Pregnancy and use of oral contraceptives reduces the biotransformation of proguanil to cycloguanil

OBJECTIVE

To determine the effects of late pregnancy and also oestrogen supplementation on the CYP2C19-mediated biotransformation of proguanil (PG) to its active antifol triazine metabolite cycloguanil (CG).

METHODS

Case control study conducted on the NW border of Thailand; a single dose of PG (4 mg/kg) was administered to Karen women in late pregnancy and a single blood and urine sample taken 6 h later. Women were studied in late pregnancy (>36 weeks) and restudied 2 months after delivery. A separate cohort of Karen women newly attending a birth-control clinic were studied before and 3 weeks into their first course of oral contraceptives (OCP: levonorgestrel 0.15 mg and ethinyloestradiol 0.03 mg). Forty-five pregnant women and forty-two healthy OCP users were studied.

RESULTS

The results were similar in both groups; pregnancy and OCP use were both associated with reduced formation of cycloguanil (CG). Impaired PG biotransformation was seen in women with the "extensive metaboliser" phenotype (urine PG/CG ratio <10). CG levels, adjusted for dose, were a median (range) 73% (-59 to 420%) higher following the pregnancy than during the pregnancy in women characterised as extensive metabolisers ( P<0.001). CG levels in women characterised as extensive metabolisers were 34% (-54 to 323%) higher before than while taking the OCP ( P<0.01).

CONCLUSION

Late pregnancy and OCP use impair biotransformation of the active antimalarial metabolite CG from the parent PG. This may be mediated by oestrogen inhibition of CYP2C19 activity. The dose of PG should be increased by 50% in these groups.

Submicroscopic Plasmodium falciparum infections in pregnancy in Ghana

Malarial parasitaemia below the threshold of microscopy but detectable by polymerase chain reaction (PCR) assays is common in endemic regions. This study was conducted to examine prevalence, predictors, and effects of submicroscopic Plasmodium falciparum infections in pregnancy. In a cross-sectional study among 530 pregnant women in Ghana, plasmodial infections were assessed by microscopy and PCR assays. Concentrations of haemoglobin and C-reactive protein (CRP) were measured and antimalarial drugs (chloroquine, pyrimethamine) in urine were demonstrated by ELISA dipsticks. By microscopy, 32% of the women were found to harbour malaria parasites. This rate increased to 63% adding the results of the parasite-specific PCR. P. falciparum was present in all but one infection. With increasing gravidity, infection rates and parasite densities decreased and the proportions of submicroscopic parasitaemia among infected women grew. Correspondingly, anaemia, fever and evidence of inflammation (CRP > 0.6 mg/dl) were more frequent in primigravidae than in multigravidae. Antimalarial drugs were detected in 65% of the women and were associated with a reduced prevalence of P. falciparum infections and a raised proportion of submicroscopic parasitaemia. Both gravidity and antimalarial drug use were independent predictors of submicroscopic P. falciparum infections. These infections caused a slight reduction of Hb levels and considerably increased serum concentrations of CRP. Conventional microscopy underestimates the actual extent of malarial infections in pregnancy in endemic regions. Submicroscopic P. falciparum infections are frequent and may contribute to mild anaemia and inflammation in seemingly aparasitaemic pregnant women.

Artemisinin induces omeprazole metabolism in human beings

OBJECTIVE

This study investigated whether time-dependent artemisinin pharmacokinetics correlated to CYP3A4 or CYP2C19 activity in vivo.

METHODS

Artemisinin (two oral doses per day of 250 mg) was given to nine healthy Vietnamese subjects for 7 days (day 1 to day 7). Single 20 mg doses of omeprazole were given orally on day -7, day 1, and day 7. Single doses of artemisinin and omeprazole were given in combination on day 14 after a 6-day washout period. The pharmacokinetics of artemisinin, omeprazole, hydroxyomeprazole, and omeprazole sulfone were evaluated on days -7, 1, 7, and 14. On the same days urine was collected for the determination of 6beta-hydroxycortisol and cortisol excretion.

RESULTS

Areas under plasma concentration-time curves (AUC) for artemisinin and omeprazole decreased on day 7 to 20% (95% confidence intervals, 13%, 28%) and 35% (25%, 46%), respectively, compared with values on day 1. AUC ratios for hydroxyomeprazole/omeprazole increased 2.2-fold (1.7, 2.7) on day 7 compared with values on day 1. All values were normalized at day 14. There were no significant changes in the omeprazole sulfone/omeprazole ratio or in the 6beta-hydroxycortisol/cortisol ratio between the study days. In one subject found to have poor CYP2C19 metabolization, the elimination of omeprazole increased after artemisinin exposure, with no change in the hydroxyomeprazole/omeprazole AUC ratio.

