Biotransformation of felodipine in liver microsomes from rat, dog, and man

The biotransformation of the calcium antagonist felodipine was investigated in liver microsomes from rat, dog, and man. The metabolites were quantified and identified by gradient elution reverse phase liquid chromatography, liquid scintillation analysis, and GC/MS. Ten metabolites were identified, including the pyridine analogue of felodipine, two carboxylic mono acids, two ester lactones, as well as the corresponding open hydroxy acid forms, and a lactonic compound with a carboxylic acid group. The presence of two decarboxylated products was also verified. Metabolites with an intact dihydropyridine nucleus were not detected. The total pool of metabolites formed in vitro was more lipophilic than that excreted in urine from the same species. The metabolic pathways were similar in the three species studied, although quantitative differences were observed. Comparison between incubations with liver microsomes from male and female rats indicated that the females metabolized felodipine more slowly than the males. From a more detailed quantitative analysis of eight metabolites, in relation to incubation time, it was apparent that the hydroxylation of the 2- and 6-methyl groups occurred at a faster rate (0.027 min-1) than did the ester hydrolysis (0.016 min-1). These hydroxy metabolites rearranged spontaneously to lactones. The results from this study indicate that the open hydroxy acid metabolites were formed enzymatically from the corresponding lactones. A metabolic scheme for the overall metabolism of felodipine is given and discussed with reference to the in vivo situation.

Identification of the main urinary metabolites of omeprazole after an oral dose to rats and dogs

The structures of seven urinary metabolites of omeprazole following high oral doses to rats and dogs were determined unambiguously by combining different analytical and spectroscopic techniques including derivatization and stable isotopes. Omeprazole was metabolized by aromatic hydroxylation at position 6 in the benzimidazole ring followed by glucuronidation. There was also oxidative O-dealkylation of both methoxy groups, and aliphatic hydroxylation of a pyridine methyl group followed by oxidation to the corresponding carboxylic acid. Due to the experimental design, implying no pH control of collected samples, all metabolites were isolated as sulfides. They were formed in both species with quantitative variations in the metabolic pattern. As far as identified metabolites are concerned, aromatic hydroxylation and subsequent glucuronide formation were the major biotransformation routes in the dog. In the rat, aliphatic hydroxylation and the formation of the carboxylic acid represented the major metabolic pathways. The identified metabolites corresponded approximately to 50% (rat) and 70% (dog) of the amount excreted in the 0-24-hr urine (about 12% of the given dose in both species).

Comparative metabolic disposition of oral doses of omeprazole in the dog, rat, and mouse

The metabolic disposition of [14C]omeprazole was studied in dogs, rats, and mice after the administration of pharmacologically active, single oral doses of drug in buffer solutions (pH 9). Averages of 38% (dogs), 43% (rats), and 55% (mice) of the radiolabeled doses were excreted in the urine in 72 hr. Most of the remaining dose was recovered in the feces. Omeprazole was extensively metabolized in all species studied and the metabolites were eliminated rapidly. No unchanged drug could be detected in the urine samples (less than 0.1% of dose). In each species at least 10 metabolites were detected in urine (pH 9) by gradient elution reverse phase HPLC. Based on liquid chromatographic retention data, the metabolic patterns were very complex and exhibited some quantitative differences between species. Bile was collected from rats and from chronic bile-fistulated dogs. Biliary excretion was a major route of elimination of omeprazole metabolites, and four polar metabolites were detected in the rat bile. The stability of omeprazole metabolites at varying pH values is discussed with reference to reductive metabolism of the parent compound.

Identification of felodipine metabolites in rat urine

After intragastric administration of 100 mumol kg-1 [14C]felodipine to rats eight urinary metabolites were isolated. Batch extraction at pH 2.2 and semipreparative reversed-phase liquid chromatography were used for trace enrichment of the metabolites. Trimethylsilylation followed by transesterification with diazomethane blocked the carboxylic acid and alcohol groups selectively before gas chromatography/mass spectrometry (GC/MS) in the electron impact (EI) mode. Deuterated derivatives of the metabolites and chemical ionization measurements added complementary structural information. All metabolites reported in this study were formed from oxidized felodipine by ester hydrolysis. Hydroxylation of the pyridine methyl group represented an important metabolic pathway and metabolites oxidized to the corresponding carboxylic acids were detected as well. Lactone formation from hydroxy acid metabolites in urine as a possible analytical artefact is discussed.

