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Chemiluminescence biosensors

Varshney, M., Li, Y. B., Nanaparmeni, R., Johnson, M. G., and Griffis, C. L. (2003). A chemiluminescence biosensor coupled with immunomagnetic separation for rapid detection of Salmonella typMmurium.. Rapid Methods Automat. Microbiol. 11,111-131. [Pg.44]

Two different systems for the detection of dopamine and uric acid, respectively, have recently been reported in the literature. Both are based on the same detection technique, that of chemiluminescence (CL). In the first one, a chemiluminescence biosensor has been assembled using whole vegetable tissue (fresh mature potato root) as molecular recognition element [155]. [Pg.251]

Marquette CA, Degiuli A, and Blum LJ (2003) Electro-chemiluminescent biosensors array for the concomitant... [Pg.737]

Piao MH, Yang DS, Yoon KR, Lee SH, Choi SH (2009) Development of an Electrogenerated Chemiluminescence Biosensor using Carboxylic acid-functionalized MWCNT and Au Nanoparticles. Sensors 9(3) 1662-1677... [Pg.145]

Xu ZA, Guo ZH, Dong SJ (2005) Electrogenerated chemiluminescence biosensor with alcohol dehydrogenase and tris(2,2 -bipytidyl)ruthenium (II) immobilized in sol-gel hybrid material. Biosens Bioelectron 21(3) 455-461. doi 10.1016/j.bios.2004.10.032... [Pg.145]

Li G, Lian J, Zheng X, Cao J (2010) Electrogenerated chemiluminescence biosensor for glucose based on poly(luminol-aniline) nanowires composite modified electrode. Biosens Bioelectron 26(2) 643-648. doi 10.1016/j.bios.2010.07.003... [Pg.146]

Huang, Y Wu, F. Plant tissue-based chemiluminescence biosensor for ethanol. Anal. Sci. 2006, 22, 965-969. [Pg.205]

Huang, C. Pork heart tissue-based chemiluminescence biosensor for pyruvic acid. Amd. Lett. 2006, 39, 1823-1836. [Pg.205]

Martin AF, Nieman TA (1997) Chemiluminescence biosensors using tris (2, 2 -bipyridyl) ruthenium (II)... [Pg.880]

Zhou GJ, Wang G, Xu JJ, Chen HY (2002) Reagentless chemiluminescence biosensor for determination of hydrogen peroxide based on the immobilization of horseradish peroxidase on biocompatible chitosan membrane. Sens Actuators B Chem 81(2) 334-339... [Pg.881]

Wu, E, Y. Fluang, and C. Huang. 2005. Chemiluminescence biosensor system for lactic acid using natural animal tissue as recognition element. Biosens. Bioelectron. 21 518-522. [Pg.222]

Several other biosensors have been developed usiag this oxygen-quenched fluorescence approach. Target species iaclude ethanol [64-17-5] hydrogen peroxide [7722-84-17, H2O2, lactate, and xanthine [69-89-6] C H4N402, usiag alcohol oxidase, catalase [9001-05-2] lactate oxidase, and xanthine oxidase, respectively. An additional technique for biocatalytic biosensors iavolves the firefly chemiluminescent reaction (17) ... [Pg.110]

Electrogenerated chemiluminescence (ECL) has proved to be useful for analytical applications including organic analysis, ECL-based immunosensors, DNA probe assays, and enzymatic biosensors. In the last few years, the electrochemistry and ECL of compound semiconductor nanocrystallites have attracted much attention due to their potential applications in analytical chemistry (ECL sensors). [Pg.341]

Finally, the integration of biochemical or biosensor methods with conventional chromatographic analyses should not be overlooked. For example, the use of im-munoaffinity columns prior to chemiluminescence or the use of biosensor detection systems following the chromatographic step may provide useful solutions to speciflc analytical needs. [Pg.747]

Table 1. H202-generating enzymatic systems for chemiluminescence-based optical fibre biosensors (Abbreviations OX = oxidase, PNPase = purine nucleoside phosphorylase). Table 1. H202-generating enzymatic systems for chemiluminescence-based optical fibre biosensors (Abbreviations OX = oxidase, PNPase = purine nucleoside phosphorylase).
Figure 7. (a) Flow diagram of the optical fibre continuous-flow system for bioluminescence and chemiluminescence measurements S, sample C, carrier stream PP, peristaltic pump IV, injection valve W, waste FO, optical fibre FC, flow-cell, (b) Details of the optical fibre biosensor/flow-cell interface a, optical fibre b, sensing layer c, light-tight flow-cell d, stirring bar. [Pg.166]

Tsafack V.C., Marquette C.A., Pizzolato F., Blum L.J., Chemiluminescent choline biosensor using histidine-modified peroxidase immobilized on metal-chelate substituted beads and choline oxidase immobilized on anion-exchanger beads co-entrapped in a photocrosslinkable polymer, Biosens. Bioelectron, 2000 15 125-133. [Pg.177]

Blum L.J., Chemiluminescent flow injection analysis of glucose in drinks with a bienzyme fiber optic biosensor, Enzyme Microb. Technol. 1993 15 407-411. [Pg.177]

Hlavay J., Haemmerli S.D., Guilbault G.G., Fibre-optic biosensor for hypoxanthine and xanthine based on a chemiluminescence reaction, Biosens. Bioelectron 1994 9 189-195. [Pg.178]

Hlavay J., Guilbault G.G., Determination of sulphite hy use of a fiber-optic biosensor based on a chemiluminescent reaction, Anal. Chim. Acta 1994 299 91-96. [Pg.178]

M. Ayyagari, S. Kametkar, R. Pande, K.A. Marx, J. Kumar, S.K. Tripathy, J. Akkara, and D.L. Kaplan, Chemiluminescence-based inhibition kinetics of alkaline phosphatase in the development of a pesticide biosensor. Biotechnol. Prog. 11, 699-703 (1995). [Pg.74]

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Chemiluminescence-based biosensors

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