Quantitative phase imaging of erythrocytes under microfluidic constriction in a high refractive index medium reveals water content changes

Han Sang, Park, Duke University; Will J., Eldridge, Duke University; Wen-Hsuan, Yang, Duke University; Michael, Crose, Duke University; Silvia, Ceballos, Duke University; John, Roback, Emory University; Jen-Tsan Alshey, Chi, Duke University; Adam, Wax, Duke University

Persistent URL

https://open.library.emory.edu/purl/6451g1jxgz-emory

Last modified

05/22/2025

Type of Material

Article

Authors

Han Sang Park, Duke University

Will J. Eldridge, Duke University

Wen-Hsuan Yang, Duke University

Michael Crose, Duke University

Silvia Ceballos, Duke University

John Roback, Emory UniversityJen-Tsan Alshey Chi, Duke UniversityAdam Wax, Duke University

Language

English

Date

2019-12-02

Publisher

Nature Publishing Group

Publication Version

Final Published Version

Copyright Statement

© 2019, The Author(s).

License

Creative Commons Attribution 4.0 International

Final Published Version (URL)

http://dx.doi.org/10.1038/s41378-019-0113-y

Title of Journal or Parent Work

Microsystems and Nanoengineering

Volume

5

Issue

1

Start Page

63

End Page

63

Grant/Funding Information

Work supported by NSF (CBET-1604562), NIH (1R21 ES029791), World anti-doping agent (WADA) and Partnership for Clean Competition (PCC).

Supplemental Material (URL)

Abstract

Changes in the deformability of red blood cells can reveal a range of pathologies. For example, cells which have been stored for transfusion are known to exhibit progressively impaired deformability. Thus, this aspect of red blood cells has been characterized previously using a range of techniques. In this paper, we show a novel approach for examining the biophysical response of the cells with quantitative phase imaging. Specifically, optical volume changes are observed as the cells transit restrictive channels of a microfluidic chip in a high refractive index medium. The optical volume changes indicate an increase of cell’s internal density, ostensibly due to water displacement. Here, we characterize these changes over time for red blood cells from two subjects. By storage day 29, a significant decrease in the magnitude of optical volume change in response to mechanical stress was witnessed. The exchange of water with the environment due to mechanical stress is seen to modulate with storage time, suggesting a potential means for studying cell storage.

Author Notes

Correspondence: Han Sang Park, Email:hansang.park@duke.edu

Keywords

Research Categories

Engineering, Biomedical

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Quantitative phase imaging of erythrocytes under microfluidic constriction in a high refractive index medium reveals water content changes

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