%0 Journal Article %1 Heilemann2002 %A Heilemann, M %A Herten, DP %A Heintzmann, R %A Cremer, C %A Muller, C %A Tinnefeld, P %A Weston, KD %A Wolfrum, J %A Sauer, M %C 1155 16TH ST, NW, WASHINGTON, DC 20036 USA %D 2002 %I AMER CHEMICAL SOC %J ANALYTICAL CHEMISTRY %K sauer mike %N 14 %P 3511-3517 %T High-resolution colocalization of single dye molecules by fluorescence lifetime imaging microscopy %U http://dx.doi.org/10.1021/ac025576g %V 74 %X Conventional fluorescence microscopy can be used to determine the positions of objects in space when those objects are separated by distances greater than several hundred nanometers, as restricted by the diffraction limit of light. Fluorescence microscopy/spectroscopy based on fluorescence resonance energy-transfer techniques can be used to measure separation distances below similar to10 nm. To fill the gap between these fundamental limits, we have developed an alternative technique for high-resolution colocalization of fluorescent dyes. The technique is based on fluorescence lifetime imaging. Under favorable conditions, the method can be used to distinguish, and to measure the distance between, two dye molecules that are less than 30 nm apart. To demonstrate the method, lifetime images of a mixture of Cy5 and JF9 (rhodamine derivative) molecules statistically adsorbed on a glass surface were acquired and analyzed. Since these two molecular species differ in fluorescence lifetime (for Cy5, tau(f) = 2.0 us, and for JF9, tau(f) = 4.0 ns), it is possible to assign the contribution of fluorescence of the two dye types to each image pixel using a pattern recognition technique. Since both dye types can be excited using the same laser wavelength, the measurement is free of chromatic aberrations. The results presented demonstrate the first high-precision distance measurements between single conventional fluorescent dyes based solely on fluorescence lifetime.

@article{Heilemann2002, abstract = {Conventional fluorescence microscopy can be used to determine the positions of objects in space when those objects are separated by distances greater than several hundred nanometers, as restricted by the diffraction limit of light. Fluorescence microscopy/spectroscopy based on fluorescence resonance energy-transfer techniques can be used to measure separation distances below similar to10 nm. To fill the gap between these fundamental limits, we have developed an alternative technique for high-resolution colocalization of fluorescent dyes. The technique is based on fluorescence lifetime imaging. Under favorable conditions, the method can be used to distinguish, and to measure the distance between, two dye molecules that are less than 30 nm apart. To demonstrate the method, lifetime images of a mixture of Cy5 and JF9 (rhodamine derivative) molecules statistically adsorbed on a glass surface were acquired and analyzed. Since these two molecular species differ in fluorescence lifetime (for Cy5, tau(f) = 2.0 us, and for JF9, tau(f) = 4.0 ns), it is possible to assign the contribution of fluorescence of the two dye types to each image pixel using a pattern recognition technique. Since both dye types can be excited using the same laser wavelength, the measurement is free of chromatic aberrations. The results presented demonstrate the first high-precision distance measurements between single conventional fluorescent dyes based solely on fluorescence lifetime.