A total of 9 patients entered in a phase I trial who received oral idarubicin daily for 3 days took part in pharmacokinetic studies, and bioavailability studies were performed on 13 additional patients receiving single doses of oral idarubicin alternating with i.v. treatment. The data were best fit by a two-compartment model (distribution and elimination compartments for i.v. drug and absorption and single-phase elimination for oral drug). For different idarubicin doses in the phase I and bioavailability studies, the median values for the terminal half-life of idarubicin varied from 5.6 to 11.6 h. High concentrations of the active metabolite idarubicinol were formed. Idarubicinol was eliminated more slowly than was the parent compound, with median half-lives for different dose levels varying from 8 to 32.7 h. Although most pharmacokinetic parameters were similar in plasma and whole blood, peak concentrations and AUCs in whole blood were about 3-4 times those calculated in plasma for idarubicin and about 1.5-2 times those determined in plasma for idarubicinol, indicating fairly extensive uptake into erythrocytes. Oral bioavailability was determined by comparing oral idarubicin to i.v. drug with respect to the combined idarubicin and idarubicinol plasma AUCs, and it varied from 12%-49% (median, 29%). Bioavailability was essentially the same (30%) when whole-blood values were used. Urinary excretion of the drug was less than 5% of the delivered dose by 96 h. Granulocytopenia correlated with plasma idarubicinol "estimated" clearance and steady-state volume of distribution, with whole-blood idarubicinol AUC, area under the moment curve (AuMC), and "estimated" clearance and volume of distribution, and with whole-blood combined idarubicin and idarubicinol AUCs. This suggests that drug contained in erythrocytes plays a major role in toxicity and that idarubicinol may play a larger role in toxicity than does the parent compound.
Autopsy tissues were collected from ten patients who had received etoposide, 150-3480 mg, from 1 to 412 days antemortem and from five patients who had received teniposide, 234-1577 mg, from 3 to 52 days antemortem. Tissues were assayed for etoposide and teniposide using high-pressure liquid chromatography with electrochemical detection. Etoposide was detectable in tissues of three of four patients dying < 5 days after their last etoposide treatments to cumulative doses of 150-432 (median, 280) mg but was detectable in tissues of only one of six patients dying 7-412 (median, 37) days after their last etoposide treatment to a cumulative dose of 607-3600 (median, 1553) mg. The highest tissue concentrations were in the small bowel, prostate, thyroid, bladder, spleen, and testicle. Intermediate concentrations were found in the lymph node, skeletal muscle, adrenal gland, stomach, tumor, liver, lung, pancreas, and kidney, and the lowest concentrations were found in the heart, brain, diaphragm, vagina, and esophagus. Teniposide was detectable in one patient dying 3 days after a cumulative teniposide dose of 576 mg (spleen, prostate, heart > large bowel, liver, pancreas > thyroid, adrenal, stomach, small bowel, bladder, testicle, and skeletal muscle) but was not detectable in any tissue from four patients dying 5-52 (median, 8) days after their last treatment to a cumulative teniposide dose of 234-1577 (median, 520) mg. The very short tissue half-life contrasts with our previous observations for human autopsy tissue concentrations of mitoxantrone, doxorubicin, menogaril metabolites, diaziquone, and amsacrine. The short tissue half-life may help explain the schedule dependency of epipodophyllotoxin efficacy and may also help explain the lack of visceral toxicity of these compounds.
Autopsy-tissues were obtained from eight patients who had last received menogaril (total cumulative dose, 175-1080 mg/m2) intravenously (one patient) or orally (seven patients) from 1 to 285 days prior to death. Tissue samples were assayed for menogaril and its metabolities by high-pressure liquid chromatography. Unchanged menogaril was found only in a single lung-tissue sample from a patient who had died < 24 h after receiving his last treatment. N-Demethylmenogaril was found in two lung-tissue samples and in single samples of the thyroid, lymph node, pancreas, cerebellum, and tumor. The major menogaril metabolite found in human autopsy-tissues was 7-deoxynogarol. The highest 7-deoxynogarol concentrations were found in the large bowel (median, 201 ng/g), liver (median, 183 ng/g), and lung (median, 177 ng/g). The heart ranked as the 9th of 18 organs in median 7-deoxynogarol concentration, after the large bowel, liver, lung, tumor, thyroid, skeletal muscle, adrenal gland, and kidney. The lowest concentrations were detected in brain tissue. Our results suggest that the low degree of cardiac toxicity and the possible pulmonary toxicity of menogaril may be related to relative tissue concentrations of menogaril metabolites. Tumor 7-deoxynogarol concentrations were comparable with those in normal tissues, except that concentrations in intracerebral tumors were higher than those in the normal brain. Tissue 7-deoxynogarol concentrations appeared to be directly related to the cumulative dose and inversely related to the time from the last treatment to death; the value obtained by dividing dose by time correlated (P < 0.05) with tissue 7-deoxynogarol concentrations.
A pharmacokinetic study of tiazofurin was carried out in 13 patients treated in a phase I clinical trial of the drug and in 7 patients undergoing surgical resection of brain tumor (in conjunction with studies on penetration of drug into central nervous system tumors). Tiazofurin was found to be rapidly eliminated from the plasma and red blood cell fraction of both groups of patients with kinetics consistent with a two-compartment model of elimination. Operative conditions did not significantly change the pharmacokinetics of tiazofurin in CNS patients. Pharmacokinetics were linear over the dose range 500-2700 mg/m2. The data suggest that there is only a small degree of tissue binding of drug and that the drug is not concentrated by tissues. Uptake into RBC was rapid and elimination from RBC was essentially parallel to drug elimination from plasma. There was no evidence that RBC sequestration of drug contributes to toxicity. Much of the drug was excreted unchanged in the urine, but there was little correlation between creatinine clearance and plasma pharmacokinetics of tiazofurin, suggesting that renal tubular secretion may be a more important method of elimination than is glomerular filtration. Patients with high AUC values and low plasma clearance values were particularly prone to develop toxicity.
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