Identification of the major covalent adduct formed in vitro and in vivo between acetaminophen and mouse liver proteins

Improved analytical methodology has been developed for the structural characterization of covalently bound drug-protein adducts and has been applied to an investigation of the conjugates formed in vivo and in vitro between [14C]acetaminophen and mouse liver proteins. The major adduct released by acid hydrolysis of hepatic protein samples, which accounted for approximately 70% of the bound radioactivity in vivo and in vitro, was identified as 3-cystein-S-yl-4-hydroxyaniline, a derivative whose structure reflects the predominance of acetaminophen thioether adducts in drug-modified proteins. It is concluded that the reactive, electrophilic metabolite of acetaminophen, which most likely is N-acetyl-p-benzoquinoneimine, binds with a high degree of selectivity to cysteinyl thiol groups on protein, formally in a Michael-type addition reaction. Cysteine residues thus represent primary target sites for arylation by the reactive metabolite of acetaminophen, and proteins rich in free thiols may be especially vulnerable to damage by this toxic intermediate.

Structural characterization of the major covalent adduct formed in vitro between acetaminophen and bovine serum albumin

The structure of the covalent adduct formed in vitro between [14C]-acetaminophen ([14C]APAP) and bovine serum albumin (BSA) has been investigated with the aid of new analytical methodology. The APAP-BSA adduct, isolated from mouse liver microsomal incubations to which the radiolabeled drug and BSA had been added, was cleaved using a combination of specific (cyanogen bromide) and non-specific (acid hydrolysis) procedures, following which the mixture of amino acids obtained was derivatized, in aqueous solution, with ethyl chloroformate. The resulting ethoxycarbonyl derivatives were recovered by extraction into ethylacetate, methylated and subjected to profile analysis using both reverse-phase and normal-phase HPLC techniques. In each HPLC step, one major radioactive amino acid adduct was detected and was identified by mass spectrometry as the derivative of 3-cystein-S-yl-4-hydroxyaniline. Based on this finding, and with a knowledge of the behavior under acidic hydrolysis conditions of the 3-cysteinyl conjugate of APAP, it could be concluded that the major APAP-BSA adduct is one in which the drug is bound, via a thioether linkage at the C-3 position, to a sulfhydryl group on the protein. Furthermore, it could be established that this -SH function almost certainly is that associated with the cys-34 residue of BSA.

Absorption, distribution and elimination of felodipine in man

The objectives of these investigations were to study the absorption and disposition characteristics of felodipine in young healthy male volunteers following acute administration of different intravenous and oral doses, and to study urinary metabolites of [14C]felodipine following oral administration. Felodipine is rapidly and extensively absorbed from the gastrointestinal tract but owing to presystemic elimination, probably primarily in the liver, only 15% on average is systemically available. The systemic availability is independent of the oral dose in the 5 to 40 mg dose interval. The major fraction of the felodipine dose is localised extravascularly with a volume of distribution of about 10 L/kg. Less than 1% is confined to the blood. Felodipine is extensively bound to plasma proteins (greater than 99%). The mean elimination half-life of felodipine is greater than 10 hours. The urinary metabolic pattern of felodipine, using high pressure liquid chromatography, reveals 3 major metabolites (carboxylic acids of oxidised felodipine) in human urine.

