In Situ Grown Gold Nanoparticles Enable Plasmonic Staining of Bacteria for High-Performance On-Site Microbial Analysis in Drinking Water

IF 4.8 Q1 ENVIRONMENTAL SCIENCES
Ying Jie Zheng, Liang Rui Zhu, Jun Jiang Luo, Hao Lin Zou, Hong Qun Luo, Nian Bing Li and Bang Lin Li*, 
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引用次数: 0

Abstract

On-site analysis of bacteria is important, but high-practicality methods are challenging due to their limited sensitivity and weak anti-interference. Herein, nitrocellulose (NC) membranes with hydrophilic characteristics and porous structures are utilized to filter those small coexisting substances in samples and selectively enrich target bacteria at the NC surfaces. To visualize bacteria with enhanced stability and sensitivity, the in situ growth of plasmonic Au nanocrystals on bacteria is implemented via the incubation of the bacterium-loaded NC membranes in Au reaction solutions. The bacteria are remarkably stained by the plasmonic Au nanocrystals, exhibiting responsive color changes for quantitative analysis. First, bacteria are visualized by in situ grown Au nanocrystals. In comparison with the presynthetic Au nanocrystals, those chemicals in Au reaction solutions are more stable, which ensures comparable stability and reproductivity. Second, the bacterium responses are amplified via plasmonic chemical reactions. Those Au nanocrystals are considered not only visual probes but also signal amplifiers. Overall, the protocol of Au-stained bacteria on NC membranes facilitates the on-site microbial analysis with characteristics of high simplicity, speediness, sensitivity, stability, and anti-interference, largely contributing to the progress of nanotechnologies from fundamental research to practical applications.

Abstract Image

原位生长金纳米粒子可对细菌进行等离子染色,实现高性能的饮用水现场微生物分析
细菌的现场分析非常重要,但由于灵敏度有限且抗干扰能力弱,实用性高的方法具有挑战性。本文利用具有亲水性和多孔结构的硝化纤维素(NC)膜来过滤样品中的微小共存物质,并在 NC 表面选择性地富集目标细菌。为了以更高的稳定性和灵敏度观察细菌,通过将细菌负载的 NC 膜在金反应溶液中培养,实现了等离子金纳米晶体在细菌上的原位生长。细菌被等离子金纳米晶体显著染色,并呈现出可用于定量分析的响应性颜色变化。首先,原位生长的金纳米晶体可视化细菌。与预合成金纳米晶体相比,金反应溶液中的化学物质更加稳定,从而确保了可比的稳定性和可重复性。第二,通过等离子化学反应放大细菌反应。这些金纳米晶体不仅是视觉探针,也是信号放大器。总之,数控膜上金染色细菌的方案有助于现场微生物分析,具有简便、快速、灵敏、稳定和抗干扰的特点,极大地推动了纳米技术从基础研究到实际应用的进展。
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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CiteScore
5.40
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0.00%
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