Year 2021,
Volume: 17 Issue: 4, 383 - 385, 29.12.2021
Fatih Kalyoncu
,
Yurdanur Akyol
References
- 1. Azbar, N, Yonar, T, Kestioglu, K. 2004. Comparison of various advanced oxidation processes and chemical treatment methods for COD and color removal from a polyester and acetate fiber dyeing effluent. Chemosphere; 55: 35–43.
- 2. Balan, D.S.L, Monteiro, R.T.R. 2001. Decolorization of textile indigo dye by ligninolytic fungi. Journal of Biotechnology; 89: 141-145.
- 3. Banat, I.M, Nigam, P, Singh, D, Marchant, R. 1996. Microbial decolorization of textile dye containing effluents: a review. Bioresource Technology; 58: 217–227.
- 4. Bıyık, H, Kalyoncu, F, Oryasin, E, Azbar, N, Kalmış, E, Basbülbül, G. 2009. Evaluation of wild and commercial types of Pleurotus strains for their ability to decolorize cibacron black W-NN textile dye. African Journal of Microbiology Research; 3: 325-329.
- 5. Eichlerova, I, Homolka, L, Nerud, F. 2006. Ability of industrial dyes decolorization and ligninolytic enzymes production by different Pleurotus species with special attention on Pleurotus calyptratus strain CCBAS 461. Process Biochemistry; 41: 941–946.
- 6. Galindo, C, Kalt, T. 1999. UV/H2O oxidation of azo dyes in aqueous media: evidence of a structure – degradability relationship. Dyes and Pigments; 42: 199–207.
- 7. Hou, H, Zhou, J, Wang, J, Du, C, Yan, B. 2004. Enhancement of laccase production by Pleurotus ostreatus and its use for the decolorization of anthraquinone dye, Process Biochemistry; 39: 1415–1419.
- 8. Kalmış, E, Azbar, N, Kalyoncu, F. 2008. Evaluation of two wild types of Pleurotus ostreatus (MCC07 and MCC20) isolated from nature for their ability to decolorize Benazol Black ZN textile dye in comparison to some commercial types of white rot fungi: Pleurotus ostreatus, Pleurotus djamor and Pleurotus citrinopileatus. Canadian Journal of Microbiology; 54: 366-370.
- 9. Levin, L, Papinutti, L, Forchiassin, F. 2004. Evaluation of Argentinean white rot fungi for their ability to produce lignin-modifying enzymes and decolorize industrial dyes. Bioresource Technology; 94: 169–176.
- 10. Liu, W, Chao, Y, Yang, X, Bao, H, Qian, S. 2004. Biodecolorization of azo, anthraquinone and triphenylmethane dyes by white-rot fungi and a laccase secreting engineered. Journal of Industrial Microbiology and Biotechnology; 31: 124-127.
- 11. Nilsson, I, Möller, A, Mattiasson, B, Rubindamayugi, M.S.T, Welander, U. 2006. Decolorization of synthetic and real textile wastewater by the use of white-rot fungi. Enzyme and Microbial Technology; 38: 94–102.
- 12. Ramsay, J.A, Nguyen, T. 2002. Decoloration of textile dyes by Trametes versicolor and its effect on dye toxicity. Biotechnology Letters; 24: 1757-1761.
- 13. Reife, A, Freeman, S. 1996. Environmental chemistry of dyes and pigments. John Wiley & Sons, New York, 75-90.
- 14. Robinson, T, McMullan, G, Marchant, R, Nigam, P. 2001. Remediation of dyes in textile effluent: a critical review on current treatment technologies with a proposed alternative. Bioresource Technology; 77: 247-255.
- 15. Tien, M, Kirk, T.K. 1988. Lignin peroxidase of Phanerochaete chrysosporium. Methods of Enzymology; 161: 238–249.
- 16. Weitz, J.H, Ballard, A.L, Campbell, C.D, Killham, K. 2001. The effect of culture conditions on the mycelial growth and luminescence of naturally bioluminescent fungi. FEMS Microbiology Letters; 202: 165–170.
- 17. Wesenberg, D, Kyriakides, I, Agathos, S.P., 2003. White-rot fungi and their enzymes for the treatment of industrial dye effluents. Biotechnology Advances; 22: 161-187.
- 18. Yesilada, O, Asma, D, Cing, S. 2003. Decolorization of textile dyes by fungal pellets. Process Biochemistry; 38: 933–938.
- 19. Yonni, F, Moreira, M.T, Fasoli, H, Grandi, L, Cabral, D. 2004. Simple and easy method for the determination of fungal growth and decolourative capacity in solid media. International Journal of Biodeterioration and Biodegradation; 54: 283-287.
- 20. Zhao, X, Hardin, I.R. 2007. HPLC and spectrophotometric analysis of biodegradation of azo dyes by Pleurotus ostreatus. Dyes and Pigments; 73: 322–325.
