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NANOSTUCTURED QCM SENSOR FOR TRYPSIN ACTIVITY DETERMINATION

Zlatev, Roumen, Stoytcheva, Margarita, Montero, Gisela, Valdez, Benjamin

First published: 2013-06-20https://doi.org/10.5593/sgem2013/bf6/s25.018View metrics

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Title
NANOSTUCTURED QCM SENSOR FOR TRYPSIN ACTIVITY DETERMINATION
Authors
Zlatev, Roumen, Stoytcheva, Margarita, Montero, Gisela, Valdez, Benjamin
Proceedings
SGEM International Multidisciplinary Scientific GeoConference EXPO Proceedings; 13th SGEM GeoConference NANO, BIO AND GREEN TECHNOLOGIES FOR A SUSTAINABLE FUTURE
Publisher
Stef92 Technology
Year
2013
Pages
197 - 204 pp
ISSN
1314-2704
ISBN
Not available yet
Language
en
Publication type
Conference Paper
References58
  1. Temler R. & Felber J-P. Radioimmunoassay of human plasma trypsin, Biochim. Biophys. Acta, vol., pp. 445, 720-728, 1976.

  2. Schwert G. & Takenaka, Y. A spectrophotometric determination of trypsin and chymotrypsin, Biochim. Biophys. Acta, vol. 16, pp. 570-575, 1955.

  3. Kersey A., Berkoff T. & Morey W. Multiplexed fiber Bragg grating strain- sensor system with a fiber Fabry -Perot wavelength filter, Opt. Le tt., vol. 18, pp. 1370- 1372, 1993.

  4. Spooncer R., Al -Ramadhan F. & Jones B. A humidity sensor using a wavelength-dependent holographic filter with fibre optic links, Int. J. Optoelectron., vol. 7, pp. 449-452, 1992.

  5. Millington R., Mayes A. Blyth J. & Lowe C. A holographic sensor for proteases, Anal. Chem., vol. 67, pp. 4229-4233, 1995.

  6. Hu Q- Z. & Jang Ch -H. I maging trypsin activity through changes in the orientation of liquid crystals coupled to the interactions between a polyelectrolyte and a phospholipid layer, ACS Appl. Mater. Interfaces, vol. 4, pp. 1791-1795, 2012. Section Advances in Biotechnology

  7. Syed M.A., Bhatti A.S., Li C. & Bokhari H. Use of SPR biosensor for the study of proteolytic action of a serine protease enzyme, Am. J. Biomed. Sci., vol. 3, pp. 253- 257, 2011.

  8. Chuang Y-C., Li J-C., Chen S-H., Liu T-Y., Kuo C-H., Huang W-T. & Lin C-S. An optical biosensing platform for proteinase activity using gold nanoparticles , Biomaterials, vol. 31, pp. 6087-6095, 2010.

  9. Zaccheo B. & Crooks R. Self-powered sensor for naked- eye detection of serum trypsin, Anal. Chem., vol. 83, pp. 1185-1188, 2011.

  10. Biloivan O., Dzyadevych S., Boubriak O., Soldatkin A. & El’skaya A. Development of enzyme biosensor based on ISFETs for quantitative analysis of serine proteinases, Electroanalysis, vol. 16, pp.1883-1889, 2004.

  11. Ionescu R., Cosnier S. & Marks S. P rotease amperometric sensor, Anal. Chem., vol. 78, pp. 6327-6331, 2006.

  12. Ionescu R., Fillit C., Jaffrezic -Renault N. & Cosnier S. Urease–gelatin interdigitated microelectrodes for the conductometric determination of protease activity , Biosens. Bioelectron., vol. 24, pp. 489-492, 2008.

  13. Fordyce K. & Shvarev A. Solid-contact electrochemical polyion sensors for monitoring peptidase activities, Anal. Chem., vol. 80, pp. 827-833, 2008.

  14. Adjemian J., Anne A., Cauet G. & Demaille C. Cleavage-sensing redox peptide monolayers for the rapid measurement of the proteolytic activity of trypsin and α - thrombin enzymes, Langmuir, vol. 26, pp. 10347-10356, 2010.

  15. Baş D. & Boyaci I.H. Rapid method for quantitative determination of proteolytic activity with cyclic voltammetry, Electroanalysis, vol. 22, pp. 265-267, 2010.

  16. Stoytcheva M., Zlatev R., Cosnier S. & Arredondo M. Square wave voltammetric determination of trypsin activity, Electrochim. Acta, vol. 76, pp. 43-47, 2012.

  17. Krause S.K, Fernandez -Sanchez C & McNeil C.J. Sensors based on thin film degradation. Encyclopedia of Sensors, American Scientific Publishers (Stevenson Ranch, California, USA), 2006.

  18. Stair J.L., Watkinson M. & Krause S. Sensor materials for the detection of proteases, Biosens. Bioelectron., vol 24, pp. 2113–2118, 2009.

  19. Ahola S., Turon X., Osterberg M., Laine J. & Rojas O.J. Enzymatic kinetics of cellulose hydrolysis: A QCM -D study, 2008. Langmuir, vol. 24, pp. 11592–11599, 2008.

