Squalene-rich fraction obtained from vegetable oil deodorizer distillate by transesterification, crystallisation and vacuum distillation

A study was performed to investigate the potential mutagenicity of constituent ‘glycerides, C16 and C18-unsatd. and C18-unsatd. hydroxy’ (as castor oil) through the reverse mutation assay using Salmonella typhimurium strains TA 1535, TA 97, TA 98 and TA 100, along with Aroclor-induced 10 and 30% liver fraction for metabolic activation (S9-mix). Salmonella strains were exposed to five different concentrations (0, 100, 333, 1,000, 3,333 and 10,000 µg/plate) of the substance and vehicle control (DMSO), in both absence and the presence of S9-mix. Three parallel plates were used for each dose. Concurrent positive controls, 2-aminoanthracene (for all strains, with metabolic activation), 4-nitro-o-phenylenediamine (on TA 98, without metabolic activation), sodium azide (TA100 and TA1535) and 9-aminoacridine (TA97) were also included in the assays. In both absence and presence of the S9-mix, the substance did not cause a significant increase in the number of revertant colonies in comparison to the control. Both positive and vehicle control groups were also valid. Hence, under the test conditions, the substance was considered to be non-mutagenic in Salmonella typhimurium mutation assay (Irwin, 1992 (1)).

A study was performed to investigate the genotoxic potential of the constituent ‘glycerides, C16 -18 and C18-unsatd.’ (as castor oil) to induce chromosomal aberrations in Chinese hamster ovary cells. Chinese hamster ovary cells were incubated with 0, 1,600, 3,000 and 5,000 µg/mL of the substance or solvent (DMSO). Cells were arrested in first metaphase by addition of colcemid and harvested by mitotic shake off, fixed, and stained in 6% Giemsa. Where relevant S9 was from the livers of Aroclor 1254-induced male Sprague Dawley rats was added. No significant chromosome aberrations were observed when treated with concentrations up to 5,000 µg/mL of the substance with and without S9. Hence, under the test conditions, the substance was considered to be non-genotoxic to Chinese hamster ovary cells in chromosomal aberration assay (Irwin, 1992 (2)).

A study was performed to investigate the genotoxic potential of the constituent ‘glycerides, C16 -18 and C18 -unsatd.’ (as castor oil) to induce sister-chromatid exchanges in Chinese hamster ovary cells. Chinese hamster ovary cells were incubated with 160, 500, 1,600 and 5,000 µg/mL of the substance or solvent (DMSO). Cells were then collected by mitotic shake-off, fixed, air-dried and stained. Where relevant S9 was from the livers of Aroclor 1254-induced male Sprague Dawley rats was added. No significant sister-chromatid exchange was observed in Chinese hamster ovary cells treated with concentrations up to 5,000 µg/mL of the substance with and without S9. Hence, under the test conditions, the substance was considered to be non-genotoxic to Chinese hamster ovary cells in sister-chromatid exchange assay (Irwin, 1992 (3)).

A study was conducted to determine the mutagenic potential of the constituent ‘glycerides, C16 -18 and C18 -unsatd.’ (as palm oil) according to OECD guideline 471. Salmonella typhimurium strains TA1535, TA1537, TA98 and TA100 were treated with the substance using the Ames plate incorporation method at five dose levels (up to 5,000 µg/plate), with and without metabolic activation. Two independent assays were conducted. Under the conditions of the study, the substance was considered to be non-mutagenic (IUCLID DS, 2000).

A study was conducted to determine the potential mutagenicity of the constituent ‘glycerides, C16 -18 and C18 -unsatd.’ (as pine nut oil) according to the OECD guideline 471. Salmonella typhimurium strains TA1535, TA1537, TA98 and TA100 and Escherichia coli strain WP2uvrA- were treated with the substance using the Ames plate incorporation method at five dose levels, in triplicate, both with and without the addition of a rat liver homogenate metabolising system (10% liver S9 in standard co-factors). The dose range was determined in a preliminary toxicity assay and was 3 to 5,000 μg/plate. The experiment was repeated using the same dose range as the range-finding test. The substance precipitated at the two highest concentrations tested and therefore it was tested up to the third dose level of 1,000 μg/plate. No precipitate was observed on the plates at any of the doses tested in either the presence or absence of S9 -mix. No significant increases in the frequency of revertant colonies were recorded for any of the bacterial strains, with any dose of the substance, either with or without metabolic activation. Under the conditions of this test, the substance was considered to be non-mutagenic (Speijers, 2009).

