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Autori principali: Yao, Jinhao, Wang, Shenqing, Deng, Chaofan, Ren, Hao, Zhang, Kena, Liu, Qingmeng, Wang, Yukun, Yue, Tongtao, Yan, Bing
Natura: Artículo científico
Lingua:en
Pubblicazione: ACS nano 2025
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Accesso online:https://pubmed.ncbi.nlm.nih.gov/40838975/
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author Yao, Jinhao
Wang, Shenqing
Deng, Chaofan
Ren, Hao
Zhang, Kena
Liu, Qingmeng
Wang, Yukun
Yue, Tongtao
Yan, Bing
author_facet Yao, Jinhao
Wang, Shenqing
Deng, Chaofan
Ren, Hao
Zhang, Kena
Liu, Qingmeng
Wang, Yukun
Yue, Tongtao
Yan, Bing
Yao, Jinhao
Wang, Shenqing
Deng, Chaofan
Ren, Hao
Zhang, Kena
Liu, Qingmeng
Wang, Yukun
Yue, Tongtao
Yan, Bing
collection PubMed - marine biology
contents Harnessing Nanotechnology for Cellular Health through Strategic Modulation and Nanoscale Control of Electron Mobility. Yao, Jinhao Wang, Shenqing Deng, Chaofan Ren, Hao Zhang, Kena Liu, Qingmeng Wang, Yukun Yue, Tongtao Yan, Bing Humans Gold Metallocenes Oxidative Stress Metal Nanoparticles Ferrous Compounds Nanotechnology Electrons Oxidation-Reduction Excessive oxidative stress in human cells is linked to aging and underpins pathologies such as Alzheimer's disease, diabetes, and cancer. Understanding the molecular mechanisms behind this is crucial, and to this end, cell models that can produce varying levels of oxidative stress are essential. This work has achieved this by creating a library of gold nanoparticles (GNPs) with diverse ferrocene-containing ligands and incorporating them into human cells in nontoxic doses. These GNPs create cell models with different levels of oxidative stress. The roles of these ligands in controlling oxidative stress were elucidated through first-principles calculations. It was found that substituents covalently adjacent to the ferrocene in the ligand significantly influence electron mobility within the ferrocene group, thereby playing a predominant role (75.6%) in modulating the redox activity of the GNPs. In contrast, the presence of distal substituents, which are not directly bonded to ferrocene, was found to have a lesser (24.4%) yet noteworthy impact on this activity through intramolecular interactions adjusting atomic charge redistribution. This mechanistic understanding of how nanostructures control cellular redox activities enriches our knowledge of nanobio interactions. It also introduces advanced methods for precisely regulating cellular oxidative stress levels and represents a significant advancement in leveraging nanotechnology for targeted redox therapies.
format Artículo científico
id pubmed_40838975
institution PubMed
language en
publishDate 2025
publisher ACS nano
record_format pubmed
spellingShingle Harnessing Nanotechnology for Cellular Health through Strategic Modulation and Nanoscale Control of Electron Mobility.
Yao, Jinhao
Wang, Shenqing
Deng, Chaofan
Ren, Hao
Zhang, Kena
Liu, Qingmeng
Wang, Yukun
Yue, Tongtao
Yan, Bing
Humans
Gold
Metallocenes
Oxidative Stress
Metal Nanoparticles
Ferrous Compounds
Nanotechnology
Electrons
Oxidation-Reduction
Harnessing Nanotechnology for Cellular Health through Strategic Modulation and Nanoscale Control of Electron Mobility. Yao, Jinhao Wang, Shenqing Deng, Chaofan Ren, Hao Zhang, Kena Liu, Qingmeng Wang, Yukun Yue, Tongtao Yan, Bing Humans Gold Metallocenes Oxidative Stress Metal Nanoparticles Ferrous Compounds Nanotechnology Electrons Oxidation-Reduction Excessive oxidative stress in human cells is linked to aging and underpins pathologies such as Alzheimer's disease, diabetes, and cancer. Understanding the molecular mechanisms behind this is crucial, and to this end, cell models that can produce varying levels of oxidative stress are essential. This work has achieved this by creating a library of gold nanoparticles (GNPs) with diverse ferrocene-containing ligands and incorporating them into human cells in nontoxic doses. These GNPs create cell models with different levels of oxidative stress. The roles of these ligands in controlling oxidative stress were elucidated through first-principles calculations. It was found that substituents covalently adjacent to the ferrocene in the ligand significantly influence electron mobility within the ferrocene group, thereby playing a predominant role (75.6%) in modulating the redox activity of the GNPs. In contrast, the presence of distal substituents, which are not directly bonded to ferrocene, was found to have a lesser (24.4%) yet noteworthy impact on this activity through intramolecular interactions adjusting atomic charge redistribution. This mechanistic understanding of how nanostructures control cellular redox activities enriches our knowledge of nanobio interactions. It also introduces advanced methods for precisely regulating cellular oxidative stress levels and represents a significant advancement in leveraging nanotechnology for targeted redox therapies.
title Harnessing Nanotechnology for Cellular Health through Strategic Modulation and Nanoscale Control of Electron Mobility.
topic Humans
Gold
Metallocenes
Oxidative Stress
Metal Nanoparticles
Ferrous Compounds
Nanotechnology
Electrons
Oxidation-Reduction
url https://pubmed.ncbi.nlm.nih.gov/40838975/