Both phenolic and acyl glucuronidation pathways of diflunisal are impaired in liver cirrhosis

Summary The pharmacokinetics of diflunisal, a salicylate derivative that undergoes phenolic and acyl glucuronidation as well as sulphate conjugation, has been studied after a single oral dose (250 mg) in patients with cirrhosis (n=5) and in healthy controls (n=5).The plasma clearance of total (bound + unbound) diflunisal was 10.2 ml · min^–1 in the control subjects and it was not affected by cirrhosis (10.9 ml · min^–1). The plasma protein binding of diflunisal was significantly reduced in cirrhosis; the percentage of unbound diflunisal in plasma was 0.089 in the controls and 0.147 in the patients with cirrhosis. Plasma clearance of unbound diflunisal was significantly impaired in cirrhosis: 11.51 · min^–1 in control subjects vs 7.41 · min^–1 in cirrhotics.In cirrhotic patients, the unbound partial clearances to the phenolic and acyl glucuronides were both significantly reduced, by approximately 38%. The unbound partial clearance to the sulphate conjugate was not significantly affected by cirrhosis.The results show that both the phenolic and acyl glucuronidation pathways of diflunisal are equally susceptible to the effects of liver cirrhosis.     

Lack of relationship between tolbutamide metabolism and debrisoquine oxidation phenotype

Summary The oxidative metabolism of tolbutamide was studied in 13 healthy subjects of known debrisoquine phenotype. Three were poor (PM) and ten were extensive (EM) metabolisers of debrisoquine.The mean values for total plasma clearance, elimination half-life, and metabolic clearance were 0.26 ml·min^–1·kg^–1, 3.4 h, and 0.17 ml·min^–1. kg^–1 in PM subjects and 0.22 ml·min^–1·kg^–1, 4.3 h and 0.15 ml·min^–1·kg^–1 in EM subjects. Total urinary recovery (% of dose) and ratio of hydroxy- to carboxytolbutamide were 69.4% and 0.219 respectively in PM subjects and 70.9% and 0.226 in EM subjects. There were no statistically significant differences between EM and PM metabolisers for any of these parameters. In addition there was no correlation between the debrisoquine metabolic ratio and tolbutamide urinary metabolite recovery or plasma clearance.These data indicate that hydroxylation of debrisoquine and tolbutamide are not catalyzed by the same enzyme.The ratio of hydroxy- to carboxytolbutamide in our subjects, and in other recent studies, suggests that some previous publications were inaccurate and their conclusions about the genetic control of tolbutamide metabolism were incorrect.     

The effect of probenecid on paracetamol metabolism and pharmacokinetics

Summary The influence of probenecid on the pharmacokinetics of paracetamol was investigated in a group of healthy volunteers.Pretreatment with probenecid caused a significant decrease in paracetamol clearance (6.23 to 3.42 ml·min^–1·kg^–1). The urinary excretion of paracetamol sulphate (243 to 193 mg); and paracetamol glucuronide (348 to 74.5 mg) were significantly reduced, whereas that of paracetamol was unchanged.Probenecid was shown to be an uncompetitive inhibitor of paracetamol glucuronidation in vitro, using rat liver microsomes.     

Effect of probenecid on the formation and elimination kinetics of the sulphate and glucuronide conjugates of diflunisal

The effect of probenecid on the pharmacokinetics of diflunisal and its glucuronide and sulphate conjugates was studied in 8 healthy volunteers. Diflunisal 250 mg b. d. was administered p. o. for 15 days and its steady state pharmacokinetics was evaluated on Day 16 after the last dose (control phase). Probenecid 500 mg b. d. was co-administered throughout the entire study period in the treatment phase of the study.The steady state plasma concentration of diflunisal was significantly higher during the probenecid treatment phase as compared to the control phase (104.0 vs. 63.1 g·ml^–1). This was the result of a significant decrease in the plasma clearance of diflunisal from 5.8 (control) to 3.4 ml·min^–1 (probenecid co-administration). The metabolite formation clearances of both glucuronides were significantly decreased by probenecid, -45 % and -54 % for the phenolic and acyl glucuronide, respectively. The metabolite formation clearance of the sulphate conjugate was not affected by probenecid co-administration.Steady state plasma concentrations of the sulphate and glucuronide conjugates of diflunisal were 2.5- to 3.1-fold higher during probenecid co-administration, due to a significant reduction in the renal clearance of the three diflunisal conjugates. Probenecid also reduced the plasma protein binding of diflunisal, but only to a minor extent; the unbound plasma fraction of diflunisal at steady state averaged between 5 and 30 % higher during probenecid co-administration.     