A study was conducted to determine the mutagenicity potential of the constituent ‘glycerides, C8 -18 and C18 -unsatd.’ (as coconut oil) according to an unspecified method. Under the study conditions, the substance was found to be non-mutagenic in Salmonella typhimurium reverse mutation assay at a concentration of 5,000 µg/plate (Biotech Index, 1970).

A study was conducted to determine the mutagenicity potential of the constituent ‘glycerides, C8 -18 and C18 -unsatd.’ (as coconut oil) in a bacterial reverse mutation assay using Salmonella typhimurium strains. The substance was tested at concentrations of 50, 150, 500, 1,500 and 5,000 µg/plate with Salmonella typhimurium TA 1535, TA 1537, TA 98 and TA 100. Under the study conditions, the substance was found to be non-mutagenic in the Salmonella typhimurium gene mutation assay (IUCLID DS, 2000).

A study was conducted to determine the mutagenic potential of the test substance techincal white oil using the modified Ames test according to the Blackbum et al (1984, 1986) protocol. Salmonella typhimurium strains TA98 in the presence of metabolic activation (Hamster liver induced S9-Aroclor 1254) was treated with the DMSO extract of the test substance using range of doses that provided a definition of the response. A tangent to the dose-response curve at zero dose (Mutagenicity Index) was computed (Blackburn el al., 1986) and used as a measure of mutagenic potency. The assay was judged to be positive if the Mutagenicity Index was greater than 1. In the study, the Mutagenicity Index was 0 for the technical white oil. Under the study conditions, the test substance was considered to be non-mutagenic in the modified Ames test, with metabolic activation (Roy, 1988).

A study was conducted to determine the mutagenic potential of the test substance squalene using bacterial reverse mutation assay (Ames test) according to the National Toxicology Program protocol. Salmonella typhimurium strains TA1535, TA97, TA98 and TA100 were treated with the test substance at eight dose levels (i.e., 1, 3.3, 10, 33, 100, 333, 1000, 3333 μg/plate), in triplicate, both with and without the addition of a rat and hamster liver homogenate metabolizing system (10% and 30% liver S9 in standard co-factors). The vehicle (acetone) 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. Test substance precipitate was observed on the plates at ≥33 μg/plate of the doses tested in either the presence or absence of S9 -mix. There were no increases in the frequency of revertant colonies recorded for any of the bacterial strains, with any dose of the test substance, either with or without metabolic activation (S9 -mix). Under the study conditions, the test substance was considered to be non-mutagenic in the Ames test, with and without metabolic activation (NTP, 1990).

A study was conducted to evaluate the genotoxic potential of test substance, squalene in human lymphocytes using an in vitro mammalian cell micronucleus test. Micronucleus preparation was performed according to the procedures of Fenech (2000) and Palus et al. (2003). The human lymphocytes cells were treated with 1250, 2500, 5000, 10,000, 20,000 µg/mL concentrations of squalene for 24 h and 48 h without metabolic activation. Totally two thousand binucleated cells (1000 cells per donor) for each treatment of squalene were examined blindly, following the scoring criteria adopted by the Human Micronucleus Project (Bonassi et al., 2001). Five hundred cells per donor (totally 1000 cells) were scored to evaluate the nuclear division index (NDI). NDI was calculated using the following formula: [(1 N1) +(2 N2) +(3 (N3 + N4))]/N; where N1 to N4 represent the number of cells with one to four nuclei and N is the total number of viable cells scored (Surrales et al., 1995). Squalene did not affect the frequency of binucleate cells with micronucleus in all treatment groups compared to the negative control. Squalene also decreased the nuclear division index (NDI) insignificantly. Under the study conditions, the test substance was considered to be non-genotoxic to human lymphocytes in an in vitro mammalian cell micronucleus test (Yüzbaşıoğlu, 2013).

