Influence of Proteome Profiles and Intracellular Drug Exposure on Differences in CYP Activity in Donor-Matched Human Liver Microsomes and Hepatocytes.

Human liver microsomes (HLM) and human hepatocytes (HH) are important in vitro systems for studies of intrinsic drug clearance (CLint) in the liver. However, the CLint values are often in disagreement for these two systems. Here, we investigated these differences in a side-by-side comparison of drug metabolism in HLM and HH prepared from 15 matched donors. Protein expression and intracellular unbound drug concentration (Kpuu) effects on the CLint were investigated for five prototypical probe substrates (bupropion-CYP2B6, diclofenac-CYP2C9, omeprazole-CYP2C19, bufuralol-CYP2D6, and midazolam-CYP3A4). The samples were donor-matched to compensate for inter-individual variability but still showed systematic differences in CLint. Global proteomics analysis outlined differences in HLM from HH and homogenates of human liver (HL), indicating variable enrichment of ER-localized cytochrome P450 (CYP) enzymes in the HLM preparation. This suggests that the HLM may not equally and accurately capture metabolic capacity for all CYPs. Scaling CLint with CYP amounts and Kpuu could only partly explain the discordance in absolute values of CLint for the five substrates. Nevertheless, scaling with CYP amounts improved the agreement in rank order for the majority of the substrates. Other factors, such as contribution of additional enzymes and variability in the proportions of active and inactive CYP enzymes in HLM and HH, may have to be considered to avoid the use of empirical scaling factors for prediction of drug metabolism.

Oil-Fortified Maize Porridge Increases Absorption of Lumefantrine in Children with Uncomplicated Falciparum Malaria.

Artemether-lumefantrine (AL) is a first-line treatment for uncomplicated malaria. Absorption of lumefantrine (LUM) is fat dependent, and in children, intake is recommended with milk. We investigated whether oil-fortified maize porridge can be an alternative when milk is not available. In an open-label pharmacokinetic study, Ugandan children <5 years with uncomplicated Plasmodium falciparum malaria were randomized to receive standard six-dose AL treatment [one tablet (20 mgA/120 mg LUM) if <15 kg and two tablets if >15 kg] with milk (A) or maize porridge plus oil (B). Parametric two-sample t-test was used to compare relative oral LUM bioavailability. The primary end-point was LUM exposure till 8 hr after the first dose (AUC0-8 hr ). Secondary outcome included day 7 concentrations (d7LUM ), LUM exposure between days 7 and 28 (AUCd7-28 ) and day 28 PCR-adjusted parasitological response. Evaluable children (n = 33) included 16 in arm A and 17 in arm B. The AUC0-8 hr was comparable between A and B [geometric mean (95% CI): 6.01 (3.26-11.1) versus 6.26 (4.5-8.43) hr*µg/mL, p = 0.9]. Less interindividual variability in AUC0-8 hr was observed in B (p = 0.01), but d7LUM and AUCd7-28 were comparable. Children receiving two tablets had significantly higher exposure than those receiving one tablet [median d7LUM (505 versus 289 ng/mL, p = 0.02) and AUCd7-28 (108 versus 41 hr*µg/mL, p = 0.006)]. One parasitological failure (d28 recrudescence) was observed. Our findings suggest that oil-fortified maize porridge can be an alternative to milk in augmenting absorption of LUM. The lower LUM exposure observed in children dosed with one AL tablet needs further attention.

Palmitoylethanolamide, a naturally occurring lipid, is an orally effective intestinal anti-inflammatory agent.

