Population analysis of the non-linear red blood cell partitioning of draflazine following various infusion durations

Objective: The pharmacokinetics and non-linear red blood cell partitioning of the nucleoside transport inhibitor draflazine were investigated in 19 healthy male and female subjects (age range 22–55 years) after a 15-min i.v. infusion of 1 mg, immediately followed by infusions of variable rates (0.25, 0.5 and 1 mg · h⁻¹) and variable duration (2–24 h). Methods: The parameters describing the capacity-limited specific binding of draflazine to the nucleoside transporters located on erythrocytes were determined by NONMEM analysis. The red blood cell nucleoside transporter occupancy of draflazine (RBC occupancy) was evaluated as a pharmacodynamic endpoint. Results: The population typical value for the dissociation constant K _d (%CV) was 0.648 (12) ng · ml⁻¹ plasma, expressing the very high affinity of draflazine for the erythrocytes. The typical value of the specific maximal binding capacity B_max (%CV) was 155 (2) ng · ml⁻¹ RBC. The interindividual variability (%CV) was moderate for K _d (38.9%) and low for B_max (7.8%). As a consequence, the variability in RBC occupancy of draflazine was relatively low, allowing the justification of only one infusion scheme for all subjects. The specific binding of draflazine to the red blood cells was a source of non-linearity in draflazine pharmacokinetics. Steady-state plasma concentrations of draflazine virtually increased dose-proportionally and steady state was reached at about 18 h after the start of the continuous infusion. The t_1/2βaveraged 11.0–30.5 h and the mean CL from the plasma was 327 to 465 ml · min⁻¹. The disposition of draflazine in whole blood was different from that in plasma. The mean t_1/2β was 30.2 to 42.2 h and the blood CL averaged 17.4–35.6 ml · min⁻¹. Conclusion: Although the pharmacokinetics of draflazine were non-linear, the data of the present study demonstrate that draflazine might be administered as a continuous infusion over a longer time period (e.g., 24 h). During a 15-min i.v. infusion of 1 mg, followed by an infusion of 1 mg · h⁻¹, the RBC occupancy of draflazine was 96% or more. As the favored RBC occupancy should be almost complete, this dose regimen could be justified in patients. Received: 6 February 1997 / Accepted in revised form: 12 May 1997     

Lack of pharmacokinetic interaction between ropinirole and theophylline in patients with Parkinson's disease

Objective: Ropinirole and theophylline have the potential to interact, because they use the same hepatic cytochrome P450 (CYP1A2) as their major metabolic pathway. The present study investigated the effect of steady-state oral theophylline on the pharmacokinetics of ropinirole at steady state and the effect of steady-state ropinirole on the pharmacokinetics of a single intravenous (i.v.) dose of theophylline, both in patients with idiopathic Parkinson's disease (PD). Methods: Pharmacokinetic parameters (AUC and C_max) for i.v. theophylline were compared before and after a 4-week period of oral treatment with ropinirole (2 mg t.i.d.) in 12 patients with PD. Patients were then maintained at this dose of ropinirole, and oral theophylline was co-administered at doses of up to 300 mg b.i.d. The parameters AUC, C_max and t_max for ropinirole were compared before, during and after oral theophylline co-treatment. Results: Co-administration of ropinirole did not significantly change the pharmacokinetics of i.v. theophylline (mean AUC with and without ropinirole: 68.6 μg · h⁻¹ · ml⁻¹ and 70.0 μ· h⁻¹ · ml⁻¹, respectively; mean C_max with and without ropinirole: 11.07 μ g · ml⁻¹ and 11.83 μg · ml⁻¹, respectively). Similarly, there were no significant changes in ropinirole pharmacokinetics when the drug was co-administered with oral theophylline (mean AUC for ropinirole with and without theophylline: 21.91 ng · h⁻¹ · ml⁻¹ and 22.09 ng · h⁻¹ · ml⁻¹, respectively; mean C_max for ropinirole with and without theophylline: 5.65 ng · ml⁻¹ and 5.54 ng · ml⁻¹, respectively; median t_max for ropinirole with and without theophylline: 2.0 h and 1.5 h, respectively). Conclusion: These results suggest a lack of significant pharmacokinetic interaction between the two drugs at current therapeutic doses. Received: 10 August 1998 / Accepted in revised form: 27 January 1999     

