Cytotoxicity and Genotoxicity Assessments of Batik Industrial Wastewater on V79 Cells

Authors

  • Normah Awang
  • Siti Nur Farahin Ahlam
  • Kok Meng Chan

Keywords:

batik wastewater, cytotoxicity, genotoxicity, V79 cells

Abstract

Batik is well known in Malaysian textile industry. It is one of the the rapidly growing industries inherited from a generation to another. The manufacturer of batik industry usually discharges the wastewater containing hazardous pollutants (a mixture of chemicals especially reactive dyes, waxes, alum, resin, and sodium silicate) into the environment without any preliminary treatment. This study was conducted to assess the cytotoxicity and genotoxicity of batik industrial wastewater in three drums of wastewater on V79 cells as a preliminary study for a toxicity testing. The physicochemical properties of the wastewater were assessed. The cytotoxicity was assessed by using MTT assay using alkaline comet assay to evaluate the genotoxicity of the wastewater. This study found that the wastewater from all the three drums demonstrated a cytotoxic effect towards V79 cells at various concentrations, and drum A showed lower IC50 value compared to drum B and C. The IC50 in drum A are 8.8%, 8.0%, and 8.4% v/v for December 2014, January 2015 and February 2015 respectively. Meanwhile, for genotoxicitystudy of the wastewater samples on V79 cells, the study found that the value of tail moment (TM) for the all samples were lower than 2 score, with the highest is 1.842 ± 0.150, while the results for the negative and positive controls were 6.5 ± 1.079 and 0.436 ± 0.012, respectively. In conclusion, the wastewater from all three the drums in this study had a cytotoxic effect but did not demostrate a genotoxic effect on V79 cells, indicating no DNA damage inflicted.

References

• Ahmad, A. L., Harris, W. A. & Ooi, B. S. 2012. Removal of dye from wastewater of textile industry using membrane technology. Jurnal of Technology 36(1): 31–44.

• Anjaneyulu, Y., Chary, N. S. & Raj, D. S. S. 2005. Decolourization of industrial effluents–available methods and emerging technologies–a review. Reviews in Environmental Science and Bio/Technology 4(4): 245-273.

• Babu, B. R., Parande, A. & Raghu, S. 1995. Textile Technology. Technology.

• Balls, M. & Fentem, J. 1992. use of basal cytotoxicity and target organ toxicity tests in hazard identification and risk assessment. Alternatives to laboratory animals: ATLA.

• Banat, I. M., Nigam, P., Singh, D. & Marchant, R. 1996. Microbial decolorization of textile-dyecontaining effluents: A review. Bioresource Technology 58(3): 217-227.

• Chaung, W., Mi, L.-J. & Boorstein, R. J. 1997. The p53 status of Chinese hamster V79 cells frequently used for studies on DNA damage and DNA repair. Nucleic acids Research 25(5): 992-994.

• Cingi, M., De Angelis, I., Fortunati, E., Reggiani, D., Bianchi, V., Tiozzo, R. & Zucco, F. 1991. Choice and standardization of test protocols in cytotoxicology: a multicentre approach. Toxicology in vitro 5(2): 119-125.

• Department of Environment, Environmental Quality (Industrial Effluent) Regulation 2009 standard B, Environmental Quality Act 1974

• Ekwall, B. & Ekwall, K. 1988. Comments on the use of diverse cell systems in toxicity testing. Alternatives to laboratory animals: ATLA.

• Ghaly, A., Ananthashankar, R., Alhattab, M. & Ramakrishnan, V. 2014. Production, characterization and treatment of textile effluents: a critical review. J Chem Eng Process Technol 5: 182.

• Hach. 2002. spectrophotometer procedure manual Ed. USA: HACH Company.

• Hai, F. I., Yamamoto, K. & Fukushi, K. 2006. Development of a submerged membrane fungi reactor for textile wastewater treatment. Desalination 192(1): 315-322.