BACKGROUND AND PURPOSE: Palmitoylethanolamide (PEA) acts via several targets, including cannabinoid CB1 and CB2 receptors, transient receptor potential vanilloid type-1 (TRPV1) ion channels, peroxisome proliferator-activated receptor alpha (PPAR α) and orphan G protein-coupled receptor 55 (GRR55), all involved in the control of intestinal inflammation. Here, we investigated the effect of PEA in a murine model of colitis. EXPERIMENTAL APPROACH: Colitis was induced in mice by intracolonic administration of dinitrobenzenesulfonic acid (DNBS). Inflammation was assessed by evaluating inflammatory markers/parameters and by histology; intestinal permeability by a fluorescent method; colonic cell proliferation by immunohistochemistry; PEA and endocannabinoid levels by liquid chromatography mass spectrometry; receptor and enzyme mRNA expression by quantitative RT-PCR. KEY RESULTS: DNBS administration caused inflammatory damage, increased colonic levels of PEA and endocannabinoids, down-regulation of mRNA for TRPV1 and GPR55 but no changes in mRNA for CB1 , CB2 and PPARα. Exogenous PEA (i.p. and/or p.o., 1 mg·kg(-1) ) attenuated inflammation and intestinal permeability, stimulated colonic cell proliferation, and increased colonic TRPV1 and CB1 receptor expression. The anti-inflammatory effect of PEA was attenuated or abolished by CB2 receptor, GPR55 or PPARα antagonists and further increased by the TRPV1 antagonist capsazepine. CONCLUSIONS AND IMPLICATIONS: PEA improves murine experimental colitis, the effect being mediated by CB2 receptors, GPR55 and PPARα, and modulated by TRPV1 channels.

N-Palmitoylethanolamine depot injection increased its tissue levels and those of other acylethanolamide lipids.

N-Palmitoylethanolamine (NAE 16:0) is an endogenous lipid signaling molecule that has limited water solubility, and its action is short-lived due to its rapid metabolism. This poses a problem for use in vivo as oral administration requires a high concentration for significant levels to reach target tissues, and injection of the compound in a dimethyl sulfoxide- or ethanol-based vehicle is usually not desirable during long-term treatment. A depot injection of NAE 16:0 was successfully emulsified in sterile corn oil (10 mg/kg) and administered in young DBA/2 mice in order to elevate baseline levels of NAE 16:0 in target tissues. NAE 16:0 levels were increased in various tissues, particularly in the retina, 24 and 48 hours following injections. Increases ranged between 22% and 215% (above basal levels) in blood serum, heart, brain, and retina and induced an entourage effect by increasing levels of other 18 carbon N-Acylethanolamines (NAEs), which ranged between 31% and 117% above baseline. These results indicate that NAE 16:0 can be used as a depot preparation, avoiding the use of inadequate vehicles, and can provide the basis for designing tissue-specific dosing regimens for therapies involving NAEs and related compounds.

Comparable lumefantrine oral bioavailability when co-administered with oil-fortified maize porridge or milk in healthy volunteers.

Co-administration of artemether-lumefantrine with milk is recommended to improve lumefantrine (L) absorption but milk may not be available in resource-limited settings. This study explored the effects of cheap local food in Uganda on oral bioavailability of lumefantrine relative to milk. In an open-label, four-period crossover study, 13 healthy adult volunteers were randomized to receive a single oral dose of artemether-lumefantrine (80 mg artemether/480 mg lumefantrine) with water, milk, maize porridge or maize porridge with oil on separate occasions. Plasma lumefantrine was assayed using high-performance liquid chromatography with ultraviolet detection. Pharmacokinetic exposure parameters were determined by non-compartmental methods using WinNonlin. Peak concentrations (Cmax ) and area under concentration-time curve restricted to 48 hr after single dosing (AUC(0-48) ) were selected for relative bioavailability evaluations using confidence interval approach for average bioequivalence. Lumefantrine exposure was comparable in milk and maize porridge plus oil study groups. When artemether-lumefantrine was administered with maize porridge plus oil, average bioequivalence ranges (means ratios 90% CI, 0.84-1.88 and 0.85-1.69 for Cmax and AUC(0-48) , respectively) were within and exceeded acceptance ranges relative to milk (90% CI, 0.80-1.25). Both fasted and maize porridge groups demonstrated similarly much lower ranges of lumefantrine exposures (bioinequivalence) relative to milk. If milk is not available, it is thus possible to recommend fortification of carbohydrate-rich food with little fat (maize porridge plus vegetable oil) to achieve similarly optimal absorption of lumefantrine after artemether-lumefantrine administration.

Understanding the pharmacokinetics of Coartem.

