Electrospun polymeric membranes: Potential removal of endocrine disrupting compounds using solid membrane extraction and filtration processes

Nectoux, Aline da Silveira; Medeiros, Leonardo Ferreira; Leão, Mayara Bitencourt; Fernandes, Andreia Neves

doi:10.1002/app.53256

Cited by 2 publications

(1 citation statement)

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“…Many solutions have been tested in recent years to efficiently remove drugs like atenolol from aqueous systems, such as advanced oxidative processes and photodegradation, ,,, catalysis, biological processes, ozonation, and nanofiltration . Chlorination was also able to degrade atenolol effectively but, at the same time, generated many byproducts with high toxicity. , Therefore, implementing technologies that apply porous materials to remove pharmaceuticals from water through the sorption processes has gained much attention in recent years. , Many materials are used to remove different organic compounds. − Among the materials used to remove atenolol from water are activated carbons, ,− montmorillonite, , kaolinite, porous metal–organic frameworks (MOF), polymers, multiwalled carbon nanotubes (MWCNT), − and graphene oxide (GO). , …”

Section: Introductionmentioning

confidence: 99%

Nanocarbon Dimensionality and Oxidation Degree Influence the Sorption of Atenolol: Implications for Water Treatment

Leão,

Fernandes,

Ferreira de Matos Jauris

2024

ACS Appl. Nano Mater.

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Emerging contaminants, such as atenolol, in water environments are a reality that cannot be avoided. One of the alternatives to alleviating this situation is using materials capable of removing these compounds from water by adsorption. Many materials have proven efficient, and carbon nanomaterials can be emphasized. A gap in these studies is the comparison of different dimensions of the materials because carbon nanomaterials can be obtained in 0, 1, 2, or 3 dimensions. In this context, the present work aims to unravel the differences in the ability to absorb atenolol in carbon nanomaterials with different dimensions and degrees of oxidation: multiwalled carbon nanotubes, oxidized or not, reduced graphene oxide, and three-dimensional reduced graphene oxide with different degrees of oxidation. Experiments were performed to evaluate the kinetic and isothermal performance of the materials as well as their reuse. In addressing the abstract graphic: yes, both the dimensionality and the degree of oxidation influence the adsorption of the drug. The results showed that the sorptive capacity tends to increase with the increase in the dimensionality and with the degree of oxidation of the structures. Thus, the more oxidized three-dimensional reduced graphene oxide showed excellent interaction with atenolol, with a high sorptive capacity that can be quickly obtained. This better sorption capacity results from its oxidized structure and morphology with noncompacted cavities. Finally, the reuse study also showed excellent results for the same nanomaterial, underlining its performance in the present study. Thus, this tridimensional material is an efficient alternative for removing atenolol from aqueous environments and can be efficiently applied in water treatment.

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