Utilization of redox and aggregation properties of methylene blue dye in nanobiophysical investigations

  • В. С. Шелковский
Keywords: methylene blue dye, dimerization, redox reactions, intermolecular interactions, mass spectrometry, nanomaterials, nanotechnology, electrochemical sensors, electron transfer

Abstract

Novel potentialities of applications of popular cationic dye Methylene Blue in molecular biophysical investigations and nanotechnology are considered in this review. The main attention is paid to utilization of redox and aggregation properties of Methylene Blue in modeling of biophysical processes and elaboration of schemes for nanodevices functioning at the molecular level. Approaches to study of methylene blue-involving redox processes and its interactions with nanomaterials using possibilities of experimental mass spectrometric techniques are systematized.

Downloads

Download data is not yet available.

References

1. Clifton J.II. Methylene blue / J.II Clifton, J.B. Leikin // Am. J. Therapeut. – 2003. – V. 10, № 4. – P. 289–291.

2. Lest we forget you ‑ methylene blue... / R.H. Schirmer, H. Adler, M. Pickhardt, E. Mandelkow // Neurobiol. Aging. – 2011. – V. 32, №12. – P. 2325.e7–2325.e16.

3. Scheindlin S. Something old... something blue / S. Scheindlin // Mol. Interv. – 2008. – V. 8, № 6. – P. 268–273.

4. Машковский М.Д. Лекарственные средства / М.Д. Машковский. – М. : Медицина, 1988. – Т. 2. – 576 с. / Mashkovskij M.D. Lekarstvennye sredstva / M.D. Mashkovskij. – M. : Medicina, 1988. – T. 2. – 576 s.

5. Гороновский И.Т. Краткий справочник по химии / И.Т. Гороновский, Ю.П. Назаренко, Е.Ф. Некряч. – К. : Наук. думка, 1987. – 830 с. / Goronovskij I.T. Kratkij spravochnik po himii / I.T. Goronovskij, Ju.P. Nazarenko, E.F. Nekrjach. – K. : Nauk. dumka, 1987. – 830 s.

6. Ohlow M.J. Foundation review: Phenothiazine: the seven lives of pharmacology’s first lead structure / M.J. Ohlow, B. Moosmann // Drug Discovery Today. – 2011. – V. 16, № 3–4. – P. 119-131.

7. Wainwright M. The phenothiazinium chromophore and the evolution of antimalarial drugs / M. Wainwright, L. Amaral // Trop. Med. Int. Health. – 2005. – V. 10, № 6. – P. 501–511.

8. Метиленовый синий. Материал из Википедии — свободной энциклопедии [Electronic resource] - Mode of access: https://ru.wikipedia.org/wiki/Метиленовый_синий. Last access: 2015. – Title from the screen. / Metilenovyj sinij. Material iz Vikipedii — svobodnoj jenciklopedii [Electronic resource] - Mode of access: https://ru.wikipedia.org/wiki/Metilenovyj_sinij. Last access: 2015. – Title from the screen.

9. Methylene blue. From Wikipedia, the free encyclopedia [Electronic resource] - Mode of access: http://en.wikipedia.org/wiki/Methylene_blue. Last access: 2015. – Title from the screen.

10. Marr H.E. The crystal structure of methylene blue pentahydrate / H.E. Marr, J.M. Stewart, M.F. Chiu // Acta Crystallogr., Sect. B: Struct. Crystallogr. Cryst. Chem. – 1973. – V. B29, № 4. – P. 847–853.

11. 3,7-Bis(dimethylamino)phenothiazin-5-ium nitrate dihydrate / K.J. Kavitha, M.M. Raj,
K. Panchanatheswaran, D.E. Lynch // Acta Crystallogr., Sect. E: Struct. Rep. Online. – 2004. – V. E60, № 8. – P. o1367–o1369.

12. Noncovalent interaction of methylene blue with carbon nanotubes: theoretical and mass spectrometry characterization / V.V. Chagovets, M.V. Kosevich, S.G. Stepanian [et al.] // J. Phys. Chem. C. – 2012. – V. 116, № 38. – P. 20579−20590.

13. Babiaczyk W.I. Hydration structure of the quaternary ammonium cations / W.I. Babiaczyk, S. Bonella, L.G. Ciccotti // J. Phys. Chem. B. – 2010. – V. 114, № 46. – P. 15018-15028.

14. Small hydrophobic organic ions in aqueous solutions / W. Kunz, P. Calmettes, T. Cartailler, P. Turq // J. Chem. Phys. – 1993. – V. 99, № 3. – P. 2074-2078.

15. Van der Post S.T. Water dynamics in aqueous solutions of tetra-n-alkylammonium salts: hydrophobic and coulomb interactions disentangled / S.T. Van der Post, S. Scheidelaar, H.J. Bakker // J. Phys. Chem. B. – 2013. – V. 117, № 48. – P. 15101–15110.

16. Yamakata A. Destruction of the water layer on a hydrophobic surface induced by the forced approach of hydrophilic and hydrophobic cations / A. Yamakata, M. Osawa // J. Phys. Chem. Lett. – 2010. – V. 1, № 9. – P. 1487-1491.

17. Noncovalent complexes of tetramethylammonium with chlorine anion and 2,5-dihydroxybenzoic acid as models of the interaction of quaternary ammonium biologically active compounds with their molecular targets. A theoretical study / V. Pashynska, M. Kosevich, S. Stepanian, L. Adamowicz // J. Mol. Struct.: THEOCHEM. – 2007. – V. 815, № 1-3. – P. 55–62.

18. Lévy B. Theoretical study of methylene blue: a new method to determine partial atomic charges; investigation of the interaction with guanine / B. Lévy, M. Enescu // J. Mol. Struct.: THEOCHEM. – 1998. – V. 432, № 3. – P. 235-245.

19. Quintao A.D. Theoretical study of the hydrogen bond interaction between methylene blue and water and possible role on energy transfer for photodynamics / A.D. Quintao, K. Coutinho, S. Canuto // Int. J. Quantum Chem. – 2002. – V. 90, № 2. – P. 634‑640.

20. Microhydration of the methylene blue cation in an electrospray ion source / T. Sato, T. Majima, K. Hashimoto [et al.] // Europ. Phys. J. D. – 2011. – V. 63, № 2. – P. 189-194.

21. Козлов А.В. От D. Romanowski к Д.Л. Романовскому. Дорога длиной в 121 год / А. В. Козлов, Н. М. Хмельницкая, Г. Д. Большакова // TERRA MEDICA. Лабораторная диагностика. – 2011. – № 2 (25) – С. 21–28. / Kozlov A.V. Ot D. Romanowski k D.L. Romanovskomu. Doroga dlinoj v 121 god / A. V. Kozlov, N. M. Hmel'nickaja, G. D. Bol'shakova // TERRA MEDICA. Laboratornaja diagnostika. – 2011. – № 2 (25) – S. 21–28.

22. Methylene blue. NIST Chemistry WebBook. [Electronic resource] // National Institute of Standards and Technology's web site - Mode of access: http://webbook.nist.gov/cgi/cbook.cgi?ID=61-73-4&Units=SI&cIR=on&cMS=on&cUV=on&cIE=on&cIC=on&cES=on. – Last access: 2015. – Title from the screen.

23. Methylene blue. SDBS Search Results (CNMR, HNMR, MS). [Electronic resource] // Spectral Database for Organic Compounds, SDBS web site - Mode of access: http://sdbs.db.aist.go.jp/sdbs/cgi-bin/cre_frame_disp.cgi?sdbsno=2609 – Last access: 2015. – Title from the screen.

24. Optical absorption of methylene blue. [Electronic resource] // Oregon Medical Lazer Center, OMLC web site - Mode of access: http://omlc.org/spectra/mb/. – Last access: 2015. – Title from the screen.

25. Cenens J. Visible spectroscopy of methylene blue on hectorite, laponite B, and barasym in aqueous suspension / J. Cenens, R.A. Schoonheydt // Clays. Clay Miner. – 1988. – V. 36, № 3. – P. 214–224.

26. Kinetics and mechanism of a fast leuco-Methylene Blue oxidation by copper(II)–halide species in acidic aqueous media / O. Impert, A. Katafias, P. Kita, [et al.] // Dalton Trans. – 2003, – № 3. – P. 348-353.

27. de Tacconi N.R. Reversibility of photoelectrochromism at the TiO2/Methylene Blue interface / N.R. de Tacconi, J. Carmona, K. Rajeshwar // J. Eectrochem. Soc. – 1994. – V. 144, № 7. – P. 2486–2490.

28. UV-Vis spectroscopic and chemometric study on the aggregation of ionic dyes in water / L. Antonov, G. Gergov, V. Petrov [et al.] // Talanta. – 1999. – V. 49, № 1. – P. 99–106.