Effect of antipyrine coadministration on the kinetics of acetaminophen and lidocaine

Summary Pharmacokinetic interactions between antipyrine and acetaminophen were evaluated in 7 healthy volunteers. On 3 occasions subjects received:1, antipyrine 1.0 g intravenously (i.v.);2, acetaminophen 650 mg i.v.;3, antipyrine 1.0 g and acetaminophen 650 mg i.v. simultaneously.Between Trials 1 and 3, antipyrine elimination t_1/2 (17.2 vs 17.4 h), clearance (0.44 vs 0.43 ml·min^–1·kg^–1) and 24-h recovery of antipyrine and metabolites (313 vs 293 mg) did not differ significantly. Between Trials 2 and 3, acetaminophen V_z was reduced (1.14 vs 1.00 l·kg^–1), t_1/2 prolonged (2.7 vs 3.3 h), clearance reduced (4.8 vs 3.6 ml·min^–1·kg^–1), and fractional urinary recovery of acetaminophen glucuronide reduced.Eight additional subjects received 50 mg of lidocaine hydrochloride i.v. in the control state, and on a second occasion immediately after antipyrine 1.0 g given i.v.The two trials did not differ significantly in lidocaine V_z (2.6 vs 2.7 l·kg^–1), t_1/2 (2.0 vs 2.4 h) or clearance (15.0 vs 13.5 ml·min^–1·kg^–1).Although acetaminophen does not alter antipyrine kinetics, acute administration of antipyrine appears to impair acetaminophen clearance, possibly via inhibition of glucuronide formation. However, antipyrine has no significant effect on the kinetics of a single i.v. dose of lidocaine.     

The effect of a low dose of quinidine on the disposition of flecainide in healthy volunteers

Summary We have studied the effects of quinidine on ECG intervals and on the pharmacokinetics of flecainide and its two metabolites in 6 healthy men in an open randomized crossover study. Flecainide acetate (150 mg) was given as a constant rate i. v. infusion over 30 min.Quinidine (50 mg orally), given the previous evening, did not change the volume of distribution of flecainide (7.9 vs 7.41·kg^–1), but significantly increased its half-life (8.8 vs 10.7 h). This was attributable to a reduction in total clearance (10.6 vs 8.1 ml·min^–1·kg^–1), most of it being accounted for by a reduction in non-renal clearance (7.2 vs 5.2 ml·min^–1·kg^–1). The excretion of the metabolites of flecainide over 48 h was significantly reduced.These findings suggest that quinidine inhibits the first step of flecainide metabolism, although it may also reduce its renal clearance, but to a lesser extent (3.5 vs 2.9 ml·min^–1·kg^–1).The effects of flecainide on ECG intervals were not altered by quinidine.Thus, quinidine tends to shift extensive metabolizer status for flecainide towards poor metabolizer status and may also alter its renal excretion.     

Polymorphic 2-hydroxylation of desipramine

Summary We have studied the clearance of monomethylaminoantipyrine (MMAAP), the pharmacologically active form of metamizol, in 46 patients in surgical intensive care with different degrees of renal dysfunction.In 23 patients without any renal impairment, mean clearance was 2.8 ml·min^–1·kg^–1. Twentyone patients with acute renal impairment had a significantly reduced clearance of MMAAP (0.83 ml·min^–1·kg^–1). There was also reduced clearance in four patients with septic shock (1.0 ml·min^–1·kg^–1).Kinetics of the metabolites of MMAAP (N-formylaminoantipyrine (FAAP), aminoantipyrine (AAP), and its secondary product N-acetylaminoantipyrine (AcAAP)) were calculated. FAAP and AcAAP showed delayed invasion, which can be explained by reduced hepatic metabolic activity. The product of N-demethylation, AAP, was not significantly altered.The delayed elimination of monomethylaminoantipyrine can be explained by reduced hepatic function in parallel with acute renal failure due to disturbed cardiovascular function caused by septic shock. This may also lead to disturbed hepatic macro- and microperfusion associated with altered oxygen supply and oxygen consumption.     

