Pharmacokinetics and pharmacodynamics of pegfilgrastim in subjects with various degrees of renal function

A phase I study was conducted to evaluate the effects of renal function on the pharmacokinetics and pharmacodynamics (absolute neutrophil count [ANC]) of pegfilgrastim in nonneutropenic subjects. Thirty subjects categorized into 5 renal function groups (normal, mildly impaired, moderately impaired, severely impaired, and end-stage renal disease) received 1 subcutaneous injection of pegfilgrastim at 6 mg. The ANC profiles after pegfilgrastim administration were similar across different renal function groups. No discernable correlation between pharmacokinetic parameter values and degree of renal impairment was observed; the mean values ranged from 147 to 201 ng/mL for C(max) and from 7469 to 8513 ng x h/mL for AUC. Results suggest that the kidney has no important role in the elimination of pegfilgrastim. Therefore, no dosage adjustment for renal impairment is indicated for pegfilgrastim.     

Tigecycline pharmacokinetics in subjects with various degrees of renal function

The pharmacokinetic parameters of tigecycline were assessed in subjects with severe renal impairment (creatinine clearance <30 mL/min, n = 6), subjects receiving hemodialysis (4 received tigecycline before and 4 received tigecycline after hemodialysis), and subjects with age-adjusted, normal renal function (n = 6) after administration of single 100-mg doses. Serial serum and urine samples were collected and assayed using validated liquid chromatography with tandem mass spectrometer (LC/MS/MS) methods. Concentration-time data were then analyzed using noncompartmental pharmacokinetic methods. Tigecycline renal clearance in subjects with normal renal function represented approximately 20% of total systemic clearance. Tigecycline clearance was reduced by approximately 20%, and area under the tigecycline concentration-time curve increased by approximately 30% in subjects with severe renal impairment. Tigecycline was not efficiently removed by dialysis; thus, it can be administered without regard to timing of hemodialysis. Based on these pharmacokinetic data, tigecycline requires no dosage adjustment in patients with renal impairment.     

Pharmacokinetics of lenalidomide in subjects with various degrees of renal impairment and in subjects on hemodialysis

The present study investigated the effect of renal impairment and hemodialysis on the pharmacokinetics of lenalidomide following a single 25-mg oral dose in 30 subjects aged 39 to 76 years. A single 25-mg dose was well tolerated by renally impaired subjects. Renal impairment did not alter the oral absorption, protein binding, or nonrenal elimination of lenalidomide. Mean urinary recovery of unchanged lenalidomide was 84% of the dose in subjects with normal renal function (creatinine clearance [CL(Cr)] > 80 mL/min), and it declined to 69%, 38%, and 43% in subjects with mild (50 < or = CL(Cr) < or = 80 mL/min), moderate (30 < or = CL(Cr) < 50 mL/min), and severe (CL(Cr) < 30 mL/min) renal impairment, respectively. The differences in pharmacokinetic parameters between normal renal function and mild renal impairment were minor to modest (11%-32%). As renal impairment progressed to moderate, severe, or end-stage renal disease, total and renal lenalidomide clearance decreased drastically, area under the concentration-time curve increased by approximately 185% to 420%, and t((1/2)) was prolonged by approximately 6 to 12 hours. A 4-hour hemodialysis removed 31% of lenalidomide in the body. Therefore, lenalidomide dose adjustments should be considered for patients with CL(Cr) < 50 mL/min, and the recommendations are given for the starting doses.     

Predictive performance study of two digoxin assays in subjects with various degrees of renal function

