C. W. Jameson

Immunological and biochemical responses in mice treated with mercuric chloride.

Adult B6C3F1 male mice were given water containing 3, 15, and 75 ppm mercury (as mercuric chloride) for 7 weeks. There were dose-related increases in blood and kidney mercury levels but only the former showed a time-dependent change. Mercury was not detected in any of the lymphoid organs except for the spleen. There was no mortality and only minimal histological changes occurred in kidneys of dosed mice. Nonspecific toxicity occurred at the 75 ppm dose level, consisting of small differences in body and organ weights, hematological changes, and general enzyme inhibition in the bone marrow and spleen. However, there were specific immunotoxic and biochemical alterations in lymphoid organs of mice treated at the lower doses of mercury. The immunological defects were consistent with altered T-cell function as evidenced by decreases in both T-cell mitogen and mixed leukocyte responses. There was a particular association between the T-cell defects and inhibition of thymic pyruvate kinase, the rate-limiting enzyme for glycolysis. The differences in the pattern of enzyme responses among lymphoid organs implied that two mechanisms of mercury toxicity were operative--one at high concentrations that caused physicochemical enzyme inhibition and another at low concentrations that caused indirect enzyme inhibition.

Toxicokinetics of cinnamaldehyde in F344 rats

The toxicokinetic profile of cinnamaldehyde (CNMA) was investigated in Fischer 344 rats. CNMA was found to be unstable in blood. After iv administration, a large fraction of CNMA was immediately oxidized to cinnamic acid. The biological half-life of CNMA after iv administration was found to be 1.7 hr. After administration by gavage of CNMA at 250 or 500 mg/kg body weight using corn oil as vehicle, the maximum blood concentrations of CNMA were in the order of 1 microgram/ml. These low blood concentrations were maintained over a 24-hr period after a dose of 500 mg/kg, which is relatively long considering the short (1.7 hr) biological half-life of CNMA. The estimated oral bioavailability of CNMA was less than 20% for both the 250 and 500 mg/kg doses. No CNMA was present in blood at any time in rats dosed with 50 mg CNMA/kg body weight. Only a small amount of the administered CNMA was excreted in rat urine as free cinnamic acid or beta-glucuronide-conjugated cinnamic acid. The majority of CNMA administered orally was excreted in urine as hippuric acid within 24 hr. The maximum excretion rate occurred at 8 hr after gavage. Hippuric acid recovered in 50-hr urine samples was found to be directly proportional to the oral dose of CNMA.

Development of renal toxicity in F344 rats gavaged with mercuric chloride for 2 weeks, or 2, 4, 6, 15, and 24 months

Both sexes of F344 rats were gavaged with maximal tolerated doses of mercuric chloride for periods from 2 wk to up to 2 yr to investigate chronic nephrotoxicity and potential carcinogenicity. The toxicity of mercuric chloride was excessive after 2 wk of exposure to doses ranging from 1.25 to 20 mg/kg, compromising renal function by selectively destroying cells of the proximal tubules, and eliciting marked elevations in urinary biomarker enzymes diagnostic for acute renal tubule necrosis. In the 2-wk studies, urinary alkaline phosphatase and aspartate amino-transferase were most sensitive to renal mercury toxicity among a panel of six enzymes, exhibiting twofold increases above controls at the 5.0 mg/kg dose, before changes in the other enzymes occurred. Urinary lactate dehydrogenase was the most responsive enzyme, with up to 11-fold increases in activity above controls. In response to mercuric chloride exposure of 5.0 mg/kg for 2-6 mo, the greatest and most persistent increases in elevation of urinary enzyme activities were exhibited by alkaline phosphatase and gamma-glutamyl transferase, which increased two-to threefold above controls. At this interval, the maximal severity of the renal lesions in both sexes of rats was graded as minimal to mild. Beyond 6 mo none of the urinary enzymes measured in this study was adequate as biomarkers of nephrotoxicity, although the severity of the renal lesions had progressed. Mercury accumulated in a dose-related fashion primarily in the kidney, and to a lesser extent in the liver. The severity of the renal lesions was increased by continued exposure to mercuric chloride, as tissue concentrations of mercury rose in proportion to dose. Mercuric chloride treatment for 2 yr clearly exacerbated the severity of the spontaneous nephrotoxicity prevalent in aging F344 rats. The excessive mortality that occurred in the male rats was probably due to a combination of these factors. No renal tumors were detected in rats, possibly because the potential for their development was reduced; however, direct tissue contact with mercury induced squamous-cell papillomas of the forestomach in both sexes.

Regression of methyl bromide-induced forestomach lesions in the rat.