CONCLUSION

Artemisinin did not alter CYP3A4 activity, whereas an increase in CYP2C19 activity was observed. The increased elimination of omeprazole in both poor and extensive CYP2C19 metabolizers suggests artemisinin induces both CYP2C19 and another enzyme.

Simultaneous determination of quinine and chloroquine anti-malarial agents in pharmaceuticals and biological fluids by HPLC and fluorescence detection

Even nowadays millions of people suffer and even die each year from malaria and hundreds of millions of people especially in tropical countries. Quinine (Q) a natural occurring alkaloid and chloroquine (CQ) a synthetic drug are widely used as anti-malarial agents. Herein an isocratic reversed-phase high performance liquid chromatographic (RP-HPLC) method is described for the simultaneous determination of quinine and chloroquine, at low concentrations, in pharmaceuticals and biological fluids. The present method is characterized by higher sensitivity and analytes are separated in less time than the already published methods. The analytical column, an MZ Kromasil, C18, 5 microm, 250 x 4mm, was operated at ambient temperature with backpressure values of 230 kg/cm(2). Mobile phase consisted of methanol-acetonitrile-0.1 mol/L ammonium acetate, (45:15:40 v/v) at a flow rate of 1.0 mL/min. Fluorescence detection was performed at excitation 325 nm and emission 375 nm, respectively. Salicylic acid was used as internal standard at a concentration of 0.5 ng/microL, resulting in a detection limit of 0.3 ng, while upper limit of linear range was 0.7 ng/microL for quinine and 0.5 ng/microL for chloroquine. Separation was completed within 5 min. The statistical evaluation of the method was examined performing intra-day (n=8) and inter-day calibration (n=8) and was found to be satisfactory, with high accuracy and precision results. Solid phase extraction provided high relative extraction recoveries from biological matrices: 92.1% for quinine and 105.4% for chloroquine from blood serum and 101.8% for quinine and 90.7% for chloroquine from urine.

Pharmacokinetic interaction of chloroquine and methylene blue combination against malaria

OBJECTIVE

The combination of chloroquine and methylene blue is potentially effective for the treatment of chloroquine-resistant malaria caused by Plasmodium falciparum. The aim of this study was to investigate whether methylene blue influences the pharmacokinetics of chloroquine.

METHODS

In a randomized, placebo-controlled, parallel group design, a 3-day course of therapeutic oral doses of chloroquine (total 2.5 g in male, 1.875 g in female participants) with oral co-administration of placebo or 130 mg methylene blue twice daily for 3 days was administered to 24 healthy individuals. Chloroquine, desethylchloroquine, and methylene blue concentrations were determined by means of HPLC/UV or LC/MS/MS assays in whole blood, plasma, and urine for 28 days after the last dose.

RESULTS

During methylene blue exposure, the area under the chloroquine whole blood concentration-time curve normalized to body weight (AUC(0-24 h)/BW) yielded a trend of reduction (249+/-98.2 h mug l(-1) kg(-1) versus 315+/-65.0 h mug l(-1) kg(-1), P=0.06). The AUC(0-24 h)/BW of desethylchloroquine was reduced by 35% (104+/-40.3 h mug l(-1) kg(-1) versus 159+/-66.6 h mug l(-1) kg(-1), P=0.03), whereas the metabolic ratio between chloroquine and desethylchloroquine remained unchanged (2.25+/-0.49 versus 1.95+/-0.42, P=0.17). The renal clearance of chloroquine and the ratio between chloroquine in whole blood and plasma remained unchanged (P>0.1).

CONCLUSION

Oral co-administration of methylene blue appears to result in a small reduction of chloroquine exposure which is not expected to be clinically relevant and thus represents no concern for further development as an anti-malarial combination.

High-performance liquid chromatographic method for determination of amodiaquine, chloroquine and their monodesethyl metabolites in biological samples

A high-performance liquid chromatographic method for determination of amodiaquine (AQ), desethylamodiaquine (DAQ), chloroquine (CQ) and desethylchloroquine (DCQ) in human whole blood, plasma and urine is reported. 4-(4-Dimethylamino-1-methylbutylamino)-7-chloroquinoline was used as internal standard. The drugs and the internal standard were extracted into di-isopropyl ether as bases and then re-extracted into an acidic aqueous phase with 0.1 M phosphate buffer at pH 4.0 for AQ samples and at pH 2.5 for CQ filter paper samples. A C(18) column was used and the mobile phase consisted of methanol-phosphate buffer (0.1 M, pH 3)-perchloric acid (250: 747.5:2.5, v/v). The absorbance of the drugs was monitored at 333 nm and no endogenous compound interfered at this wavelength. The limit of quantification in whole blood, plasma and urine was 100 nM for AQ and DAQ (sample size 100 microliter) as well as for CQ and DCQ in blood samples dried on filter paper. For 1000 microliter AQ and DAQ samples, the limit of quantification was 10 nM in all three biological fluids. The within-assay and between-assay coefficients of variations were always <10% at the limits of quantification. Plasma should be preferred for the determination of AQ and DAQ since use of whole blood may be associated with stability problems.

