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Experiments in Fluids
Published in: Experiments in Fluids 6/2020

01-06-2020 | Research Article

Structured illumination microscopy: a new way to improve the axial spatial resolution of microscale particle velocimetry

Authors: Michael Spadaro, Minami Yoda

Published in: Experiments in Fluids | Issue 6/2020

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Abstract

Many visualizations of microchannel flows illuminate a significant portion, if not all, of the channel. This volume illumination degrades the axial spatial resolution of microscale particle velocimetry measurements because signal from out-of-focus tracer particles “contaminates” the image. We present here a novel way to improve the axial spatial resolution of such velocimetry measurements, structured illumination microscopy (SIM) particle-tracking velocimetry (PTV). In these initial proof of concept experiments, double-exposure SIM PTV was used to measure velocities in plane Poiseuille flow. The velocity results obtained from the SIM images have significantly less error and standard deviation than standard microscale PTV data obtained with volume illumination. Our estimates also suggest that the axial spatial resolution of the SIM results is a twofold improvement over those obtained with “standard” microscale PTV.

Graphic abstract

next article Response of a flat plate laminar separation bubble to Reynolds number, free-stream turbulence and adverse pressure gradient variation

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Literature
Adrian L, Adrian RJ, Westerweel J (2011) Particle image velocimetry, vol 30. Cambridge University Press, CambridgeMATH
Barnkob R, Kähler CJ, Rossi M (2015) General defocusing particle tracking. Lab Chip 15(17):3556–3560CrossRef
Chan T, Vese L (2001) Active contours without edges. IEEE Trans Image Process 10(2):266–277CrossRef
Chen S, Angarita-Jaimes N, Angarita-Jaimes D, Pelc B, Greenaway AH, Towers CE, Lin D, Towers DP (2009) Wavefront sensing for three-component three-dimensional flow velocimetry in microfluidics. Exp Fluids 47(4–5):849–863CrossRef
Cierpka C, Kähler CJ (2012) Particle imaging techniques for volumetric three-component (3D3C) velocity measurements in microfluidics. J Vis 15(1):1–31CrossRef
Cierpka C, Rossi M, Segura R, Kähler CJ (2010) On the calibration of astigmatism particle tracking velocimetry for microflows. Meas Sci Technol 22(1):015401CrossRef
Fiddes LK, Raz N, Srigunapalan S, Tumarkan E, Simmons CA, Wheeler AR, Kumacheva E (2010) A circular cross-section PDMS microfluidics system for replication of cardiovascular flow conditions. Biomaterials 31(13):3459–3464CrossRef
Fouras A, Jacono DL, Nguyen CV, Hourigan K (2009) Volumetric correlation PIV: a new technique for 3D velocity vector field measurement. Exp Fluids 47(4–5):569–577CrossRef
Geisler R (2014) A fast double shutter system for CCD image sensors. Meas Sci Technol 25(2):025404CrossRef
Gustafsson MG (2000) Surpassing the lateral resolution limit by a factor of two using structured illumination microscopy. J Microsc 198(2):82–87CrossRef
Hinsch KD (2002) Holographic particle image velocimetry. Meas Sci Technol 13(7):R61CrossRef
Karadaglić D, Wilson T (2008) Image formation in structured illumination wide-field fluorescence microscopy. Micron 39(7):808–818CrossRef
Kim S, Lee SJ (2009) Measurement of Dean flow in a curved micro-tube using micro digital holographic particle tracking velocimetry. Exp Fluids 46(2):255CrossRef
Kim H, Westerweel J, Elsinga GE (2012) Comparison of Tomo-PIV and 3D-PTV for microfluidic flows. Meas Sci Technol 24(2):024007CrossRef
Kristensson E, Berrocal E (2018) Crossed patterned structured illumination for the analysis and velocimetry of transient turbid media. Sci Rep 8:11751CrossRef
Lee SJ, Kim S (2009) Advanced particle-based velocimetry techniques for microscale flows. Microfluid Nanofluid 6(5):577–588CrossRef
Lindken R, Westerweel J, Wieneke B (2006) Stereoscopic micro particle image velocimetry. Exp Fluids 41(2):161–171CrossRef
Meinhart CD, Wereley ST, Santiago JS (2000a) A PIV algorithm for estimating time-averaged velocity fields. J Fluid Eng 122:285–289CrossRef
Meinhart CD, Wereley ST, Gray MH (2000b) Volume illumination for two-dimensional particle image velocimetry. Meas Sci Technol 11(6):809–814CrossRef
Mertz J (2019) Introduction to optical microscopy, 3rd edn. Cambridge University Press, CambridgeCrossRef
Mishra YN, Kristensson E, Koegl M, Jönsson J, Zigan L, Berrocal E (2017) Comparison between two-phase and one-phase SLIPI for instantaneous imaging of transient sprays. Exp Fluids 58(9):110CrossRef
Neil MA, Juškaitis R, Wilson T (1997) Method of obtaining optical sectioning by using structured light in a conventional microscope. Opt Lett 22(24):1905–1907CrossRef
Ohno K, Tachikawa K, Manz A (2008) Microfluidics: applications for analytical purposes in chemistry and biochemistry. Electrophoresis 29:4443CrossRef
Oishi M, Kinoshita H, Fujii T, Oshima M (2011) Simultaneous measurement of internal and surrounding flows of a moving droplet using multicolour confocal micro-particle image velocimetry (micro-PIV). Meas Sci Technol 22(10):105401CrossRef
Otsu N (1979) A threshold selection method from gray-level histograms. IEEE Trans Syst Man Cybern Syst 9(1):62–66CrossRef
Park JS, Kihm KD (2006) Three-dimensional micro-PTV using deconvolution microscopy. Exp Fluids 40:491–499CrossRef
Pereira F, Lu J, Castano-Graff E, Gharib M (2007) Microscale 3D flow mapping with μDDPIV. Exp Fluids 42(4):589–599CrossRef
Raffel M, Willert CE, Scarano F, Kähler CJ, Wereley ST, Kompenhans J (2018) Particle image velocimetry: a practical guide, 3rd edn. Springer, BerlinCrossRef
Stemmer A, Beck M, Fiolka R (2008) Widefield fluorescence microscopy with extended resolution. Histochem Cell Biol 130(5):807–817CrossRef
Tien WH, Dabiri D, Hove JR (2014) Color-coded three-dimensional micro particle tracking velocimetry and application to micro backward-facing step flows. Exp Fluids 55(3):1684CrossRef
Truscott TT, Belden J, Ni R, Pendlebury J, McEwen B (2017) Three-dimensional microscopic light field particle image velocimetry. Exp Fluids 58(3):16CrossRef
Wereley ST, Meinhart CD (2010) Recent advances in micro-particle image velocimetry. Annu Rev Fluid Mech 42:557–576CrossRef
Zhou X, Lei M, Dan D, Yao B, Qian J, Yan S, Yang Y, Min J, Peng T, Ye T, Chen G (2015) Double-exposure optical sectioning structured illumination microscopy based on Hilbert transform reconstruction. PLoS ONE 10(3):e0120892CrossRef
Metadata
Title
Structured illumination microscopy: a new way to improve the axial spatial resolution of microscale particle velocimetry
Authors
Michael Spadaro
Minami Yoda
Publication date
01-06-2020
Publisher
Springer Berlin Heidelberg
Published in
Experiments in Fluids / Issue 6/2020
Print ISSN: 0723-4864
Electronic ISSN: 1432-1114
DOI
https://doi.org/10.1007/s00348-020-02965-z

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