Small-Molecule-Based Fluorescent Sensors for Selective Detection of Reactive Oxygen Species in Biological Systems

Literature Cited

1. 1. 

   Dickinson BC, Chang CJ. 2011. Chemistry and biology of reactive oxygen species in signaling or stress responses. Nat. Chem. Biol. 7:504–11
   [Google Scholar]
2. 2. 

   Winterbourn CC. 2008. Reconciling the chemistry and biology of reactive oxygen species. Nat. Chem. Biol. 4:278–86
   [Google Scholar]
3. 3. 

   Cross CE, Halliwell B, Borish ET, Pryor WA, Arnes BN et al. 1987. Oxygen radicals and human disease. Ann. Intern. Med. 107:526–45
   [Google Scholar]
4. 4. 

   Boveris A, Repetto MG. 2016. Mitochondria are the main cellular source of O₂⁻, H₂O₂ and oxidative stress. Biochemistry of Oxidative Stress: Physiopathology and Clinical Aspects RJ Gelpi, A Boveris, JJ Poderoso 23–35 Cham, Switz.: Springer
   [Google Scholar]
5. 5. 

   Cadenas E, Davies KJ. 2000. Mitochondrial free radical generation, oxidative stress, and aging. Free Radic. Biol. Med. 29:222–30
   [Google Scholar]
6. 6. 

   Gaut JP, Yeh GC, Tran HD, Byun J, Henderson JP et al. 2001. Neutrophils employ the myeloperoxidase system to generate antimicrobial brominating and chlorinating oxidants during sepsis. PNAS 98:11961–66
   [Google Scholar]
7. 7. 

   Du J, Wagner BA, Buettner GR, Cullen JJ 2015. The role of labile iron in the toxicity of pharmacological ascorbate. Free Radic. Biol. Med. 84:289–95
   [Google Scholar]
8. 8. 

   Radi R. 2018. Oxygen radicals, nitric oxide, and peroxynitrite: redox pathways in molecular medicine. PNAS 115:5839–48
   [Google Scholar]
9. 9. 

   Pham-Huy LA, He H, Pham-Huy C 2008. Free radicals, antioxidants in disease and health. Int. J. Biomed. Sci. 4:89–96
   [Google Scholar]
10. 10. 

    Schieber M, Chandel Navdeep S 2014. ROS function in redox signaling and oxidative stress. Curr. Biol. 24:453–62
    [Google Scholar]
11. 11. 

    Rani V, Deep G, Singh RK, Palle K, Yadav UCS 2016. Oxidative stress and metabolic disorders: Pathogenesis and therapeutic strategies. Life Sci 148:183–93
    [Google Scholar]
12. 12. 

    DeBerardinis RJ, Lum JJ, Hatzivassiliou G, Thompson CB 2008. The biology of cancer: metabolic reprogramming fuels cell growth and proliferation. Cell Metab 7:11–20
    [Google Scholar]
13. 13. 

    Khare A, Raundhal M, Chakraborty K, Das S, Corey C et al. 2016. Mitochondrial H₂O₂ in lung antigen-presenting cells blocks NF-κB activation to prevent unwarranted immune activation. Cell Rep 15:1700–14
    [Google Scholar]
14. 14. 

    Ishikawa K, Takenaga K, Akimoto M, Koshikawa N, Yamaguchi A et al. 2008. ROS-generating mitochondrial DNA mutations can regulate tumor cell metastasis. Science 320:661–64
    [Google Scholar]
15. 15. 

    Lukyanov KA, Belousov VV. 2014. Genetically encoded fluorescent redox sensors. Biochim. Biophys. Acta 1840:745–56
    [Google Scholar]
16. 16. 

    Wardman P. 2007. Fluorescent and luminescent probes for measurement of oxidative and nitrosative species in cells and tissues: progress, pitfalls, and prospects. Free Radic. Biol. Med. 43:995–1022
    [Google Scholar]
17. 17. 

    Winterbourn CC. 2014. The challenges of using fluorescent probes to detect and quantify specific reactive oxygen species in living cells. Biochim. Biophys. Acta 1840:730–38
    [Google Scholar]
18. 18. 

    LeBel CP, Ischiropoulos H, Bondy SC 1992. Evaluation of the probe 2′,7′-dichlorofluorescin as an indicator of reactive oxygen species formation and oxidative stress. Chem. Res. Toxicol. 5:227–31
    [Google Scholar]
19. 19. 

    Wrona M, Patel K, Wardman P 2005. Reactivity of 2′,7′-dichlorodihydrofluorescein and dihydrorhodamine 123 and their oxidized forms toward carbonate, nitrogen dioxide, and hydroxyl radicals. Free Radic. Biol. Med. 38:262–70
    [Google Scholar]
20. 20. 

