Metabolism and elimination of quinine in healthy volunteers

Objectives The aims were to investigate: (1) The renal elimination of quinine and its metabolites 3-hydoxyquinine, 2-quininone, (10R) and (10S)-11-dihydroxydihydroquinine and (2) the relative importance of CYP3A4, CYP1A2 and CYP2C19 for the formation of 2-quininone, (10R) and (10S)-11-dihydroxydihydroquinine in vivo.Methods In a randomised three-way crossover study, nine healthy Swedish subjects received a single oral dose of quinine hydrochloride (500 mg), on three different occasions: (A) alone, (B) concomitantly with ketoconazole (100 mg twice daily for 3 days) and (C) concomitantly with fluvoxamine (25 mg twice daily for 2 days). Blood and urine samples were collected before quinine intake and up to 96 h thereafter. All samples were analysed by means of high-performance liquid chromatography.Results Co-administration with ketoconazole significantly increased the area under the plasma concentration versus time curve (AUC) of 2-quininone, (10S)-11-dihydroxydihydroquinine, and (10R)-11-dihydroxydihydroquinine, the geometric mean ratios (90% CI) of the AUC were 1.9 (1.8, 2.0), 1.3 (1.1, 1.7) and 1.6 (1.4, 1.8), respectively. Co-administration with fluvoxamine had no significant effect on the mean AUC of any of the metabolites. A mean of 56% of the administered oral quinine dose was recovered in urine after hydrolysis with -glucuronidase relative to the 40% recovered before hydrolysis.Conclusion Quinine is eliminated in urine mainly as unchanged drug and as 3-hydroxyquinine. The major metabolite of quinine is 3-hydroxyquinine formed by CYP3A4. There is no evidence for the involvement of CYP3A4, 1A2 or 2C19 in the formation of 2-quininone, (10S)-11-dihydroxydihydroquinine and (10R)-11-dihydroxydihydroquinine in vivo. Glucuronidation is an important pathway for the renal elimination of quinine, mainly as direct conjugation of the drug.     

Altered flecainide disposition in healthy volunteers taking quinine

Summary The pharmacokinetics of flecainide and its two sequential metabolites, both free and conjugated, its pharmacodynamics, and the influence of simultaneously administered quinine, have been studied in 10 healthy subjects. The study comprised two, 48-h open phases at an interval of 1 week. Flecainide acetate 150 mg was given as a 30-min i.v. infusion and quinine sulphate orally 500 mg×3 over 24 h.Quinine administration did not change the apparent volume of distribution or the renal clearance of flecainide, but it significantly reduced its systemic clearance (9.2 vs 7.6 ml · kg^–1 · min^–1), thus increasing the elimination half-life (9.6 vs 11.5 h). The amount of flecainide transformed to its first, meta-O-dealkylated metabolite (MODF) fell with no change in the renal excretion of the latter, either in its free or conjugated forms.This finding, in association with a fall in amount of the second, meta-O-dealkylated lactam metabolite (MODLF) recovered in its conjugated forms in the urine, suggests that quinine inhibits both the first and the second steps of the sequential metabolism of flecainide.When the subjects received quinine in addition to flecainide, the PR interval in the ECG was slightly more prolonged than with flecainide alone. Due to the study design, an effect of quinine per se and the consequence of increased serum flecainide levels could not be distinguished.     

Hearing impairment related to plasma quinine concentration in healthy volunteers.

1. Hearing impairment was investigated in six healthy volunteers who received oral doses of 5, 10 and 15 mg kg-1 quinine single-blind and in random order. 2. The plasma concentration of quinine was followed for 48 h and the time course was fitted by a linear one compartment pharmacokinetic model. 3. Hearing thresholds were measured by pure tone audiometry. There was a delay between impairment in hearing and change in plasma quinine concentration. Thus the method of effect compartment modelling was applied. 4. The effect on hearing (L), measured as a shift in hearing threshold (dB), was used to estimate the rate constant for elimination of drug from the assumed effect compartment (ke0) and two parameters specifying the effect model (gamma and k). The effect model applied was L = 10 (log k + gamma x log Ce) where Ce is the calculated drug concentration in the effect compartment. This model is a logarithmic transform of a power expression equivalent to the Hill equation at the lower end of the effect range. In all experiments where there was a clear effect on hearing, convergence on a set of parameter estimates occurred, but inter- and intraindividual variability was large. The mean value of ke0 was 3.32 +/- 5.93 h-1 s.d., for gamma it was 1.73 +/- 1.14 s.d. and for k it was 0.59 +/- 0.66 s.d.     

