ライフサイエンスコーパス: electrokinetic

1 ons is presented to interpret the underlying electrokinetics.

2 Here, using an anti-Brownian electrokinetic (ABEL) trap and in-solution single-partic

3 Using the Anti-Brownian Electrokinetic (ABEL) trap to counteract Brownian motion

4 We employed an anti-Brownian electrokinetic (ABEL) trap to prolong measurements of si

5 We have used an anti-Brownian electrokinetic (ABEL) trap to trap individual protein mo

6 Using an Anti-Brownian ELectrokinetic (ABEL) trap, we isolate single phycobilis

7 ver, be accomplished using the Anti-Brownian ELectrokinetic (ABEL) Trap, which allows extended invest

8 65 fold compared to the results without the electrokinetic accumulation step.

9 Recently, an alternating current electrokinetic (ACEK) capacitive sensing method has been

10 pplicability of enhanced alternating current electrokinetics (ACEK) capacitive sensing as a new appli

11 le to result." With recent development in AC electrokinetics (ACEK), especially in dielectrophoresis

12 ce, we demonstrated a significantly improved electrokinetic actuation and switching microsystem that

13 standing capacity, stability, efficiency and electrokinetics, advancing electrochemical carbon separa

14 on spectroscopy, inverse gas chromatography, electrokinetic analysis, and micro-computed tomography.

15 nfocal laser scanning microscopy (CLSM), and electrokinetic analysis.

16 ofluidic device under the periodic action of electrokinetic and dielectrophoretic forces.

17 The method is compatible with electrokinetic and hydrodynamic injections, with detecti

18 The most common methods are electrokinetic and require an externally applied electri

19 or Ca(2+) and Mg(2+) cations, as revealed by electrokinetic and stability experiments.

20 ls based on experimental data from microslit electrokinetics and ellipsometry.

21 The electrokinetics and hydrodynamics in a hybrid microfluid

22 oint of departure to discuss the structural, electrokinetic, and electrochemical requirements for ach

23 We introduce an on-chip electrokinetic assay to perform high-sensitivity nucleic

24 in developing highly selective and sensitive electrokinetic assays for possible application in clinic

25 is a step toward quantitative measurement of electrokinetics at the single particle level.

26 An electrokinetic-based hydraulic pump is integrated on the

27 digestion in a capillary platform, enabling electrokinetic-based protein extraction and stacking, re

28 lectrical immuno-sandwich assay utilizing an electrokinetic-based streaming current method for signal

29 llary isoelectric focusing (CIEF) as another electrokinetics-based stacking approach, CITP/CZE not on

30 es as a nanoporous membrane and dictates the electrokinetic behavior within the adjoining microchanne

31 gh the LBM that was opposite of the expected electrokinetic behavior.

32 d to understand and simulate the interfacial electrokinetic behaviors.

33 while the hydrodynamic injection eliminates electrokinetic bias during injection, making it attracti

34 ific sensor based on an aptamer probe and AC electrokinetics capacitive sensing method that successfu

35 An accurate, simple and rapid micellar electrokinetic capillary chromatographic method was deve

36 arsenical dyes and then analyzed by micellar electrokinetic capillary chromatography (MEKC).

37 obilities is addressed by employing micellar electrokinetic capillary chromatography coupled to amper

38 idazole residues in egg by means of micellar electrokinetic capillary chromatography in combination w

39 eir contents were then separated by micellar electrokinetic capillary chromatography using the same l

40 Micellar electrokinetic capillary chromatography with electrochem

41 well were processed and analyzed by micellar electrokinetic capillary chromatography with laser-induc

42 nd 2-hydroxyethidium using cationic micellar electrokinetic capillary chromatography with laser-induc

43 rboxaldehyde, cyclodextrin-mediated micellar electrokinetic capillary chromatography, and sheath flow

44 ey undergo additional separation by micellar electrokinetic capillary chromatography.

45 al detection and the selectivity of micellar electrokinetic capillary chromatography.

46 apillary contains an SDS buffer for micellar electrokinetic capillary chromatography.

47 components are further resolved by micellar electrokinetic capillary electrophoresis.

