Amiodarone inhibits arterial thrombus formation and tissue factor translation.

BACKGROUND: In patients with coronary artery disease and reduced ejection fraction, amiodarone reduces mortality by decreasing sudden death. Because the latter may be triggered by coronary artery thrombosis as much as ventricular arrhythmias, amiodarone might interfere with tissue factor (TF) expression and thrombus formation. METHODS AND RESULTS: Clinically relevant plasma concentrations of amiodarone reduced TF activity and impaired carotid artery thrombus formation in a mouse photochemical injury model in vivo. PTT, aPTT, and tail bleeding time were not affected; platelet number was slightly decreased. In human endothelial and vascular smooth muscle cells, amiodarone inhibited tumor necrosis factor (TNF)-alpha and thrombin-induced TF expression as well as surface activity. Amiodarone lacking iodine and the main metabolite of amiodarone, N-monodesethylamiodarone, inhibited TF expression. Amiodarone did not affect mitogen-activated protein kinase activation, TF mRNA expression, and TF protein degradation. Metabolic labeling confirmed that amiodarone inhibited TF protein translation. CONCLUSIONS: Amiodarone impairs thrombus formation in vivo; in line with this, it inhibits TF protein expression and surface activity in human vascular cells. These pleiotropic actions occur within the range of amiodarone concentrations measured in patients, and thus may account at least in part for its beneficial effects in patients with coronary artery disease.

Interaction with the hERG channel and cytotoxicity of amiodarone and amiodarone analogues.

BACKGROUND AND PURPOSE: Amiodarone (2-n-butyl-3-[3,5 diiodo-4-diethylaminoethoxybenzoyl]-benzofuran, B2-O-CH(2)CH(2)-N-diethyl) is an effective class III antiarrhythmic drug demonstrating potentially life-threatening organ toxicity. The principal aim of the study was to find amiodarone analogues that retained human ether-a-go-go-related protein (hERG) channel inhibition but with reduced cytotoxicity. EXPERIMENTAL APPROACH: We synthesized amiodarone analogues with or without a positively ionizable nitrogen in the phenolic side chain. The cytotoxic properties of the compounds were evaluated using HepG2 (a hepatocyte cell line) and A549 cells (a pneumocyte line). Interactions of all compounds with the hERG channel were measured using pharmacological and in silico methods. KEY RESULTS: Compared with amiodarone, which displayed only a weak cytotoxicity, the mono- and bis-desethylated metabolites, the further degraded alcohol (B2-O-CH(2)-CH(2)-OH), the corresponding acid (B2-O-CH(2)-COOH) and, finally, the newly synthesized B2-O-CH(2)-CH(2)-N-pyrrolidine were equally or more toxic. Conversely, structural analogues such as the B2-O-CH(2)-CH(2)-N-diisopropyl and the B2-O-CH(2)-CH(2)-N-piperidine were significantly less toxic than amiodarone. Cytotoxicity was associated with a drop in the mitochondrial membrane potential, suggesting mitochondrial involvement. Pharmacological and in silico investigations concerning the interactions of these compounds with the hERG channel revealed that compounds carrying a basic nitrogen in the side chain display a much higher affinity than those lacking such a group. Specifically, B2-O-CH(2)-CH(2)-N-piperidine and B2-O-CH(2)-CH(2)-N-pyrrolidine revealed a higher affinity towards hERG channels than amiodarone. CONCLUSIONS AND IMPLICATIONS: Amiodarone analogues with better hERG channel inhibition and cytotoxicity profiles than the parent compound have been identified, demonstrating that cytotoxicity and hERG channel interaction are mechanistically distinct and separable properties of the compounds.

Toxicity of amiodarone and amiodarone analogues on isolated rat liver mitochondria.

