Prevalidation study of the Syrian hamster embryo (SHE) cell transformation assay at pH 7.0 for assessment of carcinogenic potential of chemicals.

The European Centre for the Validation of Alternative Methods (ECVAM) has organised an interlaboratory prevalidation study on the Syrian hamster embryo (SHE) cell transformation assay (CTA) at pH 7.0 for the detection of rodent carcinogens. The SHE CTA at pH 7.0 has been evaluated for its within-laboratory reproducibility, transferability and between-laboratory reproducibility. Four laboratories using the same basic protocol with minor modifications participated in this study and tested a series of six coded-chemicals: four rodent carcinogens (benzo(a)pyrene, 3-methylcholanthrene, 2,4-diaminotoluene and o-toluidine HCl) and two non-carcinogens (anthracene and phthalic anhydride). All the laboratories found the expected results with coded chemicals except for phthalic anhydride which resulted in a different call in only one laboratory. Based on the outcome of this study, it can be concluded that a standardised protocol is available that should be the basis for future use. This protocol and the assay system itself are transferable between laboratories and the SHE CTA at pH 7.0 is reproducible within- and between-laboratories.

Prevalidation study of the Syrian hamster embryo (SHE) cell transformation assay at pH 6.7 for assessment of carcinogenic potential of chemicals.

The Syrian hamster embryo (SHE) cell transformation assay (CTA) is an important in vitro method that is highly predictive of rodent carcinogenicity. It is a key method for reducing animal usage for carcinogenicity prediction. The SHE assay has been used for many years primarily to investigate and identify potential rodent carcinogens thereby reducing the number of 2-year bioassays performed in rodents. As for other assays with a long history of use, the SHE CTA has not undergone formal validation. To address this, the European Centre for the Validation of Alternative Methods (ECVAM) coordinated a prevalidation study. The aim of this study was to evaluate the within-laboratory reproducibility, test method transferability, and between-laboratory reproducibility and to develop a standardised state-of-the-art protocol for the SHE CTA at pH 6.7. Formal ECVAM principles for criteria on reproducibility (including the within-laboratory reproducibility, the transferability and the between-laboratories reproducibility) were applied. In addition to the assessment of reproducibility, this study helped define a standard protocol for use in developing an Organisation for Economic Co-operation and Development (OECD) test guideline for the SHE CTA. Six compounds were evaluated in this study: benzo(a)pyrene, 3-methylcholanthrene, o-toluidine HCl, 2,4-diaminotoluene, phthalic anhydride and anthracene. Results of this study demonstrate that a protocol is available that is transferable between laboratories, and that the SHE CTA at pH 6.7 is reproducible within- and between-laboratories.

Comparison of the Ames II and traditional Ames test responses with respect to mutagenicity, strain specificities, need for metabolism and correlation with rodent carcinogenicity.

The Ames II Salmonella mutagenicity assay procedure was used to test 71 chemicals, and the results were compared with those from the traditional Ames Salmonella test using the NTP database as the reference. All Ames II tests were performed using a fluctuation procedure in microplate format, using TAMix for the detection of base pair substitutions and TA98 to detect frameshift mutations. There was 84% agreement between the two procedures in identifying mutagens and non-mutagens, which is equivalent to the intra- and interlaboratory reproducibility of 87% for the traditional test. The two tests also performed similarly in their predictions of rodent carcinogenicity.

Advanced surface functionalization of periodic mesoporous silica: Kinetic control by trisilazane reagents.

