研究業績 (Publication list)

total peer-reviewed original papers 135, peer-reviewed review articles 8, h-index 43, i10-index=103, total number of citations 6903, Jan/1/2024) Google scholar

TSUKUBA (since Aug 16th, 2011, peer-reviewed original paper 81, review article 8, book 1, book chapter 16)

論文(original research papers)

81(135)
Porous carbon-based electrochemical platform for direct electron transfer in myoglobin
Hossain, M.M., Morshed, J., Nomoto, A., Tsujimura, S., Alwarappan, S.,
Electroanal., in press
doi.org/__

80(134)
Performance of a Fe-N-C catalyst in single-chamber MFC air-cathode at neutral media
Sato-Soto., S., Sato, S., Tsujimura, S.,
Electrochemistry, in press
doi.org/10.5796/electrochemistry.23-68141

79(133)
Effect of pore size of MgO-templated porous carbon electrode on immobilized crosslinked enzyme?mediator redox network
Hossain., M.M., and Tsujimura, S.,
J. Power Sources, 594, 233992 (2024)
https://doi.org/10.1016/j.jpowsour.2023.233992

78(132)
Adsorption of Laccase on Multi-walled Carbon Nanotubes
Ben Tahar, A., L. Suherman, A., Boualam, A., Tsujimura,S., Shitanda, I., Zebda, A.,
Electrochemistry, 92, 022010 (2024)
doi.org/10.5796/electrochemistry.23-68122

77(131)
Hierarchical Structure of Gold and Carbon Electrode for Bilirubin Oxidase-Biocathode
Nakagawa, Y., Tsujimura, S., Zelsmann, M., Zebda, A.,
Biosensors, 13, 482 (2023)
doi.org/10.3390/bios13040482

76(130)
A disposable enzymatic biofuel cell for glucose sensing via short-circuit current
Morshed, J., Hossain M., Zebda, A., Tsujimura, S.,
Biosens. Bioelectron., 230, 115272 (2023)
doi.org/10.1016/j.bios.2023.115272

75(129)
Impact of Lactic Acid and Genipin Concentration on Physicochemical and Mechanical Properties of Chitosan Membranes
Kondratowicz, I., Shalayel, I., Nadolska, M., Tsujimura, S., Yamagata, Y., Shitanda, I., and Zebda, A.,
J Polym Enviro, 31, 1221-1231 (2023)
doi.org/10.1007/s10924-022-02691-z

74(128)
High-Performance Paper-based Biocathode fabricated by Screen-printing an improved Mesoporous Carbon Ink and by Oriented Immobilization of Bilirubin Oxidase
Loew, N., Shitanda, I., Goto, H., Watanabe, H., Mikawa, T., Tsujimura S., Itagaki, M.,
Sci Rep 12, 14649 (2022).
doi.org/10.1038/s41598-022-19052-4

73(127)
Glucose-sensor Strip Using Flavin Adenine Dinucleotide-dependent Glucose Dehydrogenase with Quinones as Redox Mediators
Gong, Y., Tsujimura, S.,
Sensors and Materials, 34, 8(2), 3141-3146 (2022).
doi.org/10.18494/SAM3895

72(126)
Improved Stability of Continuous Operation of Lactate Oxidasehydrogel Electrodes Using Os(bipyridine)2Cl-pendant Poly(vinyl Imidazole)
Terazawa, R., Mikawa, T., Tsujimura, S.,
Sensors and Materials, 34, 8(2), 3133-3140 (2022).
doi:10.18494/SAM3894

71(125)
Self-Powered Diaper Sensor with Wireless Transmitter Powered by Paper-Based Biofuel Cell with Urine Glucose as Fuel
Shitanda, I., Fujimura, Y., Takarada, T., Suzuki, R., Aikawa, T., Itagaki, M., Tsujimura, S.,
ACS Sensors, 6(9), 3409-3415 (2021).
doi:10.1021/acssensors.1c01266

70(124)
Designing a cross-linked redox network for a mediated enzyme-based electrode
Hossain, M., Morshed, J., Tsujimura, S.,
Chem Comm., 57, 6999-7002 (2021).
doi:10.1039/D1CC01707A

69(123)
Chitosan-based enzyme ink for screen-printed bioanodes
Shitanda, I., Oda, K., Loew, N., Watanabe, H., Itagaki, M., Tsujimura, S., Zebda, A.,
RSC Adv., 11, 20550-20556 (2021).
doi:10.1039/D1RA03277A

68(122)
Disposable electrochemical glucose sensor based on water-soluble quinone-based mediators with flavin adenine dinucleotide-dependent glucose dehydrogenase
Morshed, J., Nakagawa, R., Hossain, M., Nishina, Y., Tsujimura, S.,
Biosens. Bioelectron., 189, 113357 (2021),
doi:10.1016/j.bios.2021.113357

67(121)
High Capacity Lactate Biofuel Cell using Enzyme Cascade without NAD
Shitanda,I., Tsuaga, M., Watanabe, H., Itagaki, M., Tsujimura, S., Mikawa, T.,
Chem. Lett., 50(6), 1160-1163 (2021)
doi:10.1246/cl.210064

66(120)
Fabrication of an organic redox capacitor with a neutral aqueous electrolyte solution
Nakagawa, Y., Tsujimura, S.,
Electrochem, 89, 317-322 (2021)
doi:10.5796/electrochemistry.21-00004

65(119)
Paper-based Lactate Biofuel Cell Array with High Power Output
Shitanda,I.,Morigayama, Y., Iwashita, R., Goto, H., Aikawa, T., Mikawa, T., Hoshi, Y., Itagaki, M., Matsui, H., Tokito, S., Tsujimura, S.,
J Power Sources, 489, 229533 (2021)
doi:10.1016/j.jpowsour.2021.229533

64(118)
Improved glucose oxidation catalytic current generation by an FAD-dependent glucose dehydrogenase-modified hydrogel electrode, in accordance with the Hofmeister effect
Yoshida, A., Tsujimura, S.,
J. Phys. Energy, 3, 024005 (2021).
doi:10.1088/2515-7655/abd877

63(117)
Polydopamine Coating on Lactate Oxidase- and 1,2-naphthoquinone-modified Porous Carbon Electrode for Stability Improvement
Shitanda, I., Takamatsu, K., Yoshihata, Y., Nakamura, T., Mikawa, T., Itagaki, M., Tsujimura, S.,
Chem. Let., 50, 593-595 (2021).
doi:10.1246/cl.200799

62(116)
Ready-to-Use Paper Biofuel Cell Driven by Water
Shitanda, I., Momiyama, M., Hoshi, Y., Itagaki, M., Tsujimura, S.,
J. Phys. Energy, 3, 016001 (2021).
doi:10.1088/2515-7655/abd385

61(115)
Continuous Sweat Lactate Monitoring System with Integrated Screen-Printed MgO-templated Carbon-Lactate Oxidase Biosensor and Microfluidic Sweat Collector
Shitanda,I., Mitsumoto,M., Loew, N., Yoshihara, Y., Watanabea, H., Mikawa, T., Tsujimura, S., Itagaki, M., Motosuke, M.,
Electrochim Acta, 368, 137620 (2021).
doi:10.1016/j.electacta.2020.137620

60(114)
Electrochemical modification at multiwalled carbon nanotube electrodes with Azure A for FAD-glucose dehydrogenase wiring: Structural optimization to enhance catalytic activity and stability
Tsujimura, S., Tanaka, S., Gross, A., Holzinger, M.,
J. Phys. Energy, 3, 024004 (2021).
doi:10.1088/2515-7655/abd298

