Electron multiplying charge-coupled device-based fluorescence cross-correlation spectroscopy for blood velocimetry on zebrafish embryos

Journal of Biomedical Optics

Volumn 19, Issue 6, 2014, Pages

  Pozzi, Paolo ^a   Sironi, Laura ^a   D'Alfonso, Laura ^a   Bouzin, Margaux ^a   Collini, Maddalena ^a   Chirico, Giuseppe ^a   Pallavicini, Piersandro ^b   Cotelli, Franco ^c   Foglia, Efrem A ^c  

^a UNIVERSITY OF MILANO BICOCCA   (Italy)

^b UNIVERSITY OF PAVIA   (Italy)

^c UNIVERSITY OF MILAN   (Italy)

Author keywords

fluorescence correlation; hemodynamics; microfluidics.; velocimetry; zebrafish

Indexed keywords

HEMODYNAMICS; INFRARED DEVICES; INTERFEROMETERS; MICROFLUIDICS; VELOCIMETERS; VELOCITY MEASUREMENT;

CROSS-CORRELATION FUNCTION; ELECTRON MULTIPLYING CHARGE COUPLED DEVICES; FLUORESCENCE CORRELATION; FLUORESCENCE CROSS-CORRELATION SPECTROSCOPY; OPTIMIZED SCANNING SYSTEMS; TWYMAN-GREEN INTERFEROMETERS; WIDE-FIELD MICROSCOPIES; ZEBRAFISH;

FLUORESCENCE;

FLUORESCENT DYE; RHODAMINE; RHODAMINE 6G;

ANIMAL; ANIMAL EMBRYO; BLOOD FLOW VELOCITY; CHEMISTRY; COMPUTER SIMULATION; CYTOLOGY; ELECTRON; ERYTHROCYTE; FLOW KINETICS; FLUORESCENCE; HEMODYNAMICS; INTERFEROMETRY; OPTICS; PHOTON; PHYSIOLOGY; PROCEDURES; SPECTROFLUOROMETRY; THEORETICAL MODEL; ZEBRA FISH;

ANIMALS; BLOOD FLOW VELOCITY; COMPUTER SIMULATION; ELECTRONS; EMBRYO, NONMAMMALIAN; ERYTHROCYTES; FLUORESCENCE; FLUORESCENT DYES; HEMODYNAMICS; INTERFEROMETRY; MODELS, THEORETICAL; OPTICS AND PHOTONICS; PHOTONS; RHEOLOGY; RHODAMINES; SPECTROMETRY, FLUORESCENCE; ZEBRAFISH;

EID: 84923373440     PISSN: 10833668     EISSN: 15602281     Source Type: Journal    
DOI: 10.1117/1.JBO.19.6.067007     Document Type: Article

References (52)

