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Administrative data

Key value for chemical safety assessment

Genetic toxicity in vitro

Description of key information

Dioctanoyl peroxide was evaluated in the reverse bacterial mutation assay using Salmonella typhimurium TA 1535, 1537, 98 and 100. Dioctanoyl peroxides was not mutagenic under the conditions of this assay. In an additional Ames test Dioctanoyl peroxide was considered to be weakly mutagenic to one strain of bacteria (Escherichia coli WP2uvrA) with and without metabolic activation. In mamalian cells the substance did not induce any toxicologically significant increases in the mutant frequency at the TK +/- locus in L5178Y cells.

Link to relevant study records

Referenceopen allclose all

Endpoint:
in vitro gene mutation study in mammalian cells
Remarks:
Type of genotoxicity: gene mutation
Type of information:
experimental study
Adequacy of study:
key study
Study period:
Experimental starting date: 24 March 2015 Experimental completion date: 11 May 2015
Reliability:
1 (reliable without restriction)
Rationale for reliability incl. deficiencies:
other: Study conducted in compliance with agreed protocols, with n or minor deviations from standard test guidelines and/or minor methodological deficiencies which do not affect the quality of relevant results.
Qualifier:
according to guideline
Guideline:
OECD Guideline 476 (In Vitro Mammalian Cell Gene Mutation Test)
Deviations:
no
Qualifier:
according to guideline
Guideline:
EU Method B.17 (Mutagenicity - In Vitro Mammalian Cell Gene Mutation Test)
Deviations:
no
Qualifier:
according to guideline
Guideline:
EPA OPPTS 870.5300 - In vitro Mammalian Cell Gene Mutation Test
Deviations:
no
Qualifier:
equivalent or similar to guideline
Guideline:
other: Test method designed to be in alignment with the following Japanese Guidelines •Kanpoan No. 287 - Environment Protection Agency •Eisei No. 127 - Ministry of Health and Welfare •Heisei 09/10/31 Kikyoku No. 2 - Ministry of International Trade and Industry
Deviations:
no
GLP compliance:
yes (incl. QA statement)
Type of assay:
mammalian cell gene mutation assay
Target gene:
TK +/- locus of the L5178Y mouse lymphoma cell line
Species / strain / cell type:
mouse lymphoma L5178Y cells
Details on mammalian cell type (if applicable):
Cell Culture
The stocks of cells are stored in liquid nitrogen at approximately -196 °C. Cells were routinely cultured in RPMI 1640 medium with Glutamax-1 and HEPES buffer (20 mM) supplemented with Penicillin (100 units/mL), Streptomycin (100 µg/mL), Sodium pyruvate (1 mM), Amphotericin B (2.5 µg/mL) and 10% donor horse serum (giving R10 media) at 37 °C with 5% CO2 in air. The cells have a generation time of approximately 12 hours and were subcultured accordingly. RPMI 1640 with 20% donor horse serum (R20) and without serum (R0) are used during the course of the study. Master stocks of cells were tested and found to be free of mycoplasma.


Cell Cleansing
The TK +/- heterozygote cells grown in suspension spontaneously mutate at a low but significant rate. Before the stocks of cells were frozen they were cleansed of homozygous (TK -/-) mutants by culturing in THMG medium for 24 hours. This medium contained Thymidine (9 µg/mL), Hypoxanthine (15 µg/mL), Methotrexate (0.3 µg/mL) and Glycine (22.5 µg/mL). For the following 24 hours the cells were cultured in THG medium (i.e. THMG without Methotrexate) before being returned to R10 medium.
Additional strain / cell type characteristics:
not applicable
Metabolic activation:
with and without
Metabolic activation system:
phenolbarbital/ beta-naphthaflavone
Test concentrations with justification for top dose:
Experiment 1, 4 hrs -S9: 0.31, 0.63, 1.25, 2.5, 5, 10, 15, 20 µg/mL
Experiment 1. 4 hrs, +S9: 2.81, 5.63, 11.25, 22.5, 33.75, 45, 90 and 180 µg/mL

