[1] I. Wong, X. Ding, C. Wu, and C.-M. Ho, Accurate and eective live bacteria microarray patterning on thick polycationic polymer layers co-patterned with hmds, RSC Adv., vol. 2, pp. 76737676, 2012. (Cited on page3.)
[2] B. G. Chung, L. A. Flanagan, S. W. Rhee, P. H. Schwartz, A. P. Lee, E. S.
Monuki, and N. L. Jeon, Human neural stem cell growth and dierentiation in a gradient-generating microuidic device, Lab Chip, vol. 5, pp. 401406, 2005. (Cited on pages 3and 4.)
[3] S. Ekström, J. Malmström, L. Wallman, M. Löfgren, J. Nilsson, T. Laurell, and G. Marko-Varga, On-chip microextraction for proteomic sample prepa- ration of in-gel digests., Proteomics, vol. 2, pp. 413421, 2002. (Cited on page4.)
[4] S.-H. Kim, S. Y. Lee, S.-M. Yang, and G.-R. Yi, Self-assembled colloidal structures for photonics, NPG Asia Mater, vol. 3, pp. 2533, 2011. (Cited on pages4 and5.)
[5] D. Zhang, J. Li, S. Chen, T. Li, J. Zhou, X. Cheng, and A. Zhang, Hybrid self-assembly, crystal, and fractal behavior of a carboxy-ended hyperbranched polyester/copper complex, Macromolecular Chemistry and Physics, vol. 214, no. 3, pp. 370377, 2013. (Cited on page5.)
[6] E. S. Andersen, M. Dong, M. M. Nielsen, K. Jahn, R. Subramani, W. Mam- douh, M. M. Golas, B. Sander, H. Stark, C. L. P. Oliveira, J. S. Pedersen, V. Birkedal, F. Besenbacher, K. V. Gothelf, and J. Kjems, Self-assembly of a nanoscale dna box with a controllable lid, Nature, vol. 459, pp. 7376, 2009.
(Cited on page5.)
[7] P. W. Sperling RA, Surface modication, functionalization and bioconjuga- tion of colloidal inorganic nanoparticles., Philos Trans A Math Phys Eng Sci., vol. 368, pp. 13331383, 2010. (Cited on page4.)
[8] W. Lee, H. Amini, H. A. Stone, and D. Di Carlo, Dynamic self-assembly and control of microuidic particle crystals, Proceedings of the National Academy of Sciences, 2010. (Cited on page4.)
[9] L. Spielman and S. L. Goren, Improving resolution in coulter counting by hydrodynamic focusing, Journal of Colloid and Interface Science, vol. 26, no. 2, pp. 175 182, 1968. (Cited on pages5 and 23.)
[10] G. Hairer and M. Vellekoop, An integrated ow-cell for full sample stream control, Microuidics and Nanouidics, vol. 7, no. 1, pp. 647658, 2009.
(Cited on pages5,6, and 137.)
[11] H.-C. Lee, H.-H. Hou, R.-J. Yang, C.-H. Lin, and L.-M. Fu, Microow cy- tometer incorporating sequential micro-weir structure for three-dimensional focusing, Microuidics and Nanouidics, vol. 11, no. 4, pp. 469478, 2011.
(Cited on pages 6,23, and 137.)
[12] N. Watkins, B. M. Venkatesan, M. Toner, W. Rodriguez, and R. Bashir, A robust electrical microcytometer with 3-dimensional hydrofocusing, Lab Chip, vol. 9, pp. 31773184, 2009. (Cited on pages 7 and137.)
[13] S. Choi and J.-K. Park, Continuous hydrophoretic separation and sizing of microparticles using slanted obstacles in a microchannel, Lab Chip, vol. 7, pp. 890897, 2007. (Cited on pages 7and 137.)
[14] A. Russom, A. K. Gupta, S. Nagrath, D. D. Carlo, J. F. Edd, and M. Toner, Dierential inertial focusing of particles in curved low-aspect-ratio microchan- nels, New Journal of Physics, vol. 11, no. 7, p. 075025, 2009. (Cited on pages8 and 137.)
[15] D. Di Carlo, D. Irimia, R. G. Tompkins, and M. Toner, Continuous inertial focusing, ordering, and separation of particles in microchannels, Proceedings of the National Academy of Sciences, vol. 104, no. 48, pp. 1889218897, 2007.
(Cited on pages 8,23, and 137.)
[16] X. Mao, J. R. Waldeisen, and T. J. Huang, "microuidic drifting"- implementing three-dimensional hydrodynamic focusing with a single-layer planar microuidic device, Lab Chip, vol. 7, pp. 12601262, 2007. (Cited on pages8,9, and137.)
[17] A. Kundt and O. Lehmann, Longitudinal vibrations and acoustic gures in cylindrical columns of liquids, Annalen der Physik und Chemie (Poggendor's Annalen), vol. 153-9, pp. 112, 1874. (Cited on pages 9,10, and 137.)
[18] J. W. S. Rayleigh, The theory of sound. Repr. edn., Dover Publ., New York, 1945. (Cited on page 9.)
[19] L. V. King, On the acoustic radiation pressure on spheres, Proc R. Soc.
London, vol. A147, pp. 212240, 1934. (Cited on pages 9and 65.)
[20] K. Yosioka and Y. Kawasima, Acoustic radiation pressure on a compressible sphere, Acustica, vol. 5, pp. 167173, 1955. (Cited on page 9.)
