Measurement of genotoxic activity in multiple tissues following inhalation exposure to dimethylnitrosamine

Genetic toxicity assessment using liver cell models: past, present, and future

Genotoxic compounds may be detoxified to non-genotoxic metabolites while many pro-carcinogens require metabolic activation to exert their genotoxicity in vivo. Standard genotoxicity assays were developed and utilized for risk assessment for over 40 years. Most of these assays are conducted in metabolically incompetent rodent or human cell lines. Deficient in normal metabolism and relying on exogenous metabolic activation systems, the current in vitro genotoxicity assays often have yielded high false positive rates, which trigger unnecessary and costly in vivo studies. Metabolically active cells such as hepatocytes have been recognized as a promising cell model in predicting genotoxicity of carcinogens in vivo. In recent years, significant advances in tissue culture and biological technologies provided new opportunities for using hepatocytes in genetic toxicology. This review encompasses published studies (both in vitro and in vivo) using hepatocytes for genotoxicity assessment. Findings from both standard and newly developed genotoxicity assays are summarized. Various liver cell models used for genotoxicity assessment are described, including the potential application of advanced liver cell models such as 3D spheroids, organoids, and engineered hepatocytes. An integrated strategy, that includes the use of human-based cells with enhanced biological relevance and throughput, and applying the quantitative analysis of data, may provide an approach for future genotoxicity risk assessment.

Use of nasal cells in micronucleus assays and other genotoxicity studies

Genotoxicity experiments with exfoliated nasal mucosa cells are a promising minimally invasive approach for the detection of DNA-damaging compounds in ambient air. Results of single cell gel electrophoresis (SCGE) assays with individual cells and organ cultures from bioptic material show that DNA damage caused by compounds such as nitrosamines, polycyclic aromatic hydrocarbons and pesticides can be detected. Biochemical studies indicate that enzymes involved in the metabolism of environmental mutagens are represented in nasal cells. Several protocols for experiments with nasal cells have been developed and it was shown that formaldehyde, metals, styrene and crystalline silica induce DNA damage in SCGE and/or in micronucleus studies; furthermore, it was also found that polluted urban air causes DNA instability in nasal epithelial cells. Comparisons of these data with results obtained in lymphocytes and buccal cells indicate that nasal cells are in general equally sensitive. Broad variations in the baseline levels, differences of results obtained in various studies as well as the lack of information concerning the impact of confounding factors on the outcome of experiments with these cells indicate the need for further standardisation of the experimental protocols.

A classification framework and practical guidance for establishing a mode of action for chemical carcinogens

The recently released U.S. Environmental Protection Agency (U.S. EPA) Supplemental Guidance for Assessing Risk from Early Life Exposure to Carcinogens (SGAC) provides guidance to account for potential increased early life susceptibility to carcinogens that are acting via a mutagenic mode of action. While determination of the mode of carcinogenic action is central to the SGAC procedures and other regulatory risk assessments, little guidance is given as to the approaches, criteria, and nature of the evidence required to define a mutagenic mode of action. The purpose of this paper is to provide a framework along with practical guidance for the process of assigning a mode of action. Strengths, weaknesses, reliability, and choice of a test battery are discussed for select bacterial, cell culture, whole animal and human cell assays. Common confounding factors of induced pathology, cytolethality, and regenerative cell proliferation in rodent cancer bioassays are discussed along with approaches to account for these effects in assigning a mode of action and in risk assessments. Specific examples are given to illustrate the complexity in generating a data set sufficient to move from the default regulatory position of assuming a genotoxic mode of action to actually assigning a nongenotoxic mode of action. A two-part framework is proposed for assigning a mode of action. First, a weight of evidence approach is used to assess mutagenic potential based on results of genetic toxicology test systems. Second, a descriptor is assigned to classify the degree to which mutagenic activity likely played a role in the mode of action of tumor formation. This option provides a more realistic way of describing the mode of action instead of being bound by the strict genotoxic vs. nongenotoxic choices.

