ライフサイエンスコーパス: capacitive

1 pid, highly sensitive, specific and low-cost capacitive affinity biosensor is presented here for labe

2 Prior to capacitive analysis, the developed particles were immobi

3 are described, although the focus is kept on capacitive and hybrid energy storage systems.

4 Capacitive and impedimetric assays showed equivalent res

5 They possess resistive, capacitive and inductive components that can concurrentl

6 hypothesized that MTs also possess intrinsic capacitive and inductive properties, leading to transist

7 sensory system to categorically distinguish capacitive and resistive properties of objects.

8 We employ a capacitive approach technique in our home-built Scanning

9 Both the impedimetric and capacitive approaches reported similar values of experim

10 ort the development of a simple and powerful capacitive aptasensor for the detection and estimation o

11 uring in vitro experiments, when using three capacitive architectures: stripped, interdigitated and c

12 This capacitive assay had a cut-off of 1.36% (confidence inte

13 Accordingly, redox tagged capacitive assays are suitable for the development of mu

14 Nonetheless capacitive assays presented better reproducibility with

15 Thus, by using capacitive assays, an improvement on the analytical perf

16 ined results to those of previously reported capacitive assays.

17 ociated with charge transfer resistance) and capacitive (associated with faradaic density of states)

18 these ACTs an ideal electrical double-layer capacitive behavior.

19 5), capacitive behaviour without discharge voltage plateaus

20 Capacitive bioaffinity detection using microelectrodes i

21 EP), we are able to develop an ACEK enhanced capacitive bioaffinity sensing method to realize simple,

22 This capacitive bioanode was compared with a noncapacitive bi

23 based on capacitive granules: the fluidized capacitive bioanode.

24 o the anodic compartment of an MFC to form a capacitive bioanode.

25 s work, we have developed a whole-cell based capacitive biosensor (WCB) to determine the biological t

26 ure possible applications of this MIPs-based capacitive biosensor for environmental and forensic anal

27 label-free and reagent-free peptide mimotope capacitive biosensor has been developed for cancer drug

28 Use of a highly sensitive, selective capacitive biosensor is reported for label-free, real-ti

29 The feasibility of the capacitive biosensor is validated using thrombin as a mo

30 phetamine was determined to be 10muM in this capacitive biosensor system.

31 nation of microcontact imprinting method and capacitive biosensor technology.

32 ted on a DMF platform with an interdigitated capacitive biosensor to detect different concentrations

33 s paper presents a label-free affinity-based capacitive biosensor using interdigitated electrodes.

34 We have developed a simple, robust capacitive biosensor using microwires coated with Zika o

35 lective and sensitive microcontact imprinted capacitive biosensor was developed for the detection of

36 A highly sensitive, capacitive biosensor was developed to monitor trace amou

37 d on the surface of a field-effect-based DNA capacitive biosensor.

38 implementing electromagnetic microcoils and capacitive biosensors on a CMOS (complementary metal oxi

39 The low sensitivity issue of capacitive biosensors was overcome with two innovations:

40 Redox capacitive biosensors were recently introduced as a pote

41 The Orai1 ion channel allows capacitive Ca(2+) influx after Ca(2+) release from the e

42 nsport comparable to electrical-double-layer-capacitive carbons.

43 nstrated to remove select contributions from capacitive characteristics changes of the electrode both

44 subnanometre pores without compromising the capacitive characteristics, improving their importance f

45 nstance, ultranarrow pores provide excellent capacitive characteristics.

46 sorption and desorption of carbon dioxide by capacitive charge and discharge of electrically conducti

47 that the platinum-based electrodes possess a capacitive charge carrying mechanism suitable for stimul

48 anges (milliseconds) were close to the SGLT1 capacitive charge movements.

49 O(2) (B) exhibits impressively high level of capacitive charge storage, e.g., ~53% at 0.5 mV s(-1) ,

50 rates a light emitting diode (LED) through a capacitive charge/discharge cycle, which is directly cor

51 ), which have the net effect of reducing the capacitive charging and decreasing the time required to

52 If one maps this redox capacitive charging as a function of electrode potential

53 Capacitive charging of the electrical double layer at op

54 control the type of charge injection, i.e., capacitive charging or ion intercalation, via the choice

55 rodes occurs on a longer time scale than the capacitive charging time scales of our CDI cell.

