Transplacental and mammary passage of radioactivity in rats treated vaginally and orally with [14C]propranolol

The influence of pregnancy on the biotransformation and urinary excretion of methoxyphenamine in mice

(i) The urinary elimination of methoxyphenamine (MPA) and its metabolites in underivatized samples was examined after single and multiple oral administration to pregnant and non-pregnant mice by GLC and GLC-MS. (ii) The major metabolite O-desmethylmethoxyphenamine (ODMP), along with lesser amounts of N-desmethylmethoxyphenamine (NDMP) and 2-hydroxyamphetamine (2OH), were the only metabolites detected in urine extracts of pregnant and non-pregnant mice. 5-Hydroxymethoxyphenamine (5HMP) was not detected. Enzyme hydrolysis did not increase the recovery of either substrate or metabolites in either the pregnant or non-pregnant animals. The results show that MPA metabolism in the Swiss-Webster mouse is distinctly different from that seen in man and other laboratory animals. (iii) The mean MPA:ODMP ratio in day-6 urine from pregnant mice after a single dose was 0.31 +/- 0.04. The NDMP:ODMP ratios were less than 0.10 in all samples. Non-pregnant mice urine had equivalent amounts of MPA, NDMP, ODMP, and 2OH after multiple dosing. (iv) While multiple dosing and pregnancy did not alter either the urinary recovery or profile of the metabolites detected, there was a linear decrease in the MPA:ODMP ratio during gestation. (v) MPA was extensively metabolized to ODMP in the male mice, and the MPA:ODMP ratio of 0.41 was slightly higher than that observed in the pregnant and non-pregnant females.

Biotransformation and urinary excretion of 4-substituted amphetamines in pregnant mice

The urinary elimination of 4-hydroxyamphetamine (PHA) and a series of homologous 4-alkoxy-substituted amphetamines and their metabolites was examined after single and multiple oral administration to pregnant and non-pregnant mice. The metabolic profile and extent of biotransformation in a series of alkoxy analogues were affected by the size of the alkoxy side chain, multiple dosing and pregnancy. There were increased recoveries of both the substrate and the conjugated derivative of PHA during gestation. The major metabolic routes observed were O-dealkylation, conjugation, and aliphatic hydroxylation of the propoxy side chain. There was some evidence of oxidative deamination. Pregnancy did not alter the profile of the major metabolites detected by GLC and NMR spectroscopy.

Determination of propranolol, labetalol and clenbuterol in rat brain by high-performance liquid chromatography

A rapid and simple HPLC method for the measurement of adrenergic drugs (propranolol, labetalol and clenbuterol) in rat brain is described. This method was applied to establish if these drugs can pass the blood-brain barrier in prenatal or early post-natal life. The chromatography was performed using a C18 column and a phosphate buffer (pH 3)-acetonitrile (65:35, v/v) mixture. After homogenization of the brain tissue in perchloric acid, the supernatant was buffered at pH 9 and extracted with diethyl ether, followed by back-extraction in sulphuric acid. Recoveries of between 80 and 100% were achieved. The method was found to be accurate (100%) and precise (coefficient of variation around 10%). All three drugs were readily detected in the brain of neonatal rats after peripheral administration. In addition, we demonstrated the presence of propranolol in the fetal brain after maternal administration.

A comparative study of the pharmacokinetics of propranolol and its major metabolites in the rat after oral and vaginal administration

1. The concentrations of propranolol (PPL) and its metabolites were monitored by h.p.l.c. in serum of rats during the first 6 h after administering single doses (20 mg/kg) of PPL either orally or intravaginally (i.vg). 2. The results showed that PPL was quickly transferred to the systemic circulation from the rat vagina and the serum concentration profile as substantially altered by the route of administration. Serum concentrations of free PPL were significantly higher in i.vg-dosed animals than their oral dosed counterparts. 3. Inter-animal serum conc. variations of PPL and its metabolites in the i.vg-dosed rats were smaller than those of the orally treated females. 4. In comparison with the i.vg-dosed rats, the levels of PPL metabolites (propranolol glycol, naphthoxylactic acid, naphthoxyacetic acid) were greater by the oral route, though these differences were not statistically significant. 5. The serum elimination half-lives (t1/2)beta of PPL and its metabolites during the beta-phase were not significantly different in the two treatment groups. 6. Following i.vg application, both the AUC and the Cmax values of PPL were significantly greater than those of orally dosed females, while no statistically significant differences were found in the tmax values. 7. Comparison of the AUC values showed that relative bioavailability of PPL was approx. 36 times greater in i.vg-treated animals than those of the orally dosed rats.