DNA damage in the nasal passageway: a literature review

The purpose of this review is to provide a compilation of work examining DNA damage in the nasal cavity. There are numerous methods to identify and quantify damage to DNA and the diversity of methods and toxicologic endpoints is illustrated by the range of studies presented here. There are a large number of independent studies measuring endpoints in the upper respiratory tract; however, with regard to toxicant induced DNA damage in the nasal passageway, the effects of two compounds, 4-(N-Methyl-N-nitrosamino)-1-(3-pyridyl)-1-butanone (NNK) and formaldehyde (HCHO), appear to have been extensively characterized. The body of work on NNK and formaldehyde have provided insights into molecular mechanisms of DNA damage and repair and induced cell replication and its relationship to nasal cancer. With new technologies and molecular techniques, the sensitivity to enable evaluations of the minute quantities of nasal tissue available in test species and human biopsy impact the study of the nasal-toxicant interactions. As methods used to characterize DNA damage increase in sensitivity, the importance of both exogenous and endogenous sources of DNA damage, steady-state levels of cellular damage, repair, and resulting mutations, low-dose exposure assessments and inter-species extrapolation will become increasingly complex. Additional studies of DNA damage in the nasal passage will undoubtedly challenge future estimations of risk and impact what are perceived to be acceptable levels of exposure to known and predicted carcinogens. The aim of this paper is to provide to the interested scientist literature relevant to the effects of agents on nasal DNA, so that areas of insufficient information can be identified and used to further develop and expand the knowledge base for nasal DNA toxicant interactions.

Investigations of the genotoxicity and cell proliferative activity of dichlorvos in mouse forestomach

This study investigated the possible mechanism by which dichlorvos may have caused forestomach tumours in mice in a chronic corn oil gavage cancer bioassay [NTP (1989) Toxicology and carcinogenesis studies of dichlorvos in F344/N rats and B6C3F1 mice (gavage studies). National Toxicology Program Technical Report 342, NIH Publ. No 89-2598]. For this purpose, a method has been developed to assess the genotoxicity of irritant substances on mouse forestomach epithelium. Groups of five B6C3F1 mice were given a single oral dose of dichlorvos, the genotoxic forestomach carcinogen 1-methyl-3-nitro-1-nitrosoguanidine (MNNG) or the irritant, non-genotoxic forestomach carcinogen butylated hydroxyanisole (BHA). After periods of 2-48 h, three parameters were assessed: unscheduled DNA synthesis (UDS) by autoradiography of tissue sections, replicative DNA synthesis (RDS) also by autoradiography of incorporated [3H]thymidine, and histopathological changes, including hyperplasia. MNNG induced UDS but not RDS or hyperplasia in forestomach epithelium, consistent with its genotoxic mode of action. BHA and dichlorvos did not induce UDS, consistent with absence of genotoxic activity in the forestomach after in vivo exposure. In contrast, BHA and dichlorvos induced RDS and subsequent hyperplasia, which is likely to result from irritant damage. These data suggest that the chronic effects of dichlorvos on mouse forestomach epithelium in the oral gavage bioassay were mediated via enforced cell proliferation, rather than by a genotoxic mechanism.

Molecular interaction of [2,3-14C] acrylonitrile with DNA in gastric tissue of rat

Acrylonitrile (VCN) is used extensively in polymer industries, and is known to induce gastric cancer following oral administration. A paucity of information exists regarding the mechanism(s) by which acrylonitrile induces gastric neoplasia. The time course for uptake of radioactivity by gastric tissue and covalent binding of [2,3-14C] VCN or its metabolites to gastric DNA were determined following a single oral dose of 46.5 mg/kg. The rates of DNA synthesis and repair, as measured by unscheduled DNA synthesis in the gastric tissue of VCN-treated rats, were also studied. Maximum tissue uptake and covalent binding of radioactivity to gastric DNA were observed at 15 minutes following [2,3-14C] VCN administration. At 6 hours following VCN administration, significant inhibition (37% of control) in gastric replicative DNA synthesis was observed. A rebound followed by an increase (211% of control) in replicative DNA synthesis was observed at 24 hours. A three-fold elevation in unscheduled DNA synthesis was observed at 24 hours following treatment with VCN. These results indicate that VCN or its metabolites irreversibly interact with gastric DNA, causing DNA damage. The results also indicate that the delayed VCN-induced DNA repair, determined as unscheduled DNA synthesis, is inefficient for the removal of the resulting DNA lesions.

