ライフサイエンスコーパス: electrochemical

1 ndwidth' by using biomolecules and providing electrochemical access to redox-based cell signals and b

2 h as heat, solvent adsorption/desorption, or electrochemical action (in systems such as carbon nanotu

3 y sensitive response, demonstrating improved electrochemical activity towards ascorbic acid.

4 d the suitability of these probes for use in electrochemical advanced oxidation processes (EAOPs), du

5 able biosensor for multiple and simultaneous electrochemical analyses in a single device remains a ch

6 For this purpose, we performed electrochemical analysis and quantum-mechanical calculat

7 The electrochemical analysis confirms the enhanced performan

8 a commercial impedance analyzer through the electrochemical analysis of a highly sensitive biosensor

9 and a microelectrode probe for the localized electrochemical analysis of the surface.

10 Electrochemical analysis revealed a pH-dependent and rem

11 sed (bio)sensors would open new horizons for electrochemical analysis.

12 eveloped a novel and cost effective portable electrochemical analyzer for the measurement of NO2(-) i

13 Here we use a combination of electrochemical and biochemical methods to assess the re

14 ) probe compound for the characterization of electrochemical and catalytic systems.

15 to morphology-dependent heterogeneity in the electrochemical and chemical stability of these films.

16 re analyzed by HPLC with coupled coulometric electrochemical and fluorescence detection, and PLP is a

17 Electrochemical and fluorescence/chemiluminescence-quenc

18 Whereas it does not significantly influence electrochemical and linear optical properties, the orien

19 erimental and theoretical description of the electrochemical and optical properties of Ni and NiFe ox

20 ne foil is designed and constructed for both electrochemical and photoelectrochemical water splitting

21 ecular docking to show both enantioselective electrochemical and photoluminescence quenching capabili

22 Based on electrochemical and photophysical measurements, when a p

23 or TCNE and TCNQ units on the photophysical, electrochemical, and computational studies was investiga

24 This opto-electrochemical approach is used to derive mechanistic i

25 Among other analytical methods, electrochemical approaches have been successfully employ

26 Electrochemical aptamer-based (E-AB) sensors offer advan

27 The electrochemical, aptamer-based (E-AB) sensor platform pr

28 xpensive, excellent, sensitive and selective electrochemical aptasensor based on sandwich architectur

29 conformation change was used to fabricate an electrochemical aptasensor via self-assembly of thiol-mo

30 This study focused on developing an electrochemical array device that could be utilized to c

31 Here, we report a simple and yet efficient electrochemical assay for the total activity of cellulas

32 lopment of low-cost, Si wafer-based IREs for electrochemical ATR-SEIRAS applications.

33 Electrochemical-based analytical methods offer an effect

34 In addition, the electrochemical behavior of a C60-phosphine borane amino

35 The electrochemical behavior of rGO-PGEs was examined by cyc

36 irectional approach that enables the complex electrochemical behavior of ZIFs to be unraveled.

37 nanocomposites were characterized, and their electrochemical behavior towards SY was investigated.

38 These results reveal that the use of this electrochemical bio-sensor may provide a potential platf

39 ified with capturing biomolecule for on-chip electrochemical biosensing.

40 work, we developed an aptamer/graphene-based electrochemical biosensor for on-step, sensitive and low

41 synthesized to fabricate a highly sensitive electrochemical biosensor for paraoxon as a model of org

42 s a novel approach based on a four-electrode electrochemical biosensor for the detection of tau prote

43 his paper focuses on developing a label-free electrochemical biosensor with high sensitivity for PoC

44 ed using a simple, monolithic, two-electrode electrochemical biosensor.

45 , sensitivity, selectivity and challenges of electrochemical biosensors are discussed in this review.

46 Electrochemical biosensors based on screen-printed elect

47 zyme-modified pencil leads (PL) as effective electrochemical biosensors for robotic substrate quantif

48 he development of highly sensitive molecular electrochemical biosensors.