48 Thanks to the advanced electrokinetic characterization implemented in this work

49 The electrokinetic characterization of membranes was complem

50 Electrokinetic characterization of the clean and coated

51 Microemulsion electrokinetic chromatography (MEEKC) is proposed for an

52 es was developed through the use of micellar electrokinetic chromatography (MEKC) coupled to inductiv

53 ng microfluidics, immunoassays, and micellar electrokinetic chromatography (MEKC) is discussed here.

54 A simple, inexpensive micellar electrokinetic chromatography (MEKC) method with UV dete

55 C is demonstrated with LSERs for 74 micellar electrokinetic chromatography (MEKC) systems taken from

56 sis sampling was coupled on-line to micellar electrokinetic chromatography (MEKC) to monitor extracel

57 to cyclodextrin stacking (MCDS) in micellar electrokinetic chromatography (MEKC) using sodium dodecy

58 ediction of retention factor, k, in micellar electrokinetic chromatography (MEKC) using the simple re

59 electrophoresis (SDS micro-CGE) and micellar electrokinetic chromatography (MEKC) were used as the se

60 Micellar electrokinetic chromatography (MEKC) which separates PB-

61 ansient isotachophoresis (tITP) and micellar electrokinetic chromatography (MEKC) with subsequent off

62 ct systems and 16 decoy systems) in micellar electrokinetic chromatography (MEKC).

63 lary zone electrophoresis (CZE) and micellar electrokinetic chromatography (MEKC).

64 previous to their determination by micellar electrokinetic chromatography (MEKC).

65 oducts, followed by separation with micellar electrokinetic chromatography (MEKC).

66 neutral, and basic pH conditions in micellar electrokinetic chromatography (MEKC).

67 of solid-phase extraction (SPE) to micellar electrokinetic chromatography (MEKC).

68 combines the favorable features of micellar electrokinetic chromatography and temperature gradient f

69 velopment of a methodology based on micellar electrokinetic chromatography for the separation of alco

70 tion of dopamine and catechol and a micellar electrokinetic chromatography separation of dopamine and

71 uid chromatography systems, and the micellar electrokinetic chromatography system of sodium dodecylsu

72 nd experimental tests show that the micellar electrokinetic chromatography system of sodium taurochol

73 ral separation is implemented using micellar electrokinetic chromatography using beta-cyclodextrin as

74 ion analysis were then separated by micellar electrokinetic chromatography using sodium dodecyl sulfa

75 ration of dopamine and serotonin by micellar electrokinetic chromatography with amperometric detectio

76 Micellar electrokinetic chromatography with electrochemical detec

77 for cotinine analysis by combining micellar electrokinetic chromatography with enrichment techniques

78 unds were separated and detected by micellar electrokinetic chromatography with laser-induced fluores

79 nanoparticles as pseudostationary phases for electrokinetic chromatography with UV and mass spectrome

80 A new chiral micellar electrokinetic chromatography-laser induced fluorescence

81 zone electrophoresis-MS, and chiral micellar electrokinetic chromatography-mass spectrometry (CMEKC-M

82 paration selectivity from electrophoresis to electrokinetic chromatography.

83 r online sample preconcentration in micellar electrokinetic chromatography.

84 s of TP and TP receptor (TPR) binding, using electrokinetic concentration (EC) and molecular charge m

85 cing between both modules, the PDMS chip for electrokinetic concentration and the substrate for DNA s

86 unosorbent assay (ELISA) using a multiplexed electrokinetic concentration chip.

87 The present study demonstrates an electrokinetic concentration device incorporating charge

88 Here, we interface electrokinetic concentration polarization with droplet m

89 Using selective electrokinetic concentration, we report one-step, liquid

90 mM for both MO-DNA surface hybridization and electrokinetic concentration.

91 This could enable the prediction and electrokinetic control of microbial deposition on surfac

92 Electrokinetic coupling, caused by the negative charge o

93 Combing spectroscopic and electrokinetic data, we identify the rate-determining st

94 Direct-current insulator-based electrokinetics (DC-iEK) is a branch of microfluidics th

95 framework for design and optimization of ac electrokinetic devices.