59(113)
Synechococcus and other bloom-forming cyanobacteria exhibit unique redox signatures
Tokunou, Y., Vieira Lemos, R., Tsujimura, S., Okamoto, Ledezma, A., P., Freguia, S.,
ChemElectroChem, 8, 360-364 (2021).
doi:10.1002/celc.202001274

58(112)
Diazonium electrografting vs. physical adsorption of Azure A at carbon nanotubes for mediated glucose oxidation with FAD-GDH
Gross, A.J., Tanaka, S., Colomies, C., Giroud, F., Nishina, Y., Cosnier, S., Tsujimura, S., Holzinger, M.,
ChemElectroChem, 7, 4543-4549 (2020).
doi:10.1002/celc.202000953

57(111)
Extracellular electron transfer by Microcystis aeruginosa is solely driven by high pH
Vieira Lemos, R., Tsujimura, S., Ledezma, P., Tokunou, Y., Okamoto, A., Freguia, S.,
Bioelectrochemistry, 137, 107637 (2021)
doi:10.1016/j.bioelechem.2020.107637

56(110)
Wearable glucose/oxygen biofuel cell fabricated using modified aminoferrocene and flavin adenine dinucleotide-dependent glucose dehydrogenase on poly(glycidyl methacrylate)-grafted MgO-templated carbon
Suzuki, R., Shitanda, I., Aikawa, T., Tojo, T., Kondo, T., Tsujimura, S., Itagaki, I., Yuasa, M.,
J. Power Sources,, 479, 228807 (2020)
doi:10.1016/j.jpowsour.2020.228807

55(109)
Mediated electrochemical oxidation of glucose via poly(methylene green) grafted on the carbon surface catalyzed by flavin adenine dinucleotide-dependent glucose dehydrogenase
Tsuruoka, N., Sato Soto, S., Ben Tahar, A., Zebda, A., Tsujimura, S.,
Colloids and Surfaces B: Biointerfaces, 192, 111065 (2020)
doi:j.colsurfb.2020.111065

54(108)
Toward an ideal platform structure based on MgO-templated carbon for flavin adenine dinucleotide-dependent glucose dehydrogenase-Os polymer-hydrogel electrodes
Tsujimura, S., Takeuchi, S.,
Electrochimica Acta, 343, 136110 (2020)
doi:10.1016/j.electacta.2020.136110

53(107)
Stable Immobilization of Enzyme on Pendant Glycidyl Group-Modified Mesoporous Carbon by Graft Polymerization of Poly(Glycidyl Methacrylate)
Shitanda, I., Kato, T., Suzuki, R., Aikawa, T., Hoshi, Y., Itagaki, M., Tsujimura, S.,
Bulletin of the Chemical Society of Japan, 93, 32-36 (2020)
doi:10.1246/bcsj.20190212

52(106)
Self-powered bioelectrochemical nutrient recovery for fertilizer generation from human urine
Freguia S., Eloisa Logrieco, M., Monetti, J., Ledezma, P., Virdis, B., Tsujimura, S.,
Sustainability, 11(19), 5490 (2019)
doi:10.3390/su11195490

51(105)
Effects of pore size and surface properties of MgO-templated carbon on the performance of bilirubin oxidase-modified oxygen reduction reaction cathode
Tsujimura, S., Oyama, M., Funabashi, H., Ishii, S.,
Electrochim. Acta, 322, 134744 (2019)
doi:10.1016/j.electacta.2019.134744

50(104)
Paper-Based Disk-Type Self-Powered Glucose Biosensor Based on Screen-Printed Biofuel Cell Array
Shitanda, I., Fujimura, Y., Nohara, S., Hoshi, Y., Itagaki, M., Tsujimura, S.,
J. Electrochem. Soc., 166, B1063-B1068
doi:10.1149/2.1501912jes

49(103)
High-power lactate/O2 enzymatic biofuel cell based on carbon cloth electrodes modified with MgO-templated carbon
Shitanda, I., Takamatsu, K., Niiyama, A., Mikawa, T., Hoshi, Y., Itagaki, M., Tsujimura, S.,
J. Power Sources, 436, 226844 (2019)
doi:10.1016/j.jpowsour.2019.226844

48(102)
Effects of electrolyte on the mediated electrocatalytic glucose oxidation reaction catalyzed by flavin adenine dinucleotide glucose dehydrogenase
Adachi, T., Tsujimura, S.,
Electrochim Acta, 313, 189-193 (2019)
doi:10.1016/j.electacta.2019.04.145

47(101)
High-performance enzymatic biofuel cell based on flexible carbon cloth modified with MgO-templated porous carbon
Niiyama, A., Murata, K., Shigemori, Y., Zebda, A., Tsujimura, S.,
J. Power Sources, 427, 49-55 (2019)
doi:10.1016/j.jpowsour.2019.04.064

46(100)
One-year stability of glucose dehydrogenase confined in a 3D carbon Nanotube electrode with coated Poly-Methylene Green: application as bioanode for a glucose biofuel cell
Ben Tahar, A., Szymczyk, A., Tingry, S., Vadgama, P., Zelsmann, M., Tsujimura, S., Cinquin, P., Martin, D., Zebda, A.,
J. Electroanal. Chem., 847, 103069 (2019)
doi:10.1016/j.jelechem.2019.04.029

45(99)
Effect of electrolyte ions on stability of flavin adenine dinucleotide-dependent glucose dehydrogenase
Nemoto, M., Sugihara, K., Adachi, T., Murata, K., Shiraki, K., Tsujimura S.,
ChemElectroChem., 6(4), 1028-1031 (2019)
doi:10.1002/celc.201801241

44(98)
Improved Formation of Pt Multilayers at Near-neutral pH: Underpotential Deposition and Surface Limited Redox Replacement
Takimoto D., Tsujimura, S.,
Chem. Lett., 47(11), 1379-1382 (2018)
doi:10.1246/cl.180652

43(97)
Oxygen Reduction Reaction Activity and Stability of Electrochemically Deposited Bilirubin Oxidase
Takimoto D., Tsujimura S.,
Chem. Lett., 47 (10), 1269-1271 (2018)
doi:10.1246/cl.180597

42(96)
Pore size effect of MgO-templated carbon on enzymatic H2 oxidation by the hyperthermophilic hydrogenase from Aquifex aeolicus
Mazurenko,I., Clement, R., Byrne-Kodjabachian, D., de Poulpiquet, A., Tsujimura, S., Lojou E.,
J. Electroanal. Chem. 812, 221-226 (2018)
10.1016/j.jelechem.2017.12.041

41(95)
Tuning the Redox Potential of Vitamin K3 Derivatives by Oxidative Functionalization Using Ag(I)/GO Catalyst
El-Hout, S.I., Suzuki, H., El-Sheikh, S.M., Hassan, H.M.A., Harraz, F.A., Ibrahim, I.A., El-Sharkawy, E. A., Tsujimura, S., Holzinger, M., and Nishina, Y.,
ChemComm, 53, 8890-8893 (2017)
10.1039/C7CC03910G

40(94)
Toward Wearable Energy Storage Devices: Paper-based Biofuel Cells based on a Screen-printing Array Structure
Shitanda, I., Momiyama, M., Watanabe, N., Tanaka, T., Tsujimura, S., Hoshi, Y., Itagaki, M.,
ChemElectroChem, 4(10), 2460-2463 (2017)
10.1002/celc.201700561