Bioavailability and pharmacokinetics of oxazepam

Summary Six healthy volunteers received oxazepam 15 mg i.v. and orally at an interval of at least one week. The kinetic variables of i.v. oxazepam were: elimination half-life (t_1/2) 6.7 h, total clearance (CL) 1.07 ml·min^–1·kg^–1, volume of distribution (V_c) 0.27 l·kg^–1 (0.21–0.49) and volume of distribution at steady-state (V_ss) 0.59 l·kg^–1. The intravenous disposition of unbound oxazepam was characterized by a clearance of 22.5ml·min^–1·kg^–1 and a distribution volume of 12.3 l·kg^–1. After oral oxazepam the peak plasma level was reached in 1.7 to 2.8 h. The plasma t_1/2 at 5.8 h was not significantly different from the i.v. value. Absorption was almost complete, with a bioavailability of 92.8%. Urinary recovery was 80.0 and 71.4% of the dose after intravenous and oral administration, respectively. Renal clearance (CL_R) of the glucuronide metabolite was 1.10 ml·min^–1·kg^–1 (0.98–1.52). Oxazepam was extensively bound to plasma protein with a free fraction of 4.5%.     

Sex-related differences in theophylline pharmacokinetics

Summary Theophylline pharmacokinetic parameters were compared in healthy males and healthy premenopausal females who were matched for age and smoking status. Twenty-four subjects (including five smokers and seven non-smokers of each sex) received a single dose of aminophylline 6 mg·kg^–1, orally or by intravenous infusion. Theophylline half-life was significantly shorter in female non-smokers (FNS) versus male non-smokers (MNS), (FNS=6.0 h; MNS=9.3 h), and in female smokers (FS) versus male smokers (MS), (FS=4.6 h; MS=6.3 h). Total body clearance was significantly different in FNS versus MNS, (FNS=43.8 ml·min^–1·^–1.73 m^–2; MNS=37.4 ml·min^–1·1.73 m^–2), but did not reach statistical significance in FS vs. MS, (FS=64.2 ml·min^–1·l^–1·1.73 m^–2; MS=53.1 ml·min^–1·1.73 m^–2). Volume of distribution did not differ significantly between groups.Sex differences in theophylline pharmacokinetics exist and may reflect differences in drug metabolism.     

Diurnal variation of methotrexate disposition in children with acute leukaemia

Summary There is recent evidence that survival is improved when maintenance therapy for acute lymphocytic leukaemia in children is given at night. We have examined the possibility that diurnal variation in methotrexate pharmacokinetics may contribute to this improvement.In 6 children with leukaemia there was a significant fall in methotrexate plasma clearance at night (from 5.6 to 4.7 ml·kg^–1·min^–1). Renal clearance of methotrexate tended to fall at night and unbound renal clearance fell significantly (from 17.5 to 8.5 ml·min^–1·kg^–1 P<0.05). Creatinine clearance did not exhibit diurnal variation, whereas there was a significant fall in the non-glomerular clearance of methotrexate (from 14.8 to 6 ml·min^–1·kg^–1).Since methotrexate is a weak organic acid, its tubular secretion depends on urinary pH. At night urinary pH is more acidic, and this may result in more reabsorption and hence reduced renal clearance.     

Pharmacokinetics of ranitidine in patients undergoing haemofiltration

Summary The pharmacokinetics of ranitidine was investigated in 11 patients with acute or end stage renal failure during haemofiltration. Each patient received 50 mg ranitidine i.v.The mean distribution and elimination half lives were 0.13 and 2.57 h, respectively. The total body clearance (CL) and volume of distribution (V_z) were 298 ml·min^–1 (5.19 ml·min^–1·kg^–1) and 1.081·kg^–1, respectively. About 17.1% of the administered dose was removed by haemofiltration (in approximately 201 filtrate). Five of the patients still had some urine output and they excreted 0.1 to 11.8% of the dose in urine in 24 h. The haemofiltration clearance was 66.9 ml·min^–1 at a filtrate flow rate of 86 ml·min^–1, corresponding to a mean sieving coefficient of 0.78 (n=6). As plasma concentrations were still in an effective range after haemofiltration, dose supplementation is not recommended.     

