Estrogenic effects of fluorinated diiodine alkanes in MCF-7 cells, H295R cells and zebrafish embryo assays.

Fluorinated diiodine alkanes (FDIAs), important industrial intermediates in the synthesis of various perfluorinated compounds, which are distributed widely in wildlife and humans. Recent studies showed that FDIAs had in vitro estrogenic effects. However, to date, little information is available regarding the in vivo estrogenic effects of FDIAs and the mechanisms are unclear. In this study, a combination of in vitro and in vivo assays was used to investigate the estrogenic effects of FDIAs. We tested the in vitro estrogenic effects and estrogen receptor-related gene expression via MCF-7 cell assay. The hormone level of estradiol and the expression of estrogenic synthesis genes were measured in the H295R cell assay. Finally, the in vivo effects of FDIAs on development and estrogen-related gene expression were assessed in the zebrafish embryos assay. The results demonstrated that FDIAs could exhibit estrogenic activity through inducing cell proliferation (1.6-6.7-fold of the control) and estrogen receptor alpha gene expression (1.07-1.39-fold of the control), altering estradiol production (1.14-1.22-fold of the control) and the major estrogenic synthesis gene expression of CYP19 (1.22-1.31-fold of the control), disrupting the estrogen-related genes (esr1 and cyp19b) levels in zebrafish (1.52-2.99-fold and 2.95-5.00-fold of the control for esr1 and cyp19b, respectively). The current findings indicated the potential estrogenic effects of FDIAs and provided novel information for human risk assessment.

A method for quantitative risk appraisal for pesticide risk assessments.

Pesticide risk assessments are fraught with uncertainties that arise from the process of estimating exposure to and toxicity of chemicals. Regulatory agencies resolve those uncertainties in a health-protective (conservative) manner, typically acknowledging only inter- and intraspecies uncertainties quantitatively. Other uncertainties may be acknowledged qualitatively, but those safety factors (SF) are not enumerated. Quantitative risk appraisal may be used to enumerate the multiplicative SF generated by conservative assumptions regarding uncertainties. The magnitude of SF derived from decision points dealing with historically unquantified uncertainty may far exceed explicit SF used to gauge acceptable margins of exposure (MoE). Examination of the basis for some previously unenumerated SF may justify potential changes in regulatory practices and policies. Using past risk assessments of 3 pesticides (mevinphos, parathion, and methyl iodide) for which the California Department of Pesticide Regulation found unacceptable risk as examples, the previously unquantified SF ranged from 47 to 1 × 106 for scenarios involving handlers, reentry workers, and bystanders.

Evaluation of the genotoxicity and cytotoxicity of filling pastes used for pulp therapy on deciduous teeth using the micronucleus test on bone marrow from mice (Mus musculus).

Pulp therapy is the last resort for preserving deciduous teeth. However, the genotoxic and cytotoxic effects of many products used in this therapy are not well established. The aim of this study was to use the micronucleus test on bone marrow from mice to evaluate the genotoxic and cytotoxic effects of four filling pastes: zinc oxide, calcium hydroxide P.A., mineral trioxide aggregate and an iodoform paste (iodoform + camphorated + paramonochlorophenol + rifamycin + prednisolone). Male Swiss mice were divided into 4 groups of 10 animals, each exposed to one of the pastes, and were subdivided according to the dilutions tested: 1/10, 1/50, 1/500 and 1/1000 administered intraperitoneally (0.1ml/10g of weight). Cyclophosphamide was the positive control. The negative controls were dimethylsulfoxide and buffered saline solution. Five animals were killed 24h and five 48h after the treatment. The material was processed in accordance with Schmid (1976) and micronuclei were counted in 1000 polychromatic erythrocytes (PCE), under an optical microscope in a blinded test. Cytotoxicity was evaluated using the PCE/normochromatic erythrocyte (NCE) ratio in 200 erythrocytes. The micronucleus analysis results were evaluated using the conditional test for comparing proportions in situations of rare events. Analysis of variance and Tukey's test were used to evaluate the PCE/NCE ratio. There was significantly greater occurrence of micronuclei in the animals treated with iodoform paste at all the dilutions tested, at both sacrifice times. Greater occurrence of micronuclei was observed among the animals treated with zinc oxide and sacrificed 48h after the treatment, at the dilutions 1:50; 1:500 and 1:1000. Calcium hydroxide P.A. and mineral trioxide aggregate did not present any genotoxic or cytotoxic effects. The genotoxicity and cytotoxicity of zinc oxide and iodoform paste revealed here constitute an initial step towards their contraindication, but additional studies will be necessary in order to securely establish the risks involved in their use.