    Wrona M, Wardman P. 2006. Properties of the radical intermediate obtained on oxidation of 2′,7′-dichlorodihydrofluorescein, a probe for oxidative stress. Free Radic. Biol. Med. 41:657–67
    [Google Scholar]
21. 21. 

    Marchesi E, Rota C, Fann YC, Chignell CF, Mason RP 1999. Photoreduction of the fluorescent dye 2′-7′-dichlorofluorescein: a spin trapping and direct electron spin resonance study with implications for oxidative stress measurements. Free Radic. Biol. Med. 26:148–61
    [Google Scholar]
22. 22. 

    Dikalov SI, Harrison DG. 2014. Methods for detection of mitochondrial and cellular reactive oxygen species. Antioxid. Redox Signal. 20:372–82
    [Google Scholar]
23. 23. 

    Zhao H, Joseph J, Fales HM, Sokoloski EA, Levine RL et al. 2005. Detection and characterization of the product of hydroethidine and intracellular superoxide by HPLC and limitations of fluorescence. PNAS 102:5727–32
    [Google Scholar]
24. 24. 

    Setsukinai K-I, Urano Y, Kakinuma K, Majima HJ, Nagano T 2003. Development of novel fluorescence probes that can reliably detect reactive oxygen species and distinguish specific species. J. Biol. Chem. 278:3170–75
    [Google Scholar]
25. 25. 

    Kohanski MA, Dwyer DJ, Hayete B, Lawrence CA, Collins JJ 2007. A common mechanism of cellular death induced by bactericidal antibiotics. Cell 130:797–810
    [Google Scholar]
26. 26. 

    Dwyer DJ, Belenky PA, Yang JH, MacDonald IC, Martell JD et al. 2014. Antibiotics induce redox-related physiological alterations as part of their lethality. PNAS 111:E2100–9
    [Google Scholar]
27. 27. 

    Imlay JA 2008. Cellular defenses against superoxide and hydrogen peroxide. Annu. Rev. Biochem. 77:755–76
    [Google Scholar]
28. 28. 

    Murphy MP 2009. How mitochondria produce reactive oxygen species. Biochem. J. 417:1–13
    [Google Scholar]
29. 29. 

    Shchepinova MM, Cairns AG, Prime TA, Logan A, James AM et al. 2017. MitoNeoD: a mitochondria-targeted superoxide probe. Cell Chem. Biol. 24:1285–98
    [Google Scholar]
30. 30. 

    Arias-Mayenco I, González-Rodríguez P, Torres-Torrelo H, Gao L, Fernández-Agüera MC et al. 2018. Acute O₂ sensing: role of coenzyme QH₂/Q ratio and mitochondrial ROS compartmentalization. Cell Metab 28:145–58
    [Google Scholar]
31. 31. 

    Alabed Alibrahim E, Andriantsitohaina R, Hardonnière K, Soleti R, Faure S, Simard G 2018. A redox-sensitive signaling pathway mediates pro-angiogenic effect of chlordecone via estrogen receptor activation. Int. J. Biochem. Cell. 97:83–97
    [Google Scholar]
32. 32. 

    Jing GJ, Hua XK, Bo T, Ling YL, Wen YG, Guo AL 2007. Selective detection of superoxide anion radicals generated from macrophages by using a novel fluorescent probe. FEBS J 274:1725–33
    [Google Scholar]
33. 33. 

    Li P, Zhang W, Li K, Liu X, Xiao H et al. 2013. Mitochondria-targeted reaction-based two-photon fluorescent probe for imaging of superoxide anion in live cells and in vivo. Anal. Chem. 85:9877–81
    [Google Scholar]
34. 34. 

    Chen JH, Ho C-T. 1997. Antioxidant activities of caffeic acid and its related hydroxycinnamic acid compounds. J. Agric. Food Chem. 45:2374–78
    [Google Scholar]
35. 35. 

    Zhang W, Li P, Yang F, Hu X, Sun C et al. 2013. Dynamic and reversible fluorescence imaging of superoxide anion fluctuations in live cells and in vivo. J. Am. Chem. Soc. 135:14956–59
    [Google Scholar]
36. 36. 

    Zhang W, Wang X, Li P, Huang F, Wang H et al. 2015. Elucidating the relationship between superoxide anion levels and lifespan using an enhanced two-photon fluorescence imaging probe. Chem. Commun. 51:9710–13
    [Google Scholar]
37. 37. 

    Zhang W, Wang X, Li P, Xiao H, Zhang W et al. 2017. Illuminating superoxide anion and pH enhancements in apoptosis of breast cancer cells induced by mitochondrial hyperfusion using a new two-photon fluorescence probe. Anal. Chem. 89:6840–45
    [Google Scholar]
38. 38. 

    Maeda H, Yamamoto K, Nomura Y, Kohno I, Hafsi L et al. 2005. A design of fluorescent probes for superoxide based on a nonredox mechanism. J. Am. Chem. Soc. 127:68–69
    [Google Scholar]
39. 39. 