Polymorphic flecainide disposition under conditions of uncontrolled urine flow and pH

Summary The pharmacokinetics of R- and S-flecainide have been determined in five poor (PM) and five extensive (EM) metabolisers of sparteine/debrisoquine under conditions of uncontrolled urine flow and pH. The half-lives of R- and S-flecainide in PMs (R 19.3 h; S 16.1 h) were approximately twice those observed in EMs (R 8.8 h; S 9.1 h). The apparent oral clearances of R- and S-flecainide were lower in PMs (R 313 ml·min^–1; S 379 ml·min^–1) than in EMs (R 783 ml·min^–1; S 828 ml·min^–1). The renal clearance, however, was comparable for both enantiomers in both EMs and PMs, and therefore the phenotypic differences in flecainide disposition observed must be due to differences in metabolic clearance. The nonrenal clearance of both enantiomers was significantly lower in poor (R 123 ml·min^–1; S 201 ml·min^–1) relative to extensive metabolisers (R 533 ml·min^–1; S 586 ml·min^–1). The partial clearance to the two major metabolites meta-O-dealkylated flecainide (MODF) and the meta-O-dealkylated lactam of flecainide (MODLF) was significantly lower in poor (62 ml·min^–1) than extensive (267 ml·min^–1) metabolisers.The impairment in flecainide metabolism in poor metabolisers of sparteine/debrisoquine has therefore been confirmed. Under conditions reflecting the clinical situation the difference in disposition between EMs and PMs would be considerable. However, it may be predicted that at standard doses concentrations greater than 1000 ng·ml^–1 would not be attained in the PMs studied. The serum protein binding of R- and S-flecainide was studied in each subject and no differences between the enantiomers or the phenotypes were observed (Free fraction EM: R 0.43; S 0.42; PM R: 0.46; S: 0.46). Enantioselective disposition was noted in all PMs studied, due to a significantly lower nonrenal clearance of the R-enantiomer. In extensive metaboliser subjects, considerable interindividual variation in the enantioselective disposition of flecainide was noted, ranging from metabolism favouring either enantiomer to the absence of any selectivity.Presented in part at the 23rd Annual Meeting of the Australasian Society of Clinical and Experimental Pharmacologists, Sydney, 4–6 December, 1989     

The disposition and protein binding of batanopride and its metabolites in subjects with renal impairment

Summary We have studied the disposition of batanopride and its three major metabolites (the erythro-alcohol, threo-alcohol, and N-desethyl metabolites) in 27 subjects with various degrees of renal function after intravenous infusion of a single dose of 3.6·mg·kg^–1 of batanopride over 15 min.The subjects were assigned to one of three treatment groups: group 1, normal renal function (creatinine clearance 75 ml·min^–1·1.73 m^–2; n=13); group 2, moderate renal impairment (creatinine clearance 30–60 ml·min^–1·1.73 m^–2; n=8); group 3, severe renal impairment (creatinine clearance 30 ml·min^–1·1.73 m^–2; n=6).The terminal half-life of batanopride was significantly prolonged from 2.7 h in group 1 to 9.9 h in group 3. The renal clearance of batanopride was significantly lower in group 3 (25 ml·min^–1) compared with group 1 (132 ml·min^–1).There were no differences in plasma protein binding or steady-state volume of distribution of batanopride among the groups.There were significantly lower renal clearances for all three metabolites in groups 2 and 3 compared with group 1. The half-lives of all three metabolites were significantly prolonged in group 3 compared with group 1.The dose of batanopride may need to be reduced in patients with creatinine clearances less than 30 ml·min^–1·1.73 m^–2 to prevent drug accumulation and avoid possible dose-related adverse effects.     

