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



Separation of blood cells with differing deformability using deterministic lateral displacement†


Journal article


D. Holmes, G. Whyte, J. Bailey, Nuria Vergara-Irigaray, Andrew E. Ekpenyong, J. Guck, T. Duke
Interface Focus, 2014

Semantic Scholar DOI PubMedCentral PubMed
Cite

Cite

APA   Click to copy
Holmes, D., Whyte, G., Bailey, J., Vergara-Irigaray, N., Ekpenyong, A. E., Guck, J., & Duke, T. (2014). Separation of blood cells with differing deformability using deterministic lateral displacement†. Interface Focus.


Chicago/Turabian   Click to copy
Holmes, D., G. Whyte, J. Bailey, Nuria Vergara-Irigaray, Andrew E. Ekpenyong, J. Guck, and T. Duke. “Separation of Blood Cells with Differing Deformability Using Deterministic Lateral Displacement†.” Interface Focus (2014).


MLA   Click to copy
Holmes, D., et al. “Separation of Blood Cells with Differing Deformability Using Deterministic Lateral Displacement†.” Interface Focus, 2014.


BibTeX   Click to copy

@article{d2014a,
  title = {Separation of blood cells with differing deformability using deterministic lateral displacement†},
  year = {2014},
  journal = {Interface Focus},
  author = {Holmes, D. and Whyte, G. and Bailey, J. and Vergara-Irigaray, Nuria and Ekpenyong, Andrew E. and Guck, J. and Duke, T.}
}

Abstract

Determining cell mechanical properties is increasingly recognized as a marker-free way to characterize and separate biological cells. This emerging realization has led to the development of a plethora of appropriate measurement techniques. Here, we use a fairly novel approach, deterministic lateral displacement (DLD), to separate blood cells based on their mechanical phenotype with high throughput. Human red blood cells were treated chemically to alter their membrane deformability and the effect of this alteration on the hydrodynamic behaviour of the cells in a DLD device was investigated. Cells of defined stiffness (glutaraldehyde cross-linked erythrocytes) were used to test the performance of the DLD device across a range of cell stiffness and applied shear rates. Optical stretching was used as an independent method for quantifying the variation in stiffness of the cells. Lateral displacement of cells flowing within the device, and their subsequent exit position from the device were shown to correlate with cell stiffness. Data showing how the isolation of leucocytes from whole blood varies with applied shear rate are also presented. The ability to sort leucocyte sub-populations (T-lymphocytes and neutrophils), based on a combination of cell size and deformability, demonstrates the potential for using DLD devices to perform continuous fractionation and/or enrichment of leucocyte sub-populations from whole blood.


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