    Hatsuo M, Kayoko Y, Iho K, Leila H, Norio I et al. 2007. Design of a practical fluorescent probe for superoxide based on protection–deprotection chemistry of fluoresceins with benzenesulfonyl protecting groups. Chem. Eur. J. 13:1946–54
    [Google Scholar]
40. 40. 

    Xu K, Liu X, Tang B, Yang G, Yang Y, An L 2007. Design of a phosphinate‐based fluorescent probe for superoxide detection in mouse peritoneal macrophages. Chem. Eur. J. 13:1411–16
    [Google Scholar]
41. 41. 

    Hu JJ, Wong N-K, Ye S, Chen X, Lu M-Y et al. 2015. Fluorescent probe HKSOX-1 for imaging and detection of endogenous superoxide in live cells and in vivo. J. Am. Chem. Soc. 137:6837–43
    [Google Scholar]
42. 42. 

    Lu D, Zhou L, Wang R, Zhang X-B, He L et al. 2017. A two-photon fluorescent probe for endogenous superoxide anion radical detection and imaging in living cells and tissues. Sens. Actuators B 250:259–66
    [Google Scholar]
43. 43. 

    Han X, Wang R, Song X, Yu F, Lv C, Chen L 2018. A mitochondrial-targeting near-infrared fluorescent probe for bioimaging and evaluating endogenous superoxide anion changes during ischemia/reperfusion injury. Biomaterials 156:134–46
    [Google Scholar]
44. 44. 

    Lu X, Chen Z, Dong X, Zhao W 2018. Water-soluble fluorescent probe with dual mitochondria/lysosome targetability for selective superoxide detection in live cells and in zebrafish embryos. ACS Sensors 3:59–64
    [Google Scholar]
45. 45. 

    Veal EA, Day AM, Morgan BA 2007. Hydrogen peroxide sensing and signaling. Mol. Cell 26:1–14
    [Google Scholar]
46. 46. 

    Azad MB, Chen Y, Gibson SB 2009. Regulation of autophagy by reactive oxygen species (ROS): implications for cancer progression and treatment. Antioxid. Redox Signal. 11:777–90
    [Google Scholar]
47. 47. 

    Burgoyne JR, Madhani M, Cuello F, Charles RL, Brennan JP et al. 2007. Cysteine redox sensor in PKGIα enables oxidant-induced activation. Science 317:1393–97
    [Google Scholar]
48. 48. 

    Zhou M, Diwu Z, Panchuk-Voloshina N, Haugland RP 1997. A stable nonfluorescent derivative of resorufin for the fluorometric determination of trace hydrogen peroxide: applications in detecting the activity of phagocyte NADPH oxidase and other oxidases. Anal. Biochem. 253:162–68
    [Google Scholar]
49. 49. 

    Reszka KJ, Wagner BA, Burns CP, Britigan BE 2005. Effects of peroxidase substrates on the Amplex red/peroxidase assay: antioxidant properties of anthracyclines. Anal. Biochem. 342:327–37
    [Google Scholar]
50. 50. 

    Zhao B, Summers FA, Mason RP 2012. Photooxidation of Amplex Red to resorufin: implications of exposing the Amplex Red assay to light. Free Radic. Biol. Med. 53:1080–87
    [Google Scholar]
51. 51. 

    Dębski D, Smulik R, Zielonka J, Michałowski B, Jakubowska M et al. 2016. Mechanism of oxidative conversion of Amplex^® Red to resorufin: pulse radiolysis and enzymatic studies. Free Radic. Biol. Med. 95:323–32
    [Google Scholar]
52. 52. 

    Chang MCY, Pralle A, Isacoff EY, Chang CJ 2004. A selective, cell-permeable optical probe for hydrogen peroxide in living cells. J. Am. Chem. Soc. 126:15392–93
    [Google Scholar]
53. 53. 

    Miller EW, Albers AE, Pralle A, Isacoff EY, Chang CJ 2005. Boronate-based fluorescent probes for imaging cellular hydrogen peroxide. J. Am. Chem. Soc. 127:16652–59
    [Google Scholar]
54. 54. 

    Dickinson BC, Huynh C, Chang CJ 2010. A palette of fluorescent probes with varying emission colors for imaging hydrogen peroxide signaling in living cells. J. Am. Chem. Soc. 132:5906–15
    [Google Scholar]
55. 55. 

    Srikun D, Miller EW, Domaille DW, Chang CJ 2008. An ICT-based approach to ratiometric fluorescence imaging of hydrogen peroxide produced in living cells. J. Am. Chem. Soc. 130:4596–97
    [Google Scholar]
56. 56. 

    Dickinson BC, Chang CJ. 2008. A targetable fluorescent probe for imaging hydrogen peroxide in the mitochondria of living cells. J. Am. Chem. Soc. 130:9638–39
    [Google Scholar]
57. 57. 