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 beta-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.

Quantitation of the antimalarial agent, mefloquine, in blood, plasma, and urine using high-pressure liquid chromatography

Sensitive and specific assays are described for the quantitation of mefloquine in whole blood, plasma, and urine specimens using high-pressure liquid chromatography. Specimens were extracted with ethyl acetate and concentrated before chromatography. Whole blood and plasma extracts were chromatographed on a polar bonded phase partitioning column, and urine extracts were chromatographed on a bonded reversed-phase partitioning column. The sensitivity of the assays for mefloquine was 0.05 microgram/ml of whole blood or plasma and 0.25 microgram/ml of urine using 5-ml samples. The assays are suitable for studying mefloquine pharmacokinetics in humans.

Enantioselective disposition of hydroxychloroquine after a single oral dose of the racemate to healthy subjects

1. Stereoselectivity in the disposition of hydroxychloroquine was investigated in 23 healthy males following a single oral dose of 200 mg racemic HCQ (rac-HCQ) sulphate. Total concentrations (R+S) and R/S ratios of HCQ and its metabolites were measured by stereoselective h.p.l.c. 2. HCQ was detected in whole blood and urine, up to 91 and 85 days after dosing, respectively. Metabolites could not be detected in whole blood while in urine detectable concentrations were still present after 85 days. The blood concentrations of HCQ enantiomers were measurable until 168 h post-dose. 3. R(-)-HCQ accounted for 62 +/- 3% (mean +/- s.d.) of the AUC of rac-HCQ AUC. The elimination half-life of S(+)-HCQ (457 +/- 122 h) was significantly shorter than that of R(-)-HCQ (526 +/- 140 h), partly due to its faster urinary excretion and hepatic metabolism. Its renal clearance was twice that of R(-)-HCQ (4.61 +/- 4.01 vs 1.79 +/- 1.30 1 h-1), and metabolites derived from the S-isomer represented 80-90% of the urinary recovery of the dose. 4. Over 85 days, 4.4 +/- 2.9 and 3.3 +/- 1.8% of the dose was recovered in urine as unchanged S(+)-HCQ and R(-)-HCQ, respectively. For the first 2 weeks, S(+)-HCQ excretion rate clearly surpassed that of R(-)-HCQ whereas afterwards the inverse was observed. However, since the first 2 weeks account for 95% of rac-HCQ renal excretion, the total urinary excretion of S(+)-HCQ clearly surpassed that of R(-)-HCQ.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of human urinary metabolites of the antimalarial piperaquine

Five metabolites of the antimalarial piperaquine (PQ) (1,3-bis-[4-(7-chloroquinolyl-4)-piperazinyl-1]-propane) have been identified and their molecular structures characterized. After a p.o. dose of dihydroartemisinin-piperaquine, urine collected over 16 h from two healthy subjects was analyzed using liquid chromatography (LC)/UV, LC/tandem mass spectrometry (MS/MS), Fourier transform ion cyclotron resonance (FTICR)/MS, and H NMR. Five different peaks were recognized as possible metabolites [M1, 320 m/z; M2, M3, and M4, 551 m/z (PQ + 16 m/z); and M5, 567 m/z (PQ + 32 m/z)] using LC/MS/MS with gradient elution. The proposed carboxylic M1 has a theoretical monoisotopic molecular mass of 320.1166 m/z, which is in accordance with the FTICR/MS (320.1168 m/z) findings. The LC/MS/MS results also showed a 551 m/z metabolite (M2) with a distinct difference both in polarity and fragmentation pattern compared with PQ, 7-hydroxypiperaquine, and the other 551 m/z metabolites. We suggest that this is caused by N-oxidation of PQ. The results showed two metabolites (M3 and M4) with a molecular ion at 551 m/z and similar fragmentation pattern as both PQ and 7-hydroxypiperaquine; therefore, they are likely to be hydroxylated PQ metabolites. The molecular structures of M1 and M2 were also confirmed using H NMR. Urinary excretion rate in one subject suggested a terminal elimination half-life of about 53 days for M1. Assuming formation rate-limiting kinetics, this would support recent findings that the terminal elimination half-life of PQ has been underestimated previously.