BACKGROUND: Amiodarone is a well-known mitochondrial toxin consisting of a benzofuran ring (ring A) coupled to a p-OH-benzene structure substituted with 2 iodines and a diethyl-ethanolamine side chain (ring B). AIM: To find out which part of amiodarone is responsible for mitochondrial toxicity. METHODS: Amiodarone, ring A and B without the ethanolamine side-chain and iodines (B0), ring A and B with iodines but no ethanolamine (B2), ring B with 1 iodine and no ethanolamine (C1) and ring B with ethanolamine and 2 iodines (D2) were studied. RESULTS: In freshly isolated rat liver mitochondria, amiodarone inhibited state 3 glutamate and palmitoyl-CoA oxidation and decreased the respiratory control ratios. B0 and B2 were more potent inhibitors than amiodarone and B2 more potent than B0. C1 and D2 showed no significant mitochondrial toxicity. After disruption, mitochondrial oxidases and complexes of the electron transport chain were inhibited by amiodarone, B0 and B2, whereas C1 and D2 revealed no inhibition. Beta-oxidation showed a strong inhibition by amiodarone, B0 and B2 but not by C1 or D2. Ketogenesis was almost unaffected. CONCLUSIONS: Amiodarone, B0 and B2 are uncouplers of oxidative phosphorylation, and inhibit complexes I, II and III, and beta-oxidation. The benzofuran structure is responsible for mitochondrial toxicity of amiodarone and the presence of iodine is not essential.

Metabolism of amiodarone (Part III): identification of rabbit cytochrome P450 isoforms involved in the hydroxylation of mono-N-desethylamiodarone.

1. Amiodarone (AMI) is a potent anti-arrhythmic drug and mono-N-desethylamiodarone (MDEA) is its only known metabolite. It was found recently that in rabbit liver microsomes MDEA was biotransformed to n-3-hydroxybutyl-MDEA (3OH-MDEA). 2. In liver microsomes isolated from the untreated rabbit, the formation of 3OH-MDEA obeyed Michaelis-Menten enzyme kinetics with Km = 6.39 +/- 1.07 microM and Vmax = 0.56 +/- 0.21 nmolmin(-1) mg(-1) protein. 3. Furthermore, (1) among chemicals usually used as inhibitors of cytochrome P450, only midazolam (MDZ), cyclosporin A and ketoconazole inhibited the MDEA hydroxylase activity significantly (>60% inhibition), (2) MDZ, a substrate of CYP3A, inhibited the 30OH-MDEA formation competitively (Ki = 10 +/- 5 microM), (3) the formation rates of 3OH-MDEA correlated positively with those of 1'OH-MDZ (r = 0.81; n = 6), and (4) MDEA hydroxylase activity of microsomes isolated from rabbit rifampicin-induced cultured hepatocytes was 4-fold more active than the control. 4. Since CYP3A6 is mainly induced by rifampicin in rabbit-cultured hepatocytes, the data suggest that this isoform is involved in the biotransformation of MDEA to 3OH-MDEA. 5. Since alpha-naphthoflavone, cimetidine and quinidine also partially inhibited the MDEA hydroxylase activity, it is possible that other CYPs, such as 1A, 2C and 2D, may also be active in the metabolism of amiodarone.

Metabolism of amiodarone. II. High-performance liquid chromatographic assay for mono-N-desethylamiodarone hydroxylation in liver microsomes.

Amiodarone (AMI) is a potent antiarrhythmic drug. In vivo and in vitro, AMI is biotransformed to mono-N-desethylamiodarone (MDEA). Recently, it was observed that MDEA was further hydroxylated to n-3'-hydroxybutyl-MDEA (3'OH-MDEA). The performance of a HPLC-UV assay being developed for the quantification of the new compound was investigated. Liver microsomes isolated from rabbit, rat and human biotransformed MDEA to 3'OH-MDEA. Their estimates of Michaelis-Menten parameters were Km=6.39, 25.2, 19.4 microM; Vmax=560, 54, 17.3 pmol/mg protein/min), respectively. Thus, hydroxylase activity in mammals may be the origin of the species dependence observed in the AMI metabolism.

Metabolism of amiodarone (part I): identification of a new hydroxylated metabolite of amiodarone.

