Adsorptive removal of ciprofloxacin and sulfamethoxazole from aqueous matrices using sawdust and plastic waste-derived biochar: A sustainable fight against antibiotic resistance

[Display omitted] •Sawdust and plastic waste are used to prepare biochars for CFX and SMX removal.•Sawdust biochar (SB) showed higher antibiotics removal compared to the hybrid one.•SB reported >95% and >99% removal efficiency for CFX and SMX, respectively.•Adsorption processes followed the PS...

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Bibliographic Details
Published in:Bioresource technology 2023-11, Vol.387, p.129537-129537, Article 129537
Main Authors: Silori, Rahul, Zang, Jian, Raval, Nirav P., Giri, Balendu Shekher, Mahlknecht, Jürgen, Mora, Abrahan, Dueñas-Moreno, Jaime, Tauseef, Syed Mohammad, Kumar, Manish
Format: Article
Language:English
Subjects:
Adsorptive removal
Antibiotics
Chemisorption
Plastic waste
Sawdust
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Summary:[Display omitted] •Sawdust and plastic waste are used to prepare biochars for CFX and SMX removal.•Sawdust biochar (SB) showed higher antibiotics removal compared to the hybrid one.•SB reported >95% and >99% removal efficiency for CFX and SMX, respectively.•Adsorption processes followed the PSO (R2=>0.8) kinetic model.•Adsorption occurred via H-bonding, electrostatic and π–π EDA interactions. We produced carbon-negative biochar from the pyrolysis of sawdust biomass alone (SB) and from the co-pyrolysis of sawdust and plastic waste (SPB). The co-pyrolysis approach in this study was driven by several hypothetical factors, such as increased porosity, surface chemistry, stability, as well as waste management. We applied pyrolyzed and co-pyrolyzed biochars for the removal of ciprofloxacin (CFX) and sulfamethoxazole (SMX). Due to its more alkaline and amorphous nature, SB showed better removal efficiencies compared to SPB. The maximum removals of CFX and SMX with SB were observed as ∼95% and >95%, respectively whereas with SPB were 58.8%, and 34.9%, respectively. The primary mechanisms involved in the adsorption process were H-bonding, electrostatic and π–π electron donor–acceptor interactions. Homogenously and heterogeneously driven adsorption of both antibiotics followed the pseudo-second-order kinetic model, implying electron sharing/transfer (chemisorption) mediated adsorption. The work is highly pertinent in the context of emerging concerns related to drivers that promote antimicrobial resistance.
ISSN:0960-8524
1873-2976
DOI:10.1016/j.biortech.2023.129537