Parallel on-axis holographic phase microscopy of biological cells and unicellular microorganism dynamics.

dc.contributor.author

Ehlers, MD

dc.contributor.author

Newpher, Thomas Mark

dc.contributor.author

Shaked, NT

dc.contributor.author

Wax, A

dc.coverage.spatial

United States

dc.date.accessioned

2011-06-21T17:27:39Z

dc.date.accessioned

2016-07-14T19:39:27Z

dc.date.issued

2010-05-20

dc.description.abstract

We apply a wide-field quantitative phase microscopy technique based on parallel two-step phase-shifting on-axis interferometry to visualize live biological cells and microorganism dynamics. The parallel on-axis holographic approach is more efficient with camera spatial bandwidth consumption compared to previous off-axis approaches and thus can capture finer sample spatial details, given a limited spatial bandwidth of a specific digital camera. Additionally, due to the parallel acquisition mechanism, the approach is suitable for visualizing rapid dynamic processes, permitting an interferometric acquisition rate equal to the camera frame rate. The method is demonstrated experimentally through phase microscopy of neurons and unicellular microorganisms.

dc.description.version

Version of Record

dc.identifier

http://www.ncbi.nlm.nih.gov/pubmed/20490249

dc.identifier

199509

dc.identifier.eissn

1539-4522

dc.identifier.uri

https://hdl.handle.net/10161/12464

dc.language

eng

dc.language.iso

en_US

dc.relation.ispartof

Appl Opt

dc.relation.journal

Applied Optics

dc.relation.replaces

http://hdl.handle.net/10161/4206

dc.relation.replaces

10161/4206

dc.subject

Animals

dc.subject

Cells, Cultured

dc.subject

Computer-Aided Design

dc.subject

Equipment Design

dc.subject

Equipment Failure Analysis

dc.subject

Euglena gracilis

dc.subject

Holography

dc.subject

Microscopy, Phase-Contrast

dc.subject

Neurons

dc.subject

Rats

dc.subject

Reproducibility of Results

dc.subject

Sensitivity and Specificity

dc.title

Parallel on-axis holographic phase microscopy of biological cells and unicellular microorganism dynamics.

dc.title.alternative
dc.type

Journal article

duke.date.pubdate

2010-5-20

duke.description.issue

15

duke.description.volume

49

pubs.author-url

http://www.ncbi.nlm.nih.gov/pubmed/20490249

pubs.begin-page

2872

pubs.end-page

2878

pubs.issue

15

pubs.organisational-group

Biomedical Engineering

pubs.organisational-group

Duke

pubs.organisational-group

Duke Institute for Brain Sciences

pubs.organisational-group

Institutes and Provost's Academic Units

pubs.organisational-group

Pratt School of Engineering

pubs.organisational-group

University Institutes and Centers

pubs.publication-status

Published

pubs.volume

49

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