1. S. A. Kim, K. G. Heinze, and P. Schwille, "Fluorescence correlation spectroscopy in living cells," Nat. Meth. 4(11), 963-973 (2007). (Pubitemid 350042387)
2. M. A. Digman and E. Gratton, "Lessons in fluctuations correlation spectroscopy," Ann. Rev. Phys. Chem. 62, 645-668 (2011).
3. D. Magde,W. W. Webb, and E. Elson, "Thermodynamic fluctuations in a reacting system-measurement by fluorescence correlation spectroscopy," Phys. Rev. Lett. 29(11), 705-708 (1972).
4. M. Ehrenberg and R. Rigler, "Rotational Brownian-motion and fluorescence intensity fluctuations," Chem. Phys. 4(3), 390-401 (1974).
5. R. Rigler, "FCS and single molecule spectroscopy," Chapter 4 in Single Molecule Spectroscopy in Chemistry, Physics and Biology, A. Gräslund, R. Rigler, and J.Widengren, Eds., Vol. 96, pp. 77-103, Springer Verlag, Berlin (2010).
6. P. C. Brister et al., "Fluorescence correlation spectroscopy for flow rate imaging and monitoring-optimization, limitations and artifacts," Lab Chip 5(7), 785-791 (2005). (Pubitemid 40980108)
7. D. Magde, W. W. Webb, and E. L. Elson, "Fluorescence correlation spectroscopy 3. Uniform translation and laminar-flow," Biopolymers 17(2), 361-376 (1978). (Pubitemid 8317012)
8. M. Gösch et al., "Hydrodynamic flow profiling in microchannel structures by single molecule fluorescence correlation spectroscopy," Anal. Chem. 72(14), 3260-3265 (2000). (Pubitemid 30482501)
9. K. K. Kuricheti, V. Buschmann, and K. D.Weston, "Application of fluorescence correlation spectroscopy for velocity imaging in microfluidic devices," Appl. Spec. 58(10), 1180-1186 (2004).
10. K. Liu et al., "Mapping vortex-like hydrodynamic flow in microfluidic networks using fluorescence correlation spectroscopy," Analytica Chimica Acta 651(1), 85-90 (2009).
11. X. Shi et al., "Probing events with single molecule sensitivity in Zebrafish and Drosophila embryos by fluorescence correlation spectroscopy," Develop. Dyn. 238(12), 3156-3167 (2009).
12. K. Brinkmeier, J. S. Doerre, and M. Eigen, "Two-beam cross-correlation: a method to characterize transport phenomena in micrometer-sized structures," Anal. Chem. 71(3), 609-616 (1999).
13. P. S. Dittrich and P. Schwille, "Spatial two-photon fluorescence crosscorrelation spectroscopy for controlling molecular transport in microfluidic structures," Anal. Chem. 74(17), 4472-4479 (2002). (Pubitemid 35006436)
14. T. Dertinger et al., "Two-focus fluorescence correlation spectroscopy: a new tool for accurate and absolute diffusion measurements," Chem. Phys. Chem. 8(3), 433-443 (2007).
15. C. B. Mueller et al., "Precise measurement of diffusion by multi-color dual-focus fluorescence correlation spectroscopy," Eur. Phys. Lett. 83(4), p1-p5 (2008).
16. T. J. Arbour and J. Enderlein, "Application of dual-focus fluorescence correlation spectroscopy to microfluidic flow-velocity measurement," Lab Chip 10(10), 1286-1292 (2010).
17. D. J. Grunwald and J. S. Eisen, "Headwaters of the zebrafish-emergence of a new model vertebrate," Nat. Rev. Genet. 3(9), 717-724 (2002). (Pubitemid 34984260)
18. M. C. Mione and N. S. Trede, "The zebrafish as a model for cancer," Dis. Model Mech. 3(9-10), 517-523 (2010).
19. E. L. Elson and D. Magde, "Fluorescence correlation spectroscopy .1. Conceptual basis and theory," Biopolymers 13(1), 1-27 (1974).
20. J. Enderlein and W. P. Ambrose, "Optical collection efficiency function in single-molecule detection experiments," Appl. Opt. 36(22), 5298-5302 (1997). (Pubitemid 127638479)
21. A. Diaspro, G. Chirico, and M. Collini, "Applications in two-photon excitation microscopy," Quart. Rev. Biophys. 38(2), 97-166 (2005).
22. J. B. Freund et al., "Fluid flows and forces in development: functions, features and biophysical principles," Development 139(7), 1229-1245 (2012).
23. B. Vollmar, S. Siegmund, and M. D. Menger, "An intravital fluorescence microscopic study of hepatic microvascular and cellular derangements in developing cirrhosis in rats," Hepatol. 27(6), 1544-1553 (1998). (Pubitemid 28264677)
24. M. Thiriet and K. H. Parker, "Physiology and pathology of the cardiovascular system: a physical perspective," Chapter 1 in Cardiovascular Mathematics: Modeling and Simulation of the Circulatory System, L. Formaggia, A. Quarteroni, and A. Veneziani, Eds., pp. 1-46, Springer Verlag, Italia (2009).
25. Y. Blum et al., "Complex cell rearrangements during intersegmental vessel sprouting and vessel fusion in the zebrafish embryo," Dev. Biol. 316(2), 312-322 (2008).
