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Yıl 2018, Cilt: 2 Sayı: 2, 200 - 207, 15.08.2018

Öz

Kaynakça

  • 1. Telefoncu, A., Biochemistry Graduate Summer School -Biosensors, 1999, Izmir-Turkey: Ege University Science Faculty Press, p. 1-2.
  • 2. Anonymous. [cited 2016 07 May]; Available from: http://iupac.org/
  • 3. Grieshaber, D., R. MacKenzie, J. Vörös, and E. Reimhult. Electrochemical Biosensors - Sensor Principles and Architectures. Sensors, Switzerland, 2008. 8(3), p. 1400–1458.
  • 4. Jain, K.K., Applications of biochips: from diagnostics to personalized medicine. Current Opinion to Drug Discovery and Development. 2004. 7, p.285–289.
  • 5. Jianrong, C., M. Yuqing, H. Nongyue, W. Xiaohua, and L. Sijiao. Nanotechnology and biosensors. Biotechnology Advances. 2004. 22, p.505–518.
  • 6. Malik, P., V. Katyal, V. Malik, A. Asatkar, G. Inwati, and T.K. Mukherjee. Nanobiosensors: Concepts and Variations. Hindawi Publishing Corporation. ISRN Nanomaterials. 2013. 2013 (327435), 9 pages.
  • 7. Abu-Salah, K.M., S.A. Alrokyan, M.N. Khan, and A.A. Ansari. Nanomaterials as Analytical Tools for Genosensors. Sensors, 2010. 10, p. 963-993.
  • 8. Li, Yanbin. 2006. Section 2.3 Biosensors, p. 52-93, of Chapter 2 Hardware, in CIGR Handbook of Agricultural Engineering Volume VI Information Technology. Edited by CIGR-The International Commission of Agricultural Engineering; Volume Editor, Axel Munack. St. Joseph, Michigan, USA: ASABE. (doi:10.13031/2013.21666).
  • 9. Tothill, I.E. Biosensors and Nanomaterials and their Application for Mycotoxin Determination. World Mycotoxin Journal. 2011. 4(4), p.361-374.
  • 10. Anonymous. [cited 2016 24 May]; Available from: http://nptel.ac.in/courses/118107015/module3/lecture4/lecture4.pdf
  • 11. Akbayırlı, P., E. Akyılmaz. Activation-based catalase enzyme electrode and its usage for glucose determination. Analytical Letters. 2007. 40, p.3360-3372.
  • 12. Clark, Jr. L. C., and C. Lyons. Electrode systems for continuous monitoring in cardiovascular surgery. Ann. N.Y. Acad. Sci. 1962. 105, p. 20-45.
  • 13. Guilbault, G. G., and J. Montalvo. Urea-specific enzyme electrode. Journal of American Chemical Society. 1969. 91(8), p. 2164-2569.
  • 14. Scheller, F.W., F. Schubert, B. Neumann, D. Pfeiffer, R. Hintsche, I. Dransfeld, U. Wollenberger, R. Renneberg, A. Warsinke, G. Johansson, M. Skoog, X. Yang, V. Bogdanovskaya, A. Bückmann, S.Y. Zaitsev.. Second generation biosensors. Biosensors and Bioelectronics. 1991 6(3), p. 245-253.
  • 15. Bhushan., B. Nanotribology and nanomechanics of MEMS/NEMS and BioMEMS/BioNEMS materials and devices. Microelectronic Engineering, 2007. 84(3), p. 387–412.
  • 16. Robertson, S. [cited 2016 24 May]; Available from: http://www.news-medical.net/health/Biosensors-and-Food-Industry.aspx
  • 17. Dong, S. and X. Chen, Some new aspects in biosensors. J Biotechnol. 2002. 82(4), p. 303-23.
  • 18. Marazuela, M. and M. Moreno-Bondi. Fiber-optic biosensors – an overview. Analytical and Bioanalytical Chemistry. 2002. 372(5–6), p. 664–682.
  • 19. Pohanka, M. Cholinesterases in biorecognition and biosensor construction, a review. Analytical Letters. 2013. 46(12), p. 1849–1868.
  • 20. Paredes A.P., J. Parellada, M.V. Fernandez, I. Katakis and E. Dominguez. Amperometric Mediated Carbon Paste Biosensor Based On D-fructose dehydrogenase for determination of fructose in food analysis. Biosensors and Bioelectronics. 1997. 12(12), p. 1233-1243.
  • 21. Sacchi S., L. Pollegioni, M.S. Pilone and C. Rosetti. Determination of D-Amino-acids using a D-amino acid oxidase biosensor with spectrophotometric and potentiometric detection. Biotechnology Techniques. 1998. 12, p. 149-153.
  • 22. Rehmrev-Broom M., M. Jonker, K. Venema, G. Jobst, R. Tiessen, and J. Korf. On-line continuous monitoring of glucose or lactate by ultraslow microdialysis combined with flow-through nanoliter biosensor based on poly (m-phenylenediamine) ultra-thin polymer membrane as enzyme electrode. Analyst. 2001. 126 (7), p. 1073-1079.
  • 23. Soldatkin O.O., V.M. Peshkara, S.V. Dzyadevych, A.P. Soldatkin, N. Jaffrezic-Renault, A.V. Elskaya. Novel sucrose three enzyme conductometric biosensor. Mater. Sci. Eng. C. 2008. 28, p. 959-964.
  • 24. Dubey, R. S. and S.N. Upadhyay. Microbial corrosion monitoring by an amperometric microbial biosensor developed using whole cell of Pseudomonas sp. Biosensors and Bioelectronics. 2001. 16(9–12), p. 995–1000.
