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Physics of nanomechanical spectrometry of viruses.


ABSTRACT: There is an emerging need of nanotools able to quantify the mechanical properties of single biological entities. A promising approach is the measurement of the shifts of the resonant frequencies of ultrathin cantilevers induced by the adsorption of the studied biological systems. Here, we present a detailed theoretical analysis to calculate the resonance frequency shift induced by the mechanical stiffness of viral nanotubes. The model accounts for the high surface-to-volume ratio featured by single biological entities, the shape anisotropy and the interfacial adhesion. The model is applied to the case in which tobacco mosaic virus is randomly delivered to a silicon nitride cantilever. The theoretical framework opens the door to a novel paradigm for biological spectrometry as well as for measuring the Young's modulus of biological systems with minimal strains.

SUBMITTER: Ruz JJ 

PROVIDER: S-EPMC7365328 | biostudies-literature | 2014 Aug

REPOSITORIES: biostudies-literature

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Physics of nanomechanical spectrometry of viruses.

Ruz J J JJ   Tamayo J J   Pini V V   Kosaka P M PM   Calleja M M  

Scientific reports 20140813


There is an emerging need of nanotools able to quantify the mechanical properties of single biological entities. A promising approach is the measurement of the shifts of the resonant frequencies of ultrathin cantilevers induced by the adsorption of the studied biological systems. Here, we present a detailed theoretical analysis to calculate the resonance frequency shift induced by the mechanical stiffness of viral nanotubes. The model accounts for the high surface-to-volume ratio featured by sin  ...[more]

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