Simultaneous determination of metoprolol and metabolites in urine by capillary column gas chromatography as oxazolidineone and trimethylsilyl derivatives

A method for the determination of metoprolol and its main metabolites in urine is presented. The method comprises derivatization of the aminopropanol side-chain with phosgene at alkaline pH and isolation in an organic phase at acidic pH. After trimethylsilylation, separation and quantification are performed by capillary column gas chromatography with flame ionization detection. The reaction is performed at pH 12 with 60 microliters of 2 M phosgene in toluene added in three portions. Diethyl ether--dichloromethane is used as extraction medium and bis(trimethylsilyl) acetamide as silylating agent. With spiked samples linear standard curves were obtained for metoprolol and three of its main metabolites with a detection limit varying between 4 and 20 mumol/l of urine. The method was applied to urine samples from a normal individual who had taken 292 mumol of metoprolol as tartrate.

Urinary metabolites of felodipine, a new vasodilator drug, in man, dog, rat and mouse

The urinary excretion of total 14C after oral administration of 25 mg (approximately 1 mumol/kg) 14C-felodipine to man, and intragastric administration (5 mumol/kg) to dog, rat and mouse, was 70, 39, 44 and 53% dose, respectively, in 72 h. Metabolites of felodipine were separated and quantified by h.p.l.c. Unchanged felodipine and its oxidized analogue were not excreted by any of the species studies. Three metabolites, present in all species studied, were isolated from urine and identified as products of the oxidation of felodipine to its pyridine analogue followed by hydrolysis of one or both of the pyridine carboxylic acid esters.

Stereoselective disposition of RS-tocainide in man

The disposition of RS-tocainide in three healthy volunteers has been studied after oral administration of a pseudoracemic mixture containing S(+) [3H] tocainide as a radioactive tracer together with a therapeutic dose of the racemate. Analytical methods based on HPLC have been developed to measure S(+) and R(-) tocainide in urine samples. Selected ion detection has been used for quantification of a tocainide conjugate. The radioactive dose was efficiently absorbed and mainly cleared via the kidneys. The elimination half-life of RS-tocainide was found to be 14.3 hours. The elimination half-lives of the two stereoisomers of tocainide differed significantly, i.e. R(-) tocainide 10 hours, and S(+) tocainide 16.7 hours. The observed t1/2 for the tocainide conjugate of 10.3 hours was close to that of R(-) tocainide, indicating that the metabolite was preferably formed from the R(-) stereoisomer of tocainide. Of the given dose, between 45 and 70% can be accounted for.

Pharmacokinetics of metoprolol and its metabolite alpha-OH-metoprolol in healthy, non-smoking, elderly individuals

The absorption and disposition of metoprolol have been evaluated in 10 healthy, non-smoking, elderly individuals (mean age 73.1 years) by simultaneous determination of [3H]-metoprolol and unlabelled metoprolol. The labelled drug was given as an intravenous tracer dose, immediately followed by oral metoprolol 25 mg. The experiment was preceded by administration of metoprolol 25 mg b.i.d. for 3 days. The volume of distribution, elimination half-life and total body clearance were almost the same as previously observed in healthy, young subjects. The mean systemic availability was about 39% in the elderly, which is lower than the mean of 55% observed in a control group of young volunteers who received 50 mg b.i.d. In the elderly, the mean plasma concentration of alpha-OH-metoprolol was about twice as high as that of the parent drug, whereas the opposite was true of the control group. The results indicate that age-related physiological changes have a negligible effect on the pharmacokinetics of metoprolol.

The metabolic disposition of the selective beta 1-adrenoceptor agonist prenalterol in mice, rats, dogs, and humans

The metabolic routes of the selective beta 1-adrenoceptor agonist prenalterol have been studied in mice, rats, dogs, and humans after oral administration. The drug was well absorbed from the gastrointestinal tract and most of the administered radioactivity was excreted in urine from all species within 24 hr. Prenalterol was metabolized to a varying extent in the species studied. About 20% of the 10-mg dose was recovered unchanged in man, the corresponding figures being 1.8% in the mouse, 7% in the rat, and 54% in the dog at 0.263 mg/kg (1 mumol/kg). Three metabolites were characterized and quantified by thin-layer chromatography, high-performance liquid chromatography, nuclear magnetic resonance (1H and 13C), and gas chromatography-mass spectrometry. Pronounced species variations in the metabolic pattern were observed. The phenolic sulfate ester of prenalterol was the main urinary metabolite in man, important in the dog, minor in the rat but not detectable in the mouse. Prenalterol glucuronide was formed in significant amounts in the animals and, in addition, beta-4(hydroxyphenoxy)lactic acid was present in dog urine. In the rat and the mouse the degree of biotransformation of prenalterol was significantly decreased at high oral doses of 2630 mg/kg (10 mmol/kg). The synthesis of prenalterol sulfate ester with use of ion pair extraction techniques is described.

