TECHNICAL DIGESTOF

THE 10TH INTERNATIONAL MEETING ONCHEMICAL SENSORS

July 11-14,2004 / Tsukuba, Japan

CHEMICAL SENSORSVol. 20 Supplement B (2004)

Organizing Committee ofThe 10th International Meeting on Chemical Sensors

Japan Association of Chemical Sensors,The Electrochemical Society of Japan

TIB/UB Hannover «9126 247 498

CONTENTS

[1PL1] Toward Innovations of Gas Sensor Technology 2Yamazoe. N. (Kyushu University Japan)

[1PL2] Gas Sensing: Basic Understanding and Devices 6Weimar. U.: Barsan, N.; Oprea, A. (University of Tubingen, Germany)

[1A01] Temperature Independent Resistive Oxygen Sensors Using Solid Electrolyte 10Zirconia as a New Temperature Compensating MaterialIzu. N.1: Shin, W.1; Matsubara, I.1; Murayama, N.1; Oh-hori, N.2; Itou, M.2 (1AIST, 2YamahaMotor Co., Ltd., Japan)

[1A02] The Defect Chemistry of SrTivxFexOa-a Oxygen Sensors for Automotive 12ApplicationsRothschild, A.; Litzelman. S. J.: Tuller, H. L. (MIT, USA)

[1A03] Comparative Study on Response Kinetics of Temperature Independent 14Resistive Oxygen Sensors by the Pressure Modulation MethodSahner. K.1: Rettig, F.1; Moos, R.1; Izu, N.2; Shin, W.2; Murayama, N.2 (University ofBayreuth, Germany, 2AIST, Japan)

[1A04] Electrical Conduction Properties of Nano-Sized SrTiO3 Semiconductor for 16Low Temperature Resistive Oxygen Gas SensorTan. O. K.1: Hu, Y.1; Pan, J. S.2 (Nanyang Technological University, 2lnstitute of MaterialsResearch and Engineering, Singapore)

[1A05] The Electrical Properties and Stability of SrTio.65Feo.35O3.a Thin Films for 18Automotive Oxygen Sensor ApplicationsLitzelman. S. J.: Rothschild, A.; Tuller, H. L. (MIT, USA)

[1A06] Selective Sublimation Processing of Thin Films for Gas Sensing 20Guidi. V.1: Martinelli, G.1; Schiffrer, G.1; Vomiero, A.2; Scian, C.2; Delia Mea, G.2; Comini,E.3; Ferroni, M.3; Sberveglieri, G.3 (University of Ferrara, 2INFN Legnaro NationalLaboratory, 3University of Brescia, Italy)

[1A07] Gas Sensing Properties of Thin Films Derived from Sols of SnO2 Different in 22Grain SizeVuong. P. P.: Sakai, G.; Shimanoe, K.; Yamazoe, N. (Kyushu University, Japan)

[1A08] CO Detection of Gold-Catalyzed Titania Nanosized Thin Films Achieved by 24Radio-Frequency SputteringComini. E.1: Ferroni, M.2; Merli, P. G.2; Morandi, V.2; Guidi, V.3; Sberveglieri, G.1 (BresciaUniversity, 2CNR, 3Ferrara University, Italy)

[1A09] Co3O4-Modified SnO2 Prepared by Ball-Milling Method for High Sensitivity CO 26SensorShimanoe. K.: Abe, S.; Sakai, G.; Choi, U.; Yamazoe, N. (Kyushu University, Japan)

[1A11] Effects of Ta/Nb Doping on Titania-Based Thin Films for Gas-Sensing 28Ferroni, M.1; Comini, E.1; Merli, P. G.2; Morandi, V.2; Guidi, V.3; Sacerdoti, M.3; Vomiero,A.4; Pella Mea, G.4; Sberveglieri. G.1 (Brescia University, 2CNR, 3Ferrara University,4INFN Legnaro National Laboratories, Italy)

[1A12] Ceramic Nano-Structure for Chemical Sensing 30Akbar. S.: Yoo, S. (Ohio State University, USA)

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[1A13] Effects of Various Metal Additives on the Gas Sensing Performances of TiO2 32Nanocrystals Obtained from Hydrothermal TreatmentsRuiz. A. M.1: Cornet, A.1; Shimanoe, K.2; Morante, J. R.1; Yamazoe, N.2 (University ofBarcelona, Spain, 2Kyushu University, Japan)

[1A14] Nanostructured Metal Oxide Sensors for the Detection of Chemical Warfare 34AgentsTomchenko. A.: Harmer, G. P.; Marquis, B. (Sensor Research & Development Corp.,USA)

[1B01] Metalloporphyrins Based Artificial Senses 36Pi Natale. C. (University of Rome "Tor Vergata" and CNR-IMM, Italy)

[1B02] Biogas Monitoring with an Electronic Nose in the Presence of a Changing 38Matrix QualityBlock, R.1; Goschnick, J.2; Haerinqer. P.2: Stahl, U.3 (BigaTec, 2lnstitut fur InstrumentelleAnalytik, 3MMTWD, Germany)

[1B03] Diagnosis of Toxins Production of Fusarium Verticilloides by an Electronic 40NoseFalasconi. M.1: Gobbi, E.2; Pardo, M.1; Sberveglieri, G.1 (University of Brescia & INFM,2University of Udine, Italy)

[1B04] Increased Classification of E-Nose Data with Support Vector Machines 42Pardo. M.: Sberveglieri, G. (INFM & University of Brescia, Italy)

[1B05] High-Sensitive Plume Detection for Industrial Alarm Monitoring Using a 44Network of Surface Acoustic Wave (SAW) Based Electronic NosesLubert, K. H.1; Dirschka, M.1; Matthes, J.2; Keller, H. B.2; Hartmann, V.3; Eppler, W.3;Rapp. M.1 (Institute for Instrumental Analysis, 2 Institute of Applied Informatics,3 Institutefor Data Processing Electronics, Germany)

[1B06] Improvement of RBF Network's Performance for Application to Odour 46Sensing System with DriftBvun. H.-G.1: Kim, N.-Y.1; Shin, J.-S.1; You, J.-B.2; Huh, J.-S.2 (Samcheok NationalUniversity, 2Kyungpook National University, Korea)

[1B07] Environmental Temperature-Independent Gas Sensor Array Based on 48Polymer CompositesHa. S.-C: Kim, Y. S.; Yang, Y; Kim, Y. J.; Cho, S.-M.; Yang, H.; Kim, Y T. (Electronicsand Telecommunications Research Institute, Korea)

[1B08] Detection of the Partial Structure of Odor Molecules by Self-Assembled 50Monolayers and Polarity Control of the SurfaceIzumi. R.: Hayama, K.; Hayashi, K; Toko, K. (Kyushu University, Japan)

[1B09] Breath Odor Characteristics After Drinking and Identification of Sake Quantity 52Jin, Z.; Shimbo, T; Hosoe, Y; Oyabu. T. (Kanazawa Seiryo University, Japan)

[1B11] Silicon Bridge Type Micro Gas Sensor Array for Low Power Consumption 54Lee. J. M.1: Moon, B. U.1; Shim, C. H.2; Lee, M. B.1; Lee, J. H.1; Lee, D.-D.1; Lee, J. H.1

(School of Electrical Engineering Kyungpook National University, 2Sense and SensorCo., Ltd., Korea)

[1B12] Detection of Decomposed Compounds from an Early Stage Fire by an 56Adsorption/Combustion-Type SensorOzawa. T.1: Ishiguro, Y.1; Toyoda, K.2; Nishimura, M.2; Sasahara, T.2; Doi, T.3 (YazakiMeter Co., Ltd., 2Techonology Center Yazaki Corp., 3Tokyo Gas Co., Ltd., Japan)

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[1B13] Mesoporous Active Filter Based Sensors for Boiler Control 58Rodriguez. J.: Cirera, A.; Cabot, A.; Cornet, A.; Morante, J. R. (Universitat de Barcelona,Spain)

[1B14] Highly Sensitive Detection of Volatile Organic Compounds by an 60Adsorption/Combustion-Type Sensor Based on Mesoporous SilicaSasahara. T.1: Kido, A.1; Ishihara, H.1; Sunayama, T.1; Egashira, M.2 (Yazaki Corp.,2Nagasaki University, Japan)

[1C01] Study on the Uric Acid Biosensor 62Liao. C.-W.1: Chou, J.-C.2; Sun, T.-P3; Hsiung, S.-K.1; Hsieh, J.-H.1 (Chung YuanChristian University, 2National Yunlin University of Science and Technology, 3National ChiNan University, Taiwan)

[1C02] Highly Sensitive Flow Biosensor for p-Chlorophenol Using Tyrosinase- 64Modified Maleimide-Pendant Polystyrene Coated on Porous Carbon MaterialHasebe. Y.1: Hagiwara, T.1; Uchiyama, S.1; Kaneko, H.2; Suda, Y3; Yamada, K.3

(Saitama Institute of Tecnology 2Tsukuba Materials Information Laboratory Ltd.,3Mitsubishi Pencil Co., Ltd., Japan)

[1C03] Cholesterol Sensors Composed of Multienzyme Systems and Its Application 66to Flow-Type Sensor TipsHavashi. Y.1: Shimasaki, T.1; Takasu, H.1; Kano, K.2; Ikeda, T.2 (ROHM Co., Ltd., 2KyotoUniversity, Japan)

[1C04] Electrolytic Regeneration of Apoenzymes from Metalloenzymes and Its 68Application to Microdetermination of Heavy Metal IonsSatoh. I.: Sekine, M.; lida, Y. (Kanagawa Institute of Technology, Japan)

[1C06] Cell-Based Biosensors and Its Application in Biomedicine 70Wang. P.; Xu, G.; Qin, L; Xu, Y; Li, Y; Ye, X. (Zhejiang University, China)

[1C07] Bio-Composite Oxides for Resistive Detection of Pathogens 72Gouma. P.: Simon, S.; Jha, P.; Sawicka, K. (Stony Brook University, USA)

[1C08] Dehydrogenase-Based Novel Enzyme Switches for on-site Testings 74Suzuki. M.: Yamamoto, K.; Iribe, Y (Toyama University, Japan)

[1C09] Direct Adsorption of Jackbean Urease to Gold Surface and Its Application to 76Fabrication of Urea Electrode Using Ammonia ElectrodeUchivama. S.: Sekioka, N. (Saitama Institute of Technology, Japan)

[1C10] Biochemo-Mechanical Gel: a Novel Sensing Element for Disposable 78BiosensorsSuzuki. H.: Kumagai, A.; Ogawa, K.; Kokufuta, E. (University of Tsukuba, Japan)

[1C11] Electrophysiological Activity Modulation by Chemical Stimulation in Networks 80of Cortical Neurons Coupled to Microelectrode Arrays: a Biosensor forNeuropharmacological ApplicationsMartinoia. S.: Bonzano, L.; Chiappalone, M.; Tedesco, M.; Bove, M. (University ofGenova, Italy)

[1C12] On-line Monolithic Enzyme Reactor Fabricated by Sol-Gel Process Integrated 82on Catecholamine Sensor for Continuous Monitoring SystemChen, Z.1; Niwa, O.1; Hayashi. K.2: Iwasaki, Y.1; Kurita, R.2; Sunagawa, K.3 (NTTMicrosystem Integration Labs., 2NTT Advanced Technology Corp., 3NationalCardiovascular Center, Japan)

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[1C13] Microelectrodes Arrays (MEAs) for in-vitro Electrophysiology 84Berdondini. L1: Pe Rooij, N. F.1; Koudelka-Hep, M.1; Seitz, P.2; Blanc, N.2 (University ofNeuchatel, 2CSEM SA, Switzerland)

[1C14] Metabolic and Enzymatic Activity of Individual Cells, Spheroids, and Embryos 86as a Function of the Sample SizeShiku, H.1; Torisawa, Y.1; Takagi, A.1; Aoyagi, S.2; Abe, H.3; Hoshi, H.4; Yasuawa, T.1;Matsue. T.1 (Tohoku University, 2Hokuto Denko Co, 3Tohoku University BiomedicalEngineering Research Organization, 4Research Institute for the Functional Peptide,Japan)

[1D01] NO2 Gas Sensing Mechanism of the Substituted Aluminumfluoro 88Phthalocyanine Thin FilmsMurakami. K.1: Xiang, Q.2; Watanabe, K.1 (Shizuoka University, Japan, 2ChineseAcademy of Sciences, China)

[1D02] Electrochemical Investigations on Platinum Alloy/YSZ Electrodes for 90Amperometric NO Gas SensorsGuth. U.1: Schmidt-Zhang, P.2; Zhang, W.2; Gerlach, F.2; Ahlbom, K.2 (DresdenUniversity of Technology, Institute of Physical Chemistry and Electrochemistry, 2Kurt-Schwabe-lnstitute for Measuring and Sensor Technology, Germany)

[1D03] Remote Room Atmosphere Monitoring System with Wireless Sensors 92ModuleChung. W.-Y.: Oh, S.-J. (Dongseo University, Korea)

[1D04] Real Time Environmental Monitoring with Wireless Distributed Sensor Array 94SystemChanie. E.: Loubet, F.; Labreche, S. (Alpha Mos, France)

[1D05] Highly Sensitive Odor Sensor for Automotive Air Quality Control 96Sakamoto. M.: Kohno, H.; Matsumoto, S.; Kira, M. (FiS Inc., Japan)

[1D06] Silicon Field-Effect Biosensor for Cyanide Detection 98Schonina. M. J.12: Kloock, J. P.12; Knobbe, D.-T.12; Rade, J.12; Keusgen, M.3 (Universityof Applied Sciences Aachen, 2lnstitute of Thin Films and Interfaces, 3University ofMarburg, Germany)

[1D07] Highly Sensitive Detection of Explosive Molecules Using SPR Sensor 100Onodera. T.1; Liang, J.2; Miyahara, K.1; Matsumoto, K.2; Miura, N.2; Imato, T.2; Toko, K.2

(Japan Science and Technology Agency, 2Kyushu University, Japan)

[1D08] High Throughput Characterization for Dissolved Organic Carbon at Low Level 102in Lake WatersWakida. S.1: Shen, S.1; Kurosawa, S.1; Fukushi, K.2; Takeda, S.1 (AIST, 2Kobe University,Japan)

[1D09] Underwater Odor Compass to Locate a Chemical Source 104Ishida. H.1: Sakata, H.1; Moriizumi, T.1; Breithaupt, T.2 (Tokyo Institute of Technology,Japan, 2University of Hull, UK)

[1D10] Expected Roles of Chemical Sensors on Monitoring Geological Repository 106for High-Level Radioactive WasteTakegahara. T.: Asano, H.; Torata, S.; Ouchi, J.; Tsuboya, T. (Radioactive WasteManagement Funding and Reserch Center, Japan)

[1D11] The New Method of Determination of Mg2+, N a \ K\ Ca2+ Ions in Erythrocytes 108Using Ion-Selective ElectrodesMalon. A.: Maj-Zurawska, M. (Warsaw University, Poland)

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[1D12] 8-Hydroxy Quinoline Based Neutral Tripodal lonophore for Cu (II) Selective 110ElectrodeMittal.S.K.1: Kumar, S.2; Kumar, A. S. K.1; Sharma, H. K.1; Kaur, S. (Deemed University,2Guru Nanak Dev University, India)

[1E01] CMOS Toolbox for Monolithic Chemical Microsensor Systems 112Hierlemann. A. (ETH Zurich, Switzerland)