49 The robust electrochemical C-H functionalization was characterized

50 Li ion battery (LIB) and electrochemical capacitor (EC) are considered as the mos

51 Here, we report our investigations of electrochemical carbon dioxide reduction over CuAg bimet

52 voltammetry was used to initially probe the electrochemical catalytic behavior.

53 taken to enhance understanding of SICM as an electrochemical cell and to enable the interpretation an

54 cript we describe a new, hermetically sealed electrochemical cell that allows for electrode rotation

55 mensions of the conventional three electrode electrochemical cell to the microscale.

56 kept at 11.0 +/- 1.3 mA/m(2) in a microbial electrochemical cell, and isotopic experiments supported

57 ue of 2.38 x 10(-6) cm(2)/s using a standard electrochemical cell.

58 electrode chip was comparable to a standard electrochemical cell.

59 Light-emitting electrochemical cells (LECs) with the thermally activate

60 used in the active layers in light-emitting electrochemical cells (LECs).

61 Unlike light emission from electrochemical cells or solid-state films containing Ru

62 We report the synthesis, UV-vis absorption, electrochemical characterisation, and DFT studies of fiv

63 nanostructured surface area as confirmed by electrochemical characterisation, as well as scanning el

64 ys (MEAs) were characterized for their basic electrochemical characteristics and used for in vivo mea

65 olve organic perovskite films and thus allow electrochemical characterization of the electronic struc

66 In addition to energetics, controlled electrochemical charge injection experiments in the nons

67 eaction partner in the rate-limiting step of electrochemical CO2 reduction catalysis mediated by plan

68 Electrochemical cobalt-catalyzed C-H functionalizations

69 Electrochemical communication between two photobioelectr

70 Electrochemical, computational, and spectroscopic studie

71 Electrochemical conversion of CO2 into energy-dense liqu

72 higher-conducting states arise from in situ electrochemical conversion of the dative Au<--N bond int

73 advancements in designing and development of electrochemical cyt c biosensors for the quantification

74 aphite electrodes (PGEs) for construction of electrochemical cytosensor was demonstrated for the firs

75 The relevance of the multi-parameter electrochemical data for accurate discrimination between

76 molecular orbital computations, and optical/electrochemical data indicate that the SBT core is compl

77 amines are analyzed by HPLC with coulometric electrochemical detection (ED), pterins are analyzed by

78 lator, the most common of which is HPLC with electrochemical detection (HPLC-ECD).

79 roposed study, for the first time, sensitive electrochemical detection of a breast cancer biomarker m

80 tic solid phase microextraction coupled with electrochemical detection of caffeine.

81 atin fragment-21-1 (anti-Cyfra-21-1) for the electrochemical detection of Cyfra-21-1.

82 Also, the recent trends in electrochemical detection of heavy metal ions with vario

83 We demonstrate its potential use toward the electrochemical detection of nitroaromatic compounds 2,4

84 Electrochemical detection of Pam3CSK4, a synthetic triac

85 Here, we validate this electrochemical detection strategy using clinical isolat

86 lds can enhance hydrocarbon conversion in an electrochemical device at lower than normal reforming te

87 Microbial fuel cells (MFCs) are novel bio-electrochemical device for spontaneous or single step co

88 he ESM data show that poly(3-hexylthiophene) electrochemical devices exhibit voltage-dependent hetero

89 Electrolytes, which are a key component in electrochemical devices, transport ions between the sulf

90 fficient proton-exchange membranes (PEM) for electrochemical devices.

91 A novel electrochemical disposable nucleic acid biosensor for si

92 erior in comparison with previously reported electrochemical DNA hybridization sensors for Dengue vir

93 erein, we address the recent developments of electrochemical DNA methylation detection approaches.

94 t chromium (Cr(VI)) as an electrocatalyst in electrochemical DNA sensing.