29. Барановский С.Ф. Агрегация 1,3,7-триметилксантина с метиленовым голубым в водном растворе / С.Ф. Барановский, П.А. Болотин, М.П. Евстигнеев // Журн. прикл. спектроскопии. – 2006. – Т. 73, № 2. – С. 158–163. / Baranovskij S.F. Agregacija 1,3,7-trimetilksantina s metilenovym golubym v vodnom rastvore / S.F. Baranovskij, P.A. Bolotin, M.P. Evstigneev // Zhurn. prikl. spektroskopii. – 2006. – T. 73, № 2. – S. 158–163.

30. Dimeric and other forms of methylene blue: absorption and fluorescence of the pure monomer / G.N. Lewis, O. Goldschmid, T.T. Magel, J. Bigeleisen // J. Am. Chem. Soc. – 1943. – V. 65, № 6. – P. 1150–1154.

31. Bergmann K. A spectroscopic study of methylene blue monomer, dimer, and complexes with montmorillonite / K. Bergmann, C.T. O'Konski // J. Phys. Chem. – 1963. – V. 67, № 10. – P. 2169–2177.

32. Spencer W. Kinetic study of the monomer-dimer equilibrium of methylene blue in aqueous solution / W. Spencer, J.R. Sutter // J. Phys. Chem. –1979. – V. 83, № 12. – P. 1573–1576.

33. Mukerjee P. Ionic strength effects on the activity coefficient of methylene blue and its self-association / P. Mukerjee, A.K. Ghosh // J. Am. Chem. Soc. – 1970. – V. 92, № 22. – P. 6413-6415.

34. Mukerjee P. Thermodynamic aspects of the self-association and hydrophobic bonding of methylene blue. Model system for stacking interactions / P. Mukerjee, A.K. Ghosh // J. Am. Chem. Soc. – 1970. – V. 92, № 22. – P. 6419–6424.

35. Thermodynamic study of the dimerization equilibrium of methylene blue, methylene green and thiazole orange at various surfactant concentrations and different ionic strengths and in mixed solvents by spectral titration and chemometric analysis / O. Yazdani, M. Irandoust, J.B. Ghasemi, Sh. Hooshman // J. Appl. Spectr. – 2007. – V. 74, № 4. – P. 598-601.

36. Tafulo P.A.R. On the “concentration-driven” methylene blue dimerization / P.A.R. Tafulo, R.B. Queiros, G. Gonzalez-Aguilar // Spectrochim. Acta Part A: Biomol. Spectr. – 2009. – V. 73, № 2. – P. 295–300.

37. Golz E.K. Modeling methylene blue aggregation in acidic solution to the limits of factor analysis / E.K. Golz, D.A. Vander Griend // Anal. Chem. – 2013. – V. 85, № 2. – P. 1240–1246.

38. Patil K. Self-aggregation of Methylene Blue in aqueous medium and aqueous solutions of Bu4NBr and urea / K. Patil, R. Pawar, P. Talap // Phys. Chem. Chem. Phys. – 2000. – V. 2, № 19. ‑ P. 4313–4317.

39. Bulakov D.V. Dimerization of molecules of methylene blue in microstructured polymer-micelle solutions / D.V. Bulakov, A.M. Saletskii // J. Appl. Spectr. – 2007. – V. 74, № 4. – P. 598-601.

40. Sanan R. Complexation, dimerisation and solubilisation of methylene blue in the presence of biamphiphilic ionic liquids: a detailed spectroscopic and electrochemical study / R. Sanan, T.S. Kang, R. K. Mahajan // Phys. Chem. Chem. Phys. – 2014. – V. 16, № 12. – P. 5667–5677.

41. Kai W. High pressure-enhanced dimeric aggregation in methylene blue solution / W. Kai, Q. Guangyu, J. Zhangmei, L. Aolei // Chem. J. Chinese U – 2014. – V. 35, № 11. – P. 2431–2434.

42. Heger D. Aggregation of methylene blue in frozen aqueous solutions studied by absorption spectroscopy / D. Heger, J. Jirkovsk, P. Kln // J. Phys. Chem. A. – 2005. – V. 109, № 30. – P. 6702–6709.

43. Rabinowitch E. Polymerization of dyestuffs in solution. Thionine and methylene blue / E. Rabinowitch, L.F. Epstein // J. Am. Chem. Soc. – 1941. – V. 63, № 1. – P. 69–78.

44. Braswell E. Evidence for the trimerisation in aqueous solutions of methylene blue / E. Braswell // J. Phys. Chem. – 1968. – V. 72, № 7. – P. 2477–2483.

45. Ghosh A.K. Multiple association equilibria in the self-association of methylene blue and other dyes / A.K. Ghosh, P. Mukerjee // J. Am. Chem. Soc. – 1970. – V. 92, № 12. – P. 6408–6412.

46. Polymeric adsorption of methylene blue in TiO2 colloids — highly sensitive thermochromism and selective photocatalysis / B. Liu, L. Wen, K. Nakata [et al.] // Chem. Eur. J. – 2012. – V. 18, № 40. – P. 12705–12711.

47. Preparation, characterization, and photophysical study of thiazine dyes within the nanotubes and nanocavities of silicate host: influence o f titanium dioxide nanoparticle on the protonation and aggregation of dyes / K. Senthilkumar, P. Paul, C. Selvaraju, P. Natarajan // J. Phys. Chem. C. – 2010. – V. 114, № 15. – P. 7085–7094.

48. Jockusch S. Aggregation of methylene blue adsorbed on starburst dendrimers / Steffen Jockusch , Nicholas J. Turro , Donald A. Tomalia // Macromolecules. – 1995. – V. 28, № 22. – P. 7416–7418.

49. Homem-de-Mello P. Cationic dye dimers: a theoretical study / P. Homem-de-Mello, B. Mennucci, J. Tomasi, A. B. F. da Silva // Theor. Chem. Acc. – 2007. – V. 118, № 2. – P. 305–314.

50. Davies D. B. 1H NMR investigation of self-association of aromatic drug molecules in aqueous solution. Structural and thermodynamical analysis / D.B. Davies, L.N. Djimant, A.N. Veselkov // J. Chem. Soc., Faraday Trans. – 1996. – V.92, № 3. – P. 383–390.

51. Davies D. B. Structure and thermodynamics of the hetero-association of aromatic molecules in aqueous solution determined by NMR spectroscopy / D.B. Davies, D.A. Veselkov, A.N. Veselkov // Mol. Phys. – 1999. – V. 97, № 3. – P. 439–451.

52. Evstigneev M. P. DNA-binding aromatic drug molecules: Physico-chemical interactions and their biological roles / M. P. Evstigneev. – Saarbrücken : LAP LAMBERT Academic Publishing, 2010. – 96 p.

53. Евстигнеев М. П. Межмолекулярные взаимодействия биологически активных ароматических веществ и ДНК в водном растворе: дис…. д-ра физ.-мат. наук.: 03.00.02/ Евстигнеев Максим Павлович. – Севастополь, 2006. – 341 с. – Библиогр.: 313-341. / Evstigneev M. P. Mezhmolekuljarnye vzaimodejstvija biologicheski aktivnyh aromaticheskih veshhestv i DNK v vodnom rastvore: dis…. d-ra fiz.-mat. nauk.: 03.00.02/ Evstigneev Maksim Pavlovich. – Sevastopol', 2006. – 341 s. – Bibliogr.: 313-341.

54. Harmann C. Electrochemistry / C. Harmann, A. Hamnett, W. Vielstich. – Weinheim : Wiley, 2007. – 550 p.

55. Hulanicki A. Redox indicators. Characterstics and applications / A. Hulanicki, S. Glab // Pure Appl. Chem. – 1978. – V. 50, № 5. – P. 463–498.

56. Химические реактивы и препараты. Справочник. / Ред. В.И. Кузнецова. – М. : ГНТИХЛ, 1953. – 662 с. / Himicheskie reaktivy i preparaty. Spravochnik. / Red. V.I. Kuznecova. – M. : GNTIHL, 1953. – 662 s.

57. The electrochemical behavior of methylene blue at a microcylinder carbon fiber electrode / H.X. Ju, J. Zhou, C.X. Cai H.Y. Chen // Electroanalysis. ‑ 1995. –V. 7, № 2. – P. 1165–1170.

58. Ferapontova E.E. Electrochemical indicators for DNA electroanalysis // Curr. Analyt. Chem. – 2011. – V. 7, № 1. – P. 51–62.

59. Studies on the radical species in solid methylene blue as revealed from the ESR spectra / M. Okuda, T. Kowata, Y. Usui, M. Koizumi // Bull. Chem. Soc. Jpn. – 1968. – V. 41, № 10. – P. 2274–2280.

60. Engerer S.C. The Blue Bottle Reaction as a general chemistry experiment on reaction mechanisms / S.C. Engerer, A.G. Cook // J. Chem. Educ. – 1999. – V. 76, № 11. – P. 1519.

61. What is happening when the blue bottle bleaches: an investigation of the methylene blue-catalyzed air oxidation of glucose / L. Anderson, S. Wittkopp, C. Painter [et al.] // J. Chem. Educ. – 2012. – V. 89, № 11. – P. 1425–1431.

