Year 2023,
, 219 - 228, 30.09.2023
Nermin Hande Avcioglu
,
Sezen Bılen Ozyurek
,
Işıl Seyis Bilkay
Project Number
FHD-2019-17719
References
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Use of Heat-killed Aspergillus ochraceus NRRL 3174 Discs as Biosorbent for petroleum Removal
Year 2023,
, 219 - 228, 30.09.2023
Nermin Hande Avcioglu
,
Sezen Bılen Ozyurek
,
Işıl Seyis Bilkay
Abstract
The purpose of this work was to evaluate the petroleum sorption capacity of heat-killed fungal discs obtained from Aspergillus ochraceus strain. Effect of various parameters such as biosorbent dose (0.5g-2.5g/100mL), petroleum concentration (0.5-5%), pH (4.0-8.0), contact time (1-12h) and re-usability of biosorbent (1-6) were investigated. Accordingly, the highest biosorption capacity was obtained with 1% petroleum concentration, 1.5 g/100mL heat-killed fungal discs, 10h contact time at pH: 5.0 and room temperature. Additionally, each disc was able to actively use for at least 6 more cycles in biosorption experiments. The specific removal rate was calculated as 0.114 day−1, the rate constant and half-life period were also 1.609 day-1, t1/2 = 0.431, respectively. The kinetic study was described by the pseudo-second order model and the equilibrium modeling was found to be well fitted with Langmuir isotherm. The biosorbent(s) were characterized by Focused Ion Beam Scanning Electron Microscopy (FIB-SEM). Over 80% removal of long-chain n-alkanes by the heat-killed fungal discs was confirmed by GC-MS analysis. Since there has been no similar study investigating the sorption of petroleum with heat-killed Aspergillus ochraceous discs, this novel bio-based sorbent with its low cost, environmentally friendly and easy-to-apply properties can be used in advanced biosorption studies.
Supporting Institution
Hacettepe University
Project Number
FHD-2019-17719
Thanks
This work is funded by Hacettepe University Scientific Research Projects Coordination Unit (Project number: FHD-2019-17719).
References
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KS, Okoli CJ. Adsorption of petroleum hydrocarbons from crude
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284-89.
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alexandrinum for the detoxification of Cr (III) contaminated water.
Desalin water Treat 2022; 246: 212–25.
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thermal pretreated biogas slurry solids for the removal of heavy
metals: optimization, kinetic, and equilibrium study. Environ Sci
Pollut Res 2022; 29 (20): 30217–32.
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integrated approach to understanding the sorption mechanism of
phenanthrene by cork. Chemosphere 2013; 90 (6): 1939–44.
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naphthalene and phenanthrene with axenic microplantlets of the
temperate green seaweed Acrosiphonia coalita. Chemosphere 2009;
76 (8): 1135–42.
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Agricultural waste as a biosorbent for oil spills. Int J Dev 2013; 2
(1): 127-35.
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sorption capacity of raw and thermally modified orange peel waste.
Alex Eng J 2020; 59(2): 925-32.
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M, Sheikh M, Chen Y, Al-Yasiri M, Alsudays A. Pomegranate
peels powder for the remediation of oil polluted water from waste
lubricating oil. Proceedings of the 5th International Conference of
Fluid Flow, Heat and Mass Transfer, Niagara Falls, Canada, 2018.
- 21. Wu J, Yu HQ. Biosorption of 2,4-dichlorophenol from aqueous
solution by Phanerochaete chrysosporium biomass: isotherms,
kinetics, and thermodynamics. J Hazard Mater 2006; 137: 498–508.
- 22. Chung M, Tsui MT, Cheung K, Tam NF, Wong MH. Removal of
aqueous phenanthrene by brown seaweed Sargassum hemiphyllum:
Sorptionkinetic and equilibrium studies. Sep Purif Technol 2007;
54 (3): 355–62.
- 23. Crognale S, Annibale AD, Pesciaroli L, Stazi SR. Fungal community
structure and as-resistant fungi in a decommissioned gold mine
site. Front Microbiol 2017; 8: 2202.
- 24. Al-Hawash AB, Zhang X, Ma F. Removal and biodegradation of
different petroleum hydrocarbons using the filamentous fungus
Aspergillus sp. RFC-1. Microbiol Open 2019; 8 (1): e00619.