[21] L. P. Gor'kov, On the forces acting on a small particle in an acoustical eld in an ideal uid, Soviet Physics Doklady, vol. 6, p. 773, Mar. 1962. (Cited on pages9 and 62.)
[22] F. Petersson, A. Nilsson, C. Holm, H. Jonsson, and T. Laurell, Separation of lipids from blood utilizing ultrasonic standing waves in microuidic channels, Analyst, vol. 129, pp. 938943, 2004. (Cited on pages10,11,21, and137.)
[23] K. Ahn, C. Kerbage, T. P. Hunt, R. M. Westervelt, D. R. Link, and D. A.
Weitz, Dielectrophoretic manipulation of drops for high-speed microuidic sorting devices, Applied Physics Letters, vol. 88, no. 2, pp. , 2006. (Cited on pages11,12,21, and 137.)
[24] Y. Kang, B. Cetin, Z. Wu, and D. Li, Continuous particle separation with lo- calized ac-dielectrophoresis using embedded electrodes and an insulating hur- dle, Electrochimica Acta, vol. 54, no. 6, pp. 1715 1720, 2009. (Cited on pages11,12,21, and137.)
[25] M. Yamada and M. Seki, Hydrodynamic ltration for on-chip particle concen- tration and classication utilizing microuidics, Lab Chip, vol. 5, pp. 1233 1239, 2005. (Cited on pages13,22, and 137.)
[26] M. Aristov, R. Eichhorn, and C. Bechinger, Separation of chiral colloidal particles in a helical ow eld, Soft Matter, vol. 9, pp. 25252530, 2013.
(Cited on pages14 and 22.)
[27] N. J. Alvarez, C. Jeppesen, K. Yvind, N. A. Mortensen, and O. Hassager, The chromatographic separation of particles using optical electric elds, Lab Chip, vol. 13, pp. 928939, 2013. (Cited on pages 14and 22.)
[28] F. A. Messaud, R. D. Sanderson, J. R. Runyon, T. Otte, H. Pasch, and S. K. R.
Williams, An overview on eld-ow fractionation techniques and their appli- cations in the separation and characterization of polymers, Progress in Poly- mer Science, vol. 34, no. 4, pp. 351 368, 2009. (Cited on pages14 and22.) [29] R. Devendra and G. Drazer, Gravity driven deterministic lateral displacement for particle separation in microuidic devices, Analytical Chemistry, vol. 84, no. 24, pp. 1062110627, 2012. (Cited on pages14,15,22, and 137.)
[30] X. Xuan, J. Zhu, and C. Church, Particle focusing in microuidic devices, Microuidics and Nanouidics, vol. 9, no. 1, pp. 116, 2010. (Cited on pages16 and137.)
[31] H. Tsutsui and C.-M. Ho, Cell separation by non-inertial force elds in mi- crouidic systems, Mechanics Research Communications, vol. 36, no. 1, pp. 92 103, 2009. <ce:title>Recent Advances in Microuidics</ce:title>. (Cited on pages17and 58.)
[32] S. K. Ravula, D. W. Branch, C. D. James, R. J. Townsend, M. Hill, G. Ka- duchak, M. Ward, and I. Brener, A microuidic system combining acoustic and dielectrophoretic particle preconcentration and focusing, Sensors and Ac- tuators B: Chemical, vol. 130, no. 2, pp. 645 652, 2008. (Cited on pages17 and58.)
[33] M. Wiklund, Acoustouidics 12: Biocompatibility and cell viability in mi- crouidic acoustic resonators, Lab Chip, vol. 12, pp. 20182028, 2012. (Cited on page 17.)
[34] D. Bazou, L. A. Kuznetsova, and W. T. Coakley, Physical enviroment of 2-d animal cell aggregates formed in a short pathlength ultrasound standing wave trap, Ultrasound in Medicine & Biology, vol. 31, no. 3, pp. 423 430, 2005.
(Cited on page17.)
[35] A. Lenshof, M. Evander, T. Laurell, and J. Nilsson, Acoustouidics 5: Build- ing microuidic acoustic resonators, Lab Chip, vol. 12, pp. 684695, 2012.
(Cited on page17.)
[36] P. Glynne-Jones, P. P. Mishra, R. J. Boltryk, and M. Hill, Ecient nite element modeling of radiation forces on elastic particles of arbitrary size and geometry, The Journal of the Acoustical Society of America, vol. 133, no. 4, pp. 18851893, 2013. (Cited on pages17 and98.)
[37] R. Townsend, M. Hill, N. Harris, and N. White, Modelling of particle paths passing through an ultrasonic standing wave, Ultrasonics, vol. 42, pp. 319324, 2004. <ce:title>Proceedings of Ultrasonics International 2003</ce:title>. (Cited on pages17 and 18.)
[38] P. Skafte-Pedersen and H. Bruus, Acoustouidic simulations: Ultrasound handling of liquids and particles in microuidic systems, Proceedings - IC- NMM, 2008. (Cited on page 17.)
[39] A. A. Doinikov, Acoustic radiation pressure on a rigid sphere in a viscous uid, Proceedings: Mathematical and Physical Sciences, vol. 447, no. 1931, pp. 447466, 1994. (Cited on page17.)
[40] H. Bruus, Acoustouidics 2: Perturbation theory and ultrasound resonance modes, Lab Chip, vol. 12, pp. 2028, 2012. (Cited on page 18.)
[41] R. Townsend, M. Hill, N. Harris, and N. White, Investigation of two- dimensional acoustic resonant modes in a particle separator, Ultrasonics, vol. 44, pp. e467e471, December 2006. (Cited on pages18 and98.)