62. PubChem. Open Chemistry Database. Leucomethylene blue. [Electronic resource] // U.S. National Library of Medicine. National Center for Biotechnology Information’s web site - Mode of access: http://pubchem.ncbi.nlm.nih.gov/compound/164695#section=Top. Last access: 2015. – Title from the screen.

63. Determination of methylene blue residues in aquatic products by liquid chromatography-tandem mass spectrometry / J. Xu, L. Dai, B. Wu [et al.] // J. Sep. Sci. – 2009. – V. 32, № 23-24. – P. 4193–4199.

64. Пат. 2013/0315992 A1 США, МКИ C07D 279/20. Phenothiazine diaminium salts and their use: Пат. 2013/0315992 A1 США, МКИ C07D 279/20 / S.Clunas (GB) et al.; Wista Laboratories Ltd. – № 13/984841; заяв. 15.08.2011; опубл. 28.11.2013; НКИ 424/464. – 67 с. / Pat. 2013/0315992 A1 SShA, MKI C07D 279/20. Phenothiazine diaminium salts and their use: Pat. 2013/0315992 A1 SShA, MKI C07D 279/20 / S.Clunas (GB) et al.; Wista Laboratories Ltd. – № 13/984841; zajav. 15.08.2011; opubl. 28.11.2013; NKI 424/464. – 67 s.

65. The PubChem Compound Database. [Electronic resource] // U.S. National Library of Medicine. National Center for Biotechnology Information’s web site - Mode of access:
http://www.ncbi.nlm.nih.gov/pccompound?cmd=Link&LinkName=pccompound_pccompound_mixture&from_uid=164695 Last access: 2015. – Title from the screen.

66. Obata H. Photoreduction of methylene blue by visible light in the aqueous solution containing certain kinds of inorganic salts. II. Photobleached product / H. Obata // Bull. Chem. Soc. Jpn. – 1961. – V. 34. – P. 1057–1063.

67. Mills A. Photobleaching of methylene blue sensitised by TiO2: an ambiguous system / A. Mills, J. Wang // J. Photochem. Photobiol. A: Chemistry. – 1999. – V. 127, № 1-3. – P. 123–134.

68. Lee S.-K. Luminescence of Leuco-Thiazine dyes / S.-K. Lee, A. Mills // J. Fluoresc. – 2003. – V. 13, № 5. – Р. 375–377.

69. Redox systems under nano-space control / Ed. T.Hirao. – Berlin : Springer-Verlag, 2006. – 295 p.

70. Gilardi G. Manipulating redox systems: applications to nanotechnology / G. Gilardi, A. Fantuzzi // Trends Biotechnol. – 2001. – V. 19, № 11. – P.468–476.

71. Tuning the unidirectional electron transfer at interfaces with multilayered redox-active supramolecular bionanoassemblies / O. Azzaroni, M. Álvarez, A.I. Abou-Kandil [et al.] // Adv. Funct. Mater. – 2008. – V. 18, № 21. – P. 3487–3496.

72. Biosensors and Modern Biospecific Analytical Techniques, Volume 44 (Comprehensive Analytical Chemistry) / Ed. L. Gorton. – Amsterdam: Elsevier, 2005. – 635 p.

73. Recent advances in nano-based electrochemical biosensors: application in diagnosis and monitoring of diseases // R.M. Iost, W.C. da Silva, J.M. Madurro [et al.] // Front. Biosci. (Elite Ed). – 2011. – V. 3. – P. 663–689.

74. Дзядевич С.В. Наукові та технологічні засади створення мініатюрних електрохімічних біосенсорів / С.В. Дзядевич, О.П. Солдаткін. – 1-е изд. – К. : Наук. думка, 2006. – 256 с. / Dzjadevich S.V. Naukovі ta tehnologіchnі zasadi stvorennja mіnіatjurnih elektrohіmіchnih bіosensorіv / S.V. Dzjadevich, O.P. Soldatkіn. – 1-e izd. – K. : Nauk. dumka, 2006. – 256 s.

75. Wu X. Biosensor sensitive to hydrogen peroxide via methylene blue incorporated into nafion film as an electron transfer mediator / X. Wu, T. Ying, K. Sun // J. Shanghai Univ. – 1998. – V. 2, № 2. – P. 156–163.

76. Electrochemical study of a new methylene blue/silicon oxide nanocomposition mediator and its application for stable biosensor of hydrogen peroxide / H. Yao, N. Li, S. Xu [et al.] // Biosens. Bioelectron. – 2005. – V. 21, № 2. – P. 372–377.

77. Yao H. Amperometric biosensor for hydrogen peroxide based on the co-electrodeposition of horseradish peroxidase and methylene blue on an ITO electrode modified with an anodic aluminum oxide template / H. Yao, H. Liu, M. Sun, L. Gong // Microchim. Acta. – 2012. – V. 177, № 1-2. – P. 31–37.

78. Tiwari I. Preparation and characterization of methylene blue-SDS- multiwalled carbon nanotubes nanocomposite for the detection of hydrogen peroxide / I. Tiwari, M. Singh // Microchim. Acta. – 2011. – V. 174, № 3–4. – P. 223–230.

79. Li J. Novel magnetic single-walled carbon nanotubes/methylene blue composite amperometric biosensor for DNA determination / J. Li, W. Zhu, H. Wang // Anal. Lett. – 2009. – V. 42. – № 2. – P. 366–380.

80. Gu J.Y. DNA sensor for recognition of native yeast DNA sequence with methylene blue as an electrochemical hybridization indicator / J.Y. Gu, X.J. Lu, H.X. Ju // Electroanalysis. – 2002. – V. 14, № 13. – P. 949–954.

81. Methylene blue immobilized on cellulose acetate with titanium dioxide: an application as sensor for ascorbic acid / A.A. HoffmannI, S.L.P. Dias, J.R. Rodrigues [et al.] // J. Braz. Chem. Soc. – 2008. – V. 19, № 5. – P. 943–949.

82. NADH oxidation using modified electrodes based on lactate and glucose dehydrogenase entrapped between an electrocatalyst film and redox catalyst-modified polymers / E. Al-Jawadi, S. Pöller, R. Haddad, W. Schuhmann // Microchim. Acta. – 2012. – V. 177, № 3-4. – P. 405–410.

83. A rapid and selective method for monitoring the growth of coliforms in milk using the combination of amperometric sensor and reducing of methylene blue / Y.G. Lee, H.Y. Wu, C.L. Hsu [et al.] // Sens. Actuators, B: Chemical. – 2009. – V. 141, № 2. – P. 575–580.

84. Korshoj L.E. Methylene Blue-mediated electrocatalytic detection of hexavalent chromium / L.E. Korshoj, A.J. Zaitouna, R.Y. Lai // Anal. Chem. – 2015. – V. 87, № 5. – P. 2560–2564.

85. Evtugyn G.A. Amperometric DNA-peroxidase sensor for the detection of pharmaceutical preparations / G.A. Evtugyn, O.E. Goldfarb, H.C. Budnikov [et al.] // Sensors. – 2005. – V. 5, № 6. – P. 364–376.

86. Евтюгин Г.А. Электрохимические ДНК-сенсоры для определения биологически активных низкомолекулярных соединений / Г.А. Евтюгин, Г.К. Будников, А.В. Порфирьева // Рос. хим. ж. (Ж. Рос. хим. об-ва им. Д.И. Менделеева). – 2008, – Т. LII, № 2. – С. 66–79. / Evtjugin G.A. Jelektrohimicheskie DNK-sensory dlja opredelenija biologicheski aktivnyh nizkomolekuljarnyh soedinenij / G.A. Evtjugin, G.K. Budnikov, A.V. Porfir'eva // Ros. him. zh. (Zh. Ros. him. ob-va im. D.I. Mendeleeva). – 2008, – T. LII, № 2. – S. 66–79.

87. Colorimetric detection of catalytic reactivity of nanoparticles in complex matrices / C. Corredor, M.D. Borysiak, J. Wolfer [et al.] // Environ. Sci. Technol. – 2015. – V. 49, № 6. – P. 3611–3618.

88. Development of highly selective interdigitated electrode sensor for detection of methylene blue / S. Zougar, A. Sbartai, N. Jaffrezic-Renault, R. Kherrat / Sensor Lett. – 2015. – V. 13, № 5. – P. 349–356.

89. Jana A.K. Solar cells based on dyes / A.K.Jana // J. Photochem. Photobiol. A. –2000. – V. 132, № 1–2. – P. 1–17.

90. Gangotri K.M. Use of mixed dyes in photogalvanic cell for solar energy conversion and storage: EDTA–Methylene blue and Azur–B system / K.M. Gangotri, C. Lal // Energy Sources. – 2001. – V. 23, № 3. – P. 267–273.

91. Biologically inspired pteridine redox centers for rechargeable batteries / J. Hong, M. Lee, B. Lee [et al.] // Nature Commun. – 2014. – V. 5. – Art. N. 5335 (9 p.).

