ライフサイエンスコーパス: biofuel cell

1 ased bioelectrodes within the framework of a biofuel cell.

2 roduction catalyst in a photoelectrochemical biofuel cell.

3 e employed as the bioanode in a pyruvate/air biofuel cell.

4 sed as the cathode in a photoelectrochemical biofuel cell.

5 - and membrane-free enzymatic glucose/oxygen biofuel cell.

6 advantages of both the glucose biosensor and biofuel cell.

7 yme electrodes were integrated to a DET-type biofuel cell.

8 stors, affinity-based biosensing, as well as biofuel cells.

9 ntually new photoelectrocatalytic systems or biofuel cells.

10 ical catalysts with potential application in biofuel cells.

11 old higher power output than other leukocyte biofuel cells.

12 and power density of pyruvate/air enzymatic biofuel cells.

13 emical applications including biosensors and biofuel cells.

14 sed electrocatalysts for oxygen reduction in biofuel cells.

15 tive for advanced biosensors, as well as for biofuel cells.

16 c electrodes for enzyme-based biosensors and biofuel cells.

17 ent delivery vehicles, and as biosensors and biofuel cells.

18 se monitoring biosensors and high performing biofuel cells.

19 o aid in the development of energy efficient biofuel cells.

20 ion of biosensors, bioanodes, biocathodes or biofuel cells.

21 ation of a novel bioanode for ethanol-oxygen biofuel cells.

22 enhance the enzyme functions in implantable biofuel cells.

23 yme immobilization enhancement in glucose/O2 biofuel cells.

24 energy conversion capability in ethanol/air biofuel cells.

25 in LbL thin films relevant to biosensors and biofuel cells.

26 igher than for previous carbon nanotube yarn biofuel cells.

27 d electrodes and their use as biosensors and biofuel cells.

28 as a molecular "wire" in oxygen cathodes for biofuel cells.

29 eating efficiently engineered biosensors and biofuel cells.

30 er 24 h), compared with previous unprotected biofuel cells.

31 ling coatings, food packaging materials, and biofuel cells.

32 electrodes for application to biosensors or biofuel cells.

33 production of cost-effective biosensors and biofuel cells.

34 plication to glucose oxidising biosensors or biofuel cells.

35 nic biosensors, thin-film protein arrays, or biofuel cells.

36 ecular bioelectronic devices, biosensors and biofuel cells.

37 Glucose oxidase is of particular interest in biofuel cell and biosensor applications, and the approac

38 unds may range from electrons or hydrogen in biofuel cell and environmental applications to complex d

39 this HTPS/GOx-based electrode in long-lived biofuel cells and amperometric biosensors.

40 catalysis promises to be valuable for future biofuel cells and biosensors.

41 sensor opens new doors for implementation of biofuel cells and capacitor circuits for medical diagnos

42 tems can find applications in biosensors and biofuel cells and for studying electrochemically the cat

43 atalysts of H(2) oxidation and production in biofuel cells and photoelectrochemical cells.

44 riety of applications, including implantable biofuel cells and self-powered sensors.

45 for evaluating and characterizing enzymatic biofuel cells and their corresponding bioanodes and bioc

46 g electrochemical paper-based biosensors and biofuel cells and to identify, at the light of newly acq

47 l and biomechanical energy using sweat-based biofuel cells and triboelectric generators, and regulati

48 y of bioelectrocatalysts for use in sensors, biofuel cells, and enzymatic electrodes.

49 in the development of biosensors, enzymatic biofuel cells, and other bioelectrocatalytic application

50 as employed to prepare the enzyme anodes for biofuel cells, and the EAPC anode produced 7.5-times hig

51 s a promising enzyme for the construction of biofuel cell anodes and biosensors capable of oxidizing

52 evelopment of glucose biosensors and glucose biofuel cell anodes working at physiological or neutral

53 de dehydrogenase (ADH and AldDH) enzymes for biofuel cell applications.

54 Biofuel cells are bio-electrochemical devices, which are

55 Enzymatic biofuel cells are bioelectronic devices that utilize oxi

56 Glucose biofuel cells are capable to generate sufficient power f

57 Our biscrolled yarn biofuel cells are woven into textiles having the mechani

58 ) at anode and cathode, respectively, in the biofuel cell arrangement.