95 In addition, the electrochemical DNA sensors provide direct electronic si

96 eV), solid state luminescence and reversible electrochemical doping creating midgap (NIR absorbing) p

97 f charge transport properties, and potential electrochemical doping of the films with in situ diagnos

98 h capacitive currents caused by an increased electrochemical double layer as well as enhanced catalyt

99 Electrochemical dual-pulse plating with sequential galva

100 By applying an electrochemical (EC) gate voltage to the molecule, we sw

101 It is known that electrochemical energy can be harvested from mammalian c

102 Aqueous electrochemical energy storage devices using potassium-i

103 hydrophilic surface show great potential in electrochemical energy storage systems including lithium

104 chemistry are attractive for next-generation electrochemical energy storage.

105 structures from earth-abundant elements for electrochemical energy storage.

106 scribe the structural evolution of Pt in the electrochemical environment.

107 Electrochemical etching is used to slice off single-crys

108 Nanoporous silicon produced by electrochemical etching of highly B-doped p-type silicon

109 contradict an alternative pathway involving electrochemical evolution of chlorine gas followed by Cl

110 catalysis is a pivotal element in the (photo)electrochemical generation of solar fuels.

111 The electrochemical genosensor was able to detect as low as

112 s in the design and fabrication of efficient electrochemical genosensors based on carbon nanostructur

113 substrate accumulation depend on the proton electrochemical gradient (DeltamuH(+)) across the inner

114 nvolves the movement of protons down a large electrochemical gradient via ATP synthase located on the

115 nduct cations of multiple valencies down the electrochemical gradient.

116 rine nucleosides utilizing Na(+) and/or H(+) electrochemical gradients.

117 templates in conjunction with site-specific electrochemical growth to create these structures, and i

118 catalytic activity, fluorescent quencher and electrochemical, high surface area, and oxygen transfer

119 hesized and used as catalytic electrodes for electrochemical hydrogen evolution, exhibiting a high an

120 In this work, a portable electrochemical immunosensor capable of detecting HA wit

121 A novel label-free electrochemical immunosensor for neutrophil gelatinase-a

122 Along with these attractive features, this electrochemical immunosensor is able to specifically rec

123 probe in the development of HCV core antigen electrochemical immunosensor.

124 O modified-SPEs to fabricate a sandwich-type electrochemical immunosensor.

125 ral overview of the possible applications of electrochemical immunosensors to the food, environmental

126 harge recombination for RSQ2 was revealed by electrochemical impedance analysis (EIS) and open-circui

127 An efficient electrochemical impedance genosensing platform has been

128 ished by scanning electron microscope (SEM), electrochemical impedance spectroscopy (EIS) and cyclic

129 ing two types of electrochemical techniques; electrochemical impedance spectroscopy (EIS) and Mott-Sc

130 gene, with an aM detection limit, utilizing electrochemical impedance spectroscopy (EIS) is presente

131 cancer cell detection were analyzed by using electrochemical impedance spectroscopy (EIS) method.

132 The hybridisation events were monitored by electrochemical impedance spectroscopy (EIS).

133 In combination with electrochemical impedance spectroscopy and neutron diffr

134 itoring of the redox couple Fe(2+)/Fe(3+) by electrochemical impedance spectroscopy and square wave v

135 results obtained from cyclic voltammetry and electrochemical impedance spectroscopy studies showed th

136 FeFe]-hydrogenases have been investigated by electrochemical impedance spectroscopy-resolving factors

137 at variable temperature and humidity, using electrochemical impedance spectroscopy.

138 The antioxidant power established by electrochemical index presented good correlation with th

139 s demonstrate that 3-NT can be used as a new electrochemical indicator, which is able to detect hybri

140 ) in order to provide both spectroscopic and electrochemical information on the very same location of

141 r cage by reduction and oxidation processes, electrochemical information storage devices can be desig

142 The study and better understanding of the electrochemical interface is important for designing bet

143 o yield highly dynamic information about the electrochemical interface.

144 d identify chemical products at solid-liquid electrochemical interfaces.