92. Дзядевич С.В. Амперометрические биосенсоры. Основные принципы работы и особенности датчиков разных генераций / С.В. Дзядевич // Bioplym. Cell. – 2002. – Т. 18, № 1. – C. 13–25. / Dzjadevich S.V. Amperometricheskie biosensory. Osnovnye principy raboty i osobennosti datchikov raznyh generacij / S.V. Dzjadevich // Bioplym. Cell. – 2002. – T. 18, № 1. – C. 13–25.

93. Дзядевич С.В. Амперометрические биосенсоры. Современные технологии и коммерческие варианты анализаторов / С.В. Дзядевич // Bioplym. Cell. – 2002. – Т. 18, № 5. – C. 363–376. / Dzjadevich S.V. Amperometricheskie biosensory. Sovremennye tehnologii i kommercheskie varianty analizatorov / S.V. Dzjadevich // Bioplym. Cell. – 2002. – T. 18, № 5. – C. 363–376.

94. An amperometric biosensor based on the coimmobilization of horseradish peroxidase and methylene blue on a carbon nanotubes modified electrode / J.Z. Xu, J.J. Zhu, Q. Wu [et al.] // Electroanalysis. – 2003. – V. 15, № 3. – P. 219–224.

95. Adsorption of methylene blue dye onto carbon nanotubes: a route to an electrochemically functional nanostructure and its layer-by-layer assembled nanocomposite / Y. Yan, M. Zhang, K. Gong [et al.] // Chem. Mater. – 2005. – V. 17, № 13. – P. 3457–3463.

96. The effect of nanosized titania-silica film composition on the photostability of adsorbed methylene blue dye / N.I. Surovtseva, A.M. Eremenko, N.P. Smirnova [et al.] // Theor. Exp. Chem. – 2007. – V. 43. – P. 235–240.

97. Photosensitizer methylene blue-semiconductor nanocrystals hybrid system for photodynamic therapy / A. Rakovich, T. Rakovich, V. Kelly [et al.] // J. Nanosci. Nanotechnol. – 2010. – V. 10, № 4. – P. 2656–2662.

98. Electrochemical property of methylene blue redox dye immobilized on porous silica-zirconia-antimonia mixed oxide / G. Zaitseva, Y. Gushikem, E.S. Ribeiro, S.S. Rosatto // Electrochim. Acta. – 2002. – V. 47, № 9. – P. 1469–1474.

99. Electrochemically functional graphene nanostructure and layer-by-layer nanocomposite incorporating adsorption of electroactive methylene blue / D. Zhang, L. Liao, B. Dai [et al.] // Electrochim. Acta. – 2012. – V. 75. – P. 71–79.

100. Electron interaction among the noncovalently engineered graphene-methylene blue nanocomposites / Z. Li, X.J. Shi, X.P. Ge [et al.] // Chem. Res. Chin. Univ. – 2012. – V. 28, № 3. – P. 520–523.

101. The route to functional graphene oxide / K. Haubner, J. Murawski, Ph. Olk, L. M. Eng [et al.] // ChemPhysChem. – 2010. – V. 11, № 10. – P. 2131–2139.

102. Complexation of C60 fullerene with aromatic drugs / M.P. Evstigneev, A.S. Buchelnikov, D.P. Voronin [et al.] // ChemPhysChem. – 2013. – V. 14, № 3. – P. 568–578.

103. Механизм комплексообразования фенотиазинового красителя метиленового голубого с фуллереном C60 / А.С. Бучельников, В.В. Костюков, М.П. Евстигнеев, Ю.И. Прилуцкий // Физ. химия. – 2013. – Т. 87, № 4. – С. 672–678. / Mehanizm kompleksoobrazovanija fenotiazinovogo krasitelja metilenovogo golubogo s fullerenom C60 / A.S. Buchel'nikov, V.V. Kostjukov, M.P. Evstigneev, Ju.I. Priluckij // Fiz. himija. – 2013. – T. 87, № 4. – S. 672–678.

104. Adsorption of methylene blue on colloidal silver - a surface-enhanced raman spectroscopy study combined with density functional theory calculations / L. Zhong, Y.J. Hu, D. Xing, H.M. Gu // Spectroscopy and Spectral Analysis [in Chinese]. – 2010. – V. 30, № 1. – P. 90–94.

105. Nicolai S.H.A. Surface-enhanced resonance raman (serr) spectra of methylene blue adsorbed on a silver electrode / S.H.A. Nicolai, J.C. Rubim // Brazil Langmuir. – 2003. – V. 19, № 10. – P. 429–4294.

106. Shahryari Z. Experimental study of methylene blue adsorption from aqueous solutions onto carbon nanotubes / Z. Shahryari, A.S. Goharrizi, M. Azadi // Int. J. Water Resour. Environ. Eng. – 2010. – V. 2. – P. 016–028.

107. Fluorescent nanoprobes dedicated to in vivo imaging: from preclinical validations to clinical translation / J.Mérian, J.Gravier, F.Navarro, I.Texier // Molecules. – 2012. – V. 17, № 5. – P. 5564–5591.

108. Methylene Blue- and thiol-based oxygen depletion for super-resolution imaging / P. Schäfer, S. van de Linde, J. Lehmann [et al.] // Anal. Chem. – 2013. – V. 85, № 6. – P. 3393–3400.

109. The Nobel Prize in Chemistry 2014 [Electronic resource]: The Official Web Site of the Nobel Prize - Mode of access: http://www.nobelprize.org/nobel_prizes/chemistry/laureates/2014/. Last access: 2015. – Title from the screen.

110. Integrating histology and imaging mass spectrometry / P. Chaurand, S.A. Schwartz, D. Billheimer [et al.] // Anal. Chem. – 2004. – V. 76, № 4. – P. 1145–1155.

111. Wain A.J. Scanning electrochemical microscopy imaging of DNA microarrays using methylene blue as a redox-active intercalator / A.J. Wain, F. Zhou // Langmuir. – 2008. – V. 24, № 9. – P. 5155–5160.

112. Usacheva M.N. The role of the methylene blue and toluidine blue monomers and dimers in the photoinacti-vation of bacteria / M.N. Usacheva, M.C. Teichert, M.A. Biel // J. Photochem. Photobiol. B. – 2003. – V. 71, № 1-3. – P. 87–98.

113. Usacheva M.N. Comparison of the methylene blue and toluidine blue photobactericidal efficacy against gram-positive and gram-negative microorganisms / M.N. Usacheva, M.C. Teichert, M.A. Biel // Lasers Surg. Med. – 2001. – V. 29, № 2. – P. 165–173.

114. Photoacoustic lifetime contrast between methylene blue monomers and self-quenched dimers as a model for dual-labeled activatable probes / E. Morgounova, Q. Shao, B.J. Hackel [et al.] // J. Biomed. Opt. – 2013. – V. 18, № 5. – P. 056004-1–056004-8.

115. Hachisako H. Extraordinary monomer-dimer transition of methylene blue induced by the phase transition of telomer-bilayer membranes formed from dialkyl L-glutamate amphiphiles with oligo-acrylic acid-head group / H. Hachisako, Y. Motozato, R. Murakami, K. Yamada // Chem. Lett. – 1992. – V. 21, № 2. – P. 219–222.

116. Effect of the molecular methylene blue aggregation on the mesoscopic domain morphology in mixed monolayers with dimyristoyl−phosphatidic acid / J.J. Giner-Casares, G. de Miguel, M. Pérez-Morales [et al.] // J. Phys. Chem. C. – 2009. – V. 113, № 14. – P. 5711–5720.

117. Methylene blue in photodynamic therapy: from basic mechanisms to clinical applications / J.P. Tardivo, A. Del Giglio, C.S. de Oliveira [et al.] // Photodiagn. Photodyn. Ther. – 2005. – V. 2, № 3. – P. 175–191.

118. Binding, aggregation and photochemical properties of methylene blue in mitochondrial suspensions / D. Gabrielli, E. Belisle, D. Severino [et al.] // Photochem. Photobiol. – 2004. – V. 79, № 3. – P. 227–232.

119. Modulation of methylene blue photochemical properties based on adsorption at aqueous micelle interfaces / H.C. Junqueira, D. Severino, L.G. Dias [et al.] // Phys. Chem. Chem. Phys. – 2002. – V. 4, № 11. – P. 2320–2328.

120. Influence of negatively charged interfaces on the ground and excited state properties of methylene blue / D. Severino, H.C. Junqueira, M. Gugliotti [et al.] // Photochem. Photobiol. – 2003. – V. 77, № 5. – P. 459–468.

121. Interactions between methylene blue and sodium dodecyl sulfate in aqueous solution studied by molecular spectroscopy / M.K. Carroll, M.A. Unger, A.M. Leach [et al.] // Appl. Spectrosc. – 1999. – V. 53, № 7. – P. 780–784.

122. Monomer/dimer dependent modulation of reduction of the cationic dye methylene blue in negatively charged nanolayers as revealed by mass spectrometry / V.S. Shelkovsky, M.V. Kosevich, O.A. Boryak [et al.] // RSC Advances. – 2014. – V. 4, № 104. – P. 60260–60269.

