Chelating silica nanoparticles for efficient antibiotic delivery and particle imaging in Gram-negative bacteria

The inefficacy of antibiotics against Gram-negative bacteria is a major challenge for treatment of many clinically important bacterial infections. The complex structure of the double cell membrane of Gram-negative bacteria makes it inaccessible to many key antibiotics such as vancomycin and also pre...

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Veröffentlicht in:	Nanoscale advances 2023-05, Vol.5 (9), p.2453-2461
Hauptverfasser:	Muguruza, Asier R, di Maio, Alessandro, Hodges, Nikolas J, Blair, Jessica M. A, Pikramenou, Zoe
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Sprache:	eng
Schlagworte:	Chemistry
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creator	Muguruza, Asier R di Maio, Alessandro Hodges, Nikolas J Blair, Jessica M. A Pikramenou, Zoe
description	The inefficacy of antibiotics against Gram-negative bacteria is a major challenge for treatment of many clinically important bacterial infections. The complex structure of the double cell membrane of Gram-negative bacteria makes it inaccessible to many key antibiotics such as vancomycin and also presents a major challenge for drug development. In this study we design of a novel hybrid silica nanoparticle system bearing membrane targeting groups with the antibiotic encapsulated together with a ruthenium luminescent tracking agent, for optical detection of the nanoparticle delivery in the bacterial cell. The hybrid system shows delivery of vancomycin and efficacy against a library of Gram negative bacterial species. Evidence of penetration of nanoparticles in bacteria cells is achieved via luminescence of the ruthenium signal. Our studies show that nanoparticles modified with aminopolycarboxylate chelating groups are an effective delivery system in bacterial growth inhibition in species whereas the molecular antibiotic is ineffective. This design provides a new platform for delivery of antibiotics that cannot alone penetrate the bacterial membrane. Silica nanoparticles decorated with aminocarboxylate ligands are novel vehicles to deliver antibiotics which are otherwise not able to penetrate the bacteria membrane and can also include agents for tracking and imaging.
doi_str_mv	10.1039/d2na00884j
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subjects	Chemistry
title	Chelating silica nanoparticles for efficient antibiotic delivery and particle imaging in Gram-negative bacteria
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