  • 25. Védrine, C., J.-C. Leclerc, C. Durrieu, and C. Tran-Minh. Optical whole-cell biosensor using Chlorella vulgaris designed for monitoring herbicides. Biosensors and Bioelectronics. 2003. 18(4), p. 457–63.
  • 26. Bragadin, M., S. Manente, R. Piazza, and G. Scutari. The Mitochondria as Biosensors for the Monitoring of Detergent Compounds in Solution. Analytical Biochemistry. 2001. 292(2), p. 305–307.
  • 27. Murugaboopathi, G., V. Parthasarathy, C. Chellaram, T. Prem Anand and S. Vinurajkumar. Applications of Biosensors in Food Industry. Biosciences Biotechnology Research Asia. 2013. 10(2), 711-714.
  • 28. Ali, M.A., T.A. Eldin, M.E. Moghazy, I.M Tork, I.I. Omara. Detection of E. coli O157:H7 in feed samples using gold nanoparticles sensor. International Journal of Current Microbiology and Applied Science. 2014. 3(6):697–708.
  • 29. Xiang, C., R.Li, B. Adhikari, Z. She, Y. Li, H.-B. Kraatz. Sensitive electrochemical detection of Salmonella with Chitosan-Gold oparticles composite film. Talanta. 2015. 140, 122-127.
  • 30. Kokbas, U., L. Kayrin, and A. Tuli. Biosensors and Their Medical Applications. Archives Medical Review Journal. 2013. 22(4), p. 499-513.
  • 31. Thakur, M.S. and K.V. Ragavan. Biosensors in food processing. Journal of Food Science and Technology. 2013. 50(4): 625–641.
  • 32. Van Gerwen, P., W. Laureyn, W. Laureys, G. Huyberechts, M. Op De Beeck, K. Baert, J. Sls, W. Sansen, P. Jacobs, L. Hermans, and R. Mertens. Nanoscaled interdigitated electrode arrays for biochemical sensors. Sensors and Actuators B. 1998. B: 49(1-2), p. 73–80.
  • 33. Yokoo, A. and H. Namatsu. Nanoelectrode Lithograpy: Chemical Nanoimprint that transfers a pattern by electrochemical reaction. Selected papers: forefront of basic research at NTT (Technical Review). 2008. 6(8), p. 1-8.
  • 34. Zhang, W., H. Tang, P. Geng, Q. Wang, L. Jin, and Z. Wu. Amperometric method for rapid detection of Escherichia coli by flow injection analysis using a bismuth nano-film modified glassy carbon electrode. Electrochem. Commun. 2007. 9, p. 833-838.
  • 35. Pak, S. C., W. Penrose, and P.J. Hesketh. An ultrathin platinum film sensor to measure biomolecular binding. Biosensors and Bioelectronics, 2001.16(6), p. 371–379.
  • 36. Lu, B.W. and W.C. Chen. A disposable glucose biosensor based on drop-coating of screen-printed carbon electrodes with magnetic nanoparticles. J. Magn. Magn. Mater. 2006. 304, p. 400-402.
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  • 52. Wang, D., X. Xiao, S. Xu, Y. Liu, and Y. Li. Electrochemical aptamer-based nanosensor fabricated on single Au-nanowire electrodes for adenosine triphosphate assay. Biosensors and Bioelectronics. 2018. 99: 431–437.
  • 53. Liu, J., D. Mazumdar, Y. Lu. A simple and sensitive ―dipstick test in serum based on lateral flow separation of aptamer-linked nanostructures. Angew. Chem. Int. Ed., 2006. 45, p. 7955-7959.
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  • 55. Liu, J., J.H. Lee, Y. Lu. Quantum dot encoding of aptamer-linked nanostructures for one-pot simultaneous detection of multiple analytes. Anal. Chem., 2007. 79, p. 4120-4125.
  • 56. Wang, J., L. Wang, X. Liu, Z. Liang, S. Song, W. Li, G. Li, C. Fan. A gold nanoparticle-based aptamer target binding readout for ATP assay. Adv. Mater., 2007. 19, p. 3943-3946.
  • 57. Chen, S.J., Y.F. Huang, C.C. Huang, K.H. Lee, Z.H. Lin, H.T. Chang. Colorimetric determination of urinary adenosine using aptamer-modified gold nanoparticles. Biosensors and Bioelectronics. 2008. 23, p. 1749-1753.
  • 58. Lee, J.-S., C.A. Mirkin. Chip-based scanometric detection of mercuric ion using DNA-functionalized gold nanoparticles. Anal. Chem., 2008. 80, p. 6805-6808.
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  • 62. Zhao, W., W. Chiuman, J.C.F. Lam, S.A. McManus, W. Chen, Y. Cui, R. Pelton, M.A. Brook, Y. Li. DNA aptamer folding on gold nanoparticles: From colloid chemistry to biosensors. J. Am. Chem. Soc., 2008.130, p. 3610-3618.
  • 63. Wang, L., X. Liu, X. Hu, S. Song, C. Fan. Unmodified gold nanoparticles as a colorimetric probe for potassium DNA aptamers. Chem. Commun., 2006. p. 3780-3782.
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Biosensors from the first generation to nano-biosensors

