References
[1] K. Singh, A.M. Rotaru, A.A. Beharry, Fluorescent Chemosensors as Future Tools for Cancer Biology, ACS Chemical Biology 13(7) (2018) 1785-
1798.
5 [2] X. Chen, Y. Zhou, X. Peng, J. Yoon, Fluorescent and colorimetric probes for detection of thiols, Chemical Society Reviews 39(6) (2010) 2120-2135.
[3] M.E. Langmuir, J.-R. Yang, A.M. Moussa, R. Laura, K.A. LeCompte, New naphthopyranone based fluorescent thiol probes, Tetrahedron Letters
36(23) (1995) 3989-3992.
[4] D.P. Li, J.F. Zhang, J. Cui, X.F. Ma, J.T. Liu, J.Y. Miao, B.X. Zhao, A ratiometric fluorescent probe for fast detection of hydrogen sulfide and
recognition of biological thiols, Sensors and Actuators, B: Chemical 234 (2016) 231-238.
10 [5] C. Szabõ, Hydrogen sulphide and its therapeutic potential, Nature Reviews Drug Discovery 6(11) (2007) 917-935.
[6] R. D'Emmanuele Di Villa Bianca, R. Sorrentino, V. Mirone, G. Cirino, Hydrogen sulfide and erectile function: A novel therapeutic target, Nature
Reviews Urology 8(5) (2011) 286-289.
[7] C. Szabo, Gaseotransmitters: New frontiers for translational science, Science Translational Medicine 2(59) (2010).
[8] D. Giuliani, A. Ottani, D. Zaffe, M. Galantucci, F. Strinati, R. Lodi, S. Guarini, Hydrogen sulfide slows down progression of experimental Alzheimer's
15 disease by targeting multiple pathophysiological mechanisms, Neurobiology of Learning and Memory 104 (2013) 82-91.
[9] B.D. Paul, J.I. Sbodio, R. Xu, M.S. Vandiver, J.Y. Cha, A.M. Snowman, S.H. Snyder, Cystathionine γ-lyase deficiency mediates neurodegeneration in
Huntington's disease, Nature 508(7498) (2014) 96-100.
[10] L.F. Hu, M. Lu, C.X. Tiong, G.S. Dawe, G. Hu, J.S. Bian, Neuroprotective effects of hydrogen sulfide on Parkinson's disease rat models, Aging Cell
9(2) (2010) 135-146.
20 [11] Y. Zhao, X. Zhu, H. Kan, W. Wang, B. Zhu, B. Du, X. Zhang, A highly selective colorimetric chemodosimeter for fast and quantitative detection of
hydrogen sulfide, Analyst 137(23) (2012) 5576-5580.
[12] L.A. Montoya, T.F. Pearce, R.J. Hansen, L.N. Zakharov, M.D. Pluth, Development of selective colorimetric probes for hydrogen sulfide based on
nucleophilic aromatic substitution, Journal of Organic Chemistry 78(13) (2013) 6550-6557.
[13] V.K. Gupta, H. Karimi-Maleh, R. Sadegh, Simultaneous determination of hydroxylamine, phenol and sulfite in water and waste water samples using
25 a voltammetric nanosensor, International Journal of Electrochemical Science 10(1) (2015) 303-316.
[14] J. Furne, A. Saeed, M.D. Levitt, Whole tissue hydrogen sulfide concentrations are orders of magnitude lower than presently accepted values,
American Journal of Physiology - Regulatory Integrative and Comparative Physiology 295(5) (2008) R1479-R1485.
[15] U. Hannestad, S. Margheri, B. Sörbo, A sensitive gas chromatographic method for determination of protein-associated sulfur, Analytical
Biochemistry 178(2) (1989) 394-398.
30 [16] A.R. Lippert, E.J. New, C.J. Chang, Reaction-based fluorescent probes for selective imaging of hydrogen sulfide in living cells, Journal of the
American Chemical Society 133(26) (2011) 10078-10080.
[17] H. Peng, Y. Cheng, C. Dai, A.L. King, B.L. Predmore, D.J. Lefer, B. Wang, A fluorescent probe for fast and quantitative detection of hydrogen
sulfide in blood, Angewandte Chemie - International Edition 50(41) (2011) 9672-9675.
[18] W. Sun, J. Fan, C. Hu, J. Cao, H. Zhang, X. Xiong, J. Wang, S. Cui, S. Sun, X. Peng, A two-photon fluorescent probe with near-infrared emission for
35 hydrogen sulfide imaging in biosystems, Chemical Communications 49(37) (2013) 3890-3892.