UNLABELLED: Amiodarone (AMI) is a potent antiarrhythmic drug, but its metabolism has not yet been fully documented. Mono-N-desethylamiodarone (MDEA) is its only known metabolite. Our preliminary investigations using rabbit liver microsomes had shown that in vitro AMI was biotransformed to MDEA, and the latter was rapidly further biodegraded to other unknown products. The aim of the present study was to investigate the chemical structure of the biotransformed compound of MDEA. Upon incubation of MDEA with rabbit liver microsomes and NADPH as cofactor, MDEA was biotransformed into three unknown products: X1, X2, and X3. The products were purified using chromatography. The chemical structure of the major product, X1, was investigated in detail. HPLC-ESI-MS revealed that MDEA had been oxygenated. Hydrogen-deuterium exchange experiments showed that the X1 molecule contained one exchangeable hydrogen atom more than its precursor MDEA, indicating that MDEA had been hydroxylated. Further results from ESI-MS/MS analysis indicated that the site of hydroxylation was the n-butyl side chain. NMR analysis (1H NMR, one-dimensional-total correlation spectroscopy, and heteronuclear multiple-bond correlation spectroscopy) established the 3-position (omega-1) of the butyl moiety as the specific carbon atom that is hydroxylated. Rat liver microsomes were also able to catalyze MDEA hydroxylation. Compound X1, as analyzed by HPLC-ESI-MS and ESI-MS/MS, was detected in the liver, heart, lung, and kidney tissue of four rats receiving AMI, suggesting that the hydroxylated MDEA was a secondary metabolite of AMI. CONCLUSION: in mammals, MDEA is hydroxylated to the secondary metabolite of AMI [2-(3-hydroxybutyl)-3-[4-(3-ethylamino-1-oxapropyl)-3,5-diiodobenzoyl]-benzofuran].

Structure-effect relationships of amiodarone analogues on the inhibition of thyroxine deiodination.

OBJECTIVES: Amiodarone (AMI) has proven to be a potent anti-arrhythmic compound. Due to the structural similarity between AMI and thyroid hormone, it is possible that the drug could inhibit the activity of the 5'-thyroxine-deiodinase. METHODS: AMI analogues resulting from (1) dealkylation, (2) deiodination and (3) deamination were synthesised and used as inhibitors in an in vitro biotransformation reaction of thyroxine (T4) to 3,3',5'-triiodothyronine (T3). Using high-performance liquid chromatography and ultraviolet detection for quantifying T3, it was found that the 5'-T4 deiodinase type I was involved in the reaction. On separate occasions, AMI or an AMI analogue was added to the reaction as an inhibitor. RESULTS: All studied AMI analogues inhibited 5'-T4 deiodination competitively (Ki value range 25-360 microM). In the concentration range of 1-1000 microM, AMI and its N-desethylated, deiodinated analogues inhibited 5'-T4 deiodination very weakly. AMI analogues with a hydroxyl group at the 4-position were strong inhibitors. Moreover, diiodo-AMI analogues inhibited 5'-T4 deiodination more strongly than their corresponding monoiodo- or deiodinated derivatives. CONCLUSION: It is likely that the degraded products of AMI could be responsible for thyroid dysfunction toxicosis in AMI therapy.

Grapefruit juice enhances the bioavailability of the HIV protease inhibitor saquinavir in man.

AIMS: Saquinavir is a potent HIV protease inhibitor whose effectiveness is limited in vivo by its low bioavailability. Since saquinavir is metabolized by CYP3A4, the effect of grapefruit juice, an inhibitor of CYP3A4, was investigated on its bioavailability. METHODS: After an overnight fast, eight healthy volunteers were treated with either 400 ml grapefruit juice or water before intravenous (12 mg) or oral saquinavir (600 mg) was administered. Serial blood samples were obtained over the following 24 h and standardized meals were served 5 and 10 h after the administration of saquinavir. The plasma concentrations of saquinavir were determined by high-performance liquid chromatography and pharmacokinetic parameters were calculated by routine methods. RESULTS: The AUC was not affected by grapefruit juice after intravenous administration, but it increased significantly from 76+/-96 (water, mean (s.d.) to 114+/-70 (microg l[-1] h) (grapefruit juice) after oral saquinavir. Similarly, the oral bioavailability of saquinavir increased by a factor of 2 with grapefruit juice (from 0.7% to 1.4%). In contrast, clearance, volume of distribution and elimination half-life of saquinavir were not affected by grapefruit juice. After oral, but not after intravenous administration, the plasma concentration-time curve showed a second peak after lunch irrespective of pretreatment, suggesting enhancement of absorption by food. CONCLUSIONS: The studies demonstrate that grapefruit juice increases the bioavailability of saquinavir without affecting its clearance, suggesting that inhibition of intestinal CYP3A4 may contribute. Since the antiretroviral effect of saquinavir is dose-dependent, inhibition of CYP3A4 may represent a way to enhance its effectiveness without increasing the dose.

