Co-culture of fungi-microalgae consortium for wastewater treatment: A review

[Display omitted] •Microalgae can be effectively harvested by co-pelletization with fungi.•Fungi-microalgae consortium has a complementary effect on pollutant removal.•Fungi-microalgae biomass facilitated the production of biofuel and lipid.•Fungi-microalgae consortium may outperform bacteria-microa...

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Published inBioresource technology Vol. 330; p. 125008
Main Authors Leng, Lijian, Li, Wenting, Chen, Jie, Leng, Songqi, Chen, Jiefeng, Wei, Liang, Peng, Haoyi, Li, Jun, Zhou, Wenguang, Huang, Huajun
Format Journal Article
LanguageEnglish
Published England Elsevier Ltd 01.06.2021
Subjects
adhesion
Biomass
Co-culture
coculture
Coculture Techniques
Consortium
exopolysaccharides
Filamentous fungi
Flocculation
Fungi
Harvest
hyphae
Microalgae
neutralization
pollution control
surface proteins
Waste Water
wastewater
Wastewater treatment
Consortium
Microalgae
Co-culture
Harvest
Wastewater treatment
Filamentous fungi
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Abstract [Display omitted] •Microalgae can be effectively harvested by co-pelletization with fungi.•Fungi-microalgae consortium has a complementary effect on pollutant removal.•Fungi-microalgae biomass facilitated the production of biofuel and lipid.•Fungi-microalgae consortium may outperform bacteria-microalgae in some areas. The treatment of wastewater by microalgae has been studied and proved to be effective through previous studies. Due to the small size of microalgae, how to efficiently harvest microalgae from wastewater is a crucial factor restricting the development of algal technologies. Fungi-assisted microalgae bio-flocculation for microalgae harvesting and wastewater treatment simultaneously, which was overlooked previously, has attracted increasing attention in the recent decade due to its low cost and high efficiency. This review found that fungal hyphae and microalgae can stick together due to electrostatic neutralization, surface protein interaction, and exopolysaccharide adhesion in the co-culture process, realizing co-pelletization of microalgae and fungi, which is conducive to microalgae harvesting. Besides, the combination of fungi and microalgae has a complementary effect on pollutant removal from wastewaters. The co-culture of fungi-microalgae has excellent development prospects with both environmental and economic benefits, and it is expected to be applied on an industrial scale.
AbstractList The treatment of wastewater by microalgae has been studied and proved to be effective through previous studies. Due to the small size of microalgae, how to efficiently harvest microalgae from wastewater is a crucial factor restricting the development of algal technologies. Fungi-assisted microalgae bio-flocculation for microalgae harvesting and wastewater treatment simultaneously, which was overlooked previously, has attracted increasing attention in the recent decade due to its low cost and high efficiency. This review found that fungal hyphae and microalgae can stick together due to electrostatic neutralization, surface protein interaction, and exopolysaccharide adhesion in the co-culture process, realizing co-pelletization of microalgae and fungi, which is conducive to microalgae harvesting. Besides, the combination of fungi and microalgae has a complementary effect on pollutant removal from wastewaters. The co-culture of fungi-microalgae has excellent development prospects with both environmental and economic benefits, and it is expected to be applied on an industrial scale.
[Display omitted] •Microalgae can be effectively harvested by co-pelletization with fungi.•Fungi-microalgae consortium has a complementary effect on pollutant removal.•Fungi-microalgae biomass facilitated the production of biofuel and lipid.•Fungi-microalgae consortium may outperform bacteria-microalgae in some areas. The treatment of wastewater by microalgae has been studied and proved to be effective through previous studies. Due to the small size of microalgae, how to efficiently harvest microalgae from wastewater is a crucial factor restricting the development of algal technologies. Fungi-assisted microalgae bio-flocculation for microalgae harvesting and wastewater treatment simultaneously, which was overlooked previously, has attracted increasing attention in the recent decade due to its low cost and high efficiency. This review found that fungal hyphae and microalgae can stick together due to electrostatic neutralization, surface protein interaction, and exopolysaccharide adhesion in the co-culture process, realizing co-pelletization of microalgae and fungi, which is conducive to microalgae harvesting. Besides, the combination of fungi and microalgae has a complementary effect on pollutant removal from wastewaters. The co-culture of fungi-microalgae has excellent development prospects with both environmental and economic benefits, and it is expected to be applied on an industrial scale.