39(93)
A Screen-printed Circular-type Paper-based Glucose/O2 Biofuel Cell
Shitanda I., Nohara, S., Hoshi, Y., Itagaki, M.,Tsujimura, S.,
J Power Sources, 360, 516-519 (2017)
j.jpowsour.2017.06.043

38(92)
New function of aldoxime dehydratase: Redox catalysis and the formation of an unexpected product
Yamada, M., Hashimoto, Y., Kumano, T., Tsujimura, S., Kobayashi, M.
PLOS ONE, 12(4):e0175846 (2017)

37(91)
Bimolecular Rate Constants for FAD-dependent Glucose Dehydrogenase from Aspergillus terreus and Organic Electron Acceptors
Tsuruoka, N., Sadakane, T., Hayashi, R., Tsujimura, S.
Int. J. Mol. Sci., 18(3),604 (2017)
10.3390/ijms18030604

36(90)
Lowering the potential of electroenzymatic glucose oxidation on redox hydrogel-modified porous carbon electrode
Suzuki, A., Mano, N., Tsujimura, S.
Electrochim. Acta, 232, 581-585 (2017)
10.1016/j.electacta.2017.03.007

35(89)
Screen-printed, Paper-based, Array-type, Origami Biofuel Cell
Shitanda, I., Kato, S., Tsujimura, S., Hoshi, Y., Itagaki, M.,
Chem. lett., 46, 726-728 (2017)
10.1246/cl.170047

34(88)
Hierarchical meso/macro-porous carbon fabricated from dual MgO templates for direct electron transfer enzymatic electrodes
Funabashi, H., Takeuchi, S., Tsujimura, S.
Sci. Rep., 7, 45147 (2017)
10.1038/srep45147

33(87)
Redox-Polymers Enable Uninterrupted Day/Night Photo-Driven Electricity Generation in Biophotovoltaic Devices
Darus, L., Sadakane, T., Ledezma, P., Tsujimura, S., Osadebe, I., Leech, D., Gorton, L., Freguia, S.
J. Electrochem. Soc., 164(3), H3037-H3040 (2017).
10.1149/2.0091703jes

32(86)
Hofmeister effects on the glucose oxidase hydrogel-modified electrode
Suzuki, A., Tsujimura, S.
Electrochim. Acta, 201, 228-232 (2016).

31(85)
Long-term continuous operation of FAD-dependent glucose dehydrogenase hydrogel-modified electrode at 37°C
Suzuki, A., Tsujimura, S.
Chem. Lett., 45(4) 484-486 (2016).

30(84)
Redox hydrogel of glucose oxidase on MgO-templated carbon electrode
Suzuki, A., Murata, K., Mano, N., Tsujimura, S.
Bull. Chem. Soc. Jpn., 89, 24-26 (2016).

29(83)
Electrochemical Oxygen Reduction Catalyzed by Bilirubin Oxidase with the Aid of 2,2'-Azinobis(3-ethylbenzothiazolin-6-sulfonate) on a MgO-template Carbon Electrode
Tsujimura, S., Murata, K.
Electrochim. Acta, 180, 555-559 (2015).

28(82)
Electrochemical Activation of a Novel Laccase, MELAC, Isolated from Compost
Murata, K., Shigemori, Y., Tsujimura, S.,
Chem. Lett., 44(5), 654-655 (2015).

27(81)
Effect of pore size of MgO-templated carbon on the direct electrochemistry of D-fructose dehydrogenase
Funabashi, H., Murata, K., Tsujimura, S.,
Electrochemistry, 83(5) 372-375 (2015).

26(80)
Electrochemical Impedance Simulation of Branch Structure Porous Carbon Electrode using Transmission Line Model
Shitanda, I., Tsujimura, S., Yanai, H., Hoshi, Y., Itagaki, M.,
Electrochemistry, 83(5), 335-338 (2015) .

25(79)
Electrochemical Impedance Study of Screen-printed Branch Structure Porous Carbon Electrode using MgO-templated Carbon and MgO Particle and its Application for Bilirubin Oxidase-immobilized Biocathode
Shitanda, I., Nakafuji, H., Tsujimura, S., Hoshi, Y., Itagaki, M.,
Electrochemistry, 83(5), 329-331 (2015).

24(78)
Exceptionally high glucose current on a hierarchically structured porous carbon electrode with “wired” flavin adenine dinucleotide-dependent glucose dehydrogenase
Tsujimura, S., Murata,K., Akatsuka, W.
J. Am. Chem. Soc., 136, 14432-14437 (2014).

23(77)
Electrostatic Interaction between an Enzyme and Electrodes in the Electric Double Layer Examined in a View of Direct Electron Transfer-type Bioelectrocatalysist
Sugimoto, Y., Kitazumi, Y., Tsujimura, S., Shirai, O., Yamamoto, M., and Kano, K.
Biosens. Bioelectron., 63, 138-144 (2015).

22(76)
Glucose oxidation catalyzed by FAD-dependent glucose dehydrogenase within Os complex-tethered redox polymer hydrogel
Murata,K., Akatsuka, W., Sadakane, T., Matsunaga, A., Tsujimura, S.
Electrochim Acta, 136, 537-541 (2014).

21(75)
Control of the pore size distribution of carbon cryogels by pH adjustment of catalyst solutions
Hamano,Y., Tsujimura, S., Shirai, O., Kano K.,
Materials Letters. 128, 191-194 (2014).

20(74)
Bioelectrocatalytic oxidation of glucose on a MgO-templated mesoporous carbon modified electrode
Murata, K., Akatsuka, W., Tsujimura, S.,
Chem. Lett. 43(6), 928-930 (2014).

19(73)
Oxygen reduction reactions of the thermostable bilirubin oxidase from Bacillus pumilus on mesoporous carbon-cryogel electrodes
Tsujimura, S., Suraniti, E., Durand,F., Mano, N.,
Electrochimica Acta, 117, 263-267(2014).

18(72)
Direct electron transfer of a metagenome-derived laccase fused to affinity tags near the electroactive copper site
Tsujimura, S., Asahi, M., Goda-Tsutsumi, M., Shirai, O., Kano, K., Miyazaki, K.,
Phys. Chem. Chem. Phys., 15 (47), 20585-20589 (2013).

17(71)
Flexible and High-Performance Paper-Based Biofuel Cells using Printed Porous Carbon Electrodes
Shitanda,I., Kato, S., Hoshi,Y., Itagaki, M., and Tsujimura S.,
Chem, Comm., 49 (94), 11110-11112 (2013).

16(70)
Re-construction of Pentose Phosphate Pathway Coupled with a Bioelectrocatalytic NADPH Oxidation System for Bioanodes of Biofuel Cells [in Japanese]
Sakai, H., Tokita, Y., Tsujimura, S., Shirai, O., and Kano, K.,
Electrochemistry, 81(12), 981-984 (2013).

15(69)
Fabrication and Characterization of Glucose Fuel Cells with Microchannels Fabricated on Flexible Polyimide Film
Fukushi, Y., Koide, S., Ikoma, R., Akatsuka, W., Tsujimura, S., Nishioka, Y.,
J. Photopoly. Sci. Tech., 26 (3) 303-308, 2013

14(68)
Water-repellent-treated enzymatic electrode for passive air-breathing biocathodic reduction of oxygen
Nakagawa, T., Mita, H., Kumita, H., Sakai, H., Tokita, Y., and Tsujimura, S.
Electrochem. Commun., 36, 46-49 (2013).