26. C.-Y. Chen et al., "Analysis of early embryonic great-vessel microcirculation in zebrafish using high-speed confocal mu PIV," Biorheol. 48(5-6), 305-321 (2011).
27. P. Pallavicini et al., "Synthesis of branched Au nanoparticles with tunable near-infrared LSPR using a zwitterionic surfactant," Chem. Commun. 47(4), 1315-1317 (2011).
28. N. D. Lawson and B. M. Weinstein, "In vivo imaging of embryonic vascular development using transgenic zebrafish," Dev. Biol. 248(2), 307-318 (2002). (Pubitemid 35002091)
29. M. A. Akimenko et al., "Differential induction Of 4 Msx Homeobox genes during fin development and regeneration in Zebrafish," Development 121(2), 347-357 (1995).
30. A. Bassi et al., "In vivo label-free three-dimensional imaging of zebrafish vasculature with optical projection tomography," J. Biomed. Opt. 16(10), 100502 (2011).
31. L. Sironi et al., "Gold branched nanoparticles for cellular treatments," J. Chem. Phys. C 116(34), 18407-18418 (2012).
32. A. J. García-Sáez and P. Schwille, "Fluorescence correlation spectroscopy for the study of membrane dynamics and protein/lipid interactions," Methods 46(2), 116-122 (2008).
33. S. K.Wilson and B. R. Duffy, "A rivulet of perfectly wetting fluid draining steadily down a slowly varying substrate," IMA J. Appl. Math. 70(2), 293-322 (2005). (Pubitemid 40564620)
34. Y. Kuo and R. I. Tanner, "Laminar Newtonian flow in open channels with surface-tension," Int. J. Mech. Sci. 14(12), 861-873 (1972).
35. H. Bruus, Theoretical Microfluidics, pp. 48-51, 123-136, Oxford University Press, United Kingdom (2008).
36. V. T. Turrito and H. R. Baumgartner, "Platelet interaction with subendotheliumin flowing rabbit blood: effect of blood shear rate," Microvasc. Res. 17(1), 38-54 (1979). (Pubitemid 9152501)
37. G. J. Tangelder et al., "Wall shear rate in arterioles in vivo: least estimates from platelet velocity profiles," Am. J. Physiol. 254(6), H1059-H1064 (1988).
38. X. Pan et al., "Characterization of flow direction in microchannels and zebrafish blood vessels by scanning fluorescence correlation spectroscopy," J. Biomed. Opt. 12(1), 014034 (2007).
39. M. Oishi et al., "Continuous and simultaneous measurement of the tanktreading motion of red blood cells and the surrounding flow using translational confocal micro-particle image velocimetry (micro-PIV) with sub-micron resolution," Meas. Sci. Techn. 23(3), 035301 (2012).
40. P. Vennemann et al., "In vivo micro particle image velocimetry measurements of blood-plasma in the embryonic avian heart," J. Biomech. 39(7), 1191-1200 (2006).
41. M. L. Smith et al., "Near-wall mu-PIV reveals a hydrodynamically relevant endothelial surface layer in venules in vivo," Biophys. J. 85(1), 637-645 (2003). (Pubitemid 36753665)
42. H. Cheng et al., "Modified laser speckle imaging method with improved spatial resolution," J. Biomed. Opt. 8(3), 559-564 (2003).
43. W. Wang et al., "Optical trapping and fluorescence detection in laminar flow streams," Appl. Phys. Lett. 67(8), 1057-1059 (1995).
44. B. Manz et al., "NMR imaging of the time evolution of electroosmotic flow in a capillary," J. Phys. Chem. 99(29), 11297-11301 (1995).
45. L. Fieramonti et al., "Quantitative measurement of blood velocity in zebrafish with optical vector field tomography," J. Biophotonics (2013) [Epub ahead of print].
46. J. R. Hove et al., "Intracardiac fluid forces are an essential epigenetic factor for embryonic cardiogenesis," Nature 421(6919), 172-177 (2003). (Pubitemid 36090985)
47. R. S. Reneman, T. Arts, and A. P. G. Hoeks, "Wall shear stress-an important determinant of endothelial cell function and structure-in the arterial system in vivo discrepancies with theory," J. Vasc. Res. 43(3), 251-269 (2006). (Pubitemid 44257044)
48. Z. Zhong et al., "Noninvasive measurements and analysis of blood velocity profiles in human retinal vessels," Invest. Ophthalmol. Vis. Sci. 52(7), 4151-4157 (2011).
49. P. Gaehtgens, H. J. Meiselman, and H. Wayland, "Velocity profiles of human blood at normal and reduced hematocrit in glass tubes up to 130 micrometer diameter," Microvasc. Res. 2(1), 13-23 (1970).
50. R. T. Yen and Y. C. Fung, "Effect of velocity distribution on red-cell distribution in capillary blood-vessels," Am. J. Physiol. 235(2), H251-H257 (1978). (Pubitemid 9165866)
51. T. W. Secomb, "Mechanics of blood flow in the microcirculation, " Symp. Soc. Exp. Biol. 49(1), 305-321 (1995).
52. D. Gandolfi et al., "The spatiotemporal organization of cerebellar network activity resolved by two-photon imaging of multiple single neurons," Front. Cell. Neurosci. 8, 92 (2014).