Subacute and chronic action of acrylonitrile on adrenals and gastrointestinal tract: biochemical, functional and ultrastructural studies in the rat

Acrylonitrile induction of rodent neoplasia: Potential mechanism of action and relevance to humans

Acrylonitrile, an industrial chemical, is a multisite carcinogen in rats and mice, producing tumors in four tissues with barrier function, that is, brain, forestomach, Zymbal’s gland, and Harderian gland. To assess mechanism(s) of action (MoA) for induction of neoplasia and to evaluate whether the findings in rodents are indicative of human hazard, data on the potential key effects produced by acrylonitrile in the four rodent target tissues of carcinogenicity were evaluated. A notable finding was depletion of glutathione in various organs, including two target tissues, the brain, and forestomach, suggesting that this effect could be a critical initiating event. An additional combination of oxidative DNA damage and cytotoxic effects of acrylonitrile and its metabolites, cyanide, and 2-cyanoethylene oxide, could initiate pro-inflammatory signaling and sustained cell and tissue injury, leading to compensatory cell proliferation and neoplastic development. The in vivo DNA-binding and genotoxicity of acrylonitrile has been studied in several target tissues with no compelling positive results. Thus, while some mutagenic effects were reported in acrylonitrile-exposed rodents, data to determine whether this mutagenicity stems from direct DNA reactivity of acrylonitrile are insufficient. Accordingly, the induction of tumors in rodents is consistent primarily with a non-genotoxic MoA, although a contribution from weak mutagenicity cannot be ruled out. Mechanistic data to support conclusions regarding human hazard from acrylonitrile exposure is weak. Comparison of metabolism of acrylonitrile between rodents and humans provide little support for human hazard. Three of the tissues affected in bioassays (forestomach, Zymbal’s gland, and Harderian gland) are present only in rodents, while the brain is anatomically different between rodents and humans, diminishing relevance of tumor induction in these tissues to human hazard. Extensive epidemiological data has not revealed causation of human cancer by acrylonitrile.

Neoplasms in Rats Ingesting Acrylonitrile for Two Years

Male Sprague-Dawley rats ingested 0, 20 ppm, or 500 ppm of acrylonitrile in drinking water for 2 years. Rats receiving 500 ppm of acrylonitrile exhibited early mortality and retarded weight gain. Tumors of Zymbal's gland were associated in dose-response fashion with acrylonitrile exposure. Age-associated incidence of pituitary adenomas containing immunoreactive prolactin was decreased in acrylonitrile-treated rats. A decrease in pituitary tumor incidence also was observed in rats treated with low doses of acrylonitrile, suggesting that reduction in this tumor frequency was not because of early death. No increases were found in tumors of other organ systems, but a trend toward development of forestomach papillomas was noted in rats receiving the highest concentration of acrylonitrile.

Acetaminophen-Induced Forestomach Lesion in Normal Rats Following Intravenous Exposure

Four groups of ten male and ten female rats each were treated intravenously with saline, 400 mg/kg/day of a commercially available injectable acetaminophen formulation, or 400 mg/kg/day of a new injectable acetaminophen formulation with (aged) or without (fresh) impurities daily for fourteen days. Gross observations of the mucosal surface of the stomachs from treated rats included multifocal to diffuse pale, elevated foci confined to the nonglandular region of the stomach. Treatment-related histologic observations consisted of epithelial hyperplasia and hyperkeratosis of the nonglandular mucosa of the stomach. The epithelial hyperplasia was characterized by a thickened epithelium, frequently accompanied by the development of undulations at the basement membrane zone, resulting in the formation of rete ridgelike structures protruding into the underlying tissue. The submucosa was usually expanded by edema and occasionally contained an infiltrate of neutrophils, eosinophils, and macrophages. The hyperplasia was usually accompanied by hyperkeratosis resulting in thickening of the stratum corneum. The incidence and severity of the gastric changes were similar across all treatment regimens. Although considered clinically irrelevant since humans do not have a forestomach equivalent, these results are significant in that this appears to be the first report of forestomach hyperplasia and hyperkeratosis following intravenous exposure to acetaminophen.

