الفهرس | Only 14 pages are availabe for public view |
Abstract 1. Turner, A., Biosensors: Fundamentals and Applications. 1989. 2. IsmailHakk, B. and M. Mehmet, Amperometric Biosensors in Food Processing, Safety, and Quality Control, in Biosensors in Food Processing, Safety, and Quality Control. 2010, CRC Press. p. 1-51. 3. Nora Savage, M.D., Jeremiah Duncan, Anita Street, and Richard Sustich, Nanotechnology Applications for Clean Water. 2009. 4. Velasco-Garcia, M.N. and T. Mottram, Biosensor Technology addressing Agricultural Problems. Biosystems Engineering, 2003. 84(1): p. 1-12. 5. Antuña-Jiménez, D., et al., Chapter 1 - Molecularly Imprinted Electrochemical Sensors: Past, Present, and Future, in Molecularly Imprinted Sensors. 2012, Elsevier: Amsterdam. p. 1-34. 6. Yahagi, T., et al., Mutagenicity of carcinogenic azo dyes and their derivatives. Cancer Letters, 1975. 1: p. 91-96. 7. Rehorek, A., et al., Monitoring of azo dye degradation processes in a bioreactor by on-line high-performance liquid chromatography. Journal of chromatography A, 2002. 949(1–2): p. 263-268. 8. Bilgi, S. and C. Demir, Identification of photooxidation degradation products of C.I. Reactive Orange 16 dye by gas chromatography– mass spectrometry. Dyes and Pigments, 2005. 66(1): p. 69-76. 9. Bersier, P.M. and J. Bersier, Polarography and voltammetry of dyes and intermediates. TrAC Trends in Analytical Chemistry, 1986. 5(4): p. 97-102. 10. ªahin, S., C. Demir, and e. Güçer, Simultaneous UV–vis spectrophotometric determination of disperse dyes in textile wastewater by partial least squares and principal component regression. Dyes and Pigments, 2007. 73(3): p. 368-376. 91 11. Pérez-Urquiza, M., R. Ferrer, and J.L. Beltrán, Determination of sulfonated azo dyes in river water samples by capillary zone electrophoresis. Journal of chromatography A, 2000. 883(1–2): p. 277-283. 12. Suzuki, T., et al., Correlation of aerobic biodegradability of sulfonated azo dyes with the chemical structure. Chemosphere, 2001. 45(1): p. 1-9. 13. Cioni, F., et al., Development of a solid phase microextraction method for detection of the use of banned azo dyes in coloured textiles and leather. Rapid Communications in Mass Spectrometry, 1999. 13(18): p. 1833-1837. 14. Muruganandham, M. and M. Swaminathan, Photochemical oxidation of reactive azo dye with UV–H< sub> 2</sub> O< sub> 2</sub> process. Dyes and Pigments, 2004. 62(3): p. 269-275. 15. Yang, Y. and L. Xu, Reusing hydrolyzed reactive dyebath for nylon and wool dyeing. American dyestuff reporter, 1996. 85(3): p. 27-34. 16. Chen, M., et al., Purification and identification of several sulphonated azo dyes using reversed-phase preparative high-performance liquid chromatography. Journal of chromatography A, 1998. 825(1): p. 37- 44. 17. Borrós, S., et al., The use of capillary electrophoresis to study the formation of carcinogenic aryl amines in azo dyes. Dyes and Pigments, 1999. 43(3): p. 189-196. 18. Stylidi, M., D.I. Kondarides, and X.E. Verykios, Pathways of solar light-induced photocatalytic degradation of azo dyes in aqueous TiO< sub> 2</sub> suspensions. Applied Catalysis B: Environmental, 2003. 40(4): p. 271-286. 92 19. Saquib, M. and M. Muneer, TiO2-mediated photocatalytic degradation of a triphenylmethane dye (gentian violet), in aqueous suspensions. Dyes and Pigments, 2003. 56(1): p. 37-49. 