Drinking water disinfection byproduct iodoacetic acid induces tumorigenic transformation of NIH3T3 cells.

Iodoacetic acid (IAA) and iodoform (IF) are unregulated iodinated disinfection byproducts (DBPs) found in drinking water. Their presence in the drinking water of China has not been documented. Recently, the carcinogenic potential of IAA and IF has been a concern because of their mutagenicity in bacteria and genotoxicity in mammalian cells. Therefore, we measured their concentrations in Shanghai drinking water and assessed their cytotoxicity, genotoxicity, and ability to transform NIH3T3 cells to tumorigenic lines. The concentrations of IAA and IF in Shanghai drinking water varied between summer and winter with maximum winter levels of 2.18 µg/L IAA and 0.86 µg/L IF. IAA with a lethal concentration 50 (LC50) of 2.77 µM exhibited more potent cytotoxicity in NIH3T3 cells than IF (LC50 = 83.37 µM). IAA, but not IF, induced a concentration-dependent DNA damage measured by γ-H2AX staining and increased tail moment in single-cell gel electrophoresis. Neither IAA nor IF increased micronucleus frequency. Prolonged exposure of NIH3T3 cells to IAA increased the frequencies of transformed cells with anchorage-independent growth and agglutination with concanavalin A. IAA-transformed cells formed aggressive fibrosarcomas after inoculation into Balb/c nude mice. This study demonstrated that IAA has a biological activity that is consistent with a carcinogen and human exposure should be of concern.

Development of an in vitro approach to point-of-contact inhalation toxicity testing of volatile compounds, using organotypic culture and air-liquid interface exposure.

In vitro chemical risk assessment using human cells is emerging as an alternative to in vivo animal testing with reduced costs, fewer animal welfare concerns, and the possibility of greater human health relevance. In vitro inhalation toxicity testing of volatile compounds poses particular challenges. Here we report our efforts to establish a testing protocol in our own lab using the EpiAirway bronchial epithelium cell culture model and the Vitrocell 12/12 system for air-liquid interface (ALI) exposures. For purposes of method development, we used methyl iodide (MeI) as a test compound. We examined viability, cytotoxicity, and epithelial integrity responses. Dose-dependent, reproducible responses were observed with all assays. EpiAirway and BEAS-2B cytotoxicity responses to acute exposure were roughly similar, but EpiAirway was more resistant than BEAS-2B by the viability measurement, suggesting a proliferative response at low MeI concentrations. If wells were sealed to prevent evaporation, in-solution MeI concentration-response could be used to predict the response to MeI vapor within 2-fold by converting from the media- to the air-concentration at equilibrium using the blood:air partition coefficient for MeI. The long-term stability of EpiAirway cultures enabled repeated exposures over a 5-d period, which produced responses at lower concentrations than did acute exposure.

Methyl iodide-induced fetal hypothyroidism implicated in late-stage fetal death in rabbits.

Methyl iodide (MeI) induces fetotoxicity in New Zealand White (NZW) rabbits when maternal exposure occurs during a susceptible window late in gestation (gestation days [GD] 23-26). To identify the possible mode of action, comprehensive maternal and fetal bioanalysis and thyroid structure/function assessments were conducted in MeI-exposed (25 ppm by whole-body inhalation) and unexposed time-mated NZW rabbits (10/group) during GD 21-27. Key developmental events were observed within this window in unexposed fetuses, including the appearance of colloid in the thyroid follicular lumen and the detection of serum T(3) beginning on GD 22. Fetal T(4) and T(3) levels were diminished following maternal MeI exposure compared to baseline values. Fetal TSH was significantly increased following 4 days of maternal MeI exposure. MeI-induced changes in the fetal thyroid included reduced colloid formation, epithelial follicular hypertrophy, and epithelial cytoplasmic vacuolation. Time-course investigations using 20 ppm MeI revealed highly concentrated levels of iodide in fetal versus maternal serum. Direct maternal administration of sodium iodide by intravenous infusion during GD 23-26 induced similar effects on fetal thyroid structure and function as MeI, identifying iodide as the putative agent. Elevated S-methylcysteine adduct concentrations were noted in fetal hemoglobin, indicating that some unreacted MeI may be delivered directly to the fetus. However, the weight of evidence from these studies suggests that late-stage fetal death following maternal exposure to MeI during GD 23-26 is the result of preferential accumulation of iodide in the fetal compartment causing disruption of the fetal hypothalamic-pituitary-thyroid axis at a critical time in the development of the rabbit fetal thyroid.