Artemether and lumefantrine (AL), the active constituents of Coartem exhibit complementary pharmacokinetic profiles. Artemether is absorbed quickly; peak concentrations of artemether and its main active metabolite, dihydroartemisinin (DHA) occur at approximately two hours post-dose, leading to a rapid reduction in asexual parasite mass and a prompt resolution of symptoms. Lumefantrine is absorbed and cleared more slowly (terminal elimination half-life 3-4 days in malaria patients), and accumulates with successive doses, acting to prevent recrudescence by destroying any residual parasites that remain after artemether and DHA have been cleared from the body. Food intake significantly enhances the bioavailability of both artemether and lumefantrine, an effect which is more apparent for the highly lipophilic lumefantrine. However, a meal with only a small amount of fat (1.6 g) is considered sufficient to achieve adequate exposure to lumefantrine. The pharmacokinetics of artemether or lumefantrine are similar in children, when dosed according to their body weight, compared with adults. No randomized study has compared the pharmacokinetics of either agent in pregnant versus non-pregnant women. Studies in healthy volunteers and in children with malaria have confirmed that the pharmacokinetic characteristics of crushed standard AL tablets and the newly-developed Coartem Dispersible tablet formulation are similar. Studies to date in healthy volunteers have not identified any clinically relevant drug-drug interactions; data relating to concomitant administration of HIV therapies are limited. While dose-response analyses are difficult to undertake because of the low rate of treatment failures under AL, it appears that artemether and DHA exposure impact on parasite clearance time while lumefantrine exposure is associated with cure rate, consistent with their respective modes of action. In conclusion, knowledge of the pharmacokinetic profiles of artemether and lumefantrine is increasing within a range of settings, including infants and children. However, additional data would be warranted to better characterize artemether and lumefantrine pharmacokinetics in patients with hepatic impairment, in pregnant women, and in patients undergoing HIV/AIDS chemotherapy.

How much fat is necessary to optimize lumefantrine oral bioavailability?

BACKGROUND: Artemether-lumefantrine (AL) is the only fixed, artemisinin-based combination antimalarial drug which is registered internationally and deployed on a large scale. Absorption of the hydrophobic lipophilic lumefantrine component varies widely between individuals and is greatly increased by fat coadministration; but patients with acute malaria are frequently nauseated and anorexic, making dietary advice difficult to comply with. The aim of this study was to describe the dose-response relationship between coadministration of fat and relative lumefantrine bioavailability, in order to determine the minimum amount of fat necessary to optimize absorption. METHOD: We conducted a multiple crossover pharmacokinetic study in 12 healthy volunteers. This compared the area under the plasma concentration-time curve (AUC) for lumefantrine after administration of a single dose of AL in the fasting state given with 0, 10, 40, 150 and 500 ml of soya milk corresponding to 0, 0.32, 1.28, 4.8 and 16 g of fat. All volumes of milk supplements were tested in all subjects with a 3- to 4-week washout period in-between. RESULTS: A dose-response relationship was demonstrated between the volume of soya milk administered and lumefantrine bioavailability. AL administration with soya milk increased the lumefantrine AUC more than five fold. The population mean estimated volume of soya milk required to obtain 90% of maximum effect (in terms of lumefantrine AUC) was 36 ml (corresponding to 1.2 g of fat). CONCLUSIONS: Coadministration of artemether-lumefantrine with a relatively small amount of fat (as soya milk) was required to ensure maximum absorption of lumefantrine in healthy adult volunteers.

Review of the carcinogenic activity of diethanolamine and evidence of choline deficiency as a plausible mode of action.

Diethanolamine (DEA) is a chemical used widely in a number of industries and is present in many consumer products. Studies by the National Toxicology Program (NTP) have indicated that lifetime dermal exposure to DEA increased the incidence and multiplicity of liver tumors in mice, but not in rats. In addition, DEA was not carcinogenic when tested in the Tg.Ac transgenic mouse model. Short-term genotoxicity tests have yielded negative results. In view of these apparent inconsistencies, we have critically evaluated the NTP studies and other data relevant to assessing the carcinogenic potential of DEA. The available data indicate that DEA induces mouse liver tumors by a non-genotoxic mode of action that involves its ability to cause choline deficiency. The following experimental evidence supports this hypothesis. DEA decreased the hepatic choline metabolites and S-adenosylmethionine levels in mice, similar to those observed in choline-deficient mice. In contrast, DEA had no effect in the rat, a species in which it was not carcinogenic at a maximum tolerated dose level. In addition, a consistent dose-effect relationship had been established between choline deficiency and carcinogenic activity since all DEA dosages that induced tumors in the NTP studies were also shown to cause choline deficiency. DEA decreased phosphatidylcholine synthesis by blocking the cellular uptake of choline in vitro, but these events did not occur in the presence of excess choline. Finally, DEA induced transformation in the Syrian hamster embryo cells, increased S-phase DNA synthesis in mouse hepatocytes, and decreased gap junctional intracellular communication in primary cultured mouse and rat hepatocytes, but all these events were prevented with choline supplementation. Since choline is an essential nutrient in mammals, this mode of action is qualitatively applicable to humans. However, there are marked species differences in susceptibility to choline deficiency, with rats and mice being far more susceptible than other mammalian species including humans. These differences are attributed to quantitative differences in the enzyme kinetics controlling choline metabolism. The fact that DEA was carcinogenic in mice but not in rats also has important implications for human risk assessment. DEA has been shown to be less readily absorbed across rat and human skin than mouse skin. Since a no observed effect level for DEA-induced choline deficiency in mice has been established to be 10 mg/kg/d, this indicates that there is a critical level of DEA that must be attained in order to affect choline homeostasis. The lack of a carcinogenic response in rats suggests that exposure to DEA did not reach this critical level. Since rodents are far more sensitive to choline deficiency than humans, it can be concluded that the hepatocarcinogenic effect of DEA in mice is not predictive of similar susceptibility in humans.