Alteration of the intravenous pharmacokinetics of a synthetic ozonide antimalarial in the presence of a modified cyclodextrin

The pharmacokinetic profile and renal clearance of a novel synthetic ozonide antimalarial (1) was found to be significantly altered when intravenously administered to rats as a cyclodextrin-based formulation (0.1 M Captisol, a sulfobutylether beta-cyclodextrin derivative (SBE(7)-beta-CD)) compared to a cyclodextrin-free isotonic buffered glucose formulation. There was an 8.5-fold decrease in the steady-state blood volume of distribution, a 6.6-fold decrease in the mean residence time and a greater than 200-fold increase in renal clearance of 1 when administered in the cyclodextrin formulation. Analysis of the whole blood and plasma concentration profiles revealed an essentially constant blood to plasma ratio when 1 was administered in the cyclodextrin-free formulation, whereas this ratio changed as a function of time when administered in the presence of the cyclodextrin derivative. It is postulated that the observed differences were due to a very strong complexation interaction between 1 and the cyclodextrin, resulting in a slow dissociation of the complex in vivo, and altered distribution and excretion profiles. Preliminary studies using isothermal titration calorimetry (ITC) indicated that the association constant for the 1/Captisol complex was approximately two orders of magnitude higher than reported for typical drug/cyclodextrin complexes.

Detection and determination of antimalarial drugs and their metabolites in body fluids

This review of methods for determining antimalarial drugs in biological fluids has focused on the various analytical techniques for the assay of chloroquine, quinine, amodiaquine, mefloquine, proguanil, pyrimethamine, sulphadoxine, primaquine and some of their metabolites. The methods for determining antimalarials and their metabolites in biological samples have changed rapidly during the last eight to ten years with the increased use of chromatographic techniques. Chloroquine is still the most used antimalarial drug, and various methods of different complexity exist for the determination of chloroquine and its metabolites in biological fluids. The pharmacokinetics of chloroquine and other antimalarials have been updated using these new methods. The various analytical techniques have been discussed, from simple colorimetric methods of intermediate selectivity and sensitivity to highly sophisticated, selective and sensitive chromatographic methods applied in a modern analytical laboratory. Knowledge concerning the method for a particular study is determined by the type of application and the facilities, equipment and personnel available. Often is it useful to apply various methods when conducting a clinical study in malaria-endemic areas. Field-adapted methods for the analysis of urine samples can be applied at the study site for screening, and corresponding blood samples can be preserved for subsequent analysis in the laboratory. Selecting samples for laboratory analysis is based on clinical, parasitological and field-assay data. The wide array of methods available for chloroquine permit carefully tailored approaches to acquire the necessary analytical information in clinical field studies concerning the use of this drug. The development of additional field-adapted and field-interfaced methods for other commonly used antimalarials will provide similar flexibility in field studies of these drugs.

Modified high-performance liquid chromatographic method to measure both dextromethorphan and proguanil for oxidative phenotyping

The activities of the polymorphic enzymes cytochromes P450 2D6 and 2C19 can be assessed by administering the probe drugs, dextromethorphan and proguanil, respectively. An existing high-performance liquid chromatographic technique, which measures dextromethorphan and its metabolites, has been modified to also measure proguanil and its polymorphic metabolite, cycloguanil in urine. Proguanil and cycloguanil are assayed in separate aliquots of urine to that used for dextromethorphan/dextrorphan as pretreatment with beta-glucuronidase is required for the analysis of dextrorphan. To assay all four compounds a common extraction procedure is used and a single reversed-phase column and isocratic mobile phase with UV and fluorescence detectors connected in series are required. This technique is specific and sensitive for each analyte (limits of detection, dextrorphan/dextromethorphan/proguanil: 0.1 microgram/ml, cycloguanil: 0.2 microgram/ml). All assays are linear over the concentration ranges investigated (dextromethorphan/dextrorphan: 0.5-10 micrograms/ml, proguanil/cycloguanil: 1-20 micrograms/ml). The method described therefore uses laboratory resources very efficiently for all the assays required for hydroxylation phenotyping using proguanil and dextromethorphan.