96 is elegans; and the second system employs an electrokinetic drive for flow control and is suited for

97 electroosmotic flow separation, a high-salt electrokinetic effect.

98 Electrokinetic effects drive the assembly of staggered d

99 then proceed to explore the hypothesis that electrokinetic effects in the bordered pit membrane (BPM

100 In particular, the importance of electrokinetic effects on the motility of Pt-PS Janus sp

101 t had been originally derived to describe AC-electrokinetic effects such as dielectrophoresis, electr

102 lectric field could in principle bring about electrokinetic effects that scale with the Helmholtz-Smo

103 Optoelectric techniques combine optical and electrokinetic effects to create thousands of such indiv

104 hus translational motion is also governed by electrokinetic effects under a naturally occurring or ap

105 ifouling performance should mainly be due to electrokinetic effects, and the electric field simulatio

106 channel, which, due to ionic dehydration and electrokinetic effects, places them in a novel transport

107 ents an experimental characterization of the electrokinetic (EK) and DEP velocities of a set of targe

108 t extract (ME) samples were treated using an electrokinetic (EK) application to investigate the impac

109 ip design that can perform both pressure and electrokinetic (EK) injection is described, and a mixtur

110 ectrophoretic (DEP) velocity counterbalances electrokinetic (EK) motion, that is, electrophoresis (EP

111 tal characterization of linear and nonlinear electrokinetic (EK) parameters, that is, the electrophor

112 s (in concept) a novel approach of combining electrokinetic (EK)-assisted delivery of an oxidant, per

113 ions were developed for optimum simultaneous electrokinetic elution and sample stacking using a trypt

114 The effects of operational factors an on an electrokinetic-enhanced filtration (EKEF) application to

115 electrode approach which directly implements electrokinetic enhancement on a self-assembled-monolayer

116 tions as a model system, we demonstrate that electrokinetic enhancement, which involves in situ stirr

117 Further, we show that such electrokinetic enrichment is rapid, on the order of seco

118 om large extracellular vesicles, followed by electrokinetic enrichment of the targets, leading to an

119 The electrokinetic equilibrium condition (E(EEC)) is a recen

120 - without immobilization -through real-time electrokinetic feedback.

121 combined numerical and experimental study of electrokinetic ferrofluid/water co-flows in microchannel

122 to straighten current streamlines in linear electrokinetic flow (zone electrophoresis).

123 ides of the first-dimension channel, and the electrokinetic flow from these control channels was used

124 post arrays, the dispersion coefficient for electrokinetic flow is a factor of 3-10 less (depending

125 Electrokinetic flow provides a mechanism for a variety o

126 bottom channel walls' stabilizing effects on electrokinetic flow through the depth averaging of three

127 hallenge this notion by reporting the use of electrokinetic flow to transport solutions with molecule

128 attributed to convection from induced charge electrokinetic flow.

129 of chaotic dynamics of a low Reynolds number electrokinetic flow.

130 ear gradients using both pressure-driven and electrokinetic flow.

131 ent model to analyze the coupling effects of electrokinetic flows (EF) such as alternating current el

132 Electrokinetic flows arise due to couplings of electric

133 electrocatalytic reactions and the resulting electrokinetic flows that drive particle motion.

134 Electrokinetic flows were generated in a series of wet-e

135 (PVA) minimize peak broadening by transverse electrokinetic flows.

136 and sodium (Na(+)), into these nanopores by electrokinetic flows.

137 article we report a free-flow variant of an electrokinetic focusing method, namely ion concentration

138 l: A two-stage microRNA detection assay uses electrokinetic focusing to speed up hybridization and a

139 hromatography, the significant advantages of electrokinetic focusing-based separations include high r

140 tion techniques--including optical tweezers, electrokinetic forces (electrophoresis, dielectrophoresi

141 ht focusing requirements; on the other hand, electrokinetic forces and other mechanisms provide high

142 Dominant electrokinetic forces are explained as a function of the

143 es the feasibility of using laminar flow and electrokinetic forces for the efficient, noninvasive sep

