The Use of Biochar and Pyrolysed Materials to Improve Water Quality through Microcystin Sorption Separation

Frišták, Vladimír; Laughinghouse, Haywood Dail; Bell, Stephen M.

doi:10.3390/w12102871

Cited by 13 publications

(20 citation statements)

References 114 publications

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“…This is likely due to the higher aromatic content in FSHA than in MC-LR that competes with MC-LR for the binding sites on BC via π–π interactions . Furthermore, FSHA (average molar mass 39.098 kDa) can also block BC mesopores to hinder the adsorption of MC-LR (∼1 kDa) by BC. ,, Therefore, the presence of FSHA negatively impacted the two major driving forces of MC-LR adsorption by BC (π–π interactions and mesopore filling) . Coating PDDA hydrogel on BC also reduced the mesopore volume (from 0.055 to 0.027 cm 3 /g as shown in Figure S2) but introduced new functional groups to the adsorbent, consequently altered the mechanisms of MC-LR adsorption from pore-filling to chemical attractions, and overcame the drawbacks of BC for MC-LR adsorption in the presence of FSHA.…”

Section: Resultsmentioning

confidence: 99%

Immobilization of Microcystin by the Hydrogel–Biochar Composite to Enhance Biodegradation during Drinking Water Treatment

Zhang,

Tang,

Jiang

2023

ACS EST Water

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Microcystin-LR (MC-LR), the most common algal toxin in freshwater, poses an escalating threat to safe drinking water. This study aims to develop an engineered biofiltration system for water treatment, employing a composite of poly(diallyldimethylammonium chloride)–biochar (PDDA–BC) as a filtration medium. The objective is to capture MC-LR selectively and quickly from water, enabling subsequent biodegradation of toxin by bacteria embedded on the composite. The results showed that PDDA–BC exhibited a high selectivity in adsorbing MC-LR, even in the presence of competing natural organic matter and anions. The adsorption kinetics of MC-LR was faster, and capacity was greater compared to traditional adsorbents, achieving a capture rate of 98% for MC-LR (200 μg/L) within minutes to tens of minutes. Notably, the efficient adsorption of MC-LR was also observed in natural lake waters, underscoring the substantial potential of PDDA–BC for immobilizing MC-LR during biofiltration. Density functional theory calculations revealed that the synergetic effects of electrostatic interaction and π–π stacking predominantly contribute to the adsorption selectivity of MC-LR. Furthermore, experimental results validated that the combination of PDDA–BC with MC-degrading bacteria offered a promising and effective approach to achieve a sustainable removal of MC-LR through an “adsorption–biodegradation” process.

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Section: Resultsmentioning

confidence: 99%

Immobilization of Microcystin by the Hydrogel–Biochar Composite to Enhance Biodegradation during Drinking Water Treatment

Zhang,

Tang,

Jiang

2023

ACS EST Water

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“…Techniques used for water filtration to remove harmful compounds, such as cyanobacteria and cyanotoxins, include activated carbon filtration, clay-like silica material, adsorption, biologically active sand filtration, and membrane filtration. In most cases, these techniques are preceded by coagulation-flocculation processes [89][90][91][92][93][94].…”

Section: Filtration and Complexationmentioning

confidence: 99%

“…For instance, it was reported that there is strong proton adsorption in the case of the presence of several hydroxyl or phenolic groups under certain pH conditions [95,97,100]. Activated carbon may derive from different materials, namely wood, coal, coconut shells, or peat [75,92,[101][102][103]. Notwithstanding, Albuquerque et al [102] related the existence of MC-LR adsorption differences even among types of woods from which charcoal can be made; therefore, a wise choice of the sample of wood to be used has been made to maximize adsorption.…”

Section: Filtration and Complexationmentioning

confidence: 99%

Multi-Soil-Layering Technology: A New Approach to Remove Microcystis aeruginosa and Microcystins from Water