Pharmacokinetics of ciprofloxacin tablets in renal failure; influence of haemodialysis

Summary The pharmacokinetics of ciprofloxacin has been studied after a single oral dose of 500 mg given to 5 normal subjects (N) and to 15 patients grouped according to their residual renal creatinine clearance: Group I, 8–30 ml·min^–1, Group II, <8 ml·min^–1, and Group III, haemodialysed patients studied twice — during an interdialysis period (IIIa) and in a 4 h haemodialysis session (IIIb). Ciprofloxacin was assayed by reverse phase HPLC using a spectrofluorimetric detection. The peak plasma concentration (2–5 mg·l^–1) was reached within 2 h after drug administration. Apparent volume of distribution, 6.6 (N), 5.0 (I), 2.7 (II) and 4.2 (IIIa) l·kg^–1 and total plasma clearance, 770 (N), 440 (I), 378 (II) and 314 (IIIa) ml·min^–1 were decreased in relation to the degree of renal impairment. Mean plasma half-lives for patients in the 4 groups were 7.3 (N), 10.4 (I), 7.2 (II) and 9.3 (IIIa) h. In groups N, I and II, 40, 16 and 8% of the administered dose was eliminated through the kidney, with mean renal clearances of 305±63,61±21 and 21±3 ml·min^–1. A linear relationship was found between the renal clearance of ciprofloxacin and the glomerular filtration rate (r=0.75,n=15). Ciprofloxacin was partly removed by haemodialysis (IIIb): the dialyser extraction ratio was 23% and the dialysis clearance was 40 ml·min^–1.     

Selective inhibition of drug oxidation after simultaneous administration of two probe drugs,antipyrine and tolbutamide

Summary The effects of sulphaphenazole, cimetidine and primaquine on the disposition of antipyrine and tolbutamide in healthy volunteers have been investigated. The model substrates were administered simultaneously in order more clearly to define any selective effects of the potential inhibitors. Sulphaphenazole produced a significant increase in the half-life of tolbutamide (7.10 to 21.50 h) and a correponding decrease in its clearance (0.260 to 0.084 ml·min^–1·kg^–1). Clearance to hydroxytolbutamide (OHTOL) and carboxytolbutamide (COOHTOL) was also significantly decreased.In contrast, sulphaphenazole had no effect on the disposition of antipyrine. Administration of cimetidine did not significantly alter the disposition of either model drug. However, a 1.6-times higher dose of cimetidine did increase the half lives both of tolbutamide and antipyrine (6.21 to 9.04 h and 14.2 to 19.2 h, respectively) and decrease their clearance (0.226 to 0.148 and 0.50 to 0.31 ml·min^–1 kg^–1, respectively). Clearance to OHTOL and hydroxymethylantipyrine (HMA) was reduced.A single dose of primaquine had no demonstrable effect on tolbutamide disposition whereas the half-life of antipyrine was increased (12.1 to 15.0 h) and its clearance decreased (0.63 to 0.38 ml·min^–1·kg^–1). The partial clearance to HMA, 4-hydroxyantipyrine (OHA) and norantipyrine (NORA) was also significantly reduced.The two main inferences are first, that tolbutamide and antipyrine are metabolished by different forms of cytochrome P-450, and second that a battery of model substrates is needed to investigate the inhibitory effects of a drug in man.     

Pharmacokinetics of cimetidine after subchronic administration

Summary The influence of cimetidine on its own pharmacokinetics after subchronic administration was assessed in 8 healthy volunteers, aged 26–29 years. On control Day 1, each subject received cimetidine 300 mg i.v., and serum and urine samples were obtained. Each subject was initiated on cimetidine 600 mg b.i.d. orally for 2 weeks. There were 3 further study days repeated after 1 and 2 weeks of cimetidine dosing and 1 week after stopping cimetidine. There was no significant difference in the mean total body clearance of cimetidine among the 4 study days. Mean elimination t_1/2 and V were similarly unchanged. However mean renal clearance (CL_R) and f_e were significantly increased following 2 weeks of drug dosing (CL_R 5.41 ml·min^–1 kg^–1; f_e 0.61) compared to control (CL_R 4.00 ml·min^–1·kg^–1; f_e 0.48). Although the non renal clearance was reduced from control values of 4.29 to 3.51 ml·min^–1·kg^–1 following 2 weeks of dosing the difference was not significant. Dosage adjustment of cimetidine appears unnecessary after short-term dosing in the presence of normal renal function.     