Two-day inhalation toxicity study of methyl iodide in the rat.

The effects of inhaled methyl iodide (MeI) on clinical pathology parameters, glutathione (GSH) tissue levels, serum thyroid hormone and inorganic iodide concentrations, S-methylcysteine hemoglobin concentrations, and liver UDP-glucuronyltransferase activity were studied in the rat. Male rats were exposed by whole-body inhalation to 0, 25, or 100 ppm MeI, 6 h/day for up to 2 days. Serum cholesterol concentrations (both high-density lipoprotein [HDL] and low-density lipoprotein [LDL] fractions) were increased and triglycerides were decreased at both exposure levels. Serum thyroid-stimulating hormone (TSH) concentrations were increased at 25 and 100 ppm, and serum triiodothyronine (T(3)) and thyroxine (T(4)) concentrations were decreased at 100 ppm. There was no change in either reverse triiodothyronine (rT(3)) or UDP-glucuronyltransferase activity at either exposure level. A dose- and time-dependent reduction in GSH levels in blood, kidney, liver, and nasal tissue was observed, with the greatest reduction in nasal tissue (olfactory and respiratory epithelium). MeI exposure also resulted in a substantial dose- and time-dependent increase in both serum inorganic iodide and red blood cell S-methylcysteine hemoglobin adducts. These results indicate that following inhalation exposure, MeI is rapidly metabolized in blood and tissue of rats, resulting in methylation products and release of inorganic iodide.

Evaluation of respiratory parameters in rats and rabbits exposed to methyl iodide.

Laboratory animals exposed to methyl iodide (MeI) have previously demonstrated lesions of the olfactory epithelium that were associated with local metabolism in the nasal tissues. Interactions of MeI in the nasal passage may, therefore, alter systemic toxicokinetics. The current study used unrestrained plethysmographs to determine the MeI effect on the breathing frequency and minute volume (MV) in rats and rabbits. Groups of 4 rats each were exposed to 0, 25, or 100 ppm and groups of 4 rabbits each were exposed to 0 and 20 ppm MeI for 6 h. Breathing frequency and MV were measured and recorded during the exposure. Blood samples were collected for inorganic serum iodide and the globin adduct S-methylcysteine (SMC) as biomarkers of systemic kinetics immediately following exposure. No significant reductions in breathing frequency were observed for either rats or rabbits. Significant changes in minute volume were demonstrated by both rats and rabbits; however, the changes observed in rats were not concentration dependent. The MeI-induced changes in MV resulted in significant differences in the total volume of test substance atmosphere inhaled over the 6-h period. Rats demonstrated a concentration-dependent increase in both inorganic serum iodide and SMC. Rabbits exposed to 20 ppm MeI demonstrated a significant increase of inorganic serum iodide; SMC was also increased but was not statistically significant. The results of this study are consistent with previous kinetic studies with MeI, and the data presented here can be integrated into a computational fluid dynamics physiologically based pharmacokinetic model for both rats and rabbits.

Prenatal developmental toxicity studies of inhaled methyl iodide vapor in rabbits reveal a susceptible window of exposure inducing late gestational fetotoxicity.

Methyl iodide (MeI), an intermediate used in the manufacture of some insecticides and pharmaceuticals, is under review for U.S. registration as a non-ozone-depleting alternative to methyl bromide in the pre-plant soil fumigation market. Guideline (OPPTS 870.3700) developmental toxicity studies in New Zealand White (NZW) rabbits showed dose-dependent increases in the litter proportions of late fetal deaths and postimplantation loss and/or decreased fetal body weight following inhalation exposure of pregnant rabbits to MeI during gestation days (GD) 6-28. A subsequent phased-exposure study was performed to pinpoint the critical window of gestational exposure that produced the rabbit fetotoxicity. Artificially inseminated NZW female rabbits were exposed to 20 ppm MeI vapors by whole-body inhalation (6 h/day) throughout major organogenesis and fetal development (GD 6-28), during early gestation (GD 6-14) or mid-gestation (GD 15-22) only, or during 2-day intervals late in gestation (GD 23-24, 25-26, or 27-28). No maternal or developmental toxicity was elicited from maternal exposure during GD 6-14, 15-22, or 27-28. However, MeI-related fetotoxicity, including increased litter proportions of late fetal deaths with or without corresponding decreases in fetal body weight, were observed for females exposed during GD 6-28 (p < .01), 23-24 and 25-26. Although the increase in late-stage fetal death for each of the 2-day exposures on GD 23-24 and GD 25-26 was not statistically significant, as noted for the combined total of fetal deaths during the GD 6-28 exposure, it can be deduced that the gestational window of GD 23-26 was the most susceptible window of exposure for eliciting developmental toxicity in rabbits exposed to MeI vapors.