Yıl 2018, Cilt: 2 Sayı: 2, 200 - 207, 15.08.2018

Öz

All living creatures tend to sense the
changes in their habitat and have to comply with them to survive. At first, the
basics of the biosensor theory began with in
vitro
studies based on sensing ability of living beings. Then, scientists
have started to use this ability in some devices. Lately, these devices have
been smaller and smaller. They are in used for medical, chemical, food and some
other sciences to make easier, cheaper, accurate and rapid detection of
specific reactions, compounds, enzymes, cells according to their electrical,
thermal or optical signals. Lastly, the 4th generation of biosensor technology,
as lived now, has started with the developments of Micro, Nano or BioNano
Electro-Mechanical Systems (MEMS/NEMS/BioNEMS), nanotechnology and
biotechnology that are expected to have lots of features. Furthermore molecular
recognition elements like aptamers which are synthetic oligonucleotide ligands
against various target molecules ranging from small ions to large proteins,
toxins and other analytes as receptors. The studies on using aptamers
conjugated with nanomaterials to fabricate and design novel biosensors appear
to continue due to various advantages such as frequency of usage, practical use
and time-saving. 

Kaynakça

  • 1. Telefoncu, A., Biochemistry Graduate Summer School -Biosensors, 1999, Izmir-Turkey: Ege University Science Faculty Press, p. 1-2.
  • 2. Anonymous. [cited 2016 07 May]; Available from: http://iupac.org/
  • 3. Grieshaber, D., R. MacKenzie, J. Vörös, and E. Reimhult. Electrochemical Biosensors - Sensor Principles and Architectures. Sensors, Switzerland, 2008. 8(3), p. 1400–1458.
  • 4. Jain, K.K., Applications of biochips: from diagnostics to personalized medicine. Current Opinion to Drug Discovery and Development. 2004. 7, p.285–289.
  • 5. Jianrong, C., M. Yuqing, H. Nongyue, W. Xiaohua, and L. Sijiao. Nanotechnology and biosensors. Biotechnology Advances. 2004. 22, p.505–518.
  • 6. Malik, P., V. Katyal, V. Malik, A. Asatkar, G. Inwati, and T.K. Mukherjee. Nanobiosensors: Concepts and Variations. Hindawi Publishing Corporation. ISRN Nanomaterials. 2013. 2013 (327435), 9 pages.
  • 7. Abu-Salah, K.M., S.A. Alrokyan, M.N. Khan, and A.A. Ansari. Nanomaterials as Analytical Tools for Genosensors. Sensors, 2010. 10, p. 963-993.
  • 8. Li, Yanbin. 2006. Section 2.3 Biosensors, p. 52-93, of Chapter 2 Hardware, in CIGR Handbook of Agricultural Engineering Volume VI Information Technology. Edited by CIGR-The International Commission of Agricultural Engineering; Volume Editor, Axel Munack. St. Joseph, Michigan, USA: ASABE. (doi:10.13031/2013.21666).
  • 9. Tothill, I.E. Biosensors and Nanomaterials and their Application for Mycotoxin Determination. World Mycotoxin Journal. 2011. 4(4), p.361-374.
  • 10. Anonymous. [cited 2016 24 May]; Available from: http://nptel.ac.in/courses/118107015/module3/lecture4/lecture4.pdf
  • 11. Akbayırlı, P., E. Akyılmaz. Activation-based catalase enzyme electrode and its usage for glucose determination. Analytical Letters. 2007. 40, p.3360-3372.
  • 12. Clark, Jr. L. C., and C. Lyons. Electrode systems for continuous monitoring in cardiovascular surgery. Ann. N.Y. Acad. Sci. 1962. 105, p. 20-45.
  • 13. Guilbault, G. G., and J. Montalvo. Urea-specific enzyme electrode. Journal of American Chemical Society. 1969. 91(8), p. 2164-2569.
  • 14. Scheller, F.W., F. Schubert, B. Neumann, D. Pfeiffer, R. Hintsche, I. Dransfeld, U. Wollenberger, R. Renneberg, A. Warsinke, G. Johansson, M. Skoog, X. Yang, V. Bogdanovskaya, A. Bückmann, S.Y. Zaitsev.. Second generation biosensors. Biosensors and Bioelectronics. 1991 6(3), p. 245-253.
  • 15. Bhushan., B. Nanotribology and nanomechanics of MEMS/NEMS and BioMEMS/BioNEMS materials and devices. Microelectronic Engineering, 2007. 84(3), p. 387–412.