[19] Y.W. Duan, X.F. Yang, Y. Zhong, Y. Guo, Z. Li, H. Li, A ratiometric fluorescent probe for gasotransmitter hydrogen sulfide based on a coumarin-
benzopyrylium platform, Analytica Chimica Acta 859 (2015) 59-65.
[20] L.A. Montoya, M.D. Pluth, Selective turn-on fluorescent probes for imaging hydrogen sulfide in living cells, Chemical Communications 48(39)
(2012) 4767-4769.
40 [21] M.Y. Wu, K. Li, J.T. Hou, Z. Huang, X.Q. Yu, A selective colorimetric and ratiometric fluorescent probe for hydrogen sulfide, Organic and
Biomolecular Chemistry 10(41) (2012) 8342-8347.
[22] X. Li, J. Cheng, Y. Gong, B. Yang, Y. Hu, Mapping hydrogen sulfide in rats with a novel azo-based fluorescent probe, Biosensors and Bioelectronics
65 (2015) 302-306.
[23] X. Cao, W. Lin, K. Zheng, L. He, A near-infrared fluorescent turn-on probe for fluorescence imaging of hydrogen sulfide in living cells based on
45 thiolysis of dinitrophenyl ether, Chemical Communications 48(85) (2012) 10529-10531.
[24] D. Maity, A. Raj, P.K. Samanta, D. Karthigeyan, T.K. Kundu, S.K. Pati, T. Govindaraju, A probe for ratiometric near-infrared fluorescence and
colorimetric hydrogen sulfide detection and imaging in live cells, RSC Advances 4(22) (2014) 11147-11151.
[25] H. Maeda, H. Matsuno, M. Ushida, K. Katayama, K. Saeki, N. Itoh, 2,4-Dinitrobenzenesulfonyl fluoresceins as fluorescent alternatives to Ellman's
reagent in thiol-quantification enzyme assays, Angewandte Chemie - International Edition 44(19) (2005) 2922-2925.
50 [26] Q. Zhao, F. Huo, J. Kang, Y. Zhang, C. Yin, A novel FRET-based fluorescent probe for the selective detection of hydrogen sulfide (H2S) and its
application for bioimaging, Journal of Materials Chemistry B 6(30) (2018) 4903-4908.
[27] K. Huang, M. Liu, Z. Liu, D. Cao, J. Hou, W. Zeng, Ratiometric and colorimetric detection of hydrogen sulfide with high selectivity and sensitivity
using a novel FRET-based fluorescence probe, Dyes and Pigments 118 (2015) 88-94.
[28] Y. Tang, G.F. Jiang, A novel two-photon fluorescent probe for hydrogen sulfide in living cells using an acedan-NBD amine dyad based on FRET
55 process with high selectivity and sensitivity, New Journal of Chemistry 41(14) (2017) 6769-6774.
[29] L. He, X. Yang, Y. Liu, W. Lin, Colorimetric and ratiometric fluorescent probe for hydrogen sulfide using a coumarin-pyronine FRET dyad with a
large emission shift, Analytical Methods 8(45) (2016) 8022-8027.
[30] C. Wei, L. Wei, Z. Xi, L. Yi, A FRET-based fluorescent probe for imaging H 2 S in living cells, Tetrahedron Letters (2013) 6937-6939.
[31] C. Wei, R. Wang, L. Wei, L. Cheng, Z. Li, Z. Xi, L. Yi, O-fluorination of aromatic azides yields improved azido-based fluorescent probes for
60 hydrogen sulfide: Synthesis, spectra, and bioimaging, Chemistry - An Asian Journal 9(12) (2014) 3586-3592.
[32] L. Yuan, Q.P. Zuo, FRET-based mitochondria-targetable dual-excitation ratiometric fluorescent probe for monitoring hydrogen sulfide in living cells,
Chemistry - An Asian Journal 9(6) (2014) 1544-1549.
[33] B. Chen, P. Wang, Q. Jin, X. Tang, Chemoselective reduction and self-immolation based FRET probes for detecting hydrogen sulfide in solution and
in cells, Organic and Biomolecular Chemistry 12(30) (2014) 5629-5633.
65 [34] J. Zhang, R. Wang, Z. Zhu, L. Yi, Z. Xi, A FRET-based ratiometric fluorescent probe for visualizing H 2 S in lysosomes, Tetrahedron 71(45) (2015)
8572-8576.
[35] K. Huang, L. Yu, P. Xu, X. Zhang, W. Zeng, A novel FRET-based ratiometric fluorescent probe for highly sensitive detection of hydrogen sulfide,
RSC Advances 5(23) (2015) 17797-17801.