[42] A. Neild, S. Oberti, A. Haake, and J. Dual, Finite element modeling of a microparticle manipulator, Ultrasonics, vol. 44, Supplement, pp. 455 460, 2006. <ce:title>Proceedings of Ultrasonics International (UI'05) and World Congress on Ultrasonics (WCU)</ce:title>. (Cited on pages 18and 58.) [43] H. Bruus, Acoustouidics 1: Governing equations in microuidics, Lab Chip,
vol. 11, pp. 37423751, 2011. (Cited on page 18.)
[44] M. Baudoin, J.-L. Thomas, F. Coulouvrat, and D. Lhuillier, An extended coupled phase theory for the sound propagation in polydisperse concentrated
suspensions of rigid particles, The Journal of the Acoustical Society of Amer- ica, vol. 121, no. 6, pp. 33863397, 2007. (Cited on page18.)
[45] J. R. Allegra and S. A. Hawley, Attenuation of sound in suspensions and emulsions: Theory and experiments, The Journal of the Acoustical Society of America, vol. 51, no. 5B, pp. 15451564, 1972. (Cited on page18.)
[46] M. Kandula, Dispersion of sound in dilute suspensions with nonlinear particle relaxation., J Acoust Soc Am., vol. 127, 2010. (Cited on page18.)
[47] R. Barnkob, I. Iranmanesh, M. Wiklund, and H. Bruus, Measuring acoustic energy density in microchannel acoustophoresis using a simple and rapid light- intensity method, Lab Chip, vol. 12, pp. 23372344, 2012. (Cited on pages18 and77.)
[48] R. Barnkob, P. Augustsson, T. Laurell, and H. Bruus, Measuring the lo- cal pressure amplitude in microchannel acoustophoresis, Lab Chip, vol. 10, pp. 563570, 2010. (Cited on pages18 and 77.)
[49] D. B. Thiessen, J. B. Lonzaga, C. F. Osterhourdt, W. Wei, and P. L. Marston, Manipulation of uid objects using acoustic radiation pressure: Beyond drops and bubbles and retrospection, The Journal of the Acoustical Society of America, vol. 116, no. 4, pp. 25972597, 2004. (Cited on page18.)
[50] J. Wang and J. Dual, Numerical simulations for the time-averaged acoustic forces acting on rigid cylinders in ideal and viscous uids, Journal of Physics A: Mathematical and Theoretical, vol. 42, no. 28, p. 285502, 2009. (Cited on page18.)
[51] J. A. Mann, J. Tichy, and A. J. Romano, Instantaneous and time averaged energy transfer in acoustic elds, The Journal of the Acoustical Society of America, vol. 82, no. 1, pp. 1730, 1987. (Cited on page18.)
[52] N. Harris, M. Hill, S. Beeby, Y. Shen, N. White, J. Hawkes, and W. Coakley, A silicon microuidic ultrasonic separator, Sensors and Actuators B: Chemical, vol. 95, no. 13, pp. 425 434, 2003. (Cited on page19.)
[53] L. Johansson, M. Evander, T. Lilliehorn, M. Almqvist, J. Nilsson, T. Laurell, and S. Johansson, Temperature and trapping characterization of an acoustic trap with miniaturized integrated transducers - towards in-trap temperature regulation, Ultrasonics, vol. 53, no. 5, pp. 1020 1032, 2013. (Cited on page19.)
[54] T. Laurell, F. Petersson, and A. Nilsson, Chip integrated strategies for acous- tic separation and manipulation of cells and particles, Chem. Soc. Rev., vol. 36, pp. 492506, 2007. (Cited on page19.)
[55] T. Kozuka, K. Yasui, S. ichi Hatanaka, T. Tuziuti, K. Suzuki, and A. Towata, Manipulation of particles in a microchannel with various geometric spaces using ultrasound, Japanese Journal of Applied Physics, vol. 50, no. 7, p. 07HE27, 2011. (Cited on page19.)
[56] R. Duraiswami, S. Prabhukumar, and G. L. Chahine, Bubble counting using an inverse acoustic scattering method, The Journal of the Acoustical Society of America, vol. 104, no. 5, pp. 26992717, 1998. (Cited on page19.)
[57] A. Haake, A. Neild, G. Radziwill, and J. Dual, Positioning, displacement, and localization of cells using ultrasonic forces, Biotechnology and Bioengineering, vol. 92, no. 1, pp. 814, 2005. (Cited on page19.)
[58] A. Haake, A. Neild, D.-H. Kim, J.-E. Ihm, Y. Sun, J. Dual, and B.-K. Ju, Ma- nipulation of cells using an ultrasonic pressure eld, Ultrasound in Medicine
& Biology, vol. 31, no. 6, pp. 857 864, 2005. (Cited on page19.)
[59] M. Hill and R. J. Wood, Modelling in the design of a ow-through ultrasonic separator, Ultrasonics, vol. 38, no. 18, pp. 662 665, 2000. (Cited on page20.) [60] M. Hill, Y. Shen, and J. J. Hawkes, Modelling of layered resonators for ultra- sonic separation, Ultrasonics, vol. 40, no. 18, pp. 385 392, 2002. (Cited on page20.)
[61] C. R. P. Courtney, C.-K. Ong, B. W. Drinkwater, P. D. Wilcox, C. Demore, S. Cochran, P. Glynne-Jones, and M. Hill, Manipulation of microparticles us- ing phase-controllable ultrasonic standing waves, The Journal of the Acous- tical Society of America, vol. 128, no. 4, pp. EL195EL199, 2010. (Cited on page20.)
