Spatial light interference tomography (SLIT)

Zhuo Wang; Daniel L. Marks; Paul Scott Carney; Larry J. Millet; Martha U. Gillette; Agustin Mihi; Paul V. Braun; Zhen Shen; Supriya G. Prasanth; Gabriel Popescu

doi:10.1364/OE.19.019907

Spatial light interference tomography (SLIT)

Zhuo Wang
, Daniel L. Marks
, Paul Scott Carney
, Larry J. Millet
, Martha U. Gillette
, Agustin Mihi
, Paul V. Braun
, Zhen Shen
, Supriya G. Prasanth
, Gabriel Popescu

Mechanical Engineering

University of Illinois at Urbana-Champaign

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

78 Scopus citations

Abstract

We present spatial light interference tomography (SLIT), a labelfree method for 3D imaging of transparent structures such as live cells. SLIT uses the principle of interferometric imaging with broadband fields and combines the optical gating due to the micron-scale coherence length with that of the high numerical aperture objective lens. Measuring the phase shift map associated with the object as it is translated through focus provides full information about the 3D distribution associated with the refractive index. Using a reconstruction algorithm based on the Born approximation, we show that the sample structure may be recovered via a 3D, complex field deconvolution. We illustrate the method with reconstructed tomographic refractive index distributions of microspheres, photonic crystals, and unstained living cells.

Original language	English
Pages (from-to)	19907-19918
Number of pages	12
Journal	Optics Express
Volume	19
Issue number	21
DOIs	https://doi.org/10.1364/OE.19.019907
State	Published - Oct 10 2011

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title = "Spatial light interference tomography (SLIT)",

abstract = "We present spatial light interference tomography (SLIT), a labelfree method for 3D imaging of transparent structures such as live cells. SLIT uses the principle of interferometric imaging with broadband fields and combines the optical gating due to the micron-scale coherence length with that of the high numerical aperture objective lens. Measuring the phase shift map associated with the object as it is translated through focus provides full information about the 3D distribution associated with the refractive index. Using a reconstruction algorithm based on the Born approximation, we show that the sample structure may be recovered via a 3D, complex field deconvolution. We illustrate the method with reconstructed tomographic refractive index distributions of microspheres, photonic crystals, and unstained living cells.",

author = "Zhuo Wang and Marks, \{Daniel L.\} and Carney, \{Paul Scott\} and Millet, \{Larry J.\} and Gillette, \{Martha U.\} and Agustin Mihi and Braun, \{Paul V.\} and Zhen Shen and Prasanth, \{Supriya G.\} and Gabriel Popescu",

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doi = "10.1364/OE.19.019907",

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T1 - Spatial light interference tomography (SLIT)

AU - Wang, Zhuo

AU - Marks, Daniel L.

AU - Carney, Paul Scott

AU - Millet, Larry J.

AU - Gillette, Martha U.

AU - Mihi, Agustin

AU - Braun, Paul V.

AU - Shen, Zhen

AU - Prasanth, Supriya G.

AU - Popescu, Gabriel

PY - 2011/10/10

Y1 - 2011/10/10

N2 - We present spatial light interference tomography (SLIT), a labelfree method for 3D imaging of transparent structures such as live cells. SLIT uses the principle of interferometric imaging with broadband fields and combines the optical gating due to the micron-scale coherence length with that of the high numerical aperture objective lens. Measuring the phase shift map associated with the object as it is translated through focus provides full information about the 3D distribution associated with the refractive index. Using a reconstruction algorithm based on the Born approximation, we show that the sample structure may be recovered via a 3D, complex field deconvolution. We illustrate the method with reconstructed tomographic refractive index distributions of microspheres, photonic crystals, and unstained living cells.

AB - We present spatial light interference tomography (SLIT), a labelfree method for 3D imaging of transparent structures such as live cells. SLIT uses the principle of interferometric imaging with broadband fields and combines the optical gating due to the micron-scale coherence length with that of the high numerical aperture objective lens. Measuring the phase shift map associated with the object as it is translated through focus provides full information about the 3D distribution associated with the refractive index. Using a reconstruction algorithm based on the Born approximation, we show that the sample structure may be recovered via a 3D, complex field deconvolution. We illustrate the method with reconstructed tomographic refractive index distributions of microspheres, photonic crystals, and unstained living cells.

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VL - 19

SP - 19907

EP - 19918

JO - Optics Express

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IS - 21

ER -

Spatial light interference tomography (SLIT)

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