A miniaturized optical tomography platform for volumetric imaging of engineered living systems

Adem Polat; Shabir Hassan; Isa Yildirim; Luis Eduardo Oliver; Maryam Mostafaei; Siddharth Kumar; Sushila Maharjan; Louis Bourguet; Xia Cao; Guoliang Ying; Milad Eyvazi Hesar; Yu Shrike Zhang

doi:10.1039/c8lc01190g

A miniaturized optical tomography platform for volumetric imaging of engineered living systems

Adem Polat, Shabir Hassan, Isa Yildirim, Luis Eduardo Oliver, Maryam Mostafaei, Siddharth Kumar, Sushila Maharjan, Louis Bourguet, Xia Cao, Guoliang Ying, Milad Eyvazi Hesar, Yu Shrike Zhang^*

^*Corresponding author for this work

Department of Electronics and Communication Engineering

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

10 Citations (Scopus)

Abstract

Volumetric optical microscopy approaches that enable acquisition of three-dimensional (3D) information from a biological sample are attractive for numerous non-invasive imaging applications. The unprecedented structural details that these techniques provide have helped in our understanding of different aspects of architecture of cells, tissues, and organ systems as they occur in their natural states. Nonetheless, the instrumentation for most of these techniques is sophisticated, bulky, and costly, and is less affordable to most laboratory settings. Several miniature imagers based on webcams or low-cost sensors featuring easy assembly have been reported, for in situ imaging of biological structures at low costs. However, they have not been able to achieve the ability of 3D imaging throughout the entire volumes for spatiotemporal analyses of the structural changes in these specimens. Here we present a miniaturized optical tomography (mini-Opto) platform for low-cost, volumetric characterization of engineered living systems through hardware optimizations as well as applications of an optimized algebraic algorithm for image reconstruction.

Original language	English
Pages (from-to)	550-561
Number of pages	12
Journal	Lab on a Chip
Volume	19
Issue number	4
DOIs	https://doi.org/10.1039/c8lc01190g
Publication status	Published - 21 Feb 2019

Bibliographical note

Publisher Copyright:
© The Royal Society of Chemistry.

Funding

This work was supported by the National Institutes of Health (K99CA201603, R21EB025270, R21EB026175) and the New England Anti-Vivisection Society (NEAVS). A. P. was supported by TUBITAK, the Scientific and Research Council of Turkey, under the grant 1059B141600590. S. H. acknowledges the financial support from the Swiss National Science Foundation (SNSF) under grant No. P2ZHP3_161965 and P300PA_177867. X. C. was supported by the National Natural Science Foundation of China (81503025). S. M. acknowledges NEAVS and the American Fund for Alternatives to Animal Research (AFAAR) for Postdoctoral Fellowship. G. L. Y. acknowledges Natural and Science Foundation of Hubei Province, China (2014CFB778).

Funders	Funder number
American Fund for Alternatives to Animal Research
Natural and Science Foundation of Hubei Province, China	2014CFB778
New England Anti-Vivisection Society
Scientific and Research Council of Turkey	1059B141600590
TUBITAK
National Institutes of Health	R21EB025270, R21EB026175
National Cancer Institute	K99CA201603
Schweizerischer Nationalfonds zur Förderung der Wissenschaftlichen Forschung	P2ZHP3_161965, P300PA_177867
National Natural Science Foundation of China	81503025

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10.1039/c8lc01190g

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abstract = "Volumetric optical microscopy approaches that enable acquisition of three-dimensional (3D) information from a biological sample are attractive for numerous non-invasive imaging applications. The unprecedented structural details that these techniques provide have helped in our understanding of different aspects of architecture of cells, tissues, and organ systems as they occur in their natural states. Nonetheless, the instrumentation for most of these techniques is sophisticated, bulky, and costly, and is less affordable to most laboratory settings. Several miniature imagers based on webcams or low-cost sensors featuring easy assembly have been reported, for in situ imaging of biological structures at low costs. However, they have not been able to achieve the ability of 3D imaging throughout the entire volumes for spatiotemporal analyses of the structural changes in these specimens. Here we present a miniaturized optical tomography (mini-Opto) platform for low-cost, volumetric characterization of engineered living systems through hardware optimizations as well as applications of an optimized algebraic algorithm for image reconstruction.",

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A miniaturized optical tomography platform for volumetric imaging of engineered living systems

Abstract

Bibliographical note

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