Recommendations for the performance of UDS tests in vitro and in vivo

The Working Group (WG) dealt with the harmonization of routine methodologies of tests for unscheduled DNA synthesis (UDS) both in vitro and in vivo. In contrast to the existing guidelines from OECD, EPA and EC on in vitro UDS tests (there is no Japanese UDS guideline), the Working Group recommends that in general in vitro UDS tests should be performed with primary hepatocytes. For routine applications any other cell types would need special justification. Hepatocytes from male rats are preferable, unless there are contra-indications on the basis of e.g. toxicokinetic data. According to the OECD, EPA and EC guidelines, UDS may be analysed by means of autoradiography (AR) or liquid scintillation counting (LSC). The WG recommends use of AR. LSC is less suitable due to the problem of differentiation between UDS activity and replicative DNA synthesis, and the disadvantage that cells cannot be analysed individually. Since a specific cell type was recommended by the WG, methodological aspects could be described in more detail than in the present guidelines. For in vitro tests, it was agreed that the initial viability of freshly isolated hepatocytes should be at least 70%. With regard to the need for confirmatory experiments in the event of a clear-cut negative result, the majority view was that confirmation by a second (normally not identical) experiment is still needed; this is in line with the present OECD and EC guidelines. Evaluation of results from UDS tests should be based primarily on net nuclear grain (NNG) values, although it is recognised that nuclear and cytoplasmic grains result from different biological processes. Since grain counts are influenced by a number of methodological parameters, no global threshold NNG value can be recommended for discrimination of positive and negative UDS results. For in vitro assays, the criteria for positive findings go beyond those of the present guidelines and two alternative approaches are given which are based on (1) dose-dependent increases in NNG values and (2) reproducibility, dose-effect relationship and cytotoxicity. At present there is no official guideline on the performance of in vivo UDS tests. Some fundamental recommendations given for in vitro methodology also apply to the in vivo assay. For routine testing with the in vivo UDS test, again the general use of hepatocytes from male rats is recommended. However, concerning the requirement to use one or two sexes, consistency with other in vivo genotoxicity assays (e.g. the micronucleus assay) would be preferable. As for the in vitro methodology, AR is preferred rather than LSC.(ABSTRACT TRUNCATED AT 400 WORDS)

Carcinogen-induced nuclear enlargement in cultures of rat tracheal primary epithelial cells

Rat tracheal epithelial cells were cultured for 72 hr and then exposed for 3 hr to a range of test chemicals, including non-carcinogens, and direct-acting and activation-dependent carcinogens. The cells were then washed and cultured in fresh medium without the test chemicals for a further 24, 72 or 120 hr. Nuclear size measurements were then made. At 72 and 120 hr after exposure, those cultures treated with the non-carcinogens pyrene and anthracene had distributions of nuclear area similar to those of the solvent controls. All cultures treated with activation dependent carcinogens (N-nitrosopyrrolidine, N-nitrosodimethylamine, benzo[a]pyrene, dimethylbenz[a]anthracene or 4-nitroquinoline-N-oxide) or direct-acting carcinogens (nitrogen mustard or methylmethanesulphonate) showed a shift in distributions to the right, indicating enlarged nuclei. These results indicate that carcinogen-induced nuclear enlargement can occur in cultures of rat primary tracheal epithelial cells, and that this may be a useful indicator system for respiratory carcinogens.

Characterization of the in vitro unscheduled DNA synthesis assay in primary lung cells of the rat

The in vitro unscheduled DNA synthesis (UDS) assay has been evaluated in rat primary lung cells with known genotoxicants. The autoradiographic method was employed to detect UDS in both alveolar macrophages and primary pulmonary cells. Data of a time course study revealed that a high radioactive labeling of DNA repair was achieved after a 16-h incubation with [3H]thymidine. Coupled with low serum (1%), hydroxyurea at the concentration of 20 mM inhibited regular DNA synthesis in primary lung cells in a satisfactory manner (81-88% inhibition). With this protocol, a dose-related increase in UDS was induced by N-methyl-N'-nitro-N-nitrosoguanidine and 2-aminoanthracene in both rat alveolar macrophages and primary lung cells. The results suggest that primary rat lung cells in culture possess DNA-repair ability and that the UDS assay may be useful for assessing the pulmonary genotoxic effect of chemicals in this cell system.

