Kaiyuan Zheng scite author profile

Bulk gold (Au) is known to be chemically inactive. However, when the size of Au nanoparticles (Au NPs) decreases to close to 1 nm or sub-nanometer dimensions, these ultrasmall Au nanoclusters (Au NCs) begin to possess interesting physical and chemical properties and likewise spawn different applications when working with bulk Au or even Au NPs. In this study, we found that it is possible to confer antimicrobial activity to Au NPs through precise control of their size down to NC dimension (typically less than 2 nm). Au NCs could kill both Gram-positive and Gram-negative bacteria. This wide-spectrum antimicrobial activity is attributed to the ultrasmall size of Au NCs, which would allow them to better interact with bacteria. The interaction between ultrasmall Au NCs and bacteria could induce a metabolic imbalance in bacterial cells after the internalization of Au NCs, leading to an increase of intracellular reactive oxygen species production that kills bacteria consequently.

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Engineering ultrasmall water-soluble gold and silver nanoclusters for biomedical applications

Luo

2014

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Gold and silver nanoclusters or Au/Ag NCs with core sizes smaller than 2 nm have been an attractive frontier of nanoparticle research because of their unique physicochemical properties such as well-defined molecular structure, discrete electronic transitions, quantized charging, and strong luminescence. As a result of these unique properties, ultrasmall size, and good biocompatibility, Au/Ag NCs have great potential for a variety of biomedical applications, such as bioimaging, biosensing, antimicrobial agents, and cancer therapy. In this feature article, we will first discuss some critical biological considerations, such as biocompatibility and renal clearance, of Au/Ag NCs that are applied for biomedical applications, leading to some design criteria for functional Au/Ag NCs in the biological settings. According to these biological considerations, we will then survey some efficient synthetic strategies for the preparation of protein- and peptide-protected Au/Ag NCs with an emphasis on our recent contributions in this fast-growing field. In the last part, we will highlight some potential biomedical applications of these protein- and peptide-protected Au/Ag NCs. It is believed that with continued efforts to understand the interactions of biomolecule-protected Au/Ag NCs with the biological systems, scientists can largely realize the great potential of Au/Ag NCs for biomedical applications, which could finally pave their way towards clinical use.

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Antimicrobial silver nanomaterials

Zheng

Setyawati

Leong

et al. 2018

Coordination Chemistry Reviews

510

293

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Antimicrobial Cluster Bombs: Silver Nanoclusters Packed with Daptomycin

et al. 2016

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Integration of two distinctive bactericides into one entity is a promising platform to improve the efficiency of antimicrobial agents. We report an efficient antimicrobial hybrid formed through conjugating silver nanoclusters (AgNCs) with daptomycin. The as-designed antimicrobial hybrid (D-AgNCs) inherits intrinsic properties of both bactericides with an enhanced synergistic performance. In particular, the chemically integrated D-AgNCs showed improved bacterial killing efficiency over the physically mixed daptomycin and AgNCs (D+AgNCs). More interestingly, the as-designed D-AgNCs could effectively damage the bacterial membrane. Propidium iodide (PI) stain showed bacterial membrane damage in about 85% of the bacteria population after treatment with D-AgNCs through creation of larger pores on the membrane as compared to D+AgNCs, largely due to the localization of daptomycin within the hybrid structure. These larger pores facilitated the entry of the D-AgNCs into the cell and led to more severe DNA damage of the bacterial DNA as compared to D+AgNCs in genomic DNA PAGE analysis. TUNEL assay further depicted more bacterial DNA breaks induced by D-AgNCs. The RecA gene expression level was upregulated, suggestive of DNA repair activation. The strong induced DNA damage benefited from the localization of AgNCs in the core of the antimicrobial hybrid structure, which could generate localized high ROS concentration and work as a critical ROS reservoir to continually generate ROS within the bacterium. The continual bombardments by these ROS generators restrict the ability of the bacteria to now develop resistance against this.

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Fine-Tuning Pore Size by Shifting Coordination Sites of Ligands and Surface Polarization of Metal–Organic Frameworks To Sharply Enhance the Selectivity for CO₂

et al. 2012

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Based upon the (3,6)-connected metal-organic framework {Cu(L1)·2H(2)O·1.5DMF}(∞) (L1 = 5-(pyridin-4-yl)isophthalic acid) (SYSU, for Sun Yat-Sen University), iso-reticular {Cu(L2)·DMF}(∞) (L2 = 5-(pyridin-3-yl)isophthalic acid) (NJU-Bai7; NJU-Bai for Nanjing University Bai group) and {Cu(L3)·DMF·H(2)O}(∞) (L3 = 5-(pyrimidin-5-yl)isophthalic acid) (NJU-Bai8) were designed by shifting the coordination sites of ligands to fine-tune pore size and polarizing the inner surface with uncoordinated nitrogen atoms, respectively, with almost no changes in surface area or porosity. Compared with those of the prototype SYSU, both the adsorption enthalpy and selectivity of CO(2) for NJU-Bai7 and NJU-Bai8 have been greatly enhanced, which makes NJU-Bai7 and NJU-Bai8 good candidates for postcombustion CO(2) capture. Notably, the CO(2) adsorption enthalpy of NJU-Bai7 is the highest reported so far among the MOFs without any polarizing functional groups or open metal sites. Meanwhile, NJU-Bai8 exhibits high uptake of CO(2) and good CO(2)/CH(4) selectivity at high pressure, which are quite valuable characteristics in the purification of natural gases.