    Dickinson BC, Tang Y, Chang Z, Chang CJ 2011. A nuclear-localized fluorescent hydrogen peroxide probe for monitoring sirtuin-mediated oxidative stress responses in vivo. Chem. Biol. 18:943–48
    [Google Scholar]
58. 58. 

    Miller EW, Tulyathan O, Isacoff EY, Chang CJ 2007. Molecular imaging of hydrogen peroxide produced for cell signaling. Nat. Chem. Biol. 3:263–67
    [Google Scholar]
59. 59. 

    Lippert AR, Van de Bittner GC, Chang CJ 2011. Boronate oxidation as a bioorthogonal reaction approach for studying the chemistry of hydrogen peroxide in living systems. Acc. Chem. Res. 44:793–804
    [Google Scholar]
60. 60. 

    Sikora A, Zielonka J, Lopez M, Joseph J, Kalyanaraman B 2009. Direct oxidation of boronates by peroxynitrite: mechanism and implications in fluorescence imaging of peroxynitrite. Free Radic. Biol. Med. 47:1401–7
    [Google Scholar]
61. 61. 

    Sawaki Y, Foote CS. 1979. Acyclic mechanism in the cleavage of benzils with alkaline hydrogen peroxide. J. Am. Chem. Soc. 101:6292–96
    [Google Scholar]
62. 62. 

    Abo M, Urano Y, Hanaoka K, Terai T, Komatsu T, Nagano T 2011. Development of a highly sensitive fluorescence probe for hydrogen peroxide. J. Am. Chem. Soc. 133:10629–37
    [Google Scholar]
63. 63. 

    Abo M, Minakami R, Miyano K, Kamiya M, Nagano T et al. 2014. Visualization of phagosomal hydrogen peroxide production by a novel fluorescent probe that is localized via SNAP-tag labeling. Anal. Chem. 86:5983–90
    [Google Scholar]
64. 64. 

    Xie X, Yang X, Wu T, Li Y, Li M et al. 2016. Rational design of an α-ketoamide-based near-infrared fluorescent probe specific for hydrogen peroxide in living systems. Anal. Chem. 88:8019–25
    [Google Scholar]
65. 65. 

    Ye S, Hu JJ, Yang D 2018. Tandem Payne/Dakin reaction: a new strategy for hydrogen peroxide detection and molecular imaging. Angew. Chem. Int. Ed. 57:10173–77
    [Google Scholar]
66. 66. 

    Ferrer-Sueta G, Campolo N, Trujillo M, Bartesaghi S, Carballal S et al. 2018. Biochemistry of peroxy-nitrite and protein tyrosine nitration. Chem. Rev. 118:1338–408
    [Google Scholar]
67. 67. 

    Bonini MG, Augusto O. 2001. Carbon dioxide stimulates the production of thiyl, sulfinyl, and disulfide radical anion from thiol oxidation by peroxynitrite. J. Biol. Chem. 276:9749–54
    [Google Scholar]
68. 68. 

    Trujillo M, Folkes L, Bartesaghi S, Kalyanaraman B, Wardman P, Radi R 2005. Peroxynitrite-derived carbonate and nitrogen dioxide radicals readily react with lipoic and dihydrolipoic acid. Free Radic. Biol. Med. 39:279–88
    [Google Scholar]
69. 69. 

    Yang D, Wang H-L, Sun Z-N, Chung N-W, Shen J-G 2006. A highly selective fluorescent probe for the detection and imaging of peroxynitrite in living cells. J. Am. Chem. Soc. 128:6004–5
    [Google Scholar]
70. 70. 

    Sun Z-N, Wang H-L, Liu F-Q, Chen Y, Tam PKH, Yang D 2009. BODIPY-based fluorescent probe for peroxynitrite detection and imaging in living cells. Org. Lett. 11:1887–90
    [Google Scholar]
71. 71. 

    Peng T, Yang D. 2010. HKGreen-3: a rhodol-based fluorescent probe for peroxynitrite. Org. Lett. 12:4932–35
    [Google Scholar]
72. 72. 

    Peng T, Wong N-K, Chen X, Chan Y-K, Ho DH-H et al. 2014. Molecular imaging of peroxynitrite with HKGreen-4 in live cells and tissues. J. Am. Chem. Soc. 136:11728–34
    [Google Scholar]
73. 73. 

    Peng T, Chen X, Gao L, Zhang T, Wang W et al. 2016. A rationally designed rhodamine-based fluorescent probe for molecular imaging of peroxynitrite in live cells and tissues. Chem. Sci. 7:5407–13
    [Google Scholar]
74. 74. 

    Chen X, Zhou B, Yan T, Wu H, Feng J et al. 2018. Peroxynitrite enhances self-renewal, proliferation and neuronal differentiation of neural stem/progenitor cells through activating HIF-1α and Wnt/β-catenin signaling pathway. Free Radic. Biol. Med. 117:158–67
    [Google Scholar]
75. 75. 

