Comparison of inhalation toxicity studies of gentamicin in rats and dogs.

Nebulized gentamicin solution was administered to rats (nose-only) and dogs (face mask) for 14 days with a 14-day recovery period. Control groups of each were exposed to saline aerosols. Mean estimated inhaled lung doses of gentamicin were 39, 123 and 245 mg/kg for rats (deposited doses 6, 17 and 34 mg/kg) over 30, 90 and 180 min, respectively. Since dogs do not tolerate exposures as long as rats, inhaled lung doses were limited to 7, 14 and 41 mg/kg (deposited doses of 1, 3 and 8 mg/kg) over 15, 30 and 60 min. Comparable doses were achieved at the low dose for rats and high dose for dogs. Serum AUCs (14 ± 2 µg/mL h (mean ± SD) at 6 mg/kg in rats and 11 ± 7 µg/mL h at 8 mg/kg in dogs) showed comparable exposure between the two, implying similar absorbed doses and confirming similar deposited lung doses. Rat exposures resulted in dose-related lung pathology (including low dose) manifested as upper respiratory tract irritant reactions with alveolar histiocytosis, inflammation, airway epithelial metaplasia and lymphomegaly in lung tissue. This was associated with high lung tissue gentamicin levels 24 h post-dose on Day 14 (375 ± 33 µg/g at deposited dose of 6 mg/kg). Dose-related kidney tubular necrosis (a well-known toxicity of parenteral gentamicin) was observed, but no test-article related effects on lung histopathology in dogs (even at highest deposited dose of 8 mg/kg) and low levels of lung tissue gentamicin (42 ± 11 µg/g) 24 h post-dose on Day 14.

Disposition and metabolism of cumene in F344 rats and B6C3F1 mice.

Cumene is a high-production volume chemical that has been shown to be a central nervous system depressant and has been implicated as a long-term exposure carcinogen in experimental animals. The absorption, distribution, metabolism, and excretion of [(14)C]cumene (isopropylbenzene) was studied in male rats and mice of both sexes after oral or intravenous administration. In both species and sexes, urine accounted for the majority of the excretion (typically ≥ 70%) by oral and intravenous administration. Enterohepatic circulation of cumene and/or its metabolites was indicated because 37% of the total dose was excreted in bile in bile duct-cannulated rats with little excreted in normal rats. The highest tissue (14)C levels in rats were observed in adipose tissue, liver, and kidney with no accumulation observed after repeat dosing up to 7 days. In contrast, mice contained the highest concentrations of (14)C at 24 h after dosing in the liver, kidney, and lung, with repeat dosing accumulation of (14)C observed in these tissues as well as in the blood, brain, heart, muscle, and spleen. The metabolites in the expired air, urine, bile, and microsomes were characterized with 16 metabolites identified. The volatile organics in the expired air comprised mainly cumene and up to 4% α-methylstyrene. The major urinary and biliary metabolite was 2-phenyl-2-propanol glucuronide, which corresponded with the main microsomal metabolite being 2-phenyl-2-propanol.

Disposition of [14C]N,N-dimethyl-p-toluidine in F344 rats and B6C3F1 mice.

N,N-Dimethyl-p-toluidine (DMPT) is used as a polymerization accelerator, in industrial glues, and as an intermediate in dye and pesticide synthesis. There is potential for human exposure to DMPT. The disposition of oral and intravenous (i.v.) doses of [14C]DMPT in F344 rats and B6C3F1 mice was investigated. A single i.v. (2.5 mg/kg) or oral (2.5, 25, or 250 mg/kg) dose of [14C]DMPT (1-25 microCi) was administered in an aqueous vehicle to male rats and mice. The 25-mg/kg oral dose was administered to females to investigate possible gender differences in disposition. However, no striking gender differences were observed. Since toxicity studies conducted elsewhere used a corn oil vehicle, the 250-mg/kg oral dose also was administered in corn oil to male rats; disposition was not dependent on vehicle. Excreta (through 24 h) and tissues collected at sacrifice were analyzed for total radioactivity. Dose-dependent differences in toxicity and disposition were observed. Toxicity at the 250-mg/kg oral dose to male mice was consistent with acute renal failure. At the same dose, male rats exhibited clinical signs of toxicity through 12 h but were clinically normal by 24 h. At lower oral doses, [14C]DMPT-derived radioactivity was well absorbed and rapidly excreted, primarily in urine.

