Role of iodine in the toxicity of diiodomethyl-p-tolylsulfone (DIMPTS) in rats: ADME.

Metabolism of diiodomethyl-p-tolylsulfone (DIMPTS) was investigated in rats to determine the role of iodide in its toxicity. Fischer 344 (F-344) (5 or 50mg/kg) or Sprague Dawley (SD) (5mg/kg) rats were gavaged with (14)C-DIMPTS or dermally applied with 5mg/kg (F-344 only) and absorption, distribution, metabolism and excretion (ADME) determined. Additional experiments were conducted with its deiodinated analog (methyl-p-tolylsulfone, MPTS) in female F-344 rats (20mg/kg) for comparison. Orally administered (14)C-DIMPTS was rapidly absorbed and eliminated in urine (92%). The elimination t(½) was 1-4h. Dermally applied (14)C-DIMPTS remained undetectable in plasma with bioavailability ≈ 7%, only 5-7% of the dose was recovered in urine. DIMPTS liberated one or both of its iodine atoms upon absorption. The rate of elimination of the liberated iodide from the systemic circulation was 2- to 3-fold slower in SD than F-344 rats, which resulted in higher bioavailability of iodide to SD rats. DIMPTS was primarily oxidized at the benzylic methyl moiety forming the corresponding benzoic acid. Glutathione conjugation on the sulfonyl methyl group, via displacement of I(-) was also observed. Overall 67-80% of the total iodine atoms were metabolically released from DIMPTS. The MPTS was rapidly absorbed from the GI tract, metabolized and eliminated in urine similar to that of DIMPTS. These data were compared to iodide toxicokinetic results of a reproductive toxicity study for DIMPTS (80 mg/kg/day) and MPTS (32 mg/kg/day), where DIMPTS was toxic to dams and pups, while MPTS caused no toxicity. These data show that the liberated iodide is the ultimate toxicant of DIMPTS, which is readily transported to pups through milk, while the methyltolylsulfone backbone structure (MPTS) of DIMPTS is relatively nontoxic.

Mechanism of trifluralin-induced thyroid tumors in rats.

Trifluralin, an herbicide, has been reported to cause a significant increase in thyroid follicular cell tumors in male Fischer 344 rats. This study was designed to determine the mechanism of thyroid hyperactivity after trifluralin exposure. A group of 15 male Fischer 344 rats were exposed to trifluralin-fortified (6500 ppm) diet for 2 weeks. The time weighted average daily intake of trifluralin was 441+/-77 mg/kg/day. Ten rats of the group were sacrificed and the sera analyzed for T3, T4, and TSH levels. The livers were also analyzed for selected T4-specific UGT gene expression and total UGT enzyme activity. In the trifluralin treated rats, the serum T3 and T4 levels decreased by 17% and 90%, respectively and TSH increased by 37% more than the control rats. Trifluralin-induced total hepatic UGT enzymes (2.4-fold) and mRNA expression of selected hepatic UGT isozymes (UGT1A1, 1.4-fold; UGT1A6, 6.4-fold; UGT2B1, 3.7-fold). For the remaining 5 rats in the group, bile was collected for 2 h and analyzed for free and conjugated T3 and T4. The total amount of T4 in bile more than doubled in trifluralin treated rats. Trifluralin treatment increased bile flow, caused a 3.2-fold increase in biliary elimination of conjugated T4 and 63% increase in conjugated T3. Based on these data, the decrease in total serum T3 and T4 levels in the trifluralin treated rats was due to enhanced peripheral metabolism and an increase in bile flow that results in a compensatory increase in TSH synthesis and secretion. The increased levels of TSH with chronic exposure to trifluralin would exert a continuous stimulation of the thyroid gland leading to cellular hypertrophy and proliferation predisposing to the development of follicular cell tumors in rats.

Direct quantitation of hydroxyethylvaline in hemoglobin by liquid chromatography/positive electrospray tandem mass spectrometry.