• Hartmann, A., Kiskinis, E., Fjallman, A. & Suter, W. 2001. Influence of cytotoxicity and compound percipitation on test results in the alkaline comet assay. Mutation Research. 497: 199-212

• Henderson, L., Wolfreys, A., Fedyk J., Bourner, C. & Widebank, S. 1998. The ability of comet assay to discriminate between genotoxins and cytotoxins. Environmental Safety Laboratory, Unilever Research. United Kingdom. Oxford University Press.

• Hussain, J., Hussain, I. & Arif, M. 2004. Characterization of Textile Wastewater. Journal of Industrial Pollution Control. 20(1): 137-144

• Klemola, K., Honkalampi-Hämäläinen, U., Liesivuori, J., Pearson, J. & Lindström-Seppä, P. 2006. Evaluating The Toxicity Of Reactive Dyes And Fabrics With The Spermatozoa Motility Inhibition Test.

• Mosmann, T. 1983. Rapid colorimetric assay for cellular growth and survival: application to proliferation and cytotoxicity assays. Journal of immunological methods 65(1): 55-63.

• Noor, S. & Rohasliney, H. 2011. A Preliminary Study on Batik Effluent in Kelantan State: A Water Quality Perspective. International Conference on Chemical, Biological and Environment Sciences, Bangkok, hlm. 274-276.

• Olive, P. L., Banáth, J. P. & Durand, R. E. 1990. Heterogeneity in radiation-induced DNA damage and repair in tumor and normal cells measured using the" comet" assay. Radiation research 122(1): 86-94.

• Puvaneswari, N., Muthukrishnan, J. & Gunasekaran, P. 2006. Toxicity assessment and microbial degradation of azo dyes. Indian journal of experimental biology 44(8): 618.

• Rashidi, H. R., Sulaiman, N. M. N. & Hashim, N. A. 2012. Batik Industry Synthetic Wastewater Treatment Using Nanofiltration Membrane. Procedia Engineering 44(0): 2010-2012.

• Rashidi, H., Sulaiman, N. N., Hashim, N. & Hassand, C. C. 2012. The Application of Hybrid Physical Pretreatment System for Treatment of Simulated Batik Wastewater.

• Sharma, K., Sharma, S., Sharma, S., Singh, P., Kumar, S., Grover, R. & Sharma, P. 2007. A comparative study on characterization of textile wastewaters (untreated and treated) toxicity by chemical and biological tests. Chemosphere 69(1): 48-54.

• Shrivastava, R., John, G., Rispat, G., Chevalier, A. & Massingham, R. 1991. Can the in vivo maximum tolerated dose be predicted using in vitro techniques? A working hypothesis. Alternatives to laboratory animals: ATLA.

• Srebrenkoska, V., Zezova, S., Spasova, S. & Golomeova, S. 2014. Methods for waste waters treatment in textile industry.

• Sridewi, N., Tan, L. T. & Sudesh, K. 2011. Solar Photocatalytic Decolorization and Detoxification of Industrial Batik Dye Wastewater Using P (3HB)â€TiO2 Nanocomposite Films. CLEAN–Soil, Air, Water 39(3): 265-273.

• Siti Zuraida, M., Nurhaslina, C. & Ku Halim, K. 2013. Influence of Agitation, pH and Temperature On Growth and Decolorization of Batik Wastewater by Bacteria Lactobacillus Delbruckii

• Wahid, Z. A. & Munaim, M. S. A. 2011. Substainable technology for treatment of batik waste effluent, Google Patents.

• Wang, C., Yediler, A., Lienert, D., Wang, Z. & Kettrup, A. 2002. Toxicity evaluation of reactive dyestuffs, auxiliaries and selected effluents in textile finishing industry to luminescent bacteria Vibrio fischeri. Chemosphere 46(2): 339-344.

• Žegura, B., Heath, E., ÄŒernoÅ¡a, A. & FilipiÄ, M. 2009. Combination of< i> in vitro bioassays for the determination of cytotoxic and genotoxic potential of wastewater, surface water and drinking water samples. Chemosphere 75(11): 1453-1460.

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Published

2017-02-20

How to Cite

Cytotoxicity and Genotoxicity Assessments of Batik Industrial Wastewater on V79 Cells. (2017). Asian Journal of Applied Sciences, 5(1). https://ajouronline.com/index.php/AJAS/article/view/3911

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