Tipton R. Tyler

Chronic toxicity and oncogenicity inhalation study with vinyl acetate in the rat and mouse.

Vinyl acetate was evaluated for chronic toxicity and oncogenicity in male and female rats and mice in a 104-week study. Target concentrations were 0, 50, 200, and 600 ppm. The study included interim terminations at approximately 53 and 83 weeks and a group whose exposure was terminated at 70 weeks and allowed a 15-week recovery period. Over the course of the exposures, body weight gain was consistently depressed in all 600 ppm groups and in the 200 ppm mice. Except for female rats of the 600 ppm exposure group, recovery animals showed significant improvements in weight gain relative to controls. There were no changes in hematological parameters of either species that could be unequivocally related to treatment. The only effect noted on clinical chemical parameters during the study were decreases in blood glucose in the 600 ppm females. There were no adverse effects on survival in either species. Increases in lung weight were noted in rats and mice primarily in the 600 ppm groups. These changes were associated with bronchial exfoliation, macrophage accumulation, and fibrous plaques and buds extending into the airway lumen, and bronchial/bronchiolar epithelial disorganization. The most significant histopathological changes were noted in the nasal cavity. In the olfactory epithelium of both rats and mice, the main nonneoplastic changes included epithelial atrophy, regenerative effects (squamous metaplasia and respiratory metaplasia of olfactory epithelium), basal cell hyperplasia, and epithelial nest-like infolds. No nonneoplastic changes were observed in the respiratory epithelium of rats, while squamous metaplasia at the naso/maxilloturbinate region was prevalent in mice. Nonneoplastic changes were similar in the recovery groups. Oncogenic responses to vinyl acetate exposure were mainly confined to the nasal cavity in rats and included endo- and exophytic papillomas, squamous cell carcinoma, carcinoma in situ in olfactory regions, and endophytic papilloma in respiratory regions. Squamous cell carcinomas were also found either in areas normally covered by cuboidal epithelium or areas of unknown origin. One squamous cell carcinoma was found in the larynx of a rat of the 600 ppm groups. One squamous cell carcinoma was found in the lung of a mouse of the 600 ppm group.(ABSTRACT TRUNCATED AT 400 WORDS)

Two-Week Aerosol Inhalation Study on Polyethylene Glycol (Peg) 3350 in F-344 Rats

PEGs in the 3000 to 4000 MW range are used in many pharmaceutical and cosmetic applications; they produce little ocular or dermal irritation and have extremely low acute and subchronic toxicity by oral and dermal routes of administration. However, little information exists on the potential of aerosols of these materials to produce adverse health effects. F-344 rats were exposed to aerosols of PEG 3350 (20% w:w in water) at 0, 109, 567, or 1008 (highest attainable) mg/m3 for 6 hr/d, 5 d/wk for 2 wk. No exposure-related toxicity was found with regard to clinical signs, ophthalmology, serum chemistry, urinalysis, or gross pathology. Exposure-related effects included: a 50% increase in the neutrophil count (males only) at 1008 mg/m3; decreased body weight gain (16%) for both the 567 and 1008 mg/m3 groups (males only); absolute lung weights of both sexes were increased 10 and 18% for the 567 and 1008 mg/m3 groups, respectively. A slight increase in the number of macrophages in the alveoli was the only change observed histologically in all PEG 3350-exposed groups. Therefore, inhalation of aerosols of PEG 3350 at concentrations up to 1008 mg/m3 produced relatively little toxicity in rats, the lung was the target organ, and the no-observable-effect-level was between 109 to 567 mg/m3.

Chronic Toxicity and Oncogenicity Study with Vinyl Acetate in the Rat: In Utero Exposure in Drinking Water

The purpose of this study was to evaluate vinyl acetate for potential chronic toxicity and oncogenicity when given to rats in drinking water from the time of gestation. Target concentrations were 0, 200, 1000, and 5000 ppm (v/v). Drinking water solutions were prepared daily and analyzed at approximately 4-week intervals. F0 rats were given solutions of vinyl acetate for 10 weeks and then mated. Offspring (F1 rats) were culled to equal group sizes of 60 main study rats and 30 rats for satellite groups. F1 rats were treated for up to 104 weeks with interim kills of satellite groups at 52 and 78 weeks. Body weights and clinical signs of toxicity were monitored in F0 and F1 rats. Food and water consumption were measured in F1 rats. At Weeks 52 and 78 of the test, clinical pathology and urine analysis examinations were conducted on 10 rats per group from satellite animals. A complete gross and histopathological examination of F1 rats was conducted at the interim kills and on main study rats at Week 104. Average vinyl acetate consumption over the course of the study in male rats of the 200, 1000, and 5000 ppm groups was 10, 47, and 202 mg/kg/day, respectively. Female rats consumed an average of 16, 76, and 302 mg/kg/day, respectively. Compound-related effects observed during the study included a concentration-related decrease in water consumption among rats of the 1000 and 5000 ppm groups and a decrease in food consumption among rats of the 5000 ppm groups. Concurrent body weight decrement was observed only in the 5000 ppm groups.(ABSTRACT TRUNCATED AT 250 WORDS)

