Label-free imaging, detection, and mass measurement of single viruses by surface plasmon resonance

Shaopeng Wang; Xiaonan Shan; Urmez Patel; Xinping Huang; Jin Lu; Jinghong Li; Nongjian Tao

doi:10.1073/pnas.1005264107

Label-free imaging, detection, and mass measurement of single viruses by surface plasmon resonance

Shaopeng Wang, Xiaonan Shan, Urmez Patel, Xinping Huang, Jin Lu, Jinghong Li, Nongjian Tao

Research output: Contribution to journal › Article › peer-review

299 Scopus citations

Abstract

We report on label-free imaging, detection, and mass/size measurement of single viral particles in solution by high-resolution surface plasmon resonance microscopy. Diffraction of propagating plasmon waves along a metal surface by the viral particles creates images of the individual particles, which allow us to detect the binding of the viral particles to surfaces functionalized with and without antibodies. We show that the intensity of the particle image is related to the mass of the particle, from which we determine the mass and mass distribution of influenza viral particles with a mass detection limit of approximately 1 ag (or 0.2 fg/mm²). This work demonstrates a multiplexed method to measure the masses of individual viral particles and to study the binding activity of the viral particles.

Original language	English (US)
Pages (from-to)	16028-16032
Number of pages	5
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	107
Issue number	37
DOIs	https://doi.org/10.1073/pnas.1005264107
State	Published - Sep 14 2010

Keywords

Human cytomegalovirus
Influenza virus
Real time detection
Silica nanoparticles
Solution phase measurement

ASJC Scopus subject areas

General

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10.1073/pnas.1005264107

Cite this

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abstract = "We report on label-free imaging, detection, and mass/size measurement of single viral particles in solution by high-resolution surface plasmon resonance microscopy. Diffraction of propagating plasmon waves along a metal surface by the viral particles creates images of the individual particles, which allow us to detect the binding of the viral particles to surfaces functionalized with and without antibodies. We show that the intensity of the particle image is related to the mass of the particle, from which we determine the mass and mass distribution of influenza viral particles with a mass detection limit of approximately 1 ag (or 0.2 fg/mm2). This work demonstrates a multiplexed method to measure the masses of individual viral particles and to study the binding activity of the viral particles.",

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T1 - Label-free imaging, detection, and mass measurement of single viruses by surface plasmon resonance

AU - Wang, Shaopeng

AU - Shan, Xiaonan

AU - Patel, Urmez

AU - Huang, Xinping

AU - Lu, Jin

AU - Li, Jinghong

AU - Tao, Nongjian

PY - 2010/9/14

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N2 - We report on label-free imaging, detection, and mass/size measurement of single viral particles in solution by high-resolution surface plasmon resonance microscopy. Diffraction of propagating plasmon waves along a metal surface by the viral particles creates images of the individual particles, which allow us to detect the binding of the viral particles to surfaces functionalized with and without antibodies. We show that the intensity of the particle image is related to the mass of the particle, from which we determine the mass and mass distribution of influenza viral particles with a mass detection limit of approximately 1 ag (or 0.2 fg/mm2). This work demonstrates a multiplexed method to measure the masses of individual viral particles and to study the binding activity of the viral particles.

AB - We report on label-free imaging, detection, and mass/size measurement of single viral particles in solution by high-resolution surface plasmon resonance microscopy. Diffraction of propagating plasmon waves along a metal surface by the viral particles creates images of the individual particles, which allow us to detect the binding of the viral particles to surfaces functionalized with and without antibodies. We show that the intensity of the particle image is related to the mass of the particle, from which we determine the mass and mass distribution of influenza viral particles with a mass detection limit of approximately 1 ag (or 0.2 fg/mm2). This work demonstrates a multiplexed method to measure the masses of individual viral particles and to study the binding activity of the viral particles.

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KW - Influenza virus

KW - Real time detection

KW - Silica nanoparticles

KW - Solution phase measurement

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Label-free imaging, detection, and mass measurement of single viruses by surface plasmon resonance

Abstract

Keywords

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