A study was conducted to evaluate the genotoxic potential of test substance, squalene in human lymphocytes using an in vitro chromosomal aberration (CA) test. The methods of Evans (1984) and Perry and Thompson (1984) were followed in CA test with minor modifications (Yüzbasıog˘ lu et al., 2006). The human lymphocytes cells were treated with 1250, 2500, 5000, 10,000, 20,000 µg/mL concentrations of squalene for 24 h and 48 h without metabolic activation. To evaluate the chromosomal aberrations, 200 well spread metaphases (100 metaphases from each donor) were scored blindly, for each treatment. The mean frequency of abnormal cells and the number of CAs per cell (CAs/cell) were calculated. The mitotic index (MI) was determined by scoring of 1000 cells from each donor. At 24 h treatment, while 1250, 2500, 10,000 and 20,000 µg/mL concentrations reduced the frequency of abnormal cell, 5000 µg/mL concentration increased this frequency. However, neither of them was significant. Similarly, squalene decrease d the frequency of CA/cell compared to negative control but these reductions were not significant. At 48 h treatment, squalene increased the frequency of aberrations and CA/cell but neither of them were significant compared to control. Squalene did not affect MI significantly at all concentrations and treatment periods (24 h and 48 h) compared to negative control. Under the study conditions, the test substance was considered to be non-genotoxic to human lymphocytes in an in vitro mammalian chromosome aberration test (Yüzbaşıoğlu, 2013).

A study was conducted to evaluate the genotoxic potential of test substance, squalene in human lymphocytes using an in vitro sister chromatid exchange (SCE) assay in mammalian cells. The methods of Evans (1984) and Perry and Thompson (1984) were followed in SCE tests with minor modifications (Yüzbasıog˘ lu et al., 2006). For the SCE assay, the slides were stained with Giemsa, according to Speit and Houpter’s (1985) method, with some modifications (Yüzbasıoglu et al., 2006). The human lymphocytes cells were treated with 1250, 2500, 5000, 10,000, 20,000 µg/mL concentrations of squalene for 24 h and 48 h without metabolic activation. In order to score SCEs, 25 second-division metaphases (M2) were analyzed blindly for each donor. In addition to SCEs, cells were analyzed for the relative frequency of first division metaphases (M1), second-division metaphases (M2) and third and subsequent division metaphases (M3). Replication index (RI) is the average number of replications completed metaphase cells and was calculated. Squalene significantly increased SCE/cell at all concentrations (except 10,000 µg/mL) at 24 h treatment compared to negative control. However, this increase was poorly concentration-dependent. At 48 h treatment, however, squalene did not increase SCE/cell compared to control. 10,000 µg/mL concentration induced SCE/cell just the same amount to control group. SCE/cell in all the other concentrations was lower than that of negative control group. Other side, squalene did not affect RI significantly at all concentrations and treatment periods (24 h and 48 h) compared to negative control. Under the study conditions, the test substance was considered to be non-genotoxic to human lymphocytes in an in vitro sister chromatid exchange assay in mammalian cells (Yüzbaşıoğlu, 2013).

A study was conducted to evaluate the genotoxic potential of test substance, squalene in human lymphocytes using an in vitro alkaline comet assay in mammalian cells. The alkaline comet assay was performed according to Singh et al. (1988) with a slight modification (Mamur et al., 2010). The human lymphocytes cells were treated with 1250, 2500, 5000, 10,000, 20,000 µg/mL concentrations of squalene for 1 h at 37 deg C without metabolic activation. The slides were incubated for 20 min ice-cold electrophoresis solution, followed by electrophoresis at 25 V, 300 mA for 20 min. Each slide was stained with 50 µL of 20 µg/mL ethidium bromide. The slides were examined using a fluorescent microscope equipped with an excitation filter of 546 nm and a barrier filter of 590 nm at 400 magnification. The tail lenght (µm) and tail intensity (%) of 100 comets on each slide (a total of 200 comets per concentration) were examined, using specialized Image Analysis System. Squalene decreased comet tail length (CTL) at 1250 and 2500 µg/mL concentrations but this decrease was significant at only 2500 µg/mL concentration compared to negative control. Squalene increased the CTL at the other three concentrations in isolated lymphocytes but this increase was not statistically significant. Also, squalene increased the comet tail intensity (CTI) at 1250, 2500, 5000 and 20,000 µg/mL concentrations but decreased the CTI at 10,000 µg/mL concentration. However, neither of them was statistically significant. Under the study conditions, the test substance was considered to be non-genotoxic to human lymphocytes in an in vitro alkaline comet assay in mammalian cells (Yüzbaşıoğlu, 2013).