20. López Cisneros, R., A. Gutarra Espinoza, and M.I. Litter, Photodegradation of an azo dye of the textile industry. Chemosphere, 2002. 48(4): p. 393-399. 21. Šafaøýìk, I. and M. Šafaøýìková, Detection of low concentrations of malachite green and crystal violet in water. Water Research, 2002. 36(1): p. 196-200. 22. Plum, A. and A. Rehorek, Strategies for continuous on-line high performance liquid chromatography coupled with diode array detection and electrospray tandem mass spectrometry for process monitoring of sulphonated azo dyes and their intermediates in anaerobic–aerobic bioreactors. Journal of chromatography A, 2005. 1084(1–2): p. 119-133. 23. Plum, A., G. Braun, and A. Rehorek, Process monitoring of anaerobic azo dye degradation by high-performance liquid chromatography– diode array detection continuously coupled to membrane filtration sampling modules. Journal of chromatography A, 2003. 987(1–2): p. 395-402. 24. Calbiani, F., et al., Development and in-house validation of a liquid chromatography–electrospray–tandem mass spectrometry method for the simultaneous determination of Sudan I, Sudan II, Sudan III and Sudan IV in hot chilli products. Journal of chromatography A, 2004. 1042(1–2): p. 123-130. 25. Holčapek, M., P. Jandera, and P. Zderadička, High performance liquid chromatography–mass spectrometric analysis of sulphonated dyes 93 and intermediates. Journal of chromatography A, 2001. 926(1): p. 175-186. 26. Pérez-Urquiza, M. and J.L. Beltrán, Determination of the dissociation constants of sulfonated azo dyes by capillary zone electrophoresis and spectrophotometry methods. Journal of chromatography A, 2001. 917(1–2): p. 331-336. 27. Riu, J., et al., Determination of sulphonated azo dyes in water and wastewater. TrAC Trends in Analytical Chemistry, 1997. 16(7): p. 405-419. 28. Netpradit, S., P. Thiravetyan, and S. Towprayoon, Adsorption of three azo reactive dyes by metal hydroxide sludge: effect of temperature, pH, and electrolytes. Journal of Colloid and Interface Science, 2004. 270(2): p. 255-261. 29. Mottaleb, M.A. and D. Littlejohn, Application of an HPLC-FTIR modified thermospray interface for analysis of dye samples. Analytical Sciences, 2001. 17(3): p. 429-434. 30. Robinson, T., et al., Remediation of dyes in textile effluent: a critical review on current treatment technologies with a proposed alternative. Bioresource Technology, 2001. 77(3): p. 247-255. 31. O’Neill, C., et al., Colour in textile effluents–sources, measurement, discharge consents and simulation: a review. Journal of Chemical Technology and Biotechnology, 1999. 74(11): p. 1009-1018. 32. Schönsee, I., J. Riu, and D. Barceló, Quim. Anal., 1997. 16: p. 243– 249. 33. Vanìrková, D., P. Jandera, and J. Hrabica, Behaviour of sulphonated azodyes in ion-pairing reversed-phase high-performance liquid 94 chromatography. Journal of chromatography A, 2007. 1143(1–2): p. 112-120. 34. Nevado, J.J.B., C.G. Cabanillas, and A.M.C. Salcedo, Simultaneous spectrophotometric determination of three food dyes by using the first derivative of ratio spectra. Talanta, 1995. 42(12): p. 2043-2051. 35. Reig, F.B. and P.C. Falcó, H-point standard additions method. Part 1. Fundamentals and application to analytical spectroscopy. Analyst, 1988. 113(7): p. 1011-1016. 36. Escandar, G.M., et al., A review of multivariate calibration methods applied to biomedical analysis. Microchemical Journal, 2006. 82(1): p. 29-42. 