    Feng J, Chen X, Lu S, Li W, Yang D et al. 2018. Naringin attenuates cerebral ischemia-reperfusion injury through inhibiting peroxynitrite-mediated mitophagy activation. Mol. Neurobiol. 55:9029–42
    [Google Scholar]
76. 76. 

    Li X, Tao R-R, Hong L-J, Cheng J, Jiang Q et al. 2015. Visualizing peroxynitrite fluxes in endothelial cells reveals the dynamic progression of brain vascular injury. J. Am. Chem. Soc. 137:12296–303
    [Google Scholar]
77. 77. 

    Li J, Lim CS, Kim G, Kim HM, Yoon J 2017. Highly selective and sensitive two-photon fluorescence probe for endogenous peroxynitrite detection and its applications in living cells and tissues. Anal. Chem. 89:8496–500
    [Google Scholar]
78. 78. 

    Zhang H, Liu J, Sun Y-Q, Huo Y, Li Y et al. 2015. A mitochondria-targetable fluorescent probe for peroxynitrite: fast response and high selectivity. Chem. Commun. 51:2721–24
    [Google Scholar]
79. 79. 

    Prolo C, Rios N, Piacenza L, Álvarez MN, Radi R 2018. Fluorescence and chemiluminescence approaches for peroxynitrite detection. Free Radic. Biol. Med. 128:59–68
    [Google Scholar]
80. 80. 

    Rios N, Piacenza L, Trujillo M, Martínez A, Demicheli V et al. 2016. Sensitive detection and estimation of cell-derived peroxynitrite fluxes using fluorescein-boronate. Free Radic. Biol. Med. 101:284–95
    [Google Scholar]
81. 81. 

    Nogueira CW, Zeni G, Rocha JBT 2004. Organoselenium and organotellurium compounds: toxicology and pharmacology. Chem. Rev. 104:6255–86
    [Google Scholar]
82. 82. 

    Yu F, Li P, Li G, Zhao G, Chu T, Han K 2011. A near-IR reversible fluorescent probe modulated by selenium for monitoring peroxynitrite and imaging in living cells. J. Am. Chem. Soc. 133:11030–33
    [Google Scholar]
83. 83. 

    Xu K, Chen H, Tian J, Ding B, Xie Y et al. 2011. A near-infrared reversible fluorescent probe for peroxynitrite and imaging of redox cycles in living cells. Chem. Commun. 47:9468–70
    [Google Scholar]
84. 84. 

    Yu F, Li P, Wang B, Han K 2013. Reversible near-infrared fluorescent probe introducing tellurium to mimetic glutathione peroxidase for monitoring the redox cycles between peroxynitrite and glutathione in vivo. J. Am. Chem. Soc. 135:7674–80
    [Google Scholar]
85. 85. 

    Wang B, Li P, Yu F, Song P, Sun X et al. 2013. A reversible fluorescence probe based on Se-BODIPY for the redox cycle between HClO oxidative stress and H₂S repair in living cells. Chem. Commun. 49:1014–16
    [Google Scholar]
86. 86. 

    Zhang W, Liu W, Li P, Kang J, Wang J et al. 2015. Reversible two-photon fluorescent probe for imaging of hypochlorous acid in live cells and in vivo. Chem. Commun. 51:10150–53
    [Google Scholar]
87. 87. 

    Venkatesan P, Wu S-P. 2015. A turn-on fluorescent probe for hypochlorous acid based on the oxidation of diphenyl telluride. Analyst 140:1349–55
    [Google Scholar]
88. 88. 

    Pullar JM, Vissers MCM, Winterbourn CC 2000. Living with a killer: the effects of hypochlorous acid on mammalian cells. IUBMB Life 50:259–66
    [Google Scholar]
89. 89. 

    Storkey C, Davies MJ, Pattison DI 2014. Reevaluation of the rate constants for the reaction of hypochlorous acid (HOCl) with cysteine, methionine, and peptide derivatives using a new competition kinetic approach. Free Radic. Biol. Med. 73:60–66
    [Google Scholar]
90. 90. 

    Sun Z-N, Liu F-Q, Chen Y, Tam PKH, Yang D 2008. A highly specific BODIPY-based fluorescent probe for the detection of hypochlorous acid. Org. Lett. 10:2171–74
    [Google Scholar]
91. 91. 

    Hu JJ, Wong N-K, Gu Q, Bai X, Ye S, Yang D 2014. HKOCl-2 series of green BODIPY-based fluorescent probes for hypochlorous acid detection and imaging in live cells. Org. Lett. 16:3544–47
    [Google Scholar]
92. 92. 

