Elimination pathways of [14C]losoxantrone in four cancer patients.

Losoxantrone is an anthrapyrazole derivative in Phase III development in the U.S. for solid tumors, notably breast cancer. To obtain information on the routes of elimination of the drug, a study was conducted in four patients with advanced solid tumors, which involved intravenous administration of 100 microCi of [14C]losoxantrone for a total dose of 50 mg/m(2) during the first course of losoxantrone therapy. Blood, urine, and feces were collected for up to 2 weeks and were analyzed for total radioactivity and parent drug. In addition, feces were profiled for the presence of metabolites. Plasma concentrations of total radioactivity exhibited a temporal pattern similar to the parent drug. Combined recovery of administered total radioactivity from urine and feces was 70% with the majority (87%) of this radioactivity excreted in the feces, presumably via biliary excretion. Feces extracts were profiled for metabolites using a high-performance liquid chromatography method developed to separate synthetic standards of previously identified human urinary metabolites. Only intact losoxantrone was found in the feces. About 9% of the dose was excreted in the urine, primarily during the first 24 h and mostly in the form of parent compound. Collectively, these data indicate that fecal excretion of unmetabolized drug via biliary and/or intestinal excretion is the primary pathway of intravenously administered losoxantrone elimination in cancer patients with refractory solid tumors.

Human moricizine metabolism. II. Quantification and pharmacokinetics of plasma and urinary metabolites.

1. The metabolism of moricizine.HCl was studied in 12 male volunteers dosed with 250 mg (300 microCi) 14C-radiolabelled drug. 2. Moricizine was biotransformed to many metabolites in humans (at least 35 plasma and 51 urine metabolites). 3. Urine and faecal combined mean (range) recovery accounted for 90.2% (73.4-101.6%) of the administered radioactivity, with most of the recovered radioactivity present in faeces (mean 58.4%; range 45.6-64.7%). Mean (range) urinary recovery was 31.8% (26.2-36.9%), with <1% of the dose recovered as intact moricizine, and no one metabolite accounting for >2.5% of the dose. 4. Total radioactivity (TR) plasma t1/2 was 85.2 h, while that for moricizine was 2.4 h. Mean half-lives for plasma metabolites ranged from 2.9 to 23.6 h. The largest portion (11%) of TR AUC (area under the plasma concentration-time curve) was attributed to 2amino-10-glucuronophenothiazine. Each of the other metabolites accounted for less of the TR AUC than parent drug except for two unidentified peaks which had comparable areas (approximately 5% of the total radioactivity area). 5. Two identified moricizine metabolites, 2-amino-10-(3-morpholinopropionyl) phenothiazine and ethyl [10-(3-aminopropionyl) phenothiazin-2-yl] carbamate, possess the structural characteristics proposed for class 1 anti-arrhythmic activity (pendant amine functionality) and have plasma half-lives 4-7-fold longer than moricizine.

Human moricizine metabolism. I. Isolation and identification of metabolites in human urine.

1. Using synthetic standards and/or spectral data, seven moricizine metabolites were structurally identified in human urine. Two novel metabolites were identified as phenothiazine-2-carbamic acid and ethyl [10-(3-aminopropionyl) phenothiazin-2-yl] carbamate. Two novel human moricizine metabolites, 2-amino-10-(3-morpholino-propionyl) phenothiazine, a previously identified dog metabolite, and 2-aminophenothiazine, a previously identified rat metabolite, were also identified. Three additional human metabolites, phenothiazine-2-carbamic acid ethyl ester sulphoxide (P2CAEES), moricizine sulphoxide, and ethyl ¿10-[N-(2'-hydroxyethyl)3-aminopropionyl] phenothiazin-2-yl¿ carbamate, all previously described in the literature, were observed. 2. Both 2-amino-10-(3-morpholinopropionyl) phenothiazine and ethyl [10-(3-aminopropionyl) phenothiazin-2-yl] carbamate, and possibly ethyl ¿10-[N-(2'-hydroxyethyl) 3-aminopropionyl]phenothiazin-2-yl¿ carbamate, possess the structural characteristics thought to be necessary for class 1 antiarrhythmic activity.

Pharmacokinetic interactions of moricizine and diltiazem in healthy volunteers.