Experiment 2: 24 hrs, -S9: 0.39, 0.78, 1.56, 3.13, 6.25, 12.5, 18.75 and 25 µg/mL
Experiment 2: 4 hrs, +S0: 1.56, 3.13, 6.25, 12.5, 25, 50, 75 and 100 µg/mL
Vehicle / solvent:
Acetone
Untreated negative controls:
no
Negative solvent / vehicle controls:
yes
Remarks:
Solvent treatment groups were used as the vehicle controls
True negative controls:
no
Positive controls:
yes
Positive control substance:
ethylmethanesulphonate
Remarks:
At 400 and 150 µg/mL for Experiments 1 and 2 respectively
Untreated negative controls:
no
Negative solvent / vehicle controls:
yes
Remarks:
Solvent treatment groups were used as the vehicle controls
True negative controls:
no
Positive controls:
yes
Positive control substance:
cyclophosphamide
Remarks:
At 1.5 µg/mL in the presence of S9
Details on test system and experimental conditions:
Test Item Preparation
Following solubility checks performed in-house, the test item was accurately weighed and formulated in acetone prior to serial dilutions being prepared. The test item had a molecular weight of 286.4. Therefore, the maximum proposed dose level in the solubility test was set at 2864 µg/mL, the maximum recommended dose level, and no correction for the purity of the test item was applied. Acetone is toxic to L5178Y cells at dose volumes greater than 0.5% of the total culture volume. Therefore, the test item was formulated at 286.4 mg/mL and dosed at 0.5% to give a maximum achievable dose level of 1432 µg/mL. There was no marked change in pH when the test item was dosed into media and the osmolality did not increase by more than 50 mOsm (Scott et al. 1991). The pH and osmolality readings are in the following table:

Dose level
µg/mL 0 5.59 11.19 22.38 44.75 89.5 179 358 716 1432
pH
7.38 7.38 7.40 7.41 7.43 7.42 7.44 7.44 7.44 7.44
Osmolality
mOsm 368 372 378 378 378 377 378 372 369 356
- Not required

No analysis was carried out to determine the homogeneity, concentration or stability of the test item formulation. The test item was formulated within two hours of it being applied to the test system. It is assumed that the formulation was stable for this duration. This is an exception with regard to GLP and has been reflected in the GLP compliance statement.


Control Preparation
Vehicle and positive controls were used in parallel with the test item. Solvent (acetone) (CAS No. 67-64-1) treatment groups were used as the vehicle controls. Ethylmethanesulphonate (EMS) (CAS No. 62-50-0) Sigma batch BCBN1209V at 400 µg/mL and 150 µg/mL for Experiment 1 and Experiment 2, respectively, was used as the positive control in the absence of metabolic activation. Cyclophosphamide (CP) (CAS No. 6055-19-2) Sigma-Aldrich batch MKBS0021V at 1.5 µg/mL was used as the positive control in the presence of metabolic activation. The positive controls were formulated in dimethyl sulfoxide (DMSO) (CAS No. 67-68-5).

Microsomal Enzyme Fraction
PB/BNF S9 was prepared in-house on 23 November 2014 from the livers of male Sprague-Dawley rats weighing approximately 250g. These had each received, orally, three consecutive daily doses of phenobarbital/β-naphthoflavone (80/100 mg per kg per day) prior to S9 preparation on the fourth day. This procedure was designed and conducted to cause the minimum suffering or distress to the animals consistent with the scientific objectives and in accordance with the Harlan Laboratories Ltd, Shardlow, UK policy on animal welfare and the requirements of the United Kingdom’s Animals (Scientific Procedures) Act 1986 Amendment Regulations 2012. The conduct of the procedure may be reviewed, as part of the Harlan Laboratories Ltd, Shardlow, UK Ethical Review Process. The S9 was stored at approximately 196 °C in a liquid nitrogen freezer.

S9-mix was prepared by mixing S9, NADP (5 mM), G-6-P (5 mM), KCl (33 mM) and MgCl2 (8 mM) in R0.

20% S9-mix (i.e. 2% final concentration of S9) was added to the cultures of the Preliminary Toxicity Test and of Experiments 1 and 2.

Preliminary Toxicity Test
A preliminary toxicity test was performed on cell cultures at 5 x 105 cells/mL, using a 4 hour exposure period both with and without metabolic activation (S9), and at 1.5 x 105 cells/mL using a 24-hour exposure period without S9. The dose range used in the preliminary toxicity test was 5.59 to 1432 µg/mL for all three of the exposure groups. Following the exposure period the cells were washed twice with R10, resuspended in R20 medium, counted and then serially diluted to 2 x 105 cells/mL, unless the mean cell count was less than 3 x 105 cells/mL in which case all the cells were maintained.

The cultures were incubated at 37 °C with 5% CO2 in air and sub-cultured after 24 hours by counting and diluting to 2 x 105 cells/mL, unless the mean cell count was less than 3 x 105 cells/mL in which case all the cells were maintained. After a further 24 hours the cultures were counted and then discarded. The cell counts were then used to calculate Suspension Growth (SG) values. The SG values were then adjusted to account for immediate post treatment toxicity, and a comparison of each treatment SG value to the concurrent vehicle control performed to give a percentage Relative Suspension Growth (%RSG) value.