Lack of a pharmacokinetic interaction between atovaquone and proguanil

Objective: To assess the magnitude of the putative effect of atovaquone on the pharmacokinetics of proguanil and to determine whether the pharmacokinetics of atovaquone are affected by concomitant administration of proguanil, with both drugs administered for 3 days to healthy adult volunteers. Methods: This was an open-label, randomized, three-way cross-over study, in which 18 healthy volunteers received 400 mg proguanil, 1000 mg atovaquone and 1000 mg atovaquone + 400 mg proguanil. Each treatment was given once daily for 3 days with a 3-week wash-out period between each occasion. For the assay of proguanil, cycloguanil and atovaquone, blood was sampled before dosing and at regular intervals over 8 days when proguanil was given, and over 17 days when atovaquone was given. Results: The geometric mean of the area under the atovaquone plasma concentration-time curve calculated from 0 to 24 h after the last dose (AUC_0→24h) was 180 μg · ml⁻¹ · h following administration of atovaquone alone and 193 μg · ml⁻¹ · h following atovaquone with proguanil. The geometric mean AUC_0→24h for proguanil was 6296 ng · ml⁻¹ · h after proguanil alone and 5819 ng · ml⁻¹ · h following proguanil with atovaquone. The corresponding values for the metabolite cycloguanil were 1297 ng · ml⁻¹ · h and 1187 ng · ml⁻¹ · h, respectively. The geometric mean elimination half-life (t_1/2) of atovaquone was 57.1 h when given alone and 59.0 h when administered together with proguanil. The corresponding geometric mean values of t_1/2 for proguanil were 13.7 h and 14.5 h. Exploratory statistical analysis showed no important gender effects on the pharmacokinetics of atovaquone, proguanil, or cycloguanil. Conclusion: The pharmacokinetics of atovaquone and proguanil and its metabolite, cycloguanil, were not different when atovaquone and proguanil were given alone or in combination. Received: 14 October 1998 / Accepted in revised form: 8 February 1999     

Helicobacter pylori clearance and serum gastrin and pepsinogen I concentrations in omeprazole treatment of duodenal ulcer patients

Objective: To determine which demographic factors may influence serum gastrin and pepsinogen I (PGI) levels in duodenal ulcer patients undergoing omeprazole treatment. Methods: We conducted an outpatient-based prospective study in the Veterans General Hospital, Taipei, to investigate the pharmacological effects on patients with duodenal ulcers receiving omeprazole treatment for 4 weeks. Sixty-eight patients (61 males/7 females, aged 25–73 years) with endoscopically confirmed duodenal ulcer were included. Gastrin and pepsinogen I levels were measured before and after treatment. Demographic factors including age, sex, smoking, ulcer healing and antral Helicobacter pylori colonization/clearance were analyzed, in order to measure their probable influences on serum gastrin and pepsinogen I levels. Results: Ulcer healing was seen in 92.6% of patients while 48 (70.6%) antral clearances were seen in 66 H. pylori colonized patients at the end of trial. Omeprazole monotherapy led to a marked elevation of serum gastrin (85.8 pg · ml⁻¹, SD 32.0 pg · ml⁻¹ vs 133.9 pg · ml⁻¹, SD 71.6 pg · ml⁻¹, P < 0.01), and pepsinogen I (111.0 ng · ml⁻¹, SD 36.7 ng · ml⁻¹ vs 253.6 ng · ml⁻¹, SD 64.8 ng · ml⁻¹, P < 0.01) levels when measured on day 29. Only patients showing antral H. pylori clearance exhibited an influence on the magnitude of pepsinogen I elevation following omeprazole monotherapy (143.9%, SD 67.3% vs 78.6%, SD 51.2%, P < 0.01). Moreover, the sensitivity and specificity of serum pepsinogen I variations were plotted on a receiving operating characteristic (ROC) curve. The 140% increased pepsinogen I level yielded a maximum accuracy of 80% specificity or 50% sensitivity to predict antral H. pylori clearance. Conclusion: Antral H. pylori clearance is at least partially responsible for the omeprzaole-induced hyperpepsinogenemia I. The magnitude of hyperpepsinogenemia I probably provides a non-invasive alternative for predicting H. pylori clearance. Received: 22 August 1996 / Accepted in revised form: 1 October 1998     

Pharmacokinetics and tolerability of oral iloprost in thromboangiitis obliterans patients