}, added-at = {2011-03-01T10:57:13.000+0100}, address = {1155 16TH ST, NW, WASHINGTON, DC 20036 USA}, affiliation = {Sauer, M (Reprint Author), Univ Heidelberg, Phys Chem Inst, Im Heuenheimer Feld 253, D-69120 Heidelberg, Germany. Univ Heidelberg, Phys Chem Inst, D-69120 Heidelberg, Germany. ATTO TEC GmbH, D-57076 Siegen, Germany. Max Planck Inst Biophys Chem, D-37077 Gottingen, Germany. Univ Heidelberg, Kirchhoff Inst Phys, D-69120 Heidelberg, Germany.}, author = {Heilemann, M and Herten, DP and Heintzmann, R and Cremer, C and Muller, C and Tinnefeld, P and Weston, KD and Wolfrum, J and Sauer, M}, biburl = {https://www.bibsonomy.org/bibtex/21e8f14d65de5eaac8f38287c2d81911c/reichert}, cited-references = {ALIVISATOS AP, 1996, SCIENCE, V271, P933. AMBROSE WP, 1999, CHEM REV, V99, P2929. BANIN U, 1999, J CHEM PHYS, V10, P1. BETZIG E, 1995, OPT LETT, V20, P237. CARDOSO MC, 1993, CELL, V74, P979. CARDOSO MC, 1998, J CELL BIOCHEM, V70, P222. CHEEZUM MK, 2001, BIOPHYS J, V81, P2378. COGNET L, 2000, APPL PHYS LETT, V77, P4052. COOK PR, 1999, SCIENCE, V284, P1790. DREXHAGE KH, 1970, J LUMIN, V1, P693. ENDERLE T, 1997, P NATL ACAD SCI USA, V94, P520. ENDERLEIN J, 2001, J PHYS CHEM A, V105, P48. ENERLEIN J, 1991, EXP TECH PHYS, V39, P479. ESA A, 2000, J MICROSC-OXFORD 2, V199, P96. JACKSON DA, 1998, MOL BIOL CELL, V9, P1523. KLAR TA, 2000, P NATL ACAD SCI USA, V97, P8206. KOLLNER M, 1992, CHEM PHYS LETT, V200, P199. KOLLNER M, 1993, APPL OPTICS, V32, P806. KOLLNER M, 1996, CHEM PHYS LETT, V250, P355. KUNO M, 2000, J CHEM PHYS, V112, P3117. LACOSTE TD, 2000, P NATL ACAD SCI USA, V97, P9461. LAMOND AI, 1998, SCIENCE, V280, P547. LEONHARDT H, 1998, J CELL BIOCH S, V30, P243. LIEBERWIRTH U, 1998, ANAL CHEM, V70, P4771. MACKLIN JJ, 1996, SCIENCE, V272, P255. MANDERS EMM, 1997, J MICROSC-OXFORD 3, V185, P321. METS U, 1994, J FLUORESC, V4, P259. MICHALET X, 2001, METHODS, V25, P87. NIE SM, 1994, SCIENCE, V266, P1018. PATWARDHAN A, 1996, BIOIMAGING, V4, P17. PAWLEY JB, 1995, HDB BIOL CONFOCAL MI. POMBO A, 1999, EMBO J, V18, P2241. PRESS WH, 1994, NUMERICAL RECIPES C. SAKO Y, 2000, NAT CELL BIOL, V2, P168. SAUER M, 1998, BIOIMAGING, V6, P14. SAUER M, 2001, J BIOTECHNOL, V86, P181. SCHMIDT T, 1996, P NATL ACAD SCI USA, V93, P2926. SCHUTZ GJ, 2000, EMBO J, V19, P892. SPECTOR DL, 1993, ANNU REV CELL BIOL, V9, P265. THOMPSON RE, 2002, BIOPHYS J, V82, P2775. TINNEFELD P, 2000, SINGLE MOL, V1, P215. TINNEFELD P, 2001, J PHYS CHEM A, V105, P7989. TRABESINGER W, 2001, ANAL CHEM, V73, P1100. VANOIJEN AM, 1998, CHEM PHYS LETT, V292, P183. VEERMAN JA, 1999, PHYS REV LETT, V83, P2155. WANSINK DG, 1996, J CELL BIOCHEM, V62, P10. WESTON KD, 1998, J CHEM PHYS, V109, P7474. ZANDER C, 1996, APPL PHYS B-LASERS O, V63, P517.}, doc-delivery-number = {573TD}, groups = {public}, interhash = {7fa9d97a555e34d464259604e3481bf4}, intrahash = {1e8f14d65de5eaac8f38287c2d81911c}, issn = {0003-2700}, journal = {ANALYTICAL CHEMISTRY}, journal-iso = {Anal. Chem.}, keywords = {sauer mike}, keywords-plus = {AQUEOUS-SOLUTION; QUANTUM DOTS; DUAL-COLOR; IDENTIFICATION; TRANSCRIPTION; NUCLEI; SPECTROSCOPY; ORGANIZATION; TEMPERATURE; REPLICATION}, language = {English}, month = {JUL 15}, number = 14, number-of-cited-references = {48}, pages = {3511-3517}, publisher = {AMER CHEMICAL SOC}, subject-category = {Chemistry, Analytical}, times-cited = {33}, timestamp = {2011-03-09T14:16:24.000+0100}, title = {High-resolution colocalization of single dye molecules by fluorescence lifetime imaging microscopy}, type = {Article}, unique-id = {ISI:000176846200037}, url = {http://dx.doi.org/10.1021/ac025576g}, username = {reichert}, volume = 74, year = 2002 }