Results from the preliminary toxicity test were used to set the test item dose levels for the mutagenicity experiments. Maximum dose levels were selected using the following criteria:

i) Maximum recommended dose level, 5000 µg/mL or 10 mM.

ii) The presence of excessive precipitate where no test item-induced toxicity was observed.

iii) Test item-induced toxicity, where the maximum dose level used should produce 10 to 20% survival (the maximum level of toxicity required). This optimum upper level of toxicity was confirmed by an IWGT meeting in New Orleans, USA (Moore et al 2002).


Mutagenicity Test
Experiment 1
Several days before starting the experiment, an exponentially growing stock culture of cells was set up so as to provide an excess of cells on the morning of the experiment. The cells were counted and processed to give 1 x 106 cells/mL in 10 mL aliquots in R10 medium in sterile plastic universals. The treatments were performed in duplicate (A + B), both with and without metabolic activation (2% S9 final concentration) at eight dose levels of the test item (0.31 to 20 µg/mL in the absence of metabolic activation, and 2.81 to 180 µg/mL in the presence of metabolic activation), vehicle and positive controls. To each universal was added 2 mL of S9 mix if required, 0.1 mL of the treatment dilutions, (0.2 or 0.15 mL for the positive control) and sufficient R0 medium to bring the total volume to 20 mL.

The treatment vessels were incubated at 37 °C for 4 hours with continuous shaking using an orbital shaker within an incubated hood.

Experiment 2
As in Experiment 1, an exponentially growing stock culture of cells was established. The cells were counted and processed to give 1 x 106 cells/mL in 10 mL cultures in R10 medium for the 4 hour treatment with metabolic activation cultures. In the absence of metabolic activation the exposure period was extended to 24 hours (Moore et al, 2007) therefore 0.3 x 106 cells/mL in 10 mL cultures were established in 25 cm2 tissue culture flasks. The treatments were performed in duplicate (A + B), both with and without metabolic activation (2% S9 final concentration) at eight dose levels of the test item (0.39 to 25 µg/mL in the absence of metabolic activation, and 1.56 to 100 µg/mL in the presence of metabolic activation), vehicle and positive controls. To each culture vessel was added 2 mL of S9 mix if required, 0.1 mL of the treatment dilutions, (0.15 or 0.2 mL for the positive controls) and sufficient R0 medium to give a final volume of 20 mL (R10 was used for the 24 hour exposure group).

The treatment vessels were incubated at 37 °C with continuous shaking using an orbital shaker within an incubated hood for 24 hours in the absence of metabolic activation and 4 hours in the presence of metabolic activation.
Evaluation criteria:
Please refer to "Any other information on materials and methods"
Statistics:
Please refer to "Any other information on materials and methods"
Key result
Species / strain:
mouse lymphoma L5178Y cells
Metabolic activation:
with and without
Genotoxicity:
negative
Cytotoxicity / choice of top concentrations:
cytotoxicity
Vehicle controls validity:
valid
Untreated negative controls validity:
not applicable
Positive controls validity:
valid
Additional information on results:
In the preliminary cytotoxicity text, there was evidence of marked reductions in the Relative Suspension Growth (%RSG) of cells treated with the test item when compared to the concurrent vehicle controls in all three of the exposure groups. The onset of test item-induced toxicity was sharp in all three of the exposure groups. A cloudy precipitate of the test item was observed at and above 44.75 µg/mL in the all three exposure groups, which turned to greasy/oily precipitate at higher concentrations. The increase in % RSG at 1432 µg/mL in the 4-hour exposure groups is attributed to the high levels of precipitate effectively reducing exposure to the cells. Based on the %RSG values observed, the maximum dose levels in the subsequent Mutagenicity Test were limited by test item induced toxicity.
Remarks on result:
other: all strains/cell types tested
Remarks:
Migrated from field 'Test system'.

Experiment 1

There was evidence of marked toxicity following exposure to the test item in both the absence and presence of metabolic activation, as indicated by the RTG and %RSG values (Tables 3 and 6). There was no evidence of reductions in viability (%V), therefore indicating that residual toxicity had not occurred (Tables 3 and 6). Based on the RTG and %RSG values observed, optimum levels of toxicity were considered to have been achieved in both the absence and presence of metabolic activation (Tables 3 and 6). The excessive toxicity observed at and above 15 µg/mL in the absence of metabolic activation, resulted in these dose levels not being plated for viability or 5-TFT resistance. The increase in survival observed in the presence of metabolic activation at 180 µg/mL is attributed to the presence of a precipitate at this dose level effectively reducing test item exposure to the cells. Acceptable levels of toxicity were seen with both positive control substances (Tables 3 and 6).

 

The vehicle controls had mutant frequency values that were considered acceptable for the L5178Y cell line at the TK +/- locus. Both of the positive controls produced marked increases in the mutant frequency per viable cell indicating that the test system was operating satisfactorily and that the metabolic activation system was functional (Tables 3 and 6).