Myocardial amiodarone concentrations after short- and long-term treatment in patients with end-stage heart failure.

BACKGROUND: Pharmacokinetics and tissue concentrations of amiodarone may vary considerably in end-stage heart failure, but may be crucial for treatment efficiency and antiarrhythmic drug therapy. OBJECTIVE: This study was undertaken to determine plasma amiodarone and desethylamiodarone concentrations and to determine whether they correlate with myocardial concentrations in explanted hearts from patients with end-stage heart failure. PATIENTS AND METHODS: Eight patients with idiopathic dilated cardiomyopathy and normal coronary arteries were included in the present study. Myocardial tissue samples (seven sites) and epicardial fat were taken from each explanted heart, and drug concentrations of amiodarone and desethylamiodarone were determined. In addition, plasma drug levels were measured and compared with the myocardial amiodarone/desethylamiodarone concentrations. RESULTS: The mean cumulative amiodarone dose was 91 g and the mean plasma concentrations of amiodarone and desethylamiodarone were 0.68 and 0.84 microg.ml(-1), respectively. The tissue concentrations of amiodarone amounted to 13.2 and 28.3 microg.g(-1), respectively, in the atria and to 13.0 and 40.8 microg.g(-1), respectively, in the ventricles. The distribution of the drug and its metabolite were similar in the right and left ventricles. There was a good correlation between myocardial concentration of amiodarone and desethylamiodarone and the cumulative ingested dose of amiodarone. Tissue drug concentrations correlated only poorly with plasma amiodarone or desethylamiodarone levels. The highest drug levels were measured in the epicardial fat tissue, where the ratio of amiodarone 105 microg.g(-1) to desethylamiodarone 32 microg.g(-1) was reversed (3.3 compared with 0.29 in the ventricles). Thus, amiodarone concentrations in epicardial fat were approximately 10 times higher than myocardial and 150 times higher than plasma levels. CONCLUSIONS: Our data confirm the slow equilibrium of amiodarone and desethylamiodarone concentrations between plasma and myocardium. Myocardial tissue concentrations of desethylamiodarone and, to a lesser degree, amiodarone correlate with the cumulative ingested dose of amiodarone. Monitoring of the total cumulative dose may be more relevant clinically than monitoring plasma levels. These results support the clinical practice of reducing the maintenance dose of amiodarone in patients who are on long-term treatment.

Determination of saquinavir in human plasma by high-performance liquid chromatography.

We developed and characterized a high-performance liquid chromatography (HPLC) assay for the determination of saquinavir, an HIV protease inhibitor, in human plasma samples. Extraction of plasma samples with diethyl ether resulted in quantitative recovery of both saquinavir and its stereoisomer Ro 31-8533 which was used as an internal standard. The assay was performed isocratically using 5 mM H2SO4 (pH 3.5) and acetonitrile (75.5:24.5, v/v) containing 10 mM tetrabutylammonium hydrogen sulfate (TBA) as a mobile phase, a Nucleosil 3C8 column kept at 45 degrees C and UV detection at 240 nm. Using this method, saquinavir and Ro 31-8533 can be separated from endogenous substances, and in the concentration range of 5-110 ng/ml the relative standard deviations for the determination of saquinavir were below 5%. The detection limit of saquinavir in human plasma was 1 ng/ml. The usefulness of the method was demonstrated by quantification of saquinavir in plasma of human subjects treated with 600 mg of saquinavir per os or 12 mg intravenously.

