Salmonella typhimurium strains TA1535, TA1537, TA98, TA100 and Escherichia coli strain WP2uvrA were treated with the test item, Lime Oil Distilled 1-Fold, Lime (Citrus aurantifolia), ext., using both the plate incorporation and pre-incubation methods at up to 7 dose levels, in triplicate, both with and without the addition of a rat liver homogenate metabolising system. The tests were performed according to OECD guideline 471.

A third experiment (plate incorporation test) was performed in response to small but non-reproducible increases in revertant colony frequency noted for Escherichia coli strain WP2uvrA in the absence and presence of S9-mix. In the first experiment (plate incorporation methodology), the test item caused a visible reduction in the growth of the bacterial background lawns of all of the tester strains, initially from 50 and 500 μg/plate in the absence and presence of S9-mix, respectively. In Experiment 2 (pre-incubation methodology) the test item induced a similar toxic response with weakened bacterial background lawns initially noted from 15 μg/plate (-S9) and 500 μg/plate (+S9). The sensitivity of the bacterial tester strains to the toxicity of the test item varied between strain type, exposures with or without S9-mix and experimental methodology. The test item was tested up to the maximum recommended dose level of 5000 μg/plate or the toxic limit, depending on bacterial strain type and presence or absence of S9-mix.

No biologically significant increases in the frequency of revertant colonies were recorded for any of the bacterial strains, with any dose of the test item, either with or without metabolic activation or exposure method. Statistically significant increases in WP2uvrA revertant colony frequency were observed at sub-toxic dose levels (1500 μg/plate in the absence and presence of S9-mix) in the first Experiment only. These increases were considered to be of no biological relevance because there was no evidence of a dose-response relationship or reproducibility. Furthermore, all of the experimental work demonstrated that the test item did exhibit toxicity regardless of exposure conditions. Therefore, the small increases in revertant colony frequency may be an artefact resulting from a modest level of toxicity to WP2uvrA. A possible mechanism may be that low level toxicity has caused a selective effect on the number of bacterial cells plated, resulting in an increase in non revertant tryptophan-dependent bacteria. Other statistically significant increases were observed in several tester strains; however, these responses were always accompanied by weakened bacterial background lawns and can, therefore, be disregarded. The test item, Lime Oil Distilled 1-Fold, Lime (Citrus aurantifolia), ext., was therefore considered to be non-mutagenic under the conditions of this test.

The study was performed in accordance with OECD Guideline 476 to investigate the potential of the substance Orange Oil Cold Pressed 1-Fold-Orange, ext. (Citrus sinensis, Rutaceae) to induce mutations at the mouse lymphoma thymidine kinase locus using the cell line L5178Y. The assay was performed in 2 independent experiments in the absence and presence of S9-mix (rat liver S9-mix induced by a combination of phenobarbital and ß-naphthoflavone). The test substance was a clear yellow liquid and was dissolved in ethanol. In the first experiment the substance was tested up to concentrations of 43 and 100 µg/ml in the absence and presence of 8% (v/v) S9-mix, resp. The incubation time was 3 h. The substance was tested up to a cytotoxic level of 12% (RTG) in the absence of S9-mix. No toxicity was observed up to and including the dose level of 100 µg/ml in the presence of S9-mix. The test substance precipitated in the culture medium at this dose level. In the second experiment the substance was tested up to concentrations of 40 and 100 µg/ml, but in the absence and presence of 12% (v/v) S9-mix, resp. The incubation times were 24 h and 3 h for incubations in the absence and presence of S9-mix, resp. The substance was tested up to a cytotoxic level of 41% (RTG) in the absence of S9-mix. No toxicity was observed up to and including the dose level of 100 µg/ml in the presence of S9-mix. The test substance precipitated in the culture medium at this dose level. The spontaneous mutation frequencies in the solvent-treated control cultures were between the minimum and maximum value of the historical control data range and within the acceptability criteria of this assay. Mutation frequencies in cultures treated with positive control chemicals were increased by 11- and 23-fold for MMS in the absence of S9-mix, and by 20- and 17-fold for CP in the presence of S9-mix. It was therefore concluded that the test conditions, both in the absence and presence of S9-mix, were appropriate and that the metabolic activation system functioned properly. In the absence and in the presence of S9-mix the test substance did not induce a significant increase in the mutation frequency in both experiments. It is concluded that Orange Oil Cold Pressed 1-Fold-Orange, ext. (Citrus sinensis, Rutaceae) does not induce gene mutations in the cultured mammalian cells used, i.e. the mouse lymphoma L5178Y test system, under the experimental conditions described in the report, as per guidance document, section 35, OECD 476.

