Experimental and modeling of tetracycline degradation in water in a flow-through enzymatic monolithic reactor

Ahmad, Sher; Sebai, Wassim; Belleville, Marie-Pierre,; Brun, Nicolas; Galarneau, Anne; Sánchez-Marcano, José

doi:10.1007/s11356-022-21204-y

Cited by 3 publications

(1 citation statement)

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“…[14] In Figure 2 flow rate of 1 mL min −1 with continuous recycling. [15] They found that 40%-50% of tetracycline was degraded in 5 h. Additionally, the silica monolith immobilized laccase presented high operational stability during 75 h which, according to the authors, indicated the applicability of the developed reactors on a large scale. However, the scalability of such minireactors is a matter to be researched.…”

Section: Immobilized-laccase Bioreactors For Wastewater Treatmentmentioning

confidence: 83%

Immobilized‐laccase bioreactors for wastewater treatment

Rodríguez‐Couto

2023

Biotechnology Journal

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Laccases have shown to be efficient biocatalysts for the removal of recalcitrant pollutants from wastewater. Thus, they catalyze the oxidation of a wide variety of organic compounds by reducing molecular oxygen to water. However, the use of free laccases holds several drawbacks such as poor reusability, high cost, low stability and sensitivity to different denaturing agents that may occur in wastewater. Such drawbacks can be circumvented by immobilizing laccase enzymes in/on solid carriers. Hence, during the last decades different approaches considering various techniques and solid carriers to immobilize laccase enzymes have been developed and tested for the removal of pollutants from wastewater. To scale up wastewater treatment bioprocesses, immobilized laccases are placed in different reactor configurations.

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Section: Immobilized-laccase Bioreactors For Wastewater Treatmentmentioning

confidence: 83%

Immobilized‐laccase bioreactors for wastewater treatment

Rodríguez‐Couto

2023

Biotechnology Journal

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Towards oxidoreductase-based processes for the removal of antibiotics from wastewater

de Boer,

Schäffer,

Moreira

2023

Rev Environ Sci Biotechnol

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The occurrence of antibiotics in surface waters is an alarming issue that can be addressed by advanced wastewater treatment technologies. Among them, enzymatic treatment is an emerging technology claimed to provide prospective benefits in terms of efficiency, controllability, and safety. This review illustrates the current state of research focused on enzyme-based approaches for pollutant abatement, specifically on the most critical classes of antibiotics (e.g. tetracyclines, sulfonamides, fluoroquinolones). In addition to providing an overview of the efficiency both in terms of compound removal as well as toxicity reduction, we critically analyze if selected reaction conditions, such as the pH, temperature and water matrix are representative for real-case scenarios. Enzyme immobilization strategies onto inorganic, organic and composite materials are analyzed in terms of their effect on enzyme stability and activity. Their feasibility to be applied in future processes was also evaluated. We found that adequate kinetic description of target compound removal by sufficiently detailed models is still scarce even though it will be key for successful conceptualization of treatment processes. Considering that only a few studies have been conducted at scales above 100 mL, we present the investigated reactor configurations which are at the forefront of further scale-up. The systematic approach presented in this manuscript, which aims to critically evaluate the feasibility to implement enzymatic processes for the removal of antibiotics, can be adapted for other types of recalcitrant compounds targeted by oxidoreductases. Intensified research in the recommended areas will contribute to the development of enzyme-based processes which can complement other advanced wastewater treatment processes. Graphical abstract

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