[1] D HUH, B D MATTHEWS, A MAMMOTO et al. Reconstituting organ-level lung functions on a chip. Science, 328, 1662-1668(2010).

[2] C N HALL, C REYNELL, B GESSLEIN et al. Capillary pericytes regulate cerebral blood flow in health and disease. Nature, 508, 55-60(2014).

[3] P O'HERRON, P Y CHHATBAR, M LEVY et al. Neural correlates of single-vessel haemodynamic responses in vivo. Nature, 534, 378-382(2016).

[4] W ZHAO, H YU, Y WEN et al. Real-time red blood cell counting and osmolarity analysis using a photoacoustic-based microfluidic system. Lab on a Chip, 21, 2586-2593(2021).

[5] B M CASTELLANO, A M THELEN, O MOLDAVSKI et al. Lysosomal cholesterol activates mTORC1 via an SLC38A9-Niemann-Pick C1 signaling complex. Science, 355, 1306-1311(2017).

[6] C XU, P LU, T M GAMAL EL-DIN et al. Computational design of transmembrane pores. Nature, 585, 129-134(2020).

[7] P SKOPINTSEV, D EHRENBERG, T WEINERT et al. Femtosecond-to-millisecond structural changes in a light-driven sodium pump. Nature, 583, 314-318(2020).

[8] C D M CAMPOS, S S T GAMAGE, J M JACKSON et al. Microfluidic-based solid phase extraction of cell free DNA. Lab on a Chip, 18, 3459-3470(2018).

[9] M RAHMAN, M A STOTT, M HARRINGTON et al. On demand delivery and analysis of single molecules on a programmable nanopore-optofluidic device. Nature communications, 10, 1-7(2019).

[10] R ZHOU, C WANG, Y HUANG et al. Label-free terahertz microfluidic biosensor for sensitive DNA detection using graphene-metasurface hybrid structures. Biosensors and Bioelectronics, 188, 113336(2021).

[11] B BRUIJNS, R TIGGELAAR, H GARDENIERS. A microfluidic approach for biosensing DNA within forensics. Applied Sciences, 10, 7067(2020).

[12] J ZHANG, Z CHEN, Y ZHANG et al. Construction of a high fidelity epidermis-on-a-chip for scalable in vitro irritation evaluation. Lab on a Chip, 21, 3804-3818(2021).

[13] A J BROWN, N A BRUNELLI, K EUM et al. Interfacial microfluidic processing of metal-organic framework hollow fiber membranes. Science, 345, 72-75(2014).

[14] M AMINIAN, F BERNARDI, R CAMASSA et al. How boundaries shape chemical delivery in microfluidics. Science, 354, 1252-1256(2016).

[15] E K SACKMANN, A L FULTON, D J BEEBE. The present and future role of microfluidics in biomedical research. Nature, 507, 181-189(2014).

[16] T H SHIN, M KIM, C O SUNG et al. A one-stop microfluidic-based lung cancer organoid culture platform for testing drug sensitivity. Lab on a Chip, 19, 2854-2865(2019).

[17] J KOMEN, E Y WESTERBEEK, R W KOLKMAN et al. Controlled pharmacokinetic anti-cancer drug concentration profiles lead to growth inhibition of colorectal cancer cells in a microfluidic device. Lab on a Chip, 20, 3167-3178(2020).

[18] J ZHAI, C LI, H LI et al. Cancer drug screening with an on-chip multi-drug dispenser in digital microfluidics. Lab on a Chip, 21, 4749-4759(2021).

[19] A J DEMELLO. Control and detection of chemical reactions in microfluidic systems. Nature, 442, 394-402(2006).

[20] H KIM, K I MIN, K INOUE et al. Submillisecond organic synthesis: outpacing Fries rearrangement through microfluidic rapid mixing. Science, 352, 691-694(2016).

[21] N BUFFI, S BEGGAH, F TRUFFER et al. An automated microreactor for semi-continuous biosensor measurements. Lab on a Chip, 16, 1383-1392(2016).

[22] Y LIU, X JIANG. Why microfluidics？Merits and trends in chemical synthesis. Lab on a Chip, 17, 3960-3978(2017).

