Principles of Fluorescence Spectroscopy

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PRINCIPLES OF FLUORESCENCE SPECTROSCOPY 619 REFERENCES Figure 18.25. Three-dimensional cell imaging using confocal or multiphoton microscopy. Figure 18.26. Three-dimensional reconstruction of a live PC cell stained with acridine orange, which emits green (525 nm) when bound to DNA and red (650 nm) when present in acidic organelles. The perspective on the left is rotated 60° from the cells around the horizontal axis. The perspective on the right is rotated 90° around the vertical axis. Figure courtesy of Dr. Stefan Hall, Max-Planck Institute for Physical Chemistry, Göttingen, Germany. 1. Friedrich DM, McClain WM. 1980. Two-photon molecular electronic spectroscopy. Annu Rev Phys Chem 31:559–577. 2. Wirth MJ, Koskelo A, Sanders MJ. 1981. Molecular symmetry and two-photon spectroscopy. Appl Spectrosc 35:14–21. 3. Birge RR. 1983. One- and two-photon excitation spectroscopy. In Ultrasensitive laser spectroscopy, pp. 109–174. Ed DS Kliger. Academic Press, New York. 4. Denk W, Strickler JH, Webb WW. 1990. Two-photon laser scanning fluorescence microscopy. Science 248:73–76. 5. Masters BR, ed. 2003. Selected papers on multiphoton excitation microscopy. SPIE milestone series, SPIE Optical Engineering Press, Bellingham, WA. 6. Diaspro A, ed. 2002. Confocal and two-photon microscopy foundations, applications, and advances. Wiley-Liss, New York, 56. 7. Hell SW, ed. 1996. Bioimaging special issue on nonlinear optical microscopy, pp. 121–224. Institute of Physics Publishing, New York. 8. Diaspro A. 1999. Introduction to two-photon microscopy. Microsc Res Technol 47:163–164. 9. Lakowicz JR, ed. 1997. Topics in fluorescence spectroscopy, Vol. 5: Nonlinear and two-photon-induced fluorescence, Plenum Press, New York. 10. So PTC, Dong CY, Masters BR, Berland KM. 2000. Two-photon excitation fluorescence microscopy. Annu Rev Biomed Eng 2:399– 429. 11. Williams RM, Piston DW, Webb WW. 1994. Two-photon molecular excitation provides intrinsic 3-dimensional resolution for laser-based microscopy and microphotochemistry. FASEB J 8:804–813. 12. Denk W, Piston DW, Webb WW. 1995. Two-photon molecular excitation in laser-scanning microscopy. In Handbook of biological confocal microscopy, pp. 445–448. Ed JB Pawley. Plenum Press, New York.
620 MULTIPHOTON EXCITATION AND MICROSCOPY 13. Goppert-Mayer M. 1931. Uber elementarakte mit zwei quantensprungen. Ann Phys Leipzig 9:273–294. 14. Masters BR, So PTC. 2004. Antecedents of two-photon excitation laser scanning microscopy. Microsc Res Technol 63:3–11. 15. Xu C, Webb WW. 1997. Multiphoton excitation of molecular fluorophores and nonlinear laser microscopy. In Topics in fluorescence spectroscopy, Vol. 5: Nonlinear and two-photon-induced fluorescence, pp. 471–540. Ed JR Lakowicz. Plenum Press, New York. 16. Xu C, Williams RM, Zipfel W, Webb WW. 1996. Multiphoton excitation cross-sections of molecular fluorophores. Bioimaging 4: 198–207. 17. Xu C, Zipfel W, Shear JB, Williams RM, Webb WW. 1996. Multiphoton fluorescence excitation: new spectral windows for biological nonlinear microscopy. Proc Natl Acad Sci USA 93:10763– 10768. 18. Xu C, Webb WW. 1996. Measurement of two-photon excitation cross sections of molecular fluorophores with data from 690 to 1050 nm. J Opt Soc Am B 13(3):481–490. 19. Xu C, Guild J, Webb WW. 1995. Determination of absolute two-photon excitation cross-sections by in situ second-order autocorrelation. Opt Lett 20:2372–2374. 20. Kennedy SM, Lytle FE. 1986. P-bis(o-methylstyryl)benzene as a power-squared sensor for two-photon absorption measurements between 537 and 694 nm. Anal Chem 58:2643–2647. 