Metal clad waveguide (MCWG) based imaging using a high numerical aperture microscope objective

Metal clad waveguide (MCWG) based imaging using a high numerical aperture microscope objective

Evanescent-field based methods such as surface plasmon resonance (SPR) have been used very effectively for label-free imaging of microscopic biological material in close proximity to a sensing surface. However, the shallow probing depth of SPR (typically less than ~200 nm) can be problematic when im...

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Veröffentlicht in:Optics express 2017-02, Vol.25 (3), p.1666-1679
Hauptverfasser: Söllradl, Thomas, Banville, Frederic A, Chabot, Vincent, Canva, Michael, Grandbois, Michel, Charette, Paul G
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Optics
Photonic
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container_end_page 1679
container_issue 3
container_start_page 1666
container_title Optics express
container_volume 25
creator Söllradl, Thomas
Banville, Frederic A
Chabot, Vincent
Canva, Michael
Grandbois, Michel
Charette, Paul G
description Evanescent-field based methods such as surface plasmon resonance (SPR) have been used very effectively for label-free imaging of microscopic biological material in close proximity to a sensing surface. However, the shallow probing depth of SPR (typically less than ~200 nm) can be problematic when imaging relatively thick biological objects such as cells or bacteria. In this paper, we demonstrate how metal-clad waveguides (MCWG) can be used to achieve deeper probing depth compared to SPR while maintaining good imaging spatial resolution. Comparative numerical simulations of imaging spatial resolution versus probing depth are shown for a number of common SPR, long-range SPR, and MCWG configurations, demonstrating that MCWG offer the best compromise between resolution and depth for imaging thick biological objects. Experimental results of synthetic target and live cell imaging are shown that validate the numerical simulations and demonstrate the capabilities of the method.
doi_str_mv 10.1364/OE.25.001666
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subjects Engineering Sciences
Optics
Photonic
title Metal clad waveguide (MCWG) based imaging using a high numerical aperture microscope objective
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