59 lts toward the development of an implantable biofuel cell as an autonomous energy conversion device f

60 The biofuel cell assembly produced a linear dynamic range of

61 - and membrane-free enzymatic glucose/oxygen biofuel cell based on transparent and nanostructured con

62 This study demonstrates the combination of a biofuel cell (BFC) and an animal brain stimulator (ABS)

63 ticle (AuNP)-based mediatorless sugar/oxygen biofuel cell (BFC) operating in neutral sugar-containing

64 mart Cup platform that harvests energy via a biofuel cell (BFC) that captures and converts metabolite

65 protein, while it is powered via paper-based biofuel cell (BFC) that extracts the energy from the ana

66 attractive new candidate for application in biofuel cells (BFCs) and biosensors.

67 Wearable biofuel cells (BFCs) are being widely studied as self-po

68 ntegration of supercapacitors with enzymatic biofuel cells (BFCs) can be used to prepare hybrid devic

69 luation of a self-powered biosensor based on biofuel cells (BFCs) for dCO(2) measurements are describ

70 nge for the broad application of implantable biofuel cells (BFCs) is to achieve inorganic-organic com

71 Enzymatic biofuel cells (BFCs) may power implanted medical devices

72 n is achieved through a self-powered glucose biofuel cell/biosensor integrated into a circuit that pe

73 These findings show that glucose biofuel cells can be further investigated in the develop

74 hrymal liquid, fully support our belief that biofuel cells can be used as electrical power sources fo

75 Enzymatic biofuel cells can generate electricity directly from the

76 A microscale membrane-less biofuel cell, capable of generating electrical energy fr

77 The specific application of the system is a biofuel cell cathode, but this protein-engineering appro

78 of a compartment-less miniature glucose-O(2) biofuel cell, comprised only of two bioelectrocatalyst-c

79 As a proof of biofuels cell conception, the bioanode was combined with

80 Here we report on the first implanted biofuel cell continuously operating in a snail and produ

81 the first prototype of a future implantable biofuel cell controlled by complex biochemical reactions

82 ort our proposition that an ascorbate/oxygen biofuel cell could be a suitable power source for glucos

83 Additionally, adapting the biofuel cell design to other neurotransmitters can poten

84 struction of an amperometric biosensor and a biofuel cell device, which are based on a thermophilic v

85 sed biocathode to generate 270 uW/cm(2) in a biofuel cell device.

86 Enzymatic biofuel cell (EBFC) operates at ambient temperature and

87 Enzymatic biofuel cell (EBFC)-based self-powered biochemical senso

88 Enzymatic biofuel cells (EBFCs) are capable of generating electric

89 Enzymatic biofuel cells (EBFCs) can generate energy from metabolit

90 edox polymer-mediated glucose/O(2) enzymatic biofuel cells (EBFCs) were prepared with an additional C

91 MCOs have been used to elaborate enzymatic biofuel cells (EBFCs), a subclass of fuel cells in which

92 The enzymatic biofuel cell (EFC) generated an open circuit potential o

93 PD in fabrication of miniature biosensor and biofuel cell electrodes are described and discussed.

94 imals, enzyme-containing battery electrodes, biofuel cell electrodes, and biosensors are often damage

95 nes was quantified at the levels expected in biofuel cell electrodes.

96 When operated in 45 mM glucose, the biofuel cell exhibited an open circuit voltage and power

97 ysiological glucose concentration (5mM), the biofuel cell exhibits open circuit voltage and power den

98 neration by flow through miniature enzymatic biofuel cells fed with an aerated solution of glucose an

99 of flexible, miniaturized probes inspired by biofuel cells for monitoring synaptically released gluta

100 Fundamental part of each Glucose biofuel cell (GBFC) is two bioelectrodes which their sur

101 rategy to boost the power density of glucose biofuel cells (GBFCs) biocathodes.

102 The biofuel cell generated maximum power output of 130microW

103 -treat" system that is based on an enzymatic biofuel cell has been developed.

104 Implantable biofuel cells have been suggested as sustainable micropo

105 f-powered sensing system, driven by a hybrid biofuel cell (HBFC) with carbon paper discs coated with

106 In this study, a supercapacitor/biofuel cell hybrid device was prepared by the immobilis

107 The specific power densities of the biofuel cell implanted in a female Blaberus discoidalis

108 Alternatively, biofuel cells in which whole cells or isolated redox enz

109 A biofuel cell incorporating a bienzymatic trehalase|gluco

110 in the relevant sub-sections of biosensors, biofuel cells, intracorporeal neural probe, dielectropho

111 he input voltage (as low as 0.25 V) from the biofuel cell is converted to a stepped-up power and char

112 de in a membraneless enzyme-based glucose/O2 biofuel cell is further evaluated.