123. Nanoparticle platform to modulate reaction mechanism of phenothiazine photosensitizers / D.B. Tada, L.M. Rossi, C.A.P. Leite [et al.] // J. Nanosci. Nanotechnol. – 2010. – V. 10, № 5. – P. 3100–3108.

124. Tada D.B. Photosensitizing nanoparticles and the modulation of ROS generation / D.B. Tada, M.S. Baptesta // Front. Chem. – 2015. – V. 3, № 33. – P. 1–14.

125. Methylene blue binding to DNA with alternating GC base sequence: a modeling study / R. Rohs, H. Sklenar, R. Lavery, B. Röder // J. Am. Chem. Soc. – 2000. – V. 122, № 12. – P. 2860–2866.

126. Rohs R. Methylene blue binding to DNA with alternating GC base sequence: continuum treatment of salt effects / R. Rohs, H. Sklenar // Indian J. Biochem. Biophys. – 2001. – V. 38, № 1-2. – P. 1–6.

127. Rohs R. Methylene blue binding to DNA with alternating AT base sequence: minor groove binding is favored over intercalation / R. Rohs, H. Sklenar // J. Biomol. Str. Dyn. ‑ 2004. ‑ V. 21, № 5. – P. 699–711.

128. Molecular flexibility in ab initio drug docking to DNA: binding-site and binding-mode transitions in all-atom Monte Carlo simulations / R. Rohs, I. Bloch, H. Sklenar, Z. Shakked // Nucleic Acids Res. – 2005. – V. 33, № 22. – P. 7048–7057.

129. Nogueira J.J. Molecular dynamics simulations of binding modes between methylene blue and DNA with alternating GC and AT sequences / J.J. Nogueira, L. González // Biochemistry. – 2014. – V. 53, № 14. – Р. 2391–2412.

130. Tuite E. Sequence-specific interaction of Methylene Blue with polynucleotides and DNA: a spectroscopic study / E. Tuite, B. Norden // J. Am. Chem. Soc. – 1994. – V. 116, № 17. – P. 7548–7556.

131. Fluorescence and photobleaching studies of methylene blue binding to DNA / B.S. Fujimoto, J.B. Clendenning, J.J. Delrow [et al.] // J. Phys. Chem. – 1994. – V. 98, № 26. – P. 6633–6643.

132. Elucidation of the mechanism of single-stranded DNA interaction with methylene blue: A spectroscopic approach / M. Ortiz, A. Fragoso, P.J. Ortiz, C.K. O'Sullivan // J. Photochem. Photobiol. A: Chemistry. – 2011. – V. 218, № 1. – P. 26–32.

133. Stability and structural features of DNA intercalation with ethidiume bromide, acridine orange and methylene blue / S. Nafisi, A.A. Saboury, N. Keramat [et al.] // J. Mol. Struct. – 2007. – V. 827, № 1–3. – P. 35–43.

134. Hossain M. DNA intercalation by quinacrine and methylene blue: a comparative binding and thermodynamic characterization study / M. Hossain, P. Giri, G.S. Kumar // DNA Cell Biol. – 2008. – V. 27, № 2. – P. 81–90.

135. Tong C. Interaction between methylene blue and calf thymus deoxyribonucleic acid by spectroscopic technologies / C. Tong, Z. Hu, J. Wu // J. Fluoresc. – 2010. – V. 20, № 1. –P. 261–267.

136. Hu Z. Synchronous fluorescence determination of DNA based on the interaction between methylene blue and DNA / Z. Hu, C. Tong // Anal. Chim. Acta. – 2007. – V. 587, № 2. – P. 187–193.

137. Methylene blue photosensitised strand cleavage of DNA: effects of dye binding and oxygen / C. Oh. Uigin, D.J. McConnell, J.M. Kelly, W.J. van der Putten // Nucleic Acids Res. – 1987. – V. 15, № 18. – Р. 7411–7427.

138. Tuite E.M. New trends in photobiology: Photochemical interactions of methylene blue and analogues with DNA and other biological substrates / E.M. Tuite, J.M. Kelly // J. Photochem. Photobiol. B: Biology. – 1993. – V. 21, № 2-3. – Р. 103–124.

139. Спектрофотометрический анализ связывания ароматических биологически активных соединений с ДНК / Чернышев Д.Н., Бучельников А.С., Мухина Ю.В., Барановский С.Ф. // Вісник СевНТУ: Серія: Фізика біологічних систем і молекул. – 2011. – Вип. 113. – С. 57–66. / Spektrofotometricheskij analiz svjazyvanija aromaticheskih biologicheski aktivnyh soedinenij s DNK / Chernyshev D.N., Buchel'nikov A.S., Muhina Ju.V., Baranovskij S.F. // Vіsnik SevNTU: Serіja: Fіzika bіologіchnih sistem і molekul. – 2011. – Vip. 113. – S. 57–66.

140. Mechanisms for binding between methylene blue and DNA / P.O. Vardevanyan, A.P. Antonyan, M.A. Parsadanyan [et al.] // J. Appl. Spectrosc. – 2013. – V. 80, № 4. – P. 595–599.

141. Механизмы связывания метиленового синего с ДНК / П.О. Вардеванян, А.П. Антонян, М.А. Парсаданян [et al.] // ЖПС. – 2013. – Т. 80, № 4. – С. 610–614. / Mehanizmy svjazyvanija metilenovogo sinego s DNK / P.O. Vardevanjan, A.P. Antonjan, M.A. Parsadanjan [et al.] // ZhPS. – 2013. – T. 80, № 4. – S. 610–614.

142. Исследование связывания метиленового синего с ДНК спектроскопическими методами / П.О. Вардеванян, А.П. Антонян, М.А. Шагинян, Л.А. Амбарцумян // ДНАН РА. – 2013. – Т. 113, № 2. – С. 180–188. / Issledovanie svjazyvanija metilenovogo sinego s DNK spektroskopicheskimi metodami /
P.O. Vardevanjan, A.P. Antonjan, M.A. Shaginjan, L.A. Ambarcumjan // DNAN RA. – 2013. – T. 113, № 2. – S. 180–188.

143. Термодинамический анализ комплексов ДНК с метиленовым синим, бромистым этидием и Hoechst 33258 / П.О. Вардеванян, А.П. Антонян, Л.А. Амбарцумян [et al.] // Biopolym. Cell. – 2013. – T. 29, № 6. – C. 515–520. / Termodinamicheskij analiz kompleksov DNK s metilenovym sinim, bromistym jetidiem i Hoechst 33258 / P.O. Vardevanjan, A.P. Antonjan, L.A. Ambarcumjan [et al.] // Biopolym. Cell. – 2013. – T. 29, № 6. – C. 515–520.

144. Hambardzumyan L.A. Effect of DNA GC-content on interaction with methylene blue / L.A. Hambardzumyan // Proc. of the Yerevan State Univ. Chemistry and Biology. – 2015. – № 1. – P. 45–49.

145. Evidence for the direct interaction between methylene blue and guanine bases using DNA-modified carbon paste electrodes / W. Yang, M. Ozsoz, D.B. Hibbert, J.J. Gooding // Electroanalysis. – 2002. – V. 14, № 18 –
P. 1299–1302.

146. Enescu M. Molecular dynamics simulation of methylene blue - guanine complex in vacuo / M. Enescu, V. Gheorghe // J. Mol. Struct. THEOCHEM. – 1998. – V. 423, № 3. – P. 213–218.

147. Enescu M. Molecular Dynamics Simulation of Methylene Blue−Guanine Complex in Water:  The Role of Solvent in Stacking / M. Enescu, B. Levy, V. Gheorghe // J. Phys. Chem. B. – 2000. – V. 104, № 5. – P. 1073–1077.

148. Enescu M. Electron transfer modeling in condensed phase by molecular dynamics simulation: Application to methylene blue-guanine complex in water / M. Enescu, J. Ridard, V. Gheorghe, B. Levy // J. Phys. Chem. B. – 2002. – V. 106, № 1. – P. 176–184.

149. Electrochemistry of methylene blue bound to a DNA-modified electrode / S.O. Kelley, J.K. Barton, N.M. Jackson, M.G. Hill // Bioconjug. Chem. – 1997. – V. 8, № 1. – P. 31–37.

150. Jackson N.M. Electrochemistry at DNA-modified surfaces: new probes for charge transport through the double helix / N.M. Jackson, M.G. Hill // Curr. Opin. Chem. Biol. – 2001. – V. 5, № 2. – P. 209–215.

151. Boon E.M. Charge transport in DNA / E.M. Boon, J.K. Barton // Curr. Opin. Struct. Biol. – 2002. – V. 12, № 3. – Р. 320–329.

152. Delaney S. Long-range DNA charge transport / S. Delaney, J.K. Barton // J. Org. Chem. – 2003. – V. 68, № 17. – P. 6475–6483.