Selected ion monitoring of metoprolol and two metabolites in plasma and urine using deuterated internal standards

A highly sensitive and specific quantitative assay for metoprolol and two of its metabolites, containing an unchanged 2-hydroxy-4-isopropylaminopropoxy sidechain, has been developed. The compounds are isolated from the alkalized sample (plasma or urine) by extraction with dichloromethane, and converted to trifluoroacetyl derivatives by reaction with methyl-bis-(trifluoroacetamide). The reaction mixture is gas chromatographed on an OV-17 column and each substance is assayed by electron impact mass spectrometry using selected ion monitoring, and quantified by comparing the intensity of fragment ion m/z 266 with the intensities of corresponding fragment ions from the deuterated internal standards (m/z 270 and 271). It is possible to determine concentrations as low as 1 nmol l-1 (0.3 ng ml-1) in 1 ml of sample with relative standard deviation of less than 10%.

Pharmacokinetic studies in man of the selective beta 1-adrenoceptor agonist, prenalterol

The pharmacokinetics of prenalterol, a selective beta 1-adrenoceptor agonist, has been studied in healthy subjects, by following the plasma concentration and urinary excretion of the unchanged compound and its total radioactive metabolites after oral and intravenous administration. Each of six healthy subjects received a single i.v. dose (2.5 mg) and three oral doses (2.5, 5.0 and 10 mg) of prenalterol. The oral dose was administered as a solution. Three of the subjects received the intravenous and oral doses of 2.5 mg as tritiated drug. Prenalterol was rapidly and completely absorbed after oral administration. The peak plasma concentration was attained after about 0.5 h. About 25% of prenalterol reached the systemic circulation. Prenalterol was extensively distributed to extravascular tissues with a half-life of the distribution phase close to 7 min. About 90% of the dose was excreted in urine within 24 h irrespective of the route of administration, indicating complete absorption of the drug. On average 60% of the i.v. and 13% of the oral doses were excreted as unchanged drug. The elimination half-life of the compound was 1.8 h, and the decline in the plasma concentration of the metabolites indicated a slower elimination rate than for the unchanged drug. Dose-dependent kinetics were not observed after the oral doses examined.

The effect of impaired renal function on the plasma concentration and urinary excretion of metoprolol metabolites

Plasma concentration and urinary excretion of total and 2 active metabolites of metoprolol have been studied in patients with varying degrees of renal impairment and in healthy subjects after intravenous and oral administration of 20 and 50 mg of 3H-metoprolol tartrate respectively. Renal clearance of total metabolites correlated directly with 51Cr-EDTA clearance (r = 0.95, p less than 0.001). A reduction of glomerular filtration rate (GFR) by 70 to 80% increased the elimination half-life of total metabolites and of the active metabolite alpha-hydroxymetoprolol about 3-fold. Significant accumulation was, however, only observed in the patients with a GFR of about 5 ml/min. Even in these patients, the contribution of alpha-hydroxymetoprolol to the beta-adrenoceptor blocking effect of metoprolol will be negligible. The second active metabolite studied is eliminated via biotransformation, and the urinary excretion as well as the plasma concentration of this metabolite were extremely low in comparison with those of the parent drug.