13(67)
Designing Thin Films of Redox Hydrogel for Highly Efficient Enzymatic Anodes
Suraniti, E., Vives, S., Tsujimura, S., and Mano, N.
J. Electrochem. Soc., 160(6), G79-G82 (2013)

12(66)
Diffusion-controlled Detection of Glucose with Microelectrodes in Mediated Bioelectrocatalytic Oxidation
Noda, T., Wanibuchi, M., Kitazumi, Y., Tsujimura, S., Shirai,O., Yamamoto, M., and Kano. K.
Anal. Sci., 29 (3), 279-281 (2013)

11(65)
Modifications of laccase activities of copper efflux oxidase, CueO by synergistic mutations in the first and second coordination spheres of the type I copper center
Kataoka, K., Kogi, H., Tsujimura, S., Sakurai, T.,
Biochem. Biophys. Res. Commun., 431, 393-397 (2013).

10(64)
Bioelectrocatalytic oxidation of glucose with antibiotic channel-containing liposomes
Fujita, S., Matsumoto, R., Ozawa, K., Sakai, H., Maesaka, A., Tokita, Y., Tsujimura, S., Shirai, O., Kano, K.,
Phys. Chem. Chem. Phys., 15, 2650-2653 (2013).

9(63)
Amperometric Biosensor Based on Reductive H2O2 Detection Using Pentacyanoferrate-bound Polymer for Creatinine Determination
Nieh, C.-H., Tsujimura, S., Shirai, O., Kano, K.,
Anal. Chim. Acta, 767, 128-133 (2013).

8(62)
Electrostatic and Steric Interaction between Redox Polymers and Some Flavoenzymes in Mediated Bioelectrocatalysis
Nieh, C.-H., Tsujimura, S., Shirai, O., Kano, K.,
J. Electroanal. Chem., 689, 26-30 (2013).

7(61)
Thermophilic Biocathode with Bilirubin Oxidase from Bacillus pumilus
Suraniti,E., Tsujimura, S., Durand, F., Mano, N.,
Electrochem. Commun., 26, 41-44 (2013).

6(60)
Micro-cubic monolithic carbon cryogel electrode for direct electron transfer reaction of fructose dehydrogenase
Hamano, Y., Tsujimura, S., Shirai, O., Kano, K.,
Bioelectrochemistry, 88, 114-117 (2012).

5(59)
Transmission mechanism of the change in membrane potential by use of organic liquid membrane system
Ueya,N., Shirai, O., Kushida, Y., Tsujimura, S., Kano, K.,
J. Electroanal. Chem., 673(1), 8-12 (2012).

4(58)
Improved Performance of Gas-diffusion Biocathode for Oxygen Reduction
Asano, I., Hamano, Y., Tsujimura S., Shirai, O., Kano K.
Electrochemistry, 80(5), 324-326 (2012).

3(57)
Electrochemical Investigation on Permeability of Organic Acid Ions through Amphotericin B Channels
Yamauchi, T., Shirai, O., Tsujimura, S., and Kano, K.
Electrochemistry, 80 (5), 315-317 (2012).

2(56)
Micro-coulometric Study of Bioelectrochemical Reaction Coupled with TCA Cycle
Tsujimura, S., Fukuda, J., Shirai, O., Kano, K., Sakai, H., Tokita, Y., Hatazawa, T.
Biosens. Bioelectron, 34, 244-248 (2012).

1(55)
A two-step synthesis of 7,8-dichloro-riboflavin with high yield
Courjean, O., Hochedez, A., Neri, W., Louerat, F., Tremey, E., Gounel, S., Tsujimura, S., and Mano N.
RSC Advances, 2, 2700-2701 (2012)

総説(reviews: 8)

8
Enzyme cascade electrode reactions with nano-materials and its applicability towards biosensor and biofuel cells
Shalini devi K. S., Rezki, M., Hossain, M., Ariga, K., Tsujimura, S.
Biosensors, 2023, 13, 1018
doi.org/10.3390/bios13121018

7
Graphene oxide-based nanomaterials for electrochemical bio/immune sensing and its advancements in health care applications: A review
Shalini devi K. S., Prakash, J., Tsujimura, S.
Hybrid Advances
https://doi.org/10.1016/j.hybadv.2023.100123

6
Emerging electrochemical biosensing strategies using enzyme incorporated metal-organic frameworks (MOFs)
Shalini devi K. S., Rezki, M., S. Tsujimura, S.
Talanta Open, 8, 100263 (2023)
https://doi.org/10.1016/j.talo.2023.100263

5
Insight into continuous glucose monitoring: from medical basics to commercialized devices
Chmayssem,A., Nadolska, M., Tubbs, E., Sadowska, K., Vadgma, P., Shitanda, I., Tsujimura, S., Lattach, Y., Peacock, M., Tingry, S., Marinesco, S., Mailley, P., Lablanche, S., Benhamou, P.Y., Zebda, A.,
Microchim Acta 190, 177 (2023)
https://doi.org/10.1007/s00604-023-05743-w

4
Toward self-powered real-time health monitoring of body fluid components based on improved enzymatic biofuel cells
Shitanda, I., Tsujimura, S.,
J. Phys. Energy, 3, 032002 (2021)
doi:10.1088/2515-7655/abebcb

3
From fundamentals to applications of bioelectrocatalysis: bioelectrocatalytic reactions of FAD-dependent glucose dehydrogenase and bilirubin oxidase
Tsujimura, S.
Bioscience, Biotechnology, and Biochemistry, 83, 39-48 (2019)
https://doi.org/10.1080/09168451.2018.1527209

2
Templated mesoporous carbons: Synthesis and applications
Inagaki, M., Toyoda, M., Soneda, Y., Tsujimura, S., Morishita, T.,
Carbon, 107, 448-473 (2016).

1
Lactate Biosensors: Current Status and Future Outlook
Rassaei, L., Olthuis, W., Tsujimura, S., Sudholter, E. J. R., and van den Berg, A.
Anal. Bioanal. Chem., 406, 123 (2014).

解説 (articles in Japanese)

酵素に適したメソ孔/マクロ孔を有する多孔質炭素を用いたバイオセンサ・バイオ燃料電池
四反田功,辻村清也
電気化学,91,10- 18 (2023)

糖や乳酸を基質とする紙基板バイオ燃料電池
四反田功,レーヴ ノヤ,辻村清也
バイオインダストリー, 39, 11, 7-15 (2022)

ウェアラブルバイオ電池とヘルスモニタリングデバイスへの応用
四反田功、辻村清也
電気学会誌,142, 572-575 (2022)

電気化学センサ・バイオ燃料電池によるウェアラブルバイオセンシング技術
四反田功、辻村清也
電子情報通信学会誌,105, 225-232 (2022)

尿糖から安定して出力する自己発電型バイオセンサの開発
四反田功、辻村清也
クリーンエネルギー,31, 21-25 (2022)

ウェアラブルデバイス用電源としてのバイオ燃料電池
四反田功、辻村清也
ペトロテック,44, 844-850, (2021)

酵素機能電極の解析とバイオセンサ/バイオ燃料電池の評価手法
辻村清也
電気化学,88, 254- 261 (2020)

酵素型バイオ燃料電池の実現に向けた材料技術
辻村清也,四反田功
材料技術,37, 153-158 (2019)