Facing the key workplace challenge: assessing and preventing exposure to nanoparticles at source

Nanomaterials present new challenges to understanding, predicting, and managing potential health risks in occupational environments. In this study, we characterize the key physical processes related to formation and growth of nanoparticles. The main focus is on various occupational environments, as these are known to be major environments with nanoparticles in indoor air. The protection of people potentially to be exposed to nanoparticles is one of the key issues in terms of risk assessment and prevention. Two of the main protection techniques that are discussed and characterized are ventilation and filtration, which are widely used in practical applications.

Derivation of noncancer reference values for acrylonitrile

Dose-response assessments were conducted for the noncancer effects of acrylonitrile (AN) for the purposes of deriving subchronic and chronic oral reference dose (RfD) and inhalation reference concentration (RfC) values. Based upon an evaluation of available toxicity data, the irritation and neurological effects of AN were determined to be appropriate bases for deriving reference values. A PBPK model, which describes the toxicokinetics of AN and its metabolite 2-cyanoethylene oxide (CEO) in both rats and humans, was used to assess the dose-response data in terms of an internal dose measure for the oral RfD values, but could not be used in deriving the inhalation RfC values. Benchmark dose (BMD) methods were used to derive all reference values. Where sufficient information was available, data-derived uncertainty factors were applied to the points of departure determined by BMD methods. From this assessment, subchronic and chronic oral RfD values of 0.5 and 0.05 mg/kg/day, respectively, were derived. Similarly, subchronic and chronic inhalation RfC values of 0.1 and 0.06 mg/m(3), respectively, were derived. Confidence in the reference values derived for AN was considered to be medium to high, based upon a consideration of the confidence in the key studies, the toxicity database, dosimetry, and dose-response modeling.

Molecular evidences on the benefit of N-acetylcysteine in experimental colitis

Inflammatory bowel disease (IBD) is a chronic recurrent disease of the digestive tract with an unknown etiology. The aim of this study was to examine the possible protective effects of N-acetylcysteine (NAC) in the mouse model of IBD by measuring specific biomarkers in the colon cells. Colitis was induced by administration of dextran sodium sulfate (DSS) in drinking water (3%) for 7 days. Three doses of NAC (106, 160, and 240 mg/kg) were given after induction of colitis (4 days post DSS) for 4 days by gavage. Lipid peroxides (LP), total antioxidant power (TAP), total thiol molecules (TTM), tumor necrosis factor-α (TNF-α), nitric oxide (NO), superoxide dismutase (SOD), and catalase (CAT) were measured in the colon homogenate of the treated animals. NAC (160 and 240 mg/kg) significantly decreased LP, TNF-α, NO and increased TTM, SOD, and CAT. The TAP was also increased by NAC (240 mg/kg). It is concluded that moderate to high doses of NAC improves cellular biomarkers of IBD in mice. Further studies should be trialled in humans suffering from two common inflammatory bowel disease called ulcerative colitis and Crohn’s disease.

Chronic toxicity and oncogenic dose-response effects of lifetime oral acrylonitrile exposure to Fischer 344 rats

Acrylonitrile (AN) was administered in the drinking water for approximately 2 years to groups of 100 male and 100 female Fischer 344 rats at nominal concentrations of 1, 3, 10, 30, and 100 ppm. Two groups, each of 100 males and 100 females, were used as untreated controls. Average daily intake was 0.1, 0.3, 0.8, 2.5 or 8.4 mg AN per kg body weight per day, respectively, for treated male rats and 0.1, 0.4, 1.3, 3.7, or 10.9 mg AN per kg per body weight per day, respectively, for dosed females. Clinical biochemistry, interim necropsies, organ weights and microscopic evaluation of tissues and organs were performed on groups of ten rats per sex per group at months 6, 12, and 18 and at study termination. Females were sacrificed in the 24th month and males were terminated after 26 months of dosing. A consistent decrease in survival, lower body weight and reduced water intake, as well as small reductions in hematological parameters, were observed in both sexes of the 100 ppm group. Elevated numbers of early deaths were observed in groups of males receiving 10 ppm AN and females receiving 30 ppm AN. Organ:body weight ratios at various study intervals were consistently elevated in the high dose group and likely were related to lower body weights. At these same intervals, mean absolute weights were either comparable to controls or only slightly elevated and few changes in weight ratios were seen when organ weights were compared with brain weights. No biochemical changes suggested a treatment-related effect. An increase in urine specific gravity in 100 ppm male rats was reflective of a decrease in liquid intake at this level. The only significant non-neoplastic finding observed histologically was a dose-related increase in hyperplasia/hyperkeratosis in squamous cells of the forestomach in male and female rats given 3 ppm and higher AN. This observation correlated with the induction of treatment-related squamous cell tumors (papillomas and carcinomas) of the forestomach seen primarily in rats at 3 ppm AN and higher. Mammary gland carcinomas were observed only in female groups. Both sexes given 10 ppm AN or more in their drinking water for their lifetime had astrocytomas of the brain/spinal cord and adenomas/carcinomas of the Zymbal's gland.

