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Referencias:

• Arden-Jacob, J., Frantzeskos, J., Kemnitzer, N.U., Zilles, A., Drexhage, K.H., New Fluorescent Markers for the Red Region (2001) Spectrochim. Acta, Part A, 57 (11), pp. 2271-2283
• Avlasevich, Y., Müller, S., Erk, P., Müllen, K., Novel Core-Expanded Rylenebis(dicarboximide) Dyes Bearing Pentacene Units: Facile Synthesis and Photophysical Properties (2007) Chem. - Eur. J., 13 (23), pp. 6555-6561
• Altman, R.B., Terry, D.S., Zhou, Z., Zheng, Q., Geggier, P., Kolster, R.A., Zhao, Y., Blanchard, S.C., Cyanine Fluorophore Derivatives with Enhanced Photostability (2011) Nat. Methods, 9 (1), pp. 68-71
• Wu, X.M., Zhu, W.H., Stability Enhancement of Fluorophores for Lighting up Practical Application in Bioimaging (2015) Chem. Soc. Rev., 44 (13), pp. 4179-4184
• Vogelsang, J., Kasper, R., Steinhauer, C., Person, B., Heilemann, M., Sauer, M., Tinnefeld, P., A Reducing and Oxidizing System Minimizes Photobleaching and Blinking of Fluorescent Dyes (2008) Angew. Chem., Int. Ed., 47 (29), pp. 5465-5469
• Pellegrotti, J.V., Acuna, G.P., Puchkova, A., Holzmeister, P., Gietl, A., Lalkens, B., Stefani, F.D., Tinnefeld, P., Controlled Reduction of Photobleaching in DNA Origami-Gold Nanoparticle Hybrids (2014) Nano Lett., 14 (5), pp. 2831-2836
• Puchkova, A., Vietz, C., Pibiri, E., Wünsch, B., Sanz Paz, M., Acuna, G.P., Tinnefeld, P., DNA Origami Nanoantennas with over 5000-Fold Fluorescence Enhancement and Single-Molecule Detection at 25 Mm (2015) Nano Lett., 15 (12), pp. 8354-8359
• Marriott, G., Clegg, R.M., Arndt-Jovin, D.J., Jovin, T.M., Time Resolved Imaging Microscopy. Phosphorescence and Delayed Fluorescence Imaging (1991) Biophys. J., 60 (6), pp. 1374-1387
• Dahan, M., Laurence, T., Pinaud, F., Chemla, D.S., Alivisatos, A.P., Sauer, M., Weiss, S., Time-Gated Biological Imaging by Use of Colloidal Quantum Dots (2001) Opt. Lett., 26 (11), pp. 825-827
• Hsiang, J.-C., Jablonski, A.E., Dickson, R.M., Optically Modulated Fluorescence Bioimaging: Visualizing Obscured Fluorophores in High Background (2014) Acc. Chem. Res., 47 (5), pp. 1545-1554
• Kobayashi, M., Mizumoto, T., Shibuya, Y., Enomoto, M., Takeda, M., Fluorescence Tomography in Turbid Media Based on Acousto-Optic Modulation Imaging (2006) Appl. Phys. Lett., 89 (18), p. 181102
• Zhang, Y., Zhang, K., Wang, J., Tian, Z., Li, A.D., Photoswitchable Fluorescent Nanoparticles and Their Emerging Applications (2015) Nanoscale, 7 (46), pp. 19342-19357
• Mahoney, D.P., Owens, E.A., Fan, C., Hsiang, J.C., Henary, M.M., Dickson, R.M., Tailoring Cyanine Dark States for Improved Optically Modulated Fluorescence Recovery (2015) J. Phys. Chem. B, 119 (13), pp. 4637-4643
• Marriott, G., Mao, S., Sakata, T., Ran, J., Jackson, D.K., Petchprayoon, C., Gomez, T.J., Aaron, H.L., Optical Lock-in Detection Imaging Microscopy for Contrast-Enhanced Imaging in Living Cells (2008) Proc. Natl. Acad. Sci. U. S. A., 105 (46), pp. 17789-17794
• Hsiang, J.-C., Fleischer, B.C., Dickson, R.M., Dark State-Modulated Fluorescence Correlation Spectroscopy for Quantitative Signal Recovery (2016) J. Phys. Chem. Lett., 7, pp. 2496-2501
• Richards, C.I., Hsiang, J.-C., Khalil, A.M., Hull, N.P., Dickson, R.M., FRET-Enabled Optical Modulation for High Sensitivity Fluorescence Imaging (2010) J. Am. Chem. Soc., 132 (18), pp. 6318-6323
• Díaz, S.A., Giordano, L., Jovin, T.M., Jares-Erijman, E.A., Modulation of a Photoswitchable Dual-Color Quantum Dot Containing a Photochromic FRET Acceptor and an Internal Standard (2012) Nano Lett., 12 (7), pp. 3537-3544
• Coronado, E.A., Encina, E.R., Stefani, F.D., Optical Properties of Metallic Nanoparticles: Manipulating Light, Heat and Forces at the Nanoscale (2011) Nanoscale, 3 (10), pp. 4042-4059
• Govorov, A.O.A.O., Richardson, H.H.H., Generating Heat with Metal Nanoparticles (2007) Nano Today, 2 (1), pp. 30-38
• Encina, E.R., Coronado, E.A., Plasmon Coupling in Silver Nanosphere Pairs (2010) J. Phys. Chem. C, 114 (9), pp. 3918-3923
• Urban, A.S., Fedoruk, M., Horton, M.R., Rädler, J.O., Stefani, F.D., Feldmann, J., Controlled Nanometric Phase Transitions of Phospholipid Membranes by Plasmonic Heating of Single Gold Nanoparticles (2009) Nano Lett., 9 (8), pp. 2903-2908