体液成分の自己駆動リアルタイムモニタリング
四反田功、辻村清也
電気化学,87, 299-305 (2019)

マルチ銅オキシダーゼを用いた電気化学的酸素還元
辻村清也
触媒,60, 340-344 (2018)

バイオ燃料電池の基礎と多孔性炭素の構造制御による高性能酵素多孔性電極の開発
辻村清也
Adsorption News,31(4),12-18, (2018)

印刷型バイオ燃料電池の開発と自己駆動型センサへの応用
四反田功,相川達夫,辻村清也
ケミカルエンジニアリング,63(1), 14-19 (2018)

バイオ燃料電池の出力向上に向けた炭素電極の開発
辻村清也
炭素,265, 205-213 (2014)

酵素電池の開発と用途展望
辻村清也
polyfile,51(4), 18-21 (2014)

バイオ燃料電池の出力向上に向けた多孔質炭素電極の開発
辻村清也
ケミカルエンジニアリング,58(9), 52-57 (2013)

書籍(books)

"Graphene: Preparations, Properties, Applications and Prospects”, Elsevier (Tsinghua Univ Press), ISBN 978-0128195765, 620 pages
K. Takai, S. Tsujimura, F. Kang, M. Inagaki, (2019/Oct/16)

書籍(book chapters)

Shalini Devi, K.S., Tsujimura, S. (2023). Hybrid Semiconductor Photocatalyst Nanomaterials for Electrochemical Sensing Applications.
In: Prakash, J., Cho, J., Campos Janegitz, B., Sun, S. (eds) Multifunctional Hybrid Semiconductor Photocatalyst Nanomaterials. Advances in Material Research and Technology. Springer, Cham.
https://doi.org/10.1007/978-3-031-39481-2_8

近未来のデジタルヘルスを支える酵素バイオ技術: ~センサと発電~ ,監修: 冨永昌人,シーエムシー出版(2022/02/17) ISBN 978-4781316604
第V編 酵素バイオ発電の研究開発ならびに関連技術,第6章 糖や乳酸を基質とする紙基盤バイオ燃料電池 (pp. 358-368)
四反田功,レーヴ ノヤ,辻村清也

近未来のデジタルヘルスを支える酵素バイオ技術: ~センサと発電~ ,監修: 冨永昌人,シーエムシー出版(2022/02/17) ISBN 978-4781316604
第V編 酵素バイオ発電の研究開発ならびに関連技術,第8章 MgO鋳型細孔制御型炭素によるバイオ燃料電池 (pp. 377-386)
辻村清也,四反田功

"酵素トランスデューサーと酵素技術展開―酵素センサ&バイオ電池,そして酵素処理応用(食品,医薬,修復)(Enzyme Transducers and Evolutions of Enzymatic Technology―Enzyme Sensors, Bio Batteries and Novel Enzymatic Approaches (Food, Medicine, Restoring) ―)",監修: 三林浩二昭,シーエムシー出版(2020/03/11) ISBN 978-4-7813-1488-4
第13章 印刷によるウェアラブルバイオ燃料電池 (pp.125-135)
四反田功,辻村清也

"酵素トランスデューサーと酵素技術展開―酵素センサ&バイオ電池,そして酵素処理応用(食品,医薬,修復)(Enzyme Transducers and Evolutions of Enzymatic Technology―Enzyme Sensors, Bio Batteries and Novel Enzymatic Approaches (Food, Medicine, Restoring) ―)",監修: 三林浩二,シーエムシー出版(2020/03/11) ISBN 978-4-7813-1488-4
第15章 多孔質炭素を活用したバイオ燃料電池の高性能化(pp.144-152)
辻村清也、四反田功

"Bioelectrochemistry : Design and Applications of Biomaterials”",Serge Cosnier(Ed.)(March, 2019),ISBN 978-3-11-057052-6, de Gruyter GmbH, Berlin, Germany
chapter 4, Porous carbon materials for enzymatic fuel cells (pp. 59-76)
S Tsujimura

"炭素材料科学の進展”",117委員会(Ed.)(2018)
第6章:さらなる進展に向けて   グラフェンが教えてくれたこと 
稲垣道夫、高井和之、辻村清也

"プリンテッドエレクトロニクス実用化最前線(Frontiers of Printed Electronics for Industrialisation)",監修:牛島洋史,シーエムシー出版(2018/09/27) ISBN 978-4-7813-1347-4
第4章 IoTセンサとエネルギーハーベスター、 3 印刷型酵素バイオ燃料電池の開発とエネルギーハーベスターへの応用 (pp.88-95)
四反田功,辻村清也

"Molecular Technology: Energy Innovation",Yamamoto H., Kato, T.(Eds.)(2018/06), John Wiley & Sons
Molecular Design of Glucose Biofuel Cell Electrodes (pp.287-306)
M Holzinger, Y Nishina, A Le Goff, M Tominaga, S Cosnier, S Tsujimura

"2018年CPC研究会研究報 炭素材料の研究開発動向",CPC研究会(2018/06)
3.2 酵素型バイオ燃料電池への応用を目指した多孔質炭素の開発
辻村清也

"Functional Electrodes for Enzymatic and Microbial Bioelectrochemical Systems". Flexer, V. and Brun, N. (Eds.). World Scientific Publishing Europe Ltd.,ISBN 978-1-78634-353-6
Chap.10, Carbonaceous electrodes featuring tunable mesopores for use as enzyme electrodes. (pp. 381-399)
Tsujimura, S.

"ウェアラブル機器の開発とマーケット・アプリケーション・法規制動向",監修:三林 浩二,八村 大輔,R&D支援センター(2017/07/26),ISBN 978-4-905507-21-5
第2章 通信・ネットワーク・エネルギー技術、 第3節 ウェアラブルデバイスのためのバイオ燃料電池
四反田功,辻村清也

"生体情報センシングとヘルスケアへの最新応用 〜ウェアラブル、非侵襲・非接触計測、連続モニタリング〜",情報技術協会(2017/06/30) ISBN 978-4-86104-661-2
第14章 センサネットワーク向け電源、電池の開発動向、 第4節 印刷技術を用いたバイオ燃料電池の開発と自己駆動型センサへの応用
四反田功,辻村清也

"ヘルスケア・ウェアラブルデバイスの開発(Advances in Healthcare Wearable Devices)",監修: 菅沼克昭,シーエムシー出版(2017/03/10) ISBN 978-4-7813-1239-2
第4章 電源・電池、 5ウェアラブル電源としてのバイオ電池(pp.133-140)
辻村清也、四反田功

"バイオ電池の最新動向(Recent Progress in Biofuel Cells)", 加納健司監修,シーエムシー出版(2011/12/15) ISBN 978-4-7813-0474-8
第1章 酵素電極反応(pp. 1-24)
加納健司,辻村清也

"バイオ電池の最新動向(Recent Progress in Biofuel Cells)", 加納健司監修,シーエムシー出版(2011/12/15) ISBN 978-4-7813-0474-8
第2章 4 多孔性炭素電極(pp. 45-51)
辻村清也

"バイオ電池の最新動向(Recent Progress in Biofuel Cells)", 加納健司監修,シーエムシー出版(2011/12/15) ISBN 978-4-7813-0474-8
第3章 4 ボルタンメトリと対流ボルタンメトリによる評価(pp. 75-80)
辻村清也

"バイオ電池の最新動向(Recent Progress in Biofuel Cells)", 加納健司監修,シーエムシー出版(2011/12/15) ISBN 978-4-7813-0474-8
第4章 3 直接電子移動型バイオ電池(pp. 115-122)
辻村清也


教科書 (textbook)

応用微生物学 第3版,横田篤,大西康夫,小川順編,文英堂出版(2016/7/31)ISBN 978-4-8300-4131-0
第7章,3.2)センサ(pp.239-243)
辻村清也

その他 (others)

研究者応援エッセイ 働きやすいって?
辻村清也
電気化学, 87, 275(2019)

書評
辻村清也
Electrochemistry, 84(9), 749(2016)

ボルドー滞在記
辻村清也
Electrochemistry, 81(8), 661-662 (2013)

ページトップへ

KYOTO (before 15th Aug 2011, 54 papers)

論文

54(54)
Efficient Direct electron Transfer of PQQ-glucose dehydrogenase on carbon cryogel electrodes at neutral pH
Flexer, V., Durand, F., Tsujimura, S., Mano, N.
Anal. Chem., 83, 5721-5727 (2011).