[1E02] Metal-Oxide-Based Monolithic CMOS Microhotplate System for Operating 114Temperatures up to 500°CGraf. M.: Barrettino, P.; Kirstein, K.-U.; Baltes, H.; Hierlemann, A. (ETH Zurich,Switzerland)

[1E03] Applications and Performance of a Polymer-Coated Monolithic CMOS Gas 116Sensor MicrosystemKurzawski. P.1: Hagleitner, C.2; Schurig, V.3; Baltes, H.1; Hierlemann, A.1 (ETH Zurich,2IBM Research, Switzerland, 3University of Tubingen, Germany)

[1E04] Development and Application of a Single Chip Multichannel SPR System 118Palumbo. M.: Petty, M. C. (University of Durham, UK)

[1E05] Development of Portable-Type Dual Surface Plasmon Resonance Sensor 120Based on Concept of SProdeImato. T.1: Asano, Y.1; Aoki, Y1; Kaneki, N.2; Hemmi, A.3; Oinuma, T.4 (Kyushu University,2Muroran Institute of Technology, 3Mebius Advanced Technology, 4Eliotech, Japan)

[1E06] A Novel Approach to the Sensing of Weak Bases 122Kusu. F.: Oshiba, K.; Kotani, A. (Tokyo University of Pharmacy and Life Science, Japan)

[1E07] Amperometric Nitric Oxide Microsensor Using Two Dimensional Cross- 124Linked Langmuir-Blodgett Films of Polysiloxane CopolymerKato. P.1; Kunitake, M.2; Nishizawa, M.3; Matsue, T.3; Mizutani, F.1 (AIST, 2KumamotoUniversity, 3Tohoku University, Japan)

[1E08] Effect of Electrode-Modification by Ionic Polymer Adsorption on 126Electrochemiluminescence of Luminol in Mild pHKamada. M.: Yoshimi, Y (Shibaura Institute of Technology, Japan)

[1E09] Realization of Higher, Stronger, Faster, and Lower Cost in Developing 128Industrial Chemical Sensors for Process ControlFeng. C.-P.: Wright, J. V; Bleak, T. M. (Rosemount Analytical Inc., USA)

[1E10] Detection Properties of Electrochemical Acidic Gas Sensors Using Halide- 130Halate Electrolytic SolutionsImava. H.1: Ishiji, T.1; Takahashi, K.2 (Riken Keiki Co., Ltd., 2RIKEN, Japan)

[1E11] A New Ion Sensing Circuit for ISFET Sensors 132Chung, W.-Y1; Yang. C.-H.12: Krzyskow, A.3; Pijanowska, P. G.3; Torbicz, W.3 (ChungYuan Christian University, 2Vanung University of Science and Technology, Taiwan,3Polish Academy of Sciences, Poland)

[1E12] Study on the Sputtered Tin Dioxide Thin Film for the Metal Oxide pH 134ElectrodePan. C.-W.1: Chou, J.-C.2; Tsai, C.-N.1; Sun, T.-R3; Hsiung, S.-K.1 (Chung Yuan ChristianUniversity, 2National Yunlin University of Science and Technology, 3National Chi NanUniversity, Taiwan)

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[1E13] Development of a Handheld 16 Channel Pen-Type LAPS for Electrochemical 136SensingSchoning, M. J.12; Wagner, T.12; Wang, C.12; Otto, R.2; Yoshinobu. T.3 (University ofApplied Sciences Aachen, 2Research Centre Jurich, Germany, 3Osaka University,Japan)

[1E14] Solid-State Hydrogen-Phosphate Ion Sensor Combined with Solid Electrolyte 138Impedance Transducer and Perovskite-Type Oxide ReceptorShimizu. Y.: Yoshida, M. (Kyushu Institute of Technology, Japan)

[2A01] Effect of Micro-Gap Electrode on Detection of Dilute Nitrogen Dioxide Using 140Tungsten Oxide Thin Film SensorsTamaki. J.: Miyaji, A.; Makinodan, J.; Ogura, S.; Konishi, S. (Ritsumeikan University,Japan)

[2A02] Tin Oxide Gas Sensors Obtained Using Nanotemplates for Synthesis and 142StabilizationCabot, A.; Rossinyol, E.; Morante. J. R. (Universitat de Barcelona, Spain)

[2A03] A New System for Discrimination and Quantification of NO2 and CO Gases 144Using a Semiconductor Gas SensorKakuuchi. H.: Kato, K.; Oto, K.; Matsuura, Y. (Figaro Engineering Inc., Japan)

[2A04] Role of Point Defects of Doped BaTiO3 Ceramics in Sensing Processing for 146Chemical SensorsZhou. Z.-G.: Tang, Z.-L.; Zhang, Z.-T. (Tsinghua University, China)

[2A05] Preparation of Large Mesoporous SnO2 Powder for Gas Sensor Application 148Shimizu. Y.: Jono, A.; Hyodo, T; Egashira, M. (Nagasaki University, Japan)

[2A06] Tailored Gas Sensors Based on Undoped and Doped SnOx Size-Selected 150Nanoparticle FilmsKennedy, M. K.1; Kruis. F. E.1: Fissan, H.2; Mehta, B. R.2 (University Duisburg-Essen,Germany, 2lndian Institute of Technology, India)

[2A07] p-Type Response of SnO2-Cr2O3 Mixed Oxide Sensors: Measurements and 152InterpretationGurlo, A.1; Barsan, N.1; Weimar. U.1: Shimizu, Y2 (University of Tubingen, Germany,2Nagasaki University, Japan)

[2A08] Nanocrystalline Tin Oxide and Preparation of Carbon Monoxide Gas Sensor 154Using at Normal TemperatureWang, L.; Liu. Y.: Yang, Y; Guo, H.; He, J. (Chinese Academy of Sciences, China)

[2A09] Hydrogen Sensing Properties of Anodically Oxidized TiO2 Film Sensors - 156Effects of Preparation and Pretreatment Conditions -Miyazaki. H.: Hyodo, T; Shimizu, Y; Egashira, M. (Nagasaki University, Japan)

[2A10] Improvement of Selectivity of Semiconductor Sensors by Light Induced 158Desorption of Surface StatesFaglia. G.1: Baratto, C.1; Comini, E.1; Zha, M.2; Zappettini, A.2; Sberveglieri, G.1 (INFM& University of Brescia, 2IMEM Institute-C.N.R, Italy)

[2A11] Simultaneous Work Function Change and Conductance Measurements on 160SnO2 Prepared from Hydrothermally Treated SolsSahm, T.1; Gurlo, A.1; Barsan. N.1: Oprea, A.1; Weimar, U.1; Yamazoe, N.2; Sakai, G.2;Shimanoe, K.2 (Universitiy of Tubingen, Germany, 2Kyushu University, Japan)

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[2A12] AC Measurements and Modeling of WO3 Thick Film Gas Sensors 162Malaau. C; Carotta, M. C; Gherardi, S.; Guidi, V; Vendemiati, B.; Martinelli, G.(University of Ferrara and INFM, Italy)

[2A13] Physico-Chemical Contribution of Metallic Electrodes on the Electrical 164Properties of Tin OxideViricelle. J.-R: Montmeat, P.; Marchand, J.-C; Lalauze, R.; Tournier, G.; Pijolat, C.(Ecole Nationale Sup. des Mines, France)

[2A14] Complementary Phenomenological and Spectroscopic Studies of Propane 166Sensing with Tin Dioxide Based SensorsKoziej. P.12: Barsan, N.1; Hoffmann, V.1; Szuber, J.2; Weimar, U.1 (University ofTubingen, Germany, 2Silesian University of Technology, Poland)

[2A15] DRIFTS Analysis of the CO2 Detection Mechanisms Using LaOCI Sensing 168MaterialMarsal. A.1: Centeno, M. A.2; Odriozola, J. A.2; Cornet, A.1; Morante, J. R.1 (Universityof Barcelona, 2Universidad de Sevilla-CSIC, Spain)

[2B01] An Urinary Incontinence Monitor System Utilizing a Semiconductor Gas 170SensorKato. K.1: Suga, T.2; Kato, Y.3; Tanaka, N.4; Setoguchi, Y1; Nakahara, T.1; Matsuura, Y1

(Figaro Engineering Inc., 2Kansai Medical University, 3The Institute of Physical andChemical Research (RIKEN), 4Forleaves Inc., Japan)

[2B02] Measurement of Ozone in Ambient Air with Microsensors : on-site Campaign 172Zdanevitch. I.1: Moser, N.2; Charpentier, C.1; Moquet, A.1; Borrel, H.2 (ineris, DRC-AIRE,France, 2Microchemical Systems SA, Switzerland)

[2B03] Feature Selection Enhances the Performance of Sensor Arrays 174Pardo. M.1: Kwong, L. G.2; Sberveglieri, G.1; Schneider, J.3; Penrose, W. R.4; Stetter, J.R.4 (INFM & University of Brescia, Italy, 2Xavier University, Philippines, 3ArgonneNational Laboratory, "Illinois Institute of Technology, USA)

[2B04] A Real-Time Intelligent Sensor System Using Nonlinear Dynamic Response 176of a Semiconductor Gas SensorKato. Y.: Mukai, T. (The Institute of Physical and Chemical Research (RIKEN), Japan)

[2B05] Time Series Analysis of Bioelectrical Potential of Plant for the Clarification of 178the Air Pollution Purification MechanismHasegawa. Y.: Asada, S.; Katsube, T; Ikeguchi, T. (Saitama University, Japan)

[2B06] Monitoring Ethylene Emission of Plants in Greenhouses for Space Mission 180Baratto. C.1: Faglia, G.1; Falasconi, M.; Pardo, M.; Vezzoli, M.; Boarino, L.2; Maffei, M.3;Sberveglieri, G.1 (University of Brescia, 2Quantum Devices Laboratory, 3University ofTorino, Italy)

[2B07] Planar Catalytic Combustor Film for Thermoelectric Hydrogen Sensor 182Shin. W.: Tajima, K; Choi, Y; Izu, N.; Matsubara, I.; Murayama, N. (AIST, Japan)

[2B08] Effect of Humidity on the Sensing Property of Thermoelectric Hydrogen 184SensorSawaguchi. N.: Shin, W.; Izu, N.; Matsubara, I.; Murayama, N. (AIST, Japan)

[2B09] Controlling Gas Selectivity Through Polymorph Selection for Metal Oxide 186Chemical DetectorsGouma. P.-l. (State University of New York, USA)

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[2B10] Dual H2-O2 Detection Using a Selective SiO2 Filter on a SnO2 Thick Gas 188SensorTournier, G.; Pijolat. C. (Ecole Nationale Sup. des Mines, France)

[2B12] Detection of Volatile Organic Compounds Using a New Integrated Single- 190Chip CMOS Cantilever Gas Sensor with Magnetic ActuationVancura. C.1: Li, Y.1; Hagleitner, C.2; Hierlemann, A.1; Baltes, H.1 (ETH Zurich, 2IBMResearch GmbH, Switzerland)

[2B16] Giant Magneto-Impedance of Permalloy-Copper Composite Thin Films by 192Electro-DepositionYe. Y.: Jiang, Y; Hu, W.; Zeng, H. (University of Electronic Science & Technology ofChina, China)

[2C02] Electrical DNA Sensing Based on the Electron Transfer in Gold Nanoparticle- 194NetworkShiigi. H.: Tokonami, S.; Nagaoka, T. (Osaka Prefecture University, Japan)

[2C03] Construction of on-chip Type Microchip System for DNA Sensing 196Nagakagawa. T.: Tanaka, T; Okochi, M.; Takeyama, H.; Matsunaga, T. (Tokyo Universityof Agriculture & Technology, Japan)

[2C04] Separation of DNA in a Versatile Microchip 198Cretich. M.1: Chiari, M.1; Suzuki, H.2; Loughran, M.3 (Consiglio Nazionale delleRicerche, Italy, 2University of Tsukuba, 3AIST, Japan)

[2C05] Surface Plasmon Resonance Biosensors for Multianalyte Detection 200Homola. J. (Institute of Radio Engineering and Electronics, Czech Republic)

[2C06] Time-Resolved Slab Optical Waveguide Absorption Spectroscopy for 202Studying Protein Adsorption Kinetics on Solid/Liquid InterfacesMatsuda. N.1: Santos, J. H.1; Qi, Z.-m.1; Takatsu, A.2; Kato, K.2 (AIST, 2NationalMetrology Institute of Japan, Japan)

[2C07] Signal Amplification for Surface Acoustic Wave (SAW) Biosensors by 204Acoustic Wave Guiding Layers and Additional Mass LabelingLange, K; Rapp. M. (Institute for Instrumental Analysis, Germany)

[2C08] A Novel Surface Plasmon Resonance Imaging Interferometry 206Yu. X.: Wang, P.; Wei, X.; Peng, Y; Liu, J.; Ping, X. (Tsinghua University, China)

[2C09] Surface-Plasmon-Resonance Immunosensor Based on Indirect Competitive 208Immunoassay Aiming for Highly Sensitive Detection of LandminesShankaran. P. R.: Gobi, K. V.; Matsumoto, K.; Imato, T; Toko, K.; Miura, N. (KyushuUniversity, Japan)

[2C10] Micrometer-Sized Optical Fiber Affinity Biosensor Using Localized Surface 210Plasmon ResonanceMitsui. K.1: Handa, Y.2; Kajikawa, K.21 (PRESTO, Japan Science and TechnologyAgency, 2Tokyo Institute of Technology, Japan)

[2C11] Lateral Field Excited Bulk Acoustic Wave Biosensor 212Hu, Y; Millard, P.; Vetelino. J. F. (University of Maine, USA)

[2C12] Indium-Tin Oxide-Coated Fiber Optic Immunosensor for the Detection of Anti 214Hepatitis C Virus-E2 Envelope ProteinKonry, T.1; Novoa, A.1; ShemerAvini, Y1; Hanuka, N.1; Marks. R. S.1: Cosnier, S.2 (Ben-Gurion University of the Negev, Israel, 2Universite Joseph Fourier, France)

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[2C13] Electrical Detection of Label-Free PSA (Prostate Specific Antigen) Using 216Self-Sensing Piezoresistive MicrocantileversWee. K. W.12: Kang, G. Y.1; Park, J.1; Kang, J. Y.1; Yoon, P. S.1; Park, J. H.2; Kim, T. S.1

(KIST, 2Korea University, Korea)

[2C14] Development of the Fluorescent Nonnatural Antibody Protein as a Novel 218Biosensing Molecular DeviceShinohara. H.1: Hamada, H.2; Hohsaka, T.3; Sisido, M.2 (Toyama University, 2OkayamaUniversity, 3AIST, Japan)

[2C15] Surface Electrochemical Enzyme Immunoassay for the Highly Sensitive 220Measurement of B-Type Natriuric PeptideMatsuura. H.1: Sato, Y.2; Sawaguchi, T.2; Mizutani, F.12 (University of Tsukuba, 2AIST,Japan)

[2C16] Highly Sensitive Electrochemical Enzyme-Linked Immunoassay Based on 222Alkaline Phosphatase Loaded Carbon Nanotube and Carbon NanotubeModified ElectrodeJan. M. R.: Wang, J.; Liu, G. (University of Peshawar, Pakistan)