The surface reactions of mesoporous silica MCM-41 with a series of new trisilylamines (trisilazanes) (SiHMe2)2NSiMe2R and (SiMe2Vin)2NSiMe2R (R = indenyl, norpinanyl, chloropropyl, 3-(N-morpholin)propyl; Vin = vinyl), disilylalkylamine (SiHMe2)iPrNSiMe2(CH2)3Cl, and monosilyldialkylamines Me2NSiMe2R (R = indenyl, chloropropyl, 3-(N-morpholin)propyl) were investigated. 1H, 13C, and 29Si MAS NMR spectroscopy, nitrogen adsorption/desorption, infrared spectroscopy, and model reactions with calix[4]arene as a mimic for an oxo surface were used to clarify the chemical nature of surface-bonded silyl groups. The trisilylamines exhibited a comparatively slow surface reaction, which allowed for the adjustment of the amount of silylated and nonreacted SiOH groups and led to a stoichiometric distribution of surface functionalities. The 2:1 integral ratio of SiHMe2 and SiMe2R moieties of such trisilazanes was found to be preserved on the silica surface as indicated by microanalytical as well as 13C and 29Si MAS NMR spectroscopic data of the hybrid materials. For example, the reaction of MCM-41 with (SiHMe2)2NSiMe2(CH2)3Cl, (SiHMe2)iPrNSiMe2(CH2)3Cl, and Me2NSiMe2(CH2)3Cl provided bi- and monofunctional hybrid materials with one-third, one-half, or all chemically accessible silanol groups derivatized by chloropropyl groups, respectively. Thus, a molecular precursor strategy was developed to efficiently control the relative amount of three different surface species, SiHMe2 (or SiVinMe2), SiMe2R, and SiOH, in a single reaction step. The reaction behavior of indenyl-substituted monosilazanes and trisilazanes (R = Ind) with calix[4]arene proved that the indenyl substituent can act as a leaving group forming a dimethylsilyl species, which is anchored bipodally on the silica surface, that is, via two Si-O bonds.

In vivo micronucleus test in mice with 1-phenylethanol.

1-Phenylethanol is one of the major primary phase-I metabolites of ethylbenzene. In principle it may yield an electrophilic intermediate by phase-II metabolism. Because of the extensive use of ethylbenzene as a solvent, 2-year carcinogenicity inhalation studies were carried out leading to renal hyperplasia and tubular neoplasms both in male and female rats and alveolar/bronchiolar neoplasms in male mice and hepatocellular neoplasms in female mice. Whereas the mechanism underlying the increased renal tumor incidences in rats has been clarified, the mechanism of tumor formation (genotoxic or nongenotoxic mode of action) in the lung and liver of mice is still unclear. The genotoxicity data available to date for 1-phenylethanol include in vitro studies using either bacteria (Salmonella reverse mutation assay, E. coli Pol A(+)/Pol A(-) test) or mammalian cells (mouse lymphoma assay, chromosome aberration test and sister chromatid exchanges using CHO cells). These experiments, however, did not always follow current standard procedures and some of the data obtained are compromised and not always convincing. The present database thus does not allow a definitive assessment of the in vitro genotoxic potential of 1-phenylethanol. The in vitro database suggests that clastogenicity may be the most relevant genetic end point, and therefore an in vivo micronucleus assay in mouse bone marrow was carried out. The animals were given 1-phenylethanol in single oral doses up to the maximum tolerated dose of 750 mg/kg body weight. Bone marrow was sampled 24 and 48 h after treatment. Under the experimental conditions used, there was no evidence of increased micronuclei frequencies at any dose or sampling time. These findings indicate that 1-phenylethanol is not clastogenic in vivo. This information, together with other negative or inconclusive genotoxicity data available so far, suggests a nongenotoxic mode of action responsible for the lung and liver tumors observed in mice following 2 years of inhalation exposure to ethylbenzene.

A re-assessment of styrene-induced clastogenicity in mice in a subacute inhalation study.

To date, a number of in vivo cytogenetic assays have studied the clastogenicity (chromosome aberrations, micronuclei formation) in bone marrow of rodents exposed to styrene by various routes. The majority of all these cytogenetic experiments yielded negative findings (Scott and Preston, Mutat Res 318:175-203, 1994). Recently published data from a micronucleus test in mice exposed via inhalation for up to 21 days showed some positive response, but was not fully conclusive (Vodicka et al., Chem Biol Interact 137:213-227, 2001). Since this exposure regimen has considerable relevance for workplace exposure, the present study was performed to further elucidate these findings. NMRI mice were exposed by whole body inhalation to styrene concentrations of 750 mg/m3 and 1,500 mg/m3 for 1, 3, 7, 14 and 21 consecutive days (6 h/day). Animals were killed directly after exposure and bone marrow was sampled for analysis of micronucleus induction. Under the experimental conditions used in the present investigation, there was no evidence of clastogenicity at any concentration or exposure interval.