56 -metallic conductivity transition, quantized capacitive charging, and anisotropic conductivity charac

57 NIR, which can be dynamically modulated via capacitive charging.

58 requency-resolved manner, through associated capacitive charging.

59 asures of aorto-femoral pulse wave velocity, capacitive compliance (C1), and oscillatory compliance (

60 fast charge-transfer kinetics and increased capacitive contribution in hydrogen-treated 3D graphene.

61 existence of induced charging currents, the capacitive contribution to the total current is differen

62 polar resistive switching, with a concurrent capacitive contribution, is governed by an ultrathin (<3

63 based method for removal of the differential capacitive contributions to the FSCV current.

64 We also achieve capacitive control of the electrophysiology in isolated

65 plementation of oscillator and bidirectional capacitive coupling allow small footprint area and low o

66 Capacitive coupling and direct shuttling of charges in n

67 The ionization is induced by a capacitive coupling between an electrode and the sample.

68 igned stretchable antennas in which parallel capacitive coupling circuits yield several independent,

69 ge operation via an enhanced gate-to-channel capacitive coupling is unable to deliver high-performanc

70 ith a shielding layer effectively suppresses capacitive coupling of stimulation signals.

71 By capacitive coupling the latter creates electric potentia

72 ssDNA whose potential is determined by both capacitive coupling with a primary, addressable gate ele

73 electromagnetic fields, direct current, and capacitive coupling) increased the odds of a successful

74 de is purely capacitive (we refer to this as capacitive coupling).

75 d the relative role of its two components, a capacitive current (Ic) and a resistive current (Iion),

76 particularly important when the ratio of the capacitive current and the total current is close to uni

77 Utilizing the principles of capacitive current changes due to selective binding of g

78 y rectifying Cl(-) currents with significant capacitive current components.

79 The capacitive current densities of these 3D-electrodes as w

80 posed method allowed us to separate the real capacitive current even in the situations where the conv

81 This moving permanent charge induces capacitive current flow everywhere.

82 C potential is applied to the sample and the capacitive current generated at the tip is recorded as a

83 n to the total current is different from the capacitive current measured in the absence of electroact

84 ochemical properties such as high faradic-to-capacitive current ratios, high current density and elec

85 relaxation, thus leading to an asymmetrical capacitive current that briefly depolarized the cell.

86 e photothermally induces a cell-depolarizing capacitive current, and predicts that delivering a given

87 tiveness by increasing the magnitude of this capacitive current.

88 lead to a large uptake of charge and a large capacitive current.

89 electrochemical assays is the nonfaradaic or capacitive current.

90 that NDC is minimized as it acts to increase capacitive currents and decrease the solvent window.

91 By this, high capacitive currents caused by an increased electrochemic

92 In addition, undesirable capacitive currents disguise the faradaic currents from

93 nates from the coupling between faradaic and capacitive currents in the presence of uncompensated res

94 An analysis of the capacitive currents obtained under voltage clamp in mole

95 n signals are absent, and instead only small capacitive currents or currents attributed to redox chem

96 This allows us to record light-induced capacitive currents that reflect KR2's ion transport act

97 lop a method that separates the faradaic and capacitive currents, combining simulation and experiment

98 nalysis (i.e., widest solvent window, lowest capacitive currents, stable and reproducible current res

99 DC signature in the solvent window and lower capacitive currents, this is not a practical procedure f

100 utant (E268A) was shown to exhibit transient capacitive currents.