21. Courtesy of Drs. Zygmunt Gryczynski and Ignacy Gryczynski. 22. Birch DJS. 2001. Multiphoton excited fluorescence spectroscopy of biomolecular systems. Spectrochim Acta, Part A 57:2313–2336. 23. Gryczynski I, Malak H, Lakowicz JR. 1996. Multiphoton excitation of the DNA stains DAPI and Hoechst. Bioimaging 4:138–148. 24. Lakowicz JR, Gryczynski I, Malak H, Schrader M, Engelhardt P, Kano H, Hell SW. 1997. Time-resolved fluorescence spectroscopy and imaging of DNA labeled with DAPI and Hoechst 33342 using three-photon excitation. Biophys J 72:567–578. 25. Lakowicz JR, Gryczynski I. 1992. Fluorescence intensity and anisotropy decay of the 4',6-diamidino-2-phenylindole–DNA complex resulting from one-photon and two-photon excitation. J Fluoresc 2(2):117–122. 26. Callis PR. 1997. The theory of two-photon induced fluorescence anisotropy. In Topics in fluorescence spectroscopy, Vol. 5: Nonlinear and two-photon induced fluorescence, pp. 1–42. Ed JR Lakowicz. Plenum Press, New York. 27. Johnson CK, Wan C. 1997. Anisotropy decays induced by two-photon excitation. In Topics in fluorescence spectroscopy, Vol. 5: Nonlinear and two-photon induced fluorescence, pp. 43–85. Ed JR Lakowicz. Plenum Press, New York. 28. Callis PR. 1997. Two-photon induced fluorescence. Annu Rev Phys Chem 48:271–297. 29. Lakowicz JR, Gryczynski I, Gryczynski Z, Danielson E, Wirth MJ. 1992. Time-resolved fluorescence intensity and anisotropy decays of 2,5-diphenyloxazole by two-photon excitation and frequencydomain fluorometry. J Phys Chem 96:3000–3006. 30. Wan C, Johnson CK. 1994. Time-resolved two-photon induced anisotropy decay: the rotational diffusion regime. J Chem Phys 101: 10283–10291. 31. Chen SY, Van Der Meer BW. 1993. Theory of two-photon induced fluorescence anisotropy decay in membranes. Biophys J 64:1567– 1575. 32. Gryczynski I, Malak H, Lakowicz JR. 1995. Three-photon induced fluorescence of 2,5-diphenyloxazole with a femtosecond Ti:Sapphire laser. Chem Phys Lett 245:30–35. 33. Monson PR, McClain WM. 1970. Polarization dependence of the two-photon absorption of tumbling molecules with application to liquid 1-chloronaphthalene and benzene. J Chem Phys 53(1):29–37. 34. Aleksandrov AP, Bredikhin VI, Genkin VN. 1971. Two-photon absorption by centrally symmetric organic molecules. Soviet Phys JETP 33(6):1078–1082. 35. Mohler CE, Wirth MJ. 1988. Solvent perturbations on the excited state symmetry of randomly oriented molecules by two-photon absorption. J Chem Phys 88(12):7369–7375. 36. Lakowicz JR, Gryczynski I, Kusba J, Danielsen E. 1992. Two photon-induced fluorescence intensity and anisotropy decays of diphenylhexatriene in solvents and lipid bilayers. J Fluoresc 2(4): 247–258. 37. Lakowicz JR, Gryczynski I. 1997. Multiphoton excitation of biochemical fluorophores. In Topics in fluorescence spectroscopy, Vol. 5: Nonlinear and two-photon induced fluorescence, pp. 84–144. Ed JR Lakowicz. Plenum Press, New York. 38. Malak H, Gryczynski I, Dattelbaum JD, Lakowicz JR. 1997. Threephoton-induced fluorescence of diphenylhexatriene in solvents and lipid bilayers. J Fluoresc 7(2):99–106. 39. Squirrell JM, Wokosin DL, White JG, Bavister BD. 1999. Long-term two-photon fluorescence imaging of mammalian embryos without compromising viability. Nature Biotechnol 17:763–767. 40. Lakowicz JR, Gryczynski I. 1992. Tryptophan fluorescence intensity and anisotropy decays of human serum albumin resulting from one-photon and two-photon excitation. Biophys Chem 45:1–6. 41. Kierdaszuk B, Gryczynski I, Modrak-Wojcik A, Bzowska A, Shugar D, Lakowicz JR. 1995. Fluorescence of tyrosine and tryptophan in proteins using one- and two-photon excitation. Photochem Photobiol 61(4):319–324. 