Harnessing water fleas for water reclamation: A nature-based tertiary wastewater treatment technology

Muhammad Abdullahi; Iestyn Stead; Sophie Bennett; Rafael Orozco; Mohamed Abou-elwafa Abdallah; Sara Jabbari; Lynne E. Macaskie; Alexandra Tzella; Stefan Krause; Bushra Al-Duri; Robert G. Lee; Ben Herbert; Peter Thompson; Megan Schalkwyk; Samuel Getahun; Karl D. Dearn; Luisa Orsini

doi:10.1016/j.scitotenv.2023.167224

Harnessing water fleas for water reclamation: A nature-based tertiary wastewater treatment technology

Muhammad Abdullahi, Iestyn Stead, Sophie Bennett, Rafael Orozco, Mohamed Abou-elwafa Abdallah, Sara Jabbari, Lynne E. Macaskie, Alexandra Tzella, Stefan Krause, Bushra Al-Duri, Robert G. Lee, Ben Herbert, Peter Thompson, Megan Schalkwyk, Samuel Getahun, Karl D. Dearn, Luisa Orsini^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

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Abstract

Urbanisation, population growth, and climate change have put unprecedented pressure on water resources, leading to a global water crisis and the need for water reuse. However, water reuse is unsafe unless persistent chemical pollutants are removed from reclaimed water. State-of-the-art technologies for the reduction of persistent chemical pollutants in wastewater typically impose high operational and energy costs and potentially generate toxic by-products (e.g., bromate from ozonation). Nature-base solutions are preferred to these technologies for their lower environmental impact. However, so far, bio-based tertiary wastewater treatments have been inefficient for industrial-scale applications. Moreover, they often demand significant financial investment and large infrastructure, undermining sustainability objectives. Here, we present a scalable, low-cost, low-carbon, and retrofittable nature-inspired solution to remove persistent chemical pollutants (pharmaceutical, pesticides and industrial chemicals). We showed Daphnia's removal efficiency of individual chemicals and chemicals from wastewater at laboratory scale ranging between 50 % for PFOS and 90 % for diclofenac. We validated the removal efficiency of diclofenac at prototype scale, showing sustained performance over four weeks in outdoor seminatural conditions. A techno-commercial analysis on the Daphnia-based technology suggested several technical, commercial and sustainability advantages over established and emerging treatments at comparable removal efficiency, benchmarked on available data on individual chemicals. Further testing of the technology is underway in open flow environments holding real wastewater. The technology has the potential to improve the quality of wastewater effluent, meeting requirements to produce water appropriate for reuse in irrigation, industrial application, and household use. By preventing persistent chemicals from entering waterways, this technology has the potential to maximise the shift to clean growth, enabling water reuse, reducing resource depletion and preventing environmental pollution.

Original language	English
Article number	167224
Number of pages	11
Journal	Science of the Total Environment
Volume	905
Early online date	20 Sept 2023
DOIs	https://doi.org/10.1016/j.scitotenv.2023.167224
Publication status	Published - 20 Dec 2023

Bibliographical note

Acknowledgements:
We thank Chantal Jackson for the artwork of Fig. 1. This work was funded by the NERC highlights grant deCODE (NE/N016777/1), the Alan Turing Institute (under EPSRC grant R-BIR-001). MA is supported by the Petroleum Technology Development Fund, Nigeria (PTDF/ED/OSS/POF/1369/18).

Keywords

Water reclamation
Biotechnology
Tertiary wastewater treatment
Pharmaceuticals
Pesticides
PFOS

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10.1016/j.scitotenv.2023.167224Licence: Creative Commons: Attribution (CC BY)

Abdullahi2023_Harnessing_water_fleasFinal published version, 6.42 MBLicence: Creative Commons: Attribution (CC BY)

Cracking the Code of Adaptive Evolution (deCODE)
Brown, J., Orsini, L., Viant, M., Compton, L., Colbourne, J., He, S. & Windridge, D.
Natural Environment Research Council
1/05/16 → 31/01/22
Project: Research Councils

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Abdullahi, M., Stead, I., Bennett, S., Orozco, R., Abdallah, M. A., Jabbari, S., Macaskie, L. E., Tzella, A., Krause, S., Al-Duri, B., Lee, R. G., Herbert, B., Thompson, P., Schalkwyk, M., Getahun, S., Dearn, K. D., & Orsini, L. (2023). Harnessing water fleas for water reclamation: A nature-based tertiary wastewater treatment technology. Science of the Total Environment, 905, Article 167224. https://doi.org/10.1016/j.scitotenv.2023.167224