Effect of methyl iodide on deiodinase activity.

Methyl iodide (MeI) has been proposed as an alternative for methyl bromide in pre-plant soil fumigation applications that does not affect stratospheric ozone. Preliminary studies in rabbits noted fetal resorptions if the pregnant does were exposed to MeI during a critical period during gestation. In addition, abnormalities in thyroid hormone parameters were also observed in animals exposed to MeI. Since monodeiodination is the major metabolic pathway of the thyroid hormones, we examined the effect of MeI on deiodinase activity as a possible etiology for the alteration in thyroid hormone parameters and ultimate fetal demise. In vitro studies using tissue microsomes and cell culture showed that MeI has no effect on type I 5'-deiodinase (D1) or type II 5'-deiodinase (D2) at physiologically relevant concentrations. At high concentrations (>10 mM,>10,000 ppm), MeI caused a nonspecific inactivation of D1 and D2. Analysis of D1 and D2 activity in rats exposed by inhalation to increasing concentrations of MeI showed a significant decrease in enzyme activity at 100 ppm, while brain type III 5'-deiodinase (D3) was unaffected by MeI at the exposures studied. While the drop in D1 can be explained by the induction of a hypothyroid state in the exposed rats, there is no clear explanation for the fall in D2 levels. In the rabbit studies, there was a significant decrease in kidney D1 in the adult rabbits exposed to 20 ppm MeI. However, there was no effect on liver D1, brain D2, or placental D3 in the MeI-exposed rabbits. Similarly, there was no effect of MeI on fetal D1 or D2 activity. The lack of a significant direct effect of MeI on deiodinase activity and the absence of a change in placental or fetal deiodinase activity make it unlikely that alterations in deiodinase activity plays a role in the fetal resorptions in the MeI-exposed rabbits.

Investigations of the pathways of toxicity of methyl iodide in the rat nasal cavity.

The monohalomethane methyl iodide (MeI) is a site specific toxin within the nasal cavity of the rat, selectively damaging the olfactory epithelium (OE) whilst respiratory epithelium (RE) is spared. The aim of this study was to investigate the rates and routes of metabolism of MeI within the nasal cavity, in order to understand the reasons for the observed site-selectivity. Cytosolic glutathione S-transferases (GSTs) of both OE and RE catalysed the conjugation of MeI with glutathione (GSH), but rates were 4-fold higher in OE than RE. The product of this reaction was confirmed as S-methyl GSH. In both OE and liver the GST catalysing the conjugation of MeI was shown to belong to the theta class. No cytochrome P450-dependent oxidation of MeI to formaldehyde could be detected in incubations containing hepatic or olfactory microsomes. Intact nasal turbinates were incubated with [14C]-MeI, and a dose- and time-dependent covalent binding of MeI to olfactory protein was demonstrated. The rates of protein methylation were found to be similar in OE and RE. Thus the only parameter that correlates with the site-selectivity of the observed lesion is the rate of conjugation of MeI with GSH. Whether toxicity is due to production of a reactive metabolite or GSH depletion per se, remains to be elucidated.

Methyl iodide toxicity in rat cerebellar granule cells in vitro: the role of glutathione.

The monohalomethane methyl iodide (MeI) is toxic to a number of organ systems including the central nervous system. Clinical symptoms of neurotoxicity suggest that the cerebellum is the target within the brain, and we have now modelled the toxicity of MeI in cultured rat cerebellar granule cells. Cytotoxicity is maximal 24 h after a 5 min exposure to MeI, and the EC50 for MeI under these conditions was calculated to be 1.6 mM. The glutathione S-transferase (GST) dependent metabolism of MeI was investigated in these cultures. There was a marked decrease in intracellular glutathione (GSH) 15 min after exposure to MeI, and GSH concentrations then increased, reaching 130% of control levels 7 h after exposure. To investigate the role of conjugation with GSH in the toxicity of MeI, GSH levels were modulated prior to exposure. Depletion of GSH exacerbated the cytotoxicity of MeI while provision of a bioavailable source of GSH was protective. Inclusion of antioxidants [vitamin E, butylated hydroxytoluene (BHT) or desferrioxamine mesylate (DF)] also protected against the cytotoxicity of MeI. Our in vitro data suggest that MeI is conjugated with GSH in the cerebellum, and the resulting extensive depletion of GSH may be the first step en route to toxicity, rendering the tissue susceptible to methylation and/or oxidative stress.