42. Lakowicz JR, Kierdaszuk B, Gryczynski I, Malak H. 1996. Fluorescence of horse liver alcohol dehydrogenase using one- and two-photon excitation. J Fluoresc 6(1):51–59. 43. Lakowicz JR, Gryczynski I, Danielsen E, Frisoli J. 1992. Anisotropy spectra of indole and n-acetyl-L-tryptophanamide observed for twophoton excitation of fluorescence. Chem Phys Lett 194(4,5,6):282–287. 44. Cramb DT, Wallace SC. 1998. The adsorption of L-tryptophan to the H 2 0–CCL 4 interface, monitored by red-edge two photon-induced polarized fluorescence. J Fluoresc 8(3):243–252. 45. Lippitz M, Erker W, Decker H, van Holde KE, Basche T. 2002. Twophoton excitation microscopy of tryptophan-containing proteins. Proc Natl Acad Sci USA 99(5):2772–2777. 46. Gryczynski I, Malak H, Lakowicz JR. 1996. Three-photon excitation of a tryptophan derivative using an fs-Ti:Sapphire laser. Biospectroscopy 2:9–15. 47. Gryczynski I, Malak H, Lakowicz JR, Cheung HC, Robinson J, Umeda PK. 1996. Fluorescence spectral properties of troponin c mutant F22W with one-, two-, and three-photon excitation. Biophys J 71:3448–3453. 48. Callis P. 1993. On the theory of two-photon induced fluorescence anisotropy with application to indoles. J Chem Phys 99(1):27–37. 49. Rehms AA, Callis PR. 1993. Two-photon fluorescence excitation spectra of aromatic amino acids. Chem Phys Lett 208(3,4):276–282.
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Principles of Fluorescence Spectros
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Joseph R. Lakowicz Center for Fluor
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Preface The first edition of Princi
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x GLOSSARY OF ACRONYMS DNS dansyl o
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xii GLOSSARY OF ACRONYMS TRES time-
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xiv GLOSSARY OF MATHEMATICAL TERMS
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xvi CONTENTS 2.9.4. Conversion betw
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xviii CONTENTS 6. Solvent and Envir
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xx CONTENTS 10.4.4. Alignment of Po
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xxii CONTENTS 14.7.1. Simulations o
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xxiv CONTENTS 19.12. New Approaches
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xxvi CONTENTS 25.3. Optical Propert
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2 INTRODUCTION TO FLUORESCENCE Figu
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6 INTRODUCTION TO FLUORESCENCE inst
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10 INTRODUCTION TO FLUORESCENCE Fig
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12 INTRODUCTION TO FLUORESCENCE ns,
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14 INTRODUCTION TO FLUORESCENCE 1.7
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24 INTRODUCTION TO FLUORESCENCE due
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28 INSTRUMENTATION FOR FLUORESCENCE
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3 Fluorescence probes represent the
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PRINCIPLES OF FLUORESCENCE SPECTROS
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98 TIME-DOMAIN LIFETIME MEASUREMENT
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100 TIME-DOMAIN LIFETIME MEASUREMEN
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5 In the preceding chapter we descr
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6 Solvent polarity and the local en
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238 DYNAMICS OF SOLVENT AND SPECTRA
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278 QUENCHING OF FLUORESCENCE 8.1.
