Compact, common path quantitative phase microscopic techniques for imaging cell dynamics

A. Anand; P. Vora; S. Mahajan; V. Trivedi; V. Chhaniwal; A. Singh; R. Leitgeb; B. Javidi

doi:10.1007/s12043-013-0644-y

Compact, common path quantitative phase microscopic techniques for imaging cell dynamics

A. Anand, P. Vora, S. Mahajan, V. Trivedi, V. Chhaniwal, A. Singh, R. Leitgeb, B. Javidi

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

21 Scopus citations

Abstract

Microscopy using visible electromagnetic radiation can be used to investigate living cells in various environments. But bright field microscopy only provides two-dimensional (2D) intensity distribution at a single object plane. One of the ways to retrieve object height/thickness information is to employ quantitative phase microscopic (QPM) techniques. Interferometric QPM techniques are widely used for this. Digital holographic microscopy (DHM) is one of the stateof- the-art methods for quantitative three-dimensional (3D) imaging. Usually it is implemented in two-beam geometry, which is prone to mechanical vibrations. But to study dynamics of objects like red blood cells, one needs temporal stability much better than the fluctuations of the object, which the two-beam geometry fails to deliver. One way to overcome this hurdle is to use selfreferencing techniques, in which a portion of the object beam will act as the reference beam. Here the development of self-referencing QPM techniques is described along with the results.

Original language	English
Pages (from-to)	71-78
Number of pages	8
Journal	Pramana - Journal of Physics
Volume	82
Issue number	1
DOIs	https://doi.org/10.1007/s12043-013-0644-y
State	Published - Jan 2014
Externally published	Yes

Bibliographical note

Funding Information:
A Anand acknowledges research funding through DST-FIST and UGC-DRS projects and also UGC major research grant (42-776/2013(SR)).

Funding

A Anand acknowledges research funding through DST-FIST and UGC-DRS projects and also UGC major research grant (42-776/2013(SR)).

Funders	Funder number
DST-FIST
UGC-DRS
University Grants Committee

Keywords

Cell imaging
Diffraction
Digital holography
Quantitative phase contrast imaging
Three-dimensional microscopy

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10.1007/s12043-013-0644-y

Cite this

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title = "Compact, common path quantitative phase microscopic techniques for imaging cell dynamics",

abstract = "Microscopy using visible electromagnetic radiation can be used to investigate living cells in various environments. But bright field microscopy only provides two-dimensional (2D) intensity distribution at a single object plane. One of the ways to retrieve object height/thickness information is to employ quantitative phase microscopic (QPM) techniques. Interferometric QPM techniques are widely used for this. Digital holographic microscopy (DHM) is one of the stateof- the-art methods for quantitative three-dimensional (3D) imaging. Usually it is implemented in two-beam geometry, which is prone to mechanical vibrations. But to study dynamics of objects like red blood cells, one needs temporal stability much better than the fluctuations of the object, which the two-beam geometry fails to deliver. One way to overcome this hurdle is to use selfreferencing techniques, in which a portion of the object beam will act as the reference beam. Here the development of self-referencing QPM techniques is described along with the results.",

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author = "A. Anand and P. Vora and S. Mahajan and V. Trivedi and V. Chhaniwal and A. Singh and R. Leitgeb and B. Javidi",

note = "Funding Information: A Anand acknowledges research funding through DST-FIST and UGC-DRS projects and also UGC major research grant (42-776/2013(SR)).",

year = "2014",

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doi = "10.1007/s12043-013-0644-y",

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AU - Anand, A.

AU - Vora, P.

AU - Mahajan, S.

AU - Trivedi, V.

AU - Chhaniwal, V.

AU - Singh, A.

AU - Leitgeb, R.

AU - Javidi, B.

N1 - Funding Information: A Anand acknowledges research funding through DST-FIST and UGC-DRS projects and also UGC major research grant (42-776/2013(SR)).

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N2 - Microscopy using visible electromagnetic radiation can be used to investigate living cells in various environments. But bright field microscopy only provides two-dimensional (2D) intensity distribution at a single object plane. One of the ways to retrieve object height/thickness information is to employ quantitative phase microscopic (QPM) techniques. Interferometric QPM techniques are widely used for this. Digital holographic microscopy (DHM) is one of the stateof- the-art methods for quantitative three-dimensional (3D) imaging. Usually it is implemented in two-beam geometry, which is prone to mechanical vibrations. But to study dynamics of objects like red blood cells, one needs temporal stability much better than the fluctuations of the object, which the two-beam geometry fails to deliver. One way to overcome this hurdle is to use selfreferencing techniques, in which a portion of the object beam will act as the reference beam. Here the development of self-referencing QPM techniques is described along with the results.

AB - Microscopy using visible electromagnetic radiation can be used to investigate living cells in various environments. But bright field microscopy only provides two-dimensional (2D) intensity distribution at a single object plane. One of the ways to retrieve object height/thickness information is to employ quantitative phase microscopic (QPM) techniques. Interferometric QPM techniques are widely used for this. Digital holographic microscopy (DHM) is one of the stateof- the-art methods for quantitative three-dimensional (3D) imaging. Usually it is implemented in two-beam geometry, which is prone to mechanical vibrations. But to study dynamics of objects like red blood cells, one needs temporal stability much better than the fluctuations of the object, which the two-beam geometry fails to deliver. One way to overcome this hurdle is to use selfreferencing techniques, in which a portion of the object beam will act as the reference beam. Here the development of self-referencing QPM techniques is described along with the results.

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KW - Digital holography

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Compact, common path quantitative phase microscopic techniques for imaging cell dynamics

Abstract

Bibliographical note

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Keywords

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