There is continuing concern about the role of irritation in cancer development. Methyl bromide, a widely used fumigant and known irritant reported to cause forestomach carcinomas in rats, was dissolved in peanut oil and given by gavage at 50 mg/kg body wt to Wistar rats five times per week for 13 to 25 weeks. Starting at Week 13, methyl bromide administration was discontinued for half of the methyl bromide-treated rats (stop treatment group). After that, rats from both the continuous treatment and stop treatment groups were terminated at 4-week intervals to follow the progression of the stomach lesions. Forestomach lesions were not found in control rats receiving peanut oil and killed at 13 or 25 weeks. At 13 weeks the forestomachs from rats receiving methyl bromide were contracted and adherent to the liver and spleen. Inflammation, acanthosis, fibrosis, and a high incidence of pseudoepitheliomatous hyperplasia were found microscopically in treated animals. At 25 weeks, 100% of the rats receiving methyl bromide continuously had hyperplastic lesions of the forestomach which were more severe than those at 13 weeks. Evidence of malignancy was seen in one rat and the lesion was considered a very early carcinoma. In the stop treatment group that received methyl bromide for 13 weeks, there was regression of the stomach lesions, but at the 12-week final sacrifice, adhesions, fibrosis, and mild acanthosis remained. This study illustrates the need for regression experiments for complex forestomach lesions in rodents, especially when an irritating chemical is given by gavage.

Influence of dietary zinc on di(2-ethylhexyl)phthalate-induced testicular atrophy and zinc depletion in adult rats

Groups of 48 adult male F344 rats were maintained on synthetic diets containing 20 ppm (normal), 2 ppm (low), or 200 ppm (high) zinc. After 1 week of acclimation to the various diets, groups of 12 rats from each dietary regimen were gavaged for 13 consecutive days with 0.0 (vehicle), 0.33, 1.0, or 3.0 g/kg di(2-ethylhexyl)phthalate (DEHP). These were selected as relatively nontoxic, mildly toxic, and moderately toxic doses for producing testicular injury in adult male rats. At termination on the 14th day, body weight gain was reduced by 3.0 g/kg DEHP dose in the normal and low-zinc diet groups but not in the high-zinc diet group. The low-zinc diet alone reduced body weight gain, independent of DEHP treatment. DEHP had no perceptible effects on the weights of testis, seminal vesicle, prostate, or epididymis from rats maintained on normal- or high-zinc diets, but reduced the weights of all of these organs from animals on the low-zinc diet in a dose-dependent manner. Lactate dehydrogenase activity, total and free sulfhydryl contents, and zinc concentrations in testes were also reduced, and testicular degeneration was induced by DEHP in the low-zinc diet groups. In contrast, dose-dependent liver enlargement and hypolipidemia (reduction of serum cholesterol and triglyceride concentrations) were produced by equivalent doses of DEHP in all of the three zinc groups. The selectively enhanced susceptibility of adult male F344 rats on a zinc deficient diet to the gonadotoxic effects of DEHP supports the hypothesis that testicular zinc depletion is causally related to the ensuing testicular and accessory sex organ atrophies. Other biological effects of DEHP (e.g., hypolipidemia, hepatomegaly) appear to occur independent of zinc homeostasis.

Application of Microencapsulation for Toxicology Studies: III. Bioavailability of Microencapsulated Cinnamaldehyde

The bioavailability of microencapsulated cinnamaldehyde (CNMA) was investigated in male F344 rats. Rats were gavaged with CNMA in corn oil using either microencapsulated or the neat chemical at doses of 50, 250, and 500 mg/kg. No differences between the two formulations at any of the doses were found in either CNMA blood concentration profiles or in the rate of urinary hippuric acid excretion. Both formulations showed a low bioavailability (< 20%) at 250 and 500 mg/kg. Regardless of the formulation used, oral gavage of CNMA significantly increased the urinary excretion of hippuric acid. About 75% of the dose of CNMA was metabolized to hippuric acid and recovered in the urine. The total amount of hippuric acid recovered in a 50-hr urinary collection correlated well with the CNMA dose. The data suggest that there was complete release of CNMA from the microcapsules and that microencapsulation of CNMA does not affect its bioavailability or its metabolism. Since CNMA microcapsules are stable in rodent diet, the microencapsulation of CNMA, and perhaps other labile chemicals, will prevent degradation and facilitate the testing of such compounds in toxicology studies.

Comparison of the toxicity of citral in F344 rats and B6C3F1 mice when administered by microencapsulation in feed or by corn-oil gavage

A study of the potential effects of microencapsulation on the toxicity of citral was conducted in 14-day continuous feeding studies with both sexes of F344 rats and B6C3F1 mice. Toxicity by the feeding route was compared with that from bolus doses of the neat chemical in corn oil administrated by gavage. Both sexes of rats and mice were given diet containing 0, 0.63, 1.25, 2.5, 5 and 10% citral microcapsules. These feed formulations were equivalent to daily doses of 0, 142, 285, 570, 1140 and 2280 mg citral/kg body weight for rats and 0, 534, 1068, 2137, 4275 and 8550 mg citral/kg body weight for mice. The daily gavage doses were 0, 570, 1140 and 2280 mg citral/kg body weight for both sexes of rats, and 0, 534, 1068 and 2137 mg citral/kg body weight for both sexes of mice. Citral microcapsules administered in the diet did not cause mortality in mice or rats. Toxicity was confined to decreases in body weight at the 10% concentration in mice, at the 5 and 10% concentrations in rats, and decreases in absolute weights of the liver, kidney and spleen at the 10% concentration in rats. The only histopathological change observed was minimal to mild hyperplasia and/or squamous metaplasia of the respiratory epithelium in the anterior portion of the nasal passages of rats fed 5 or 10% citral microcapsules. By contrast, citral gavage caused mortality in five out of five male and female mice at 2137 mg/kg body weight, and in two out of five male mice at 1068 mg/kg body weight. There were dose-related increases in absolute liver weights of male and female mice. Cytoplasmic vacuolization of hepatocytes occurred in all female mice gavaged with 1068 and 2137 mg citral/kg body weight, and in male mice from the 2137 mg/kg dose group. Necrosis, ulceration and/or acute inflammation of the forestomach occurred in the high-dose mice of both sexes. Inflammation and/or hyperplasia of the forestomach occurred in about half of the male and female mice dosed with 1068 mg citral/kg. Citral gavage at doses that were equivalent to up to 10% in the diet (2280 mg/kg body weight) did not cause toxicity in rats, except for minimal hyperplasia of the squamous epithelium of the forestomach in high-dose males.(ABSTRACT TRUNCATED AT 400 WORDS)