Activity of germ-cell mutagens and nonmutagens in the rat spermatocyte UDS assay

The ability of 13 chemicals of known germ-cell mutagenicity to induce unscheduled DNA synthesis (UDS) in rat spermatocytes was examined. At selected times following i.p. injection of test compounds, spermatocytes were isolated from Fischer 344 rats by enzymatic digestion of the seminiferous tubules and cultured for 24 h in the presence of [3H]thymidine. 7 compounds, methyl methanesulfonate, triethylenemelamine, cyclophosphamide, methylnitrosourea, ethylnitrosourea, procarbazine, and dibromochloropropane produced positive UDS responses in spermatocytes. These chemicals are also positive for specific locus mutations, heritable translocations, or dominant lethal mutations when administered to male rodents. Mitomycin C, which produces DNA interstrand crosslinks and induces heritable mutations and translocations in male germ cells, failed to stimulate UDS in rat spermatocytes. Germ-cell nonmutagens N-methyl-N'-nitro-N-nitrosoguanidine, dimethylnitrosamine, 4-nitroquinoline 1-oxide, and ethylene dibromide were negative in the rat spermatocyte UDS assay. Correlation of these results with those of other assays for heritable mutations in germ cells indicates that the in vivo/in vitro spermatocyte DNA repair assay is useful in predicting the mutagenic potential of chemicals in male germ cells.

Factors that affect the sensitivity of the in vivo-in vitro hepatocyte DNA repair assay in the male rat

Measurement of chemically induced DNA repair as unscheduled DNA synthesis (UDS) in rat hepatocytes following in vivo exposure has been shown to be a useful indicator of the genotoxicity of chemicals in rat liver. We have examined some of the parameters of this assay in an attempt to increase its sensitivity and reduce cytoplasmic backgrounds. Fischer-344 rats were treated with a low dose of a known positive chemical, water, or corn oil. Livers were perfused with a collagenase solution and isolated hepatocytes were incubated with [3H]thymidine (3H-TdR) followed by overnight incubation in unlabeled TdR, then cell fixation and washing. UDS was measured by quantitative autoradiographic grain-counting as net grains/nucleus (NG). Incubation in 3H-TdR ranging in age from 1 week to more than 12 months gave highly variable background (BKG) and NG counts and a slight overall decrease in NG when the 3H-TdR used was more than 4 months old. Control BKG was 3 times higher after 19 h than after 4 h of incubation in 3H-TdR, with little change in NG. Incubation in unlabeled TdR also reduced BKG significantly. Reduction of autoradiogram exposure from two to one week cut BKG in half without significantly reducing NG. A half-hour wash in fixative (1:3 acetic acid:ethanol) followed by two water washes was as effective in reducing BKG as three 10-min washes in fixative followed by 6 water washes, and resulted in better overall cell attachment. An examination of the distribution of historical control data shows that vehicle control animals never exceed zero NG. This suggests that any NG response greater than zero should be viewed as a possible positive response.

A protocol and guide for the in vivo rat hepatocyte DNA-repair assay

The in vivo rat hepatocyte DNA-repair assay is a valuable tool in assessing the genotoxic activity of chemical agents. An advantage of the system is that it reflects the complex patterns of uptake, distribution, metabolism, detoxification and excretion that actually occur in the whole animal. This article provides a typical procedure and guidelines for conducting the rat in vivo hepatocyte DNA-repair assay.

A comparative study of hepatic DNA repair, DNA replication and hepatotoxicity in the CD-1 mouse following multiple administrations of dimethylnitrosamine