[62] C. R. P. Courtney, C.-K. Ong, B. W. Drinkwater, A. L. Bernassau, P. D.
Wilcox, and D. R. S. Cumming, Manipulation of particles in two dimensions using phase controllable ultrasonic standing waves, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Science, 2011. (Cited on page20.)
[63] M. Grundy, W. Bolek, W. Coakley, and E. Benes, Rapid agglutination testing in an ultrasonic standing wave, J Immunol Methods., vol. 165, pp. 4757, 1993. (Cited on pages 20 and58.)
[64] M. Grundy, K. M. WT, and C. ., Increased sensitivity of diagnostic latex agglutination tests in an ultrasonic standing wave eld., J Immunol Methods., vol. 176 (2), pp. 16977., 1994. (Cited on pages 20and 58.)
[65] J. J. Hawkes and W. Coakley, A continuous ow ultrasonic cell-ltering method, Enzyme and Microbial Technology, vol. 19, no. 1, pp. 57 62, 1996.
(Cited on pages 20and 58.)
[66] S. Gupta, D. L. Feke, and I. Manas-Zloczower, Fractionation of mixed partic- ulate solids according to compressibility using ultrasonic standing wave elds, Chemical Engineering Science, vol. 50, no. 20, pp. 3275 3284, 1995. (Cited on page20.)
[67] P. B. Muller, M. Rossi, A. G. Marín, R. Barnkob, P. Augustsson, T. Laurell, C. J. Kähler, and H. Bruus, Ultrasound-induced acoustophoretic motion of microparticles in three dimensions, Phys. Rev. E, vol. 88, p. 023006, Aug 2013. (Cited on page20.)
[68] R. Barnkob, P. Augustsson, T. Laurell, and H. Bruus, Acoustic radiation- and streaming-induced microparticle velocities determined by microparticle image velocimetry in an ultrasound symmetry plane, Phys. Rev. E, vol. 86, p. 056307, Nov 2012. (Cited on pages20 and66.)
[69] S. M. Hagsater, T. G. Jensen, H. Bruus, and J. P. Kutter, Acoustic resonances in microuidic chips: full-image micro-piv experiments and numerical simula- tions, Lab Chip, vol. 7, pp. 13361344, 2007. (Cited on pages21and 77.) [70] S. M. Hagsater, A. Lenshof, P. Skafte-Pedersen, J. P. Kutter, T. Laurell, and
H. Bruus, Acoustic resonances in straight micro channels: Beyond the 1d- approximation, Lab Chip, vol. 8, pp. 11781184, 2008. (Cited on page21.) [71] Y. Shin, J. Chung, N. Kladias, E. Panides, G. A. Domoto, and C. P. Grig-
oropoulos, Compressible ow of liquid in a standing wave tube, J. Fluid Mech., vol. 536, pp. 321345, 2005. (Cited on page21.)
[72] O. Manneberg, S. M. Hagsater, J. Svennebring, H. Hertz, J. Kutter, H. Bruus, and M. Wiklund, Spatial connement of ultrasonic force elds in microuidic channels., Ultrasonics, vol. 49, pp. 112119, 2009. (Cited on page21.) [73] O. Manneberg, B. Vanherberghen, J. Svennebring, H. M. Hertz, B. Önfelt,
and M. Wiklund, A three-dimensional ultrasonic cage for characterization of individual cells, Applied Physics Letters, vol. 93, no. 6, pp. , 2008. (Cited on pages21and 58.)
[74] B. Vanherberghen, O. Manneberg, A. Christakou, T. Frisk, M. Ohlin, H. M.
Hertz, B. Onfelt, and M. Wiklund, Ultrasound-controlled cell aggregation in a multi-well chip, Lab Chip, vol. 10, pp. 27272732, 2010. (Cited on pages21 and58.)
[75] P. Brodeur, Motion of uid-suspended bres in a standing wave eld, Ultra- sonics, vol. 29, pp. 302307, 1991. (Cited on page21.)
[76] F. Petersson, A. Nilsson, H. Jonsson, and T. Laurell, Carrier medium ex- change through ultrasonic particle switching in microuidic channels, Anal Chem, vol. 77, pp. 12161221, 2005. (Cited on page21.)
[77] M. Hoyos and A. Castro, Controlling the acoustic streaming by pulsed ultra- sounds, Ultrasonics, vol. 53, no. 1, pp. 70 76, 2013. (Cited on page21.) [78] A. Lenshof, C. Magnusson, and T. Laurell, Acoustouidics 8: Applications of
acoustophoresis in continuous ow microsystems, Lab Chip, vol. 12, pp. 1210 1223, 2012. (Cited on page21.)
[79] M. Ward, P. Turner, M. DeJohn, and G. Kaduchak, Fundamentals of Acoustic Cytometry, ch. Curr. Protoc. Cytom. 49, pp. 1.22.11.22.12. John Wiley &
Sons, Inc., 2001. (Cited on page 21.)
[80] G. R. Goddard, C. K. Sanders, J. C. Martin, G. Kaduchak, and S. W. Graves, Analytical performance of an ultrasonic particle focusing ow cytometer, Anal Chem, vol. 79, pp. 87406, 2007. (Cited on page 21.)
[81] G. Goddard, J. C. Martin, S. W. Graves, and G. Kaduchak, Ultrasonic particle-concentration for sheathless focusing of particles for analysis in a ow cytometer, Cytometry Part A, vol. 69A, no. 2, pp. 6674, 2006. (Cited on page21.)