101 odes are being investigated for use in mixed capacitive deionization (CDI) and battery electrode deio

102 Capacitive deionization (CDI) as a class of electrochemi

103 In order for capacitive deionization (CDI) as a water treatment techn

104 port the use of ultramicroporous carbon as a capacitive deionization (CDI) electrode for selectively

105 Capacitive deionization (CDI) is a promising desalinatio

106 Capacitive deionization (CDI) is a promising procedure f

107 Capacitive deionization (CDI) is a rapidly emerging desa

108 Capacitive deionization (CDI) is an emerging technology

109 Capacitive deionization (CDI) is an emerging water desal

110 Capacitive deionization (CDI) is an emerging water treat

111 Capacitive deionization (CDI) is currently limited by po

112 silicon templates can enable salt removal in capacitive deionization (CDI) ranging from 0.36% by mass

113 s is critical to maximizing the longevity of capacitive deionization (CDI) systems.

114 Capacitive deionization (CDI) technologies couple electr

115 The energy efficiency of capacitive deionization (CDI) with porous carbon electro

116 Capacitive deionization (CDI), a class of electrochemica

117 Capacitive deionization (CDI), based on the principle of

118 , a high salt removal rate in flow-electrode capacitive deionization (FCDI) can be achieved theoretic

119 to elucidate such impacts in flow-electrode capacitive deionization (FCDI) cells.

120 s of water desalination using flow-electrode capacitive deionization (FCDI) is described in this stud

121 Membrane capacitive deionization (MCDI) is a water desalination t

122 inuous flow ED and constant-current membrane capacitive deionization (MCDI) to systematically evaluat

123 r splitting regimes) and the two in membrane capacitive deionization (ohmic and water splitting regim

124 e areas, indicating their huge potential for capacitive deionization applications.

125 An inverted capacitive deionization cell was constructed using amine

126 Biofouling commonly occurs on carbonaceous capacitive deionization electrodes in the process of tre

127 Electrochemical processes such as capacitive deionization have shown great promise for sal

128 he performance of graphene-based material in capacitive deionization is lower than the expectation of

129 coated electrodes were evaluated in a hybrid capacitive deionization system to understand the relatio

130 ween porous electrodes, either bare (CDI, or capacitive deionization), coated with ionic exchange mem

131 proving their importance for energy storage, capacitive deionization, and electrochemical heat harves

132 ocess (reverse osmosis, electrodialysis, and capacitive deionization, respectively) in salinity gradi

133 t electrodes can be successfully employed in capacitive deionization.

134 me monitoring, illustrates the selective and capacitive detection of Staphylococcus epidermidis in sy

135 A novel urea biosensor based on capacitive detection was developed using nano-sized mole

136 The variable MEMS capacitive device is able to detect and forecast blockag

137 Here, it is argued that current capacitive device models neglect lateral ion currents in

138 at molecular redox films are electrochemical capacitive devices possessing specific field effect in w

139 hermore, these transistors with double-layer capacitive dielectric can mimic the synaptic behavior of

140 to-electric storage element can operate with capacitive displacement charge and potentially reach 1-1

141 sensitivity and specificity of a label-free capacitive DNA detection system using immobilized pyrrol

142 Energy extraction based on capacitive Donnan potential (CDP) is a recently suggeste

143 The accumulation of Cu(+) ions via an ionic capacitive effect at the Schottky junction under the dir

144 Via capacitive effect, a gate field modifies the carrier den

145 as large as that caused by the conventional capacitive effect.

146 es of living organisms, which comes from the capacitive effects generated by the cell membrane struct

147 st be optimized to balance piezoelectric and capacitive effects.

148 ne (Fe-AAPyr); (ii) the use of an additional capacitive electrode (additional electrode, AdE) which i

149 ode and the low impedances of the additional capacitive electrode and the MFC anode permitted to achi

150 With a capacitive electrode it is possible to use the MFC simul

151 The capacitive electrode outperformed the noncapacitive elec

152 During polarization curves the capacitive electrode reached a maximum current density o

153 The system contained a capacitive electrode that was inserted into the anodic c

154 g the charge recovery of each electrode, the capacitive electrode was able to recover 52.9% more char

155 n of charging and 20 min of discharging, the capacitive electrode was able to store a total of 22,831