113 lectron transfer (DET) based sulphite/oxygen biofuel cell is reported that utilises human sulphite ox

114 The present biofuel cell is the first prototype of a future implanta

115 seless and membraneless miniature glucose-O2 biofuel cell, is rapidly damaged by serum urate at its o

116 scussed including electrochemical batteries, biofuel cells, lithium-ion batteries, supercapacitors, a

117 A switchable biofuel cell logically controlled by immune signals was

118 tions, including electrochemical biosensors, biofuel cells, neural probes, and dielectrophoretic cell

119 This study focuses on an improved biofuel cell operating on phorbol myristate acetate (PMA

120 ery few examples of abiotic and enzyme-based biofuel cells operating in animals in vivo have been rep

121 Biofuel cell operation in human serum provides high area

122 s the advancements in the field of enzymatic biofuel cells over the last 30 years.

123 aneless glucose and air photoelectrochemical biofuel cell (PBFC) with a visible light assisted photob

124 Enzyme-based biofuel cells possess several positive attributes for en

125 The contact lens biofuel cell presented here is a step toward achieving s

126 In the optimum conditions the biofuel cell produced the power density of 1.713 mW cm(-

127 he fibers in the grape leads to an operating biofuel cell producing 2.4 micro W at 0.52 V.

128 that our separator-free carbon nanotube yarn biofuel cells provide an open-circuit voltage of 0.70 V,

129 However, enzyme-based biofuel cells remain limited by short lifetimes, low pow

130 Biofuel cell researchers have studied multienzyme system

131 The biofuel cell structure-based glucose sensor synergizes t

132 or glucose oxidation is of great interest in biofuel cell technology because the enzyme are unaffecte

133 Recent advances in biofuel cell technology have addressed these deficiencie

134 Contact lens biofuel cell testing was performed in a synthetic tear s

135 to a biocathode to form an ascorbic acid/O2 biofuel cell that functions as a self-powered biosensor.

136 Biofuel cells that generate electricity from glucose in

137 physiological pH 7.3 electrolyte battery or biofuel cell, the O2 cathode should operate at, or posit

138 the feasibility of POx-based biosensors and biofuel cells, the enzyme electrodes were prepared using

139 illustrates the enhancement of an enzymatic biofuel cell through the hybrid multi-catalytic systems,

140 es were observed in the photoelectrochemical biofuel cell using either hydrogenase or platinum cathod

141 We show the performance of a biofuel cell using these modified bacteria at the anode,

142 The maximum power densities of biofuel cells using CA, EC and EPC electrodes without BQ

143 Biofuel cells utilize vegetable and animal fluids (e.g.

144 The biofuel cell was also switched OFF by another biochemica

145 A contact lens biofuel cell was fabricated using buckypaper electrodes

146 The cathode used in the biofuel cell was modified with a polymer-brush functiona

147 ted for the oxygen reduction, and the entire biofuel cell was switched ON.

148 me in electrochemical glucose biosensors and biofuel cells, was measured between pH 4.5 and 8.5 using

149 ently used in a conventional two-compartment biofuel cell where the power density output was recorded

150 Enzymatic biofuel cells, which replace expensive metal catalysts w

151 The snail with the implanted biofuel cell will be able to operate in a natural enviro

152 nd electrode configuration in biosensors and biofuel cells will be discussed.

153 de of a membrane-less glucose/O(2) enzymatic biofuel cell with a maximum power density of 22 muW cm(-

154 ity obtained from the continuously operating biofuel cell with a maximum power output of 0.086microW/

155 An enzyme-based biofuel cell with a pH-switchable oxygen electrode, cont

156 l for maximum power output of a hypothetical biofuel cell with a planar cathode and a reversible hydr

157 -2) , a new efficiency record for a hydrogen biofuel cell with base metal catalysts.

158 We propose the use of this bioanode in biofuel cells with increased current density and coulomb

159 flexible self-powering unit in the form of a biofuel cell, with a flexible electronic device - a circ

160 eview highlights the progress on implantable biofuel cell, with focus on the nano-carbon functionaliz