[2D01] Amperometric NOX Sensor Based on Oxygen Pumping Current by Using 224LaGaO3 Based Solid Electrolyte for Monitoring Exhaust GasIshihara. T.1: Putta, A.1; Takita, Y.2 (Kyushu University, 2Oita University, Japan)

[2D02] Development of a New Capacitive Type Gas Sensor Combining 226Semiconductor and Solid ElectrolyteZamani. C: Shimanoe, K.; Yamazoe, N. (Kyushu University, Japan)

[2D03] Planar Non-Nernstian Electrochemical Sensors: Testing in the Exhausts of an 228Engine Bench TestPi Bartolomeo. E.: Grilli, M. L.; Antonias, N.; Cordiner, S.; Traversa, E. (University ofRome "Tor Vergata", Italy)

[2D04] Mixed-Potential-Type Zirconia Sensor Using Nickel Oxide Sensing-Electrode 230for Detection of NOX at High TemperaturesWang. J.: Nakatou, M.; Miura, N. (Kyushu University, Japan)

[2D05] Stability of CO2 Gas Sensor with Alkali Carbonate/Na2O-AI2O3-4SiO2/8YSZ 232StructureOkamoto, T; Tsumura, N.; Aono. H.: Sadaoka, Y. (Ehime University, Japan)

[2D06] NASICON-Based Potentiometric CO2 Sensor Combined with New Materials 234Operative at Room TemperatureObata. K.1: Kumazawa, S.2; Matsushima, S.1; Shimanoe, K.3; Yamazoe, N.3 (KitakyushuNational College of Technology, 2TDK Corporation R & D Center, 3Kyushu University,Japan)

[2D07] A Novel Solid Electrolyte Hydrogen Sensor 236Wollenstein. J.1: Baumann, R.2; Rademacher, S.1; Stich, R.1; Hammer, F.2 (FraunhoferInstitut fiir Physikalische Messtechnik, 2ESCUBE GmbH, Germany)

[2D08] Amperometric Hydrocarbon Sensor Using La(Sr)Ga(Fe)O3 Solid Electrolyte 238for Monitoring in Exhaust GasPutta. A.2: Nishiguchi, H.1; Takita, Y1; Ishihara, T.2 (Oita University, 2Kyushu University,Japan)

[2D09] Effect of Characteristic on the Thin-Film Limiting Current Type Oxygen 240Sensor by the Difference in Electrode Interface StructureSuzuki. T.: Kondo, M.; Ogino, K.; Ishiguro, Y; Takahashi, H. (Yazaki Meter Co., Ltd.,Japan)

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[2D10] The Influence of Catalytic Activity and Temperature on the Binary Switch 242Point of MISiC-FET Lambda SensorsWingbrant. H.: Lloyd Spetz, A. (Linkoping University, Sweden)

[2D11] Performance of a Miniature Zirconia Oxygen Sensor with a Pd-PdO Internal 244ReferenceKaneko, H.1; Okamura, T.1; Taimatsu, H.1; Matsuki, Y.2; Nishida, H.2 (Akita University,2Tohoku Fujikura Co., Ltd., Japan)

[2D12] A Novel Zirconia Oxygen Sensor with Dense Diffusion Barrier 246Tang. Z.: Zhou, X.; Yao, W.; Zhang, Z.; Zhou, Z. (Tsinghua University, China)

[2D13] Novel Oxygen Sensor Using 0-/3" Alumina Electrolyte 248Park, J.; Park, P.; Park. C. O. (Korea Advanced Institute of Science and Technology,Korea)

[2D14] Behavior of Oxygen Concentration Cells Using BiMeVOx (Me=Cu, Ti, Sb) 250CompoundsCho. H. S.: Sakai, G.; Shimanoe, K.; Yamazoe, N. (Kyushu University, Japan)

[2D15] An Oxygen Sensor with a Screen-Printed Solid-State CeO2-ZrO2-TiO2 252ReferenceRajabbeigi, N.1; Elyassi, B.1; Khodadadi. A.1: Mohajerzadeh, S. S.1; Mortazavi, Y.1;Sahimi, M.2 (University of Tehran, Iran, 2University of Southern California, USA)

[2D16] Doping Effects on NO2 Sensing Characteristics of WO3-Based Thin Film 254Micro Gas SensorHe. X.: Li, J.; Gao, X. (Chinese Academy of Sciences, China)

[2E01] Sensitive Mai-Odor Sensor for Breath Analysis Using an Array of Plasma- 256Deposited Organic Film Coated Quartz Crystal Resonators Combined with aNovel Humidity-Control SystemSeyama. M.1: Iwasaki, Y.1; Sugimoto, I.2; Tate, A.1; Niwa, O.1 (NTT Corporation, 2TokyoUniversity of Technology, Japan)

[2E02] Preparation of Long-Lifetime Gas Recognition Films by Plasma- 258Polymerization TechniqueMiura, H.12; Takahashi, H.12; Kurosawa. S.12: Park, J.-W.13; Aizawa, H.14; Noda, K.1;Yamada, K.2; Hirata, M.2 (AIST, 2Nihon University, 3The University of Tokyo, 4NEDO,Japan)

[2E03] Quartz Crystal Microbalance (QCM) Sensor for CH3SH Gas by Using 260Polyelectrolyte Coated Sol-Gel FilmKikuchi. M.: Shiratori, S. (Keio University, Shiratori Nanotechnology Co., Ltd., Japan)

[2E05] Pesticide Detection Using a Lateral Field Excited Acoustic Sensor 262Hu, Y; Li, H.; Frankel, P.; Vetelino. J. F. (University of Maine, USA)

[2E06] Electrospun Nanofibrous Polyelectrolyte Membranes for Advanced Chemical 264SensorsPing. B.: Kim, J.; Fujimoto, K.; Shiratori, S. (Keio University, Shiratori Nanotechnology,Co., Ltd., Japan)

[2E07] An Improved System Based on Surface Acoustic Wave Sensors for Reliable 266MeasurementShen, C.-Y.1; Chen, R.2; Shen, Y.-T.3; Wu. L.2: Huang, C.-R1; Jeng, J.-S.1 (l-ShouUniversity, 2ftech Corporation, 3National Cheng Kung University, Taiwan)

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[2E08] Bulk Acoustic Wave Resonator as a Sensing Platform for NOX at High 268TemperaturesSeh. H.: Hyodo, T; Tuller, H. L. (MIT, USA)

[2E09] High-Throughput Screening of Polymer/Solvent Interactions Using 24- 270Channel Acoustic-Wave Sensor SystemPotyrailo. R. A.: Morris. W. G.; Wroczynski, R. J. (GE Company, USA)

[2E10] Radio Frequency Thin Film Characterization with Polymer-Coated Love- 272Wave Sensor.Razan, F.2; Rebiere. P.1; Pejous, C.1; Pistre, J.1; Pestaruc, M.2; Pavageau, B.2

(Universite Bordeaux 1, 2Centre de Recherche d'Aubervilliers, France)

[2E11] Amino-Functional Cross-Linked Polymer Coatings for QCM-Based NO2 Gas 274Monitoring ApplicationsMatsuguchi. M.: Kadowaki, Y; Tanaka, M. (Ehime University, Japan)

[2E12] Preparation of Intercalate Organic/MoO3 Nanohybrids and Their VOC Gas 276Sensing PropertiesMatsubara. I.: Hosono, K.; Murayama, N.; Shin, W.; Izu, N. (AIST, Japan)

[2E13] Analyte Sorption and Distribution Profiles in Thin Metal Nanoparticle/Organic 278Composite Films-Implication to the Mechanism of Vapor SensingKrasteva. N.1: Besnard, I.1; Joseph, Y.1; Krustev, R.2; Yasuda, A.1; Vossmeyer, T.1 (SonyInternational (Europe) GmbH, 2Hahn-Meitner Institute Berlin, Germany)

[2E14] Studying the Binding Processes between Porphyrins and Organic Vapours 280Macagnano, A.1; Sgreccia, E.2; Pi Natale, C.21; Paolesse, R.21; Pantalei, S.2; Zampetti,E.2; Pennazza. G.2: P'Amico, A.1'2 (National Research Council, 2Tor Vergata University,Italy)

[3A02] H2S Micro Gas Sensor Fabricated by Thermal Oxidation of Cu/Sn Double 282LayerLee. J.-M.1: Moon, B.-U.1; Shim, C.-H.2; Lee, M.-B.1; Lee, D.-D.1; Lee, J.-H.1 (KyungpookNational University, 2Sense and Sensor Co., Ltd., Daegu, Korea)

[3A03] Vanadium and Tantalum Doped Titanium Oxide (TiTaV): A Novel Material for 284Gas SensingCarotta. M. C.1: Galliera, S.1; Guidi, V.1; Malagu, C.1; Vendemiati, B.1; Zanni, A.1;Martinelli, G.1; Sacerdoti, M.1; Licoccia, S.2; Pi Vona, M. L.2; Traversa, E.2 (Universita diFerrara, 2Universita di Roma "Tor Vergata", Italy)

[3A04] Nano-Crystalline High Sensitivity SnO2-Based Sensors on (100) Silicon 286Substrates for H2S and CO SensingEsfandyarpour, B.; Mohajerzadeh, S.; Khodadadi. A.: Robertson, M. P. (University ofTehran, Iran)

[3A05] The Preparation of Al-Doped ZnO Thin Films by Sol-Gel Dip Coating Method 288and the Application for CO Gas Sensor MaterialJung. S. J.: Yang, J. B.; Lee, H. W.; Kim, Y. H.; Kim, S. R.; Kim, C. Y (Korea Institute ofCeramic Engineering and Technology, Korea)

[3A06] CeO2 (WO3)-Based Thin Film Gas Sensor for VOC Detection 290Takada. T.: Pougami, N. (New Cosmos Electric Co., Ltd., Japan)

[3A07] Highly Sensitive Detection of Volatile Organic Amines Using V2O5 Nanofibers 292Besnard, I.1; Schlecht, U.2; Burghard, M.2; Yasuda, A.1; Vossmeyer. T.1 (SonyInternational (Europe) GmbH, 2MPI for Solid State Research, Germany)

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[3A08] Development of a WO3 Thick Film Based Sensor for the Detection of VOC 294Kanda. K. (New Cosmos Electric Co., Ltd., Japan)

[3A09] Grain Surface Area and Gas Sensing Characteristics of Tungsten Oxide Gas 296SensorsSrivudthsak. M.1: Supothina, S.2(Chulalongkorn University,2National Metal and MaterialTechnology Center, Thailand)

[3A10] Gas Sensing Properties of ZnO/SnO2 Thin Films Prepared by the Sol-Gel 298MethodShoyama. M. (Mie Science and Technology Promotion Center, Japan)

[3A11] Hydrocarbon Sensing with Thick and Thin Film P-Type Conducting Perovskite 300MaterialsMatam. M.1: Sahner, K.2; Moos, R.2; Post, M.1; Tunney, J.1 (National Research Councilof Canada, Canada, 2University of Bayreuth, Germany)

[3A12] N-type and P-Type Metal Oxide Gas Sensors Based on the Titanium- 302Chromium-Vanadium Ternary CompoundPonzoni, A.1; Comini. E.1: Colombi, P.2; Bontempi, E.2; Pepero, L. E.2; Sberveglieri, G.1

(Brescia University, 2University of Brescia, Italy)

[3A13] Application of Semiconductor-Metal Phase Transformation in Rare Earth 304Elements Cobaltites for Making Chemical Sensors of GasesBashkirau, L.; Kurhan, S.; Petrov. G.; Chabatar, A.; Klyndziuk, A.; Bashmakov, I.(Belarus State Technological University, Belarus)

[3A14] Tungsten Oxides Phase Transitions as Gas Sensitive States 306Shishkin. N. Y1: Cherkasov, V. A.1; Komarov, A. A.1; Bardi, U.2; Gunko, Y K.3; Zharsky,I. M.1; Bashkirov, L. A.1 (Belarus State University of Technology, Belarus, 2Universita diFirenze, Italy, 3 Trinity College Dublin, Ireland)

[3B01] Interference Effects on Chemical Warfare Agent Detection by MEMS-Based 308Microsensor ArraysMeier. P. C.1: Cavicchi, R. E.1; Ellzy, M. W.2; Boger, Z.3; Semancik, S.1 (NIST, 2ECBC,3Optimal-Industrial Neural Systems Ltd., USA)

[3B02] A Micromachined Gas Sensor Based on a Catalytic Thick Film/SnO2 Thin 310Film Bilayer and Thin Film Heater Part 1: CH4 SensingSuzuki. T.1: Kunihara, K.1; Kobayashi, M.1; Tabata, S.2; Higaki, K.2; Ohnishi, H.2 (FujiElectric Advanced Technology Co., Ltd., 2Osaka Gas Co., Ltd., Japan)

[3B03] A Micromachined Gas Sensor Based on a Catalytic Thick Film/SnO2 Thin 312Film Bilayer and Thin Film Heater Part 2: CO SensingTabata. S.1: Higaki, K.1; Ohnishi, H.1; Suzuki, T.2; Kunihara, K.2; Kobayashi, M.2 (OsakaGas Co., Ltd., 2Fuji Electric Advanced Technology Co., Ltd., Japan)

[3B04] The Development of Temperature-Controlled Microanalytical Components for 314Space ExplorationSemancik, S.1; Cavicchi, R. E.1; Meier. P. C.1: Benkstein, K. P.; Li, G.1; Ryan, M. A.2;Homer, M. L.2; Manatt, K.2; Kisor, A.2; Taylor, C. J.3 (National Institute of Standards andTechnology, 2Jet Propulsion Laboratory, 3Pomona College, USA)

[3B05] Pull-in Voltage of the Microfabricated Cantilever with Step-up Support in 316MEMS-Based MicrosensorWang. C. S.1: Cheng, T. J.2; Fang, J.2; Zhang, P. C.2; Liu, M.1 Chen, B. Q.1 (IME, CAS,2Peking University, China)

[3B06] Cantilever Tip-Probe Arrays for Simultaneous SECM and AFM Analysis 318Faschina. R. J.: Tao, Y; Prinz, F. B. (Stanford University, USA)

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[3B07] Novel Micromachining Sequence to Improve Performance and Yield of 320Calorimetric MicrosensorsSalo. T.: Kurzawski, P.; Hierlemann, A.; Baltes, H. (ETH Zurich, Switzerland)

[3B08] Micromechanical Fabrication of Low-Power Thermoelectric Hydrogen Sensor 322Tajima. K: Qiu, F; Shin, W.; Izu, N.; Matsubara, I.; Murayama, N. (AIST, Japan)

[3B09] Advanced Metal Oxide Based Structures for Sensor Technologies 324Vayssieres. L.12 (National Institute for Materials Science, Japan, 2Lawrence BerkeleyNational Laboratory, USA)

[3B10] Gas Sensor Microhotplate Technology: Silicon Oxide/Nitride or Thin Alumina 326Film (TAF)?Vasiliev. A. A.1: Gogish-Klushin, S. Y.1; Kharitonov, P. Y.1; Pisliakov, A. V.1; Guarnieri, V.2;Zen, M.2; Margasin, B.2; Soncini, G.2; Paranjape, M.3 (RRC Kurchatov Institute, Russia,2lstituto Trentino di Cultura, Italy, 3Georgetown University, USA)

[3C01] Amperometric Detection of Hydrogen Peroxide at a Prussian Blue Modified 328FTO ElectrodeTseng, K.-S.; Chen, L.-C; Ho. K.-C. (National Taiwan University, Taiwan)