The treatment of wastewater by microalgae has been studied and proved to be effective through previous studies. Due to the small size of microalgae, how to efficiently harvest microalgae from wastewater is a crucial factor restricting the development of algal technologies. Fungi-assisted microalgae bio-flocculation for microalgae harvesting and wastewater treatment simultaneously, which was overlooked previously, has attracted increasing attention in the recent decade due to its low cost and high efficiency. This review found that fungal hyphae and microalgae can stick together due to electrostatic neutralization, surface protein interaction, and exopolysaccharide adhesion in the co-culture process, realizing co-pelletization of microalgae and fungi, which is conducive to microalgae harvesting. Besides, the combination of fungi and microalgae has a complementary effect on pollutant removal from wastewaters. The co-culture of fungi-microalgae has excellent development prospects with both environmental and economic benefits, and it is expected to be applied on an industrial scale.The treatment of wastewater by microalgae has been studied and proved to be effective through previous studies. Due to the small size of microalgae, how to efficiently harvest microalgae from wastewater is a crucial factor restricting the development of algal technologies. Fungi-assisted microalgae bio-flocculation for microalgae harvesting and wastewater treatment simultaneously, which was overlooked previously, has attracted increasing attention in the recent decade due to its low cost and high efficiency. This review found that fungal hyphae and microalgae can stick together due to electrostatic neutralization, surface protein interaction, and exopolysaccharide adhesion in the co-culture process, realizing co-pelletization of microalgae and fungi, which is conducive to microalgae harvesting. Besides, the combination of fungi and microalgae has a complementary effect on pollutant removal from wastewaters. The co-culture of fungi-microalgae has excellent development prospects with both environmental and economic benefits, and it is expected to be applied on an industrial scale.
ArticleNumber 125008
Author Wei, Liang
Li, Jun
Li, Wenting
Zhou, Wenguang
Peng, Haoyi
Leng, Songqi
Leng, Lijian
Chen, Jiefeng
Chen, Jie
Huang, Huajun
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  email: huanghuajun2004@126.com
  organization: School of Land Resources and Environment, Jiangxi Agricultural University, Nanchang 330045, China
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IngestDate Fri Jul 11 14:10:33 EDT 2025
Fri Jul 11 08:33:52 EDT 2025
Wed Feb 19 02:28:03 EST 2025
Thu Apr 24 23:02:58 EDT 2025
Tue Jul 01 03:18:52 EDT 2025
Fri Feb 23 02:42:39 EST 2024
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Keywords Consortium
Microalgae
Co-culture
Harvest
Wastewater treatment
Filamentous fungi
Language English
License Copyright © 2021 Elsevier Ltd. All rights reserved.
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Snippet [Display omitted] •Microalgae can be effectively harvested by co-pelletization with fungi.•Fungi-microalgae consortium has a complementary effect on pollutant...
The treatment of wastewater by microalgae has been studied and proved to be effective through previous studies. Due to the small size of microalgae, how to...
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SubjectTerms adhesion
Biomass
Co-culture
coculture
Coculture Techniques
Consortium
exopolysaccharides
Filamentous fungi
Flocculation
Fungi
Harvest
hyphae
Microalgae
neutralization
pollution control
surface proteins
Waste Water
wastewater
Wastewater treatment
Title Co-culture of fungi-microalgae consortium for wastewater treatment: A review
URI https://dx.doi.org/10.1016/j.biortech.2021.125008
https://www.ncbi.nlm.nih.gov/pubmed/33773267
https://www.proquest.com/docview/2506280999
https://www.proquest.com/docview/2524218957
Volume 330
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