53(53)
Ion Transport across Planar Bilayer Lipid Membrane Driven by D-Fructose Dehydrogenase-Catalyzed Electron Transport
Sasakura, K., Shirai, O., Hichiri, K., Goda-Tsutsumi, M., Tsujimura, S., and Kano, K.
Chem. Lett., 10 (4), 486-488 (2011)..

52(52)
Mediated Bioelectrocatalysis with Liposome for Multi-enzyme Linked System
Matsumoto, R., Kakuta, M., Goto, Y., Sugiyama, T., Sakai, H., Tokita, Y., Hatazawa, T., Tsujimura, S., Shirai, S., and Kano, K.
Phys. Chem. Chem. Phys., 12(42) 13904-12906 (2010).

51(51)
Flavin Mononucleotide Mediated Electron Pathway for Microbial U(VI) Reduction
Suzuki, Y., Kitatsuji, Y., Ohnuki, T., and Tsujimura, S.
Phys. Chem. Chem. Phys., 12(34) 10081-10087 (2010).

50(50)
X-ray Crystal Analysis of Bilirubin Oxidase from Myrothecium verrucaria at 2.3 A Resolution using a Twin Crystal
Mizutani, K., Toyoda, M., Kenta Sagara, K., Takahashi, N., Sato, A., Kamitaka, Y., Tsujimura, S., Nakanishi, Y., Sugiura, T., Yamaguchi, S., Kano, K., and Mikami, B.
Acta Crystallogra. F, F66, 765-770 (2010).

49(49)
Effects of Oxygen on Shewanella decolorationis NTOU1 Electron Transfer to Carbon Felt Electrodes
Li, S.-L., Freguia, S., Liu, S.-M., Cheng, S.-S., Tsujimura, S., Shirai, S., and Kano, K.
Biosens. Bioelectron., 25 (12), 2651-2656 (2010).

48(48)
Bioelectrocatalytic Endpoint Assays Based on Steady-state Diffusion Current at Microelectrode Array
Noda, T., Hamamoto, K., Tsutsumi, M., Tsujimura, S., Shirai, O., and Kano, K.
Electrochem. Commun., 12 (8), 839-842 (2010).

47(47)
Stopped-flow Kinetic Studies on Reductive Half-reaction of Histamine Dehydrogenase from Nocardioides simplex with Histamine
Tsutsumi, M., Tsujimura, S., Shirai, O., and Kano, K.
J. Biochem., 147 (2), 257-264 (2010).

46(46)
Electrochemical reaction of fructose dehydrogenase on carbon cryogel electrodes with controlled pore sizes
Tsujimura S., Nishina A., Hamano Y., Kano K., and Shiraishi S.
Electrochem. Commun., 12 (3), 446-449 (2010).

45(45)
Coulometric D-fructose biosensor based on direct electron transfer using D-fructose dehydrogenase
Tsujimura, S., Nishina, A., Kamitaka, Y., Kano, K.
Anal. Chem., 81, 9383-9387 (2009).

44(44)
Electron Transfer Pathways in Microbial Oxygen Biocathodes
Freguia, S., Tsujimura, S., and Kano, K.
Electrochimica Acta, 55 (3), 813-816 (2010).

43(43)
Flavins Contained in Yeast Extract are Exploited for Anodic Electron Transfer by Lactococcus lactis
Masuda, M., Freguia, S., Wang, Y.-F., Tsujimura, S., and Kano, K.
Bioelectrochemistry, 78 (2), 173-175 (2010).

42(42)
Lactococcus lactis catalyses electricity generation at microbial fuel cell anodes via excretion of a soluble quinone
Freguia, S., Masuda, M., Tsujimura, S., Kano, K.
Bioelectrochemistry, 76 (1/2), 14-18 (2009).

41(41)
Air Diffusion Biocathode with CueO as Electrocatalyst Adsorbed on Carbon Particle Modified Electrodes
Kontani. R., Tsujimura, S., Kano, K.
Bioelectrochemistry, 76 (1/2), 10-13 (2009).

40(40)
Modification of Spectroscopic Properties and Catalytic Activity of Escherichia coli CueO by Mutations of Methionine 510, the Axial Ligand to the Type I Cu
Kurose, S., Kataoka, K., Shinohara, N., Miura, Y., Tsutsumi, M., Tsujimura, S., Kano, K., and Sakurai, T.
Bull. Chem. Soc. Jpn., 82 (4), 504-508 (2009).

39(39)
Direct electrochemistry of histamine dehydrogenase from Nocardioides simplex
Tsutsumi, M., Tsujimura, S., Shirai, O., and Kano, K.
J. Electroanal. Chem., 625 (2), 144-148 (2009).

38(38)
A High-power Glucose/oxygen Biofuel Cell Operating under Quiescent Conditions
Sakai, H., Nakagawa, T., Sato, A., Tomita, T., Tokita, Y., Hatazawa, T., Ikeda, T., Tsujimura, S., Kano, K.
Energy Environ. Sci., 2 (1), 133-138 (2009).

37(37)
Coulometric bioelectrocatalytic reactions based on NAD-dependent dehydrogenases in tricarboxylic acid cycle
Fukuda, J., Tsujimura, S., and Kano, K.,
Electrochimica Acta, 54(2), 328-333 (2008).

36(36)
Bioelectrochemical Determination at Histamine Dehydrogenase-based Electrodes
Yamada, R. Fujieda, N., Tsutsumi, M., Tsujimura, S., Shirai, O., and Kano, K.
Electrochemistry, 76 (8) 600-602 (2008).

35(35)
Direct Electrochemistry of CueO and Its Mutants at Residues to and near Type I Cu for Oxygen-Reducing Biocathode
Miura, Y., Tsujimura, S., Kurose, K., Kamitaka, Y., Kataoka, K., Sakurai, T., and Kano, K.
Fuel Cells, 9(1), 70-78 (2009).

346(34)
Direct Electron Transfer Reaction of D-Gluconate 2-Dehydrogenase Adsorbed on Bare and Thiol-modified Gold Electrodes
Tsujimura, S., Abo, T., Matsushita, K., Ano, Y., and Kano, K.
Electrochemistry, 76 (8), 549-551 (2008).

33(33)
Amperometric Detection of Acetate Based on Mediated Bioelectrocatalysis using Escherichia coli Cells Cultivated with Acetate
Yung-Fu Wang, Y.-F., Tsujimura, S., and Kano, K.
Electrochemistry, 76 (8), 631-633 (2008).