Metabolism of primaquine in normal human volunteers: investigation of phase I and phase II metabolites from plasma and urine using ultra-high performance liquid chromatography-quadrupole time-of-flight mass spectrometry

BACKGROUND

Primaquine (PQ), an 8-aminoquinoline, is the only drug approved by the United States Food and Drug Administration for radical cure and prevention of relapse in Plasmodium vivax infections. Knowledge of the metabolism of PQ is critical for understanding the therapeutic efficacy and hemolytic toxicity of this drug. Recent in vitro studies with primary human hepatocytes have been useful for developing the ultra high-performance liquid chromatography coupled with high-resolution mass spectrometric (UHPLC-QToF-MS) methods for simultaneous determination of PQ and its metabolites generated through phase I and phase II pathways for drug metabolism.

METHODS

These methods were further optimized and applied for phenotyping PQ metabolites from plasma and urine from healthy human volunteers treated with single 45 mg dose of PQ. Identity of the metabolites was predicted by MetaboLynx using LC-MS/MS fragmentation patterns. Selected metabolites were confirmed with appropriate standards.

RESULTS

Besides PQ and carboxy PQ (cPQ), the major plasma metabolite, thirty-four additional metabolites were identified in human plasma and urine. Based on these metabolites, PQ is viewed as metabolized in humans via three pathways. Pathway 1 involves direct glucuronide/glucose/carbamate/acetate conjugation of PQ. Pathway 2 involves hydroxylation (likely cytochrome P450-mediated) at different positions on the quinoline ring, with mono-, di-, or even tri-hydroxylations possible, and subsequent glucuronide conjugation of the hydroxylated metabolites. Pathway 3 involves the monoamine oxidase catalyzed oxidative deamination of PQ resulting in formation of PQ-aldehyde, PQ alcohol and cPQ, which are further metabolized through additional phase I hydroxylations and/or phase II glucuronide conjugations.

CONCLUSION

This approach and these findings augment our understanding and provide comprehensive view of pathways for PQ metabolism in humans. These will advance the clinical studies of PQ metabolism in different populations for different therapeutic regimens and an understanding of the role these play in PQ efficacy and safety outcomes, and their possible relation to metabolizing enzyme polymorphisms.

Quinidine as a probe for CYP3A4 activity: intrasubject variability and lack of correlation with probe-based assays for CYP1A2, CYP2C9, CYP2C19, and CYP2D6

BACKGROUND

In vitro studies have shown that the formation of 3-hydroxyquinidine from quinidine is catalyzed almost exclusively by CYP3A4. In vivo this result has been supported in various interaction studies, and the use of this reaction as an in vivo biomarker reaction of CYP3A4 activity has been suggested. We studied the possible correlation of the formation clearance of 3-hydroxyquinidine with probe-based assays for CYP1A2, CYP2C9, CYP2C19, and CYP2D6. Descriptive analyses of the outcome of various biomarker reactions were performed.

METHODS

Forty-two healthy, young male volunteers participated in an open study consisting of two identical test periods separated by a 12- to 14-week washout period. In each period biomarker reactions of CYP1A2 (caffeine), CYP2C9 (tolbutamide), CYP2C19 (mephenytoin), CYP2D6 (sparteine), CYP3A4 (urinary excretion of 6beta-hydroxycortisol), as well as the pharmacokinetics of quinidine after a 200-mg single oral dose of quinidine sulfate were studied.

RESULTS

The median formation clearance of 3-hydroxyquinidine were 2.40 and 2.33 L/h in the two test periods. As measured by the formation clearance of 3-hydroxyquinidine, the intraindividual coefficient of variation for CYP3A4 activity was 18%, whereas the interindividual activity varied fourfold. The formation clearance of 3-hydroxyquinidine did not correlate with the outcome of indexes for activities of CYP1A2, CYP2C9, CYP2C19, or CYP2D6 or the urinary excretion of 6beta-hydroxycortisol. The formation clearance of 3-hydroxyquinidine correlated well to point values of 3-hydroxyquinidine to quinidine ratios in plasma and urine.

CONCLUSION

The formation clearance of 3-hydroxyquinidine after a single oral dose of 200 mg quinidine sulfate may represent a useful index of CYP3A4 activity in vivo.

The pharmacokinetics of mefloquine in man: lack of effect of mefloquine on antipyrine metabolism

A method is described for the determination of the new antimalarial agent, mefloquine, in plasma and urine. After oral administration of 750 mg mefloquine to six volunteers, absorption, was apparently slow, with plasma mefloquine concentrations at 24 h (559 +/- 181 ng ml-1; mean +/- s.d.) higher than at 6 h (459 +/- 166 ng ml-1). The elimination half-life was 373 +/- 249 h, oral clearance was 5.09 +/- 2.7 1 h-1, and apparent volume of distribution was 35.7 +/- 30.7 l kg-1 (assuming 100% bioavailability). Mefloquine (750 mg) had no significant effect on salivary kinetics of antipyrine or on the metabolic clearance of antipyrine to its three main metabolites, 3-hydroxymethylantipyrine, 4-hydroxyantipyrine and norantipyrine, when antipyrine was administered either 2 h or 2 weeks after dosing with mefloquine.