Application of Molecular Encapsulation for Toxicology Studies: Comparative Toxicity of p-Chloro-α,α,α-trifluorotoluene in α-Cyclodextrin Vehicle versus Corn Oil Vehicle in Male and Female Fischer 344 Rats and B6C3F1 Mice

Abstract The application of α-cyclodextrin (α-CD) as an alternative vehicle for water insoluble and volatile chemicals was investigated in toxicity studies of p -chloro-α,α,α-trifluorotoluene (CTFT). Groups of F344 rats and B6C3F1 mice of each sex were administered CTFT (97% pure) by gavage in either corn oil or α-CD aqueous formulations daily for 14 consecutive days. The dose levels used were 10 (mice only), 50, 400, and 1000 mg/kg for corn oil vehicle and 10, 50, and 400 mg/kg (maximum achievable dose at gavage volume of 5 ml/kg) for α-CD vehicle. With both vehicles CTFT and α 2u -globulin were found to accumulate in the male rat kidney after 14 days of exposure and a dose-related toxic nephropathy was observed at dose of 50 mg/kg or higher. The hepatocellular hypertrophy and cytoplasmic vacuolation of the adrenal cortex which appeared in dosed male and female rats were also found to be independent of vehicle. Clinical pathology findings suggested a mild anemia and cholestasis in rats. With both vehicles no tissue bioaccumulation of CTFT was found in male or female mice. Vehicle-independent hepatocellular hypertrophy and cholestasis were also observed in mice at doses of 400 and 1000 mg/kg. In conclusion, the α-CD vehicle does not affect the toxic responses of CTFT in both sexes of both species. The results of the studies suggest that α-CD may be an appropriate alternative vehicle for toxicity studies.

Application of molecular encapsulation for toxicology studies: Toxicokinetics of p-chloro-α,α,α-trifluorotoluene in α-cyclodextrin or corn oil vehicles in male F344 rats

Toxicokinetics of p-chloro-alpha,alpha,alpha-trifluorotoluene (CTFT) after administration as an aqueous alpha-cyclodextrin (alpha-CD) molecular encapsulation suspension (alpha-CD vehicle) or as a corn oil solution (corn oil vehicle) were compared. Male F344 rats were administered intragastrically CTFT in alpha-CD vehicle or corn oil vehicle at dose levels of 10, 50, or 400 mg/kg. Other male F344 rats were administered CTFT intravenously in a 10% Tween 80 aqueous solution. Serial blood samples were taken from a cannulated jugular vein for up to 52 hr after dosing and the CTFT concentrations in whole blood were determined by gas chromatography. The biological elimination half-life of CTFT from the center compartment was not affected by the vehicle used; however, absorption of CTFT from the alpha-CD vehicle was much faster than from the corn oil vehicle. The average absorption half-lives from the alpha-CD vehicle and corn oil vehicle were 17 and 98 min, respectively. Despite the differences in absorption, no statistical difference was observed in the calculated areas under the blood concentration versus time curves (AUC) obtained from rats dosed with either vehicle. Dose proportionality for CTFT was established up to 400 mg/kg and bioavailability was shown to be complete for both vehicles.

Molecular Encapsulator: A Novel Vehicle for Toxicology Studies

The use of a molecular encapsulator, α-cyclodextrin (α-CD), as a novel gavage dosing vehicle in toxicology studies was investigated. p-Chloro-α,α,α-trifluorotoluence (CTFT) was chosen as the test chemical. CTFT can be easily encapsulated at the molecular level using α-CD molecular encapsulator in aqueous solution. The resulting molecular-encapsulated CTFT precipitates can be suspended homogeneously in water and can be used as a gavage formulation. The stability and syringeability of this gavage formulation were evaluated prior to being used in a toxicology study. Comparative studies showed that the molecular encapsulator released CTFT more rapidly than conventional corn oil vehicle after gavage dosing to male F344 rats. The results of this study indicate that the molecular encapsulator can be used as an alternative gavage vehicle in toxicology studies of water-insoluble or volatile chemicals to avoid the potential side effects of corn oil vehicle. Procedures for the analysis of the molecular-encapsulated ...