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17 results on '"Shaw, Z. L."'

3. Ionizable Lipid Containing Nanocarriers for Antimicrobial Agent Delivery.

Author

Yu, Haitao, Sarkar, Sampa, Shaw, Z. L., Dyett, Brendan, Cai, Xudong, Yap, Sue Lyn, Conn, Charlotte E., Elbourne, Aaron, Drummond, Calum J., and Zhai, Jiali

Subjects
LYOTROPIC liquid crystals, CATIONIC lipids, SMALL-angle scattering, BACTERIAL cell walls, SURFACE charges
Abstract

Antimicrobial resistance (AMR) poses a global health crisis demanding innovative solutions. Traditional antibiotics, though pivotal over the past century in combating bacterial infections, face diminished efficacy against evolving bacterial defense mechanisms, especially in Gram‐negative strains. This study explores self‐assembled ionizable lipid nanoparticles (LNPs) with the incorporation of two ionizable lipid components (one cationic, one anionic) in nanocarriers for advanced antimicrobial drug delivery of the broad‐spectrum antibiotic Piperacillin (Pip). Incorporating cationic ionizable lipid ALC‐0315, recognized as a functional lipid in the Pfizer‐BioNTech mRNA‐based SARS‐CoV‐2 vaccine, into LNPs allowed mesophase transition, pH responsiveness, and ionization behavior in acidic environments found in sites of bacterial infections, to be studied using synchrotron small angle X‐ray scattering, dynamic light scattering, and a 2‐(p‐toluidino)‐6‐naphthalene sulfonic acid assay. Incorporating another anionic ionizable lipid, oleic acid not only modulates the LNPs' physicochemical properties, such as size, internal phase nanostructure, and surface charge but also synergistically enhances the antimicrobial potency together with ALC‐0315 with a benefit enhancing permeability and fusion with bacterial membranes. This study introduces a strategy for tailoring ionizable lipid compositions in LNPs, providing a new approach to antimicrobial treatment contributing to the fight against AMR. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Interactions between Liquid Metal Droplets and Bacterial, Fungal, and Mammalian Cells (Adv. Mater. Interfaces 7/2022)

Author

Cheeseman, Samuel, primary, Elbourne, Aaron, additional, Gangadoo, Sheeana, additional, Shaw, Z. L., additional, Bryant, Saffron J., additional, Syed, Nitu, additional, Dickey, Michael D., additional, Higgins, Michael J., additional, Vasilev, Krasimir, additional, McConville, Chris F., additional, Christofferson, Andrew J., additional, Crawford, Russell J., additional, Daeneke, Torben, additional, Chapman, James, additional, and Truong, Vi Khanh, additional

Published
2022
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11. Illuminating the biochemical interaction of antimicrobial few-layer black phosphorus with microbial cells using synchrotron macro-ATR-FTIR

Author

Shaw, Z. L., primary, Cheeseman, Samuel, additional, Huang, Louisa Z. Y., additional, Penman, Rowan, additional, Ahmed, Taimur, additional, Bryant, Saffron J., additional, Bryant, Gary, additional, Christofferson, Andrew J., additional, Orrell-Trigg, Rebecca, additional, Dekiwadia, Chaitali, additional, Truong, Vi Khanh, additional, Vongsvivut, Jitraporn Pimm, additional, Walia, Sumeet, additional, and Elbourne, Aaron, additional

Published
2022
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12. Analysis of Pathogenic Bacterial and Yeast Biofilms Using the Combination of Synchrotron ATR-FTIR Microspectroscopy and Chemometric Approaches

Author

Cheeseman, Samuel, primary, Shaw, Z. L., additional, Vongsvivut, Jitraporn, additional, Crawford, Russell J., additional, Dupont, Madeleine F., additional, Boyce, Kylie J., additional, Gangadoo, Sheeana, additional, Bryant, Saffron J., additional, Bryant, Gary, additional, Cozzolino, Daniel, additional, Chapman, James, additional, Elbourne, Aaron, additional, and Truong, Vi Khanh, additional

Published
2021
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13. Broad-Spectrum Solvent-free Layered Black Phosphorus as a Rapid Action Antimicrobial

Author

Shaw, Z. L., primary, Kuriakose, Sruthi, additional, Cheeseman, Samuel, additional, Mayes, Edwin L. H., additional, Murali, Alishiya, additional, Oo, Zay Yar, additional, Ahmed, Taimur, additional, Tran, Nhiem, additional, Boyce, Kylie, additional, Chapman, James, additional, McConville, Christopher F., additional, Crawford, Russell J., additional, Taylor, Patrick D., additional, Christofferson, Andrew J., additional, Truong, Vi Khanh, additional, Spencer, Michelle J. S., additional, Elbourne, Aaron, additional, and Walia, Sumeet, additional

Published
2021
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14. 2-D transition metal trichalcophosphogenide FePS 3 against multi-drug resistant microbial infections.