 

The test item induced a very small but statistically significant and dose related (linear-trend) increases in the mutant frequency x 10-6per viable cell, in the absence of metabolic activation. However all the values were within the acceptable range for a vehicle control culture and the GEF was not exceeded, therefore considered to be of no toxicological significance. With no evidence of any toxicologically significant increases in mutant frequency, in either the absence or presence of metabolic activation, the test item was considered to have been adequately tested. A precipitate of the test item was observed at and above 90 µg/mL in the presence of metabolic activation.

 

The numbers of small and large colonies and their analysis are presented in Tables 4 and 7.

 

Experiment 2

As was seen previously, there was evidence of marked toxicity in both the absence and presence of metabolic activation, as indicated by the RTG and %RSG values (Tables 9 and 12). There was no evidence of marked reductions in viability (%V) therefore indicating that residual toxicity had not occurred (Tables 9 and 12). Based on the RTG values observed, optimum levels of toxicity were considered to have been achieved in the absence of metabolic activation. The same levels of toxicity were not observed at similar dose levels in the presence of metabolic activation than in Experiment 1, with maximum exposure occurring around 75 µg/mL. The excessive toxicity observed at and above 18.75 µg/mL in the absence of metabolic activation resulted in these dose levels not being plated for viability or 5-TFT resistance. Acceptable levels of toxicity were seen with both positive control substances (Tables 9 and 12).

 

The 24-hour exposure without metabolic activation (S9) treatment, demonstrated that the extended time point had a marked effect on the toxicity of the test item.

 

The vehicle (solvent) controls had mutant frequency values that were considered acceptable for the L5178Y cell line at the TK +/- locus. Both of the positive controls produced marked increases in the mutant frequency per viable cell indicating that the test system was operating satisfactorily and that the metabolic activation system was functional (Tables 9 and 12).

 

The test item did not induce any statistically significant or dose related (linear-trend) increases in the mutant frequency x 10-6per viable cell in either the absence or presence of metabolic activation (Tables 9 and 12). All of the values observed were within the acceptable range for a vehicle control culture and the GEF was not exceeded. Therefore, with no evidence of any toxicologically significant increases in mutant frequency at any of the dose levels, in either the absence or presence of metabolic activation, in either experiment, the test item was once again considered to have been adequately tested. A precipitate of the test item was observed at and above 75 µg/mL in the presence of metabolic activation.

 

The numbers of small and large colonies and their analysis are presented in Tables 10 and 13.

Conclusions:
Interpretation of results:
negative

The test item did not induce any toxicologically significant increases in the mutant frequency at the TK +/- locus in L5178Y cells.
Executive summary:

Introduction

The study was conducted according to a method that was designed to assess the potential mutagenicity of the test item on the thymidine kinase, TK +/-, locus of the L5178Y mouse lymphoma cell line. The method was designed to be compatible with the OECD Guidelines for Testing of Chemicals No.476 "In VitroMammalian Cell Gene Mutation Tests" adopted 21 July 1997, Method B17 of Commission Regulation (EC) No. 440/2008 of 30 May 2008, the US EPA OPPTS 870.5300 Guideline, and in alignment with the Japanese MITI/MHW guidelines for testing of new chemical substances.

 

Methods…….

Two independent experiments were performed. In Experiment 1, L5178Y TK +/- 3.7.2c mouse lymphoma cells (heterozygous at the thymidine kinase locus) were treated with the test item at eight dose levels in duplicate, together with vehicle (acetone), and positive controls using 4-hour exposure groups both in the absence and presence of metabolic activation (2% S9). In Experiment 2, the cells were treated with the test item at eight dose levels using a 4‑hour exposure group in the presence of metabolic activation (2% S9) and a 24-hour exposure group in the absence of metabolic activation.

 

The dose range of test item used in the main test was selected following the results of a preliminary toxicity test. The dose levels plated out for viability and expression of mutant colonies were as follows:

 

Experiment 1

Group

Concentration of Dioctanoyl peroxide (CAS# 762-16-3) (µg/mL) plated for viability and mutant frequency

4-hour without S9

0.31, 0.63, 1.25, 2.5, 5, 10

4-hour with S9 (2%)

11.25, 22.5, 33.75, 45, 90, 180

 

Experiment 2

Group

Concentration of Dioctanoyl peroxide (CAS# 762-16-3) (µg/mL) plated for viability and mutant frequency

24-hour without S9

0.39, 0.78, 1.56, 3.13, 6.25, 12.5

4-hour with S9 (2%)

6.25, 12.5, 25, 50, 75, 100

 

 

Results…………

The maximum dose levels used in the Mutagenicity Test were limited by test item-induced toxicity. Precipitate of the test item was observed at and above 75 µg/mL in the presence of metabolic activation only. The vehicle controls (acetone) had mutant frequency values that were considered acceptable for the L5178Y cell line at the TK +/- locus. The positive control treatment induced marked increases in the mutant frequency indicating the satisfactory performance of the test and of the activity of the metabolizing system.