A comparison of the pharmacokinetic and pharmacodynamic properties of quinine and quinidine in healthy Thai males.

1. Eight healthy Thai males, aged 19-27 years, received quinine or quinidine dihydrochloride 10 mg kg-1 body weight by intravenous infusion over 1 h. At least 1 week later, the alternative alkaloid was administered. 2. The terminal elimination half-time of quinidine was shorter than that of quinine (median [range]; 5.7 [5.0-10.0] vs 9.9 [8.8-15.1] h, P < 0.01), the volume of distribution at steady state (Vss) for quinidine was larger than that for quinine (3.5 [2.5-5.6] vs 3.1 [1.8-4.1] 1 kg-1; P = 0.02) and quinidine was less bound to plasma proteins (% free drug: 22.8 [15.4-47.2] vs 9.4 [7.3-15.0]%, P < 0.01). Total clearance was greater for quinidine (7.7 [3.9-11.4] vs 3.4 [1.8-4.6] ml min-1 kg-1, P < 0.01) but not for clearance of unbound drug (32.2 [14.6-50.4] vs 29.9 [20.2-50.9] ml min-1 kg-1 respectively, P > 0.2). 3. Side-effects, including transient hypotension after quinidine in two cases, were mild. 4. Both drugs produced prolongation of the rate-corrected QT interval (QTc), with similar rates of elimination from the cardiac conduction 'effect' compartment (keo; 4.14 [0.03-15.33] h-1 for quinine, 3.74 [1.63-13.14] h-1 for quinidine, P > 0.19). Using a linear concentration-response model, the intercept ('threshold') for quinidine effect was lower than that for quinine (P = 0.004) but the slopes (change in QTc for a given change in free drug concentration) were similar (P = 0.56).(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of olanzapine and ziprasidone on glucose tolerance in healthy volunteers.

Atypical antipsychotics have been linked to a higher risk for glucose intolerance, and consequentially the development of type 2 diabetes mellitus (DM2). We have therefore set out to investigate the acute effects of oral administration of olanzapine and ziprasidone on whole body insulin sensitivity in healthy subjects. Using the standardized hyperinsulinemic euglycemic clamp technique we compared whole body insulin sensitivity of 29 healthy male volunteers after oral intake of either olanzapine 10 mg/day (n = 14) or ziprasidone 80 mg/day (n = 15) for 10 days. A significant decrease (p<0.001) in whole body insulin sensitivity from 5.7 ml/h/kg ( = mean, SM = 0.4 ml/h/kg) at baseline to 4.7 ml/h/kg ( = mean, SM = 0.3 ml/h/kg) after oral intake of olanzapine (10 mg/day) for 10 days was observed. The ziprasidone (80 mg/day) group did not show any significant difference (5.2+/-0.3 ml/h/kg baseline vs 5.1+/-0.3 ml/h/kg) after 10 days of oral intake. Our main finding demonstrates that oral administration of olanzapine but not ziprasidone leads to a decrease in whole body insulin sensitivity in response to a hyperinsulinemic euglycemic challenge. Our finding is suggestive that not all atypical antipsychotics cause acute direct effects on glucose disposal and that accurate determination of side effect profile should be performed when choosing an atypical antipsychotic.     

Comparative amnesic and sedative effects of lorazepam and oxazepam in healthy volunteers

Oxazepam and its chlorinated derivative, lorazepam, have similar half-lives but differing potencies. This study compared the effects of these two benzodiazepines with a placebo on memory, mood and psychomotor function. Thirty six volunteers took part in a double-blind, independent groups design. Subjects completed a battery of tests before and 2.5 h after drug administration. Lorazepam 2 mg produced more profound subjective and motor sedation than oxazepam 30 mg, and this in turn produced a similar, global pattern of impairments across a wide range of tasks. However, lorazepam produced greater decrements than oxazepam on a task involving episodic memory even when sedative effects were partialled out. We suggest that this finding may reflect either differential task sensitivities or a contribution of priming to performance on the explicit memory task.     

