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



Mechanical deformation induces depolarization of neutrophils


Journal article


Andrew E. Ekpenyong, N. Toepfner, C. Fiddler, M. Herbig, Wenhong Li, G. Cojoc, C. Summers, J. Guck, E. Chilvers
Science Advances, 2017

Semantic Scholar DOI PubMedCentral PubMed
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Cite

APA   Click to copy
Ekpenyong, A. E., Toepfner, N., Fiddler, C., Herbig, M., Li, W., Cojoc, G., … Chilvers, E. (2017). Mechanical deformation induces depolarization of neutrophils. Science Advances.


Chicago/Turabian   Click to copy
Ekpenyong, Andrew E., N. Toepfner, C. Fiddler, M. Herbig, Wenhong Li, G. Cojoc, C. Summers, J. Guck, and E. Chilvers. “Mechanical Deformation Induces Depolarization of Neutrophils.” Science Advances (2017).


MLA   Click to copy
Ekpenyong, Andrew E., et al. “Mechanical Deformation Induces Depolarization of Neutrophils.” Science Advances, 2017.


BibTeX   Click to copy

@article{andrew2017a,
  title = {Mechanical deformation induces depolarization of neutrophils},
  year = {2017},
  journal = {Science Advances},
  author = {Ekpenyong, Andrew E. and Toepfner, N. and Fiddler, C. and Herbig, M. and Li, Wenhong and Cojoc, G. and Summers, C. and Guck, J. and Chilvers, E.}
}

Abstract

In vivo–mimicking mechanical deformations quickly depolarize neutrophils—a mechanism potentially failing in acute lung injury. The transition of neutrophils from a resting state to a primed state is an essential requirement for their function as competent immune cells. This transition can be caused not only by chemical signals but also by mechanical perturbation. After cessation of either, these cells gradually revert to a quiescent state over 40 to 120 min. We use two biophysical tools, an optical stretcher and a novel microcirculation mimetic, to effect physiologically relevant mechanical deformations of single nonadherent human neutrophils. We establish quantitative morphological analysis and mechanical phenotyping as label-free markers of neutrophil priming. We show that continued mechanical deformation of primed cells can cause active depolarization, which occurs two orders of magnitude faster than by spontaneous depriming. This work provides a cellular-level mechanism that potentially explains recent clinical studies demonstrating the potential importance, and physiological role, of neutrophil depriming in vivo and the pathophysiological implications when this deactivation is impaired, especially in disorders such as acute lung injury.


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