Developmental Toxicity Evaluation of Inhaled 2–Ethoxyethanol Acetate in Ficher 344 Rats and New Zealand White Rabbits

Pregnant Fischer 344 rats and New Zealand white rabbits were exposed to 2-ethoxyethanol acetate (EEA; CAS No. 111-15-9) vapor by inhalation on Gestational Days 6 through 15 (rats) or 6 through 18 (rabbits) at concentrations of 0, 50, 100, 200, or 300 ppm, 6 hr/day. The animals were terminated on Gestational Day 21 (rats) or 29 (rabbits) and fetuses were examined for external, visceral, and skeletal malformations and variations. In rabbits, exposure to 100-300 ppm resulted in maternal toxicity: decreased weight gain at 100-300 ppm, clinical signs at 200-300 ppm, alterations in hematology at 100-300 ppm, reduced gravid uterine weight at termination at 200-300 ppm, and elevated absolute liver weight at 300 ppm. Developmental toxicity was observed at 100-300 ppm: an increased incidence of totally resorbed litters at 200-300 ppm, an increase in nonviable fetuses at 300 ppm, and a decrease in viable implants (live fetuses) per litter at 200-300 ppm. The incidence of fetal malformations (external, visceral, and skeletal) was increased at 200-300 ppm. The incidence of total malformations was 100% at 300 ppm and significantly increased at 200 ppm. Reduced fetal ossification was observed at 100-300 ppm. In rats, exposure to 100-300 ppm also resulted in maternal toxicity: reduced weight gain and reduced food consumption at 200-300 ppm and elevated relative liver weight and alterations in hematology at 100-300 ppm. Absolute maternal liver weight was increased at all EEA exposure concentrations; relative liver weight was increased at 100-300 ppm. Developmental toxicity was observed at 100-300 ppm: increased nonviable implantations/litter (300 ppm), reduced fetal body weight/litter (200-300 ppm), and increased incidence of external (300 ppm), visceral, and skeletal (100-300 ppm) variations indicative of toxicity. The incidence of visceral, skeletal, and total malformations was increased at 200-300 ppm. In conclusion, in both species, inhalation exposure to EEA during organogenesis produced maternal toxicity at 100-300 ppm and developmental toxicity at 100-300 ppm, including teratogenicity at 200-300 ppm. At 50 ppm in both species, there was no evidence of maternal or developmental toxicity, including teratogenicity.

Evaluation of subchronic toxicity of n-butyl acetate vapor

The subchronic toxicity of n-butyl acetate (nBA), a common industrial solvent, was tested in rats in a 13-week inhalation study. Male and female Sprague-Dawley (SD) rats were exposed to concentrations of 0, 500, 1500 or 3000 ppm nBA for 6 h per day, 5 days per week for 13 consecutive weeks. Transient signs of sedation were observed only during exposure to the 1500 and 3000 ppm concentrations. Body weights for the 1500 and 3000 ppm groups were significantly reduced. Feed consumption values for the 1500 and 3000 ppm groups were significantly lower than the control group. Weights of the liver, kidneys and spleen were significantly lower for the 3000 ppm male group; testes and adrenal gland weights for the 1500 and 3000 ppm groups and the lung weight for the 3000 ppm male group were significantly higher than for the control group. Signs of irritation of the glandular stomach and necrosis in the non-glandular stomach were observed in 3000 ppm female rats. Degeneration of the olfactory epithelium along the dorsal medial meatus and ethmoturbinates of the nasal passages of some 1500 and all 3000 ppm rats was also seen. The severity was mild to moderate for the 3000 ppm group and minimal to mild for the 1500 ppm group. No effects were observed in the lungs of any group. The no-observed-effect level (NOEL) for this study is considered to be 500 ppm. The data presented here are relevant to the toxicity risk assessment of n-butanol due to the rapid hydrolysis of nBA in vivo.