153. Sontz P.A. DNA charge transport for sensing and signaling / P.A. Sontz, N.B. Muren, J.K. Barton // Acc. Chem. Res. – 2012. – V. 45, № 10. – P. 1792–1800.

154. Genereux J.C. DNA-mediated charge transport in redox sensing and signaling / J.C. Genereux, A.K. Boal, J.K. Barton // J. Am. Chem. Soc. – 2010. – V. 132, № 3. – P. 891–905.

155. Gorodetsky A.A. DNA-Mediated Electrochemistry / A.A. Gorodetsky, M.C. Buzzeo, J.K. Barton // Bioconjugate Chem. – 2008. – V. 19, № 12. – Р. 2285–2296.

156. Wohlgamuth C.H. DNA as a molecular wire: distance and sequence dependence /C.H. Wohlgamuth, M.A. McWilliams, J.D. Slinker // Anal. Chem. – 2013. – V. 85, № 18. – P. 8634–8640.

157. ДНК-сенсоры с электрохимически активными индикаторами – производными фенотиазина / Е.Е. Стойкова, О.Э. Гольдфарб, С.В. Белякова и др. // Вестник ТО РЭА. – 2003. – №3. – С. 51–55. / DNK-sensory s jelektrohimicheski aktivnymi indikatorami – proizvodnymi fenotiazina / E.E. Stojkova, O.Je. Gol'dfarb, S.V. Beljakova i dr. // Vestnik TO RJeA. – 2003. – №3. – S. 51–55.

158. Drummond, T.G. Electrochemical DNA sensors / T.G. Drummond, M.G. Hill, J.K. Barton // Nat. Biotech. – 2003. – V. 21, № 10. – P. 1192–1199.

159. Odenthal K.J. An introduction to electrochemical DNA biosensors / K.J. Odenthal, J.J. Gooding // Analyst. – 2007. – V. 132, № 7. – P. 603–610.

160. Overview of electrochemical DNA biosensors: new approaches to detect the expression of life / S. Cagnin, M. Caraballo, C. Guiducci [et al.] // Sensors (Basel). – 2009. – V. 9, № 4. – P. 3122–3148.

161. DNA interactions with a Methylene Blue redox indicator depend on the DNA length and are sequence specific / E. Farjami, L. Clima, K.V. Gothelf, E.E. Ferapontova // Analyst. – 2010. – V. 135, № 6. – P. 1443–1448.

162. Comparing the properties of electrochemical-based DNA sensors employing different redox tags / D. Kang, X. Zuo, R. Yang [et al.] // Anal. Chem. – 2009. – V. 81, № 21. – P. 9109–9113.

163. García-González R. Methylene blue covalently attached to single stranded DNA as electroactive label for potential bioassays / R. García-González, A. Costa-García, M.T. Fernández-Abedul // Sens. Actuators B. – 2014. – V. 191. – P. 784–790.

164. García-González R. Enzymatic amplification-free nucleic acid hybridisation sensing on nanostructured thick-film electrodes by using covalently attached methylene blue / R. García-González, A. Costa-García, M.T. Fernández-Abedul // Talanta. – 2015. – V. 142. – P. 11–19.

165. Catrina G. Intraduplex DNA-mediated electrochemistry of covalently tethered redox-active reporters / C.G. Pheeney, J.K. Barton // J. Am. Chem. Soc. – 2013. – V. 135, № 40. – P. 14944–14947.

166. Pheeney C.G. DNA electrochemistry with tethered methylene blue / C.G. Pheeney, J.K. Barton// Langmuir. – 2012. – V. 28, № 17. – P. 7063–7070.

167. A multiplexed, two-electrode platform for biosensing based on DNA-mediated charge transport / A.L. Furst, M.G. Hill, J.K. Barton // Langmuir. – 2015. – V. 31, № 23. – P. 6554–6562.

168. Abi A. Unmediated by DNA electron transfer in redox-labeled DNA duplexes end-tethered to gold electrodes / A. Abi, E.E. Ferapontova // J. Am. Chem. Soc. – 2012. – V. 134, № 35. – P. 14499–14507.

169. Farjami E. Effect of the DNA end of tethering to electrodes on electron transfer in methylene blue-labeled DNA duplexes / E. Farjami, R. Campos, E.E. Ferapontova // Langmuir. – 2012. – V. 28, № 46. – P. 16218–16226.

170. Electrochemical interrogation of interactions between surface-confined DNA and methylene blue / D. Pan, X. Zuo, Y. Wan [et al.] // Sensors. – 2007. – V. 7, № 11. – P. 2671–2680.

171. Electrochemical genosensor for the detection of interaction between methylene blue and DNA / P. Kara, K. Kerman, D. Ozkan [et al.] // Electrochem. Commun. – 2002. –V. 4, № 9. – P. 705–709.

172. DNA and PNA sensing on mercury and carbon electrodes by using methylene blue as an electrochemical label / D. Ozkan, P. Kara, K. Kerman [et al.] // Bioelectrochemistry. – 2002. – V. 58, № 1. – P. 119–126.

173. Label-free and label based electrochemical detection of hybridization by using methylene blue and peptide nucleic acid probes at chitosan modified carbon paste electrodes / P. Kara, K. Kerman, D. Ozkan // Electroanalysis. – 2002. – V. 14, № 24. – P. 1685–1690.

174. Novel hybridization indicator methylene blue for the electrochemical detection of short DNA sequences related to the hepatitis B virus / A. Erdem, K. Kerman, M. Meric [et al.] // Anal. Chim. Acta. – 2000. – V. 422, № 2. – P. 139–149.

175. Tani A. Methylene blue as an electrochemical discriminator of single- and double-stranded oligonucleotides immobilized on gold substrates / A. Tani, A.J. Thomson, J.N. Butt // Analyst. – 2001. – V. 126, № 10. – P. 1756–1759.

176. The effect of interfacial design on the electrochemical detection of DNA and microRNA using methylene blue at low-density DNA films / R. Tavallaie, N. Darwish, M. Gebala [et al.] // ChemElectroChem. – 2014. – V. 1, № 1. – P. 165–171.

177. Supercoiled and linear plasmid DNAs interactions with methylene blue / A.Gniazdowska, A. Palinska-Saadi, E. Krawczyk [et al.] // Bioelectrochemistry. – 2013. – V. 92. – P. 32–41.

178. Methylene blue as a G-Quadruplex binding probe for label-free homogeneous electrochemical biosensing / F.T. Zhang, J. Nie, D.W. Zhang [et al.] // Anal. Chem. – 2014. – V. 86, № 19. – P. 9489–9495.

179. Amplified electrochemical detection of DNA through the aggregation of Au nanoparticles on electrodes and the incorporation of methylene blue into the DNA-crosslinked structure / D. Li, Y. Yan, A. Wieckowska,
I. Willner // Chem. Commun. – 2007. – № 34. – P. 3544–3546.

180. Zhang Y. Cyclic voltammetric detection of chemical DNA damage induced by styrene oxide in natural dsDNA layer-by-layer films using methylene blue as electroactive probe / Y. Zhang, N. Hu // Electrochem. Commun. – 2007. – V. 9, № 1-9. – P. 35–41.

181. Combining a loop-stem aptamer sequence with methylene blue: a simple assay for thrombin detection by resonance light scattering technique / X. Huang, Y. Li, X. Huang [et al.] // RSC Adv. – 2015. – V. 5, № 38. – P. 30268–30274.

182. Electrochemical behaviors of methylene blue on DNA modified electrode and its application to the detection of PCR product from NOS sequence / L. Zhu, R. Zhao, K. Wang [et al.] // Sensors. – 2008. – V. 8, № 9. – P. 5649–5660.

183. Electrochemical method for monitoring the progress of polymerase chain reactions using Methylene blue as an indicator / K. Wang, Y.P. Chen, Y. Lei [et al.] // Microchim. Acta – 2013. – V. 180, № 9-10. – P. 871–878.

184. Hairpin DNA probe based on electrochemical biosensor using methylene blue as hybridization indicator / Y. Jin, X. Yao, Q. Liu, J. Li // Biosens. Bioelectron. – 2007. – V. 22, № 6. – P. 1126–1130.

185. Yang W. Comparison of the stem-loop and linear probe-based electrochemical DNA sensors by alternating current voltammetry and cyclic voltammetry / W. Yang, R.Y. Lai // Langmuir. – 2011. – V. 27, № 23. – P. 14669–14677.

186. Adenosine-triggered elimination of methylene blue noncovalently bound to immobilized functional dsDNA-aptamer constructs / D. Yun, C. Banani, G. Bixia, Y. Hua-Zhong // J. Phys. Chem. B. – 2012. – V. 116, № 22. – P. 6361–6368.

187. Yu Z. effect of signaling probe conformation on sensor performance of a displacement-based electrochemical DNA sensor / Z. Yu, R.Y. Lai // Anal. Chem. – 2013. – V. 85, № 6. – P. 3340–3346.