145 e high resolution of Mt/AFM-SECM enables the electrochemical interrogation of several hundreds of ind

146 Detailed electrochemical, kinetic and vibrational spectroscopic s

147 voltammetry) indicated a surface-controlled electrochemical kinetics of the resorufin reduction on t

148 areas with aqueous feedstock solutions using electrochemical liquid phase epitaxy (ec-LPE) at low tem

149 rovides a comprehensive understanding of the electrochemical lithiation process and mechanism of alph

150 omplementary measurements using differential electrochemical mass spectrometry.

151 We describe an electrochemical measurement technique that enables bioel

152 a, approximately 4.7 times), as validated by electrochemical measurements and first-principles calcul

153 Our electrochemical measurements in clinical serum from cloz

154 lation lifetime spectroscopy correlated with electrochemical measurements show that the formation of

155 Community analysis and electrochemical measurements suggested that electrochemi

156 ls on this surface was also characterized by electrochemical measurements.

157 Herein, we report an electrochemical method for the direct, highly sensitive

158 In this study, an enzyme-based electrochemical method was developed for the detection o

159 An electrochemical methodology for the characterization of

160 Electrochemical methods allow fast and inexpensive analy

161 Additionally, electrochemical methods are highly amenable to miniaturi

162 However, application of electrochemical methods for the purpose of high-throughp

163 (3+):Ce(4+) are produced and are analyzed by electrochemical methods.

164 cterized using confocal laser microscopy and electrochemical methods.

165 intrinsic) in copper sulfide nanocrystals by electrochemical methods.

166 nvolved the fabrication of nano-hybrid based electrochemical micro fluidic paper-based analytical dev

167 croelectrode used as the tip in the scanning electrochemical microscope (SECM).

168 d using cyclic voltammetry (CV) and scanning electrochemical microscopy (SECM) approach curves and im

169 Scanning electrochemical microscopy (SECM) can map surface charac

170 higher than previously reported for scanning electrochemical microscopy (SECM) imaging of molecular m

171 h Raman microscopy is combined with scanning electrochemical microscopy (SECM) in order to provide bo

172 ubstrate collection (TG/SC) mode of scanning electrochemical microscopy (SECM).

173 ty in individual cancer cells using scanning electrochemical microscopy (SECM).

174 um diameter each) for use as a dual scanning electrochemical microscopy probe.

175 oving the spatial resolution of fluorescence electrochemical microscopy.

176 as a thin film on an Au film electrode in an electrochemical miniaturized microfluidic cell.

177 s obtained here using the developed portable electrochemical nitrite analyzer were also compared with

178 can simultaneously exhibit field-effect and electrochemical operation regimes, with the operation mo

179 as receptors in biosensing platforms such as electrochemical, optical and mass biosensors to detect v

180 ntibodies in vicinity to transducers such as electrochemical, optical and piezoelectric is presented.

181 These issues are addressed by electrochemical oxidation methods, but such approaches t

182 radical cation 3(+*) (generated using online electrochemical oxidation of 3), is successfully establi

183 metric expansion due to ion uptake following electrochemical oxidation of the semiconductor.

184 Chemical and electrochemical oxidation or reduction of our recently r

185 l calculations to describe the mechanisms of electrochemical oxidation, and we selected the two metho

186 e (ERGO) for the detection of glucose via an electrochemical oxidation.

187 ace restructuring of Pt(111) electrodes upon electrochemical oxidation/reduction in 0.1 M HClO4 was s

188 tance of MXene electrode architecture on the electrochemical performance and can guide future work on

189 ned graphitic carbon networks show excellent electrochemical performance for the insertion and extrac

190 ure and speed, were first optimized, and the electrochemical performance of these devices was then ev

191 The electrochemical performance recovered upon removal of ni

192 t fabrication, patterning, conductivity, and electrochemical performance.

193 between the defect content and the improved electrochemical performance.

194 al oxide electrodes have exhibited excellent electrochemical performance.