Objective: Iloprost is a potent PGI₂ mimetic, which has been shown to be therapeutically effective in several vascular disorders. Due to its rapid clearance from the central compartment, iloprost is administered mainly by i.v. infusion, which limits its use to hospitalized patients. In order to improve pharmacotherapeutic use of this PGI₂ mimetic, an oral extended-release (ER) dosage form has been developed, which should mimic plasma level profiles as observed after i.v. infusion and serve as a therapeutic equivalent. Methods: This trial was performed to investigate the tolerability and pharmacokinetics of iloprost administered perorally, compared with i.v. infusion, in 12 patients suffering from thromboangiitis obliterans (TAO). A dose titration was carried out for 1 week with i.v. iloprost, followed by a p.o. titration and treatment phase of 3 weeks' duration. Pharmacokinetics was investigated at the individually tolerated dose levels; i.e., on days 5–7 (i.v. infusion at 2, 2.5 and 3 ng · kg⁻¹ · min⁻¹), and twice during p.o. treatment after b.i.d. administration of 50, 100, 150, 200 or 300 μg. Results: Individual tolerability of iloprost varied: 7 patients out of 12 tolerated the maximum i.v. dose of 3 ng · kg⁻¹ · min⁻¹; six tolerated the maximum oral dose of 600 μg. No patients withdrew from the study due to adverse events. Flush and headache were the most common adverse events and seemed to be related to the study drug. After i.v. infusion of iloprost, dose-normalized (3 ng · kg⁻¹ · min⁻¹), steady-state plasma levels were 260 pg · ml⁻¹. Terminal half-life was 0.57 h. Total clearance ranged from 8 to 17 ml · min⁻¹ · kg⁻¹. Peroral administration of the ER formulation resulted in dose-dependent C_max and AUC values. AUC values of the first and second daily dose interval, i.e., 0–5 h and 5–11 h after first dosing, were almost identical. Absolute bioavailability was 24%, with the exception of two patients who tolerated only 50 μg b.i.d. and exhibited a bioavailability of approx. 60%. The AUC values observed in weeks 2 and 4 were identical, demonstrating low day-to-day variability of iloprost plasma level profiles in TAO patients. Conclusion: Based upon pharmacokinetic data, the ER formulation provides an equivalent to the i.v. infusion of iloprost and broadens the range of therapy to non-hospitalized patients. The availability of capsules with 50 and 100 μg iloprost enables individual dose titration and pharmacotherapy. Beneficial effects, as observed with i.v. iloprost in TAO patients, should therefore be achievable by peroral pharmacotherapy using the new ER formulation. Received: 18 July 1996 / Accepted in revised form: 2 April 1997     

Pharmacokinetics of oxypolygelatine in healthy volunteers

Objective/methods: The pharmacokinetics of the plasma substitute oxypolygelatine (OPG) were studied in 12 healthy volunteers after single-dose administration of 27 ml · kg⁻¹ body weight, with a maximum of 2000 ml. OPG was determined in plasma and urine over 48 h after the infusion. Peak plasma OPG concentrations at the end of the infusion were determined to 4.600 (623) μg · ml⁻¹, the area under the plasma concentration/time curve (AUC_0∞) was calculated to 70.135 (15.861) μg · h · ml⁻¹. Results: The model-independently calculated volume of distribution came to 23.1 (4.8) l with a clearance total is (Cl_tot) of 24.6 (6.8) ml · min⁻¹. The initial half-life according to a three-compartment model came to 0.3 (0.2) h, followed by a distribution half-life of 3.1 (2.6) h and a terminal elimination half-life of 13.4 (2.2) h. Cumulative urinary excretion of OPG was 64% after 48 h. Conclusion: This low recovery rate may be explained by the distribution of OPG into the extravascular space and subsequent degradation in tissue sites. Received: 9 June 1998 / Accepted in revised form: 23 November 1998     

Temperature dependency of the release and bioavailability of nicotine from a nicotine vapour inhaler; in vitro/ in vivo correlation

Objective: To investigate the temperature dependency of the dose released and the plasma levels of nicotine from a vapour inhaler. Methods: In an open, randomised, three-way cross-over pharmacokinetic study 18 healthy subjects inhaled nicotine for 20 min (80 inhalations) every hour for 10 h (11 administrations) at three different environmental temperatures: 20°, 30° and 40 °C. In the in vitroexperiment, 5, 10, 15 and 20 l air were forced through the inhaler. With a 15 l air volume, the average amount of nicotine released was 1.44, 3.49, 4.80 and 6.99 mg at 10 °C, 22 °C, 29 °C and 40 °C, respectively. The maximum dose released at the highest temperature (40 °C) and the largest air volume investigated (20 l) was approximately 7.5 mg. Results: In vivo peak plasma levels obtained at 30° and 40 °C were 29.7 and 34.0 ng · ml⁻¹, compared with 22.5 ng · ml⁻¹ at ambient room temperature (20 °C). At 20 °C, the area under the plasma concentration–time curve (AUC) of the last dosing interval was 20.5 ng · ml⁻¹ · h. At 30 °C and 40 °C, the AUCs were 26.5 and 30.3 ng · ml⁻¹ · h, respectively. The results thus showed a mean increase of the in vivo AUC by 29% at 30 °C and by 48% at 40 °C compared with the AUC at 20 °C. These increases should be compared to the in vitro results, showing a mean increase of 59% and 122%, respectively, at 30° and 40 °C. The in vitro results also showed that a relatively larger fraction of the dose was released into the first 5 l of air at the higher temperatures, at 40 °C, about 50% of the total amount released into 20 l. Conclusion: It was concluded that the in vitro/in vivo discrepancy was most probably due to increased aversive effects at elevated temperatures, causing the subjects to inhale smaller puff volumes. Further, the inhaler would not produce nicotine plasma levels exceeding those achieved following cigarette smoking, even in a hot climate. Received: 20 September 1996 / Accepted in revised form: 5 March 1997     

Pharmacokinetics of glibenclamide and its metabolites in diabetic patients with impaired renal function