[23] S BASU, A MIGLANI. Combustion and heat transfer characteristics of nanofluid fuel droplets: a short review. International Journal of Heat and Mass Transfer, 96, 482-503(2016).

[24] S MUKHERJEE, P C MISHRA, S K S PARASHAR et al. Role of temperature on thermal conductivity of nanofluids: a brief literature review. Heat and Mass Transfer, 52, 2575-2585(2016).

[25] A P SINGH, V R KISHORE, Y YOON et al. Effect of wall thermal boundary conditions on flame dynamics of CH4-air and H2-air mixtures in straight microtubes. Combustion Science and Technology, 189, 150-168(2017).

[26] Zhanhua LI, Xu ZHENG. The problems and progress in the experimental study of micro/nano-scale flow. Journal of Experiments in Fluid Mechanics, 28, 1-11(2014).

[27] M GAD-EL-HAK. The fluid mechanics of microdevices—the freeman scholar lecture. Journal of Fluids Engineering, 121, 5-33(1999).

[29] R J ADRIAN. Twenty years of particle image velocimetry. Experiments in Fluids, 39, 159-169(2005).

[30] J WESTERWEEL, P F GEELHOED, R LINDKEN. Single-pixel resolution ensemble correlation for micro-PIV applications. Experiments in Fluids, 37, 375-384(2004).

[31] Shengze CAI, Chao XU, Qi GAO et al. Particle image velocimetry based on a deep neural network. Acta Aerodynamica Sinica, 37, 455-461(2019).

[32] Zeyu GAO, Xinyang LI, Hongwei YE. Aberration correction for flow velocity measurements using deep convolutional neural networks. Infrared and Laser Engineering, 49, 9-18(2020).

[33] M G OLSEN, R J ADRIAN. Brownian motion and correlation in particle image velocimetry. Optics & Laser Technology, 32, 621-627(2000).

[34] Feng SHEN, Zhaomiao LIU. Review on the micro-particle image velocimetry technique and applications. Journal of Mechanical Engineering, 48, 155-168(2012).

[35] J WESTERWEEL, G E ELSINGA, R J ADRIAN. Particle image velocimetry for complex and turbulent flows. Annual Review of Fluid Mechanics, 45, 409-436(2013).

[36] R J ADRIAN. Scattering particle characteristics and their effect on pulsed laser measurements of fluid flow: speckle velocimetry vs particle image velocimetry. Applied Optics, 23, 1690-1691(1984).

[37] J G SANTIAGO, S T WERELEY, C D MEINHART et al. A particle image velocimetry system for microfluidics. Experiments in Fluids, 25, 316-319(1998).

[38] S T WERELEY, C D MEINHART. Recent advances in micro-particle image velocimetry. Annual Review of Fluid Mechanics, 42, 557-576(2010).

[39] S J WILLIAMS, C PARK, S T WERELEY. Advances and applications on microfluidic velocimetry techniques. Microfluidics and Nanofluidics, 8, 709-726(2010).

[40] R J ADRIAN. Particle-imaging techniques for experimental fluid mechanics. Annual Review of Fluid Mechanics, 23, 261-304(1991).

[41] U MIENER, T HELMERS, R LINDKEN et al. PIV measurement of the 3D velocity distribution of Taylor droplets moving in a square horizontal channel. Experiments in Fluids, 61, 125(2020).

[42] M OISHI, H KINOSHITA, T FUJII et al. Phase-locked confocal micro-PIV measurement for 3D flow structure of transient droplet formation mechanism in T-shaped microjunction. Measurement Science and Technology, 29, 115204(2018).

[43] M ROSSI, R SEGURA, C CIERPKA et al. On the effect of particle image intensity and image preprocessing on the depth of correlation in micro-PIV. Experiments in Fluids, 52, 1063-1075(2012).

[44] H KINOSHITA, S KANEDA, T FUJII et al. Three-dimensional measurement and visualization of internal flow of a moving droplet using confocal micro-PIV. Lab on a Chip, 7, 338-346(2007).

[45] S A KLEIN, J D POSNER. Improvement in two-frame correlations by confocal microscopy for temporally resolved micro particle imaging velocimetry. Measurement Science and Technology, 21, 105409(2010).