Hemoglobin adducts are often used as biomarkers of exposure to reactive chemicals in toxicology studies. Therefore rapid, sensitive, accurate, and reproducible methods for quantifying these globin adducts are key to evaluate test material dosimetry. A new, simple, fast, and sensitive LC/ESI-MS/MS methodology has been developed and validated for the quantitation of hydroxyethylvaline (HEVal) in globin samples isolated from rats, both control and exposed to ethylene. Globin samples were first hydrolyzed to amino acids (including HEVal), followed by direct LC/ESI-MS/MS analysis. The lower limit of quantitation was 0.0095 ng/mL (0.026 pmol/mg globin). Typical calibration curves obtained over three days were linear over a concentration range from 0.0095 to 9.524 ng/mL, with correlation coefficient R(2)>0.999. The intra-day assay precision RSD values for all QC samples were ≤11.2%, with accuracy values ranging from 90.6 to 105%. The inter-day assay precision RSD values for all QC samples were ≤8.73%, with accuracy values ranging from 89.3 to 104.5%. The stability of HEVal in three freeze-thaw cycles over 48 h and at room temperature over 24 h was also evaluated, and the measured concentrations of HEVal were compared to the nominal values, with accuracy ranging from 94.8% to 109%. In conclusion, this method provides results comparable to those obtained using the traditional and complex Edman degradation phenylthiohydantoin-related quantitation method, but is much simpler and faster to conduct.

Agreement of pesticide biomarkers between morning void and 24-h urine samples from farmers and their children.

In pesticide biomonitoring studies, researchers typically collect either single voids or daily (24-h) urine samples. Collection of 24-h urine samples is considered the "gold-standard", but this method places a high burden on study volunteers, requires greater resources, and may result in misclassification of exposure or underestimation of dose due to noncompliance with urine collection protocols. To evaluate the potential measurement error introduced by single void samples, we present an analysis of exposure and dose for two commonly used pesticides based on single morning void (MV) and 24-h urine collections in farmers and farm children. The agreement between the MV concentration and its corresponding 24-h concentration was analyzed using simple graphical and statistical techniques and risk assessment methodology. A consistent bias towards overprediction of pesticide concentration was found among the MVs, likely in large part due to the pharmacokinetic time course of the analytes in urine. These results suggest that the use of single voids can either over- or under-estimate daily exposure if recent pesticide applications have occurred. This held true for both farmers as well as farm children, who were not directly exposed to the applications. As a result, single void samples influenced the number of children exposed to chlorpyrifos whose daily dose estimates were above levels of toxicologic significance. In populations where fluctuations in pesticide exposure are expected (e.g., farm families), the pharmacokinetics of the pesticide and the timing of exposure events and urine collection must be understood when relying on single voids as a surrogate for longer time-frames of exposure.

Investigation of the formation of N-nitrosodiethanolamine in B6C3F1 mice following topical administration of triethanolamine.

To determine potential nitrosation of triethanolamine (TEA) to N-nitrosodiethanolamine (NDELA) at different physiological conditions of the GI tract, in vitro NDELA formation was examined in aqueous reaction mixtures at several pHs (2-10) adjusted with acetic, sulphuric or hydrochloric acids or in cultures of mouse cecal microflora incubated. In vivo NDELA formation was also determined in blood, ingesta, and urine of female B6C3F1 mice after repeated dermal, most relevant human route, or single oral exposure to 1000 mg/kg TEA in the presence of high oral dosages of NaNO(2). Appropriate diethanolamine (DEA) controls were included to account for this impurity in the TEA used. Samples were analyzed for NDELA using GC/MS. The highest degree of nitrosation of TEA to NDELA ( approximately 3%) was observed in the in vitro cultures at pH 4 and acetic acid with lower amounts obtained using sulphuric acid ( approximately 1.3%) and hydrochloric acid ( approximately 1.2%). At pH 7, <1% of the TEA was nitrosated to NDELA and at pH 2 (HCl) or pH 10 (NaOH) no NDELA was found above the limit of detection. In incubated cultures containing cecal microflora and nutrient broth, only 0.68% of TEA was nitrosated to NDELA. No NDELA was formed in rats repeatedly dermally dosed with TEA at the limits of detection in blood (0.001 microg/ml, ppm), ingesta (0.006 microg/ml, ppm), and urine (0.47 microg/ml, ppm). Levels of NDELA measured in blood and ingesta after a single oral dose of TEA and NaNO(2) were less than those in DEA controls. These findings in toto confirm the lack of any significant formation of NDELA from TEA in vivo.