    Hu JJ, Wong N-K, Lu M-Y, Chen X, Ye S et al. 2016. HKOCl-3: a fluorescent hypochlorous acid probe for live-cell and in vivo imaging and quantitative application in flow cytometry and a 96-well microplate assay. Chem. Sci. 7:2094–99
    [Google Scholar]
93. 93. 

    Koide Y, Urano Y, Kenmoku S, Kojima H, Nagano T 2007. Design and synthesis of fluorescent probes for selective detection of highly reactive oxygen species in mitochondria of living cells. J. Am. Chem. Soc. 129:10324–25
    [Google Scholar]
94. 94. 

    Guo T, Cui L, Shen J, Wang R, Zhu W et al. 2013. A dual-emission and large Stokes shift fluorescence probe for real-time discrimination of ROS/RNS and imaging in live cells. Chem. Commun. 49:1862–64
    [Google Scholar]
95. 95. 

    Shepherd J, Hilderbrand SA, Waterman P, Heinecke JW, Weissleder R, Libby P 2007. A fluorescent probe for the detection of myeloperoxidase activity in atherosclerosis-associated macrophages. Chem. Biol. 14:1221–31
    [Google Scholar]
96. 96. 

    Chen S, Lu J, Sun C, Ma H 2010. A highly specific ferrocene-based fluorescent probe for hypochlorous acid and its application to cell imaging. Analyst 135:577–82
    [Google Scholar]
97. 97. 

    Park J, Kim H, Choi Y, Kim Y 2013. A ratiometric fluorescent probe based on a BODIPY-DCDHF conjugate for the detection of hypochlorous acid in living cells. Analyst 138:3368–71
    [Google Scholar]
98. 98. 

    Xiao H, Li J, Zhao J, Yin G, Quan Y et al. 2015. A colorimetric and ratiometric fluorescent probe for ClO⁻ targeting in mitochondria and its application in vivo. J. Mater. Chem. B 3:1633–38
    [Google Scholar]
99. 99. 

    Wu Y, Wang J, Zeng F, Huang S, Huang J et al. 2016. Pyrene derivative emitting red or near-infrared light with monomer/excimer conversion and its application to ratiometric detection of hypochlorite. ACS Appl. Mater. Interfaces 8:1511–19
    [Google Scholar]
100. 100. 

     Zhang Z, Fan J, Cheng G, Ghazali S, Du J, Peng X 2017. Fluorescence completely separated ratiometric probe for HClO in lysosomes. Sens. Actuators B 246:293–99
     [Google Scholar]
101. 101. 

     Weiying L, Lingliang L, Bingbing C, Wen T 2009. A ratiometric fluorescent probe for hypochlorite based on a deoximation reaction. Chem. Eur. J. 15:2305–9
     [Google Scholar]
102. 102. 

     Shi J, Li Q, Zhang X, Peng M, Qin J, Li Z 2010. Simple triphenylamine-based luminophore as a hypochlorite chemosensor. Sens. Actuators B 145:583–87
     [Google Scholar]
103. 103. 

     Cheng G, Fan J, Sun W, Sui K, Jin X et al. 2013. A highly specific BODIPY-based probe localized in mitochondria for HClO imaging. Analyst 138:6091–96
     [Google Scholar]
104. 104. 

     Yuan L, Lin W, Song J, Yang Y 2011. Development of an ICT-based ratiometric fluorescent hypochlorite probe suitable for living cell imaging. Chem. Commun. 47:12691–93
     [Google Scholar]
105. 105. 

     Goswami S, Paul S, Manna A 2013. Highly reactive (<1 min) ratiometric “naked eye” detection of hypochlorite with real application in tap water. Dalton Trans 42:10097–101
     [Google Scholar]
106. 106. 

     Wu W-L, Zhao Z-M, Dai X, Su L, Zhao B-X 2016. A fast-response colorimetric and fluorescent probe for hypochlorite and its real applications in biological imaging. Sens. Actuators B 232:390–95
     [Google Scholar]
107. 107. 

     Yue Y, Huo F, Yin C, Escobedo JO, Strongin RM 2016. Recent progress in chromogenic and fluorogenic chemosensors for hypochlorous acid. Analyst 141:1859–73
     [Google Scholar]
108. 108. 

     Zhang Z, Zheng Y, Hang W, Yan X, Zhao Y 2011. Sensitive and selective off–on rhodamine hydrazide fluorescent chemosensor for hypochlorous acid detection and bioimaging. Talanta 85:779–86
     [Google Scholar]
109. 109. 

     Zhang Y-R, Zhao Z-M, Miao J-Y, Zhao B-X 2016. A ratiometric fluorescence probe based on a novel FRET platform for imaging endogenous HOCl in the living cells. Sens. Actuators B 229:408–13
     [Google Scholar]
110. 110. 