Plasma levels and beta-blocking effect of alpha-hydroxymetoprolol--metabolite of metoprolol--in the dog

The plasma levels and the beta-blocking effect of metoprolol and its active metabolite alpha-hydroxymetoprolol have been studied after i.v. bolus injections of the substances to dogs. For both substances the beta-blockade increased with the dose, and there was a linear relationship between percent reduction in exercise heart rate and the logarithm of plasma concentration. The dose of the metabolite, however, had to be 5 times higher than that of metoprolol to induce the same degree of beta-blockade. Because of differences in the volume of distribution, 2.0 liters/kg for alpha-OH-metoprolol and 3.5 liters/kg for metoprolol, the 5 times higher dose of alpha-OH-metoprolol resulted in 10 times higher plasma levels of the metabolite than of metoprolol. alpha-OH-Metoprolol was more slowly eliminated (t1/2 approximately 7.0 hr, total body clearance approximately 3.5 ml-kg-1-min-1) than metoprolol (t 1/2 approximately 2.0 hr, total body clearance approximately 20.0 ml-kg-1-min-1). Approximately 5% of an i.v. dose of metoprolol was metabolized to alpha-OH-metoprolol. The half-life of the endogenously formed metabolite was the same as after an i.v. dose of the compound.

Species differences in the metabolism of pamatolol, a cardioselective beta--adrenoceptor antagonist

The metabolism of pamatolol was studied in man, dogs, rats and mice after oral administration of a single dose. The drug was well absorbed in the gastro-intestinal tract and excreted in the urine, mainly in unchanged form, within 24 hrs. Four urinary metabolites were identified by gas chromatographic-mass spectrometric techniques. The metabolic data, in man, dog and mouse was found to be similar, both qualitatively and quantitatively. One metabolism route, involving aliphatic hydroxylation and subsequent oxidation, was found, to a significant extent only in the rat. The species variation between the mouse and the rat with regard to long-term toxicity of pamatolol is discussed. Artefact formation during trace analysis was observed.

Biotransformation of alprenolol in dog, guinea-pig and rat liver microsomes

1. Metabolites of alprenolol were isolated and identified in dog, guinea-pig and rat liver microsomes by means of g.l.c.-mass spectrometry and comparison with synthetic reference compounds. 2. The compounds were chromatographed as n-butylboronate derivatives, giving a series of diagnostic ions in the mass spectral fragmentation, which was elucidated by using stable isotopes. 3. Alprenolol was metabolized by aromatic ring hydroxylation, oxidation of the allylic function, and degradation of the isopropylaminopropanol side-chain. Alprenolol and four metabolites were quantified by h.p.l.c. and batch extraction techniques based on radioactivity measurements. 4. Five metabolites were detected in rat and guinea-pig liver microsomes and four in the dog. A species variation in the biotransformation of the allyl function in alprenolol was observed. The metabolite formed by oxidation of the allyl double bond was detected in significant amounts in the guinea-pig, and was also formed in the rat but could not be detected in dog liver microsomes.

Identification of urinary and biliary metabolites of alprenolol in the rat

1. After oral administration of alprenolol to rat, 12 metabolites were isolated and characterized as trifluoroacetyl, trimethylsilyl and n-butylboronate derivatives, using a g.l.c.-mass spectrometry-computer system. Fragmentation pathways of derivatives in the mass-spectrometric analysis are discussed. 2. Metabolic reactions involved are oxidative degradation of the propanolisopropylamine side-chain, aromatic hydroxylation, oxidation of the allyl group, and conjugation. A method for direct analysis of epoxide functions in the allyl group is described. 3. In comparison with metabolism of alprenolol in vitro, more polar metabolites are formed in vivo but the same principal metabolic pathways are valid. Structural features for biliary excretion are discussed.

