Dr Andrew E. Ekpenyong

Associate Professor of Physics. BPhil (Rome), BD (Rome), MS (Physics, Creighton, USA), PhD (Physics, Cambridge, UK)



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Dr Andrew Edet Ekpenyong

Associate Professor of Physics


Curriculum vitae



Office Phone: +14022802208


Physics

Creighton University

2500 California Plaza,
Omaha,
NE 68178,
USA




Dr Andrew E. Ekpenyong

Associate Professor of Physics. BPhil (Rome), BD (Rome), MS (Physics, Creighton, USA), PhD (Physics, Cambridge, UK)



Office Phone: +14022802208


Physics

Creighton University

2500 California Plaza,
Omaha,
NE 68178,
USA



Viscoelastic Properties of Differentiating Blood Cells Are Fate- and Function-Dependent


Journal article


Andrew E. Ekpenyong, G. Whyte, K. Chalut, S. Pagliara, F. Lautenschläger, C. Fiddler, S. Paschke, U. Keyser, E. Chilvers, J. Guck
PLoS ONE, 2012

Semantic Scholar DOI PubMedCentral PubMed
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Cite

APA   Click to copy
Ekpenyong, A. E., Whyte, G., Chalut, K., Pagliara, S., Lautenschläger, F., Fiddler, C., … Guck, J. (2012). Viscoelastic Properties of Differentiating Blood Cells Are Fate- and Function-Dependent. PLoS ONE.


Chicago/Turabian   Click to copy
Ekpenyong, Andrew E., G. Whyte, K. Chalut, S. Pagliara, F. Lautenschläger, C. Fiddler, S. Paschke, U. Keyser, E. Chilvers, and J. Guck. “Viscoelastic Properties of Differentiating Blood Cells Are Fate- and Function-Dependent.” PLoS ONE (2012).


MLA   Click to copy
Ekpenyong, Andrew E., et al. “Viscoelastic Properties of Differentiating Blood Cells Are Fate- and Function-Dependent.” PLoS ONE, 2012.


BibTeX   Click to copy

@article{andrew2012a,
  title = {Viscoelastic Properties of Differentiating Blood Cells Are Fate- and Function-Dependent},
  year = {2012},
  journal = {PLoS ONE},
  author = {Ekpenyong, Andrew E. and Whyte, G. and Chalut, K. and Pagliara, S. and Lautenschläger, F. and Fiddler, C. and Paschke, S. and Keyser, U. and Chilvers, E. and Guck, J.}
}

Abstract

Although cellular mechanical properties are known to alter during stem cell differentiation, understanding of the functional relevance of such alterations is incomplete. Here, we show that during the course of differentiation of human myeloid precursor cells into three different lineages, the cells alter their viscoelastic properties, measured using an optical stretcher, to suit their ultimate fate and function. Myeloid cells circulating in blood have to be advected through constrictions in blood vessels, engendering the need for compliance at short time-scales (<seconds). Intriguingly, only the two circulating myeloid cell types have increased short time scale compliance and flow better through microfluidic constrictions. Moreover, all three differentiated cell types reduce their steady-state viscosity by more than 50% and show over 140% relative increase in their ability to migrate through tissue-like pores at long time-scales (>minutes), compared to undifferentiated cells. These findings suggest that reduction in steady-state viscosity is a physiological adaptation for enhanced migration through tissues. Our results indicate that the material properties of cells define their function, can be used as a cell differentiation marker and could serve as target for novel therapies.


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