Metabolism and toxicity of methyl iodide in primary dissociated neural cell cultures.

The metabolism and the toxicity of methyl iodide (Mel) has been studied in primary dissociated neuronal and glial murine cell cultures to further characterize the mechanisms of monohalomethane neurotoxicity. Measurement of intracellular glutathione (GSH) concentrations in cerebellar and cerebral cultures revealed GSH levels (21.6 +/- 1.9 and 29.1 +/- 1.9 nmol/mg protein, respectively) close to brain GSH levels measured in vivo. A GSH-depleting effect of Mel was demonstrated, with an ED50 for a 5 min exposure of 0.2 and 0.5 mM for glial and mixed (neurons + glia) cultures, respectively. Mel-induced GSH depletion was correlated with its neurotoxicity as the two powerful protective agents of monohalomethane toxicity, 3-amino-1-[m-(trifluoromethyl) phenyl]-2-pyrazoline (BW 755C, 1 mM) and nordihydroguaiaretic acid (NDGA, 10 microM) provided a 20-fold protection against depletion of GSH levels following Mel exposure. When glia and neurons from cerebral cultures were exposed in suspension to increasing concentrations of Mel for 30 min at 37 degrees C, a concentration-dependent increase in the production of formaldehyde resulted. Formaldehyde appeared to be an indicator of Mel metabolism as its production was decreased by sulfasalazine, a compound which was shown to be an inhibitor of the glutathione-S-transferases in this culture system. Since BW 755C and NDGA had no effect on formaldehyde production, while sulfasalazine as well as semicarbazide, a protective agent against formaldehyde-producing toxicants, failed to protect the cells against Mel toxicity, mechanism(s) of Mel neurotoxicity appeared independent of the GSH-mediated metabolism of this compound. It is concluded that GSH-mediated metabolic biotransformation is not necessary for the neurotoxicity of the monohalomethanes, that GSH depletion may act as a starting point in the chain of events leading to neural cell death, and that glia may be more sensitive than neurons to this primary effect. Moreover, these results demonstrate the value of primary dissociated neuronal cell cultures for studies of biochemical mechanisms of neurotoxicity.

Mitochondrial glutathione and methyl iodide-induced neurotoxicity in primary neural cell cultures.

The status of both cytosolic and mitochondrial glutathione was studied in primary cultured cerebrocortical cells from fetal mice using the selective membrane-solubilizing properties of digitonin and after exposure to the monohalomethane methyl iodide. A correlation was found between cell injury (assessed by lactate dehydrogenase leakage 24 hr after exposure) and early loss of mitochondrial glutathione (2 hr after exposure), while cell death did not appear directly dependent on cytosolic glutathione depletion. The antioxidants BW 755C (3-amino-1-[m-(trifluoromethyl)phenyl]-2-pyrazoline) and DPPD (N,N'-diphenyl-p-phenylenediamine), and the glutathione precursor N-acetyl-L-cysteine were used to modify cellular responses to methyl iodide. Prevention of cell injury by these reagents was obtained only under conditions where at least 50% of the normal level of mitochondrial glutathione was preserved after methyl iodide exposure. Mitochondrial metabolic activity (reduction of 3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium bromide, MTT) was affected by exposure to methyl iodide and correlated with mitochondrial glutathione depletion and cytotoxicity. These findings indicate that the mitochondrial glutathione pool and mitochondrial functions may be the most significant intracellular targets of methyl iodide in neural cultures. Moreover, the present work exemplifies the dependence of neural cell viability on the status of mitochondrial functions and suggests that, as in the liver, mitochondrial glutathione is an important component of cellular homeostasis in nervous tissue.

Chemical reactivity and mutagenicity of some dihalomethanes.

Four dihalomethanes; dichloromethane, bromochloromethane, dibromomethane and diiodomethane, have been studied with respect to their reactivities towards nucleophilic compounds of different strengths in water solution and with respect to their toxicities and mutagenic effectiveness in bacterial test systems. The correlation between biological activity (toxicity and mutagenic effectiveness in Salmonella TA100) and reactivity towards strong nucleophiles indicates that reactions with nucleophilic groups of high reactivity in the biological material, possibly SH or amino groups in proteins, are involved in their mechanism of action.