Therapeutic efficacy of artemether-lumefantrine and artesunate-mefloquine for treatment of uncomplicated Plasmodium falciparum malaria in Luang Namtha Province, Lao People's Democratic Republic.

The efficacy of the six-dose regimen of artemether-lumefantrine was compared with the combination of artesunate and mefloquine in a randomised, comparative trial in Luang Namtha Province, Northern Laos. Of 1033 screened patients, 201 were positive for Plasmodium falciparum; 108 patients of all age groups (2-66 years) with acute, uncomplicated P. falciparum malaria were enrolled in the study, 100 of whom were followed-up for 42 days. Fifty-three patients received artemether-lumefantrine and 55 received artesunante-mefloquine. Both drug combinations induced rapid clearance of parasites and malaria symptoms; there was no significant difference in the initial therapeutic response parameters. Both regimes were well tolerated. After 42 days, cure rates were 93.6% (95% CI = 82.5-98.7%; 44 of 47 patients) for artemether-lumefantrine and 100% (95% CI = 93.3-100.0%; 53 of 53 patients) for artesunate-mefloquine. The results show the excellent efficacy and tolerability of both artemether-lumefantrine and artesunate-mefloquine in Northern Laos.

Coartemether (artemether and lumefantrine): an oral antimalarial drug.

Coartemether (Riamet, Coartem, Novartis), a tablet formulation of artemether and lumefantrine, is a well-tolerated, fast-acting and effective blood schizontocidal drug that serves primarily in the treatment of uncomplicated falciparum malaria that is resistant to other antimalarials. Initial clinical-parasitological response relies mainly on the artemether component, while lumefantrine effects radical cure. The absorption of lumefantrine is poor during the fasting state, the normal condition in acutely ill malaria patients, but with return to normal diet it becomes adequate. This highlights the need for an appropriate adjustment of the dose regimen. In the area where Plasmodium falciparum shows the highest degree of multidrug resistance worldwide, the best results (99% cure) were obtained with a six-dose regimen given over 5 days. Extensive cardiological investigations have demonstrated the high cardiac safety of coartemether.

A clinical and pharmacokinetic trial of six doses of artemether-lumefantrine for multidrug-resistant Plasmodium falciparum malaria in Thailand.

The efficacy-safety and pharmacokinetics of the six-dose regimen of artemether-lumefantrine (Coartem/Riamet; Novartis Pharma AG, Basel, Switzerland) were assessed in a randomized trial in 219 patients (> or = 12 years old) with acute, uncomplicated Plasmodium falciparum malaria in Thailand. One hundred and sixty-four patients received artemether-lumefantrine and 55 received the standard treatment combination of mefloquine-artesunate. Both drugs induced rapid clearance of parasites and malaria symptoms. The 28-day cure rates were 95.5% (90% confidence interval [CI] = 91.7, 97.9%) for artemether-lumefantrine and 100% (90% CI = 94.5, 100%) for mefloquine-artesunate. This high-dose regimen of artemether-lumefantrine was very well tolerated, with very good compliance. The most frequent adverse events were headache, dizziness, nausea, abdominal pain, dyspepsia, vomiting, and skin rash. Overall, only 2% of patients in both groups showed QTc prolongations but without any cardiac complication, and no differences were seen between patients with and without measurable baseline plasma levels of quinine or mefloquine. Plasma levels of artemether, dihydroartemisinin, and lumefantrine were consistent with historical data for the same dose regimen, and were higher, particularly for lumefantrine, than those previously observed with the four-dose regimen, explaining the greater efficacy of the six-dose regimen in a drug-resistant setting. These results confirm the excellent safety and efficacy of the six-dose regimen of artemether-lumefantrine in the treatment of multidrug-resistant P. falciparum malaria.