Interaction between amiodarone and lidocaine.

We investigated the in vitro and in vivo interaction between amiodarone and lidocaine. The interaction on a molecular level was first studied in microsomes from 11 human livers. Close correlations between amiodarone N-monodesethylase activities and (a) the amounts of cytochrome P-4503A4 (CYP3A4), and (b) the rates of lidocaine N-monodesethylation were observed. Lidocaine inhibited amiodarone N-monodesethylation (Ki = 120 microM) competitively; inversely, amiodarone suppressed lidocaine N-monodesethylase activity in the same manner (Ki = 47 microM). Moreover, the metabolite N-monodesethylamiodarone (DEA) was stable and inhibited lidocaine metabolism in a concentration-dependent manner. The in vivo interaction was investigated in 6 cardiac patients. Each of them received a dose of 1 mg/kg lidocaine hydrochloride intravenously (i.v.) on three different occasions: before amiodarone treatment (control), and after cumulative doses of 3 g (phase I) and 13 g (phase II), respectively, amiodarone hydrochloride. The analysis of lidocaine pharmacokinetics showed an increase in lidocaine area under the curve (AUC) when amiodarone was administered, whereas that of N-monodesethylated lidocaine decreased. Moreover, the systemic clearance of lidocaine decreased, while the elimination half-life (t1/2) and the distribution volume at steady state of lidocaine remained unchanged. The pharmacokinetic parameters during phase II were the same as those during phase 1, indicating that the interaction had already occurred early in the loading phase of amiodarone administration. The interaction between amiodarone and lidocaine may be explained by the inhibition of CYP3A4 by amiodarone and/or by its main metabolite DEA.

Biotransformation of caffeine by cDNA-expressed human cytochromes P-450.

OBJECTIVES: The biotransformation of caffeine has been studied in vitro using human cytochrome P-450 isoenzymes (CYPs) expressed in human B-lymphoblastoid cell lines, namely CYP1A1, 1A2, 2A6, 2B6, 2D6-Val, 2E1 and 3A4, and microsomal epoxide hydroxylase (EH). In addition, CYP2D6-Met was also studied, in which a valine in the wild type (CYP2D6-Val) has been replaced by a methionine due to a G to A mutation in position 112. RESULTS: At caffeine 3 mmol center dot l-1, five CYPs (1A1, 1A2, 2D6-Met, 2E1 and 3A4) catalysed the biotransformation of caffeine. Among the enzymes studied, CYP1A2, which predominantly catalysed paraxanthine formation, had the highest intrinsic clearance (160 l center dot h-1 center dot mmol-1 CYP). Together with its high abundance in liver, it should be considered, therefore, to be the most important isoenzyme in caffeine metabolism. The affinity of caffeine for CYP1A1 was comparable to that of its homologue 1A2. CYP2D6-Met, which catalysed caffeine metabolism by demethylation and 8-hydroxylation, also had a relatively high intrinsic clearance (3.0 l center dot h-1 mmol-1 CYP), in particular for theophylline and paraxanthine formation, with kM values between 9-16 mmol center dot l-1. In contrast, the wild type, CYP2D6-Val, had no detectable activity. In comparison, CYP2E1 played a less important role in in vitro caffeine metabolism. CYP3A4 predominantly catalysed 8-hydroxylation with a kM value of 46 mmol center dot l-1 and an intrinsic clearance of 0.60 l center dot h-1 center dot mmol-1 CYP. Due to its high abundance in human liver, the latter CYP may contribute significantly to the in vivo formation of TMU. CONCLUSION: The findings of this study indicate that i) microsomes from transfected human B-lymphoblastoid cell lines give results close to those obtained with microsomes isolated from human liver, ii) at least four CYP isoforms are involved in caffeine metabolism, iii) at a substrate concentration <0.1 mmol center dot l-1, CYP1A2 and 1A1 are the most important isoenzymes, iv) at higher concentrations the participation of other isoenzymes, in particular CYP3A4, 2E1 and possibly also CYP2D6-Met, are important in caffeine metabolism, and v) the nucleotide composition at position 1120 of CYP2D6 determines the activity of this isoenzyme in caffeine metabolism.

