 |
 |
 |
 |
 |
 |
Sains Malaysiana 33(2): 55-66 (2004) Sains Fizis dan Gunaan / Physical and Applied Sciences
Elektrod Ag/AgCl sebagai Transduser Potentiometrik untuk Sensor/Biosensor Jenis Keadaan-Pepejal (Ag/AgCl Electrode for Potentiometric Traansducer for Solid State Sensors (biosensors)
Khor Sook Mei. Lee Yook Heng & Musa Ahmad Pusat Pengajian Sains Kimia & Teknologi Makanan Fakulti Sains dan Teknologi Universiti Kebangsaan Malaysia 43600 UKM Bangi, Selangor Malaysia
ABSTRAK
Kajian rekabentuk sensor ion jenis keadaan-pepejal telah dilakukan. Elektrod yang digunakan adalah berdasarkan kepada Ag/AgCl. Rekabentuk dua jenis elektrod keadaan pepejal telah dipilih, iaitu berdasarkan elektrod Ag/AgCl jenis rod dan jenis elektrod Ag/AgCl bercetak skrin (screen printed electrode, SPE). Penilaian termasuk kajian responsnya terhadap anion, khasnya ion klorida. Di samping itu, respons elektrod keadaan-pepejal ini terhadap beberapa kation juga dilakukan setelah elektrod rod dan SPE disalutkan dengan beberapa jenis fotopolimer serta pemegunan garam lipofilik yang peka kepada kation. Hasil kajian menunjukkan penggunaan poli(hidroksi etil metakrilat) terhidrat dengan larutan garam untuk menggantikan larutan rujukan dalaman bagi elektrod pemilih ion konvensional yang bukan berbentuk keadaan-pepejal adalah penting demi menghasilkan sensor berbentuk keadaan pepejal yang bersifat normal. Ciri sensor ion yang masih bersifat hampir Nernstian walaupun telah mengalami beberapa proses fabrikasi sistem fotopolimer menunjukkan bahawa sensor keadaan-pepejal ini boleh juga digunakan dalam rekabentuk biosensor potentiometrik selain daripada sensor ion.
ABSTRACT
A study on the design of solid-state ion sensor was carried out. The electrode used was based on Ag/AgCl and two types of Ag/AgCl electrode designs used were rod-shape and screen printed (SPE) Ag/AgCl electrodes. The assessment of the electrode response was based on anion response, especially the response of chloride ions. Apart from that, the solid-state electrodes were also assessed for their response to several cations after a photocured polymer membrane with an immobilised lipophilic salt sensitive to cations was deposited on the electrodes. The results show that the use of a poly(hydroxyl ethyl methacrylate) hydrated with a salt solution is important to replace the inner reference solution of a conventional non solid-state ion-selective electrode if normal response of an electrode is to be obtained. The sensor response which remains near to Nernstian after undergoing membrane deposition processes by photocuring technique indicate that these solid-state ion sensors can be used for the construction of biosensors that are based on potentiometric transduction.
RUJUKAN/REFERENCES
Banoli. J. Alerm, L., Fabry, P., Siebert, E. 1995. Conductive epoxy-graphite composite as a solid internal reference in a NASICON-based sodium ion-selective electrode for flow-injection analysis. Anal. Chem. Acta, 308: 102-108. Bobacka. 1.. Lindors. T., McCarrick M., Ivaska, A.,Lewenstam, A. 1995. Single piece all-solid-state ion-selective electrode. Anal. Chem. 67: 3819-3823. Dror. M. Bergs. E.A. Rhodes, RK. 1987. Potassium ion-selective electrodes based on valinomycin/PVC overlayered solid substrates.. Sensors and Actuators. 11: 23-36. Forster. RJ., Diamond. D. 1996. Miniaturized chemical sensors. Anal. Commun., 33: IH-4H. Hara. H .. Kondoh. Y .. Mitani, O., Okazaki, S. 1990. Solid solvent membrane coated wire electrodes and their response to nitrate, p-toluenesulfonate, chloride, calcium and potassium. Anal. Chem. 62: 1139-1143. Hower. RW., Shin, J.H., Chao G.S., Meruva, RK., Meyerhoff, M.E., Brown, RB. 1996. New novel system for the improved electrochemical performance of screen-printed polyurethane membrane-based solid-state sensors. Sensors and Actuators B. 33: 168-172. IUPAC. 1994. Recommendations for Nomenclature of Ion Selective Electrodes. Pure Appl. Chem. 66: 2527-2536. Janata J. 1990. Solid state potentiometric sensors dalam Biosens. Technol. Buck, RP. (Pynt), Dekker. New York. 17-38. Karl. C. 1979. Working With Ion Selective Electrode. Chemical Laboratory Practice. Berlin: Springer-Verlag. Kelly. RG., Owen, A. E. 1986. Solid-state ion sensors. J. Chem. Soc. Faraday Trans. 82(1): 1195-1208. Lee. Y. H., Hall, E. A H. 2000. Making non-plasticised ion-selective membranes. Anal. Chem., 72: 42-51. Lee. Y. H., Hall, E. A. H. 2001. Assessing of photocurred self plasticised acrylic membrane recipe for Na+ and K+ ion selective electrodes. Anal. Chim. Acta. 443(1): 25-40. Lee Y. H .. Loh H. C., Musa A 2002a. A hydrogen ion-selective sensor based on nonplasticised methacrylic-acrylic membranes. Sensors, 2: 339-346. Lee Y. H., Loh, H.C., Hall E.AH., Musa. A 2002b. The possibility of non-plasticised methacrylic-acrylic membrane-based ion sensors for the analysis of lithium and pH in human blood. Mal. J. Chem., 4(1): 41-47. Lima. J.L.F.C. Machado, A.S.C. 1986. Procedure for the construction of all-solid-sate PVC membrane electrodes. Analyst, 111: 799-802. Morf. W. E. 1981. Studies in Analytical Chemitry. The Principles of Ion Selective Electrodes and of Membrane Transport. Ji1.2. Amsterdam: Elsevier. Pace, J.S., Hamerslag, J.D. 1992. Thick-film multiplayer ion sensors for biomedical applications. Dlm Biosensors and Chemical Sensors. American Chemical Society, Chapter 21: 261-273. Pandey, P.C., Singh, G. 2001. Tetraphyenylborate doped polyaniline based novel pH Sensor and solid-state urea biosensor. Talanta, 55(4): 773-782. Schnakenberg, U. Lisec. T., Hintsche, R., Kuna, I., Uhlig, A., Wagner, B. 1995. Novel potentiometric silicon sendor for medical devices. Proceedings of the 8th International Conference on Solid-state Sensors and Actuators and Eurosensors IX, Stockholm, Sweden, 959-962. Thomas, J.D.R., Lima, J.L.F.C., Machado, A.S.C. 1988. Characterisation of poly(vinylchloride) barium ion-selective electrodes without an internal reference solution. Analyst, 113: 1023-1027. Tinklic, N, Cubuk, O., Isildak, I. 2002. Glucose and urea biosensors based on all solid-state PVC-NH2 membrance electrodes. Anal. Chim. Acta, 452:1, 29-34. Walter, B. 1983. Dry reagent chemistries. Anal. Chem. 55(4): 498A-514A.
|
|||
|