Comparative chronic toxicity and carcinogenicity of acrylonitrile by drinking water and oral intubation to Spartan Sprague-Dawley rats

Groups of 100 male and 100 female Spartan Sprague-Dawley rats were administered lifetime oral doses of Acrylonitrile (AN) by one of two routes of dosing, either at 0.1 or 10 mg/kg per day, 7 day per week by intubation or continually at 1 or 100 ppm AN in their drinking water. The doses selected were designed to approximate the same daily intake of AN in each of two separate studies, whether by a single bolus dose (intubation) or a more continuous dosing regimen in drinking water. Each study had its own untreated control group of 100 rats per sex. In the drinking water study, the equivalent mean dosage of AN administered to males and females were 0, 0.09, and 0.15 mg/kg per day, respectively, at the 1 ppm level, and 0, 8.0 and 10.7 mg/kg per day, respectively, for 100 ppm dose groups. In both studies, groups of ten rats per sex were sacrificed at 6, 12 and 18 months and at study term. Ophthalmoscopic, hematological, clinical biochemistry, urinalysis and full histopathological exams were performed on control and high dose groups of rats in each study. Similar tests were done in lower dose groups, as required, to define dose-responses of observed effects. All animals were necropsied and underwent microscopic examination of target tissues, including brain, ear canal, stomach, spinal cord and any observable tissue masses. High dose male and female rats in both studies exhibited statistically decreased body weights. Food consumption and water intake were reduced only in the drinking water study. Due to increased deaths in groups of high dose rats of both studies receiving AN, all intubation test groups were terminated after 20 months of treatment. Surviving males and females in the drinking water study were terminated after 22 and 19 months, respectively. Small, sometimes statistically significant, reductions in hemoglobin, hematocrit and erythrocyte count were observed in male and female rats in both high dose (10 mg/kg per day intubation and 100 ppm drinking water) groups from both studies. There were increases in absolute or relative organ weight ratios for liver and adrenal in the high dose intubation study groups, but could not be correlated with AN toxicity in the absence of adverse clinical biochemistry or microscopic findings. Similar organ weight findings were not observed in the drinking water study. Again, there were no changes in clinical biochemistry or microscopic findings in these tissues. Absolute kidney weights were increased in high dose male and female rats in the intubation study and high dose female rats only in the drinking water study. Male and female rats from high dose groups in each study had a higher incidence of palpable masses of the head and the nonglandular stomach and, in females only, the mammary region. In both sexes, treatment-related tumors of the central nervous system (brain, spinal cord), ear canal, and gastrointestinal tract, and in females only, the mammary gland (intubation only) were observed in rats administered either 10 mg/kg per day by intubation or 100 ppm in drinking water. Animals from the intubation study had a substantially higher incidence of AN-related site-specific tumors than did their drinking water study counterparts. While a similar spectrum of tumors was produced by both oral dosing regimens, there were some notable differences in organ-specific incidence of tumors. Astrocytomas of the brain and spinal cord were found at a higher incidence in those rats exposed continuously to AN administered in the drinking water versus bolus dosing by intubation. Conversely, a higher incidence of squamous cell carcinomas/papillomas of the forestomach and adenocarcinomas of the intestine and, in females only, carcinomas of the mammary gland were observed in high dose rats receiving AN by intubation. An increase in the degree of severity of forestomach hyperplasia was observed in all high dose groups of animals, irrespective of mode of administration. These effects were more pronounced, were correlated with a much higher incidence of forestomach tumors, and were identified earlier (12 months) in the intubation study in which there was direct tissue contact with a more concentrated AN solution. Elevations in epidermal cysts in high dose males and females in the intubation study and renal hyperplasia in high dose animals of both sexes in both studies may have a treatment relationship. All other clinical and microscopic findings were considered unremarkable. There were no discernable non-neoplastic effects attributable to treatment in groups of low dose male and female rats given AN by intubation at 0.1 mg/kg per day or 1 ppm in drinking water. The results of this study indicate a consistent spectrum of neoplastic and non-neoplastic effects produced by AN in the same rat strain, whether administered orally by bolus or by continuous dosing in the drinking water. While the spectrum of tumors and target organ toxicity produced was similar, bolus dosing clearly increased tumors associated with the gastrointestinal tract. Neoplasms found in several other tissues were most prominently displayed in groups of more continuously dosed rats.