 

The test item did not induce any toxicologically significant dose-related (linear-trend) increases in the mutant frequency at any of the dose levels, either with or without metabolic activation, in either the first or the second experiment.

 

Conclusion

The test item did not induce any toxicologically significant increases in the mutant frequency at the TK +/- locus in L5178Y cells.

Endpoint:
in vitro gene mutation study in bacteria
Remarks:
Type of genotoxicity: gene mutation
Type of information:
experimental study
Adequacy of study:
key study
Study period:
Experimental starting date: 4th February 2015 Experimental completion date: 27th February 2015
Reliability:
1 (reliable without restriction)
Rationale for reliability incl. deficiencies:
other: Study conducted to GLP and in compliance with agreed protocols, with no or minor deviations from standard test guidelines and/or minor methodological deficiencies, which do not effect the quality of relevant results
Qualifier:
according to guideline
Guideline:
OECD Guideline 471 (Bacterial Reverse Mutation Assay)
Deviations:
no
Qualifier:
according to guideline
Guideline:
EU Method B.13/14 (Mutagenicity - Reverse Mutation Test Using Bacteria)
Deviations:
no
GLP compliance:
yes (incl. QA statement)
Type of assay:
bacterial reverse mutation assay
Target gene:
Histidine operon for Salmonella
Tryptophan operon for Escherichia
Species / strain / cell type:
S. typhimurium TA 1535, TA 1537, TA 98 and TA 100
Details on mammalian cell type (if applicable):
Not applicable
Species / strain / cell type:
E. coli WP2 uvr A
Details on mammalian cell type (if applicable):
Not applicable
Metabolic activation:
with and without
Metabolic activation system:
Phenobarbitome/ neta-naphthoflavone induced rat liver, S9
Test concentrations with justification for top dose:
Experiment 1: 1.5, 5, 15, 50, 150, 500, 1500 and 5000 µg per plate

Experiment 2:
All Salmonella strains: 0.5, 1.5, 5, 15, 50, 150, 500 and 1500 µg per plate
E.coli strain WP2uvrA: 15, 50, 150, 300, 500, 1000, 1500, 2500 and 5000 µg/plate
Vehicle / solvent:
Dimethyl sulphoxide
Untreated negative controls:
yes
Remarks:
Spontaneous mutation rate
Negative solvent / vehicle controls:
yes
Remarks:
Dimethyl sulphoxide
True negative controls:
no
Positive controls:
yes
Positive control substance:
N-ethyl-N-nitro-N-nitrosoguanidine
Remarks:
-S9 (2 µg/plate for Wp2uvrA, 3 µg/plate for TA100 and 5 µg/plate for TA1535)
Untreated negative controls:
yes
Remarks:
Spontaneous mutation rate
Negative solvent / vehicle controls:
yes
Remarks:
Dimethyl sulphoxide
True negative controls:
no
Positive controls:
yes
Positive control substance:
9-aminoacridine
Remarks:
-S9 (80 µg/plate fpr TA1537)
Untreated negative controls:
yes
Remarks:
Spontaneous mutation rate
Negative solvent / vehicle controls:
yes
Remarks:
Dimethyl sulphoxide
True negative controls:
no
Positive controls:
yes
Positive control substance:
4-nitroquinoline-N-oxide
Remarks:
-S9 (0.2 µg/plate for TA98)
Untreated negative controls:
yes
Remarks:
Spontaneous mutation rate
Negative solvent / vehicle controls:
yes
Remarks:
Dimethyl sulphoxide
True negative controls:
no
Positive controls:
yes
Positive control substance:
other: 2-Aminoanthracene (2AA)
Remarks:
+S9 (1 µg/plate for TA100, 2 µg/plate for TA1535 and TA1537, and 10 µg/plate for WP2uvrA)
Untreated negative controls:
yes
Remarks:
Spontaneous mutation rate
Negative solvent / vehicle controls:
yes
Remarks:
Dimethyl sulphoxide
True negative controls:
no
Positive controls:
yes
Positive control substance:
benzo(a)pyrene
Remarks:
+S9 (5 µg/plate for TA98)
Details on test system and experimental conditions:
Test for Mutagenicity (Experiment 1) – Plate Incorporation Method
Dose selection
Dioctanoyl peroxide (CAS# 762-16-3) was tested using the following method. The maximum concentration was 5000 ug/plate (the maximum recommended dose level). Eight concentrations (1.5, 5, 15, 50, 150, 500, 1500 and 5000 ug/plate) were assayed in triplicate against each tester strain, using the direct plate incorporation method.