This prospective study was conducted to compare the predictive performance of fluorescence polarization immunoassay (FPIA, Abbott TDx Digoxin II) and radioimmunoassay (RIA, Kallestad Labs) with combined low-pressure liquid chromatography/RIA (LPLC/RIA) digoxin assay in measuring 15-17 serum digoxin concentrations (SDC) obtained after a single 10 microg/kg intravenous digoxin dose in patients with various degrees of renal function and at different SDC ranges. Eighteen men and women were stratified into 3 age- and gender-matched groups based upon renal function [N = 6 in each, group I (Cl(cr) < 10 mL/min), group II (Cl(cr) = 10-50 mL/min), and group III (Cl(cr) > 50 mL/min)]. Serum digoxin concentrations were measured at time zero; at 0.25, 0.5, 0.75, 1, 2, 3, 4, 6, 8, and 12 hours; and at 2, 3, 4, and 5-7 days after the digoxin dose, using the three different digoxin assays. TDx Digoxin II was unbiased [mean error -0.09 (95% CI -0.19, 0.01)] and RIA biased [mean error -0.29 (95% CI -0.36, -0.21)] to over-predict SDC by 14.2%. In group I patients, the analysis revealed a bias to over-predict SDC by 6.0% for TDx Digoxin II [mean error -0.16 (95% CI -0.29, -0.07)] and an unbiased performance by RIA. In groups II and III, both TDx Digoxin II and RIA showed biased performance, the mean magnitude of bias was low (< 20%). For intermediate SDC range (> 0.5 ng/mL and < or = 3.0 ng/mL), TDx Digoxin II was unbiased in predicting SDC, whereas RIA was biased to under-predict SDC [mean error 0.13 (95% CI 0.10, 0.16)] by 9.9%. The magnitude of bias observed in all cases was less than 20%. Both assays, TDx Digoxin II and RIA, imprecisely measured SDC for all samples combined, different groups and SDC ranges. In all time-paired samples, TDx Digoxin II (FPIA) performed better than the RIA. In conclusion, the magnitude of bias observed with either assay at different groups and SDC ranges was not likely to be clinically relevant. Therefore, either assay may be used to measure SDC in clinical practice.     

Disposition of recombinant human interleukin-10 in subjects with various degrees of renal function.

The pharmacokinetics of intravenously administered recombinant human interleukin-10 (rHuIL-10) were evaluated in 18 subjects with creatinine clearances (Clcr) between 2.7 and 116.7 mL/min/1.73 m2. Serum samples for rHuIL-10 were obtained over a 48-hour period after a single 25 micrograms/kg i.v. bolus infusion. AUC, total body clearance (Clp), and steady-state volume of distribution (Vdss) were derived by compartmental methods. Analysis of serum concentrations showed statistically significant group differences for log-transformed AUC and original scale Clp (p < 0.01). The AUC and effective half-life increased, while the mean Clp of rHuIL-10 decreased as renal function declined. A linear relationship between AUC and Clcr as well as Clp and Clcr demonstrates that the disposition of rHuIL-10 is altered in subjects with renal insufficiency. No serious adverse events were noted.     

Pharmacokinetics of intravenous, single-dose tiotropium in subjects with different degrees of renal impairment

Tiotropium, a new potent anticholinergic bronchodilator, is excreted mainly by the kidney. To investigate the pharmacokinetics of tiotropium in renal impairment, the authors evaluated the pharmacokinetics and safety after administration of a single dose of intravenous tiotropium 4.8 microg, given as an infusion over 15 minutes in subjects with normal renal function and a wide range of renal impairment based on measured creatinine clearance (normal: > 80 mL/min, n = 6; mild impairment: > 50-80 mL/min, n = 5; moderate impairment: 30-50 mL/min, n = 7; severe impairment: < 30 mL/min, n =6). As expected for a drug excreted predominantly in unchanged form by the kidneys, tiotropium plasma concentrations increased as renal impairment worsened, with mean values of 55.5 (16.2 percent geometric coefficient of variation [%gCV]), 77.1 (20.1 %gCV), 101 (29.8 %gCV), and 108 (27.3 %gCV) pgh/mL for AUC(0-4h) in the normal renal function and the mild, moderate, and severe renal impairment groups, respectively. The percentage of tiotropium dose excreted unchanged in the urine decreased from 60.1% of dose (17.7 %gCV) to 59.3% (14.4 %gCV), 39.9% (34.5 %gCV), and 37.4% (10.2 %gCV) in the normal renal function and the mild, moderate, and severe renal impairment groups, respectively. Plasma protein binding of tiotropium did not significantly change in the renal-impaired subjects. Two subjects with normal renal function experienced headache 10 hours after the infusion, which was mild and transient. No adverse events occurred in subjects with renal impairment. There were no clinically relevant changes in blood pressure, pulse rate, 12-lead ECG, physical examination, hematology, or clinical chemistry, compared with baseline values, in any subject after intravenous administration of tiotropium. Tiotropium should only be used in patients with moderate to severe renal insufficiency if the potential benefit outweighs the potential risks.     