Author

Kodakkat S, Valliant PHA, Ch'ng S, Shaw ZL, Awad MN, Murdoch BJ, Christofferson AJ, Bryant SJ, Walia S, and Elbourne A

Subjects
Humans, Anti-Bacterial Agents pharmacology, Anti-Bacterial Agents chemistry, Microbial Sensitivity Tests, Nanostructures chemistry, Transition Elements chemistry, Transition Elements pharmacology, Animals, Drug Resistance, Multiple, Bacterial drug effects, Bacteria drug effects, Reactive Oxygen Species metabolism
Abstract

Antimicrobial resistance (AMR) is a significant concern to society as it threatens the effectiveness of antibiotics and leads to increased morbidity and mortality rates. Innovative approaches are urgently required to address this challenge. Among promising solutions, two dimensional (2-D) nanomaterials with layered crystal structures have emerged as potent antimicrobial agents owing to their unique physicochemical properties. This antimicrobial activity is largely attributed to their high surface area, which allows for efficient interaction with microbial cell membranes, leading to physical disruption or oxidative stress through the generation of reactive oxygen species (ROS). The latter mechanism is particularly noteworthy as it involves the degradation of these nanomaterials under specific conditions, releasing ROS that can effectively kill bacteria and other pathogens without harming human cells. This study explores the antimicrobial properties of a novel biodegradable nanomaterial based on 2-D transition metal trichalcogenides, FePS 3 , as a potential solution to drug-resistant microbes. Our findings indicate that FePS 3 is an exceptionally effective antimicrobial agent with over 99.9% elimination of various bacterial strains. Crucially, it exhibits no cytotoxic effects on mammalian cells, underscoring the potential for safe biomedical application. The primary mechanism driving the antimicrobial efficacy of FePS 3 is the release of ROS during biodegradation. ROS has a crucial role in neutralizing bacterial cells, conferring significant antipathogenic properties to this compound. The unique combination of high antimicrobial activity, biocompatibility, and biodegradability makes FePS 3 a promising candidate for developing new antimicrobial strategies. This research contributes to the increasing body of evidence supporting the use of 2-D nanomaterials in addressing the global challenge of AMR, offering a potential pathway for the development of advanced, effective, and safe antimicrobial agents.

Published
2024
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15. Gold nanoparticle adsorption alters the cell stiffness and cell wall bio-chemical landscape of Candida albicans fungal cells.

Author

Penman R, Kariuki R, Shaw ZL, Dekiwadia C, Christofferson AJ, Bryant G, Vongsvivut J, Bryant SJ, and Elbourne A

Subjects
Animals, Gold chemistry, Adsorption, Cell Wall metabolism, Mammals metabolism, Candida albicans, Metal Nanoparticles chemistry
Abstract

Hypothesis: Nanomaterials have been extensively investigated for a wide range of biomedical applications, including as antimicrobial agents, drug delivery vehicles, and diagnostic devices. The commonality between these biomedical applications is the necessity for the nanoparticle to interact with or pass through the cellular wall and membrane. Cell-nanomaterial interactions/uptake can occur in various ways, including adhering to the cell wall, forming aggregates on the surface, becoming absorbed within the cell wall itself, or transversing into the cell cytoplasm. These interactions are common to mammalian cells, bacteria, and yeast cells. This variety of interactions can cause changes to the integrity of the cell wall and the cell overall, but the precise mechanisms underpinning such interactions remain poorly understood. Here, we investigate the interaction between commonly investigated gold nanoparticles (AuNPs) and the cell wall/membrane of a model fungal cell to explore the general effects of interaction and uptake., Experiments: The interactions between 100 nm citrate-capped AuNPs and the cell wall of Candida albicans fungal cells were studied using a range of advanced microscopy techniques, including atomic force microscopy, confocal laser scanning microscopy, scanning electron microscopy, transmission electron microscopy, and synchrotron-FTIR micro-spectroscopy., Findings: In most cases, particles adhered on the cell surface, although instances of particles being up-taken into the cell cytoplasm and localised within the cell wall and membrane were also observed. There was a measurable increase in the stiffness of the fungal cell after AuNPs were introduced. Analysis of the synchrotron-FTIR data showed significant changes in spectral features associated with phospholipids and proteins after exposure to AuNPs., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published
2024
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16. Cell Adhesion, Elasticity, and Rupture Forces Guide Microbial Cell Death on Nanostructured Antimicrobial Titanium Surfaces.

