Studies on lung tumours. III. Oxidative metabolism of dimethylnitrosamine by rodent and human lung tissue

6 Final Report on the Safety Assessment of Formaldehyde

The report selectively reviews the extensive literature available on the toxicity of Formaldehyde. It is concluded that Formaldehyde in cosmetic products is safe to the great majority of consumers. Because of the skin sensitivity of some individuals to this agent, the formulation and manufacture of a cosmetic product should be such as to ensure use at the minimal effective concentration of Formaldehyde, not to exceed 0.2% measured as free Formaldehyde. It cannot be concluded that Formaldehyde is safe in cosmetic products intended to be aerosolized.

Correlation between induction of DNA fragmentation in lung cells from rats and humans and carcinogenic activity

Six chemicals, known to induce lung tumors in rats, were examined for their ability to induce DNA fragmentation in primary cultures of rat and human lung cells, and in the lung of intact rats. Significant dose-dependent increases in the frequency of DNA single-strand breaks and alkali-labile sites, as measured by the single-cell gel electrophoresis (Comet) assay, were obtained in primary lung cells from male rats with the following, minimally toxic, concentrations of the six test compounds: N-nitrosodimethylamine (NDMA; 2.5-10 mM), hydrazine (HZ; 0.5-4 mM), cadmium sulfate (CD; 31.2 and 62.5 μM), 4,4'-methylene bis (2-chloroaniline) (MOCA; 31.2-125 μM), isobutyl nitrite (IBN; 7.8-31.2 μM) and tetranitromethane (TNM; 1.9-15.6 μM). Similar degrees of DNA fragmentation were obtained in primary human lung cells; however, due to inter-donor differences, the minimum effective concentrations were in some donors lower and in others higher than in rats, and IBN induced DNA damage only in one of three donors. The DNA-damaging potency of HZ was higher in rats than in humans, and the opposite was true for MOCA. In agreement with these findings, statistically significant increases in the average frequency of DNA breaks were obtained in the lung of rats given a single oral dose (1/2 LD50) of the six test compounds. These findings give evidence that genotoxic lung carcinogens may be identified by use of the DNA fragmentation/Comet assay on rat lung cells as targets cells, and show that the six compounds tested produce in primary cultures of lung cells from human donors DNA-damaging effects substantially similar to those observed in rats.

Formaldehyde in drinking water: comparative hazard evaluation and an approach to regulation

Formaldehyde, a widely used industrial chemical to which humans are ubiquitously exposed, presented cause for concern when it was demonstrated to be carcinogenic in laboratory animals. Risk assessment protocols subsequently applied to formaldehyde are of questionable validity in light of the results of recent mechanistic investigations of biological responses to formaldehyde. Further, the hazard of ingested formaldehyde is not addressed in current assessment protocols. This paper addresses the potential human health risks accompanying low-level exposure to formaldehyde as a contaminant in drinking water. In this exposure scenario, noncarcinogenic risk from inhalation of formaldehyde from drinking water is evaluated through knowledge of the metabolism and biological effects of formaldehyde exposure. Noncarcinogenic risk from ingestion of formaldehyde in drinking water is evaluated from the perspective gained by comparison with dietary sources of formaldehyde. Carcinogenic risk to humans is evaluated in light of recent investigations into the mechanisms underlying biological responses to formaldehyde exposure. Finally, based on a comparison of ingestion of formaldehyde in drinking water with ingestion of naturally occurring formaldehyde in foods, a comparative hazard approach to formaldehyde regulation is offered as a supplement to the rigid evaluation protocols currently used.

alpha-Hydroxylation pathway in the in vitro metabolism of carcinogenic nitrosamines: N-nitrosodimethylamine and N-nitroso-N-methylaniline

Evolution of 15N2-labeled molecular nitrogen was used to gauge the extent of alpha-hydroxylation during rat liver homogenate metabolism of doubly 15N-labeled N-nitrosodimethylamine (DMN) and N-nitrosomethylaniline (NMA). These measurements were correlated with the extent of total metabolism as measured by the disappearance of the nitrosamines and by the formation of formaldehyde. The results indicate that approximately 34% of DMN and 19% of NMA were metabolized by the alpha-hydroxylation pathway. Positive controls utilizing doubly 15N-labeled N-nitroso-N-methylurea yielded 96% of labeled nitrogen. These results are in variance with previously published data which claimed that either less than 5% or about 100% of DMN is metabolized by that route in vitro. Formaldehyde formation was shown to be a poor measure of the extent of metabolism. Semicarbazide gave rise to both formaldehyde and nitrogen, which makes it an undesirable component of the in vitro metabolism mixtures, particularly when those two substances are being measured.