Sixteen healthy male volunteers completed a nonrandomized, sequential, three-phase study. The three phases were 1) moricizine at 250 mg every 8 hours for 7 days with 12 days washout; 2) diltiazem at 60 mg every 8 hours for 7 days; and 3) concomitant administration of moricizine at 250 mg and diltiazem at 60 mg every 8 hours for 7 days. The plasma concentration-time profiles were obtained at the end of each phase for moricizine, diltiazem (with its metabolites desacetyl-diltiazem and N-desmethyl-diltiazem), and both when administered together. Under steady-state conditions, there was a two-way (opposing) pharmacokinetic drug interaction when moricizine and diltiazem were coadministered in healthy volunteers. Both maximum plasma concentration (Cmax) and the area under the plasma concentration-time curve from time 0 to the end of administration (AUC tau) of moricizine increased significantly by 88.9% and 121.1%, respectively. Oral clearance (Clo) decreased by 54%. The terminal half-life (t1/2) of moricizine was not affected, however (2.1 +/- 0.5 hours versus 2.4 +/- 0.7 hours). It is believed that these changes were due to the inhibition of hepatic metabolism by diltiazem, which resulted in an increased systemic availability of moricizine. Moricizine had opposite effects on the pharmacokinetics of diltiazem. Moricizine decreased the Cmax of diltiazem significantly (by 36%) and increased Clo by 52%. A small but statistically significant decrease in the t1/2 from 4.6 +/- 1.3 hours to 3.6 +/- 0.7 hours was observed. Despite this result, no remarkable changes (e.g., in Cmax, AUC, or t1/2) were found for the two major diltiazem metabolites desacetyl-diltiazem and N-desmethyl-diltiazem. It appears that the pharmacokinetic interaction of moricizine and diltiazem was metabolic. With the increase in moricizine concentrations and the decrease in diltiazem concentrations, adjustments in dose may be required to achieve optimal therapeutic response when coadministering both agents.

Determination of naltrexone and its major metabolite, 6-beta-naltrexol, in human plasma using liquid chromatography with electrochemical detection.

A sensitive and specific high-performance liquid chromatographic method with electrochemical detection was developed for the simultaneous determination of naltrexone and its major metabolite, 6-beta-naltrexol, in human plasma. After alkalinizing 2 ml plasma samples with pH 9 sodium carbonate buffer, naltrexone and 6-beta-naltrexol were extracted into dichloromethane and then back-extracted into 0.017 M phosphoric acid. A portion of the acid extract was chromatographed on a YMC phenyl column using a mobile phase of methanol-phosphoric acid (50 mM) (20:80, v/v) (pH* 3.2) at a flow-rate of 1.2 ml min 1. Quantification was performed using an ESA Coulometric electrochemical detector. Acceptable intra-day and assay precision (RSD < 10%) and accuracy (< 16%) for both compounds were observed over concentration ranges of 0.25-50.0 ng ml-1 for naltrexone and 0.5-100 ng ml-1 for 6-beta-naltrexol. No degradation of either naltrexone or 6-beta-naltrexol was observed in frozen human plasma stored at -20 degrees C over an 8 month period. The method is sufficiently sensitive and selective to quantify plasma concentrations of naltrexone and 6-beta-naltrexol after oral doses of 50 mg of naltrexone to healthy subjects or alcoholic patients.

The effect of hepatic disease on the disposition of moricizine in humans.

The pharmacokinetics of moricizine and two of its metabolites, moricizine sulfoxide and phenothiazine-2-carbamic acid ethyl ester sulfoxide, were studied in healthy control subjects and in patients with chronic liver disease (cirrhosis). Moricizine disposition was significantly altered by hepatic cirrhosis. Compared to healthy subjects, the hepatic disease patients had an increased Cmax (59%), an increased t1/2 (141%), and a reduced plasma clearance (71%). Additionally, small but statistically significant increases were observed for tmax and the fraction of moricizine not bound to plasma proteins in patients with hepatic disease. The elimination of both moricizine metabolites was also altered by hepatic dysfunction as indicated by significantly prolonged terminal half-lives. Furthermore, there was a reduction in the conversion of moricizine to moricizine sulfoxide. Both hepatic blood flow and hepatic metabolizing capacity were assessed in all subjects and patients by administration of indocyanine green and antipyrine, respectively. Indocyanine green and antipyrine plasma clearances were decreased by 38 and 51%, respectively, indicating that both functions were diminished by hepatic cirrhosis. We conclude that the moricizine dose required for arrhythmia patients with hepatic disease should be lower, and perhaps, the dosing frequency should be less than in patients with normal liver function.

Epidermal growth factor antagonizes vasopressin in vivo and in vitro.

