Silver, in the form of nanostructures, is widely employed as an antimicrobial agent. The origin of the biocidal mechanism has been elucidated in the last decades, originating from silver cation release due to oxidative dissolution followed by cellular uptake of silver ions, a process that causes a severe disruption of bacterial metabolism, leading to eradication. Despite the large body of work addressing the effects of nanosilver shape/size on the antibacterial mechanism and on the (bio)physical chemistry pathways that drive bacterial eradication, little effort has been devoted to the investigation of nanostructured silver plasmon response upon interaction with bacteria. We investigate the bacteria-induced changes of the plasmonic response of silver nanoplates after exposure to the bacterial model Escherichia coli. Ultrafast pump-probe measurements indicate that the dramatic changes on particle size/shape and crystallinity, which likely stem from a bacteria-induced oxidative dissolution process, translate into a clear modification of the plasmonic response. Specifically, exposure to bacteria causes a decrease in the electron–phonon coupling time and an increase in lattice-environment coupling time, effects explained by an increase in the free electron density and amorphization of the silver particles. Coherent oscillations that are observed in pristine silver are completely damped in contaminated samples, which can be attributed again to amorphization of the nanoplates at the surface and an increase in polydispersivity of particle geometries. This study opens innovative avenues in the biophysics of bio-responsive materials, with the aim of providing reliable biophysical signatures of the interaction of plasmonic materials with complex biological environments.
In past decades, the exploitation of silver nanoparticles in novel antibacterial and detection devices has risen to prominence, owing to the well-known specific interaction of silver with bacteria. The vast majority of the investigations focus on the investigation over the mechanism of action underpinning bacterial eradication, while few efforts have been devoted to the study of the modification of silver optical properties upon interaction with bacteria. Specifically, given the characteristic localized surface plasmon resonance of silver nanostructures, which is sensitive to changes in the charge carrier density or in the dielectric environment, these systems can offer a handle in the detection of bacteria pathogens. In this review, we present the state of art of the research activity on the interaction of silver nanoparticles with bacteria, with strong emphasis on the modification of their optical properties. This may indeed lead to easy color reading of bacterial tests and pave the way to the development of nanotechnologic silver-based bacterial detection systems and drug-screening platforms.
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