Dual therapy for the eradication of bacterial biofilms: Iron oxide nanoparticles and carbon dots as magnetic actuator and photothermal agents

IF 6.7 2区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY Materials Today Chemistry Pub Date : 2024-01-13 DOI:10.1016/j.mtchem.2024.101920
Célia Sahli, Julien Deschamps, Laurent Royon, John S. Lomas, Romain Briandet, Miryana Hémadi
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Abstract

Nanohybrids based on maghemite iron oxide nanoparticles (IONPs) and carbon dots (CDs), with different linkers between the two components, are synthesized, with the idea of combining several properties (magnetic and optical) in one nanomaterial in order to eradicate bacterial biofilm. The photothermal capacities of these materials are expressed by two parameters: the specific absorption rate (SAR) and the photothermal light-to-heat conversion constant (η). They show that the IONP/CD combination is more effective in photothermia (PT) than either of the components, but depends on the linkage (amide > ester > electrostatic). The antibacterial properties of the nanohybrids are first determined for the exponential and stationary growth phases of planktonic S. aureus and B. subtilis with and without PT. In the absence of PT, no nanohybrid has any significant bactericidal effect, but with PT the nanohybrids have different activities, with the IONP-amide-CD pattern the most effective. Combining magnetic actuation and PT on B. subtilis biofilms shows a synergistic effect and reveals the advantages of using such nanohybrid materials for killing bacteria and eradicating biofilm.

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根除细菌生物膜的双重疗法:作为磁性致动器和光热剂的氧化铁纳米粒子和碳点
我们合成了基于氧化镁铁纳米颗粒(IONPs)和碳点(CDs)的纳米混合体,两种成分之间有不同的连接物,目的是在一种纳米材料中结合多种特性(磁性和光学),以消除细菌生物膜。这些材料的光热能力由两个参数表示:比吸收率(SAR)和光热光热转换常数(η)。研究结果表明,IONP/CD 组合比其中任何一种成分的光热作用(PT)都更有效,但这取决于连接方式(酰胺> 酯> 静电)。首先测定了纳米混合物在有和无 PT 的情况下对浮游金黄色葡萄球菌和枯草杆菌的指数生长期和静止生长期的抗菌特性。在没有 PT 的情况下,任何纳米杂交种都没有明显的杀菌效果,但在有 PT 的情况下,纳米杂交种具有不同的活性,其中以 IONP-amide-CD 模式最为有效。在枯草杆菌生物膜上将磁驱动与 PT 结合使用可产生协同效应,并揭示了使用此类纳米杂化材料杀灭细菌和消除生物膜的优势。
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来源期刊
CiteScore
8.90
自引率
6.80%
发文量
596
审稿时长
33 days
期刊介绍: Materials Today Chemistry is a multi-disciplinary journal dedicated to all facets of materials chemistry. This field represents one of the fastest-growing areas of science, involving the application of chemistry-based techniques to the study of materials. It encompasses materials synthesis and behavior, as well as the intricate relationships between material structure and properties at the atomic and molecular scale. Materials Today Chemistry serves as a high-impact platform for discussing research that propels the field forward through groundbreaking discoveries and innovative techniques.
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