Investigation of Brilliant Blue R Dye Bioremoval Capacity of Trichoderma sp.

Sevgi Ertuğrul; Gözde Bodur; Ekin Demiray; Gönül Dönmez

Araştırma Makalesi

Investigation of Brilliant Blue R Dye Bioremoval Capacity of Trichoderma sp.

Yıl 2020, Cilt: 15 Sayı: 1, 1 - 8, 31.01.2020

Sevgi Ertuğrul Gözde Bodur Ekin Demiray Gönül Dönmez

Öz

In
the current study bioremoval of the reactive dyes; Brilliant Blue R, Remazol
Brilliant Blue R, Reactive Red 120, Reactive Black 5 and Reactive Orange 14 by Trichoderma sp. were investigated. The
bioremoval yields were 90.63%, 97.35%, 73.56%, 99.82% and 88.0% for Reactive
Black 5, Reactive Red 120, Reactive Orange 14, Brilliant Blue R and Remazol
Brilliant Blue R, respectively in the presence of 300mg/L initial dye concentration.
The highest bioremoval yield was observed at Brilliant Blue R among the tested
dyes. Therefore, further optimizations such as pH, initial dye concentration,
incubation period, inoculum amount and maximum specific dye uptake were carried
out with Brilliant Blue R. In bio removal experiments, sugar beet molasses
which is cheap and abundant feedstock was used as a carbon source. In the
presence of molasses medium Trichoderma
sp. showed 99.24% removal yield in the presence of 315.23 mg/L Brilliant Blue
R.

Anahtar Kelimeler

Trichoderma sp., Fungi, Bioremoval, Brilliant Blue R., Molasses

Kaynakça

[1] Adegoke, K.A. and Bello, O.S., (2015). Dye Sequestration Using Agricultural Wastes as Adsorbents. Water Resources and Industry, Volume:12, pp:8-24. Last Accession Date: 06.11.2019.
[2] Bankole, O.P., Adekunle, A.A., Obidi, O.F., Olukanni, O.D., and Govindwar, S.P., (2015). Degradation of Indigo Dye by a Newly Isolated Yeast, Diutina Rugosa from Dye Wastewater Polluted Soil. Journal of Environmental Chemical Engineering, Volume:5, pp:4639-4648. Last Accession Date: 24.07.2019.
[3] Senthilkumar, S., Perumalsamy, M., and Janardhana Prabhu, H., (2014). Decolourization Potential of White-rot Fungus Phanerochaete Chrysosporium on Synthetic dye Bath Effluent Containing Amido Black 10B. Journal of Saudi Chemical Society, Volume:6, pp:845-853. Last Accession Date: 24.07.2019.
[4] Wang, J. and Chen, C., (2009). Biosorbents for Heavy Metals Removal and Their Future. Biotechnology advances, 27(2):195-226. Last Accession Date: 07.11.2019.
[5] Mohan, S.V., Rao, N.C., and Sarma, P.N., (2007). Simulated Acid Azo Dye (Acid black 210) Wastewater Treatment by Periodic Discontinuous Batch Mode Operation under Anoxic–Aerobic–Anoxic Microenvironment Conditions. Ecological Engineering, 31(4):242-250. Last Accession Date: 06.11.2019.
[6] Wang, J. and Chen, C., (2009). Biosorbents for Heavy Metals Removal and Their Future. Biotechnology advances, 27(2):195-226. Last Accession Date: 06.11.2019.
[7] Bayramoglu, G. and Yilmaz, M., (2018). Azo Dye Removal Using Free and Immobilized Fungal Biomasses: Isotherms, Kinetics and Thermodynamic Studies. Fibers and Polymers, 19(4):877-886. Last accession date: 06.11.2019.
[8] Sandhya, S., (2010). Biodegradation of Azo Dyes Under Anaerobic Condition: Role of Azoreductase. 39-57. Springer, Berlin, Heidelberg. Last Accession Date: 24.07.2019.
[9] Akkara, M. and Tosun, H., (2014). Industrial Products Derived From Fungi: a review. Electronic Journal of Food Technologies, 9:46-53. Last Accession Date: 24.07.2019.
[10] Kiliç, N.K., Duygu, E., and Dönmez, G., (2010). Triacontanol Hormone Stimulates Population, Growth and Brilliant Blue R Dye Removal by Common Duckweed from Culture Media. Journal of Hazardous Materials, 182:525-530. Last Accession Date: 11.11.2019.
[11] Gül, Ü.D., (2013). Treatment of Dyeing Wastewater Including Reactive Dyes (Reactive Red RB, Reactive Black B, Remazol Blue) and Methylene Blue by fungal biomass. Water SA, 39(5):593-598. Last Accession Date: 24.07.2019.
[12] Saravanakumar, K. and Kathiresan, K., (2014). Bioremoval of the Synthetic Dye Malachite Green by Marine Trichoderma sp. SpringerPlus, 3(1):631-643. Last Accession Date: 10.11.2019.
[13] Ibrahim, N.N., Talib, S.A., Ismail, H.N., and Tay, C.C., (2017). Decolorization of Reactive red-120 by Using Macrofungus and Microfungus. Journal of Fundamental and Applied Sciences, 9(6S):954-964. Last Accession Date: 24.07.2019.
[14] Salar, R.K., Rohilla, S.K., and Rohilla, J.K., (2012). Decolorization of Reactive Black HFGR by Aspergillus Sulphureus. Annals of Biological Research, 3:3811-3817. Last Accession Date:08.11.2019.
[15] Wang, B.E. and Hu, Y.Y., (2008). Bioaccumulation Versus Adsorption of Reactive Dye by Immobilized Growing Aspergillus Fumigatus Beads. Journal of Hazardous Materials, 157(1):1-7. Last Accession Date: 24.07.2019.
[16] Taştan, B.E., Ertuğrul, S., and Dönmez, G., (2010). Effective Bioremoval of Reactive Dye and Heavy Metals by Aspergillus versicolor. Bioresource Technology, 101(3):870-876. Last Accession Date: 07.11.2019.
[17] Erdem, Ö. and Cihangir, N., (2018). Color Removal of Some Textile Dyes from Aqueous Solutions Using Trametes Versicolor. Hacettepe Journal of Biology and Chemistry, 48(4):499-507. Last Accession Date: 08.11.2019.
[18] Kumari, K. and Abraham, T. E., (2007). Biosorption of Anionic Textile Dyes by Nonviable Biomass of Fungi And Yeast. Bioresource Technology, 98(9):1704-1710. Last Accession Date: 07.11.2019