[3C02] In Situ Sensing of Cellular Stress Signal Using a PMP Complex (Cu) 330Ikeno. S.1'2: Haruyama, T.12 (Kyushu Institute of Technology, 2CREST, Japan)

[3C03] Development of a Microfluidic Gas-Diffusion Unit for Flow Injection 332Biosensinglida. Y.: Suganuma, Y; Satoh, I. (Kanagawa Institute of Technology, Japan)

[3C04] Enzyme Electrode Response in Solution Containing Enzyme Substrate and 334Species That Associates with the SubstrateMizutani. F.; Yabuki, S.; Sato, Y.; lijima, S. (AIST, Japan)

[3C05] Microbial Fuel Cell-Type BOD Sensor 336Kim. B. H.; Chang, I. S.; Moon, H. (Korea Institute of Science & Technology, Korea)

[3C06] Preparation of a Bio-Fuel Cell Using Functional Bio-Sensing Electrodes 338Taniguchi. I.1: Tabata, P.1; Koga, T.1; Tominaga, M.1; Sotomura, T.2 (KumamotoUniversity, 2Matushita Electric Industrial Co., Ltd., Japan)

[3C07] Simultaneous Determination of Glucose and Ascorbic Acid by Using Gold 340Electrode Modified with Ferrocenylalkanethiol MonolayerSato. Y.: Kato, P.; Mizutani, F. (AIST, Japan)

[3C08] Synthesis of Redox-Active Thermosensitive Polymers and Their Application 342to Electrocatalytic Reactions of Glucose OxidaseNakadan N.; Imabayashi. S.: Watanabe, M. (Yokohama National University, Japan)

[3C09] Possibility of "Super Catalytic Antibody" (Antigenase) as a Sensing Molecule 344Uda. T.2: Mitsuda, Y.1; Hifumi, E.2 (Hiroshima Prefectural University, 2Japan Science andTechnology Agency, Japan)

[3C10] A Twin Microcantilever Array for Measurement of Red Blood Cell 346Deformability and Electrical ImpedanceCho. Y H.: Takama, N.; Kim, B. J. (University of Tokyo, Japan)

[3C11] The Frequency Response of QCM in Electrochemically Characterizing the 348Immobilization on Gold ElectrodePong. Y-G. (Tsinghua University, China)

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[3C12] Construction of Nano-Structured Interfaces Using Self-Assembled Thiol 350Monolayers and Application to BiosensorsSawaauchi. T.: Mizutani, F; Niwa, O. (AIST, Japan)

[3C13] Electroanalysis of Lincomycin Using Boron-Doped Diamond Thin Film 352Electrode Applied to Flow Injection SystemBoonsong. K.: Wangfuengkanakul, N.; Chailapakul, O. (Chulalongkorn University,Thailand)

[3D01] Distributed Hydrogen Determination with Fiber-Optic Sensor 354Sumida. S.1: Okazaki, S.1; Asakura, S.1; Nakagawa, H.2; Murayama, H.2; Kamita, T.3;Hasegawa, J.3(Yokohama National University, 2University of Tokyo, 3Japan AerospaceExploration Agency, Japan)

[3D02] Temperature Programmed Sensing for Gas Identification Using 356Cataluminescence-Based SensorsOkabavashi. T.1: Matsuo, N.1; Yamamoto, I.1; Utsunomiya, K.1; Yamashita, N.2;Nakagawa, M.1 (Okayama University of Science, 2Okayama University, Japan)

[3D03] Optical CO Gas Sensing via Co 3 0 4 /Co0 Phase Transformation in 358Nanostructured Films Fabricated by Pulsed Laser DepositionZbroniec, L.; Sasaki, T; Koshizaki. N. (AIST, Japan)

[3D04] Spontaneous Deposition of Ordered Film of Amphiphilised Porphyrin 360Derivatives on GlassMastroianni. M.1: Monti, D1.; Paolesse, R.12; Nardis, S.1; Russo, M.1; Pi Natale, C.12;P'Amico, A12. (Universita di Roma "Tor Vergata", 2CNR-IMM Sezione di Roma, Italy)

[3D05] Chromogenic Calixarene Sensors for Amine Detection 362Liu. C.-H.1: Lin, J. T.1; Wang, S. H.1; Lin, L. G.2 (National Taiwan University of Scienceand Technology, 2Chinese Culture University, Taiwan)

[3D06] Determination of Heavy Metal Ions Based on Quenching of the Rare Earth 364Luminescence(2)Arakawa. T.: Muraki, A.; Hashimoto, M. (Kinki University, Japan)

[3D08] A Novel Fibre Optic LED Spectrophotometer for Direct in-situ Environmental 366MonitoringLouohran. M.1: Pozzi, R.2; Porro, G.2 (AIST, Japan, 2DataMed Sri, Italy)

[3D10] Novel Inorganic and Organic-Inorganic Hybrid Nanostructured Thin Film for 368Gas MicroSensors Prepared by Supersonic Cluster Beam DepositionSiciliano. P.1: Taurino, A.1; Toccoli, T.2; Pallaoro, A.2; lannotta, S.2; Milani, P.3 (Universityof Lecce, 2IFN-CNR Trento, 3University of Milano, Italy)

[3D11] Study on Dielectric Properties of Humidity Sensing Nanometer Materials 370Wang. J.: Wang, X.-H.; Xiao, X.; Wang, X.-P. (Dalian University of Technology, China)

[3D12] Promoting Effect of TiO2 Nanowire Composited with Nafion Material 372Application in Measurement of HumidityWu. R.-J.: Sun, Y.-L.; Chen, H.-W. (Industrial Technology Research Institute, Taiwan)

[3E01] Pt/y-AI2O3 Particles for Long Term Stable, Highly Selective MISiCFET Gas 374SensorsCerda, J.1; Salomonsson, A.1; Strand, M.2; Sanati, M.2; Lloyd Spetz. A.1 (LinkopingUniversity, 2Vaxj6 University, Sweden)

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[3E02] Influence of Gate Bias of MISiC-FET Gas Sensor Device on the Sensing 376PropertiesNakagomi. S.1: Fukumura, A.1; Kokubun, Y1; Savage, S.2; Wingbrant, H.3; Andersson,M.3; Lundstrom, I.3; Lofdahl, M.4; Lloyd Spetz, A.3 (Ishinomaki Senshu University, Japan,2ACREO AB, 3Link6ping University, 4AppliedSensor AB, Sweden)

[3E03] Controlling the Sensitivity Region of Hydrogen Sensitive Field Effect Devices 378Eriksson. M.1: Tenselius, P.2; Einehag, M.2; Lofdahl, M.2 (Linkoping University,2AppliedSensor Sweden AB, Sweden)

[3E04] Chemical Images as a Tool for Optimising Gas Sensor Properties 380Klingvall. R.: Lundstrom, I.; Eriksson, M. (Linkoping University, Sweden)

[3E05] Dielectrophoretic Micropatterning of Microparticles Monolayer Covalently 382Linked to Glass SurfaceYasukawa. T: Suzuki, M.; Shiku, H.; Matsue, T. (Tohoku University, Japan)

[3E06] Chiral-Selectivity on Gate Effect of Phenylalanine Imprinted Polymers Grafted 384onto Cellulosic MembraneHattori. K.1: Sasaki, A.1; Yoshimi, Y.2; Kohori, F.1; Sakai, K.1 (Waseda University,2Shibaura Institute of Technology, Japan)

[3E07] Intelligent Dissolved Oxygen Microsensor with an Integrated Actuation 386MicrosystemPark. J.1: Kim, Y-J.2; Kim, C.-S.1 (University of Missouri-Rolla, USA, 2KyungpookNational University, Korea)

[3E08] Micro Fluidic Transport Module Based on Electrowetting and its Application 388for Micro-Sensor SystemsSatoh. W.1: Loughran, M.2; Suzuki, H.1 (University of Tsukuba, 2AIST, Japan)

[3E09] Miniaturized One-Chip Electrochemical Biosensors Integrated with a Dialysis 390Membrane and Double Thin-Layer Flow ChannelsKurita. R.1: Yabumoto, N.1; Hayashi, K.2; Iwasaki, Y.2; Niwa, O.3 (NTT AdvancedTechnology, Corp., 2NTT Microsystem Integration Labs., 3AIST, Japan)

[2P002] Preparation and Characterization of Combined Environmental Sensors 392Xie, G.; Wang, T; Jiang, B.; Wu, Z.; Xu, J.; Jiang. Y.: Zeng, H.; Ye, Y; Yang, B.(University of Electronic Science & Technology of China, China)

[2P003] Carbon Dioxide Gas Sensor Based on Trivalent Cation and Divalent Oxide 394Anion Conducting Solids with Rare Earth Oxycarbonate Based AuxiliaryElectrodeTamura. S.1: Hasegawa, I.1; Imanaka, N.1; Maekawa, T.2; Tsumiishi, T.2; Suzuki, K.2;Ishikawa, H.2; Ikeshima, A.3; Kawabata, Y.3; Sakita, N.3; Adachi, G.3(Osaka University,2New Cosmos Electric Co., Ltd., 3College of Analytical Chemistry, Japan)

[2P005] NO2 Gas Adsorption-Desorption Process on Polyaniline Thin Films Monitored 396by an Optochemical SensorElizalde-Torres. J.: Hu, H.; Garcia-Valenzuela, A.; Saniger, J. (UNAM, Mexico)

[2P006] Solid Electrolyte Type SO2 Gas Sensor with Rare Earth Oxysulfate Based 398Auxiliary ElectrodeTamura. S.: Hasegawa, I.; Kim, Y. W.; Imanaka, N. (Osaka University, Japan)

[2P007] Solid Electrolyte Type Nitrogen Monoxide Gas Sensor Operating at 400Intermediate Temperature RegionHasegawa. I.: Tamura, S.; Imanaka, N. (Osaka University, Japan)

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[2P008] Vanadium Oxides Phase Transitions at Doping and Vapour Presence 402Shishkin. N. Y1: Cherkasov, V. A.1; Komarov, A. A.1; Kosov, P. V.1; Bardi, U.2; Gunko, Y.K.3; Zharsky, I. M.1; Bashkirov, L. A.1 (Belarus State Univ. of Tech., Belarus, 2Universitadi Firenze, Italy, 3 Trinity College Dublin, Ireland)

[2P010] Piezoelectric Ethanol Sensors: AT-Cut Quartz Resonators with Stearic Acid 404FilmsWang. C.-H.1: Huang, Y. C.2 (Nan-Jeon Institute of Technology, 2National Cheng KungUniversity, Taiwan)

[2P011] Undoped and 0.1wt% Ca-Doped Pt-Catalyzed SnO2 Sensors for CH4 406DetectionMin, B.-K; Choi. S.-P. (Yeungnam University, Korea)

[2P012] C4H10 Sensing Characteristics of Ion Beam Sputtered SnO2 Sensors 408Min, B.-K.; Choi. S.-P. (Yeungnam University, Korea)

[2P013] Sensitization of SnO2 Gas Sensor for Ethylene Oxide 410Kugishima. M.: Sakai, G.; Shimanoe, K.; Yamazoe, N. (Kyushu University, Japan)

[2P014] Improvement of Warming-up Characteristics of Potentiometric CO2 Sensor by 412Using Solid Reference Counter ElectrodeMivachi. Y.: Sakai, G.; Shimanoe, K; Yamazoe, N. (Kyushu University, Japan)

[2P015] Room Temperature Hydrogen Sensitivity of a MIS Structure Based on the 414Pt/LaF3 InterfaceFilippov, V. I.1; Vasiliev. A. A.1: Szeponik, J.2; Moritz, W.3 (RRC Kurchatov Institute,Russia, 2BST BioSensorTechnologie GmbH, 3Humboldt University of Berlin, Germany)

[2P016] Resistive Oxygen Gas Sensors Based on Ce1.xZrxO2 Nano Powder Prepared 416Using New Precipitaion MethodIzu, N.1; Oh-hori. N.2: Itou, M.2; Shin, W.1; Matsubara, I.1; Murayama, N.1 (AIST, 2YamahaMotor Co., Ltd., Japan)

[2P017] Determination of the Sensitive Layer Temperature of the Adsorption 418Semiconductor Gas SensorIsaienko. P.: Maksymovych, N.; Yatsimirsky, V. (National Taras Shevchenko KyivUniversity, Ukraine)

[2P018] Response Characteristic of Resistive Oxygen Sensors Based on Cerium 420Oxide Thick FilmIzu. N.: Shin, W.; Matsubara, I.; Murayama, N. (AIST, Japan)

[2P019] A Biochemical Gas-Sensor with Monoamine Oxidase for Methyl Mercaptan 422VaporMinamide. T.1: Saito, H.2; Mitsubayashi, K.2 (Tokai University, 2Tokyo Medical and DentalUniversity, Japan)

[2P020] Organically Hybridized SnO2 Gas Sensors 424Matsubara. I.: Hosono, K.; Murayama, N.; Shin, W.; Izu, N. (AIST, Japan)

[2P021] Amperometric Electrochemical Gas Sensor for Monitoring of Sulfur Dioxide 426in Volcanic GasIshiji. T.1: Matsuda, H.1; Takahashi, K.2 (Riken Keiki Co., Ltd., 2The Institute of Physicaland Chemical Research (RIKEN), Japan)

[2P022] Improvement of Electrochemical NO2 Sensor by Use of Carbon- 428Fluorocarbon Gas Permeable ElectrodeMizutani. Y.1'2: Matsuda, H.1; Ishiji, T.1; Furuya, N.2 (Riken Keiki Co., Ltd., 2YamanashiUniversity, Japan)

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[2P023] High Order Modes to Improve Sensitivity of Resonant Microcantilever 430Chemical MicrosensorsPufour. I.: Lochon, F.; Fadel, L. (Laboratoire IXL, France)

[2P024] The Simple Detection of Trichloroethylene by Applying Oxidizing Agents to 432the Quartz Crystal Microbalance MethodNoda. K.: Naganawa, R.; Kanekiyo, Y; Kurosawa, S.; Aizawa, H.; Tao, H. (AIST, Japan)

[2P025] The Effects of Annealing Temperature on the Characteristic of Low 434Temperature SrTiO3 Oxygen Gas SensorHu. Y.1: Tan, O. K.1; Pan, J. S.2; Huang, H.1; Cao, W.1 (Nanyang TechnologicalUniversity, 2lnstitute of Materials Research and Engineering, Singapore)

[2P026] Effect of Humidity of Polypyrrole Sensor to Methanol Gas 436Cho. J.-H.: Kim, J.-S.; Sohn, S.-O.; Han, Y.-A.; Huh, J.-S. (Kyungpook NationalUniversity, Korea)

[2P027] Toxic Gas Detection Using Porphyrin Dispersed Polymer Composites 438Peki, K.; Nakashima. S.: Itagaki, Y; Sadaoka, Y. (Ehime University, Japan)

[2P028] Formation Alkali Ionic Conductive Layer on YSZ and Application to 440Potentiometric Gas SensorItoh, Y; Fujishima, M.; Aono, H.; Sadaoka. Y. (Ehime University, Japan)

[2P029] A Gas-Phase Biosensor for Hydrogen Peroxide Vapor 442Goto. T.1: Amagai, H.1; Mitsubayashi, K.2 (Tokai University, 2Tokyo Medical and DentalUniversity, Japan)