Disposition of minoxidil in patients with various degrees of renal function

The disposition of minoxidil was evaluated after a 5 mg oral dose in 24 subjects with various degrees of renal function. Patients were divided into four groups based on a 24-hour ambulatory creatinine clearance (Clcr): Group I (n = 6) Clcr greater than 90 mL/min, Group II (n = 6) Clcr 50-80 mL/min, Group III (n = 5) Clcr of 30-49 mL/min, and Group IV (n = 7) Clcr less than 30 mL/min. Blood and urine samples obtained over 36 hours were analyzed for minoxidil by a high pressure liquid chromatography technique. Maximum plasma concentration (Cmax) and time to reach Cmax did not differ among the four groups. The terminal elimination half-life was prolonged in Group IV subjects (8.87 +/- 6.12 hours) (mean +/- SD) compared to those in Groups I, II and III (1.38 +/- 0.16, 1.99 +/- 0.45 and 2.42 +/- 0.53 hours, respectively). Apparent total body clearance (Clp/F) decreased as renal function declined; Clp/F = 0.82(Clcr) + 21.8, r = 0.739, P = 0.0001. Renal clearance and apparent nonrenal clearance also were significantly correlated with Clcr. The apparent volume of distribution significantly increased as renal function declined. Thus, the disposition of minoxidil is significantly delayed and dosage adjustment may be necessary in patients with renal insufficiency.     

Pharmacokinetics of aspoxicillin in subjects with normal and impaired renal function

The pharmacokinetics of aspoxicillin [2S,5R,6R)-6-[(2R)-2-[(2R)-2-amino-3-(methylcarbamoyl)propionam ido]-2- (p-hydroxyphenyl)acetamido]penicillanic acid) in 10 subjects with normal kidney function and in 20 patients suffering from impaired renal function were examined after an i.v. short-term infusion of 4 g for a period of 20 min. In contrast to available semi-synthetic penicillins, aspoxicillin shows a slightly longer half-life elimination. As the substance is mainly excreted renally, the areas under the curve (AUC) are larger in cases of impaired renal function. Mathematical correlations can be established between the AUC and the renal function parameters creatinine and glomerular filtration rate. Dosage reduction factors are then derived which allow appropriate dosages to be established for the substances under examination. Dosages for differing degrees of impaired renal function are given in tables. Since sufficiently high and long-lasting urine levels are achieved, it is reasonable to use aspoxicillin as treatment of urinary tract infections in patients suffering from end-stage renal failure.     

Pharmacokinetics of glucarpidase in subjects with normal and impaired renal function

Glucarpidase (formerly known as carboxypeptidase G2 or CPG2) is being evaluated for the adjunctive treatment of patients experiencing, or at risk of, methotrexate toxicity attributable to its delayed elimination. Delayed elimination of methotrexate can occur in patients with methotrexate-induced renal toxicity. In this study, glucarpidase pharmacokinetics were assessed in volunteer subjects with normal (n = 8) and severely impaired (n = 4) renal function. Each subject received a single intravenous dose of glucarpidase 50 U/kg (equivalent to 114.5 microg/kg) infused over 5 minutes. The mean maximum serum concentration (C(max)) for glucarpidase in renally impaired subjects was 2.9 microg/mL, the mean half-life (t(1/2)) was 10.0 hours, and the mean area under the serum concentration-time curve from time zero to infinity (AUC(0-infinity)) was 24.5 microg x h/mL. Similar values were found in subjects with normal renal function (mean C(max) 3.1 microg/mL, mean t(1/2) 9.0 hours, and mean AUC(0-infinity) 23.4 microg x h/mL). The results indicated little effect of renal impairment on the serum pharmacokinetics of glucarpidase.     

Pharmacokinetics of naproxen in subjects with normal and impaired renal function

Summary The pharmacokinetics of naproxen after a single oral dose of 250 mg has been studied in 8 subjects with normal renal function and 16 patients with varying degrees of chronic renal insufficiency. Unchanged naproxen and its main unconjugated metabolite, 6-0-desmethylnaproxen, were determined fluorometrically in serum. In healthy subjects the elimination half-life of naproxen was 17.7± 3.0 h (mean±SD) and it was not significantly prolonged in patients with renal failure (18.1±5.3) h. No accumulation of naproxen in serum occurred in uraemic patients. On the contrary, serum drug levels were slightly but significantly lower in patients with severe renal failure. The total body clearance and apparent volume of distribution of naproxen were significantly increased in this group of patients. Decreased binding of naproxen to serum proteins was observed in patients with renal failure. The apparent half-life of desmethylnaproxen was of the same order of magnitude as that of naproxen (18.6± 4.4 h), and was also independent of renal function. A good correlation was found between the area under the curve (AUC), the peak concentration of the metabolite and the serum creatinine concentration. These observations suggest increased metabolism and an increased apparent volume of distribution of naproxen in severe renal failure, probably caused by decreased serum protein binding of the drug. However, it is proposed that in naproxen therapy no adjustment of the dosage regimen is necessary in patients with impaired renal function.     