188. Wu Y. Effects of DNA probe and target flexibility on the performance of a “signal-on” electrochemical DNA sensor / Y. Wu, R.Y. Lai // Anal. Chem. – 2014. – V. 86, № 17. – P. 8888–8895.

189. Будников Г.К. Амперометрические ДНК-сенсоры на основе модифицированных графитовых электродов / Г.К. Будников, Г.А. Евтюгин, О.Э. Гольдфарб // Наукоемкие технологии – 2004. – Т. 5, № 4. – С. 30–37. / Budnikov G.K. Amperometricheskie DNK-sensory na osnove modificirovannyh grafitovyh jelektrodov / G.K. Budnikov, G.A. Evtjugin, O.Je. Gol'dfarb // Naukoemkie tehnologii – 2004. – T. 5, № 4. – S. 30–37.

190. Belluzo M.S. Assembling amperometric biosensors for clinical diagnostics / M.S. Belluzo, M.É. Ribone, C.M. Lagier // Sensors – 2008. – V. 8, № 3. – Р. 1366–1399.
191. Farjami E. An "off-on" electrochemical hairpin DNA-based genosensor for cancer diagnostics / E. Farjami, L. Clima, K.V. Gothelf // Anal. Chem. – 2011. – V. 83, № 5. – P. 1594–1602.

192. Liu Y. An aptasensor for electrochemical detection of tumor necrosis factor in human blood / Y. Liu, Q. Zhoua, A. Revzin // Analyst. – 2013. – V. 138, № 15. – P. 4321–4326.

193. Detection of IP-10 protein marker in undiluted blood serum via an electrochemical E-DNA scaffold sensor / A.J. Bonham, N.G. Paden, F. Ricci, K.W. Plaxco // Analyst. – 2013. – V. 138, № 19. – P. 5580–5583.

194. Electrochemical biocomputing: a new class of molecular-electronic logic devices / Y. Jia, R. Duan, F. Hong [et al.] // Soft Matter. – 2013. – V. 9, № 29. – P. 6571–6577.

195. Biocomputing security system: Concatenated enzyme-based logic gates operating as a biomolecular keypad lock / G. Strack, M. Ornatska, M. Pita, E. Katz // J. Am. Chem. Soc. – 2008. – V. 130, № 13. – Р. 4234–4235.

196. Kristiansen J.E. Dyes, antipsychotic drugs, and antimicrobial activity. Fragments of a development, with special reference to the influence of Paul Ehrlich / J.E. Kristiansen // Dan. Med. Bull. – 1989. – V. 36, № 2. – P. 178–185.

197. Kwok E.S. Use of methylene blue in sepsis: a systematic review / E.S. Kwok, D. Howes // J. Intensive Care Med. – 2006. – V. 21, № 6. – P. 359–363.

198. WHO Model List of Essential Medicines. 18th list. [Electronic resource] // 18th WHO Model List of Essential Medicines (April 2013). WHO Medicines web site - Mode of access: http://apps.who.int/iris/bitstream/10665/93142/1/EML_18_eng.pdf. Last access: 2015. – Title from the screen.

199. Brookes M.M. Methylene blue as antidote for cyanide and carbon monoxide poisoning / M.M. Brookes // J. Am. Med. Assoc. – 1933. – V. 100, № 1. – P. 59.

200. Thayer A.M. Giving new life to an old molecule / A.M. Thayer // Chem. Eng. News. – 2011. – V. 89, № 12. – P. 16–17.

201. Ginimuge P.R. Methylene Blue: Revisited / P.R. Ginimuge, S.D. Jyothi // J. Anaesthesiol., Clin. Pharmacol. – 2010. – V. 26, № 4. – P. 517–520.

202. Wainwright M. Methylene Blue ‑ a therapeutic dye for all seasons? / M. Wainwright, K.B. Crossley // J. Chemother. – 2002. – V. 14, № 5. – P. 431–443.

203. Methylene blue as an antimalarial agent / R.H. Schirmer, B. Coulibaly, A. Stich [et al.] // Redox Rep. – 2003. – V. 8, № 5. – P. 272–275.

204. Wainwright M. The phenothiazinium chromophore and the evolution of antimalarial drugs / M. Wainwright., L. Amaral // Trop. Med. Int. Health. – 2005. – V. 10, № 6. – P. 501–511.

205. Wagner S.J. Virus inactivation in blood components by photoactive phenothiazine dyes / S.J. Wagner // Transfus. Med. Rev. – 2002. – V. 16, № 1. – Р. 61–66.

206. Пирузян Л.А. Красители со свойствами модуляторов окислительно-восстановительных процессов как потенциальные иммунотропные средства / Л.А. Пирузян, И.Е. Ковалев, В.Л. Ковалева // Известия РАН, Серия биологическая. – 2001. – № 5. – С. 563–572. / Piruzjan L.A. Krasiteli so svojstvami moduljatorov okislitel'no-vosstanovitel'nyh processov kak potencial'nye immunotropnye sredstva / L.A. Piruzjan, I.E. Kovalev, V.L. Kovaleva // Izvestija RAN, Serija biologicheskaja. – 2001. – № 5. – S. 563–572.

207. Piruzian L.A. Dyes with properties of modulators of redox processes as potential immunotropic agents / L.A. Piruzian, I.E. Kovalev, V.L. Kovaleva // Biol. Bull. Russ. Acad. Sci. – 2001. – V. 28, № 5. – P. 477–485.

208. Structure and pathology of tau protein in alzheimer disease / M. Kolarova, F. García-Sierra, A. Bartos [et al.] // Int. J. Alzheimer's Dis. – 2012. – V. 2012. – Article ID 731526, 13 p.

209. Modulation and detection of tau aggregation with small-molecule ligands / E. Chang, N.S. Honson, B. Bandyopadhyay [et al.] // Curr. Alzheimer Res. – 2009. – V. 6, № 5. – P. 409–414.

210. Mechanistic basis of phenothiazine-driven inhibition of Tau aggregation / E. Akoury, M. Pickhardt, M. Gajda [et al.] // Angew. Chem. Int. Ed. Engl. – 2013. – V. 52, № 12. – P. 3511–3515.

211. Aminothienopyridazines and methylene blue affect Tau fibrillization via cysteine oxidation / A. Crowe, M.J. James, V.M-Y. Lee [et al.] // J. Biol. Chem. ‑2013. – V. 288, № 16. – P. 11024–11037.

212. Oxidation of cysteine-322 in the repeat domain of microtubule-associated protein tau controls the in vitro assembly of paired helical filaments / O. Schweers, E.M. Mandelkow, J. Biernat, E. Mandelkow // Proc. Natl. Acad. Sci. USA. – 1995. – V. 92, № 18. – P. 8463–84677.

213. Rojas J.C. Neurometabolic mechanisms for memory enhancement and neuroprotection of methylene blue / J.C. Rojas, A.K. Bruchey, F. Gonzalez-Lima // Prog. Neurobiol. – 2012. – V. 96, № 1. – P. 32–45.

214. Methylene blue delays cellular senescence and enhances key mitochondrial biochemical pathways / H. Atamna, A. Nguyen, C. Schultz [et al.] // FASEB J. – 2008. – V. 22, № 3. – P. 703–712.

215. Лебедев А.Т. Масс-спектрометрия в органической химии / А.Т. Лебедев. – М.: БИНОМ, 2003.–493 с. / Lebedev A.T. Mass-spektrometrija v organicheskoj himii / A.T. Lebedev. – M.: BINOM, 2003.–493 s.

216. Покровский В.А. Десорбционная масс-спектрометрия и ее применение в химии поверхности: дис.... докт. физ.-мат. наук.: 01.04.01 / Покровский Валерий Александрович. – К., 1990. - 347 с. / Pokrovskij V.A. Desorbcionnaja mass-spektrometrija i ee primenenie v himii poverhnosti: dis.... dokt. fiz.-mat. nauk.: 01.04.01 / Pokrovskij Valerij Aleksandrovich. – K., 1990. - 347 s.

217. Kazakoff C.W. Reduction processes in fast atom bombardment mass spectrometry: Methylene blue in glycerol-thioglycerol and glycerol-nitrobenzyl alcohol matrices / C.W. Kazakoff, R.T.B. Rye // Org. Mass Spectrom. – 1991. – V. 26, № 3. – P. 154–156.

218. Burinsky D.J. Reduction of methylene blue during the ionization process / D.J. Burinsky, R.L. Dilliplane, G.C. DiDonato, K.L. Busch // Org. Mass Spectrom. – 1988. – V. 23, № 4. – P. 231–235.

219. Pelzer G. Oxidation-reduction processes occurring in secondary ion mass spectrometry and fast atom bombardment of glycerol solutions / G. Pelzer, E. De Pauw, J. Marien // J. Phys. Chem. – 1984. – V. 88, № 21. – P. 5065–5068.
220. Gale P.J. Reduction in liquid secondary ion mass spectrometry. Comparison of the fission fragments and liquid secondary ion mass spectra for organic dyestuff / P.J. Gale, B.L. Bentz // Anal. Chem. – 1986. ‑ V. 58, № 6. – P. 1070–1076.