Isopropanol 13-Week Vapor Inhalation Study in Rats and Mice with Neurotoxicity Evaluation in Rats

This study was conducted to evaluate the possible subchronic toxicity as well as neurobehavioral effects of isopropanol, a widely used industrial and commercial solvent. Five groups, each containing 10 Fischer 344 rats/sex and 10 CD-1 mice/sex, were exposed for 6 hr/day, 5 days/week, for 13 weeks to isopropanol vapor at concentrations of 0 (control), 100, 500, 1500, or 5000 ppm. An additional 15 rats/sex were assigned to the 0, 500, 1500, and 5000 ppm groups for assessment of neurobehavioral function. No exposure-related mortalities occurred during the study. The narcotic effects of isopropanol were noted only during exposures at 1500 and 5000 ppm. These signs, noted during exposures, were typically absent following exposures. The only clinical signs observed following exposures included swollen periocular tissue, perinasal encrustation, and ataxia for rats of the 5000 ppm group. Neurobehavioral evaluations indicated no changes in any of the parameters of the functional observational battery; however, increased motor activity for female rats in the 5000 ppm group was noted at Weeks 9 and 13. Decreases in body weight and body weight gain were observed for rats of the 5000 ppm group at the end of the first week of exposure. During the remaining weeks, increases in body weight and/or body weight gain were observed for rats of the 1500 and 5000 ppm groups. No exposure-related effects on body weight were noted for male mice; however, increased body weight and body weight gain were observed for female mice of the 5000 ppm group.(ABSTRACT TRUNCATED AT 250 WORDS)

Motor activity effects in female Fischer 344 rats exposed to isopropanol for 90 days

In a previous subchronic neurotoxicity study, increases in motor activity were observed for female rats after 9 and 13 weeks of exposure to 5000 ppm of isopropanol vapor.1 The present study was conducted to evaluate the reproducibility of these effects and, if reproducible, to assess the potential for reversibility following cessation of exposure. Two groups, each containing 30 female Fischer 344 rats, were exposed to concentrations of zero (control) and 5000 ppm of isopropanol vapor for 6 h per day, 5 days per week. Fifteen of the animals in the control and 5000 ppm groups were exposed for 9 weeks (designated as the 9‐week subgroup), while the other 15 animals in each group were exposed for 13 weeks (designated as the 13‐week subgroup). Motor activity was assessed for both subgroups prior to exposure and following 4, 7 and 9 weeks of exposure. Motor activity was also measured for rats in the 13‐week subgroup following 11 and 13 weeks of exposure. These motor activity measurements were made 18–20 h following the end of the last exposure for that week. In addition, to evaluate the reversibility of motor activity effects, measurements were made on three occasions during the week following the final exposure for rats in both the 9‐week and 13‐week subgroups and weekly thereafter for five additional weeks for rats in the 13‐week subgroup. Increases in cumulative test session motor activity counts were observed following 4, 7 and 9 weeks of exposure for rats in the 9‐week subgroup. Increases in cumulative test session motor activity counts were also observed following 4, 7, 9, 11 and 13 weeks of exposure for rats in the 13‐week subgroup. Reversibility of this effect was observed for rats in the 9‐week subgroup within 2 days following the last exposure. Reversibility was also noted for rats in the 13‐week subgroup but not until Study Week 15 (2 weeks following the last exposure). Minor changes were observed in the shape of the motor activity habituation curves for isopropanol‐exposed animals in the 9‐week and 13‐week subgroups at ca. 50% of the measurement intervals beginning at Study Week 4. While most of these statistical changes were observed in conjunction with increases in cumulative test session motor activity, some were observed following time points where recovery of the cumulative test session motor activity counts had occurred. No change in the shape of the motor activity habituation curve was observed at 42 days following the last exposure, indicating that complete recovery of motor activity effects had occurred. Thus, repeated exposure of female rats to 5000 ppm of isopropanol produced reversible increases in motor activity.