Rapid identification of phase I and II metabolites of artemisinin antimalarials using LTQ-Orbitrap hybrid mass spectrometer in combination with online hydrogen/deuterium exchange technique

Artemisinin drugs have become the first-line antimalarials in areas of multi-drug resistance. However, monotherapy with artemisinin drugs results in comparatively high recrudescence rates. Autoinduction of CYP-mediated metabolism, resulting in reduced exposure, has been supposed to be the underlying mechanism. To better understand the autoinduction of artemisinin drugs, we evaluated the biotransformation of artemisinin, also known as Qing-hao-su (QHS), and its active derivative dihydroartemisinin (DHA) in vitro and in vivo, using LTQ-Orbitrap hybrid mass spectrometer in conjunction with online hydrogen (H)/deuterium (D) exchange high-resolution (HR)-LC/MS (mass spectrometry) for rapid structural characterization. The LC separation was improved allowing the separation of QHS parent drugs and their metabolites from their diastereomers. Thirteen phase I metabolites of QHS have been identified in liver microsomal incubates, rat urine, bile and plasma, including six deoxyhydroxylated metabolites, five hydroxylated metabolites, one dihydroxylated metabolite and deoxyartemisinin. Twelve phase II metabolites of QHS were detected in rat bile, urine and plasma. DHA underwent similar metabolic pathways, and 13 phase I metabolites and 3 phase II metabolites were detected. Accurate mass data were obtained in both full-scan and MS/MS mode to support assignments of metabolite structures. Online H/D exchange LC-HR/MS experiments provided additional evidence in differentiating deoxydihydroxylated metabolites from mono-hydroxylated metabolites. The results showed that the main phase I metabolites of artemisinin drugs are hydroxylated and deoxyl products, and they will undergo subsequent phase II glucuronidation processes. This study also demonstrated the effectiveness of online H/D exchange LC-HR/MS(n) technique in rapid identification of drug metabolites.

Pharmacokinetic aspects of chloroquine-induced pruritus: influence of dose and evidence for varied extent of metabolism of the drug

The significance of a pharmacokinetics basis in chloroquine (CQ)-induced pruritus was investigated by determining the disposition of the drug in two groups of volunteers; pruritus positive and pruritus negative. Single oral dose of 600 mg CQ was administered to each of 36 volunteers, 18 for each of the two groups. After a washout period of 9 months, 150 mg single oral dose of the drug was given to 12 of the same volunteers, six each from the two groups. Blood and urine samples were collected at predetermined times following administration of each dose. Concentrations of CQ and its major metabolite, desethylchloroquine (CQM), were measured in plasma and urine using an established HPLC method. Results showed that the ratio, AUC (CQ)/AUC (CQM), as well as AUC(0-48 h) and 24-h urinary CQ excretion were all significantly higher (P<0.05) in pruritus-positive compared to pruritus-negative volunteers, following administration of the 600-mg CQ dose. Also, urinary drug-metabolite ratios monitored over 0-48 h postdose were markedly higher in the pruritus positive group. However, after administration of the 150-mg dose, 24-h urinary CQ collection and urinary drug-metabolite ratios were highly comparable between the two groups (P>0.1). This study indicates that there might be a decreased metabolism of CQ in subjects susceptible to CQ-induced pruritus following ingestion of a therapeutic dose. It also suggests that the extent of metabolism of CQ in this group may be influenced by the dose of the drug. Comparatively higher CQ levels in pruritus susceptible subjects may possibly be responsible for the pruritus experienced by such individuals when given therapeutic regimen.

Grapefruit juice has no effect on quinine pharmacokinetics

OBJECTIVE

As quinine is mainly metabolised by human liver CYP3A4 and grapefruit juice inhibits CYP3A4, the effect of grapefruit juice on the pharmacokinetics of quinine following a single oral dose of 600 mg quinine sulphate was investigated.

METHODS

The study was carried out in ten healthy volunteers using a randomised cross-over design. Subjects were studied on three occasions, with a washout period of 2 weeks. During each period, subjects received a pretreatment of 200 ml orange juice (control), full-strength grapefruit juice or half-strength grapefruit juice twice daily for 5 days. On day 6, the subjects were given a single oral dose of 600 mg quinine sulphate with 200 ml of one of the juices. Plasma and urine samples for measurement of quinine and its major metabolite, 3-hydroxyquinine, were collected over a 48-h period and analysed by means of a high-performance liquid chromatography method.

