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Prolonging Glucose Sensor’s Performance in In Vivo Environment

Nashrul Fazli Mohd Nasir, and Ying, Yang, (2006) Prolonging Glucose Sensor’s Performance in In Vivo Environment. Engineering e-Transaction, 1 (2). pp. 1-4. ISSN 1823-6379

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Official URL: http://ejum.fsktm.um.edu.my/ArticleInformation.aspx?ArticleID=399

Affiliations

Universiti Utara Malaysia. College of Engineering. School of Mechatronics
Keele University. School of Medicine. Institute for Science and Technology in Medicine

Abstract

In this paper, a sol gel based needle type biosensor using 3-glycidoxypropyl dimethylethoxy silane, as silane agent was developed to improve the immobilization efficiency of glucose oxidase (GOD). The glucose sensor was coated with 3C-copolymer as the outmost layer to increase sensor’s biocompatibility. The biosensor’s performance fabricated by this technique was compared with the conventional sensors which use glutaraldehyde as the cross link agent for immobilization of GOD. Both types of sensor were immersed in 20 mM glucose solution for more than 24 hours and the sol gel based sensor exhibited better stability. This indicates that the sol gel immobilization technique applied is able to retain enzyme for longer time of period compared to the conventional method. Furthermore, the study revealed once the sensors were tested in a glucose solution containing 1% bovine serum albumin in a long term stability test, the performance of the sol gel based sensor coated with 3C-copolymer was not affected considerably by protein adsorption, which was a vital character for an in vivo biosensor.

Item Type:Journal
Keywords:biosensor, glucose sensor, immobilization technique, sol gel technique, biocompatibility
Subjects:T Technology
R Medicine
ID Code:502

[1] B.R. Eggins, Biosensors: an Introduction, John Wiley and Sons, Chichester, 1996.

[2] G.W.J. Harwood & C.W. Pouton, Amperometric enzyme biosensors for the analysis of drugs and metabolites, Advanced Drug Delivery Reviews, 18,163-191, 1996.

[3] T. Yao, & K. Takashima, Amperometric biosensor with a composite membrane of sol gel derived enzyme film and electrochemically generated poly (1,2-diaminobenzene) film. Biosensors & Bioelectronics, 13, 67-73, 1997.

[4] J. Wu, J. Suls, & W. Sansen, Amerometric glucose sensor with enzyme covalently immobilized by sol gel technology. Analytical Sciences, 15,1029-1032, 1999.

[5] P. D'Orazio, Biosensors in clinical chemistry, Clinica Chimica Acta, 334, 41-69, 2003.

[6] M. Gerard, A. Chaubey & B.D. Malhotra, Application Of Conducting Polymers To Biosensors, Biosensors and Bioelectronics, 17:345-359, 2002.

[7] M. A. Kim & W.Y. Lee, Amperometric phenol biosensor based on sol–gel silicate/Nafion composite film, Analytica Chimica Acta ,479,143-150, 2003.

[8] E. Ohashi, & I. Karube, Development of a thin membrane glucose sensor using -type crystalline chitin for implantable biosensor. Journal of Biotechnology. 40, 13-19, 1995.

[9] N. Wisniewski & M. Reichert, Methods for reducing biosensor membrane biofouling, Colloids and Surfaces B: Biointerfaces, 18,197–219, 2000.

[10] R. F. B. Turner, D. J. Harrison & R. V. Rojotte, Preliminary in vivo biocompatibility studies on perfluorosulphonic acid polymer membranes for biosensor applications, Biomaterials, 12,361-368, 1991.

[11] F. Moussy, D.J. Harrison, D.W. O'Brien, & R.V. Rajotte, Performance of subcutaneously implanted needle-type glucose sensors employing a novel trilayer coating. Analytical Chemistry. 65, 2072–2077, 1993.

[12] S. P. J. Higson & P. M. Vadgama, Diamond-like carbon coated microporous polycarbonate as a composite barrier for a glucose enzyme electrode, Analytica Chimica Acta, 271, 125-133,1993.

[13] K. Ishihara, R. Aragaki, T.Ueda, , A. Watenabe, & N. Nakabayashi, Reduced thrombogenicity of polymers having phospholipids polar groups. Journal of Biomedical Materials Research, 24, 1069-1077, 1990.

[14] K. Ishihara, H. Oshida, Y. Endo, T.Ueda, A. Watenabe, & N. Nakabayashi, Haemocompatibility of human whole blood on polymers with a phospholipid polar group and its mechanism. Journal of Biomedical Materials Research, 26, 1543-1552, 1992.

[15] K. Ishihara, N.P. Ziats, B.P. Tierney & N. Nakabayashi, Protein adsorption from human plasma is reduced on phospholipid polymers. Journal of Biomedical Materials Research, 25, 1397-1407, 1991.

[16] Y. Yang, S.F. Zhang, M.A. Kingston, G.Jones, G. Wright, S.A. Spencer, Glucose sensor with improve haemocompatibility. Biosensors & Bioelectronics, 15, 221-227, 2000.

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