The 1'-hydroxylation of Rac-bufuralol by rat brain microsomes.

The 1'-hydroxylation of rac-bufuralol, which is catalyzed by polymorphic CYP2D6 in humans, was studied in brain microsomes from male and female Wistar rats and from the female Dark Agouti rat, a model of the CYP2D6 poor metabolizer phenotype. The kinetics of the 1'-hydroxylation of bufuralol (1-1500 microM) by brain microsomes were biphasic. The activity of the high-affinity site of metabolism was consistent with Michaelis-Menten kinetics (apparent K(m1) = 0. 61-1.42 microM, V(max1) = 4.3-4.8 fmol/min/mg of protein), whereas the low-affinity activity was better described by a Hill function (K(50%(2)) = 253-258 microM, V(max2) = 817-843 fmol/min/mg of protein, n = 1.2-1.3). Values for kinetic constants were similar in all rat strains. Quinine was only a weak inhibitor of both the high- (apparent K(i) = 90 microM) and low-affinity (210 microM) sites of metabolism. In contrast, the kinetics of 1'-hydroxylation of bufuralol by rat liver microsomes were best described by a two-site Michaelis-Menten function. V(max) values were 3 to 5 orders of magnitude greater compared with those for brain microsomes (male and female Wistar), and liver microsomes from female Dark Agouti rats were significantly less active than those from Wistar rats. These data, together with the known potent inhibitory effect of quinine on bufuralol 1'-hydroxylation by rat liver microsomes, indicate tissue-specific differences in the enzymology of this reaction. The role of brain CYP2D enzymes remains to be clarified.

Pharmacokinetics and pharmacodynamics of lumefantrine (benflumetol) in acute falciparum malaria.

The objective of this study was to conduct a prospective population pharmacokinetic and pharmacodynamic evaluation of lumefantrine during blinded comparisons of artemether-lumefantrine treatment regimens in uncomplicated multidrug-resistant falciparum malaria. Three combination regimens containing an average adult lumefantrine dose of 1,920 mg over 3 days (four doses) (regimen A) or 2,780 mg over 3 or 5 days (six doses) (regimen B or C, respectively) were given to 266 Thai patients. Detailed observations were obtained for 51 hospitalized adults, and sparse data were collected for 215 patients of all ages in a community setting. The population absorption half-life of lumefantrine was 4.5 h. The model-based median (5th and 95th percentiles) peak plasma lumefantrine concentrations were 6.2 (0.25 and 14.8) microgram/ml after regimen A, 9. 0 (1.1 and 19.8) microgram/ml after regimen B, and 8 (1.4 and 17.4) microgram/ml after regimen C. During acute malaria, there was marked variability in the fraction of drug absorbed by patients (coefficient of variation, 150%). The fraction increased considerably and variability fell with clinical recovery, largely because food intake was resumed; taking a normal meal close to drug administration increased oral bioavailability by 108% (90% confidence interval, 64 to 164) (P, 0.0001). The higher-dose regimens (B and C) gave 60 and 100% higher areas under the concentration-time curves (AUC), respectively, and thus longer durations for which plasma lumefantrine concentrations exceeded the putative in vivo MIC of 280 microgram/ml (median for regimen B, 252 h; that for regimen C, 298 h; that for regimen A, 204 h [P, 0.0001]) and higher cure rates. Lumefantrine oral bioavailability is very dependent on food and is consequently poor in acute malaria but improves markedly with recovery. The high cure rates with the two six-dose regimens resulted from increased AUC and increased time at which lumefantrine concentrations were above the in vivo MIC.

Pharmacokinetics and tolerability of formoterol in healthy volunteers after a single high dose of Foradil dry powder inhalation via Aerolizer.