221. Reduction of organic dyes in matrix-assisted laser desorption/ionization and desorption/ionization on porous silicon / S. Okuno, M. Nakano, G.E. Matsubayashi [et al.] // Rapid Commun. Mass Spectrom. – 2004. – V. 18, № 23. – P. 2811–2817.

222. Козик О.И. Масс-спектрометрическое изучение термической деструкции гетероароматических катионных красителей в твердой фазе и на поверхности дисперсного кремнезема: дис.... канд. хим. наук: 02.00.18 / Козик Олег Иосифович – К., 1992. – 175 с. / Kozik O.I. Mass-spektrometricheskoe izuchenie termicheskoj destrukcii geteroaromaticheskih kationnyh krasitelej v tverdoj faze i na poverhnosti dispersnogo kremnezema: dis.... kand. him. nauk: 02.00.18 / Kozik Oleg Iosifovich – K., 1992. – 175 s.

223. Шмиголь І.В. Хімічно модифікований пористий кремній як підкладка для лазерної десорбції / іонізації низькомолекулярних органічних сполук: дис. ... канд. хім. наук: 01.04.18 / І. В. Шмиголь Ірина Василівна. – К., 2009. – 125 с. / Shmigol' І.V. Hіmіchno modifіkovanij poristij kremnіj jak pіdkladka dlja lazernoї desorbcії / іonіzacії niz'komolekuljarnih organіchnih spoluk: dis. ... kand. hіm. nauk: 01.04.18 / І. V. Shmigol' Іrina Vasilіvna. – K., 2009. – 125 s.

224. Фесенко Т.В. Лазерна десорбція/іонізація фотоактивних органічних молекул на поверхні мезопористих оксидних золь-гель плівок: дис…. канд. хім. наук: 01.04.18 / Фесенко Татьяна Викторовна. – К., 2014. – 143 с. / Fesenko T.V. Lazerna desorbcіja/іonіzacіja fotoaktivnih organіchnih molekul na poverhnі mezoporistih oksidnih zol'-gel' plіvok: dis…. kand. hіm. nauk: 01.04.18 / Fesenko Tat'jana Viktorovna. – K., 2014. – 143 s.

225. Kosevich M.V. Chapter Seven: Interactions of Biologically Active Redox-Sensitive Dyes with Nanomaterials: Mass Spectrometric Diagnostics / M.V. Kosevich, O.A. Boryak, V.V. Chagovets, V.S. Shelkovsky, V.A. Pokrovskiy // Nanobiophysics: Fundamental and Applications. Ed. V. Karachevtsev. – Singapore: Pan Stanford Publishing, 2015. – P. 193–233.

226. Evaluation of the reduction of imidazophenazine dye derivatives under fast atom bombardment mass spectrometric conditions / M.V. Kosevich, O.A. Boryak, V.V. Orlov [et al.] // J. Mass Spectrom. – 2006. – V. 41, № 1. – P. 113–123.

227. Sensitivity of redox reactions of dyes to variations of conditions created in mass spectrometric experiments / M.V. Kosevich, V.V. Chagovets, I.V. Shmigol [et al.] // J. Mass Spectrom. – 2008. – V. 43, № 10. – P. 1402–1412.

228. Chemically modified porous silicon for laser desorption/ionization mass spectrometry of ionic dyes / I.V. Shmigol, S.A. Alekseev, O.Yu. Lavrynenko [et al.] // J. Mass Spectrom. – 2009. – V. 44, № 8. – P. 1234–1240.

229. Масс-спектрометрия с лазерной десорбцией/ионизацией красителя метиленового голубого с поверхности мезопористых тонких пленок TiO2, SiO2 /TiO2 и SiO2 / Т.В. Фесенко, М.В. Косевич, Н.И. Суровцева и др. // Масс-спектрометрия. ‑ 2007. ‑ Т. 4, N 4. – C. 289-296. / Mass-spektrometrija s lazernoj desorbciej/ionizaciej krasitelja metilenovogo golubogo s poverhnosti mezoporistyh tonkih plenok TiO2, SiO2 /TiO2 i SiO2 / T.V. Fesenko, M.V. Kosevich, N.I. Surovceva i dr. // Mass-spektrometrija. ‑ 2007. ‑ T. 4, N 4. – C. 289-296.

230. Габович В.О. Іоноутворення метиленового блакитного на різних поверхнях / Габович В.О., Покровський В.О. // Поверхность. – 2011. – Т. 3, № 18. – С. 191–195. / Gabovich V.O. Іonoutvorennja metilenovogo blakitnogo na rіznih poverhnjah / Gabovich V.O., Pokrovs'kij V.O. // Poverhnost'. – 2011. – T. 3, № 18. – S. 191–195.

231. Експериментальне та теоретичне дослідження лазерної десорбції/іонізації метиленоsвого блакитного з поверхні терморозширеного графіту / В.О. Габович, В.О. Покровський, Є.М. Дем’яненко, А.Г. Гребенюк // Укр. фіз. журнал. – 2012. – Т. 57, № 7. – С. 775–782. / Eksperimental'ne ta teoretichne doslіdzhennja lazernoї desorbcії/іonіzacії metilenosvogo blakitnogo z poverhnі termorozshirenogo grafіtu / V.O. Gabovich, V.O. Pokrovs'kij, Є.M. Dem’janenko, A.G. Grebenjuk // Ukr. fіz. zhurnal. – 2012. – T. 57, № 7. – S. 775–782.

232. Габович В.О. Порівняння лазерної десорбції/іонізації барвників акридинового оранжевого та метиленового блакитного з поверхні терморозширеного графіту / В.О. Габович, В.О. Покровський // Хім., фіз. та технологія поверхні. – 2013. – Т. 4, № 2. – С. 196–201. / Gabovich V.O. Porіvnjannja lazernoї desorbcії/іonіzacії barvnikіv akridinovogo oranzhevogo ta metilenovogo blakitnogo z poverhnі termorozshirenogo grafіtu / V.O. Gabovich, V.O. Pokrovs'kij // Hіm., fіz. ta tehnologіja poverhnі. – 2013. – T. 4, № 2. – S. 196–201.

233. Квантовохімічне дослідження структурних перетворень акридинового оранжoвого в умовах лазерної десорбції/іонізації на поверхні терморозширеного графіту / Є.М. Дем’яненко, А.Г. Гребенюк, В.В. Лобанов [та інш.] // Хім., фіз. та технологія поверхні. – 2014. – Т. 5, № 3. – С. 284–290. / Kvantovohіmіchne doslіdzhennja strukturnih peretvoren' akridinovogo oranzhovogo v umovah lazernoї desorbcії/іonіzacії na poverhnі termorozshirenogo grafіtu / Є.M. Dem’janenko, A.G. Grebenjuk, V.V. Lobanov [ta іnsh.] // Hіm., fіz. ta tehnologіja poverhnі. – 2014. – T. 5, № 3. – S. 284–290.

234. Photocatalytic degradation of methylene blue on nanocrystalline TiO2: Surface mass spectrometry of reaction intermediates / H. Gnaser, M.R. Savina, W.F. Calaway [et al.] // Int. J. Mass Spectrom. – 2005. – V. 245, № 1-3. – P. 61–67.

235. Kertesz V. Electropolymerization of Methylene Blue investigated using on-line electrochemistry / electrospray mass spectrometry / V. Kertesz, G.J. Van Berkel // Electroanalysis. – 2001. – V. 13, № 17. – P. 1425–1430.

236. Quantification of cationic anti-malaria agent methylene blue in different human biological matrices using cation exchange chromatography coupled to tandem mass spectrometry / J. Burhenne, K.D. Riedel, J. Rengels-hausen [et al.] // J. Chromatogr. B Analyt. Technol. Biomed. Life Sci. – 2008. – V. 863, № 2. – P. 273–282.

237. Analysis of methylene blue and its metabolites in blood by capillary electrophoresis/electrospray ionization mass spectrometry / F. Yang, S. Xia, Z. Liu, Chen J, Lin Y, Qiu B, Chen G. [et al.] // Electrophoresis. – 2011. – V. 32, № 6-7. – P. 659–64.

238. Paper spray for direct analysis of complex mixtures using mass spectrometry / H. Wang, J. Liu, R.G. Cooks, Z. Ouyang // Angew. Chem. Int. Ed. Engl. – 2010. – V. 49, № 5. – P. 877–880.
Cited
How to Cite
Шелковский, В. С. (1). Utilization of redox and aggregation properties of methylene blue dye in nanobiophysical investigations. Biophysical Bulletin, 1(33), 5-29. Retrieved from https://periodicals.karazin.ua/biophysvisnyk/article/view/4270
Issue
Vol. 1 No. 33 (2015): Biophysical Bulletin
Section
Molecular biophysics
Copyright (c) 2015 В. С. Шелковский

Authors who publish with this journal agree to the following terms:

  1. Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.
  2. Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.
  3. Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work (See The Effect of Open Access).