Kathleen F. Tillery scite author profile

Kalin

Journal of Toxicology and Environmental Health

et al. 1987

The disposition of 14C-labeled decabromobiphenyl ether (DBBE) in male Fischer rats dosed by feeding (0.025-5.0% of the diet) or intravenously (1 mg/kg) was determined. For rats dosed by feeding, intestinal absorption of DBBE was evident in that the intact compound was present in extracts of liver. For these rats, the size of the liver increased with increasing concentration of DBBE in the diet. Liver contained a maximum of 0.449% of the administered radioactivity at 24 h after feeding rats a diet containing 0.0277% [14C]DBBE; no other organ or tissue contained more than 0.26%. The total amount of radioactivity found in tissues was less than 1% of the dose. Of the radioactivity recovered in the feeding experiments, more than 99% was in the feces and gut contents at 72 h; a maximum of 0.012% of the dose was in the urine. In the feces of rats fed [14C]DBBE, there were three metabolites, which together comprised 1.5-27.9% of the radioactivity. Since absorption was minimal, most of the metabolism of [14C]DBBE apparently took place in the gastrointestinal tract. The metabolites increased in percent of total radioactivity with the content of DBBE in the diet, an indication that enzyme induction in intestinal bacteria may have occurred at the higher doses. More extensive metabolism of [14C]DBBE occurred after intravenous administration; only 37% of the radioactivity in the feces was unchanged DBBE. At 72 h after dosing, fecal excretion accounted for 70% of the dose; only 0.129% appeared in the urine. Muscle retained 12.9% and skin 7.25% of the radioactivity administered. In 4 h, rats with biliary cannulas excreted in the bile 7.17% of the intravenously administered radioactivity; less than 1% was excreted as intact DBBE. Biliary excretion was apparently the major route for elimination of the intravenously administered compound. The rapid excretion and extensive metabolism of DBBE, relative to other polyhalogenated compounds, are advantageous properties that may allow it to be used in place of structurally similar compounds presently employed in industrial applications.

Disposition of 2‐hydroxy‐4‐methoxybenzophenone in rats dosed orally, intravenously, or topically

Kalin

Journal of Toxicology and Environmental Health

et al. 1986

Administration to rats of oral doses of [14C]-2-hydroxy-4-methoxybenzophenone (HMB) in the range of 3.01-2570 mg/kg revealed that a dose-dependent elimination process was operative at the highest dose. Urinary excretion (63.9-72.9% of the dose in 72 h) was the major route for elimination of radioactivity. An intravenous dose (4.63 mg/kg) distributed rapidly throughout the body of rats and appeared in the urine in an amount (67.4%) similar to those for the oral doses. Rats absorbed large portions of doses of [14C]HMB administered topically, either as an ethanolic solution (50, 200, or 800 micrograms/rat) or formulated in a lotion (50 micrograms/rat). For rats with biliary cannulas, 36.6% of the radioactivity of an intravenous dose (4.46 mg/kg) appeared in the bile in 4 h; the initial half-life for biliary elimination was 40 min. In the bile, at least five radioactive components, none of which was intact HMB, were present. The two major components were glucuronides of HMB and demethylated HMB, and a third was probably a sulfate ester of hydroxylated HMB. In urine, there were nine radioactive components, two of which were unchanged HMB and its glucuronide.

High-performance liquid chromatographic determination of doxorubicin and its metabolites in plasma and tissue

Rose

Journal of Chromatography B: Biomedical Sciences and Applicatio

et al. 1988

Disposition in mice of 7-hydroxystaurosporine, a protein kinase inhibitor with antitumor activity

Hill

Cancer Chemother. Pharmacol.

Rose

et al. 1994

UCN-01, a hydroxylated derivative of staurosporine, was selected for study because of its promising antitumor activity. For mice dosed intravenously, subcutaneously, or by oral gavage with this compound, the maximum tolerated doses (MTD) were 20, 10, and > 100 mg/kg, respectively. UCN-01 was stable in mouse and dog plasma, but in human plasma it was converted to a metabolite in a process not inhibited by standard protease and esterase inhibitors. Following an intravenous dose of 10 mg/kg UCN-01, the half-lives for the initial (t1/2 alpha) and terminal (t1/2 beta) exponential phases of elimination were 10 and 85 min, respectively; the area under the plasma concentration-time curve (AUC value) was 117 micrograms min ml-1. In mice dosed by oral gavage with 10 mg/kg, the calculated value for the half-life of the elimination phase was 150 min. The AUC value was 15 micrograms min ml-1, giving a value for bioavailability of 13%. After subcutaneous dosing with 10 mg/kg, the calculated values for half-lives for the distribution and elimination phases were 23 and 130 min, respectively; the AUC value was 113 micrograms min ml-1. Since this value is equivalent to that obtained for intravenous dosing, administration of UCN-01 by the subcutaneous route may be an alternative to intravenous dosing in preclinical and clinical trials.

Disposition of 2‐mercaptobenzothia2ole and 2‐mercaptobenzothiazole disulfide in rats dosed intravenously, orally, and topically and in guinea pigs dosed topically

Kalin

Journal of Toxicology and Environmental Health

et al. 1989

To determine the metabolic disposition of [14C]-2-mercaptobenzothiazole (MBT) and [14C]-2-mercaptobenzothiazole disulfide (MBTS), male and female rats were dosed topically. Topical doses were 36.1 micrograms/animal for [14C]MBT and 33.6 micrograms/animal for [14C]MBTS. Although more MBT passed through the skin than MBTS and although, relative to rats, guinea pigs absorbed a greater percentage of the dose (33.4% compared to 16.1-17.5% of the MBT and 12.2% compared to 5.94-7.87% for MBTS), the disposition of radioactivity derived from the two compounds was similar. Washing of the skin removed more of the radioactivity from guinea pigs than from rats. For both sexes of rats dosed intravenously with [14C]MBT (0.602 mg/kg) or [14C]MBTS (0.571 mg/kg), disposition of the compounds was similar. In 72 h, 90.9-101% of the dose appeared in the urine and 3.79-15.1% in the feces. At this time, a small portion of the administered radioactivity (1.52-1.96% of the dose) remained associated with erythrocytes. Oral dosing of rats for 14 d with unlabeled MBT (0.510 mg/kg.d) prior to a single dose of [14C]MBT (0.503 mg/kg) or with unlabeled MBTS (0.521 mg/kg.d) prior to a single dose of [14C]MBTS (0.730 mg/kg). For both sexes, disposition of the compounds was similar. At 96 h after dosing, a small portion of the administered radioactivity (1.20-1.69% of the dose) remained associated with erythrocytes, most of which was bound to the membranes. For both compounds and sexes, 60.8-101% of the radioactivity administered appeared in the urine and 3.46-9.99% in the feces in 96 h. At the time, only trace amounts of radioactivity remained in tissues other than blood. Of these tissues, thyroid contained the highest concentration. In the urine, there was a detectable MBT or MBTS, but there were two metabolites, one of which was identified as a thioglucuronide derivative of MBT. The other was possibly a sulfonic acid derivative of MBT. In conclusion, there were similarities in absorption, distribution, and metabolism of [14C]MBT and [14C]MBTS in rats and in guinea pigs, indicating that [14C]MBTS was readily converted to [14C]MBT.