OBJECTIVE: The pharmacokinetics of the long-acting beta2-agonist formoterol fumarate, which is a racemate of the (S,S)- and (R,R)-enantiomers were evaluated in 12 healthy (eight male, four female) volunteers after a single inhaled high dose of 120 microg of formoterol fumarate. The tolerability and safety were also assessed. METHODS: Each volunteer inhaled the single 120-microg dose through the Aerolizer device within 2-5 min, using ten 12-microg dry powder capsules for inhalation. Formoterol, i.e., the sum of both enantiomers, was determined in plasma over 24 h, whereas the separate enantiomers were determined in urine over 48 h. Incidence, seriousness and severity of adverse experiences, electrocardiogram (ECG), including the corrected QT interval (QTc) calculation, systolic blood pressure, heart rate, and plasma potassium levels were recorded. RESULTS: In nine of the 12 volunteers, the peak plasma concentration of formoterol was observed already at 5 min after inhalation. The absorption kinetics were complex, as depicted by multiple peaks or shoulders within 0.5-6 h after inhalation. Mean with (SD; n = 12) of maximum concentration (Cmax) and area under the curve (AUC) of formoterol in plasma were 266 (108) pmol x l(-1) and 1330 (398) pmol x l(-1), respectively. The moderate inter-individual variability in systemic exposure of formoterol reflects the homogeneous pharmacokinetics of the drug. A predominant slow elimination of formoterol from plasma with a mean half-life (t1/2) of 10 h was demonstrated. Assuming linear kinetics in plasma suggested by urinary data, the steady-state trough plasma levels of formoterol for a b.i.d. dosing regimen are predicted to amount to 20% of Cmax. In urine, mean with (SD; n = 10) of the amount excreted over 48 h was 3.61 (0.89)% of dose for the pharmacologically active (R,R)-enantiomer and 4.80 (1.33)% of dose for the (S,S)-enantiomer. The terminal half-lives calculated from the excretion rate-time curves, i.e., 13.9 h and 12.3 h for the (R,R)- and (S,S)-enantiomer, respectively, confirm the slow elimination of formoterol from plasma. The dose inhaled was 10 times the most frequently recommended dose (12 microg) and 5 times the highest recommended dose (24 microg). Ten of 12 subjects experienced mild and transient nervousness. Pulse readings demonstrated the maximum mean increase of 25.8 beats x min(-1) at 6 h. The mean maximum QTc increase was 25 msec at 6 h. Pulse and QTc values returned to baseline or close to baseline values at 24 h or before. Potassium levels in plasma decreased in eight out of 12 subjects; the lowest mean value was 3.53 mmol x l(-1) at 2 h post-dose. The lowest individual potassium measurement was 2.95 mmol x l(-1) between 15 min and 6 h. By 8 h post-dose all values had returned to within the normal ranges. CONCLUSIONS: The extremely fast appearance of formoterol in plasma shows the predominance of airways absorption shortly after inhalation. Due to a terminal elimination half-life of about 10 h, sustained systemic concentrations of formoterol are predicted for a twice daily treatment regimen without noteworthy accumulation. The excreted amounts in percent of dose of the enantiomers in urine and the enantiomer ratio are similar to data reported previously after lower doses and suggest linear kinetics for doses between 12 microg and 120 microg of formoterol fumarate. The expected side effects on heart rate, QTc interval, and plasma potassium were small and had no clinical consequences in spite of the very high dose of 120 microg (5 to 10 times the recommended therapeutic dose of Foradil). It should be noted that the impact of high doses may be greater in patients. Nevertheless these findings provide reassurance on the safety margin of formoterol after accidental and intentional overdosing.

Pharmacokinetics of benflumetol given as a fixed combination artemether-benflumetol (CGP 56697) in Thai patients with uncomplicated falciparum malaria.

