{"title":"谷胱甘肽在铜纳米团簇和纳米粒子上的作用:综述","authors":"Mamta Sahu, Mainak Ganguly, Ankita Doi","doi":"10.1007/s10876-024-02639-4","DOIUrl":null,"url":null,"abstract":"<div><p>Being a highly available 3d group11 transition metal, copper in the form of nanoparticles (NPs) and nanoclusters (NCs) has been extensively investigated. However, aerial oxidation limits its application. Capping agents and experimental conditions have quite a significance in the stability of copper particles. Here, we reviewed the glutathione (GSH) capping on copper nanopaticles (CuNPs) and copper nanoclusters (CuNCs). CuNCs and CuNPs benefit greatly from the stabilizing, modifying, and enhancing effects of GSH, a naturally occurring tripeptide. It assists in preventing their aggregation, which is a typical problem for these tiny particles. Strong metal-sulfur (Cu-S) interactions allow the thiol (-SH) groups in GSH molecules to attach to the copper surface, forming a protective coating that prevents copper particles from clumping together. The synthesis with the mechanism, and the fate of copper particles, with myriad applications such as bioimaging, antibacterial activity, and sensing (antibiotics, heavy metals, pH, and other biomolecules) were reviewed here. Such particles were satisfactorily biocompatible. Moreover, the effect of components was also summarized justifying that tripeptide GSH was much superior to individual components in the context of applications, although cysteine was considered to be a pivotal component. The effect of adulteration of other metals in copper particles often enhances their utility. 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引用次数: 0
摘要
作为一种高度可用的 3d 族 11 过渡金属,纳米颗粒(NPs)和纳米团簇(NCs)形式的铜已被广泛研究。然而,空中氧化限制了其应用。封端剂和实验条件对铜粒子的稳定性有相当重要的影响。在此,我们综述了谷胱甘肽(GSH)对纳米铜(CuNPs)和纳米铜簇(CuNCs)的封端作用。CuNCs和CuNPs从谷胱甘肽(一种天然三肽)的稳定、修饰和增强作用中获益匪浅。它有助于防止这些微小颗粒的典型问题--聚集。强烈的金属-硫(Cu-S)相互作用使 GSH 分子中的硫醇(-SH)基团附着在铜表面,形成一层保护膜,防止铜微粒聚集在一起。本文综述了铜微粒的合成、机理和归宿,以及在生物成像、抗菌和传感(抗生素、重金属、pH 值和其他生物大分子)等方面的众多应用。这些微粒具有令人满意的生物相容性。此外,还总结了各成分的影响,证明在应用方面,三肽 GSH 远远优于单个成分,尽管半胱氨酸被认为是关键成分。铜微粒中掺杂其他金属的效果往往会提高其实用性。这篇综述将为涉足材料科学领域的年轻研究人员打开一扇硫醇化封盖的新窗口。
Role of Glutathione Capping on Copper Nanoclusters and Nanoparticles: A Review
Being a highly available 3d group11 transition metal, copper in the form of nanoparticles (NPs) and nanoclusters (NCs) has been extensively investigated. However, aerial oxidation limits its application. Capping agents and experimental conditions have quite a significance in the stability of copper particles. Here, we reviewed the glutathione (GSH) capping on copper nanopaticles (CuNPs) and copper nanoclusters (CuNCs). CuNCs and CuNPs benefit greatly from the stabilizing, modifying, and enhancing effects of GSH, a naturally occurring tripeptide. It assists in preventing their aggregation, which is a typical problem for these tiny particles. Strong metal-sulfur (Cu-S) interactions allow the thiol (-SH) groups in GSH molecules to attach to the copper surface, forming a protective coating that prevents copper particles from clumping together. The synthesis with the mechanism, and the fate of copper particles, with myriad applications such as bioimaging, antibacterial activity, and sensing (antibiotics, heavy metals, pH, and other biomolecules) were reviewed here. Such particles were satisfactorily biocompatible. Moreover, the effect of components was also summarized justifying that tripeptide GSH was much superior to individual components in the context of applications, although cysteine was considered to be a pivotal component. The effect of adulteration of other metals in copper particles often enhances their utility. This review will open a new window for thiolated capping to young researchers, venturing into the field of material science.
期刊介绍:
The journal publishes the following types of papers: (a) original and important research;
(b) authoritative comprehensive reviews or short overviews of topics of current
interest; (c) brief but urgent communications on new significant research; and (d)
commentaries intended to foster the exchange of innovative or provocative ideas, and
to encourage dialogue, amongst researchers working in different cluster
disciplines.
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