Decolorization Potential of Pleurotus ostreatus, Lentinula edodes and Ganoderma lucidum against Solvaderm Brown MF-GO Textile Dye
Year 2021,
Volume: 17 Issue: 4, 383 - 385, 29.12.2021
Fatih Kalyoncu
,
Yurdanur Akyol
Abstract
Biological decolorization of Solvaderm Brown MF-GO was comparatively studied using three different macrofungi strains (Pleurotus ostreatus, Lentinus sajor-caju and Ganoderma lucidum). In the medium; the inceptive concentrations of dye were 250, 500 and 1000 mg/L, respectively. Whole fungi studied decolorized Solvaderm Brown to varying degrees. Fungi strains resulted in the good decolorization at low dye concentration, but mycelia negatively affected from increasing dye concentrations.
References
- 1. Azbar, N, Yonar, T, Kestioglu, K. 2004. Comparison of various advanced oxidation processes and chemical treatment methods for COD and color removal from a polyester and acetate fiber dyeing effluent. Chemosphere; 55: 35–43.
- 2. Balan, D.S.L, Monteiro, R.T.R. 2001. Decolorization of textile indigo dye by ligninolytic fungi. Journal of Biotechnology; 89: 141-145.
- 3. Banat, I.M, Nigam, P, Singh, D, Marchant, R. 1996. Microbial decolorization of textile dye containing effluents: a review. Bioresource Technology; 58: 217–227.
- 4. Bıyık, H, Kalyoncu, F, Oryasin, E, Azbar, N, Kalmış, E, Basbülbül, G. 2009. Evaluation of wild and commercial types of Pleurotus strains for their ability to decolorize cibacron black W-NN textile dye. African Journal of Microbiology Research; 3: 325-329.
- 5. Eichlerova, I, Homolka, L, Nerud, F. 2006. Ability of industrial dyes decolorization and ligninolytic enzymes production by different Pleurotus species with special attention on Pleurotus calyptratus strain CCBAS 461. Process Biochemistry; 41: 941–946.
- 6. Galindo, C, Kalt, T. 1999. UV/H2O oxidation of azo dyes in aqueous media: evidence of a structure – degradability relationship. Dyes and Pigments; 42: 199–207.
- 7. Hou, H, Zhou, J, Wang, J, Du, C, Yan, B. 2004. Enhancement of laccase production by Pleurotus ostreatus and its use for the decolorization of anthraquinone dye, Process Biochemistry; 39: 1415–1419.
- 8. Kalmış, E, Azbar, N, Kalyoncu, F. 2008. Evaluation of two wild types of Pleurotus ostreatus (MCC07 and MCC20) isolated from nature for their ability to decolorize Benazol Black ZN textile dye in comparison to some commercial types of white rot fungi: Pleurotus ostreatus, Pleurotus djamor and Pleurotus citrinopileatus. Canadian Journal of Microbiology; 54: 366-370.
- 9. Levin, L, Papinutti, L, Forchiassin, F. 2004. Evaluation of Argentinean white rot fungi for their ability to produce lignin-modifying enzymes and decolorize industrial dyes. Bioresource Technology; 94: 169–176.
- 10. Liu, W, Chao, Y, Yang, X, Bao, H, Qian, S. 2004. Biodecolorization of azo, anthraquinone and triphenylmethane dyes by white-rot fungi and a laccase secreting engineered. Journal of Industrial Microbiology and Biotechnology; 31: 124-127.
- 11. Nilsson, I, Möller, A, Mattiasson, B, Rubindamayugi, M.S.T, Welander, U. 2006. Decolorization of synthetic and real textile wastewater by the use of white-rot fungi. Enzyme and Microbial Technology; 38: 94–102.
- 12. Ramsay, J.A, Nguyen, T. 2002. Decoloration of textile dyes by Trametes versicolor and its effect on dye toxicity. Biotechnology Letters; 24: 1757-1761.
- 13. Reife, A, Freeman, S. 1996. Environmental chemistry of dyes and pigments. John Wiley & Sons, New York, 75-90.
- 14. Robinson, T, McMullan, G, Marchant, R, Nigam, P. 2001. Remediation of dyes in textile effluent: a critical review on current treatment technologies with a proposed alternative. Bioresource Technology; 77: 247-255.
- 15. Tien, M, Kirk, T.K. 1988. Lignin peroxidase of Phanerochaete chrysosporium. Methods of Enzymology; 161: 238–249.
- 16. Weitz, J.H, Ballard, A.L, Campbell, C.D, Killham, K. 2001. The effect of culture conditions on the mycelial growth and luminescence of naturally bioluminescent fungi. FEMS Microbiology Letters; 202: 165–170.
- 17. Wesenberg, D, Kyriakides, I, Agathos, S.P., 2003. White-rot fungi and their enzymes for the treatment of industrial dye effluents. Biotechnology Advances; 22: 161-187.
- 18. Yesilada, O, Asma, D, Cing, S. 2003. Decolorization of textile dyes by fungal pellets. Process Biochemistry; 38: 933–938.
- 19. Yonni, F, Moreira, M.T, Fasoli, H, Grandi, L, Cabral, D. 2004. Simple and easy method for the determination of fungal growth and decolourative capacity in solid media. International Journal of Biodeterioration and Biodegradation; 54: 283-287.
- 20. Zhao, X, Hardin, I.R. 2007. HPLC and spectrophotometric analysis of biodegradation of azo dyes by Pleurotus ostreatus. Dyes and Pigments; 73: 322–325.