Investigation of depth-resolved nanoscale structural changes in regulated cell proliferation and chromatin decondensation

Shikhar Uttam; Rajan K. Bista; Kevin Staton; Sergey Alexandrov; Serah Choi; Christopher J. Bakkenist; Douglas J. Hartman; Randall E. Brand; Yang Liu

doi:10.13025/15672

Investigation of depth-resolved nanoscale structural changes in regulated cell proliferation and chromatin decondensation

Shikhar Uttam
, Rajan K. Bista
, Kevin Staton
, Sergey Alexandrov
, Serah Choi
, Christopher J. Bakkenist
, Douglas J. Hartman
, Randall E. Brand
, Yang Liu

Physics

Biomedical and Optical Imaging Laboratory (BOIL), Departments of Medicine and Bioengineering, University of Pittsburgh
University of Pittsburgh School of Medicine

Research output: Contribution to a Journal (Peer & Non Peer) › Article › peer-review

17 Citations (Scopus)

Abstract

We present depth-resolved spatial-domain low-coherence quantitative phase microscopy, a simple approach that utilizes coherence gating to construct a depth-resolved structural feature vector quantifying sub-resolution axial structural changes at different optical depths within the sample. We show that this feature vector is independent of sample thickness variation, and identifies nanoscale structural changes in clinically prepared samples. We present numerical simulations and experimental validation to demonstrate the feasibility of the approach. We also perform experiments using unstained cells to investigate the nanoscale structural changes in regulated cell proliferation through cell cycle and chromatin decondensation induced by histone acetylation.

Original language	English
Pages (from-to)	596-613
Number of pages	18
Journal	Biomedical Optics Express
Volume	4
Issue number	4
DOIs	https://doi.org/10.13025/15672 https://doi.org/10.1364/boe.4.000596
Publication status	Published - 1 Apr 2013

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10.13025/15672Licence: CC BY-NC-ND
10.1364/boe.4.000596

BOE 2013-4-4-596 AranAccepted author manuscript, 1.42 MBLicence: CC BY-NC-ND

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abstract = "We present depth-resolved spatial-domain low-coherence quantitative phase microscopy, a simple approach that utilizes coherence gating to construct a depth-resolved structural feature vector quantifying sub-resolution axial structural changes at different optical depths within the sample. We show that this feature vector is independent of sample thickness variation, and identifies nanoscale structural changes in clinically prepared samples. We present numerical simulations and experimental validation to demonstrate the feasibility of the approach. We also perform experiments using unstained cells to investigate the nanoscale structural changes in regulated cell proliferation through cell cycle and chromatin decondensation induced by histone acetylation.",

author = "Shikhar Uttam and Bista, \{Rajan K.\} and Kevin Staton and Sergey Alexandrov and Serah Choi and Bakkenist, \{Christopher J.\} and Hartman, \{Douglas J.\} and Brand, \{Randall E.\} and Yang Liu",

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AU - Uttam, Shikhar

AU - Bista, Rajan K.

AU - Staton, Kevin

AU - Alexandrov, Sergey

AU - Choi, Serah

AU - Bakkenist, Christopher J.

AU - Hartman, Douglas J.

AU - Brand, Randall E.

AU - Liu, Yang

PY - 2013/4/1

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N2 - We present depth-resolved spatial-domain low-coherence quantitative phase microscopy, a simple approach that utilizes coherence gating to construct a depth-resolved structural feature vector quantifying sub-resolution axial structural changes at different optical depths within the sample. We show that this feature vector is independent of sample thickness variation, and identifies nanoscale structural changes in clinically prepared samples. We present numerical simulations and experimental validation to demonstrate the feasibility of the approach. We also perform experiments using unstained cells to investigate the nanoscale structural changes in regulated cell proliferation through cell cycle and chromatin decondensation induced by histone acetylation.

AB - We present depth-resolved spatial-domain low-coherence quantitative phase microscopy, a simple approach that utilizes coherence gating to construct a depth-resolved structural feature vector quantifying sub-resolution axial structural changes at different optical depths within the sample. We show that this feature vector is independent of sample thickness variation, and identifies nanoscale structural changes in clinically prepared samples. We present numerical simulations and experimental validation to demonstrate the feasibility of the approach. We also perform experiments using unstained cells to investigate the nanoscale structural changes in regulated cell proliferation through cell cycle and chromatin decondensation induced by histone acetylation.

UR - http://hdl.handle.net/10379/7176

UR - https://www.scopus.com/pages/publications/84875705740

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JO - Biomedical Optics Express

JF - Biomedical Optics Express

IS - 4

ER -

Investigation of depth-resolved nanoscale structural changes in regulated cell proliferation and chromatin decondensation

Abstract

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