The pharmacokinetics of benflumetol as a fixed combination, artemether-benflumetol (CGP 56697), following three regimens [regimen A: four tablets at 0, 8, 24 and 48 h (320 mg artemether, 1,920 mg benflumetol); regimen B: two tablets at 0, 8, 24 and 48 h (160 mg artemether, 960 mg benflumetol); regimen C: four tablets at 0, 8 and 24 h (240 mg artemether, 1,440 mg benflumetol)] were investigated in 39 patients with acute uncomplicated falciparum malaria. All patients showed a rapid initial response with a median parasite clearance time of 40, 41 and 39.5 h and a fever clearance time of 27.8, 32 and 24.5 h for regimens A, B and C, respectively. In nine patients (two, four and three patients in regimens A, B and C, respectively), however, parasitemia reappeared in the peripheral blood smear between days 9 and 23. The pharmacokinetics of benflumetol were highly variable, with coefficients of variation in pharmacokinetic parameters ranging from 14.9% to 144%. Absorption and elimination of benflumetol were relatively slow. Median Cmax per dose (first dose) was significantly higher in regimen B (6.29 ng/ml/mg dose) than in regimen A (2.6 ng/ml/mg dose) and regimen C (3.06 ng/ml/mg dose). Mean T1/2z in regimen C (2.65 h) was significantly shorter than in regimen A (4.5 h) and regimen B (3.89 h). In patients on regimens A and B who showed a sensitive response, plasma concentrations of benflumetol were significantly higher than in those with treatment failure.

Population pharmacokinetics and therapeutic response of CGP 56697 (artemether + benflumetol) in malaria patients.

AIMS: To investigate the pharmacokinetic and pharmacodynamic properties of artemether and benflumetol in a fixed combination tablet (CGP 56697) and to offer an explanation for the lower than expected cure rate in a Thai clinical trial. METHODS: Two hundred and sixty patients were enrolled into a randomized, double-blind, parallel group, dose-finding trial. CGP 56697 was given orally, either as: A, 4 x 4 tablets over 48 h; B, 4 x 2 tablets over 48 h or C, 3 x 4 tablets over 24 h. Each tablet contained artemether 20 mg amd benflumetol 120 mg. The pharmacokinetics were determined using a population-based approach combining full profiles (42 patients) and sparse data (218 patients). Parasite clearance time and 28 day cure rate were correlated with the derived pharmacokinetic parameters. RESULTS: The median absorption half-life of benflumetol was 5.3 h, with a tmax of 10 h and terminal elimination half-life of 4.5 days. For artemether (and its metabolite, dihydroartemisinin), the corresponding values were 1.9 (1.9) h, 1.8 (1.2) h, and 0.84 (0.43) h. The variability in bioavailability of artemether and dihydroartemisinin was large both between doses and between patients, but was less pronounced for benflumetol. Compared with the first dose, benflumetol bioavailability was estimated to increase three-fold by the third and fourth doses. Higher artemether or dihydroartemisinin AUC was found to decrease parasite clearance time. Higher benflumetol AUC was found to significantly increase the chance of cure. CONCLUSIONS: Using a population-based approach it was confirmed that the pharmacokinetic and pharmacodynamic properties of benflumetol and artemether differ markedly. Benflumetol AUC is associated with cure and the effect of benflumetol when coadministered with artemether is to prevent recrudescence. The mode of action of benflumetol is consistent with its longer elimination half-life. A short course of low-dose artemether, which is rapidly absorbed and has a short elimination half-life, produced effective parasite clearance. The complementary pharmacokinetic and pharmacodynamic properties of benflumetol and artemether was the main rationale for developing a fixed-dose combination. While the 4 x 4 dose regimen is very effective in most endemic areas, the poorer absorption (2.5 fold lower than in China) and the more resistant parasites in Thailand require higher doses of this drug.

Measurement of pharmacodynamic effects of dexamethasone on epidermis by phosphorus nuclear magnetic resonance spectroscopy in vitro.

An intact, viable epidermal preparation was perfused and phosphoenergetic and phospholipid metabolite levels were measured by 31P NMR. The preparation was stable in the NMR perfusion apparatus for 24 h. The effects of inclusion of ethanolamine and dexamethasone-21-acetate in the perfusion media on phosphorus-containing metabolites was assessed by examination of serial 31P NMR spectra. Phosphomonoesters increased significantly during the fourth hour of perfusion with ethanolamine (3 mM) and remained elevated. A corresponding decrease in nucleotide triphosphates was noted, but phosphocreatine (PCr) remained unchanged. Dexamethasone perfusion resulted in a biphasic effect on phosphomonoester metabolism and a dose-dependent decrease in PCr and nucleotide triphosphate levels. A log-linear relationship was observed between dexamethasone dose in the 1-100-nM range and a decrease in PCr. These techniques with an isolated intact epidermal preparation are useful for elucidating mechanisms of corticosteroid action on the skin and serve as a basis for developing a mechanistically relevant topical corticosteroid bioequivalence technique.