[46] J JAMES, C M BROWN. Any way you slice it-acomparison of confocal microscopy techniques. Journal of Biomolecular Techniques, 26, 54-65(2015).

[48] J WESTERWEEL. Efficient detection of spurious vectors in particle image velocimetry data. Experiments in Fluids, 16, 236-247(1994).

[49] Dexin SUN, Zhihao SUN, Zhiwei SONG et al. Experimental study on the flow characteristics of electrohydrodynamic plumes of dielectric liquid. Scientia Sinica Technologica, 50, 983-996(2020).

[50] W ZHAO, F YANG, J KHAN et al. Measurement of velocity fluctuations in microfluidics with simultaneously ultrahigh spatial and temporal resolution. Experiments in Fluids, 57, 11(2015).

[51] F ROBBEN, R K CHENG, M M POPOVICH et al. Associating particle tracking with laser fringe anemometry. Journal of Physics E: Scientific Instruments, 13, 315(1980).

[52] P CORNIC, B LECLAIRE, F CHAMPAGNAT et al. Double-frame tomographic PTV at high seeding densities. Experiments in Fluids, 61, 23(2020).

[53] D GALLO, U GÜLAN, A DI STEFANO et al. Analysis of thoracic aorta hemodynamics using 3D particle tracking velocimetry and computational fluid dynamics. Journal of Biomechanics, 47, 3149-3155(2014).

[54] G ERGIN, B W BO, N F GADE-NIELSEN. A review of planar PIV systems and image processing tools for Lab-On-Chip microfluidics. Sensors, 18, 3090(2018).

[55] Y WU, X WU, L YAO et al. Simultaneous measurement of 3D velocity and 2D rotation of irregular particle with digital holographic particle tracking velocimetry. Powder Technology, 284, 371-378(2015).

[56] W D FULLMER, J E HIGHAM, C Q LAMARCHE et al. Comparison of velocimetry methods for horizontal air jets in a semicircular fluidized bed of Geldart Group D particles. Powder Technology, 359, 323-330(2020).

[57] F PEREIRA, H STÜER, E C GRAFF et al. Two-frame 3D particle tracking. Measurement Science and Technology, 17, 1680(2006).

[58] D GOLLIN, W BREVIS, E T BOWMAN et al. Performance of PIV and PTV for granular flow measurements. Granular Matter, 19, 1-16(2017).

[59] C J KHLER, S SCHARNOWSKI, C CIERPKA. On the uncertainty of digital PIV and PTV near walls. Experiments in Fluids, 52, 1641-1656(2012).

[60] D SCHANZ, S GESEMANN, A SCHRDER. Shake-the-box: Lagrangian particle tracking at high particle image densities. Experiments in Fluids, 57, 70(2016).

[61] M PEARCE, Z SPARROW, T R MABOTE et al. StoBEST: an efficient methodology for increased spatial resolution in two-component molecular tagging velocimetry. Measurement Science and Technology, 32, 035302(2021).

[62] W WATER, N DAM. How to find patterns written in turbulent air. Experiments in Fluids, 54, 1574(2013).

[63] A D BORDOLOI, A A MARTINEZ, K PRESTRIDGE. Relaxation drag history of shock accelerated microparticles. Journal of Fluid Mechanics, 823, 10.1017(2017).

[64] J J CHARONKO, D FRATANTONIO, J M MAYER et al. Windowed Fourier transform and cross-correlation algorithms for molecular tagging velocimetry. Measurement Science and Technology, 31, 074007(2020).

[65] F LI, H ZHANG, B BAI. A review of molecular tagging measurement technique. Measurement, 171, 108790(2020).

[66] R B MILES, J J CONNORS, E C MARKOVITZ et al. Instantaneous profiles and turbulence statistics of supersonic free shear layers by Raman excitation plus laser-induced electronic fluorescence (Relief) velocity tagging of oxygen. Experiments in Fluids, 8, 17-24(1989).

[67] W R LEMPERT, P RONNEY, K MAGEE et al. Flow tagging velocimetry in incompressible flow using photo-activated nonintrusive tracking of molecular motion (PHANTOMM). Experiments in Fluids, 18, 249-257(1995).