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Bio-NCs – the marriage of ultrasmall metal nanoclusters with biomolecules

2014

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Ultrasmall metal nanoclusters (NCs) have attracted increasing attention due to their fascinating physicochemical properties. Today, functional metal NCs are finding growing acceptance in biomedical applications. To achieve a better performance in biomedical applications, metal NCs can be interfaced with biomolecules, such as proteins, peptides, and DNA, to form a new class of biomolecule-NC composites (or bio-NCs in short), which typically show synergistic or novel physicochemical and physiological properties. This feature article focuses on the recent studies emerging at the interface of metal NCs and biomolecules, where the interactions could impart unique physicochemical properties to the metal NCs, as well as mutually regulate biological functions of the bio-NCs. In this article, we first provide a broad overview of key concepts and developments in the novel biomolecule-directed synthesis of metal NCs. A special focus is placed on the key roles of biomolecules in metal NC synthesis. In the second part, we describe how the encapsulated metal NCs affect the structure and function of biomolecules. Followed by that, we discuss several unique synergistic effects observed in the bio-NCs, and illustrate them with examples highlighting their potential biomedical applications. Continued interdisciplinary efforts are required to build up in-depth knowledge about the interfacial chemistry and biology of bio-NCs, which could further pave their ways toward biomedical applications.

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Surface Ligand Chemistry of Gold Nanoclusters Determines Their Antimicrobial Ability

et al. 2018

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Surface properties of nanoparticles (NPs) could greatly influence their biomedical efficacy. This paradigm drives many NPs-based antimicrobial agents as the common belief that a more positively charged surface would favor intimate interactions with the negatively charged bacterial cell wall, leading to a higher overall antimicrobial efficacy. Surprisingly, this study shows the opposite effect when using ultrasmall gold nanoclusters (Au NCs) as a model to investigate the effect of surface properties on their antimicrobial performance. Leveraging on the molecular properties of ultrasmall Au NCs, the surface properties of thiolate-protected Au NCs could be precisely controlled at the atomic level, generating a family of Au NCs with the same number of gold atoms but different surface properties. By tuning the type and ratio of surface ligands on Au NCs, more negatively charged Au NCs would produce more reactive oxygen species (ROS), leading to a better bacterial killing efficiency. This finding is in stark contrast to the previous paradigm and suggests the complexities of the nanomaterial-cell interactions, shedding some light on the design of high-performance NP-based antimicrobial agents.

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Recent advances in the synthesis, characterization, and biomedical applications of ultrasmall thiolated silver nanoclusters

et al. 2014

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Kaiyuan Zheng

Antimicrobial Gold Nanoclusters

Engineering ultrasmall water-soluble gold and silver nanoclusters for biomedical applications

Antimicrobial silver nanomaterials

Antimicrobial Cluster Bombs: Silver Nanoclusters Packed with Daptomycin

Fine-Tuning Pore Size by Shifting Coordination Sites of Ligands and Surface Polarization of Metal–Organic Frameworks To Sharply Enhance the Selectivity for CO₂

Bio-NCs – the marriage of ultrasmall metal nanoclusters with biomolecules

Surface Ligand Chemistry of Gold Nanoclusters Determines Their Antimicrobial Ability

Recent advances in the synthesis, characterization, and biomedical applications of ultrasmall thiolated silver nanoclusters

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Product

Resources

About

Kaiyuan Zheng

Antimicrobial Gold Nanoclusters

Engineering ultrasmall water-soluble gold and silver nanoclusters for biomedical applications

Antimicrobial silver nanomaterials

Antimicrobial Cluster Bombs: Silver Nanoclusters Packed with Daptomycin

Fine-Tuning Pore Size by Shifting Coordination Sites of Ligands and Surface Polarization of Metal–Organic Frameworks To Sharply Enhance the Selectivity for CO2

Bio-NCs – the marriage of ultrasmall metal nanoclusters with biomolecules

Surface Ligand Chemistry of Gold Nanoclusters Determines Their Antimicrobial Ability

Recent advances in the synthesis, characterization, and biomedical applications of ultrasmall thiolated silver nanoclusters

Contact Info

Product

Resources

About

Fine-Tuning Pore Size by Shifting Coordination Sites of Ligands and Surface Polarization of Metal–Organic Frameworks To Sharply Enhance the Selectivity for CO₂