195 However, the electrochemical performances of the various systems are

196 The influence of synthesis conditions on electrochemical performances was investigated and discus

197 In this work, dual electrochemical pH and cell-attachment sensor arrays wer

198 The nanocomposite was synthesized by electrochemical polymerization of aniline and 3-aminoben

199 Subsequently, an electrochemical polymerization procedure was carried out

200 uron specific enolase (NSE) was developed by electrochemical polymerizing ionic liquid, which was fun

201 due to its favorable combination of negative electrochemical potential and high theoretical capacity.

202 power generation technology that produces an electrochemical potential difference from a salinity gra

203 because of its adaptable conductance to the electrochemical potentials of both sides of the QDs laye

204 oaches, a hybrid electrophoresis device with electrochemical preprocessing and contactless conductivi

205 A simple electrochemical process was used to grow an ultrathin si

206 could be simultaneously detected during the electrochemical process.

207 A strong correlation between the electrochemical processes and the fluorescence was found

208 Control of interfacial morphology in electrochemical processes is essential for applications

209 nd low normalized space velocity obtained in electrochemical processes with two - dimensional electro

210 evolution and oxidation state changes during electrochemical processes.

211 oroether (HFE) solvent-based electrolyte for electrochemical processing and characterization of organ

212 l now, they were not considered suitable for electrochemical processing.

213 To validate the method, the electrochemical properties of different mediators (hexac

214 ii) the coating method significantly affects electrochemical properties of NDs and (iii) the ND coati

215 -type electrical conductivity and remarkable electrochemical properties of the exfoliated crystals, s

216 number of fundamental studies unveiling the electrochemical properties of this "wonder" material.

217 lytic reactions, but also provides excellent electrochemical properties such as high faradic-to-capac

218 We report on the superior electrochemical properties, in-vivo performance and long

219 duce ATP by rotary catalysis, powered by the electrochemical proton gradient across the membrane.

220 ule, followed by substrate addition and fast electrochemical pulse amperometric detection.

221 ermore, there is broad interest in selective electrochemical quantification of H2O2, because it is of

222 from the surface of this catalyst during the electrochemical reaction has been proposed to be benefic

223 f cell components in the presence of desired electrochemical reaction products is clearly problematic

224 gating effects, the electrostatic doping and electrochemical reaction, are distinguished at various g

225 to probe their structural changes during the electrochemical reaction.

226 and transfer in liquid-solid, gas-solid and electrochemical reactions and exhibit enhanced performan

227 However, the electrochemical reactions between CO2 (0.04 % in ambient

228 as local light source to initiate photo(bio)electrochemical reactions while acting as sensitive bios

229 mechanistic and kinetic characterization of electrochemical reactions with high electroanalytical se

230 p-down dealloying for efficient chemical and electrochemical reactions.

231 al treatment of the kinetics of outer sphere electrochemical reactions.

232 g the observed profound differences in their electrochemical reactivity and stability.

233 plet microarray platform with the sequential electrochemical read-out of individual droplets.

234 fication procedure by C2CA combined with the electrochemical readout and the magnetic actuation enabl

235 of nanoporous gold by surface relaxation via electrochemical redox cycling is reported.

236 Here, we used mediated electrochemical reduction (MER) to directly quantify the

237 surface binding of salts of the cations and electrochemical reduction gave a mixture of chemically d

238 Electrochemical reduction of biomass-derived platform mo

239 i NWs) in bulk quantities through the direct electrochemical reduction of CaSiO3 , an abundant and in

240 The electrochemical reduction of CO2 is known to be influenc

241 Electrochemical reduction of CO2 to ethanol, a clean and

242 The unique high selectivity of copper in the electrochemical reduction of CO2 to hydrocarbons has cal

243 Using the electrochemical reduction of dioxygen catalyzed by iron

244 icated by focused ion beam milling and their electrochemical response from a reversible redox pair wa

245 Herein, we investigate the electrochemical response of multi-valent CNPs in presenc

246 onstration of the simultaneous evaluation of electrochemical responses from multiple, unique fabricat

247 The electrochemical responses of purified low and high densi

248 The electrochemical responses of this device to a reversible

249 ormed with untreated plants and the obtained electrochemical results clearly proved the formation of

250 ive reporter molecules irrespective of their electrochemical reversibility in individual nanoliter-si

251 Herein, we develop an electrochemical sacrificial-template strategy to fabrica

252 and fabrication of a versatile and low-cost electrochemical-scanning probe microscope (EC-SPM) is pr

253 The electrochemical sensing activities of the graphene-elect

254 This article discusses current trends in the electrochemical sensing and biosensing of DNA methylatio

255 ong with the appropriate signal suitable for electrochemical sensing applications.

