Technological watch
Paper coating biomaterials derived from anaerobic granular sludge may be cost-effective
The demand for paper and paperboard production continuously grows worldwide, particularly in the packaging industry. Due to the paper’s nature, it usually requires a surface coating to keep out water, oil, and other unwanted substances. These coatings can come with high financial and environmental costs. Using renewable coating materials that are also cost-effective can support sustainability strategies.
A promising new technique using extracellular polymeric substances (EPS) recovered from anaerobic granular sludge may offer a cost-effective, sustainable approach for transforming wastewater into industrially valuable products, and help to reduce carbon emissions.
In a study published in researchers coated paper using EPS extracted from various anaerobic granules in wastewater. This approach enhanced waterproofing (65%), as well as oil and grease resistance, while the multi-layered microstructure of the coated paper exhibited a smoother and less porous surface overall. Extracellular proteins, abundant in ?-sheets and random coils, play a pivotal structural role in paper coating.
Biological treatment based on activated sludge has been the most widely used approach in removing major pollutants from wastewater. However, excess sludge disposal accounts for up to 50% of wastewater treatment costs and presents a significant challenge in wastewater treatment. Wastewater treatment plants are shifting to recovering raw materials, turning these into potential renewable sources. Excess sludge, rich in EPS, is becoming increasingly attractive and contributes to implementing the “biorefinery” paradigm from wastewater treatment plants. EPS-based biomaterials are potential alternatives to synthetic polymers in various applications, such as agriculture, medical, and construction industries, as they have polysaccharides, proteins, and humic-acid substances.
In this study, anaerobic granules were collected from a brewery wastewater treatment plant and a paper-industry wastewater treatment plant. Regardless of the different sludge sources, EPS from both types were mainly composed of proteins. EEM spectra confirmed that tryptophan or protein-like components were the dominant substances, together with humic-like components.
The addition of EPS resulted in improved water/grease-proofing behaviour. The best results were achieved with the EPS samples from paper-industry sludge, characterised by a higher fraction of proteins and hydrophobic contents than the other EPS samples. Moreover, the extracellular proteins rich in ?-sheets and random coil would facilitate a structural role for paper coating.
This research establishes for the first time that EPS derived from anaerobic granules exhibits interesting water barrier properties when used as paper coating additives. More importantly, from the paper industry’s perspective, these EPS enhance resistance to grease penetration and absorbance. These biomaterials recovered from waste granular sludge provide a sustainable resource for industrial application and promise to realise a sustainable and circular economy.
Journal
Environmental Science and Ecotechnology
DOI
10.1016/j.ese.2024.100397
Method of Research
Experimental study
Subject of Research
Cells
Article Publication Date
1-Feb-2024
A promising new technique using extracellular polymeric substances (EPS) recovered from anaerobic granular sludge may offer a cost-effective, sustainable approach for transforming wastewater into industrially valuable products, and help to reduce carbon emissions.
In a study published in researchers coated paper using EPS extracted from various anaerobic granules in wastewater. This approach enhanced waterproofing (65%), as well as oil and grease resistance, while the multi-layered microstructure of the coated paper exhibited a smoother and less porous surface overall. Extracellular proteins, abundant in ?-sheets and random coils, play a pivotal structural role in paper coating.
Biological treatment based on activated sludge has been the most widely used approach in removing major pollutants from wastewater. However, excess sludge disposal accounts for up to 50% of wastewater treatment costs and presents a significant challenge in wastewater treatment. Wastewater treatment plants are shifting to recovering raw materials, turning these into potential renewable sources. Excess sludge, rich in EPS, is becoming increasingly attractive and contributes to implementing the “biorefinery” paradigm from wastewater treatment plants. EPS-based biomaterials are potential alternatives to synthetic polymers in various applications, such as agriculture, medical, and construction industries, as they have polysaccharides, proteins, and humic-acid substances.
In this study, anaerobic granules were collected from a brewery wastewater treatment plant and a paper-industry wastewater treatment plant. Regardless of the different sludge sources, EPS from both types were mainly composed of proteins. EEM spectra confirmed that tryptophan or protein-like components were the dominant substances, together with humic-like components.
The addition of EPS resulted in improved water/grease-proofing behaviour. The best results were achieved with the EPS samples from paper-industry sludge, characterised by a higher fraction of proteins and hydrophobic contents than the other EPS samples. Moreover, the extracellular proteins rich in ?-sheets and random coil would facilitate a structural role for paper coating.
This research establishes for the first time that EPS derived from anaerobic granules exhibits interesting water barrier properties when used as paper coating additives. More importantly, from the paper industry’s perspective, these EPS enhance resistance to grease penetration and absorbance. These biomaterials recovered from waste granular sludge provide a sustainable resource for industrial application and promise to realise a sustainable and circular economy.
Journal
Environmental Science and Ecotechnology
DOI
10.1016/j.ese.2024.100397
Method of Research
Experimental study
Subject of Research
Cells
Article Publication Date
1-Feb-2024
This project has received funding from the Bio Based Industries Joint Undertaking under the European Union’s Horizon 2020 research and innovation programme under grant agreement No 837761.