144 The toroidal vortices, induced by secondary electrokinetic forces originating out of temperature-dep

145 Here we report a method using AC electrokinetic forces that can guide, accelerate, slow d

146 that f*= O(1), where Re(eof) is the ratio of electrokinetic forces to viscous forces and f*is the non

147 Electrokinetic forces were used to mobilize the sample a

148 Driven by electrokinetic forces, analytes could be flowed rapidly

149 control through the use of optically-guided electrokinetic forces, vortex laser beams, plasmonics, a

150 Electrokinetics in porous media entails complex transpor

151 We have explored the role of electrokinetics in the spontaneous motion of platinum-go

152 esents numerical simulations and analysis of electrokinetic induced mixing in a microchamber in the p

153 Electrokinetic injection and separation were used with f

154 the sample injection plug, and to eliminate electrokinetic injection bias provides a powerful approa

155 portance is clearly portrayed in the case of electrokinetic injection for electrophoretic separations

156 Electrokinetic injection of fluorescent dye (Cy3) labele

157 The electrokinetic injection of sodium dodecyl sulphate (SDS

158 d to integrate protein concentration with an electrokinetic injection scheme.

159 , which was filled with the PCR cocktail, by electrokinetic injection.

160 atability is explored using nine consecutive electrokinetic injections of a K(+), Na(+), and Li(+) mi

161 Rapid electrokinetic injections of the LC effluent into the CE

162 ections are not significantly different from electrokinetic injections under similar separation condi

163 have a more stable chemical composition than electrokinetic injections, with peak area relative stand

164 We describe a concentric-flow electrokinetic injector for efficiently delivering micro

165 nd investigate their potential to regularize electrokinetic instabilities.

166 found accurate to predict both the observed electrokinetic instability patterns and the measured thr

167 Electrokinetic instability refers to unstable electric f

168 Electrokinetic ion transport in a pH-regulated nanopore,

169 e confined microchannels for observation, AC electrokinetics is demonstrated for capturing bacteria t

170 Here, we demonstrate a novel electrokinetic liquid biosensing method for the sensitiv

171 mally enhanced DEP will broaden the limit of electrokinetic manipulations in high-conductivity media.

172 hysics-based numerical model to simulate the electrokinetic mass transport of short interacting ssDNA

173 as been accomplished in our current work via electrokinetic means allowing a significant increase in

174 In this paper, we develop a simple electrokinetic means for fractionating protein samples a

175 Electrokinetic measurements are consistent with a mechan

176 In this work we showed how thorough electrokinetic measurements can provide essential inform

177 Electrokinetic measurements typically distinguish betwee

178 t-potential (i-V) curves in conical nanopore electrokinetic measurements, is quantitatively correlate

179 ere analyzed by dynamic light-scattering and electrokinetic measurements.

180 ed and suggest the importance of a unique TM electrokinetic mechanism.

181 Furthermore, the capacity of the electrokinetic method for direct electrical detection of

182 Here, we present a novel electrokinetic method termed stochastic electrotransport

183 separation efficiency, we primarily employed electrokinetic methods for elution and separation after

184 Electrokinetic methods that conveniently concentrate cha

185 n be harnessed to promote mixing for various electrokinetic microfluidic applications.

186 e reported from a combined optical force and electrokinetic microfluidic device that separates indivi

187 applications such as liquid crystal-enabled electrokinetics, micropumping and mixing.

188 this work that dispersion of analytes during electrokinetic migration is also the results of Taylor d

189 is induced in the direction opposite to the electrokinetic migration of the analyte.

190 ow concentrations of the HbA1c obtained from electrokinetic mixing assisted and conventional immunoas

191 The technology proposed here uses electrokinetic mixing of the reagents involved in a sand

192 btained with conventional immunoassay, while electrokinetic mixing still facilitated acquisition of s

193 The electrokinetic mixing technique has the potential to imp

194 duced by approximately a factor of five when electrokinetic mixing was employed.

195 oretic mobility than live cells, whereas the electrokinetic mobilities of live and dead cells were in

196 pectroscopy, second harmonic scattering, and electrokinetic mobility measurements.

