Tamoxifen enhances the cytotoxicity of conventional chemotherapy in esophageal adenocarcinoma cells.

INTRODUCTION: Esophageal adenocarcinoma is a lethal malignancy which is increasing in incidence, and many patients receive chemotherapy as part of their treatment. We have previously demonstrated that esophageal adenocarcinoma-derived cell lines respond to treatment with estrogen receptor modulators, such as tamoxifen. Reports from breast cancer suggest that tamoxifen may attenuate the efficacy of other chemotherapeutic agents. We have therefore assessed the response of esophageal adenocarcinoma cell lines to tamoxifen therapy when given in combination with conventional agents. METHODS: Two estrogen receptor (ER)-positive esophageal adenocarcinoma cell lines (OE-19 and OE-33) were treated with combinations of tamoxifen, cisplatin and 5-fluorouracil (5-FU). Effects on cell viability were measured using an MTS assay, and cell death was detected with annexin V/propidium iodide flow cytometry. To assess whether the efficacy of tamoxifen in these cell lines might be relevant to the clinical setting, we analyzed ER status in 10 esophageal adenocarcinoma tissue specimens by immunohistochemistry. RESULTS: IC50 values (µM) for OE-19 and OE-33 were 11.2 and 7.1 for tamoxifen, 19.6 and 4.7 for cisplatin, and 1.7 and 5.9 for 5-FU, respectively. Cell death was detected in 11.9% and 15.8% of cells treated with tamoxifen, 7.9% and 8.7% cells treated with cisplatin, and 3.6% and 8.6% cells treated with 5-FU at their IC50s. The addition of tamoxifen to cisplatin increased cell death by 11.4% in OE-19 (p < 0.0001) and 16.3% in OE-33 (p < 0.0001). Similarly, the addition of tamoxifen to 5-FU increased cell death by 11.6% in OE-19 (p < 0.0001) and 15.9% in OE-33 (p < 0.0001). Eight of 10 tissue specimens showed positive staining for ERα and 7 of 10 for ERß. CONCLUSIONS: In a cell culture model the addition of tamoxifen to conventional chemotherapy appears to be both feasible and beneficial. Expression of ERα and ERß was also confirmed in esophageal adenocarcinoma tissues.

The difference in activity between (+)- and (-)-methadone is intrinsic and not due to a difference in metabolism.

The disposition and metabolism of (+)- and (-)-methadone has been compared in rats. At equal molecular doses, somewhat higher plasma levels of (-)-isomer were observed. At equal analgesic doses, brain and plasma concentrations of (+)-methadone were at least 25 times greater than those of (-)-methadone. No qualitative differences were observed between isomers with respect to in vivo metabolic pattern or in vitro N-demethylation rates. The results strongly support the conclusion that the large differences in analgesic potency between the isomers is due to an intrinsic difference in pharmacologic properties and is not related to a difference in disposition or metabolism.

Species differences in the metabolism of alpha-1-trans-4-dimethylaminotetrahydro-3-furyl-cyclohexanephenylglycolate, an experimental anticholinergic agent.

Metabolism studies in the rat, dog and cat have demonstrated a definite species difference in biotransformation and elimination of alpha-1-trans-4-dimethylaminotetrahydro-3-furylcyclohexanephenylglycolate (Lilly 82537), an experimental anticholinergic agent. Separation and identification of urinary and biliary metabolites by gas chromatographic mass spectrometric analysis has shown three mechanisms to be involved in the metabolism of Lilly 82537 in these species; N-demethylation, aliphatic hydroxylation ahd ester hydrolysis. A major portion of the drug administered was eliminated unaltered in the cat and dog, while only trace quantities of parent drug were observed in the urine and bile of rats. These metabolic differences may be responsible for observed species differences in the pharmacologic activity of Lilly 82537.

Metabolism of 1,4-dihydro-6-trifluoromethylquinoxaline-2,3-dione (Lilly 72525) in rats and cats.

1. The metabolism of 1,4-dihydro-6-trifluoromethylquinoxaline-2,3-dione (Lilly 72525), a sedative hypnotic drug, was studied in rat and cat. 2. Plasma concentrations of Lilly 72525 were measured fluorometrically after oral and intravenous doses of the compound in rats. A comparison of the area under the two curves suggested that 84% of the oral dose was absorbed. 3. Studies with 14C-labelled material in both species confirmed that the drug was well absorbed after oral administration and revealed that the dione was mainly eliminated unchanged in the urine. Bile duct cannulation experiments suggested that biliary excretion accounted for most or all of the drug present in faeces of rats. 4. Metabolites isolated from urinary extracts by t.l.c. were identified by g.l.c.-mass spectrometry. The only metabolite detected in rat urine or bile extracts was a ring-hydroxylated compound. This metabolite plus two N-hydroxylated metabolites were identified in extracts of cat urine.

Propoxyphene: pathways of metabolism in man and laboratory animals.

Through the combined use of stable isotope labeling and gas chromatographic mass spectrometric analysis, the metabolic patterns for propoxyphene have been determined in laboratory animals and man. The rat and dog eliminated propoxyphene and its metabolites principally via the bile, while the rabbit more closely resembled man in excreting the metabolic products into urine. Metabolites in rat and rabbit existed as conjugates, whereas in dog and man the metabolites were excreted as a mixture of the free and unconjugated forms. The primary route of metabolism in all species studied was N-demethylation. However, the rat and rabbit extensively hydroxylated propoxyphene and its metabolites prior to elimination. Metabolites arising from ester hydrolysis were found in rat and man. N-acetylated products were identified in all four species. A metabolite formed from cyclization and dehydration of dinorpropoxyphene was isolated in urine and was further identified as a circulating metabolite in dog plasma.

Metabolism of (14C) cefaclor, a cephalosporin antibiotic, in three species of laboratory animals.

The metabolic fate of the orally effective cephalosporin antibiotic cefaclor (Lilly 99638) has been studied in rats, mice, and dogs. Cefaclor is efficiently absorbed from the gastrointestinal tract as the intact antibiotic. In rats and mice, cefaclor, for the most part, escapes metabolism in the body and is eliminated unchanged as unaltered antibiotic, primarily by renal excretion. In dogs, however, cefaclor is more labile to metabolism and only a portion of the administered antibiotic is eliminated unchanged via the kidney.

Metabolic fate of [14C]cefamandole, a parenteral cephalosporin antibiotic, in rats and dogs.

The biotransformation of the parenterally effective cephalosporin antibiotic cefamandole nafate (I) has been studied in rats and dogs. After rapid in vivo hydrolysis of the nafate pharmaceutical form to cefamandole (II), the antibiotic was found to be very resistant to metabolic degradation in both species. In dogs, cefamandole escaped metabolism and was eliminated as unaltered antibiotic almost exclusively by renal excretion. In rats, cefamandole was somewhat labile to metabolism; however, a major portion of the administered antibiotic was eliminated unchanged principally by renal excretion.