  • 16. Robertson, S. [cited 2016 24 May]; Available from: http://www.news-medical.net/health/Biosensors-and-Food-Industry.aspx
  • 17. Dong, S. and X. Chen, Some new aspects in biosensors. J Biotechnol. 2002. 82(4), p. 303-23.
  • 18. Marazuela, M. and M. Moreno-Bondi. Fiber-optic biosensors – an overview. Analytical and Bioanalytical Chemistry. 2002. 372(5–6), p. 664–682.
  • 19. Pohanka, M. Cholinesterases in biorecognition and biosensor construction, a review. Analytical Letters. 2013. 46(12), p. 1849–1868.
  • 20. Paredes A.P., J. Parellada, M.V. Fernandez, I. Katakis and E. Dominguez. Amperometric Mediated Carbon Paste Biosensor Based On D-fructose dehydrogenase for determination of fructose in food analysis. Biosensors and Bioelectronics. 1997. 12(12), p. 1233-1243.
  • 21. Sacchi S., L. Pollegioni, M.S. Pilone and C. Rosetti. Determination of D-Amino-acids using a D-amino acid oxidase biosensor with spectrophotometric and potentiometric detection. Biotechnology Techniques. 1998. 12, p. 149-153.
  • 22. Rehmrev-Broom M., M. Jonker, K. Venema, G. Jobst, R. Tiessen, and J. Korf. On-line continuous monitoring of glucose or lactate by ultraslow microdialysis combined with flow-through nanoliter biosensor based on poly (m-phenylenediamine) ultra-thin polymer membrane as enzyme electrode. Analyst. 2001. 126 (7), p. 1073-1079.
  • 23. Soldatkin O.O., V.M. Peshkara, S.V. Dzyadevych, A.P. Soldatkin, N. Jaffrezic-Renault, A.V. Elskaya. Novel sucrose three enzyme conductometric biosensor. Mater. Sci. Eng. C. 2008. 28, p. 959-964.
  • 24. Dubey, R. S. and S.N. Upadhyay. Microbial corrosion monitoring by an amperometric microbial biosensor developed using whole cell of Pseudomonas sp. Biosensors and Bioelectronics. 2001. 16(9–12), p. 995–1000.
  • 25. Védrine, C., J.-C. Leclerc, C. Durrieu, and C. Tran-Minh. Optical whole-cell biosensor using Chlorella vulgaris designed for monitoring herbicides. Biosensors and Bioelectronics. 2003. 18(4), p. 457–63.
  • 26. Bragadin, M., S. Manente, R. Piazza, and G. Scutari. The Mitochondria as Biosensors for the Monitoring of Detergent Compounds in Solution. Analytical Biochemistry. 2001. 292(2), p. 305–307.
  • 27. Murugaboopathi, G., V. Parthasarathy, C. Chellaram, T. Prem Anand and S. Vinurajkumar. Applications of Biosensors in Food Industry. Biosciences Biotechnology Research Asia. 2013. 10(2), 711-714.
  • 28. Ali, M.A., T.A. Eldin, M.E. Moghazy, I.M Tork, I.I. Omara. Detection of E. coli O157:H7 in feed samples using gold nanoparticles sensor. International Journal of Current Microbiology and Applied Science. 2014. 3(6):697–708.
  • 29. Xiang, C., R.Li, B. Adhikari, Z. She, Y. Li, H.-B. Kraatz. Sensitive electrochemical detection of Salmonella with Chitosan-Gold oparticles composite film. Talanta. 2015. 140, 122-127.
  • 30. Kokbas, U., L. Kayrin, and A. Tuli. Biosensors and Their Medical Applications. Archives Medical Review Journal. 2013. 22(4), p. 499-513.
  • 31. Thakur, M.S. and K.V. Ragavan. Biosensors in food processing. Journal of Food Science and Technology. 2013. 50(4): 625–641.
  • 32. Van Gerwen, P., W. Laureyn, W. Laureys, G. Huyberechts, M. Op De Beeck, K. Baert, J. Sls, W. Sansen, P. Jacobs, L. Hermans, and R. Mertens. Nanoscaled interdigitated electrode arrays for biochemical sensors. Sensors and Actuators B. 1998. B: 49(1-2), p. 73–80.
  • 33. Yokoo, A. and H. Namatsu. Nanoelectrode Lithograpy: Chemical Nanoimprint that transfers a pattern by electrochemical reaction. Selected papers: forefront of basic research at NTT (Technical Review). 2008. 6(8), p. 1-8.
  • 34. Zhang, W., H. Tang, P. Geng, Q. Wang, L. Jin, and Z. Wu. Amperometric method for rapid detection of Escherichia coli by flow injection analysis using a bismuth nano-film modified glassy carbon electrode. Electrochem. Commun. 2007. 9, p. 833-838.
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Toplam 86 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Bölüm Review Articles
Yazarlar