     Zhang Y-R, Zhao Z-M, Su L, Miao J-Y, Zhao B-X 2016. A ratiometric fluorescence sensor for HOCl based on a FRET platform and application in living cells. RSC Adv 6:17059–63
     [Google Scholar]
111. 111. 

     Hou J-T, Li K, Yang J, Yu K-K, Liao Y-X et al. 2015. A ratiometric fluorescent probe for in situ quantification of basal mitochondrial hypochlorite in cancer cells. Chem. Commun. 51:6781–84
     [Google Scholar]
112. 112. 

     Hou J-T, Wu M-Y, Li K, Yang J, Yu K-K et al. 2014. Mitochondria-targeted colorimetric and fluorescent probes for hypochlorite and their applications for in vivo imaging. Chem. Commun. 50:8640–43
     [Google Scholar]
113. 113. 

     Zhang Y-R, Liu Y, Feng X, Zhao B-X 2017. Recent progress in the development of fluorescent probes for the detection of hypochlorous acid. Sens. Actuators B 240:18–36
     [Google Scholar]
114. 114. 

     Zhou J, Li L, Shi W, Gao X, Li X, Ma H 2015. HOCl can appear in the mitochondria of macrophages during bacterial infection as revealed by a sensitive mitochondrial-targeting fluorescent probe. Chem. Sci. 6:4884–88
     [Google Scholar]
115. 115. 

     Koide Y, Urano Y, Hanaoka K, Terai T, Nagano T 2011. Development of an Si-rhodamine-based far-red to near-infrared fluorescence probe selective for hypochlorous acid and its applications for biological imaging. J. Am. Chem. Soc. 133:5680–82
     [Google Scholar]
116. 116. 

     Chen X, Lee K-A, Ha E-M, Lee KM, Seo YY et al. 2011. A specific and sensitive method for detection of hypochlorous acid for the imaging of microbe-induced HOCl production. Chem. Commun. 47:4373–75
     [Google Scholar]
117. 117. 

     Xu Q, Heo CH, Kim G, Lee HW, Kim HM, Yoon J 2015. Development of imidazoline-2-thiones based two-photon fluorescence probes for imaging hypochlorite generation in a co-culture system. Angew. Chem. Int. Ed. 54:4890–94
     [Google Scholar]
118. 118. 

     Xu Q, Heo CH, Kim JA, Lee HS, Hu Y et al. 2016. A selective imidazoline-2-thione-bearing two-photon fluorescent probe for hypochlorous acid in mitochondria. Anal. Chem. 88:6615–20
     [Google Scholar]
119. 119. 

     Liu S-R, Vedamalai M, Wu S-P 2013. Hypochlorous acid turn-on boron dipyrromethene probe based on oxidation of methyl phenyl sulfide. Anal. Chim. Acta 800:71–76
     [Google Scholar]
120. 120. 

     Lou Z, Li P, Pan Q, Han K 2013. A reversible fluorescent probe for detecting hypochloric acid in living cells and animals: utilizing a novel strategy for effectively modulating the fluorescence of selenide and selenoxide. Chem. Commun. 49:2445–47
     [Google Scholar]
121. 121. 

     Zhou Y, Li J-Y, Chu K-H, Liu K, Yao C, Li J-Y 2012. Fluorescence turn-on detection of hypochlorous acid via HOCl-promoted dihydrofluorescein-ether oxidation and its application in vivo. Chem. Commun. 48:4677–79
     [Google Scholar]
122. 122. 

     Zhu H, Fan J, Wang J, Mu H, Peng X 2014. An “enhanced PET”-based fluorescent probe with ultrasensitivity for imaging basal and elesclomol-induced HClO in cancer cells. J. Am. Chem. Soc. 136:12820–23
     [Google Scholar]
123. 123. 

     Wei P, Yuan W, Xue F, Zhou W, Li R et al. 2018. Deformylation reaction-based probe for in vivo imaging of HOCl. Chem. Sci. 9:495–501
     [Google Scholar]
124. 124. 

     Balasubramanian B, Pogozelski WK, Tullius TD 1998. DNA strand breaking by the hydroxyl radical is governed by the accessible surface areas of the hydrogen atoms of the DNA backbone. PNAS 95:9738–43
     [Google Scholar]
125. 125. 

     Wolff SP, Garner A, Dean RT 1986. Free radicals, lipids and protein degradation. Trends Biochem. Sci. 11:27–31
     [Google Scholar]
126. 126. 

     Britigan BE, Coffman TJ, Buettner GR 1990. Spin trapping evidence for the lack of significant hydroxyl radical production during the respiration burst of human phagocytes using a spin adduct resistant to superoxide-mediated destruction. J. Biol. Chem. 265:2650–56
     [Google Scholar]
127. 127. 

     Grootveld M, Halliwell B. 1986. Aromatic hydroxylation as a potential measure of hydroxyl-radical formation in vivo. Identification of hydroxylated derivatives of salicylate in human body fluids. Biochem. J. 237:499–504
     [Google Scholar]
128. 128. 

