Your search keyword '"Oliaei, Erfan"' showing total 3 results

1. Lignin nanoparticles as co-stabilizers and modifiers of nanocellulose-based Pickering emulsions and foams

Author

Agustin, Melissa B., Nematollahi, Neda, Bhattarai, Mamata, Oliaei, Erfan, Lehtonen, Mari, Rojas, Orlando J., and Mikkonen, Kirsi S.

Published

2023

2. Enzymatic crosslinking of lignin nanoparticles and nanocellulose in cryogels improves adsorption of pharmaceutical pollutants.

Author

Agustin, Melissa B., Lahtinen, Maarit H., Kemell, Marianna, Oliaei, Erfan, Mikkonen, Kirsi S., Grönqvist, Stina, and Lehtonen, Mari

Subjects

*DRUG adsorption, *POLLUTANTS, *LIGNINS, *NANOPARTICLES, *ADSORPTION capacity, *SORBENTS

Abstract

Pharmaceuticals, designed for treating diseases, ironically endanger humans and aquatic ecosystems as pollutants. Adsorption-based wastewater treatment could address this problem, however, creating efficient adsorbents remains a challenge. Recent efforts have shifted towards sustainable bio-based adsorbents. Here, cryogels from lignin-containing cellulose nanofibrils (LCNF) and lignin nanoparticles (LNPs) were explored as pharmaceuticals adsorbents. An enzyme-based approach using laccase was used for crosslinking instead of fossil-based chemical modification. The impact of laccase treatment on LNPs alone produced surface-crosslinked water-insoluble LNPs with preserved morphology and a hemicellulose-rich, water-soluble LNP fraction. The water-insoluble LNPs displayed a significant increase in adsorption capacity, up to 140 % and 400 % for neutral and cationic drugs, respectively. The crosslinked cryogel prepared by one-pot incubation of LNPs, LCNF and laccase showed significantly higher adsorption capacities for various pharmaceuticals in a multi-component system than pure LCNF or unmodified cryogels. The crosslinking minimized the leaching of LNPs in water, signifying enhanced binding between LNPs and LCNF. In real wastewater, the laccase-modified cryogel displayed 8–44 % removal for cationic pharmaceuticals. Overall, laccase treatment facilitated the production of bio-based adsorbents by improving the deposition of LNPs to LCNF. Finally, this work introduces a sustainable approach for engineering adsorbents, while aligning with global sustainability goals. [Display omitted] • Developing sustainable efficient adsorbents for pharmaceuticals remains challenging. • Nanocellulose and lignin nanoparticles were laccase-crosslinked to produce adsorbents. • The enzyme-based approach effectively anchored lignin nanoparticles onto nanocellulose. • Enzymatic crosslinking prevented the leaching of LNPs from the adsorbent. • Enzymatic crosslinking improved the removal of pharmaceuticals both from synthetic and real wastewater. [ABSTRACT FROM AUTHOR]

Published

2024

3. Lignin nanoparticle-decorated nanocellulose cryogels as adsorbents for pharmaceutical pollutants.

Author

Agustin, Melissa B., Lehtonen, Mari, Kemell, Marianna, Lahtinen, Panu, Oliaei, Erfan, and Mikkonen, Kirsi S.

Subjects

*SORBENTS, *LIGNINS, *POLLUTANTS, *CHEMICAL structure, *SURFACE charges, *LIGNIN structure

Abstract

Adsorption is a relatively simple wastewater treatment method that has the potential to mitigate the impacts of pharmaceutical pollution. This requires the development of reusable adsorbents that can simultaneously remove pharmaceuticals of varying chemical structure and properties. Here, the adsorption potential of nanostructured wood-based adsorbents towards different pharmaceuticals in a multi-component system was investigated. The adsorbents in the form of macroporous cryogels were prepared by anchoring lignin nanoparticles (LNPs) to the nanocellulose network via electrostatic attraction. The naturally anionic LNPs were anchored to cationic cellulose nanofibrils (cCNF) and the cationic LNPs (cLNPs) were combined with anionic TEMPO-oxidized CNF (TCNF), producing two sets of nanocellulose-based cryogels that also differed in their overall surface charge density. The cryogels, prepared by freeze-drying, showed layered cellulosic sheets randomly decorated with spherical lignin on the surface. They exhibited varying selectivity and efficiency in removing pharmaceuticals with differing aromaticity, polarity and ionic characters. Their adsorption potential was also affected by the type (unmodified or cationic), amount and morphology of the lignin nanomaterials, as well as the pH of the pharmaceutical solution. Overall, the findings revealed that LNPs or cLNPs can act as functionalizing and crosslinking agents to nanocellulose-based cryogels. Despite the decrease in the overall positive surface charge, the addition of LNPs to the cCNF-based cryogels showed enhanced adsorption, not only towards the anionic aromatic pharmaceutical diclofenac but also towards the aromatic cationic metoprolol (MPL) and tramadol (TRA) and neutral aromatic carbamazepine. The addition of cLNPs to TCNF-based cryogels improved the adsorption of MPL and TRA despite the decrease in the net negative surface charge. The improved adsorption was attributed to modes of removal other than electrostatic attraction, and they could be π-π aromatic ring or hydrophobic interactions brought by the addition of LNPs or cLNPs. However, significant improvement was only found if the ratio of LNPs or cLNPs to nanocellulose was 0.6:1 or higher and with spherical lignin nanomaterials. As crosslinking agents, the LNPs or cLNPs affected the rheological behavior of the gels, and increased the firmness and decreased the water holding capacity of the corresponding cryogels. The resistance of the cryogels towards disintegration with exposure to water also improved with crosslinking, which eventually enabled the cryogels, especially the TCNF-based one, to be regenerated and reused for five cycles of adsorption-desorption experiment for the model pharmaceutical MPL. Thus, this study opened new opportunities to utilize LNPs in providing nanocellulose-based adsorbents with additional functional groups, which were otherwise often achieved by rigorous chemical modifications, at the same time, crosslinking the nanocellulose network. [Display omitted] • Pharmaceutical pollutants pose serious threats to human and aquatic life. • Lignin nanoparticle (LNP)-nanocellulose cryogels were developed as adsorbents. • Multi-component adsorption system was used to assess simultaneous adsorption. • LNPs acted as a functionalizing agent that enhanced adsorption capacity. • LNPs acted as crosslinking agent that strengthen the nanocellulose network. [ABSTRACT FROM AUTHOR]

Published

2023