156 The trypsin-MIP capacitive electrode was used for ~80 assays during 2 mo

157 ic pumping scheme can be implemented through capacitive electrodes surrounding the device that allows

158 rformed with trypsin-imprinted (trypsin-MIP) capacitive electrodes using standard trypsin solutions i

159 -the-art for future transparent, conductive, capacitive electrodes, and translate into technologicall

160 Recently, it was shown that AC-driven, capacitive electroluminescent devices with carbon nanotu

161 AM) dendrimer and carbon nanotubes (CNTs) on capacitive electrolyte-insulator-semiconductor (EIS) fie

162 extractable charge stored under operation: a capacitive electronic charge ( approximately 0.2 muC/cm(

163 pect to the force capacity per electrostatic capacitive energy and are robust to defects or damage th

164 lable pathway to enable the high-temperature capacitive energy applications of a wide range of engine

165 This suggests that the capacitive energy of the interfaces stabilizes these int

166 networks (PPNs) are attractive materials for capacitive energy storage because they offer high surfac

167 nanocomposites have outstanding high-voltage capacitive energy storage capabilities at record tempera

168 high-temperature dielectric materials toward capacitive energy storage has been driven by the rise of

169 ards the application of 2D nanomaterials for capacitive energy storage is provided.

170 and high power capabilities associated with capacitive energy storage make this approach an attracti

171 sed EDLC electrode materials in the field of capacitive energy storage, from the viewpoint of materia

172 CV displays capacitive features associated with ss- and ds-ON.

173 The reusability of capacitive field-effect electrolyte-insulator-semiconduc

174 However, in the newly emerging, capacitive, field-activated AC-driven organic devices, c

175 h a p < 0.01 in a reagentless and label-free capacitive format.

176 uble layer (EDL) near a charged surface in a capacitive format.

177 ntensive electromagnetic field into a spiral capacitive gap (around 200 mum), which provides sufficie

178 gy to heat-up droplets that pass through the capacitive gap.

179 netic reed switches connected in between the capacitive gaps of each split-ring resonator.

180 ere, we show a novel reactor design based on capacitive granules: the fluidized capacitive bioanode.

181 In this paper, we demonstrate a touchless capacitive imaging-based sensor in the situation where t

182 The ACEK-enhanced capacitive immunosensor is a platform technology, and ca

183 The capacitive immunosensor presented here employs elevated

184 forms [differential pulse voltammetry (DPV), capacitive impedimetry (CI), and PM] were integrated wit

185 r the piezoelectric microgravimetry (PM) and capacitive impedometry (CI) determination of ATP, respec

186 cteristics (e.g. bandwidth, determination of capacitive/inductive contribution to sensor's impedance

187 Utilizing the capacitive interface at the ionic-electronic contact, th

188 (impedimetric) and redox tethered receptive (capacitive) interfaces engineered by self-assembly monol

189 with the use of models that account for the capacitive leakage present in the reference channels of

190 ty, which could be explained by the lopsided capacitive load imposed on the proximal end of the AIS b

191 ion is finely tuned with the somatodendritic capacitive load, serving as a homeostatic regulation of

192 a time constant of ~20 ms, which represents capacitive loading of neighboring cells through gap junc

193 nce yarn supercapacitor by depositing pseudo-capacitive materials on the outer surface of the carbon

194 m(2) (8.8 mF/g) without the use of any other capacitive materials.

195 er presents a microwave sensor designed as a capacitive matrix for label-free Escherichia coli detect

196 he mean value of capacitances' change in the capacitive matrix sensor is an indicator of the bacteria

197 Here, we present a method based on capacitive measurements, which allows the detailed, auto

198 lse waveform with analytical calculations of capacitive membrane charging/discharging, also known as

199 in turn, could also serve as models to study capacitive memory and signal processing in neuronal memb

200 le, voltage-controlled memcapacitor in which capacitive memory arises from reversible and hysteretic

201 e first time, the use of the electrochemical capacitive method for the detection of NS1 DENV biomarke

202 ensing of aflatoxin B1(AFB1) by field effect capacitive method using electrophoretically deposited re