Are there stereoselective electrophysiologic effects of intravenously administered (S)- or (R)-propafenone hydrochloride in patients with supraventricular tachycardia?

OBJECTIVE: The electrophysiological effects of intravenously administered pure (S)- and (R)-propafenone hydrochloride has been determined for the first time in humans-12 patients with supraventricular tachycardia. METHODS: Measurements were performed before and during drug therapy. RESULTS: (S)- and (R)-propafenone prolonged the AH interval from 82 to 107 ms and 75 to 84 ms, respectively, and significantly increased the V nodal Wenckebach cycle length by 58 ms and 37 ms, respectively. The AV nodal effective refractory period in both groups was increased significantly to the same extent (45 vs 42 ms). Sinus node recovery times were not significantly influenced by either enantiomers. Both (S)- and (R)-propafenone significantly prolonged the HV interval to the same extent (from 41 to 51 ms, and 42 to 53 ms). Changes in the electrophysiological characteristics of the myocardium were more pronounced in the atria than in the ventricles. Only (S)-propafenone significantly increased the atrial effective refractory period from 204 to 230 ms, and the ventricular effective refractory period from 225 to 241 ms compared to (R)-propafenone (from 221 to 239 ms, and from 219 to 222 ms, respectively). There was a more pronounced electrophysiological effect on AV nodal conduction of (S)- than (R)-propafenone, probably as a result of its beta-blocking activity. CONCLUSION: The electrophysiological effects of (S)-compared to (R)-propafenone were not very pronounced, so it still remains questionable whether one of the enantiomers might be clinically superior to the other, or to the racemic mixture.

Prolonged sedation due to accumulation of conjugated metabolites of midazolam.

Midazolam is a short-acting benzodiazepine routinely used in intensive-care medicine. Conjugates of its main metabolite, alpha-hydroxymidazolam, have been shown to accumulate in renal failure but have not previously been related to the prolonged sedative effects commonly observed in critically ill patients. We report five patients with severe renal failure who had prolonged sedation after administration of midazolam. In all five patients, the comatose state was immediately reversed by the benzodiazepine-receptor antagonist flumazenil. Serum concentration monitoring showed high concentrations of conjugated alpha-hydroxymidazolam when concentrations of the unconjugated metabolite and the parent drug were below the therapeutic range. In-vitro binding studies showed that the affinity of binding to the cerebral benzodiazepine receptor of glucuronidated alpha-hydroxymidazolam was only about ten times weaker (affinity constant 16 nmol/L) than that of midazolam (1.4 nmol/L) or unconjugated alpha-hydroxymidazolam (2.2 nmol/L). Conjugated metabolites of midazolam have substantial pharmacological activity. Physicians should be aware that these metabolites can accumulate in patients with renal failure.

Interaction between grapefruit juice and midazolam in humans.

OBJECTIVE: To investigate the effects of grapefruit juice on the pharmacokinetics and dynamics of midazolam. METHODS: Eight healthy male subjects participated in this open crossover study. Intravenous (5 mg) or oral (15 mg) midazolam was administered after pretreatment with water or grapefruit juice. We measured the pharmacokinetics and pharmacodynamics (reaction time, Digit Symbol Substitution Test [DSST], general impression judged by the investigators, and drug effect judged by the subjects) of midazolam and the pharmacokinetics of alpha-hydroxymidazolam. RESULTS: In comparison to water, pretreatment with grapefruit juice did not change the pharmacokinetics or pharmacodynamics of intravenous midazolam. After oral administration, pretreatment with grapefruit juice led to a 56% increase in peak plasma concentration (Cmax), a 79% increase in time to reach Cmax (tmax), and a 52% increase in the area under the plasma concentration-time curve (AUC) of midazolam, which was associated with an increase in the bioavailability from 24% +/- 3% (water) to 35% +/- 3% (Grapefruit juice; mean +/- SEM, p < 0.01) After oral administration of midazolam, pretreatment with grapefruit juice was associated with a 105% increase in tmax and with a 30% increase in the AUC of alpha-hydroxymidazolam. For oral midazolam, pretreatment with grapefruit juice led to significant increases in tmax for all dynamic parameters and in the AUC values for the reaction time and DSST, whereas the maximal dynamic effects remained unchanged. CONCLUSIONS: Pretreatment with grapefruit juice is associated with increased bioavailability and changes in the pharmacodynamics of midazolam that may be clinically important, particularly in patients with other causes for increased midazolam bioavailability such as advanced age, cirrhosis of the liver, and administration of other inhibitors of cytochrome P450.