The study was performed in accordance with OECD Guideline 476 to investigate the potential of the substance Lemon Oil Cold Pressed 1-Fold-Lemon, ext. (Citrus limonum, Rutaceae) to induce mutations at the mouse lymphoma thymidine kinase locus using the cell line L5178Y. The assay was performed in 2 independent experiments in the absence and presence of S9-mix (rat liver S9-mix induced by a combination of phenobarbital and ß-naphthoflavone). The test substance was a clear yellow liquid and was dissolved in ethanol. In the first experiment the substance was tested up to concentrations of 43 and 100 µg/ml in the absence and presence of 8% (v/v) S9-mix, resp. The incubation time was 3 h. The substance was tested up to a cytotoxic level of 12% (RTG) in the absence of S9-mix. No toxicity was observed up to and including the dose level of 100 µg/ml in the presence of S9-mix. The test substance precipitated in the culture medium at this dose level. In the second experiment the substance was tested up to concentrations of 40 and 100 µg/ml, but in the absence and presence of 12% (v/v) S9-mix, resp. The incubation times were 24 h and 3 h for incubations in the absence and presence of S9-mix, resp. The substance was tested up to a cytotoxic level of 41% (RTG) in the absence of S9-mix. No toxicity was observed up to and including the dose level of 100 µg/ml in the presence of S9-mix. The test substance precipitated in the culture medium at this dose level. The spontaneous mutation frequencies in the solvent-treated control cultures were between the minimum and maximum value of the historical control data range and within the acceptability criteria of this assay. Mutation frequencies in cultures treated with positive control chemicals were increased by 11- and 23-fold for MMS in the absence of S9-mix, and by 20- and 17-fold for CP in the presence of S9-mix. It was therefore concluded that the test conditions, both in the absence and presence of S9-mix, were appropriate and that the metabolic activation system functioned properly. In the absence and in the presence of S9-mix the test substance did not induce a significant increase in the mutation frequency in both experiments. It is concluded that Lemon Oil Cold Pressed 1-Fold-Lemon, ext. (Citrus limonum, Rutaceae) does not induce gene mutations in the cultured mammalian cells used, i.e. the mouse lymphoma L5178Y test system, under the experimental conditions described in the report, as per guidance documents, section 35 OECD 476.

A chromosomal aberration test in vitro using a Chinese hamster fibroblast cell line (CHL) was carried out on Lime oil. The test was performed comparable to OECD Guideline 473. The cells were continuously exposed to Lime oil at three different doses for 24 and 48 hours without metabolic activation. The maximum dose of the Lime oil sample was selected by a preliminary test in which the dose needed for 50% cell-growth inhibition was estimated using a cell densitometer, representing the highest non-cytotoxic dose: 0.04 mg/ml. 100 Metaphases were examined. The incidence of polyploid cells at 24 hr after treatment was 0.0 %. The incidence of cells with structural chromosome aberrations at 24 hr after treatment was 4.0 %. Lime oil did not significantly induce chromosomal aberrations in CHL cells in vitro at three different concentrations in the absence of metabolic activation and was therefore considered not clastogenic in this test.

A chromosomal aberration test in vitro using a Chinese hamster fibroblast cell line (CHL) was carried out on Orange oil. The test was performed comparable to OECD Guideline 473. The cells were continuously exposed to Orange oil at three different doses for 24 and 48 hours without metabolic activation. The maximum dose of the Orange oil sample was selected by a preliminary test, in which the highest non-cytotoxic dose was 0.125 mg/ml. 100 Metaphases were examined. The incidence of polyploid cells at 48 hr after treatment was 1.0 %. The incidence of cells with structural chromosome aberrations at 48 hr after treatment was 1.0 %. Orange oil did not significantly induce chromosomal aberrations in CHL cells in vitro at three different concentrations in the absence of metabolic activation and was therefore considered not clastogenic in this test.

An in vitro chromosomal aberration test using a Chinese hamster fibroblast cell line (CHL) was carried out on grapefruit oil. The test was performed comparable to OECD Guideline 473. The cells were continuously exposed to grapefruit oil at three different doses for 24 and 48 hours without metabolic activation. The maximum dose of the grapefruit oil sample was selected by a preliminary test in which the dose needed for 50% cell-growth inhibition was estimated using a cell densitometer, representing the highest non-cytotoxic dose: 0.063 mg/ml. 100 Metaphases were examined. The incidence of polyploid cells at 24 hr after treatment was 0.0 %. The incidence of cells with structural chromosome aberrations at 24 hr after treatment was 2.0 %. Grapefruit oil did not significantly induce chromosomal aberrations in CHL cells in vitro at three different concentrations in the absence of metabolic activation and was therefore considered not clastogenic in this test.

A chromosomal aberration test in vitro using a Chinese hamster fibroblast cell line (CHL) was carried out on Lemon oil. The test was performed comparable to OECD Guideline 473. The cells were continuously exposed to Lemon oil at three different doses for 24 and 48 hours without metabolic activation. The maximum dose of the Lemon oil sample was selected by a preliminary test in which the dose needed for 50% cell-growth inhibition was estimated using a cell densitometer, representing the highest non-cytotoxic dose: 0.125 mg/ml. 100 Metaphases were examined. The incidence of polyploid cells at 24 hr after treatment was 1.0 %. The incidence of cells with structural chromosome aberrations at 24 hr after treatment was 2.0 %. Lemon oil did not significantly induce chromosomal aberrations in CHL cells in vitro at three different concentrations in the absence of metabolic activation and was therefore considered not clastogenic in this test.