Author

Huang LZY, Shaw ZL, Penman R, Cheeseman S, Truong VK, Higgins MJ, Caruso RA, and Elbourne A

Subjects
Cell Adhesion, Titanium pharmacology, Titanium chemistry, Bacterial Adhesion, Elasticity, Methicillin-Resistant Staphylococcus aureus, Nanostructures chemistry, Anti-Infective Agents pharmacology
Abstract

Naturally occurring and synthetic nanostructured surfaces have been widely reported to resist microbial colonization. The majority of these studies have shown that both bacterial and fungal cells are killed upon contact and subsequent surface adhesion to such surfaces. This occurs because the presence of high-aspect-ratio structures can initiate a self-driven mechanical rupture of microbial cells during the surface adsorption process. While this technology has received a large amount of scientific and medical interest, one important question still remains: what factors drive microbial death on the surface? In this work, the interplay between microbial-surface adhesion, cell elasticity, cell membrane rupture forces, and cell lysis at the microbial-nanostructure biointerface during adsorptive processes was assessed using a combination of live confocal laser scanning microscopy, scanning electron microscopy, in situ amplitude atomic force microscopy, and single-cell force spectroscopy. Specifically, the adsorptive behavior and nanomechanical properties of live Gram-negative ( Pseudomonas aeruginosa ) and Gram-positive (methicillin-resistant Staphylococcus aureus ) bacterial cells, as well as the fungal species Candida albicans and Cryptococcus neoformans , were assessed on unmodified and nanostructured titanium surfaces. Unmodified titanium and titanium surfaces with nanostructures were used as model substrates for investigation. For all microbial species, cell elasticity, rupture force, maximum cell-surface adhesion force, the work of adhesion, and the cell-surface tether behavior were compared to the relative cell death observed for each surface examined. For cells with a lower elastic modulus, lower force to rupture through the cell, and higher work of adhesion, the surfaces had a higher antimicrobial activity, supporting the proposed biocidal mode of action for nanostructured surfaces. This study provides direct quantification of the differences observed in the efficacy of nanostructured antimicrobial surface as a function of microbial species indicating that a universal, antimicrobial surface architecture may be hard to achieve.

Published
2024
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17. Dual-action silver functionalized nanostructured titanium against drug resistant bacterial and fungal species.

Author

Huang LZY, Elbourne A, Shaw ZL, Cheeseman S, Goff A, Orrell-Trigg R, Chapman J, Murdoch BJ, Crawford RJ, Friedmann D, Bryant SJ, Truong VK, and Caruso RA

Subjects
Silver pharmacology, Silver chemistry, Titanium pharmacology, Titanium chemistry, Antifungal Agents pharmacology, Sodium Hydroxide, Bacteria, Anti-Bacterial Agents pharmacology, Anti-Bacterial Agents chemistry, Alloys pharmacology, Biocompatible Materials pharmacology, Metal Nanoparticles chemistry, Nanostructures chemistry, Anti-Infective Agents pharmacology
Abstract

Hypothesis: Titanium and its alloys are commonly used implant materials. Once inserted into the body, the interface of the biomaterials is the most likely site for the development of implant-associated infections. Imparting the titanium substrate with high-aspect-ratio nanostructures, which can be uniformly achieved using hydrothermal etching, enables a mechanical contact-killing (mechanoresponsive) mechanism of bacterial and fungal cells. Interaction between cells and the surface shows cellular inactivation via a physical mechanism meaning that careful engineering of the interface is needed to optimse the technology. This mechanism of action is only effective towards surface adsorbed microbes, thus any cells not directly in contact with the substrate will survive and limit the antimicrobial efficacy of the titanium nanostructures. Therefore, we propose that a dual-action mechanoresponsive and chemical-surface approach must be utilised to improve antimicrobial activity. The addition of antimicrobial silver nanoparticles will provide a secondary, chemical mechanism to escalate the microbial response in tandem with the physical puncture of the cells., Experiments: Hydrothermal etching is used as a facile method to impart variant nanostrucutres on the titanium substrate to increase the antimicrobial response. Increasing concentrations (0.25 M, 0.50 M, 1.0 M, 2.0 M) of sodium hydroxide etching solution were used to provide differing degrees of nanostructured morphology on the surface after 3 h of heating at 150 °C. This produced titanium nanospikes, nanoblades, and nanowires, respectively, as a function of etchant concentration. These substrates then provided an interface for the deposition of silver nanoparticles via a reduction pathway. Methicillin-resistant Staphylococcous aureus (MRSA) and Candida auris (C. auris) were used as model bacteria and fungi, respectively, to test the effectiveness of the nanostructured titanium with and without silver nanoparticles, and the bio-interactions at the interface., Findings: The presence of nanostructure increased the bactericidal response of titanium against MRSA from ∼ 10 % on commercially pure titanium to a maximum of ∼ 60 % and increased the fungicidal response from ∼ 10 % to ∼ 70 % in C. auris. Introducing silver nanoparticles increased the microbiocidal response to ∼ 99 % towards both bacteria and fungi. Importantly, this study highlights that nanostructure alone is not sufficient to develop a highly antimicrobial titanium substrate. A dual-action, physical and chemical antimicrobial approach is better suited to produce highly effective antibacterial and antifungal surface technologies., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published
2022
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