Identification of urinary metabolites of orally administered N,N-dimethyl-p-toluidine in male F344 rats.

The metabolism of orally administered N,N-dimethyl-p-toluidine (DMPT) in male F344 rats was investigated. The rat urinary metabolite profile was determined by analytical reverse-phase high performance liquid chromatography (HPLC). Four radiolabeled peaks were observed, isolated, and purified by solid-phase extraction (SPE) and preparative HPLC methods. The 4 peaks were identified as p-(N-acetylhydroxyamino)hippuric acid (M1), DMPT N-oxide (M2), N-methyl-p-toluidine (M3), and parent DMPT. Metabolites M1 and M2 were identified by spectrometric and spectroscopic methods, including mass fragmentation pattern identification from both liquid chromatography/mass spectrometry and gas chromatography/mass spectrometry, and from chemical analysis of nuclear magnetic resonance spectra. Structural confirmation of metabolite M2 was accomplished by comparison with a synthetic standard. Peaks M3 and the peak suspected to be DMPT were identified by comparison of their HPLC retention times and mass fragmentation patterns with authentic standards of N-methyl-p-toluidine and DMPT, respectively. DMPT metabolism is similar to that reported for N,N-dimethylaniline.

Disposition of orally and intravenously administered methyltetrahydrofuran in rats and mice.

The disposition of [14C]methyltetrahydrofuran (14C-MTHF) in rats and mice was determined by following changes in the radioactivity in tissue and excreta with time after dosing. MTHF administered orally (1, 10, or 100 mg/kg) or intravenously (1 mg/kg) to either rats or mice was rapidly metabolized and excreted with <8% (mice) or 8-22% (rats) of the dose remaining in the body after 24 h (1 and 10 mg/kg doses) or 72 h (100 mg/kg dose). Based on recovery of radioactivity in excreta (other than feces) and tissues (other than the gastrointestinal [GI] tract), absorption of orally administered MTHF was essentially complete (93-100%). There were no overt signs of toxicity observed at any dose studied. The major route of excretion in mice was in urine followed by exhaled CO2. In rats the major route of excretion was exhaled CO2 followed by urinary excretion. The excretion of exhaled volatile organic compounds (VOC) was dose-dependent in both species; at lower doses exhaled VOC represented 1-5% of dose, but at the highest dose (100 mg/kg) this proportion rose to 14% (mice) and 27% (rats). Analysis of the VOCs exhaled at the high dose indicated that the increase was due to exhalation of the parent compound, 14C-MTHF. Analysis of urine showed three highly polar peaks in the mouse urine and two polar peaks in the rat urine. Because the 14C label in MTHF was in the methyl group, the polar metabolites were considered likely due to the one-carbon unit getting into the metabolic pool and labeling intermediate dietary metabolites.

Clinical characteristics and pharmacokinetics of purified soy isoflavones: single-dose administration to healthy men.

BACKGROUND: Soy isoflavones are potential cancer chemoprevention treatments. OBJECTIVE: We conducted safety studies of purified unconjugated genistein, daidzein, and glycitein, and defined pharmacokinetic parameters for their absorption and metabolism. DESIGN: Thirty healthy men ingested a single dose of 1 of 2 isoflavone preparations purified from soy. The delivered doses of genistein (1, 2, 4, 8, or 16 mg/kg body wt) were higher than those previously administered to humans. Formulation A was composed of 90 +/- 5% genistein, 10% daidzein, and 1% glycitein. Formulation B was composed of 43% genistein, 21% daidzein, and 2% glycitein. RESULTS: We observed no clinically significant behavioral or physical changes after treatment. We observed elevations in lipoprotein lipase and hypophosphatemia that were possibly related to the treatment but that were associated with no clinical toxicity. Considerable quantities of isoflavones were excreted in urine as conjugates. The terminal elimination rate, elimination half-life, area under the curve, maximum plasma concentration, apparent systemic clearance, and volume of distribution were estimated for genistein and daidzein. The mean elimination half-lives with both formulations were 3.2 h for free genistein and 4.2 h for free daidzein. The mean pseudo half-lives were 9.2 h for total genistein and 8.2 h for total daidzein. CONCLUSIONS: Dietary supplements of purified unconjugated isoflavones administered to humans in single doses exceeding normal dietary intake manyfold resulted in minimal clinical toxicity. Genistein and daidzein (free and total) were rapidly cleared from plasma and excreted in urine.