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title = "Harnessing water fleas for water reclamation: A nature-based tertiary wastewater treatment technology",

abstract = "Urbanisation, population growth, and climate change have put unprecedented pressure on water resources, leading to a global water crisis and the need for water reuse. However, water reuse is unsafe unless persistent chemical pollutants are removed from reclaimed water. State-of-the-art technologies for the reduction of persistent chemical pollutants in wastewater typically impose high operational and energy costs and potentially generate toxic by-products (e.g., bromate from ozonation). Nature-base solutions are preferred to these technologies for their lower environmental impact. However, so far, bio-based tertiary wastewater treatments have been inefficient for industrial-scale applications. Moreover, they often demand significant financial investment and large infrastructure, undermining sustainability objectives. Here, we present a scalable, low-cost, low-carbon, and retrofittable nature-inspired solution to remove persistent chemical pollutants (pharmaceutical, pesticides and industrial chemicals). We showed Daphnia's removal efficiency of individual chemicals and chemicals from wastewater at laboratory scale ranging between 50 % for PFOS and 90 % for diclofenac. We validated the removal efficiency of diclofenac at prototype scale, showing sustained performance over four weeks in outdoor seminatural conditions. A techno-commercial analysis on the Daphnia-based technology suggested several technical, commercial and sustainability advantages over established and emerging treatments at comparable removal efficiency, benchmarked on available data on individual chemicals. Further testing of the technology is underway in open flow environments holding real wastewater. The technology has the potential to improve the quality of wastewater effluent, meeting requirements to produce water appropriate for reuse in irrigation, industrial application, and household use. By preventing persistent chemicals from entering waterways, this technology has the potential to maximise the shift to clean growth, enabling water reuse, reducing resource depletion and preventing environmental pollution.",

keywords = "Water reclamation, Biotechnology, Tertiary wastewater treatment, Pharmaceuticals, Pesticides, PFOS",

author = "Muhammad Abdullahi and Iestyn Stead and Sophie Bennett and Rafael Orozco and Abdallah, {Mohamed Abou-elwafa} and Sara Jabbari and Macaskie, {Lynne E.} and Alexandra Tzella and Stefan Krause and Bushra Al-Duri and Lee, {Robert G.} and Ben Herbert and Peter Thompson and Megan Schalkwyk and Samuel Getahun and Dearn, {Karl D.} and Luisa Orsini",

note = "Acknowledgements: We thank Chantal Jackson for the artwork of Fig. 1. This work was funded by the NERC highlights grant deCODE (NE/N016777/1), the Alan Turing Institute (under EPSRC grant R-BIR-001). MA is supported by the Petroleum Technology Development Fund, Nigeria (PTDF/ED/OSS/POF/1369/18).",

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Abdullahi, M, Stead, I, Bennett, S, Orozco, R , Abdallah, MA , Jabbari, S, Macaskie, LE, Tzella, A , Krause, S , Al-Duri, B, Lee, RG, Herbert, B, Thompson, P, Schalkwyk, M, Getahun, S, Dearn, KD & Orsini, L 2023, 'Harnessing water fleas for water reclamation: A nature-based tertiary wastewater treatment technology', Science of the Total Environment, vol. 905, 167224. https://doi.org/10.1016/j.scitotenv.2023.167224

TY - JOUR

T1 - Harnessing water fleas for water reclamation

T2 - A nature-based tertiary wastewater treatment technology

AU - Abdullahi, Muhammad

AU - Stead, Iestyn

AU - Bennett, Sophie

AU - Orozco, Rafael

AU - Abdallah, Mohamed Abou-elwafa

AU - Jabbari, Sara

AU - Macaskie, Lynne E.

AU - Tzella, Alexandra

AU - Krause, Stefan

AU - Al-Duri, Bushra

AU - Lee, Robert G.

AU - Herbert, Ben

AU - Thompson, Peter

AU - Schalkwyk, Megan

AU - Getahun, Samuel

AU - Dearn, Karl D.