[2P030] NOX Gas Response Characteristics of Thin Film Mixed Oxide Semiconductor 444Song. K.-P.: Bang, J.-l.; Lee, R.-S.; Lee, Y.-S.; Hong, Y.-H.; Lee, P.-P. (KyungpookNational University, Korea)

[2P031] Hydrogen Sensing Property of Pd-Capped Mg2Ni Thin Film 446Yoshimura. K.: Yamada, Y; Okada, M.; Tazawa, M.; Jin, P. (AIST, Japan)

[2P032] Studies on Trapping Agent of the Trace Formaldehyde in Air by Droplet- 448Fluorophotometry MethodAn. C.-J.1: Zhang, Z.-Q.2; Ping, Z.-Z.1; Zhang, Y.-Z.2; Zheng, P.1; Wu, Z.-Y.1 (WuhanUniversity, 2Yangtze University, China)

[2P033] Light-Dark Photosynthesis Reaction of Teaching Tools for Science Education 450Using Handmade Oxygen SensorTakahashi. M.1: Takeda, T.1; Ishiji, T.2; Kawashima, N.3 (Tokyo National College of Tokyo,2Riken Keiki Co., Ltd., 3Toin University of Yokohama, Japan)

[2P034] Silicon Carbide Diode-Based Carbon Monoxide Gas Sensor with Pt/SnO2 as 452a Catalytic GateKim. C. K.1: Lee, J. H.1; Lee, J. H.1; Noh, I. L.1; Jang, S. W.1; Lee, E. S.1; Lee, B. W.1;Yang, S. J.1; Cho, N. I.2; Yoo, H. J.1; Yoo, K. S.3; Kee, C. J.4 (Soonchunhyang University,2Sunmoon University, 3University of Seoul, 4Seoul Information Tech. University, Korea)

[2P036] NO2 Gas Sensing Characteristics of Carbon Nanotube Gas Sensor 454Fabricated by DielectrophoresisSuehiro. J.: Zhou, G.; Hara, M. (Kyushu University, Japan)

[2P037] Influence of NH4H2PO4 on Properties of the SnO2 Based CO Sensor 456Liu, F; Quan. B.: Chen, L.; Liu, Z. (Jilin University, China)

[2P038] Improvement of Gas-Sensing Properties of SnO2 by Surface Thiourea 458ModificationLiu, Z.; Quan. B.: Liu, F; Chen, L. (Jilin University, China)

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[2P039] The Sensing Behaviors of SnO2-Based Thick-Film Gas Sensors at a Low 460Concentration of Chemical Agent SimulantsLee. W. S.: Lee, S. C; Lee, P.-P.; Huh, J. S.; Kim, J. C. (Kyungpook National University,Korea)

[2P040] MOS-Type Odor Sensor System for Early Fire Detection and Its Application 462to Utility Mobile RobotTakei. Y.1: Tashiro, T.1; Kubota, N.1; Kasahara, H.2; Iwasaki, S.3; Nanto, H.1 (KanazawaInstitute of Technology, 2New Cosmos Electric. Co., Ltd., 3tmsuk Co., Ltd., Japan)

[2P042] Monitoring of Environmental Odours by an Electronic Nose: Waste Water 464Treatment Plant and Rubbish Dump, Three Case StudyPennazza. G.1: Pi Natale, C.12; Valenti, A.1; Martinelli, E.1; Paolesse, R.12; Macagnano,A.2; P'Amico, A.12 (University of Rome "Tor Vergata", 2CNR-IMM, Italy)

[2P043] Classification of Chemical Warfare Agent Gases Using a Thick Film Gas 466Sensor ArrayChoi. N. J.: Kwak, J. H.; Lim, Y. T; Ban, T. H.; Yun, K. Y; Lee, W. S.; Kim, J. C; Huh, J.S.; Lee, P.-P. (Kyungpook National University, Korea)

[2P044] An Alcohol Gas-Sensor Using An Enzyme Immobilized Paper 468Akahori. Y.1: Yamazaki, H.1; Nishio, G.2; Matsunaga, H.2; Mitsubayashi, K.3 (Nikkiso Co.,Ltd., 2Tokai University, 3Tokyo Medical and Dental University, Japan)

[2P045] Portable Electronic Nose System Based on the Carbon Black-Polymer 470Composite Sensor ArrayKim. Y. S.: Ha, S.-C; Yang, Y; Kim, Y. J.; Cho, S.-M.; Yang, H.; Kim, Y T. (Electronicsand Telecommunications Research Institute, Korea)

[2P046] Novel All-Solid-State Calcium-Selective Electrode with Conducting Polymer 472Layer for Low-Level Concentration MeasurementsKonopka. A.1: Sokalski, T.2; Michalska, A.1; Lewenstam, A.2; Maj-Zurawska, M.1

(Warsaw University, Poland, 2Abo Akadem University, Finland)

[2P047] Study on the Light Behaviour and Temperature Properties for the AIN pH- 474ISFETChiang, J.-L.1; Chou. J.-C.2: Chen, Y.-C.3 (Chung Chou Institute of Technology, 2NationalYunlin University of Science and Technology, 3National Sun Yat-Sen University, Taiwan)

[2P048] Calcium Ion Selective Electrode under Galvanostatic Current Control 476Bedlechowicz. I.1: Sokalski, T.2; Lewenstam, A.2; Maj-Zurawska, M.1 (Warsaw University,Poland, 2Abo Akademi University, Finland)

[2P049] Electronic Tongue for Environmental Detection 478Men, H.; Liu, P.; Zou, S.; Fang, F; Ye, X.; Wang. P. (Zhejiang University, China)

[2P050] Sensing Beverage Tastes from Organic Acids Separated by Capillary 480Electrophoresis and Assessed by Pattern RecognitionFung. Y.-S.1: Gong, F12.; You, T.-Y.1 (University of Hong Kong, 2Central South University,China)

[2P052] Naked Eye Detection of F" Anion with Luminescent Europium Complexes 482Tsukube, H.; Onimaru. A.: Shinoda, S. (Osaka City University, Japan)

[2P053] Tuning of Anion Luminescence Sensing via Ligand Architecture of 484Lanthanide ComplexesKataoka. Y.: Shinoda, S.; Miyake, H.; Tsukube, H. (Osaka City University, Japan)

[2P054] Disposable Taste Biosensor 486Gotoh. M. (Tokyo University of Technology, Japan)

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[2P055] Rapid Detection of E. coli 0-157 Verotoxin: Convenient Use of Gb2- 488Embedded Anionic Polymer for an SPR Sensor SystemUzawa. H.: Ito, H.; Taguchi, K.; Zeng, X.; Minoura, N. (AIST, Japan)

[2P056] Molecular Design of a PMP Complex and Its Application for Molecular 490Transducer on Cellular NO SensingAsakawa. H,: Ikeno, S.; Haruyama, T. (Kyushu Institute of Technology, Japan)

[2P057] Preparation of Amperometric Glucose Sensor Based on Electrochemically 492Polymerized Films of Indole DerivativesYabuki. S.: Mizutani, F. (AIST, Japan)

[2P058] Molecularly Imprinted Polymer for Recognizing Double-Stranded DNA 494Ogiso. M.: Slinchenko, O.; Rachkov, A.; Miyachi, H.; Minoura, N. (AIST, Japan)

[2P059] Sugar Sensitive Thin Films Based on Concanavalin A and Sugar Polymers 496Sato. K.: Odagiri, T; Sugama, J.; Imoto, Y; Anzai, J. (Tohoku University, Japan)

[2P060] Three-Dimensional Micro-Culture System with a Silicon Based Cell Array 498Device for Multi-Channel Drug Sensitivity TestTorisawa. Y.: Shiku, H.; Yasukawa, T; Nishizawa, M.; Matsue, T. (Tohoku University,Japan)

[2P061] Piezoelectric Quartz Crystal (PQC) with Photochemically Deposited Nano- 500Sized Ag Particles for Determining Cyanide at Trace Levels in WaterSun. H.12: Si, S. H.1; Zhang, Y Y1; Zhu, P. R.1; Fung, Y. S.1 (University of Hong Kong,2Anshan Normal College, China)

[2P062] Ammonia Biosensor with Flavin-Containing Monooxygenase 502Nakakura. S.1: Saito, H.2; Kaneko, Y.1; Hashimoto, Y1; Mitsubayashi, K.2 (TokaiUniversity, 2Tokyo Medical and Dental University, Japan)

[2P063] Conducting Organic Langmuir-Blodgett Films as Chemical Sensors 504Watanabe. N.1: Ohnuki, H.2; Saiki, T.2; Endo, H.2; Izumi, M.2; Imakubo, T.3 (Oki ElectricIndustry Co., Ltd., 2Tokyo University of Marine Science and Technology, 3RIKEN, Japan)

[2P065] Application of Polymaleimidestylene Blended Polystylene Membrane to 506Biosensor TechnologyUchiyama, S.; Sekioka. N.: Imaizumi, E. (Saitama Institute of Technology, Japan)

[2P067] Bioelectronic Sniffer Devices for Measurements of Breath Alcohol and 508Acetaldehyde after DrinkingNishio. G.1: Ogawa, M.2; Matsunaga, H.1; Mitsubayashi, K.2 (Tokai University, 2TokyoMedical and Dental University, Japan)

[2P068] Taguchi Approach to Design Optimization for Nickel Coated Protein Chip 510Hu. C.-Y1: Tsao, C.-Y2; Chang, C.-H.1; Tsao, J.-H.2; Chiu, S.-F.2; Yin, L.-T.2; Chang, Y-J.1 (Chung Yuan Christian University, 2lndustrial Technology Research Institute Hsinchu,Taiwan)

[2P069] Amperometric DNA Sensor Using Gold Electrode Modified with Polymeric 512Mediator by Layer-by-Layer AdsorptionSuve. S.1: Kimura, T.1; Zheng, H.1; Hori, T.1; Amano, Y2; Katayama, H.2 (University ofFukui, 2Daikin Environmental Laboratory, Ltd., Japan)

[2P071] Two-Dimensional Surface Plasmon Resonance (2DSPR): A Comparative 514Study as a Parallel Detection Technique for Protein Binding onto DNAMicroarraysOtsuki. S.: Yamada, H.; Iwahashi, H.; Tamada, K. (AIST, Japan)

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[2P073] The Merits/Demerits of Biochemical Reaction Measurements by SPR 516Reflectance Signal at a Fixed AngleNakagawa. H.1: Saito, I.1; Chinzei, T.1; Nakaoki, Y.2; Iwata, Y2 (The University of Tokyo,2Aisin Cosmos R & D Co., Ltd., Japan)

[2P074] Application of Microbial Chip for Amperometric Detection of Metabolic 518Alteration in BacteriaNagamine. K: Kaya, T; Yasukawa, T; Shiku, H.; Matsue, T. (Tohoku University, Japan)

[2P075] Amperometric Xanthine Sensors Based on Polyelectrolyte Multilayer Films 520Hoshi. T.: Noguchi, T; Anzai, J. (Tohoku University, Japan)

[2P076] Enhanced Surface Plasmon Resonance Sensing of Endocrine Disruptors on 522Renewable Biosensing ProbesGobi. K. V.1'2: Kataoka, C.3; Miura, N.1 (Kyushu University, 2Japan Society for thePromotion of Science, 3Kyoto Electronics Manufacturing, Japan)

[2P077] A Porous Membrane-Based Culture Substrate for Evaluating Chemical and 524Electrical Local Stimulation on Cell SheetsTakoh. K: Matsue, T; Nishizawa, M. (Tohoku University, Japan)

[2P078] Development of Bio-Chip Nanoarrays by Using Random Fluidic Self- 526Assembly MethodJuno. K.-H.1: Kim, P.-K.2; Shin, H.-K; Kwon, Y.-S.1 (Dong-A University, Korea, 2AIST,Japan)

[2P079] Development of Ion-Channel Sensors for Detection of Oligonucleotides 528Aoki. H.1: Umezawa, Y2; Tao, H.1 (AIST, 2The University of Tokyo, Japan)

[2P080] Study on Signal Acquisition and Processing for SPR Biosensors 530Wang. P.: Liu, J.; Yu, X.; Peng, Y. (Tsinghua University, China)

[2P082] Optical Sensing of UV Irradiation by Polysaccharide Film Using Dye and Acid 532GeneratorTakato. K.12: Kaburagi, Y1; Tokita, S.3; Kaneko, M.1 (Ibaraki University, 2Tokyo KaseiGakuin Tsukuba Junior College, 3Saitama University, Japan)

[2P083] Optical Ozone Sensing Properties of Poly(2-Chloroaniline) and Poly(n- 534Methylaniline) FilmsAndo. M.1: Swart, C.2; Pringsheim, E.2; Mirsky, V. M.2; Wolfbeis, O. S.2 (AIST, Japan,2University of Regensburg, Germany)

[2P084] Development of Optical Waveguide SPR Sensor with Dual LEDs for 536Chemical and Biochemical ApplicationsSuzuki, A.1; Matsui, Y.1; Kondoh. J.1: Shiokawa, S.2; Kubota, H.3 (Shizuoka University,2A&R Center for Surface Wave Technology, 3Medical & Biological Laboratories Co., Ltd.,Japan)

[2P085] Optical Fiber Sensors Based on Vapochromic Gold Complexes for 538Environmental ApplicationsBariain, C.1; Matias. I. R.1: Fernandez-Valdivielso, C.1; Elosua, C.1; Luquin, A.1; Garrido,J.1; Laguna, M.2 (Universidad Publica de Navarra, 2Universidad de Zaragoza, Spain)

[2P086] Detection of Buthylamine as a Malodorous Substance by Means of Surface 540Plasmon ResonanceArakawa. T.: Kawabayashi, A.; Saga, T. (Kinki University, Japan)

[2P087] SPR Observation of Adsorption and Desorption of Water-Soluble Polymers 542on an Au SurfaceToyama. S.: Aoki, K.; Kato, S. (National Rehabilitation Center for the Disabled, Japan)

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[2P088] Optical Oxygen Sensing Based on the Stationary State Quenching of Triplet- 544Triplet Absorption.Kamachi. T.: Mochizuki, K; Asakura, N.; Okura, I. (Tokyo Institute of Technology, Japan)

[2P089] On Exploring Sol-Gel Deposited ZnO Thin Film as Humidity Sensor: An 546Optical Fiber ApproachShukla. S. K.1: Parashar, G. K.1; Mishra, A. P.2; Misra, P.3; Yadav, B. C.3; Shukla, R. K.3;Srivastava, A.; Srivastava, A.; Deva, F; Pubey, G. C.4 (University of Delhi, 2TechnologyBhawan, 3University of Lucknow, "Solid State Physics Laboratory, India)

[2P090] The PFC Detection Based on an Amperometic HF Sensor with Pyrolysis 548Hirota, T.1; Komiya. H.1: Van der Kruk, P.2; Satoh, I.3 (Bionics Instrument Co., Ltd.,Japan, 2Bionics Instrument Europe B.V., The Netherlands, 3Kanagawa Institute ofTechnology, Japan)

[2P091] Supervision of Rinses in a Washing Machine by a Voltammetric Electronic 550TongueIvarsson. P.12: Johansson, M.2; Hojer, N.-E.2; Krantz-Rulcker, C.1; Winquist, F.1;Lundstrom, I.1 (Linkoping University, 2Asko Cylinda AB, Sweden)

[2P093] CAT Imprinted Polymer and Its Application to the Electrochemical 552Determination of CATShoji, R.1; Shimizu, A.1; Suzuki, H.2; Kubo. I.1 (Soka University, 2University of Tsukuba,Japan)