Pharmacokinetic interactions between ritonavir and quinine in healthy volunteers following concurrent administration

AIMS

To evaluate the pharmacokinetic interactions between ritonavir and quinine in healthy volunteers.

METHODS

Ten healthy volunteers were each given 600-mg single oral doses of quinine alone, ritonavir alone (200 mg every 12 h for 9 days), and quinine in combination with ritonavir, in a three-period pharmacokinetic nonrandomized sequential design study. Quinine was co-administered with the 15th dose of ritonavir. Blood samples collected at predetermined time intervals were analysed for ritonavir, quinine and its major metabolite, 3-hydroxyquinine, using a validated high-performance liquid chromatography method.

RESULTS

Concurrent ritonavir administration resulted in about fourfold increases in both the C_max and AUC_T[C_max 2.79 ± 0.22 vs. 10.72 ± 0.32 mg l⁻¹, 95% confidence interval (CI) 7.81, 8.04; AUC 50.06 ± 2.52 vs. 220.47 ± 6.68 mg h⁻¹ l⁻¹, 95% CI 166.3, 175.3], a significant increase (P < 0.01) in the elimination half-life (11.15 ± 0.80 vs. 13.37 ± 0.33 h, 95% CI 1.64, 2.77) and about a 4.5-fold decrease in CL/F (12.01 ± 0.61 vs. 2.71 ± 0.09 l h⁻¹) of quinine. Also, with ritonavir, there was a pronounced reduction of AUC(metabolite)/AUC(unchanged drug) ratio of quinine (1.35 ± 0.10 vs. 0.13 ± 0.02) along with a marked decrease in C_max (1.80 ± 0.12 vs. 0.96 ± 0.09 mg l⁻¹) and AUC_0–48h (62.80 ± 6.30 vs. 25.61 ± 2.44 mg h⁻¹ l⁻¹) of the metabolite. Similarly, quinine caused modest but significant increases (P < 0.01) in the C_max, AUC and elimination T_½ of ritonavir.

CONCLUSIONS

Downward dosage adjustment of quinine appears necessary when concurrently administered with ritonavir.     

The effect of fever on quinine and quinidine disposition in the rat.

The pharmacokinetics of quinine and its diastereoisomer quinidine has been investigated in normal and febrile rats. Endotoxin-induced fever in rats resulted in an increased quinine clearance (CL) (4.49 +/- 1.45 vs 1.38 +/- 0.65 L h-1 kg-1, P less than 0.001) and volume of distribution (Vd) (42.6 +/- 8.8 vs 28.9 +/- 10.3 L kg-1, P less than 0.05) with a concomitant shortening of the elimination half-life (t1/2) (7.1 +/- 2.5 vs 15.9 +/- 5.9 h, P less than 0.01). With quinidine, however, fever resulted in an increased CL (3.95 +/- 1.05 vs 1.89 +/- 0.60 L h-1 kg-1, P less than 0.002) with no change in Vd and a significant decrease in t1/2 (5.1 +/- 0.7 vs 10.1 +/- 2.8 h, P less than 0.001). In both studies there was no significant difference in hepatic microsomal protein or cytochrome P450 content. Neither drug accumulated in the liver but low concentrations of quinidine were present in the heart 24 h after administration. In-vitro studies suggest that temperature does not alter the binding of either drug. These data suggest that fever enhances the clearance of quinine and quinidine. These findings may offer some additional explanation of the lack of serious quinine and quinidine toxicity during the treatment of malaria infection, even after large dosages of the drug administered during the initial period of treatment when fever is most intense.     