256 paper-based analytical device (EmuPADs) for electrochemical sensing of ketamine.

257 ss of size-selective ionophores dedicated to electrochemical sensing of molecular ions.

258 ssisted deposition technique to increase the electrochemical sensing properties.

259 The electrochemical sensor exhibited excellent sensitivity (

260 A molecularly imprinted electrochemical sensor for neuron specific enolase (NSE)

261 tive and specific imprinted polymer modified electrochemical sensor for the targeted detection, remov

262 ng this challenge, the use of screen-printed electrochemical sensor is reported.

263 These results suggest this electrochemical sensor is suitable for environmental and

264 The proposed non-enzymatic electrochemical sensor was used for determining H2O2 in

265 This review presents an overview of recent electrochemical sensors and biosensors based on graphene

266 further development of new membrane protein electrochemical sensors and enzyme electrodes.

267 Electrochemical sensors are an attractive platform for a

268 have promising implications in the design of electrochemical sensors or biosensors for the detection

269 Electrochemical sensors that employ roughness to increas

270 These attributes also make electrochemical sensors well suited for wearable applica

271 te two individual cases where we use NRS and electrochemical SERS (EC-SERS) to detect IV therapy anal

272 tions as well as the comparison of different electrochemical set-ups also enhanced the applicability

273 The assay exploits the difference in electrochemical signals from a soluble redox indicator,

274 aterials have very attractive ON/OFF ratios, electrochemical stabilities, and coloration efficiencies

275 A promising new approach, the electrochemical steric hindrance hybridization assay (eS

276 The electrochemical stimulus used for luminescence generatio

277 Using in situ electrochemical strain microscopy (ESM), we demonstrate

278 lization of deep eutectic solvents (DESs) in electrochemical studies has grown in recent years due to

279 uced on pyrite at the Eh-pH predicted by the electrochemical study.

280 gnitude higher than any similar enzyme-based electrochemical superoxide sensor and is attributed to t

281 Electrochemical surface stress is important in nanomater

282 Using a H2 recycling electrochemical system (HRES) we achieved high TAN trans

283 present a simple yet efficient membrane free electrochemical system for P removal and recovery as cal

284 This electrochemical system is applied to glucose determinati

285 cted in the catholyte of a three-compartment electrochemical system, with up to 880 mg of Nd L(-1) ac

286 interface is important for designing better electrochemical systems where their applications may inc

287 Multimodal electrochemical technique incorporating both open circui

288 from co-deposited magnetite in situ by other electrochemical techniques and is undetectable ex situ b

289 Electrochemical techniques are emerging as alternatives,

290 Either of the electrochemical techniques studied could be successfully

291 osensor was characterized using two types of electrochemical techniques; electrochemical impedance sp

292 lower risk of chloride oxidation compared to electrochemical technologies and high rates and independ

293 ntially expands the application of microbial electrochemical technologies.

294 tients with AMI was assessed on the basis of electrochemical threshold values (this requires the refe

295 on as a cut-and-paste exclusive and flexible electrochemical transducer.

296 d associated materials for several different electrochemical transformations involving water, hydroge

297 Organic electrochemical transistors (OECTs) are promising transd

298 Materials for organic electrochemical transistors (OECTs) require both efficie

299 n acetonitrile-water mixture, at neutral pH, electrochemical water oxidation to hydrogen peroxide was

300 GC microelectrodes have more than 70% wider electrochemical window and 70% higher CTC (charge transf