Yıl 2020, Cilt: 15 Sayı: 1, 1 - 8, 31.01.2020

Sevgi Ertuğrul Gözde Bodur Ekin Demiray Gönül Dönmez

Öz

Kaynakça

[1] Adegoke, K.A. and Bello, O.S., (2015). Dye Sequestration Using Agricultural Wastes as Adsorbents. Water Resources and Industry, Volume:12, pp:8-24. Last Accession Date: 06.11.2019.
[2] Bankole, O.P., Adekunle, A.A., Obidi, O.F., Olukanni, O.D., and Govindwar, S.P., (2015). Degradation of Indigo Dye by a Newly Isolated Yeast, Diutina Rugosa from Dye Wastewater Polluted Soil. Journal of Environmental Chemical Engineering, Volume:5, pp:4639-4648. Last Accession Date: 24.07.2019.
[3] Senthilkumar, S., Perumalsamy, M., and Janardhana Prabhu, H., (2014). Decolourization Potential of White-rot Fungus Phanerochaete Chrysosporium on Synthetic dye Bath Effluent Containing Amido Black 10B. Journal of Saudi Chemical Society, Volume:6, pp:845-853. Last Accession Date: 24.07.2019.
[4] Wang, J. and Chen, C., (2009). Biosorbents for Heavy Metals Removal and Their Future. Biotechnology advances, 27(2):195-226. Last Accession Date: 07.11.2019.
[5] Mohan, S.V., Rao, N.C., and Sarma, P.N., (2007). Simulated Acid Azo Dye (Acid black 210) Wastewater Treatment by Periodic Discontinuous Batch Mode Operation under Anoxic–Aerobic–Anoxic Microenvironment Conditions. Ecological Engineering, 31(4):242-250. Last Accession Date: 06.11.2019.
[6] Wang, J. and Chen, C., (2009). Biosorbents for Heavy Metals Removal and Their Future. Biotechnology advances, 27(2):195-226. Last Accession Date: 06.11.2019.
[7] Bayramoglu, G. and Yilmaz, M., (2018). Azo Dye Removal Using Free and Immobilized Fungal Biomasses: Isotherms, Kinetics and Thermodynamic Studies. Fibers and Polymers, 19(4):877-886. Last accession date: 06.11.2019.
[8] Sandhya, S., (2010). Biodegradation of Azo Dyes Under Anaerobic Condition: Role of Azoreductase. 39-57. Springer, Berlin, Heidelberg. Last Accession Date: 24.07.2019.
[9] Akkara, M. and Tosun, H., (2014). Industrial Products Derived From Fungi: a review. Electronic Journal of Food Technologies, 9:46-53. Last Accession Date: 24.07.2019.
[10] Kiliç, N.K., Duygu, E., and Dönmez, G., (2010). Triacontanol Hormone Stimulates Population, Growth and Brilliant Blue R Dye Removal by Common Duckweed from Culture Media. Journal of Hazardous Materials, 182:525-530. Last Accession Date: 11.11.2019.
[11] Gül, Ü.D., (2013). Treatment of Dyeing Wastewater Including Reactive Dyes (Reactive Red RB, Reactive Black B, Remazol Blue) and Methylene Blue by fungal biomass. Water SA, 39(5):593-598. Last Accession Date: 24.07.2019.
[12] Saravanakumar, K. and Kathiresan, K., (2014). Bioremoval of the Synthetic Dye Malachite Green by Marine Trichoderma sp. SpringerPlus, 3(1):631-643. Last Accession Date: 10.11.2019.
[13] Ibrahim, N.N., Talib, S.A., Ismail, H.N., and Tay, C.C., (2017). Decolorization of Reactive red-120 by Using Macrofungus and Microfungus. Journal of Fundamental and Applied Sciences, 9(6S):954-964. Last Accession Date: 24.07.2019.
[14] Salar, R.K., Rohilla, S.K., and Rohilla, J.K., (2012). Decolorization of Reactive Black HFGR by Aspergillus Sulphureus. Annals of Biological Research, 3:3811-3817. Last Accession Date:08.11.2019.
[15] Wang, B.E. and Hu, Y.Y., (2008). Bioaccumulation Versus Adsorption of Reactive Dye by Immobilized Growing Aspergillus Fumigatus Beads. Journal of Hazardous Materials, 157(1):1-7. Last Accession Date: 24.07.2019.
[16] Taştan, B.E., Ertuğrul, S., and Dönmez, G., (2010). Effective Bioremoval of Reactive Dye and Heavy Metals by Aspergillus versicolor. Bioresource Technology, 101(3):870-876. Last Accession Date: 07.11.2019.
[17] Erdem, Ö. and Cihangir, N., (2018). Color Removal of Some Textile Dyes from Aqueous Solutions Using Trametes Versicolor. Hacettepe Journal of Biology and Chemistry, 48(4):499-507. Last Accession Date: 08.11.2019.
[18] Kumari, K. and Abraham, T. E., (2007). Biosorption of Anionic Textile Dyes by Nonviable Biomass of Fungi And Yeast. Bioresource Technology, 98(9):1704-1710. Last Accession Date: 07.11.2019