The objective of this study was to quantify hepatic DNA repair and DNA replication following multiple administrations of dimethylnitrosamine (DMN) and to determine if these events were correlated with hepatotoxicity. Male CD-1 mice, 50-100 days old, were dosed daily, p.o., with DMN in water at dose levels of 2, 4, 7 and 10 mg/kg for 2 weeks. After 2, 7 and 14 days of dosing, hepatocytes were isolated by an in situ perfusion procedure, incubated in the presence of [3H] thymidine, and fixed. Unscheduled as well as scheduled DNA synthesis were assessed by quantitative autoradiography. Unscheduled DNA synthesis (UDS) represents DNA repair while scheduled DNA synthesis (S phase) represents DNA replication. In addition, the animals' serum was examined for enzymes which indicate hepatic toxicity. After 1, 7 and 14 days of dosing, animals were orbital-bled and the serum was analyzed for serum glutamic pyruvic transaminase (SGPT), serum glutamic oxalacetic transaminase (SGOT), alkaline phosphatase (AP) and gamma-glutamyl transpeptidase (GGT). No morbidity or mortality was observed at dose levels of 2 and 4 mg/kg, but all animals receiving 7 and 10 mg/kg died after 4-6 days of dosing. GGT or AP were not elevated at any dose level or at any time point examined. At 4 mg/kg only a slight increase (less than or equal to 2 X) in the concentration of SGOT and SGPT was observed but a sharp increase (greater than 20 X) in replicative DNA synthesis was seen. The 2 mg/kg dose level of DMN did not increase replicative DNA synthesis and SGOT and SGPT were not elevated above control values at any time point following dosing at 2 mg/kg. A weakly positive DNA repair response was observed for dose levels of 4, 7 and 10 mg/kg DMN after two consecutive days of dosing. No DNA repair was observed after either 7 or 14 days of dosing at the 2 and 4 mg/kg/day levels. These results indicate that hepatic toxicity is associated with the induction of replicative DNA synthesis (S phase) but not with the induction of DNA repair. The results also confirm and extend a previous study (Doolittle et al., 1987b) indicating that a significant elevation in hepatic DNA replication is induced by hepatocarcinogens after multiple administrations of dose levels which do not alter hepatic DNA replication after a single administration. This finding indicates that the utility of the in vivo-in vitro hepatocyte assay may be enhanced by using a multi-dose protocol.

The in vivo-in vitro hepatocyte assay for assessing DNA repair and DNA replication: studies in the CD-1 mouse

The in vivo-in vitro hepatocyte assay, a short-term test that is useful for detecting potential rodent hepatocarcinogens, has been extended to the CD-1 mouse. Male CD-1 mice, 50-100 days old, were dosed orally with N-nitrosodimethylamine (NDMA), trichloroethylene (TCE), 2-acetylaminofluorene (2-AAF), 4-acetylaminofluorene (4-AAF), phenobarbital (PB) or a vehicle. At 3, 16, 24 and 48 hr after dosing, hepatocytes were isolated by an in situ perfusion procedure, incubated in the presence of [3H]thymidine and fixed. Unscheduled as well as scheduled DNA synthesis was assessed by quantitative autoradiography. Unscheduled DNA synthesis represents DNA repair, while scheduled DNA synthesis (S phase) represents DNA replication. No mortality or morbidity was observed in the animals dosed in this study. The vehicles used, distilled water and corn oil, did not induce DNA repair or increase the percentage of hepatocytes in S phase at any of the time points examined. The higher dose of NDMA (10 mg/kg) induced DNA repair and increased S phase, whereas the lower dose (2 mg/kg) induced DNA repair but did not increase S phase. TCE (1000 mg/kg), PB (100 mg/kg) and 4-AAF (200 mg/kg) all markedly increased the percentage of hepatocytes in S phase (5-10 times the control) but all failed to induce DNA damage and repair. 2-AAF (200 mg/kg) caused a slight (twofold) increase in S phase but did not induce DNA repair. This assay appears useful for detecting potential CD-1 mouse hepatocarcinogens and, in addition, may provide information on the mode of action of known hepatocarcinogens.

Effect of mode of administration of methyl methanesulfonate and triethylenemelamine on induction of unscheduled DNA synthesis in mouse germ cells

The effect of route of administration on induction of unscheduled DNA synthesis (UDS) in mouse germ cells in vivo was studied using two germ cell mutagens, methyl methanesulfonate (MMS) and triethylenemelamine (TEM). The chemicals were administered to male mice (C3Hf X 101)F1 by IP injection or gavage using acute or 5-day subacute regimens. After completion of dosing, methyl-[3H]thymidine [( 3H]TdR) was injected into the testes, and spermatozoa were collected 16 days later. The sperm heads were isolated, and UDS was determined by the amount of [3H]TdR incorporated. Acute administration of MMS (2-100 mg/kg) induced a strong, dose-related UDS response. The response was slightly higher with IP injection than with gavage. The UDS response after five daily doses of 50 mg MMS/kg was 20-30% higher than that induced by a single IP or gavage dose. Acute administration of TEM (0.05-4.0 mg/kg) by IP injection or gavage induced weak and variable responses. Retesting TEM using inbred C3Hf mice produced weak but exposure-related responses with both acute IP and gavage treatments. There was a slight increase in UDS response with subacute IP injection but not with subacute gavage. Acute testicular injection of TEM produced a higher but more variable UDS response. The study showed that gavage, as well as IP injection, can be used for the administration of test chemicals and that the subacute 5-day regimen induced a higher UDS response than the acute regimen. Furthermore, the testicular route may enhance the detection of weak UDS inducers.