Since EGF causes diuresis through a renal action and may antagonize the hydroosmotic effect of AVP in vitro we investigated the antagonistic action of EGF with AVP in vivo and the mechanism of the antagonism in vitro. Conscious ewes received i.m. injections of a selective AVP V2-receptor agonist (1-desamino, D-Arg8 vasopressin acetate, DDAVP) every 12 hours for days 5 to 16. All ewes received an i.v. isotonic saline infusion (100 ml/day) for days 1 to 8 and days 13 to 16, and i.v. EGF in 100 ml saline/day at doses of 0 (N = 8) or 10 (N = 8) micrograms/hr for days 9 to 12. DDAVP reduced both urine volume and water intake, and increased urine osmolality. In contrast, simultaneous infusion of EGF reversed the DDAVP-induced responses, resulting in a transient negative fluid balance, kaliuresis and a transient natriuresis (all P < 0.05). When EGF treatment ceased, the effects of DDAVP treatment alone gradually became apparent. From the in vitro studies, the AVP-related peptides displaced specific AVP V1- and V2-receptor antagonist radioligands from rat renal inner medullary membranes, whereas EGF had no effect. However, EGF antagonized AVP V2-stimulated cAMP production in a dose-dependent way (IC50 = 2 x 10(-7) M). Therefore, the diuretic effect of EGF is not via direct antagonism of the antidiuretic AVP V2-receptor but seems mediated by inhibition of the antidiuretic AVP V2-receptor second messenger system.

Enzyme induction by moricizine: time course and extent in healthy subjects.

Moricizine.HCl, a novel phenothiazine derivative with oral antiarrhythmic activity, was examined for its potential to induce its own hepatic metabolism and to alter the pharmacokinetics of the test substrate, antipyrine, in 12 healthy male subjects. Antipyrine oral clearance increased from a starting value of .74 mL/minute/kg to .98 (+32%, P < .01) after 7 days of moricizine administration (250 mg every 8 hours) and to 1.15 mL/minute/kg after 14 days (+47%, P < .05); t1/2 was correspondingly reduced. Moricizine oral clearance increased from a baseline of 3.01 L/hour/kg to 3.62 (+20%, P < .05) after 6 days of oral moricizine and 4.66 (+51%, not significant) after 13 days. Moricizine t1/2 was marginally, but consistently, increased (+23%, P < .05) instead of decreased as one would expect because of enzyme induction, presumably due to a decrease in systemic bioavailability and its influence on the oral volume of distribution. In half of the subjects who discontinued moricizine after 7 days, antipyrine pharmacokinetic values returned to near baseline 7 days later. Although moricizine was able to induce its own hepatic metabolism and that of antipyrine after 6 or 7 days of continuous administration, the electrocardiographic properties of moricizine did not appear to be altered by continuous dosing.

Effect of moricizine on the pharmacokinetics of single-dose theophylline in healthy subjects.

We studied the effect of multiple oral doses of moricizine on the pharmacokinetics of theophylline in healthy male subjects. Twelve subjects initially received two single oral doses of theophylline, one in the form of immediate-release Aminophyllin on day 1 and the other in the form of controlled-release Theo-Dur on day 3. Multiple oral doses of moricizine (Ethmozine, 250 mg every 8 h) began on day 5 and continued for 18 days. While receiving moricizine, the subjects were again given the two formulations of theophylline in the same order on days 19 and 21. Theophylline pharmacokinetic profiles were obtained over 36 h after all theophylline administrations. Multiple-dose moricizine administration significantly decreased (p < 0.0005) theophylline area under the curve by 32 and 36% after Aminophyllin and Theo-Dur, respectively. Theophylline t1/2 was also significantly decreased (p < 0.02) by concomitant moricizine dosing. Moricizine had no apparent effect on theophylline absorption after Aminophyllin, based on the lack of changes in the maximum plasma concentration (Cmax) and the time to reach Cmax; however, moricizine administration did decrease (p < 0.0005) the Cmax of theophylline after Theo-Dur. We conclude that these pharmacokinetic changes are most likely due to enzyme induction mediated by moricizine. Consequently, concomitant use of moricizine and theophylline may necessitate the administration of more frequent and higher doses of theophylline.

Effects of multiple doses of moricizine hydrochloride on its pharmacokinetics and hepatic microsomal enzymes in rats.

We studied the influence of chronic moricizine hydrochloride (MRZ) treatment on the drug's pharmacokinetics and on drug metabolizing enzyme activities in rats. Separate groups of 8 rats (4 males and 4 females) were treated with 40 and 100 mg/kg oral MRZ once daily for 7 days and saline control for 7 days prior to the preparation of hepatic microsomal enzyme suspensions. Depending on the substrate, treatments with multiple oral MRZ increased or decreased hepatic microsomal enzyme activities. For the pharmacokinetic study, rats (4 males and 4 females) were treated with 40 mg/kg oral MRZ once daily for 7 days. A comparison of MRZ pharmacokinetics obtained on day 1 relative to day 7 revealed that both AUC0-t and AUC0-infinity increased about 7-fold in males and 2-fold in females. Cmax also increased about 5-fold from day 1 to day 7 in males. These increases in blood concentrations and AUC's are likely due to enzyme inhibition. Results obtained from female rats on days 1, 4 and 7 suggest that metabolic changes probably occur after the 4th day of dosing. Therefore, chronic MRZ treatment affected its pharmacokinetics and hepatic metabolizing enzyme activities in rats.