[82] N. M. Jesu`s-Pe´rez and B. H. Lapizco-Encinas, Dielectrophoretic monitoring of microorganisms in environmental applications, Electrophoresis, vol. 32, no. 17, pp. 23312357, 2011. (Cited on page21.)
[83] S. Burgarella, S. Merlo, B. Dell'Anna, G. Zarola, and M. Bianchessi, A mod- ular micro-uidic platform for cells handling by dielectrophoresis, Microelec- tronic Engineering, vol. 87, no. 11, pp. 2124 2133, 2010. (Cited on page21.) [84] N. Demierre, T. Braschler, R. Muller, and P. Renaud, Focusing and continu- ous separation of cells in a microuidic device using lateral dielectrophoresis, Sensors and Actuators B: Chemical, vol. 132, no. 2, pp. 388 396, 2008. (Cited on page 21.)
[85] O. Hofmann, G. Voirin, P. Niedermann, and A. Manz, Three-dimensional microuidic connement for ecient sample delivery to biosensor surfaces.
application to immunoassays on planar optical waveguides, Analytical Chem- istry, vol. 74, no. 20, pp. 52435250, 2002. (Cited on page 22.)
[86] G. Justin, M. Nasir, and F. Ligler, Hydrodynamic and electrical considera- tions in the design of a four-electrode impedance-based microuidic device, Analytical and Bioanalytical Chemistry, vol. 400, no. 5, pp. 13471358, 2011.
(Cited on page22.)
[87] Z. Liu, F. Huang, J. Du, W. Shu, H. Feng, X. Xu, and Y. Chen, Rapid isolation of cancer cells using microuidic deterministic lateral displacement structure, Biomicrouidics, vol. 7, no. 1, pp. , 2013. (Cited on page 22.)
[88] A. Luque, F. Perdigones, J. Estevá, J. Montserrat, A. Gan˜án-Calvo, and J. M.
Quero, Reduction of droplet-size dispersion in parallel ow-focusing microde- vices using a passive method, Journal of Micromechanics and Microengineer- ing, vol. 19, no. 4, p. 045029, 2009. (Cited on page 22.)
[89] T. Schneider, G. H. Chapman, and U. O. Häfeli, Eects of chemical and physical parameters in the generation of microspheres by hydrodynamic ow focusing, Colloids and Surfaces B: Biointerfaces, vol. 87, no. 2, pp. 361 368, 2011. (Cited on page22.)
[90] T. Schneider, H. Zhao, J. K. Jackson, G. H. Chapman, J. Dykes, and U. O.
Häfeli, Use of hydrodynamic ow focusing for the generation of biodegrad- able camptothecin-loaded polymer microspheres, Journal of Pharmaceutical Sciences, vol. 97, no. 11, pp. 49434954, 2008. (Cited on page22.)
[91] R. Karnik, F. Gu, P. Basto, C. Cannizzaro, L. Dean, W. Kyei-Manu, R. Langer, and O. C. Farokhzad, Microuidic platform for controlled syn- thesis of polymeric nanoparticles, Nano Letters, vol. 8, no. 9, pp. 29062912, 2008. PMID: 18656990. (Cited on page22.)
[92] H. Y. Park, X. Qiu, E. Rhoades, J. Korlach, L. W. Kwok, W. R. Zipfel, W. W.
Webb, and L. Pollack, Achieving uniform mixing in a microuidic device:
Hydrodynamic focusing prior to mixing, Analytical Chemistry, vol. 78, no. 13, pp. 44654473, 2006. PMID: 16808455. (Cited on page22.)
[93] N.-T. Nguyen and X. Huang, Mixing in microchannels based on hydrody- namic focusing and time-interleaved segmentation: modelling and experi- ment, Lab Chip, vol. 5, pp. 13201326, 2005. (Cited on page22.)
[94] T. Cubaud and T. G. Mason, Formation of miscible uid microstructures by hydrodynamic focusing in plane geometries, Phys. Rev. E, vol. 78, p. 056308, Nov 2008. (Cited on page22.)
[95] M. Masaeli, E. Sollier, H. Amini, W. Mao, K. Camacho, N. Doshi, S. Mi- tragotri, A. Alexeev, and D. Di Carlo, Continuous inertial focusing and sepa- ration of particles by shape, Phys. Rev. X, vol. 2, p. 031017, Sep 2012. (Cited on page23.)
[96] H.-T. Chen and Y.-N. Wang, Optical microow cytometer for particle count- ing, sizing and uorescence detection, Microuidics and Nanouidics, vol. 6, no. 4, pp. 529537, 2009. (Cited on page23.)
[97] Y. AS and H. WH., Hydrodynamic focusing investigation in a micro-ow cy- tometer., Biomed Microdevices, vol. 9, pp. 113122., 2007. (Cited on page23.) [98] M. Rosenauer, W. Buchegger, I. Finoulst, P. Verhaert, and M. Vellekoop, Miniaturized ow cytometer with 3d hydrodynamic particle focusing and
integrated optical elements applying silicon photodiodes, Microuidics and Nanouidics, vol. 10, no. 4, pp. 761771, 2011. (Cited on page 23.)
[99] N. Sundararajan, M. Pio, L. P. Lee, and A. Berlin, Three-dimensional hydro- dynamic focusing in polydimethylsiloxane (pdms) microchannels, Microelec- tromechanical Systems, Journal of, vol. 13, no. 4, pp. 559567, 2004. (Cited on page 23.)
