialysis.

The pharmacokinetics of cefmenoxime were characterized in five healthy volunteers and in 15 subjects with various degrees of renal insufficiency after a single 10-mg/kg, 5-min intravenous infusion. Five of these subjects were studied both on hemodialysis and during an interdialytic period. Plasma, urine and dialysate were assayed for cefmenoxime by a specific high-pressure liquid chromatographic assay. Peak plasma concentrations of cefmenoxime were ca. 94 micrograms/ml after completion of the infusion. The mean plasma and renal clearances in the healthy volunteers were 281 +/- 66 and 228 +/- 52 ml/min, respectively. Plasma clearance declined in patients with renal insufficiency and correlated significantly with creatine clearance. The mean apparent volume of distribution at steady state in the healthy volunteers was 0.23 liters/kg and was not found to be significantly different in subjects with renal insufficiency. The mean cumulative 24-h urinary recovery of cefmenoxime in healthy volunteers was 81% of the administered dose and decreased with reduced renal function. Cefmenoxine dosage should be reduced in proportion to the decline in creatinine clearance. A simple nomogram for dose selection is provided.