203 at tuneable mode coupling can be achieved in capacitive microelectromechanical devices with dynamic e

204 We manufactured and tested a capacitive micromachined ultrasound transducer (CMUT)-ba

205 is (PRO), reverse electrodialysis (RED), and capacitive mixing (CapMix) and provide perspectives on t

206 Capacitive mixing (CapMix) is a promising class of SGE t

207 is (PRO), reverse electrodialysis (RED), and capacitive mixing (CapMix), are being developed to recov

208 gradient energy that can be obtained through capacitive mixing based on double layer expansion depend

209 ar, osmotic power and blue energy as well as capacitive mixing); applications in detergency and clean

210 dance-based biosensor, it was found that the capacitive nature of blood obscures the clotting respons

211 A peak relating to the capacitive nature of the pH CV was identified.

212 silicon support for the membrane contributes capacitive noise and limits integration with microfluidi

213 The high capacitive noise from conventionally used conductive sil

214 ation to the charging time and resistive and capacitive noise.

215 SGE technologies that captures energy using capacitive or battery electrodes, but CapMix devices hav

216 is >10x higher than all previously reported capacitive or resistive pressure sensors.

217 nical sensing technologies (i.e., resistive, capacitive, or piezoelectric) have yet offered a satisfa

218 n neat serum ( approximately 0.5ngmL(-1) for capacitive over approximately 30ngmL(-1) for impedimetri

219 A robust capacitive peak around -0.35 V versus saturated calomel

220 The reversible shift of a capacitive peak in the voltammetric profile of the elect

221 er-associated currents: the recovery rate of capacitive peak, but not of steady state, currents was s

222 n RGM show superior gravimetric and per-area capacitive performance (specific capacitance: 502.78 F g

223 strated to preserve excellent dielectric and capacitive performance after intensive bending cycles.

224 The factors that directly influence capacitive performance are discussed throughout the text

225 he composite electrode displayed an enhanced capacitive performance of 3616 F/g at 8 A/g, and showed

226 ork effectively enhance the conductivity and capacitive performance of the SSCs device.

227 The electrochemical stability, excellent capacitive performance, and the ease of preparation sugg

228 ining Al(2) O(3) nanoplates display a record capacitive performance, e.g., a discharged energy densit

229 ultimodal pores, and an excellent volumetric capacitive performance.

230 ene hydrogels are demonstrated with superior capacitive performances and extraordinary mechanical fle

231 e most crucial factors in the enhancement of capacitive performances.

232 The model also captures the capacitive pile up of ions in the vestibules that link t

233 ng and learning via synapse-like, short-term capacitive plasticity.

234 es that are induced by the electrochemically capacitive, positively charged ferritin.

235 harging voltage of a supercapacitor with the capacitive potential ranges and the capacitance ratio of

236 results provide insight into the predominant capacitive processes occurring at different states of ch

237 ling of the electrical impedance results the capacitive properties of the barrier next to the well-kn

238 The excellent dielectric and capacitive properties of the polymer nanocomposites may

239 le tuning of the surface coverage and redox (capacitive) properties of the polymers, which, in turn,

240 Also, the capacitive readout can be used to establish mixing quali

241 A constant potential capacitive readout of solid-contact ion-selective electr

242 sing Voltage technique in the doping-induced capacitive regime (doping-CELIV) is extended to the case

243 sed on various operating principles, such as capacitive, resistive, or optical sensing.

244 ic arrays of unit cells containing inductive-capacitive resonators and conductive wires.

245 phase angle is broadly defined by the local capacitive response of the electrical double layer (EDL)

246 o that in the bulk solution allows the local capacitive response of the working electrode substrate i

247 proton-coupled redox couples appear over the capacitive response with 0.94 and 1.19 (V vs SHE) pH = 7

248 nanoparticles, exhibit unique resistive and capacitive responses to changes in O2 and H2O.