37. Geladi, P., Chemometrics in spectroscopy. Part 1. Classical chemometrics. Spectrochimica Acta Part B: Atomic Spectroscopy, 2003. 58(5): p. 767-782. 38. Hemmateenejad, B., M.A. Safarpour, and A. Mohammad Mehranpour, Net analyte signal–artificial neural network (NAS–ANN) model for efficient nonlinear multivariate calibration. Analytica Chimica Acta, 2005. 535(1–2): p. 275-285. 39. Korn, M.d.G.A., et al., Separation and preconcentration procedures for the determination of lead using spectrometric techniques: A review. Talanta, 2006. 69(1): p. 16-24. 40. El-Barghouthi, M.I., et al., Adsorption Behavior of Anionic Reactive Dyes on H-type Activated Carbon: Competitive Adsorption and Desorption Studies. Separation Science and Technology, 2007. 42(10): p. 2195-2220. 95 41. de Castro Dantas, T.N., et al., Use of microemulsions for removal of color and dyes from textile wastewater. Journal of Chemical Technology and Biotechnology, 2004. 79(6): p. 645-650. 42. López-Grimau, V., et al., Electrochemical decolourisation of cotton dye baths for reuse purposes: a way to reduce salinity of the textile wastewater. Desalination and Water Treatment, 2013. 51(7-9): p. 1527-1532. 43. Rodrigues, C.S., L.M. Madeira, and R.A. Boaventura, Optimization and Economic Analysis of Textile Wastewater Treatment by Photo- Fenton Process under Artificial and Simulated Solar Radiation. Industrial & Engineering Chemistry Research, 2013. 52(37): p. 13313-13324. 44. Bard, A.J., New challenges in electrochemistry and electroanalysis. Pure Appl. Chem, 1992. 64: p. 185-192. 45. Zhu, Q.-Z., et al., Determination of nucleic acids using phosphin 3R as a fluorescence probe. Anal. Chim. Acta.,, 1999. 394(2): p. 177- 184. 46. Kaifer, A. and M. Gomez-Kaifer, Supramolecular Electrochemistry 1999. 1999, Wiley-VCH: Weinheim. 47. Gupta, N. and H. Linschitz, Hydrogen-bonding and protonation effects in electrochemistry of quinones in aprotic solvents. J. Am. Chem. Soc., 1997. 119(27): p. 6384-6391. 48. Heffner, J.E., et al., Using cyclic voltammetry and molecular modeling to determine substituent effects in the one-electron reduction of benzoquinones. J. Chem. Educ., 1998. 75(3): p. 365. 49. Gomez .M, F.J.G.a.I.G., Electroanalysis, 2003. 15: p. 635 96 50. Allen, J.B. and R.F. Larry, Electrochemical methods: fundamentals and applications. Department of Chemistry and Biochemistry University of Texas at Austin, John Wiley & Sons, Inc, 2000. 51. Otles, S., Handbook of food analysis instruments. 2008: CRC Press. 52. Bard, A.J. and L.R. Faulkner, Electrochemical methods: fundamentals and applications. Vol. 2. 1980: Wiley New York. 53. Palanti, S., G. Marrazza, and M. Mascini, Electrochemical DNA probes. Analytical Letters, 1996. 29(13): p. 2309-2331. 54. Carter, M.T., M. Rodriguez, and A.J. Bard, Voltammetric studies of the interaction of metal chelates with DNA. 2. Tris-chelated complexes of cobalt (III) and iron (II) with 1, 10-phenanthroline and 2, 2’-bipyridine. Journal of the American Chemical Society, 1989. 111(24): p. 8901-8911. 55. Jiao, K., et al., Studies on the recognition interaction of rhodamine B and DNA by voltammetry. Chemical Research in Chinese Universities, 2005. 21(2): p. 145-148. 56. Wang, Q.-X., et al., Spectroscopic, viscositic and electrochemical studies of DNA interaction with a novel mixed-ligand complex of nickel (II) that incorporates 1-methylimidazole and thiocyanate groups. Journal of Biochemical and Biophysical Methods, 2007. 