[2P094] Miniaturized Flow-Through Cell with Integrated Capacitive EIS Sensors 554Fabricated at Wafer Level Using Si and SU-8 TechnologiesSchoning, M. J.12; Nather, N.123; Auger, V.3; Poghossian, A.2; Koudelka-Hep. M.3

(University of Applied Sciences Aachen,2 Institute of Thin Films and Interface, Germany,3University of Neufchatel, Switzerland)

[2P096] Miniature Ion-Selective Electrodes 556Paciorek, R. Maj-Zurawska. M.: (Warsaw University, Poland)

[2P097] Structure and Properties of RF-Sputtered AIN Films on Y-1280 LiNbO3 558SubstratesWang. C.-H.1: Cheng, C.-C.2 (Nan-Jeon Institute of Technology, 2National Cheng KungUniversity, Taiwan)

[2P098] Study on Thermal Distribution Microfluidic Sensor Based on Silicon 560Weiping. Y.: Wenzhu, X.; Jianhua, L.; Liqun, P.; Pefang, N. (Dalian University ofTechnology, China)

[2P099] Micro Optical pH and Oxygen Sensor Array for Cell Chips 562Suzuki. M.: Nakabayashi, H.; Honda, M. (Toyama University, Japan)

[2P100] Layered SAW Hydrogen Sensor with Modified Tungsten Trioxide Selective 564LayerIppolito. S. J.12: Kandasamy, S.1; Kalantar-zadeh, K.1'2; Wlodarski, W.12 (RMITUniversity, 2CRC for Microtechnology, Australia)

[2P101] Amperometric PDMS-Glass Capillary Electrophoresis-Based Biosensor 566Microchip for Catechol and Dopamine DetectionSchonino. M. J.12: Wang, J.3; Jacobs, M.123; Knobbe, P.-T.1'2; Muck, A.3 (University ofApplied Sciences Aachen, 2lnstitute of Thin Films and Interfaces, Germany, 3NewMexico State University, USA)

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[2P102] Integration of Micropatterned Cell Culture into MicroChannel Using 568Electrochemical ReactionKaji. H.1: Matsue, T.1; Nishizawa, M.2 (Graduate School of Environmental Studies,2Tohoku University, Japan)

[2P103] Poly(dimethylsiloxane)-Based Sandwich Microchip for DNA Electrophoresis 570Liu, C; Cui. P.: Cai, H.; Wang, L.; Su, B. (Chinese Academy of Sciences, China)

[2P104] Improvement on Organic Compound Adsorption and/or Detection by Using 572Metallic Thin Films Deposited onto Highly-Rough Silicon SubstratesT. Carvalho, A.; P. da Silva, M. L.; G Santos Filho, S.; Nascimento Filho. A. P.: P. Jesus,P. (Escola Politecnica da Universidade de Sao Paulo-USP, Brasil)

[2P105] PCR Chip Based on Silicon for DNA Amplification 574Weiping. Y.: Linfzhi, M.; Jing, W.; Liqun, P.; Pazhen, L. (Dalian University of Technology,China)

[2P106] Micro Analysis System for Ammonia, Creatinine, and Urea Using Air-Gap 576Ammonia ElectrodesSuzuki. H.: Matsugi, Y. (University of Tsukuba, Japan)

[2P107] Miniaturized Sensing System with a Modular Structure for on-line Monitoring 578of pO2, pCO2, and pHKojima. S.: Suzuki, H. (University of Tsukuba, Japan)

[2P108] Modifications of the Catalytic Gate Material to Increase the Long-Term 580Stability of MISiC-FET Lambda SensorsWingbrant. H.: Lunden, M.; Lloyd Spetz, A. (Linkoping University, Sweden)

[2P109] Piezoelectric Membranes Used as Resonators for Mass Detection of Gold 582Colloids Adsorption at a Solid/Liquid InterfaceGuirardel, M.1; Nicu, L.1; Saya, P.1; Tauran, Y1; Soyer, C.2; Cattan, E.2; Berqaud. C.3

(LAAS-CNRS, 2IEMN-CNRSIDOAE, France, 3LIMMS/CNRS-IIS, Japan)

[2P110] Development of the Real-Time Sensing System for Array Sensors 584Pan, C.-W.1; Chou. J.-C.2: Sun, T.-P.3; Hsiung, S.-K.1 (Chung Yuan Christian University,2National Yunlin University of Science and Technology, 3National Chi Nan University,Taiwan)

[2P111] Study on the Hysteresis of the Metal Oxide pH Electrode 586Tsai, C.-N.1; Chou. J.-C.2: Sun, T.-P.3; Hsiung, S.-K.1 (Chung Yuan Christian University,2National Yunlin University of Science and Technology, 3National Chi Nan University,Taiwan)

[2P112] Complex Impedance Analysis of Ga2O3 Based MRISiC Gas Sensors 588Trinchi, A.1; Wlodarki. W.1: Li, Y1; Faglia, G.2; Sberveglieri, G.2 (RMIT University,Australia, 2University of Brescia, Italy)

[2P113] Construction and Performance of Al-Doped Tin Black Filter Based on SnO2 590Gas SensorLee. Y.-S.1: Kwon, O.-S.1; Rue, G.-H.1; Hong, Y.-H.2; Lee, P.-P.1 (Kyungpook NationalUniversity, 2Kyungwoon University, Korea)

[2P114] Study of Electrical Properties for BaTiO3 PTCR as Gas Chemical Sensors 592Using Impedance MethodsZhou. Z.-G.: Tang, Z.-L.; Zhang, Z.-T. (Tsinghua University, China)

[2P115] LixMo(i.y)WyO3 Bronzes as Electrochemical Sensors 594Gabel. J.: Vonau, W.; Guth, U. (Kurt-Schwabe-lnstitute for Measuring and SensorTechnology e.V. Meinsberg, Germany)

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[2P116] Water Purification Through Bioconversion of Phenol Compounds by 596Tyrosinase and Chemical Adsorption by ChitosanYamada. K: Akiba, Y; Hirata, M. (Nihon University, Japan)

[2P117] Polypyrrole/MoO3 Nanohybrid Thin Films for VOC Gas Sensors 598Hosono. K.: Matsubara, I.; Murayama, N.; Shin, W.; Izu, N. (AIST, Japan)

[2P118] Conductometric p-Type Perovskite Sensor Thin-Films with Nanostructured 600Morphology Deposited by Pulsed Laser DepositionTunney. J. J.1: Post, M. L.1; Pu, X.1; Koshizaki, N.2; Sasaki, T.2; Wang, Z.2 (NationalResearch Council of Canada, Canada, 2AIST, Japan)

[2P119] QCM Humidity Sensor Using an Anodized Alumina Thin-Film 602Hara. K. (Tokyo Denki University, Japan)

[2P120] Production of Adsorbent Films and Deposition on Low Cost Micromachined 604Non-Planar Microchannels for Preconcentration of Organic Compound in AirLima, R. R.1; Carvalho, R. A. M.2; Nascimento Filho. A. P.2: P. Silva, M. L.2; R.Pemarquette, N.3 (Universidade de Sao Paulo, 2PSI, 3PMT, Brazil)

[2P121] Humidity Sensing Properties of CNX Film by RF Magnetron Sputtering 606Lee. J. G.: Lee, S. P. (Kyungnam University, Korea)

[2P122] A High Sensitivity Nitric Dioxide Sensor Based on MCM-41 Incorporation of 608TinYuliarto. B.12: Zhou, H. S.1; Honma, I.1; Katsumura, Y.2 (AIST, 2The University of Tokyo,Japan)

[2P123] Hydrogen Sensing by NKN Thin Film with High Dielectric Constant and Ferro- 610Electric PropertyNakagomi. S.1: Wingqvist, G.2; Abom, A. E.3; Helmersson, U.3; Spetz, A. L.3 (IshinomakiSenshu University, Japan, 2UppSala University, 3Link6ping University, Sweden)

[2P124] Multi-Sensor Technique and Solid-State Electrochemical Sensor System for 612Real-Time and Dynamic Monitoring of Multi-Component GasesZhou. Z.-B.1: He, B.-S.1; Feng, L.-P.2; Cai, N.-C.1 (Wuhan University, 2Huaiyin Instituteof Technology, China)

[2P125] Monitoring of Proteins on Biosensor Surface by Means of TOF-SIMS 614Aoyagi. S.: Kudo, M. (Seikei University, Japan)

[2P126] A Novel Sensing System for Endocrine Disrupting Chemicals (EDCs) Based 616on Their Hydrophobic Interaction with Model Cell MembranesNakane. Y.: Kubo, I. (Soka University, Japan)

[2P127] Fluorescence Resonance Energy Transfer by a -Helical Coiled Coil 618Polypeptides in Response to Metal IonsKashiwada. A.: Nakamura, Y; Matsuda, K. (Nihon University, Japan)

[2P128] A Biochemo-Mechanical Sensor with Active Transportation for Hydrogen 620PeroxideOkamoto. T.1: Wakabayashi, Y.1; Mitsubayashi, K.2 (Tokai University, 2Tokyo Medical andDental University, Japan)

[2P129] Magnetic Detection of Biotin-Streptavidin Interactions Using Magnetic 622Nanoparticles and Organosilane Monolayer Modified SubstrateArakaki. A.1: Hideshima, S.1; Nakagawa, T.2; Niwa, P.1; Tanaka, T.2; Matsunaga, T.2;Osaka, T.1 (Waseda University, 2Tokyo University of Agriculture and Technology, Japan)

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[2P130] Development of a Biosensor by Employing Fluorescent Quantum Dots for 624Immuno-Assay SingnalHuano. C.-P.1: Liu, H.-W.1; Tsao, C.-Y.2; Yin, L.-T.2; Chiu, S.-F.2; Chen, T.-M1 (NationalChiao Tung University, 2lndustrial Technology Research Institute, Taiwan)

[2P131] Micro and Nanoscale Patterns of Organosilane Monolayer Templates for 626Applying to on-chip Ion and Biomolecule SensingOmichi. K.: Niwa, P.; Motohashi, N.; Homma, T; Osaka, T. (Waseda University, Japan)

[2P132] Determination of Thiabendazole on the Basis of Electrochemiluminescence 628Generated from the Reaction with Ruthenium ComplexEgashira. N.: Mitoma, Y; Shimizu, K.; Uda, T. (Hiroshima Prefectural University, Japan)

[2P133] Study on the Metal Oxide pH Sensor Using Thick Film Technology 630Hung, C.-S.1; Chou. J.-C.2: Sun, T.-P.3; Hsiung, S.-K.1 (Chung Yuan Christian University,2National Yunlin University of Science and Technology, 3National Chi Nan University,Taiwan)

[2P134] Fabrication of Clinical Gas Sensor Using MEMS Process 632Lee. Y.-S.1: Song, K.-P.1; Choi, N.-J.1; Huh, J.-S.1; Chung, W.-Y2; Lee, P.-P.1

(Kyungpook National University, 2Dongseo University, Korea)

[2P135] Surface Acoustic Wave Chemical Sensor Using Ultrathin Multilayer Films 634Nomura. T.1: Saitoh, A.1; Furukawa, S.2 (Shibaura Institute of Technology, 2KyushuInstitute of Technology, Japan)

[2P136] BP Algorithm Design and Simulation of Gas Sensor Arrays 636Xie, G.; Tai, H.; Wang, T; Xu, J.; Jiang. Y.: Ye, Y; Zeng, H.; Yang, B. (University ofElectronic Science & Technology of China, China)

[2P137] A Multi-Parameter Biochemical Sensor with a Linear Readout Circuit 638Liao, H.-C.1; Sun. T.-P.2: Chen, C.-Y.2; Chou, J.-C.3; Hsiung, S.-K.1 (Chung YuanChristian University, 2National Chi Nan University, 3National Yunlin University of Scienceand Technology, Taiwan)

[2P138] A Novel Li+Sensor Based on LiNbO3 Membrane 640Feng, C.-L.; Xu, H.; Li, Y. (Liaoning Normal University, China)

[2P139] Preparation and Conductivity of Tungstovanadogermanic Heteropoly Acid 642Supported on Mesoporous Silicates MCM-41 or MCM-48Wu. Q.1: Jin, H.1; Wu, C.1; Pang, W.12 (Zhejiang University, 2Jilin University, China)

[2P140] Preparation and Properties of Enzyme Micro Sensors 644Takaoka. H.2: Shimizu, T.1; Imai, S.1; Furukawa, S.2; Yasuzawa, M.2 (Toyo PrecisionParts MFG. Co., Ltd., 2The University of Tokushima, Japan)

[3P001] Highly Sensitive SnO2-Based Gas Sensor for Indoor Air Quality Monitoring 646Shi. L.1: Hasegawa, Y.1; Katsube, T.1; Kaneko, T.2, Nakano, M.2; Nakamura, K.2 (SaitamaUniversity, 2Uchiya Thermostat Co., Ltd, Japan)

[3P002] Characteristics of HC Sensor Using Pr6On Electrode 648Inaba. T.: Masuoka, Y; Saji, K.; Sakata, J. (Toyota Central R & D Labs. Inc., Japan)

[3P003] Thin-Film Limiting-Current Type NOX Sensor 650Sa|i. K.: Inaba, T; Sakata, J. (Toyota Central Research and Development Laboratories,Inc., Japan)

[3P004] Hydrogen Sensing Characteristics of WO3 Thin Film Conductometric Sensors 652Activated by Pt and Au CatalystsIppolito, S. J.12; Kandasamy, S.1; Kalantar-zadeh, K.12; Wlodarski. W.12 (RMITUniversity, 2CRC for MicroTechnology, Australia)

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[3P005] Plasma Polymerized TEOS Films for Nanochannels Formation and Sensor 654Development.Carvalho, R. A. M.1; Lima, R. R.2; Nascimento Filho. A. P.1: Silva, M. L. P.1; Pemarquette,N. R.1 (Escola Politecnica da Universidade de Sao Paulo, 2Institute de Fisica daUniversidade de Sao Paulo, Brazil)

[3P006] Nano-Grained Thin-Film Indium Tin Oxide Gas Sensors for H2 Detection 656Park, S. H.1; Kang, J. H.1; Yoo. K. S.1: Kim, C. K.2 (University of Seoul, 2SoonchunhyangUniversity, Korea)

[3P007] Correlation between Gas Sensing Properties and Surface Structures of the 658Sputtered Tin Oxde Thin FilmsChoi. G.-P.: Park, Y.-J.; Ryu, H.-W.; Park, J. (Chosun University, Korea)

[3P008] NH3 Gas Sensing Characteristics and Heating Effects of Single-Walled 660Carbon NanotubesYun. K.-H.: Lee, S.-T; Quang, N.-H.; Trinh, M.-V; Huh, J.-S. (Kyungpook NationalUniversity, Korea)

[3P009] Characteristics of Thin Polyisobutylene SAW Sensor for Different Operating 662Frequencies.Huh. Y.-H.: Joo, B.-S.; Lee, E.-W.; Lee, J.-H.; Lee, Y.-S.; Huh, J.-S.; Lee, P.-P.(Kyungpook National University, Korea)

[3P010] Sensing Properties of ZnO doped SnO2 Thick Films with DPGME 664Yun. K.-Y: Baek, W.-W.; Choi, N.-J.; Lee, P.-P.; Kim, J.-C; Huh, J.-S. (KyungpookNational University, Korea)