Background: Glibenclamide (Gb) may provoke long-lasting hypoglycaemic reactions, and one of the known risk factors is impaired renal function. We have demonstrated Gb to have a terminal elimination half-life of 15 h, and the main metabolites have a hypoglycaemic effect. With few exceptions, detailed studies on second generation sulphonylureas in diabetics with impaired renal function are lacking. Therefore, we analysed the pharmacokinetics of Gb and its active metabolites, 4-trans-hydroxyglibenclamide (M1) and 3-cis-hydroxyglibenclamide (M2) in this patient group. Methods: Two groups of 11 diabetic patients with impaired renal function (IRF, iohexol clearance range 7–42 ml · min⁻¹ · 1.73 m⁻²) or normal renal function (NRF, iohexol clearance range 75–140 ml · min⁻¹ · 1.73 m⁻²) were compared. A single oral 7-mg dose of Gb was administered after overnight fasting. Serum samples and urine collections were obtained over 48 h and 24 h, respectively. Concentrations of Gb, M1 and M2 were determined by a sensitive and selective high-performance liquid chromatography assay. Results: Peak serum values of M1 (24–85 ng · ml⁻¹ vs 16–57 ng · ml⁻¹), M2 (7–22 ng · ml⁻¹ vs <5–18 ng · ml⁻¹) and M1 + M2 (32–100 ng · ml⁻¹ vs 23–76 ng · ml⁻¹) were higher in the IRF group. AUC and C_max of Gb were lower and the clearance to bioavailability ratio (CL/f) was higher in the IRF group. AUC and C_max of M1 were higher and CL/f lower in the IRF group. Much lower amounts of M1 and M2 were excreted in the urine in the IRF group (7.2% vs 26.4% in 24 h). The fraction of the Gb dose excreted as metabolites (fe(met) 0–24 h), ranged between 0.005 and 0.36 and correlated significantly with renal function measured by iohexol clearance. No other pharmacokinetic differences were found. Conclusion: The differences in AUC, C_max and CL/f of Gb may be explained by a higher free fraction in the IRF group which would increase Gb metabolic clearance. The inverse findings regarding M1 may be explained by the fact that the metabolites are primarily eliminated by the kidneys. After a single dose of Gb, neither Gb, M1 nor M2 seemed to accumulate in diabetic subjects with IRF. As only small amounts of M1 and M2 were excreted in the urine, this indicates one or several complementary non-renal elimination routes, e.g. shunting of metabolised Gb to the biliary excretion route and/or enterohepatic recycling of both metabolites and unmetabolised Gb. Received: 21 April 1997 / Accepted in revised form: 14 October 1997     

Codeine in post-operative pain Study of the influence of sparteine phenotype and serum concentrations of morphine and morphine-6-glucuronide

Objective: Within the past decade, human experimental pain studies have supported the 50-year-old hypothesis that codeine is a prodrug, which has to be converted to morphine to exert an analgesic effect. This study aimed at evaluating the impact of sparteine phenotype and serum concentrations of morphine on the efficacy of codeine in post-operative pain. Methods: Eighty-one patients with a pain rating of 3 or more on a 0–10 numerical rating scale 0.5 h after surgery were included in the study. The patients were given an oral dose of 100 mg codeine and rated pain with the numerical rating scale 0.5 h and 1 h after medication. Blood for determination of serum concentration of codeine and its metabolites was collected 1 h after medication, and a 12-h urine sample after administration of 100 mg sparteine was used to determine the sparteine phenotype. Results: Eight patients were poor metabolizers and 66 were extensive metabolizers of sparteine, while the urine samples for the remaining seven patients were lost. In 22 patients, including the eight poor metabolizers, the serum concentrations of both morphine and morphine-6-glucuronide (M6G) were below the limit of determination of the assay, i.e. 1.5 nmol · l⁻¹ and 2 nmol · l⁻¹, respectively. A sum of the concentration of these two substances below 10 nmol · l⁻¹ was found in an additional eight patients. The sum of differences between pre- and post-operative pain ratings did not differ between the two phenotypes (P= 0.60), whereas the 30 patients with serum concentrations of morphine plus M6G below 10 nmol · l⁻¹ had a marginally significant lower sum than the 51 patients with higher levels of these substances (median 1.5 vs 2.5, P = 0.058). Conclusion: A low serum concentration of morphine and M6G seems to be common in patients treated with codeine for post-operative pain, and low concentrations of these active substances may be related to decreased efficacy of codeine. Received: 23 September 1997 / Accepted in revised form: 11 May 1998     

Distribution and metabolism of N G-nitro-l-arginine methyl ester in patients with septic shock

