Halo-free Phase Contrast Microscopy

Tan H. Nguyen; Mikhail Kandel; Haadi M. Shakir; Catherine Best-Popescu; Jyothi Arikkath; Minh N. Do; Gabriel Popescu

doi:10.1038/srep44034

Halo-free Phase Contrast Microscopy

Tan H. Nguyen, Mikhail Kandel, Haadi M. Shakir, Catherine Best-Popescu, Jyothi Arikkath, Minh N. Do, Gabriel Popescu

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Abstract

We present a new approach for retrieving halo-free phase contrast microscopy (hfPC) images by upgrading the conventional PC microscope with an external interferometric module, which generates sufficient data for reversing the halo artifact. Acquiring four independent intensity images, our approach first measures haloed phase maps of the sample. We solve for the halo-free sample transmission function by using a physical model of the image formation under partial spatial coherence. Using this halo-free sample transmission, we can numerically generate artifact-free PC images. Furthermore, this transmission can be further used to obtain quantitative information about the sample, e.g., the thickness with known refractive indices, dry mass of live cells during their cycles. We tested our hfPC method on various control samples, e.g., beads, pillars and validated its potential for biological investigation by imaging live HeLa cells, red blood cells, and neurons.

Original language	English (US)
Article number	44034
Journal	Scientific reports
Volume	7
DOIs	https://doi.org/10.1038/srep44034
State	Published - Mar 24 2017

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abstract = "We present a new approach for retrieving halo-free phase contrast microscopy (hfPC) images by upgrading the conventional PC microscope with an external interferometric module, which generates sufficient data for reversing the halo artifact. Acquiring four independent intensity images, our approach first measures haloed phase maps of the sample. We solve for the halo-free sample transmission function by using a physical model of the image formation under partial spatial coherence. Using this halo-free sample transmission, we can numerically generate artifact-free PC images. Furthermore, this transmission can be further used to obtain quantitative information about the sample, e.g., the thickness with known refractive indices, dry mass of live cells during their cycles. We tested our hfPC method on various control samples, e.g., beads, pillars and validated its potential for biological investigation by imaging live HeLa cells, red blood cells, and neurons.",

author = "Nguyen, {Tan H.} and Mikhail Kandel and Shakir, {Haadi M.} and Catherine Best-Popescu and Jyothi Arikkath and Do, {Minh N.} and Gabriel Popescu",

note = "Funding Information: This research was supported in part by the National Science Foundation (grants CBET-1040462 MRI, CBET-0939511 STC, IIP-1353368). J. A. research is supported by grants from NIH COBRE (5P20GM103471), Alzheimer's Association and Brain and Behavior Research Foundation. We want to thank Dr. Lynford Goddard from the Micro and Nanotechnology Laboratory, University of Illinois at Urbana-Champaign for providing the pillar sample. T.N. acknowledges support from the Computational Science Engineering department through a Computational Science Engineering Fellowship. For more information, visit http://light.ece.Illinois.edu. Publisher Copyright: {\textcopyright} 2017 The Author(s).",

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AU - Nguyen, Tan H.

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AU - Best-Popescu, Catherine

AU - Arikkath, Jyothi

AU - Do, Minh N.

AU - Popescu, Gabriel

N1 - Funding Information: This research was supported in part by the National Science Foundation (grants CBET-1040462 MRI, CBET-0939511 STC, IIP-1353368). J. A. research is supported by grants from NIH COBRE (5P20GM103471), Alzheimer's Association and Brain and Behavior Research Foundation. We want to thank Dr. Lynford Goddard from the Micro and Nanotechnology Laboratory, University of Illinois at Urbana-Champaign for providing the pillar sample. T.N. acknowledges support from the Computational Science Engineering department through a Computational Science Engineering Fellowship. For more information, visit http://light.ece.Illinois.edu. Publisher Copyright: © 2017 The Author(s).

PY - 2017/3/24

Y1 - 2017/3/24

N2 - We present a new approach for retrieving halo-free phase contrast microscopy (hfPC) images by upgrading the conventional PC microscope with an external interferometric module, which generates sufficient data for reversing the halo artifact. Acquiring four independent intensity images, our approach first measures haloed phase maps of the sample. We solve for the halo-free sample transmission function by using a physical model of the image formation under partial spatial coherence. Using this halo-free sample transmission, we can numerically generate artifact-free PC images. Furthermore, this transmission can be further used to obtain quantitative information about the sample, e.g., the thickness with known refractive indices, dry mass of live cells during their cycles. We tested our hfPC method on various control samples, e.g., beads, pillars and validated its potential for biological investigation by imaging live HeLa cells, red blood cells, and neurons.

AB - We present a new approach for retrieving halo-free phase contrast microscopy (hfPC) images by upgrading the conventional PC microscope with an external interferometric module, which generates sufficient data for reversing the halo artifact. Acquiring four independent intensity images, our approach first measures haloed phase maps of the sample. We solve for the halo-free sample transmission function by using a physical model of the image formation under partial spatial coherence. Using this halo-free sample transmission, we can numerically generate artifact-free PC images. Furthermore, this transmission can be further used to obtain quantitative information about the sample, e.g., the thickness with known refractive indices, dry mass of live cells during their cycles. We tested our hfPC method on various control samples, e.g., beads, pillars and validated its potential for biological investigation by imaging live HeLa cells, red blood cells, and neurons.

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Halo-free Phase Contrast Microscopy

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