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280 QUENCHING OF FLUORESCENCE Figur
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282 QUENCHING OF FLUORESCENCE ly ev
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290 QUENCHING OF FLUORESCENCE relat
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298 QUENCHING OF FLUORESCENCE σ ar
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320 QUENCHING OF FLUORESCENCE 47. R
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322 QUENCHING OF FLUORESCENCE 113.
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328 QUENCHING OF FLUORESCENCE P8.3.
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330 QUENCHING OF FLUORESCENCE P8.11
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332 MECHANISMS AND DYNAMICS OF FLUO
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10 Measurements of fluorescence ani
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11 In the preceding chapter we desc
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12 In the preceding two chapters we
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444 ENERGY TRANSFER Figure 13.1. Fl
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446 ENERGY TRANSFER wavelength is e
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448 ENERGY TRANSFER Table 13.1. Cal
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450 ENERGY TRANSFER Figure 13.6. Ab
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452 ENERGY TRANSFER safe for many p
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454 ENERGY TRANSFER Figure 13.12. P
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456 ENERGY TRANSFER Figure 13.16. E
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458 ENERGY TRANSFER Figure 13.21. R
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460 ENERGY TRANSFER Figure 13.24. R
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462 ENERGY TRANSFER tiple acceptors
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464 ENERGY TRANSFER Figure 13.29. A
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466 ENERGY TRANSFER Figure 13.33. F
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468 ENERGY TRANSFER Table 13.3. Rep
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470 ENERGY TRANSFER 55. Clegg RM. 1
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472 ENERGY TRANSFER Tong AK, Jockus
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474 ENERGY TRANSFER Figure 13.39. O
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14 In the previous chapter we descr
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15 In the previous two chapters on
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16 The biochemical applications of
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676 NOVEL FLUOROPHORES Figure 20.1.
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678 NOVEL FLUOROPHORES Figure 20.7.
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680 NOVEL FLUOROPHORES Figure 20.12
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698 NOVEL FLUOROPHORES 33. Acherman
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700 NOVEL FLUOROPHORES 103. Demas J
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702 NOVEL FLUOROPHORES 176. Montalt
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21 During the past 20 years there h
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22 Fluorescence microscopy is one o
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758 SINGLE-MOLECULE DETECTION Figur
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766 SINGLE-MOLECULE DETECTION small
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770 SINGLE-MOLECULE DETECTION Table
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786 SINGLE-MOLECULE DETECTION face
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788 SINGLE-MOLECULE DETECTION TCSPC
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790 SINGLE-MOLECULE DETECTION 53. H
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792 SINGLE-MOLECULE DETECTION Ke PC
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794 SINGLE-MOLECULE DETECTION Polar
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24 In the previous chapter we descr
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862 RADIATIVE-DECAY ENGINEERING: SU
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Appendix I Corrected Emission Spect
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Appendix II Fluorescence Lifetime S
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890 APPENDIX III P ADDITIONAL READI
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892 APPENDIX III P ADDITIONAL READI
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894 ANSWERS TO PROBLEMS A1.4. A. Th
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896 ANSWERS TO PROBLEMS Energy tran
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898 ANSWERS TO PROBLEMS Figure 4.65
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900 ANSWERS TO PROBLEMS expected to
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904 ANSWERS TO PROBLEMS where f is
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906 ANSWERS TO PROBLEMS [BSA] Obser
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908 ANSWERS TO PROBLEMS emission. T
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910 ANSWERS TO PROBLEMS dx rA A (
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912 ANSWERS TO PROBLEMS B. A covale
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914 ANSWERS TO PROBLEMS The α i va
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920 ANSWERS TO PROBLEMS CHAPTER 24
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Index A Absorption spectroscopy, 12
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