Objective: The pharmacokinetics of N ^G-nitro-l-arginine methyl ester (l-NAME), an inhibitor of nitric oxide (NO) synthesis, was investigated in patients with septic shock. Methods: Blood was sampled at intervals before, during and after 12-h infusion of l-NAME 1 mg · kg⁻¹ · h⁻¹ in nine septic shock patients for determination of plasma concentrations by high-performance liquid chromatography (HPLC). In three patients the renal clearance of the drug was determined. Results: Incubation of l-NAME with plasma and blood in vitro revealed hydrolysis to N ^G-nitro-l-arginine (l-NOARG), the active inhibitor of NO synthesis. l-NOARG did not undergo further degradation. Continuous intravenous infusion of 1 mg · kg⁻¹ · h⁻¹ of l-NAME for 12 h in patients with septic shock increased blood pressure and resulted in increasing plasma concentrations of l-NOARG (C_max 6.2 μg · ml⁻¹ at 12 h) whereas l-NAME concentrations reached a plateau within 1.5 h (C_max 1.0 μg · ml⁻¹). After the infusion was stopped l-NAME disappeared from the plasma rapidly (half-life 19.2 min) whereas l-NOARG concentration declined slowly (half-life 22.9 h). The calculated volume of distribution for l-NAME was 0.45 l · kg⁻¹ body weight and 1.96 l · kg⁻¹ for l-NOARG. The renal clearance for l-NOARG was 3.5% of total body clearance for l-NOARG, whereas l-NAME could not be detected in urine. Conclusion: We conclude that vasoconstriction with l-NAME in septic patients may result from hydrolysis to l-NOARG, the active inhibitor of NO synthesis. The long plasma half-life and large volume of distribution for l-NOARG suggests extensive distribution to extravascular tissues. Since renal excretion is minimal, elimination of the metabolite l-NOARG follows other pathways. Received: 13 March 1998 / Accepted in revised form: 30 June 1998     

Pharmacokinetics and distribution of 6-mercaptopurine administered intravenously in children with lymphoblastic leukaemia

Objective: The pharmacokinetics of 6-mercaptopurine, including cerebrospinal-fluid (CSF) distribution, and the erythrocyte 6-thioguanine nucleotide concentrations were determined in children randomised to receive intravenous mercaptopurine for acute lymphoblastic leukaemia (ALL), according to the EORTC protocol ALL n°58881. Results: After 1 month of oral treatment at a dose of 50 mg · m⁻² · day⁻¹, the pharmacokinetic parameters were determined after the first i.v. administration of 1 g · m⁻² (bolus dose of 0.2 g · m⁻² followed by an 8-h infusion of 0.8 g · m⁻²) in 11 patients: systemic clearance was 23.02 l · h⁻¹, volume of distribution was 0.75 l · kg⁻¹, and elimination half-life was 1.64 h. The erythrocyte thioguanine concentrations were measured in the same 11 patients and increased significantly between the beginning and the end of infusion (10 pmol × 10⁸ packed RBC) or within 24 h of infusion (223 pmol × 10⁸ packed RBC). The CSF concentration was 3.78 μmol · l⁻¹, 1–6 h after the beginning of infusion (n=28) and the CSF to plasma ratio was 0.15 (n=16). In patients receiving the oral dose of 50–165 mg · m⁻² · day⁻¹ of 6-mercaptopurine, CSF concentrations were below 0.18 μmol · l⁻¹, 1–24 h after drug intake (n=67), and the CSF to plasma ratio was not calculated. Conclusion: Following the i.v. administration of 6-mercaptopurine, we observed high CSF concentrations of 6-mercaptopurine and an acute increase of erythrocyte thioguanine nucleotide concentrations. The clinical trial (EORTC protocol ALL n°5881), comparing the oral and i.v. administrations of mercaptopurine, will demonstrate if the i.v. administration reduces the incidence of CNS relapses. Received: 15 August 1996 / Accepted in revised form: 8 April 1997     

Cardiovascular effects of different infusion rates of sufentanil in patients undergoing coronary surgery

   Objective: Pharmacokinetics and haemodynamic effects of a total dose of 15 μg · kg⁻¹ sufentanil, an opioid anaesthetic agent, were studied in patients undergoing aortocoronary bypass surgery at three infusion rates of 30 (group I), 5 (group II), and 2 (group III) μg · kg⁻¹ · min⁻¹, respectively. Results: Plasma concentrations of sufentanil could be optimally characterized by a linear biexponential pharmacokinetic model. Non-compartmental analyses indicated that there was no significant difference in the values of clearance (11.6, 13.3, 14.3 ml · min⁻¹ · kg⁻¹), steady-state volume of distribution (0.220, 0.255 and 0.331 l · kg⁻¹) and mean residence time (18.8, 13.3 and 14.3 min) among the groups. The observed mean C_max values of 421 (group I), 125 (group II), and 53 (group III) ng · ml⁻¹ and observed mean AUC values from 0 to 3 min were all consistent with the dosing regimens. There were large inter-individual variations in haemodynamic response. Compared to plasma data, a delay in haemodynamic effects was found. Times to reach peak haemodynamic effect ranged from 4.3 to 4.9 min for group I, from 4.6 to 6.1 min for group II, and from 9.9 to 11.3 for group III. Except heart rate, peak haemodynamic effects in these study patients generally ranged from 20.9% to 35.2%. Significant reductions in the area under the effect-time profiles of mean arterial blood pressure and systemic vascular resistance were observed in group II and group III, but not in group I. Significant reductions in the area under the effect-time profiles of left ventricular stroke work index were observed in group III only. No effect on heart rate was found in any group. Conclusion: Our findings suggested that a slower infusion rate of sufentanil at a dose of 15 μg · kg⁻¹ tends to give a greater reduction in mean arterial blood pressure, systemic vascular resistance, and left ventricular stroke work index than does a faster infusion rate. Received: 23 August 1995 / Accepted in revised form: 19 August 1996     