[100] D. S. Kim, D. S. D. Kim, K. Han, and W. Yang, An ecient 3-dimensional hydrodynamic focusing microuidic device by means of locally increased as- pect ratio, Microelectron. Eng., vol. 86, pp. 13431346, Apr. 2009. (Cited on page23.)
[101] M. Kennedy, S. Stelick, S. Perkins, L. Cao, and C. Batt, Hydrodynamic focusing with a microlithographic manifold: controlling the vertical position of a focused sample, Microuidics and Nanouidics, vol. 7, no. 4, pp. 569578, 2009. (Cited on page 23.)
[102] C.-C. Chang, Z.-X. Huang, and R.-J. Yang, Three-dimensional hydrodynamic focusing in two-layer polydimethylsiloxane (pdms) microchannels, Journal of Micromechanics and Microengineering, vol. 17, no. 8, p. 1479, 2007. (Cited on page 23.)
[103] P. A. d. G. Josep M. Gasol, Using ow cytometry for counting natural plank- tonic bacteria and understanding the structure of planktonic bacterial com- munities, Sci. Mar., vol. 64(2), pp. 197224, 2000. (Cited on page23.) [104] J. Zhou and I. Papautsky, Fundamentals of inertial focusing in microchan-
nels, Lab Chip, vol. 13, pp. 11211132, 2013. (Cited on page 23.)
[105] J. Zhou, P. V. Giridhar, S. Kasper, and I. Papautsky, Modulation of aspect ratio for complete separation in an inertial microuidic channel, Lab Chip, vol. 13, pp. 19191929, 2013. (Cited on page 23.)
[106] J. Hultström, O. Manneberg, K. Dopf, H. Hertz, H. Brismar, and M. Wiklund, Proliferation and viability of adherent cells manipulated by standing-wave ultrasound in a microuidic chip, Ultrasound in medicine & biology, vol. 33, pp. 145151, 2007. (Cited on page25.)
[107] H. M. Wyss, D. L. Blair, J. F. Morris, H. A. Stone, and D. A. Weitz, Mecha- nism for clogging of microchannels., Physical review. E, Statistical, nonlinear, and soft matter physics, vol. 74, no. 061402, 2006. (Cited on page 25.) [108] F. Dubois, M.-L. N. Requena, C. Minetti, O. Monnom, and E. Istasse, Partial
spatial coherence eects in digital holographic microscopy with a laser source, Appl. Opt., vol. 43, pp. 11311139, Feb 2004. (Cited on pages 26and 34.) [109] N. T. Clemens, Encyclopedia of Imaging Science and Technology, ch. Flow
Imaging, pp. 390419. John Wiley & Sons, Inc., 2002. (Cited on page 31.)
[110] C. Cierpka and C. Kähler, Particle imaging techniques for volumetric three- component (3d3c) velocity measurements in microuidics, Journal of Visu- alization, vol. 15, no. 1, pp. 131, 2012. (Cited on pages31 and 32.)
[111] T. Kreis, Digital holographic interference-phase measurement using the fourier-transform method, J. Opt. Soc. Am. A, vol. 3, pp. 847855, 1986.
(Cited on pages33 and 36.)
[112] F. Dubois, N. Callens, C. Yourassowsky, M. Hoyos, P. Kurowsky, and O. Mon- nom, Digital holographic microscopy with reduced spatial coherence for three- dimensional particle ows analysis, Appl. Opt, vol. 45, pp. 864871, 2006.
(Cited on page33.)
[113] M. Takeda, H. Ina, and S. Kobayashi, Fourier-transform method of fringe- pattern analysis for computer-based topography and interferometry, J. Opt.
Soc. Am., vol. 72, pp. 156160, Jan 1982. (Cited on pages33 and36.) [114] T. Zhang and I. Yamaguchi, Three-dimensional microscopy with phase-
shifting digital holography, Opt. Lett., vol. 23, pp. 12211223, 1998. (Cited on page33.)
[115] M. Sebesta and M. Gustafsson, Object characterization with refractometric digital fourier holography, Opt. Lett., vol. 30, pp. 471473, 2005. (Cited on pages33 and34.)
[116] G. Popescu, L. Deores, J. Vaughan, K. Badizadegan, H. Iwai, R. Dasari, and M. Feld, Fourier phase microscopy for investigation of biological structures and dynamics, Opt. Lett., vol. 29, pp. 25032505, 2004. (Cited on page34.) [117] J. Garcia-Sucerquia, W. Xu, S. Jericho, P. Klages, M. Jericho, and H. Kreuzer, Digital in-line holographic microscopy, Appl. Opt., vol. 45, pp. 836850, 2006. (Cited on page34.)
[118] L. Yu, S. Mohanty, J. Zhang, S. Genc, M. Kim, M. Berns, and Z. Chen, Digital holographic microscopy for quantitative cell dynamic evaluation during laser microsurgery, Appl. Opt., vol. 17, pp. 1203112038, 2009. (Cited on page34.) [119] F. Dubois, C. Yourassowsky, O. Monnon, J.-C. Legros, O. Debeir, P. V.
Ham, R. Kiss, and C. Decaestecker, Digital holographic microscopy for three- dimensional dynamic analysis of in vitro cancer cell migration, J. Biomed.
Opt., vol. 11, p. 054032, 2006. (Cited on page34.)
[120] M. Gustafsson and M. Sebesta, Refractometry of microscopic objects with digital holography, Appl. Opt., vol. 43, pp. 47964801, 2005. (Cited on page34.)