Use of in vivo/in vitro unscheduled DNA synthesis for identification of organ-specific carcinogens

There are still only a few in vivo short-term assay methods for predicting potential organ-specific carcinogens and mutagens in mammals, although such methods are required for evaluating the in vivo effects of in vitro mutagens. In the in vivo/in vitro UDS assay methods described here, chemicals are given to experimental animals and induction of UDS in target organs is determined by in vitro organ culture or primary cell culture in the presence of [3H]dThd. Incorporation of [3H]dThd into DNA is measured with a liquid scintillation counter or by autoradiography. These methods have now been applied to the glandular stomach, forestomach, colon, liver, kidney, pancreas, tracheal epithelium, nasal epithelium, and spermatocytes. With minor modifications, they may also be applied to other organs. The present review shows that induction of UDS in various organs correlated well with the induction of cancer in these organs. The present authors have used the present methods to identify some potential organ-specific mutagens and carcinogens in mammals. The present authors found that three dicarbonyl compounds, glyoxal, methylglyoxal, and diacetyl, induced apparent UDS and TDS in the glandular stomach, and other groups found that 2-NT, MA6BT, and CNEt6BT induced UDS in the liver. These in vivo/in vitro UDS assays are better than in vitro UDS assay for identification of potential organ-specific mutagens and carcinogens in mammals and are especially useful for identifying potential mutagens and carcinogens that are specific for certain organs, such as the stomach, liver, and kidney. They are also useful for examining the potential mutagenicities and carcinogenicities of carcinogen analogs. However, these methods are not suitable for general in vivo screening because they are not yet available for all organs. A further advantage of the methods is that they can be used to examine larger numbers of animals at one time than other methods for detecting DNA damage, such as alkaline elution or alkaline sucrose density gradient centrifugation. Glyoxal enhanced cancer induction in the glandular stomach by the administration of a limited amount of MNNG and then glyoxal afterward in the two-stage stomach carcinogenesis.

Unscheduled DNA synthesis in rat tracheal epithelial cells, hepatocytes and spermatocytes following exposure to methyl chloride in vitro and in vivo

Measurement of DNA repair as unscheduled DNA synthesis (UDS) in vitro following exposure in vivo in multiple tissues from the same treated animal can provide valuable information relating to the tissue- and organ-specificity of chemically induced DNA damage. UDS was evaluated in primary cultures of rat tracheal epithelial cells, hepatocytes and pachytene spermatocytes after exposure in vitro to methyl chloride (MeCl), and after isolation from the same treated animal following inhalation exposure in vivo. Concentrations of 1-10% MeCl in vitro induced UDS in hepatocytes and spermatocytes, but not in tracheal epithelial cells. Inhalation exposure to MeCl in vivo (3000-3500 ppm 6 h/day for 5 successive days) failed to induce DNA repair in any cell type. In vivo exposure to 15 000 ppm MeCl for 3 h also failed to induce UDS in tracheal epithelial cells and spermatocytes, but did cause a marginal increase in UDS in hepatocytes. Thus, MeCl appears to be a weak, direct-acting genotoxicant. While activity could be measured in hepatocytes and spermatocytes directly in vitro, only extremely high concentrations of MeCl elicited a response in the whole animal, and then only in hepatocytes.

Detection of the cytogenetic effect of inhaled aerosols by the micronucleus test

The induction of micronuclei in mice exposed to aerosols of the following 6 genotoxic chemicals by inhalation was examined: cyclophosphamide (CP), methyl methanesulfonate (MMS), mitomycin C (MMC), dimethylnitrosamine (DMN), ethylcarbamate and colchicine. Exposure of mice to CP aerosols at a theoretical concentration of 2426 mg/m3 for 29, 81 and 139 min induced 0.6, 1.0 and 2.3% micronucleated polychromatic erythrocytes (MNPCEs) in bone marrow 24 h after the termination of exposure. The other chemicals except for DMN showed a similar exposure-response relationship following in vivo exposures to their aerosols. The results obtained in this study suggest that the cytogenetic effect of inhaled aerosols can be detected by the micronucleus test, and the method described in the present report is useful as a rapid in vivo test for atmospheric aerosols.