Effects of drugs on pituitary fine structure in laboratory animals

Although an increasing number of chemicals are reported to affect endocrine glands, only a few studies are dealing with their toxic effect on pituitary. The drugs can induce lesions acting directly on endocrine cells or indirectly by interfering with the regulation of their endocrine activities. Some drugs stimulate pituitary cell proliferation leading to hyperplasia and tumor formation; other chemicals have an inhibitory effect on adenohypophysial cells; and only one drug, hexadimethrine bromide, has been found to induce pituitary necrosis. Although complex toxicologic studies have been carried out on many chemicals, the mechanism of action of most drugs is not completely elucidated and further studies are necessary to establish structure function correlations.

Adrenal gland: chemically induced structural and functional changes in the cortex

The adrenal cortex is the target of a surprisingly large number of exogenous chemicals. Until recently, the toxic action of these chemicals was discovered serendipitously. Following our observations that acrylonitrile, cysteamine or pyrazole induces hemorrhagic adrenocortical necrosis in the rat, we recently recognized a structure-activity correlation which predicts the adrenocorticolytic property of alkyl chemicals, i.e., 2-3 carbons with double or triple bonds and with nucleophilic terminal radicals (e.g., -CN, -SH, -NH2). On the basis of our results obtained with electron microscopic, histochemical and biochemical studies as well as those of others, we propose the following sequence of events in the pathogenesis of chemically induced adrenocortical necrosis: 1) Depletion of glutathione and increased dopamine concentration in the adrenals; 2) Endothelial damage and rupture of capillary walls in the adrenal cortex due to either direct attack by the chemicals (metabolites) and/or released monoamines; 3) Retrograde embolization of medullary tissue fragments into the cortical capillaries; 4) Enhanced destruction of cortical vascular walls with subsequent platelet aggregation, fibrin deposition which is often associated with a systemic drop in platelet counts, and changes in blood coagulation; 5) Escape of plasma and cellular elements of blood into extravascular spaces and damage of adrenocortical parenchymal cells; and 6) Hemorrhage and necrosis in the adrenal cortex. This pathogenetic sequence was investigated in detail with acrylonitrile, and studied in various aspects with thioguanine, cysteamine and pyrazole.

Time-course studies of the distribution of [1-14C]acrylonitrile in rats after intravenous administration

Intravenous injection of acrylonitrile (ACN) causes adrenal hemorrhagic necrosis. ACN and its metabolites react with glutathione and bind covalently with macromolecules. Hence the purpose of this investigation was to measure the distribution and covalent binding of radiolabel derived from [1-14C]ACN in order to determine whether binding of ACN or its metabolites may be implicated in the pathogenesis of ACN-induced adrenal injury. Following intravenous injections of ACN, concentrations of total radiolabel were highest in the blood, liver, duodenum, kidneys, and adrenals. Except for blood, there was a time-dependent decrease in total radiolabel in these tissues. Compared with other major organ systems, the levels of covalently bound radiolabel were lower in the adrenal glands. These results do not support a role of covalent binding of ACN or its metabolites in the adrenal toxicity of ACN, but suggest that the initial high concentrations of total radiolabelled compounds derived from ACN could play a role in the action of ACN on the adrenal glands.