Metabolism of theophylline by cDNA-expressed human cytochromes P-450.

1. Theophylline metabolism was studied using seven human cytochrome P-450 isoforms (CYPs), namely CYP1A1, 1A2, 2A6, 2B6, 2D6, 2E1 and 3A4, and microsomal epoxide hydroxylase (EH), expressed in human B-lymphoblastoid cell lines. 2. At a high theophylline concentration of 10 mM four CYPs (1A1, 1A2, 2D6, 2E1) catalyzed the metabolism of theophylline. 3. Theophylline had the highest affinity (apparent Km range 0.2-1.0 mM) for the CYP1A subfamily and the kinetics of metabolic formation mediated by CYP1A2 indicated substrate-inhibition (Ki range 9-16 mM). 4. CYP1A2 catalyzed the demethylation of theophylline as well as its hydroxylation, and was associated with the highest intrinsic clearance (1995 l h-1 per mol CYP) to 1,3-dimethyluric acid (DMU). Therefore, this isoform can be considered to be the most important enzyme involved in theophylline metabolism in vitro. 5. CYP2E1 was responsible for a relatively high intrinsic clearance by 8-hydroxylation (289 l h-1 per mol CYP). The apparent Km value of this reaction was about 15 mM, suggesting that CYP2E1 may be the low-affinity high-capacity isoform involved in theophylline metabolism. 6. The affinity of theophylline for CYP1A1 was comparable with that of its homologue 1A2. When induced, the participation of CYP1A1 in theophylline metabolism may be important. 7. CYP2D6 played only a minor role and CYP3A4 was not active in the in vitro metabolism of theophylline. 8. Our findings confirm the major role of CYP1A2 in theophylline metabolism and explain why in vivo the elimination kinetics of theophylline are non-linear and in vitro theophylline metabolism by human liver microsomes does not obey monophasic kinetics. 9. The data suggest also that not only tobacco smoking but also chronic alcohol intake may influence theophylline elimination in man as ethanol induces CYP2E1.

In vitro inhibition of midazolam and quinidine metabolism by flavonoids.

Studies in humans in vivo have demonstrated that substances found in grapefruit juice may increase the bioavailability of dihydropyridine derivatives as a result of the inhibition of liver enzyme activities by flavonoids found in grapefruit. Since the metabolism of dihydropyridine drugs is mediated by cytochrome P-450 (CYP) 3A4, it has been hypothesized that flavonoids may also influence the metabolism of other drugs, such as midazolam and quinidine, which are biotransformed by the same CYP isoform. Three flavonoids, kaempferol, naringenin and quercetin, are found in grapefruit juice but not in orange juice. The effect of these substances on the metabolism of midazolam and quinidine has been investigated in human liver microsomes. In the concentration range 10-160 microM the inhibitory potential of flavonoids was the same for both of the tested drugs; it decreased in the order quercetin >> kaempferol > naringenin. The data suggest that the flavonoids found in grapefruit juice may influence the kinetics of midazolam and quinidine in man.

Determination of piroximone in human plasma by high-performance liquid chromatography.