AU - Orsini, Luisa

N1 - Acknowledgements: We thank Chantal Jackson for the artwork of Fig. 1. This work was funded by the NERC highlights grant deCODE (NE/N016777/1), the Alan Turing Institute (under EPSRC grant R-BIR-001). MA is supported by the Petroleum Technology Development Fund, Nigeria (PTDF/ED/OSS/POF/1369/18).

PY - 2023/12/20

Y1 - 2023/12/20

N2 - Urbanisation, population growth, and climate change have put unprecedented pressure on water resources, leading to a global water crisis and the need for water reuse. However, water reuse is unsafe unless persistent chemical pollutants are removed from reclaimed water. State-of-the-art technologies for the reduction of persistent chemical pollutants in wastewater typically impose high operational and energy costs and potentially generate toxic by-products (e.g., bromate from ozonation). Nature-base solutions are preferred to these technologies for their lower environmental impact. However, so far, bio-based tertiary wastewater treatments have been inefficient for industrial-scale applications. Moreover, they often demand significant financial investment and large infrastructure, undermining sustainability objectives. Here, we present a scalable, low-cost, low-carbon, and retrofittable nature-inspired solution to remove persistent chemical pollutants (pharmaceutical, pesticides and industrial chemicals). We showed Daphnia's removal efficiency of individual chemicals and chemicals from wastewater at laboratory scale ranging between 50 % for PFOS and 90 % for diclofenac. We validated the removal efficiency of diclofenac at prototype scale, showing sustained performance over four weeks in outdoor seminatural conditions. A techno-commercial analysis on the Daphnia-based technology suggested several technical, commercial and sustainability advantages over established and emerging treatments at comparable removal efficiency, benchmarked on available data on individual chemicals. Further testing of the technology is underway in open flow environments holding real wastewater. The technology has the potential to improve the quality of wastewater effluent, meeting requirements to produce water appropriate for reuse in irrigation, industrial application, and household use. By preventing persistent chemicals from entering waterways, this technology has the potential to maximise the shift to clean growth, enabling water reuse, reducing resource depletion and preventing environmental pollution.

AB - Urbanisation, population growth, and climate change have put unprecedented pressure on water resources, leading to a global water crisis and the need for water reuse. However, water reuse is unsafe unless persistent chemical pollutants are removed from reclaimed water. State-of-the-art technologies for the reduction of persistent chemical pollutants in wastewater typically impose high operational and energy costs and potentially generate toxic by-products (e.g., bromate from ozonation). Nature-base solutions are preferred to these technologies for their lower environmental impact. However, so far, bio-based tertiary wastewater treatments have been inefficient for industrial-scale applications. Moreover, they often demand significant financial investment and large infrastructure, undermining sustainability objectives. Here, we present a scalable, low-cost, low-carbon, and retrofittable nature-inspired solution to remove persistent chemical pollutants (pharmaceutical, pesticides and industrial chemicals). We showed Daphnia's removal efficiency of individual chemicals and chemicals from wastewater at laboratory scale ranging between 50 % for PFOS and 90 % for diclofenac. We validated the removal efficiency of diclofenac at prototype scale, showing sustained performance over four weeks in outdoor seminatural conditions. A techno-commercial analysis on the Daphnia-based technology suggested several technical, commercial and sustainability advantages over established and emerging treatments at comparable removal efficiency, benchmarked on available data on individual chemicals. Further testing of the technology is underway in open flow environments holding real wastewater. The technology has the potential to improve the quality of wastewater effluent, meeting requirements to produce water appropriate for reuse in irrigation, industrial application, and household use. By preventing persistent chemicals from entering waterways, this technology has the potential to maximise the shift to clean growth, enabling water reuse, reducing resource depletion and preventing environmental pollution.

KW - Water reclamation

KW - Biotechnology

KW - Tertiary wastewater treatment

KW - Pharmaceuticals

KW - Pesticides

KW - PFOS

U2 - 10.1016/j.scitotenv.2023.167224

DO - 10.1016/j.scitotenv.2023.167224

M3 - Article

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SN - 0048-9697

VL - 905

JO - Science of the Total Environment

JF - Science of the Total Environment

M1 - 167224

ER -

Harnessing water fleas for water reclamation: A nature-based tertiary wastewater treatment technology

Abstract

Bibliographical note

Keywords

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Cracking the Code of Adaptive Evolution (deCODE)

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