RESULTS

The intake of grapefruit juice did not significantly alter the oral pharmacokinetics of quinine. There were no significant differences among the three treatment periods with regard to pharmacokinetic parameters of quinine, including the peak plasma drug concentration (Cmax), the time to reach Cmax (tmax), the terminal elimination half-life (t1/2), the area under the concentration-time curve and the apparent oral clearance. The pharmacokinetics of the 3-hydroxyquinine metabolite were slightly changed when volunteers received grapefruit juice. The mean Cmax of the metabolite (0.25+/-0.09 mg l(-1), mean +/- SD) while subjects received full-strength grapefruit juice was significantly less than during the control period (0.31+/-0.06 mg l(-1), P < 0.05) and during the intake of half-strength grapefruit juice (0.31+/-0.07 mg l(-1), P < 0.05).

CONCLUSION

These results suggest that there is no significant interaction between the parent compound quinine and grapefruit juice, so it is not necessary to advise patients against ingesting grapefruit juice at the same time that they take quinine. Since quinine is a low clearance drug with a relatively high oral bioavailability, and is primarily metabolised by human liver CYP3A4, the lack of effect of grapefruit juice on quinine pharmacokinetics supports the view that the site of CYP inhibition by grapefruit juice is mainly in the gut.

Pharmacokinetics of halofantrine in the rat: stereoselectivity and interspecies comparisons

The antimalarial drug, halofantrine, is chiral and is administered clinically as the racemate. In order to define the pharmacokinetic properties of halofantrine enantiomers in the rat, male Sprague-Dawley rats (264-311 g) were given halofantrine HCl orally (n = 5; 14 mg/kg) or intravenously (i.v.) (n = 5; 2 mg/kg). Plasma samples were collected over a 72 h period, and these were assayed for halofantrine enantiomer concentrations using a stereospecific reverse phase HPLC assay. After dosing by both routes of administration the (+) enantiomer was found to have significantly higher AUC, and higher Cmax after oral dosing. Pharmacokinetic analysis indicated that in the rat, the (+) enantiomer is cleared slower, and is less extensively distributed than its antipode. The bioavailability of the enantiomers after oral administration was less than 27%. Urinary excretion was a negligible route of elimination of unchanged drug. Using allometry, the pharmacokinetics of (+/-)-halofantrine in rats scaled nicely with literature data from dogs and humans. The pharmacokinetic properties of halofantrine enantiomers in the rat resembled those seen in humans, indicating that the rat is a good model for the study of halofantrine pharmacokinetics.

A literature assessment of sample pretreatments and limits of detection for capillary electrophoresis of drugs in biological fluids and practical investigation with some antimalarials in plasma

A literature survey on published reports of the determination of drugs in biological fluids shows that all methods of sample pretreatment have been used and that the limits of detection achieved vary widely, ranging from low ngcm(-3) to microgcm(-3). The most widely used injection method was hydrodynamic and, in the majority of cases, whenever low detection limits were achieved, this was a result of preconcentration during the sample pretreatment. Only a small proportion of the reported methods employed electrokinetic injection and utilised the field amplified sample injection (FASI) techniques. An experimental investigation of the alternative hydrodynamic and electrokinetic injection methods for a small set of antimalarial drugs is reported. It was found that electrokinetic injection with FASI from an acetonitrile-water matrix produced dramatic improvements in detection limits. This improvement could not, however, be achieved when the drugs were in plasma using protein precipitation, liquid-liquid extraction or solid phase extraction pretreatment methods. This highlights the importance of sample pretreatment in utilising the potential sensitivity of capillary electrophoresis with electrokinetic injection.

Simultaneous determination of chloroquine, proguanil and their metabolites in human biological fluids by high-performance liquid chromatography

A reversed-phase ion-pair high-performance liquid chromatographic method with ultraviolet detection is described for the simultaneous measurement of chloroquine, proguanil and their major metabolites in human plasma, erythrocytes and urine. After a liquid-solid extraction on a Bond Elut C8 cartridge, the compounds are separated on a C8 Lichrospher 60 RP select B column by isocratic elution; the mobile phase is water-acetonitrile-methanol (78:28:4, v/v/v) with 0.5 M ammonium formate and 0.075 M perchloric acid. The eluent is monitored with an ultraviolet detector at 254 nm. The lower limits of quantification in plasma are near 6.0 ng ml-1 for chloroquine and near 9.0 ng ml-1 for proguanil. No chromatographic interference can be detected from endogenous compounds or from other antimalarial drugs. The method is accurate and precision is good with inter- and intra-assay relative standard deviations lower than 6.8% for plasma samples. N-(2-6 dichlorobenzylidene amino)guanidine is used as an internal standard. The chromatographic procedure takes 35 min and can be used for therapeutic drug monitoring and clinical studies.