Toplam 18 adet kaynakça vardır.

Ayrıntılar

Birincil Dil	İngilizce
Bölüm	Makaleler
Yazarlar	Sevgi Ertuğrul 0000-0001-9544-0276 Gözde Bodur 0000-0003-2426-7941 Ekin Demiray 0000-0003-2675-134X Gönül Dönmez 0000-0001-7972-5570
Yayımlanma Tarihi	31 Ocak 2020
Yayımlandığı Sayı	Yıl 2020 Cilt: 15 Sayı: 1

Kaynak Göster

APA	Ertuğrul, S., Bodur, G., Demiray, E., Dönmez, G. (2020). Investigation of Brilliant Blue R Dye Bioremoval Capacity of Trichoderma sp. Ecological Life Sciences, 15(1), 1-8.
AMA	Ertuğrul S, Bodur G, Demiray E, Dönmez G. Investigation of Brilliant Blue R Dye Bioremoval Capacity of Trichoderma sp. NWSA. Ocak 2020;15(1):1-8.
Chicago	Ertuğrul, Sevgi, Gözde Bodur, Ekin Demiray, ve Gönül Dönmez. “Investigation of Brilliant Blue R Dye Bioremoval Capacity of Trichoderma Sp”. Ecological Life Sciences 15, sy. 1 (Ocak 2020): 1-8.
EndNote	Ertuğrul S, Bodur G, Demiray E, Dönmez G (01 Ocak 2020) Investigation of Brilliant Blue R Dye Bioremoval Capacity of Trichoderma sp. Ecological Life Sciences 15 1 1–8.
IEEE	S. Ertuğrul, G. Bodur, E. Demiray, ve G. Dönmez, “Investigation of Brilliant Blue R Dye Bioremoval Capacity of Trichoderma sp”., NWSA, c. 15, sy. 1, ss. 1–8, 2020.
ISNAD	Ertuğrul, Sevgi vd. “Investigation of Brilliant Blue R Dye Bioremoval Capacity of Trichoderma Sp”. Ecological Life Sciences 15/1 (Ocak 2020), 1-8.
JAMA	Ertuğrul S, Bodur G, Demiray E, Dönmez G. Investigation of Brilliant Blue R Dye Bioremoval Capacity of Trichoderma sp. NWSA. 2020;15:1–8.
MLA	Ertuğrul, Sevgi vd. “Investigation of Brilliant Blue R Dye Bioremoval Capacity of Trichoderma Sp”. Ecological Life Sciences, c. 15, sy. 1, 2020, ss. 1-8.
Vancouver	Ertuğrul S, Bodur G, Demiray E, Dönmez G. Investigation of Brilliant Blue R Dye Bioremoval Capacity of Trichoderma sp. NWSA. 2020;15(1):1-8.