32(32)
Pentacyanoferrate and Bilirubin Oxidase-bound Polymer for Oxygen Reduction Bio-cathode
Ishibashi, K., Tsujimura, S., and Kano, K.
Electrochemistry, 76 (8), 594-596 (2008).

31(31)
AC Impedance Analysis of Enzyme-functional Electrodes
Samukawa, T., Tsujimura, S., and Kano, K.
Bunseki Kagaku, 57 (8), 625-630 (2008).

30(30)
Electrochemical regulation of the end-product profile in Propionibacterium freudenreichii ET-3 with an endogenous mediator
Wang, Y.-F., Masuda, M., Tsujimura, S., and Kano, K.
Biotechnol. Bioeng., 101 (3), 579-586 (2008).

29(29)
CueO-immobilized Porous Carbon Electrode Exhibiting Improved Performance of Electrochemical Reduction of Dioxygen to Water
Tsujimura, S., Miura, Y., Kano, K.
Electrochim. Acta, 53 (18), 5716-5720 (2008).

28(28)
Thermodynamic Redox Properties Governing Half-reduction Characteristics of Histamine Dehydrogenase from Nocardioides simplex
Tsutsumi, M., Fujieda, N., Tsujimura, S., Shirai, S., and Kano, K.
Biosci. Biotechnol. Biochem., 72 (3), 786-796 (2008).

27(27)
Mediated Bioelectrocatalytic Reaction Using Monolayered Redox Polymer on a Glassy Carbon Electrode Surface and Effect of the Ionic Strength on the Catalytic Current
Tsujimura, S., Ishii, A., Abo, T., and Kano K.
J. Electroanal. Chem., 614, 67-72 (2008).

26(26)
Diffusion-controlled Oxygen Reduction on Multi-copper Oxidase-adsorbed Carbon Aerogel Electrodes without Mediator
Tsujimura, S., Kamitaka, Y., and Kano, K.
Fuel cells, 7 (6), 463-469 (2007).

25(25)
Self-excreted Mediator from Escherichia coli K-12 for Electron Transfer to Carbon Electrodes
Wang, Y.-F., Tsujimura, S., Cheng, S.-S., and Kano, K.
Appl. Microbial. Biotechnol., 76, 1439-46 (2007).

24(24)
Structure and Function of the Engineered Multicopper Oxidase, CueO from Escherichia coli - Deletion of the Methionine-Rich Helical Region Covering the Substrate Binding Site -
Kataoka, K., Komori, H., Ueki, Y., Konno, Y., Kamitaka, Y., Kurose, S., Tsujimura, S., Higuchi, Y., Kano, K., Seo, D., and Sakurai, T.
J. Mol. Biol., 373 (1), 141-152 (2007).

23(23)
Electrochemistry of D-Gluconate 2-Dehydrogenase from Gluconobacter frateurii on Indium Tin Oxide Electrode Surface
Tsujimura, S., Abo, T., Ano, Y., Matsushita, K., and Kano, K.
Chem. Lett., 36 (9), 1164-1165 (2007).

22(22)
Dependence of steady-state catalytic currents on the thickness of an enzyme-mediator-immobilized layer fabricated by layer?by-layer method
Ishii, A., Tsujimura, S., Kano, K.,
Bunseki Kagaku, 56 (6), 419-424 (2007).

21(21)
Fructose/dioxygen biofuel cell based on direct electron transfer-type bioelectrocatalysis
Kamitaka, Y., Tsujimura, S., Setoyama, N., Kajino, T., and Kano, K.
Phys. Chem. Chem. Phys., 9 (15), 1793-1801 (2007).

20(20)
Effects of axial ligand mutation of the type I copper site in bilirubin oxidase on direct electron transfer-type bioelectrocatalytic reduction of dioxygen
Kamitaka, Y., Tsujimura, S., Kataoka, K., Sakurai, T., Ikeda, T., and Kano, K.
J. Electroanal. Chem., 601 (1-2), 119-124 (2007).

19(19)
High Current Density Bio-electrolysis of D-Fructose at Fructose Dehydrogenase-adsorbed and Ketjen Black-modified Electrodes without a Mediator
Kamitaka, Y., Tsujimura, S., Kano, K.
Chem. Lett., 37 (2), 218-219 (2007).

18(18)
Bioelectrocatalytic Reduction of O2 Catalyzed by CueO from Escherichia coli Adsorbed on a Highly Oriented Pyrolytic Graphite Electrode
Miura, Y., Tsujimura, S., Kamitaka, Y., Kurose, S., Kataoka, K., Sakurai, T., and Kano, K.
Chem. Lett., 36 (1) 132-133 (2007).

17(17)
Osmium Complex Grafted on a Carbon Electrode Surface as a Mediator for a Bioelectrocatalytic Reaction
Tsujimura, S., Katayama, A., and Kano, K.
Chem. Lett., 35 (11) 1244-1245 (2006).

16(16)
Potential-step coulometry of D-glucose using novel FAD-dependent glucose dehydrogenase
Tsujimura, S., Kojima, S., Ikeda, T., Kano, K.
Anal. Bioanal. Chem., 386 (3), 645-651(2006).

15(15)
Escherichia coli-catalyzed Bioelectrochemical Oxidation of Acetate in the Presence of Mediators
Wang, Y.F., Cheng, S.S., Tsujimura, S., Ikeda, T., and Kano, K.
Bioelectrochemistry, 69, 74-81 (2006).

14(14)
Electrochemical Quartz Crystal Microbalance Study on Adsorption of Bilirubin Oxidase as a Catalyst in Bioelectrocatalytic Reduction of Dioxygen
Kamitaka, Y., Tsujimura, S., Ikeda, T., and Kano, K.
Electrochemistry, 74 (8), 642-644 (2006).

13(13)
Electron Transfer Kinetics between PQQ-dependent Soluble Glucose Dehydrogenase and Mediators
Okumura, N., Abo, T., Tsujimura, S., and Kano, K.
Electrochemistry, 74 (8), 639-641 (2006).

12(12)
Novel FAD-dependent glucose dehydrogenase to construct dioxygen-insensitive glucose biosensor
Tsujimura, S., Kojima, S., Kano, K., Ikeda, T., Sato,M., Sanada, H., and Omura, H.
Biosci., Biotech., Biochem., 70 (3), 654-659 (2006).

11(11)
Mediated Spectroelectrochemical Titration of Proteins for Redox Potential Measurements by a Separator-less One-compartment Bulk Electrolysis Method
Tsujimura, S., Kuriyama, A., Fujieda, N., Kano, K., and Ikeda, T.
Anal. Biochem., 337 (2), 325-331 (2005).

10(10)
Bilirubin Oxidase in Multiple Layer Catalyzes Four-electron Reduction of Dioxygen to Water Without Redox Mediators
Tsujimura, S., Kano, K., and Ikeda, T.
J. Electroanal. Chem., 576 (1), 113-120 (2005).

9(9)
Separator-less One-compartment Bulk Electrolysis with a Small Auxiliary Electrode and Its Application to Spectroelectrochemistry
Kuriyama, A., Arasaki, M., Fujieda, N., Tsujimura, S., Kano, K., and Ikeda, T.
Electrochemistry, 72 (7), 484-486 (2004).

8(8)
Kinetic Study of Direct Bioelectrocatalysis of Dioxygen Reduction with Bilirubin Oxidase at Carbon Electrodes
Tsujimura, S., Nakagawa, T., Kano, K., and Ikeda, T.
Electrochemistry, 72 (6) 437-439 (2004).