Safety and pharmacokinetics of purified soy isoflavones: single-dose administration to postmenopausal women.

BACKGROUND: Soy isoflavones are being evaluated as chemopreventive agents for breast and other cancers. OBJECTIVE: The objective was to perform safety and pharmacokinetic studies of purified unconjugated isoflavone preparations containing genistein, daidzein, and glycitein in postmenopausal women. DESIGN: Twenty-four healthy postmenopausal women ingested a single dose of 1 of 2 purified (from soybeans) isoflavone preparations that delivered a genistein dose of 2, 4, 8, or 16 mg/kg body wt. These doses were higher than those previously administered to human females. Toxicity studies were performed 24 h and 3, 6, 14, and 30 d after isoflavone administration. Kinetic studies were performed during the first 24 h. RESULTS: We observed a 7% decrease in systolic and diastolic blood pressure and a 32% decrease in the neutrophil count 24 h after treatment with formulation A. Isolated episodes of nausea, pedal edema, and breast tenderness were judged to be possibly related to the study treatment. The terminal plasma half-lives for free genistein, daidzein, and glycitein averaged 3.8, 7.7, and 3.4 h, respectively. The terminal pseudo half-lives for total genistein and total daidzein in plasma averaged 10.1 and 10.8 h, respectively. The estimated bioavailabilities of both total genistein and total daidzein from each of the 2 formulations were not significantly different. CONCLUSIONS: A single-dose administration of purified unconjugated isoflavones at amounts that exceed normal dietary intakes had minimal clinical toxicity in healthy postmenopausal women. The pharmacokinetic data suggest that chronic dosing at 12-24-h intervals would not lead to progressive accumulation of these isoflavones.

Inhalation administration of all-trans-retinoic acid for treatment of elastase-induced pulmonary emphysema in Fischer 344 rats.

A past study demonstrated that all-trans-retinoic acid (ATRA) treatment by intraperitoneal injection in a rat model of elastase-induced emphysema caused tissue regeneration as evidenced by a decrease in alveolar size and lung volume and an increase in alveolar number. We postulated that treatment with this retinoid by nose-only inhalation exposure would be a more efficient means of targeting damaged lung tissue. Emphysema was induced in male Fischer 344 rats by intratracheal instillation of pancreatic elastase (0.5 IU/g body weight). Four weeks after elastase instillation, animals were treated once daily, 4 days/week, for 3 weeks by exposing them nose-only to aerosolized ATRA (target concentration-time of 3000 or 15,000 mg-min/m3) or by injecting them intraperitoneally with ATRA in cottonseed oil (0.5 or 2.5 mg/kg). Based on estimates of particle deposition in the respiratory tract, inhalation doses were chosen to be consistent with injected doses. Lungs were fixed by inflation with formalin (constant pressure for 6 hours followed by >48 hours of immersion) and were embedded in paraffin. Sections were evaluated by histopathology and stereology. Inhalation exposure to ATRA at both aerosol concentrations caused significant elevations of ATRA in the lung, whereas only the high-dose injection treatment was associated with an elevation of lung ATRA. The mean ATRA concentration from lungs of rats in the high-dose inhalation exposure groups as measured by liquid chromatography--mass spectrometry was approximately 12-fold greater than that of high-dose injection-treated rats. Elastase instillation caused increased lung volumes, irregular alveolar air space enlargement, and fragmentation and attenuation of alveolar septa. Neither inhaled nor injected ATRA reduced the enlarged lung volumes associated with this emphysema model. Stereology demonstrated that alveolar air space enlargement in ATRA-treated rats was similar to that in sham-treated emphysematous animals. Thus, while inhalation treatment caused greater levels of the drug in lung tissue in comparison to that of injection-treated animals, treatment with ATRA by either route of administration did not cause a reversal of lung tissue damage in this model of elastase-induced emphysema.