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Geometrical effect characterization of femtosecond-laser manufactured glass microfluidic chips based on optical manipulation of submicroparticles

Publication ,  Journal Article
Kotsifaki, DG; Mackenzie, MD; Polydefki, G; Kar, AK; Makropoulou, M; Serafetinides, AA
Published in: Optical Engineering
December 1, 2017

Microfluidic devices provide a platform with wide ranging applications from environmental monitoring to disease diagnosis. They offer substantive advantages but are often not optimized or designed to be used by nonexpert researchers. Microchannels of a microanalysis platform and their geometrical characterization are of eminent importance when designing such devices. We present a method that is used to optimize each microchannel within a device using high-throughput particle manipulation. For this purpose, glass-based microfluidic devices, with three-dimensional channel networks of several geometrical sizes, were fabricated by employing laser fabrication techniques. The effect of channel geometry was investigated by employing an optical tweezer. The optical trapping force depends on the flow velocity that is associated with the dimensions of the microchannel. We observe a linear dependence of the trapping efficiency and of the fluid flow velocity, with the channel dimensions. We determined that the highest trapping efficiency was achieved for microchannels with aspect ratio equal to one. Numerical simulation validated the impact of the device design dimensions on the trapping efficiency. This investigation indicates that the geometrical characteristics, the flow velocity, and trapping efficiency are crucial and should be considered when fabricating microfluidic devices for cell studies.

Duke Scholars

Published In

Optical Engineering

DOI

EISSN

1560-2303

ISSN

0091-3286

Publication Date

December 1, 2017

Volume

56

Issue

12

Related Subject Headings

  • Optics
  • 5102 Atomic, molecular and optical physics
  • 4603 Computer vision and multimedia computation
  • 4008 Electrical engineering
  • 0906 Electrical and Electronic Engineering
  • 0801 Artificial Intelligence and Image Processing
  • 0205 Optical Physics
 

Citation

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ICMJE
MLA
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Kotsifaki, D. G., Mackenzie, M. D., Polydefki, G., Kar, A. K., Makropoulou, M., & Serafetinides, A. A. (2017). Geometrical effect characterization of femtosecond-laser manufactured glass microfluidic chips based on optical manipulation of submicroparticles. Optical Engineering, 56(12). https://doi.org/10.1117/1.OE.56.12.124111
Kotsifaki, D. G., M. D. Mackenzie, G. Polydefki, A. K. Kar, M. Makropoulou, and A. A. Serafetinides. “Geometrical effect characterization of femtosecond-laser manufactured glass microfluidic chips based on optical manipulation of submicroparticles.” Optical Engineering 56, no. 12 (December 1, 2017). https://doi.org/10.1117/1.OE.56.12.124111.
Kotsifaki DG, Mackenzie MD, Polydefki G, Kar AK, Makropoulou M, Serafetinides AA. Geometrical effect characterization of femtosecond-laser manufactured glass microfluidic chips based on optical manipulation of submicroparticles. Optical Engineering. 2017 Dec 1;56(12).
Kotsifaki, D. G., et al. “Geometrical effect characterization of femtosecond-laser manufactured glass microfluidic chips based on optical manipulation of submicroparticles.” Optical Engineering, vol. 56, no. 12, Dec. 2017. Scopus, doi:10.1117/1.OE.56.12.124111.
Kotsifaki DG, Mackenzie MD, Polydefki G, Kar AK, Makropoulou M, Serafetinides AA. Geometrical effect characterization of femtosecond-laser manufactured glass microfluidic chips based on optical manipulation of submicroparticles. Optical Engineering. 2017 Dec 1;56(12).
Journal cover image

Published In

Optical Engineering

DOI

EISSN

1560-2303

ISSN

0091-3286

Publication Date

December 1, 2017

Volume

56

Issue

12

Related Subject Headings

  • Optics
  • 5102 Atomic, molecular and optical physics
  • 4603 Computer vision and multimedia computation
  • 4008 Electrical engineering
  • 0906 Electrical and Electronic Engineering
  • 0801 Artificial Intelligence and Image Processing
  • 0205 Optical Physics