Organic pollution sensor based on surface photovoltage

Sensors and Actuators, B: Chemical

Volumn 53, Issue 3, 1998, Pages 163-172

  Murakami, Yuji ^a   Kikuchi, Takayuki ^a   Yamamura, Akira ^a   Sakaguchi, Toshifumi ^a   Yokoyama, Kenji ^a   Ito, Yoshitaka ^c   Takiue, Masataka ^d   Uchida, Hidekazu ^b   Katsube, Teruaki ^b   Tamiya, Eiichi ^a  

^a JAPAN ADVANCED INSTITUTE OF SCIENCE AND TECHNOLOGY   (Japan)

^b SAITAMA UNIVERSITY   (Japan)

^c Research and Development Center   (Japan)

^d 1 26 2 Tamagawa Chofu 182 0025   (Japan)

Author keywords

[No Author keywords available]

Indexed keywords

BIOCATALYSTS; BIOCHEMICAL OXYGEN DEMAND; FABRICATION; MICROBIAL ELECTRODES; PH SENSORS; POTENTIOMETRIC SENSORS;

MICROBIAL MEMBRANE; ORGANIC POLLUTION SENSOR; SURFACE PHOTOVOLTAGE DEVICE; TRICHOSPORON CUTANEUM;

BIOSENSORS;

EID: 0032278062     PISSN: 09254005     EISSN: None     Source Type: Journal    
DOI: 10.1016/S0925-4005(99)00010-6     Document Type: Article

References (28)

1. Hafeman D.G., Parce J.W., McConnell H.M. Light-addressable potentiometric sensor for biochemical systems. Science. 240:1988;1182-1185.
2. Owicki J.C., Parce J.W. Biosensors based on the energy metabolism of living cells: the physical chemistry and cell biology of extracellular acidification. Biosens. Bioelectron. 7:1992;255-272.
3. Adami M., Sartore M., Baldini E., Rossi A., Nicolini C. New measuring principle for LAPS devices. Sensors and Actuators B. 9:1992;25-31.
4. Sartore M., Adami M., Nicolini C., Bousse L., Mostarshed S., Hafeman D. Minority carrier diffusion length effects on light-addressable potentiometric sensor (LAPS) devices. Sensors and Actuators A. 32:1992;431-436.
5. Libby J.M., Wada H.G. Detection of Neisseria meningitidis and Yersinia pestis with a novel silicon-based sensor. J. Clin. Microbiol. 27:1989;1456-1459.
6. Briggs J., Panfili P.R. Quantitation of DNA and protein impurities in biopharmaceuticals. Anal. Chem. 63:1991;850-859.
7. Sasaki Y., Kanai Y., Uchida H., Katsube T. Highly sensitive taste sensor with a new differential LAPS method. Sensors and Actuators B. 24-25:1995;819-822.
8. Pecora A., Fortunato G., Carluccio R., Sacco S.J. Hydrogenated amorphous silicon based light-addressable potentiometric sensor (LAPS) for hydrogen detection. J. Noncryst. Solids. 164-166:1993;793-796.
9. Parce J.W., Owicki J.C., Kercso K.M., Sigal G.B., Wada H.G., Muir V.C., Bousse L.J., Ross K.L., Sikic B.I., McConnell H.M. Detection of cell-affecting agents with a silicon biosensor. Science. 246:1989;243-247.
10. Owicki J.C., Parce J.W., Kercso K.M., Sigal G.B., Muir V.C., Venter J.C., Fraser C.M., McConnell H.M. Continuous monitoring of receptor-mediated changes in the metabolic rates of living cells. Proc. Natl. Acad. Sci. USA. 87:1990;4007-4011.
11. McConnell H.M., Owicki J.C., Parce J.W., Miller D.L., Baxter G.T., Wada H.G., Pitchford S. The cytosensor microphysiometer: Biological application s of silicon technology. Science. 257:1992;1906-1912.
12. Wada H.G., Indelicato S.R., Meyer L., Kitamura T., Miyajima A., Kirk G., Muir V.C., Parce J.W. GM-CSF triggers a rapid, glucose dependent extracellular acidification by TF-1 cells: Evidence for sodium/proton antiporter and PKC mediated activation of acid production. J. Cell. Physiol. 154:1993;129-138.
13. Chan S.D.H., Antoniucci D.M., Fok K.S., Alajoki M.L., Harkins R.N., Thompson S.A., Wada H.G. Heregulin activation of extracellular acidification in mammary carcinoma cells is associated with expression of HER2 and HER3. J. Biolog. Chem. 270:1995;22608-22613.
14. Japanese Industrial Standard Committee, JIS K 3602, Japanese Standards Association, Tokyo, 1990.
15. Japanese Industrial Standard Committee, JIS K 0102, Japanese Standards Association, Tokyo, 1974.
16. Karube I., Matsunaga T., Mitsuda S., Suzuki S. Microbial electrode BOD sensors. Biotechnol. Bioeng. 19:1977;1535-1547.
17. Karube I., Mitsuda S., Matsunaga T., Suzuki S. A rapid method for estimation of BOD by using immobilized microbial cells. J. Ferment. Technol. 55:1979;243-248.
18. Hikuma M., Suzuki H., Yasuda T., Karube I., Suzuki S. Amperometric estimation of BOD by using living immobilized yeasts. Eur. J. Appl. Microbiol. Biotechnol. 8:1979;289-297.
19. Tan T.C., Li F., Neoh K.G. Measurement of BOD by initial rate of response of a microbial sensor. Sensors and Actuators B. 10:1993;137-142.
20. Tanaka H., Nakamura E., Minamiyama Y., Toyoda T. BOD biosensor for secondary effluent from wastewater treatment plants. Wat. Sci. Tech. 30:1994;215-227.
21. Ohki A., Shinohara K., Ito O., Naka K., Maeda S., Sato T., Akano H., Kato N., Kawamura Y. A BOD sensor using Klebsiella oxytoca AS1. Int. J. Environ. Anal. Chem. 56:1994;261-269.
22. Li F., Tan T.C., Lee Y.K. Effects of pre-conditioning and microbial composition on the sensing efficacy of a BOD biosensor. Biosens. Bioelectron. 9:1994;197-205.
23. Li F., Tan T.C. Monitoring BOD in the presence of heavy metal ions using a poly(4-vinylpyridine)-coated microbial sensor. Biosens. Bioelectron. 9:1994;445-455.
24. Iranpour R., Straub B., Jugo T. Real time BOD monitoring for wastewater process control. J. Environ. Eng. 123:1997;154-159.
25. Hyun C.K., Tamiya E., Takeuchi T., Karube I., Inoue N. A novel BOD sensor based on bacterial luminescence. Biotech. Bioeng. 41:1993;1107-1111.
26. Li X.M., Ruan F.C., Ng W.Y., Wong K.Y. Scanning optical sensor for the measurement of dissolved oxygen and BOD. Sensors and Actuators B. 21:1994;143-149.
27. Comber S.D.W., Gardner M.J., Gunn A.M. Measurement of absorbance and fluorescence as potential alternatives to BOD. Environ. Technol. 17:1996;771-776.
28. Janata J. Do optical sensors really measure pH? Anal. Chem. 59:1987;1351-1356.