  20. Hu G., Heitmann J.A. & Rojas O.J., Quantification of cellulase activity using the quartz crystal microbalance technique, Anal. Chem., vol 81, pp. 1872-1880, 2009.

  21. Jeong C., Maciel A.M., Pawlak J.J., Heitmann J.A., Argyropoulos D.S. & Rojas O.J.cFollowing cellulase activity by the quartz crystal microbalance technique, 13th GeoConference on Nano, Bio and Green – Technologies for a Sustainable Future International Symposium on Wood, Fibre and Pulping Chemistry (ISWFPC), Vol. 2: 495-502, Auckland, New Zealand, May 16-19, 2005.

  22. Josefsson P., Henriksson G. & Wågberg, L., The physical action of cellulases revealed by a quartz crystal microbalance study using ultrathin cellulose films and pure cellulases, Biomacromolecules, vol. 9, pp. 249–254, 2008.

  23. Turon X., Rojas O.J. & Deinhammer R.S. Enzymatic kinetics of cellulose hydrolysis: a QCM-D study, Langmuir, vol. 24, pp. 3880-3887, 2008.

  24. Chao Chen, Yingchun Fu, Canhui Xiang, Qingji Xie, Qingfang Zhang, Yuhua Su, LihuaWang & Shouzhuo Yao, Electropolymerization of preoxidized catecholamines on Prussian blue matrix to immobilize glucose oxidase for sensitive amperometric biosensing, Biosens. Bioelectron., vol. 24, pp. 2726–2729, 2009.

  25. Chao Chen, Qingji Xie, Lihua Wang, Cong Qin, Fangyun Xie, Shouzhuo Yao & Jinhua Chen, Experimental platform to study heavy metal ion−enzyme interactions and amperometric inhibitive assay of Ag + based on solution state and immobilized glucose oxidase, Anal. Chem., vol. 83, pp. 2660–2666, 2011.

  26. Chunyan Deng, Mingrui Li, Qingji Xie, Meiling Liu, Yueming Tan, Xiahong Xu & Shouzhuo Yao, New glucose biosensor based on a poly(o- phenylendiamine)/glucose oxidase -glutaraldehyde/Prussian blue/Au electrode with QCM monitoring of various electrode -surface modifications, Anal. Chim. Acta, vol. 557, pp. 85-94, 2006.

  27. Khaydarov R.A., Khaydarov R.R., Gapurova O., Estrin Y. & Scheper T., Electrochemical method for the synthesis of silver nanoparticles, J. Nanopart. Res., vol. 11, pp. 1193–1200, 2009.

  28. Evanoff D.D. Jr. & Chumanov G. Synthesis and optical properties of silver nanoparticles and arrays, Chem. Phys. Chem., vol. 6, pp. 1221 – 1231, 2005.

  29. Snabe T. & Petersen S.B. Lag phase and hydrolysis mechanisms of triacylglycerol film lipolysis, Chem. Phys. Lipids, vol. 125, pp. 69-82, 2003.

  30. Temler R. & Felber J-P. Radioimmunoassay of human plasma trypsin, Biochim. Biophys. Acta, vol., pp. 445, 720-728, 1976.

  31. Schwert G. & Takenaka, Y. A spectrophotometric determination of trypsin and chymotrypsin, Biochim. Biophys. Acta, vol. 16, pp. 570-575, 1955.

  32. Kersey A., Berkoff T. & Morey W. Multiplexed fiber Bragg grating strain- sensor system with a fiber Fabry -Perot wavelength filter, Opt. Le tt., vol. 18, pp. 1370- 1372, 1993.

  33. Spooncer R., Al -Ramadhan F. & Jones B. A humidity sensor using a wavelength-dependent holographic filter with fibre optic links, Int. J. Optoelectron., vol. 7, pp. 449-452, 1992.

  34. Millington R., Mayes A. Blyth J. & Lowe C. A holographic sensor for proteases, Anal. Chem., vol. 67, pp. 4229-4233, 1995.

  35. Hu Q- Z. & Jang Ch -H. I maging trypsin activity through changes in the orientation of liquid crystals coupled to the interactions between a polyelectrolyte and a phospholipid layer, ACS Appl. Mater. Interfaces, vol. 4, pp. 1791-1795, 2012. Section Advances in Biotechnology

  36. Syed M.A., Bhatti A.S., Li C. & Bokhari H. Use of SPR biosensor for the study of proteolytic action of a serine protease enzyme, Am. J. Biomed. Sci., vol. 3, pp. 253- 257, 2011.

  37. Chuang Y-C., Li J-C., Chen S-H., Liu T-Y., Kuo C-H., Huang W-T. & Lin C-S. An optical biosensing platform for proteinase activity using gold nanoparticles , Biomaterials, vol. 31, pp. 6087-6095, 2010.

  38. Zaccheo B. & Crooks R. Self-powered sensor for naked- eye detection of serum trypsin, Anal. Chem., vol. 83, pp. 1185-1188, 2011.