• Pustovalov, V.K., Smetannikov, A.S., Analytical and Computer Modelling of Thermal Processes of Laser Interaction with a Single Nanoparticle (2014) RSC Adv., 4 (99), pp. 55760-55772
• Baffou, G., Polleux, J., Rigneault, H., Monneret, S., Super-Heating and Micro-Bubble Generation around Plasmonic Nanoparticles under Cw Illumination (2014) J. Phys. Chem. C, 118 (9), pp. 4890-4898
• Baffou, G., Quidant, R., Thermo-Plasmonics: Using Metallic Nanostructures as Nano-Sources of Heat (2013) Laser Photon. Rev., 7 (2), pp. 171-187
• Skirtach, A.G., Dejugnat, C., Braun, D., Susha, A.S., Rogach, A.L., Parak, W.J., Möhwald, H., Sukhorukov, G.B., The Role of Metal Nanoparticles in Remote Release of Encapsulated Materials (2005) Nano Lett., 5 (7), pp. 1371-1377
• Stehr, J., Hrelescu, C., Sperling, R.A., Raschke, G., Wunderlich, M., Nichtl, A., Heindl, D., Klar, T.A., Gold NanoStoves for Microsecond DNA Melting Analysis (2008) Nano Lett., 8 (2), pp. 619-623
• Adleman, J.R., Boyd, D.A., Goodwin, D.G., Psaltis, D., Heterogenous Catalysis Mediated by Plasmon Heating (2009) Nano Lett., 9 (12), pp. 4417-4423
• Boyer, D., Tamarat, P., Maali, A., Lounis, B., Orrit, M., Photothermal Imaging of Nanometer-Sized Metal Particles among Scatterers (2002) Science, 297 (5584), pp. 1160-1163
• Gobin, A.M., Lee, M.H., Halas, N.J., James, W.D., Drezek, R.A., West, J.L., Near-Infrared Resonant Nanoshells for Combined Optical Imaging and Photothermal Cancer Therapy (2007) Nano Lett., 7 (7), pp. 1929-1934
• Valeur, B., (2002) Molecular Fluorescence Principles and Applications, , Wiley-VCH
• Jenness, J.R., Effect of Temperature upon the Fluorescence of Some Organics Solutions (1929) Phys. Rev., 34, pp. 1275-1285
• Tawde, N.R., Ramanathan, N., Fluorescence of Dyestuff Solutions: Viscosity and Temperature Effects (1952) Proc. Phys. Soc., London, Sect. B, 65 (1), pp. 33-40
• Jenness, J., Effect of Temperature upon the Fluorescence of Some Organic Solutions (1929) Phys. Rev., 34, pp. 1275-1285
• Bur, A., Vangel, M., Roth, S., Fluorescence Based Temperature Measurements and Applications to Real Time Polymer Processing (2001) Polym. Eng. Sci., 41 (8), p. 1380
• Ross, D., Gaitan, M., Locascio, L.E., Temperature Measurement in Microfluidic Systems Using a Temperature-Dependent Fluorescent Dye (2001) Anal. Chem., 73 (17), pp. 4117-4123
• Deprédurand, V., Miron, P., Labergue, A., Wolff, M., Castanet, G., Lemoine, F., A Temperature-Sensitive Tracer Suitable for Two-Colour Laser-Induced Fluorescence Thermometry Applied to Evaporating Fuel Droplets (2008) Meas. Sci. Technol., 19 (10), p. 105403
• Estrada-Pérez, C.E., Hassan, Y.A., Tan, S., Experimental Characterization of Temperature Sensitive Dyes for Laser Induced Fluorescence Thermometry (2011) Rev. Sci. Instrum., 82 (7), p. 74901
• Baffou, G., Kreuzer, M.P., Kulzer, F., Quidant, R., Temperature Mapping near Plasmonic Nanostructures Using Fluorescence Polarization Anisotropy (2009) Opt. Express, 17 (5), pp. 3291-3298
• Park, K., Biswas, S., Kanel, S., Nepal, D., Vaia, R.A., Engineering the Optical Properties of Gold Nanorods: Independent Tuning of Surface Plasmon Energy, Extinction Coe Ffi Cient, and Scattering Cross Section (2014) J. Phys. Chem. C, 118 (11), pp. 5918-5926
• Natrajan, V.K., Christensen, K.T., Two-Color Laser-Induced Fluorescent Thermometry for Microfluidic Systems (2009) Meas. Sci. Technol., 20 (1), p. 15401
• MacKey, M.A., Ali, M.R.K., Austin, L.A., Near, R.D., El-Sayed, M.A., The Most Effective Gold Nanorod Size for Plasmonic Photothermal Therapy: Theory and in Vitro Experiments (2014) J. Phys. Chem. B, 118 (5), pp. 1319-1326
• Neumann, O., Urban, A.S., Day, J., Lal, S., Nordlander, P., Halas, N.J., Solar Vapor Generation Enabled by Nanoparticles (2013) ACS Nano, 7 (1), pp. 42-49
• Mayilo, S., Kloster, M.A., Wunderlich, M., Lutich, A., Klar, T.A., Nichtl, A., Kürzinger, K., Feldmann, J., Long-Range Fluorescence Quenching by Gold Nanoparticles in a Sandwich Immunoassay for Cardiac Troponin T (2009) Nano Lett., 9 (12), pp. 4558-4563

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