Without Metabolic Activation
0.1 mL of the appropriate concentration of Dioctanoyl peroxide (CAS# 762-16-3), vehicle or appropriate positive control was added to 2 mL of molten trace amino-acid supplemented media containing 0.1 mL of one of the bacterial strain cultures and 0.5 mL of phosphate buffer. These were then mixed and overlayed onto a Vogel Bonner agar plate. Negative (untreated) controls were also performed on the same day as the mutation test. Each concentration of the test item, appropriate positive, vehicle and negative controls, and each bacterial strain, was assayed using triplicate plates.

With Metabolic Activation
The procedure was the same as described previously (see 4.5.1.2) except that following the addition of the Dioctanoyl peroxide (CAS# 762-16-3) formulation and bacterial culture, 0.5 mL of S9 mix was added to the molten trace amino-acid supplemented media instead of phosphate buffer.

Incubation and Scoring
All of the plates were incubated at 37 deg C± 3 deg C for approximately 48 hours and scored for the presence of revertant colonies using an automated colony counting system. The plates were viewed microscopically for evidence of thinning (toxicity). Manual counts were performed at 5000 ug/plate because of test item precipitation. Several further manual counts were required, predominantly due to interference in the base agar e.g. minor precipitation of salts or marks on the base of the plates slightly distorting the counts.


Test for Mutagenicity (Experiment 2) – Plate Incorporation Method
As Experiment 1 was deemed weakly positive the plate incorporation method was employed for Experiment 2 in the presence and absence of metabolic activation to confirm initial findings.

Dose selection
The dose range used for Experiment 2 was determined by the results of Experiment 1 and was as follows:

All Salmonella strains (presence and absence of S9-mix): 0.5, 1.5, 5, 15, 50, 150, 500, 1500 µg/plate.
E.coli strain WP2uvrA (presence and absence of S9-mix): 15, 50, 150, 300, 500, 1000, 1500, 2500, 5000 µg/plate.

Eight dose levels of Dioctanoyl peroxide (CAS# 762-16-3) were selected in Experiment 2 (Salmonella strains) in order to achieve both four non-toxic dose levels and the toxic limit. Nine (including intermediate) dose levels of Dioctanoyl peroxide (CAS# 762-16-3) were selected for Escherichia coli strain WP2uvrA to establish a better dose-response relationship in both the absence and presence of S9 mix following the observation of statistically significant increases in revertant colony frequency in the first mutation test.

Without Metabolic Activation
The procedure was the same as described previously.

With Metabolic Activation
The procedure was the same as described previously.

Incubation and Scoring
All of the plates were incubated at 37°C± 3°C for approximately 48 hours and scored for the presence of revertant colonies using an automated colony counting system. The plates were viewed microscopically for evidence of thinning (toxicity). Several manual counts were required due to bubbles in the base agar slightly distorting the actual plate count.



4.5.2.3 With Metabolic Activation
The procedure was the same as described previously (see 4.5.1.3).


4.5.2.4 Incubation and Scoring
All of the plates were incubated at 37 deg C± 3 C for approximately 48 hours and scored for the presence of revertant colonies using an automated colony counting system. The plates were viewed microscopically for evidence of thinning (toxicity). Several manual counts were required due to bubbles in the base agar slightly distorting the actual plate count.
Evaluation criteria:
There are several criteria for determining a positive result. Any, one, or all of the following can be used to determine the overall result of the study:

1. A dose-related increase in mutant frequency over the dose range tested (De Serres and Shelby, 1979).
2. A reproducible increase at one or more concentrations.
3. Biological relevance against in-house historical control ranges.
4. Statistical analysis of data as determined by UKEMS (Mahon et al., 1989).
5. Fold increase greater than two times the concurrent solvent control for any tester strain (especially if accompanied by an out of historical range response (Cariello and Piegorsch, 1996)).

A test item will be considered non-mutagenic (negative) in the test system if the above criteria are not met.

Although most experiments will give clear positive or negative results, in some instances the data generated will prohibit making a definite judgment about test item activity. Results of this type will be reported as equivocal.
Key result
Species / strain:
S. typhimurium TA 1535, TA 1537, TA 98 and TA 100
Metabolic activation:
with and without
Genotoxicity:
negative
Cytotoxicity / choice of top concentrations:
no cytotoxicity
Vehicle controls validity:
valid
Untreated negative controls validity:
not examined
Positive controls validity:
valid
Key result
Species / strain:
E. coli WP2 uvr A
Metabolic activation:
with and without
Genotoxicity:
positive
Cytotoxicity / choice of top concentrations:
no cytotoxicity
Vehicle controls validity:
valid
Untreated negative controls validity:
not examined
Positive controls validity:
valid
Additional information on results:
The vehicle (dimethyl sulphoxide) control plates gave counts of revertant colonies within the normal range. All of the positive control chemicals used in the test induced marked increases in the frequency of revertant colonies, both with or without metabolic activation. Thus, the sensitivity of the assay and the efficacy of the S9-mix were validated.