Relationship between alveolar PO2 and the rate of p-nitroanisole O-demethylation by the cytochrome P-450 pathway in isolated rabbit lungs

The relationship between alveolar PO2 and the rate of O-demethylation of p-nitroanisole, a model substrate for cytochrome P-450 -linked mixed-function oxidation, was evaluated in the isolated rabbit lung perfused with Krebs-Ringer bicarbonate buffer. The appearance of the product, p-nitrophenol, in the pulmonary perfusate was measured spectrophotometrically, The PO2 of the ventilating gas was varied with an accurate gas mixing pump and measured with an electrochemical O2 analyzer. In control lungs ventilated with 5% CO2 in air, the rate of p-nitrophenol production was approximately equal to 3.1 +/- 0.04 (mean +/- SE; n = 9) mumol/h per g dry wt. p-Nitrophenol production was unaltered when O2 in the ventilating gas was decreased to 1%, but it was depressed reversibly when alveolar O2 WAS 0.1% OR LESS AND WAS ABOLISHED DURING VENTILATION WITH 0.005% O2. The rate of the reaction was inhibited by 50% when alveolar PO2 was 0.3 mm Hg representing and intracellular [O2] OF approximately equal to muM. In the presence of metyrapone (0.1--1 mM), an inhibitor of cytochrome P-450-dependent reactions, p-nitrophenol production was 0.07--0.17 mumol/h per g dry wt. Ventilation of lungs with varying CO concentration in 20% O2 resulted in 50% inhibition of p-nitrophenol production when CO concentration was 10% (CO/O2 = 0.5). These results indicated that O-demethylation of p-nitroanisole by the lung is a cytochrome P-450-dependent reaction and that its rate is not affected until alveolar PO2 is less than 1 mm Hg.

Studies on lung tumours. IV. Correlation between [3H]thymidine labelling of lung and liver cells and tumour formation in GRS/A and C3Hf/A male mice following administration of dimethylnitrosamine

Male mice of the inbred strain GRS/A are highly susceptible to lung tumour but refractory to liver tumour formation, whereas the opposite relation holds for C3Hf/A male mice. Liver and lung cells of these 2 mouse strains were studied autoradiographically after intraperitoneal injection of [3H]dimethylnitrosamine (DMN) and of [3H]thymidine at days 1--14 after administration of unlabelled DMN. Corresponding cell types in the lungs or livers of these 2 mouse strains bound similar amount of [3H]DMN. Among the various types of lung cells only the alveolar Type II cells, from which the lung adenomas derive, showed a strain-specific difference in [3H]thymidine labelling indices, much more cells becoming labelled in the case of the GRS/A than of the C3Hf/A strain at days 3--7 after carcinogen administration. Opposite thymidine labelling indices were exhibited by the parenchymal liver cells of the 2 strains, with C3Hf/A now showing a greater response than did GRS/A males. Thus thymidine-labelling and tumourigenic responses of target lung and liver cells to carcinogen in the 2 strains coincided. Sulphur dioxide and carbon tetrachloride mimicked the effects of DMN on the thymidine labelling indices of, respectively, the lung alveolar Type II and the thymidine labelling indices of, respectively, the lung alveolar Type II and the liver parenchymal cells of the 2 strains. The nature of the differential effect of carcinogen on the [3H]thymidine labelling of the cells and the correlation of these patterns with susceptibility to tumour formation, are briefly discussed.

Oxidative metabolism of dimethylnitrosamine: correlation with toxicity

The relationship between oxidative metabolism and acute toxicity of dimethylnitrosamine (DMN) was examined in neonatal and adult rats to take advantage of developmental changes in activity of the metabolizing enzymes. The objective was to determine the extent to which CO2 production from DMN is correlated with toxicity. Neonatal rat liver and kidney demonstrated the ability to metabolize DMN. This ability progressed to a maximum activity in liver between the 5th and 21st d of age and in kidney between the 15th and 21st d of age. After weaning, the activity of DMN oxidation decreased with age in both tissues. Evidence is also presented to suggest that more than one enzyme may be responsible for the oxidation of DMN to CO2 and that the predominance of individual enzymes varies as the neonate develops. Estimates of LD50 values, used to quantitate the acute toxicity of DMN at various ages, suggest that the rat is most sensitive to DMN toxicity at 5 d of age; however, conversion of DMN to CO2, both in vitro and in vivo, was not well correlated with acute toxicity.