[68] T HANDA, K MII, T SAKURAI et al. Study on supersonic rectangular microjets using molecular tagging velocimetry. Experiments in Fluids, 55, 1725(2014).

[69] J R ELSNAB, D MAYNES, J C KLEWICKI et al. Mean flow structure in high aspect ratio microchannel flows. Experimental Thermal and Fluid Science, 34, 1077-1088(2010).

[70] F SAMOUDA, S COLIN, J J BRANDNER et al. Micro molecular tagging velocimetry for analysis of gas flows in mini and micro systems. Microsystem Technologies, 21, 527-537(2015).

[71] H H MOHAND, A FREZZOTTI, J J BRANDNER et al. Molecular tagging velocimetry by direct phosphorescence in gas microflows: correction of Taylor dispersion. Experimental Thermal and Fluid Science, 83, 177-190(2017).

[72] D FRATANTONIO, R C MARCOS, C BARROT et al. Velocity measurements in channel gas flows in the slip regime by means of molecular tagging velocimetry. Micromachines (Basel), 11, 1-32(2020).

[73] H SANAVANDI, S BAO, Y ZHANG et al. A cryogenic-helium pipe flow facility with unique double-line molecular tagging velocimetry capability. Review of Scientific Instruments, 91, 053901(2020).

[74] F DOMINIQUE, R C MARCOS, H H MOHAND et al. Molecular tagging velocimetry for confined rarefied gas flows: Phosphorescence emission measurements at low pressure. Experimental Thermal and Fluid Science, 99, 510-524(2018).

[75] D HUANG, E A SWANSON, C P LIN et al. Optical coherence tomography. Science, 254, 1178-1181(1991).

[76] Zehao TAN, Yunpeng FENG, Zhong WANG. Advances in measurement of optical central thickness by low coherence interferometry. Imaging Science and Photochemistry, 34, 5-14(2016).

[77] Y LI, J CHEN, Z CHEN. Advances in Doppler optical coherence tomography and angiography. Translational Biophotonics, 1, e201900005(2019).

[78] Dongxiao LU, Wenhui FANG, Yuyao LI et al. Optical coherence tomography: principles and recent developments. Chinese Optics, 13, 920-935(2020).

[79] B DONG, B PAN. Optical coherence tomography and its applications in experimental mechanics: a review. Chinese Science Bulletin, 65, 2094-2105(2020).

[81] A I KOPONEN, S HAAVISTO. Analysis of industry-related flows by optical coherence tomography—a review. KONA Powder and Particle Journal, 37, 42-63(2020).

[84] J M HALLAM, E RIGAS, T O H CHARRETT et al. 2D spatially-resolved depth-section microfluidic flow velocimetry using dual beam OCT. Micromachines, 11, 351(2020).

[85] E RIGAS, J M HALLAM, T O H CHARRETT et al. Metre-per-second microfluidic flow velocimetry with dual beam optical coherence tomography. Optics Express, 27, 23849-23863(2019).

[86] C POELMA. Measurement in opaque flows: a review of measurement techniques for dispersed multiphase flows. Review and Perspective in Mechanics, 231, 2089-2111(2020).

[87] L F GLADDEN, A J SEDERMAN. Recent advances in flow MRI. Journal of Magnetic Resonance, 229, 2-11(2013).

[88] C J ELKINS, M T ALLEY. Magnetic resonance velocimetry: applications of magnetic resonance imaging in the measurement of fluid motion. Experiments in Fluids, 43, 823-858(2007).

[89] D J BRYANT, J A PAYNE, D N FIRMIN et al. Measurement of flow with NMR imaging using a gradient pulse and phase difference technique. Journal of Computer Assisted Tomography, 8, 588-593(1984).

[90] M SADEGHI, M MIRDRIKVAND, G R PESCH et al. Full-field analysis of gas flow within open-cell foams: comparison of micro-computed tomography-based CFD simulations with experimental magnetic resonance flow mapping data. Experiments in Fluids, 61, 124(2020).

[91] K JOHN, S JAHANGIR, U GAWANDALKAR et al. Magnetic resonance velocimetry in high-speed turbulent flows: sources of measurement errors and a new approach for higher accuracy. Experiments in Fluids, 61, 1-17(2020).