197 An electrokinetic model of the ocular surface epithelium wa

198 Alternating current (ac) electrokinetic motion of colloidal particles suspended i

199 affect mechanical properties and to generate electrokinetic motions.

200 ressed the electroosmotic flow; allowing the electrokinetic movement of DS(-) monomers and micelles i

201 .15-7.2) x 10(8)-fold lower than that of the electrokinetic network at the junction of the sample int

202 Flow splitting into the electrokinetic network from hydrodynamic flow in the sam

203 n of the sample introduction channel and the electrokinetic network.

204 k, we propose a new approach inspired in the electrokinetics of soft particles: a layer of polyelectr

205 The results illustrated that electrokinetic particle trapping can occur by linear and

206 Rapid electrokinetic patterning (REP), an optoelectrokinetic t

207 esis (DEP) and electrorotation (ROT) are two electrokinetic phenomena exploiting nonuniform electric

208 Electrokinetic phenomena such as dielectrophoresis and e

209 addition to capable of interpreting relevant electrokinetic phenomena, the results gathered also prov

210 is primarily due to a catalytically induced electrokinetic phenomenon and that other mechanisms, suc

211 We demonstrate here a new electrokinetic phenomenon, Electroosmotic flow (EOF) rec

212 ind that tetramethylammonium ions change the electrokinetic potential and the water structure but do

213 Electrokinetic potential measurements of PI(4,5)P2 conta

214 ses that are dependent on buffer type, mcDNA electrokinetic potential, and temperature conditions.

215 rgeted particles with near-constant size and electrokinetic potential.

216 te integration of isotachophoresis (ITP), an electrokinetic preconcentration and extraction technique

217 e, we use isotachophoresis (ITP), a powerful electrokinetic preconcentration and separation technique

218 Electrokinetic preconcentration coupled with mobility sh

219 Herein, we apply electrokinetic preconcentration of the neuropeptide onto

220 Electrokinetic principles such as streaming current and

221 litated transport is largely governed by the electrokinetic properties and dispersion stability (resi

222 Additionally, an extensive evaluation of the electrokinetic properties and hydrodynamic diameters of

223 The presented electrokinetic properties combined with simple, low-cost

224 "corona", of NOM alters the hydrodynamic and electrokinetic properties of diamond nanoparticles (DNPs

225 kinetic theory, coupled with measurements of electrokinetic properties of plant materials from the li

226 lular polymeric substances (EPS) components, electrokinetic property, and hydrophobicity of these int

227 w confinement of a lysis buffer, followed by electrokinetic purification of nucleic acids from the sa

228 ination of first principles calculations and electrokinetic rate theories.

229 lyte under reversed polarity that results in electrokinetic rejection of matrix interferences at the

230 Here, we present a simple and fast electrokinetic removal method of DS(-) from small volume

231 icrodevices make SEBS a quality material for electrokinetic research and application development.

232 The electrokinetic response was only exhibited by a subpopul

233 This assay integrates electrokinetic sample focusing using isotachophoresis (I

234 The laser-induced fluorescence detection and electrokinetic sample injection process in capillary ele

235 rodynamic sample introduction is superior to electrokinetic sample introduction.

236 by applying an electric field, also known as electrokinetic sample introduction.

237 phase EE will enable new possibilities using electrokinetic sample pretreatment for fully automated,

238 We also present a method we term electrokinetic separation by ion valence (EKSIV) whereby

239 We demonstrate a method we term electrokinetic separation by ion valence, whereby both i

240 We further demonstrate electrokinetic separation of two anionic fluorophores wi

241 Electrokinetic separation techniques in microfluidics ar

242 Among a number of electrokinetic separation techniques, transient capillar

243 osite direction to nontarget molecules using electrokinetic separation.

244 Under optimum chemical (3 mM NaOH, pH 11.5), electrokinetic (separation voltage +750 V, injection +15

245 as an electric valve for charged species in electrokinetic separations.