Plasma esterases in cystic fibrosis: the impact of a respiratory exacerbation and its treatment

Objectives: To determine the effect of an exacerbation of respiratory symptoms in cystic fibrosis (CF) on the activities of plasma benzoylcholinesterase and butyrylcholinesterase. Methods: Twenty-nine patients with CF in a respiratory exacerbation and 27 healthy volunteers matched for age and sex were recruited. Blood was obtained from the patients when commencing antibiotic treatment and 14 days later on completion of treatment. One blood sample was taken from the healthy volunteers. The activities of benzoylcholinesterase and butyrylcholinesterase were determined by spectrophotometric assay. The circulating inflammatory markers, C-reactive protein and neutrophil elastase-α₁antiproteinase complex were also measured. Results: Benzoylcholinesterase activity was significantly (P = 0.001) lower in patients at the start of a respiratory exacerbation, compared with healthy controls [mean (SD): 917 (274) versus 1191(298) nmol · ml⁻¹ · min⁻¹]. Benzoylcholinesterase activity increased significantly in patients to 1013 (237) nmol · ml⁻¹ · min⁻¹, following a course of antibiotic treatment (P = 0.006). Butyrylcholinesterase activity was also lower (P = 0.001) in patients at the start of a respiratory exacerbation, compared with healthy controls [5.54 (1.64) versus 7.01 (1.79) μmol · ml⁻¹ · min⁻¹], and increased significantly in the patients to 6.31 (1.58) μmol · ml⁻¹ · min⁻¹ following treatment (P = 0.006). Conclusion: We demonstrated significant suppression of plasma esterase activities during an exacerbation of respiratory symptoms in CF, which was only partially reversed after antibiotic treatment. Further studies are needed to examine other pathways of drug metabolism in this group of chronically infected patients. Received: 8 June 1998 / Accepted in revised form: 18 September 1998     

Effects of dopamine on veins in humans: comparison with noradrenaline and influence of age

Objective: To compare the venoconstricting effect of dopamine with that of noradrenaline and to investigate the influence of age on the responsiveness to dopamine in human subjects. Methods: In eight young and eight elderly male subjects, increasing doses of dopamine or noradrenaline were infused into a dorsal hand vein and its diameter was measured using a linear variable differential transformer. Results: There was no significant difference between the maximum venoconstriction (E_max) for dopamine and that for noradrenaline. The infusion rate to induce 50% of E_max (ED₅₀) for dopamine in the young and elderly subjects was 363 ng · min⁻¹ and 352 ng · min⁻¹, and the ED₅₀ for noradrenaline was 40.7 ng · min⁻¹ and 43.8 ng · min⁻¹, respectively. Neither in the E_max nor in the ED₅₀ for these drugs were there significant differences between the young and elderly subjects. Conclusion: The venoconstricting effect of dopamine is 5–20 times less than that of noradrenaline, and aging does not influence the responsiveness to dopamine and noradrenaline in human subjects. Received: 29 August 1997 / Accepted in revised form: 5 February 1998     

Determination of the relative bioavailability of nedocromil sodium to the lung following inhalation using urinary excretion

Objective: To determine the effects of cimetidine on the steady-state pharmacokinetics and pharmacodynamics of atorvastatin, a 3-hydroxymethylglutaryl coenzyme A (HMG-CoA) reductase inhibitor. Methods: Twelve healthy subjects participated in a randomized two-way crossover study. Each subject received atorvastatin 10 mg every morning for 2 weeks and atorvastatin 10 mg every morning with cimetidine 300 mg four times a day for 2 weeks, separated by a 4-week washout period. Steady-state pharmacokinetic parameters (based on an enzyme inhibition assay) and lipid responses were compared. Results: Pharmacokinetic parameters and lipid responses were similar following administration of atorvastatin alone and atorvastatin with cimetidine. Mean values for C_max (the maximum concentration) were 5.11 ng · eq · ml⁻¹ and 4.54 ng eq · ml⁻¹, for t_max (the time to reach maximum concentration) 2.2 h and 1.3 h, for AUC_0–24 (area under the concentration-time curve from time 0 h to 24 h) 58.6 ng eq · h · ml⁻¹ and 58.5 ng eq · h · ml⁻¹, and for t_1/2 (terminal half-life) 10.1 h and 17.0 h, respectively, following administration of atorvastatin alone and atorvastatin with cimetidine. Following treatment with atorvastatin alone and atorvastatin with cimetidine, mean values for the percentage change from baseline for total cholesterol were −29.5% and −29.9%, for low-density lipoprotein (LDL) cholesterol −41.0% and −42.6%, for high-density lipoprotein (HDL) cholesterol 6.3% and 5.8%, and for triglycerides −33.8% and −25.8%, respectively. Conclusions: The rate and extent of atorvastatin absorption and the effects of atorvastatin on LDL-cholesterol responses are not influenced by coadministration of cimetidine. Received: 17 February 1997 / Accepted in revised form: 3 November 1997     