  39. Biloivan O., Dzyadevych S., Boubriak O., Soldatkin A. & El’skaya A. Development of enzyme biosensor based on ISFETs for quantitative analysis of serine proteinases, Electroanalysis, vol. 16, pp.1883-1889, 2004.

  40. Ionescu R., Cosnier S. & Marks S. P rotease amperometric sensor, Anal. Chem., vol. 78, pp. 6327-6331, 2006.

  41. Ionescu R., Fillit C., Jaffrezic -Renault N. & Cosnier S. Urease–gelatin interdigitated microelectrodes for the conductometric determination of protease activity , Biosens. Bioelectron., vol. 24, pp. 489-492, 2008.

  42. Fordyce K. & Shvarev A. Solid-contact electrochemical polyion sensors for monitoring peptidase activities, Anal. Chem., vol. 80, pp. 827-833, 2008.

  43. Adjemian J., Anne A., Cauet G. & Demaille C. Cleavage-sensing redox peptide monolayers for the rapid measurement of the proteolytic activity of trypsin and α - thrombin enzymes, Langmuir, vol. 26, pp. 10347-10356, 2010.

  44. Baş D. & Boyaci I.H. Rapid method for quantitative determination of proteolytic activity with cyclic voltammetry, Electroanalysis, vol. 22, pp. 265-267, 2010.

  45. Stoytcheva M., Zlatev R., Cosnier S. & Arredondo M. Square wave voltammetric determination of trypsin activity, Electrochim. Acta, vol. 76, pp. 43-47, 2012.

  46. Krause S.K, Fernandez -Sanchez C & McNeil C.J. Sensors based on thin film degradation. Encyclopedia of Sensors, American Scientific Publishers (Stevenson Ranch, California, USA), 2006.

  47. Stair J.L., Watkinson M. & Krause S. Sensor materials for the detection of proteases, Biosens. Bioelectron., vol 24, pp. 2113–2118, 2009.

  48. Ahola S., Turon X., Osterberg M., Laine J. & Rojas O.J. Enzymatic kinetics of cellulose hydrolysis: A QCM -D study, 2008. Langmuir, vol. 24, pp. 11592–11599, 2008.

  49. Hu G., Heitmann J.A. & Rojas O.J., Quantification of cellulase activity using the quartz crystal microbalance technique, Anal. Chem., vol 81, pp. 1872-1880, 2009.

  50. Jeong C., Maciel A.M., Pawlak J.J., Heitmann J.A., Argyropoulos D.S. & Rojas O.J.cFollowing cellulase activity by the quartz crystal microbalance technique, 13th GeoConference on Nano, Bio and Green – Technologies for a Sustainable Future International Symposium on Wood, Fibre and Pulping Chemistry (ISWFPC), Vol. 2: 495-502, Auckland, New Zealand, May 16-19, 2005.

  51. Josefsson P., Henriksson G. & Wågberg, L., The physical action of cellulases revealed by a quartz crystal microbalance study using ultrathin cellulose films and pure cellulases, Biomacromolecules, vol. 9, pp. 249–254, 2008.

  52. Turon X., Rojas O.J. & Deinhammer R.S. Enzymatic kinetics of cellulose hydrolysis: a QCM-D study, Langmuir, vol. 24, pp. 3880-3887, 2008.

  53. Chao Chen, Yingchun Fu, Canhui Xiang, Qingji Xie, Qingfang Zhang, Yuhua Su, LihuaWang & Shouzhuo Yao, Electropolymerization of preoxidized catecholamines on Prussian blue matrix to immobilize glucose oxidase for sensitive amperometric biosensing, Biosens. Bioelectron., vol. 24, pp. 2726–2729, 2009.

  54. Chao Chen, Qingji Xie, Lihua Wang, Cong Qin, Fangyun Xie, Shouzhuo Yao & Jinhua Chen, Experimental platform to study heavy metal ion−enzyme interactions and amperometric inhibitive assay of Ag + based on solution state and immobilized glucose oxidase, Anal. Chem., vol. 83, pp. 2660–2666, 2011.

  55. Chunyan Deng, Mingrui Li, Qingji Xie, Meiling Liu, Yueming Tan, Xiahong Xu & Shouzhuo Yao, New glucose biosensor based on a poly(o- phenylendiamine)/glucose oxidase -glutaraldehyde/Prussian blue/Au electrode with QCM monitoring of various electrode -surface modifications, Anal. Chim. Acta, vol. 557, pp. 85-94, 2006.

  56. Khaydarov R.A., Khaydarov R.R., Gapurova O., Estrin Y. & Scheper T., Electrochemical method for the synthesis of silver nanoparticles, J. Nanopart. Res., vol. 11, pp. 1193–1200, 2009.

  57. Evanoff D.D. Jr. & Chumanov G. Synthesis and optical properties of silver nanoparticles and arrays, Chem. Phys. Chem., vol. 6, pp. 1221 – 1231, 2005.

  58. Snabe T. & Petersen S.B. Lag phase and hydrolysis mechanisms of triacylglycerol film lipolysis, Chem. Phys. Lipids, vol. 125, pp. 69-82, 2003.

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