246 se of capillary zone electrophoresis with an electrokinetic sheath-flow electrospray interface couple

247 e, shape and surface charge to influence the electrokinetic signals and consequently, the sensitivity

248 isolate rare cells from complex mixtures, an electrokinetic sorting methodology was developed that ex

249 The electrokinetic speed fields were also compared to corres

250 To solve this problem, an electrokinetic stacking injection (EKSI) scheme was deve

251 Electrokinetic studies indicate that the improved cataly

252 Electrokinetic studies provide insights into the mechani

253 These electrokinetic studies, combined with recent XAS studies

254 This work includes electrokinetic studies, cyclic voltammetric analysis, an

255 entration of sorbed Ca(II), whereas previous electrokinetics studies clearly show that Ca(2+) is the

256 only for advancing the fundamental nanoscale electrokinetic study as well as interfacial ion transpor

257 vel method using resistive pulse sensors for electrokinetic surface charge measurements of nanopartic

258 In nanometer-scale electrokinetic systems, the electric double layer thickn

259 plicability of continuum theory to nanoscale electrokinetic systems.

260 The electrokinetic technique achieves a loading efficiency o

261 In this work we implement an electrokinetic technique for the separation of trypanoso

262 We present an electrokinetic technique to increase the reaction rate a

263 We use standard electrokinetic theory, coupled with measurements of elec

264 The mechanism of apparent "electrokinetic thinning/thickening" is proposed to expla

265 Electrokinetic tip-sample forces were predicted from top

266 arge reservoirs, is proposed to regulate the electrokinetic translocation of a soft nanoparticle (NP)

267 Electrokinetic translocation of biomolecules through sol

268 usefulness of continuum theory in predicting electrokinetic transport and electrophoretic separations

269 is paper, we report an experimental study of electrokinetic transport and separation of double-strand

270 The governing equations for the electrokinetic transport are solved by a high-efficiency

271 With nonreactive and reactive electrokinetic transport experiments combined with proce

272 del provides quantitative descriptions of ac electrokinetic transport for the given target species in

273 e present an experimental study of nanoscale electrokinetic transport in custom-fabricated quartz nan

274 Electrokinetic transport in fluidic channels facilitates

275 eometric characteristics of roughness on the electrokinetic transport in microchannels are therefore

276 e present a numerical framework to model the electrokinetic transport in microchannels with random ro

277 Our results have important implications on electrokinetic transport in porous media and may greatly

278 as a boundary condition for the nanochannel electrokinetic transport model.

279 sh an energy barrier for either diffusion or electrokinetic transport of cations through the nanomete

280 In this article, we analyze the electrokinetic transport of charged samples through rect

281 the nanopore wall, which in turn affects the electrokinetic transport of ions, fluid, and particles w

282 Ms yield information regarding diffusive and electrokinetic transport of protons.

283 ormative analytical parameter to analyze the electrokinetic transport through broadly defined nanopor

284 Electrokinetic transport was achieved by applying up to

285 Electrokinetic transport within a buffer-filled microcha

286 fluorescence detection, (ii) electrodes for electrokinetic transport, (iii) a primary membrane to re

287 We developed a feedback-based anti-Brownian electrokinetic trap in which classical thermal noise is

288 brium state of DNA by using an anti-Brownian electrokinetic trap to confine the center of mass of the

289 single-molecule technique, the anti-Brownian electrokinetic trap, to study LH2 in a solution-phase (n

290 edback trapping provided by an Anti-Brownian ELectrokinetic trap.

291 The electrokinetic trapping and collection can be maintained

292 Using this electrokinetic trapping concentrator, we could achieve a

293 sample preconcentration device based on the electrokinetic trapping mechanism enabled by nanofluidic

294 od, based on the principles of anti-Brownian electrokinetic trapping of single fluorescent proteins,

295 Utilizing the preconcentration (electrokinetic trapping) directly from cell lysate (1 mM

296 Anti-Brownian electrokinetic traps have been used to trap and study th

297 channel geometry reproduced the experimental electrokinetic velocity field, quantitatively accounting

298 micro interdigitated electrode chip, and AC electrokinetics was employed to accelerate the binding o

299 on DNA concentration techniques are based on electrokinetics, which require an external electric fiel

300 sity functional theory, implicate a shift in electrokinetic zone between Co and Ni hangman porphyrins