Elucidating the role of the nanostructure in protein aerogels for removal of organic water pollutants†

RSC sustainability Pub Date : 2024-11-04 DOI:10.1039/D4SU00352G

Rodrigo Sanches Pires, Antonio J. Capezza, David Jonsson, Jessica Lyrner Morén, Mikael S. Hedenqvist and Christofer Lendel

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Abstract

Access to efficient and affordable materials for water purification is of fundamental importance for the sustainable development of our society. Materials based on protein nanofibrils (PNFs) from agricultural waste- or side streams have recently been shown to have excellent adsorption properties for organic as well as inorganic pollutants. We here investigate the role of the nanostructure in aerogels made from whey protein isolate for the removal of a model pollutant (ibuprofen) from water. Water stable aerogels were produced using a recently developed approach for intrinsic crosslinking of protein materials without requiring additives. By comparing materials made from PNFs and from non-fibrillar whey protein we find that the fibrils have dual roles in enhancing the ibuprofen binding capacity. The PNFs do have a higher direct binding affinity but they also remodel the cell wall structures of the aerogels, resulting in a mesoporous network with enhanced ability of pollutant adsorption.

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阐明蛋白质气凝胶中的纳米结构在去除水中有机污染物中的作用†。

获得高效且经济实惠的水净化材料对我们社会的可持续发展至关重要。最近的研究表明，基于来自农业废弃物或副流的蛋白质纳米纤维（PNFs）的材料对有机和无机污染物都具有出色的吸附性能。在此，我们研究了由乳清蛋白分离物制成的气凝胶中的纳米结构在去除水中的模型污染物（布洛芬）方面所起的作用。我们采用最近开发的一种无需添加剂的蛋白质材料内在交联方法制备了水稳定性气凝胶。通过比较由 PNF 和非纤维乳清蛋白制成的材料，我们发现纤维在增强布洛芬结合能力方面具有双重作用。PNF 确实具有更高的直接结合亲和力，但它们也重塑了气凝胶的细胞壁结构，从而形成了具有更强污染物吸附能力的介孔网络。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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RSC sustainability

CiteScore

0.60

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0.00%

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