Solar photocatalytic oxidation of recalcitrant natural metabolic by-products of amoxicillin biodegradation

Pereira, João; Reis, Ana C.; Homem, Vera; Silva, José Avelino; Alves, Arminda; Borges, Maria Teresa Mendes Ribeiro; Boaventura, Rui A.R.; Vilar, Vítor J.P.; Nunes, Olga C.

doi:10.1016/j.watres.2014.07.037

Cited by 40 publications

(17 citation statements)

References 59 publications

(58 reference statements)

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“…Previous investigations have revealed that the degradation of recalcitrant compounds may lead to the creation of harmful solutions (Bernabeu et al, 2012;Pereira et al, 2014;Wu et al, 2009). To evaluate the extent of degradation during the UV/H 2 O 2 /Fe 2þ , UV/ TiO 2 and US processes, the evolution of DXC and dissolved organic carbon (DOC) was determined (Fig.…”

Section: Evaluation Of Antimicrobial Activity Mineralization and Levmentioning

confidence: 99%

Selecting the best AOP for isoxazolyl penicillins degradation as a function of water characteristics: Effects of pH, chemical nature of additives and pollutant concentration

Villegas-Guzmán

Silva-Agredo

Flórez

et al. 2017

Journal of Environmental Management

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a b s t r a c tTo provide new insights toward the selection of the most suitable AOP for isoxazolyl penicillins elimination, the degradation of dicloxacillin, a isoxazolyl penicillin model, was studied using different advanced oxidation processes (AOPs): ultrasound (US), photo-Fenton (UV/H 2 O 2 /Fe 2þ ) and TiO 2 photocatalysis (UV/TiO 2 ). Although all processes achieved total removal of the antibiotic and antimicrobial activity, and increased the biodegradability level of the solutions, significant differences concerning the mineralization extend, the pH of the solution, the pollutant concentration and the chemical nature of additives were found. UV/TiO 2 reached almost complete mineralization; while~10% mineralization was obtained for UV/H 2 O 2 /Fe 2þ and practically zero for US. Effect of initial pH, mineral natural water and the presence of organic (glucose, 2-propanol and oxalic acid) were then investigated. UV/H 2 O 2 /Fe 2þ and US processes were improved in acidic media, while natural pH favored UV/TiO 2 system. According to both the nature of the added organic compound and the process, inhibition, no effect or enhancement of the degradation rate was observed. The degradation in natural mineral water showed contrasting results according to the antibiotic concentration: US process was enhanced at low concentration of dicloxacillin followed by detrimental effects at high substrate concentrations. A contrary effect was observed during photo-Fenton, while UV/TiO 2 was inhibited in all of cases. Finally, a schema illustrating the enhancement or inhibiting effects of water matrix is proposed as a tool for selecting the best process for isoxazolyl penicillins degradation.

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Section: Evaluation Of Antimicrobial Activity Mineralization and Levmentioning

confidence: 99%

Selecting the best AOP for isoxazolyl penicillins degradation as a function of water characteristics: Effects of pH, chemical nature of additives and pollutant concentration

Villegas-Guzmán

Silva-Agredo

Flórez

et al. 2017

Journal of Environmental Management

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“…Regarding the technology for β-lactam antibiotic degradation, various methods such as nano ltration [26], ozonation [27,28], biodegradation [29], surface adsorption [30], advanced oxidation [19,31] and photocatalytic processes [22,32] have been reported to remove β-lactam antibiotics. However, biodegradation typically results in incomplete mineralization; furthermore, low degradation e ciency has been observed by several authors [33,34]. Mineralization degradation of antibiotic residues occur at different scales, including in wastewater, antibiotic mycelium, and other ecological environments.…”

Section: Introductionmentioning

confidence: 99%

Degradation of Penicillin G by Visible Light Irradiation-Assisted Biotransformation by Whole Cell paracoccus sp .

Wang¹,

Shen²,

Cong³

et al. 2020

Preprint

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Background: The Paracoccus sp. strain (KDSPL-02) isolated from sludge was identified and evaluated for catalytic activity in the degradation of penicillin G. Results: High degradation efficiency and synergistic catalytic effects of the whole cell and visible light without additional catalysts were observed. The key factors influencing the degradation and kinetics of penicillin G were investigated. The results showed the phenylacetic acid, which was produced during penicillin G biodegradation, exhibited stronger inhibiting effects on KDSPL-02. However, this effect was reduced by visible light irradiation without any additional photocatalyst; furthermore, the rate of penicillin G biodegradation was accelerated, reaching a 100% rate in 12 h at a penicillin G concentration of 1.2 g/L. Four key intermediates produced during penicillin G degradation were isolated and identified by LC–MS, 1H NMR, and 13C NMR. Enzymes involved in the PAA pathway were proposed from a genomic analysis of paracoccus sp. KDSPL-02. Conclusions:These results provide a new method for bio-degrading of penicillin or other antibiotic pollutants using photoaccelerating biocatalysts with greater efficiency and more environmentally friendly conditions.

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“…Currently, physicochemical methods such as ion exchange, reverse osmosis, and electrodialysis have been used to remove nitrate from water, but they generally require further treatment of the concentrated solution, cause the losses of other useful elements (Chaplin et al, 2012;Li et al, 2016;Zhang et al, 2014), and usually consume high energy. Biological approaches are useful for nitrate removal from wastewater, though their application for water environmental remediation is limited, due to the challenges of performance maintenance and secondary pollution associated with carbon source supply and the pathogen concerns (Cardoso et al, 2016;Cheng et al, 2012;Pereira et al, 2014). Performance of a biological treatment system is affected by many factors, especially microbial communities involved in the system.…”

Section: Introductionmentioning

confidence: 99%

Denitrification in an integrated bioelectro-photocatalytic system

Lin

Yuan

et al. 2017

Water Research

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Since nitrate causes severe ecological and health risks, nitrate contamination of drinking water sources has become one of the most important water quality concerns all over the world. Photocatalytic reduction of nitrate to molecular nitrogen presents a promising approach to remove nitrate from drinking water sources. However, harmful intermediates like NO, NO, NO and NO are usually formed, and metal loading or hole scavengers are generally needed to reduce the recombination of photo-generated electrons and holes, which will cause secondary pollution to drinking water. In this work, an efficient, selective and sustainable bioelectro-photocatalytic nitrate-reducing system by utilizing commercial TiO nanoparticles P25 as the photocatalyst and bio-electrons from microbial metabolism as the hole scavenger is reported. In this system, bio-electrons extracted from organic substrates in bioanode are transferred to the photocathode through an external circuit for hole quenching. With the utilization of the residual photogenerated electrons, nitrate is completely reduced to nitrogen without accumulation of harmful nitrite or ammonium. The experimental results and the mechanistic analysis using the first-principles density functional theory calculations demonstrate that toxic by-products like nitrite or ammonium will not be accumulated in this system. Thus, this approach has a great potential for sustainable remediation of nitrate-contaminated drinking water sources.

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Solar photocatalytic oxidation of recalcitrant natural metabolic by-products of amoxicillin biodegradation

Cited by 40 publications

References 59 publications

Selecting the best AOP for isoxazolyl penicillins degradation as a function of water characteristics: Effects of pH, chemical nature of additives and pollutant concentration

Selecting the best AOP for isoxazolyl penicillins degradation as a function of water characteristics: Effects of pH, chemical nature of additives and pollutant concentration

Degradation of Penicillin G by Visible Light Irradiation-Assisted Biotransformation by Whole Cell paracoccus sp .

Denitrification in an integrated bioelectro-photocatalytic system

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