Age-dependent differences in the anticoagulant effect of phenprocoumon in patients after heart valve surgery

Objective: An enhanced response to warfarin and an increased risk of major bleeding has been observed in older patients. The reason for this increase in sensitivity remains unknown. It could be due to pharmacodynamic reasons, pharmacokinetic reasons, or both. Methods: We therefore followed an anticoagulant regimen with phenprocoumon in 19 older (76 years) and 19 younger patients (50 years) following heart valve replacement. INR values were determined frequently. At the 4th and around the 24th day after starting treatment with phenprocoumon, we also measured the total and unbound plasma concentration of phenprocoumon. Results: The dose requirement to obtain the desired anticoagulant effect was significantly lower in the older patients than in the younger patients (26.3 vs. 37.3 μg · kg⁻¹ · day⁻¹). The total plasma concentration (2.19 vs. 2.43 μg · ml⁻¹), the percentage unbound drug in the plasma (0.61 vs. 0.64%) and the unbound plasma concentration (13.8 vs. 15.1 ng · ml⁻¹) did not differ significantly between older and younger patients. The dose-adjusted INR (INR/dose) was higher in the older patients (110 vs. 67) but the INR adjusted for the unbound plasma concentration (INR/C_uss) which reflects the intrinsic sensitivity to the drug, was not significantly different (192 vs. 173). However, the older patients had an about 30% significantly lower metabolic clearance based on unbound drug (84 vs. 115 ml · kg⁻¹ · h⁻¹). Conclusions: Older patients (> 70 years) require a dose approximately 30% lower than younger patients (< 160␣years). Pharmacokinetic reasons (reduced metabolic clearance) are mainly responsible for the lower dose requirement of the older patients after heart valve surgery. Received: 23 August 1996 / Accepted November 11 1996     

Effect of itraconazole on the pharmacokinetics and pharmacodynamics of zolpidem

Objective: Zolpidem is a short-acting␣imidazopyridine hypnotic which is biotransformed in humans mainly by CYP3A4. Itraconazole strongly interacts with many substrates of CYP3A4 such as midazolam and triazolam. In this study, the effect of itraconazole on the pharmacokinetics and pharmacodynamics of zolpidem was investigated to uncover a possible clinically significant interaction. Methods: In a randomized cross-over study with two phases, ten healthy volunteers took either 200 mg itraconazole or placebo once daily for 4 days. A single oral dose of 10 mg zolpidem was given on day 4. Plasma drug concentrations were measured up to 17 h and effects of zolpidem up to 9 h after the ingestion of zolpidem. Results: Itraconazole had no marked effects on the pharmacokinetics of zolpidem; the total area under the plasma zolpidem concentration–time curve (AUC_0–∞) was 34% larger during the itraconazole phase (759 ng · h · ml⁻¹) than during the placebo phase (567 ng · h · ml⁻¹). Exophoria of the eyes by the Maddox wing test was significantly increased by itraconazole, but the results of the digit symbol substitution test, critical flicker fusion test, postural sway tests and the visual analogue scale tests for subjective drowsiness and overall drug effect did not differ between the phases. Conclusion: The pharmacokinetics and pharmacodynamics of zolpidem were not remarkably affected by itraconazole in healthy volunteers. Therefore, unlike triazolam, for example, zolpidem can be used in normal or nearly normal doses together with itraconazole and probably also with other CYP3A4 inhibitors. Received: 30 September 1997 / Accepted in revised form: 12 January 1998     

Penetration of ciprofloxacin, norfloxacin and ofloxacin into the aqueous humour of patients by different topical application modes

Objectives: A prospective study was undertaken to determine the transcorneal penetration of three topically applied fluoroquinolones into aqueous humour. Methods: Two hundred and twenty-four patients undergoing cataract extraction received 0.3% ciprofloxacin, norfloxacin or ofloxacin eye drops by two different administration modes with different frequencies and intervals of application. At the beginning of cataract extraction (0.5–3 h after the last drop), 50–100 μl aqueous fluid was aspirated from the anterior chamber and immediately stored at −80 °C. Antibiotic concentrations were measured using high-performance liquid chromatography. Results: Generally, topical ofloxacin and ciprofloxacin yielded aqueous humour levels higher than topical norfloxacin. The highest concentrations of all tested fluoroquinolones were measured after using an application mode, in which one drop was given every 15 min between 0600 hours and 0800 hours, prior to operation. When applied by this mode, ciprofloxacin achieved a mean aqueous level of 0.380 (±0.328) μg · ml⁻¹ (range 0.033–1.388 μg · ml⁻¹), norfloxacin 0.182 (0.118) μg · ml⁻¹ (range 0.038–0.480 μg · ml⁻¹) and ofloxacin 0.564 (0.372) μg · ml⁻¹ (range 0.064–1.455 μg · ml⁻¹). These mean concentrations were above the minimum inhibitory concentration (MIC₉₀), concentrations required for inhibition of 90% of pathogen strains in vitro of gram-negative bacteria, such as Proteus mirabilis and Escherichia coli. Therapeutic values above the MIC₉₀ of Staphylococcus epidermidis, the pathogen causing eye infections most frequently, were reached by 67.5% of patients after ofloxacin and by 41% after ciprofloxacin, but never after norfloxacin treatment. Conclusion: Of the currently available topical fluoroquinolones, ofloxacin achieved the highest aqueous humour concentration. This fluoroquinolone may be an useful ophthalmic agent for topical antibacterial management, but it does not seem to be prophylactically effective against Streptococcus pneumoniae or Pseudomonas aeruginosa. Received: 22 April 1997 / Accepted: 8 June 1997     