Morphological transformation of C3H/10T1/2 CL8 cells by alkylating agents.

The standard method of the C3H/10T1/2 cell transformation assay cannot adequately detect alkylating agents. A modification of the standard procedure as described by Bertram and Heidelberger using a large number of synchronized cells and high levels of toxicity was evaluated for transformation using several alkylating agents. By using this method, N-methyl-N' -nitro-N-nitrosoguanidine (MNNG), beta-propiolactone (BPL), methyl methanesulfonate (MMS), methylnitrosourea (MNU) and 1,3-propane sultone (PS) transformed these cells. However, methyl iodide (MI) failed to induce any transformed foci.

Mutagenic activity of some clastogenic chemicals at the hypoxanthine guanine phosphoribosyl transferase locus of Chinese hamster ovary cells.

4 presumptive clastogens (caffeine, dimethyl sulfoxide, diethylstilbestrol and p,p'-DDE) and 4 chemicals thought to induce chromosomal mutations in L5178Y mouse lymphoma cells (procarbazine X HCl, epichlorohydrin, hycanthone and iodomethane) were tested in the CHO/HGPRT gene mutation assay for the induction of 6-thioguanine-resistant ( 6TGR ) mutants. Of the clastogens, p,p'-DDE was mutagenic at several concentrations and diethylstilbestrol (DES) increased the 6TGR mutant frequency over control levels at the 6.7 and 8.0 micrograms/ml doses, but the results for DES were neither convincing nor significant. Caffeine was not mutagenic although at very high concentrations (6667-8000 micrograms/ml) there was a slight elevation in mutant frequency over background. This was probably due to a selective effect of caffeine against the HGPRT+ phenotype, for 2 different HGPRT- cell lines were refractory to the toxic effects of caffeine at the highest test level (8000 micrograms/ml). All 4 'chromosomal mutagens' produced dose-related increases in mutant frequencies at the HGPRT locus of these CHO cells. 6TGR colonies were generally uniform in size when normal precautions were taken to prevent the formation of satellite (secondary) colonies. Excepting DES, dimethyl sulfoxide, and caffeine, these data demonstrate that 5 of 8 clastogenic chemicals reproducibly induce mutations at the HGPRT locus of CHO cells which lack the small colony-forming potential of 3.7.2C L5178Y cells.

Root canal sealer cytotoxicity with human gingival Fibroblasts. III. Calcium hydroxide-based sealers.

The cytotoxicity of four different calcium hydroxide-based root canal sealers (Sealapex, Apexit, CRCS, and Endoflas FS) was tested using human gingiva fibroblasts. The fibroblasts were acquired from the attached gingiva of apparently healthy patients. The sealers were allowed to set for 24 and 48 h before being covered with a fibroblastic suspension. The estimation of the incorporation rate of L-[14C]leucine in the fibroblasts after being in contact with the sealers was utilized to designate the fibroblasts' protein synthesis potential. The research was conducted over a period of 21 days. Endoflas FS induced a dramatic reduction in the protein synthesis potential of the fibroblasts in the 24-h group. In the 48-h group, Endoflas FS showed a slightly better response. Endoflas FS, however, showed a significantly higher cytotoxicity with respect to other sealers in both trials (p < 0.05). Sealapex demonstrated a relatively low cytotoxicity after 3 days of culturing. Although CRCS showed a slightly higher cytotoxicity during the initial phase of the experiments, a declining level of toxicity could be measured after 3 days of culturing. Apexit had a relatively high cytotoxicity in the beginning phase, but an ascending incorporation rate of L-[14C]leucine in the fibroblasts could be distinguished after 3 days of culturing.

Potential halogenated industrial carcinogenic and mutagenic chemicals. II. Halogenated saturated hydrocarbons.

The halogenated saturated hydrocarbons analogously to the previously considered halogenated unsaturated hydrocarbons (Part I) possess considerable utility in a broad spectrum of applications including; solvents, dry-cleaning fluids, refrigerants, fumigants, degreasing agents, propellants and intermediates in the production of other chemicals, textiles and plastics. Methyl chloride, methylene chloride, chloroform, carbon tetrachloride, methyl chloroform, 1,1,2-trichloroethane, hexachloroethane, ethyl chloride and fluorocarbons were reviewed principally in terms of their synthesis (or occurrence), areas of application, stability, distribution, reactivity, levels of exposure, populations at risk, carcinogenicity, mutagenicity and metabolism.