The maximum dose level of Dioctanoyl peroxide (CAS# 762-16-3) in the first experiment was selected as the maximum recommended dose level of 5000 µg/plate. Dioctanoyl peroxide (CAS# 762-16-3) induced a visible reduction in the growth of the bacterial background lawns of all of the tester strains dosed in the absence and presence of S9-mix, starting from 500 µg/plate, in the first mutation test. Consequently the test item was either tested up to the maximum recommended dose level of 5000 ug/plate (Escherichia coli strain WP2uvrA) or the toxic limit (Salmonella strains). The toxicity of Dioctanoyl peroxide (CAS# 762-16-3) to the bacterial cells was very similar in the second experiment with weakened background lawns again noted starting from 500 µg/plate to the Salmonella strains and at 5000 µg/plate to Escherichia coli strain WP2uvrA. A test item precipitate (greasy in appearance) was noted at and above 500 ug/plate; this observation did not prevent the scoring of revertant colonies.

In the first mutation test, small but statistically significant increases in WP2uvrA revertant colony frequency were initially noted from 150 and 500 µg/plate in the absence and presence of S9-mix respectively. It should be noted that toxicity was observed at 5000 µg/plate in both the absence and presence of S9-mix. These increases exhibited a modest dose response relationship with a number of individual counts exceeding the maximum historical control value of the strain. Therefore (for confirmation and reproducibility reasons) the second experiment was performed using the same dosing conditions as the first mutation test (plate incorporation method) with the inclusion of a number of intermediate dose levels. The results from the first experiment were reproduced in the second mutation test for E.coli strain WP2uvrA in both the presence and absence of S9-mix with dose-related and statistically significant increases noted at the upper sub-toxic test item dose levels. These increases again exhibited a modest dose response with a number of individual counts again exceeding the maximum historical control value of the strain and, in the absence of S9 mix, a twofold increase noted over the concurrent vehicle control. Therefore, Dioctanoyl peroxide (CAS# 762-16-3) was considered to have induced a dose-related, reproducible and statistically significant increase in the frequency of WP2uvrA revertant colonies in both the absence and presence of S9-mix at sub-toxic dose levels.

There were no toxicologically significant increases in the frequency of revertant colonies recorded for any of the Salmonella strains, with any dose of Dioctanoyl peroxide (CAS# 762-16-3), either with or without S9 mix in two separate experiments employing plate incorporation methodology. A small, statistically significant increase in TA100 revertant colony frequency was observed in the presence of S9-mix at 15 µg/plate in the second mutation test. This increase was considered to be of no biological relevance because there was no evidence of a dose-response relationship or reproducibility. Furthermore, the individual revertant colony counts at 15 µg/plate were within the in-house historical untreated/vehicle control range for the tester strain and the fold increase was only 1.4 times the concurrent vehicle control.

Remarks on result:
other: all strains/cell types tested
Remarks:
Migrated from field 'Test system'.

Prior to use, the master strains were checked for characteristics, viability and spontaneous reversion rate (all were found to be satisfactory). The amino acid supplemented top agar and the S9-mix used in both experiments was shown to be sterile. A 50 mg/mL formulation of Dioctanoyl peroxide (CAS# 762-16-3)was also shown to be sterile. These data are not given in the report. 

 

Results for the negative controls (spontaneous mutation rates) were considered to be acceptable. These data are for concurrent untreated control plates performed on the same day as the Mutation Test.

Conclusions:
Interpretation of results (migrated information):
positive considered to be weakly mutagenic to one strain of bacteria (Escherichia coli WP2uvrA)

Dioctanoyl peroxide (CAS# 762-16-3) was considered to be weakly mutagenic to one strain of bacteria (Escherichia coli WP2uvrA) under the conditions of the bacterial reverse mutation assay (Ames Test).
Executive summary:

Introduction

The test method was designed to be compatible with the guidelines for bacterial mutagenicity testing published by the major Japanese Regulatory Authorities including METI, MHLW and MAFF, the OECD Guidelines for Testing of Chemicals No. 471 "Bacterial Reverse Mutation Test", Method B13/14 of Commission Regulation (EC) number 440/2008 of 30 May 2008 and the USA, EPA OCSPP harmonized guideline - Bacterial Reverse Mutation Test.

 

Methods…….