A rapid and selective high-performance liquid chromatographic (HPLC) method using solid-phase extraction (SPE) for measuring piroximone in plasma samples has been developed. Human plasma and internal standard were pipetted onto a Bond Elut C18 extraction cartridge conditioned with methanol and water. Impurities and proteins were washed out with water. Piroximone and internal standard were eluted with methanol. After evaporation, the residue was dissolved in the mobile phase and the aliquot injected into the HPLC system. Piroximone and its related compounds were separated on a reversed phase C18 HPLC column maintained at 50 degrees C using a mobile phase consisting of phosphate buffer and methanol. Piroximone-N-oxide, piroximone, and internal standard were detected spectrophotometrically at 340 nm. The extraction recovery for piroximone was 94%. The within- and between-run coefficients of variation were < 3% in the concentration range of 320-5,000 ng/ml and < 17.5% at lower concentrations, e.g., 20 ng/ml. The limit of detection was 10 ng/ml.

Determination of midazolam and its alpha-hydroxy metabolite in human plasma and urine by high-performance liquid chromatography.

We describe a new high-performance liquid chromatography (HPLC) method for measurement of midazolam and its major metabolite, alpha-hydroxymidazolam, in clinical samples. Plasma or urine was mixed with 100 ng internal standard Ro 05-6669 and borate buffer, 0.1 M, pH 9. Midazolam and its related compounds were extracted into diethylether. The organic phase was evaporated to dryness. The residue was dissolved in HPLC mobile phase [methanol-isopropyl alcohol-perchloric acid, 0.5 microM (57:25:18)] and injected into the chromatograph. The separation of substances was performed on an Spherisorb S5CN 250 x 4.6 mm HPLC column maintained at 45 degrees C. The detection was performed by absorption measurement at 245 nm. At a flow rate of 1.7 ml/min, the retention times of Ro 05-6669, 1,4 dihydroxymidazolam, alpha-hydroxymidazolam, 4-hydroxymidazolam and midazolam were 4.0, 6.7, 7.8, 9.6, and 10.8 min, respectively. In the concentration range of 5-1,000 ng/ml, the calibration graphs for both compounds were linear. The coefficients of variation of the between-day and within-day assay were < 14% for the concentration range 5-10 and < 7% for the range 10-600 ng/ml. The limits of detection for midazolam and alpha-hydroxymidazolam were 2 and 4 ng/ml, respectively. This assay is more sensitive than earlier methods; it is simple and rapid, and it enables the quantification of midazolam and its alpha-hydroxy metabolite with very good precision and accuracy in human plasma and urine.

Hemodynamic effects and concentration-effect relationship of a graded infusion of piroximone in patients with severe heart failure.

Piroximone is a new phosphodiesterase III inhibitor that combines inotropic and vasodilator properties. To elucidate the optimal dose regimen and the dose-concentration-effect relationships, we studied eight patients with congestive heart failure of New York Heart Association class IV during a continuous multistage infusion over a 24-h period followed by a 4-h washout. After a bolus of 0.5 mg/kg, infusions at a rate of 2.5, 5.0, and 10.0 micrograms/kg/min for 8 h each were given to determine the maintenance dose of piroximone required to achieve an increase in cardiac index > or = 30%. Serial assessment of hemodynamics, plasma piroximone levels, and ventricular ectopic beats was performed. Following the loading dose and at higher infusion rates (5 and 10 micrograms/kg/min) Piroximone produced significant hemodynamic changes compared to baseline, i.e., a maximum increase in cardiac index from 2.2 +/- 0.4 to 3.6 +/- 0.8 L/min/m2 (67 +/- 21%), decreases in right atrial pressure from 14 +/- 3 to 9 +/- 3 mm Hg (40 +/- 16%), pulmonary capillary wedge pressure from 29 +/- 5 to 23 +/- 7 mm Hg (28 +/- 18%), pulmonary vascular resistance from 249 +/- 93 to 151 +/- 59 (45 +/- 19%), and systemic vascular resistance from 1,330 +/- 442 to 752 +/- 272 dyn s/cm5 (44 +/- 19%). Piroximone increased the heart rate by 10% at the highest dose and produced a decrease in mean arterial pressure by 13%. There was a slight increase in ventricular ectopy in two patients (2.2 and 3 VPBs/min) and no change in the remaining six.(ABSTRACT TRUNCATED AT 250 WORDS)