Pharmacokinetics of ofloxacin in healthy subjects and patients with varying degrees of renal impairment.

The pharmacokinetics of the new fluoroquinolone antimicrobial ofloxacin were studied in 18 subjects with normal renal function or varying degrees of renal impairment, including patients undergoing continuous ambulatory peritoneal dialysis (CAPD) and haemodialysis. Apparent total body and renal clearances declined and elimination half-life increased with decreasing creatinine clearance. CAPD and haemodialysis removed clinically insignificant fractions of ofloxacin body burden over the study period (6-15% and 9-11% of the dose, respectively). The apparent volume of distribution, peak concentration, time to peak concentration, and non-renal clearance were not altered significantly by renal insufficiency. An extended dosing interval of 24-48 h is recommended, depending upon the degree of renal impairment, when creatinine clearance falls below 50 mL/min. In addition, supplemental doses would not appear to be necessary during CAPD and following haemodialysis.     

Pharmacokinetics of tamsulosin in subjects with normal and varying degrees of impaired renal function: an open-label single-dose and multiple-dose study

Objective: This study was performed to estimate whether the pharmacokinetics and safety of tamsulosin, an α_1A-adrenoceptor antagonist for the treatment of symptomatic benign prostatic hyperplasia (BPH), are influenced by impaired renal function. Methods: In an open-label study design, the plasma concentration profile of 0.4 mg tamsulosin p.o. was studied in age-matched groups of male subjects with normal (n = 10), moderately impaired (n = 10), and severely impaired (n = 8) renal function after single-dose administration and in steady state, i.e. after 21 days of multiple-dose administration. Results: The AUC of total, but not of unbound, tamsulosin was correlated to creatinine clearance and α₁-acid glycoprotein plasma levels, and was found to be significantly higher in both groups of subjects with impaired renal function than in controls after single- and multiple-dose administration. However, the pharmacokinetics of total and unbound tamsulosin were comparable for both trial periods. Conclusions: Impaired renal function increases total tamsulosin plasma concentration by approximately 100% after single-dose administration and in steady state. Since active unbound drug levels are not affected, no dose modification is required in symptomatic BPH patients with renal impairment. Received: 25 November 1997 / Accepted in revised form: 20 February 1998     

Gentamicin disposition in young and elderly patients with various degrees of renal function

The effect of aging on the total body clearance, volume of distribution, and half-life of gentamicin was examined in 99 febrile patients with various degrees of renal function. In the 50 patients who were 18 to 64 years old, clearance of gentamicin was 79.0 +/- 27.0 mL/min (mean +/- standard deviation), creatinine clearance was 98.6 +/- 33.3 mL/min, volume of distribution was 0.242 +/- 0.077 L/kg, and half-life was 2.63 +/- 0.90 hours. In the 49 patients who were 65 to 90 years old, these values were 36.9 +/- 16.3 mL/min, 51.2 +/- 21.2 mL/min, 0.244 +/- 0.102 L/kg, and 5.80 +/- 4.13 hours. Significant differences were observed between the two groups for all parameters except volume of distribution. Linear regression revealed good correlations between the disposition characteristics (clearance and elimination-rate constant) of gentamicin and age as well as creatinine clearance. However, there was no apparent relationship between the ratio of gentamicin clearance to creatinine clearance and age (r = .0731). These findings suggest that the disposition of gentamicin is independent of age but dependent on renal function.     

Mechanistic modelling of tesaglitazar pharmacokinetic data in subjects with various degrees of renal function--evidence of interconversion

AIMS

To develop a mechanistic pharmacokinetic (PK) model for tesaglitazar and its metabolite (an acyl glucuronide) following oral administration of tesaglitazar to subjects with varying renal function, and derive an explanation for the increased plasma exposure of tesaglitazar in subjects with impaired renal function.