70(3): p. 427-433. 57. Brett, A.M.O., S.H. Serrano, and A.J.P. Piedade, Electrochemistry of DNA, in Comprehensive Chemical Kinetics. 1999, Elsevier: Amsterdam. p. 91-119. 58. Brett, A.M.O., et al., Electrochemical determination of carboplatin in serum using a DNA ‐ modified glassy carbon electrode. Electroanalysis, 1996. 8(11): p. 992-995. 97 59. Benesi, H.A. and J.H. Hildebrand, A spectrophotometric investigation of the interaction of iodine with aromatic hydrocarbons. Journal of the American Chemical Society, 1949. 71(8): p. 2703-2707. 60. Cao, Y. and X.-w. He, Studies of interaction between safranine T and double helix DNA by spectral methods. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 1998. 54(6): p. 883-892. 61. Chuan, D., W. Yu-xia, and W. Yan-li, Study on the interaction between methylene violet and calf thymus DNA by molecular spectroscopy. Journal of Photochemistry and Photobiology A: Chemistry, 2005. 174(1): p. 15-22. 62. Modukuru, N.K., et al., Contributions of a long side chain to the binding affinity of an anthracene derivative to DNA. The Journal of Physical Chemistry B, 2005. 109(23): p. 11810-11818. 63. Long, E.C. and J.K. Barton, On demonstrating DNA intercalation. Accounts of Chemical Research, 1990. 23(9): p. 271-273. 64. Cantor, C.R. and P.R. Schimmel, Biophysical Chemistry. 1980, WH Freeman: San Francisco, CA. 65. Pyle, A., et al., Mixed-ligand complexes of ruthenium (II): factors governing binding to DNA. Journal of the American Chemical Society, 1989. 111(8): p. 3051-3058. 66. Wolfe, A., G.H. Shimer Jr, and T. Meehan, Polycyclic aromatic hydrocarbons physically intercalate into duplex regions of denatured DNA. Biochemistry, 1987. 26(20): p. 6392-6396. 67. Carter, M.T., M. Rodriguez, and A.J. Bard, Voltammetric studies of the interaction of metal chelates with DNA. 2. Tris-chelated complexes of cobalt(III) and iron(II) with 1,10-phenanthroline and 98 2,2′-bipyridine. Journal of the American Chemical Society, 1989. 111(24): p. 8901-8911. 68. Takenaka, S., T. Ihara, and M. Takagi, Bis-9-acridinyl derivative containing a viologen linker chain: Electrochemically active intercalator for reversible labelling of DNA. Journal of the Chemical Society - Series Chemical Communications, 1990(21): p. 1485-1487. 69. Dang, X.J., et al., Inclusion of the parent molecules of some drugs with β-cyclodextrin studied by electrochemical and spectrometric methods. Journal of Electroanalytical Chemistry, 1998. 448(1): p. 61- 67. 70. Bard, A. and L. Faulkner, Electrochemical methods: principles and applications. Electrochemical Methods: Principles and Applications, 2001. 71. Meggers, E., M.E. Michel-Beyerle, and B. Giese, Sequence dependent long range hole transport in DNA. Journal of the American Chemical Society, 1998. 120(49): p. 12950-12955. 72. Delaney, S. and J.K. Barton, Long-range DNA charge transport. The Journal of organic chemistry, 2003. 68(17): p. 6475-6483. 73. Hall, D.B. and J.K. Barton, Sensitivity of DNA-mediated electron transfer to the intervening π-stack: a probe for the integrity of the DNA base stack. Journal of the American Chemical Society, 1997. 119(21): p. 5045-5046. 74. Ahmadi, F., et al., The experimental and theoretical QM/MM study of interaction of chloridazon herbicide with ds-DNA. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2011. 79(5): p. 1004-1012. |