American Journal of Environmental Science and Engineering
Volume 1, Issue 3, August 2017, Pages: 64-67
Received: Mar. 10, 2017;
Accepted: Apr. 8, 2017;
Published: May 18, 2017
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Mohamed A. Hassaan, Marine Environment Division, National Institute of Oceanography and Fisheries, Alexandria, Egypt
Ahmed El Nemr, Marine Environment Division, National Institute of Oceanography and Fisheries, Alexandria, Egypt
The textile industry is one of the important industries which generates large amount of industrial effluents each year causing the main source of water pollution which is not only harmful for aquatic life but also mutagenic to human. The aim of this work is to give an overview on the health and environmental impact of dyes as pollutants as well as; the most recent treatment techniques of textile effluents wastewater.
Mohamed A. Hassaan,
Ahmed El Nemr,
Health and Environmental Impacts of Dyes: Mini Review, American Journal of Environmental Science and Engineering.
Vol. 1, No. 3,
2017, pp. 64-67.
Hassaan, M. A. 2016. Advanced oxidation processes of some organic pollutants in fresh and seawater, PhD, A Thesis, Faculty of Science, Port Said University, 180 P.
Health and Safety Executive, HSE (2016). Dyes and chemicals in textile finishing: An introduction. Dyeing and Finishing Information Sheet No 1- HSE information sheet. (accessed 2016.10.10).
Elliott, A., Hanby, W and Malcolm, B. (1954). The near infra-red absorption spectra of natural and synthetic fibres. Br. J. Appl. Phys., (5): 377.
Hassaan, M. A. and El Nemr, A., Advanced Oxidation Processes for Textile Wastewater Treatment, International Journal of Photochemistry and Photobiology. Vol. 2, No. 3, 2017, pp. 85-93.
Ananthashankar, R. 2012. Treatment of textile effluent containing reactive red 120 dye using advanced oxidation, M. Sc, A Thesis, Dalhousie University, Halifax, Nova Scotia, 145 P.
Kdasi, A., Idris, A., Saed, K and Guan, C. (2004). Treatment of textile wastewater by advanced oxidation processes: A review. Global Nest. Int. J., 6 (3): 222-230.
Eswaramoorthi, S, Dhanapal, K. and Chauhan, D. (2008). Advanced in textile waste water treatment: The case for UV-ozonation and membrane bioreactor for common effluent treatment plants in Tirupur, Tamil Nadu, India. Environment with People’s Involvement & Co-ordination in India. Coimbatore, India.
Hassaan, M. A., El Nemr, A., and Madkour, F. F. (2016c). Application of Ozonation and UV assisted Ozonation for Decolorization of Direct Yellow 50 in Sea water, The Pharmaceutical and Chemical Journal, ISSN: 2349-7092, Volume 3 Issue 3 2016, Page No. 131-138.
Nese, T., Sivri, N. and Toroz, I. (2007). Pollutants of textile industry wastewater and assessment of its discharge limits by water quality standards. Turkish J., 7: 97-103.
"http://www.fibre2fashion.com/industry-article/4434/pollution-and-its-control-in-textile-industry" accessed on 20th March 2017.
UNCTAD (2003). Major uses of cotton fibres. United Nations Conference on Trade and Development, Updated on Oct 2003.
Mohan, V., Rao, C. and Karthikeyan, J. (2002). Adsorptive removal of direct azo dye from aqueous phase onto coal based sorbents: A kinetic and mechanistic study. Journal of Harzardous Materials, 90 (2): 189-204.
Robert, L., Joseph, F. and Alexander, A. (2008). Fisher's contact dermatitis in: Textiles and shoes. BC Decker Inc., Ontario, p.339-401.
Manu, B. (2003). Decolourization of indigo and azo dye in semicontinous reactors with long hydraulic retention time. PhD thesies submitted to IIT Bombay, India.
Hassaan, M. A., El Nemr, A., and Madkour, F. F. (2017). Advanced Oxidation Processes (AOPs) for Wastewater Treatment. Lambert Academic publishing, Editor: Scole, e-book [ISBN: 978-3-330-03170-8]. pp. 202.