Mugani

Prisca

Hejjaj

et al. 2022

Water

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Eutrophication of surface waters caused by toxic cyanobacteria such as Microcystis aeruginosa leads to the release of secondary metabolites called Microcystins (MCs), which are heptapeptides with adverse effects on soil microbiota, plants, animals, and human health. Therefore, to avoid succumbing to the negative effects of these cyanotoxins, various remediation approaches have been considered. These techniques involve expensive physico-chemical processes because of the specialized equipment and facilities required. Thus, implementing eco-technologies capable of handling this problem has become necessary. Indeed, multi-soil-layering (MSL) technology can essentially meet this requirement. This system requires little space, needs simple maintenance, and has energy-free operation and high durability (20 years). The performance of the system is such that it can remove 1.16 to 4.47 log10 units of fecal contamination from the water, 98% of suspended solids (SS), 92% of biological oxygen demand (BOD), 98% of chemical oxygen demand (COD), 92% of total nitrogen (TN), and 100% of total phosphorus (TP). The only reported use of the system to remove cyanotoxins has shown a 99% removal rate of MC-LR. However, the mechanisms involved in removing this toxin from the water are not fully understood. This paper proposes reviewing the principal methods employed in conventional water treatment and other technologies to eliminate MCs from the water. We also describe the principles of operation of MSL systems and compare the performance of this technology with others, highlighting some advantages of this technology in removing MCs. Overall, the combination of multiple processes (physico-chemical and biological) makes MSL technology a good choice of cyanobacterial contamination treatment system that is applicable in real-life conditions, especially in rural areas.

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“…These techniques rely on the removal of whole cells and are not as effective against the free microcystins released upon cell lysis . Sand filtration is another commonly used water treatment technique, which can effectively remove up to 94% of microcystins under optimal conditions. , However, reductions in temperature to 0–10 °C have been found to greatly reduce efficiency, with only 43% microcystin removal reported. Sand filtration also relies on long water residing times of 2–6 months for optimal microcystin removal, which is not always feasible; therefore, rapid sand filtration methods with reduced residing times are often employed.…”

Section: Introductionmentioning

confidence: 99%

“…In conjunction with the aforementioned water treatment methods, additional disinfection processes such as chlorination, ozone, or activated carbon may be employed. Chlorination has been shown to remove up to 99% of microcystin in lab-scale studies, however, the formation of undesirable toxic byproducts is problematic. , Ozone treatment of drinking water can effectively remove microcystins; however, the process requires close monitoring as the amount of ozone required to achieve this varies depending on the water quality. , Combination of these methods with UV irradiation has been shown to improve their efficacy. , …”

Section: Introductionmentioning

confidence: 99%

Nature-Based Solution to Eliminate Cyanotoxins in Water Using Biologically Enhanced Biochar

Moore,

Jayakumar,

Soldatou

et al. 2023

Environ. Sci. Technol.

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Climate change and high eutrophication levels of freshwater sources are increasing the occurrence and intensity of toxic cyanobacterial blooms in drinking water supplies. Conventional water treatment struggles to eliminate cyanobacteria/ cyanotoxins, and expensive tertiary treatments are needed. To address this, we have designed a sustainable, nature-based solution using biochar derived from waste coconut shells. This biochar provides a low-cost porous support for immobilizing microbial communities, forming biologically enhanced biochar (BEB). Highly toxic microcystin-LR (MC-LR) was used to influence microbial colonization of the biochar by the natural lake-water microbiome. Over 11 months, BEBs were exposed to microcystins, cyanobacterial extracts, and live cyanobacterial cells, always resulting in rapid elimination of toxins and even a 1.6−1.9 log reduction in cyanobacterial cell numbers. After 48 h of incubation with our BEBs, the MC-LR concentrations dropped below the detection limit of 0.1 ng/mL. The accelerated degradation of cyanotoxins was attributed to enhanced species diversity and microcystin-degrading microbes colonizing the biochar. To ensure scalability, we evaluated BEBs produced through batch-scale and continuous-scale pyrolysis, while also guaranteeing safety by maintaining toxic impurities in biochar within acceptable limits and monitoring degradation byproducts. This study serves as a proof-of-concept for a sustainable, scalable, and safe nature-based solution for combating toxic algal blooms.

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The Use of Biochar and Pyrolysed Materials to Improve Water Quality through Microcystin Sorption Separation

Cited by 13 publications

References 114 publications

Immobilization of Microcystin by the Hydrogel–Biochar Composite to Enhance Biodegradation during Drinking Water Treatment

Immobilization of Microcystin by the Hydrogel–Biochar Composite to Enhance Biodegradation during Drinking Water Treatment

Multi-Soil-Layering Technology: A New Approach to Remove Microcystis aeruginosa and Microcystins from Water

Nature-Based Solution to Eliminate Cyanotoxins in Water Using Biologically Enhanced Biochar

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