249 in selectively quantified by electrochemical capacitive sensing (an impedance-derived capacitance met

250 d alternating current electrokinetics (ACEK) capacitive sensing as a new application for rapidly dete

251 We show that capacitive sensing can be used to measure fluid levels,

252 iontronic film is introduced as a thin-film capacitive sensing material for emerging wearable and he

253 an alternating current electrokinetic (ACEK) capacitive sensing method has been reported to demonstra

254 d on an aptamer probe and AC electrokinetics capacitive sensing method that successfully detected BPA

255 Experimental study of the ACEK-enhanced capacitive sensing method was conducted, and the results

256 Our capacitive sensing method was shown to work with bovine

257 The capacitive sensing responses showed clear frequency depe

258 Capacitive sensing technique is used to determine the bo

259 good accuracy is developed to use with ACEK capacitive sensing to produce a true POC technology.

260 The capacitive sensing was compared to traditional concurren

261 e adaption of the protocol for use with ACEK capacitive sensing.

262 ve insulating layer, which is sufficient for capacitive sensing.

263 Results from the capacitive sensor corresponded well with the antimicrobi

264 -resistance problems, a sensitive label-free capacitive sensor developed in our group was investigate

265 n Au patch electrode Ag-SnO(2)/SiO(2)/Si MIS capacitive sensor equipped with a microcontroller was de

266 The proposed capacitive sensor exhibited good selectivity for urea, c

267 The designed capacitive sensor has high selectivity and was able to d

268 Here, an Au metal patch electrode capacitive sensor is introduced for rapid and accurate d

269 ACEK capacitive sensor performance was evaluated using two di

270 Thus the RGO based field effect capacitive sensor provides a combined advantage of both

271 technique incorporating a novel interdigital capacitive sensor with multiple sensing thin film gold m

272 for application as recognition elements in a capacitive sensor.

273 at least 1000 times higher than any existing capacitive sensors and one order of magnitude higher tha

274 eventual leakage current-related problems in capacitive sensors operating in liquid.

275 Using these nanogap capacitive sensors, highly sensitive, label-free aptamer

276 nics) and related stretchable devices (e.g., capacitive sensors, supercapacitors and electroactive po

277 n the signal-to-noise ratio in the generated capacitive signals, allowing the ultraconformal microhai

278 ew method for fabricating textile integrable capacitive soft strain sensors is reported, based on mul

279 demonstrate the promise of using 2D COFs for capacitive storage.

280 m x 1.5 mum devices containing inductive and capacitive structures were designed and fabricated as po

281 ow that this effect allows us to introduce a capacitive susceptibility that assumes a maximum in the

282 f antibacterial susceptibility response by a capacitive system can be done within a short time, 2.5h

283 ative for assaying trypsin and the developed capacitive system might be used successfully to monitor

284 mount of captured enzyme calculated from the capacitive system was 7.9mU/mL which shows the correlati

285 e show a proof-of-principle of the fluidized capacitive system with a total anode volume of 2 L.

286 AC granules after operation in the fluidized capacitive system.

287 e target DNA was directly measured using the capacitive system.

288 nd vast applications in e.g. circuit boards, capacitive touch pads, and radio frequency identificatio

289 Transparent conductive films for capacitive touch screens and pixels of microscopic resis

290 ities for dynamic colorations and multipoint capacitive touch sensing.

291 S films were used as patterned electrodes in capacitive touch sensors and organic photovoltaics to de

292 A surface-capacitive touch system is adopted to sense a touched po

293 based behavioral licking task monitored by a capacitive touch-sensor water spout.

294 -free and reagentless aptasensor, based on a capacitive transducer with simple face-to-face electrode

295 ngly, the combination of SC and SAM bringing capacitive transduction at the forefront of ultrasensiti

296 An affinity sensor based on capacitive transduction was developed to detect a model

297 be optimal; increasing [B] results in higher capacitive values and increases the likelihood of nondia

298 le applications such as grid energy storage, capacitive water deionization, and wastewater treatment.

299 potentials exhibiting biphasic and inverted capacitive waveforms, indicative of varying ion-channel

300 ile current at the other electrode is purely capacitive (we refer to this as capacitive coupling).