Pulmonary Fibrosis Produced in F-344 Rats by Subchronic Inhalation of Aerosols of a 4000 Molecular Weight Ethylene Oxide/Propylene Oxide Polymer

Inhalation of aerosols of the ethylene oxide/propylene oxide polymer (U-5100) evaluated in this study has previously been shown in acute and 2-week studies to produce toxicologic effects on the lungs, with increased lung weights and microscopic findings of congestion and hemorrhage of pulmonary alveolar capillaries and necrosis of alveolar epithelial cells (D. R. Klonne, D.J. Nachreiner, D. E. Dodd, P. E. Losco, and T.R. Tyler, 1987, Fundam. Appl. Toxicol. 9, 773-784). In the present studies, F-344 rats were exposed 6 hr/day, 5 day/week for 2 weeks to aerosols at mean concentrations of 0, 0.9, or 5.0 mg/m3 or for 13 weeks to mean concentrations of 0, 0.3, 1.1, or 5.2 mg/m3. Following the 2-week study, minimal multifocal hemorrhage and eosinophilic proteinaceous debris in alveoli were observed in the 0.9 mg/m3 group; similar lesions plus alveolar cell necrosis were found in the 5 mg/m3 group. In the 13-week study, the 5.2 mg/m3 group had a slight decrease in body weight gain, while increases in absolute and/or relative lung weights occurred for both the 1.1 and 5.2 mg/m3 groups at the end of the exposure regimen and at the end of a 5-week recovery period. Histologic lesions of the lungs occurred in all U-5100-exposed groups and consisted of hemorrhage, alveolar histocytosis, interstitial pneumonia, and multifocal fibrosis. The incidence and severity of the pulmonary lesions were concentration related.(ABSTRACT TRUNCATED AT 250 WORDS)

Disposition and Pharmacokinetics of Isopropanol in F-344 Rats and B6C3F1 Mice,

The absorption, metabolism, disposition, and excretion of isopropanol (IPA) were studied in male and female rats and mice. Animals were exposed by i.v. (300 mg/kg) and inhalation (500 and 5000 ppm for 6 hr) routes; additionally, IPA was given by gavage to rats only in single and multiple 300 and 3000 mg/kg doses. In the rat approximately 81-89% of the administered dose was exhaled (as acetone, CO2, and unmetabolized IPA); approximately 76% of the dose in mice was exhaled after i.v. bolus but 92% was exhaled following inhalation. Approximately 3-8% of the administered dose was excreted in urine as IPA, acetone, and a metabolite tentatively identified as isopropyl glucuronic acid. Small amounts of radiolabel were found in feces and in the carcass. There were no major differences in the rates or routes of excretion observed either between sexes or between routes of administration. Additionally, repeated exposure had no effect on excretion. However, both the route of administration and the exposure or dose level influenced the form in which material was exhaled. Following exposure to 5000 ppm, a greater percentage of unmetabolized IPA was recovered in the expired air than following exposure to 500 ppm, implying saturation of metabolism.

Acute and 2-Week Inhalation Toxicity Studies on Aerosols of Selected Ethylene Oxide/Propylene Oxide Polymers in Rats

The ethylene oxide/propylene oxide (EO/PO) polymers evaluated in this study have previously been shown to have a low order of toxicity and/or irritancy by ocular, dermal, or oral routes of administration. These studies evaluated the acute inhalation toxicity of respirable aerosols of three EO/PO compounds (U-660, U-2000, and U-5100) that differ in chain length, molecular weight, and viscosity. The respective 4-hr LC50 values (95% confidence limits) for U-660, U-2000, and U-5100 in Wistar albino rats were 4670 (4090-5320), 330 (227-480), and 106 (45-245) mg/m3. Occasionally, slight increases in respiration rate and slight hyperactivity were observed during the postexposure period. All deaths were delayed for 2-5 days postexposure. Body weight gains were transiently depressed in rats exposed to U-2000 and U-5100. Discolored lungs and livers occurred in animals which died during the 14-day postexposure period. Subsequently, a repeated-exposure study was conducted on U-5100 in F-344 rats exposed for 6 hr/day, 5 days/week, for 9 exposures at mean concentrations of 0, 5, 26, and 50 mg/m3. Portions of the control and 50 mg/m3 groups were maintained for an additional 2-week recovery period. Exposure-related effects included transient urogenital wetness in 50 mg/m3 group females; decreased body weight gain (7-29%) in all U-5100 groups except the 5 mg/m3 group females; increases in absolute (17-52%) and relative lung weights in all U-5100 groups; macroscopic red foci in the lungs; and microscopic findings of congestion and hemorrhage of pulmonary alveolar capillaries and necrosis of alveolar epithelial cells. Lung weights remained elevated after the 2-week recovery period, but the severity of the microscopic lesions was noticeably less, indicating partial reversibility of the lesions. In conclusion, EO/PO polymers have a higher order of toxicity by inhalation in comparison to other routes of administration, vary considerably in their acute lethal toxicity as a function of chain length/molecular weight, and induce pulmonary hemorrhage, and possibly edema, following repeated aerosol exposures at concentrations as low as 5 mg/m3.