The cardiac effects of terfenadine after inhibition of its metabolism by grapefruit juice

Objective: To determine whether the pharmacokinetics and electrocardiographic pharmacodynamics of terfenadine are affected by the concomitant administration of grapefruit juice. Methods: Six healthy volunteers were recruited for a balanced cross-over study. Each volunteer received 120 mg terfenadine 30 min after drinking 300 ml of either water or freshly squeezed grapefruit juice. The alternative treatment was administered on the second study day 2 weeks later. Measurements of the area under the terfenadine plasma concentration-time curve (AUC), maximum terfenadine concentration (C_max) and the time to maximum concentration (t_max) were made, and the corrected QT (QTc) interval was measured from the surface electrocardiogram. Results: Terfenadine was quantifiable in plasma in all 6 subjects on both study days for up to 24 h post-dosing. The AUC of terfenadine was significantly increased by concomitant grapefruit administration (median values 40.6 vs 16.3 ng · ml⁻¹ · h), as was the C_max (median values 7.2 vs 2.1 ng · ml⁻¹). The t_max was not significantly increased and there was no significant change in the median QTc interval despite the increased terfenadine levels. The 95% confidence interval for the difference in the change in QTc interval at C_max was −13 to +38 ms. Conclusion: Administration of grapefruit juice concomitantly with terfenadine may lead to an increase in terfenadine bioavailability, but the increase observed in this study did not lead to significant cardiotoxicity in normal subjects. However, this does not exclude the risk of cardiotoxicity in high-risk subjects given greater doses of grapefruit juice over longer periods of time. Received: 14 October 1996 / Accepted in revised form: 10 December 1996     

The area under the plasma concentration–time curve for oral midazolam is 400-fold larger during treatment with itraconazole than with rifampicin

Objective: To determine the effects of treatment with itraconazole and rifampicin (rifampin) on the pharmacokinetics and pharmacodynamics of oral midazolam during and 4 days after the end of the treatment. Methods: Nine healthy volunteers received itraconazole (200 mg daily) for 4 days and, 2 weeks later, rifampicin (600 mg daily) for 5 days. In addition, they ingested 15 mg midazolam before the first treatment, 7.5 mg on␣the␣last day of itraconazole administration, and 4 days␣later,␣and 15 mg 1 day and 4 days after the last dose␣of␣rifampicin.␣The disposition of midazolam and its α-hydroxy metabolite was determined and its pharmacodynamic effects were measured. Results: During itraconazole treatment, or 4 days after, α-hydroxymetabolite the dose-corrected area under the plasma midazolam concentration–time curve (AUC_0–∞) was 8- or 2.6-fold larger than that before itraconazole (i.e. 1707 or 695 versus 277 ng · h · ml⁻¹), respectively. One day after rifampicin treatment, the AUC_0–∞ of midazolam was 2.3% (i.e. 4.4 ng · h · ml⁻¹) of the before-treatment value and only 0.26% of its value during itraconazole treatment; 4 days after rifampicin, the AUC_0–∞ was still only 13% (i.e. 27.1 ng · h · ml⁻¹) of the before-treatment value. The peak concentration and elimination half-life of midazolam were also increased by itraconazole and decreased by rifampicin. The ratio of plasma α-hydroxymidazolam to midazolam was greatly decreased by itraconazole and increased by rifampicin. In addition, the effects of midazolam were greater during itraconazole and smaller 1 day after rifampicin than without treatment. Conclusion: Switching from inhibition to induction of cytochrome P450 3A (CYP3A) enzymes causes a very great (400-fold) change in the AUC of oral midazolam. During oral administration of CYP3A substrates that undergo extensive first-pass metabolism, similar changes in pharmacokinetics are expected to occur when potent inhibitors or inducers of CYP3A are added to the treatment. After cessation of treatment with itraconazole or rifampicin, the risk of significant interaction continues up to at least 4 days, probably even longer. Received: 17 June 1997 / Accepted in revised form: 16 October 1997