Kinetic studies of dose-dependent metabolism of alprenolol: in vitro and in vivo studies in different species

Kinetic studies of the metabolism of alprenolol were performed with isolated microsomes from the rat, guinea-pig, dog and man at an initial substrate concentration of 0.17--150 micrometer. In all species the rate of aromatic hydroxylation reached a plateu above 50 micrometer of alprenolol in contrast to the rate of desisopropylation, where consistent saturation level was not obtained. The Km-values for the aromatic hydroxylation in the guinea-pig and man, 2,7 micrometer and 1.3 micrometer respectively, showed no concentration dependency in contrast to the rat (Km1 = 0.20 micrometer, Km2 = 26 micrometer) and the dog (Km1 = 0.78 micrometer, Km2 = 66 micrometer). The apparent Km-value of 0.20 micrometer for aromatic hydroxylation in the rat seemed to be of the same order of magnitude as reported spectral dissociation constant (Ks = 0.34 micrometer). In vivo experiments in the rat by oral administration of 7--700 mu mol/kg demonstrated a dose-dependent presystemic elimination of alprenolol. The urinary excretion of hydroxy-alprenolol was significantly lower after the highest dose. It is proposed, that the saturation of the aromatic hydroxylation, catalyzed by a high affinity site or subspecies of cytochrome P-450 with a low capacity, contributes to the dose-dependent kinetics in vivo.

Study of the metabolic pathways of alprenolol in man and the dog using stable isotopes

The metabolic pathways of alprenolol have been investigated in man and the dog, using an ion doublet technique of deuterium labelling combined with gas chromatography mass spectrometry. The drug is eliminated mainly by aromatic hydroxylation and glucuronidation. Specific analytical methods are applied to demonstrate that allylic oxidation and oxidative deamination are quantitatively of minor importance. The mechanism for oxidative deamination via an intermediary aldehyde could be elucidated by using the deuterium labelled compound. A method for characterization of 4-hydroxy-alprenolol glucuronides based on formation of stable derivatives and the following enzymatic hydrolysis is described. This approach has a general applicability to hydroxylated metabolites from compounds with an aminopropanol structure common for beta-adrenoceptor antagonists, for example. The metabolic routes for alprenolol in man and the dog are almost identical and in man more than 95% of a given dose can be accounted for.

Metabolism of metoprolol in the rat in vitro and in vivo

1. Metoprolol was metabolized in rat liver microsomes in vitro by O-demethylation with subsequent oxidation and by aliphatic hydroxylation of the methoxy-ethyl substituent and by oxidative deamination of the propanolisopropylamine side-chain. The same routes of metabolism in the rat in vivo were revealed from urinary metabolites. Eight metabolites were identified by g.l.c.-mass spectrometry by comparison with synthetized reference compounds. 2. Metoprolol binds to cytochrome-P-450 eliciting a type I difference spectrum with KS = 23 +/- 2-0 muM. The apparent Michaelis-Menten constant Km = 39 +/- 4-0 muM and Vmax = 1-28 +/- 0-22 nmol/mg protein X min were not significantly affected by pre-treatment of the rats with metoprolol or phenobarbital. Metoprolol pre-treatment had no effect on the cytochrome-P-450 level in the microsomes nor on the rate of metabolism of four standard substrates. Phenobarbital increased the cytochrome P-450 as expected. 3. Four metabolites representing the three main routes of metabolism were quantitatively determined after metabolism with rat liver microsomes and compared with the urinary levels of the same compounds. The same major metabolites were found in vitro and in vivo. The total amount of metabolites was not influenced by pre-treatment with metoprolol or phenobarbital. The relative amounts of the three main metabolites were slightly affected by pre-treatment.

Fibrin-stabilizing factor inhibitors. 12. 5-Dibenzylaminopentylamine and related compounds, a new type of FSF inhibitors

A series of omegadibenzylaminoalkylamines and related compounds have been prepared and tested as inhibitors of fibrin cross-linking. This structural type was chosen in an attempt to develop noncompetitive inhibitors of fibrinoligase. By the combination of the dibenzylamino moiety at one end and the primary amino group at the other end of a polymethylene chain, the same compound could function both as a pseudo donor substrate and as a noncompetitive alkylating inhibitor. Some of the compounds, notably 74-79, are among the most active fibrinoligase inhibitors described. However, the data indicate that the compounds probably function only as pseudo donor inhibitors.