[121] D. Carl, B. Kemper, G. Wernicke, and G. von Bally, Parameter-optimized digital holographic microscope for high-resolution living-cell analysis, Appl.
Opt., vol. 43, pp. 65366544, 2004. (Cited on page34.)
[122] N. Warnasooriya, F. Joud, P. Bun, G. Tessier, M. Coppey-Moisan, P. Des- biolles, M. Atlan, M. Abboud, and M. Gross, Imaging gold nanoparticles in living cell environments using heterodyne digital holographic microscopy, Opt. Express, vol. 18, pp. 32643273, 2010. (Cited on page34.)
[123] B. Kemper and G. von Bally, Digital holographic microscopy for live cell applications and technical inspection, Appl. Opt., vol. 47, pp. A52A61, 2008.
(Cited on page34.)
[124] F. Dubois, O. Debeir, R. Kiss, C. Decaestecker, P. Van Ham, C. Youras- sowsky, O. Monnom, and J.-C. Legros, Digital holographic microscopy for the three-dimensional dynamic analysis of in vitro cancer cell migration, Journal of Biomedical Optics, vol. 11, no. 5, pp. 0540320540325, 2006. (Cited on page34.)
[125] T.-W. Su, L. Xue, and A. Ozcan, High-throughput lensfree 3d tracking of human sperms reveals rare statistics of helical trajectories, Proceedings of the National Academy of Sciences, vol. 109, pp. 1601816022, 2012. (Cited on page34.)
[126] D. Lebrun, D. Allano, L. Méès, F. Walle, F. Corbin, R. Boucheron, and D. Fré- chon, Size measurement of bubbles in a cavitation tunnel by digital in-line holography, Appl. Opt, vol. 50, pp. H1H9, 2011. (Cited on page34.) [127] D. Lebrun, A. Benkouider, S. Coëtmellec, and M. Malek, Particle eld digital
holographic reconstruction in arbitrary tilted planes, Opt. Express, vol. 11, pp. 224229, 2003. (Cited on page34.)
[128] D. Allano, M. Malek, F. Walle, F. Corbin, G. Godars, S. Coëtmellec, B. Lecordier, J.-M. Foucaut, and D. Lebrun, Three-dimensional velocity near- wall measurements by digital in-line holography : calibration and results, Appl. Opt, vol. 52, pp. A9A17, 2013. (Cited on page34.)
[129] F. C. Cheong, B. Sun, R. Dreyfus, J. Amato-Grill, K. Xiao, L. Dixon, and D. G. Grier, Flow visualization and ow cytometry with holographic video microscopy, Opt. Express, vol. 17, pp. 1307113079, Jul 2009. (Cited on page34.)
[130] N. Pandey and B. Hennelly, Fixed-point numerical-reconstruction for digital holographic microscopy, Opt. Lett., vol. 35, pp. 10761078, 2010. (Cited on page34.)
[131] C. Minetti, N. Callens, G. Coupier, T. Podgorski, and F. Dubois, Fast mea- surments of concentration proles inside deformable objects in microows with spatial coherence digital holography, Appl. Opt., vol. 45, pp. 53055314, 2008.
(Cited on pages 34and 37.)
[132] F. Dubois, O. Monnom, C. Yourassowsky, and J.-C. Legros, Pattern recogni- tion with digital holographic microscope working in partially coherent illumi- nation, Appl. Opt., vol. 41, pp. 41084119, 2002. (Cited on page34.) [133] B. Javidi, I. Moon, S. Yeom, and E. Carapezza, Three-dimensional imaging
and recognition of microorganism using single-exposure on-line (seol) digital holography, Opt. Express, vol. 13, pp. 44924506, 2005. (Cited on page34.) [134] C. D. F. El Mallahi, A.and Minetti, Automated three-dimensional detection and classication of living organisms using digital holographic microscopy with partial spatial coherent source: application to the monitoring of drinking water resources, Appl. Opt., vol. 52, pp. A68A80, Jan 2013. (Cited on page34.) [135] E. Cuche, F. Bevilacqua, and C. Depeursinge, Digital holography for quanti-
tative phase contrast imaging, Opt. Lett., vol. 24, pp. 291293, 1999. (Cited on page34.)
[136] F. Charrière, A. Marian, F. Montford, J. Kuehn, T. Colomb, E. Cuche, P. Mar- quet, and C. Depeursinge, Cell refractive index tomography by digital holo- graphic microscopy, Opt. Lett., vol. 31, pp. 178180, 2006. (Cited on page34.) [137] P. Marquet, B. Rappaz, P. J. Magistretti, E. Cuche, Y. Emery, T. Colomb, and C. Depeursinge, Digital holographic microscopy : a noninvasive contrast imaging technique allowing quantitative visualization of living cells with sub- wavelength axial accuracy, Opt. Lett., vol. 30, pp. 468470, 2005. (Cited on page34.)
[138] F. Dubois, O. Monnom, C. Yourassowsky, and J.-C. Legros, Border processing in digital holography by extension of the digital hologram and redution of the higher spatial frequencies, Appl. Opt., vol. 41, pp. 26212626, 2002. (Cited on page34.)
[139] T. Colomb, E. Cuche, F. Charrière, J. Kühn, N. Aspert, F. Monfort, P. Mar- quet, and C. Despeursinge, Automatic procedure for aberration compensation in digital holographic microscopy and applications to specimen shape compen- sation, Appl. Opt., vol. 45, pp. 851863, 2006. (Cited on page34.)