Hassaan, M. A., El Nemr, A., and Madkour, F. F. (2016a). Testing the advanced oxidation processes on the degradation of Direct Blue 86 dye in wastewater. Egyptian Journal of Aquatic Research (2016), http://dx.doi.org/10.1016/j.ejar.2016.09.006.
Hassaan, M. A., El Nemr, A., and Madkour, F. F. (2016b). Advanced oxidation processes of Mordant Violet 40 dye in freshwater and seawater. Egyptian Journal of Aquatic Research (2016), http://dx.doi.org/10.1016/j.ejar.2016.09.004.
Hassaan, M. A., El Nemr, A., and Madkour, F. F. (2015). Ultraviolet assisted ozone degradation process of Acid Red 17 dye. Fifth International Conference on Aquatic Resources ICAR-15 "Challenges, Development and Sustainability".
Hassaan, M. A., El Nemr, A., and Madkour, F. F. (2016d). Color removal and detoxification of chrysophenine G (Direct Yellow 12) using ultraviolet assisted ozone degradation for possible water reuse. The International Conference on Biotechnology and Environment, organized by Alexandria University, Egypt; and University of Leeds, United Kingdom held on 1-3 November 2016, Alexandria, Egypt.
Hassaan, M. A., El Nemr, A., and Madkour, F. F. (2016e). Examination of advanced oxidation processes on decolorization of Direct Blue 86 dye in two different wastewaters. The International Conference on Biotechnology and Environment, organized by Alexandria University, Egypt; and University of Leeds, United Kingdom held on 1-3 November 2016, Alexandria, Egypt.
Hassaan, M. A., El Nemr, A., and Madkour, F. F. (2016f). Removal of Mordant Violet 40 Dye from wastewater using UV/O3 Advanced oxidation Processes. The International Conference on Biotechnology and Environment, organized by Alexandria University, Egypt; and University of Leeds, United Kingdom held on 1-3 November 2016, Alexandria, Egypt.
Savin, I. and Butnaru, R. (2008). Wastewater characteristics in textile finishing mills. Environmental Engineering and Management Journal, 7(6): 859-864.
Chung, K. T. (1983) The significance of azo-reduction in the mutagenesis and carcinogenesis of azo dyes. Mutat Res. 114(3):269-81.
Apostol, L. C., Pereira, L., Pereira, R., Gavrilescu, M., Alves, M.M. (2012) Biological decolorizartion of Xanthene dyes by anaerobic granular biomass. Biodegradation DOI: 10.1007/s10532-012-9548-7.
Report by LGC (1999) The risk of cancer caused by textiles and leather goods coloured with azo dyes. Presented, CSTEE plenary meeting, Brussels.
Puvaneswari, N., et al. (2006) Toxicity assessment and microbial degradation of azo dyes. Indian journal of experimental biology 44(8): 618.
Babel S, Kurniawan TA. Low-cost adsorbents for heavy metals uptake from contaminated water: a review. Journal of Hazardous Materials. 2003; 97(1-3) 219-243.
Associação Brasileira da Indústria Têxtil e de Confecção. Economia. (accessed 19 August 2011).
Glaze, W. H., Kang, J. W. and Chapin, D. H. (1987). The chemistry of water treatment processes involving ozone, hydrogen peroxide and ultraviolet radiation. Ozone Sci. & Eng, 9: 335-342.
Arslan, I., Balcioglu, A. and Tuhkanen, T. (1999). Oxidative treatment of simulated dyehouse effluent by UV and near-UV light assisted fenton`s reagent. Chemosphere; 39(15).: 2767-2783.
Kestioglu, K., Yonar, T. and Azbar, N. (2005). Feasibility of physico-chemical treatment and advanced oxidation processes (AOPs) as a means of pretreatment of olive mill effluent (OME). Process Biochemistry, 40 (7): 2409-2416.
Chung, K. T., Stevens, S. E. J. and Cerniglia, C. E. (1992). The reduction of azo dyes by the intestinal microflora. Critical Reviews in Microbiology, 18: 175-97.