Salmonella typhimuriumstrains TA1535, TA1537, TA98 and TA100 and Escherichia coli strain WP2uvrA were treated with Dioctanoyl peroxide (CAS# 762-16-3) using the Ames plate incorporation method at up to nine dose levels, in triplicate, both with and without the addition of a rat liver homogenate metabolizing system (10% liver S9 in standard co‑factors). The dose range for Experiment 1 was predetermined and was 1.5 to 5000 ug/plate. The experiment was repeated on a separate day using fresh cultures of the bacterial strains and fresh formulations of Dioctanoyl peroxide (CAS# 762-16-3). The dose range was amended following the results of Experiment 1 and ranged between 0.5 and 5000 µg/plate, depending on bacterial strain type and presence or absence of S9-mix.

 

Eight dose levelsofDioctanoyl peroxide (CAS# 762-16-3)were selected in Experiment 2 (Salmonellastrains) in order to achieve both four non-toxic dose levels and the toxic limit. Nine (including intermediate) dose levelsof Dioctanoyl peroxide (CAS# 762-16-3) were selected forEscherichia colistrain WP2uvrA to establish a better dose-response relationship in both the absence and presence of S9‑mix following the observation of statistically significant increases in revertant colony frequency in the first mutation test.

 

Results….

The vehicle (dimethyl sulphoxide) control plates gave counts of revertant colonies within the normal range. All of the positive control chemicals used in the test induced marked increases in the frequency of revertant colonies, both with or without metabolic activation. Thus, the sensitivity of the assay and the efficacy of the S9-mix were validated.

 

The maximum dose level of Dioctanoyl peroxide (CAS# 762-16-3) in the first experiment was selected as the maximum recommended dose level of 5000 µg/plate. Dioctanoyl peroxide (CAS# 762-16-3) induced a visible reduction in the growth of the bacterial background lawns of all of the tester strains dosed in the absence and presence of S9-mix, starting from 500 µg/plate, in the first mutation test. Consequently the test item was either tested up to the maximum recommended dose level of 5000 ug/plate (Escherichia colistrain WP2uvrA) or the toxic limit (Salmonella strains). The toxicity of Dioctanoyl peroxide (CAS# 762-16-3) to the bacterial cells was very similar in the second experiment with weakened background lawns again noted starting from 500 µg/plate to theSalmonella strains and at 5000 µg/plate to Escherichia colistrain WP2uvrA. A test item precipitate (greasy in appearance) was noted at and above 500 ug/plate; this observation did not prevent the scoring of revertant colonies.

 

In the first mutation test, small but statistically significant increases in WP2uvrA revertant colony frequency were initially noted from 150 and 500 µg/plate in the absence and presence of S9-mix respectively. It should be noted that toxicity was observed at 5000 µg/plate in both the absence and presence of S9-mix. These increases exhibited a modest dose response relationship with a number of individual counts exceeding the maximum historical control value of the strain. Therefore (for confirmation and reproducibility reasons) the second experiment was performed using the same dosing conditions as the first mutation test (plate incorporation method) with the inclusion of a number of intermediate dose levels. The results from the first experiment were reproduced in the second mutation test for E.colistrain WP2uvrA in both the presence and absence of S9-mix with dose-related and statistically significant increases noted at the upper sub-toxic test item dose levels. These increases again exhibited a modest dose response with a number of individual counts again exceeding the maximum historical control value of the strain and, in the absence of S9‑mix, a twofold increase noted over the concurrent vehicle control. Therefore,Dioctanoyl peroxide (CAS# 762-16-3) was considered to have induced a dose-related, reproducible and statistically significant increase in the frequency of WP2uvrA revertant colonies in both the absence and presence of S9-mix at sub-toxic dose levels. 

 

There were no toxicologically significant increases in the frequency of revertant colonies recorded for any of theSalmonella strains, with any dose of Dioctanoyl peroxide (CAS# 762-16-3), either with or without S9‑mix in two separate experiments employing plate incorporation methodology. A small, statistically significant increase in TA100 revertant colony frequency was observed in the presence of S9-mix at 15 µg/plate in the second mutation test. This increase was considered to be of no biological relevance because there was no evidence of a dose-response relationship or reproducibility. Furthermore, the individual revertant colony counts at 15 µg/plate were within the in-house historical untreated/vehicle control range for the tester strain and the fold increase was only 1.4 times the concurrent vehicle control.

 

Conclusion

Dioctanoyl peroxide (CAS# 762-16-3) was considered to be weakly mutagenic to one strain of bacteria (Escherichia coliWP2uvrA) under the conditions of the bacterial reverse mutation assay (Ames Test).

Endpoint conclusion
Endpoint conclusion:
no adverse effect observed (negative)

Genetic toxicity in vivo

Endpoint conclusion
Endpoint conclusion:
no study available

Additional information

Justification for classification or non-classification

Based on the available information the substance is not classified as mutagenic.