[3P011] Characteristic of Thick Film Sensor CH3CN Detection by ln2O3 Added SnO2 666Kwak. J. H.: Choi, N. J.; Bahn, T. H.; Lim, Y T; Huh, J. S.; Kim, J. C; Lee, P.-P.(Kyungpook National University, Korea)

[3P012] Sensing Properties of ZrO2-Added SnO2 for Nerve Gas and Posgene 668SimulantYun. K.-Y: Baek, W.-W.; Choi, N.-J.; Lee, P.-P.; Kim, J.-C; Huh, J.-S. (KyungpookNational University, Korea)

[3P013] Toxic Gas Response Properties of Thin Film Sensors Based on SnO2 670Bahn. T. H.: Choi, N.-J.; Kwak, J.-H.; Lim, Y.-T; Kim, J.-C; Huh, J.-S.; Lee, P.-P.(Kyungpook National University, Korea)

[3P014] The QCM Type Aldehyde Sensor 672Naganawa. R.1: Hirayama, K.2; Noda, K.1; Kurosawa, S.1; Tao, H.1 (AIST, 2EhimePrefectural Government, Japan)

[3P015] Ozone, NO2 and VOCs Detection with SmFeO3 Based Gas Sensor 674Itagaki, Y; Hosoya. Y.: Aono, H.; Sadaoka, Y (Ehime University, Japan)

[3P016] Characteristics of Polyaniline Sensor Coated with Poly(Vinylidenefluoride) 676Layer for Volatile Organic CompoundsKim. J.-S.: Cho, J.-H.; Han, Y.-A.; Sohn, S.-O.; Huh, J.-S. (Kyungpook NationalUniversity, Korea)

[3P017] Identification with a Four Sensor Array Using Pattern Classification 678Kim. J.-S.: Hoh, Y.-S.; Cho, J.-H.; Sohn, S.-O.; Huh, J.-S. (Kyungpook NationalUniversity, Korea)

[3P018] Fabrication and Characteristics of Sensor Arrays for Atmospheric 680Environment GasCha, G.-Y; Lee, S.-T; Huh, J.-S. (Kyungpook National University, Korea)

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[3P019] Piezoelectric Methane Sensors: AT-Cut Quartz Resonators with Polyethylene 682Glycol 400 FilmsWang. C.-H. (Nan-Jeon Institute of Technology, Taiwan)

[3P020] Analysis of Diabetic Patient's Breathe Using Conducting Polymer Sensor 684ArrayYu. J.-B.: Lee, K.-M.; Byun, H.-G.; Huh, J.-S. (Kyungpook National University, Korea)

[3P021] Gas Sensors Based on MIS Diodes 686Gaman, V. I.; Baljuba, V. I.; Gritsyk. V. Y: Pavidova, T. A.; Kalygina, V. M.; Khludkova,L. S. (Tomsk State University, Russia)

[3P022] Peculiarities of Response to CH4 and H2 of Pt/SnO2:Sb Thin Films 688Anisimov. O. V.1: Maksimova, N. K.1; Chernikov, E. V.1; Masalov, S. M.2 (SiberianPhysical Technical Institute, 2 Tomsk State University, Russia)

[3P024] Preparation and Properties of Langmuir-Blodgett Fims Based on Bis [octakis 690(octyloxy) phthalocyaninto] ComplexJiang. Y.: Xie, G.; Wang, T; Wu, Z. (University of Electronic Science and Technology,China)

[3P025] Research of CO2 Sensor with New Structure 692Liu, X.; Quan. B.: He, Y; Wu, Y; Chen, L. (Jilin University, China)

[3P026] Hydrogen Sensitive Micro Sensor of Nano-Crystalline F-Doped SnO2 Using 694MEMS TechnologyHan. C.-H.1: Kim, I.-J.2; Lee, W.-B.2; Han, S.-P.1 (Korea Institute of Energy Research,2Seju Engineering, Koea)

[3P028] Wide Range Gas-Flow Sensor with Multi-Step Temperature Sensing 696ElementsChung. W.-Y (Dongseo University, Korea)

[3P029] Nanoporous TiO2 Film as Coating for Piezoelectric Crystal Sensor in the 698Detection of Organic Vapors in AirFung, Y S.1; Si. S. H.12: Zhu, P. R.1; Sun, H.1 (The University of Hong Kong, 2CentralSouth University, China)

[3P030] Impedancemetric Zirconia-Based Sensor Using Oxide Sensing-Electrode for 700Detecting Water Vapor in Low Concentration RangeNakatou. M.: Miura, N. (Kyushu University, Japan)

[3P031] Influence of Thickness of Oxide Electrode on Sensing Performances of 702Mixed-Potential-Type and Impedancemetric NOX SensorsKoga. T.: Nakatou, M.; Elumalai, P.; Miura, N. (Kyushu University, Japan)

[3P032] Gas Sensing Properties of Poly 3-Hexylthiophene Thin Film Transistors 704Yamagishi. Y.: Ise, M.; Takano, N.; Fukuda, H. (Muroran Institute of Technology, Japan)

[3P033] A Semiconductor Micro Gas Sensor with Improved Gas Selectivity Using 706Electric FieldTakeda, R.; Hara. K. (Tokyo Denki University, Japan)

[3P034] The Sensitivity and Selectivity Analyses of SnO2 and CeO2/SnO2 Gas 708Sensors to Ethanol in the Presence of CO, LPG and CH4

Pourfayaz, F; Khodadadi, A.; Mortazavi. Y.: Mohajerzadeh, S. S. (University of Tehran,Iran)

[3P035] Methane Detection Using Palladium Doped Single-Walled Carbon Nanotube 710SensorsLi. J.: Lu, Y; Ng, H. T; Han, J.; Meyyappan, M. (NASA Ames Research Center, USA)

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[3P037] Gas Sensing Properties of SnO2 Pellet; Surface Modified by Laser Ablated 712CUInamdar, A. P.1; Ansari. S. G.2: Aiyer, R. C.1 (University of Pune, India, 2School ofMaterials Science, JAIST, Japan)

[3P038] Porous Nano-Crystalline Tungsten Oxide Based NO2 Sensor 714Wang. S.-H.1: Chou, T.-C2; Liu, C.-C3 (l-Shou University, 2National Cheng KungUniversity, Taiwan, 3Case Western Reserved University, USA)

[3P039] Structure and Mass Spectrometry Study of Nanometer Sn-a-Fe2O3 Carbon 716Monoxide Sensor MaterialsQin. H.1: Chen, G.2; Bao, J.1 (Hangzhou Institute of Electronic Engineering, 2SichuanPedagogic University, China)

[3P041] A Novel Electronic Nose for Detection of Lung Cancer 718Chen, X.; Cao, M.; Yu, H.; Li, Y; Wang. P. (Zhejiang University, China)

[3P042] Study on the Chloride Ion Selective Electrode Based on the SnO2/ITO Glass 720and Double-Layer Sensor StructureCheng, J.-F.1; Chou. J.-C.2: Sun, T.-P3; Hsiung, S.-K.1 (Chung Yuan Christian University,2National Yunlin University of Science and Technology,3National Chi Nan University, Taiwan)

[3P043] Study of the Humidity Sensor Based on Various Poly(Vinyl Acetate) 722Yu, C.-H.1; Chou. J.-C2: Sun, T.-P.3; Hsiung, S.-K.1 (Chung Yuan Christian University,2National Yunlin University of Science and Technology,3National Chi Nan University, Taiwan)

[3P044] Percussion Probe Equipped with the Karlsruhe Micronose KAMINA for Rapid 724Online Soil Analysis of Volatile PollutantsArnold, C; Kochbeck, M.; Goschnick. J.: (Forschungszentrum Karlsruhe, Germany)

[3P045] Samarium (III) Selective Membrane Sensor Based On Tin (IV) Boratophosphate 726Mittal. S. K: Sharma, H. K; Kumar, A. S. K. (Deemed University, India)

[3P046] Ion-Selective Microelectrode Array Platform for Recording of Calcium Ion 728ActivitiesGuenat, O.1; Pufour, J.-F.2; Berdondini. L1: Morf, W.1; Pe Rooij, N. F.1; Van Per War, P. P.1;Koudelka-Hep, M.1 (University of Neuchatel, 2University of Bern, Switzerland)

[3P047] Manufacture and Characterization of an ISFET-Probe for Deep-Sea pH 730MeasurementsFujii. T.1: Van Per Wai, P.2; Kyo, M.3; Shitashima, K.4; de Rooij, N.2 (University of Tokyo,Japan, 2University of NeuchStel, Switzerland, 3Japan Agency for Marine-Earth Scienceand Technology, 4Central Research Institute of Electric Power Industry, Japan)

Effect of Mg2+-Dopant on the Characteristics of Lead Titanate SensingMembrane for Ion-Sensitive Field-Effect TransistorsChen. Y.-C1: Jan, S.-S.2; Chou, J.-C3 (National Sun Yat-Sen University, 2Ling TungCollege, 3National Yunlin University of Science and Technology, Taiwan)

Study on the Disposable Potentiometric Biosensor for CreatinineDetermination Based on PVC-COOH Membrane Ammonium Ion-SelectiveElectrodeChou, N.-H.1; Sun. T.-P.2: Chou, J.-C.3; Hsiung, S.-K.1 (Chung Yuan Christian University,2National Chi Nan University, 3National Yunlin University of Science and Technology,Taiwan)

[3P050] Miniaturized Fluorescence Detection System to Remove Background Noise 736of the Incident Light Using Micro Mirror and LensJang, J. M.1; Kano. J. Y1: Lee, J.-H.1; Hwang, S. W.2; Yang, E. G.1; Yoon, P. S.1; Kim, T.S.1 (Korea Institute of Science and Technology, 2Korea University, Korea)

[3P048]

[3P049]

732

734

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[3P052] Formation of lonassotiation Metal Complexes with Neutral lonophores and 738Lipophilic Compounds and Analytical Characteristics of Corresponding ISEsPetrukhin. O. M.1: Schipulo, E. V.1; Kurachenkova, S. N.1; Yakshin, V. V.2 (D. MendeleyevUniversity of Chemical Technology of Russia,2All Russian Research Institite of ChemicalTechnology, Russia)

[3P053] Evaluation of the MOSFET Type Hybrid Biosensor 740Hirano. Y.: Ooe, K.; Hamamoto, Y; Matsuda, R.; Koike, K.; Sasa, S. (Osaka Institute ofTechnology, Japan)

[3P054] Frequency Stability by the Communication Technique for Biosensors 742Koyama. M.1: Akaike, K.1; Aizawa, H.2; Kurosawa, S.2 (Nihon Dempa Kogyo Co., Ltd.,2AIST, Japan)

[3P055] Use of Quinone as a Mediator at Anode in a Glucose/O2 Biofuel Cell 744Islam. M.K.1: Ohashi, T.1; Yasukawa, T.1; Shiku, H.1; Nishizawa, M.1; Kosuge, J.2;Fukasaku, N.2; Matsue, T.1 (Tohoku University, 2Daiichipure Chemicals Co., Ltd., Japan)

[3P056] Thermophilic Glucokinase-Based Sensors for the Detection of Various 746Saccharides and GlycosidesAoki. K.: Suzuki, H.; Ishimaru, Y; Toyama, S.; Ikariyama, Y; lida, T. (NationalRehabilitation Center for the Persons with Disabilities, Japan)

[3P057] Immobilization of Antigen Molecules by Self-Assembled Aminosilane on 748LiNO3 Surfaces and Detection of ImmunoreactionsFeng. C.-l.: Sun, Y; Li, Y; Ma, A.-l. (Liaoning Normal University, China)

[3P058] DNA-Cu (II) Complex Membrane Modified Electrodes for Novel Type of 750Biosensors for Glucose and DNA-Binding DrugsHasebe. Y.: Gu, T; Uchiyama, S. (Saitama Institute of Tecnology Japan)

[3P059] High Performance Amperometric Glucose Sensor Based on Two- 752Dimensional Cross-Linked Langmuir-Blodgett FilmsYonezaki. K.1: Kato, P.2; Sakata, M.1; Hirayama, C.1; Hirata, Y.2; Mizutani, F.2; Kunitake,M.1 (Kumamoto University, 2AIST, Japan)

[3P060] Imaging of Antibody Microarray by Scanning Electrochemical Microscopy 754with Shear Force Feedback Regulation of Substrate-Probe DistanceHirano. Y.1: Mase, Y1; Oyamatsu, P.2; Yasukawa, T.1; Shiku, H.1; Matsue, T.1 (TohokuUniversity, 2Osaka University, Japan)

[3P061] Development of Beta-Hydroxybutyrate Electrochemical Biosensor 756Ma. N. Z.: Guan, W. J.; Pan, M.; Li, G. (Zhejiang University, China)

[3P062] An Amperometric Biosensor with Immobilized Algae for Water Toxicity Testing 758Shitanda. I.: Takada, K.; Sakai, Y; Tatsuma, T. (University of Tokyo, Japan)

[3P064] Study of Protein Adsorption on Polymer Coatings Surface by Quartz Crystal 760Microbalance and Electrochemical Impedance MethodsZhang. Y.1'2: Fung, Y1; Yao, S.2 (The University of Hong Kong, 2Hunan University,China)

[3P065] Temperature Compensation in Detection of Nucleic Acid by Surface Plasmon 762Resonance BiosensorWang, Y; Cui. P.: Xiang, S (Chinese Academy of Sciences, China)

[3P066] Multichannel Detection of Hydrogen Peroxide Released from a Rat 764Hippocampal SliceKasai. N.1: Han, C.1; Torimitsu, K.12 (NTT Corp., 2SORST, JST, Japan)

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[3P068] In vivo Studies of Implantable Electrochemically Fabricated Glucose Sensors 766Yasuzawa, M.1; Inoue, S.1; Takaoka. H.1: Murakami, J.2; Shimizu, T.2; Imai, S.2 (TheUniversity of Tokushima, 2Japan Toyo Precision Parts MFG. Co., Ltd., Japan)

[3P069] Fundamental Study for an Oxygen-Insensitive Amperometric Glucose Sensor 768Using a Novel Glucose DehydrogenaseKojima. S.1: Tsujimura, S.1; Kano, K.1; Ikeda, T.1; Sato, M.2; Sanada, H.2; Omura, H.2

(Kyoto University, 2Ikeda Food Research Co., Ltd., Japan)

[3P070] Kinetic Study of Direct Electron Transfer between Enzyme and Carbon 770ElectrodesTsujimura. S.: Nakagawa, T; Knao, K.; Ikeda, T. (Kyoto University, Japan)

[3P071] AFM Patterning and Immobilization of Biomolecules on Si 772Moon, W.1'2; Yoshinobu. T.1: Nishikawa, A.3; Iwasaki, H.1 (ISIR, Osaka University,2CREST/JST, 3Osaka Electro-Communication Junior College, Japan)

[3P072] Three-Dimensional Sol-Gel Network on Platinum Electrode for Interference- 774Free Amperometric BiosensorMatsuhisa. H.: Tsuchiya, M.; Hasebe, Y. (Saitama Institute of Technology, Japan)

[3P073] Amperometric Immunosensor Based on Mediator/Antigen Hybrid Carbon 776ElectrodeUeda. M.1: Gu, T.1; Hasebe, Y1; Kaneko, H.2; Suda, Y.3; Yamada, K.3 (Saitama Instituteof Technology, 2Tsukuba Materials Imformation Laboratory Ltd., 3Mitsubishi Pencil Co.,Ltd., Japan)