7(7)
Mediated Bioelectrocatalytic O2 Reduction to Water at Highly Positive Electrode Potentials near Neutral pH
Tsujimura, S., Kawaharada, M., Nakagawa, T., Kano, K., and Ikeda. T.
Electrochem. Commun., 5 (2), 138-141 (2003).

6(6)
Bilirubin Oxidase and [Fe(CN)6]3-/4- Modified Electrode Allowing Diffusion-controlled Reduction of O2 to Water at pH 7.0
Nakagawa, T., Tsujimura, S., Kano, K., and Ikeda, T.
Chem. Lett., 32 (1), 54-55 (2003).

5(5)
Electrochemical Oxidation of NADH Catalyzed by Diaphorase Conjugated with Poly-1-vinylimidazle Complexed with Os(2,2'-dipyridylamine)2Cl
Tsujimura, S., Kano, K., and Ikeda, T.
Chem. Lett., 31(10), 1022-1023. (2002)

4(4)
Glucose/O2 Biofuel Cell Operating at Physiological Conditions
Tsujimura, S., Kano, K., and Ikeda, T.
Electrochemistry, 70 (12), 940-942 (2002).

3(3)
Photosynthetic Bioelectrochemical Cell Utilizing Cyanobacteria and Water-Generating Oxidase
Tsujimura, S., Wadano, A., Kano, K. and Ikeda, T.
Enz. Microbial Tech., 29 (4-5), 225-231 (2001).

2(2)
Bioelectrocatalysis-based Dihydrogen/Dioxygen Fuel Cell Operating at Physiological pH
Tsujimura, S., Fujita, M., Tatsumi, H., Kano, K., and Ikeda, T.
Phys. Chem. Chem. Phys., 3(3), 1331-1335 (2001).

1(1)
Bioelectrocatalytic Reduction of Dioxygen to Water at Neutral pH Using Bilirubin Oxidase as an Enzyme and 2,2'-Azinobis (3-Ethylbenzothiazolin-6-Sulfonate) as an Electron Transfer Mediator
Tsujimura, S., Tatsumi, H.,Ogawa, J., Shimizu, S., Kano, K., and Ikeda, T.
J. Electroanal. Chem., 496 (1/2), 69-75 (2001).


 

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解説

酵素バイオ電池
辻村清也, 加納健司
化学と教育, 59 (3), 124-127 (2011).

グルコースの生物電気化学的酸化反応と血糖センサーへの応用
辻村清也
ビタミン, 84 (5/6), 261-264 (2010).

バイオ燃料電池の研究開発
辻村清也
化学工業, 61(2), 9-14 (2010).

酵素を使った燃料電池用電極
辻村清也,加納健司
機能材料, 29(9), 44-57 (2009).

マルチ銅酵素を機軸とするカソード触媒
辻村清也,加納健司
燃料電池, 9(1), 62-71 (2009).

使える解析テクニック!具体例で説明する電気化学測定法  分極曲線・サイクリックボルタンメトリー(5)生物電気化学
辻村清也,白井 理
Electrochemistry, 77(6), 486-492 (2009).

次世代型エネルギー変換装置バイオ電池―クエン酸回路内酵素反応と電極反応の共役系
辻村清也
C & I Commun., 34(1), 7-9 (2009).

酵素バイオ電池の最近の展開
辻村清也,加納健司
GS Yuasa Technical Report, 5 (2), 1-6 (2008).

バイオ電池のための酵素触媒機能電極
辻村清也,加納健司
Electrochemistry, 76 (12), 900-909 (2008). 

今日の話題:酸化還元酵素を電極触媒に利用する 糖−酸素燃料電池など,新規エネルギー変換デバイスの開発に期待
辻村清也
化学と生物, 45(1), 7-9(2007)

生体機能を利用する次世代型エネルギー変換装置
辻村清也,加納健司
化学工業, 58(1), 33-38(2007).

酵素触媒定常電流 Steady-state bioelectrocatalytic current
辻村清也
Review of Polarography, 52 (2), 81-89 (2006).

バイオ燃料電池
辻村清也, 加納健司
電池技術, 18, 115-164 (2006).

生体物質の電気分析化学
辻村清也,加納健司
ぶんせき, 2005 (2), 90-95 (2005).

光合成呼吸電池の可能性
辻村清也、加納健司、池田篤治
エコインダストリー, 10(4), 12-18 (2005).

特集にあたって−バイオ電池の最新動向
辻村清也、加納健司、池田篤治
エコインダストリー, 10(4), 5-11 (2005).

バイオ電池のしくみ
辻村清也,加納健司,池田篤治
ケミカルエンジニヤリング, 49 (9), 717-722 (2004).

バイオ電池の実用化が開く新しい可能性
辻村清也, 加納健司, 池田篤治
Material Stage, 3 (12), 60-65 (2004).

バイオ電池 しくみと応用
辻村清也, 加納健司, 池田篤治
バイオサイエンスとインダストリー, 62 (3), 175-178 (2004).

生物の仕組みに学ぶ燃料電池
辻村清也, 加納健司, 池田篤治
化学, 57 (2), 22-24, (2002).

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書籍

“酵素利用技術体系―基礎・解析から改変・高機能化・産業利用まで―”, 小宮山 真監修, エス・ティー・エス (2010/4) ISBN 978-4-86043-271-3
第3章 第1節,酵素の酵素電気化学的特性評価(pp.106-111)
辻村清也, 加納健司

“産業酵素の応用技術と最新動向”,シーエムシー出版,(2009/3) ISBN 978-4-7813-0108-2
バイオ電池(pp. 246-256)
辻村清也,加納健司

“電気化学測定/解析 テクニック & 事例集 ―電池/キャパシタ/めっき/腐食/センサ―”,情報機構 (2009/2) ISBN 978-4-904080-20-7
バイオ燃料電池(pp. 391-400)
辻村清也,加納健司

“小型燃料電池の最新技術”,監修:神谷信行,梅田 実,シーエムシー出版,(2008/10)
バイオ燃料電池(pp. 209-219)ISBN 978-4-7813-0054-2
池田篤治,辻村清也

"バイオ電気化学の実際―バイオセンサ・バイオ電池の実用展開―", 池田篤治監修, シーエムシー出版 (2007/3) ISBN978-4-88231-679-4
第18章, 直接電子移動型バイオ電池(pp. 290-302)
辻村清也, 加納健司

“ユビキタスエネルギーの最新技術”,監修:境哲男,小林哲彦,シーエムシー出版(2006/5)ISBN4-88231-565-3
生物燃料電池の開発状況と課題(p 187-193)
池田篤治, 辻村清也, 加納健司

"電池革新が拓く次世代電源", エス・ティー・エス(2006/1/31)ISBN4-86043-102-2
1,1 バイオ燃料電池のメカニズムと開発の現状(pp. 17-26)
辻村清也,加納健司

エコバイオエネルギーの最前線-ゼロエミッション型社会を目指して-(Frontier of Eco-Bioenergy-Construction of Sustainable Society Oriented Zero Emission, K. Ueda and A. Kondo Eds., CMC Publishing CO.,LTD)(2005/9)ISBN 4-88231-522-X C3058
バイオ電池の最新動向
辻村清也、加納健司、池田篤治
光合成呼吸電池の可能性
辻村清也、加納健司、池田篤治
 

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