METHODS

Data were from a 6-week study in subjects with renal insufficiency and matched controls undergoing repeated oral dosing with tesaglitazar (n = 41). Compartmental population PK modelling was employed to describe the PK of tesaglitazar and its metabolite, in plasma and urine, simultaneously. Two hypotheses were tested to investigate the increased exposure of tesaglitazar in subjects with renal functional impairment: tesaglitazar metabolism is correlated with renal function, or metabolite elimination is reduced in renal insufficiency, leading to increased hydrolysis (interconversion) to the parent compound via biliary circulation.

RESULTS

The hypothesis for interconversion was best supported by the data. The population PK model included first-order absorption, two-compartment disposition and separate renal (0.027 l h⁻¹) and metabolic (1.9 l h⁻¹) clearances for tesaglitazar. The model for the metabolite; one-compartment disposition with renal (saturable, V_max = 0.19 μmol l⁻¹ and K_m = 0.04 μmol l⁻¹) and nonrenal clearances (1.2 l h⁻¹), biliary secretion (12 h⁻¹) to the gut, where interconversion and reabsorption (0.8 h⁻¹) of tesaglitazar occurred.

CONCLUSION

A mechanistic population PK model for tesaglitazar and its metabolite was developed in subjects with varying degrees of renal insufficiency. The model and data give insight into the likely mechanism (interconversion) of the increased tesaglitazar exposure in renally impaired subjects, and separate elimination and interconversion processes without dosing of the metabolite.

WHAT IS ALREADY KNOWN ABOUT THIS SUBJECT

• Tesaglitazar, is predominantly metabolized (to an acyl glucuronide of the parent compound) and 20% of given dose is found unchanged in the urine.
• Acyl glucuronides are know to be unstable and can become hydrolysed back to parent compound, a phenomena called interconversion.

WHAT THIS STUDY ADDS

• A likely mechanism (interconversion) for the cause of the increased exposure of tesaglitazar in subjects with impaired renal function.
• A possible modelling framework to evaluate interconversion without dosing of the metabolite based on the simultaneous analysis of plasma and urine data from a group of subjects with varying renal function.
• A mechanistic understanding of the pharmacokinetic properties of tesaglitazar and its metabolite.

     

Pharmacokinetics of meropenem in subjects with renal insufficiency

Summary The pharmacokinetics of IV meropenem (500 mg over 30 min) has been studied in 6 healthy volunteers and 26 patients with various degrees of renal impairment. Blood samples were taken at different times over 24 h in healthy subjects and 36 to 48 h in uraemic patients, and four or five urine samples were collected over 24 or 48 h. Meropenem concentrations in plasma and urine were measured by a microbiological assay.The mean peak plasma concentration of meropenem ranged from 28 to 40 g·ml^–1 and was not affected by the degree of renal impairment. The terminal half-life of meropenem was approximately 1 h in subjects with normal kidney function and it was proportionately increased as renal function decreased. A significant linear relationship between total body clearance and creatinine clearance as well as between renal clearance and creatinine clearance was observed. The mean apparent volume of distribution at steady state was not significantly altered in uraemic patients. The mean cumulative urinary recovery of meropenem in healthy volunteers was 77% of the administered dose and it was significantly decreased in patients with renal impairment. Haemodialysis shortened the elimination half-life, from 9.7 h during the predialysis period to 1.4 h during the dialysis period. The dose of meropenem should be reduced in relation to the decrease in creatinine clearance.     

Pharmacokinetics of ceftriaxone in subjects with renal insufficiency

The pharmacokinetics of ceftriaxone was studied in 14 men and women volunteers with renal insufficiency. Subjects were grouped by renal function: those with end-stage renal disease (CLcr less than 15 mL/min/1.73 sq m) but not receiving dialysis, those with severe renal insufficiency (CLcr 16-30 mL/min/1.73 sq m), and those with moderate renal insufficiency (CLcr 31-60 mL/min/1.73 sq m). Ceftriaxone 1 g as the sodium salt was administered by i.v. infusion over 30 minutes, and blood and urine samples were collected before and up to 48 hours after drug administration. The pharmacokinetic data were described using a nonlinear least-squares computer program. For volunteers with a creatinine clearance of less than 15 mL/min/1.73 sq m, the mean half-life was 15.6 hours. For subjects with a creatinine clearance of 31-60 mL/min/1.73 sq m, the mean half-life was 11.9 hours. Plasma ceftriaxone concentrations measured at the conclusion of the infusion (mean peak concentration 122 +/- 53.1 micrograms/mL) or 24 hours after the infusion (mean concentration 20.2 +/- 6.14 micrograms/mL) were similar in each study group. A dose of ceftriaxone 1 g every 24 hours in patients with renal insufficiency is probably adequate for inhibiting most susceptible gram-positive and gram-negative microorganisms.     