[3P074] A Psoralen Derivative Containg Ferrocene for Redox-Labeling of DNA and 778Electrochemical Gene Sensor ApplicationsNakano. K: Shirakawa, S.; Taguchi, S. (Kyushu University, Japan)

[3P075] Parallel Detection of Protein Binding onto DNA Microarrays Using Two- 780Dimensional Internal Reflection Ellipsometry (2DIRE)Otsuki. S.: Yamada, H.; Iwahashi, H.; Tamada, K. (AIST, Japan)

[3P076] Self-Wiring with Redox Polymers from Tyrosinase to an Electrode 782Tatsuma. T.: Sato, T. (University of Tokyo, Japan)

[3P078] Detection and Classification of DNA by Electrophoresis in Conjugation with 784Infrared Absorption SpectroscopyMiyamoto. K.1: Kimura, Y1'2; Ishii, H.1'2; Niwano, M.1'2 (Tohoku University, 2JapanScience and Technology Corporation, Japan)

[3P079] Superoxide Sensor Based on Polymerized Superoxide Dismutase Prepared 786by "SUMO" TechniqueNishivama. K.: Miura, S.; Saitoh, H.; Taniguchi, I. (Kumamoto University, Japan)

[3P081] Immobilization of Urease and Cholinesterase on the Surface of 788Semiconductor Transducer for the Development of Light-AddressablePotentiometric SensorsMourzina, I. G.12; Yoshinobu, T.3; Ermolenko. Y E.1: Vlasov, Y G.1; Schoning, M. J.24;Iwasaki, H.3 (St. Petersburg State University, Russia, 2Research Centre Julich,Germany, 3Osaka University, Japan, "University of Applies Sciences Aachen, Germany)

[3P082] Development of PANi Gas Sensor Using Optical Properties in Visible 790Wavelength ReigonLee. Y.-S.1: Huh, Y.-H.1; Lee, S.-M.1; Huh, J.-S.1; Chung, W.-Y2; Lee, P.-P.1 (KyungpookNational University, 2Dongseo University, Korea)

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[3P083] ESA Based NanoFabry-Perot Cavity Fabrication towards Detection of 792Hydrogen PeroxidePel Villar, I.1; Matias. I. R.1: Arregui, F. J.1; Claus, R. O.2; Goicoechea, J.1 (UniversidadPublica de Navarra, Spain, 2 Virginia Polytechnic Institute and State Universtiy, USA)

[3P084] Compact Surface-Plasmon-Resonance Immunosensor Using Multichannels 794for Detection of Small-Molecule CompoundsKawazumi. H.1: Gobi, K. V.2; Ogino, K.3; Maeda, H.3; Miura, N.2 (Kinki University Kyushu,2Kyushu University, 3AIST Kyushu, Japan)

[3P086] Fiber-Optic Water Hardness Sensor Based on Eriochrome Black T 796Achaerandio, M.1; Alzueta, J.1; Arregui, F. J.1; Fernandez-Sanchez, J. F.2; Segura-Carretero, A.2; Matias. I. R.1 (Public University of Navarra, 2University of Granada,Spain)

[3P087] Development of An Eco-Friendly Optical Sensor Element Based on 798Tetraphenylporphyrin Derivatives Dispersed in Biodegradable Polymer.Effects of Substituents of Tetraphenylporphyrins on HCI Detection andBiodegradation.Nakagawa. K.1: Aono, T.1; Ueda, G.1; Tsutsumi, C.1; Hayase, N.1; Mabuchi, M.1;Sadaoka, Y2 (Niihama National College of Tech., 2Ehime University, Japan)

[3P089] Detection of Aromatic Nitro Compounds with Electrode Polarization 800Controlling SensorMasunaga. K.1: Hayama, K.1; Onodera, T.2; Hayashi, K.1; Miura, N.1; Matsumoto, K.1;Toko, K.1 (Kyushu University, 2Japan Science and Technology Agency, Japan)

[3P090] A Transcutaneous Oxygen Sensor for Rabbit Conjunctiva 802louchi. S.1: Ogawa, M.2; Uehara, T.1; Mitsubayashi, K.2 (Tokai University, 2Tokyo Medicaland Dental University, Japan)

[3P091] Study on the Electron Transfer of the Viologen Self-Assembled Monolayers 804Ock. J.-Y1: Lee, P.-Y1; Shin, H.-K.1; Miyake, J.2; Kwon, Y.-S.1 (Dong-A University, Korea,2AIST, Japan)

[3P092] Amplified Electrochemical Detection Based on Redox Recycling at a Liquid- 806Liquid Interface Formed in a Micro ChannelTorimura. M.1: Ichieda, N.1; Tao, H.1; Ito, T.2; Ohya, S.2 (AIST, 2Kanagawa IndustrialTechnology Research Institute, Japan)

[3P093] A Kinetic Study for Electrooxidation of NO Gas at a Pt/Membrane Electrode- 808Application to Amperometric NO SensorHo. K.-C: Liao, J.-Y; Yang, J.-C. (National Taiwan University, Taiwan)

[3P094] Electrical Property of a Networked Monolayer Film Prepared from Au 810NanoparticlesShiigi. H.: Yamamoto, Y; Nagaoka, T. (Osaka Prefecture University, Japan)

[3P095] The Effects of Interfering Gases on CO2 Sensor with Various Filters 812Hong. H. S.1: Kim, J. W.1; Jung, S. J.2; Park, C. O.1 (Korea Advanced Institute of Scienceand Technology, 2Korea Institute of Ceramic Engineering and Technology, Korea)

[3P096] Chemical Warfare Agent Sensor Using MEMS Structure and Thick Film 814Fabrication MethodChoi. N. J.1: Lee, Y S.1; Kwak, J. H.1; Park, J. S.2; Park, K. B.2; Shin, K. S.2; Park, H. P.2;Kim, J. C.1; Huh, J. S.1; Lee, P.-P.1 (Kyungpook National University, 2Korea ElectronicsTechnology Institute, Korea)

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[3P097] A Micro Gas Sensor Fabricated on a Micro Bridge Using Surface 816MicromachiningKimura, M.; Hara. K. (Tokyo Denki University, Japan)

[3P098] Properties and Structure of Aluminum Nitride Thin Films on ST-Quartz 818Wang. C.-H.1: Cheng, C.-C.2 (Nan-Jeon Institute of Technology, 2National Cheng KungUniversity, Taiwan)

[3P099] The Design and Manufacture of a Micro Gas Sensor Array 820Gao. X.: Li, J.; He, X.; Wang, L. (Chinese Academy of Science, China)

[3P100] Sand Blasting Patterning Technology for Micro-Biochemical Reactor with 822Integrated Thin Film Platinum Resistors as Sensors and HeatersLee. J.-H.: Eun, P.-S.; Lee, J.-H. (Kyungpook National University, Korea)

[3P101] Microfarbricated Ultra Small Packed Gas Chromatographic Column 824Sturmann. J.1: Lang, W.1; Benecke, W.1; Zampolli, S.2; Elmi, I.2 (University of Bremen,Germany, 2CNR-IMM Sezione di Bologna, Italy)

[3P102] Micro Fluidic Sensor System for the Determination of GOT and GPT Enzyme 826ActivitiesOhgami. N.1: Suzuki, H.1; Kusakabe, H.2 (University of Tsukuba, 2Yamasa Corporation,Japan)

[3P103] Contactless Conductivity Detection for Microchip of Laminated Laser-Printed 828Polyester FilmsNeves. C. A.: Po Lago, C. L. (Universidade de Sao Paulo, Brazil)

[3P104] Polymer Chip Incorporated with ISFET for Micro Flow Analysis 830Masadome. T.1: Ishikawa, M.2; Wakida, S.3 (Shibaura Institute of Technology, 2AriakeNational College of Technology, 3AIST, Japan)

[3P105] Structures Production for Organic Compounds Preconcentration in Gas or 832Liquid PhasesNascimento Filho. A. P.: da Silva, M. L. P.; Jesus, P. P.; Pemarquette, N. R.; T. Carvalho,A. (University of Sao Paulo, Brazil)

[3P106] An Integrated On-Chip Sorter for Bioparticles and Macromolecules 834Inoue. T.: Noguchi, Y; Yokoyama, H. (AIST, Japan)

[3P107] Effect of the Immersion Angle of a One-Face Sealed Quartz Crystal 836Microbalance in Electrolytic SolutionTokimura. S.1: Yoshimoto, M.1; Kurosawa, S.2; Naitoh, M.3 (Kagoshima University, 2AIST,3Tokyo Woman's Christian University, Japan)

[3P108] Behaviors of the Quartz Crystal Microbalance in a Newtonian Liquid 838Maruyama. Y.1: Yoshimoto, M.1; Kurosawa, S.2; Naito, M.3 (Kagoshima University, 2AIST,3Tokyo Woman's Christian University, Japan)

[3P110] A Novel Approach for the Drift Mechanisms of EGFET by Post-Baking 840TreatmentLai, C.-S.; Yang. C.-M.: Ko, H.-P.; Lue, C.-E.; Lue, T. F; Wang, C.-Y. (Chang GungUniversity, Taiwan)

[3P111] Enhancing Chemiresistor-Type NO Gas Sensing Properties Using Ethanol- 842Treated Lead Phthalocyanine Thin FilmsHo. K.-C: Chen, C.-M.; Liao, J.-Y. (National Taiwan University, Taiwan)

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[3P112] Ammonia Gas Interaction with WO3-Based Nanocrystalline Powders: Gas 844Sensors and DRIFTS StudiesJimenez, I.1; Centeno, M. A.2; Cornet, A.1; Morante. J. R.1 (Universitat de Barcelona,2Universidad de Sevilla-CSIC, Spain)

[3P114] Effect of Sm, Eu and Gd on Nb-Doped TiO2 Varistors 846Tang. Z.: Mi, J.; Zhang, Z.; Zhou, Z. (Tsinghua University, China)

[3P115] Analysis of Point Defects in Doped BaTiO3 Ceramics as CO Gas Sensors by 848Electron Paramagnetic ResonanceZhou. Z.-G.: Tang, Z.-L.; Zhang, Z.-T. (Tsinghua Universty China)

[3P116] Sensory Properties of the La06Pb04MnO3 - VO2 Composites for the Presence 850of Organics in AirBogomazova, N. V.1; Busel, N. I.1; Tarasevitch, T. I.1; Shishkin. N. Y1: Bashkirov, L. A.1;Bardi, U.2; Gunko, Y. K.3 (Belarus State University of Technology, Belarus, 2Universitadi Firenze, Italy, 3Trinity College Dublin, Ireland)

[3P117] Spectroscopic and Electrical Studies of MoO3-WO3 Systems 852Morandi. S.1: Ghiotti, G.1; Chiorino, A.1; Comini, E.2; Sberveglieri, G.2 (University ofTorino, 2University of Brescia, Italy)

[3P118] Sensor Properties of Some Perovskite-Like Metal Oxides 854Klyndziuk, A.; Petrov. G.: Kurhan, S.; Chizhova, Y; Chabatar, A.; Kunitski, L.; Bashkirov,L. A. (Belarus State Technological University, Belarus)

[3P120] Sol-Gel Synthesis and Characterization of Nano Powder Particles of Cu-Ni 856Mixed FerriteUnnikrishnan, V. K; Chandrasekaran. G. (Pondicherry University, India)

[3P121] Gas Sensing Properties of Nanocrystalline Oxide Doped Silica Sol-Gel Films 858Post. M.1: Cantalini, C2; Martucci, A.3; Buso, P.3; Guglielmi, M.3; Zbroniec, L.4; Sasaki,T.4; Koshizaki, N.4 (National Research Council of Canada, Canada, 2Universita dell'Aquila, 3Universita di Padova, Italy, 4AIST, Japan)

[3P124] The Gas Classification Using Time Response Based on PANi Gas Sensor 860Lee. Y.-S.1: Joo, B.-S.1; Huh, J.-S.1; Hong, Y.-H.2; Lee, P.-P.1 (Kyungpook NationalUniversity, 2Kyungwoon University, Korea)

[3P125] Enantioselective Crystallization on Self-Assembled Monolayers and Its 862Application to Chiral SensingNakanishi. T.: Banno, N.; Matsunaga, M.; Asahi, T; Osaka, T. (Waseda University, Japan)

[3P126] Oscillatory Response of Pt Based CO Sensors 864Li, L.; Wlodarski. W.: Galatsis, K; Akolekar, P. B.; Bhargava, S. (RMIT University,Australia)

[3P127] Development of a Novel Modular pH Meter 866Ito. Y. (Shindengen Kogyo, Japan)

[3P128] Bio and Chemical Sensors Based on Resonant Frequency Changes of 868Magnetically Oscillating CantileversNishida. S.: Inoue, T; Yokoyma, H. (National Institute of Advanced Science andTechnology, Japan)

[3P130] Nanostructure Engineered Gas Sensor Array Using Carbon Nanotubes and 870MEMS Fabrication TechnologyLu. Y.: Pelzeit, L; Ye, Q.; Li, J.; Han, J.; Meyyappan, M. (NASA Ames Research Center, USA)

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[3P131] Discrimination of Taste Solutions Using Ultrasonic Wave and Various 872SensorsKojima. Y. (Tomakomai National College of Technology, Japan)

[3P132] The Design and Implementation of Smart Chemical Sensor Platform 874Chou. J. C: Hong, W. B. (National Yunlin University of Science and Technology, Taiwan)

[3P134] Development of a Novel Micro Gas Sensor with Suspended Micro Heater and 876Electrodes Bridging on Pillars Formed on the Silicon SubstrateKim. C. K.1: Lee, J. H.1; Joo, Y C.1; Lee, C. H.1; Yoo, K. S.2 (Soonchunhyang University,2University of Seoul, Korea)

[3P135] Kinetic Study of Chemical Oscillating Reaction in the System of HCHO-DL- 878Malic Acid- BrO3~ -Mn2+-H2SO4

An. C.-J.1: Zhang, Z.-Q.2; Ping, Z.-Z.1; Zhang, Y.-Z.2; Zheng, P.1; Wu, Z.-Y.1 (WuhanUniversity, 2 Yangtze University, China)

[3P136] Sensing Properties of a Sensor Using LaF3 Solid Electrolyte for Dissolved 880CO2 in Artificial Sea WaterMatayoshi. N. U.: Takyu, A. (University of the Ryukyus, Japan)

[3P137] A New Heart Monitoring System Developed with Piezoelectric Film Sensor 882Liu. Y.: Xu, J.; Liu, X.; Song, Y; Hu, H.; Wang, G. (Chinese Academy of Sciences,China)

[3P138] A DNA Chip Based on in Situ Synthesis Technology Utilizing Polymer as a 884Masking MaterialKuroiwa. T.1: Obara, P.1; Goshoo, Y.1; Ishikawa, N.1; Vinet, F.2; Vauchier, C.2;Soucemarianadin, A.3 (Yamatake Corporation, Japan, 2LETI-CEA/Grenoble, 3UniversiteJoseph Fourier-INPG-CNRS, France)

[3P139] Sensing Technology for Chemical-Warfare Agents and Its Evaluation Using 886Real AgentsSeto. Y.: Kataoka, M.; Tsuge, K; Ohsawa, I.; Matsushita, K; Sekiguchi, H. (NationalResearch Institute of Police Science, Japan)

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