Influence of a very low calorie diet on the clearance of oxazepam and antipyrine in man

Summary A very low calorie diet (Prodi) was administered to eleven otherwise healthy obese subjects for fourteen days. The daily intake of protein was 52.7 g and carbohydrate 25.7 g, corresponding to 360 kcal. The clearance of oxazepam and antipyrine was investigated before and after the diet period.Total oxazepam clearance was 1.04 ml·min^–1·kg^–1 and it decreased 0.88-fold after the diet. The mean clearance of unbound oxazepam was correspondingly reduced 0.88-fold. The elimination half-life increased to 1.22-times the control value, 7.9 h.No significant change was found in the volume of distribution or protein binding of oxazepam. Antipyrine clearance, estimated by the one-sample technique, was 52.4 and 51.8 ml·min^–1, before and after the diet, respectively.It appears that a very low calorie diet with a sufficient protein and a very low carbohydrate content decreases the metabolism of oxazepam by glucuro-conjugation, whereas no effect was seen on the oxidative metabolism of antipyrine.     

The pharmacokinetics ofα-human atrial natriuretic polypeptide in healthy subjects

Summary We have analysed the pharmacokinetics of-human atrial natriuretic polypeptide (-hANP) in healthy subjects, using a two-compartment open model following bolus intravenous injection. The plasma half-times for the fast and slow components were 1.7±0.07 min and 13.3±1.69 min respectively. V₁ (the volume of the central compartment), V_z (volume of distribution) and V_ss (volume of distribution at steady-state) were 5370±855 ml (89.5±14.3 ml·kg^–1), 32000±4620 ml (533±77.0 ml·kg^–1), and 11900±1530 ml (198±25.5 ml·kg^–1) respectively. The mean plasma clearance was 1520±121 ml·min^–1 (25.4±2.0 ml·min^–1·kg^–1.     

Pharmacokinetics of dexamethasone in premature neonates

Objective: Dexamethasone is frequently used in premature neonates with bronchopulmonary dysplasia, however little is known about its disposition in this population. Methods: We evaluated the pharmacokinetics of dexamethasone in 9 premature neonates with a mean gestational age of 27.3 weeks and a postnatal age of 21.8 days. Results: There was a strong relationship between clearance (4.96 ml·min^–1·kg^–1) and gestational age (r=0.884). Pharmacokinetic parameters were grouped based on a gestational age of less than 27 weeks (Group I) and greater than 27 weeks (Group II). Mean clearance in group I and group II was 1.69 and 7.57 ml·min^–1·kg^–1, respectively. Mean distribution volume in group I and II was 1.26 and 2.19 l·kg^–1, respectively. No significant relationships were noted between the disposition of dexamethasone and ventilator requirements or adverse effects. Conclusion: The pharmacokinetics of dexamethasone in premature neonates was related to gestational age.     

Determination of phenobarbitone population clearance values for South African children

Non-linear Mixed Effects Modelling (NONMEM) was used to estimate phenobarbitone population clearance values for South African children, using 52 serum levels gathered from 32 patients during their routine care. NONMEM was also used to evaluate the influence of fixed effects such as weight, age and concomitant medication. The final model describing phenobarbitone clearance was CL=[Exp(0.0288 Wt–2.53)] M, where CL=clearance (l·h^–1), Exp=the base of the natural logarithm, Wt=patient weight (kg) and M=a scaling factor for concomitant medication with a value of 1 for patients on phenobarbitone monotherapy, 0.62 for those receiving concomitant valproate and 0.87 for those patients receiving concomitant carbamazepine or phenytoin. Mean (95% confidence interval) phenobarbitone clearance values were 7.6 ml·h^–1·kg^–1 (6.2, 9.0 ml·h^–1·kg^–1) for the monotherapy group, 5.0 ml·h^–1·kg^–1 (4.0, 6.0 ml·h^–1·kg^–1) in the presence of concomitant valproate and 6.8 ml·h^–1·kg^–1 (5.6, 8.0 ml·h^–1·kg^–1) in the presence of concomitant carbamazepine or phenytoin. These values are similar to those previously reported from both traditional and NONMEM pharmacokinetic studies.