[140] F. Dubois, C. Schockaert, N. Callens, and C. Yourassowsky, Focus plane detection criteria in digital holography microscopy by amplitude analysis, Opt. Express, vol. 14, pp. 58955908, Jun 2006. (Cited on pages35 and40.) [141] C. Perfetti, C. Iorio, A. El Mallahi, and F. Dubois, Quantitative analysis of 3d
hydrodynamic focusing of microparticles by digital holographic microscopy, Experiments in Fluids, vol. 55, no. 2, pp. 112, 2014. (Cited on page41.) [142] C. Perfetti, C. Iorio, and F. Dubois, 3d focusing of micro-particles by sheath
ow warping, Proceedings - ICNMM, 2013. (Cited on page41.)
[143] Z. Wu and N.-T. Nguyen, Hydrodynamic focusing in microchannels under consideration of diusive dispersion: theories and experiments, Sensors and Actuators B: Chemical, vol. 107, no. 2, pp. 965 974, 2005. (Cited on page42.) [144] M. Nasir, D. Mott, M. Kennedy, J. Golden, and F. Ligler, Parameters af- fecting the shape of a hydrodynamically focused stream, Microuidics and Nanouidics, vol. 11, no. 2, pp. 119128, 2011. (Cited on page 42.)
[145] P. Lammers, J. Jovanovic, and A. Delgado, Persistence of turbulent ow in microchannels at very low reynolds number, Microuidics and Nanouidics, vol. 9, no. 1, pp. 116, 2011. (Cited on page43.)
[146] i. Fluent Inc c⃝, FLUENT 6.3 User's Book, vol. 12. Fluent, 2006. (Cited on page43.)
[147] W. Szablewski, B. E. Launder, and D. B. Spalding, Mathematical models of turbulence, ZAMM - Journal of Applied Mathematics and Mechanics / Zeitschrift fur Angewandte Mathematik und Mechanik, vol. 53, no. 6, pp. 424 424, 1973. (Cited on page 44.)
[148] A. Wol, I. R. Perch-Nielsen, U. D. Larsen, P. Friis, G. Goranovic, C. R.
Poulsen, J. P. Kutter, and P. Telleman, Integrating advanced functionality in a microfabricated high-throughput uorescent-activated cell sorter, Lab Chip, vol. 3, pp. 2227, 2003. (Cited on page 46.)
[149] J. Friend and L. Y. Yeo, Microscale acoustouidics: Microuidics driven via acoustics and ultrasonics, Rev. Mod. Phys., vol. 83, pp. 647704, Jun 2011.
(Cited on page60.)
[150] T. Kamakura, K. Yasuda, and Y. Kumamoto, Unied description of second- order phenomena in sound waves, Electronics and Communications in Japan (Part III: Fundamental Electronic Science), vol. 82, no. 2, pp. 7682, 1999.
(Cited on pages 61and 106.)
[151] H. Mitome, The mechanism of generation of acoustic streaming, Electronics and Communications in Japan (Part III: Fundamental Electronic Science), vol. 81, no. 10, pp. 18, 1998. (Cited on page61.)
[152] H. Azhari, Appendix A: Typical Acoustic Properties of Tissues, pp. 313314.
John Wiley & Sons, Inc., 2010. (Cited on pages63 and 138.)
[153] M. A. H. Weiser, R. E. Apfel, and E. A. Neppiras, Interparticle forces on red cells in a standing wave eld, Acta Acustica united with Acustica, vol. 56, no. 2, pp. 114119, 1984-10-01T00:00:00. (Cited on page 64.)
[154] L. A. Crum, Bjerknes forces on bubbles in a stationary sound eld, J. Acoust.
Soc. Am., vol. 57, pp. 13631370, 1975. (Cited on page65.)
[155] A. Hancock, Observation of Forces on Microparticles in Acoustic Standing Waves. University of California, Davis, 2001. (Cited on page65.)
[156] J. F. Spengler, W. T. Coakley, and K. T. Christensen, Microstreaming eects on particle concentration in an ultrasonic standing wave, AIChE Journal, vol. 49, no. 11, pp. 27732782, 2003. (Cited on page66.)
[157] M. F. Hamilton, Y. A. Ilinskii, and E. A. Zabolotskaya, Acoustic streaming generated by standing waves in two-dimensional channels of arbitrary width, The Journal of the Acoustical Society of America, vol. 113, no. 1, pp. 153160, 2003. (Cited on page66.)
[158] H. Bruus, Acoustouidics 7: The acoustic radiation force on small particles., Lab on a chip, vol. 12, pp. 14730189, 2012. (Cited on page 66.)
[159] H. Bruus, Theoretical Microuidics. Oxford Master Series in Physics, OUP Oxford, 2008. (Cited on page72.)
[160] C. Iorio, C. Perfetti, V. Vancauwenberghe, and F. Dubois, 3d focusing of mi- croparticles by acoustic standing waves in a ow through channel, Proceedings - ICNMM, 2013. (Cited on page75.)
[161] M. M. Gibson and B. E. Launder, Ground eects on pressure uctuations in the atmospheric boundary layer, Journal of Fluid Mechanics, vol. 86, pp. 491 511, June 1978. (Cited on page 100.)
[162] C.-T. Chen, R. A. Fine, and F. J. Millero, The equation of state of pure water determined from sound speeds, The Journal of Chemical Physics, vol. 66, no. 5, pp. 21422144, 1977. (Cited on page 103.)