- 25. Dusengemungu L, Kasali G, Gwanama C, Ouma KO. Recent
Advances in Biosorption of Copper and Cobalt by Filamentous
Fungi. Front Microbiol 2020; 11: 582016.
- 26. Shah SS, Palmieri MC, Sponchiado SRP, Bevilaqua D. Enhanced
bio-recovery of aluminum from low-grade bauxite using adapted
fungal strains. Braz J Microbiol 2020; 51: 1909-18.
- 27. Oladipo OG, Awotoye OO, Olayinka A, Bezuidenhout CC, Maboeta
MS. Heavy metal tolerance traits of filamentous fungi isolated from
gold and gemstone mining sites. Braz J Microbiol 2018; 49: 29–37.
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secondary metabolites and biosynthetic diversity from Aspergillus
ochraceus. Front in Chem 2022; 10: 938626.
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SGA, Mohamed GA, Ibrahim SRM. Aspergillus ochraceus:
metabolites, bioactivities, biosynthesis, and biotechnological
potential. Molecules 2022; 27 (19): 6759.
- 30. Vahabisani A, An C. Use of biomass derived adsorbents for the
removal of petroleum pollutants from water: a mini review. Environ
Syst Res 2021; 10 (1): 1-10.
- 31. Rao J, Viraraghavan T. Biosorption of phenol from an aqueous
solution by Aspergillus niger biomass. Bioresour Technol 2002; 85
(2): 165–71.
- 32. Kumar R, Bishnoi NR, Bishnoi K. Biosorption of chromium (VI)
from aqueous solution and electroplating wastewater using fungal
biomass. Chem Eng J 2008; 135 (3): 202–8.
- 33. Lu N, Hua T, Zhai Y, Qin H, Aliyeva J, Zhang H. Fungal cell
with artificial metal container for heavy metals biosorption:
Equilibrium, kinetics study and mechanisms analysis. Environ Res
2020; 182: 109061.
- 34. Raghukumar C, Shailaja M, Parameswaran P, Singh S. Removal
of polycyclic aromatic hydrocarbons from aqueous media by the
marine fungus NIOCC 312: Involvement of lignin-degrading
enzymes and exopolysaccharides. Indian J Mar Sci 2006; 35 (4):
373-79.
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potential of Aspergillus ochraceus NRRL 3174. Arch Microbiol
2021; 203: 5937-50.
- 36. Mohammadi M, Sedighi M, Hemati M. Removal of petroleum
asphaltenes by improved activity of NiO nanaoparticles supported
on green AlPO-5 zeolite: process optimization and adsorption
isotherm. Petroleum 2020; 6 :182-88.
- 37. Benguenab A, Chibani A. Biodegradation of petroleum
hydrocarbons by filamentous fungi (Aspergillus ustus and
Purpureocillium lilacinum) isolated from used engine oil
contaminated soil. Acta Ecologica Sinica 2021; 41 (5): 416-23.
- 38. Bilen Ozyurek S, Seyis Bilkay I. Comparison of petroleum
biodegradation efficiencies of three different bacterial consortia
determined in petroleum contaminated waste mud pit. SN Appl Sci
2020; 2: 1-12.
- 39. Kachieng’a L, Momba MNB. Kinetics of petroleum oil
biodegradation by consortium of three protozoan isolates
(Aspidisca sp., Trachelophyllum sp. and Peranema sp.). Biotechnol
Rep 2017; 15: 125–31.
- 40. Cheng Z, Feng K, Su Y, Ye J, Chen D, Zhang S, Zhang X, Dionysiou
DD. Novel biosorbents synthesized from fungal and bacterial
biomass and their applications in the adsorption of volatile organic
compounds. Bioresour Technol 2020; 300: 122705.
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recirculation process for treating arsenate using bacterial
biosorbent. Bioresour Technol 2020; 316: 123961.
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dyes by Aspergillus ochraceus (NCIM-1146). Ind J Biotechnol 2006;
5: 407-10.
- 43. Legorreta-Castañeda AJ, Lucho-Constantino CA, Beltrán-
Hernández RI, Coronel-Olivares C, Vázquez-Rodríguez GA.
Biosorption of water pollutants by fungal pellets. Water 2020; 12
(4): 1155.
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