Sercan Dede

Filiz Altay

Yayımlanma Tarihi 15 Ağustos 2018
Gönderilme Tarihi 14 Mart 2018
Kabul Tarihi 21 Mayıs 2018
Yayımlandığı Sayı Yıl 2018 Cilt: 2 Sayı: 2

Kaynak Göster

APA Dede, S., & Altay, F. (2018). Biosensors from the first generation to nano-biosensors. International Advanced Researches and Engineering Journal, 2(2), 200-207.
AMA Dede S, Altay F. Biosensors from the first generation to nano-biosensors. Int. Adv. Res. Eng. J. Ağustos 2018;2(2):200-207.
Chicago Dede, Sercan, ve Filiz Altay. “Biosensors from the First Generation to Nano-Biosensors”. International Advanced Researches and Engineering Journal 2, sy. 2 (Ağustos 2018): 200-207.
EndNote Dede S, Altay F (01 Ağustos 2018) Biosensors from the first generation to nano-biosensors. International Advanced Researches and Engineering Journal 2 2 200–207.
IEEE S. Dede ve F. Altay, “Biosensors from the first generation to nano-biosensors”, Int. Adv. Res. Eng. J., c. 2, sy. 2, ss. 200–207, 2018.
ISNAD Dede, Sercan - Altay, Filiz. “Biosensors from the First Generation to Nano-Biosensors”. International Advanced Researches and Engineering Journal 2/2 (Ağustos 2018), 200-207.
JAMA Dede S, Altay F. Biosensors from the first generation to nano-biosensors. Int. Adv. Res. Eng. J. 2018;2:200–207.
MLA Dede, Sercan ve Filiz Altay. “Biosensors from the First Generation to Nano-Biosensors”. International Advanced Researches and Engineering Journal, c. 2, sy. 2, 2018, ss. 200-7.
Vancouver Dede S, Altay F. Biosensors from the first generation to nano-biosensors. Int. Adv. Res. Eng. J. 2018;2(2):200-7.



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