In vitro and in vivo metabolism of pyronaridine characterized by low-energy collision-induced dissociation mass spectrometry with electrospray ionization

The in vitro and in vivo metabolism of pyronaridine, an antimalarial agent, was investigated in rats and humans. In vitro incubation of pyronaridine with rat and human liver microsomes resulted in the formation of 11 metabolites, with pyronaridine quinoneimine (M3) as the major metabolite. The structures of pyronaridine metabolites were characterized on the basis of the product ion mass spectra obtained under low-energy collision-induced dissociation (CID) ion trap mass spectrometry. Both pyronaridine (m/z 518) and M3 (m/z 516) produced the same product ion (m/z 447). These results could be explained by the characteristic neutral loss of a 69 Da fragment from M3 via gamma-H rearrangement and 1,7 sigmatropic shift, whereas the neutral loss of a 71 Da fragment from the pyronaridine occurred by charge site-initiated heterolytic cleavage. These fragmentations were further supported by the tandem mass spectrum of D(3)-pyronaridine. Other metabolites generated in the microsomal incubations were carbonylated, hydroxylated and O-demethylated derivatives. Pyronaridine and its metabolites were detected in both feces and urine after intraperitoneal administration to rats. The in vivo metabolic profile in rats was different from the in vitro profile. M3, a chemically reactive quinonimine, was not detected whereas O-demethylated derivatives (M14, M15, M16, and M19) were identified in fecal and urinary extracts. The role of quinoneimine metabolites in pyronaridine-caused toxicity should be further evaluated, although these metabolites or their conjugates were not detected in urine and feces.

Plasmodium falciparum pfcrt and pfmdr1 polymorphisms are associated with the pfdhfr N108 pyrimethamine-resistance mutation in isolates from Ghana

The Plasmodium falciparum chloroquine resistance transporter gene (pfcrt) T76 and multidrug resistance gene analogue (pfmdr1) Y86 mutations are associated with chloroquine(CQ)-resistance. In isolates from 172 pregnant women living in the area of Agogo, Ghana, pfcrt T76 was detected in 69% and pfmdr1 Y86 in 66%. Pfcrt T76 but not pfmdr1 Y86 was more prevalent in samples from women with residual CQ in urine or serum. Parasite densities and multiplicity of infection of pfmdr wild type but not of resistant isolates were reduced by CQ. Adjusted for CQ and pyrimethamine (PYR) in urine, the P. falciparum dihydrofolate reductase (pfdhfr) N108 mutation which confers PYR-resistance was 3.1 and 3 times, respectively, more likely to be detected in isolates containing pfcrt and pfmdr1 mutations than in those comprising wild type alleles. Pfcrt, pfmdr, and pfdhfr mutations are frequent in P. falciparum from this part of Ghana which may limit the choice of drugs for the prevention of malaria in pregnancy. The association of CQ- and PYR-resistance mutations independent of recent drug use could indicate accelerated development of resistance to structurally unrelated drugs. Alternatively, it may reflect selection of resistance in persisting infections due to no longer detectable drug pressure.

Sensitive ELISA dipstick test for the detection of chloroquine in urine under field conditions

OBJECTIVE

To evaluate a new enzyme-linked immunosorbent assay (ELISA) dipstick test for detecting chloroquine (CQ) in urine in a malaria-endemic region of north-western Namibia.

METHOD

Urine samples from 92 patients attending the outpatient department of Kamhaku Hospital with suspected malaria infection were tested for CQ with both the Dill-Glazko test and the ELISA dipstick test. Results were compared to the history of CQ intake as documented in the patients' health passes.

RESULTS

The dipstick test proved an easy-to-handle and very sensitive tool for the detection of CQ with a lower limit of detection at 120 nmol/l. It showed high agreement with the history of CQ intake within the last 6 months. The specificity in a negative control group was 100%. The Dill-Glazko test was far less sensitive and specific with a lower detection limit of 150 micromol/l.

CONCLUSION

The dipstick test can be used in pharmacological studies to evaluate the use of CQ, and as an inclusion criterion for in vivo and in vitro sensitivity tests, whereas the Dill-Glazko test is appropriate to test compliance during and a few days after CQ intake.