A study was performed to investigate the genotoxic potential of plant sterols in human lymphocytes. No significant chromosome aberrations were observed when treated with concentrations up to 200 µg/mL of the substance, with and without metabolic activation (S9). Under the test conditions, the substance was considered to be non-genotoxic to human lymphocytes in a chromosomal aberration assay (ANZFA, 2001).

Similar negative results were obtained in two studies of Akhurst LC and Taylor K (Feb 03, 1997) and Akhurst LC and Taylor K (Feb 12, 1997) conducted with  fresh human lymphocyte at concentration of  ≤100 μg/ml (phytosterol ester) and  ≤160 μg/ml (plant sterol) respectively in a chromosome aberration assay. These studies have been cited in the ANZFA risk analysis report (ANZFA, 2001).

A study was performed to investigate the genotoxic potential of β-sitosterol. The test substance at concentration of 1000 µM was incubated with gamma DNA for 1 h at 37 degree Celsius and DNA strand breaks were identified by electrophoresis under neutral conditions. Under the test conditions, the substance did not induce DNA damage (Tice, 1997).

A study was performed to investigate the potential mutagenicity of the constituent β –sitosterol (at concentrations upto 5000 µg/plate (12 µmol/plate)) through the reverse mutation assay using Salmonella typhimurium strains TA98, TA100, TA1535, TA1537 and TA1538 without metabolic activation. The substance did not cause a significant increase in the number of revertant colonies. Under the test conditions, the substance was considered to be non-mutagenic in Salmonella mutation assay (Ames test) (Tice, 1999).

Similar negative results were obtained in two studies of Lawson et al., 1989 and Malaveille et al., 1982  conducted with Salmonella typhimurium strains T98 and TA100 with and without metabolic activation. Lawson et al used concentrations 150, 300, and 600 µg/plate (0.36, 0.72, and 1.4 mol/plate) and Malaveille et al used 1000 µg/plate (2.4 µmol/plate). These studies have been cited in the Integrated Laboratory Systems (ILS) review of toxicological literature.

A study was performed to investigate the potential of phytosterols to induce mutation in Salmonella typhimurium strains TA 1535, TA 1537, TA 98 and TA 100 in Ames test. No mutations were observed when treated with concentrations up to 5000 µg/mL of the substance, with and without metabolic activation (S9).

Under the test conditions, the substance was considered to be non-mutagenic in Ames test (ANZFA, 2001).

Similar negative results were obtained in two studies of Gant RA (1996) and Kitching J and Anderson DH (1998) conducted with Salmonella typhimurium strains TA98, TA100, TA1535, TA1537 and Salmonella typhimurium TA98, TA100, TA1535, TA1537 and E. coli CM891 WP2 respecively with and without metabolic activation at concentration of 5000 µg/plate. These studies have been cited in the ANZFA risk analysis report

According to the CIR review report, d-alpha tocopherol was found to be negative in a Salmonella typhimurium reverse mutation assay at a concentration of 0.033–10 mg/plate (Fiume, 2002).

Antigenotoxicity effects of the constituent dl-alpha tocopherol at 10 µM concentrations was evaluated by observing the reduction of chromosomal breaks induced by 7,12-dimethylbenz(a)anthracene in leucocyte cultures. The addition of the substance to leucocyte cultures reduced the number of chromosome breaks induced by 1.6 µM 7,12 -dimethylbenz(a)anthracene. Similar effects were observed in another anti-genotoxicity study of Shamberger et al., 1979 cited in the JECFA evaluation, where dl-alpha-tocopherol markedly reduced the mutagenic effect of malonaldehyde and ß-propiolactone in five strains of Salmonella typhimurium, which mutated with a frameshift mechanism. Under the test conditions, the substance was considered to be non-genotoxic (JECFA, 1987).