     Yang X-F, Guo X-Q. 2001. Investigation of the anthracene-nitroxide hybrid molecule as a probe for hydroxyl radicals. Analyst 126:1800–04
     [Google Scholar]
129. 129. 

     Yang X-F, Guo X-Q. 2001. Study of nitroxide-linked naphthalene as a fluorescence probe for hydroxyl radicals. Anal. Chim. Acta 434:169–77
     [Google Scholar]
130. 130. 

     Maki T, Soh N, Fukaminato T, Nakajima H, Nakano K, Imato T 2009. Perylenebisimide-linked nitroxide for the detection of hydroxyl radicals. Anal. Chim. Acta 639:78–82
     [Google Scholar]
131. 131. 

     Li P, Xie T, Duan X, Yu F, Wang X, Tang B 2010. A new highly selective and sensitive assay for fluorescence imaging of ^•OH in living cells: effectively avoiding the interference of peroxynitrite. Chem. Eur. J. 16:1834–40
     [Google Scholar]
132. 132. 

     Yapici NB, Jockusch S, Moscatelli A, Mandalapu SR, Itagaki Y et al. 2012. New rhodamine nitroxide based fluorescent probes for intracellular hydroxyl radical identification in living cells. Org. Lett. 14:50–53
     [Google Scholar]
133. 133. 

     Cao L, Wu Q, Li Q, Shao S, Guo Y 2014. Fluorescence and HPLC detection of hydroxyl radical by a rhodamine-nitroxide probe and its application in cell imaging. J. Fluoresc. 24:313–18
     [Google Scholar]
134. 134. 

     Cui G, Ye Z, Chen J, Wang G, Yuan J 2011. Development of a novel terbium(III) chelate-based luminescent probe for highly sensitive time-resolved luminescence detection of hydroxyl radical. Talanta 84:971–76
     [Google Scholar]
135. 135. 

     Zhuang M, Ding C, Zhu A, Tian Y 2014. Ratiometric fluorescence probe for monitoring hydroxyl radical in live cells based on gold nanoclusters. Anal. Chem. 86:1829–36
     [Google Scholar]
136. 136. 

     Bai X, Huang Y, Lu M, Yang D 2017. HKOH-1: a highly sensitive and selective fluorescent probe for detecting endogenous hydroxyl radicals in living cells. Angew. Chem. Int. Ed. 56:12873–77
     [Google Scholar]
137. 137. 

     Manevich Y, Held KD, Biaglow JE 1997. Coumarin-3-carboxylic acid as a detector for hydroxyl radicals generated chemically and by gamma radiation. Radiat. Res. 148:580–91
     [Google Scholar]
138. 138. 

     Ganea GM, Kolic PE, El-Zahab B, Warner IM 2011. Ratiometric coumarin−neutral red (CONER) nanoprobe for detection of hydroxyl radicals. Anal. Chem. 83:2576–81
     [Google Scholar]
139. 139. 

     Yu M, Zhang G, Wang W, Niu J, Zhang N 2012. Fluorescence sensing and intracellular imaging for hydroxyl radical using coumarin-modified cyclodextrin derivatives. Supramol. Chem. 24:799–802
     [Google Scholar]
140. 140. 

     Hai X, Guo Z, Lin X, Chen X, Wang J 2018. Fluorescent TPA@GQDs probe for sensitive assay and quantitative imaging of hydroxyl radicals in living cells. ACS Appl. Mater. Interfaces 10:5853–61
     [Google Scholar]
141. 141. 

     Yuan L, Lin W, Song J 2010. Ratiometric fluorescent detection of intracellular hydroxyl radicals based on a hybrid coumarin-cyanine platform. Chem. Commun. 46:7930–32
     [Google Scholar]
142. 142. 

     Kim M, Ko S-K, Kim H, Shin I, Tae J 2013. Rhodamine cyclic hydrazide as a fluorescent probe for the detection of hydroxyl radicals. Chem. Commun. 49:7959–61
     [Google Scholar]
143. 143. 

     Soh N, Makihara K, Sakoda E, Imato T 2004. A ratiometric fluorescent probe for imaging hydroxyl radicals in living cells. Chem. Commun. 2004:496–97
     [Google Scholar]
144. 144. 

     Tang B, Zhang N, Chen Z, Xu K, Zhuo L et al. 2008. Probing hydroxyl radicals and their imaging in living cells by use of FAM–DNA–Au nanoparticles. Chem. Eur. J. 14:522–28
     [Google Scholar]
145. 145. 

     Liu F, Du J, Song D, Xu M, Sun G 2016. A sensitive fluorescent sensor for the detection of endogenous hydroxyl radicals in living cells and bacteria and direct imaging with respect to its ecotoxicity in living zebra fish. Chem. Commun. 52:4636–39
     [Google Scholar]