Effects of concurrent administration of nevirapine on the disposition of quinine in healthy volunteers

Objectives Nevirapine and quinine are likely to be administered concurrently in the treatment of patients with HIV and malaria. Both drugs are metabolised to a significant extent by cytochrome P450 (CYP)3A4 and nevirapine is also an inducer of this enzyme. This study therefore evaluated the effect of nevirapine on the pharmacokinetics of quinine. Methods Quinine (600 mg single dose) was administered either alone or with the 17th dose of nevirapine (200 mg every 12 h for 12 days) to 14 healthy volunteers in a crossover fashion. Blood samples collected at predetermined time intervals were analysed for quinine and its major metabolite, 3‐hydroxquinine, using a validated HPLC method. Key findings Administration of quinine plus nevirapine resulted in significant decreases (P < 0.01) in the total area under the concentration–time curve (AUC_T), maximum plasma concentration (C_max) and terminal elimination half‐life (T_1/2β) of quinine compared with values with quinine dosing alone (AUC: 53.29 ± 4.01 vs 35.48 ± 2.01 h mg/l; C_max: 2.83 ± 0.16 vs 1.81 ± 0.06 mg/l; T_1/2β: 11.35 ± 0.72 vs 8.54 ± 0.76 h), while the oral plasma clearance markedly increased (11.32 ± 0.84 vs 16.97 ± 0.98 l/h). In the presence of nevirapine there was a pronounced increase in the ratio of AUC(metabolite)/AUC (unchanged drug) and highly significant increases in C_max and AUC of the metabolite (P < 0.01). Conclusions Nevirapine significantly alters the pharmacokinetics of quinine. An increase in the dose of quinine may be necessary when the drug is co‐administered with nevirapine.     

The metabolism of imiloxan hydrochloride in healthy male volunteers.

1. The metabolism of imiloxan hydrochloride [(+-)-2-(1-ethyl-2-imidazoyl)methyl-1,4-benzodioxane hydrochloride], an alpha 2-adrenoceptor antagonist, was studied in four male volunteers given a 500 mg oral dose containing 0.48 MBq of the 14C-labelled material. Compound-related radioactivity was rapidly excreted chiefly in the urine within 24 h of dosing. 2. Metabolites derived by initial oxidation on either or both the benzodioxane and imidazoyl moieties followed by glucuronic acid and sulphate conjugation, and an N-glucuronide of imiloxan were tentatively identified in urine. 3. The major urinary metabolites, comprising some 37-41% of the dose, appeared to be +-2-(1-ethyl-2-imidazoyl)methyl-1,4-benzodioxane-6/7-sulphonic acid (19% of dose), [+-2-(1-ethyl-2-imidazoyl)methyl-1,4-benzodioxane- 6/7-ylium D-glucopyranoside]uronate (10-14% of dose), and a glucuronide conjugate of +-2-(1-ethyl-2-imidazoyl-4/5-hydroxy)methyl-1,4-benzodioxane (8% of dose).     

Comparative electrophysiologic effects of metabolites of quinidine and hydroquinidine.

To evaluate whether the hydroxylated metabolites of quinidine (Q) and hydroquinidine (HQ): hydroxy-3S-quinidine (OH-Q) and hydroxy-3S-hydroquinidine (OH-HQ), exert electrophysiologic effects and participate in the therapeutic action of the parent drugs, we examined and compared the effects of the metabolites and the parent drugs on the electrical activity of guinea pig ventricular cells recorded by standard microelectrode technique. In addition, we investigated the potential arrhythmogenic properties of these compounds in rabbit Purkinje fibers in low K+ (2.7 mM) Tyrode's solution. The concentration [C]-, frequency-, and voltage-dependent effects of the drugs were investigated. Maximum upstroke velocity of phase 0 (Vmax) was [C]-dependently depressed by both OH-Q and OH-HQ but at a lesser degree than with Q and HQ, respectively: at the [C] of 50 microM, Vmax depression attained 26.7 +/- 2.6% with OH-Q versus 45.9 +/- 1.6% with Q and 32.3 +/- 1.9% with OH-HQ versus 54.6 +/- 1.4% with HQ. This effect was frequency and voltage dependent without significant differences between the four compounds. In the presence of equipotent [C], recovery kinetics of Vmax was significantly slower with metabolites than with respective parent drugs. In contrast, the effects of metabolites on action potential duration at 90% of repolarization (APD90) and effective refractory period (ERP) differed from those observed with parent drugs. With metabolites, APD90 and ERP were increased in a [C]-dependent manner, whereas the Q- and HQ-induced lengthening in APD90 and ERP was observed only at low concentration and low frequency. In addition, the OH-Q- and OH-HQ-induced APD90 lengthening was not altered by increasing pacing rate. In rabbit Purkinje fibers, increase in cycle length and prolonged exposure to either metabolites or parent drug caused early afterdepolarizations (EADs) and triggered activity. With all drugs tested, EADs arose more frequently at the plateau level than at the final repolarization of AP, but the incidence of EADs appeared to be much lower with metabolites than with parent drugs. The present results demonstrate that OH-Q and OH-HQ exert qualitatively similar but quantitatively less potent depressant effects on Vmax than Q and HQ, respectively, but differ in the lengthening effect on APD. We suggest that metabolites may participate in class I antiarrhythmic action of their respective parent drug and contribute to their arrhythmogenicity.     