Pharmacokinetics of teduglutide in subjects with renal impairment

Purpose

Teduglutide is a recombinant analogue of human glucagon-like peptide-2 that has recently been approved for the treatment of short bowel syndrome in adults. This study was designed to study the influence of renal function and age on teduglutide pharmacokinetics.

Methods

This was an open-label study with six parallel groups (6 subjects each). Three groups with renal impairment (moderate, severe and end-stage renal disease) were compared to healthy subjects with normal renal function, which were matched to the renal-impaired subjects with respect to demographics. At least two elderly subjects (≥65 years) were enrolled per group. A single dose of 10 mg teduglutide was subcutaneously administered to each subject. Teduglutide plasma concentrations were measured using a validated liquid chromatography method with tandem mass spectrometric detection, and the primary pharmacokinetic variables (AUC_inf and C_max) were calculated.

Results

Area under the concentration versus time curve extrapolated to infinity (AUC_inf) and maximum plasma concentration (C_max) of teduglutide in subjects with end-stage renal disease were approximately 2.59- and 2.08-fold higher, respectively, than those of healthy subjects. The AUC_inf and C_max were also slightly higher in subjects with moderate and severe renal impairment. Comparison of healthy subjects aged <65 years with healthy elderly subjects revealed very similar pharmacokinetics in both subgroups.

Conclusions

In our study population, the primary pharmacokinetic parameters of teduglutide increased with increased severity of renal impairment. These results suggest that the daily dose of teduglutide should be reduced by 50 % in patients with moderate and severe renal impairment and end-stage disease. We found no effect of age on the pharmacokinetics of teduglutide in healthy subjects. The treatment was well tolerated, and there were no safety concerns.     

Pharmacokinetics of maribavir, a novel oral anticytomegalovirus agent, in subjects with varying degrees of renal impairment

The effect of renal function on the pharmacokinetics of maribavir, a novel anticytomegalovirus agent, was evaluated in 12 adults with normal renal function (creatinine clearance [CrCl] >80 mL/min) and 19 adults with renal impairment classified as mild (n = 5), moderate (n = 5), or severe (n = 9), as measured by CrCl 50-80, 30-49, and <30 mL/min, respectively. After a single oral dose of maribavir 400 mg, the pharmacokinetics of maribavir, based on total and unbound plasma concentrations, showed no statistically significant difference between subjects with normal renal function and subjects with mild/moderate or severe renal impairment. Renal impairment was associated with an increase in area under the plasma concentration-time curve (AUC) values for an inactive metabolite of maribavir, VP 44469. Results were consistent with those of previous studies, which showed that very little maribavir was excreted unchanged in urine, whereas about 22% of an oral dose of maribavir is recovered in urine as VP 44469.     

The pharmacokinetics of remoxipride and metabolites in patients with various degrees of renal function.

1. The pharmacokinetics of remoxipride, a new neuroleptic, were investigated in an open study with three parallel groups. Twenty-one patients with severely impaired (ClCr < 25 ml min-1), moderately impaired (ClCr 25-50 ml min-1) and normal (ClCr > 65 ml min-1) renal function were evaluated. A single oral dose of remoxipride hydrochloride 100 mg was administered, and blood and urine were collected over 48 h. Concentrations of remoxipride and metabolites were measured by h.p.l.c. 2. In patients with severely decreased renal function, the AUC and Cmax of remoxipride were increased significantly, and t1/2 was prolonged, as compared with the control patients. The renal clearance and urinary recovery of the unchanged drug were significantly diminished. 3. The unbound fraction of remoxipride in plasma was decreased in patients with renal failure, in association with a disease-related increase in alpha 1-acid glycoprotein. In spite of a 25% recovery of unchanged drug in the urine in patients with normal renal function, the AUC of unbound drug was twice as high in patients with severely impaired renal function. 4. A strong correlation between creatinine clearance and renal drug clearance was observed indicating a direct relationship between kidney function and the renal clearance of remoxipride. 5. Remoxipride was the predominant compound in plasma as well as in urine in patients with severely decreased as well as normal renal function. In patients with severely decrease renal function, remoxipride and all five pharmacologically inactive metabolites showed increased peak plasma concentrations, delayed tmax, increased AUC, prolonged half-lives and decreased renal clearance.