[92] G R WANG. Laser induced fluorescence photobleaching anemometer for microfluidic devices. Lab on a Chip, 5, 450-456(2005).

[93] C F KUANG, G R WANG. A novel far-field nanoscopicvelocimetry for nanofluidics. Lab on a Chip, 10, 240-245(2010).

[94] C F KUANG, R QIAO, G R WANG. Ultrafast measurement of transient electroosmotic flow in microfluidics. Microfluidics and Nanofluidics, 11, 353-358(2011).

[95] W ZHAO, X LIU, F YANG et al. Study of oscillating electroosmotic flows with high temporal and spatial resolution. Analytical Chemistry, 90, 1652-1659(2018).

[96] W ZHAO, F YANG, J KHAN et al. Corrections on LIFPA velocity measurements in microchannel with moderate velocity fluctuations. Experiments in Fluids, 56, 39(2015).

[97] Y C WANG, W ZHAO, Z Y HU et al. Parametric study of the emission spectra and photobleaching time constants of a fluorescent dye in laser induced fluorescence photobleaching anemometer (LIFPA) applications. Experiments in Fluids, 60, 106(2019).

[98] G R WANG, H E FIEDLER. On high spatial resolution scalar measurement with LIF. Experiments in Fluids, 29, 265-274(2000).

[99] S W HELL, J WICHMANN. Breaking the diffraction resolution limit by stimulated emission: stimulated-emission-depletion fluorescence microscopy. Optics Letters, 19, 780-782(1994).

[100] G R WANG, F YANG, W ZHAO. There can be turbulence in microfluidics at low Reynolds number. Lab on a Chip, 14, 1452-1458(2014).

[101] G R WANG, F YANG, W ZHAO. Microelectrokinetic turbulence in microfluidics at low Reynolds number. Physical Review E, 93, 013106(2016).

[102] Y CHEN, S S MENG, K G WANG et al. Numerical simulation of the photobleaching process in laser-induced fluorescence photobleaching anemometer. Micromachines, 12, 1592(2021).

[103] J F PINTON, R LABBÉ. Correction to the Taylor hypothesis in swirling flows. Journal De Physique II, 4, 1461-1468(1994).

[104] C F KUANG, W ZHAO, F YANG et al. Measuring flow velocity distribution in microchannels using molecular tracers. Microfluidics and Nanofluidics, 7, 509-517(2009).

[105] C F KUANG, F YANG, W ZHAO et al. Study of the rise time in electroosmotic flow within a microcapillary. Analytical Chemistry, 81, 6590-6595(2009).

[106] G R WANG, F YANG, W ZHAO et al. On micro-electrokinetic scalar turbulence in microfluidics at a low Reynolds number. Lab on a Chip, 16, 1030-1038(2016).

[107] A N KOLMOGOROV. The local structure of turbulence in incompressible viscous fluid for very large Reynolds' numbers. AkademiiaNauk SSSR Doklady, 434, 9-13(1941).

[108] P DUTTA, A BESKOK. Analytical solution of time periodic electroosmotic flows: analogies to Stokes' second problem. Analytical Chemistry, 73, 5097-5102(2001).

[109] Z Y HU, T Y ZHAO, H WANG et al. Asymmetric temporal variation of oscillating AC electroosmosis with a steady pressure-driven flow. Experiments in Fluids, 61, 233(2020).

[110] R J HUNTER. Foundations of colloid science(2001).

[111] E KARATAY, C L DRUZGALSKI, A MANI. Simulation of chaotic electrokinetic transport: Performance of commercial software versus custom-built direct numerical simulation codes. Journal of Colloid and Interface Science, 446, 67-76(2015).

[112] S M DAVIDSON, M B ANDERSEN, A MANI. Chaotic induced-charge electro-osmosis. Physical Review Letters, 112, 128302(2014).

[113] Z Y HU, T Y ZHAO, W ZHAO et al. Transition from periodic to chaotic AC electroosmotic flows near electric double layer. AICHE Journal, 67, e17148(2020).

[114] V SURESH, G M HOMSY. Stability of time-modulated electroosmotic flow. Physics of Fluids, 16, 2349-2356(2004).