Effects of rifampicin on porphyrin metabolism in healthy volunteers

Pregnane X receptor (PXR) is known to stimulate haem synthesis, but detailed knowledge on the effects of PXR activation on porphyrin metabolism in humans is lacking. We utilized a randomized, crossover, open (blinded laboratory) and placebo-controlled trial with 600-mg rifampicin or placebo dosed for a week to investigate the effects of PXR activation on erythrocyte, plasma, faecal and urine porphyrins. Sixteen healthy volunteers participated on the trial, but the number of volunteers for blood and urine porphyrin analyses was 15 while the number of samples for faecal analyses was 14. Rifampicin increased urine pentaporphyrin concentration 3.7-fold (mean 1.80 ± 0.6 vs. 6.73 ± 4.4 nmol/L, p = 0.003) in comparison with placebo. Urine coproporphyrin I increased 23% (p = 0.036). Faecal protoporphyrin IX decreased (mean 31.6 ± 23.5 vs. 19.2 ± 27.8 nmol/g, p = 0.023). The number of blood erythrocytes was slightly elevated, and plasma bilirubin, catabolic metabolite of haem, was decreased. In conclusion, rifampicin dosing elevated the excretion of certain urinary porphyrin metabolites and decreased faecal protoporphyrin IX excretion. As urine pentaporphyrin and coproporphyrin I are not precursors in haem biosynthesis, increased excretion may serve as a hepatoprotective shunt when haem synthesis or porphyrin levels are increased.     

奎尼丁和奎宁对人和大鼠肝微粒体氧化酶的抑制作用

奎尼丁和奎宁对人和大鼠肝微粒体氧化酶的抑制作用１涂植光，赵梁立２（重庆医科大学临床生化教研室，２药理教研室，重庆６３００４６，中国）关键词奎尼丁；奎宁；肝微粒体；遗传药理学；丁呋洛尔；烃基香豆素脱烃基酶；芳基烃羟化酶类目的：比较奎尼丁和奎宁对人和大鼠...     

Differences in the binding of quinine and quinidine to plasma proteins.

1. Little is known about the comparative plasma protein binding of the antimalarial agents quinine (QN) and its isomer quinidine (QD). We have examined the in vitro binding of QN and QD to albumin, alpha 1-acid glycoprotein, normal human plasma, and maternal and foetal umbilical cord plasma. 2. QN was more avidly bound than QD, and binding of both drugs was substantially higher to alpha 1-acid glycoprotein than to albumin, indicating that alpha 1-acid glycoprotein is the more important binding protein. 3. Protein and drug concentration dependent binding was evident for both QN and QD. The unbound fraction of both drugs fell with increasing albumin (10 to 60 g l-1) and alpha 1-acid glycoprotein (0.5 to 2.0 g l-1) concentration, and there was a marked increase in unbound fraction of QN (6 to 19%) and QD (13 to 36%) in human plasma when drug concentrations were increased over the antimalarial therapeutic range (0.5 to 10 mg l-1). 4. In human volunteer plasma, the unbound fractions of QN and QD were 7.5 +/- 2.2% and 12.3 +/- 2.3% respectively, whilst the unbound fractions for both drugs were significantly higher in maternal plasma (QN = 13.0 +/- 5.4%, QD = 18.3 +/- 2.5%) and significantly higher still in foetal umbilical cord plasma (QN = 25.7 +/- 10%, QD = 35 +/- 5.3%).